CN100429558C - Projection optical system and its imaging module and imaging method - Google Patents

Abstract

The present invention relates to a projection optical system and an imaging module and an imaging method thereof, which utilizes the matching of a trimming prism with an imaging error, an isosceles trigonal prism and the imaging module of a digital microlens device, and through the optimal arrangement combination of a lens module with two lens sets, a volume can be decreased to a half of the public projection optical system. The present invention has the advantages of portability and convenient use for users. The projection optical system which is decreased has the advantages of short optical path and good effect of projection.

Description

Projection optical system and image-forming module thereof and formation method

Technical field

The present invention relates to a kind of projection optical system and image-forming module thereof and formation method, especially refer to a kind of optimization permutation and combination that cooperates, reaches two set of shots groups of utilizing image error fine setting prism, isosceles right triangle prism and digital micro-mirror device, the shortest to reach the light path path, and projection optical system of drop shadow effect's the best and image-forming module thereof and formation method.

Background technology

See also shown in Figure 1ly, it is the synoptic diagram that the image-forming module of known projection optical system and camera lens module cooperate.As shown in Figure 1, known projection optical system includes: an image-forming module 1a and a camera lens module 2a.Wherein, this image-forming module 1a include a digital micro-mirror device 11a (DigitalMicromirror Device, DMD) and a prism group 12a.This camera lens module 2a includes the first lens group 21a, the second lens group 22a, three-lens group 23a and four-barrel group 24a at least, by moving mutually of this four set of shots group, focus the effect of (adjustment focal length) and zoom (adjusting the window size of projection imaging) to reach.

See also shown in Figure 2ly, it is the process flow diagram of the formation method of known projection optical system.Process flow diagram by Fig. 2 cooperates Fig. 1 as can be known, and the step of the formation method of known projection optical system includes: at first, 12a receives a light beam (step S100) by this prism group; Then, 12a reflects this light beam by this prism group, and this beam reflected is projeced into this digital micro-mirror device 11a (step S102); Then, reflect this light beam (step S104) again by this digital micro-mirror device 11a; Then, receive beam reflected again by this prism group 12a, and make this light beam penetrate this prism group 12a (step S106) from this digital micro-mirror device 11a institute; At last, receive the light beam (step S108) that penetrates this prism group 12a by the first lens group 21a of this camera lens module 2a, the second lens group 22a, three-lens group 23a and four-barrel group 24a, to reach the purpose of projection imaging to screen 3a.

In order to reach above-mentioned effect, the overall volume of known projection optical system be subject to optical path length, and this image-forming module 1a be difficult for the respective outer side edges of this camera lens module 2a changing.That is optical path length is subject to the simple combination (triangular prisms of a plurality of different angles) of conventional prism group 12 and the labyrinth (cooperations of a plurality of lens group) of conventional lenses module 2a, and can't shorten.

In other words, in order to reach good drop shadow effect, known projection optical system is subject to the textural association of this image-forming module 1a and this camera lens module 2a, and the influence of the optical path length that is produced under the textural association, and can't dwindle its original volume, and, expose dwindling of other projection optics assembly though have because of the present volume of existing projection optical system on the market, but volume is still too huge, and causes the user to portably use easily.

As from the foregoing, above-mentioned known projection optical system on reality is used, obviously has inconvenience and shortcoming, need be improved.

Summary of the invention

Fundamental purpose of the present invention provides a kind of projection optical system and image-forming module and formation method, its image error fine setting prism, isosceles right triangle prism that utilizes image-forming module and digital micro-mirror device cooperate and by the optimization permutation and combination of camera lens module with two set of shots groups, volume-diminished being become half size of known projection optical system, and the projection optical system of being dwindled can produce the shortest and effect of drop shadow effect's the best in light path path.

In order to reach above-mentioned purpose, the invention provides a kind of projection optical system, include: have the image-forming module of digital micro-mirror device and prism group and have first lens group and the camera lens module of second lens group.Wherein, this prism group has image error fine setting prism and the isosceles right triangle prism that cooperatively interacts with this digital micro-mirror device.This camera lens module is arranged at a side of this image-forming module, and this second lens group is arranged at a side of this first lens group, is used for producing with this first lens group relatively moving to adjust focal length.

Wherein, this prism group is used to receive a light beam and allows this light beam to penetrate, and the light beam that this penetrates is projeced into this digital micro-mirror device to produce reflection.This isosceles right-angle triangle prism is used for receiving from this digital micro-mirror device institute beam reflected, and reflects this light beam again.This first lens group is used for receiving from this isosceles right-angle triangle prism institute's beam reflected and allows this light beam to penetrate.This second lens group is used to receive the light beam that penetrated from this first lens group with projection imaging.

In addition, the present invention also provides a kind of projection optical system, includes: image-forming module, and it includes: digital micro-mirror device; And the prism group, it has image error fine setting prism and the isosceles right triangle prism that cooperatively interacts with this digital micro-mirror device; And camera lens module, it is arranged at a side of this image-forming module, and this camera lens module includes: first lens group, wherein this first lens group has first eyeglass, second eyeglass, prismatic glasses, the 4th eyeglass, the 5th eyeglass and the 6th eyeglass, 0.2 millimeter at interval of the center of this first eyeglass and this second eyeglass, 0.23 millimeter at interval of the center of this second eyeglass and this prismatic glasses, this prismatic glasses and the 4th eyeglass are connected together, the center of the 4th eyeglass and the 5th eyeglass is separated by 3.26 millimeters, and the center of the 5th eyeglass and the 6th eyeglass is separated by 3.88 millimeters; And second lens group, it is arranged at a side of this first lens group, be used for relatively moving to adjust focal length with this first lens group generation, wherein this second lens group has first eyeglass, second eyeglass and prismatic glasses, 2.72 millimeters at interval of the centers of this first eyeglass and this second eyeglass, and 2.86 millimeters at the interval, center of this second eyeglass and this prismatic glasses; Wherein the length between this first lens group and this second lens group adjusts between 42.73 to 43.07 millimeters; Wherein by this prism group of received and allow light beam to penetrate, the light beam that this is penetrated is projeced into this digital micro-mirror device producing reflection again, and receives institute's beam reflected by this isosceles right-angle triangle prism, and reflects this light beam again to this first lens group; Wherein this first lens group and this second lens group are arranged between this image-forming module and the screen, and this first lens group than this second lens group more near this image-forming module.

In order to reach above-mentioned purpose, the invention provides a kind of formation method of projection optical system, its step includes: at first, one image-forming module with a digital micro-mirror device and a prism group, an and camera lens module with one first lens group and one second lens group are provided, and wherein this prism group has an isosceles right-angle triangle prism; Then, receive a light beam, and this light beam penetrates this image-forming module by this image-forming module; Then, make the light beam that penetrates this image-forming module be projeced into this digital micro-mirror device; Next, make be projeced into this digital micro-mirror device beam reflection in this isosceles right-angle triangle prism; By this isosceles right-angle triangle prism, reflection is from this digital micro-mirror device institute beam reflected; Then, receive from this isosceles right-angle triangle prism institute beam reflected, and this light beam penetrates this first lens group; Then, by this second lens group, receive and penetrate the light beam of this first lens group with projection imaging; At last, move the spacing of this first lens group and this second lens group, to be adjusted to the focal length of picture.

In addition, the present invention also provides a kind of formation method of projection optical system, its step includes: an image-forming module with a digital micro-mirror device and a prism group is provided, an and camera lens module with one first lens group and one second lens group, wherein this camera lens module is arranged at a side of this image-forming module, and this camera lens module includes: first lens group, wherein this first lens group has first eyeglass, second eyeglass, prismatic glasses, the 4th eyeglass, the 5th eyeglass and the 6th eyeglass, 0.2 millimeter at interval of the center of this first eyeglass and this second eyeglass, 0.23 millimeter at interval of the center of this second eyeglass and this prismatic glasses, this prismatic glasses and the 4th eyeglass are connected together, the center of the 4th eyeglass and the 5th eyeglass is separated by 3.26 millimeters, and the center of the 5th eyeglass and the 6th eyeglass is separated by 3.88 millimeters; And second lens group, it is arranged at a side of this first lens group, be used for relatively moving to adjust focal length with this first lens group generation, wherein this second lens group has first eyeglass, second eyeglass and prismatic glasses, 2.72 millimeters at interval of the centers of this first eyeglass and this second eyeglass, and 2.86 millimeters at the interval, center of this second eyeglass and this prismatic glasses; Wherein the length between this first lens group and this second lens group adjusts between 42.73 to 43.07 millimeters; Wherein this prism group has an isosceles right-angle triangle prism; The step of this formation method also comprises: by this prism group of received one light beam, this light beam penetrates this prism group; Make the light beam that penetrates this prism group be projeced into this digital micro-mirror device; Make the beam reflection that is projeced into this digital micro-mirror device in this isosceles right-angle triangle prism; By the hypotenuse face of this isosceles right-angle triangle prism, reflection is from this digital micro-mirror device institute beam reflected; Reception is from this isosceles right-angle triangle prism institute beam reflected, and this light beam penetrates this first lens group; By this second lens group, receive and penetrate the light beam of this first lens group with projection imaging; And the spacing of adjusting this first lens group and this second lens group, to be adjusted to the focal length of picture.

Reach technology, means and the effect that predetermined purpose is taked in order further to understand the present invention, see also following about detailed description of the present invention and accompanying drawing, believe purpose of the present invention, feature and characteristics, go deep into and concrete understanding when getting one thus, yet accompanying drawing only provides reference and explanation usefulness, is not to be used for the present invention is limited.

Description of drawings

Fig. 1 is the image-forming module of known projection optical system and the synoptic diagram of camera lens module;

Fig. 2 is the process flow diagram of the formation method of known projection optical system;

Fig. 3 is the image-forming module of projection optical system of the present invention and the synoptic diagram of camera lens module; And

Fig. 4 is the process flow diagram of the formation method of projection optical system of the present invention.

Embodiment

See also shown in Figure 3ly, it is for the synoptic diagram of the image-forming module of projection optical system of the present invention and camera lens module.As shown in Figure 3, the invention provides a kind of projection optical system, it includes: an image-forming module 1 and a camera lens module 2.

Wherein, this image-forming module 1 has a digital micro-mirror device 11 and a prism group 12.This prism group 12 has an image error fine setting prism 121 and an isoceles triangle shape prism 122 that cooperatively interacts with this digital micro-mirror device 11.Three interior angles of this isoceles triangle shape prism 122 are 45 degree, 45 degree and 90 degree, can reach the shortest optical path length when it is used to make beam reflection.In addition, this prism group 12 is used to receive a light beam and allows this light beam to penetrate, and make the big radian of this light beam ground yawing moment, and the light beam that this prism group 12 can penetrate this is projeced into this digital micro-mirror device 11 to produce reflection, and this image error fine setting prism 121 is used to finely tune the light path path of the light beam that is projeced into this digital micro-mirror device 11, and this isoceles triangle shape prism 122 is used for receiving from 11 beam reflected of this digital micro-mirror device, and reflects this light beam again.

Wherein, this camera lens module 2 is arranged at a side of this image-forming module 1, and this camera lens module 2 includes: first lens group 21 and second lens group 22.This second lens group 22 is arranged at a side of this first lens group 21, is used for relatively moving to adjust focal length with 21 generations of this first lens group.In addition, this first lens group 21 is used for receiving from 122 beam reflected of this isoceles triangle shape prism and allows this light beam to penetrate, and this second lens group 22 be used to receive the light beam that penetrated from this first lens group 21 with projection imaging in a screen 3.Length between this first lens group and this second lens group adjusts between 42.73 to 43.07 millimeters.Yet this length is one of them embodiment of the present invention, and is not used in qualification the present invention.

In addition, this first lens group 21 also has first eyeglass 211, second eyeglass 212, prismatic glasses 213, the 4th eyeglass 214, the 5th eyeglass 215 and the 6th eyeglass 216,0.2 millimeter at interval of the center of this first eyeglass 211 and this second eyeglass 212,0.23 millimeter at interval of the center of this second eyeglass 212 and this prismatic glasses 213, this prismatic glasses 213 is connected together with the 4th eyeglass 214, the center of the 4th eyeglass 214 and the 5th eyeglass 215 is separated by 3.26 millimeters, and the center of the 5th eyeglass 215 and the 6th eyeglass 216 is separated by 3.88 millimeters.Yet the center distance of these eyeglasses of this first lens group 21 is one of them embodiment of the present invention, and is not used in qualification the present invention.

And, this second lens group 22 has first eyeglass 221, second eyeglass 222 and the prismatic glasses 223,2.72 millimeters at interval of the centers of this first eyeglass 221 and this second eyeglass 222, and 2.86 millimeters at interval of the centers of this second eyeglass 222 and this prismatic glasses 223.Yet the center distance of these eyeglasses of this second lens group 22 is one of them embodiment of the present invention, and is not used in qualification the present invention.

See also shown in Figure 4ly, it is the process flow diagram of the formation method of projection optical system of the present invention.Process flow diagram by Fig. 4 cooperates Fig. 3 as can be known, the invention provides a kind of formation method of projection optical system, its step includes: at first, one image-forming module 1 with a digital micro-mirror device 11 and a prism group 12, an and camera lens module 2 with one first lens group 21 and one second lens group 22 are provided, wherein this prism group 12 has an image error fine setting prism 121 and an isoceles triangle shape prism 122 (step S200), and wherein this image error fine setting prism 121 and this isoceles triangle shape prism 122 are bonded together; Then, receive a light beam by this image-forming module 1, and this light beam penetrates this image-forming module 1 (step S202).

Then, throw this light beam that penetrates image-forming module 1 in this digital micro-mirror device 11 (step S204); Then, reflect this light beam that is projeced into digital micro-mirror device 11 in this isoceles triangle shape prism 122 (step S206); Then, reflect from 11 beam reflected of this digital micro-mirror device (step S208) by this isoceles triangle shape prism 122; Next, receive from 122 beam reflected of this isoceles triangle shape prism, and this light beam penetrates this first lens group 21 (step S210); Continue, by this second lens group, to receive this light beam that penetrates first lens group with projection imaging; At last, move the spacing of this first lens group and this second lens group, to be adjusted to the focal length of picture.

In sum, the present invention utilizes cooperating of this image error fine setting prism 121, this isoceles triangle shape prism 122 and this digital micro-mirror device 11 and by the optimization permutation and combination of the camera lens module 2 with two set of shots groups 21,22, volume-diminished being become half size of known projection optical system, and the projection optical system of being dwindled can produce the shortest and effect of drop shadow effect's the best in light path path.

The above only is the detailed description and the accompanying drawing of one the specific embodiment of the best of the present invention, but feature of the present invention is not limited thereto, be not in order to restriction the present invention, all scopes of the present invention should be as the criterion with following claims, all closing in the embodiment of the spirit variation similar of the present patent application claim with it, all should be contained in the category of the present invention, anyly be familiar with this operator in the field of the invention, can think easily and variation or modify and all can be encompassed in following claim of the present invention.

Claims (5)

1, a kind of projection optical system includes:

Image-forming module, it includes:

Digital micro-mirror device; And

The prism group, it has image error fine setting prism and the isosceles right triangle prism that cooperatively interacts with this digital micro-mirror device; And

Camera lens module, it is arranged at a side of this image-forming module, and this camera lens module includes:

First lens group, wherein this first lens group has first eyeglass, second eyeglass, prismatic glasses, the 4th eyeglass, the 5th eyeglass and the 6th eyeglass, 0.2 millimeter at interval of the center of this first eyeglass and this second eyeglass, 0.23 millimeter at interval of the center of this second eyeglass and this prismatic glasses, this prismatic glasses and the 4th eyeglass are connected together, the center of the 4th eyeglass and the 5th eyeglass is separated by 3.26 millimeters, and the center of the 5th eyeglass and the 6th eyeglass is separated by 3.88 millimeters; And

Second lens group, it is arranged at a side of this first lens group, be used for relatively moving to adjust focal length with this first lens group generation, wherein this second lens group has first eyeglass, second eyeglass and prismatic glasses, 2.72 millimeters at interval of the centers of this first eyeglass and this second eyeglass, and 2.86 millimeters at the interval, center of this second eyeglass and this prismatic glasses;

Wherein the length between this first lens group and this second lens group adjusts between 42.73 to 43.07 millimeters;

Wherein by this prism group of received and allow light beam to penetrate, the light beam that this is penetrated is projeced into this digital micro-mirror device producing reflection again, and receives institute's beam reflected by this isosceles right-angle triangle prism, and reflects this light beam again to this first lens group;

Wherein this first lens group and this second lens group are arranged between this image-forming module and the screen, and this first lens group than this second lens group more near this image-forming module.

2, projection optical system as claimed in claim 1 is characterized in that, this first lens group receives from this isosceles right-angle triangle prism institute's beam reflected and allows this light beam to penetrate.

3, projection optical system as claimed in claim 2 is characterized in that, this second lens group receives the light beam that penetrated from this first lens group with projection imaging.

4, a kind of formation method of projection optical system, its step includes:

One image-forming module with a digital micro-mirror device and a prism group, an and camera lens module with one first lens group and one second lens group are provided, and wherein this camera lens module is arranged at a side of this image-forming module, and this camera lens module includes:

First lens group, wherein this first lens group has first eyeglass, second eyeglass, prismatic glasses, the 4th eyeglass, the 5th eyeglass and the 6th eyeglass, 0.2 millimeter at interval of the center of this first eyeglass and this second eyeglass, 0.23 millimeter at interval of the center of this second eyeglass and this prismatic glasses, this prismatic glasses and the 4th eyeglass are connected together, the center of the 4th eyeglass and the 5th eyeglass is separated by 3.26 millimeters, and the center of the 5th eyeglass and the 6th eyeglass is separated by 3.88 millimeters; And

Second lens group, it is arranged at a side of this first lens group, be used for relatively moving to adjust focal length with this first lens group generation, wherein this second lens group has first eyeglass, second eyeglass and prismatic glasses, 2.72 millimeters at interval of the centers of this first eyeglass and this second eyeglass, and 2.86 millimeters at the interval, center of this second eyeglass and this prismatic glasses;

Wherein the length between this first lens group and this second lens group adjusts between 42.73 to 43.07 millimeters;

Wherein this prism group has an isosceles right-angle triangle prism;

By this prism group of received one light beam, this light beam penetrates this prism group;

Make the light beam that penetrates this prism group be projeced into this digital micro-mirror device;

Make the beam reflection that is projeced into this digital micro-mirror device in this isosceles right-angle triangle prism;

By the hypotenuse face of this isosceles right-angle triangle prism, reflection is from this digital micro-mirror device institute beam reflected;

Reception is from this isosceles right-angle triangle prism institute beam reflected, and this light beam penetrates this first lens group;

By this second lens group, receive and penetrate the light beam of this first lens group with projection imaging; And

Adjust the spacing of this first lens group and this second lens group, to be adjusted to the focal length of picture.

5, the formation method of projection optical system as claimed in claim 4 is characterized in that, this prism group also includes an image error fine setting prism that is connected with this isosceles right-angle triangle prism.

Images