JP2009192931A - Display device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device that suppresses deterioration in picture quality due to an aberration of an image displayed on a display medium. <P>SOLUTION: The display device 10 is provided with a vari-focus lens 46 and a driving section 48 which drives the vari-focus lens 46 between a light irradiation section 42 and the display medium 11, and write light 50 with which the display medium 11 is irradiated from a light source 43 of the light irradiation section 42 is adjusted under the control of a control section 38 to be focused on one of a plurality of a photoconducting layer 22A, a photoconducting layer 22B, and a photoconducting layer 22C of the display medium 11. Consequently, deterioration in picture quality due to an aberration of an image displayed on the display medium 11 can be suppressed. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a display device.

  In recent years, with the spread of personal computers and the development of the information society such as the Internet, the consumption of paper as so-called short-lived documents for the purpose of temporary browsing of electronic information has been increasing. Realization of a rewritable display medium instead of paper is desired for reasons such as conservation of the global environment such as resource protection and improvement of the office environment.

  Therefore, cholesteric liquid crystal is used as a display medium instead of paper that has memory characteristics without power supply and can be rewritten in a short time by an external device, and free by internal photoelectric effect by light irradiation under an electric field. A display medium using a photoconductor that generates electron movement has been proposed (see, for example, Patent Document 1).

  In Patent Document 1, as a display medium in which a photoconductive layer and a display layer are combined, a photoconductive layer and a display layer are stacked between electrodes formed on a pair of substrates such as a film. A plurality of such display elements are stacked. In this display medium, writing to the display layer of the display medium is performed by irradiating the photoconductive layer with writing light, and an image written on the display layer is read by irradiating the display layer with reading light. It is done.

  The plurality of photoconductive layers have a characteristic of absorbing light in a specific wavelength region, and the resistance value changes when irradiated with light in the wavelength region within the light absorption region of each photoconductive layer. have. Here, when a voltage is applied between a pair of electrodes provided so as to sandwich a display layer that develops a target color, each of the display layer and the photoconductive layer provided between the electrodes A partial pressure is applied. With this partial pressure applied, light in the wavelength region of the light absorption wavelength region of the photoconductive layer is irradiated as writing light, so that the light irradiated by the photoconductive layer is absorbed and writing is performed. The resistance distribution of the photoconductive layer changes according to light. Thus, by irradiating the writing light in the wavelength region of the light absorption wavelength region of the target photoconductive layer, the partial pressure applied to the display layer provided between the same electrodes as this photoconductive layer is reduced. Change. When the voltage distribution applied to the display layer changes, the orientation distribution of the liquid crystal changes and the optical characteristic distribution changes, so that an image corresponding to the irradiated writing light is recorded on the display layer.

  According to the technique of Patent Document 1, in order to irradiate the display medium with light in the wavelength region within the light absorption wavelength region of each photoconductive layer having a specific light absorption wavelength region, the light absorption wavelength region of each photoconductive layer The display medium is irradiated with light having a wavelength of.

Here, the light irradiated to the display medium often has a diffusivity, so that it may be difficult to expose the optical pattern of the image displayed on the display medium on the photoconductive layer, resulting in a decrease in resolution. Because of concern, the technique of Patent Document 2 uses a two-dimensional lens array that forms a two-dimensional image at a predetermined position on one photoconductive layer of a display medium including one display element. The optical pattern of the image is exposed. According to the technique of Patent Document 2, the light transmitted through the two-dimensional lens array is condensed on one photoconductive layer of the display element, and an optical pattern is formed on one photoconductive layer.
JP 2007-033677 A JP 2002-318348 A

  It is an object of the present invention to provide a display device that displays an image on a display medium having a plurality of photoconductive layers, in which image quality deterioration caused by aberration of the image displayed on the display medium is suppressed. .

  The above-mentioned subject is achieved by the following present invention. That is,

  The invention according to claim 1 is a photoconductivity provided between a pair of electrodes and a pair of electrodes and exhibiting an electrical characteristic distribution according to the intensity distribution of the light by absorbing light in a predetermined wavelength region. And a display layer that displays an image based on an optical characteristic distribution according to the partial pressure applied to the layer and a voltage distribution according to the electrical characteristic distribution of the photoconductive layer due to a voltage applied to the pair of electrodes A plurality of display elements including a plurality of display elements, and each of the photoconductive layers included in the plurality of display elements is included in each of the plurality of display elements with respect to a display medium that absorbs light in a specific wavelength region. A first voltage applying means for applying a voltage to the pair of electrodes; a light source for irradiating the display medium with light in a wavelength region including an absorption wavelength region of the plurality of photoconductive layers; the light source and the display medium; Light emitted from the light source provided between , A variable focus lens that changes the focus of the incident light according to the applied voltage, a second voltage applying unit that applies a voltage to the variable focus lens, and a plurality of display elements. The first voltage applying means is controlled to apply a voltage to the pair of electrodes included in at least one, and the photoconductive layer of the display element to which the voltage is applied is irradiated from the light source based on image data. And a control means for controlling the second voltage application means so that the focused light is focused and for controlling the light source so that the light of the intensity based on the image data is irradiated. is there.

  According to the first aspect of the present invention, the image quality deterioration due to the aberration of the image displayed on the display medium is suppressed as compared with the case where the variable focus lens according to the present invention is not provided. Play.

  An embodiment of a display device and a writing method of the present invention will be described with reference to the drawings.

  As shown in FIG. 1, the display device 10 according to the present embodiment is a device that writes an image to be displayed on the display medium 11 to the display medium 11.

  The display medium 11 is configured by laminating a plurality of display elements 30 between a substrate 12 and a substrate 18 via a substrate 14 and a substrate 16. In the present embodiment, a case will be described in which the display medium 11 is configured by stacking three layers of display elements (a display element 30A, a display element 30B, and a display element 30C) as the plurality of display elements 30. However, the number of display elements to be stacked is not limited to three layers, and two layers or four or more layers may be stacked.

  The display element 30A is configured by laminating a photoconductive layer 22A and a display layer 20A between an electrode 18A and an electrode 19A. The display element 30B is configured by laminating a photoconductive layer 22B and a display layer 20B between an electrode 18B and an electrode 19B. The display element 30C is configured by laminating a photoconductive layer 22C and a display layer 20C between an electrode 18C and an electrode 19C.

  In the present embodiment, each display element 30A, display element 30B, and display element 30C is provided with one display layer (display layer 20A, display layer 20B, and display layer 20C). However, a configuration in which two display layers are provided or a configuration in which three or more display layers are provided may be used.

  The display device 10 corresponds to the display device of the present invention, and the display medium 11 corresponds to the display medium in the display device of the present invention. The photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C correspond to the photoconductive layer of the display medium in the display device of the present invention, and the display layer 20A, the display layer 20B, and the display layer 20C are the present invention. Corresponds to the display layer of the display device. The electrode 18A and the electrode 19A, the electrode 18B and the electrode 19B, and the electrode 18C and the electrode 19C correspond to a pair of electrodes of the display medium in the display device of the present invention. Corresponds to means.

Each of the substrate 12, the substrate 14, the substrate 16, and the substrate 18 has an insulating property (volume resistance of 10 ¹² Ωcm or more, hereinafter the same). In addition, each of the substrate 12, the substrate 14, the substrate 16, and the substrate 18 is transparent. In the present embodiment, the term “transparent” refers to the property of transmitting 80% or more of light having a wavelength of 380 nm to 780 nm.

  Each of these substrates 12, 14, 16, and 18 is provided with a known functional film such as a liquid crystal alignment layer, a wear-resistant layer, or a barrier layer for preventing gas contamination on the surface as necessary. It may be formed.

  The substrate 12, the substrate 15, the substrate 16, and the substrate 18 are configured using an inorganic sheet such as glass and silicon, or a polymer film such as polyethylene terephthalate, polysulfone, polyethersulfone, polycarbonate, and polyethylene naphthalate. The thicknesses of the substrate 12, the substrate 14, the substrate 16, and the substrate 18 are preferably in the range of 0.01 mm to 0.5 mm.

  Each of the electrode 18A and the electrode 19A, the electrode 18B and the electrode 19B, and the electrode 18C and the electrode 19C is configured as a so-called solid electrode provided so as to cover the surface direction of each substrate. In the present embodiment, the case where each of the electrode 18A and the electrode 19A, the electrode 18B and the electrode 19B, and the electrode 18C and the electrode 19C is configured as a solid electrode will be described. However, the structure is a partially divided structure. May be.

  The electrode 18A, the electrode 19A, the electrode 18B, the electrode 19B, the electrode 18C, and the electrode 19C have conductivity (volume resistance of 2000 Ωcm or less, hereinafter the same applies) and also have translucency.

ITO (Indium Tin Oxide) is used for the electrodes 18A, 19A, 18B, 19B, 18C, and 19C. Note that in this embodiment, the case where ITO is used for the electrode 18A, the electrode 19A, the electrode 18B, the electrode 19B, the electrode 18C, and the electrode 19C will be described, but besides ITO, a metal film such as Au, SnO ₂ , An electric conductor such as an oxide such as ZnO or a film of a conductive polymer such as polypyrrole is used. Further, the electrode 18A of this embodiment is sputtered on the substrate 12, the electrode 19A and the electrode 18B are sputtered on both surfaces of the substrate 14, the electrode 19B and the electrode 18C are sputtered on both surfaces of the substrate 16, respectively, Although described as being formed by sputtering on the substrate 18, it is not necessarily required by sputtering, and may be formed by printing, CVD, vapor deposition, or the like.

  The photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C have a specific absorption wavelength region with respect to the irradiated light, and are irradiated with light in the wavelength region of the absorption wavelength region under an electric field. Then, free electrons move due to the internal photoelectric effect, and the resistance value decreases according to the light intensity. The light absorption wavelength regions of these photoconductive layer 22A, photoconductive layer 22B, and photoconductive layer 22C may be J or the same.

  The photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C include: (a) a layer composed of an amorphous semiconductor, a compound semiconductor such as ZnSe, CdS, or the like (b) an organic semiconductor material; As a semiconductor material, a layer composed of anthracene, polyvinyl carbazole, etc., (c) a layer composed of a mixture of a charge generation material that generates charge by light irradiation and a charge transport material that generates charge transfer by an electric field, or a laminate. Can be mentioned.

The photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C are made of inorganic photoconductors such as a-Si: H, a-Se, Te-Se, As ₂ Se ₃ , CdSe, and CdS, or azo pigments, It is composed of an organic photoconductor obtained by combining a charge generation material such as a phthalocyanine pigment, a perylene pigment, a quinacridone pigment, a pyrrolopyrrole pigment, and an indigo pigment and a charge transport material such as arylamine, hydrazone, triphenylmethane, and PVK.

  Here, the photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C have the internal photoelectric effect as described above, and the resistance value changes according to the intensity of the irradiated light. It is possible to drive and it is preferable to drive the target with respect to the irradiated light. From this viewpoint, the photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C are not shown, A three-layer structure in which a pair of charge generation layers (CGL) and a charge generation layer are stacked so as to sandwich the charge transport layer (CTL) from above and below is preferable.

These charge generation layers are layers having a function of generating free electrons by absorbing writing light (detailed later) irradiated from the display device 10 for writing.
Each charge generation layer has a wavelength included in writing light to be described later, and is the same as the charge generation layer of another photoconductive layer (photoconductive layer 22A, photoconductive layer 22B, or photoconductive layer 22C). Excitons may be generated by absorbing light of a specific wavelength, or they may be different from each other. Further, those that can be efficiently separated into free electrons inside the charge generation layer or at the interface with the charge transport layer are preferable.

  Examples of the charge generation material constituting each of the charge generation layers include perylene-based, phthalocyanine-based, bisazo-based, dithiopytochelopyrrole-based, squarylium-based, azurenium-based, and thiapyrylium / polycarbonate-based compounds.

Examples of the charge transport material constituting the charge transport layer include trinitrofluorene-based, polyvinylcarbazole-based, oxadiazole-based, pyralizone-based, hydrazone-based, stilbene-based, triphenylamine-based, triphenylmethane-based, and diamine-based materials. A compound, polyvinyl alcohol to which LiClO ₄ is added, polyethylene oxide, or the like is used, and a laminate, a mixture, a microcapsule, or the like is used as a composite of a charge generation material and a charge transport material.

  The thicknesses of the photoconductive layer 22A, photoconductive layer 22B, and photoconductive layer 22C are used in the range of 1 μm to 100 μm, and the resistance ratio when writing light is irradiated and when writing light is not irradiated is larger. Is desirable.

  Each of the display layer 20A, the display layer 20B, and the display layer 20C has a function of modulating the selective reflection and transmission state of light of a specific color by an electric field, and has a property that the selected state is maintained without an electric field. It is. When the display layer 20A, the display layer 20B, and the display layer 20C are in a selective reflection state of light of a specific color by an electric field, light of different colors is selectively reflected from incident light. Note that each of the display layer 20A, the display layer 20B, and the display layer 20C preferably has a structure that is not deformed by an external force such as bending or pressure.

  Note that in the case where a plurality of display layers are provided in the same display element, modulation from a transmission state to a selective reflection state occurs by applying different electric fields, that is, voltages having different values. What is necessary is just to comprise. For example, in the case where the display layer 20A and the display layer 20B are provided in the same display element, modulation from the transmission state to the selective reflection state occurs when voltages different from each other are applied, and the hue is changed. What is necessary is just to adjust beforehand so that it may change.

  Each of the display layer 20A, the display layer 20B, and the display layer 20C has a PDLC (Polymer Network Liquid Crystal) structure in which chiral nematic liquid crystal (cholesteric liquid crystal) is dispersed in a gelatin binder (polymer matrix). Note that in this embodiment, the case where each of the display layer 20A, the display layer 20B, and the display layer 20C adopts a PDLC structure is described. However, the cholesteric liquid crystal is not limited to this structure and the interelectrode distance is interposed via a rib. This may be realized by arranging the liquid crystal in a fixed cell or using a capsule liquid crystal. Further, the liquid crystal is not limited to the cholesteric liquid crystal, but a smectic A liquid crystal, a nematic liquid crystal, a discotic liquid crystal, or the like is used.

  The selective reflection wavelength regions (display color wavelength regions) of the display layer 20A, the display layer 20B, and the display layer 20C are different from each other when they are in the selective reflection state of light. For example, the display layer 20A is composed of cholesteric liquid crystal that selectively reflects B (blue) light, the display layer 20B is composed of cholesteric liquid crystal that selectively reflects G (green) light, and the display layer 20C is , R (red) color cholesteric liquid crystal that selectively reflects.

For example, when a cholesteric liquid crystal is used as the liquid crystal, the reflection wavelength region (display color wavelength region) of each of the display layer 20A, the display layer 20B, and the display layer 20C is adjusted by the helical pitch of the cholesteric liquid crystal. The helical pitch of the cholesteric liquid crystal is adjusted by the amount of chiral agent added to the nematic liquid crystal. Further, in order to compensate the temperature dependence of the helical pitch of the cholesteric liquid crystal, a known method of adding a plurality of chiral agents having different twisting directions or opposite temperature dependences may be used.
In addition, as an auxiliary member that assists in changing the optical characteristics of the liquid crystal, it may be used in combination with passive optical components such as a polarizing plate, a retardation plate, and a reflection plate, or a dichroic dye may be added to the liquid crystal.

  In addition, it is desirable to use each display layer 20A, the display layer 20B, and the display layer 20C in a range of usually 1 μm or more and 100 μm or less.

  Examples of the liquid crystal material included in each of the display layer 20A, the display layer 20B, and the display layer 20C include cyanobiphenyl, phenylcyclohexyl, phenylbenzoate, cyclohexylbenzoate, azomethine, azobenzene, pyrimidine, dioxane, and cyclohexyl. Known liquid crystal compositions such as cyclohexane, stilbene, and tolan are used. Additives such as pigments and particles such as dichroic pigments and particles may be added to the liquid crystal material, and may be dispersed in a polymer matrix, polymerized, or microencapsulated. The liquid crystal may be a polymer, medium molecule, or low molecule, or a mixture thereof.

  The substrate 18 and the electrode 19C are materials that also transmit light including the light absorption wavelength of the photoconductive layer 22C, the photoconductive layer 22B, and the photoconductive layer 22C, which is irradiated from a light irradiation unit (details will be described later). It is comprised by. In addition, the electrode 18C, the substrate 16, and the electrode 19B are made of a material that also transmits light including a light absorption wavelength of the photoconductive layer 22B and the photoconductive layer 22A, which is irradiated from a light irradiation unit (described in detail later). Has been. Furthermore, the electrode 18B, the substrate 14, and the electrode 19A are made of a material that also transmits light including a wavelength of the light absorption wavelength of the photoconductive layer 22A, which is irradiated from a light irradiation unit (described later in detail).

  Next, the display device 10 for writing an image on the display medium 11 will be described.

  As illustrated in FIG. 1, the display device 10 includes a light irradiation unit 42, a control unit 38, a voltage application unit 40, and a focus adjustment unit 44. The light irradiation unit 42, the voltage application unit 40, and the focus adjustment unit 44 are connected to the control unit 38 so as to be able to exchange signals.

  The light irradiation unit 42 is provided such that a plurality of light sources 43 can irradiate light at positions corresponding to the respective pixels of the image displayed on the display medium 11. The focus adjustment unit 44 is provided between the light irradiation unit 42 and the display medium 11, and the plurality of variable focus lenses 46 and the drive unit 48 correspond to each of the plurality of light sources 43 provided in the light irradiation unit 42. Is provided.

  The plurality of light sources 43 of the light irradiation unit 42 correspond to the light source of the display device of the present invention, and the variable focus lens 46 provided in the focus adjustment unit 44 corresponds to the variable focus lens of the display device of the present invention. The drive unit 48 provided in the focus adjustment unit 44 corresponds to the second voltage application unit of the display device of the present invention, and the control unit 38 corresponds to the control unit of the display device of the present invention.

  The control unit 38 is configured as a microcomputer including a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory), and controls each unit in the display device 10.

  The voltage application unit 40 includes a voltage application unit 40A, a voltage application unit 40B, and a voltage application unit 40C. The voltage application unit 40A is connected to the electrodes 18A and 19A of the display element 30A of the display medium 11 so as to transmit and receive signals, and applies a voltage to the electrodes 18A and 19A. The voltage application unit 40B is connected to the electrodes 18B and 19B of the display element 30B of the display medium 11 so as to transmit and receive signals, and applies a voltage to the electrodes 18B and 19B. The voltage application unit 40C is connected to the electrodes 18C and 19C of the display element 30C of the display medium 11 so as to transmit and receive signals, and applies a voltage to the electrodes 18C and 19C.

The display device 10 is provided with a slot (not shown) for mounting the display medium 11, and is provided in the slot (not shown) by mounting the display medium 11 in this slot (not shown). The electrode 18A and the electrode 19A of the display medium 11 are electrically connected to the voltage applying unit 40A via the connector (not shown) or the like, and the electrode 18B and the electrode 19B are electrically connected to the voltage applying unit 40B. The eleventh electrode 18C and the electrode 19C are configured to be electrically connected to the voltage application unit 40C.
When the display medium 11 is installed in a slot (not shown) of the display device 10, the light irradiation unit 42 can irradiate the writing light 50 from the substrate 18 side to the substrate 12 side of the display medium 11. It becomes.

  The voltage application unit 40 outputs a voltage having a voltage value based on the signal input from the control unit 38, the voltage application time based on the signal, the voltage application unit 40A, the voltage application unit 40B, and the voltage application unit 40B to each electrode ( The electrode 18A and the electrode 19A, the electrode 18B and the electrode 19B, or the electrode 18C and the electrode 19C) may be selectively applied. However, from the viewpoint of performing faster speed display, AC output is possible and It is preferable to have a high slew rate. For example, a bipolar high voltage amplifier is used as the voltage application unit 40.

  The light irradiation unit 42 includes a plurality of light sources 43 that irradiate the writing light 50 toward a plurality of photoconductive layers (the photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C) in the display medium 11. It is configured. In the present embodiment, the plurality of light sources 43 are described as one type of light source that emits light of the same wavelength region as the writing light 50. These light sources 43 are configured to be able to adjust the intensity of light emitted under the control of the control unit 38.

  In the present embodiment, it is assumed that the plurality of light sources 43 are provided corresponding to each pixel of the image when the image is displayed on the display medium 11.

  Here, in the present embodiment, as described above, the wavelength region of the light emitted from the light source 43 is all of the plurality of photoconductive layers included in the display medium 11 (the photoconductive layer 22A, the photoconductive layer 22B, and The light absorption wavelength region of the photoconductive layer 22C) is included. As used herein, “including the light absorption wavelength region of the photoconductive layer” does not mean that all the wavelength regions that the photoconductive layer absorbs must be comprehensively included, but the photoconductive layer absorbs it. It indicates that it is sufficient to include at least part of light in the wavelength region. In other words, as long as the photoconductive layer contains light in the wavelength region necessary for forming the electrical characteristic distribution, it is not always necessary to include light in the entire absorption wavelength region. For example, the wavelength of light emitted from each light source 43 preferably includes a wavelength region corresponding to the maximum absorption intensity of each of the photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C.

  As the light source 43, for example, a fluorescent lamp, a halogen lamp, a xenon lamp, a mercury lamp, an LED, an inorganic EL, an organic EL, a laser, or the like is used.

  When an LED is used as the light source 43, luminance unevenness due to the light source is suppressed and the distance between the display medium 11 and the display device 10 can be shortened as compared with the case where the present technology is not used. Can be made thinner.

  The focus adjustment unit 44 controls the control unit 38 to control the writing light emitted from the light irradiation unit 42 to the display medium 11, the plurality of photoconductive layers 22 </ b> A, the photoconductive layer 22 </ b> B, and the photoconductive layer of the display medium 11. The focus is adjusted to focus on any of 22C.

  The focus adjustment unit 44 is provided between the light irradiation unit 42 and the display medium 11, and the plurality of variable focus lenses 46 and the drive unit 48 correspond to each of the plurality of light sources 43 provided in the light irradiation unit 42. Is provided. The drive unit 48 is connected to the control unit 38 so as to be able to send and receive signals, and applies a voltage to the variable focus lens 46 under the control of the control unit 38.

  In the present embodiment, a plurality of light sources 43, a plurality of variable focus lenses 46, and a plurality of driving units 48 are provided corresponding to each pixel of the image when the image is displayed on the display medium 11. A description will be given assuming that each is provided.

The variable focus lens 46 receives the writing light 50 emitted from the light source 43. The writing light 50 incident on the variable focus lens 46 is irradiated from the substrate 18 side of the display medium 11 toward the substrate 12 side.
The variable focus lens 46 is configured such that the lens shape changes according to the voltage value of the voltage applied from the drive unit 48. Therefore, the writing light 50 emitted from the light source 43 corresponds to the voltage value of the voltage applied from the driving unit 48 in the thickness direction of the display medium 11 (the direction from the substrate 18 side to the substrate 12 side). Focus on the desired position.

  The variable focus lens 46 may be of any configuration as long as the focus of incident light can be adjusted. For example, the variable focus lens 46 has an elasticity inside a lens formed of a transparent rubber film. A liquid crystal layer in which the orientation can be freely adjusted by changing the shape from a convex lens to a concave lens by injecting or draining liquid into the lens, or a liquid crystal layer in which the alignment state changes depending on the voltage between a pair of electrodes, one of which has a hole. A liquid crystal lens that adjusts the focal position by applying a voltage between the electrodes, a liquid-filled variable-focus lens that adjusts the focal position when one or both lens surfaces change due to a change in fluid pressure, and an insulating liquid And a liquid lens using as a lens.

  In the case of using the insulating liquid as a lens, for example, as shown in FIG. 2A, the variable focus lens 46 is provided with a transparent and insulating substrate 49 on the display medium 11 side. It is configured so as to be covered with a casing 47 made of a transparent insulating film through a gap 51.

  The substrate 49 is provided with a conical hole 47A centering on the optical axis of the writing light 50 emitted from the light source 43. The hole 47 </ b> A is formed in a conical shape that decreases toward the light source 43, and the side closest to the light source 43 is an entrance for the writing light 50.

The hole 47A is filled with a transparent insulating liquid 46B, and a pair of electrodes 46C are provided in a region of the hole 47A closest to the display medium 11 so as to face each other. The pair of electrodes 46 </ b> C are electrically connected to the drive unit 48. Therefore, the variable focus lens 46 is configured to be able to apply a voltage from the drive unit 48 to the pair of electrodes 46C under the control of the control unit 38. On the other hand, the gap 51 is filled with a transparent conductive liquid 46A. Note that in this embodiment mode, conductivity refers to a volume resistivity of 10 ¹⁰ Ωcm or less.

  The conductive liquid 46A and the insulating liquid 46B are both transparent, have different refractive indexes without being mixed with each other, and have values of almost equal density. It is preferable that the region of the substrate 49 serving as the interface with the gap 46A is surface-treated so as to have a hydrophobic property with respect to the insulating liquid 46B. By performing the surface treatment in this way, the insulating liquid 46B is prevented from overflowing from the hole 47A to the outside.

  As the conductive liquid 46A and the insulating liquid 46B, any liquid may be used as long as the above conditions are satisfied. Specifically, the conductive liquid 46A includes water. For the purpose of increasing, it is preferable to add a supporting electrolyte. Examples of the supporting electrolyte include potassium chloride, sodium chloride, tetramethylammonium perchlorate, tetrabutylammonium hexafluorophosphate, and the like. Moreover, methyl alcohol, ethanol, an ionic liquid, etc. are mentioned. An example of the insulating liquid 46B is an organic solvent. Organic solvents include hydrocarbons (hexane, heptane, pentane, octane, isopar, etc.), hydrocarbon aromatic compounds (benzene, toluene, xylene, mesitylene), ether compounds (difluether, anisole, diphenyl ether), silicon oil Etc.

  When a voltage is applied from the drive unit 48 to the pair of electrodes 46C of the variable focus lens 46, the conductive liquid 46A attempts to collect on each side of the pair of electrodes 46C according to the voltage value of the applied voltage. The insulating liquid 46B in the hole 47A is pushed out toward the gap 51 by the force of collecting the conductive liquid 46A on the electrode 46C (see FIGS. 2B, 2C, and 2D). ). Thereby, the insulating liquid 46B has a lens shape protruding toward the display medium 11 side.

  Then, by changing the voltage value of the voltage applied to the pair of electrodes 46C, the shape of the lens formed by the conductive liquid 46A changes, and by changing the shape of the lens, the focus variable lens 46 is changed. The focal position of the incident writing light 50 is adjusted from the side closer to the variable focus lens 46 to the far side or from the far side to the near side (FIGS. 2B and 2C). (See FIG. 2D).

  In this way, the focus adjustment unit 44 controls the control unit 38 to control the writing light 50 irradiated from the light irradiation unit 42 to the display medium 11 to the plurality of photoconductive layers 22A and the photoconductive layers of the display medium 11. 22B and the photoconductive layer 22C are configured so that the focal point can be adjusted so as to be focused on one of them.

Next, the writing process to the display medium 11 in the display device 10 will be described. In the present embodiment, in order to simplify the description, it is assumed that image data of an image to be displayed on the display medium 11 is stored in advance in the RAM or the like in the control unit 38. In the following description, it is assumed that a program for executing the processing routine shown in FIG. 3 is stored in advance in the ROM of the control unit 38 and that the program is read when power is supplied to the display device 10.
Further, the ROM of the control unit 38 has a voltage value of a voltage applied to the driving unit 48 for focusing the writing light 50 emitted from the light source 43 onto the photoconductive layer 22A, and the writing light 50 as the photoconductive layer 22B. Information indicating the voltage value of the voltage applied to the drive unit 48 to be focused on and the voltage value of the voltage applied to the drive unit 48 to focus the writing light 50 on the photoconductive layer 22C is stored in advance. And This voltage value may be measured and stored in advance in the display device 10.

  In the control unit 38 of the display device 10 according to the present embodiment, an instruction to display an image on the display medium 11 by mounting the display medium 11 on the display device 10 and operating an instruction switch (not shown). When the signal is input, the processing routine shown in FIG.

  In step 100, the image data stored in the RAM is read, and in the next step 102, based on the information indicating the color of each pixel of the image when the image of the image data is displayed on the display medium 11, the pixel Every time, the voltage applied to the driving unit 48 so that the writing light 50 is focused on the target photoconductive layer irradiated with the writing light 50 among the photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C. In addition, for each pixel, light intensity information indicating the intensity of light emitted from the corresponding light source 43 is derived, and an electrode pair to which a voltage is applied is obtained from the voltage application unit 40. The electrode pair to which a voltage is applied from the voltage application unit 40 is at least one of the electrode pair of the electrode 18A and the electrode 19A, the electrode pair of the electrode 18B and the electrode 19B, and the electrode pair of the electrode 18C and the electrode 19C. It may be selectively applied based on image data, or a voltage may be applied to all electrode pairs regardless of the image data.

  The voltage value is derived by deriving a display layer necessary for displaying the color of each pixel on the display medium 11 among the display layer 20A, the display layer 20B, and the display layer 20C. The photoconductive layers (the photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C) stacked in the same display element are defined as the photoconductive layers to which the writing light 50 is focused. The voltage value corresponding to is read from the ROM. Thereby, the voltage value of the voltage applied to the drive unit 48 is derived so that the writing light 50 is focused on the photoconductive layer to be irradiated with the writing light 50.

  The display layer necessary for displaying the color of each pixel on the display medium 11 is derived, for example, by selecting the display layer 20C capable of displaying red as the display layer in order to display red as the color of each pixel. In order to display green as the pixel color, the display layer 20B that can display green is selected as the display layer, and in order to display blue, the display layer 20A that can display blue is selected as the display layer. That's fine.

  The above-mentioned “photoconductive layer laminated in the same display element as the derived display layer” specifically refers to a photoconductive layer laminated between a pair of electrodes capable of applying a voltage to the derived display layer. Show. For example, when the derived display layer is the display layer 20A, the photoconductive layer 22A stacked between the electrode 18A and the electrode 19A, which is an electrode pair capable of applying a voltage to the display layer 20A, is written light. 50 is defined as a photoconductive layer to be focused.

  By the processing in step 102, the voltage value of the voltage applied to the drive unit 48 that drives the variable focus lens 46 corresponding to each pixel is calculated for each pixel of the target image displayed on the display medium 11. For example, when red is displayed on a specific pixel by the processing of step 102, the focus of the writing light 50 emitted from the light source 43 that irradiates the writing light 50 to the region corresponding to the specific pixel is adjusted. The writing light 50 incident on the variable focus lens 46 is focused from the drive unit 48 to the variable focus lens 46 so as to be focused on the photoconductive layer 22C stacked on the display layer 20C that is a display layer for displaying red. The voltage value to be applied is determined.

  In addition, by the processing in step 102, for each display layer of the target image displayed on the display medium 11, an electrode pair to be applied with a voltage from the voltage application unit 40 is selected, and the selected electrode pair is selected. The voltage value to be applied is determined according to the electrical characteristics of each display layer.

  Further, the processing of step 102 corresponds to each pixel so that the writing light 50 having the intensity corresponding to the density of each pixel of the image is irradiated based on the image data of the image displayed on the display medium 11. Light intensity information indicating the intensity of the writing light 50 emitted from the light source 43 is derived. The light intensity information may be derived by, for example, storing light intensity information corresponding to the density of each pixel in advance and reading the light intensity information corresponding to the density of each pixel of the image data. The method is not limited to this, and may be obtained from, for example, a previously stored calculation formula.

  The “electrode pair to be applied with a voltage from the voltage application unit 40” is a display layer (display layer 20A, display layer 20B, and display layer 20C required for presenting the color of each pixel). At least one of the electrode 18A and the electrode 19A, the electrode 18B and the electrode 19B, and the electrode 18C and the electrode 19C. Selected according to the color of the layer.

For example, when red is displayed on a specific pixel by the processing of Step 100 to Step 102, the electrode 18C and the electrode 19C of the display layer 20C that is a display layer for displaying red are selected and each display layer 20 is displayed. A pre-measured voltage value for driving is determined.
In addition, light intensity information indicating the intensity of the writing light 50 corresponding to the red density displayed on each pixel is determined for each light source 43 corresponding to each pixel of the light irradiation unit 42.

  In the next step 103, information indicating the electrode pair and the voltage value applied to each electrode pair derived in step 102 is output to the voltage applying unit 40 as a voltage application signal. In the voltage application unit 40 that has received the voltage application signal, a charge application unit (voltage application unit 40C) that applies a voltage to an electrode pair (for example, the electrode 18C and the electrode 19C) corresponding to information indicating the electrode pair included in the voltage application signal. ) Is applied to the electrode pair.

  In the next step 104, information indicating the voltage value of the voltage applied to the drive unit 48 corresponding to each pixel calculated in step 100 and a drive signal are output to the corresponding drive unit 48 of the focus adjustment unit 44.

  Each drive unit 48 that has received the drive signal applies a voltage having a voltage value included in the received drive signal between the pair of electrodes 46 </ b> C electrically connected to each drive unit 48.

  In the next step 106, irradiation of the light intensity information derived for each light source 43 by the processing of step 102 and the writing light 50 having the intensity of the light intensity information is started to each light source 43 of the light irradiation unit 42. And a light irradiation start signal including the start signal shown. Each light source 43 that has received the light irradiation start signal irradiates the display medium 11 with writing light 50 having the light intensity information included in the signal.

By the processing of Step 103 to Step 106, for example, the voltage of the voltage value that focuses the writing light 50 on the photoconductive layer 22C is applied between the driving unit 48 and the electrode 46C. When the processing is executed, the writing light 50 emitted from the light source 43 is focused on the photoconductive layer 22C as shown in FIGS. 2B and 1 from the state shown in FIG. The
Similarly, when the voltage of the voltage value for focusing the writing light 50 on the photoconductive layer 22B is applied between the drive unit 48 and the electrode 46C by the process of step 104, the process of step 106 is executed. Then, the writing light 50 emitted from the light source 43 is focused on the photoconductive layer 22B as shown in FIGS.
Similarly, when the voltage of the voltage value that focuses the writing light 50 on the photoconductive layer 22A is applied between the drive unit 48 and the electrode 46C by the process of step 104, the process of step 106 is executed. Then, the writing light 50 emitted from the light source 43 is focused on the photoconductive layer 22A as shown in FIGS. Therefore, the writing light 50 emitted from the light source 43 is focused at a position corresponding to the voltage value applied from the driving unit 48.
Each photoconductive layer is irradiated with writing light 50 having an intensity corresponding to the density of each pixel from each light source 43 corresponding to each pixel.

  In this way, display is performed from each light source 43 to a specific photoconductive layer among the photoconductive layer 22A, the photoconductive layer 22B, and the photoconductive layer 22C by the variable focus lens 46 according to the color of each pixel. The writing light 50 having an intensity corresponding to the density of each pixel of the image is focused, and a voltage is applied to the electrodes 18B and 19B of the display element 30B including the specific photoconductive layer (for example, the photoconductive layer 22B). Is applied, the resistance value of the photoconductive layer 22B changes due to the absorption of the write light 50 in the focused photoconductive layer 22B. Here, since the respective partial pressures are applied to the display layer 20B and the photoconductive layer 22B provided between the electrode 18B and the electrode 19B, a change in the resistance value of the photoconductive layer 22B causes a change in the display layer. The partial pressure applied to the region irradiated with the writing light 50 of 20B changes. As a result, the orientation distribution of the liquid crystal in the display layer 20B changes to change the optical characteristic distribution, and the region of the display layer 20B irradiated with the writing light 50 from the light source 43 is caused by selective reflection of the liquid crystal in the display layer 20B. Visible as a color. Similarly, the photoconductive layer 22A and the photoconductive layer 22C are selectively irradiated with the writing light 50 according to the image data, and the voltage is applied to the electrodes 18A and 19A, and the electrodes 18C and 19C. Is applied, and the color due to the selective reflection of the liquid crystal of the display layer 20A and the display layer 20C is visually recognized. As a result, an image of the image data is displayed on the display medium 11.

  As described above, in the display device 10 according to the present embodiment, the variable focus lens 46 and the drive unit 48 that drives the variable focus lens 46 are provided between the light irradiation unit 42 and the display medium 11, and the control unit 38. Under the control, the writing light 50 irradiated to the display medium 11 from the light irradiation unit 42 is focused on one of the plurality of photoconductive layers 22A, the photoconductive layer 22B, and the photoconductive layer 22C of the display medium 11. Make adjustments. For this reason, image quality deterioration due to the aberration of the image displayed on the display medium 11 is suppressed.

  In the present embodiment, the plurality of light sources 43, the plurality of variable focus lenses 46, and the plurality of driving units 48 correspond to each pixel of the image when the image is displayed on the display medium 11 as described above. The case where one is provided is described, but it is not limited to such a form. For example, one focus variable lens 46 and a drive unit 48 as a focus adjustment unit 44 for adjusting the focus of light emitted from the light source 43 between the light source 43 and the display medium 11. It is also possible to prepare a unit including the above-described units and to provide the unit so as to be movable in the surface direction of the display medium 11. Then, under the control of the control unit 38, the unit is moved to a position corresponding to each pixel of the image displayed on the display medium 11, and the display layer (display layer 20A, display layer 20B or display layer corresponding to the color of the image) is displayed. 20C) may be adjusted so that the writing light 50 is focused on the photoconductive layers (photoconductive layer 22A, photoconductive layer 22B, and photoconductive layer 22C) stacked in contact with 20C). In this way, the display device 10 can be reduced in size.

It is a block diagram which shows an example of the display apparatus with which the display medium was mounted in embodiment of this invention. FIG. 4 is an enlarged schematic diagram illustrating an example of a light source, a focus variable lens, and a drive unit according to an embodiment of the present invention, in which (A) shows a voltage applied between a pair of electrodes provided in the focus variable lens. It is a schematic diagram which shows the state which is not performed, (B)-(D) is a schematic diagram which shows the case where the voltage value of the voltage applied between this pair of electrodes is changed. It is a flowchart which shows the process performed with the display apparatus in embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Display apparatus 11 Display medium 18A Electrode 18B Electrode 18C Electrode 19A Electrode 19B Electrode 19C Electrode 20A Display layer 20B Display layer 20C Display layer 22A Photoconductive layer 22B Photoconductive layer 22C Photoconductive layer 30 Display element 30A Display element 30B Display element 30C Display Element 38 Control unit 40 Voltage application unit 40A Voltage application unit 40B Voltage application unit 40C Voltage application unit 43 Light source 46 Focus variable lens 48 Drive unit

Claims (1)

A pair of electrodes, a photoconductive layer provided between the pair of electrodes and exhibiting an electrical characteristic distribution according to the intensity distribution of the light by absorbing light in a predetermined wavelength region; and the pair of electrodes A display layer that includes a display layer that displays an image based on an optical characteristic distribution according to the partial pressure applied to the photoconductive layer according to the applied voltage. A voltage is applied to the pair of electrodes included in each of the plurality of display elements with respect to a display medium in which a plurality of the photoconductive layers included in the plurality of display elements absorb light in a specific wavelength region. First voltage applying means,
A light source that irradiates the display medium with light in a wavelength region including an absorption wavelength region of the plurality of photoconductive layers;
A variable focus lens that is provided between the light source and the display medium and that receives light emitted from the light source and changes a focus of the incident light according to an applied voltage;
Second voltage applying means for applying a voltage to the variable focus lens;
The first voltage application unit is controlled to apply a voltage to the pair of electrodes included in at least one of the plurality of display elements, and the photoconductivity of the display element to which the voltage is applied is based on image data. Control means for controlling the second voltage application means so that the light emitted from the light source is focused on the layer, and for controlling the light source so that the light of the intensity based on the image data is emitted;
A display device comprising:

Images