Source: https://patents.google.com/patent/JP2014209170A/en
Timestamp: 2020-08-04 06:49:19
Document Index: 356086163

Matched Legal Cases: ['art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 12', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 14', 'art 26', 'art 28']

JP2014209170A - Liquid crystal optical device, solid-state imaging device, portable information terminal, and display unit - Google Patents
Liquid crystal optical device, solid-state imaging device, portable information terminal, and display unit Download PDF
JP2014209170A
JP2014209170A JP2013227338A JP2013227338A JP2014209170A JP 2014209170 A JP2014209170 A JP 2014209170A JP 2013227338 A JP2013227338 A JP 2013227338A JP 2013227338 A JP2013227338 A JP 2013227338A JP 2014209170 A JP2014209170 A JP 2014209170A
JP2013227338A
岐　津　裕　子
津 裕 子 岐
藤 真知子 伊
崎 幸 男 木
鎬 楠 権
和 拓 鈴木
木 和 拓 鈴
野 梨紗子 上
林 光 吉 小
多 浩 大 本
Hironaga Honda
2013-03-22 Priority to JP2013060361 priority Critical
2013-03-22 Priority to JP2013060361 priority
2013-10-31 Application filed by 株式会社東芝, Toshiba Corp filed Critical 株式会社東芝
2013-10-31 Priority to JP2013227338A priority patent/JP2014209170A/en
2014-11-06 Publication of JP2014209170A publication Critical patent/JP2014209170A/en
239000004973 liquid crystal related substances Substances 0.000 title claims abstract description 315
238000003384 imaging method Methods 0.000 title claims abstract description 113
PROBLEM TO BE SOLVED: To provide a liquid crystal optical device having a function capable of switching between an imaging mode in which a subject depth-directional distance can be obtained and an imaging mode for high-resolution two-dimensional image, a solid-state imaging device, a portable information terminal, and a display unit.SOLUTION: A liquid crystal optical device includes: a first electrode part which has a first light-permeable substrate having a first surface, a light-permeable layer provided on the first substrate and a first light-permeable electrode provided on the light-permeable layer, the light-permeable layer having a recessed part, arrayed in a first direction parallel with the first surface and extending in a second direction crossing the first direction, on a surface opposed to an electrode film; a second electrode part which has a second light-permeable substrate having a second surface opposed to the first substrate with the first electrode part interposed, two second electrodes provided on the second surface of the second substrate, arrayed in the second direction, and extending in the first direction; a liquid crystal layer held between the first electrode part and second electrode part; a first polarization plate opposed to the liquid crystal layer with the second electrode part interposed; and a driving part which applies a voltage between the first electrode and second electrode.
Embodiments described herein relate generally to a liquid crystal optical device, a solid-state imaging device, a portable information terminal, and a display device.
As an imaging technique capable of obtaining a depth direction distance to a subject as two-dimensional array information, various methods such as a technique using reference light and a stereo ranging technique using a plurality of cameras are known. In particular, in recent years, there has been an increasing need for an imaging device capable of obtaining distance information that is relatively inexpensive as a new input device for consumer use.
Therefore, an imaging apparatus having a compound eye configuration that has an imaging lens has been proposed as a configuration that can obtain multiple parallaxes with multiple eyes and suppress a reduction in resolution. This imaging apparatus has an imaging system lens, for example, and a plurality of optical systems are arranged as a re-imaging system optical system between the imaging system lens and the imaging device. For example, as the plurality of optical systems, a microlens array in which a large number of microlenses are formed on a plane is used. Below each microlens, a plurality of pixels are provided at corresponding positions to acquire the image. The image formed in the imaging lens is formed again on the image sensor by the re-imaging microlens, and the re-imaged single-eye image has a viewpoint corresponding to the amount of parallax existing depending on the arrangement position of the microlens. The image is shifted.
By subjecting a group of parallax images obtained from a large number of microlenses to image processing, it is possible to estimate the distance of the subject based on the principle of triangulation, and to reconstruct it as a two-dimensional image by performing splicing image processing. It is also possible to do.
In general, the resolution of a reconstructed two-dimensional image is lower than that of a two-dimensional image obtained without a plurality of optical systems. By switching the presence or absence of a plurality of optical systems using a variable microlens array, it is possible to switch between an imaging mode capable of obtaining a distance in the subject depth direction and a high-resolution two-dimensional image imaging mode. . Disclosed is a technology for switching a liquid crystal optical device between an imaging action and a non-imaging state by applying or removing a voltage using a liquid crystal optical device combined with a liquid crystal lens element and a polarization switching liquid crystal element as a plurality of optical systems. Has been. However, since two types of liquid crystal elements are combined, the number of members is large and the elements are thick.
In addition, a liquid crystal optical device in which a polarization rotating liquid crystal element is provided between a first liquid crystal polarizing element that deflects an optical path of polarized light in one direction and a second liquid crystal polarizing element that deflects in a direction orthogonal to the one direction. A technique is known that biases the optical path up, down, left and right. Since this liquid crystal optical device has three liquid crystal optical elements laminated, it is difficult to reduce the thickness of the device.
JP 2008-167395 A JP 2002-214579 A JP 2007-213081 A
The present embodiment provides a liquid crystal optical device, a solid-state imaging device, a portable information terminal, and a liquid crystal optical device having a function capable of switching between an imaging mode capable of obtaining a subject depth direction distance and a high-resolution two-dimensional image imaging mode. And a display device.
The liquid crystal optical device according to the present embodiment includes a light transmissive first substrate having a first surface, a light transmissive layer provided on the first substrate, and a light transmissive property provided on the light transmissive layer. The light transmission layer is arranged on a surface facing the electrode film along a first direction parallel to the first surface, and extends in a second direction intersecting the first direction. Provided on a second surface of the second substrate, a first electrode portion having a concave portion, a light transmissive second substrate having a second surface facing the first substrate via the first electrode portion, and the second substrate. A second electrode portion having two second electrodes arranged in the second direction and extending along the first direction, and a liquid crystal layer sandwiched between the first electrode portion and the second electrode portion A first polarizing plate facing the liquid crystal layer via the second electrode portion, and driving for applying a voltage to the first electrode and the second electrode Liquid crystal optical device comprising a and.
The figure which shows the solid-state imaging device by 1st Embodiment. 1 is a cross-sectional view illustrating a solid-state imaging device according to a first embodiment. 1 is a top view of a liquid crystal optical device according to a first embodiment. 4A and 4B are cross-sectional views of the liquid crystal optical device according to the first embodiment. 5A and 5B are views for explaining the operation of the liquid crystal optical device according to the first embodiment. 6A and 6B are views for explaining the operation of the liquid crystal optical device according to the first embodiment. FIG. 4 is a waveform diagram showing voltages for driving the liquid crystal optical device according to the first embodiment. The wave form diagram which shows the voltage which drives the liquid crystal optical device by the modification of 1st Embodiment. FIGS. 8A and 8B are diagrams illustrating the operation of a liquid crystal optical device according to another example. 9A and 9B are diagrams for explaining the operation of a liquid crystal optical device according to another example. The wave form diagram which shows an example of the voltage which drives the liquid crystal optical device by another example. Sectional drawing of the liquid crystal optical device of one specific example which concerns on 2nd Embodiment. Sectional drawing of the liquid crystal optical device of one specific example which concerns on 2nd Embodiment. FIG. 10 is a waveform diagram showing an example of a voltage for driving a liquid crystal optical device of one specific example according to the second embodiment. The wave form diagram which shows an example of the voltage which drives the liquid crystal optical apparatus of the other specific example which concerns on 2nd Embodiment. Sectional drawing of the liquid crystal optical device of one specific example which concerns on 3rd Embodiment. Sectional drawing of the liquid crystal optical device of one specific example which concerns on 3rd Embodiment. Sectional drawing of the liquid crystal optical device of the other specific example which concerns on 3rd Embodiment. Sectional drawing of the liquid crystal optical device of the other specific example which concerns on 3rd Embodiment. The figure which shows an example of the voltage which drives the liquid crystal optical device which concerns on 3rd Embodiment. The figure which shows the manufacturing method of the liquid crystal optical device by 4th Embodiment. The perspective view which shows the portable information terminal by 5th Embodiment. The block diagram which shows the display apparatus by 6th Embodiment. 23A and 23B are cross-sectional views of a liquid crystal optical device according to a modification of the first embodiment. Sectional drawing of the liquid crystal optical device of one specific example which concerns on 7th Embodiment. Sectional drawing of the liquid crystal optical device of one specific example which concerns on 7th Embodiment. The figure explaining the solid-state imaging device of 7th Embodiment. The figure explaining the modification of the solid-state imaging device of 3rd Embodiment. The figure which shows the characteristic plot of the refractive index distribution produced at the time of the voltage application of the liquid crystal optical device which concerns on 7th Embodiment.
FIG. 1 shows a solid-state imaging device (camera module) 1 according to the first embodiment. The solid-state imaging device 1 according to the first embodiment includes an imaging module unit 10 and an imaging signal processor (hereinafter also referred to as ISP (Image Signal Processor)) 20.
The imaging module unit 10 includes an imaging optical system 12, a liquid crystal optical device 14, an imaging element 16, and an imaging circuit 18. The imaging optical system 12 functions as an imaging optical system that takes light from the subject into the imaging device 16. The imaging element 16 faces the imaging optical system 12 and functions as an element that converts light captured by the imaging optical system 12 into a signal charge. A plurality of pixels (for example, photodiodes as photoelectric conversion elements) are two-dimensional. They are arranged in an array. The plurality of pixels form one pixel block. That is, the image sensor 16 has a plurality of pixel blocks, and one pixel block has a plurality of pixels. The liquid crystal optical device 14 is provided between the imaging optical system 12 and the image sensor 16 and has a structure in which, for example, a liquid crystal layer is sandwiched between two opposing electrodes, as will be described later. By applying a voltage to the two electrodes, the refractive index of the liquid crystal layer changes, and the liquid crystal optical device 14 becomes a microlens array having a plurality of microlenses. When no voltage is applied to the two transparent electrodes, the refractive index of the liquid crystal layer does not change, and light incident on the liquid crystal optical device 14 is transmitted through the liquid crystal optical device. That is, the liquid crystal optical device 14 can switch between a lens state and a non-lens state depending on whether or not a voltage is applied. Thereby, the solid-state imaging device can switch between an imaging mode in which the subject depth direction distance can be obtained and an imaging mode for high-resolution two-dimensional images.
When the liquid crystal optical device 14 is a microlens array, for example, the surface facing the imaging element 16 has a convex shape, and the surface facing the imaging optical system 12 is a flat surface. Each of the plurality of microlenses of the liquid crystal optical device 14 corresponds to each of a plurality of pixel blocks provided on the image sensor 16. One of the microlenses of the liquid crystal optical device 14 functions as an optical system for reducing and imaging the light transmitted through the imaging optical system 12 onto the pixel block corresponding to the microlens. In other words, the light beam group that is imaged on the imaging surface by the imaging optical system 12 is reduced and re-imaged on the pixel block corresponding to the microlens of the liquid crystal optical device 14 in the pixel array of the image sensor 16.
The imaging circuit 18 includes a drive circuit unit (not shown) that drives each pixel of the imaging device 16 and a pixel signal processing circuit unit (not shown) that processes a signal output from the pixel. Alternatively, a driving circuit unit and a driving processing circuit having a function of combining the pixel signal processing circuit unit may be included. In the following embodiments, the imaging circuit 18 has a drive processing circuit. The drive circuit unit includes, for example, a vertical selection circuit that sequentially selects pixel units arranged in a horizontal line (row) in the vertical direction, a horizontal selection circuit that sequentially selects pixels in units of columns, a vertical selection circuit, and a horizontal selection circuit. It has a TG (timing generator) circuit that is driven by various pulses. The pixel signal processing circuit unit includes an AD conversion circuit that digitally converts an analog electrical signal from the pixel region, a gain adjustment / amplifier circuit that performs gain adjustment and an amplifier operation, and a digital signal processing circuit that performs digital signal correction processing, etc. Etc.
The ISP 20 includes a camera module I / F (interface) 22, an image capturing unit 24, a signal processing unit 26, and a driver I / F 28. A RAW image obtained by imaging by the imaging module unit 10, that is, a RAW image obtained by the image signal processing circuit unit, is captured from the camera module I / F 22 to the image capturing unit 24. The signal processing unit 26 performs signal processing on the RAW image captured by the image capturing unit 24. The driver I / F (interface) 28 outputs an image signal that has undergone signal processing in the signal processing unit 26 to a display driver (not shown). The display driver displays an image captured by the solid-state imaging device.
FIG. 2 shows a cross section of the solid-state imaging device 1 according to the first embodiment. As shown in FIG. 2, in the solid-state imaging device 1 of the first embodiment, the imaging element 16 includes a semiconductor substrate 16a, a plurality of pixels 16b formed on the semiconductor substrate 16a and having photodiodes, and these pixels. A driving / reading circuit (not shown) is provided for driving 16b and reading signals from these pixels 16b. The image sensor 16 may further include a color filter 16c provided on the pixel 16b. The color filter 16c may include, for example, R (red), G (green), and B (blue) filters provided corresponding to the pixels 16b. The R (red), G (green), and B (blue) filters may be formed by an array method such as a Bayer array. The image pickup device 16 may include a pixel condensing microlens 16d provided on the color filter 16c and corresponding to each of the pixels 16b. A liquid crystal optical device 14 is formed above the color filter 16c. The liquid crystal optical device 14 is attached to the liquid crystal optical device holder 40.
The liquid crystal optical device holder 40 is bonded to the semiconductor substrate 16a by, for example, a resin material spacer 42 provided around the imaging region where the pixels 16b are formed. Note that alignment when the semiconductor substrate 16a and the liquid crystal optical device holder 40 are bonded is performed with reference to an alignment mark or the like.
The semiconductor substrate 16a is provided with readout electrode pads 44a and 44b of the pixel 16b, and a through electrode 46 penetrating the semiconductor substrate 16c is formed below the electrode pads 44a and 44b. The electrode pad 44 b is further electrically connected to the liquid crystal optical device 14 and transmits a driving signal for the liquid crystal optical device 14.
The semiconductor substrate 16 a is electrically connected to the chip 50 through the through electrode 46 and the bump 48. The chip 50 is formed with a drive processing circuit (image pickup circuit 18) for driving the image pickup apparatus and processing the read signal.
Further, an imaging lens 12 is provided above the liquid crystal optical device 14, and this imaging lens 12 is attached to a lens barrel 62, and this lens barrel 62 is attached to a lens holder 64. The lens holder 64 is bonded onto the liquid crystal optical device holder 40. When the imaging lens 12 is attached, the focal length of the lens 12 may be adjusted from the relationship between the pressing pressure and the output image. A light shielding cover 52 for blocking unnecessary light is attached around the semiconductor substrate 16a, the liquid crystal optical device holder 40, and the chip 50. The light shielding cover 52 is provided with a module electrode 54 that electrically connects the chip 50 and the outside. The above configuration is not limited to this, and for example, the electrode pads 44a and 44b may be electrically connected to an external chip by wire bonding or the like.
Next, the liquid crystal optical device 14 will be described with reference to FIGS.
FIG. 3 shows the upper surface of a specific example of the liquid crystal optical device 14 according to the present embodiment, FIG. 4A shows a cross section cut along the cutting line AA shown in FIG. 3, and FIG. FIG. 4B shows a cross section cut along the cutting line BB. FIG. 4A is also a cross section cut along a cutting line AA shown in FIG.
In the liquid crystal optical device 14, lens portions that are microlenses are arranged in a square pattern. The liquid crystal optical device 14 includes a pair of opposing electrode portions 14a and 14b, a liquid crystal layer 14c sandwiched between the electrode portions 14a and 14b, and a polarizing plate 14d. The polarizing plate 14d is provided on the side opposite to the liquid crystal layer 14c with respect to the electrode portion 14b.
Electrode portion 14a includes a substrate 14a 1 of the optically transparent mold portion (light transmitting layer) and 14a 2, and includes an electrode 14a 3, a. Substrate 14a 1 is a flat substrate, such as quartz is used. The substrate 14a 1 has one main surface, and this one main surface is defined as an XY plane. The mold part 14a 2 is provided on one main surface of the substrate 14a 1 and has a plurality of recesses arranged at equal intervals in one direction (X-axis direction). The recess faces the liquid crystal layer 14c. Each recess extends in the Y-axis direction perpendicular to the X-axis direction, and each recess has a hemispherical cross section cut along a plane (XZ plane) orthogonal to the Y-axis direction. That is, each concave portion has, for example, a semi-cylindrical shape whose surface extends in the Y-axis direction. Each concave portion corresponds to a convex portion of the lens when the liquid crystal optical device 14 functions as a lens. The mold part 14a 2 is light transmissive, and transmits visible light, for example. As will be described later, the material of the mold part 14a 2 is selected so that the refractive index of the mold part is substantially equal to the refractive index of the liquid crystal layer 14c. For example, resin or silicon oxide can be used. Electrodes 14a 3 is a film of optically transparent electrode material disposed on the surface of the mold portion 14a 2, for example, ITO (Indium Tin Oxide) is used. Electrodes 14a 3 has a recess in the liquid crystal layer 14c and the opposite surfaces. Between the mold portions 14a 2 and the electrodes 14a 3, the film may be interposed, such as for improving adhesion. The Z-axis direction is opposite to the direction of light incident on the liquid crystal optical device 14.
Electrode portion 14b includes a substrate 14b 1 of a light-transmissive, and a wire-shaped electrode 14b 4 extending in the X-axis direction. Electrode portion 14b is further a surface electrode 14b 2, and the insulating film 14b 3, may be provided with. The substrate 14b 1 has a second surface opposite to the first surface of the substrate 14a 1 . For example, the first surface and the second surface are parallel. The substrate 14b 1 is a flat substrate, and for example, quartz is used. The surface electrode 14b 2 is provided on the second surface of the substrate 14b 1 . Plane electrode 14b 2 is an electrode material, for example, formed from ITO (Indium Tin Oxide), a planar electrode film provided on the substrate 14b 1. Insulating film 14b 3 is provided on the surface electrode 14b 2, to electrically insulate the surface electrode 14b 2 and the electrode 14b 4. The electrode 14b 4 is provided on the insulating film 14b 3 . The electrode 14b 4 faces the surface electrode 14b 2 with the insulating film 14b 3 interposed therebetween, and the electrode 14b 4 overlaps part of the surface electrode 14b 2 . The electrode 14b 4 has a configuration in which electrodes 14b 41 extending in the X-axis direction and electrodes 14b 42 extending in the X-axis direction are alternately arranged. As will be described later, when the liquid crystal optical device 14 functions as a lens, different voltages are applied to the electrode 14b 41 and the electrode 14b 42 . In this case, the distance between the adjacent electrodes 14b 41 across the electrode 14b 42 is the lens pitch. The electrode 14b 4 may be composed of electrodes to which the same voltage is applied. The state where the same voltage is applied includes a state where voltage waveforms having the same amplitude but different phases are applied. In this case, the distance between adjacent electrodes 14b 4 is the pitch of the lens. Further, the surface electrode 14b 2 may not be provided. In this case, the insulating film 14b 3 is not necessary, and the wiring electrode 14b 4 is provided directly on the substrate 14b 1 . In any configuration, a coating for improving adhesion or the like may be interposed between the surface electrode 14b 2 or the electrode 14b 4 and the substrate 14b 1 . As in this embodiment, when the surface electrode 14b 2 is provided to cooperate with the wiring electrode 14b 4 , the controllability of the electric field distribution applied to the liquid crystal layer 14c, that is, the verticality of the electric field is improved. And the optical characteristics of the liquid crystal optical device when a voltage is applied can be improved.
The electrode portion 14a and the electrode portion 14b, and the electrode 14a 3 and the wiring-shaped electrode 14b 4 are arranged so as to face, sandwiched between the liquid crystal and the electrode portion 14a and the electrode portion 14b. As the sandwiching method, for example, a well-known method for manufacturing a liquid crystal display device can be applied. An alignment film (not shown) is provided between each of the electrode portions 14a and 14b and the liquid crystal layer 14c.
The polarizing plate 14 d is provided on the light incident surface of the liquid crystal optical device 14. The polarizing plate 14d faces the liquid crystal layer 14c through the electrode portion 14b. The polarizing plate 14d polarizes the incident light into light having a transmission axis in the vertical and horizontal directions (or an intermediate direction thereof) and makes this polarized light incident on the liquid crystal layer 14c. Polarizer 14d may be a linear polarizer having an optical axis, for example, mold section 14a 2 of the recess in the extending direction (Y-axis direction). The polarizing plate 14d may be a circular polarizing plate, for example. The polarizing plate 14d may be, for example, a linear polarizing plate having an optical axis that forms an angle of 45 degrees with respect to a direction in which the alignment of liquid crystal molecules in the liquid crystal layer 14c is planarly projected.
An electrode 14a 3 of the electrode portions 14a, and the surface electrode 14b 2 and the electrode 14b 4 of the electrode portion 14b, is driven by the drive unit. This drive unit is provided in the chip 50 shown in FIG. 2 in the solid-state imaging device of the present embodiment.
One lens is formed by one concave portion of the first electrode portion, two second electrodes of the second electrode portion, and a liquid crystal layer provided therebetween.
FIG. 5A to FIG. 6B are cross-sectional views showing the operation of the liquid crystal optical device 14. FIGS. 5 (a) and 5 (b) show the operations in the cross sections shown in FIGS. 4 (a) and 4 (b), respectively, and FIGS. 6 (a) and 6 (b) show FIGS. The operation in the cross section shown in FIG. FIGS. 5A and 5B show the operation when no voltage is applied to the liquid crystal optical device 14 or when each electrode is not connected to a power source. FIGS. 6A and 6B show the liquid crystal. The operation when a voltage is applied to the optical device 14 will be described.
As can be seen from FIGS. 5A and 5B, when no voltage is applied, the liquid crystal molecules of the liquid crystal layer 14c are uniformly arranged when viewed from the plane direction. At this time, the planar projection direction of the liquid crystal array is, for example, the direction in which the electrodes 14b 4 are arranged (Y-axis direction). The alignment orientation of the liquid crystal alignment is, for example, the vertical direction (Z-axis direction). In this case, the plane projection direction is indefinite. If the material is selected so that the refractive index of the mold part 14a 2 is substantially equal to the refractive index of the liquid crystal layer 14c when no voltage is applied, the refractive index of the liquid crystal layer 14c and the mold part 14a 2 are matched. For example, the refractive index difference between the refractive index of the molding part 14a 2 and no voltage is applied when the liquid crystal layer 14c refractive index of 0.3 within. Therefore, as shown in FIG. 5A, the light incident on the liquid crystal optical device 14 goes straight without being refracted by the convex surface portion of the lens. Further, as shown in FIG. 5B, since the liquid crystal layer 14c is uniform in the plane and the refractive index is constant, the incident light travels straight in the same manner. At this time, the liquid crystal optical device 14 is in a non-lens state.
As shown in FIGS. 6A and 6B, voltages V1 and V2 are applied to the electrodes 14b 2 and 14b 4 of the electrode part 14b, respectively, and the electrodes of the electrode part 14a are set to GND. At this time, the liquid crystal molecules of the liquid crystal layer 14c rearrange according to the electric field distribution formed in the liquid crystal. Accordingly, a refractive index distribution is generated in the liquid crystal layer 14c. That is, the refractive index distribution of the liquid crystal layer 14c, which causes a mismatch refractive index of the liquid crystal layer 14c and the mold portion 14a 2. Therefore, in FIG. 6 (a), a surface electrode 14b 2 of the light incident side electrode portion 14b, when a voltage is applied to the liquid crystal layer 14c between the electrodes 14a 3 of the electrode portions 14a, generally vertical electric field distribution As a result, if the liquid crystal layer 14c is a material having positive dielectric anisotropy, the liquid crystal molecules are aligned vertically. If the liquid crystal layer 14c is a material having negative dielectric anisotropy, the liquid crystal molecules are aligned horizontally. As a result, the refractive index changes, the refractive index difference between the mold portions 14a 2 occurs. The refractive index at this time usually decreases when the liquid crystal molecules are rearranged vertically, and increases when the liquid crystal molecules are rearranged horizontally. Thereby, the liquid crystal layer 14c functions as a lens. Therefore, the liquid crystal layer 14c collects the light transmitted through the liquid crystal layer 14c.
In FIG. 6B, a voltage is applied to one electrode of the electrode 14b 4 (14b 41 , 14b 42 ) of the electrode portion 14b, for example, the liquid crystal layer 14c between the electrode 14b 41 and the electrode 14a 3 of the electrode portion 14a. Then, if the liquid crystal layer 14c is a material having a positive dielectric anisotropy, there is a relatively large vertical component immediately above the electrode to which a voltage is applied, and the relative relationship between the electrode 14b 42 and the electrode 14a 3 is relatively high. An electric field distribution having a large horizontal component and periodically changing occurs (a schematic refractive index distribution is indicated by a broken line in the liquid crystal layer 14c). If the liquid crystal layer 14c is a material having negative dielectric anisotropy, the horizontal component is relatively high immediately above the electrode to which a voltage is applied, and the liquid crystal layer 14c is relatively between the electrode 14b 42 and the electrode 14a 3. many vertical component, periodically varying electric field distribution occurs (in this case, the refractive index profile for the distribution shown in FIG. 6 (b), half the arrangement direction of the wiring-shaped electrode 14b 4 (Y-axis direction) (The distribution will be out of period). As a result of the periodic change in the inclination of the liquid crystal alignment along the electric field distribution, the refractive index periodically changes along the direction (Y-axis direction) in which the wiring electrodes 14b4 are arranged, and the liquid crystal layer 14c It functions as a GRIN (GRadient INdex) lens and collects light. At this time, the liquid crystal optical device 14 is in a lens state. That is, the liquid crystal optical device 14 can switch between a lens state and a non-lens state depending on whether or not a voltage is applied.
FIG. 7A shows an example of a voltage waveform that is driven so as to be in the non-lens state and the lens state shown in FIGS. 5 (a) to 6 (b). FIG. 7A shows an example in which a material having negative dielectric anisotropy is used for the liquid crystal layer 14c. FIG. 7 is a voltage waveform diagram of the electrode 14a 3 of the electrode portion 14a, the surface electrode 14b 2 of the electrode portion 14b, and the wiring electrodes 14b 41 and 14b 42 , respectively. An AC voltage obtained by increasing or decreasing the voltage Vh ′ from the reference voltage Vc is applied to the surface electrode 14b 2 , and an AC voltage obtained by increasing or decreasing the voltage Vh2 from the reference voltage Vc is applied to the electrode 14b 41. An alternating voltage obtained by increasing or decreasing the voltage Vh from the reference voltage Vc is applied to 42 . Vh ′ is greater than or equal to Vh, and Vh2 is greater than or equal to Vh ′. Vh ′ is the voltage V1 applied to the liquid crystal layer 14c described with reference to FIGS. 6 (a) and 6 (b). Vh2 is the voltage V2 applied to the liquid crystal layer 14c described with reference to FIGS. 6 (a) and 6 (b). The voltage waveform of the surface electrode 14b 2 may be substantially synchronized with either the electrode 14b 41 or the electrode 14b 42 . Further, the voltage of the surface electrode 14b 2 and the electrode 14b 42 may be a constant voltage Vc that does not vary. The application order of the voltages of the surface electrode 14b 2 , the electrode 14b 41 , and the electrode 14b 42 may be reversed from the case shown in FIG. In the example shown in FIG. 7A, the voltage application of the electrode 14b 41 and the electrode 14b 42 is simultaneous, but the application timing may be shifted. In the example shown in FIG. 7A, the voltage waveforms of the surface electrode 14b 2 , the electrode 14b 41 , and the electrode 14b 42 are rectangular waveforms, but may be any AC waveform. Further, while maintaining the state in which there is a potential difference between the surface electrode 14b 2 and the electrode 14a 3, it may be applied an AC waveform to the electrodes 14a 3.
In this way, it is possible to put the liquid crystal optical device 14 in a non-lens state without applying a voltage to the electrode portion 14b, and put the liquid crystal optical device 14 in a lens state by applying a voltage to the electrode portion 14b.
The thickness of the electrode portion 14a may be made thinner than the thickness of the electrode portion 14b. For example, when the lens array has a small diameter, an image obtained by this lens tends to be dark. In order to obtain bright imaging, it is desirable to shorten the focal length and bring it closer to the image sensor. Therefore, it is preferable that the first electrode portion is thin. If the second electrode portion is also thinned, the entire element is likely to be deformed, which may increase the number of defects during mounting. Therefore, when making the electrode part 14a thin, it is preferable that the second electrode part is thicker than this.
As shown in FIGS. 23 (a) and 23 (b), the liquid crystal optical device 14 may be arranged so that the electrode portion 14a faces the light and the electrode portion 14b faces the imaging device. The thickness of the electrode portion 14a is the sum of the substantially thicknesses of the mold portion 14a 2 of the substrate 14a 1. Since the substrate 14a 1 supports the mold part 14a 2 , it may be difficult to reduce the thickness. The mold portion 14a 2, the formation of the concavo-convex structure, it is necessary that the depth or thickness. However, when the electrode portion 14a side and the light incident side, (in effect, the substrate 14b 1 of thickness) The thickness of the electrode portion 14b of the lens by thin can be brought closer to the imaging device. At this time, the polarizing plate 14d is provided so as to face the liquid crystal layer 14c with the electrode portion 14a interposed therebetween. Note that FIG. 23B is a cross section cut along the cutting line BB shown in FIG. 23A, and FIG. 23A is cut along the cutting line AA shown in FIG. It is a cross section.
As shown in FIG. 7B, when a material having positive dielectric anisotropy is used as the liquid crystal layer 14c of the liquid crystal optical device 14 shown in FIGS. 5 to 6, another lens state may be realized. it can.
FIG. 7B is a voltage waveform diagram of the electrode 14a 3 of the electrode portion 14a, the surface electrode 14b 2 of the electrode portion 14b, and the wiring electrodes 14b 41 and 14b 42 , respectively. An AC voltage obtained by increasing or decreasing the voltage Vh ′ from the reference voltage Vc is applied to the surface electrode 14 b 2 , and an AC voltage obtained by increasing or decreasing the voltage Vh from the reference voltage Vc is applied to the electrodes 14 b 41 and 14 b 42. Is done. Vh ′ is greater than or equal to Vh. Vh ′ is the voltage V1 applied to the liquid crystal layer 14c described with reference to FIGS. 6 (a) and 6 (b). Vh is the voltage V2 applied to the liquid crystal layer 14c described with reference to FIGS. 6 (a) and 6 (b). The voltage waveform of the surface electrode 14b 2 may be substantially synchronized with either the electrode 14b 41 or the electrode 14b 42 . The voltage of the surface electrode 14b 2 is may be a constant voltage Vc does not vary. The order in which the voltages of the surface electrode 14b 2 , the electrode 14b 41 , and the electrode 14b 42 are applied may be reversed from the case shown in FIG. 7B or may be applied simultaneously. In the example shown in FIG. 7B, the voltage application of the electrode 14b 41 and the electrode 14b 42 is simultaneous, but the application timing may be shifted. In the example shown in FIG. 7B, the voltage waveforms of the surface electrode 14b 2 , the electrode 14b 41 , and the electrode 14b 42 are rectangular waveforms, but may be any AC waveform. Further, while maintaining the state in which there is a potential difference between the surface electrode 14b 2 and the electrode 14a 3, it may be applied an AC waveform to the electrodes 14a 3.
In this example, a refractive index distribution having the same period as the concavo-convex period of the electrode portion 14a is generated in the element cross section shown in FIG. On the other hand, the refractive index distribution in the element cross section shown in FIG. 6B changes from the shape shown by the broken line. In the example shown in FIG. 7B, an AC voltage having the same amplitude and reverse polarity is applied to the electrode 14b 41 and the electrode 14b 42 . At this time, the voltage at the center of the distance between the electrode 14b 41 and the electrode 14b 42 is constant almost remains Vc, the electrode 14a 3 opposed, and substantially the same potential. For this reason, there is a relatively large vertical component immediately above the electrode 14b 41 and the electrode 14b 42 , and there is a relatively large horizontal component at the center of the interval between the electrode 14b 42 and the electrode 14a 3, and the periodically changing electric field distribution. Occurs. Furthermore, between the electrode 14b 42 and the electrode 14a 3, substantially amplitude AC voltage 2Vh is applied. Therefore, between the electrode 14b 42 and the electrode 14a 3, particularly in the liquid crystal layer 14c of the electrode portion 14b near occurs more horizontal component of many field distribution. That is, in the device section shown in FIG. 6 (b), a low relative refractive index immediately above the electrode 14b 41 and the electrodes 14b 42, a relatively high refractive index of between the electrodes 14b 41 and the electrode 14b 42 Distribution occurs.
Incidentally, when the dielectric anisotropy of the liquid crystal 14c is negative, the application of a voltage waveform shown in FIG. 7B, with relatively high refractive index directly above the electrode 14b 41 and the electrodes 14b 42, electrode 14b 41 and the electrode 14b 42 A distribution with a relatively low refractive index occurs between the two.
Next, a liquid crystal optical device 14 according to another specific example will be described with reference to FIGS. 8 (a) to 9 (b). 8 to 9 are examples in the case where a material having positive dielectric anisotropy is used for the liquid crystal layer 14c.
8 (a) and 8 (b) show the operations in the cross sections shown in FIGS. 4 (a) and 4 (b), respectively, and FIGS. 9 (a) and 9 (b) show FIG. 4 (a) and FIG. The operation in the cross section shown in FIG. 8A and 8B show the operation when a relatively weak voltage Vl is applied to the liquid crystal optical device 14, and FIGS. 9A and 9B are compared with the liquid crystal optical device 14. The operation when a strong voltage Vt is applied is shown.
The liquid crystal optical device 14 according to another example is in a lens state as can be seen from FIGS. 8A and 8B when a relatively weak voltage Vl is applied to the electrode of the electrode portion 14b. In this case, in the cross section shown in FIG. 8 (a), the refractive index mismatch between the liquid crystal layer 14c and the mold portion 14a 2 is generated. In the cross section shown in FIG. 8B, a refractive index distribution is generated by a periodic change in the arrangement of the liquid crystal layer 14c. However, the alignment state of liquid crystal in the vicinity of the mold section 14a 2 is not yet changed.
Further, as shown in FIGS. 9A and 9B, when a relatively strong voltage Vt is applied to the electrode of the electrode portion 14b, a non-lens state is obtained. In the state shown in FIG. 9 (a), changes to the alignment state of the liquid crystal layer 14c in the vicinity of the mold section 14a 2, the refractive index is matched with the liquid crystal layer 14c and the mold portion. In the state shown in FIG. 9B, a substantially vertical electric field is generated between the electrode portions 14a and 14b, and the liquid crystal layer 14c is uniformly arranged.
FIG. 10 shows an example of voltage waveforms for driving the lens state and the non-lens state shown in FIGS. FIG. 10 is a voltage waveform diagram of each of the electrode 14a 3 of the electrode portion 14a, the surface electrode 14b 2 of the electrode portion 14b, and the wiring electrodes 14b 41 and 14b 42 . An AC voltage obtained by increasing or decreasing the voltage Vt ′ from the reference voltage Vc is applied to the surface electrode 14b 2 , and an AC voltage obtained by increasing or decreasing the voltage Vt from the reference voltage Vc is applied to the electrode 14b 41 and the electrode 14b 42. Is done. Vt ′ is greater than or equal to Vt, and Vt is greater than Vl. The voltage waveform of the surface electrode 14b 2 may be substantially synchronized with either the electrode 14b 41 or the electrode 14b 42 .
In this way, the liquid crystal optical device 14 is placed in the lens state by applying the first voltage to the electrode portion 14b, and the liquid crystal optical device 14 is placed in the non-lens state by applying a second voltage higher than the first voltage to the electrode portion 14b. It is possible.
The second voltage can be, for example, twice or more of the first voltage. The value of the second voltage is preferably set as appropriate depending on the material of the liquid crystal layer 14c, but can be, for example, 50 times or less of the first voltage.
The application order of the voltages of the surface electrode 14b 2 , the electrode 14b 41 , and the electrode 14b 42 may be reversed from the case shown in FIG. 10 or may be applied simultaneously. In the example shown in FIG. 10, the voltages of the electrodes 14b 41 and 14b 42 are applied simultaneously, but the application timings may be shifted. In the example shown in FIG. 10, the voltage waveforms of the surface electrode 14b 2 , the electrode 14b 41 , and the electrode 14b 42 are rectangular waveforms, but may be any AC waveform. Further, in the lens state, while keeping the state in which there is a potential difference between the electrodes 14b 41, electrodes 14a 3, 14b 42, may be applied an AC waveform to the 14a 3. Further, in a non-lens state, an AC waveform may be applied to the electrode 14a 3 while maintaining a state in which there is a potential difference between the surface electrode 14b 2 and the electrode 14a 3 .
In the liquid crystal optical device 14 of the other example, the dielectric anisotropy of the liquid crystal layer 14c is positive. If the dielectric anisotropy of the liquid crystal 14c is negative, the refractive index distribution for the distribution shown in FIG. 8 (b), shifted by a half period in the arrangement direction of the wiring-shaped electrode 14b 4 (Y-axis direction) Distribution.
As described above, according to the present embodiment and the modification thereof, a function capable of switching between an imaging mode capable of obtaining a subject depth direction distance and an imaging mode of a high-resolution two-dimensional image is provided. A liquid crystal optical device and a solid-state imaging device can be provided.
A solid-state imaging device according to the second embodiment will be described with reference to FIGS. The solid-state imaging device of the second embodiment is different from the solid-state imaging device of the first embodiment in the liquid crystal optical device 14. A liquid crystal optical device 14A used in the solid-state imaging device of the second embodiment is shown in FIGS. 11 and 12 respectively correspond to the cross-sectional views shown in FIGS. 4 and 5 of the liquid crystal optical device 14 described in the first embodiment. 11 is a cross-sectional view taken along the cutting line AA shown in FIG. 12, and FIG. 12 is a cross-sectional view taken along the cutting line BB shown in FIG.
The liquid crystal optical device 14A according to the second embodiment has a configuration in which the electrode portion 14a is replaced with the electrode portion 14e in the liquid crystal optical device 14 according to the first embodiment. The electrode portion 14e includes a substrate 14e 1 of the optical transparency, the surface electrode 14e 2, an insulating film 14e 3, and a wiring-shaped electrodes 14e 4 extending in the X-axis direction. The light transmissive substrate 14e 1 is a flat substrate, and for example, quartz is used. The surface electrode 14e 2 is formed of a light transmissive electrode material, for example, ITO (Indium Tin Oxide), and is provided on the substrate 14e 1 . Insulating film 14e 3 is provided on the surface electrode 14e 2, to electrically insulate the surface electrode 14e 2 and the electrode 14e 3. The electrode 14e 4 is provided on the insulating film 14b 3 . In the liquid crystal optical device 14A shown in FIGS. 11 and 12, the wiring-shaped electrode 14e 4 is constituted by the electrodes of the same type which the same voltage is applied. However, as described in the first embodiment, it may be composed of different types of electrodes to which different voltages are applied. The same applies to the electrodes 14b 4 of the electrode portion 14b. Further, the surface electrode 14e 2 may not be provided. In this case, the insulating film 14e 3 is unnecessary, and the wiring electrode 14e 4 is provided directly on the substrate 14e 1 . In either configuration, the surface electrode 14e 2 or electrodes 14e 4, the substrate 14e 1, during the coating may be interposed for such adhesion improvement. As in the second embodiment, when the surface electrode 14e 2 is provided and cooperates with the wiring electrode 14e 4 , the controllability of the electric field distribution applied to the liquid crystal layer 14c, that is, the verticality of the electric field is improved. The optical characteristics of the liquid crystal optical device when a voltage is applied can be improved. That is, the electrode portions 14e, instead of the mold portion 14a 2 and the electrodes 14a 3 of the electrode portion 14a of the first embodiment has a configuration in which the electrodes 14e 4 provided on the surface electrode 14e 2 and the wiring pattern. An alignment film (not shown) is provided between each of the electrode part 14e and the electrode part 14b and the liquid crystal layer 14c.
An example of a voltage waveform for driving the liquid crystal optical device 14A according to the second embodiment is shown in FIG. Figure 13 is a plane electrode 14b 2 and the wiring-shaped electrode 14b 4 of the electrode portion 14b, a voltage waveform diagram of the surface electrode 14e 2 and the wiring-shaped electrodes 14e 4 of the electrode portion 12e. An AC voltage obtained by increasing or decreasing the voltage Vh ′ from the reference voltage Vc is applied to the surface electrode 14 b 2 and the surface electrode 14 e 2 , and the voltage Vh is increased or decreased from the reference voltage Vc to the electrode 14 b 4 and the electrode 14 e 4. Applied AC voltage is applied. The applied voltage amplitude to the liquid crystal layer 14c is ± 2 Vh. Vh ′ is greater than or equal to Vh. The voltage application order of the surface electrode 14b 2 , the surface electrode 14e 2 , the electrode 14b 4 , and the electrode 14e 4 may be reversed from the case shown in FIG. 13 or may be applied simultaneously. In the example shown in FIG. 13, the voltage application to the surface electrode 14b 2 and the surface electrode 14e 2 is simultaneous, but the application timing may be shifted. Moreover, although the voltage application of the electrode 14b 4 and the electrode 14e 4 is simultaneous, the application timing may be shifted. In the example illustrated in FIG. 13, the voltage waveforms of the surface electrode 14b 2 , the surface electrode 14e 2 , the electrode 14b 4 , and the electrode 14e 4 are rectangular waveforms, but may be any AC waveform.
Electrode 14e 4 side electrode 14b 2 and the wiring-shaped electrode portion 12e of the electrode portion 14b is to function liquid crystal layer 14c as a liquid crystal GRIN lens in the cross section shown in FIG. 12. The wiring-shaped electrode 14b 4 of the surface electrode 12e 2 and the electrode portion 14b of the electrode portion 12e causes the functional liquid crystal layer 14c as a liquid crystal GRIN lens in the cross section shown in FIG. 11. Accordingly, the liquid crystal optical device 14A can switch between a lens state and a non-lens state depending on whether or not a voltage is applied.
Further, as in the case shown in FIG. 4B, the wiring-like electrode 14b 4 of the electrode part 14b is composed of two types of wiring-like electrodes 14b 41 and 14b 42 with different applied voltages. 14e wire-shaped electrode 14e 4 of similarly from applied voltage is two different wires shaped electrodes 14e 41, 14e 42 is a case made, it shows a driving voltage waveform in Figure 14.
The liquid crystal optical device 14A according to the second embodiment does not require the formation of a mold part, and the liquid crystal optical device 14A can be manufactured by a simpler manufacturing method. Furthermore, by using this configuration, it is possible to improve the light straightness of the liquid crystal optical device when no voltage is applied.
As described above, according to the second embodiment, as in the first embodiment, the imaging mode capable of obtaining the subject depth direction distance and the imaging mode of the high-resolution two-dimensional image can be switched. It is possible to provide a liquid crystal optical device and a solid-state imaging device having a function capable of being performed.
A solid-state imaging device according to the third embodiment will be described with reference to FIGS. 15 to 19. The solid-state imaging device of the third embodiment is different from the solid-state imaging device of the first embodiment in the liquid crystal optical device. A specific example of the liquid crystal optical device 14B used in the solid-state imaging device of the third embodiment is shown in FIGS. FIGS. 15 and 16 correspond to the cross-sectional views of the liquid crystal optical device 14 described in the first embodiment shown in FIGS. 4A and 4B, respectively. 15 is a cross-sectional view taken along the cutting line AA shown in FIG. 16, and FIG. 16 is a cross-sectional view taken along the cutting line BB shown in FIG.
A specific example of the liquid crystal optical device 14B according to the third embodiment includes an electrode portion 14f, an electrode portion 14g, an electrode portion 14h, liquid crystal layers 14c 1 and 14c 2, and a polarizing plate 14d. .
The electrode part 14g is provided between the electrode part 14f and the electrode part 14h. The liquid crystal layer 14c 1 is sandwiched between the electrode portions 14f and the electrode portions 14g, the liquid crystal layer 14c 2 is sandwiched between the electrode portions 14g and the electrode portion 14h. Polarizer 14d is provided on the opposite side of the liquid crystal layer 14c 2 to the electrode portions 14h.
Electrode portion 14f includes a substrate 14f 1 of the optical transparency, and a surface electrode 14f 3 provided on the substrate 14f 1.
Electrode portion 14g includes a substrate 14g 1 light transmissive, a plurality of wiring-shaped electrodes 14g 2 provided in the liquid crystal layer 14c 1 side with respect to the substrate 14g 1, the liquid crystal layer 14c 2 to the substrate 14g 1 It includes a plane electrode 14 g 3 provided on the side, a. Each electrode 14 g 2, when the liquid crystal optical device 14B is a lens state, has a different wiring like electrode voltage is applied 14 g 21, 14 g 22. The electrodes 14g 21 and 14g 22 are alternately arranged.
Electrode portion 14h includes a substrate 14h 1 light transmissive, and a plurality of wiring-shaped electrodes 14h 2 provided in the liquid crystal layer 14c 2 side with respect to the substrate 14h 1. Each electrode h 2, the liquid crystal optical device 14B is when the lens state, has a different wiring shaped electrodes 14h which voltage is applied 21, 14h 22. The electrodes 14h 21 and 14h 22 are alternately arranged. The wiring electrode 14h 2 is arranged so as to intersect with the wiring electrode 14g 2 . That is, the electrodes 14h 21 and 14h 22 and the electrodes 14g 21 and 14g 22 are disposed so as to intersect with each other. In the third embodiment, the electrodes 14h 21 and 14h 22 and the electrodes 14g 21 and 14g 22 are arranged so as to be orthogonal to each other. Incidentally, the respective electrode portions 14f and the electrode portions 14g, between the liquid crystal layer 14c 1, and respectively of the electrode portions 14g and the electrode portions 14h, the alignment film (not shown) is provided between the liquid crystal layer 14c 2.
In the liquid crystal optical device 14B for a specific example of the third embodiment thus configured, the surface electrode 14f 3 and a plurality of electrodes 14 g 2 is, in the cross section shown in FIG. 16, the liquid crystal GRIN lens of the liquid crystal layer 14c 1 To function as. The surface electrode 14 g 3 and a plurality of electrodes 14h 2 is, in the cross section shown in FIG. 15, to function liquid crystal layer 14c 2 as liquid crystal GRIN lens. Thereby, the liquid crystal optical device 14B according to the third embodiment can switch between a lens state and a non-lens state depending on whether or not a voltage is applied. By using the liquid crystal optical device 14B according to the third embodiment, it is possible to improve the imaging performance of the liquid crystal optical device when a voltage is applied.
Next, another specific example of the liquid crystal optical device 14C used in the solid-state imaging device of the third embodiment is shown in FIGS. 17 and 18 respectively correspond to the cross-sectional views shown in FIGS. 4 and 5 of the liquid crystal optical device 14 described in the first embodiment. 17 is a cross-sectional view taken along the cutting line AA shown in FIG. 18, and FIG. 18 is a cross-sectional view taken along the cutting line BB shown in FIG.
The liquid crystal optical device 14C of another embodiment according to the third embodiment, FIG. 15, the liquid crystal optical device 14B of a specific example shown in FIG. 16, the surface electrode 14f 3 a plurality of wiring-shaped electrodes of the electrode portion 14f is replaced with the 14f 3, has a configuration obtained by replacing the plurality of wiring-shaped electrodes 14g 2 of the electrode portions 14g on the surface electrode 14g 4. That is, the electrode portion 14f includes a substrate 14f 1 of the light-transmissive, and a plurality of wiring-shaped electrodes 14f 3 provided on the substrate 14f 1, a. Each electrode 14f 2 has a wire-shaped electrode 14f 31, 14f 32. The electrodes 14f 31 and the electrodes 14f 32 are alternately arranged, and different voltages are applied when the liquid crystal optical device 14C functions as a lens.
The electrode portion 14g includes a substrate 14g 1 light transmissive, the surface electrode 14g 4 provided in the liquid crystal layer 14c 1 side with respect to the substrate 14g 1, the liquid crystal layer 14c 2 side of the substrate 14g 1 and a surface electrode 14 g 3 provided. Thus, the electrode unit 14g includes a substrate 14g 1, since the substrate 14g 1 of patterning to form the wiring shape of the electrodes on both sides unnecessary plane electrode 14g 3, 14g 4 are provided, FIG. 15 In addition, as shown in FIG.
In the liquid crystal optical device 14C of another embodiment according to the third embodiment thus configured, the plurality of electrodes 14f 3 and the surface electrode 14 g 4 is, in the cross section shown in FIG. 18, the liquid crystal of the liquid crystal layer 14c 1 GRIN To function as a lens. The surface electrode 14 g 3 and a plurality of electrodes 14h 2 is, in the cross section shown in FIG. 17, to function liquid crystal layer 14c 2 as liquid crystal GRIN lens. Accordingly, the liquid crystal optical device 14C of another specific example according to the third embodiment can switch between a lens state and a non-lens state depending on whether or not a voltage is applied. By using the liquid crystal optical device 14C of another specific example according to the third embodiment, it is possible to improve the imaging performance of the liquid crystal optical device when a voltage is applied.
An example of voltage waveforms for driving these liquid crystal optical devices 14B and 14C is shown in FIG. Figure 19 is a plane electrode 14f 3 and the wiring-shaped electrode 14f 31, 14f 32 of the electrode portion 14f, and the plane electrode 14 g 3, 14 g 4 and the wiring-shaped electrodes 14 g 21, 14 g 22 of the electrode portions 12g, the electrode portions 14h It is a voltage waveform diagram of a plurality of electrodes 14h 21 , 14h 22 . The electrode 14f 31, 14g 21, 14h 21 , an AC voltage to which the voltage V is increased or decreased is applied from the voltage Vc as the reference, electrode 14f 32, 14g 22, 14h 22 and the surface electrode 14f 2, 14g 3, 14g 4 A reference voltage Vc is applied to. The applied voltage amplitude to the liquid crystal layer 14c is ± V. In the example illustrated in FIG. 19, the voltage waveforms of the electrode 14 f 31 , the electrode 14 g 21 , and the electrode 14 h 21 are rectangular waveforms, but may be any AC waveform. While maintaining the state in which there is a potential difference between the electrodes 14f 31, 14g 21, 14h 21 , also by applying an AC waveform to the electrodes 14f 32, 14g 22, 14h 22 and the surface electrode 14f 2, 14g 3, 14g 4 Good.
In the liquid crystal optical device 14C used in the third embodiment, the wiring-shaped electrodes 14 g 2 and between and interconnect shaped electrodes 14h 2 and the light transmittance of the substrate 14 g 1 of the light transparent substrate 14h 1 As in the case described in the first embodiment, a surface electrode may be provided therebetween. In this case, an insulating film is provided between the surface electrode arrangement and the linear electrode. Similarly, in the liquid crystal optical device 14C used in the third embodiment, a wiring-shaped electrode 14f 3 and the substrate 14h 1 between and interconnect shaped electrodes 14h 2 and the light transmittance of the light transmitting substrate 14f 1 As in the case described in the first embodiment, a surface electrode may be provided between the two. In this case, an insulating film is provided between the surface electrode arrangement and the linear electrode. Moreover, you may interpose the film for an adhesive improvement etc. between a transparent substrate and an electrode.
As described above, according to the third embodiment, as in the first embodiment, switching between the imaging mode capable of obtaining the subject depth direction distance and the imaging mode of the high-resolution two-dimensional image is possible. It is possible to provide a liquid crystal optical device and a solid-state imaging device having a function capable of being performed.
In the liquid crystal optical devices according to the first to third embodiments, the optical characteristics of the lens state are the same as the liquid crystal optical device 14A according to the second embodiment, the liquid crystal optical device 14 according to the first embodiment, and the third embodiment. The liquid crystal optical devices 14B and 14C are improved in this order.
The optical characteristics when the liquid crystal optical device is in a non-lens state are better for the liquid crystal optical device 14A according to the second embodiment than for the liquid crystal optical devices 14B and 14C according to the third embodiment.
In terms of ease of manufacture, the liquid crystal optical device according to the second embodiment is better than the liquid crystal optical devices 14B and 14C according to the third embodiment.
For ease of driving, that is, circuit simplicity, the liquid crystal optical device according to the third embodiment is better than the liquid crystal optical device 14 according to the first embodiment.
A method for manufacturing the liquid crystal optical device described in the first to third embodiments will be described as a fourth embodiment with reference to FIGS. 20 (a) to 20 (l). In the manufacturing method of the fourth embodiment, the liquid crystal optical device 14 described in the first embodiment is manufactured.
First, a light transmitting substrate 14a 1, to form the mold portion 14a 2 on the substrate 14a 1 (FIG. 20 (a), 20 (b )). The mold part 14a 2 on the electrode 14a 3 is formed to complete the electrode portion 14a (FIG. 20 (c)). The sealant 80 is applied to the outer peripheral portion of the mold part 14a 2 (FIG. 20 (d)). On the other hand, a light transmissive substrate 14b 1 is prepared, and a surface electrode 14b 2 is formed on the substrate 14b 1 (FIGS. 20E and 20F). Subsequently, an insulating film 14b 3 on the surface electrode 14b 2 (FIG. 20 (g)). A wiring electrode 14b 4 is formed on the insulating film 14b 3 to complete the electrode portion 14b (FIG. 20H). Thereafter, the electrode portion 14b is turned over (FIG. 20 (i)) and bonded to the electrode 14a coated with the sealing agent 8- (FIG. 20 (j)). Subsequently, the liquid crystal layer 14c is sealed between the electrode portion 14a and the electrode portion 14b (FIG. 20 (k)). Thereafter, a polarizing plate is pasted on the substrate 14b1 of the electrode portion 14b to complete the liquid crystal optical device 14 (FIG. 20 (l)).
A portable information terminal according to the fifth embodiment is shown in FIG. The portable information terminal 200 according to the fifth embodiment includes the solid-state imaging device 1 according to the first to third embodiments. In FIG. 21, the imaging module unit 10 of the solid-state imaging device 1 is shown. Note that the portable information terminal illustrated in FIG. 21 is an example.
According to the fifth embodiment, it is possible to provide a portable information terminal having a function capable of switching between an imaging mode capable of obtaining a distance in the depth direction of a subject and an imaging mode of a high-resolution two-dimensional image. it can.
The liquid crystal optical device used in the portable information terminal of this embodiment can use any of the first to third embodiments.
A display device according to the sixth embodiment will be described with reference to FIG. FIG. 22 is a block diagram showing the display device of the sixth embodiment. The display device 300 according to the sixth embodiment is a display device that can switch between a two-dimensional image and a three-dimensional image, and includes a display panel 310, a drive circuit 320, and a liquid crystal optical device 330. I have.
The display panel 310 has a display screen in which pixels are arranged in a matrix. A direct-view or projection-type liquid crystal display panel, plasma display panel, field emission display panel, or organic EL display as long as the pixels whose positions are defined in the display screen are arranged in a matrix in a plane A panel etc. may be sufficient.
The driving circuit 320 drives the display panel 310, sends a video signal (display data) sent from the outside to the display panel 310, assigns the display data to the pixels of the display panel 310, and displays a two-dimensional image. Alternatively, the display panel 310 is driven so as to display a three-dimensional image. Note that the drive circuit 320 may be integrated with the display panel 310 or may be provided outside the display panel 310.
The liquid crystal optical device 330 is provided on the front surface of the display panel 310, and controls light rays from the pixels of the display panel 310 so that the focus is variable. The liquid crystal optical device 330 is, for example, any one of the liquid crystal optical devices 14, 14A, 14B, and 14C according to the first to third embodiments, and can be used by switching the function of moving light straight and the lens function. For example, when the display device displays a two-dimensional image, a function of moving a light beam straight is used, and when a three-dimensional image is displayed, a lens function is used. Switching between the function of moving the light beam straight and the lens function may be automatically performed by the drive circuit 340 based on the video signal input to the drive circuit 320, or the viewer may instruct the drive circuit 340 using the remote controller 350. A signal may be sent and the drive circuit 340 may perform based on this command signal. In this case, in the display device 300, when the video signal sent from the outside is a two-dimensional video signal, the depth information is estimated or detected from the two-dimensional video signal using a known technique, and the estimated or detected information is detected. It is preferable that the display panel 310 or the drive circuit 320 has a function of generating a 3D video signal using the depth information. The estimation or detection of depth information can be performed, for example, by obtaining a motion vector of an image and using this motion vector.
Further, as in the case of the first embodiment, a plurality of pixels (pixel blocks) corresponding to the number of parallaxes constituting a three-dimensional image are assigned to each lens of the liquid crystal optical device 330. When the liquid crystal optical device 330 that can be used by switching the function of moving the light straight and the lens function is used in a display device that can display a three-dimensional image, the display can be performed without reducing the resolution when the two-dimensional image is displayed. can do.
According to the sixth embodiment, it is possible to provide a display device having a function capable of switching between a three-dimensional image display mode and a high-resolution two-dimensional image display mode.
A solid-state imaging device according to the seventh embodiment will be described with reference to FIGS. The solid-state imaging device of the seventh embodiment is different from the solid-state imaging device of the third embodiment in the liquid crystal optical device. A specific example of the liquid crystal optical device 14D used in the solid-state imaging device of the seventh embodiment is shown in FIGS. 24 and 25 respectively correspond to the cross-sectional views shown in FIGS. 15 and 16 of the liquid crystal optical device 14 described in the third embodiment. 24 is a cross-sectional view taken along the cutting line AA shown in FIG. 25, and FIG. 25 is a cross-sectional view taken along the cutting line BB shown in FIG.
A liquid crystal optical device 14D as a specific example according to the seventh embodiment has a configuration in which the electrode portion 14g of the liquid crystal optical device 14B of the third embodiment shown in FIGS. 15 and 16 is replaced with an electrode portion 14ga. Electrode portion 14Ga has a configuration obtained by replacing the substrate 14g 1 of the light-transmitting electrode portion 14g to the polarization rotation plate 14ga 1.
A liquid crystal optical device 14D as a specific example according to the seventh embodiment is used in, for example, a solid-state imaging device shown in FIG. In this solid-state imaging device, an image from the subject is formed by the main lens 12, and this image is re-imaged on the imaging device 16 by the liquid crystal optical device 14D. That is, the image light beam formed by the main lens 12 becomes, for example, linearly polarized light by the polarizing plate 14d. In the first lens composed of the electrode portion 14h, the liquid crystal layer 14c 2 , and the surface electrode 14g 3 , a polarizing plate 14d is disposed so as to have a polarization axis in the depth direction on the drawing, and the long axis of the liquid crystal molecule at the polarization incident side interface. The liquid crystal layer 14c 2 is disposed so that the initial alignment direction is also substantially the depth direction, the electrode portion 14h is disposed so that the electrode extends in the horizontal direction, that is, the direction orthogonal to the depth direction, and the electrode portion 14h (electrode 14h) 21 , 14 h 22 ) and the surface electrode 14 g 3 . For this reason, the linearly polarized light that has passed through the polarizing plate 14d is condensed in the depth direction on the drawing by the first lens. The polarization axis of the light focused on the depth direction is rotated rotated on the drawing in the horizontal direction by the polarizing plate 14ga 1, i.e. in a direction perpendicular to the depth direction. Electrodes 14 g 21, 14 g 22, the liquid crystal layer 14c 1, and a second lens made of the electrode portion 14f, the polarization is incident from the rotating polarizer 14Ga 1 having a polarization axis in the horizontal direction in the drawing, the liquid crystal in polarized incident side interface The liquid crystal layer 14c 1 is arranged so that the initial alignment direction of the molecular long axis is also substantially horizontal, and the electrodes 14g 21 , 14g 22 are arranged so that the electrodes extend in the depth direction, and the electrodes 14g 21 , 14g 22 , A voltage is applied to the electrode portion 14f. For this reason, the light whose polarization axis is rotated by the rotating polarizing plate 14ga 1 is condensed in the horizontal direction by the second lens. Thereby, high-contrast point condensing can be performed.
Further, in the liquid crystal optical device 14B of one specific example of the third embodiment shown in FIGS. 15 and 16, for example, a first lens and electrodes 14g 21 and 14g each including an electrode portion 14h, a liquid crystal layer 14c 2 , and a surface electrode 14g 3 are used. 22, the liquid crystal layer 14c 1, and similarly when the voltage so that the liquid crystal layer in the one of the lenses is the twisted alignment of the second lens made of the electrode portion 14f is applied, by performing the point focusing of the high-contrast (See FIG. 27). In this case, the polarization axis of the polarizer 14d, and the arrangement direction of the initial alignment direction and the electrode portions 14h of the liquid crystal molecular long axis in the polarization incidence side interface of the liquid crystal layer 14c 2, are arranged to be substantially parallel. These azimuth axes are arranged so that the initial alignment direction of the major axis of the liquid crystal molecule at the polarization incident side interface of the liquid crystal layer 14c 1 and the arrangement direction of the electrode portion electrodes 14g 21 and 14g 22 are substantially orthogonal.
FIG. 28 is a diagram illustrating a characteristic plot of a refractive index distribution generated when a voltage is applied to the liquid crystal optical device according to the present embodiment. The distribution of lens unit sections having two types of liquid crystal alignment is shown. When the parallel alignment mode in which the dotted line is generally used is adopted, the solid line is twisted and the alignment mode is adopted. On the horizontal axis of the plot, 0 corresponds to the center of the lens section, and ± 0.5 corresponds to the left and right lens ends. The vertical axis of the plot is the relative refractive index normalized by the value when no voltage is applied.
As shown in FIG. 28, the outlines of the curves of the solid line and the dotted line are almost the same, and the refractive index modulation amount (the amount of decrease at the end) in the lens section is also at the same level. Accordingly, even when the twisted array mode is used instead of the parallel array mode, an equivalent light collecting effect can be obtained. It is known that the local increase in refractive index seen in the region at the plot end (near the vertical axis 0.5) is a phenomenon caused by the occurrence of alignment defects. This alignment defect is caused by the collision between the spontaneous rising direction of the liquid crystal molecules determined by the liquid crystal alignment processing direction on the substrate surface and the tilting direction of the inclined electric field generated from the edge of the striped electrode when a voltage is applied. This occurs because the molecular rotation effect induced by the factor antagonizes. Since the desired lens effect does not appear in the local refractive index increase region, it is desirable that the generation region is narrow. Although the generation position is different between the solid line and the dotted line, the region length is about the same. Thus, even when the twisted arrangement mode is used instead of the parallel arrangement mode, the influence on the lens characteristics can be kept to the same extent.
In the liquid crystal optical device 14D according to the seventh embodiment constructed in this manner, the surface electrodes 14f 3 and a plurality of electrodes 14 g 2 is, in the cross section shown in FIG. 25, to function the liquid crystal layer 14c 1 as a liquid crystal GRIN lens. The surface electrode 14 g 3 and a plurality of electrodes 14h 2 is, in the cross section shown in FIG. 24, to function liquid crystal layer 14c 2 as liquid crystal GRIN lens. Accordingly, the liquid crystal optical device 14D according to the seventh embodiment can switch between a lens state and a non-lens state depending on whether or not a voltage is applied. By using the liquid crystal optical device 14D according to the seventh embodiment, it is possible to improve the imaging performance of the liquid crystal optical device when a voltage is applied.
The liquid crystal optical device according to the seventh embodiment can also be used for the portable information terminal shown in FIG. 21 and the display device shown in FIG. 22, for example, similarly to the liquid crystal optical devices of the first to third embodiments.
1 Solid-state imaging device (camera module)
DESCRIPTION OF SYMBOLS 10 Image pick-up module part 12 Imaging optical system 14 Liquid crystal optical apparatus 14A Liquid crystal optical apparatus 14B Liquid crystal optical apparatus 14C Liquid crystal optical apparatus 14a Electrode part 14a 1 light-transmitting board | substrate 14a 2 type | mold frame part 14a 3 electrode 14b Electrode part 14b 1 light transmissive 14b Two- sided electrode 14b 3 Insulating film 14b 4 Wiring electrode 14b 41 Wiring electrode 14b 42 Wiring electrode 14c Liquid crystal layer 14c 1 Liquid crystal layer 14c 2 Liquid crystal layer 14d Polarizing plate 14e Electrode part 14e 1 Light transmission 14e 2 side electrode 14e 3 insulating film 14e 4 wiring electrode 14f electrode portion 14f 1 light transmitting substrate 14f 2 wiring electrode 14f 21 wiring electrode 14f 22 wiring electrode 14f 3 surface electrode 14g Electrode part 14g 1 Light-transmitting substrate 14g 2 Wiring electrode 14g 21 Wiring electrode 14g 22 Wiring electrode 14g 3- sided electrode 14g 4- sided electrode 14h Electrode part 14h 1 Light-transmitting substrate 14h 2 Wiring-like electrode 14h 21 Wiring-like electrode 14h 22 Wiring-like electrode 16 Imaging element 16a Semiconductor substrate 16b Pixel 16c Color filter 16d Micro lens 18 Drive circuit 20 Imaging signal processor (ISP)
DESCRIPTION OF SYMBOLS 22 Camera module interface 24 Image acquisition part 26 Signal processing part 28 Driver interface 40 Liquid crystal optical apparatus holder 42 Spacer 44 Electrode pad 44a Electrode pad 44b Electrode pad 46 Through electrode 48 Bump 50 Chip 52 Light shielding cover 54 Module electrode 62 Lens barrel 64 Lens holder 200 Portable information terminal 300 Display device 310 Display panel 320 Drive circuit 330 Liquid crystal optical device 340 Drive circuit 350 Remote controller
A light transmissive first substrate having a first surface; a light transmissive layer provided on the first substrate; and a light transmissive first electrode provided on the light transmissive layer. The light transmission layer is arranged along a first direction parallel to the first surface on a surface facing the electrode film, and has a first electrode portion having a recess extending in a second direction intersecting the first direction; ,
A light transmissive second substrate having a second surface facing the first substrate through the first electrode portion; and a first substrate disposed on the second surface of the second substrate and arranged in the second direction. A second electrode portion having two second electrodes extending along a direction;
A liquid crystal layer sandwiched between the first electrode portion and the second electrode portion;
A first polarizing plate facing the liquid crystal layer via the second electrode portion;
A driving unit for applying a voltage to the first electrode and the second electrode;
A liquid crystal optical device comprising:
The second electrode portion includes a light-transmitting surface electrode provided between the second substrate and the second electrode, and a light-transmitting surface electrode provided between the surface electrode and the plurality of electrodes. An insulating film;
The liquid crystal optical device according to claim 1, wherein the second electrode overlaps a part of the surface electrode.
The second electrode part further includes a third electrode provided between the two second electrodes,
The liquid crystal optical device according to claim 1, wherein the driving unit applies different voltages to the second electrode and the third electrode.
A light-transmissive first substrate having a first surface; and a first substrate disposed on the first surface of the first substrate and arranged along a first direction parallel to the first surface and intersecting the first direction. A first electrode portion having two first electrodes extending in two directions;
A light-transmissive second substrate facing the first surface through the first electrode, and arranged on the second surface of the second substrate and arranged along the second direction in the first direction A second electrode portion having two second electrodes extending;
The first electrode portion is provided between a light-transmitting first surface electrode provided between the first substrate and the first electrode, and between the first surface electrode and the plurality of first electrodes. A light-transmitting first insulating film,
The liquid crystal optical device according to claim 4, wherein the first electrode overlaps a part of the first surface electrode.
The second electrode portion includes a light transmissive second surface electrode provided between the second substrate and the plurality of second electrodes, and between the second surface electrode and the plurality of second electrodes. The liquid crystal optical device according to claim 4, further comprising a light-transmissive second insulating film provided on the liquid crystal.
The first electrode portion further includes a third electrode provided between the first electrodes,
The liquid crystal optical device according to claim 4, wherein the driving unit applies different voltages to the second electrode and the third electrode.
The second electrode portion further includes a fourth electrode provided between the second electrodes,
A first electrode portion having a first surface and a light-transmitting first substrate; and a first surface electrode provided on the first surface of the first substrate;
A light-transmissive second substrate having a second surface opposite to the first surface, and a second direction provided on the second surface and arranged along the first direction and intersecting the first direction A second electrode portion having two first electrodes extending in parallel and a second surface electrode facing the first electrode through the second substrate,
A first liquid crystal layer sandwiched between the first electrode portion and the second electrode portion;
A third substrate having a third surface opposite to the second surface and transmitting light; and arranged on the third surface of the third substrate along the second direction and extending in the first direction. A third electrode portion having two existing third electrodes;
A second liquid crystal layer sandwiched between the second electrode portion and the third electrode portion;
A first polarizing plate facing the second liquid crystal layer via the third electrode portion;
A rotating polarizing plate having a third surface facing the second surface; and two second polarizing plates provided on the third surface of the rotating polarizing plate and arranged in the second direction and extending in the first direction. A third electrode portion having three electrodes;
The liquid crystal optical device according to claim 1, wherein the second electrode portion is thinner than the first electrode portion.
An imaging optical system capable of imaging a subject on an imaging plane;
An imaging element facing the imaging optical system;
The liquid crystal optical device according to any one of claims 1 to 11, provided between the coupling optical system and the imaging device,
A portable information terminal comprising the solid-state imaging device according to claim 12.
A display panel having a display screen in which pixels are arranged in a matrix;
Driving the display panel, sending display data to the display panel, allocating the display data to the pixels of the display panel, driving the display panel to display a two-dimensional image or to display a three-dimensional image Circuit,
The liquid crystal optical device according to claim 1, which faces the display panel.
JP2013227338A 2013-03-22 2013-10-31 Liquid crystal optical device, solid-state imaging device, portable information terminal, and display unit Pending JP2014209170A (en)
US14/206,365 US9781311B2 (en) 2013-03-22 2014-03-12 Liquid crystal optical device, solid state imaging device, portable information terminal, and display device
JP2014209170A true JP2014209170A (en) 2014-11-06
JP2013227338A Pending JP2014209170A (en) 2013-03-22 2013-10-31 Liquid crystal optical device, solid-state imaging device, portable information terminal, and display unit
US10453888B2 (en) 2017-03-30 2019-10-22 Canon Kabushiki Kaisha Semiconductor apparatus and equipment having laminated layers
JP4052803B2 (en) 2001-01-19 2008-02-27 株式会社リコー Image display device
DE602007005151D1 (en) * 2006-08-24 2010-04-15 Koninkl Philips Electronics Nv Crunge reduction for a switchable liquid crystal lens array
BRPI1009721A2 (en) * 2009-06-26 2016-08-23 Koninkl Philips Electronics Nv switchable auto stereoscopic display device and control method of a auto stereoscopic display device
CN103733129A (en) 2011-09-16 2014-04-16 株式会社东芝 Gradient index liquid crystal optical element and image display device
2013-10-31 JP JP2013227338A patent/JP2014209170A/en active Pending
2014-03-12 US US14/206,365 patent/US9781311B2/en active Active
US9781311B2 (en) 2017-10-03
US20140285703A1 (en) 2014-09-25
US10425632B2 (en) 2019-09-24 Imaging apparatus and image sensor array
JP4901870B2 (en) 2012-03-21 Camera device, liquid lens, and imaging method
TWI544779B (en) 2016-08-01 Three dimensional image capture device
US9389454B2 (en) 2016-07-12 Liquid crystal lens, method of driving liquid crystal lens, lens unit, camera module, and capsule type medical device
JP2015528234A (en) 2015-09-24 Display device imitating holographic 3D scene and visual display method
US10247866B2 (en) 2019-04-02 Imaging device