CN1409828A

CN1409828A - optical apparatus which uses virtually imaged phased array to produce chromatic dispersion

Info

Publication number: CN1409828A
Application number: CN 00817151
Authority: CN
Inventors: 白崎正孝; 西蒙·曹小帆
Original assignee: Fujitsu Ltd
Current assignee: Fujitsu Ltd
Priority date: 1999-12-14
Filing date: 2000-12-13
Publication date: 2003-04-09
Anticipated expiration: 2020-12-13
Also published as: JP2004500600A; JP4373046B2; CN100514118C; EP1252544A1; AU2727001A; WO2001050177A1

Abstract

A VIPA generator (240) produces a light traveling from the VIPA generator (240), and the mirror (254) reflects the light back to the generator (240).

Description

Use virtual image phased array to produce the optical devices of chromatic dispersion

Cross reference to related application

The right of priority of the U.S. Patent application 09/576,541 that the application requires to submit on Dec 14th, 1999 U.S. Patent application was submitted at May 23 in 09/461,277,2000, its content is contained in this for your guidance.

The right of priority that the U.S. Patent application that the application also requires to submit on Dec 4th, 2000 " uses virtual image phased array to produce the optical devices of chromatic dispersion ", its invention people is Simon Cao and Masataka Shirasaki, application number is also unallocated, lawyer's number of documents is 21.1930cip2, and its content is contained in this for your guidance.

The U.S. Patent application 08/796,842 that the application's subject content relates on February 7th, 1997 to be submitted; The U.S. Patent application 08/685,362 that July 24 in 1996 submitted; And on August 13rd, 1997 U.S. Patent application 08/910,251 submitted; Its content is contained in this for your guidance.

Background of invention

1. invention field

The present invention relates to produce the device of chromatic dispersion, it is used to compensate the chromatic dispersion of accumulating in optical fiber transmission line.The present invention relates to a kind of method more specifically, it uses virtual image phased array to produce chromatic dispersion.

2. background technology

Fig. 1 illustrates the synoptic diagram that is used for by the conventional fiber communication system of Optical Fiber Transmission information.Referring now to Fig. 1 (A),, transmitter 30 sends to receiver 36 to pulse 32 by optical fiber 34.Unfortunately, the chromatic dispersion of optical fiber 34 is also referred to as " wavelength dispersion ", reduces the signal quality of system.More specifically, because the result of chromatic dispersion, the velocity of propagation of the signal in optical fiber depends on the wavelength of signal.For example, when the pulse with longer wavelength (for example, pulse with wavelength of expression " red " look pulse) faster than the transmission speed of the pulse with shorter wavelength (for example, having the pulse of the wavelength of expression " indigo plant " look pulse), this chromatic dispersion is commonly referred to as " normally " chromatic dispersion.On the contrary, when the pulse with shorter wavelength (for example blue wavelength pulse) is faster than the speed of the pulse with longer wavelength (for example red pulse), then this chromatic dispersion is commonly referred to as abnormality " chromatic dispersion.

Therefore, if from transmitter 30 emissions the time, pulse 32 is made of red and blue pulse, then can separate when it passes optical fiber 34, thereby receive the red pulse 38 and the blue pulse 40 of separating in the different time by receiver 36.Fig. 1 (A) illustrates the situation of " normally " chromatic dispersion, and wherein the red pulse transmission speed is faster than blue pulse.

As another example of burst transmissions, Fig. 1 (B) illustrates has a pulse 42 of the wavelength from the blueness to the redness continuously, and is launched by transmitter 30.Fig. 1 (C) is for illustrating the pulse 42 when arriving receiver 36.Because red composition and blue composition be with different speed transmission, so pulse 42 is broadened in optical fiber 34, and caused distortion by chromatic dispersion as shown in Fig. 1 (C).Because all pulses comprise limited wavelength coverage, this chromatic dispersion is very general in optical fiber telecommunications system.

Therefore, provide higher transmission capacity in order to make fibre system, this optical fiber telecommunications system must compensation of dispersion.

Fig. 2 illustrates to have the synoptic diagram that the opposite color separate component comes the optical fiber telecommunications system of compensation of dispersion.Referring now to Fig. 2,, opposite color separate component 44 adds " on the contrary " chromatic dispersion in the pulse to usually, to eliminate the chromatic dispersion that is caused owing to by optical fiber 34 transmission.

There is a kind of conventional equipment that can be used as opposite color separate component 44.For example, Fig. 3 illustrates the optical fiber telecommunications system with dispersion compensating fiber, and it has specific cross-section index section (cross-section index profile), and comes compensation of dispersion as the opposite color separate component.Referring now to Fig. 3,, dispersion compensating fiber 46 provides opposite chromatic dispersion, to eliminate the chromatic dispersion that is caused by optical fiber 34.But dispersion compensating fiber is expensive, and needs relatively long length to come abundant compensation of dispersion.For example, if optical fiber 34 has 100 kilometers length, then the form and aspect compensated optical fiber approximately has 20 to 30 kilometers length.

Fig. 4 illustrates the chirped grating (chirpedgrating) that is used as the opposite color separate component, with compensation of dispersion.Referring now to Fig. 4,, is provided to the input port 48 of optical circulator 50 by optical fiber and the light that is subjected to chromatic dispersion.Circulator 50 is provided to chirped grating 52 to this light.Chirped grating 52 is light reflected back circulator 50, and the different wave length composition with different distances along chirped grating 52 reflections, make the different wave length composition by different distances, thus compensation of dispersion.For example, chirped grating 52 can be designed as and makes long wavelength composition pass through long distance reflection along chirped grating 52, arrives longer than shorter wavelength composition thereby propagate distance.Then, circulator 50 is provided to input port 54 to the reflected light from chirped grating 52.Therefore, chirped grating 52 can add opposite chromatic dispersion by paired pulses.

Unfortunately, chirped grating has very narrow bandwidth and is used for reflected impulse, therefore can not provide enough wavelength to bring and compensate the light that comprises many wavelength, for example wavelength division multiplexed light.A plurality of chirped gratings can cascade, is used for wavelength-division multiplex signals, but this can cause expensive system.In addition, the chirped grating with circulator as shown in Figure 4 is suitable for more when the situation of individual channel quilt by the optical fiber telecommunications system transmission.

Fig. 5 is the synoptic diagram that conventional diffraction grating is shown, and it can be used to produce chromatic dispersion.Referring now to Fig. 5,, diffraction grating 56 has grating surface 58.Parallel light 60 with different wave length is by on the grating surface 58 of incident.Light is reflected on each step of grating surface 58, and interferes mutually.As a result, the

light

62,64 with different wave length is exported from diffraction grating 56 with different angles with 66.As hereinafter more specifically describing, diffraction grating can space grating in the structure, with compensation of dispersion.

More specifically, Fig. 6 (A) is for illustrating the synoptic diagram of the space grating of the opposite color separate component that is used as compensation of dispersion to structure.Referring now to Fig. 6 (A),, light 67 is diffracted to short wavelength's light 69 and long wavelength's light 70 from first diffraction grating 68.These light 69 and 70 are diffracted to the light of propagating in the same direction by second diffraction grating 72 then.Shown in Fig. 6 (A), the wavelength composition with different wave length is by different distances, increasing opposite chromatic dispersion, thus compensation of dispersion.Because long wavelength (for example light 70) passes through than the longer distance of shorter wavelength (for example light 69), then the grating pair structure shown in Fig. 6 (A) has anomalous dispersion.

Fig. 6 (B) is the synoptic diagram that the additional space grating pair of the opposite color separate component that is used as compensation of dispersion is shown.Shown in Fig. 6 (B), lens 72 and 74 are placed between first and second diffraction grating 68 and 71, make them have an identical focus.Because the distance that longer wavelength (for example light 70) passes through is shorter than shorter wavelength (for example light 69), so the space grating shown in Fig. 6 (B) has normal dispersion to structure.

As the space grating as shown in Fig. 6 (A) and 6 (B) to being used to be controlled at the chromatic dispersion in the laser resonator the structure.But, the relatively large dispersion measure that actual space grating does not occur in optical fiber telecommunications system enough to provide enough big chromatic dispersion to compensate structure.More specifically, very little usually by the angular dispersion that diffraction grating produced, and generally be approximately 0.05 degree/nm.Therefore, in order to compensate the chromatic dispersion that occurs in optical fiber telecommunications system, first and second gratings 68 must separate very large distance with 71, thereby make this space become unrealistic to structure.

Summary of the invention

Therefore an object of the present invention is to provide a kind of device, it produces chromatic dispersion and be actually used in the chromatic dispersion that compensation is accumulated in optical fiber.

An object of the present invention is to be included in the equipment that this is called " the phased matrix of the virtual image ", " VIPA " or " VIPA generator " in this device by providing a kind of device to realize.This VIPA generator produces the light from this VIPA generator spread out.This device also comprises a mirror or reflecting surface, and its light reflected back VIPA generator repeatedly reflects in this VIPA generator.

The objective of the invention is by providing a device that comprises VIPA generator and reflecting surface to realize.This VIPA generator receives the input light of different wave length, and produces the collimation output light that sends from the VIPA generator on by the determined direction of this input light wavelength.This reflecting surface is this output light reflected back VIPA generator.This reflecting surface is along having different curvature with the perpendicular direction of the angular dispersion direction of VIPA generator or with comprising from the perpendicular direction in the plane of the transmission direction of the collimation output light of the VIPA generator of the light that is used to import different wave length at different positions.

Purpose of the present invention also realizes by the device that a kind of VIPA of comprising generator, reflecting surface and lens are provided.This VIPA generator receives the input light of different wave length, and produce corresponding collimation output light on by input light wavelength determined direction, thereby the output light differentiation mutually spatially that this output light and input light with different wave length are produced from the transmission of VIPA generator.This reflecting surface has the coniform of coniform or modification.Lens to this reflecting surface, are exported light to the light focusing of propagating from the VIPA generator thereby this reflecting surface reflects, and the light that is reflected directly returns the VIPA generator by lens.Coniform can be designed as of this modification makes this device have even chromatic dispersion to the same channel of a wavelength-division multiplex light.

The objective of the invention is by providing a device that comprises angular dispersion parts and reflecting surface to realize.These angular dispersion parts have a passage area that receives light and export light from these angular dispersion parts.These angular dispersion parts receive the input light with each wavelength in the continuous wavelength scope by this passage area, and this input light is repeatedly reflected, to produce self-interference, it forms the collimation output light that sends from these angular dispersion parts along by the determined direction of input light wavelength, thereby and with in this continuous wavelength scope by the difference mutually spatially of the formed output light of the input light with other wavelength.This reflecting surface is output light reflected back angular dispersion parts, repeatedly to reflect in these angular dispersion parts, then from this passage area output.This reflecting surface along with the perpendicular direction in plane that comprises from the transmission direction of the collimation output light of the angular dispersion parts of the light that is used to import different wave length, have different curvature at diverse location.

In addition, purpose of the present invention realizes by a kind of device that comprises angular dispersion parts and reflecting surface is provided.These angular dispersion parts have a passage area that receives light and export light from these angular dispersion parts.These angular dispersion parts receive the input light of line focus by this passage area, and this input light is repeatedly reflected, to produce self-interference, it forms the collimation output light that sends from these angular dispersion parts along by the determined direction of input light wavelength, thereby and with the difference mutually spatially of the formed output light of the input light with different wave length.This reflecting surface is output light reflected back angular dispersion parts, repeatedly to reflect in these angular dispersion parts, then from this passage area output.This reflecting surface along with the perpendicular direction in plane that comprises from the transmission direction of the collimation output light of the angular dispersion parts of the light that is used to import different wave length, have different curvature at diverse location.

Purpose of the present invention can also realize by a device that comprises first and second reflecting surfaces and minute surface is provided.Second reflecting surface has the feasible reflectivity that the part light on it sees through that incides.Input light at each wavelength is focused on the straight line.First and second reflecting surfaces are provided so that the input light that sends from this straight line is repeatedly reflected between first and second reflecting surfaces, thereby make many light see through second reflecting surface.Many transmitted ray is interfered mutually, producing the collimation output light that sends from this second reflecting surface along by the determined direction of input light wavelength, thereby for the difference mutually spatially of the formed output light of the input light with different wave length.This minute surface export back second reflecting surface to the reflection of this light, passing through this second reflecting surface, and repeatedly reflects between first and second reflecting surfaces.This minute surface has different curvature along exporting the perpendicular direction in plane of the transmission direction of light with comprising the input light for different wave length from the collimation of second reflecting surface at diverse location.

Purpose of the present invention can also realize by the device that a kind of VIPA of comprising generator, lens, first and second minute surfaces and wavelength filter are provided.This VIPA generator receives wavelength-division multiplex (WDM) light of the line(ar) focus that comprises first and second wavelength, and generation is exported light with first and second of the corresponding collimation of first and second wavelength respectively.This first and second output light is being sent from the VIPA generator respectively by determined first and second directions of first and second wavelength respectively.Lens focus is from the first and second output light of VIPA generator.This first and second minute surface has the coniform of coniform or modification respectively, is used to produce uniform chromatic dispersion.This wavelength filter is to carrying out filtering by the light that lens focused on, thereby is focused first minute surface at the light of first wavelength, and reflected by first minute surface, and is focused second minute surface at the light of second wavelength and reflected by second minute surface.First and second light that are reflected are turned back to the VIPA generator by wavelength filter and lens institute orientation.

In addition, purpose of the present invention realizes by the far-field distribution that makes input light have double-peak shape.For example, a phase mask can provided on the input optical fibre or on the surface of VIPA generator, so that input light has the far-field distribution of double-peak shape.

The objective of the invention is to be included in hereinafter by providing a kind of that the device that is called " virtual image phased array ", " VIPA " or " VIPA generator " equipment realizes.This VIPA generator produces the light of propagating from this VIPA generator.This device also comprises minute surface or reflecting surface, and its light turns back to the VIPA generator, so that it repeatedly reflects in the VIPA generator.

The object of the invention realizes by the device that a kind of VIPA of comprising generator and reflecting surface are provided.This VIPA generator receives the input light of different wave length, and is created in the corresponding collimation output light that transmits from this VIPA generator by on the determined direction of input light wavelength.This reflecting surface is this output light reflected back VIPA generator.Reflecting surface along with the perpendicular direction of the angle distribution arrangement of VIPA generator, perhaps export the perpendicular direction in plane of the transmission direction of light from the collimation of VIPA generator output, have different curvature in different positions with the input light that comprises for different wave length.

Purpose of the present invention can also realize by the device that a kind of VIPA of comprising generator, reflecting surface and lens are provided.The VIPA generator is accepted the input light of different wave length, and be created in the corresponding collimation output light that transmits from the VIPA generator by on the determined direction of input light wavelength, thereby should export the output light difference mutually spatially that light can produce with the input light for different wave length.This reflecting surface has the coniform of coniform or modification.These lens focus on this reflecting surface to the output light from the VIPA generator, thereby this reflecting surface reflects this output light, and this reflection ray is turned to back the VIPA generator by lens.Coniform can be designed as of this modification makes this device have uniform chromatic dispersion for light in the channel of identical wavelength division multiplexed light.

Purpose of the present invention realizes by a kind of device that comprises angular dispersion parts and reflecting surface is provided.These angular dispersion parts have the passage area that receives light and export light from these angular dispersion parts.These angular dispersion parts receive the input light with each wavelength in connecting wavelength coverage by this passage area, and this input light is repeatedly reflected to produce self-interference, formation is exported light from the angular dispersion parts along the collimation that is transmitted by the determined direction of input light wavelength, thereby from the input light with any other wavelength in the continuous wavelength scope is formed diacritic input light on the space.This reflecting surface is exported repeatedly to be reflected then in the angular dispersion parts output light reflected back angular dispersion parts from passage area.This reflecting surface has different curvature along exporting the perpendicular direction in plane of the transmission direction of light with the input light that comprises for different wave length from the collimation of angular dispersion parts output in different positions.

In addition, purpose of the present invention realizes by a kind of device that comprises angular dispersion parts and reflecting surface is provided.These angular dispersion parts have the passage area that receives light and export light from these angular dispersion parts.These angular dispersion parts receive the input light of line(ar) focus by this passage area, and this input light is repeatedly reflected to produce self-interference, formation is exported light from the angular dispersion parts along the collimation that is transmitted by the determined direction of input light wavelength, thereby the input light with different wave length forms diacritic input light on the space.This reflecting surface is exported repeatedly to be reflected then in the angular dispersion parts output light reflected back angular dispersion parts from passage area.This reflecting surface has different curvature along exporting the perpendicular direction in plane of the transmission direction of light with the input light that comprises for different wave length from the collimation of angular dispersion parts output in different positions.

Another object of the present invention realizes by a kind of device that comprises first and second reflecting surfaces and minute surface is provided.Second reflecting surface has the feasible reflectivity that the part light on it sees through that incides.Input light at each wavelength is focused on the straight line.First and second reflecting surfaces are provided so that the input light that sends from this straight line is repeatedly reflected between first and second reflecting surfaces, thereby make many light see through second reflecting surface.Many transmitted ray is interfered mutually, producing the collimation output light that sends from this second reflecting surface along by the determined direction of input light wavelength, thereby for the difference mutually spatially of the formed output light of the input light with different wave length.This minute surface export back second reflecting surface to the reflection of this light, passing through this second reflecting surface, and repeatedly reflects between first and second reflecting surfaces.This minute surface has different curvature along exporting the perpendicular direction in plane of the transmission direction of light with comprising the input light for different wave length from the collimation of second reflecting surface at diverse location.

Purpose of the present invention realizes by a kind of device is provided, and is set to the minute surface of handle by the variable curvature of virtual image phased array (VIPA) the reflected back VIPA generator that generator produced comprising (a); And (b) rotating shaft, this minute surface is around this rotating shaft rotation, to change the curvature at this minute surface of position of reflection output light.

Purpose of the present invention also by providing a kind of device to realize, produces from virtual image phased array (VIPA) generator of the light of VIPA generator transmission comprising (a); (b) be set to the minute surface of the variable curvature of light reflected back VIPA generator; And (c) rotating shaft, this minute surface is around this rotating shaft rotation, to change the curvature at this minute surface of position of reflection output light.

Purpose of the present invention is further by providing a kind of device to realize, comprising (a) virtual image phased array (VIPA) generator, it receives the input light of each wavelength and is created in the corresponding output light that is transmitted from the VIPA generator by the determined direction of input light wavelength; (b) minute surface of variable curvature, it is set to a light reflected back VIPA generator, thus the output light that is reflected is by the VIPA generator, so that the dispersion compensation to input light to be provided; And (c) rotating shaft, this minute surface with the curvature of change at this minute surface of position of reflection output light, thereby provides the chromatic dispersion compensation quantity of variation to importing light around this rotating shaft rotation.

In addition, purpose of the present invention realizes by a kind of device is provided, comprising: (a) illumination window; (b) first and second reflecting surfaces that are parallel to each other, first reflecting surface does not make light see through basically, and be placed in the illumination window same level on, this second reflecting surface has the reflectivity that the part light that shines on it is seen through, wherein the input light of each wavelength is by this illumination window and focus on the straight line, this first and second reflecting surface is provided so that the input light repeatedly reflection between first and second reflecting surfaces from this straight line emission, thereby make many light see through second reflecting surface, these many transmitted rays are interfered the collimation output light that transmits from second reflecting surface along by the determined direction of input light wavelength to produce mutually, thereby spatially can distinguish for the formed output light of the input light with different wave length; (c) minute surface of variable curvature, its output light reflected back second reflecting surface be with by this second reflecting surface, and repeatedly reflect between first and second reflecting surfaces; And (d) rotating shaft, this minute surface rotates to change the curvature at the minute surface of the position that output light is reflected around this rotating shaft.

Purpose of the present invention can also realize that comprising (a) a plurality of minute surfaces, it has different surface curvatures with reflection ray by a kind of device is provided; And (b) support, it has a rotating shaft and supporting and the equally spaced a plurality of minute surfaces of this rotating shaft, this support rotates around rotating shaft, so that the different minute surface of each of a plurality of minute surfaces is in the position by virtual image phased array (VIPA) the light reflected back VIPA generator that generator produced.

Purpose of the present invention realizes by a kind of device is provided, and produces virtual image phased array (VIPA) generator of light comprising (a); (b) a plurality of minute surfaces, it has different surface curvatures; And (c) support, it has a rotating shaft and supporting and the equally spaced a plurality of minute surfaces of this rotating shaft, this support rotates around rotating shaft, so that the different minute surface of each of a plurality of minute surfaces is in the position of the light reflected back VIPA generator that is produced by the VIPA generator.

In addition, purpose of the present invention realizes by a kind of device is provided, comprising (a) virtual image phased array (VIPA) generator, it receives the input light of each wavelength, and is created in the corresponding output light that is transmitted from the VIPA generator by the determined direction of input light wavelength; (b) a plurality of minute surfaces, it has different surface curvatures; And (c) support, it has a rotating shaft and supporting and the equally spaced a plurality of minute surfaces of this rotating shaft, this support rotates around rotating shaft, so that the different minute surface of each of a plurality of minute surfaces is in the position of the light reflected back VIPA generator that is produced by the VIPA generator, thereby provide importing the dispersion compensation of light.

Purpose of the present invention is also by providing a kind of device to realize, comprising: (a) illumination window; (b) first and second reflecting surfaces that are parallel to each other, first reflecting surface does not make light see through basically, and be placed in the illumination window same level on, this second reflecting surface has the reflectivity that the part light that shines on it is seen through, wherein the input light of each wavelength is by this illumination window and focus on the straight line, this first and second reflecting surface is provided so that the input light repeatedly reflection between first and second reflecting surfaces from this straight line emission, thereby make many light see through second reflecting surface, these many transmitted rays are interfered the collimation output light that transmits from second reflecting surface along by the determined direction of input light wavelength to produce mutually, thereby spatially can distinguish for the formed output light of the input light with different wave length; (c) a plurality of minute surfaces with different surfaces curvature; And (d) support, it has a rotating shaft and supporting and the equally spaced a plurality of minute surfaces of this rotating shaft, this support rotates around rotating shaft, so that the different minute surface of each of a plurality of minute surfaces is in the position of output light reflected back second reflecting surface, repeatedly to reflect by this second reflecting surface and between first and second surfaces.

In addition, purpose of the present invention realizes having a plurality of fixedly minute surfaces that different surfaces curvature is used for reflection ray comprising (a) by a kind of device is provided; And (b) rotating mirror, it can be around a rotating shaft rotation each fixing minute surface virtual image phased array (VIPA) light that generator was produced is reflexed to a plurality of fixedly minute surfaces, and by each light reflected back VIPA generator that fixedly minute surface reflected.

In addition, purpose of the present invention realizes by a kind of device is provided, and produces virtual image phased array (VIPA) generator of light comprising (a); (b) have a plurality of fixedly minute surfaces that different surfaces curvature is used for reflection ray; And (c) rotating mirror, each fixing minute surface that it can reflex to a plurality of fixedly minute surfaces with the light that the VIPA generator is produced around a rotating shaft rotation, and handle is by each light reflected back VIPA generator that fixedly minute surface reflected.

In addition, purpose of the present invention realizes by a kind of device is provided, comprising (a) virtual image phased array (VIPA) generator, it receives the input light of each wavelength, and is created in the corresponding output light that transmits from the VIPA generator by on the determined direction of input light wavelength; (b) have a plurality of fixedly minute surfaces that different surfaces curvature is used for reflection ray; And (c) rotating mirror, it can be around rotating shaft rotation each fixing minute surface the output light from the VIPA generator is reflexed to a plurality of fixedly minute surfaces, and, thereby produce importing the dispersion compensation of light the light reflected back VIPA generator that fixedly minute surface reflected by each.

And purpose of the present invention is also by providing a kind of device to realize, comprising: (a) illumination window; (b) first and second reflecting surfaces that are parallel to each other, first reflecting surface does not make light see through basically, and be placed in the illumination window same level on, this second reflecting surface has the reflectivity that the part light that shines on it is seen through, wherein the input light of each wavelength is by this illumination window and focus on the straight line, this first and second reflecting surface is provided so that the input light repeatedly reflection between first and second reflecting surfaces from this straight line emission, thereby make many light see through second reflecting surface, these many transmitted rays are interfered the collimation output light that transmits from second reflecting surface along by the determined direction of input light wavelength to produce mutually, thereby spatially can distinguish for the formed output light of the input light with different wave length; (c) a plurality of have a fixedly minute surface that different surfaces curvature is used for reflection ray; And (d) one the rotation minute surface, it can rotate around rotating shaft, with each the fixing minute surface that reflexes to a plurality of fixedly minute surfaces from the output light of second reflecting surface, and light reflected back second reflecting surface that fixedly minute surface reflected by each, repeatedly to reflect by this second reflecting surface and between first and second surfaces.

Purpose of the present invention realizes by a kind of device is provided, comprising: (a) have a plurality of fixedly minute surfaces that different surfaces curvature is used for reflection ray; And (b) from the parabolic minute surface of axle, it can rotate around a rotating shaft, with each the fixing minute surface that reflexes to a plurality of fixedly minute surfaces by virtual image phased array (VIPA) light that generator was produced, and by each light reflected back VIPA generator that fixedly minute surface reflected.

In addition, the objective of the invention is by providing a kind of device to realize, comprising: (a) virtual image phased array (VIPA) generator of generation light; (b) a plurality of fixedly minute surfaces, it has different surface curvatures, with reflection ray; And (c) from the parabolic minute surface of axle, it rotates around rotating shaft, with each the fixing minute surface that the light that is produced by the VIPA generator is reflexed to a plurality of fixedly minute surfaces, and by each light reflected back VIPA generator that fixedly minute surface reflected.

In addition, purpose of the present invention can realize by a kind of device is provided, comprising: (a) virtual image phased array (VIPA) generator, it receives the input light of each wavelength, and is created in the corresponding output light that transmits from the VIPA generator by on the determined direction of input light wavelength; (b) have a plurality of fixedly minute surfaces that different surfaces curvature is used for reflection ray; And (c) from the parabolic minute surface of axle, it rotates around rotating shaft, with each the fixing minute surface that the light that is produced by the VIPA generator is reflexed to a plurality of fixedly minute surfaces, and by each light reflected back VIPA generator that fixedly minute surface reflected, thereby dispersion compensation provided to this input light.

In addition, purpose of the present invention realizes by a kind of device is provided, comprising: (a) illumination window; (b) first and second reflecting surfaces that are parallel to each other, first reflecting surface does not make light see through basically, and be placed in the illumination window same level on, this second reflecting surface has the reflectivity that the part light that shines on it is seen through, wherein the input light of each wavelength is by this illumination window and focus on the straight line, this first and second reflecting surface is provided so that the input light repeatedly reflection between first and second reflecting surfaces from this straight line emission, thereby make many light see through second reflecting surface, these many transmitted rays are interfered the collimation output light that transmits from second reflecting surface along by the determined direction of input light wavelength to produce mutually, thereby spatially can distinguish for the formed output light of the input light with different wave length; Individual have a fixedly minute surface that different surfaces curvature is used for reflection ray; And (d) from the parabolic minute surface of axle, it rotates around rotating shaft, with each the fixing minute surface that reflexes to a plurality of fixedly minute surfaces from the output light of second reflecting surface, and handle is by each light reflected back second reflecting surface that fixedly minute surface reflected, with by this second reflecting surface, and repeatedly reflection between first and second reflecting surfaces.

Description of drawings

From hereinafter in conjunction with the accompanying drawings the detailed description of the preferred embodiment, it is clearer that these and other objects of the present invention and advantage will become, wherein:

Fig. 1 (A) (prior art) is for illustrating the synoptic diagram of conventional fiber communication system.

Fig. 1 (B) is transmitting by the synoptic diagram before the optical fiber in the conventional fiber communication system for pulse is shown.

Fig. 1 (C) is transmitting by the synoptic diagram after the optical fiber in the conventional fiber communication system for pulse is shown.

Fig. 2 (prior art) has the synoptic diagram that the opposite color separate component is used for a kind of optical fiber telecommunications system of compensation of dispersion for illustrating.

Fig. 3 (prior art) is for illustrating the synoptic diagram that has as a kind of optical fiber telecommunications system of the dispersion compensating fiber of opposite color separate component.

Fig. 4 (prior art) is for illustrating the synoptic diagram of the chirped FM grating that is used as the opposite color separate component that is used for compensation of dispersion.

Fig. 5 (prior art) is for illustrating the synoptic diagram of conventional diffraction grating.

Fig. 6 (A) (prior art) is used to produce the synoptic diagram of the space grating of anomalous dispersion to structure for illustrating.

Fig. 6 (B) (prior art) is used to produce the synoptic diagram of the space grating of normal dispersion to structure for illustrating.

Fig. 7 is the synoptic diagram that VIPA is shown.

Fig. 8 is the detailed view that the VIPA of Fig. 7 is shown.

Fig. 9 illustrates the cross sectional view of the VIPA shown in Fig. 7 along line IX-IX.

Figure 10 is the synoptic diagram that the interference between the reflection that is produced by VIPA is shown.

Figure 11 is the synoptic diagram that illustrates along the line IX-IX intercepting of the VIPA shown in Fig. 7, is used to illustrate the inclination angle of input light.

Figure 12 (A), 12 (B), 12 (C) and 12 (D) are for illustrating the synoptic diagram of the method that is used to make a VIPA.

Figure 13 illustrates to use the schematic representation of apparatus of VIPA as the angular dispersion parts that produce chromatic dispersion.

Figure 14 is the detailed view that the operation of the device among Figure 13 is shown.

Figure 15 is each other synoptic diagram of level that the interference of VIPA is shown.

Figure 16 is the curve map that the chromatic dispersion of the several channels that are used for wavelength division multiplexed light is shown.

Figure 17 illustrates the synoptic diagram that is accumulated in the different channels of the wavelength division multiplexed light on the difference of minute surface by VIPA.

Figure 18 illustrates to use VIPA light to be carried out the lateral plan of a kind of device of variable chromatic dispersion.

Figure 19 illustrates to use VIPA light to be carried out the lateral plan of a kind of device of variable chromatic dispersion.

Figure 20 (A) and 20 (B) use VIPA light to be carried out the lateral plan of a kind of device of variable chromatic dispersion for illustrating.

Figure 21 is the curve map that illustrates from the relation between the well-illuminated wavelength of the well-illuminated output angle of the light of VIPA and light.

Figure 22 is the curve map that the relation between the well-illuminated wavelength of the angular dispersion of VIPA and light is shown.

Figure 23 is the curve map that is illustrated in the effect of the different mirror types in the device that uses VIPA.

Figure 24 is the dissimilar minute surface that illustrates for used in device, the curve map of the relation between the chromatic dispersion versus wavelength in the device that uses VIPA.

Figure 25 is the curve map that the effect of the minute surface in the device that uses VIPA is shown.

Figure 26 is the curve map that the constant chromatic dispersion of the device that uses VIPA is shown.

Figure 27 is the curve map that the characteristic of the different minute surfaces that the device that uses VIPA is designed is shown.

Figure 28 (A), 28 (B), 28 (C), 28 (D), 28 (E) and 28 (F) are the synoptic diagram of the example of minute surface that the device that uses VIPA is shown.

Figure 29 is the synoptic diagram that cylindrical mirror is shown.

Figure 30 (A) has after the VIPA compensation of dispersion of cylindrical mirror for being illustrated in to use, for a channel of a wavelength division multiplexed light, and the curve map of the relation between the chromatic dispersion versus wavelength.

Figure 30 (B) has after the VIPA compensation of dispersion of cylindrical mirror for being illustrated in to use, for all wavelengths of a wavelength division multiplexed light, and the curve map of the relation between the chromatic dispersion versus wavelength.

Figure 31 (A) is illustrated in after the VIPA compensation of dispersion of using the cylindrical mirror with modification, for a channel of a wavelength division multiplexed light, and the curve map of the relation between the chromatic dispersion versus wavelength.

Figure 31 (B) is illustrated in after the VIPA compensation of dispersion of using the cylindrical mirror with modification, for all wavelengths of a wavelength division multiplexed light, and the curve map of the relation between the chromatic dispersion versus wavelength.

Figure 32 is for illustrating the top view that uses VIPA to come light is provided the device of variable chromatic dispersion according to a further embodiment of the invention.

Figure 33 (A) and 33 (B) are for illustrating according to one embodiment of present invention the synoptic diagram that how forms a minute surface from the cross section of circular cone.

Figure 34 (A) is for illustrating according to one embodiment of the invention for using VIPA to provide in the device of chromatic dispersion, for the curve map of the relation of the chromatic dispersion versus wavelength of radius-of-curvature in a channel of different minute surfaces.

Figure 34 (B) is for illustrating the synoptic diagram of the radius-of-curvature of Figure 34 (A) according to an embodiment of the invention.

Figure 34 (C) is for illustrating the synoptic diagram of improved radius-of-curvature according to an embodiment of the invention.

Figure 35 is for illustrating according to one embodiment of the invention, using VIPA that the curve map of the relation between the chromatic dispersion versus wavelength is provided in the device of chromatic dispersion for different curvature radius.

Figure 36 is for illustrating according to one embodiment of the invention the synoptic diagram of all angles in the device of use VIPA.

Figure 37 is for illustrating according to one embodiment of present invention another synoptic diagram of the angle in the device of use VIPA.

How Figure 38 produces the synoptic diagram of chromatic dispersion for illustrating according to one embodiment of the invention in the device that uses VIPA.

Figure 39 (A), 39 (B) and 39 (C) are for illustrating the curve map of minute surface bending according to an embodiment of the invention.

Figure 40 is the synoptic diagram that the taper that is used to form minute surface according to an embodiment of the invention is shown.

Figure 41 illustrates the synoptic diagram that forms the step of minute surface according to one embodiment of the invention.

Figure 42 uses VIPA that the lateral plan of the device of chromatic dispersion gradient is provided for illustrating according to a further embodiment of the invention.

Figure 43 (A) is for illustrating according to one embodiment of the invention, in the device of the Figure 42 that uses the taper minute surface, for the curve map of the dispersion measure of all wavelengths.

Figure 43 (B) is for illustrating according to one embodiment of the invention, in the device of the Figure 42 that uses the taper minute surface, for the curve map of the dispersion measure of all wavelengths.

Figure 44 uses the synoptic diagram of holographic grating for illustrating according to one embodiment of the invention between VIPA and lens.

Figure 45 uses the synoptic diagram of reflection-type grating for illustrating according to one embodiment of the invention between VIPA and lens.

Figure 46 and 47 uses the synoptic diagram of half-wave plate for illustrating according to one embodiment of the invention.

Figure 48 (A) is for illustrating according to a further embodiment of the invention, uses VIPA to come different channels is provided the side view or the top view of the device of different chromatic dispersion.

Figure 48 (B) is for illustrating according to a further embodiment of the invention, for the device in Figure 48 (A), the curve map of the relation between the chromatic dispersion versus wavelength.

Figure 49 is according to one embodiment of the invention, uses VIPA to come different channels is provided the side view or the top view of the device of different chromatic dispersion.

Figure 50 is for illustrating according to one embodiment of the invention, uses VIPA that the synoptic diagram of the insertion loss in the device of chromatic dispersion is provided.

Figure 51 is for illustrating according to one embodiment of the invention, uses VIPA that the synoptic diagram of insertion loss of the device of chromatic dispersion is provided.

Figure 52 is for illustrating according to one embodiment of the invention, sends and enter the synoptic diagram of light intensity of the light of VIPA from optical fiber.

Figure 53 is for illustrating according to one embodiment of the invention, in the device of the chromatic dispersion of using VIPA to provide, on input optical fibre with the side view of the light phase mask of the far-field distribution that produces bimodal shape.

Figure 54 is for illustrating according to one embodiment of the invention the cross sectional view that the line 54-54 in Figure 53 intercepts.

Figure 55 is for illustrating according to one embodiment of the invention, the light that receives in the VIPA provided the side view of light phase mask of the far-field distribution of bimodal shape on VIPA.

Figure 56 is for illustrating according to one embodiment of the invention, the light that receives in the VIPA provided the side view of light phase mask of the far-field distribution of bimodal shape on VIPA.

Figure 57 and 58 is for illustrating according to one embodiment of the invention, the light that receives in the VIPA provided the side view of light phase mask of the far-field distribution of bimodal shape on VIPA.

Figure 59 is increased to the synoptic diagram of the excess loss on the damage curve for illustrating according to one embodiment of the invention.

Figure 60 uses the excess loss parts that the synoptic diagram of excess loss is provided for illustrating according to one embodiment of the invention.

Figure 61 uses VIPA that the side view of the minute surface of chromatic dispersion is provided for illustrating according to one embodiment of the invention.

Figure 62 illustrates the front elevation of minute surface according to an embodiment of the invention.

Figure 63 (A), 63 (B) and 63 (C) are for illustrating according to one embodiment of the invention, the synoptic diagram of the method for accommodation reflex rate effectively in the device that uses VIPA.

Figure 64 uses the synoptic diagram of grating for illustrating according to one embodiment of the invention between VIPA and lens.

Figure 65,66 and 67 uses the synoptic diagram of the VIPA with movable minute surface for illustrating according to embodiments of the invention.

Figure 68 and 69 utilizes the synoptic diagram of the scalable dispersion compensator of rotatable variable curved mirror for illustrating according to one embodiment of the invention.

Figure 70 is for illustrating according to one embodiment of the invention, is used as the synoptic diagram of example of variable curved mirror of the part of scalable dispersion compensator.

Figure 71 is for illustrating according to one embodiment of the invention, utilizes the synoptic diagram of scalable dispersion compensator of the part of a plurality of curved mirrors or minute surface.

Figure 72 is for illustrating according to one embodiment of the invention, utilizes the synoptic diagram of the scalable dispersion compensator of the part of a plurality of curved mirrors or minute surface and rotatable level crossing.

Figure 73 utilizes the synoptic diagram of the scalable dispersion compensator of a plurality of curved mirrors or minute surface part and rotatable off-axis paraboloidal mirror face for illustrating according to one embodiment of the invention.

Embodiment

To describe currently preferred embodiment of the present invention in detail below, example of the present invention is shown in the drawings, and wherein identical reference number is represented identical parts.

Fig. 7 is for illustrating the synoptic diagram of virtual image phased array (VIPA).In addition, hereinafter, term " virtual image phased array ", " VIPA " and " VIPA generator " can exchange.

Referring now to Fig. 7,, VIPA76 is preferably made by thin glass sheet.The input light 77 quilts for example such lens 80 of semicylinder mirror focus on the straight line 78, thereby input light 77 is sent on the VIPA76.Straight line 78 is called as " focal line 78 " hereinafter.Input light 77 is propagated radially from focal line 78, with inner reception the in VIPA76.VIPA78 exports the luminous flux 82 of collimated light then, and wherein the output angle of luminous flux 82 changes along with the wavelength of input light 77.For example, when input light 77 during in wavelength X 1, VIPA76 output wavelength on specific direction is the luminous flux 82a of λ 1.When input light 77 during in wavelength X 2, VIPA76 output wavelength on different directions is the luminous flux 82b of λ 2.Therefore, VIPA76 produces the luminous flux 82a and the 82b that spatially can distinguish mutually.

Fig. 8 is the detailed view that VIPA76 is shown.Referring now to Fig. 8,, VIPA76 for example comprises made and have a thin slice 120 of

reflectance coating

122 and 124 by glass.Reflectance coating 122 preferably has about 95% or higher, but less than 100% reflectivity.Reflectance coating 124 preferably has about 100% reflectivity.Illumination window 126 is formed on the thin slice 120, and preferably has about 0% reflectivity.

Input light 77 is focused on the focal line 78 by illumination window 126 by lens 80, and repeatedly reflects between reflectance coating 122 and 124.Focal line 78 is preferably on the surface of the thin slice 120 that is applied with reflectance coating 122.Therefore, focal line 78 is essentially by illumination window 126 and focuses on straight line on the reflectance coating 122.The width of focal line 78 can be called as " girdling the waist " of the input light 77 that is focused on by lens 80.Therefore, embodiments of the invention as shown in Figure 8 focus on input light 77 with a tight waist on the far surface of thin slice 120 (being the surface that has reflectance coating 122 on it).By focusing on the far surface of thin slice 120 with a tight waist, current embodiment of the present invention reduced (i) input light 77 be transfused to during by illumination window 126 thin slice 120 that light 77 covered lip-deep illumination window 126 the zone (for example, zone shown in Figure 11 " a ", describe in further detail hereinafter), with the (ii) zone on input light 77 is reflected the reflection thin 124 that 124 reflex times of film are covered by input light 77 for the first time (for example, at the zone shown in Figure 11 " b ", describe in further detail hereinafter) between overlapping possibility.Preferably reduce this overlapping, to guarantee the correct work of VIPA.

In Fig. 8, the optical axis 132 of input light 77 has little inclination angle [theta].After the first reflection of reflectance coating 122,5% light separates by this reflectance coating 122 and after with a tight waist, and 95% light is reflected to reflectance coating 124.After film 124 first reflections that are reflected, light shines on the reflectance coating 122 again, but side-play amount is d.Then, 5% light is by reflectance coating 122.In a comparable manner, as shown in Figure 8, this light is separated into the mulitpath with fixing interval d.Beam shape in every paths forms and makes light separate from the virtual image with a tight waist 134.The virtual image 134 along with the perpendicular straight line of thin slice 120 at a distance of constant interval 2t, wherein t is the thickness of thin slice 120.Being alignd certainly in position with a tight waist in the virtual image 134, and does not need to regulate position separately.Interfere mutually from the light of the virtual image 134 branches, and form the collimated light of propagating on the direction that changes according to the wavelength of importing light 77 136.

Opticpath be spaced apart d=2tSin θ, and the path length difference between adjacent beams is 2tCos θ.The ratio of angular dispersion and these two numerical value, promptly cot θ is proportional.As a result, VIPA produces bigger angular dispersion.

Can find out easily that from Fig. 8 term " virtual image phased array " derives from the formation of the array of the virtual image 134.

Fig. 9 is the sectional view that illustrates along the line IX-IX intercepting of the VIPA76 of Fig. 7.Referring now to Fig. 9,, thin slice 120 has reflecting surface 122 and 124.Reflecting

surface

122 and 124 is parallel to each other and at a distance of the thickness t of thin slice 120.Reflecting

surface

122 and 124 generally is the reflectance coating that is deposited on the thin slice 120.As indicated above, except illumination window 126, reflecting surface 124 has about 100% reflectivity, and reflecting surface 122 has about 95% or higher reflectivity.Therefore, reflecting surface 122 has about 5% or littler transmissivity, make incide about 5% on the reflecting surface 122 or light still less will be by transmission, and about 95% or more rays be reflected.Reflecting

surface

122 and 124 reflectivity change according to the application of specific VIPA easily.But reflecting surface 122 has the reflectivity less than 100% usually, thereby incident ray can see through.

Reflecting surface 124 has illumination window 126.Illumination window 126 makes light pass through, and preferably not reflection, and considerably less reflection is perhaps arranged.Illumination window 126 receives input light 77, so that input light 77 is received in wherein, and reflection between reflecting

surface

122 and 124.

Because the cross section along line IX-IX intercepting in Fig. 9 presentation graphs 7, therefore the focal line 78 in Fig. 7 shows as one " point " in Fig. 9.Then, input light 77 is from focal line 78 emissions.In addition, as shown in Figure 9, focal line 78 is placed on the reflecting surface 122.Although do not require focal line 78 on reflecting surface 122, the skew of the position in focal line 78 may cause the minor alteration of the characteristic of VIPA76.

As shown in Figure 9, input light 77 enters thin slice 120 by the regional A0 in the illumination window 126, and its mid point P0 represents the peripheral point of regional A0.

Because the reflectivity of reflecting surface 122, make about 95% or 122 reflections in surface that are reflected of more incident light 77, and incide on the regional A1 of reflecting surface 124.Point P1 represents the peripheral point of regional A1.After regional A1 on the reflecting surface 124 was left in reflection, input light 77 arrived reflecting surfaces 122, and part is by reflecting surface 122, as the represented output light Out1 of light R1 is arranged.In this manner, as shown in Figure 9, through repeatedly reflection, wherein each reflection of reflecting surface 122 also causes each output optical transmission to input light 77 between reflecting surface 122 and 124.Therefore, for example, and then input light 77 be reflected leave regional A2, A3 and A4 on the reflecting surface 124 after, reflecting surface 122 is left in 77 reflections of input light, to produce output light Out2, Out3 and Out4.Point P2 represents the peripheral point of regional A2, and some P3 represents the peripheral point of regional A3, and some P4 represents the peripheral point of regional A4.Out2 is represented by light R2 for output light, and Out3 is represented by light R3 for output light, and output light Out4 is represented by light R4.Although output light Out0, Out1, Out2, Out3 and Out4 only are shown among Fig. 9,, in fact more output light can be arranged according to the power of input light 77 and the reflectivity of reflecting surface 122 and 124.As hereinafter describing in further detail, output light is interfered mutually, has the light beam of the direction that changes according to the wavelength of importing light 77 with generation.Therefore, light beam can be described to because the formed synthetic output light of interference of output light Out0, Out1, Out2, Out3 and Out4.

Figure 10 illustrates the interference between the reflection that is produced by VIPA.Referring now to Figure 10,, the light that sends from focal line 78 124 reflections in surface that are reflected.As indicated above, reflecting surface 124 has about 100% reflectivity, so its function is basically as a catoptron.As a result, output light Out1 can be just looked like that reflecting

surface

122 and 124 does not exist like that by optical analysis, the substitute is and exports light Out1 from focal line I ₁Send.Similarly, output light Out2, Out3 and Out4 can be by optical analysiss, just look like they be respectively from focal line I ₁, I ₂, I ₃And I ₄Send.Focal line I ₂, I ₃And I ₄Be focal line I ₀The virtual image.

Therefore, as shown in Figure 10, focal line I ₁With focal line I ₀At a distance of the distance of 2t, wherein t equals the distance between reflecting surface 122 and 124.Similarly, each follow-up focal line with and then the preceding focal line at a distance of the distance of 2t.Therefore, focal line I ₂With focal line I ₁Distance at a distance of 2t.In addition, the each follow-up reflection multilayer between the reflecting

surface

122 and 124 produces than the preceding more weak output light of light intensity of once exporting light.Therefore, the beam intensity ratio output light Out1 of output light Out2 is more weak.

As shown in Figure 10, from the output light overlaid of intersection and interference mutually.More specifically, because focal line I ₁, I ₂, I ₃And I ₄Be focal line I ₀Empty, therefore export light Out0, Out1, Out2, Out3 and Out4 at focal line I ₁, I ₂, I ₃And I ₄The position have identical optical phase.Therefore, the wavelength according to input light 77 is created in the light beam that transmits on the specific direction.

VIPA according to the above embodiment of the present invention has the condition of enhancing, and this is the feature of the design of VIPA.The condition of this enhancing increases the input interference of light, thereby forms light beam.The enhancing condition of VIPA is represented by following equation (1):

2t*cosφ＝mλ

Wherein φ represents that λ represents to import light wavelength with respect to the transmission direction of the synthetic light beam of the surperficial perpendicular line measurement of reflecting

surface

122 and 124, and t represents the distance between reflecting

surface

122 and 124, and m represents an integer.

Therefore, if t is a constant, and the designated specific numerical value of m, then can determine the direction of propagation φ of light beam that the input light with wavelength X is formed.

More specifically, input light 77 is dispersed from focal line 78 by specific angle.Therefore, the input light with identical wavelength will transmit in a plurality of directions from focal line 78, reflection between reflecting surface 122 and 124.The enhancing condition of VIPA makes and to make the light that transmits on specific direction be enhanced by the output interference of light, has light beam corresponding to the direction of input light wavelength in formation.With the required specific direction of enhancing condition outside different directions on the light that transmits be output interference of light and weaken.

Figure 11 is the sectional view along line IX-IX that the VIPA shown in Fig. 7 is shown, and is used for determining the characteristic of the VIPA at the incident angle of input light or pitch angle shown in it.

Referring now to Figure 11,, input light 77 is assembled and is focused on the focal line 78 by the cylindrical lens (not shown).As shown in Figure 11, input light 77 covers and has the zone that width equals " a " on the illumination window 126.At input light 77 by once from reflecting surface 122 reflex times, input light 77 is incident upon on the reflecting surface 124, and covers the zone with the width that equals " b " on the reflecting surface 124.In addition, as shown in Figure 11, input light 77 forms optical axis 132 transmission at the inclination angle of θ 1 along the normal with respect to reflecting surface 122.

Inclination angle [theta] 1 should be set to prevent to import light 77 and penetrate this thin slice from illumination window 126 after 122 reflections in surface that are reflected for the first time.In other words, inclination angle [theta] 1 should be imported light 77 quilts " reservation " between reflecting

surface

122 and 124 for making by equipment, and does not penetrate from illumination window 126.Therefore, in order to prevent that importing light 77 leaves this thin slice by illumination window 126, inclination angle [theta] 1 should be provided with according to following equation (2):

Optical axis angle θ 1 〉=(a+b)/4t

Therefore shown in Fig. 7-11, VIPA receives the input light with each wavelength in connecting wavelength coverage.VIPA makes input light by multipath reflection, to produce self-interference, exports light thereby form.This output light with spatially can distinguish by the formed output light of the input light with any other wavelength in the continuous wavelength scope.For example, Fig. 9 is illustrated in the input light 77 of multipath reflection between reflecting surface 122 and 124.This multipath reflection produces a plurality of output light Out0, Out1, Out2, Out3 and the Out4 that interferes mutually, produces spatially diacritic light beam with each wavelength to input light 77.

" self-interference " is to be illustrated in the interference that produces between a plurality of light of same light source or the light beam.Because output light Out0, Out1, Out2, Out3 and Out4 are from same light source (that is, input light 77), therefore the interference of exporting between light Out0, Out1, Out2, Out3 and the Out4 is called as the self-interference of importing light 77.

Input light can be any wavelength in the continuous wavelength scope.Therefore, this input light is not limited to from the wavelength of the numerical value of range of discrete values selection.In addition, the output light that the input light of the specific wavelength in the continuous wavelength scope is produced spatially can be imported the light output light that different wave length produced in the continuous wavelength scope with this and distinguishes mutually.Therefore, for example shown in Fig. 7, when input light 77 is in different wave length in the continuous wavelength scope, the then transmission direction of light beam 82 (that is, " spatial character ") difference.

Figure 12 (A), 12 (B), 12 (C) and 12 (D) are for illustrating the synoptic diagram of the method that is used to produce VIPA.

Referring now to Figure 12 (A),, parallel thin slice 164 is preferably made by glass, and has good degree of parallelism.By vacuum deposition, ion sputtering or other similar method,

reflectance coating

166 and 168 is formed on the both sides of parallel thin slice 164.Reflectance coating 166 and one of 168 tools approach 100% reflectivity, and another reflectance coating has less than 100% and preferably is higher than 80% reflectivity.

Referring now to Figure 12 (B),,

reflectance coating

166 and 168 is partly peeled off to form illumination window 170.In Figure 12 (B), reflectance coating 166 is stripped from, thereby illumination window 170 can be formed on the parallel thin slice 164 on the surface identical with reflectance coating 166.But reflectance coating 168 can partly be peeled off in addition, thereby illumination window is formed on the parallel thin slice 164 on the surface identical with reflectance coating 168.Shown in each embodiment of the present invention, illumination window can be formed on the both sides of parallel thin slice 164.

Can carry out peeling off of reflectance coating by corrosion treatment, but also can use mechanical stripping to handle, and cheap more.But, if reflectance coating by mechanical stripping, then parallel thin slice 164 should be handled carefully, so that the infringement of parallel thin slice 164 is minimized.For example, if the part of parallel thin slice that forms illumination window by badly damaged, then this parallel thin slice 164 will produce the excess loss that the input scattering of light owing to reception is caused.

Except at first forming reflectance coating peels off it then, can be by blocking in advance corresponding to the parallel thin slice 164 of the part of illumination window, prevent this part thin covering that be reflected then.

Referring now to Figure 12 (C),, clear binder 172 is applied to reflectance coating 166 and has removed on the part of parallel thin slice 164 of reflection thin 166.Clear binder 172 is owing on the part that also will be applied to the parallel thin slice 164 that forms illumination window, so it should produce as far as possible little optical loss.

Referring now to Figure 12 (D),, parallel transparency protected 174 is applied on the clear binder 172, with protection reflectance coating 166 and parallel thin slice 164.Because clear binder 172 is filled owing to removing the sunk part that reflectance coating 166 produces, and therefore transparency protected 174 upper surface with parallel thin slice 164 is paralleled.

Similarly, in order to protect reflectance coating 168, can be applied to the bonding agent (not shown) upper surface of reflectance coating 168, and the screening glass (not shown) should be provided.If reflectance coating 168 has about 100% reflectivity, and do not have illumination window on the similar face of parallel thin slice 164, it is transparent then needn't making this bonding agent and screening glass.

In addition, antireflection film 176 can be applied on the transparent screening glass 174.For example, transparency protected 174 and illumination window 170 can be covered by antireflection film 176.

Focal line can enter on the apparent surface of parallel thin slice on the surface of illumination window or at input light.In addition, focal line can be on parallel thin slice or before illumination window.

According to mentioned above, reflection ray between two reflectance coatings, the reflectivity of a reflectance coating is approximately 100%.But, also can obtain similar effects with two reflectance coatings that have less than 100% respectively.For example, two reflectance coatings can have 95% reflectivity.In this case, each reflectance coating has light and sees through and cause interference.As a result, depending on that the light beam that transmits on the direction of wavelength is formed on the both sides of the parallel thin slice with reflectance coating.Therefore, can easily change each reflectivity of any embodiment of the present invention according to the desirable characteristics of VIPA.

According to mentioned above, form waveguide device by parallel thin slice or by two reflecting surfaces that are parallel to each other.But this thin slice or reflecting surface are not necessarily parallel.

According to mentioned above, VIPA uses multipath reflection, and keeps constant phase differential between the interference light.As a result, the characteristic of VIPA is stable, thereby reduces because the optical characteristics that polarization caused changes.On the contrary, undesirable change is made us in generation to the optical characteristics of conventional diffraction grating according to importing polarisation of light.

According to mentioned above, VIPA provides mutually the light beam " can distinguish on the space "." can distinguish on the space " and be meant that this light beam spatially can be distinguished.For example, if each light beam is collimated and transmit on different directions or focus on different positions, then each light beam spatially can be distinguished.But this is not limited to these embodiment, has many other methods light beam spatially can be distinguished.

Figure 13 illustrates to use VIPA to produce a kind of device of chromatic dispersion as angular dispersion parts rather than use diffraction grating.Referring now to Figure 13,, VIPA240 has the first surface 242 of for example about 100% transmissivity, and the second surface 244 of for example about 98% transmissivity.VIPA240 also comprises illumination window 247.But VIPA240 is not limited to this concrete structure.But VIPA240 can have various as described herein different structures.

As shown in Figure 13, light collimates from optical fiber 246 outputs, collimated lens 248, and passes through illumination window 247 line focuss in VIPA240 by cylindrical lens 250.Then, VIPA240 produces by condenser lens 252 and focuses on collimated light 251 on the minute surface 254.Minute surface 254 can be formed in the minute surface part 256 on the substrate 258.

Minute surface 254 reflexes to light among the VIPA240 by condenser lens 252.Then, light repeatedly reflects in VIPA240, and from illumination window 247 outputs.Pass through cylindrical lens 250 and collimation lens 248 from the light of illumination window 247 outputs, and received by optical fiber 246.

Therefore, light is from VIPA240 output and by minute surface 254 reflected back VIPA240.Light by minute surface 254 reflections transmits by the path of direction just in time opposite with the path of its original transmission on direction.From hereinafter specifically describing as can be seen, the different wave length composition in light is focused the diverse location of minute surface 254, and is reflected back toward VIPA240.As a result, the different wave length composition is by different distances, thus the generation chromatic dispersion.

Figure 14 is the more detailed synoptic diagram that the operation of VIPA among Figure 13 is shown.Suppose that the light with various wavelength compositions is received by VIPA240.As shown in Figure 14, VIPA240 makes with a tight waist 262 the virtual image 260 form, and wherein each virtual image 260 emits beam.

As shown in Figure 14, condenser lens 252 focuses on the different wave length composition from VIPA240 on the difference of minute surface 254.More specifically, long wavelength 264 focuses on a little on 272, and middle wavelength 266 focuses on a little on 270, and shorter wavelength 268 focuses on a little on 274.Then, longer wavelength 264 turns back to than central wavelength 266 more approaching with a tight waist 262 the virtual images 260.Shorter wavelength 268 turns back to than the virtual image 260 of central wavelength 266 further from a tight waist 262.Therefore, this structure provides normal dispersion.

Minute surface 254 is designed to only be reflected in the light of predetermined order of interference, and the light of what order of interference in office should be focused on outside the minute surface 254.More specifically, as indicated above, VIPA will export collimated light.This collimated light will transmit having on the direction in path of difference of m λ with each virtual image, and wherein m is an integer.The m level is interfered the output light that is defined as corresponding to m.

For example, Figure 15 is the synoptic diagram that each order of interference of VIPA is shown.Referring now to Figure 15,, for example the such VIPA of VIPA240 launches collimated light 276,278 and 280.Each collimated light 276,278 with 280 corresponding to different order of interference.Therefore, for example collimated light 276 is the collimated lights corresponding to (n+2) individual order of interference, and collimated light 278 is the collimated lights corresponding to (n+1) individual order of interference, and collimated light 280 is the collimated lights corresponding to n order of interference, and wherein n is an integer.Collimated light 276 is shown as has several wavelength composition 276a, 276b and 276c.Similarly, collimated light 278 is shown as has several wavelength composition 278a, 278b and 278c, and collimated light 280 is shown as and has several wavelength composition 280a, 280b and 280c.At this, wavelength composition 276a, 278a have identical wavelength with 280a.Wavelength composition 276b, 278b have identical wavelength (but different with the wavelength of wavelength composition 276a, 278a and 280a) with 280b.Wavelength composition 276c, 278c and 280c have identical wavelength (but with wavelength composition 276a, 278a and 280a, and different with the wavelength of wavelength composition 276b, 278b and 280b).Although Figure 15 only illustrates the collimated light for three different order of interference, can also be by the collimated light of many other order of interference.

Because the collimated light for the identical wavelength of different order of interference transmits, therefore focus on different positions, thereby minute surface 254 can be only the light reflected back VIPA240 from the single interference level on different directions.For example, as shown in Figure 15, the length of the reflecting part of minute surface 254 should be less relatively, thereby only be reflected corresponding to the light of single interference level.More specifically, in Figure 15, only collimated light 278 is reflected by minute surface 254.In this manner, collimated light 276 and 278 is focused on outside the minute surface 254.

Whose multichannel wavelength division multiplexed light comprises usually.Refer again to Figure 13, if the thickness t between first and

second surfaces

242 and 244 of VIPA240 is set at specific numerical value, then this structure can compensate the chromatic dispersion in each channel simultaneously.

More specifically, each channel has central wavelength.These central wavelengths are usually at a distance of fixing frequency interval.The thickness t of first and second VIPA240s of surface between 242 and 244 should be provided so that all wavelengths composition corresponding to central wavelength has the identical output angle from VIPA240, therefore has identical position on minute surface 254.When thickness t is provided so that for each channel, by being the multiple of the central wavelength of each channel corresponding to the wavelength composition transmission of the central wavelength light path back and forth by VIPA240.Thickness t is called as " WDM coupling Free Spectral Range thickness " or " WDM coupling FSR thickness " hereinafter.

In addition, for identical θ and different integers, light path back and forth (2ntcos θ) by VIPA240 in this situation equals the integer that the wavelength of the central wavelength in corresponding each channel multiply by, wherein n is the refractive index of the material between first and

second surfaces

242 and 244, and θ represents the direction of propagation corresponding to the light beam of the central wavelength of each channel.More specifically, as indicated above, θ represents to import the small inclination (referring to Fig. 8) of the optical axis of light.

Therefore, to have identical output angle corresponding to all wavelengths composition of central wavelength from VIPA240, therefore has the identical focal position on minute surface 254, if t is provided so that the wavelength composition of the central wavelength in corresponding each channel, 2ncos θ is the integral multiple for the central wavelength of each channel of identical θ and different integers.

For example, physical length of 2 millimeters distance back and forth (it approximately is the twice of 1 millimeter thickness of VIPA240) and 1.5 refractive index make all wavelengths at interval with 100GHz satisfy this condition.As a result, VIPA240 can compensate the chromatic dispersion in all channels of wavelength division multiplexed light simultaneously.

Therefore, referring to Figure 14, by thickness t is set is WDM coupling FSR thickness, VIPA240 and condenser lens 252 will make (a) to be focused on the point 270 of minute surface 254 corresponding to the wavelength composition of the central wavelength of each channel, (b) the wavelength composition corresponding to the longer wavelength composition of each channel is focused on the point 272 of minute surface 254, and (c) focuses on the point 274 of minute surface 254 corresponding to the wavelength composition of the shorter wavelength composition of each channel.Therefore, VIPA240 can be used as the chromatic dispersion in all channels that compensate wavelength division multiplexed light.

Figure 16 is the curve map that the dispersion measure of several passages of wavelength division multiplexed light when thickness t is set to WDM coupling FSR thickness is shown.As shown in Figure 16, all channels are provided identical chromatic dispersion.But this chromatic dispersion is discontinuous at interchannel.In addition, can be by the size of minute surface 254 suitably be set, and the wavelength coverage of VIPA240 with each channel of compensation of dispersion is set.

If thickness t is not set to WDM coupling FSR thickness, then the different channels of wavelength division multiplexed light will focus on the difference of minute surface 254.For example, if thickness is back and forth the thickness of 1/2nd, 1/3rd or other mark of light path, then two, three, four or more channel may focus on the identical minute surface, and each channel focuses on different focuses.More specifically, when thickness t is a half of WDM coupling FSR thickness, will focus on the identical point place of minute surface 254 from the light of odd-numbered channels.But, will focus on count different with odd-numbered channels from the light of even-numbered channels.

For example, Figure 17 is the different channels that illustrates on the difference that focuses on minute surface 254.As shown in Figure 17, the wavelength composition of the central wavelength of even-numbered channels is focused on the point of minute surface 254, and the wavelength composition of the central wavelength of odd-numbered channels is focused on the different points.As a result, VIPA240 can compensate the chromatic dispersion in all channels of wavelength division multiplexed light adaptively simultaneously.

There are several different modes to come to change the chromatic dispersion numerical value that adds by VIPA.For example, Figure 18 is for illustrating the side view that uses VIPA to come light is provided a kind of device of variable chromatic dispersion.Referring now to Figure 18,, VIPA240 makes all different order of interference have different angular dispersions.Therefore, the dispersion measure of adding light signal to can change by rotation or mobile VIPA240, thereby is focused on the minute surface 254 corresponding to the light of different order of interference, and is reflected back toward VIPA240.

Figure 19 is for illustrating the side view that uses VIPA that the device of variable dispersion is provided.Referring now to Figure 19,, the relative distance between condenser lens 252 and the minute surface 254 is maintained fixed, and condenser lens 252 and minute surface 254 together move with respect to VIPA240.The motion of condenser lens 252 and minute surface 254 changes the skew that turns back to the light of VIPA240 from lens 254, thereby changes chromatic dispersion.

Figure 20 (A) and 20 (B) are for illustrating the side view of device that uses VIPA to come light is provided the dispersion values of variation.Figure 20 (A) and 20 (B) are similar to Figure 14, in the transmission direction of longer wavelength 264, middle wavelength 266 and the shorter wavelength 268 of the light of being launched by with a tight waist 262 the virtual image 260 shown in Figure 20 (A) and 20 (B).

Referring now to Figure 20 (A),, minute surface 254 is convex mirrors.Beam deviation is amplified by convex mirror.Therefore, can obtain bigger chromatic dispersion with short focal length and less space.When minute surface 254 was convex mirror, shown in Figure 20 (A), the shape of projection generally only can be observed from the side, and can not be from top view.

Referring now to Figure 20 (B),, minute surface 254 is a concave mirror.For concave mirror, the sign of chromatic dispersion is inverted.Therefore, can obtain anomalous dispersion with the short focal length of lens and less space.When minute surface 254 was concave mirror, shown in Figure 20 (B), recessed shape generally only can be observed from the side, and can not be from top view.

Appear as flat pattern when therefore, minute surface 254 is from top view usually.But during from top view, minute surface 254 may be convex mirror or concave mirror, thereby represents that this minute surface is " one dimension " minute surface.

In Figure 20 (A) and 20 (B), minute surface 254 be positioned at condenser lens 252 the focus place or near.

Therefore, as indicated above, it can be raised or sunken that minute surface 254 is watched from the side, for example respectively shown in Figure 20 (A) and 20 (B).Convex mirror can strengthen chromatic dispersion, and concave mirror can weaken chromatic dispersion or make chromatic dispersion just be reversed to (abnormality) from negative (normally).More specifically, convex mirror is created in chromatic dispersion bigger on the negative direction, and concave mirror is created in chromatic dispersion littler on the negative direction, perhaps chromatic dispersion is reversed to positive dirction.This is because chromatic dispersion is a function of the curvature of the minute surface watched from the side.

Figure 21 is the curve map that illustrates from the relation between the wavelength of the output angle of the light beam of VIPA240 and light beam.As shown in Figure 21, the relation curve 282 of wavelength and output angle is not linear.

Because the relation between the output angle of the light beam that wavelength and VIPA produced is not linear, if when therefore use level crossing, common concave mirror or common convex mirror are as minute surface 254, the chromatic dispersion in a wavelength band is not constant.The non-linear high-order dispersion that is called as in chromatic dispersion.

Usually, referring to the device among Figure 20 (A) and 20 (B), usually be appreciated that non-linear in the chromatic dispersion with reference to following equation (3):

(dispersion angle) (1-f (1/R)) ∝ chromatic dispersion

Wherein f is the focal length of lens 252, and R is the radius-of-curvature of minute surface 254.

Figure 22 is the curve that the relation between the wavelength of the angular dispersion of VIPA240 and light beam is shown.Usually, the slope of the curve 282 among the 84 expression Figure 20 of the curve in Figure 22.As shown in Figure 22, angular dispersion is not constant.In addition, angular dispersion changes along with wavelength shift.

Figure 23 is for illustrating one (1-f (1/R)) and the relation curve between the wavelength of above-mentioned equation (3).More specifically, line 286 is represented for level crossing (radius-of-curvature equals " ∞ " (infinity)), the curve of the relation between (1-f (1/R)) item and the wavelength.Line 288 is represented for concave mirror (radius-of-curvature equals "+"), the curve of the relation between (1-f (1/R)) item and the wavelength.Line 290 expression is for convex mirror (radius-of-curvature equals "-"), (1-f1/R)) and wavelength between the curve of relation.As shown in Figure 23, every kind of minute surface has fixing radius-of-curvature.

Figure 24 is for illustrating when minute surface 254 during for convex mirror, level crossing and concave mirror, for example the relation between the chromatic dispersion versus wavelength of the such device of Figure 20 (A) and 20 (B).More specifically, curve 292 is relation curves of chromatic dispersion versus wavelength when minute surface 254 is convex mirror.Curve 294 is relation curves of chromatic dispersion versus wavelength when minute surface 254 is level crossing.Curve 296 is relation curves of chromatic dispersion versus wavelength when minute surface 254 is concave mirror.

In a kind of very general mode, curve 292 and 294 and 296 is represented the product of the suitable straight line shown in the angular dispersion shown in Figure 22 and Figure 23 respectively, shown in above-mentioned equation 3.More specifically, the curve 284 among common curve 292 expression Figure 22 and the product of the straight line 290 among Figure 23.Usually, the curve 284 among curve 294 expression Figure 22 and the product of the straight line 286 among Figure 23.Usually, the curve 284 among curve 296 expression Figure 22 and the product of the straight line 288 among Figure 23.

As can be seen from Figure 24, no matter convex mirror, level crossing and concave mirror are used as minute surface 254, and chromatic dispersion all is unfixed.

According to mentioned above, the linear frequency modulation of the curvature that the wavelength dependence of chromatic dispersion can be by minute surface 254 reduces or eliminates.

More specifically, Figure 25 illustrates curve 298 of (1-f (the 1/R)) item in the above-mentioned equation 3 and the relation curve between the wavelength.Usually, the curve among Figure 25 298 is opposite with curve 284 among Figure 22.Therefore, the minute surface with the characteristic among Figure 25 will provide the constant chromatic dispersion shown in the curve among Figure 26 300.

For example, for the device shown in Figure 14, long wavelength has the chromatic dispersion bigger than the short wavelength on negative direction.Therefore, minute surface 254 can be designed as has the sunk part of long wavelength of reflection, and the bossing of reflects shorter-wavelength, to eliminate the wavelength dependence of chromatic dispersion effectively.Ideally, when wavelength was elongated from weak point, the curvature of minute surface 254 became depression from projection continuously along the focus of light.If this change is based on conventional convex mirror, rather than level crossing, then when wavelength was elongated from weak point, the curvature of minute surface can become slight projection continuously from strong projection.

Therefore, be difficult to design minute surface 254 fixing chromatic dispersion is provided.For example, Figure 27 is the curve map that the characteristic of many different minute surfaces designs is shown.Curve 302 among Figure 27 illustrates when the output light wavelength increases, and becomes the minute surface of depression continuously from projection.Curve 304 illustrates the minute surface that becomes slight convex when the output light wavelength increases from strong projection.Curve 306 illustrates the minute surface that becomes strong depression when the output light wavelength increases from slight depression.Other minute surface design example is as comprising shown in curve 308 and 310.

In fact can adopt countless minute surface designs, and this design can be shown in Figure 27.In addition, the minute surface design is not limited to have as shown in Figure 27 the family curve of same slope.

Figure 28 (A), 28 (B), 28 (C) and 28 (D) illustrate the surface configuration of the various minute surfaces that can be used as minute surface 254.For example, Figure 28 (A) illustrates as the 302 represented minute surfaces that become depression from projection continuously of the curve among Figure 27.Figure 28 (B) illustrates as the 310 represented minute surfaces that become weak projection from strong projection continuously of the curve among Figure 27.Figure 28 (C) illustrates as the 306 represented minute surfaces that become strong depression from weak depression continuously of the curve among Figure 27.

In addition, in fact can adopt countless minute surface designs.For example, Figure 28 (D) illustrates from level crossing and becomes convex mirror.Figure 28 (E) illustrates from level crossing and becomes concave mirror.Figure 28 (F) illustrates the minute surface with bossing and sunk part, but this minute surface does not become depression continuously from projection.

Therefore, as indicated above, a device comprises VIPA, minute surface and lens.VIPA receives input light and produces the corresponding output light (for example light beam) that sends out from VIPA.Lens focus on output light on the minute surface, thus this direct reflection output light, and the light of reflection is turned back to VIPA by lens.This minute surface has makes this device produce constant chromatic dispersion.

For example, the output light by the focusing of lens is incident on the different table millet cake of minute surface along with the output light wavelength changes.The shape of this minute surface makes that this surface point becomes depression from projection continuously along with the output light wavelength is elongated from weak point.As another example, this minute surface can be formed and make this surface point along with the output light wavelength is elongated from weak point, and becomes weak projection from strong projection continuously.

In addition, minute surface can form and make that this surface point becomes strong depression from weak depression continuously along with the output light wavelength is elongated from weak point.At this many other examples are arranged.For example, minute surface has sunk part and bossing, makes to be reflected by this bossing than long more short wavelength's the output light of certain wave, thereby is reflected by sunk part than long more long wavelength's the output light of certain wave.

In addition, for example this minute surface is corresponding to greater than the increase of the output light wavelength of specific wavelength and become sunk part from flat continuously, thereby be irradiated to this flat than long more short wavelength's the output light of certain wave, and be mapped to sunk part than long more long wavelength's the output illumination of certain wave.Perhaps, this minute surface is corresponding to greater than the increase of the output light wavelength of specific wavelength and become flat continuously from bossing, thereby than the long shorter wavelength output of certain wave rayed at bossing, and than the long more long wavelength's of certain wave output rayed at flat.

As indicated above, VPIA provides the angular dispersion more much bigger than diffraction grating.Therefore, VIPA can be used for compensating such as the space grating shown in Fig. 6 (A) and 6 (B) the much bigger chromatic dispersion of structure.

As indicated above, can be called as cylindrical mirror to light reflected back VIPA with the minute surface of compensation of dispersion, because the surface that is shaped as cylinder of this minute surface.In other words, as shown in Figure 29, this minute surface has identical radius-of-curvature along the axle that forms cylinder.Because chromatic dispersion is a function of the radius of curvature mirror mentioned above, therefore when minute surface when forming cylinder spool mobile, chromatic dispersion does not change.As shown in Figure 30 (A), chromatic dispersion can change (referring to Figure 24) in each channel as indicated above.But this chromatic dispersion will be periodic, shown in Figure 30 (B), and this chromatic dispersion approximately equal for all channels.

Figure 31 (A) has Figure 28 (A) for example after the VIPA of the cylindrical mirror of the modification shown in 28 (F) carries out dispersion compensation for being illustrated in to adopt, for a channel of wavelength division multiplexed light, and the relation curve of chromatic dispersion versus wavelength.Referring now to Figure 31 (A),, dispersion measure is identical for each wavelength in the same channel basically as can be seen.

Figure 31 (B) has Figure 28 (A) for example after the VIPA of the cylindrical mirror of the modification shown in 28 (F) carries out dispersion compensation, for all wavelengths (being a plurality of channels therefore) of wavelength division multiplexed light, the relation curve of chromatic dispersion versus wavelength for being illustrated in to adopt.Referring now to Figure 31 (B),, dispersion measure is identical or consistent for all wavelengths in all channels basically as can be seen.

Figure 32 comes light is provided the top view of the device of variable dispersion for using VIPA according to a further embodiment of the invention.Referring now to Figure 32,, coniform mirror 400 is used to a light reflected back VIPA240.Minute surface 400 can move on direction 401.

As indicated above, VIPA240 is created in the collimated light beam that transmits by on the determined direction of light wavelength, and it is called as collimation output light.The angular dispersion direction of VIPA240 is the transmission direction of the collimation output light that changes along with the wavelength shift of light, and for example represented by the direction among Figure 32 402.Collimation output light for different wave length will be on identical plane.

Therefore, direction 402 is along the conical surface and can be described as and the angular dispersion direction of VIPA240 and perpendicular from the transmission direction of the collimated light of VIPA240.In addition, direction 401 can be described to the plane that comprises from the transmission direction of the collimation output light of the different wave length of VIPA240 perpendicular.

Figure 33 (A) and 33 (B) are for illustrating according to one embodiment of present invention, how form the synoptic diagram of minute surface 400 from a cross section of cone 405.Shown in Figure 33 (A), direction 402 is the summit along the surface of cone 405 and by cone 405 preferably.Although, preferably making the summit of direction 401 by cone 405, it not necessarily will pass through this summit.

In Figure 33 (B), minute surface 400 has the radius of 3 different curvature A, B and C.The radius of curvature A is maximum, and the radius of curvature C is minimum, and the radius of curvature B is between A and C.

By minute surface is moved (for example corresponding to the direction among Figure 32 401) on direction 401, the lip-deep A of the coniform mirror of the position of light focus from Figure 33 (B) moves to the C place.Because the radius of A, B and C is different, so chromatic dispersion is also different.Thereby chromatic dispersion changes along with moving of coniform mirror.

Figure 34 (A) is for illustrating according to one embodiment of present invention, when minute surface is mobile on the such direction of direction for example 401, and for curvature A, the B of coniform mirror and the radius of C, dispersion measure and the relation curve between a channel medium wavelength.From Figure 34 (A) as can be seen, the radius of curvature C produces maximum dispersion measure usually.Usually the radius of curvature A produces minimum dispersion measure.From Figure 34 (A) as can be seen, the dispersion measure of the radius of common curvature B generation is between A and C.

From Figure 34 (A) as can be seen, and described with reference to Figure 24 and 30 (A), dispersion measure is for the different wave length in the channel and difference.But, as described in referring to Figure 26,31 (A) and 31 (B),, can provide even dispersion measure at each channel and in all channels by changing minute surface.

For example, Figure 34 (B) be according to one embodiment of the invention when on the coniform mirror direction such when mobile along direction for example 401, the synoptic diagram of the radius of curvature A, B and C is shown.On the contrary, Figure 34 (C) for according to one embodiment of the invention when on the coniform mirror of the distortion that even chromatic dispersion the is provided direction such when mobile along direction for example 401, the synoptic diagram of the radius of curvature A ', the B ' of modification and C ' is shown.For example, in the minute surface of modification, the output light that is focused on by lens 252 is radiated at along with the change of output light wavelength on the different surface points.Thereby when the output light wavelength was elongated from weak point, minute surface was formed and makes surface point become depression from projection continuously.As another example, this minute surface can form and make that surface point becomes weak projection from strong projection continuously when the output light wavelength is elongated from weak point.

In addition, this minute surface can form and make that surface point becomes strong depression from weak depression continuously when the output light wavelength is elongated from weak point.At this many examples are arranged.For example, this minute surface can have sunk part and bossing, thereby is being reflected by the lug boss branch than long more short wavelength's the output light of certain wave, and is reflected by the depressed part branch than long more long wavelength's the output light of certain wave.

As a result, the minute surface of this modification provides even chromatic dispersion at each channel and in all channels.

Figure 35 is for illustrating according to one embodiment of the invention, for the radius of curvature A ', B ' and C ', and the curve map of the relation between chromatic dispersion and the wavelength in a channel.As can be seen from Figure 35, but the radius of each curvature A ', B ' and C ' produces consistent different dispersion measures.Therefore, each channel will have uniform chromatic dispersion, and dispersion measure can change by mobile minute surface.

Figure 36 is the synoptic diagram that illustrates according to the various angles in the device of one embodiment of the invention use VIPA.Referring now to Figure 36,, Θ and θ are average incident angle, and Φ and φ are the output angle that the normal for the such thin slice of the second surface 244 that forms VIPA240 forms.Θ and Φ represent aerial angle between the

surface

242 and 244 of VIPA240, and θ and φ represent the angle in glass between the

surface

242 and 244 of VIPA240.Because the refraction on glass surface, aerial angle are approximately n times of the angle in glass.Wherein n is the refractive index of glass.

Figure 37 is for illustrating according to one embodiment of the invention another synoptic diagram of the angle in the device of use VIPA.As shown in Figure 37, output angle φ is confirmed as the whole road direction doubly that the difference in two adjacent light paths with a tight waist is a wavelength.Adjacently be spaced apart 2t (t is the thickness of VIPA, for example shown in Fig. 8) between with a tight waist, and the output angle in glass is φ.Thereby, 2tcos φ=m λ/n (m is an integer).Thus, angular dispersion be d Φ/d λ=-n ²/ λ Φ, shown in following equation (4):

The spacing of light path: d=2tsin φ

Path poor:

m \cdot \frac{λ}{n} = 2 t \cos φ

\frac{mΔλ}{n} = - 2 t \sin φΔφ

Δφ = - \cos φ \cdot \frac{Δλ}{λ} \approx - \frac{1}{φ} \frac{Δλ}{λ}

θ: the input angle φ in glass: the output angle in glass

Θ: aerial input angle Φ: aerial output angle

Θ≈θ

Φ≈φ

ΔΦ≈Δφ

ΔΦ \approx - \frac{n}{φ} \frac{Δλ}{λ} \approx - \frac{n^{2}}{Φ} - \frac{Δλ}{λ}, \frac{dΦ}{dλ} \approx - \frac{n^{2}}{λΦ}

Equation (4)

Figure 38 illustrates according to one embodiment of the invention how to produce the synoptic diagram of chromatic dispersion in the device that uses VIPA.Figure 14 also illustrates chromatic dispersion and how to produce, but Figure 38 is the synoptic diagram that quantizes more.

Referring now to Figure 38,, the light transmission angle with respect to the normal of VIPA in air is Φ-Θ.And Jiao of lens 252 is poly-to be f, and central authorities' degree of depth with a tight waist is a.Light focusing position on minute surface is f, and central authorities' degree of depth with a tight waist is a.Light focusing position y on minute surface is y=f (Φ-Θ).Mirror shape is the function c (y) of y.Minute surface slope h is dc/dy.Then, by the beam deviation of following equation (5) acquisition after coming transmission back:

Mirror shape: c (y), the slope of minute surface:

h (y) = \frac{dc (y)}{dy}, y \approx f (Φ - Θ)

(beam deviation) ≈ 2 (f-a) (Φ-Θ)+2fh (y)

\approx \frac{{2 n}^{2}}{cΦ} {(f - a) (Φ - Θ) + fh (y)}

Equation (5)

Distance in Figure 38 changes and can easily obtain from beam deviation, and this delay be this apart from the change amount divided by the light velocity in glass.Chromatic dispersion is calculated as the delay change amount along with wavelength shift, and is illustrated by following equation (6):

\approx \frac{{2 n}^{2}}{c} {(f - a) \frac{Θ}{Φ^{2}} + \frac{f}{Φ} \frac{dh (y)}{dy} \frac{dy}{dΦ} - \frac{fh (y)}{Φ^{2}}} \frac{dΦ}{dλ}

Equation (6)

\approx - \frac{{2 n}^{4}}{cλ Φ^{3}} {(f - a) Θ + f^{2} Φ \frac{dh (y)}{dy} - fh (y)}

For the cylindrical mirror of radius r,

If Equation (7)

Then this minute surface is a cylindrical mirror, and has round-shapedly along the direction of angular dispersion, and dh/dy is 1/r simply, and obtains following equation (7):

From equation (7), the chromatic dispersion in the WDM channel is uneven as can be seen, and chromatic dispersion change amount is about and 1/ Φ ³Be directly proportional.

As shown in equation (6), chromatic dispersion is the function of Φ.In order to make the chromatic dispersion in the WDM channel even, this formula need keep constant when Φ changes.Therefore, the numerical value in the braces of equation (6) should with Φ ³Be directly proportional (ignoring the little change of λ).Suppose that proportionality constant is that K (this means that chromatic dispersion is-2n ⁴K/c λ), wherein for the little change of wavelength, n, c, λ, f and a are constant or substantial constant, and we obtain following equation (8):

(f - a) Θ + f^{2} Φ \frac{dh (y)}{dy} - fh (y) = K Φ^{3}

Equation (8) is at this, and y ≈ f (Φ-Θ).Thereby,

Φ = \frac{y}{f} + Θ

Condition for the even chromatic dispersion in the WDM channel is

f^{2} (\frac{y}{f} + Θ) \frac{dh (y)}{dy} - fh (y) = k {(\frac{y}{f} + Θ)}^{3} - (f - a) Θ

At central y=0 place, minute surface slope h should be 0.Can solve equation (8) to obtain following equation (9):

h (y) = \frac{K}{{2 f}^{4}} y^{3} + \frac{3 KΘ}{{2 f}^{3}} y^{2} + \frac{{KΘ}^{2} - (f - a)}{f^{2}} y

Equation (9) obtains the minute surface curve after integration, and by shown in the following equation (10)

c (y) = &Integral; h (y) dy

= \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{K Θ^{2} - (f - a)}{{2 f}^{2}} y^{2}

Equation (10)

Equation (10) decision is for the ideal curve of different K, and example as shown in Figure 28.

Mirror shape is determined that by numerical value K it provides chromatic dispersion.In order to provide the shape of curve A, B and C in Figure 33 (B), can be respectively equation (10) be used little K, medium K and big K value.This curve is shown in Figure 39 (A), 39 (B) and 39 (C).But for the ease of making, this shape is approximately ellipse, parabola or a bi-curved part.In this situation, this minute surface can be used as the part of circular cone.

Figure 40 is the example that the circular cone that is used to form minute surface according to one embodiment of present invention is shown.Referring now to Figure 40,, circular cone 405 has bottom 406.If bottom 406 is circular, then circular cone 406 is common circular cone.But circular cone 405 for example can extend on side surface direction.In this case, bottom 406 is oval, as shown in Figure 40.In the situation of ellipse, bottom 406 has major axis r ₁With minor axis r ₂Direction 401 is determined to the major axis or the crossing straight line of minor axis of bottom and bottom 406 by the summit along conical surface from circular cone.But this straight line not necessarily will be with wherein an axle be crossing.As shown in Figure 40, circular cone 406 is cut with the perpendicular plane 407 of direction 401.According to the drift angle of circular cone 405, be oval, para-curve or hyperbolic curve for the cutting curve 408 of this minute surface.Therefore, the secant in mirror sections 408 is the part of one of these three kinds of curves.The conical minute surface of modification is defined as making secant 408 to be determined rather than determined by these three kinds of shapes by equation (10).

To be focused on the diverse location place of offset direction 401 for the light of different WDM channels.Therefore, different WDM channels will obtain different curves and produce different chromatic dispersions.Therefore, this taper can further be out of shape, and makes to be determined by the equation with required numerical value K (10) for the cutting curve of different WDM channels.This expression chromatic dispersion change is not limited to along with wavelength or WDM channel linearity change, and it can change in any way.

Figure 41 illustrates the synoptic diagram of the minute surface of step shape according to an embodiment of the invention.This quiet can provide different shapes to different WDM channels, and does not cause the over-tilting of minute surface with respect to incident light.

Refer again to Figure 32, minute surface 400 can move on direction 401.Minute surface 400 can also be described to can be in the focal plane of lens 252 or near move.As indicated above, minute surface 400 has cone shape, the perhaps round taper of modification, thus minute surface 400 will have different curvature surfacewise.Owing to curvature is being prolonged direction 401 and changed, and minute surface 400 moves on this direction, therefore can be by minute surface 400 mobile phases are changed chromatic dispersion to less distance.In this design, the displacement of minute surface 400 is generally less than 1 centimetre, the displacement of this minute surface 254 in Figure 19.

In addition, in Figure 19, the position of lens 252 is movably, and in Figure 32, the position of minute surface 252 generally is fixed.Therefore, in Figure 19, need between VIPA240 and lens 252, have bigger interval, thus lens 252 and minute surface 254 together mobile phase with bigger distance, so that required dispersion measure to be provided.Big distance between VIPA240 and the lens 252 is undesirable, and this can increase the overall dimensions of this device.By comparing, in Figure 32, need to have less relatively interval between VIPA240 and the lens 252, and minute surface 400 only needs mobile phase to less distance, so that required dispersion measure to be provided, thereby make whole device more much smaller than the device shown in Figure 19.

Figure 42 uses the side diagrammatic sketch of VIPA with device that chromatic dispersion gradient is provided according to another embodiment of the invention for illustrating.Referring now to Figure 42,, angular dispersion parts 500 are placed between VIPA240 and the lens 252.Angular dispersion parts 500 for example can be transmission-type diffraction grating, reflection-type diffraction grating or holographic grating.

Angular dispersion parts 500 have and the perpendicular angular dispersion direction of the angular dispersion direction of VIPA240.

Best, the angular dispersion amount that is provided by angular dispersion parts 500 should be enough big, is used for the different wave length of different WDM channels with difference.Therefore, the angular dispersion that is preferably provided by angular dispersion parts 500 should be greater than about 0.1 degree/nm.This numerical value is easily by using the diffraction grating as angular dispersion parts 500 to obtain.But, the invention is not restricted to the angular dispersion of any specified quantitative.

In Figure 42, the position of minute surface 400 preferably is fixed.This is different from Figure 32, and wherein the position of minute surface 400 is movably.But in Figure 42, minute surface 400 is not limited to be fixed, and can move to increase variable chromatic dispersion.

By using the angular dispersion parts 500 between VIPA240 and the lens 252, because the angular dispersion of angular dispersion parts 500, light in different channels will be by along the lip-deep direction 401 (not shown in Figure 42) of minute surface 400 and be offset, and will obtain the different curvature of minute surface 400.As a result, different channels will have identical chromatic dispersion.This chromatic dispersion relevant with channel is called as high-order dispersion or chromatic dispersion gradient, and owing to transmit different WDM channels in optical fiber, therefore will see different chromatic dispersions in optical fiber, thereby need the compensation of fibre-optical dispersion.

Figure 43 (A) is used as the curve map of the coniform minute surface of the minute surface 400 among Figure 42 for the dispersion measure of all wavelengths (many channels) for illustrating according to one embodiment of the invention.For example, this coniform minute surface is general shown in Figure 33 (A) and 33 (B).Shown in Figure 43 (A), dispersion measure is not consistent in each channel, and to different channels and difference.

Figure 43 (B) for illustrate use modification according to one embodiment of present invention coniform minute surface as the curve map of the minute surface among Figure 42 400 for the dispersion measure of all wavelengths (many channels).For example, according to one embodiment of present invention, the coniform minute surface of this modification generally has the radius that has curvature A ', B ' and C ' as Figure 34 (C).As shown in Figure 43 (B), dispersion measure is consistent in each channel, and is different for different channels.

In Figure 43 (A) and 43 (B), chromatic dispersion increases and increases along with wavelength.But, in some embodiments of the invention, be inverted or make the direction counter-rotating of taper minute surface by making angular dispersion parts 500, chromatic dispersion can reduce along with the increase of wavelength.

Therefore, chromatic dispersion composition when compensating all WDN, parameter (for example mirror shape, burnt poly-or the like) is designed so that preferably the chromatic dispersion for each WDM channel of for example Figure 43 (A) or 43 (B) is identical amount, but with the opposite in sign of the chromatic dispersion of the transmission line of respective wavelength.That is to say that although by transmission line, different WDM channels can have different dispersion measures, as the chromatic dispersion of the WDM channel that can use VIPA to compensate shown in herein to have different dispersion measures.

Figure 44 illustrates according to one embodiment of the invention to use the synoptic diagram of holographic grating 510 as the angular dispersion parts between VIPA240 and the lens 252.

In addition, Figure 45 illustrates according to one embodiment of the invention to use the synoptic diagram of holographic grating 520 as the angular dispersion parts between VIPA240 and the lens 252.

When diffraction grating is used as the angular dispersion parts (referring to Figure 42), a problem is polarization correlated.Therefore, can use half-wave plate to eliminate the polarization correlated of diffraction grating.

For example, Figure 46 illustrates to use the synoptic diagram that is inserted in the half-wave plate 530 between diffraction grating and the lens 252.

Figure 47 illustrates to use the synoptic diagram that is inserted in the half-wave plate 530 between lens 252 and the coniform minute surface 400.As an example, the plane of polarization that half-wave plate 530 is placed as with respect to the s of diffraction grating or p forms on the axle of miter angle.

Adopt the structure as shown in Figure 46 and 47, the light of the diffraction grating by having the p polarization will turn back to the diffraction grating that this has the s polarization, and the light of the diffraction grating by having the s polarization will turn back to the diffraction grating with p polarization.Therefore, the polarization correlated of diffraction grating is eliminated.

Figure 48 (A) is for illustrating side view or the top view that uses VIPA to come to provide for different channels the device of two different chromatic dispersions according to a further embodiment of the invention.Referring now to Figure 48 (A),, wavelength filter 510 is placed between lens 252 and minute surface M1 and the M2.510 pairs of light from lens 252 of wavelength filter carry out filtering, are directed to minute surface M2 thereby wavelength is the light of λ 1, and wavelength is that the light of λ 2 is directed to M2.Minute surface M1 has the curvature different with M2, so λ 1 will have different chromatic dispersions with λ 2.Therefore, each minute surface M1 and M2 for example can be the cylindrical mirrors of described in this article cylindrical mirror or modification.But for example, minute surface M1 and M2 can be the cylindrical mirrors of modification, to provide consistent in the channel corresponding to λ 1 and λ 2 different dispersion measures.

Figure 48 (B) is for illustrating according to one embodiment of present invention, is used for the relation curve of chromatic dispersion versus wavelength of the device of Figure 48 (A), and wherein minute surface M1 and M2 are the cylindrical mirror of modification, so that uniform chromatic dispersion to be provided in each channel.The device of constructing although Figure 48 (A) is depicted as two wavelength, generally without limits to the number of the wavelength filter that is used to separate other wavelength or channel and minute surface.

For example, Figure 49 uses VIPA to come different channels is provided the side view or the top view of the device of three kinds of different chromatic dispersions for illustrating according to one embodiment of the invention.Referring now to Figure 49,, it is that the turn light rays of λ 1, λ 2 and λ 3 is to minute surface M1, M2 and M3 that

wavelength filter

520 and 530 is used to respectively wavelength.

According to the abovementioned embodiments of the present invention, the device that uses the such minute surface of VIPA and for example coniform mirror coniform or modification the to combine chromatic dispersion that produces chromatic dispersion gradient or higher-order.The coniform chromatic dispersion gradient of this device or the chromatic dispersion gradient or the high-order dispersion that higher-order dispersion compensation sends light (optical fiber) of being designed so that of the coniform or modification of this minute surface.

Light signal is sent in the optical communication system of receiver by transmission line at transmitter, device of the present invention can be inserted in the transmitter, in the transmission line, in the receiver or in any combination of transmitter, transmission line and receiver.For example, in Fig. 1, device of the present invention can be inserted in the transmitter 30, in optical fiber 34 (for example, transmission line) or the receiver, perhaps in any combination of transmitter 30, optical fiber 34 and receiver 36.In addition, two or more devices of the present invention can cascade together, perhaps only a device can be used for transmitter 30, optical fiber 34 and/or receiver 36.Therefore, the invention is not restricted to together to use the number of the device that required effect is provided.

Described in the above embodiment of the present invention, using VIPA that a problem of the device of chromatic dispersion is provided is that this device has the frequency band of relative narrower in transmission spectrum.Usually, the insertion loss owing to from optical fiber-optical fiber makes this frequency band narrow down.For example, in Figure 13, after transmission is reflected by VIPA240 and by minute surface 254, be issued to light from light by optical fiber 246 and loss occurred inserting by 246 reception periods of optical fiber once more.

For example, Figure 50 is for illustrating according to one embodiment of the invention, using VIPA that the curve map of the insertion loss in the device of chromatic dispersion is provided.Referring now to Figure 50,, curve 550 illustrates the actual insertion loss that may generally occur for a channel.On the contrary, curve 560 illustrates the more desirable insertion loss for this channel.

This insertion loss is because several different factors cause, and a principal element is the loss that is caused owing to the different diffraction efficient at different wave length.

For example, Figure 51 is the synoptic diagram that is illustrated in the different diffraction efficient of different wave length.Referring now to Figure 51,, focused on the minute surface 570 by lens 252 from the output light of VIPA240.Be focused on a little on 580 at the light of minimal wave length, be focused on a little on 590, and be focused on a little on 600 at long wavelength's light at the light of central wavelength.But, because the characteristic of VIPA240,, make light at the central wavelength of point 590, and putting 580 and 600 for the most weak respectively at minimal wave length and long wavelength's light for the strongest particularly in the inner repeatedly reflection that occurs of VIPA240.

For example, Figure 52 illustrates the synoptic diagram of light intensity that spreads out of and enter the light of the VIPA the above embodiment of the present invention from optical fiber.Figure 52 comprises optical fiber 246 and

lens

248 and 250 as shown in Figure 13, but VIPA is removed, and allows light to be sent to screen 610.Frame of broken lines 240 illustrates the position that should place VIPA.

As shown in Figure 52, on screen 610, have by the light intensity shown in the curve 620 at light.As a result, be double-peak shape if be provided to the far-field distribution of the input light of VIPA, then insert loss and approach the ideal insertion loss 560 shown in Figure 50.In this manner, the transmission spectrum of this device will be very smooth.

Figure 53 is using VIPA to provide in the device of chromatic dispersion for illustrating according to one embodiment of the invention, and the light phase mask on input optical fibre is with the side view of far-field distribution that double-peak shape is provided.Referring now to Figure 53,, input optical fibre 246 (for example, corresponding to the input optical fibre among Figure 13 246) has core 650.

Light phase mask

660 and 670 covers the upper and lower of core respectively.As a result, will provide the far-field distribution (not shown in Figure 53) of bimodal shape at VIPA and input end, and the insertion loss of this device will have more desirable insertion loss.

Figure 54 illustrates according to the cross sectional view of one embodiment of the invention along the line 54-54 intercepting of Figure 53.From Figure 53 and 54 as can be seen,

phase mask

660 and 670 covers top and bottom respectively.This phase mask should be on the lateral parts of this core.

Not necessarily on input optical fibre, increase phase mask.But, for example can on VIPA, increase phase mask.

For example, Figure 55 is for illustrating according to one embodiment of the invention, the lateral plan of phase mask that is used for the light that VIPA inside receives is provided the far-field distribution of bimodal shape on VIPA.Similar among parts in Figure 55 and Figure 11.

Referring now to Figure 55,, light phase mask 690 and 695 is placed in light entrance window surface 124, so that the bimodal shape far-field distribution of the light that is received VIPA to be provided.

Figure 56 is for illustrating according to a further embodiment of the invention, the lateral plan of phase mask that is used for the light that VIPA inside receives is provided the far-field distribution of bimodal shape on VIPA.Figure 56 is different from Figure 55 part and is that phase mask 690 and 695 is provided on the reflecting surface 122.Therefore, phase mask can be on the reflecting surface or light entrance window of VIPA.

In addition, can obtain the far-field distribution of bimodal shape by the central authorities that phase mask placed input light.

For example, Figure 57 and 58 is for according to a further embodiment of the invention, is used for lateral plan to the phase mask of far-field distribution that bimodal shape is provided at the inner light that receives of VIPA on VIPA.In Figure 57 and 58, phase mask 700 is placed in the central authorities of input light.In this situation, may be π at the light phase of far-field distribution central authorities, and may be 0 in the end.This is opposite with far-field distribution among Figure 53-56.

As indicated above, phase mask can be used to provide the far-field distribution of bimodal shape.This phase mask preferably has the thick position that adds light phase corresponding to π.But the preferable range that adds the light phase of this phase mask is 2/3 π to 4/3 π.

Provide any transparent material of suitable additive phase can be used for this phase mask.For example, SiO ₂It is the typical material that is used as phase mask.

As indicated above, phase mask is used to provide the far-field distribution of bimodal shape.At this, " bimodal shape " is defined as having two peak value and trench between this peak value much at one.The degree of depth of trench should be less than or equal to 50% of top peak value, and preferably less than 20% of top peak value.Best, this peak value is for equating, but 10% the amplitude of differing between this peak value also meets the demands.

In addition, except using phase mask, there is alternate manner to produce the far-field distribution of bimodal shape, and the invention is not restricted to use phase mask to reach this purpose.

The embodiment that above-mentioned use phase mask produces the far-field distribution of bimodal shape can be applicable to use VIPA of the present invention and produces the embodiment of chromatic dispersion.But these embodiment can also be applied to use VIPA as demultiplexer.For example, relate to the invention described above embodiment that uses phase mask to produce the far-field distribution of bimodal shape and can be applied to VIPA in Fig. 7 and 8.

As indicated above, use VIPA to come the device of compensation of dispersion generally to have the damage curve in each WDM channel as shown in Figure 50.As indicated above, this damage curve can become smooth by using the light phase mask.But, have alternate manner and make this damage curve become smooth, for example by adding extra loss.

For example, Figure 59 is according to one embodiment of the invention, excess loss is added to the synoptic diagram of this damage curve.Referring now to Figure 59,, by adding excess loss 705, damage curve 550 will be flattened and become curve 710.

Figure 60 is for illustrating according to one embodiment of the invention, thereby uses the excess loss parts to provide excess loss to make the synoptic diagram of this damage curve planarization.Referring now to Figure 60,, 720 expressions of VIPA dispersion compensator use VIPA to produce a kind of device of chromatic dispersion as described herein.Excess loss parts 730 and VIPA dispersive component 720 cascade mutually.Excess loss parts 730 can be in the upstream or the downstream of VIPA dispersive component 720, and between VIPA dispersive component 720 and excess loss parts 730 some optical elements can be arranged.Therefore, the invention is not restricted to the particular location of VIPA dispersive component 720 with respect to excess loss parts 730.

Excess loss parts 730 for example can be interferometer or wavelength filter.But Mach-Zehnder interferometer or Fabry-Perot interferometer are suitable for, because they have periodic transmission curve, and by selecting suitable interferometric parameter, this cycle can be adjusted to the WDM channel spacing.Therefore, will be simultaneously to all WDM channels, make whole transmission curve planarization.

Use the foregoing description of excess loss parts to be used to use VIPA to produce the embodiments of the invention of chromatic dispersion.But these embodiment can also be applied to use VIPA as demultiplexer.For example, the above embodiment of the present invention relevant with the use of excess loss parts can be applied to the VIPA in Fig. 7 and 8.

Except using the excess loss parts, can also make otherwise smooth this damage curve.

For example, Figure 61 is for illustrating according to one embodiment of the invention, is used for that VIPA provides the minute surface of chromatic dispersion and with the lateral plan of the minute surface of smooth this damage curve.Referring now to Figure 61,, minute surface 704 can be coniform mirror, the coniform mirror of modification, smooth minute surface or the minute surface of any other shape.Figure 61 illustrates the lateral plan of position P, Q and R.Position P, Q and R correspond respectively to the point 274,270 and 272 among Figure 14.Be focused on a little 274 or the P place at short wavelength's light, and long wavelength's light is focused on a little 272 or the R place.

Adjusted along the angular dispersion direction of VIPA at the reflectivity of minute surface 740.That is to say, minimum at the reflectivity at position Q place, thus higher loss is provided, and higher at the reflectivity at position P and R place, so that lower loss to be provided.Therefore, in the position of approaching WDM channel middle part, catoptrical power reduction, so damage curve is flattened.In order to change reflectivity, the light absorbing material layer can cover approximated position Q part, perhaps under the situation of multilayer minute surface, can regulate the thickness of one or more aspects.

If it is not the cone shape minute surface of coniform or modification that VIPA uses, that is to say, if VIPA uses the minute surface 254 among for example Figure 14,20 (A), 20 (B) or uses the mirror shape of Figure 28 (A) to 28 (F), then the adjusting of reflectivity can be effectively by realizing minute surface composition rather than practical adjustments reflectivity.

For example, Figure 62 illustrates the front view of minute surface 750 according to an embodiment of the invention.Referring now to Figure 62,, minute surface 750 is patterned to as shown in FIG., to change the reflectivity of minute surface 750.At this, near the Q of position, the width of minute surface 750 less than narrow beam size 760, therefore be reduced near the reflected optical power the Q of position.

Figure 63 (A), 63 (B) and 63 (C) are for illustrating according to one embodiment of the invention, and using at VIPA is not under the situation of cone shape minute surface 770 of coniform or modification, are used to regulate the synoptic diagram of the another kind of mode of effective reflectivity.More specifically, Figure 63 (A), 63 (B) and 63 (C) are illustrated in the vertical view that position P, Q and R are in the incident light 780 on the minute surface 770 respectively.Shown in Figure 63 (A), 63 (B) and 63 (C), not the accommodation reflex rate, and change the mirror angle in overlooking.In the embodiment of the invention described above, for example shown in Figure 14, under the situation of overlooking, the best average light incident angle of minute surface is perpendicular.But if minute surface is inclination in vertical view, shown in Figure 63 (A), 63 (B) and 63 (C), reflected light is deflected, and the coupling efficiency of output optical fibre is reduced.At position P and R place, incident light 780 is perpendicular with minute surface 770, and light turns back to output optical fibre fully.On the other hand, at position Q place, minute surface 770 is inclination in vertical view, and reflected light departs from the output optical fibre direction a little.This causes the planarization of excess loss and damage curve.By progressively changing the pitch angle of the minute surface 770 in the vertical view, then can produce the excess loss that is used to make the damage curve planarization effectively along the angular dispersion direction of VIPA.

The change of the specular angle as shown in Figure 63 (A), 63 (B) and 63 (C), and can be used for said apparatus as the composition of the minute surface among Figure 62, this device are used VIPA and are not coniform or the cone shape minute surface of modification combines.This be because, in the situation of the coniform minute surface of coniform or modification, overlook down, may be focused on the diverse location of minute surface effectively at the light of a certain wavelength, so this minute surface should be not patterned or in the vertical view medium dip.

Figure 64 illustrates the synoptic diagram that uses the grating between VIPA and lens according to one embodiment of the invention.Figure 64 is similar to Figure 44 and 45.But the embodiment among Figure 44 and 45 uses holographic grating and reflection-type grating respectively, and the embodiment in Figure 64 uses grating 800.Grating 800 for example is a kind of transmission-type grating, but has big angle from the output light of grating 800 with respect to the input light that arrives grating 800, and this angle is more than or equal to 30 degree and be less than or equal in the scopes of 150 degree.For example, in the object lesson of Figure 64, form about 90 degree with respect to the input light that arrives grating 800 from the output light of grating 800.Grating 800 for example can be made by holograph.Because the angular dispersion of grating 800 is relatively large in little space, then the structure in Figure 64 is very practical.

In addition, the embodiment among Figure 46 and 47 can be applied to the embodiment of Figure 64.More specifically, the half-wave plate 530 shown in Figure 46 and 47 can be applied to the embodiment among Figure 64, to eliminate the polarization correlated of grating 800.

In Figure 44,45 and 64, minute surface 400 can be moved to change dispersion measure.

For example, Figure 65,66 and 67 corresponds respectively to Figure 44,45 and 64, but this illustrates minute surface 400 and can be moved to change dispersion measure.For example, in Figure 65,66 and 67, minute surface 400 moves on direction 810 along minute surface 400 surfaces, and perpendicular to the angular dispersion direction 402 of VIPA240.

From above being appreciated that among each embodiment of the present invention, can change dispersion measure.Therefore, VIPA combines so that an adjustable dispersion compensator to be provided with other parts (for example minute surface, lens or the like).

Figure 68 and 69 illustrates scalable dispersion compensator in accordance with another embodiment of the present invention.Referring now to Figure 68 and 69,, this adjustable dispersion compensator comprises a variable curvature minute surface 455, and its curvature changes along the direction that parallels with the angular dispersion direction of VIPA340.As shown in Figure 70, this variable curvature minute surface 455 for example comprises flat 455a and bossing 455b, but other structure of countless versions can be arranged.

As shown in Figure 68 and 69, this scalable dispersion compensator comprise be used to make variable curvature minute surface 455 around with the mechanisms of perpendicular axle 456 rotations of the angular dispersion direction of VIPA340.In addition, axle 456 can be described to the plane that comprises for from the transmission direction of the collimation output light of the different wave length of VIPA340 perpendicular.This turning axle 456 can make the differently curved part of minute surface 455 arrive on the focal plane of condenser lens 352.

Figure 68 and 69 illustrates by the scalable dispersion compensator by the light of the longer wavelength 464 that comprises a channel and the synoptic diagram in the path of the light of the shorter wavelength 468 that comprises a channel.But the light that comprises any optical channel comprises the light of continuous wavelength.In Figure 68, variable curvature minute surface 455 is provided so that bossing 455b intercepting and the light 464 of reflection longer wavelength and the light 468 of shorter wavelength, and in Figure 69, this minute surface is provided so that flat 455a intercepting and reflects these light.As indicated above, projection and flat 455a-455b scioptics 352 reflect back into VIPA340 to light 464 and 468, thereby produce chromatic dispersion by a relatively large margin when bossing is placed in the light path.

Because the minute surface 455 of variable curvature comprises a plane, it has and places on this plane or inner rotating shaft, and usually, the center of curvature of any specific part of this rotating shaft and variable curvature minute surface 455 is inconsistent.Therefore, can not make the different sweep of this variable curvature minute surface arrive lens 352 focus places or near tram usually around axle 456 rotation variable curvature minute surfaces 455.Therefore, the motion of minute surface between variable position comprises variable curvature minute surface 455 around axle 456 rotations, and axle 456 is along the predefined paths translation.In Figure 68 and 69, axle 456 is included in from the position shown in Figure 68 and rotates to the process of the position shown in Figure 69, or in inverse process, the bar or the pin that move along a slit or track 458.In addition, Zhou translation can realize by many other mechanisms.Thereby the path that the minute surface that makes the curvature (projection, depression and plane) that comprises different amplitudes and type partly arrives required light path is controlled in the translation of the rotation of minute surface 455 and axle 456 simultaneously in this device.In this manner, the device in Figure 68 and 69 is as a kind of adjustable dispersion compensator.

Figure 71 illustrates scalable dispersion compensator according to another embodiment of the invention.Compensator in Figure 71 comprise with Figure 68 and 69 in the similar parts of compensator, the single variable curvature minute surface 455 replaced among Figure 68 and 69 of the mirror components 558 of this compensator just.Mirror components 558 comprises a plurality of

minute surface

555a, 555b, 555c or the like, all minute surfaces be fixed be set to approximately and rotating shaft 556 equidistant.At this, " a plurality of " minute surface is represented two or more minute surfaces or minute surface segment.These minute surfaces or minute surface segment generally include the surface of the curvature (projection, depression and plane) with various amplitudes and type.It is on the minute surface support 557 at center that minute surface or

minute surface segment

555a, 555b, 555c or the like are affixed to rotating shaft 556.By the rotation of minute surface support 557 around rotating shaft 556, each minute surface of a plurality of

minute surface

555a, 555b, 555c or the like can arrive the position of intercepting and

reflection ray

464 and 468.

In Figure 71, minute surface support 557 comprises that with rotating shaft 556 be the cylinder at center.But, can adopt any geometric configuration and structure as this minute surface support 557, as long as the distance on the surface of 464 and 468 minute surface keeps Jiao who is substantially equal to lens 352 to gather from lens 352 to reflection ray.Although this minute surface or

minute surface segment

555a, 555b, 555c or the like are shown in the discontinuous minute surface segment of segmentation among Figure 71, these minute surfaces can also comprise the part of the single minute surface of continuous variation curvature.

Figure 72 is the synoptic diagram of scalable dispersion compensator in accordance with another embodiment of the present invention.Scalable dispersion compensator among Figure 72 comprises identical VIPA340 and constitutes scalable dispersion compensator among Figure 68 and 69 and condenser lens 352 parts of the scalable dispersion compensator among Figure 71.But, opposite with scalable dispersion compensator and the scalable dispersion compensator among Figure 71 in Figure 68 and 69, at this curved mirror of not placing along the focal line of lens 352.In addition, the compensator in Figure 72 is included in outside described focal line and the rotating mirror 602 a plurality of minute surfaces of placing or

minute surface segment

655a, 655b, 655c or the like.Minute surface or

minute surface segment

655a, 655b, 655c or the like generally include the surface with various amplitudes and curvature (projection, depression and plane).Separate discontinuous minute surface fragment although these minute surfaces or minute surface fragment are shown as in Figure 72, these minute surfaces also comprise the part of the single minute surface of continuous variation curvature.

In Figure 72, rotating mirror 602 is placed relative with VIPA340 along the focal line of lens 352, and at an angle linear with this, thereby is the path doubling of

light

464 and 468 one or more minute surfaces or

minute surface segment

655a, 655b, 655c or the like.Level crossing 602 is around placing on the reflecting surface level crossing 602 and along axle 603 rotations of the focal line of lens 352.Note that the axle 603 shown in Figure 72 usually is not actual parts but a geometry.The path (not shown) of the light of the central wavelength of optical channel is crossing with the minute surface 602 in turning axle 603 positions.

The circular arc 606 of a part that constitutes a plurality of minute surfaces of the scalable dispersion compensator among Figure 72 or

minute surface segment

655a, 655b, 655c or the like and along expression with rotating shaft 603 be the circle at center is placed.The center that the radius of circular arc 606 is provided so that lens 352 to the distance of axle 603 add from axle 603 to circular arc 606 to equal Jiao of lens 352 apart from sum poly-.Therefore, light 464 and 468 all focuses on respectively a little on 472 and 474, and its

mid point

472 and 474 all is positioned on the surface of a minute surface or

minute surface segment

655a, 655b, 655c or the

like.Light

464 and 468 is reflected by a plurality of minute surfaces or minute surface segment 655a, one of 655b, 655c or the like, makes every light 464 and 468 turn back to rotating mirror 602, returns scioptics 352 and turns back to VIPA340.

In the scalable dispersion compensator of Figure 72, the dispersion measure that produces in light signal can change around its center rotation by making level crossing 602, as regulating shown in the direction 604.The rotation of this rotating mirror 602 can be controlled

reflection spot

472 and 474 from one group of fixedly motion of another arrangement of mirrors face by the time such as minute surface or

minute surface segment

655a, 655b, 655c etc.As indicated above, make light signal be reflected back toward the size and Orientation decision of curvature mirror of the specific minute surface of VIPA340 or

minute surface segment

655a, 655b, 655c by dispersion measure that this device produced.According to placing these minute surfaces or minute surface fragments along circular arc 606, flashlight remains focused on the surface of each minute surface or

minute surface segment

655a, 655b, 655c or the like.This device is as a kind of and adjusting dispersion compensator in this manner.

Figure 73 is the synoptic diagram that a kind of in accordance with another embodiment of the present invention scalable dispersion compensator is shown.Scalable dispersion compensator among Figure 73 comprise with Figure 68,69,71 and 72 in the scalable dispersion compensator in the identical VIPA340 of VIPA.But opposite with these other scalable dispersion compensators, the scalable dispersion compensator in Figure 73 is not included in the condenser lens of VIPA340 outgoing side.In addition, the scalable dispersion compensator in Figure 73 comprises the off axis paraboloidal mirror 702 of carrying out focusing function.Off axis paraboloidal mirror is placed in the outgoing side of VIPA340 from axle, thereby intercepting and reflection comprise the light by the optical channel of VIPA340 output.Two such opticpaths comprise long wavelength's light 464 and comprise short wavelength's light 468, and are shown in Figure 73.Off axis paraboloidal mirror 702 can be around an axle 703 rotation, and this is along the light setting of the central wavelength (not shown) of the optical channel that intersects with paraboloidal mirror 702.Note that the axle 703 among Figure 73 is not a physical unit, but a kind of geometry.

Off axis paraboloidal mirror 702 comprises focus 705.By the focusing of off axis paraboloidal mirror 702, be focused on a little 705 by VIPA340 output and the collimated ray that comprises the central wavelength of optical channel (not shown).Comprising long wavelength's the light 464 of described channel and the light 468 that comprises the short wavelength of described channel focuses on respectively a little on 472 and 474, shown in

Figure 73.Point

472 and 474 is set at the opposite side of focus 705, shown in Figure 73.Off axis paraboloidal mirror 702 around axle 703 rotary courses in, focus 705 and

point

472 and 474 move along circular arc 706, this arc representation is the part of the circle at center with axle 703.Scalable dispersion compensator in Figure 73 further comprises a plurality of minute surfaces or minute surface segment 755a, 755b, 755c or the like, and place along circular arc 706 on its surface, and tangent with this circular arc.Although minute surface or minute surface segment 755a, 755b, 755c or the like are shown as the discontinuous minute surface fragment of separation among Figure 73, these minute surfaces can also comprise the part of the single minute surface of continuous variation curvature.

In the scalable dispersion compensator in Figure 73, the dispersion measure that produces in the light signal that comprises light 464 and 468 can change by off axis paraboloidal mirror 702 is rotated on adjusting direction 704 around axle 703.The rotation of off axis paraboloidal mirror 702 can be controlled

reflection spot

472 and 474 from one group of fixedly motion of another arrangement of mirrors face by the time such as minute surface or minute surface segment 755a, 755b, 755c etc.The light that comprises signaling channel is then by a minute surface or minute surface segment 755a, 755b, 755c or the like reflected back off axis paraboloidal mirror 702.These light are collimated and reflected back VIPA340 again by off axis paraboloidal mirror 702 then.As indicated above, make light signal be reflected back toward the size of curvature mirror of the specific minute surface of VIPA or minute surface segment 755a, 755b, 755c and type (projection, depression or plane) decision by the dispersion measure that device produced among Figure 73.According to placing these minute surfaces or minute surface fragments along circular arc 706, flashlight remains focused on the surface of each minute surface or minute surface segment 755a, 755b, 755c or the like.This device is as a kind of and adjusting dispersion compensator in this manner.

As indicated above, minute surface is used to a light reflected back VIPA.Therefore, minute surface can be called as " the light Returning equipment " that light is turned back to VIPA.But, the invention is not restricted to use minute surface as the light Returning equipment.For example, prism (replacement minute surface) can be used as the light Returning equipment that light is turned back to VIPA.In addition, minute surface/or the various combinations or the lens devices of prism can be used as the light Returning equipment that light is turned back to VIPA.

In each embodiment of the present invention, lens be used to from the light focusing of VIPA to minute surface, and return projector turned back to VIPA from minute surface.For example, referring to the operation of the lens among Figure 13 252.But, the invention is not restricted to use lens to be used for this purpose.For example, minute surface can be used to replace lens 252 and focus on light from VIPA, and return projector is turned back to VIPA.

In last these embodiments of the invention, VIPA has the reflectance coating of reflection ray.For example, Fig. 8 illustrates and has the reflectance coating 122 that is used for reflection ray and 124 VIPA76.But VIPA does not limit the use of use " film " and comes the cremasteric reflex surface.In addition, VIPA only must have suitable reflecting surface, and these reflecting surfaces may by " film " formed or may can't help " film " formed.

In addition, in the above embodiment of the present invention, VIPA comprises the transparent glass sheet that generation is repeatedly reflected.For example, Fig. 8 illustrates the VIPA76 of the transparent glass sheet 120 that has reflecting surface on it.But VIPA is not limited to use " thin slice " of glass material or type of service to separate this reflecting surface.In addition, this reflecting surface only must keep being isolated mutually at interval by some.For example, the reflecting surface of VIPA can be isolated by " air ", and without glass sheet.Therefore, reflecting surface can be described to for example be isolated by optical glass or the such transparent material of air.

According to the abovementioned embodiments of the present invention, a kind of device uses VIPA to come compensation of dispersion.For this purpose, embodiments of the invention are not limited to concrete VIPA structure.But, any in these different VIPA structures of discussing or can be used for the device of compensation of dispersion in United States Patent (USP) 08/685,362 disclosed structure.For example, VIPA can have or not have illumination window, and is not limited to accordance with any particular embodiment at each lip-deep reflectivity of VIPA.

The present invention relates to a kind of VIPA dispersion compensator." VIPA dispersion compensator " this term is meant and uses VIPA to produce the device of chromatic dispersion as described herein.For example, the device in Figure 13,19,32,42,44 and 48 (A) illustrates a kind of VIPA dispersion compensator.

Each embodiment of VIPA described herein can be called as virtual image phased array (VIPA) generator.

Although described several preferred embodiments of the present invention, one of skill in the art can make change to these embodiment, and does not break away from principle of the present invention and spirit, and scope of the present invention defines in claims.

Claims

1. device, comprising:

Virtual image phased array device (VIPA) generator, it receives the input light of different wave length, and produces the corresponding collimation output light that sends from the VIPA generator on by the determined direction of this input light wavelength; And

Reflecting surface, it should output light reflected back VIPA generator, and this reflecting surface is along having different curvature at different positions with comprising from the perpendicular direction in the plane of the transmission direction of the collimation output light of the VIPA generator of the light that is used to import different wave length.

2. device according to claim 1 wherein further comprises:

Lens or minute surface, its output light from the VIPA generator focuses on reflecting surface, thus this reflecting surface reflects this output light, and the light that is reflected is turned back to the VIPA generator by described lens or minute surface.

3. device according to claim 1, wherein this reflecting surface has the coniform of coniform or modification.

4. device according to claim 2, wherein this reflecting surface can be on the focal plane of lens or near in move.

5. device according to claim 2, wherein this reflecting surface has the coniform of coniform or modification.

6. device according to claim 2, wherein this reflecting surface along on the focal plane and with the perpendicular straight line of optical transmission direction from the collimation of VIPA output light, contact with the focal plane of lens.

7. device according to claim 1, wherein this reflecting surface can move on described rectilinear direction.

8. device according to claim 2 wherein further comprises:

Angular dispersion parts between VIPA generator and described lens or minute surface, these angular dispersion parts have the angular dispersion direction perpendicular with described plane.

9. device according to claim 8, wherein these angular dispersion parts are transmission-type diffraction grating, reflection-type diffraction grating or holographic grating.

10. device according to claim 1, wherein the input light that is received by the VIPA generator has bimodal shape far-field distribution.

11. device according to claim 1 wherein further comprises:

The device that is used to make the input light that received by the VIPA generator to have bimodal shape far-field distribution.

12. device according to claim 1 wherein further comprises:

At least one phase mask, it makes the input light that is received by the VIPA generator have bimodal shape far-field distribution.

13. device according to claim 1 wherein further comprises:

Input light is provided to the optical fiber of VIPA generator; And

At least one phase mask on optical fiber, it makes the input light that is received by the VIPA generator have bimodal shape far-field distribution.

14. device according to claim 1 wherein further comprises:

At least one is at the lip-deep phase mask of VIPA generator, and it makes the input light that is received by the VIPA generator have bimodal shape far-field distribution.

15. device according to claim 1, wherein

This input only has wavelength-division multiplex (WDM) light of a plurality of channels, owing to, make each channel have dispersion measure corresponding to wavelength by a transmission lines, and

The parameter of reflecting surface makes this device provide with it each channel and transmits the identical but dispersion measure of opposite in sign of the dispersion measure caused by transmission line.

16. device according to claim 1, wherein

This input light has relevant damage curve, and

This device further comprises loss is added to input light with the excess loss parts of smooth this damage curve.

17. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the input light of different wave length, and produce corresponding collimation output light on by input light wavelength determined direction, thereby the output light differentiation mutually spatially that this output light and input light with different wave length are produced from the transmission of VIPA generator;

Cone shape reflecting surface with coniform or modification; And

Lens and minute surface, its light focusing of propagating from the VIPA generator is to this reflecting surface, thus this reflecting surface reflection output light, the light that is reflected directly returns the VIPA generator by described lens or minute surface.

18. device according to claim 17, cone shape reflecting surface wherein coniform or modification is corrected inhomogeneous chromatic dispersion.

19. device according to claim 17, wherein the coniform reflecting surface of this coniform or modification can with the perpendicular direction of the angular dispersion direction of VIPA generator on move.

20. device according to claim 17, wherein this reflecting surface can with the perpendicular direction in plane on move, this plane comprise for the input light of different wave length from the collimation output side optical transmission of VIPA generator output to.

21. device according to claim 17, wherein this reflecting surface can be on the focal plane of lens or minute surface or near in move.

22. device according to claim 17 wherein further comprises:

Angular dispersion parts between VIPA generator and lens.

23. device according to claim 22, wherein these angular dispersion parts have and the perpendicular angular dispersion direction of the angular dispersion direction of VIPA generator.

24. device according to claim 22, wherein these angular dispersion parts are transmission-type diffraction grating, reflection-type diffraction grating or holographic grating.

25. device according to claim 17, wherein the input light that is received by the VIPA generator has bimodal shape far-field distribution.

26. device according to claim 17 wherein further comprises:

27. device according to claim 17 wherein further comprises:

28. device according to claim 17 wherein further comprises:

Input light is provided to the optical fiber of VIPA generator; And

29. device according to claim 17 wherein further comprises:

30. device according to claim 17, wherein

The parameter of described at least reflecting surface and described lens or minute surface makes this device provide with it each channel and transmits the identical but dispersion measure of opposite in sign of the dispersion measure caused by transmission line.

31. device according to claim 17, wherein

This input light has relevant damage curve, and

32. a device, comprising:

The angular dispersion parts, it has a passage area that receives light and export light from these angular dispersion parts, these angular dispersion parts receive the input light with each wavelength in the continuous wavelength scope by this passage area, and this input light is repeatedly reflected, to produce self-interference, it forms the collimation output light that sends from these angular dispersion parts along by the determined direction of input light wavelength, thereby and with in this continuous wavelength scope by the difference mutually spatially of the formed output light of the input light with other wavelength; And

Reflecting surface, output light reflected back angular dispersion parts, in these angular dispersion parts, repeatedly to reflect, then from this passage area output, this reflecting surface along with the perpendicular direction in plane that comprises from the transmission direction of the collimation output light of the angular dispersion parts of the light that is used to import different wave length, have different curvature at diverse location.

33. device according to claim 32 wherein further comprises:

Lens or minute surface, its output light from the angular dispersion parts focuses on reflecting surface, thus this reflecting surface reflects this output light, and the light that is reflected is turned back to the angular dispersion parts by described lens or minute surface.

34. device according to claim 32, wherein this reflecting surface has the coniform of coniform or modification.

35. device according to claim 33, wherein this reflecting surface has the coniform of coniform or modification.

36. device according to claim 32, wherein this reflecting surface can with the perpendicular direction in described plane on move.

37. device according to claim 35, wherein this reflecting surface can with the perpendicular direction in described plane on move.

38. device according to claim 33, wherein these angular dispersion parts are first angular dispersion parts, and this device further comprises:

The second angular dispersion parts between the first angular dispersion parts and described lens or minute surface, these second angular dispersion parts have the angular dispersion direction perpendicular with described plane.

39. according to the described device of claim 38, wherein these second angular dispersion parts are transmission-type diffraction grating, reflection-type diffraction grating or holographic grating.

40. device according to claim 32, wherein the input light that is received by these angular dispersion parts has bimodal shape far-field distribution.

41. device according to claim 32 wherein further comprises:

The device that is used to make the input light that received by these angular dispersion parts to have bimodal shape far-field distribution.

42. device according to claim 32 wherein further comprises:

At least one phase mask, it makes the input light that is received by the angular dispersion parts have bimodal shape far-field distribution.

43. device according to claim 32 wherein further comprises:

Input light is provided to the optical fiber of angular dispersion parts; And

At least one phase mask on optical fiber, it makes the input light that is received by the angular dispersion parts have bimodal shape far-field distribution.

44. device according to claim 32 wherein further comprises:

At least one phase mask on the angular dispersion parts surface, it makes the input light that is received by the angular dispersion parts have bimodal shape far-field distribution.

45. a device, comprising:

The angular dispersion parts, has a passage area that receives light and export light from these angular dispersion parts, these angular dispersion parts receive the input light of line focus by this passage area, and this input light is repeatedly reflected, to produce self-interference, it forms the collimation output light that sends from these angular dispersion parts along by the determined direction of input light wavelength, thereby and with the difference mutually spatially of the formed output light of the input light with different wave length; And

Reflecting surface, its output light reflected back angular dispersion parts, in these angular dispersion parts, repeatedly to reflect, then from this passage area output, this reflecting surface along with the perpendicular direction in plane that comprises from the transmission direction of the collimation output light of the angular dispersion parts of the light that is used to import different wave length, have different curvature at diverse location.

46., wherein further comprise according to the described device of claim 45:

47. according to the described device of claim 45, wherein this reflecting surface has the coniform of coniform or modification.

48. according to the described device of claim 46, wherein this reflecting surface has the coniform of coniform or modification.

49. according to the described device of claim 45, wherein this reflecting surface can with the perpendicular direction in described plane on move.

50. according to the described device of claim 46, wherein this reflecting surface can with the perpendicular direction in described plane on move.

51. according to the described device of claim 46, wherein these angular dispersion parts are first angular dispersion parts, this device further comprises:

52. according to the described device of claim 51, wherein these second angular dispersion parts are transmission-type diffraction grating, reflection-type diffraction grating or holographic grating.

53. according to the described device of claim 45, wherein the input light that is received by these angular dispersion parts has bimodal shape far-field distribution.

54., wherein further comprise according to the described device of claim 45:

55., wherein further comprise according to the described device of claim 45:

56., wherein further comprise according to the described device of claim 45:

Input light is provided to the optical fiber of angular dispersion parts; And

57., wherein further comprise according to the described device of claim 45:

58. a device, comprising:

First and second reflecting surfaces, this second reflecting surface have to make and to incide the reflectivity that the part light on it sees through, wherein:

Input light at each wavelength is focused on the straight line, and

First and second reflecting surfaces are provided so that the input light that sends from this straight line is repeatedly reflected between first and second reflecting surfaces, thereby make many light see through second reflecting surface, many transmitted ray is interfered mutually, producing the collimation output light that sends from this second reflecting surface along by the determined direction of input light wavelength, thereby for the difference mutually spatially of the formed output light of the input light with different wave length; And

Minute surface, second reflecting surface is exported back in its this light reflection, to pass through this second reflecting surface, and between first and second reflecting surfaces, repeatedly reflect, this minute surface has different curvature along exporting the perpendicular direction in plane of the transmission direction of light with comprising the input light for different wave length from the collimation of second reflecting surface at diverse location.

59., wherein further comprise according to the described device of claim 58:

Lens or minute surface, its output light from second reflecting surface focuses on the mirror surface, thus this mirror surface reflection should be exported light, and the light that is reflected is turned back to this second reflecting surface by described lens or minute surface.

60. according to the described device of claim 58, wherein this mirror surface has the coniform of coniform or modification.

61. according to the described device of claim 59, wherein this mirror surface has the coniform of coniform or modification.

62. according to the described device of claim 59, wherein this mirror surface can with the perpendicular direction in described plane on move.

63., wherein further comprise according to the described device of claim 59:

Angular dispersion parts between second reflecting surface and described lens or minute surface, these angular dispersion parts have the angular dispersion direction perpendicular with described plane.

64. according to the described device of claim 63, wherein these angular dispersion parts are transmission-type diffraction grating, reflection-type diffraction grating or holographic grating.

65. according to the described device of claim 58, wherein this input light has bimodal shape far-field distribution.

66., wherein further comprise according to the described device of claim 58:

Be used to the device that makes this input light have bimodal shape far-field distribution.

67., wherein further comprise according to the described device of claim 58:

At least one phase mask, it makes this input light have bimodal shape far-field distribution.

68., wherein further comprise according to the described device of claim 58:

Input light is focused on the optical fiber of this straight line; And

At least one phase mask on optical fiber, it makes this input light have bimodal shape far-field distribution.

69., wherein further comprise according to the described device of claim 58:

At least one phase mask on one of first and second reflecting surfaces, it makes by this input light has bimodal shape far-field distribution.

70. a device, comprising:

First and second reflecting surfaces, second reflecting surface have the feasible reflectivity that the part light on it sees through that incides;

Be used to make input light at each wavelength to be focused device on the straight line, the radiant light that sends from this straight line is repeatedly reflected between first and second reflecting surfaces, thereby make many light see through second reflecting surface, many transmitted ray is interfered mutually, producing the collimation output light that sends from this second reflecting surface along by the determined direction of input light wavelength, thereby for the difference mutually spatially of the formed output light of the input light with different wave length;

Cone shape mirror surface with coniform or modification; And

Lens or minute surface focus on the output light from second reflecting surface on this mirror surface, thereby this mirror surface reflection should be exported light, and the light that is reflected is returned second reflecting surface by described lens or minute surface.

71. a device, comprising:

Virtual image phased array (VIPA) generator, its reception comprises the wavelength division multiplexed light of the line(ar) focus of first and second wavelength, and produce respectively with first and second of the corresponding collimation of first and second wavelength and export light, this first and second output light is being sent from the VIPA generator respectively by determined first and second directions of first and second wavelength respectively;

Lens, it focuses on the first and second output light from the VIPA generator;

First and second minute surfaces, it has the coniform of coniform or modification respectively, is used to produce uniform chromatic dispersion; And

Wavelength filter, it is to carrying out filtering by the light that lens focused on, thereby the light at first wavelength is focused first minute surface, and reflected by first minute surface, and be focused second minute surface at the light of second wavelength and reflected by second minute surface, first and second light that are reflected are turned back to the VIPA generator by wavelength filter and described lens institute orientation.

72. according to the described device of claim 71, wherein first and second minute surfaces are removable, the dispersion measure that provides with the light that changes respectively first and second wavelength.

73. a device, comprising:

First and second reflecting surfaces, second reflecting surface have to make and to incide the reflectivity that the part light on it sees through, wherein

Wavelength-division multiplex (WDM) light that comprises the light of first and second wavelength is focused

To straight line, and

First and second reflecting surfaces are provided so that the WDM light that sends from this straight line

By repeatedly reflection between first and second reflecting surfaces, thereby make many light see through the

Two reflecting surfaces, many transmitted rays are interfered mutually, from first of second reflecting surface

With the second output light respectively by determined first and second directions of first and second wavelength

Last transmission;

Focusing from the first and second output lens of light of second reflecting surface or photoconduction to minute surface;

Coniform first and second minute surfaces that are used to produce even chromatic dispersion that have coniform or modification respectively; And

Wavelength filter, it is to carrying out filtering by described lens or photoconduction to the light that minute surface focused on, thereby the light at first wavelength is focused first minute surface, and reflected by first minute surface, and being focused second minute surface at the light of second wavelength is reflected by second minute surface, first and second light that are reflected are turned back to second reflecting surface by wavelength filter and described lens or photoconduction to minute surface institute orientation, repeatedly to reflect by second reflecting surface and between first and second surfaces.

74. according to the described device of claim 73, wherein first and second minute surfaces are removable, the dispersion measure that provides with the light that changes respectively first and second wavelength.

75. a communication system, comprising:

Optical transmission line;

Transmitter by this transmission line transmitting optical signal;

Reception is from the receiver of the light signal of this transmission line; And

Compensation equipment, it is connected on one of transmitter, receiver and transmission line, and light signal is provided chromatic dispersion gradient or high-order dispersion, this compensation equipment comprises:

Virtual image phased array (VIPA) generator, it receives the input as line(ar) focus

The light signal of light, and be created in by importing on the determined direction of light wavelength from VIPA

The corresponding collimation output light of generator output,

Cone shape minute surface with coniform or modification, and

Light guide, its output light from the VIPA generator focuses on the minute surface,

Thereby this direct reflection output light, this output light is turned back to VIPA by this light guide

Generator.

76. a communication system, comprising:

Optical transmission line;

Transmitter by this transmission line transmitting optical signal;

First and second reflecting surfaces, second reflecting surface have feasible inciding on it

The reflectivity that part light sees through, wherein

Light signal is focused on the straight line, and is poly-as the line to this compensation equipment

Burnt input light, and

First and second reflecting surfaces are provided so that the input of sending from this straight line

Light is repeatedly reflected between first and second reflecting surfaces, thereby makes many light

See through second reflecting surface, many transmitted rays are interfered mutually, from second reflection

The collimation output light on surface, it is along by on the determined direction of input light wavelength

Transmission, thus can be to the formed output light of the input light with different wave length at sky

Between go up difference, and

Minute surface, its output light reflected back second reflecting surface is to show by second reflection

Face, and between first and second reflecting surfaces, repeatedly reflecting, this minute surface along

Export light with the input light that comprises for different wave length from the collimation of second reflecting surface output

The perpendicular direction in the plane of transmission direction on, have different songs in different positions

Rate.

77. a device, comprising:

Virtual image phased array (VIPA) generator, it receives each wavelength and has the input light of the far-field distribution of bimodal shape, and is created in by exporting light from the corresponding collimation of VIPA generator output on the determined direction of input light wavelength; And

The reflecting surface of this output light reflected back VIPA generator.

78., wherein further comprise according to the described device of claim 77:

79., wherein further comprise according to the described device of claim 77:

The device that is used to make the input light that received by this VIPA generator to have bimodal shape far-field distribution.

80., wherein further comprise according to the described device of claim 77:

81., wherein further comprise according to the described device of claim 77:

Input light is provided to the optical fiber of VIPA generator; And

82., wherein further comprise according to the described device of claim 77:

83. a device, comprising:

Virtual image phased array (VIPA) generator, it receives each wavelength and has the input light of the far-field distribution of bimodal shape, and be created in by on the input light wavelength determined direction from the corresponding collimation output light of VIPA generator output, thereby can spatially distinguish mutually for the output light that the input light of different wave length is produced;

Reflecting surface; And

Lens or minute surface, its input light from the VIPA generator focuses on this reflecting surface, thus this reflecting surface reflects this output light, and the light that is reflected is turned back to this VIPA generator by described lens or minute surface.

84. 3 described devices according to Claim 8 wherein further comprise:

85. 3 described devices according to Claim 8 wherein further comprise:

86. 3 devices of stating according to Claim 8 wherein further comprise:

Input light is provided to the optical fiber of VIPA generator; And

87. 3 described devices according to Claim 8 wherein further comprise:

88. a device, comprising:

The angular dispersion parts, it has a passage area that receives light and export light from these angular dispersion parts, these angular dispersion parts receive the input light that has each wavelength in the continuous wavelength scope and have bimodal shape far-field distribution by this passage area, and this input light is repeatedly reflected, to produce self-interference, it forms the collimation output light that sends from these angular dispersion parts along by the determined direction of input light wavelength, thereby and with in this continuous wavelength scope by the difference mutually spatially of the formed output light of the input light with other wavelength; And

A reflecting surface, its output light reflected back angular dispersion parts are repeatedly to reflect in these angular dispersion parts, then from this passage area output.

89. 8 described devices according to Claim 8 wherein further comprise:

90. 8 described devices according to Claim 8 wherein further comprise:

91. 8 described devices according to Claim 8 wherein further comprise:

92. 8 described devices according to Claim 8 wherein further comprise:

Input light is provided to the optical fiber of angular dispersion parts; And

93. 8 described devices according to Claim 8 wherein further comprise:

94. a device, comprising:

The angular dispersion parts, it has a passage area that receives light and export light from these angular dispersion parts, these angular dispersion parts receive the input light of the line focus with bimodal shape far-field distribution by this passage area, and this input light is repeatedly reflected, to produce self-interference, it forms the collimation output light that sends from these angular dispersion parts along by the determined direction of input light wavelength, thereby and with the difference mutually spatially of the formed output light of the input light with different wave length; And

Reflecting surface, its output light reflected back angular dispersion parts are repeatedly to reflect in these angular dispersion parts, then from this passage area output.

95., wherein further comprise according to the described device of claim 94:

96., wherein further comprise according to the described device of claim 94:

The device that makes the input light that received by these angular dispersion parts have bimodal shape far-field distribution.

97., wherein further comprise according to the described device of claim 94:

98., wherein further comprise according to the described device of claim 94:

Input light is provided to the optical fiber of angular dispersion parts; And

99., wherein further comprise according to the described device of claim 94:

100. a device, comprising:

Input light at each wavelength is focused on the straight line, and

Minute surface, second reflecting surface export back in its this light reflection, passing through this second reflecting surface, and repeatedly reflects between first and second reflecting surfaces.

101., wherein further comprise according to the described device of claim 100:

Lens or minute surface, its output light from this second reflecting surface focuses on the mirror surface, thus this mirror surface reflection should be exported light, and the light that is reflected is turned back to second reflecting surface by described lens or photoconduction to minute surface.

102., wherein further comprise according to the described device of claim 100:

103., wherein further comprise according to the described device of claim 100:

104., wherein further comprise according to the described device of claim 100:

Input light is focused on the optical fiber of this straight line; And

105., wherein further comprise according to the described device of claim 100:

At least one phase mask on one of first and second reflecting surfaces, it makes this input light have bimodal shape far-field distribution.

106. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the line focus input light of each wavelength, and be created in by exporting light from the corresponding collimation of VIPA generator output on the determined direction of input light wavelength, thereby can spatially distinguish mutually for the output light that the input light of different wave length is produced, this input light has relevant damage curve; And

Excess loss parts, its loss add in the input light, with smooth this damage curve.

107. according to the device described in the claim 106, wherein these excess loss parts are one of Mach-Zehnder interferometer, Fabry-Perot interferometer, interference of light meter and wavelength filter.

108. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the line focus input light of each wavelength, and be created in by exporting light from the corresponding collimation of VIPA generator output on the determined direction of input light wavelength, this VIPA generator has corresponding angular dispersion direction; And

Reflecting surface, its output light reflected back VIPA generator, to provide chromatic dispersion or high-order dispersion to this input light, wherein the reflectivity of this reflecting surface quilt is regulated along the angular dispersion direction of VIPA generator.

109. according to the described device of claim 108, wherein this reflecting surface is one of the coniform minute surface of coniform minute surface, modification and column minute surface.

110. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the line focus input light of each wavelength, and be created in by exporting light from the corresponding collimation of VIPA generator output on the determined direction of input light wavelength, this VIPA generator has corresponding angular dispersion direction, and this input light has relevant damage curve;

Reflecting surface; And

Lens or minute surface, its input light from the VIPA generator focuses on this reflecting surface, thereby this reflecting surface reflects this output light, and the light that is reflected is turned back to this VIPA generator by described lens or minute surface, wherein this reflecting surface is patterned, with smooth this damage curve.

111. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the line focus input light of each wavelength, and is created in by exporting light from the corresponding collimation of VIPA generator output on the determined direction of input light wavelength; And

Reflecting surface, its output light reflected back VIPA generator, along exporting the perpendicular direction in plane of the transmission direction of light from the standard value of VIPA generator output with the input light that comprises for different wave length, this reflecting surface has different curvature in different positions, and the curvature c of this reflecting surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

112., wherein further comprise according to the described device of claim 111:

Lens or minute surface, its output light from the VIPA transmitter focuses on reflecting surface, thus this reflecting surface reflects this output light, and the light that is reflected is turned back to the VIPA transmitter by described lens or minute surface.

113. according to the described device of claim 111, wherein this reflecting surface has the coniform of coniform or modification.

114. according to the described device of claim 112, wherein this reflecting surface can move in the focal plane of these lens or near it.

115. according to the described device of claim 112, wherein this reflecting surface has the coniform of coniform or modification.

116. according to the described device of claim 112, wherein this reflecting surface along on the focal plane and with the perpendicular straight line of optical transmission direction from the collimation of VIPA output light, contact with the focal plane of lens.

117. according to the described device of claim 116, wherein this reflecting surface can move on described rectilinear direction.

118., wherein further comprise according to the described device of claim 112:

119. according to the described device of claim 118, wherein these angular dispersion parts are gratings.

120., wherein further comprise according to the described device of claim 119:

Eliminate the polarization correlated quarter-wave plate of this grating.

121. according to the described device of claim 119, wherein this reflecting surface is removable, to change dispersion measure.

122. according to the described device of claim 111, wherein the input light that is received by the VIPA generator has bimodal shape far-field distribution.

123., wherein further comprise according to the described device of claim 111:

124., wherein further comprise according to the described device of claim 111:

Input light is provided to the optical fiber of VIPA generator; And

125., wherein further comprise according to the described device of claim 111:

126. according to the described device of claim 111, wherein

127. according to the described device of claim 111, wherein this VIPA generator comprises:

First and second surfaces, this second surface is light tight substantially; And

With the first surface same level on illumination window, this input light enters into the VIPA generator by illumination window, first and second surfaces are provided so that the input light repeatedly reflection between first and second surfaces that enters the VIPA generator by illumination window, to produce described output light.

128. according to the described device of claim 127, wherein:

First surface has 100% reflectivity basically, and

This illumination window has 100% transmissivity basically.

129. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the line focus input light of each wavelength, and be created in by on the input light wavelength determined direction from the corresponding collimation output light of VIPA generator output, thereby the output light difference mutually spatially that is produced by the input light of different wave length;

Cone shape reflecting surface with coniform or modification; And

Lens or minute surface, its output light from the VIPA generator focuses on the reflecting surface, thus this reflecting surface reflects this output light, and the light that is reflected is turned back to the VPIA generator by described lens or minute surface, and the curvature c of this reflecting surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

130. according to the described device of claim 129, wherein this cone shape reflecting surface coniform or modification is corrected uneven chromatic dispersion.

131. according to the described device of claim 129, the coniform reflecting surface of wherein coniform or modification can with the perpendicular direction of the angular dispersion direction of VIPA generator on move.

132. according to the described device of claim 129, wherein this reflecting surface can move with comprising on the direction perpendicular from the plane of the transmission direction of the collimation output light of VIPA generator for the input light of different wave length.

133. according to the described device of claim 129, wherein this reflecting surface can move in the focal plane of these lens or near it.

134., wherein further comprise according to the described device of claim 129:

Angular dispersion parts between VIPA generator and this lens.

135. according to the described device of claim 134, wherein these angular dispersion parts have the perpendicular angular dispersion direction of angular dispersion direction of this VIPA generator.

136. according to the described device of claim 134, wherein these angular dispersion parts are gratings.

137., wherein further comprise according to the described device of claim 136:

Eliminate the polarization correlated quarter-wave plate of this grating.

138. according to the described device of claim 136, wherein this reflecting surface is removable, to change dispersion measure.

139. according to the described device of claim 129, wherein the input light that is received by the VIPA generator has bimodal shape far-field distribution.

140., wherein further comprise according to the described device of claim 129:

141., wherein further comprise according to the described device of claim 129:

Input light is provided to the optical fiber of VIPA generator; And

142., wherein further comprise according to the described device of claim 129:

143. according to the described device of claim 129, wherein

The parameter of at least one described reflecting surface and described lens and minute surface makes this device provide with it each channel and transmits the identical but dispersion measure of opposite in sign of the dispersion measure caused by transmission line.

144. according to the described device of claim 129, wherein this VIPA generator comprises:

145. according to the described device of claim 144, wherein:

First surface has 100% reflectivity basically, and

This illumination window has 100% transmissivity basically.

146. a device, comprising:

A reflecting surface, its output light reflected back angular dispersion parts, in these angular dispersion parts, repeatedly to reflect, then from this passage area output, this reflecting surface along with comprise on the direction perpendicular from the plane of the transmission direction of the collimation output light of angular dispersion parts for the input light of different wave length, have different curvature in different positions, the curvature c of this reflecting surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

147., wherein further comprise according to the described device of claim 146:

148. according to the described device of claim 146, wherein this reflecting surface has the coniform of circular cone or modification.

149. according to the described device of claim 147, wherein this reflecting surface has the coniform of circular cone or modification.

150. according to the described device of claim 147, wherein this reflecting surface can with the perpendicular direction in described plane on move.

151. according to the described device of claim 147, wherein this reflecting surface can with the perpendicular direction in described plane on move.

152. according to the described device of claim 147, wherein these angular dispersion parts are first angular dispersion parts, this device further comprises:

The second angular dispersion parts between the first angular dispersion parts and described lens or minute surface, these first angular dispersion parts have the angular dispersion direction perpendicular with described plane.

153. according to the described device of claim 152, wherein these angular dispersion parts are gratings.

154., wherein further comprise according to the described device of claim 153:

Eliminate the polarization correlated quarter-wave plate of this grating.

155., wherein further comprise according to the described device of claim 146:

156., wherein further comprise according to the described device of claim 146:

Input light is provided to the optical fiber of angular dispersion parts; And

157., wherein further comprise according to the described device of claim 146:

158. according to the described device of claim 146, wherein these angular dispersion parts comprise:

First and second surfaces, this first surface is light tight substantially, with the first surface same level on passage area, this first and second surface is provided so that by the input light of the separate component repeatedly reflection between first and second surfaces of getting inside the character that one is playing of this passage area, to produce described output light.

159. according to the described device of claim 158, wherein:

First surface has 100% reflectivity basically, and

This passage area has 100% transmissivity basically.

160. a device, comprising:

The angular dispersion parts, it has a passage area that receives light and export light from these angular dispersion parts, these angular dispersion parts receive line focus input light by this passage area, and this input light is repeatedly reflected, to produce self-interference, it forms the collimation output light that sends from these angular dispersion parts along by the determined direction of input light wavelength, thereby and with in this continuous wavelength scope by the difference mutually spatially of the formed output light of the input light with other wavelength; And

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

161., wherein further comprise according to the described device of claim 160:

162. according to the described device of claim 160, wherein this reflecting surface has the coniform of circular cone or modification.

163. according to the described device of claim 161, wherein this reflecting surface has the coniform of circular cone or modification.

164. according to the described device of claim 160, wherein this reflecting surface can with the perpendicular direction in described plane on move.

165. according to the described device of claim 161, wherein these angular dispersion parts are first angular dispersion parts, this device further comprises:

166. according to the described device of claim 165, wherein these angular dispersion parts are gratings.

167., wherein further comprise according to the described device of claim 166:

Eliminate the polarization correlated quarter-wave plate of this grating.

168., wherein further comprise according to the described device of claim 160:

The device that is used to make the input light that received by the angular dispersion parts to have bimodal shape far-field distribution.

169., wherein further comprise according to the described device of claim 160:

170., wherein further comprise according to the described device of claim 160:

Input light is provided to the optical fiber of angular dispersion parts; And

171., wherein further comprise according to the described device of claim 160:

172. according to the described device of claim 160, wherein these angular dispersion parts comprise:

173. according to the described device of claim 172, wherein:

First surface has 100% reflectivity basically, and

This passage area has 100% transmissivity basically.

174. a device, comprising:

Illumination window;

First and second reflecting surfaces, this first reflecting surface do not make light see through basically, and be placed in the illumination window same level on, this second reflecting surface has the reflectivity that the part light that shines on it is seen through, wherein

The input light of each wavelength is by this illumination window and focus on the straight line, with

And

This first and second reflecting surface is provided so that from the input light of this straight line emission

Repeatedly reflection between first and second reflecting surfaces, thus make many light see through the

Two reflecting surfaces, these many transmitted rays are interfered mutually to produce along the ripple by input light

The collimation output light that long determined direction transmits from second reflecting surface, thereby for tool

There is the formed output light of input light of different wave length spatially can distinguish;

The mirror surface, its output light reflected back second reflecting surface is to pass through this second reflecting surface, and between first and second reflecting surfaces, repeatedly reflect, this minute surface along with comprise for the input light of different wave length on the perpendicular direction in the plane of the transmission direction of the collimation output light of second reflecting surface output, have different curvature in different positions, the curvature c on this mirror surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

175., wherein further comprise according to the described device of claim 174:

Lens or minute surface, its output light from second reflecting surface focuses on the mirror surface, thus this mirror surface reflection should be exported light, and the light that is reflected is turned back to second reflecting surface by described lens or minute surface.

176. according to the described device of claim 174, wherein this mirror surface has the coniform of circular cone or modification.

177. according to the described device of claim 175, wherein this mirror surface has the coniform of circular cone or modification.

178. according to the described device of claim 175, wherein this mirror surface can with the perpendicular direction in described plane on move.

179., wherein further comprise according to the described device of claim 175:

180. according to the described device of claim 179, wherein these angular dispersion parts are gratings.

181., wherein further comprise according to the described device of claim 180:

Eliminate the polarization correlated quarter-wave plate of this grating.

182. according to the described device of claim 180, wherein this mirror surface is removable, to change dispersion measure.

183. according to the described device of claim 174, wherein this input light has bimodal shape far-field distribution.

184., wherein further comprise according to the described device of claim 174:

Be used for the device that this input light has bimodal shape far-field distribution.

185., wherein further comprise according to the described device of claim 174:

186., wherein further comprise according to the described device of claim 174:

Input light is focused on the optical fiber of this straight line; And

At least one phase mask on optical fiber, it makes by this input light has bimodal shape far-field distribution.

187., wherein further comprise according to the described device of claim 174:

This illumination window has 100% reflectivity basically, and

This first reflecting surface has 100% transmissivity basically.

188. a device, comprising:

Illumination window;

First and second reflecting surfaces, this first reflecting surface do not make light see through basically, and be placed in the illumination window same level on, this second reflecting surface has the reflectivity that the part light that shines on it is seen through;

Device, the input light that is used to make each wavelength is by this illumination window and focus on straight line, disperse with repeatedly reflection between this first and second reflecting surface from this straight line, thereby make many light see through second reflecting surface, these many transmitted rays are interfered the collimation output light that transmits from second reflecting surface along by the determined direction of input light wavelength to produce mutually, thereby spatially can distinguish for the formed output light of the input light with different wave length;

The mirror surface, it has the coniform of circular cone or modification; And

Lens or minute surface, its output light from second reflecting surface focuses on this mirror surface, thus this mirror surface reflection should be exported light, and the light that is reflected is returned second reflecting surface by described lens or minute surface, and the curvature c on this mirror surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

189. a device, comprising:

Virtual image phased array (VIPA) generator, its reception comprises the line focus wavelength division multiplexed light of the light of first and second wavelength, and produce respectively and export light corresponding to the collimation first and second of first and second wavelength, the first and second output light are being sent from the VIPA generator on determined first and second directions by first and second wavelength respectively;

Lens or photoconduction are to minute surface, and it focuses on the first and second output light from the VIPA generator;

First and second minute surfaces, it has the coniform of the coniform or modification that is used to produce uniform chromatic dispersion respectively; And

Wavelength filter, it filters by described lens or photoconduction to light that minute surface focused on, thereby the light of first wavelength is focused first minute surface, and reflected by first minute surface, the light of second wavelength is focused second minute surface, and reflected by second minute surface, first and second light that reflected are led to minute surface by wavelength filter and described lens or photoconduction and turn back to the VIPA generator, and the curvature c of each first and second minute surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

190. according to the described device of claim 189, wherein first and second minute surfaces are removable, the dispersion measure that provides with the light that changes respectively first and second wavelength.

191. according to the described device of claim 189, wherein this VIPA generator comprises:

First and second surfaces, this first surface do not allow light see through basically; And

With the first surface same level on illumination window, this first and second surface is provided so that the wavelength division multiplexed light by this illumination window is received by the VIPA generator, repeatedly reflection between first and second surfaces then, thus the described first and second output light produced.

192. according to the described device of claim 191, wherein:

This first surface has and is essentially 100% reflectivity, and

This illumination window has 100% transmissivity basically.

193. a device, comprising:

Illumination window;

Wavelength-division multiplex (WDM) light that comprises first and second wavelength is by this illumination window

And focus on the straight line, and

This first and second reflecting surface is provided so that the input light of dispersing from this straight line

Long determined direction transmits from second reflecting surface, corresponds respectively to first and second

The first and second output light of the collimation of wavelength;

Lens or photoconduction are to minute surface, and it focuses on the first and second output light from second reflecting surface;

Wavelength filter, it filters by described lens or photoconduction to light that minute surface focused on, thereby the light of first wavelength is focused first minute surface, and reflected by first minute surface, the light of second wavelength is focused second minute surface, and reflected by second minute surface, first and second light that reflected are led to minute surface by wavelength filter and described lens or photoconduction and turn back to second reflecting surface, to pass through second reflecting surface, and be subjected to repeatedly reflecting between first and second surfaces, the curvature c of each first and second minute surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

194. according to the described device of claim 193, wherein first and second minute surfaces are removable, the dispersion measure that provides with the light that changes respectively first and second wavelength.

195. a communication system, comprising:

Optical transmission line;

Transmitter by this transmission line transmitting optical signal;

Basically unreflecting illumination window,

First and second reflecting surfaces, this first reflecting surface do not allow light see through basically,

And on the plane identical with illumination window, second reflecting surface has to make and to incide it

On the reflectivity that sees through of part light, wherein

Light signal is by this illumination window and be focused on the straight line, as arriving

The line focus input light of this compensation equipment, and

First and second reflecting surfaces are provided so that the input of dispersing from this straight line

See through second reflecting surface, many transmitted rays are interfered mutually, to produce from the

The collimation output light of two reflecting surfaces, it is along determined by the input light wavelength

Transmit on the direction, thereby to the formed output light of the input light with different wave length

Can spatially distinguish, and

Minute surface, its output light reflected back second reflecting surface, to pass through second reflecting surface, and between first and second reflecting surfaces, repeatedly reflect, this minute surface along with comprise for the input light of different wave length on the perpendicular direction in the plane of the transmission direction of the collimation output light of second reflecting surface output, have different curvature in different positions, the curvature c on this mirror surface (y) is as follows:

c (y) = \frac{K}{{8 f}^{4}} y^{4} + \frac{KΘ}{{2 f}^{3}} y^{3} + \frac{{KΘ}^{2} - (f - a)}{{2 f}^{2}} y^{2} .

196. a device, comprising:

The variable curvature minute surface, it is set to handle by virtual image phased array (VIPA) the light reflected back VIPA generator that generator produced; And

Rotating shaft, this minute surface is around this rotating shaft rotation, and this exports the curvature of the minute surface of light to change reflection.

197. according to the described device of claim 196, wherein the curvature of this minute surface changes along the direction that parallels with the angular dispersion direction of VIPA generator.

198. according to the described device of claim 196, wherein the angular dispersion direction of this rotating shaft and VIPA generator is perpendicular.

199. according to the described device of claim 197, wherein the angular dispersion direction of this rotating shaft and VIPA generator is perpendicular.

200. according to the described device of claim 196, wherein this rotating shaft is placed on this minute surface or its inside.

201. according to the described device of claim 197, wherein this rotating shaft is placed on this minute surface or its inside.

202. according to the described device of claim 198, wherein this rotating shaft is placed on this minute surface or its inside.

203. according to the described device of claim 196, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

204. according to the described device of claim 197, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

205. according to the described device of claim 198, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

206. according to the described device of claim 196, wherein the curvature of this minute surface becomes bossing from flat.

207. according to the described device of claim 197, wherein the curvature of this minute surface becomes bossing from flat.

208. according to the described device of claim 198, wherein the curvature of this minute surface becomes bossing from flat.

209. according to the described device of claim 200, wherein the curvature of this minute surface becomes bossing from flat.

210. according to the described device of claim 203, wherein the curvature of this minute surface becomes bossing from flat.

211. a device, comprising:

Virtual image phased array (VIPA) generator, it produces the light that the VIPA generator sends;

The variable curvature minute surface, it is set to a light reflected back VIPA generator; And

Rotating shaft, this minute surface are exported the curvature of the minute surface of light around this rotating shaft rotation to change reflection.

212. according to the described device of claim 211, wherein the curvature of minute surface changes along the direction that parallels with the angular dispersion direction of VIPA generator.

213. according to the described device of claim 211, wherein the angular dispersion direction of this rotating shaft and VIPA generator is perpendicular.

214. according to the described device of claim 212, wherein the angular dispersion direction of this rotating shaft and VIPA generator is perpendicular.

215. according to the described device of claim 211, wherein this rotating shaft is placed on this minute surface or its inside.

216. according to the described device of claim 212, wherein this rotating shaft is placed on this minute surface or its inside.

217. according to the described device of claim 213, wherein this rotating shaft is placed on this minute surface or its inside.

218. according to the described device of claim 211, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

219. according to the described device of claim 212, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

220. according to the described device of claim 213, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

221. according to the described device of claim 211, wherein the curvature of this minute surface becomes bossing from flat.

222. according to the described device of claim 212, wherein the curvature of this minute surface becomes bossing from flat.

223. according to the described device of claim 213, wherein the curvature of this minute surface becomes bossing from flat.

224. according to the described device of claim 215, wherein the curvature of this minute surface becomes bossing from flat.

225. according to the described device of claim 218, wherein the curvature of this minute surface becomes bossing from flat.

226., wherein further comprise according to the described device of claim 211:

Lens, its turn light rays from the VIPA generator arrives this minute surface, thus this light of this direct reflection, the light that is reflected is turned to back the VIPA generator by these lens.

227., wherein further comprise according to the described device of claim 218:

228. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the input light of each wavelength, and is created in the corresponding output light that sends from the VIPA generator on the determined direction of input light wavelength;

The variable curvature minute surface, it is set to the generator output light reflected back VIPA, thus the output light that is reflected passes through the VIPA generator, thus provide dispersion compensation to this input light; And

Rotating shaft, this minute surface are exported the curvature of the minute surface of light to change reflection, thereby are changed the input dispersion measure that light provided around this rotating shaft rotation.

229. according to the described device of claim 228, wherein the curvature of minute surface changes along the direction that parallels with the angular dispersion direction of VIPA generator.

230. according to the described device of claim 228, wherein the angular dispersion direction of this rotating shaft and VIPA generator is perpendicular.

231. according to the described device of claim 229, wherein the angular dispersion direction of this rotating shaft and VIPA generator is perpendicular.

232. according to the described device of claim 228, wherein this rotating shaft is placed on this minute surface or its inside.

233. according to the described device of claim 228, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

234. according to the described device of claim 230, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

235. according to the described device of claim 228, wherein the curvature of this minute surface becomes bossing from flat.

236., wherein further comprise according to the described device of claim 228:

237., wherein further comprise according to the described device of claim 223:

238. a device, comprising:

Illumination window;

First and second reflecting surfaces that are parallel to each other, this first reflecting surface do not make light see through basically, and be placed in the illumination window same level on, this second reflecting surface has the reflectivity that the part light that shines on it is seen through, wherein

And

The minute surface of variable curvature, its output light reflected back second reflecting surface be with by this second reflecting surface, and repeatedly reflect between first and second reflecting surfaces; And

239. according to the described device of claim 238, wherein the curvature of this minute surface changes along the perpendicular direction in plane of the direction of transfer of the collimation output light that sends from second reflecting surface with comprising for the input light of different wave length.

240. according to the described device of claim 238, wherein the plane of the direction of transfer of the collimation output light that sends from second reflecting surface with comprising for the input light of different wave length of this rotating shaft is perpendicular.

241. according to the described device of claim 238, wherein this rotating shaft is placed on this minute surface or its inside.

242. according to the described device of claim 238, wherein further comprise a path for translation, this rotating shaft can be rotated and translation thereby provide along this path movement, exports the curvature of the minute surface of light to change reflection.

243. according to the described device of claim 238, wherein the curvature of this minute surface becomes bossing from flat.

244., wherein further comprise according to the described device of claim 238:

Lens, its output light from second reflecting surface redirect to this minute surface, thus this direct reflection should be exported light, and the light that is reflected turns to back second reflecting surface by these lens.

245. a device, comprising:

A plurality of minute surfaces, it has the different surfaces curvature that is used for reflection ray; And

Support, it has a rotating shaft and supports and the equally spaced a plurality of minute surfaces of this rotating shaft, this support can be around this rotating shaft rotation, so that each minute surface of the different a plurality of minute surfaces in position is by virtual image phased array (VIPA) the light reflected back VIPA generator that generator produced.

246. according to the described device of claim 245, wherein a plurality of minute surfaces are the discontinuous minute surfaces that separate.

247. according to the described device of claim 245, wherein a plurality of minute surfaces are the parts that continuously change the single mirror surface of curvature.

248. a device, comprising:

Produce virtual image phased array (VIPA) generator of light;

A plurality of minute surfaces with different surfaces curvature; And

Support, it has a rotating shaft and supports and the equally spaced a plurality of minute surfaces of this rotating shaft, and this support can be around this rotating shaft rotation, so that the light reflected back VIPA generator that each minute surface handle of the different a plurality of minute surfaces in position is produced by the VIPA generator.

249. according to the described device of claim 248, wherein a plurality of minute surfaces are the discontinuous minute surfaces that separate.

250. according to the described device of claim 248, wherein a plurality of minute surfaces are the parts that continuously change the single mirror surface of curvature.

251., wherein further comprise according to the described device of claim 248:

Lens, its light focusing that is produced by the VIPA generator are to each minute surface, with reflection ray, and institute's reflection ray are turned to back the VIPA generator.

252. a device, comprising:

Virtual image phased array (VIPA) generator, it receives the input light of each wavelength, and is created in the corresponding output light that sends from the VIPA generator by on the determined direction of input light wavelength;

A plurality of minute surfaces with different surfaces curvature; And

Support, it has a rotating shaft and supports and the equally spaced a plurality of minute surfaces of this rotating shaft, this support can be around this rotating shaft rotation, so that each minute surface of the different a plurality of minute surfaces in position is the light reflected back VIPA generator that is produced by the VIPA generator, thereby provides dispersion compensation to input light.

253. according to the described device of claim 252, wherein a plurality of minute surfaces are the discontinuous minute surfaces that separate.

254. according to the described device of claim 252, wherein a plurality of minute surfaces are the parts that continuously change the single mirror surface of curvature.

255., wherein further comprise according to the described device of claim 252:

256. a device, comprising:

Illumination window;

And

A plurality of minute surfaces with different surfaces curvature; And

Support, it has a rotating shaft and supports and the equally spaced a plurality of minute surfaces of this rotating shaft, this support can be around this rotating shaft rotation, so that each minute surface of the different a plurality of minute surfaces in position is output light reflected back second reflecting surface, with by this second reflecting surface, and repeatedly reflection between first and second surfaces.

257. according to the described device of claim 256, wherein a plurality of minute surfaces are the discontinuous minute surfaces that separate.

258. according to the described device of claim 256, wherein a plurality of minute surfaces are the parts that continuously change the single mirror surface of curvature.

259., wherein further comprise according to the described device of claim 256:

Lens, its output light focusing that transmits from this second reflecting surface are to each minute surface, reflecting this output light, and institute's reflection ray are turned to back second reflecting surface.

260. a device, comprising:

The a plurality of fixedly minute surfaces that are used for reflection ray with different surfaces curvature; And

The rotation minute surface, it can be around rotating shaft rotation, with each the fixing minute surface that reflexes to a plurality of fixedly minute surfaces by virtual image phased array (VIPA) light that generator was produced, and by each light reflected back VIPA generator that fixedly minute surface reflected.

261. according to the described device of claim 260, a plurality of minute surfaces of wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

262. according to the described device of claim 260, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.

263. a device, comprising:

Produce virtual image phased array (VIPA) generator of light;

The rotation minute surface, it can be around rotating shaft rotation, with each the fixing minute surface that the light that is produced by the VIPA generator is reflexed to a plurality of fixedly minute surfaces, and by each light reflected back VIPA generator that fixedly minute surface reflected.

264. according to the described device of claim 263, wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

265. according to the described device of claim 263, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.

266., wherein further comprise according to the described device of claim 263:

Lens, its light focusing that is produced by the VIPA generator are to the rotation minute surface, and from this fixing minute surface and return the VIPA generator by the turn light rays of this rotation direct reflection.

267. a device, comprising:

The rotation minute surface, it can be around a rotating shaft rotation, with each the fixing minute surface that the light that is produced by the VIPA generator is reflexed to a plurality of fixedly minute surfaces, and by each light reflected back VIPA generator that fixedly minute surface reflected, thereby dispersion compensation provided to this input light.

268. according to the described device of claim 267, wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

269. according to the described device of claim 267, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.

270., wherein further comprise according to the described device of claim 267:

271. a device, comprising:

Illumination window;

And

The rotation minute surface, it can be around a rotating shaft rotation, with each fixing minute surface from a plurality of fixedly minute surfaces of output light reflected back of second reflecting surface, and light reflected back second reflecting surface that fixedly minute surface reflected by each, with by this second reflecting surface, and between first and second reflecting surfaces, repeatedly reflect.

272. according to the described device of claim 271, wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

273. according to the described device of claim 271, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.

274., wherein further comprise according to the described device of claim 271:

Lens, its from output light focusing of second reflecting surface to the rotation minute surface, and from this fixedly minute surface light and return second reflecting surface by the turn light rays that this rotation minute surface is reflected.

275. a device, comprising:

The off-axis paraboloidal mirror face, it can be around a rotating shaft rotation, with each the fixing minute surface that reflexes to a plurality of fixedly minute surfaces by virtual image phased array (VIPA) light that generator was produced, and by each light reflected back VIPA generator that fixedly minute surface reflected.

276. according to the described device of claim 275, wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

277. according to the described device of claim 275, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.

278. a device, comprising:

Produce virtual image phased array (VIPA) generator of light;

The off-axis paraboloidal mirror face, it can be around rotating shaft rotation, with each the fixing minute surface that the light that is produced by the VIPA generator is reflexed to a plurality of fixedly minute surfaces, and by each light reflected back VIPA generator that fixedly minute surface reflected.

279. according to the described device of claim 278, wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

280. according to the described device of claim 278, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.

281. a device, comprising:

The off-axis paraboloidal mirror face, it can be around a rotating shaft rotation, with each the fixing minute surface that reflexes to a plurality of fixedly minute surfaces by virtual image phased array (VIPA) light that generator was produced, and, thereby provide dispersion compensation to this input light the light reflected back VIPA generator that fixedly minute surface reflected by each.

282. according to the described device of claim 281, wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

283. according to the described device of claim 281, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.

284. a device, comprising:

Illumination window;

And

The off-axis paraboloidal mirror face, it can be around a rotating shaft rotation, with each the fixing minute surface that reflexes to a plurality of fixedly minute surfaces from the output light of second reflecting surface, and light reflected back second reflecting surface that fixedly minute surface reflected by each, with by this second reflecting surface, and between first and second reflecting surfaces, repeatedly reflect.

285. according to the described device of claim 284, wherein a plurality of fixedly minute surfaces are the discontinuous minute surfaces that separate.

286. according to the described device of claim 284, wherein a plurality of fixedly minute surfaces are the parts that continuously change the single mirror surface of curvature.