JP4193544B2 - Optical touch panel and electronic device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is used, for example, on a display screen of an electro-optical device such as a liquid crystal device, and is capable of inputting coordinates by a finger input method, a pen input method, or the like, and such an optical touch panel and an electro-optical device. The present invention belongs to the technical field of various electronic devices comprising the device.
[0002]
[Background]
Conventionally, as a touch panel, a resistance film type, an ultrasonic type, a capacitance type, an optical type, and the like are known.
[0003]
Of these, the optical touch panel is superior in durability, visible light transmittance, environmental resistance, and the like as compared with other types of touch panels such as a resistive film type, an ultrasonic type, and a capacitance type. However, the optical touch panel is generally inferior in terms of resolution, mounting area for the display screen, current consumption, price, and the like. In order to cope with this, an optical touch panel has been developed in which light source light is derived using a waveguide, and further guided from the light receiving surface to the photodetector using the waveguide (see Patent Document 1).
[0004]
[Patent Literature]
JP 10-91348 A
[0005]
[Problems to be solved by the invention]
However, according to the above-described optical touch panel, it is necessary to attach an optical touch panel having various optical components to an electro-optical device such as a liquid crystal device having a display screen. There is a problem that it is technically difficult to increase the resolution related to coordinate input while keeping the entire apparatus in a practical size.
[0006]
On the other hand, with a resistive film type, ultrasonic type, capacitive type touch panel, etc., it is necessary to attach some kind of sensing panel on the display screen. There is a technical problem.
[0007]
The present invention has been made in view of the above-described problems, and is an optical touch panel used, for example, on a display screen of an electro-optical device such as a liquid crystal device, where coordinate input is performed without causing deterioration in image quality of the display screen It is possible to provide an optical touch panel capable of increasing the resolution of coordinate input and making it relatively easy and various electronic devices including such an optical touch panel and an electro-optical device. Let it be an issue.
[0008]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the first optical touch panel of the present invention is an optical touch panel having a transparent coordinate input area superimposed on a display screen, along a part of the side of the coordinate input area. The coordinate input region is arranged so that the light source light emitted from the light source is directed in a direction intersecting from a part of the side to a part of the side and toward the coordinate input region. And a light receiving means for receiving light source light traveling in the first direction in the coordinate input area at a position opposite to the light output means across the coordinate input area. The light emitting means includes a first waveguide that guides light source light emitted from the light source along a part of the side, and an extension of the first waveguide into the first waveguide. Arranged along the direction, the first waveguide A plurality of light branches that bend the light source light guided along a part of the side at least partially in the first direction from the middle of the first waveguide and emit the light into the coordinate input region, respectively. Means.
[0009]
According to the first optical touch panel of the present invention, during the operation, in the light emitting means arranged along a part of the side of the coordinate input area, first, for example, it faces the end face or the input end of the first waveguide. The light source light is emitted by the light source arranged to do so. The “light source light” according to the present invention may be visible light used exclusively for coordinate input or as display light for image display, or may not be visible light. In addition, the “light source” according to the present invention may be externally attached to or built in the optical touch panel. Specifically, a light source such as a white light source, a lamp, an LED (Light Emitting Diode), and an LD (Laser Diode) can be used. The light source light guided by the first waveguide is at least partially from the middle of the first waveguide by each of the plurality of light branching means arranged along the extending direction in the first waveguide. Each is bent in the first direction and emitted into the coordinate input area. Each of the light branching units includes, for example, a half mirror configured to be able to selectively split light source light at least partially by switching between a transmissive state and a non-transmissive state according to an electric signal or the like. Alternatively, for example, the micromirror device is configured so that the light source light can be selectively branched at least partially by mechanically changing the reflection angle according to an electric signal or the like.
[0010]
In this way, the light source light is time-divisionally or simultaneously or one by one or a plurality from a plurality of locations arranged along the side where the light emitting means is arranged by a plurality of light branching means from the first waveguide. As a ray, it is emitted into the coordinate input area. Then, the light source light travels in the coordinate input area in the first direction, and then is received by the light receiving means at a position facing the light emitting means with the coordinate input area interposed therebetween. At this time, in the light receiving means, the light source light is received, for example, in time division, simultaneously, one by one, or as a plurality of light beams according to an emission form such as time division or simultaneous emission in the light branching means. That is, the light receiving means may include a single light receiving element that receives the light source light that has traveled in the first direction in the coordinate input area after being collected and guided in a single waveguide. Alternatively, it may include a plurality of light receiving elements that directly receive the light source light traveling in the first direction in the coordinate input region for each light branching means arranged along the light receiving side. In any case, the “light receiving element” constituting the light receiving means according to the present invention includes, for example, a photodiode, a CCD (Charged Coupled Device), a linear sensor array, and the like.
[0011]
Accordingly, when a specific part of the coordinate input area is touched by a human finger or a pen tip, that is, if an object that blocks light source light exists in the coordinate input area, the coordinate input area is moved in the first direction. Of the light source light that travels, the light intensity of the light source light that passes through a specific location decreases or becomes zero. For this reason, if the decrease in light intensity is detected by the light receiving means, it is possible to specify the coordinates of a specific location.
[0012]
Preferably, the “first direction” according to the present invention is two mutually intersecting directions, for example, the vertical direction (for example, Y direction) and the horizontal direction (for example, X direction) of the coordinate input area. And according to the detection result about these two directions, it becomes possible to detect a specific location as coordinates in the coordinate input area. However, the “first direction” according to the present invention may be one of the vertical direction (for example, the Y direction) and the horizontal direction (for example, the X direction) of the coordinate input area. In this case, it is possible to detect a specific location as a vertical or horizontal position in the coordinate input area (for example, a height position or a horizontal position in the coordinate input area) according to the detection result for the one direction. It is said. For example, depending on the content of the display screen on which the coordinate input area is overlaid, it is sufficient to detect a specific part in one direction.
[0013]
As a result, according to the first optical touch panel of the present invention, it is possible to input arbitrary coordinates on the display screen by touching the coordinate input area superimposed on the display screen with a finger or the like. At this time, it is sufficient to irradiate the first waveguide with light source light from one or a small number of light sources from the end face or the like. For example, various light sources such as a dedicated light source or a combined light source can be used and It becomes possible to keep the peripheral area necessary for emission relatively small. Accordingly, it is possible to reduce the size of the peripheral area relative to the display screen or the coordinate input area, and it is possible to reduce the size of the entire apparatus.
[0014]
Furthermore, on the light emitting side, it is possible to adopt a configuration in which a plurality of light branching units are arranged along the first waveguide according to the pixel pitch of the display screen. Furthermore, it is possible to adopt a configuration in which the light source light is scanned by sequentially operating a plurality of light branching means in accordance with scanning such as field scanning on the display screen. Therefore, it is possible to input high-resolution coordinates according to the resolution of the display screen.
[0015]
In addition, since it is not necessary to superimpose the components of the optical touch panel on the display screen, it is very advantageous in that there is little or no influence on the image quality on the display screen.
[0016]
In one aspect of the first optical touch panel of the present invention, the light receiving means is disposed at a position opposite to the first waveguide with the coordinate input area interposed therebetween, and a side of the coordinate input area. A second waveguide disposed along the other portion, and arranged in the second waveguide along the extending direction of the second waveguide, and proceeds in the first direction in the coordinate input region. A plurality of optical coupling means for bending the emitted light source light at least partially from the middle of the second waveguide in a direction along the second waveguide and emitting the light into the second waveguide; A light receiving element that receives light source light emitted into the waveguide at one end of the second waveguide.
[0017]
According to this aspect, the light source light traveling in the first direction in the coordinate input area is transmitted from the middle of the second waveguide to the second waveguide by each of the plurality of optical coupling means arranged in the second waveguide. Are bent in the extending direction of the light and emitted into the second waveguide. Each of the optical coupling means includes, for example, a half mirror configured so that the optical path of the light source light can be coupled by switching between a transmission state and a non-transmission state according to an electric signal or the like. Alternatively, for example, the micro mirror device is configured such that the optical path of the light source light can be selectively coupled by mechanically changing the reflection angle according to an electric signal or the like. In this way, the light source light that has traveled in the first direction in the coordinate input area as time-division or simultaneously, one-by-one or multiple-by-one rays is collected and guided to the second waveguide by a plurality of optical coupling means. Then, the light is received by the light receiving element at one end of the second waveguide. In other words, the light receiving means receives the light source light in, for example, time division according to the emission form such as time division or simultaneous emission in the light branching means.
[0018]
As a result of the above, by detecting a decrease in the light intensity of the light source light received by the light receiving element in accordance with the contact of the finger or the like to the specific part of the coordinate input region, the coordinates of the specific part related to the contact of the finger or the like can be obtained. It becomes possible to specify.
[0019]
In order to solve the above-mentioned problem, the second optical touch panel of the present invention is an optical touch panel having a transparent coordinate input area superimposed on a display screen, along a part of the side of the coordinate input area. The coordinate input region is arranged so that the light source light emitted from the light source is directed in a direction intersecting from a part of the side to a part of the side and toward the coordinate input region. And a light receiving means for receiving light source light traveling in the first direction in the coordinate input area at a position opposite to the light output means with the coordinate input area interposed therebetween. The light receiving means is disposed at a position opposite to the light emitting means across the coordinate input area, and is arranged along the other part of the side of the coordinate input area. A waveguide and the second waveguide Are arranged along the extending direction of the second waveguide, and the light source light traveling in the first direction in the coordinate input area is at least partially from the middle of the second waveguide to the second waveguide. A plurality of optical coupling means that respectively bend in the direction along the waveguide and emit into the second waveguide, and light reception that receives the light source light emitted into the second waveguide at one end of the second waveguide An element.
[0020]
According to the second optical touch panel of the present invention, during the operation, the light source light from the light source is coordinated in the first direction by the light emitting means arranged along a part of the side of the coordinate input area. It is emitted into the input area.
[0021]
Then, the light source light travels in the coordinate input area in the first direction, and then is received by the light receiving means at a position facing the light emitting means with the coordinate input area interposed therebetween. At this time, in the light receiving means, the light source light traveling in the first direction in the coordinate input area is second guided from the middle of the second waveguide by each of the plurality of optical coupling means arranged in the second waveguide. The light is bent in the extending direction of the waveguide and emitted into the second waveguide. In this way, for example, the light source light traveling in the first direction in the coordinate input region as time-division or simultaneously, one by one or a plurality of light beams is collected in the second waveguide by a plurality of optical coupling means. After being guided, the light receiving element receives light at one end of the second waveguide. In other words, the light receiving means receives the light source light in, for example, time division according to the emission form such as time division or simultaneous emission in the light branching means.
[0022]
Accordingly, when a specific part of the coordinate input area is touched by a human finger or a pen tip, that is, if an object that blocks light source light exists in the coordinate input area, the coordinate input area is moved in the first direction. Of the light source light that travels, the light intensity of the light source light that passes through a specific location decreases or becomes zero. For this reason, if the decrease in light intensity is detected by the light receiving means, it is possible to specify the coordinates of a specific location.
[0023]
As a result, according to the second optical touch panel of the present invention, it is possible to input arbitrary coordinates on the display screen by touching the coordinate input area superimposed on the display screen with a finger or the like. At this time, since it is sufficient to receive the light source light from one end of the second waveguide as the light receiving means, it is possible to keep the peripheral region necessary for light emission relatively small. Accordingly, it is possible to reduce the size of the peripheral area relative to the display screen or the coordinate input area, and it is possible to reduce the size of the entire apparatus.
[0024]
Further, on the light receiving side, it is possible to adopt a configuration in which a plurality of optical coupling means are arranged along the second waveguide according to the pixel pitch of the display screen. Further, it is possible to adopt a configuration in which the light source light is scanned by sequentially operating a plurality of optical coupling means in accordance with scanning such as field scanning on the display screen. Therefore, it is possible to input high-resolution coordinates according to the resolution of the display screen.
[0025]
In addition, since it is not necessary to superimpose the components of the optical touch panel on the display screen, it is very advantageous in that there is little or no influence on the image quality on the display screen.
[0026]
In another aspect of the first optical touch panel of the present invention, each of the plurality of light branching units bends light source light guided along a part of the side at least partially in the first direction. The first optical switch means is selectively switchable to either one of the operating state and the non-bending non-operating state.
[0027]
According to this aspect, on the light emitting side, the light source light emitted from the light source and guided by the first waveguide is selectively changed by switching the first optical switch means such as a half mirror or a micro mirror device. Bent in one direction. Therefore, the light source light guided to the first waveguide can be emitted from a plurality of locations of the first waveguide into the coordinate input area in a time-division manner, one by one or a plurality of light beams.
[0028]
In this aspect, the first optical switch means may be configured to sequentially enter the operating state along a part of the side.
[0029]
If comprised in this way, it will become possible to carry out light emission scanning of the light source light along the edge | side of the light emission side by switching of a 1st optical switch means. That is, in the coordinate input area, scanning is performed along a part of the side of the coordinate input area by the light source light traveling in the first direction. On the light receiving side, the light receiving scanning may or may not be performed by switching the optical coupling means.
[0030]
In one aspect of the second optical touch panel of the present invention, each of the plurality of optical coupling means at least partially transmits light source light traveling in the first direction in the coordinate input area to the second waveguide. A second optical switch means that can be selectively switched to either one of an operation state of bending in a direction along the line and a non-operation state of non-bending;
[0031]
According to this aspect, on the light receiving side, the light source light that has traveled in the first direction in the coordinate input area is selectively converted into the second waveguide by switching the second optical switch means such as a half mirror or a micromirror device. Bend along the direction. Therefore, the light source light bent at a plurality of locations of the second waveguide and guided by the second waveguide is time-divisionally or simultaneously or one by one or a plurality by the light receiving element at one end of the second waveguide. It can be received as a light beam.
[0032]
In this aspect, the second optical switch means may be configured to sequentially enter the operating state along the other part of the side.
[0033]
If comprised in this way, it will become possible to carry out light reception scanning along the edge | side of a light reception side by switching of a 2nd optical switch means. That is, in the coordinate input area, scanning is performed along a part of the side of the coordinate input area by the light source light traveling in the first direction. Note that, on the light emitting side, the light emission scanning may or may not be performed by switching the light branching means.
[0034]
In the aspect including the second waveguide, the optical coupling unit, and the light receiving element according to the first optical touch panel of the present invention described above, each of the plurality of optical branching units is guided along a part of the side. Including a first optical switch means capable of selectively switching at least partially between an operation state in which the light source light is bent in the first direction and a non-operation state in which the light source light is not bent; Respectively, the light source light traveling in the first direction in the coordinate input area is selectively at least partially selected from one of an operation state in which the light source light is bent in the direction along the second waveguide and a non-operation state in which the light is not bent The first optical switch means is sequentially set in the operating state along a part of the side, and the second optical switch means is configured to include the first optical switch means. Sequential operation Synchronously it may be configured to be other portion the operating state sequentially along the sides.
[0035]
If comprised in this way, it will become possible to carry out light emission scanning of the light source light along the edge | side of the light emission side by switching of a 1st optical switch means. At the same time or before and after this, it is possible to perform light reception scanning along the side of the light reception side by switching the second optical switch means. That is, in the coordinate input area, scanning is performed along a part of the side of the coordinate input area by the light source light traveling in the first direction. Therefore, it is possible to specify the coordinates of a specific portion related to the contact of the finger or the like while efficiently using the light source light or avoiding the waste of the light source light.
[0036]
In the aspect including the first or second optical switch unit related to the first or second optical touch panel described above, at least one of the first and second optical switch units selects a reflective state and a non-reflective state. The light source light may be configured to include reflection means that can be switched automatically and bends the light source light by reflection in the reflection state.
[0037]
If comprised in this way, a light source will be reflected by the reflection means which consists of a transflective mirror which will be in a reflective state, for example, when a reflectance changes electrochemically, such as a temperature optical material, an electro-optical material, and an ultrasonic optical material. Light can be selectively bent. Alternatively, the light source light is selectively bent by reflecting means including a micromirror device or the like that is brought into a reflecting state by mechanically changing an angle with respect to the optical path or changing the arrangement.
[0038]
In another aspect of the first optical touch panel of the present invention, a plurality of the first waveguides are provided in parallel along a part of the side, and the light source light is the plurality of first waveguides. Are respectively guided separately.
[0039]
According to this aspect, on the light emitting side, a plurality of light source lights guided by the plurality of first waveguides can be emitted into the coordinate input area simultaneously or before and after. Thereby, for example, scanning using a plurality of light source lights separately or in synchronization is possible.
[0040]
In an aspect including the second waveguide, the optical coupling unit, and the light receiving element according to the first optical touch panel of the present invention or in another aspect of the second optical touch panel of the present invention, the second waveguide is: A plurality of the light receiving elements may be provided in parallel along the other part of the side, and the light receiving element may receive light separately for each of the plurality of second waveguides.
[0041]
If comprised in this way, it will become possible to receive separately the several light source light light-guided by several 2nd waveguide by a light receiving element by the light-receiving side. Thereby, for example, scanning using a plurality of light source lights separately or in synchronization is possible.
[0042]
In another aspect of the first, second, or third optical touch panel of the present invention, the light emitting means and the light receiving means are formed, and the substrate occupies the coordinate input area, and is disposed on the substrate. A transparent plate member, and the light source light travels between the substrate and the transparent plate member in the coordinate input region.
[0043]
According to this aspect, the light source light emitted from the light emitting means travels between the substrate and the transparent plate member in the coordinate input area and is received by the light receiving means. Therefore, when the transparent plate member is brought into contact with a finger or the like, the light source light that passes through the deformed portion out of the light source light that travels in the coordinate input area in the first direction is deformed. Decrease or become zero. For this reason, if the light intensity drop is detected by the light receiving means, it is possible to specify the coordinates of a specific location as a deformation location.
[0044]
The transparent plate member may be made of resin, plastic, glass, or the like, and may function as a dustproof or protective cover. However, in the present invention, it is also possible to configure the exposed space on the substrate so that the light source light travels without such a transparent plate member.
[0045]
In another aspect of the first or second optical touch panel of the present invention, the light source light has a microlens on at least one of an optical path portion incident on the coordinate input region and an optical path portion emitted from the coordinate input region. Is provided.
[0046]
According to this aspect, since the light source light emitted from the light emitting means is collected by the microlens, the light travels in the coordinate input area as a thinner light flux, and the resolution of the optical touch panel can be increased. Alternatively, since the light source light from the coordinate input area is collected by the microlens, it is received as a narrower light beam by the light receiving means, and the resolution of the optical touch panel can be increased.
[0047]
In another aspect of the first or second optical touch panel of the present invention, the light source light includes light of a specific frequency band that does not interfere with display light emitted from the display screen.
[0048]
According to this aspect, since the light source light includes light in a specific frequency band that does not interfere with the display light emitted from the display screen, it is effective that the light source light is disturbed by the display light in the coordinate input area. To be blocked. As a result, stable light detection can be performed on the light receiving means side regardless of the content on the display screen.
[0049]
The light in the specific frequency band may be visible light or not visible light, but light other than visible light is preferable.
[0050]
In this aspect, the light receiving means may be configured to be able to detect light in the specific frequency band.
[0051]
With this configuration, light on a specific frequency band is selectively or dominantly received on the light receiving means side, so that very stable light detection can be performed regardless of the content on the display screen. Become.
[0052]
In another aspect of the first or second optical touch panel of the present invention, the light emitting means incorporates the light source.
[0053]
According to this aspect, a light source such as an LED built in the optical touch panel is turned on continuously or intermittently, and the finger or the like is used with high reliability using the light source light emitted thereto. It becomes possible to specify the coordinates of a specific location related to the contact.
[0054]
Alternatively, in another aspect of the first or second optical touch panel of the present invention, the light source light is supplied from an external light source to the light emitting means via a light guide means.
[0055]
According to this aspect, the light source light is supplied from the external light source attached or attached to the optical touch panel to the light emitting means via the light guide means such as an optical fiber.
[0056]
Alternatively, in another aspect of the first or second optical touch panel of the present invention, the light source light is supplied from the second waveguide to the light receiving element via a light guide.
[0057]
According to this aspect, the light source light is supplied to an external light receiving element that is externally attached or retrofitted to the optical touch panel via a light guide means such as an optical fiber.
[0058]
Alternatively, in another aspect of the first or second optical touch panel of the present invention, the light source light does not interfere with the surface of the display screen.
[0059]
According to this aspect, the light source light emitted from the light emitting means travels in the space on the substrate in the coordinate input area without contacting the display screen of the electro-optical device, and is received by the light receiving means. Therefore, for example, the light source light is not reflected by the display screen and the optical path is not changed, and the light source light is prevented from being disturbed in the coordinate input area. As a result, accurate light detection can be performed on the light receiving means side.
[0060]
In order to solve the above problems, an electronic apparatus of the present invention includes the above-described first or second optical touch panel of the present invention (including various aspects thereof) and an electro-optical device having the display screen. .
[0061]
According to the electronic apparatus of the present invention, the above-described first or second optical touch panel of the present invention is overlaid on a display screen of various electro-optical devices such as a liquid crystal device and an organic EL device. Therefore, it is possible to input coordinates in the coordinate input area as a relative positional relationship with the displayed content while displaying arbitrary content on the display screen of the electro-optical device.
[0062]
Such an operation and other advantages of the present invention will become apparent from the embodiments described below.
[0063]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, the optical touch panel of the present invention is applied to an electronic apparatus having a display function and a coordinate input function constructed by overlapping an electro-optical device having a display screen.
[0064]
(First embodiment)
1st Embodiment which concerns on the optical touch panel of this invention is described with reference to FIGS. FIG. 1 is a perspective view showing the overall configuration of the optical touch panel according to the present embodiment, together with an electro-optical device to which the optical touch panel is attached. FIG. 2 is a schematic plan view showing the detailed configuration of the optical touch panel according to the present embodiment and the operation of the optical system. 3 is a cross-sectional view taken along the line H-H 'in FIG. 4 is a cross-sectional view taken along the line VV ′ in FIG.
[0065]
First, the overall configuration of the optical touch panel according to the present invention will be described with reference to FIG.
[0066]
As shown in FIG. 1, the optical touch panel 200 according to the present embodiment is overlaid on the electro-optical device 100.
[0067]
The electro-optical device 100 includes, for example, a liquid crystal device, an organic EL (Electro-Luminescence) device, a CRT (Cathode Ray Tube) display device, and the like. The electro-optical device 100 includes at least one substrate, and a display screen 110 is defined on the substrate. On the display screen 100, for example, various images including icons, buttons, numeric keys, maps, and the like that can be selected or specified by touching with a finger, an input pen, or the like, which are targets of coordinate input by the optical touch panel 200, or an optical touch panel Information input by the user 200 is displayed.
[0068]
The optical touch panel 200 includes a touch panel substrate 201, and a light source 210, a photodetector 220, a light emitting side optical waveguide 250, and a light receiving side optical waveguide 260 on the touch panel substrate 201. On the touch panel substrate 201, a coordinate input area 202 is defined as an area corresponding to the display screen 110.
[0069]
The touch panel substrate 201 is made of a transparent substrate that transmits light, such as glass or plastic. The touch panel substrate 201 is attached to the electro-optical device 100 so that the coordinate input area 202 is superimposed on the display screen 110.
[0070]
In the coordinate input area 202, for example, an arbitrary physical position by the user as seen by handwriting input by touching the touch panel substrate 201 with a pen or the like, or input by touching a finger, etc. Specification is made. The designated position is detected by the photodetector 220 as described later in detail, and is taken in as input information.
[0071]
Around the rectangular coordinate input area 202, light emitting side optical waveguides 250X and 250Y are arranged along two adjacent sides (corresponding to the X direction and the Y direction in FIG. 1). Furthermore, light receiving side optical waveguides 260X and 260Y are arranged along the remaining two adjacent sides (corresponding to the X direction and the Y direction in FIG. 1). The light emitting side optical waveguides 250X and 250Y and the light receiving side optical waveguides 260X and 260Y introduce the light source light from the light collection port at one end thereof or from the middle and guide it to the light emission port at the other end or guide it halfway. However, the operation of the optical system including these will be described in detail later.
[0072]
The light source 210 is provided at one end of the light emission side optical waveguide 250, and emits light introduced into the light outlet of the light emission side optical waveguide 250. Specifically, a light source such as a white light source, a lamp, an LED, or an LD can be used.
[0073]
The photodetector 220 includes a light receiving element 290 that is provided at one end of the light receiving side optical waveguide 260 and receives and detects light emitted from the light receiving side optical waveguide. Two light receiving elements 290 are provided corresponding to the light receiving side optical waveguides 260X and 260Y (hereinafter referred to as the light receiving element 290X corresponding to the light receiving side optical waveguide 260X and the light receiving element 290Y corresponding to the light receiving side optical waveguide 260Y). To show). As such a light receiving element, a photodiode, a CCD, a linear sensor array, or the like can be used.
[0074]
Next, the detailed configuration of the optical touch panel 200 according to this embodiment and the operation of the optical system will be described with reference to FIG.
[0075]
As shown in FIG. 2, the light source light emitted from the light source 210 is introduced into the light emission side optical waveguide 250Y from the light outlet 251Y at one end of the light emission side optical waveguide 250Y, and the light emission side optical waveguide 250Y, That is, the light is guided along one side of the coordinate input area 202 in the direction opposite to the Y direction.
[0076]
A half mirror 203 is disposed between the light source 210 and the light emitting side optical waveguide 250X, and branches a part of the light source light in the X direction as shown in FIG. It is preferable to set the reflectance of the half mirror 203 so that the amount of the light source light branched in the X direction and the Y direction is halved, but the ratio of the branched light amount is controlled. A drive-type half mirror that can be used may be configured. For example, the light source light can be incident on the light emitting side optical waveguides 250X and 250Y alternately at a predetermined cycle.
[0077]
The light source light emitted from the light source 210 and branched by the half mirror 203 is introduced into the inside of the light emission side optical waveguide 250X from the daylighting port 251X at one end of the light emission side optical waveguide 250X, as shown in FIG. Light is guided along the other side of the coordinate input region 202 in the light emitting side optical waveguide 250X, that is, in the X direction.
[0078]
A plurality of optical switches 270X and a plurality of optical switches 270Y are arranged along the respective extending directions (that is, one side of the corresponding coordinate input area) inside the light emitting side optical waveguides 250X and 250Y ( Hereinafter, the individual optical switches are appropriately referred to as 270X (i) and 270Y (i) (where i = 0, 1, 2, 3,..., N), or simply referred to as optical switches 270X and 270Y. ). The optical switches 270X (i) are arranged at equal intervals over the entire length of the light emitting side optical waveguide 250X. On the other hand, the optical switches 270Y (i) are arranged at equal intervals over the entire length of the light emitting side optical waveguide 250Y.
[0079]
Each of the optical switches 270X (i) reflects a part of the light source light traveling inside the light emitting side optical waveguide 250X in accordance with a driving signal from the outside (hereinafter referred to as an “operating state” as appropriate). ) And a state in which all of the light is transmitted (hereinafter, referred to as “non-operating state” as appropriate) can be selectively switched to one of them. On the other hand, each of the optical switches 270Y (i) is configured to be selectively switchable to one of an operating state and a non-operating state in accordance with an external drive signal.
[0080]
Here, the optical switch 270X (i) or 270Y (i) has a temperature optical material, an electro-optical material, an acousto-optic material, a magneto-optic material, etc., each of which can appropriately change the refractive index in accordance with an external driving signal. Can be configured. Alternatively, in accordance with a driving signal from the outside, a micro that selectively switches between one of reflection and transmission of light source light (that is, an operating state and a non-operating state) by mechanical movement or angle change. You may comprise by a mirror etc.
[0081]
In FIG. 2, optical switches 270X (i) and 270Y (i) are schematically shown as mirror-like components, and detailed illustrations are omitted, but various material configurations and driving as described above are shown. It is assumed that each includes a connection terminal, a drive unit, or the like according to the system.
[0082]
When the optical switch 270Y (i) is driven, the light source light guided along the light emitting side optical waveguide 250Y is reflected in the direction of the coordinate input area 202, that is, in the X direction (hereinafter, the optical switch 270Y ( i) (where i = 0, 1, 2, 3,..., n), the light source light LYi (where i = 0, 1, 2,..., n) is associated with each optical switch. 3,..., N)). On the other hand, when the optical switch 270X (i) is driven, the light source light guided along the light emitting side optical waveguide 250X is reflected in the direction of the coordinate input area 202, that is, the direction opposite to the Y direction ( Hereinafter, the light source light reflected by the optical switch 270X (i) (where i = 0, 1, 2, 3,..., N) corresponds to the respective optical switch, and the light source light LXi (where i = 0, 1, 2, 3,..., N)).
[0083]
The light source lights LY1, LY2,... LYn travel in the space on the coordinate input area 202 in parallel with each other, and are received at positions facing the light emitting side optical waveguide 250Y with the coordinate input area 202 interposed therebetween. It reaches the side optical waveguide 260Y. On the other hand, the light source lights LX1, LX2,..., LXn travel through the space on the coordinate input area 202 in parallel with each other, and are arranged at positions facing the light emitting side optical waveguide 250X with the coordinate input area 202 in between. The light receiving side optical waveguide 260X is reached.
[0084]
Here, similarly to the light emitting side optical waveguides 250X and 250Y, a plurality of light beams are provided inside the light receiving side optical waveguides 260X and 260Y along each extending direction (that is, one side of the coordinate input area corresponding to each). Switches 280X and 280Y are arranged (hereinafter referred to as 280X (i) and 280Y (i) (where i = 0, 1, 2, 3,..., N) as appropriate for individual optical switches, or Simply referred to as optical switches 280X, 280Y). The optical switches 280X (i) and 280Y (i) are arranged at equal intervals over the entire lengths of the light emitting side optical waveguides 250X and 250Y. The configuration and driving method of the optical switch element in each of the optical switches 280X (i) and 280Y (i) can be appropriately selected from the same as those of the optical switches 270X (i) and 270Y (i). It is assumed that the light source can be selectively switched to either one of a state of reflecting a part of the light source (operating state) or a state of transmitting all the light (non-operating state).
[0085]
Here, in particular, the optical switch 280Y (i) is provided in one-to-one correspondence with the optical switch 270Y (i) provided in the light emitting side optical waveguide 250Y. For example, the optical switch 270Y (1), The light source lights LY1 and LY2 reflected by 270Y (2) are received by the optical switches 280Y (1) and 280Y (2). On the other hand, similarly, the optical switch 280X (i) is provided in one-to-one correspondence with the optical switch 270X (i) provided in the light emitting side optical waveguide 250X. For example, the optical switch 270X (1) The light source lights LX1 and LX2 reflected by 270X (2) are received by the optical switches 280X (1) and 280X (2).
[0086]
When the optical switch 280Y (i) is driven, the light source light LYi that has passed through the space on the coordinate input area 202 is reflected in the Y direction, and the light receiving side optical waveguide 260Y is provided at one end of the light receiving side optical waveguide 260Y. The light is guided to the exit 261Y. On the other hand, similarly, when the optical switch 280X (i) is driven, the light source light LXi that has passed through the space on the coordinate input area 202 is reflected in the X direction, and passes through the light receiving side optical waveguide 260X. The light is guided to an emission port 261Y provided at one end of 260X.
[0087]
In this embodiment, as shown in FIG. 2, the light-receiving side optical waveguide 260X is bent at the corner where the two sides around the coordinate input area 202 intersect and is provided over the two sides. The light source light LXi reflected by the switch 280X (i) is configured to be bent at the corner and guided to the exit 261X, but the light receiving side optical waveguide 260X is 2 of the coordinate input area 202 described above. The light source light is bent by providing a half mirror similar to the half mirror 203 provided between the light source 210 and the light emitting side optical waveguide 250Y at the divided portion at the corner where the sides intersect. May be.
[0088]
Finally, the light source light emitted from the emission ports of the light receiving side optical waveguides 260X and 260Y reaches the photodetector 220 and is received by the light receiving elements 290X and 290Y.
[0089]
With the configuration of the optical system as described above, a plurality of light source lights LXi and LYi intersect with each other in the space on the coordinate input area 202 to form a matrix-like light net.
[0090]
Hereinafter, the position detection method using the optical touch panel according to the present embodiment will be described with reference to FIGS. 3 and 4.
[0091]
As shown in FIG. 3, when a user-desired position is designated in the coordinate input area 202 by an input medium 500 (for example, a user's finger or input pen) from the user, the horizontal direction in FIG. The light source light LYi passing over the coordinate input area 202 is blocked. At the same time, as shown in FIG. 4, the light source light LXi passing on the coordinate input area 202 in the vertical direction of FIG. At this time, the light detector 220 recognizes which light source light of the plurality of light source lights LYi is blocked, so that which position in the vertical direction of FIG. 2 (that is, the direction from V to V ′). Is detected. Similarly, by recognizing which one of the plurality of light source lights LXi is blocked, it is detected which position is designated in the horizontal direction (ie, the direction from H to H ′) in FIG. The Taking the case where the user designates the point P shown in FIG. 2 as an example, the light detector light 220 detects that the light source light LX2 and the light source light LX3 are blocked, and the designated position P is used as input information. Be recognized.
[0092]
Therefore, the optical touch panel according to the present embodiment has, for example, a case where a plurality of light sources are arranged along one side and a plurality of light receiving elements are arranged on the opposite side, for example, on the coordinate input area 202 over the front surface. Compared with the case where the optical waveguide is formed on the matrix, it can be constituted by a small number of light sources, light receiving elements, optical waveguides, etc., and the entire apparatus can be miniaturized. In the present embodiment, since the optical waveguides on the light emitting side and the light receiving side are both arranged in a space other than the coordinate input area, the display light from the display screen 110 is not blocked by the optical waveguide at all. It is possible to maintain a high-quality image display. It is detected that the optical switches 270X (i), 270Y (i), 280X (i), and 280Y (i) are driven, and that the timing and the light source lights LXi and LYi are blocked. The timing relationship will be described in detail below.
[0093]
In the present embodiment, in particular, the optical switches 270X and 270Y on the light emitting side and the optical switches 280X and 280Y on the light receiving side are sequentially brought into the operating state by sequentially supplying drive signals from the outside to each. Then, the light source lights LXi and LYi are sequentially emitted on the coordinate input area.
[0094]
Hereinafter, the light emission side optical switch 270Y (i) and the light reception side optical switch 280Y (i) related to the light source light LYi shown in FIG. 2 will be described more specifically.
[0095]
First, the drive signal DSY is sequentially supplied from the outside in the order of DSY1, DSY2,... Corresponding to the optical switches 270Y (1), 270Y (2),. 270Y (1), 270Y (2),... Are sequentially operated in this order. At this time, the drive signal DSX from the outside also corresponds to the optical switches 280Y (1), 280Y (2),... In the light receiving side optical switch 280Y (i). By sequentially supplying in order, the optical switch 280Y is sequentially activated in the order of 280Y (1), 280Y (2),. That is, the light emitting side optical switch 270Y (i) and the corresponding light receiving side optical switch 280Y (i) are brought into operation in synchronization with each other. The light source light LYi is sequentially received by the light receiving element 290Y in the order of the light source lights LY1, LY2,. Here, the light source lights LY1, LY2,... Reach the light receiving element 290Y at different times. In other words, each of the light source lights LY1, LY2,... By the photodetector 220 can be detected so as not to overlap on the time axis. For this reason, the light detector 220 identifies which light source light LYi is blocked by the input medium 500 among the plurality of light source lights LYi, and the vertical direction (V-V) on the coordinate input area 202 shown in FIG. In the “direction”, which position is designated by the user is recognized.
[0096]
A series of sequential operations as described above (hereinafter referred to as “sequential operation in the Y direction” as appropriate) is performed also in the light emitting side optical switch 270X (i) and the light receiving side optical switch 280X (i) related to the light source light LXi. The drive signal DSX is similarly supplied by sequentially supplying DSX1, DSX2,... Corresponding to the optical switches 270X (1), 270X (2),. "Sequential operation in the X direction").
[0097]
Here, a series of sequential operations in the X direction and sequential operations in the Y direction are each performed once in a unit time (hereinafter referred to as “one frame”). That is, one position (PX) detected by the photodetector 220 corresponding to the sequential operation in the X direction and one position (PY) detected corresponding to the sequential operation in the Y direction within one frame. Each point is recognized, and one point P (PX, PY) in the coordinate input area 202 is specified. Then, by repeating this one frame continuously, for example, a position designation continuous on the time axis such as a line drawing by the user is recognized as input information.
[0098]
By the sequential operation in the X direction and the sequential operation in the Y direction as described above, a plurality of light source lights LYi emitted by one light source are guided by one light receiving side optical waveguide 260Y as in the present embodiment. In addition, even if light is received by one light receiving element 290Y, the input position can be detected. That is, it can be constituted by a relatively small number of light sources and light receiving elements, and the entire apparatus can be miniaturized.
[0099]
In each of the sequential operations in the X direction and the Y direction, the optical switches 270X and 270Y on the light emitting side are always in an operating state, and only the optical switches 280X and 280Y on the light receiving side are sequentially in an operating state. Good. In this case, part of the light source light is always emitted from the all-optical switches 270X (i) and 270Y (i) on the light emitting side, and among the plurality of optical switches 280X (i) and 280Y (i) on the light receiving side The light source light emitted by the operating state is detected. Alternatively, the light receiving side optical switches 280X and 280Y may be always in an operating state, and only the light emitting side optical switches 270X and 270Y may be sequentially operated. In this case, the light source light emitted by the one in the operating state among the plurality of optical switches 270X (i) and 270Y (i) on the light emitting side is detected. Even when either of these two methods is adopted, the input position can be detected in the same manner.
[0100]
In the present embodiment, in particular, the light source light emitted from the light source 210 includes light in a specific frequency band that does not interfere with the display light emitted from the display screen 110. Preferably, the light source 210 includes a light emitting element that emits light having a wavelength band other than the visible light frequency band of display light, in other words, the visible light wavelength range (about 400 nm to 700 nm). Yes. Specifically, an infrared LED or the like can be used. With this configuration, the light source light has a specific frequency band that does not interfere with the display light even if it travels in the space on the coordinate input area 202 with the display light from the display screen 110 as described above. This effectively prevents the light source light from being disturbed by the display light within the coordinate input area 202. As a result, stable light detection can be performed on the light receiving means side regardless of the content on the display screen 110.
[0101]
In addition, in the present embodiment, in particular, the photodetector 220 is configured to selectively detect light in the same specific frequency band as the above-described light source light. More specifically, it is configured by including a light receiving element 209 (for example, a photodiode or the like) having sensitivity to light in a specific frequency band. With this configuration, even if the light receiving element 290 receives light in a frequency band different from that of the light source, such as scattered light from the outside, for example, erroneous recognition does not occur and the content on the display screen 110 is not affected. In addition, it is possible to perform very stable light detection.
[0102]
In the present embodiment, the light source 210 and the light detector 220 are not limited to the touch panel substrate 201, and may be provided outside the optical touch panel 200, for example, on one substrate of the electro-optical device 100. More specifically, when the light source 210 is provided outside, the light source 210 can be configured to guide the light from the light source 210 to the light output side optical waveguide 250 via a light guide means such as an optical fiber cable. Even when the photodetector 220 is provided outside, it can be similarly configured in relation to the photodetector 220 and the light receiving side optical waveguide 260. With this configuration, it is possible to save space on the touch panel substrate. Furthermore, by providing the light source outside, it is possible to emit light source light having a relatively high output that is not easily interfered from the outside, and position detection with high accuracy is possible. As described above, it is particularly effective when a transflective optical switch and a half mirror are provided, that is, when a means for branching a part of the light source light halfway a plurality of times is provided.
[0103]
In FIG. 2, for convenience of explanation, the arrangement pitch of the optical switches in the optical waveguide is shown relatively large. However, in practice, the arrangement pitch of the optical switches is preferably narrow. For example, the pitch may be narrower to the pixel pitch or to an integer multiple thereof. By reducing the arrangement pitch of the optical switches, it is possible to increase the resolution related to coordinate input. For example, it is possible to increase the resolution related to coordinate input to the same pixel pitch.
[0104]
(Second Embodiment)
A second embodiment according to the optical touch panel of the present invention will be described below with reference to FIGS. FIG. 5 is a schematic plan view showing a detailed configuration of the optical touch panel according to the present embodiment provided with microlenses. FIG. 6 is a perspective view showing a positional relationship between the light guide side optical waveguide, the optical switch, and the microlens. FIG. 7 is a perspective view showing the positional relationship between the optical waveguide on the light receiving side, the optical switch, and the microlens. FIG. 8 is a plan view showing the relationship between the light emitting side microlens and the light flux. FIG. 9 is a plan view showing the relationship between the microlenses on the light receiving side and the luminous flux.
[0105]
The second embodiment differs from the first embodiment described above in that it further includes a microlens described later. Therefore, the components of the optical touch panel of the first embodiment correspond as they are, and the input position detection method and procedure are the same as those of the first embodiment. Therefore, in the following, a configuration different from the first embodiment will be described. In addition, the same code | symbol is attached | subjected to a common location with 1st Embodiment, and description is abbreviate | omitted.
[0106]
As shown in FIG. 5, the optical touch panel 200 according to the present embodiment includes a plurality of microlenses 301 and microlenses in an area outside the coordinate input area 202 and along the four sides around the coordinate input area 202. 302 is provided. Note that the microlenses provided along the light output side optical waveguides 250X and 250Y are shown as a microlens 301X and a microlens 301Y, respectively, and the microlenses provided along the light reception side optical waveguides 260X and 260Y are respectively shown. , Shown as microlens 302X and microlens 302Y.
[0107]
In particular, as shown in FIGS. 5, 6, and 7, the microlenses 301 and 302 include the above-described light emitting side optical switches 270 </ b> X (i) and 270 </ b> Y (i) and the light receiving side optical switch 280 </ b> X (i ) And 280Y (i), respectively.
[0108]
As shown in FIG. 8, the light exit side microlens 301 is reflected by the light exit side optical switch 270 and diffused due to variations in the refractive index within the reflection surface or drive variations in the light exit side optical switch 270. The light beam is condensed and emitted as a parallel light beam.
[0109]
Accordingly, the light source lights LXi and LYi travel on the coordinate input area 202 as a narrower light flux whose diameter is adjusted to be constant in the traveling direction. For this reason, many light source lights can be advanced on the coordinate input area at relatively short intervals, and the resolution of the optical touch panel according to the present invention can be further increased. Further, the light source light LXi and LYi emitted on the coordinate input area 202 are diffused, so that the light receiving side optical switches 280 that do not correspond to each other (for example, the light receiving side optical switch 280 (2) with respect to the light source light LX1). There is no problem that the light is incident on. In other words, it is possible to compensate for variations in reflection due to the emission-side optical switch 270, and it is possible to maintain highly accurate detection of the input position.
[0110]
On the other hand, as shown in FIG. 9, the microlens 302 on the light receiving side collects the light source lights LXi and LYi, which are parallel light beams that have passed through the coordinate input area 202, with the reflection surface of the light receiving side optical switch 280 as the focal point. Let Then, the light receiving side optical switch 280 receives a thinner light beam and introduces it into the light receiving side optical waveguide 260.
[0111]
Accordingly, it is possible to form a thinner light receiving side optical waveguide. Further, since the light other than the light source lights LXi and LYi is not condensed on the light receiving side optical switch 280 by the micro lens 302, it is possible to prevent erroneous recognition due to, for example, external scattered light.
[0112]
(Third embodiment)
A third embodiment according to the optical touch panel of the present invention will be described below with reference to FIGS. 10 to 12. FIG. 10 is a perspective view showing the overall configuration of the optical touch panel according to the present embodiment provided with a transparent plate member. 11 is a cross-sectional view taken along line HH ′ in FIG. 12 is a cross-sectional view taken along the line VV ′ in FIG.
[0113]
The third embodiment differs from the first embodiment described above in that a transparent plate member is further provided on the coordinate input area 202. Therefore, the components of the optical touch panel of the first embodiment correspond as they are, and the input position detection method and procedure are the same as those of the first embodiment. Therefore, in the following, a configuration different from the first embodiment will be described. In addition, the same code | symbol is attached | subjected to a common location with 1st Embodiment, and description is abbreviate | omitted.
[0114]
As shown in FIG. 10, the optical touch panel 200 according to this embodiment includes a rectangular transparent plate member 400 that is overlaid on the coordinate input area 202.
[0115]
As shown in FIGS. 11 and 12, the light source light LXi and the light source light LYi travel through the space between the touch panel substrate 201 and the transparent plate member 400.
[0116]
Here, as shown in FIGS. 11 and 12, when an arbitrary position is designated by the user by bringing a pen, a finger, or the like into contact with the transparent plate member 400 at a point P in the figure, for example, The transparent plate member 400 is deformed at the position, and the light intensity of the light source light LXi and light source light LYi traveling on the coordinate input area 202 that passes through the point P decreases or becomes zero. . For this reason, the designated position can be specified by detecting the decrease in the light intensity by the light receiving element 290.
[0117]
The transparent plate member 400 can be made of, for example, resin, plastic, glass, or the like.
[0118]
Here, preferably, the transparent plate member 400 according to the present embodiment functions as a dustproof or protective cover. Therefore, for example, it is possible to prevent a problem that an unintended position is erroneously recognized due to dust or the like.
[0119]
In addition, this embodiment is good also as a form by which the transparent plate member 400 was added to the optical touch panel 200 of 2nd Embodiment.
[0120]
As described above, the optical touch panel according to the present invention described in the first to third embodiments can be configured in preparation for an electro-optical device having various display screens such as a liquid crystal device, for example. These electro-optical devices are mounted on various electronic devices such as mobile phones, video phones, and POS terminals.
[0121]
The present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist or concept of the invention that can be read from the claims and the entire specification. An electro-optical device and an electronic apparatus provided with the same are also included in the technical scope of the present invention.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an overall configuration of an optical touch panel according to a first embodiment.
FIG. 2 is a schematic plan view showing the detailed configuration of the optical touch panel according to the first embodiment and the operation of the optical system.
FIG. 3 is a cross-sectional view taken along the line HH ′ of FIG.
4 is a cross-sectional view taken along the line VV ′ of FIG.
FIG. 5 is a schematic plan view showing a detailed configuration of an optical touch panel including a microlens according to a second embodiment.
FIG. 6 is a perspective view showing a positional relationship among an optical waveguide, an optical switch, and a microlens on the light emitting side according to the second embodiment.
FIG. 7 is a perspective view showing a positional relationship among an optical waveguide, an optical switch, and a microlens on the light receiving side according to the second embodiment.
FIG. 8 is a plan view showing a relationship between a light exit side microlens and a light beam in a second embodiment.
FIG. 9 is a plan view showing a relationship between a microlens on the light receiving side and a light beam in the second embodiment.
FIG. 10 is a perspective view showing an overall configuration of an optical touch panel including a transparent plate member according to a third embodiment.
11 is a cross-sectional view taken along the line HH ′ of FIG.
12 is a cross-sectional view taken along the line VV ′ of FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 100 ... Electro-optical device, 110 ... Display screen, 200 ... Optical touch panel, 201 ... Touch-panel board, 202 ... Coordinate input area, 203 ... Half mirror, 210 ... Light source , 220: photodetector, 250: light emitting side optical waveguide, 260 ... light receiving side optical waveguide, 270 ... light emitting side optical switch, 280 ... light receiving side optical switch, 290. -Light receiving element, 301 ... micro lens, 302 ... micro lens, 400 ... transparent plate member, 500 ... input medium

Claims (18)

An optical touch panel having a transparent coordinate input area superimposed on a display screen,
It is arranged along a part of the side of the coordinate input area, and the light source light emitted from the light source intersects the part of the side from a part of the side to the side of the coordinate input area. A light emitting means for emitting light into the coordinate input area toward the first direction toward
Light receiving means for receiving light source light that has traveled in the first direction in the coordinate input area at a position opposite to the light output means across the coordinate input area;
The light receiving means is
A second waveguide disposed along the other part of the side of the coordinate input area, disposed at a position opposite to the light input means across the coordinate input area;
The light source light that is arranged in the second waveguide along the extending direction of the second waveguide and that has traveled in the first direction in the coordinate input region is at least partly of the second waveguide. A plurality of optical coupling means that respectively bend in the direction along the second waveguide from the middle and exit into the second waveguide;
An operation state that is included in each of the plurality of optical coupling means and that bends the light source light that has traveled in the first direction in the coordinate input area at least partially in a direction along the second waveguide, and non-operation that does not bend A second optical switch means selectively switchable to any one of the states;
An optical touch panel, comprising: a light receiving element that receives light source light emitted into the second waveguide at one end of the second waveguide. The light emitting means is
A first waveguide for guiding light source light emitted from the light source along a part of the side;
The light source light arranged along the extending direction of the first waveguide in the first waveguide and guided along a part of the side by the first waveguide, at least partially, 2. The optical touch panel according to claim 1, further comprising: a plurality of optical branching units that respectively bend in the first direction from the middle of the first waveguide and emit the respective light into the coordinate input area. Each of the plurality of light branching means selects at least part of the light source light guided along a part of the side as one of an operation state where the light source light is bent in the first direction and a non-operation state where it is not bent. The optical touch panel according to claim 2 , further comprising first optical switch means that can be switched automatically. The optical touch panel as set forth in claim 3 , wherein the first optical switch unit is sequentially placed in the operating state along a part of the side. Said second optical switching means, optical touch panel according to claim 1, any one of 4, characterized in that the other part the operating state sequentially along the sides. The first optical switch means is sequentially in the operating state along a part of the side,
4. The optical device according to claim 3 , wherein the second optical switch unit is sequentially placed in the operation state along the other part of the side in synchronization with the sequential operation of the first optical switch unit. Touch panel. At least one of the first and second optical switch means includes a reflection means that can selectively switch between a reflection state and a non-reflection state and bends the light source light by reflection in the reflection state. The optical touch panel as described in any one of Claim 1 to 6 . A plurality of the first waveguides are provided in parallel along a part of the side,
The optical touch panel according to any one of claims 2 to 7, wherein the light source light is separately guided by each of the plurality of first waveguides. A plurality of the second waveguides are provided in parallel along the other part of the side,
The light receiving element, said plurality of second waveguides each for an optical touch panel of the mounting serial to any one of claims 1 to 8, characterized in that separately received. A substrate on which the light emitting means and the light receiving means are formed and occupies the coordinate input area;
A transparent plate member disposed on the substrate, and
The optical touch panel according to any one of claims 1 to 9 , wherein the light source light travels between the substrate and the transparent plate member in the coordinate input region. The light from the light source, at least one of the optical path portion exiting from the optical path portion is incident on the coordinate input region and the coordinate input region, any one of claims 1 to 10, characterized in that it comprises a microlens The optical touch panel as described in 1. The source light is optical touch panel according to any one of claims 1 to 11, characterized in that it comprises a light in a specific frequency band that does not interfere with the display light emitted from the display screen. The optical touch panel according to claim 12 , wherein the light receiving unit is configured to be able to detect light in the specific frequency band. Said light emitting means, optical touch panel according to any one of claims 1 to 13, characterized in that a built-in light source. The source light from an external light source, an optical touch panel according to any one of claims 1 to 14 via the light guiding means, characterized in that it is supplied to the light emitting unit. The light source light from said second waveguide, the optical touch panel according to any one of claims 1 to 15, characterized in that to be supplied to the light receiving element through the light guiding means. The optical touch panel according to any one of claims 1 to 16 , wherein the light source light does not interfere with a surface of the display screen. The optical touch panel according to any one of claims 1 to 17 ,
An electronic apparatus comprising: an electro-optical device having the display screen.

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