WO2010131449A1 - 光学反射素子 - Google Patents
光学反射素子 Download PDFInfo
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- WO2010131449A1 WO2010131449A1 PCT/JP2010/003153 JP2010003153W WO2010131449A1 WO 2010131449 A1 WO2010131449 A1 WO 2010131449A1 JP 2010003153 W JP2010003153 W JP 2010003153W WO 2010131449 A1 WO2010131449 A1 WO 2010131449A1
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- mirror
- vibrator
- vibrators
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- mirror part
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B26/00—Optical devices or arrangements for the control of light using movable or deformable optical elements
- G02B26/08—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light
- G02B26/10—Scanning systems
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B26/00—Optical devices or arrangements for the control of light using movable or deformable optical elements
- G02B26/08—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light
- G02B26/0816—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements
- G02B26/0833—Optical devices or arrangements for the control of light using movable or deformable optical elements for controlling the direction of light by means of one or more reflecting elements the reflecting element being a micromechanical device, e.g. a MEMS mirror, DMD
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B81—MICROSTRUCTURAL TECHNOLOGY
- B81B—MICROSTRUCTURAL DEVICES OR SYSTEMS, e.g. MICROMECHANICAL DEVICES
- B81B3/00—Devices comprising flexible or deformable elements, e.g. comprising elastic tongues or membranes
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/01—Head-up displays
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/01—Head-up displays
- G02B27/017—Head mounted
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/01—Head-up displays
- G02B27/0101—Head-up displays characterised by optical features
- G02B2027/0147—Head-up displays characterised by optical features comprising a device modifying the resolution of the displayed image
Definitions
- the present invention relates to an optical reflecting element used in an image projection apparatus such as a head-up display or a head-mounted display.
- FIG. 13 is a perspective view of a conventional optical reflecting element.
- the optical reflection element includes a mirror unit 1, a pair of vibrators 3, and a frame body 4.
- Each of the vibrators 3 is connected to an end of the mirror unit 2.
- the frame 4 surrounds the outer periphery of the vibrator 3 and the mirror unit 2.
- a straight line connecting the connection position 5 between the mirror unit 2 and the vibrator 3 and the connection position 6 between the frame body 4 and the vibrator 3 is parallel to the mirror unit central axis S131 passing through the center of the mirror unit 2.
- Each of the vibrators 3 is composed of a plurality of diaphragms 3A to 3D and 3E to 3H connected in a folded manner.
- drive elements each including a lower electrode layer, a piezoelectric layer, and an upper electrode layer are disposed on the diaphragms 3A to 3H.
- the vibrator 3 is driven and the mirror part 2 can be rotated. Then, when light is incident on the rotating mirror unit 2, the reflected light can be scanned on the screen.
- the mirror unit 2 can be excited in the vertical and horizontal directions by the vibration of these four vibrators. With this configuration, an image can be projected on a wall, a screen, or the like.
- These vibrators are further provided with a monitor element composed of a lower electrode layer, a piezoelectric layer, and an upper electrode layer. If the electric signal detected by this monitor element is input to the upper electrode of the drive element via the feedback circuit, the optical reflection element can theoretically always be driven at the resonance frequency. A large amplitude can be maintained by such a self-excited drive system.
- a monitor element composed of a lower electrode layer, a piezoelectric layer, and an upper electrode layer.
- the present invention is an optical reflecting element that enhances energy transfer efficiency by a vibrator and realizes a large mirror amplitude angle.
- the optical reflecting element of the present invention has a frame-shaped support, a first vibrator, a second vibrator, and a mirror portion.
- the first ends of the first and second vibrators are connected to the inside of the support.
- the mirror portion has a rectangular shape having a first side, a second side parallel to the first side, a third side perpendicular to the first side, and a fourth side parallel to the third side.
- the mirror part is connected to the second end of the first vibrator at the end between the first side and the third side, and the second part of the second vibrator at the end between the first side and the fourth side. It is connected to the end and disposed between the first and second vibrators.
- the mirror portion has a reflecting surface surrounded by the first side, the second side, the third side, and the fourth side.
- the mirror part has a mirror part central axis passing through the center of the mirror part along the direction in which the first and second vibrators and the mirror part are arranged.
- Each of the first and second vibrators has a drive unit that vibrates the mirror unit, and has a meander shape in which three or more diaphragms are connected so as to be folded back by two or more turn units.
- the turn part is parallel to the central axis of the mirror part.
- a line segment connecting the connection position between the mirror unit and the first vibrator and the connection position between the support and the first vibrator intersects the central axis of the mirror part, and the connection position between the mirror part and the second vibrator.
- a line segment connecting the support and the connection position of the second vibrator intersects the central axis of the mirror portion.
- At least a part of at least one of the turn parts is located outside a first end axis parallel to the central axis of the mirror part and passing through the first side of the mirror part, or at least one whole of the turn part Is located inside the first end axis.
- at least a part of at least one of the turn parts of the vibrator is located outside a second end axis parallel to the central axis of the mirror part and passing through the second side of the mirror part, or the turn part of the vibrator At least one of these is located inside the second end axis. Satisfy at least one of these conditions. With this configuration, it is possible to realize an optical reflecting element with high efficiency and a large amplitude angle of the mirror even if it is small.
- FIG. 1 is a perspective view of an optical reflecting element according to Embodiment 1 of the present invention.
- FIG. 2 is a cross-sectional view of the optical reflecting element shown in FIG.
- FIG. 3 is a top view of the optical reflecting element shown in FIG. 4 is an enlarged top view of the main part of the optical reflecting element shown in FIG.
- FIG. 5 is a top view of another optical reflecting element for comparison with the optical reflecting element shown in FIG.
- FIG. 6 is a top view of still another optical reflecting element for comparison with the optical reflecting element shown in FIG.
- FIG. 7 is a cross-sectional view of the mirror portion during operation of the optical reflecting element shown in FIG. FIG.
- FIG. 8 is a perspective view of the mirror portion of the optical reflecting element according to Embodiment 2 of the present invention on the side opposite to the reflecting surface.
- FIG. 9 is a top view of the optical reflecting element according to Embodiment 2 of the present invention.
- FIG. 10 is a top view of another optical reflecting element according to Embodiment 2 of the present invention.
- FIG. 11 is a perspective view of an optical reflecting element according to Embodiment 3 of the present invention.
- FIG. 12 is a perspective view of an optical reflecting element according to Embodiment 4 of the present invention.
- FIG. 13 is a perspective view of a conventional optical reflecting element.
- FIG. 1 is a perspective view of an optical reflecting element according to Embodiment 1 of the present invention
- FIG. 2 is a cross-sectional view of the optical reflecting element shown in FIG.
- FIG. 3 is a top view of the optical reflecting element shown in FIG. 1 with terminals omitted
- FIG. 4 is an enlarged top view of the main part of the optical reflecting element shown in FIG.
- the optical reflecting element 10 according to the present embodiment includes a frame-shaped support 14, a vibrator 12 that is a first vibrator, a vibrator 13 that is a second vibrator, And a mirror unit 11.
- the mirror unit 11 includes a first side 111, a second side 112 parallel to the first side 111, a third side 113 perpendicular to the first side 111, and a second side parallel to the third side 113.
- the mirror unit 11 is connected to the second end of the vibrator 12 at the end between the first side 111 and the third side 113. That is, the mirror unit 11 is coupled to the vibrator 12 at the coupling position 22A.
- the mirror unit 11 is connected to the second end of the vibrator 13 at the end between the first side 111 and the fourth side 114. That is, the mirror unit 11 is coupled to the vibrator 13 at the coupling position 22B.
- the mirror unit 11 is disposed between the vibrators 12 and 13.
- the mirror unit 11 has a reflecting surface 11 ⁇ / b> R surrounded by a first side 111, a second side 112, a third side 113, and a fourth side 114.
- the mirror unit 11 includes a mirror unit central axis S1 (2-2 line) passing through the center of the mirror unit 11 along the direction in which the vibrators 12, 13 and the mirror unit 11 are arranged. ).
- the vibrators 12 and 13 have a meander shape in which three or more diaphragms are connected so as to be folded at two or more turn portions.
- 1 and 3 show an example in which the vibrator 12 has diaphragms 12A to 12C and turn parts 24A and 25A, and the vibrator 13 has diaphragms 13A to 13C and turn parts 24B and 25B.
- the turn parts 24A to 25B are parallel to the mirror part central axis S1.
- the vibrator 12 includes the diaphragms 12A to 12C and the turn portions 24A and 25A that are connected so as to be folded 180 degrees on the same plane and perpendicular to the mirror center axis S1.
- the vibrator 13 is composed of diaphragms 13A to 13C and turn parts 24B and 25B connected so as to be folded 180 degrees on the same plane and perpendicular to the mirror part central axis S1.
- the diaphragms 12A to 12C and 13A to 13C constituting the vibrators 12 and 13 are respectively provided with a drive element 15 which is a drive part for applying a drive signal to vibrate the mirror part 11, and a vibrator.
- the drive element 15 includes a base material 17, a lower electrode layer 18 formed on the base material 17, a piezoelectric layer 19 stacked on the lower electrode layer 18, and an upper electrode stacked on the piezoelectric layer 19.
- Drive electrode 20 which is a layer.
- the monitor element 16 includes a base material 17, a lower electrode layer 18, a piezoelectric layer 19, and a monitor electrode 21 that is an upper electrode layer laminated on the piezoelectric layer 19.
- terminals 41A and 42A are formed on the vibrator 12 side on the support body 14, and terminals 41B and 42B are formed on the vibrator 13 side on the support body 14. As shown in FIG. 2, these terminals are formed on an insulating film 43 provided on the drive electrode 20.
- the terminals 41A and 41B are connected to the monitor electrode 21 via the surfaces of the coupling positions 23A and 23B.
- the terminals 42A and 42B are connected to the drive electrode 20 formed under the insulating film 43 through through-hole electrodes (not shown) formed in the insulating film 43.
- the line segment connecting the coupling position 22A and the coupling position 23A and the line segment coupling the coupling position 22B and the coupling position 23B are connected to each other so that the respective coupling positions intersect the mirror center axis S1.
- At least a part of the turn parts 24A and 24B is located outside the first end axis T1 that is parallel to the mirror part central axis S1 and passes through the first side 111 of the mirror part 11.
- at least a part of the turn parts 25A and 25B is located outside the second end axis T2 that is parallel to the mirror part central axis S1 and passes through the second side 112 of the mirror part 11.
- the base material 17 is comprised with materials, such as a silicon wafer, a metal, glass, a ceramic substrate, or resin.
- materials such as a silicon wafer, a metal, glass, a ceramic substrate, or resin.
- Metal, quartz, glass, quartz, ceramic material, resin, or the like is preferable from the viewpoint of availability.
- the element structure design is facilitated by selecting a material having optimum characteristics for realizing a target element size, vibration frequency, and mechanical strength.
- an insulating layer is formed between the base material 17 and the lower electrode layer 18, and the conductive material constituting the base material 17 and the lower electrode layer 18 are formed. Are electrically insulated from each other. At this time, silicon dioxide is desirable as the insulating layer.
- the piezoelectric layer 19 is made of a piezoelectric material.
- a piezoelectric material having a high piezoelectric constant such as lead zirconate titanate (PZT) is desirable.
- the lower electrode layer 18, the drive electrode 20, and the monitor electrode 21 are produced by a thin film forming method such as vapor deposition of metal, sol / gel, CVD, sputtering.
- the lower electrode layer 18 is preferably formed of platinum because the crystallinity of the piezoelectric layer 19 can be improved.
- the drive electrode 20 and the monitor electrode 21 are made of, for example, gold, titanium / gold, or the like.
- the titanium film under the gold film is formed in order to increase the adhesion with the piezoelectric layer 19 such as a PZT thin film, and a metal such as chromium can be used in addition to titanium.
- the adhesion between the drive electrode 20 and the monitor electrode 21 and the piezoelectric layer 19 can be improved.
- the titanium and chromium films and the gold film form a strong diffusion layer, so that the vibrators 12 and 13 having high adhesion strength can be formed.
- the reflecting surface 11R which is the uppermost surface of the mirror portion 11 can be formed by mirror polishing the surface of the piezoelectric layer 19.
- a metal thin film 115 having excellent light reflection characteristics such as gold or aluminum may be formed.
- a protective film may be formed on the metal thin film 115.
- the lower electrode layer 18 and the piezoelectric layer 19 are also provided on the base material 17 in the mirror part 11, but may be formed only by the base material 17.
- the reflective surface 11R can be formed by mirror polishing the surface of the substrate, but the metal thin film 115 may be formed thereon.
- a drive element 15 is formed on the diaphragms 12A to 12C and 13A to 13C of the vibrators 12 and 13.
- the lower electrode layer 18 of the vibrators 12 and 13 is grounded.
- an electric signal (AC voltage) for driving the vibrators 12 and 13 is input to the drive electrode 20 from the terminals 42A and 42B.
- an electric signal having a unique vibration frequency of the vibrators 12 and 13 is input to the drive electrode 20 to drive the vibrators 12 and 13 in resonance.
- the vibrators 12 and 13 are always driven at the resonance frequency, the vibrators 12 and 13 can be driven efficiently, the displacement can be increased, and the deflection angle can be increased.
- the electrical signals are synthesized through impedance elements such as resistors and supplied to the terminals 42A and 42B.
- the impedance element may be a reactance element such as a capacitor or a coil, or a combination of an impedance element and a reactance element.
- the monitor electrode 21 disposed on the vibrators 12 and 13 detects the displacement of the vibrators 12 and 13 as an electric signal.
- the electric signal is drawn out to the terminals 41A and 41B.
- the extracted electrical signal is taken out through a filter (not shown), and inputted again to the drive electrode 20 through an amplifier (not shown).
- the optical reflecting element 10 can be driven by self-excitation.
- the width of the drive element 15 is different between the even-numbered and odd-numbered diaphragms 12A to 12C and 13A to 13C. That is, adjacent drive element widths 15A and 15B are different. Therefore, when an alternating voltage (electric signal) having the resonance frequency of the vibrators 12 and 13 is applied to the drive electrode 20, the vibration plates 12A, 12C, 13A, and 13C formed with a wide width of the drive element 15 causes flexural vibration. Then, the diaphragms 12B, 13B adjacent to the diaphragms 12A, 12C, 13A, 13C cause flexural vibration in the opposite direction due to the principle of resonance.
- substantially no voltage is applied to the diaphragms 12B and 13B in which the width of the drive element 15 is formed narrow.
- the diaphragms 12A, 12C, 13A, and 13C are displaced in opposite phases. Accordingly, the diaphragms 12A to 12C and 13A to 13C alternately vibrate in opposite phases, the displacement is accumulated around a vibration axis (not shown), and the mirror portion 11 can be largely repetitively oscillated about the vibration axis. .
- the mirror unit 11 can be rotated with its center as a fixed point. Therefore, if the mirror part 11 is irradiated with light, the light can be scanned in one direction.
- the mirror unit 11 is supported by the support 14 via vibrators 12 and 13 that are coupled so as to face each other with the mirror unit 11 interposed therebetween.
- the mirror part 11 is being fixed at both ends.
- the mirror unit 11 vibrates left and right in the in-plane direction of the optical reflecting element 10 in addition to the rotational movement. Such unnecessary vibration is applied.
- the mirror part 11 is fixed at both ends, the above-described unnecessary vibration can be suppressed.
- the connecting position 22A between the mirror portion 11 and the vibrator 12 is arranged at a point where the third side 113 intersects with the first end axis T1A.
- the connection position 22B between the mirror unit 11 and the vibrator 13 is arranged at a point where the fourth side 114 and the first end axis T1A intersect. Therefore, it is possible to vibrate the mirror unit 11 with a small driving force compared to the case where the connection position is arranged at a point where the third side 113 or the fourth side 114 intersects the mirror unit central axis S1. . This is because the mirror unit 11 can be rotated with the distance from the first side 111 as the center to the second side 112 being a radius. In this way, high-efficiency driving is possible.
- the mirror unit 11 vibrates around the vibration axis.
- the vibration axis is brought close to the mirror center axis S1
- the mass balance of the optical reflection element 10 can be achieved, and the energy transmission efficiency by the vibrators 12 and 13 can be increased. That is, the energy transfer efficiency depends on the position of the vibration axis with respect to the mirror center axis S1, and the energy transfer efficiency becomes maximum when both the mirror center axis S1 and the vibration axis coincide.
- the amplitude degree can be stably increased with a constant driving force, and a large mirror amplitude angle can be realized in the optical reflecting element 10.
- a line segment connecting the connecting position 22A between the mirror part 11 and the vibrator 12 and the connecting position 23A between the support 14 and the vibrator 12 intersects the mirror part central axis S1.
- a line segment connecting the connection position 22B between the mirror part 11 and the vibrator 13 and the connection position 23B between the support body 14 and the vibrator 13 intersects the mirror part central axis S1. That is, the coupling position 22A and the coupling position 23A are positioned on opposite sides of the mirror center axis S1, and the coupling position 22B and the coupling position 23B are positioned on opposite sides of the mirror center axis S1. Yes. With this configuration, the vibration axis can be brought close to the mirror center axis S1.
- the midpoint of the line segment connecting the above-mentioned connection positions is on the mirror portion center portion S1 axis.
- the symmetry of the vibrators 12 and 13 is improved, and the vibration axis can be brought closer to the mirror part central axis S1.
- the position of the turn part connecting the diaphragm may be changed. If the position of the turn part is changed, the position of the center of gravity of the diaphragm changes. Therefore, the vibration axis can be brought close to the mirror unit central axis S1.
- at least a part of the turn parts 24A and 24B is located outside the first end part axis T1
- at least a part of the turn parts 25A and 25B is a second end part axis. It is located outside T2.
- at least any one of the turn portions may be located inside the first end axis T1, or at least any one of the turn portions may be located inside the second end axis T2. There is also.
- the vibration axis can be made closer to the mirror center axis S1 by adjusting the positions of the turn portions 24A to 25B and adjusting the lengths of the vibrators 12 and 13.
- the force that restrains the vibrators 12 and 13 differs between the side close to the mirror part 11 and the side close to the support 14. Since the vibrators 12 and 13 are close to the free end on the mirror part 11 side, the force for restraining the vibrators 12 and 13 is weak. On the other hand, since the support 14 has a frame shape, the force for restraining the vibrators 12 and 13 is strong on the support 14 side. Therefore, when the vibration plates 12A to 12C and 13A to 13C constituting the vibrators 12 and 13 have the same length, the vibration shafts 12C and 13C closer to the support body 14 are displaced from the mirror center axis S1. .
- At least one part of at least one of the turn parts 24A and 24B is located outside the first end axis T1, or at least one of the turn parts 24A and 24B is entirely the first end part. Located inside the axis T1. Alternatively, at least a part of at least one of the turn parts 25A and 25B is located outside the second end axis T2, or at least one of the turn parts 25A and 25B is entirely the second end axis T2. Located on the inner side. It is only necessary to satisfy at least one of these two conditions.
- FIGS. 1 to 4 are top views of the optical reflecting element for comparison with the optical reflecting element 10.
- the vibrator 512 and the support body 514 are connected at a connection position 523A on the mirror part central axis S51, and the vibrator 513 and the support body 514 are on the mirror part central axis S51. They are connected at a connection position 523B.
- the outer circumferences of the turn portions of the vibrators 512 and 513 are all along the first end axis T51 and the second end axis T52.
- the other configuration is the same as that shown in FIG. That is, the mirror unit 511 is connected to the vibrators 512 and 513 at a position along the first end axis T51.
- the outer peripheries of the turn portions 624A, 624B, 625A, and 625B provided in the vibrators 612 and 613 are all along the first end portion axis T61 and the second end portion axis T62.
- the other configuration is the same as that shown in FIG. That is, the mirror unit 611 is coupled to the vibrators 612 and 613 at a position along the first end axis T61.
- FIG. 7 shows, as an example, a cross section of the mirror portion during the operation of the optical reflecting element 10 shown in FIG.
- the structure No. shown in FIG. No. 2 of the structure shown in FIG. No. 3 is compared with that in (Table 1).
- the element 3 has a smaller amount of vibration axis deviation. That is, the position of the vibration axis is close to the center axis of the mirror part. Also, the amplitude angle is large.
- at least a part of the turn parts 24A, 24B is located outside the first end axis T1, and at least a part of the turn parts 25A, 25B is from the second end axis T2. It is preferable to be located outside. It was confirmed that this configuration can realize an optical reflecting element that is driven with higher efficiency.
- At least one of the turn portions 24A and 24B is located inside the first end portion axis T1, or at least one of the turn portions 25A and 25B is the second end portion. It may be located inside the axis T2.
- the number of diaphragms 12A to 12C and 13A to 13C may be an odd number of 3 or more, and is not particularly limited.
- the drive element 15 is disposed in any of the vibrators 12 and 13 facing the mirror unit 11.
- the drive element 15 may be disposed only on one of the vibrators 12 and 13.
- the vibration propagates from the vibrator 12 to the vibrator 13 via the mirror unit 11, and the vibrator 13 is similarly driven by resonance.
- the monitor element 16 is disposed on both the vibrators 12 and 13.
- the drive element 15 may be disposed only on one of the vibrators 12 and 13.
- the monitor element 16 may be disposed only on the vibrator 13.
- the monitor element 16 and the drive element 15 are formed on one diaphragm. Therefore, the width of the monitor element 16 is narrow in the diaphragm having the wide drive element width 15A, and the width of the monitor element 16 is wide in the diaphragm having the narrow drive element width 15B.
- the monitor element 16 detects the displacement of the piezoelectric layer of the vibrator 13 in which the monitor element 16 is formed as an electric signal. This electrical signal can be input to the drive element 15 of the vibrator 12 via a feedback circuit.
- FIG. 8 is a perspective view of the mirror portion of the optical reflecting element according to Embodiment 2 of the present invention on the side opposite to the reflecting surface.
- FIG. 9 is a top view of the optical reflecting element according to Embodiment 2 of the present invention.
- the present embodiment is different from the first embodiment in that a frame-shaped weight 26 as shown in FIG. 8 is provided on the back side of the reflecting surface 911R of the mirror portion 911 of the optical reflecting element as shown in FIG. It is a point.
- a pair of frame width 26A and frame width 26B which are parallel to the mirror unit central axis S91 are different. That is, the frame width between the inner side and the outer side of the weight 26 is different between the first side 9111 side and the second side 9112 side.
- the vibrators 912 and 913 are formed of five diaphragms, but this is not an essential difference. Other basic configurations are the same as those in FIG.
- the position of the vibration axis of the mirror part 911 is determined by the balance between the moment due to the displacement of the vibrators 912 and 913 and the moment of inertia of the mirror part 911.
- the moment of inertia of the mirror portion 911 can be adjusted by forming the weight 26 having the frame width 26A and the frame width 26B different from each other on the back side of the reflecting surface 911R as described above.
- the vibration axis of the mirror part 911 can be brought close to the mirror part central axis S91, and an optical reflection element that is driven more efficiently can be realized. It is also possible to adjust the position of the vibration axis by adding the weight 26 to the mirror portion 911 after configuring the optical reflecting element without the weight 26.
- the mass of the mirror portion 911 is increased by forming the weight 26, the frequency can be shifted to the low frequency side without increasing the size of the optical reflecting element. Furthermore, since the weight 26 has a frame shape, the bending deformation of the mirror part 11 can be suppressed.
- the weight 26 is added to the optical reflecting element substantially the same as the structure of FIG. 3.
- the weight 26 also has the above-described effect when added to the optical reflecting element of another structure. That is, the driving efficiency can be improved independently of the configuration of the first embodiment.
- connection positions 1023A and 1023B between the support 1014 and the vibrators 1012, 1013 are on the mirror unit central axis S101. Further, the outer periphery of each turn part of the vibrators 1012, 1013 is along end axis T101, T102. In other words, a structure in which the vibration axis deviation is likely to increase unless the vibration axis is intentionally adjusted is selected, and the difference due to the difference in the symmetry of the weight 26 on the back surface of the mirror portion 1011 is examined.
- the size of the mirror unit 1011 was 1300 ⁇ m ⁇ 1000 ⁇ m.
- the number of diaphragms of the vibrators 1012, 1013 is 5.5, the length of each diaphragm is 1300 ⁇ m, the width is 130 ⁇ m, and the thickness is 100 ⁇ m.
- the thickness 26D of the weight 26 was 575 ⁇ m.
- the frame widths 26A, 26B, and 26C of the weight 26 are set as shown in (Table 2). No. 1 in which such a weight is added to the mirror unit 1011. 4, no.
- the optical reflection element of No. 5 was produced and resonantly oscillated as in the first embodiment, and the vibration axis deviation and the amplitude angle were evaluated. The results are shown in (Table 2).
- the frame widths 26 ⁇ / b> A, 26 ⁇ / b> B, and 26 ⁇ / b> C of the frame-shaped weight formed on the back surface of the mirror portion 911 are the same.
- the frame width 26A and the frame width 26B of the weight 26 are set to No. 4 and the optical reflection element.
- the sum of the frame width 26A and the frame width 26B is not changed. In this way, the frame widths 26A and 26B are asymmetrical with respect to the mirror center axis S101.
- the connecting positions 1023A and 1023B between the support 1014 and the vibrators 1012 and 1013 are not on the mirror central axis S101, but the same is achieved by setting the widths 26A and 26B of the weight 26 to appropriate values. An effect can be obtained. Note that it is desirable that the thickness 26D of the weight 26 is the same as the thickness of the support 1014 because the processing is easy.
- the thickness 26D may be changed to make the mass asymmetric. Even in such a configuration, the same effect as that obtained when the frame width 26A and the frame width 26B are different can be obtained. Or when frame width 26A, 26B is the same, and thickness is also the same, what is necessary is just to form a pair of frame part parallel to mirror part center axis
- FIG. 11 is a perspective view of an optical reflecting element according to Embodiment 3 of the present invention.
- the description is abbreviate
- the difference between the present embodiment and the first embodiment is that the optical reflection element is driven biaxially.
- the optical reflection element 110 includes a mirror unit 11, vibrators 12 and 13, a support body 14, vibrators 27 and 28, and a support body 29.
- the vibrator 12 that is the first vibrator and the vibrator 13 that is the second vibrator face each other via the mirror unit 11 and are connected to the mirror unit 11 at their first ends.
- a support 14, which is a frame-shaped first support is connected to the second ends of the vibrators 12 and 13 and surrounds the outer peripheries of the vibrators 12 and 13 and the mirror unit 11.
- the vibrator 27 that is the third vibrator and the vibrator 28 that is the fourth vibrator face each other via the support body 14 and are connected to the support body 14 at their first ends.
- a support body 29 that is a frame-shaped second support body is connected to the second ends of the vibrators 27 and 28 and surrounds the outer circumferences of the vibrators 27 and 28 and the support body 14.
- the mirror unit 11, the vibrators 12 and 13, and the support 14 form the same structure as the optical reflecting element 10 of the first embodiment. That is, the vibrators 12 and 13 have a plurality of diaphragms 12A to 12C and 13A to 13C, and the diaphragms are connected so as to be folded at the turn portion.
- a line segment connecting the connection position 22A and the connection position 23A, and a line segment connecting the connection position 22B and the connection position 23B intersect the mirror unit central axis S111. Furthermore, the outer periphery of each turn part of the vibrators 12 and 13 is parallel to the mirror part central axis S111 and is located outside the first and second end axes along the first and second sides of the mirror part 11. is doing.
- the configurations, compositions, connection positions, and arrangement positions of the upper electrode layers of the vibrators 12 and 13 are the same as those in the first embodiment.
- the vibrators 27 and 28 have a plurality of diaphragms 27A to 27E and 28A to 28E, and the diaphragms are connected so as to be folded at the turn portion.
- the mirror unit central axis S112 in which the connection positions 30A and 30B between the support 14 and the vibrators 27 and 28 and the connection positions 31A and 31B between the support 29 and the vibrators 27 and 28 pass through the center of the mirror part 11, respectively. It is comprised so that it may be on the opposite side on both sides. That is, a line segment connecting the connection position 30A and the connection position 31A and a line segment connecting the connection position 30B and the connection position 31B intersect with the mirror unit central axis S112.
- the mirror center axis S112 is orthogonal to the mirror center axis S111. Therefore, when the support body 14 is viewed in the mirror portion 611, the support body 14, the vibrators 27 and 28, and the support body 29 have the same configuration as the optical reflection element in FIG.
- the vibration axes of the vibrators 12 and 13 and the vibration axes of the vibrators 27 and 28 are orthogonal to each other. Thereby, the light reflected from the mirror part 11 can be scanned in the horizontal direction and the vertical direction.
- the vibration axes of the vibrators 12 and 13 and the vibration axes of the vibrators 27 and 28 intersect at the center of the mirror unit 11. Therefore, the center of the mirror part 11 becomes a fixed point. If light is incident on this stationary part, the optical path length between the incident light and the reflected light becomes constant, and a highly accurate image can be projected.
- the coupling position 30A and the coupling position 31A, and the coupling position 30B and the coupling position 31B are not necessarily located on the opposite side with respect to the mirror center axis S112. At least the connecting position 22A and the connecting position 23A, the connecting position 22B and the connecting position 23B are located on the opposite side of the mirror part central axis S111, and the outer periphery of the turn part is outside the first end axis and the second end axis. If it is located, the same effect as in the first embodiment can be obtained.
- the coupling position 30A and the coupling position 31A and the coupling position 30B and the coupling position 31B are located on the opposite side with respect to the mirror center axis S112, it is desirable for high-efficiency driving.
- the outer periphery of the turn part of the vibrators 27 and 28 is parallel to the mirror part central axis S112 and along two parallel sides of the support part 14 that are not connected to the vibrators 27 and 28. More preferably, it is located outside the first end axis and the second end axis. As a result, the mirror unit 11 can be driven with higher efficiency.
- FIG. 12 is a perspective view of an optical reflecting element according to Embodiment 4 of the present invention.
- the description is abbreviate
- the optical reflecting element 120 in the present embodiment replaces the mirror unit 11, the vibrators 12 and 13, and the support 14 in the third embodiment, and the mirror unit 1011 and the vibrator 1012 in FIG. 10 described in the second embodiment. 1013, the support 1014, and the weight 26 are applied. That is, the coupling position of the vibrators 1012, 1013 and the support 1014 is on the mirror center axis S121, and the weight 26 is a pair of weights 26A parallel to the mirror center axis S122 as shown in FIG. , 26B are asymmetric. Although the number of diaphragms in the vibrators 1012, 1013 is different from that in FIG. 9, this is not an essential difference.
- the mirror unit 1011 can be driven with high efficiency as in the second embodiment. Further, similarly to the third embodiment, the optical reflecting element 120 can be driven biaxially.
- the mirror section 911 is further provided. It can be driven with high efficiency.
- the vibrators 27 and 28 have the same shape as in FIG. 11. However, as in the third embodiment, the length of the diaphragm of the vibrators 27 and 28 is changed to change the position of the turn portion. You may adjust.
- the optical reflecting element of the present invention can increase the amplitude angle of the mirror part as compared with the prior art, and can project a highly accurate image.
- This optical reflection element can be used for an image projection apparatus such as a head-up display or a head-mounted display.
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Abstract
Description
以下、本発明の実施の形態1における光学反射素子に関して、図1~図5を用いて説明する。図1は本発明の実施の形態1における光学反射素子の斜視図、図2は図1に示す光学反射素子の2-2線における断面図である。図3は図1に示す光学反射素子の、端子を省略した上面図、図4は図1に示す光学反射素子の要部拡大上面図である。図1~図3に示すように、本実施の形態における光学反射素子10は、枠形状の支持体14と、第1振動子である振動子12と第2振動子である振動子13と、ミラー部11とを有する。
図8は本発明の実施の形態2における光学反射素子のミラー部の、反射面の反対側の斜視図である。図9は本発明の実施の形態2における光学反射素子の上面図である。
図11は本発明の実施の形態3における光学反射素子の斜視図である。なお、実施の形態1と同様の構成を有するものについては、その説明を省略し、相違点について詳述する。本実施の形態と実施の形態1との違いは、光学反射素子を二軸駆動させている点である。
図12は本発明の実施の形態4における光学反射素子の斜視図である。なお、実施の形態2、3と同様の構成を有するものについては、その説明を省略し、相違点について詳述する。
11,511,611,911,1011 ミラー部
11R,911R 反射面
12,512,612,912,1012 振動子(第1振動子)
12A,12B,12C,13A,13B,13C 振動板
13,513,613,913,1013 振動子(第2振動子)
14,514,914,1014 支持体
15 ドライブ素子
15A,15B ドライブ素子幅
16 モニター素子
17 基材
18 下部電極層
19 圧電体層
20 ドライブ電極
21 モニター電極
22A,22B,23A,23B,523A,523B,1023A,1023B 連結位置
24A,24B,25A,25B,624A,624B,625A,625B ターン部
26 錘
26A,26B,26C 枠幅
26D 厚さ
27 振動子(第3振動子)
27A,27B,27C,27D,27E,28A,28B,28C,28D,28E 振動板
28 振動子(第4振動子)
29 支持体(第2支持体)
30A,30B,31A,31B 連結位置
41A,41B,42A,42B 端子
43 絶縁膜
111,9111 第1辺
112,9112 第2辺
113 第3辺
114 第4辺
115 金属薄膜
Claims (2)
- 枠形状の支持体と、
前記支持体の内側に第1端が連結された第1振動子と、
前記支持体の内側に第1端が連結された第2振動子と、
第1辺と、前記第1辺に平行な第2辺と、前記第1辺に垂直な第3辺と、前記第3辺に平行な第4辺とを有する矩形形状であり、前記第1辺と前記第3辺との間の端部で前記第1振動子の第2端に連結され、前記第1辺と前記第4辺との間の端部で前記第2振動子の第2端に連結され、前記第1、第2振動子の間に配置され、前記第1辺、第2辺、第3辺、第4辺に囲まれた反射面を有するミラー部と、を備え、
前記ミラー部は、前記第1、第2振動子と前記ミラー部とが並んだ方向に沿って前記ミラー部の中心を通るミラー部中心軸を有し、
前記第1、第2振動子は前記ミラー部を振動させる駆動部を有するとともに、3以上の振動板が2以上のターン部で折り返すように連結されたミアンダ形であり、前記ターン部は前記ミラー部中心軸に平行であり、
前記ミラー部と前記第1振動子との連結位置と、前記支持体と前記第1振動子との連結位置とを結ぶ線分が、前記ミラー部中心軸と交差し、
前記ミラー部と前記第2振動子との連結位置と、前記支持体と前記第2振動子との連結位置とを結ぶ線分が、前記ミラー部中心軸と交差し、
前記ターン部の少なくともいずれか1つの少なくとも一部が、前記ミラー部中心軸に平行で前記ミラー部の前記第1辺を通る第1端部軸より外側に位置するか、前記ターン部の少なくともいずれか1つの全体が前記第1端部軸より内側に位置するか、前記ターン部の少なくともいずれか1つの少なくとも一部が、前記ミラー部中心軸に平行で前記ミラー部の前記第2辺を通る第2端部軸より外側に位置するか、前記ターン部の少なくともいずれか1つの全体が前記第2端部軸より内側に位置するか、のうちの少なくともいずれか1つを満たす、
光学反射素子。 - 前記ミラー部は、前記反射面の裏側に枠形状の錘を有し、
前記枠形状の錘の内側と外側との間の枠幅が、前記第1辺側と前記第2辺側とで異なる、
請求項1記載の光学反射素子。
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