JP2013140522A - Coordinate input device and control method thereof and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coordinate input device and a control method thereof and a program capable of precisely detecting coordinates with no error and superior in S/N even in a large scale.SOLUTION: The coordinate input device comprises: a light receiving part and plural light projection parts which are disposed at a corner of a coordinate input effective region; and a reflecting part disposed in a periphery area of the coordinate input effective region to recursively reflect incident light. The plural light projection parts are disposed with a predetermined distance from the light receiving part in a vertical direction with respect to the coordinate input effective region. The plural light projection parts are driven synchronously with the drive timing of the light receiving part. A threshold value is set at a level so that the rising portion and the falling part of a light-shielding portion included in a light quantity distribution obtained by the light receiving part are maintained symmetrically with respect to the center position between the two. An instruction position is calculated based on the pixel number corresponding to the center position between the rising portion and the falling part of the light-shielding portion corresponding to a point crossing at the threshold value with respect to the light quantity distribution.

Description

  The present invention relates to a coordinate input device that calculates a pointing position by a pointing tool for a coordinate input effective area, a control method thereof, and a program.

  A coordinate input device used to control a connected computer or to write characters, figures, etc. by inputting coordinates on a coordinate input surface by pointing with a pointing tool (for example, a dedicated input pen, finger, etc.) Exists.

  Conventionally, various types of coordinate input devices (touch panels and digitizers) have been proposed or commercialized as this type of coordinate input device. For example, a touch panel that can easily operate a terminal such as a PC (personal computer) by touching the screen with a finger without using a special instrument or the like is widely used.

  There are various coordinate input methods such as those using a resistive film and those using ultrasonic waves. As a method using light, a method is known in which a retroreflective sheet is provided outside the coordinate input surface, the light from the light projecting unit is reflected by the retroreflective sheet, and the light quantity distribution is detected by the light receiving unit. (See Patent Document 1). In this method, the direction of the light shielding area shielded by a finger or the like in the coordinate input area is detected, and the light shielding position, that is, the coordinate of the coordinate input position is determined.

  In the configuration of the light projecting unit, in Patent Document 2, a plurality of light sources and lenses are arranged so as to form a fan-shaped light projecting pattern parallel to the detection plane as if light is projected from one virtual point light source. A floodlighting unit is disclosed. With this configuration of the light projecting unit, it is said that an increase in the amount of projected light can be realized efficiently. Moreover, the structure of the light projection part using the same some light source is disclosed by the literature 3. FIG. The configuration of the light projecting unit (light source) is horizontal with respect to the detection surface and in the vicinity of the side of the light receiving imaging lens, and sandwiches either the light receiving imaging lens or the light receiving imaging lens. In this way, light sources are arranged on both sides.

  On the other hand, as a detection unit for detecting the direction and the light shielding position of the light shielding area shielded by a finger or the like in the coordinate input area, a plurality of threshold values corresponding to the distance from the coordinate input surface are compared with the light shielding state, and the instruction state is determined. A technique for detection is disclosed in Patent Document 4.

  Further, Patent Document 5 discloses a configuration in which two light-receiving imaging lenses are arranged for one light-receiving device and a plurality of instruction inputs can be detected.

U.S. Pat. No. 4,507,557 Patent Registration No. 3830121 JP 2002-149329 A Patent Registration No. 3905670 Patent Registration No. 4522113

  The above-described conventional optical coordinate input device has the following problems.

  In the case where a plurality of light sources are arranged, in order for the shade shape of the light shielding to reflect the exact designated position, a single light source constituting the plurality of light sources for the light shielding object arranged at the designated position It is necessary to block light in independent areas where the optical paths from each other do not overlap. For this purpose, it is necessary to design each light projecting lens so that interference does not occur in the light projecting range between the light sources, and the structure becomes complicated and expensive.

  In the case where each of the plurality of light sources is provided with a non-expensive normal projection lens for each of the plurality of light sources, a plurality of light beams from each of the light sources are projected onto a light shielding object arranged at one designated position, and one light shielding object On the other hand, a plurality of light shielding optical paths are formed. In particular, the plurality of light shielding optical paths may be asymmetrical with respect to the original designated position or may be deformed depending on the designated position, particularly in a portion where the light amount is large. Therefore, if the detection threshold is fixed, the shaded shadow does not reflect the exact designated position, and may change depending on the designated position, resulting in a detection error. This shows that the same thing occurs when a plurality of light-shielding optical paths from a plurality of light sources are formed even if the arrangement is as if light is projected from one virtual point light source. Yes. Even if it is arranged as if light is projected from one virtual point light source, when a plurality of LEDs are arranged without arranging a light projection lens, a plurality of light-shielding light paths from the plurality of light sources are formed. The degree increases. Accordingly, there is a possibility that a larger erroneous detection occurs.

  The present invention has been made in order to solve the above-described problems, and is a coordinate input device capable of performing highly accurate coordinate detection without error and having excellent S / N even when the size is increased, and control thereof. The object is to provide a method and a program.

In order to achieve the above object, a coordinate input device according to the present invention comprises the following arrangement. That is,
A coordinate input device for calculating a pointing position by a pointing tool for a coordinate input effective area,
A light receiving means provided at a corner of the coordinate input effective area;
A plurality of light projecting means provided at corners of the coordinate input effective area;
Reflecting means provided around the coordinate input effective region and recursively reflecting incident light;
Control means for controlling driving of the light receiving means and the plurality of light projecting means;
Calculation means for calculating the indicated position of the coordinate input effective area based on a variation in the light amount distribution obtained from the light receiving means when the coordinate input effective area is indicated by the pointing tool;
In the direction perpendicular to the coordinate input effective area, the plurality of light projecting means are arranged at a predetermined distance from the light receiving means,
Of the plurality of light projecting means, the reference light projecting means is arranged at a position where the light projecting position coincides with the optical axis of the light receiving means in the horizontal direction with respect to the coordinate input effective area, and the remaining light projecting means. The plurality of light projecting means are arranged at positions that are line symmetric with respect to the optical axis of the light receiving means,
The control means drives the plurality of corresponding light projecting means in synchronization with the drive timing of the light receiving means, and a rising portion and a falling portion of a light shielding portion included in the light amount distribution obtained from the light receiving means, However, the threshold is set at a level where symmetry is maintained with respect to the center position between the two,
The calculation means calculates the indicated position based on a pixel number corresponding to a center position between a rising portion and a falling portion of the light-shielding portion corresponding to a point that crosses the light amount distribution at the threshold value. .

  According to the present invention, it is possible to provide a coordinate input device, a control method therefor, and a program that can perform coordinate detection with excellent S / N, no error, and high accuracy even when the size is increased.

It is a schematic block diagram of the coordinate input device of Embodiment 1. FIG. 3 is an exploded perspective view of a sensor unit of the coordinate input device according to the first embodiment. FIG. 3 is an external view of a sensor unit of the coordinate input device according to the first embodiment. It is explanatory drawing of the light-receiving part in the sensor unit of the coordinate input device of Embodiment 1. It is a figure which shows the relationship between the pixel number N and angle (theta) in the coordinate input device of Embodiment 1. FIG. FIG. 3 is a block diagram of a control / arithmetic unit of the coordinate input device according to the first embodiment. 3 is a timing chart of light emission of a light projecting unit of the coordinate input device according to the first embodiment. It is a figure which shows an example of the light quantity distribution of the light-receiving part of the coordinate input device of Embodiment 1. It is a figure which shows an example of the time-dependent change of the reflective surface of the retroreflection part of the coordinate input device of Embodiment 1. It is explanatory drawing of the light quantity change in the coordinate input device of Embodiment 1. FIG. It is explanatory drawing of the light quantity change amount and light quantity change rate in the coordinate input device of Embodiment 1. FIG. It is explanatory drawing of the light-shielding part detection in the coordinate input device of Embodiment 1. FIG. It is explanatory drawing of the coordinate calculation in the coordinate input device of Embodiment 1. FIG. 3 is a flowchart illustrating coordinate detection processing in the coordinate input device according to the first embodiment. It is explanatory drawing of the state of the light ray which concerns on a prior art, and received light quantity distribution. It is explanatory drawing of the state of the light ray which concerns on a prior art, and received light quantity distribution. It is explanatory drawing of the state of the light ray which concerns on Embodiment 1, and received light quantity distribution. 6 is a flowchart showing a subroutine process for detecting a pixel corresponding to a designated position by a plurality of threshold values according to the first embodiment. FIG. 5 is an explanatory diagram showing a relationship between a threshold value Vn and Δn in the first embodiment. 10 is a flowchart showing a subroutine process for detecting a pixel corresponding to a designated position by a plurality of threshold values according to the second embodiment. It is explanatory drawing which showed the relationship between the threshold value Vn of Embodiment 2, and (DELTA) mn. It is a block diagram of the sensor unit of the coordinate input device of Embodiment 2. 10 is a timing chart of a light projecting unit of the sensor unit according to the second embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
<Embodiment 1>
<Overview of device configuration>
First, a schematic configuration of an optical coordinate input apparatus according to the present invention will be described with reference to FIG.

  In FIG. 1, reference numerals 2001L and 2001R denote sensor units having a light projecting unit (light emitting unit) and a light receiving unit (detecting unit). This light projecting portion is formed by a plurality of light projecting portions which are the features of the present invention. Details will be described later. In the first embodiment, the horizontal line indicates the X axis, the vertical line indicates the Y axis, and O indicates the intersection coordinates (0, 0) between the X axis and the Y axis. The sensor units 2001L and 2001R are arranged at a predetermined distance away from each other at a position parallel to the X axis and symmetrical to the Y axis of the coordinate input effective area 300 which is a coordinate input surface as shown in the drawing. In other words, the sensor units 2001L and 2001R are provided near both ends (corner portions) of one side of the coordinate input effective area 300.

  The sensor units 2001L and 2001R are connected to the control / arithmetic unit 20, receive a control signal from the control / arithmetic unit 20, and transmit the detected signal to the control / arithmetic unit 20. The control / arithmetic unit 20 controls various processes in the coordinate input device. The coordinate input effective area 300 is an area in which this type of optical coordinate input device can detect the position designated by the pointing tool (finger, input pen, etc.).

  Reference numeral 400 denotes a retroreflective portion, which is arranged in a shape (a U-shape) surrounding the outer three sides of the coordinate input effective area 300.

  Reference numeral 400 denotes a retroreflective unit having a retroreflective surface that recursively reflects incident light in the direction of arrival. The retroreflective unit 400 is arranged on the outer three sides (peripheral parts) of the coordinate input effective area 300, and the light projected from the left and right sensor units 2001L and 2001R in the θ ° (approximately 90 °) range is used as the sensor unit. Retroreflects toward 2001L and 2001R. The light retroreflected by the retroreflecting unit 400 is one-dimensionally detected by the sensor units 2001L and 2001R, and a signal indicating the light amount distribution is transmitted to the control / arithmetic unit 20.

  With this configuration, when an input instruction is given to the coordinate input effective area 300 by the pointing tool, the light projected from the light projecting portions of the sensor units 2001L and 2001R is blocked by the pointing tool (light shielding portion). In this case, in the light receiving portions of the sensor units 2001L and 2001R, it becomes impossible to detect light (reflected light due to retroreflection) only at a portion (light-shielding portion) blocked by the indicator, and as a result, light from which direction Can be identified.

  That is, the control / arithmetic unit 20 detects the light-shielding portion of the portion instructed to be input by the pointing tool from the light amount change detected by the sensor units 2001L and 2001R. The direction (angle) of the light shielding position (designated position) is calculated from the information of the light shielding part. This light-shielding portion detection / calculation method is the main feature of the present invention, which will be described in detail later. Further, the light shielding position (coordinates) is geometrically calculated from the derived direction (angle) and distance information between the sensor units 2001L and 2001R. At the same time, the coordinate value is output to an information processing apparatus such as a PC (personal computer) connected to a display unit (not shown) via an interface such as a USB.

  In addition, as a retroreflective member which comprises the retroreflective part 400, the bead type retroreflective sheet which has a retroreflective characteristic by arranging a spherical bead on a reflective surface is used. Alternatively, a retroreflective sheet or the like that causes a retroreflection phenomenon by regularly arranging the corner cubes that are optical reflection surfaces by machining or the like is used.

  Moreover, the material of the coordinate input surface which comprises the coordinate input effective area | region 300 of FIG. 1 is the display surface of the display apparatus combined with a coordinate input device, Furthermore, the transparent glass plate which is the front plate, or transparent Consists of resin plates. For example, the display device may be a liquid crystal display device, a plasma display device, a rear projection display device or the like, or a configuration in which the coordinate input surface is a projector screen configuration. An integral configuration with this display device makes it possible to use as an interactive input device.

<Detailed description of sensor units 2001L and 2001R>
FIG. 2 is an exploded perspective view of the sensor units 2001L and 2001R, and shows a configuration example of a light projecting unit and a light receiving unit in the sensor units 2001L and 2001R.

  In FIG. 2, reference numeral 30 denotes a light projecting unit, and the light projecting unit 30 includes three unit light projecting units each including an infrared LED (light emitting diode) 31 that emits infrared light and a light projecting lens 32. ing. The light emitted from the infrared LED 31 is projected by the light projecting lens 32 substantially parallel to the surface of the coordinate input effective area 300. At the same time, light is projected in a fan shape in the in-plane direction of the coordinate input effective area 300.

  FIG. 3A is a front view of the sensor units 2001L and 2001R in the assembled state, and the arrows in FIG. 3 indicate the coordinates of the light emitted from the light projecting unit 30 including three unit light projecting units for each unit light projecting unit. A state in which the input effective area 300 is distributed in a fan shape in the in-plane direction is shown. FIG. 3B is a view of FIG. 3A as viewed from the side. Similarly, the light is projected as a light beam restricted in the vertical direction substantially parallel to the surface of the coordinate input effective area 300, and is mainly displayed. FIG. 9 shows a state in which light is projected to the retroreflective portion 400.

  Referring back to FIG. 2 again, reference numeral 40 denotes a light receiving unit. The light receiving unit 40 includes a one-dimensional line CCD 41, a condensing lens 42 as a condensing optical system, a diaphragm 43 that roughly restricts the incident direction of incident light, The infrared filter 44 is configured to prevent the incidence of extra light such as visible light. Then, the light projected by the light projecting unit 30 is retroreflected by the retroreflecting unit 400, passes through the infrared filter 44 and the diaphragm 43, and is collected on the surface of the detection element group in the line CCD 41 by the condenser lens 42. Focused.

  In FIG. 2, 51 is a lower housing and 52 is an upper housing. The aperture 43, the upper housing 52, and the lower housing 51 mainly have a visual field in the height direction (the height direction from the surface of the coordinate input effective area 300) so that only the retroreflected light of the retroreflecting unit 400 passes. Is limiting. The field of view in the in-plane direction of the coordinate input effective area 300 is roughly limited.

  In the first embodiment, the lower casing 51 and the diaphragm 43 are integrally formed with each other, but it goes without saying that these may be formed of separate members.

  Here, the arrangement of the light projecting unit 30 in the entire configuration of the sensor units 2001L and 2001R will be described. As described above, the light projecting unit 30 includes three unit light projecting units. Of the three sets of unit light projecting units, the central unit light projecting unit (infrared LED 31-1 and light projecting lens 32-1) is perpendicular to the coordinate input effective area 300 with respect to the light receiving unit 40. A certain distance away. Further, the positional relationship in the plane (horizontal) direction with respect to the coordinate input effective region 300 is that the light projecting position of the unit light projecting unit (infrared LED 31-1 and light projecting lens 32-1) and the optical function of the light receiving unit 40. The light receiving center (optical axis) is located close to the position (center position of the diaphragm 43) that coincides with the position. Further, among the three unit light projecting units, the unit light projecting units (infrared LED 31-2 and light projecting lens 32-2) on both sides and the unit light projecting unit (infrared LED 31-3 and light projecting lens 32-3) are provided. Are arranged on both side surfaces of the central unit projector (infrared LED 31-1 and projector lens 32-1). In addition, the unit light projecting units (infrared LED 31-2 and light projecting lens 32-2) and unit light projecting units (infrared LED 31-3 and light projecting lens 32-3) on both sides are arranged on the optical axis of the light receiving unit 40. Are arranged in a line-symmetric position.

  As shown in the figure, the light beams from each of the three unit light projecting units in FIG. 3 are projected within a range of approximately 90 ° in the plane direction with respect to the coordinate input effective area 300 without causing any vignetting. It is shining.

  2 and 3 show a configuration in which the light projecting unit 30 is separated from the light receiving unit 40 by a predetermined distance in the vertical direction with respect to the coordinate input effective area 300. However, it is not limited to this configuration. For example, the light projecting unit 30 may be configured to be separated from the light receiving unit 40 by a predetermined distance in the vertical direction in the direction approaching the coordinate input effective area 300.

  FIG. 4 is a diagram for explaining an optical path until light from the light projecting unit 30 of the sensor units 2001L and 2001R is retroreflected by the retroreflecting unit 400 and detected by the line CCD 41 of the light receiving unit 40. In the figure, the same parts as those in FIGS. 2A and 3 are denoted by the same reference numerals.

  4A is a front view seen from the direction perpendicular to the surface of the coordinate input effective area 300, and FIG. 4B is a side view thereof.

  In FIG. 4A, the light of the light projecting unit 30 projected in the substantially 90 ° direction described above is retroreflected by the retroreflecting unit 400 through the light transmitting member. The retroreflected light passes through the infrared filter 44 and the diaphragm 43 and enters the condenser lens 42. The retroreflected light is a pixel of the line CCD 41 according to the incident angle with respect to the condenser lens 42. An image is formed on 45 (see FIG. 4B). Accordingly, since the output signal of the line CCD 41 outputs a light amount distribution corresponding to the incident angle of the retroreflected light, the pixel number of the line CCD 41 indicates angle information.

  Further, in the case of the first embodiment, the light projecting unit 30 and the light receiving unit 40 that is the detection unit are arranged so as to overlap each other in the vicinity with a predetermined distance L (see FIG. 3B). Accordingly, the predetermined distance L is sufficiently smaller than the distance from the light projecting unit 30 to the retroreflective unit 400, and even if the predetermined distance L is present, sufficient retroreflected light is received by the detection unit. The unit 40 can be detected.

  FIG. 5 is a diagram showing the relationship between the pixel number N of the line CCD 41 observed by the light receiving optical system (light receiving unit 40) in the coordinate input device according to Embodiment 1 and the angle θ to be derived. In the figure, the vertical axis represents the angle θ to be derived, and the horizontal axis represents the pixel number of the line CCD 41.

  Here, the normal direction of the line CCD 41 and the symmetry axes βL and βR of the light receiving optical system are made to coincide with each other, and the direction is defined as an angle of 0 °. At this time, if the measurement angle range is small, it is easy to design and manufacture a condensing lens 42 in which the relationship between the pixel number N of the line CCD 41 and the measurement angle θ is, for example, good linearity. However, when the measurement angle range becomes large, it becomes difficult to remove the optical distortion generated at the end of the condenser lens 42, and a large error occurs in the measurement angle.

  On the other hand, the coordinate input device according to the first embodiment displays the handwriting by the pointing tool on the display device by arranging the coordinate input device so as to overlap the display device or the front projector screen. This makes it possible to achieve ease of use like paper and pencil.

Regarding the trend of display devices, the aspect ratio (aspect ratio) of the display area is mainly 4: 3, but the aspect ratio of 16: 9 is becoming widespread as seen in full HD images and the like. In other words, the coordinate input effective area 300 of the coordinate input device also has a horizontally long specification to cope with it. <Description of Control / Calculation Unit 20>
Between the control / arithmetic unit 20 and the sensor units 2001L and 2001R, a CCD control signal for the line CCD 41, a clock signal for the CCD, an output signal of the line CCD 41, and a drive signal of the infrared LED 31 are transmitted and received.

  FIG. 6 is a block diagram showing the configuration of the control / arithmetic unit 20.

  In the figure, 2001L and 2001R are sensor units, 81L and 81R are A / D converters, 82 is a memory, and 83 is a CPU (central processing unit) constituted by a one-chip microcomputer or the like. Further, 84L and 84R are LED drive circuits, 85 is an operation clock generation circuit for CPU control, 86 is an operation clock generation circuit (CLK) for CCD control, and 87 is a serial interface.

  In FIG. 6, the CCD control signal is output from the CPU 83 and performs shutter timing of the line CCD 41, data output control, and the like. The clock for the line CCD 41 is transmitted from the CLK 86 to the sensor units 2001L and 2001R, and is also input to the CPU 83 in order to perform various controls in synchronization with the line CCD 41.

  The LED drive signal is supplied from the CPU 83 to the infrared LEDs 31-1 to 31-3 in the sensor units 2001L and 2001R via the LED drive circuits 84L and 84R.

  Detection signals from the line CCD 41 which is a detection unit in the sensor units 2001L and 2001R are input to the A / D converters 81L and 81R in the control / arithmetic unit 20, and are converted into digital values under the control of the CPU 83. The converted digital value is stored in the memory 82 as necessary, and an angle calculation and further a coordinate value are calculated by a method described later, and the result is sent to an external PC (personal computer) or the like via the serial interface 87. Is output.

<Explanation of light intensity distribution detection>
FIG. 7 is a timing chart of control signals according to the first embodiment. In FIG. 7, reference numerals 91, 92, and 93 denote control signals for controlling the line CCD 41, and the shutter release time of the line CCD 41 is determined by the interval of the Sh signal 91. Is done. The ICGL signal 92 and the ICGR signal 93 are gate signals to the sensor units 2001L and 2001R, respectively, and are signals for transferring the charge of the photoelectric conversion unit in the line CCD 41 to the reading unit.

  An LEDL signal 94 and an LEDR signal 95 are drive signals for the infrared LEDs 31 of the sensor units 2001L and 2001R, respectively. Then, one of the infrared LEDs 31-1 to 31-3 (in this case, the infrared LED 31-2 in the sensor unit 2001L) is turned on in the first cycle of the Sh signal 91. Therefore, the LEDL signal 94 is supplied to the infrared LED 31 through the LED drive circuit (in this case, the LED drive circuit 84L).

  In the next cycle, the other infrared LEDs 31-1 to 31-3 (in this case, the infrared LED 31-2 in the sensor unit 2001R) are turned on. For this purpose, the LEDR signal 95 is supplied to the infrared LED 31 via the LED drive circuit (in this case, the LED drive circuit 84R).

  After the driving of both the infrared LEDs 31-1 and 31-2 is completed, the signal of the line CCD 41 is read from the sensor units 2001L and 2001R.

  For example, when there is no input by the pointing tool, that is, when there is no light-shielding portion, the read signal has a light amount distribution as shown in FIG. 8A as an output from each of the sensor units 2001L and 2001R. .

  FIG. 8 is a diagram showing the relationship between the output level [V] of the line CCD 41 and the CCD pixel number [N]. In the figure, the vertical axis represents the output level [V] of the line CCD 41, and the horizontal axis represents the CCD pixel number [N].

  Of course, such a light quantity distribution is not necessarily obtained in every system. That is, the characteristics of the retroreflective part 400 (retroreflective characteristics depending on the incident angle of the retroreflective part 400), the characteristics of the light projecting part 30 including the infrared LED 31, and changes with time (dirt of the reflection surface of the retroreflective part 400, etc.) Thus, the light quantity distribution changes. Furthermore, the relationship between the light quantity distribution and the configuration of the retroreflecting portion is as described above.

  In FIG. 8A, it is assumed that level A is the level when the maximum light amount is detected, and level B is the level when the minimum light amount is detected. Therefore, in the state where there is no reflected light, the obtained light quantity level is near level B, and the level of light quantity approaches the level A as the reflected light quantity increases. In this way, the detection signal output from the line CCD 41 is sequentially A / D converted by the corresponding A / D converters 81L and 81R, and then taken into the CPU 83 as digital data. The actual light amount distribution is obtained by integrating factors such as the light projecting distribution of the light projecting unit 30, the light receiving distribution of the light receiving unit 40, the reflection characteristics of the retroreflective unit 400, and the distance from the sensor units 2001L and 2001R to the retroreflective unit 400. It will show the distribution of levels. However, here, in order to simplify the explanation, it is schematically shown in a uniform level state.

  FIG. 8B is a diagram illustrating an example of output when input is performed with the pointing tool, that is, when the reflected light of the retroreflecting unit 400 is blocked, and a portion C in FIG. 8 is retroreflected with the pointing tool. Since the reflected light of the part 400 is blocked, the light quantity of only that part is reduced.

  The detection of the light quantity distribution is performed by detecting the change in the light quantity distribution. Specifically, first, an initial state without input (hereinafter, data obtained in the initial state is initial data) as shown in FIG. 8A is stored in the memory 82 in advance, and is obtained in each sample period. The difference between the stored data and the initial data stored in the memory 82 is calculated. Then, based on the calculation result, it is determined whether or not there is a change as shown in FIG.

  The above description of the light amount distribution in FIGS. 8A and 8B is a case where the light projecting unit 30 includes a pair of infrared LEDs 31 and a light projecting lens 32 for the sake of simplicity. A case where the unit is constituted by three sets of unit light projecting units each including the infrared LED 31 and the light projecting lens 32 according to the present invention will be described after a description of a single light shielding portion detection.

<Description of angle calculation>
In calculating the angle, first, it is necessary to detect a light shielding portion.

  As described above, since the light quantity distribution is not constant due to a change with time or the like, it is desirable to store the aforementioned initial data in the memory 82 at the time of starting the system. That is, when initial data is set at the time of shipment from a factory or the like and the data is not updated sequentially, for example, when dust adheres to the reflection surface of the retroreflective unit 400 at a predetermined position, retroreflection at that part is performed. Efficiency is reduced.

  Therefore, the saddle causes a serious result that the coordinate input operation is performed at the position (direction seen from the sensor units 2001L and 2001R), that is, erroneous detection is performed. Therefore, by storing initial data in the memory 82 at the time of starting the system or the like, even if the reflection surface of the retroreflective unit 400 is contaminated with dust or the like over time and the retroreflective efficiency is lowered, the state is set as the initial state. Since it can be set again, malfunctions can be eliminated.

  Of course, if the signal from the retroreflective unit 400 cannot be received at the part where the dust is attached, the coordinate cannot be detected, and the dust or the like must be removed by some method. However, if the optical signal from the retroreflecting unit 400 is greatly reduced, the signal reliability is reduced due to the S / N ratio (for example, although the same point is indicated). A phenomenon in which the coordinates fluctuate, and the coordinate calculation resolution is reduced).

  Now, when the power is turned on, there is no input (no light-shielding portion), and in the state where the light projection from the light projecting unit 30 is stopped, the output of the line CCD 41 is A / D converted by the A / D converters 81L and 81R. After D conversion, this value is stored in the memory 82 as Bas_data [N]. This value is data including variations in the bias of the line CCD 41, and is data near level B in FIG. Here, [N] is the CCD pixel number of the line CCD 41, and a pixel number corresponding to an effective input range is used.

  Next, the light amount distribution in a state where light is projected from the light projecting unit 30 is stored. This is data represented by a solid line in FIG. 8A and is stored in the memory 82 as Ref_data [N]. This completes the storage of two types of data as initial data.

  Then, using Bas_data [N] and Ref_data [N] stored in the memory 82, first, the presence / absence of an input by the pointing tool and the presence / absence of a light shielding portion are determined.

  Here, the pixel data of the Nth pixel within the sample period of the output of the line CCD 41 is Norm_data [N].

  First, in order to specify the light-shielding portion, the presence / absence of input by the pointing tool is determined based on the absolute amount of data change. This is to prevent erroneous determination due to noise or the like and to detect a certain amount of reliable change. Specifically, the absolute amount of change in the pixel data is calculated by the following equation (1) for each pixel of the line CCD 41 and compared with a predetermined threshold value Vtha.

Norm_data_a [N] = Norm_data [N] − Ref_data [N] (1)
Here, Norm_data_a [N] corresponds to the absolute change amount in each pixel.

  Since this process only calculates the absolute change amount Norm_data_a [N] of each pixel of the line CCD 41 and compares it with the threshold value Vtha, the processing time can be shortened and the presence / absence of input can be determined at high speed. It is. Then, when the number of pixels exceeding the threshold value Vtha for the first time is detected exceeding a predetermined number, it is determined that there is an input from the pointing tool.

  Next, a method for determining the input point by calculating the change ratio of the pixel data in order to detect with higher accuracy will be described.

  FIG. 9 is a diagram illustrating a retroreflective surface of the retroreflective unit 400. In the figure, reference numeral 910 denotes a reflecting surface of the retroreflecting unit 400, and 911 denotes an indicator. Here, assuming that the reflectance of the region (10) of the reflecting surface 910 is reduced due to dirt or the like, the distribution of Ref_data [N] at this time is as follows. Less.

  FIG. 10 is a diagram showing the relationship between the output level [V] of the line CCD 41 and the CCD pixel number [N], as in FIG. In the figure, the vertical axis represents the output level [V] of the line CCD 41, and the horizontal axis represents the CCD pixel number [N].

  In the state of FIG. 10 (A), if substantially half of the retroreflective portion 400 is covered with the pointing tool 911 as shown in FIG. 9, the amount of reflected light is substantially halved. The distribution Norm_data [N] will be observed. When the above equation (1) is applied to this state, the state is as shown in FIG.

  FIG. 11A is a diagram illustrating the relationship between Norm_data_a [N] and the CCD pixel number [N]. In the figure, the vertical axis indicates Norm_data_a [N], and the horizontal axis indicates the CCD pixel number [N].

  FIG. 11B is a diagram showing the relationship between Norm_data_r [N] and the CCD pixel number [N]. In the figure, the vertical axis indicates Norm_data_r [N], and the horizontal axis indicates the CCD pixel number [N].

  Here, in FIG. 11, the vertical axis represents the differential voltage from the initial state.

  When this pixel data is compared with the threshold value Vtha, there is a case where the original input range is deviated (broken line area in FIG. 11A). Of course, by setting the threshold value Vtha to a smaller value, a certain degree of detection is possible, but the possibility of being affected by noise or the like increases, resulting in a problem that the coordinate calculation performance is degraded.

  Therefore, the light quantity of the light shielding portion blocked by the indicator 911 is the first half of both the area (10) and the area (11) of the reflecting surface 910 (corresponding to the V1 level in the area (10) and equivalent to the level V2 in the area (11)). Therefore, the change ratio is calculated by the following equation (2).

Norm_data_r [N] = Norm_data_a [N] / (Bas_data [N] −Ref_data [N]) (2)
The calculation result of the equation (2) is as shown in FIG. 11B, and the light quantity distribution is represented by the change ratio. Therefore, even when the reflectivity of the retroreflecting unit 400 is different, it can be handled equally.

  A threshold value Vthr is separately set for this pixel data (light quantity distribution). Then, from the pixel number of the rising part and the falling part of the light quantity variation region corresponding to the light shielding part in the light quantity distribution corresponding to the point crossing the threshold value Vthr, for example, the pixel corresponding to the input by the pointing tool at the center of both By doing so, pixel information can be acquired with high accuracy.

  FIG. 11B is schematically drawn for convenience of explanation, and FIG. 12 shows an actual detection signal waveform in detail.

  Now, it is assumed that the rising portion of the light-shielding portion in comparison with the threshold value Vthr exceeds the threshold value Vthr at the Nrth pixel, and is lower than the threshold value Vthr at the Nfth pixel. At this time, as described above, the pixel number Np of the line CCD 41 to be output may be calculated as the median value of the pixel numbers of the rising part and the falling part as shown in the following formula (3). The pixel interval of the line CCD 41 becomes the resolution of the output pixel number.

Np = Nr + (Nf-Nr) / 2 (3)
Therefore, in order to detect with higher resolution, a virtual pixel number crossing the threshold value Vthr is calculated using the data level of each pixel and the data level of the immediately preceding adjacent pixel.

In FIG. 12, the output level of the line CCD 41 with the pixel number Nr is Lr, and the output level of the pixel number Nr-1 is Lr-1. Similarly, the output level of the pixel number Nf is Lf, and the output level of the pixel number Nf-1 is Lf-1. At this time, if the pixel numbers to be detected are Nrv and Nfv, respectively,
Nrv = Nr-1 + (Vthr-Lr-1) / (Lr-Lr-1) (4)
Nfv = Nf-1 + (Vthr-Lf-1) / (Lf-Lf-1) (5)
Can be calculated. According to this calculation formula, a virtual pixel number corresponding to the output level, that is, a pixel number smaller than the pixel number of the line CCD 41 can be acquired. And the virtual center pixel Npv of these virtual pixel numbers Nrv and Nfv is determined by the following equation (6).

Npv = Nrv + (Nfv−Nrv) / 2 (6)
Thus, by calculating the virtual virtual pixel number that crosses the threshold value Vthr of the predetermined level from the pixel number of the pixel of the data level exceeding the threshold value Vthr, the adjacent pixel number, and the data level thereof, the resolution can be further increased. High detection can be realized.

  However, in the case of the light projecting unit 30 composed of a plurality of unit light projecting units according to the present invention, the light beams related to the light shielding from each unit light projecting unit are superimposed, resulting in a complicated light shielding shape. If only the fixed threshold value Vthr is set, there is a possibility that the angle detection includes an error. The means for solving the problem of the present invention will be described later.

<Conversion from CCD pixel number to angle information>
Next, in order to calculate the actual coordinate value of the pointing tool from the center pixel number corresponding to the virtual center pixel indicating the center point of the light shielding portion, it is necessary to convert this center pixel number into angle information.

FIG. 5 is a graph plotting the relationship between the obtained pixel number and the angle θ. When an approximate expression of this relationship (the following expression (7)) is defined,
θ = f (N) (7)
Thus, it is possible to convert the pixel number to θ using this approximate expression (conversion expression).

  In the first embodiment, the light receiving unit 40 in the sensor units 2001L and 2001R is configured by a lens group so that it can be approximated using a linear approximation formula. However, there are cases where it is possible to obtain angle information with higher accuracy by using a higher-order approximate expression due to optical aberrations of the lens and the like.

  Here, what lens group is adopted is closely related to the manufacturing cost. In particular, when correcting optical distortion generally generated by lowering the manufacturing cost of the lens group using a higher-order approximate expression, a certain amount of calculation capability (calculation speed) is required. Therefore, both may be set as appropriate in consideration of the coordinate calculation accuracy required for the target product.

<Description of coordinate calculation method>
FIG. 13 is a diagram illustrating a positional relationship between the sensor unit 2001L and the sensor unit 2001R in the coordinate input device according to the first embodiment. It is assumed that the coordinate input effective area 300 is arranged with the X axis in the horizontal direction, the Y axis in the vertical direction, and the center of the coordinate input effective area 300 at the origin position. Then, the sensor unit 2001L and the sensor unit 2001R are attached symmetrically with respect to the Y axis on the left and right sides of the upper side of the coordinate input effective area 300, and the distance between the sensor units 2001L and 2001R is Ds.

  Further, as shown in the drawing, the light receiving surfaces of the line CCDs 41 of the sensor units 2001L and 2001R are arranged such that the normal direction forms an angle of 45 ° with the X axis, and the normal direction is 0 ° (reference Direction). At this time, the sign of the angle is the clockwise direction in the case of the sensor unit 2001L arranged on the left side, and the counterclockwise direction in the case of the sensor unit 2001R arranged on the right side. The direction of is defined as the “+” direction.

  Furthermore, Po in the figure is the position of the intersection of the sensor units 2001L and 2001R in the normal direction, and the distance from the origin in the Y-axis direction is defined as Poy. At this time, if the angles obtained by the respective sensor units 2001L and 2001R are θL and θR, the coordinates P (x, y) of the point P to be detected (= the position of the pointing tool 911) are expressed by the following equation (8). , (9).

x = Ds / 2 * (tanθR-tanθL) / (1-(tanθR * tanθL)) (8)
y = Ds / 2 * (tanθR + tanθL + (2 * tanθR * tanθL)) /
(1-(tanθR * tanθL)) + Poy (9)
<Description of coordinate calculation processing flow>
Next, a series of processing steps of the coordinate input device according to the first embodiment will be described with reference to FIG.

  FIG. 14 is a flowchart illustrating a coordinate calculation process from data acquisition to coordinate calculation of the coordinate input device according to the first embodiment.

  When the power is turned on, first, in step S1801, various initializations relating to the coordinate input device such as port setting and timer setting of the CPU 83 are performed. Next, in step S1802, a CCD pixel effective range of the line CCD 41, which is a light receiving element to be described later, is set by reading from a setting value stored in advance in the memory 82, for example. Next, in step S1803, the initial reading count of the initial reading operation of the line CCD 41 is set.

  This initial reading operation is an operation for removing unnecessary charges from the line CCD 41 when the coordinate input device is activated. In the line CCD 41, unnecessary charges may be accumulated when the line CCD 41 is not operated. If the coordinate input operation is executed in a state where the charges are accumulated, detection becomes impossible or erroneous detection is caused. . Therefore, in order to avoid this, in step S1804, a predetermined number of reading operations are executed in a state where the light projection by the light projecting unit 30 is stopped. Thereby, unnecessary charges are removed.

  In step S1805, it is determined whether the number of readings has reached a predetermined number. If the number of readings has not reached the predetermined number (NO in step S1805), the process returns to step S1804. On the other hand, if the number of readings has reached the predetermined number (YES in step S1805), the process proceeds to step S1806.

  In step S1806, pixel data (Bas_data [N]) of the line CCD 41 in a state where the light projection by the light projecting unit 30 is stopped is taken as base data. In step S 1807, the base data is stored in the memory 82.

  In step S1808, pixel data (corresponding to an initial light amount distribution: Ref_data [N]) of the line CCD 41 in a state where light is emitted from the light projecting unit 30 is fetched as reference data. In step S 1809, the reference data is stored in the memory 82.

  The processing so far is the initial setting operation when the power is turned on. It goes without saying that this initial setting operation may be configured to operate according to the operator's intention using a reset switch or the like configured in the coordinate input device. After this initial setting operation, a transition is made to a normal take-in operation state for inputting coordinates with the pointing tool.

  In the normal capture operation, first, in step S1810, the normal capture operation of the line CCD 41 is executed in the coordinate input sampling state to capture pixel data (Norm_data [N]). Next, in step S1811, a difference value between the memory data (reference data Ref_data [N]) and the pixel data (Norm_data [N]) is calculated. In step S1812, based on the difference value and the threshold value Vthp, it is determined whether or not there is a light shielding portion, that is, whether or not there is a coordinate input. If it is determined that there is no coordinate input (NO in step S1812), the process returns to step S1810.

  Note that the threshold value Vthp for determining the presence / absence of the light-shielding portion may be the same as the above-described threshold value Vthr, or may be provided with another value.

  On the other hand, if it is determined that there is a coordinate input (YES in step S1812), the process proceeds to step S1813, and the ratio of change in pixel data is calculated using equation (2). Next, in step S1814, a plurality of threshold values Vthn different from the threshold value Vthp are used for the calculated pixel data change ratio, and the falling portion and the rising portion of the pixel data distribution corresponding to the light shielding portion by the pointing tool are used. Part detection. Then, a virtual center pixel number that is the center of the light-shielding portion is calculated using the detected falling portion and rising portion and equations (4), (6), and (7).

  In addition, in step S1814, the slope (differential value) of the rising portion and the falling portion of each of the plurality of threshold values Vthn is calculated at the same time, thereby calculating the center pixel number at the optimum threshold value Vthn. The processing for the light-shielding part in step S1814 is the main part of the present invention and will be described in detail later.

  In step S1815, for example, Tanθ is calculated from the calculated center pixel number using an approximate expression (Expression (7)).

  In step S1816, the input coordinate P (x, y) of the pointing tool is calculated using Tan θ calculated for the sensor units 2001L and 2001R and the equations (8) and (9).

  In step S1817, the calculated coordinate value is transmitted to the external terminal. This transmission may be performed using an arbitrary communication interface such as serial communication such as USB or RS232C. Then, after the transmission process in step S1817 is completed, the process returns to the process in step S1810, and thereafter, this process is repeated until the power is turned off or a reset state is set according to the operator's intention.

  If the repetition cycle is set to about 10 [msec], the coordinate input device according to the first embodiment can output the coordinates designated by the pointing tool 911 to the external device or the like at a cycle of 100 times / second. .

  As described above, according to the coordinate input device according to the first embodiment, the difference between the maximum light amount and the minimum light amount of the detection signal waveform can be reduced, so that the coordinate calculation resolution of the coordinate input device is significantly improved. be able to.

<Explanation of Projection Unit and Light Distribution Consisting of Multiple Unit Projection Units Characteristic of the Present Invention>
Here, a light projecting unit composed of a plurality of unit light projecting units, a state of a light beam by the light projecting unit, and a received light amount distribution as a result will be described.

  First, the basic configuration of the light projecting unit 30 shown in FIG. 15 will be described. Here, the retroreflected light from the retroreflective unit 400 is a light shielding state when the pointing tool 911 indicates the light path detected by the light receiving unit 40 of the sensor unit 2001R, and the pixel number corresponding to the indicated position from the light shielding state. The calculation will be described in detail in addition to the above description. First, by explaining the basic structure of the conventional light projecting, the characteristics of the light projecting unit of the present invention to be described later will be clarified.

  FIG. 15A shows an optical path in the surface direction of the coordinate input effective area 300 with respect to the simple light projecting unit 30 configured by one set of unit light projecting units instead of the three unit light projecting units shown in FIG. The state is shown in a plan view. The light beam from the infrared LED 31-1 is collimated by the light projecting lens 32-1 in the direction perpendicular to the surface of the coordinate input effective region 300 and substantially parallel to the surface of the coordinate input effective region 300 as described above. On the other hand, in the direction parallel to the surface of the coordinate input effective area 300, the light is radiated in a substantially radial direction at least ± 45 ° with respect to the front direction. In FIG. 15A, the position of the infrared LED 31-1 is indicated by L1. The reflection positions Q and R with respect to the retroreflective portion 400 are defined only for the boundary of the light ray shielded by the indicator 911 (hereinafter, cross-sectional circle display) schematically shown in a circular cross-section in the optical path radiated from there. It is shown by the line segment which connects.

  For the sake of explanation, the position where the line connecting the center portion of the pointing tool 911 and the position L1 of the infrared LED 31-1 intersects with the retroreflective portion 400 is indicated by P. Further, the light receiving reference position when the light beam retroreflected by the retroreflecting unit 400 is condensed on the pixels of the line CCD 41 through the light receiving unit 40 (infrared filter 44, diaphragm 43 and condenser lens 42) is stopped. 43. In the present invention, the position L1 of the infrared LED 31-1 in FIG. 15A and the diaphragm 43, which is the reference position of the light receiving unit 40, are shown at the same position on the plane.

  Accordingly, the light shielding portion blocked by the indicator 911 by the light beam from the position L1 of the infrared LED 31-1 is the shadow boundary when the indicator 911 (cross-sectional circle display) blocks the light, and the shadow boundary is indicated by the indicator 911 (cross-sectional circle display). This is indicated by line segments L1Q and L1R which are two tangent lines formed by a circle indicating L and a line segment L1. As described above, since the reference position of the light receiving unit 40 is L1 similarly to the light projecting unit 30, both the line segments L1Q and L1R have the same optical path when they are recursively reflected from the light projection and received by reciprocation. I understand that

Further, the angles ∠PL1Q and ∠PL1R related to the center of the pointing tool 911 (indicated by a cross-sectional circle) at this time are expressed by the following equation (10).
∠PL1Q = ∠PL1R (10)
It is self-explanatory geometrically. This does not change even if the incident angle of the light beam on the retroreflective portion 400 changes, that is, even if the positional relationship between the pointing tool 911 (cross-sectional circle display) and the sensor unit 2001R changes.

  The received light amount distribution at the line CCD 41 at this time is shown in FIG. A portion indicated by C in the figure is a light shielding portion. The central pixel of two pixels that intersects the threshold value V1 shown in the figure with respect to the falling part and the rising part of the light shielding part is indicated by O in the figure. This threshold value may be the same as the threshold value for determining the presence or absence of light shielding, that is, the pen-down determination by the pointing tool, or may be a value set separately for detection of the pixel number at the indicated position.

  In the present invention, this threshold value is set intermittently when V0 is the baseline where the light amount of the received light amount distribution in the figure is zero. For example, in the first embodiment, as shown in the drawing, V1, V2, V3, V4, V5 and threshold values that increase with respect to V0 with a constant width are set. Here, the following detection process is performed at the smallest value V1. The process of sequentially increasing the threshold value according to the present invention will be described later. Further, the threshold value V (V0 to V5) shown here is actually the threshold value Vthr with respect to the ratio of the change in the amount of received light, which is represented by the equation (2) described with reference to FIG. That is, the threshold value Vthr is originally a value that should be indicated by a ratio of what percentage.

  Therefore, the values of the threshold values V1 to V5 in FIGS. 15 to 17 below are indications indicating the relative value level only in the light amount distribution of each figure. Accordingly, the value of the threshold value V between the drawings is not equivalent, and the threshold value is a relative standard within each component, and the absolute value of the light amount distribution indicates a standard for comparing the light amount between the components. . The meaning of the light amount distribution absolute value is to compare the substantial light amount due to the difference in the configuration in FIGS. 15 to 17.

  As described above, since the optical paths when the light is reflected retroreflected from the light projections indicated by the line segments L1Q and L1R are overlapped and become the same, the falling and rising portions of this shading are not misaligned on the light beam, and clearly A simple edge state close to a straight line is shown.

In addition, the pixel width from the rising portion pixel crossing the threshold value V1 to O is WL1, and the pixel width from the falling portion pixel crossing the threshold value V1 to O is WR1. Here, as described above, since the pixel number in the figure is uniquely associated with the angle with respect to the light receiving unit 40, ∠PL1Q corresponds to the pixel width WL1, and ∠PL1R corresponds to the pixel width WR1. And from the above equation (10),
WL1 = WR1 (11)
It turns out that it is. That is, the position of the center point O of the pointing tool 911 (cross-sectional circle display) that is the original detection angle intersects the threshold V1 shown in the figure with respect to the light-shielding portion C with respect to the falling portion and the rising portion. It can be seen that it can be calculated accurately by detecting the center pixel O of one pixel. At this time, it is understood that the threshold value V is as large as possible with respect to the ground level (zero light amount) V0 of the light amount portion in order to perform detection without affecting noise.

  Therefore, for example, in this case, in an environment where noise equivalent to the threshold value V1 exists, an error occurs in detection, so that it is necessary to increase the level of the entire detected light amount distribution. Alternatively, when the coordinate input device is made larger, the detected light amount is reduced by increasing the distance between the sensor units 2001L and 2001R and the retroreflective unit 400, and thus the level of the entire detected light amount distribution is similarly increased. The need to come out. That is, when the sensor units 2001L and 2001R are configured by the simple light projecting unit 30 configured by the conventional unit light projecting unit, this noise (S / N) and an increase in size are dealt with. You can't do it.

  FIG. 16 shows a case where two unit light projecting units are arranged side by side as the light projecting unit 30 in order to increase the amount of light. However, this configuration is not yet a configuration example of the present invention. In FIG. 16, as the unit light projecting unit on the right side toward the unit light projecting unit (infrared LED 31-1 and light projecting lens 32-1) in FIG. 15, infrared LED 31-2 and light projecting lens 32- 2 is arranged in the vicinity of the horizontal direction of the light receiving unit 40 at a predetermined distance. Similarly to the case of FIG. 15, the position of the light emitting portion of the infrared LED 31-2 is L2.

  In the case of this configuration, in addition to the light rays in the case of FIG. 15, light rays from the light emitting portion L2 are added, and the light shielding portion blocked by the indicator 911 (cross-sectional circle display) with the light rays from the position L2 of the infrared LED 31-2 is It becomes as follows. That is, the light-shielding part before reflection relating only to the light emitting part L2 is a circle and a line segment L2 indicating the indicator 911 (cross-sectional circle display) that is a shadow boundary when the indicator 911 (cross-sectional circle display) is shielded. This is indicated by line segments L2S and L2T, which are two tangent lines formed by. Here, this merely indicates the optical path to the point where the light beam projected from the position L2 is blocked by the indicator 911 and reaches the reflecting surface 910.

  How the reflected light is detected by the light receiving unit 40 will now be described. First, the line segment L2S is reflected at the point S, but the retroreflected light in the correct sense here returns the line segment L2S along the same optical path and returns to the position L2 of the infrared LED 31-2. become. However, since the actual light receiving unit 40 is not located at the position L2, but is located at the position L1, the light beam in the optical path L2S is not detected. Then, the point returns to the point S on the reflecting surface 910 again. The reflection that occurs here is basically a retroreflection.

  Retroreflective is a phenomenon in which the reflected light returns in the incident direction. Actually, the reflected light is generated although the amount of light slightly decreases even in a direction slightly deviated from the incident angle direction. To do. The angle direction slightly deviated from the incident direction is called an observation angle. Depending on the structure and characteristics of the retroreflective portion 400, the reflected light quantity of 50 with respect to 0 ° (incident direction) is approximately 0.2 ° or less. Generally, it is possible to obtain a reflected light amount of% or more. Now, let d be the distance between the position L2 of the infrared LED 31-2 that is the light source of the unit light projecting unit additionally arranged in this configuration and the position L1 of the infrared LED 31-1 that is the original light source. In this case, if the distance L between the light projecting unit 30 and the light receiving unit 40 is sufficiently smaller than d, the observation angle depends on the distance L and the distance between the sensor unit 2001R and the reflecting surface 910.

  Therefore, if the distance between the sensor unit 2001R and the reflecting surface 910 is sufficiently large, the observation angle can be set within 0.2 °. This is an element to be considered when designing the configuration of the entire apparatus of the present invention, but this condition is more easily realized especially when the apparatus is enlarged. When the observation angle is configured to be sufficiently small, a considerable amount of light indicated by the optical path SL1 reflected from the light source L2 to the point S of the reflection surface 910 toward the position L1 of the light receiving unit 40 is received. The

  However, although the light receiving angle of the optical path SL1 is a light beam due to light shielding on substantially the same side of the same indicator 911 (displayed in a cross-sectional circle), the light receiving unit 40 detects the incident angle different from the optical path QL1, that is, a different pixel position. Is done. Since the reflected light at the reflection position above the point S that is the reflection position is superimposed on the reflected light from the position L1 and received by the light receiving unit 40, the amount of received light is smaller than that of the configuration of FIG. To increase. Since the reflected light from the point S that is the reflection position to the point Q that is the reflection position is only the light beam projected from the position L1 of the infrared LED 31-1 that is the light source, it is equivalent to the configuration of FIG. This is the amount of light received. Actually, the received light amount distribution related to the reflected light from the point S which is the reflection position to the point Q which is the reflection position includes a slight amount of diffracted light in the indicator 911 and shows a gradual change.

  Further, regarding the other optical path L2T which is a light shielding beam with respect to the indicator 911, if the reflected light to the light receiving unit 40 similar to QL1 is considered, the return optical path is TL1, but of course the return optical path TL1 is indicated. It is blocked by the tool 911 and does not reach the light receiving unit 40. Therefore, in the figure, L2T and TL1 are indicated by broken lines as optical paths that do not actually exist. All the reflected light from the point T to the point R, which is the reflection position related to the position L2 of the infrared LED 31-2 as the light source, is blocked by the pointing tool 911 and does not reach the light receiving unit 40. The reflected light from the position L2 of the infrared LED 31-2 at the point R that is the reflection position is the same as the return optical path of the retroreflected light from the position L1 of the infrared LED 31-1 in FIG. 40. At this time, the reflected light of the forward optical path L2R and the return optical path RL1 is the same as that of the forward optical path L2S and the return optical path SL1, and the original reflected light Compared with the retroreflected light corresponding to the distance, the received light amount of 50% or more can be superimposed and increased.

  The received light amount distribution at the line CCD 41 at this time is shown in FIG. A portion indicated by C in the figure is a light shielding portion. The central pixel of the two pixels that intersects the lowest threshold value V1 shown in the figure with respect to the falling part and the rising part of the light shielding part is indicated by O in the figure. Compared to the case of FIG. 15B, the shape of the light shielding part is such that the light shielding width changes in the light shielding depth direction and the light shielding part is symmetric with respect to the center pixel O, but the shallow part. (Threshold values V2 to V3) are asymmetric. As shown in FIG. 16A, this is a result of the overlapping state of the optical paths of the position L1 of the infrared LED 31-1 and the position L2 of the infrared LED 31-2 related to the indicator 911.

  That is, the light-shielding portions corresponding to the points Q to P that are the reflection positions of the reflection surface 910 are indicated by the pixel width WL1 from the rising portion pixels crossing the threshold value V1 to O in FIG. Similarly, the light-shielding portion corresponding to the points P to R that are the reflection positions of the reflecting surface 910 is indicated by the pixel width WR2 from the rising pixel crossing the threshold value V1 to O in FIG. The pixel width WL1 and the pixel width WR2 are the same because symmetry is maintained with respect to the center O of the pointing tool 911 as in the case of FIG.

  However, as described above, with respect to the pixel width WL1, in the light shielding boundary region corresponding to the point Q, the light shielding is performed only by the amount of light emitted from the position L1, so that the threshold V1 is the same as in the case of FIG. The light shielding boundaries intersect and are detected. On the other hand, in the light-shielding boundary region related to the point R, the light is blocked by the amount of light that includes the light projection from the position L1 and the light projection from the position L2.

  Therefore, the optical paths when light is reflected retroreflected from the light projections indicated by the line segment L1Q and the line segment L1R overlap, and the falling edge of the light shield has no deviation on the light beam and is a simple edge close to a clear straight line. Indicates the state. Therefore, as can be seen from the figure, the light shielding boundary intersects and is detected at the threshold value V3 larger than the threshold value V1.

  The light shielding portion corresponding to the points Q to S which are the reflection positions on the opposite side is indicated by the pixel width WL2 in FIG. The amount of light at this light-shielding portion is reached only from the position L1, and the light from the position L2 is blocked by the indicator 911 (indicated by a cross-sectional circle). is there. Actually, since there is light that circulates around the pointing tool 911 (indicated by a cross-sectional circle), even with the pixel width WL2, the amount of light increases as it approaches the end of the light shielding portion. In the light amount distribution corresponding to the point S that is the reflection position, as described above, the light amounts of the light projection from the position L1 and the light projection from the position L2 are superimposed, so that the point R that is substantially the reflection position. The same amount of light can be obtained. That is, for the purpose of increasing the amount of received light only, the S / N can be improved by detecting the threshold V3 at the pixel positions corresponding to the points S and R which are the reflection positions.

  However, when the center of the pixel that intersects each of the rising portion and the falling portion of the light shielding portion is detected by the threshold value V3, the center of the pixel width defined by WR1 + WL1 + WL2 is detected. The detected pixel detected in this case is a pixel different from the pixel O corresponding to the point O that is the designated position of the original pointing tool 911 (cross-sectional circle display), and a detection error occurs. As can be seen from FIG. 16B, when the two sets of unit light projecting units shown in FIG. 16A are configured, the light projecting from only the position L1, such as the points Q to S, which are reflection positions, This region occurs on one side with respect to the point P that is the reflection position. Then, this generates a light-shielding portion that is asymmetric with respect to the original detection pixel as shown in FIG.

  Therefore, in order to calculate the original accurate designated position from the light-shielding portion of FIG. 16B, it is necessary to perform the following processing. That is, it is necessary to detect a pixel that intersects the falling portion and the rising portion of the light-shielding portion with the threshold value V1 instead of the threshold value V3, and to calculate the center pixel (black circle in the figure) having a pixel width defined by them. is there. However, this is the same as in the case of FIG. 15 in terms of S / N, that is, the amount of light, and the original purpose cannot be achieved.

  FIG. 17 is Embodiment 1 of the present invention. In the first embodiment, three light projecting units are arranged side by side as the light projecting unit 30 in order to increase the amount of light. More specifically, centering on one unit light projecting unit, the two unit light projecting units are symmetrical with respect to the optical axis of the light receiving unit 40 in the direction parallel to the surface of the coordinate input effective area 300. They are arranged equidistant from each other on the left and right. That is, on the side opposite to the unit projector (infrared LED 31-2 and projector lens 32-2) having the configuration shown in FIG. 16, the unit projector (infrared LED 31-3 and projector lens 32-3) is axisymmetric. ). The position of the infrared LED 31-3, which is the light source, is L3, and the description regarding the position L1 and the position L2 common to FIG.

  With respect to the light beam from the position L3 of the infrared LED 31-3, the light shielding portion blocked by the indicator 911 (indicated by a cross-sectional circle) is as follows. That is, the light-shielding part before reflection related only to the projection from the position L3 of the infrared LED 31-3 is the indicator 911 (cross-sectional circle display) that is the boundary of the shadow when being shielded by the indicator 911 (cross-sectional circle display). ) And two line segments L3U and L3Z which are two tangent lines formed by the line segment L3. Here, this only shows the optical path to the point where the light beam projected from the position L3 of the infrared LED 31-3 is blocked by the indicator 911 and reaches the reflecting surface 910.

  How the reflected light is detected by the light receiving unit 40 will now be described. First, regarding the line segment L3U, it is reflected at the point U, but the retroreflected light in the correct sense here returns the line segment L3U along the same optical path and returns to the position L3 of the infrared LED 31-3. become. However, since the actual light receiving unit 40 is not at the position L3 but at the position L1, the light beam in the optical path L3U is not detected. Therefore, the point returns to the point U on the reflecting surface 910 again. Here, as in the case of FIG. 16, the distance between the position L3 of the infrared LED 31-3 and the position L1 of the original infrared LED 31-1 of the unit light projecting unit additionally arranged in this configuration is d. .

  Therefore, if the distance L between the light projecting unit 30 and the light receiving unit 40 is sufficiently smaller than the distance d, the observation angle depends on the distance L and the distance between the sensor unit 2001 and the reflecting surface 910. Similarly to the case of FIG. 16, when the observation angle is configured to be sufficiently small, the light that has reached the point U on the reflection surface 910 from the position L3 of the infrared LED 31-3 is red in the light receiving unit 40. A considerable amount of light in the optical path UL1 reflected toward the position L1 of the outer LED 31-1 is received.

  However, the light receiving angle of the optical path UL1 is detected by the light receiving unit 40 at an incident angle different from that of the optical path RL1, that is, at a different pixel position, although it is a light beam due to light shielding on substantially the same side of the same indicator 911 (indicated by a circular cross section). Is done. The reflected light at the reflection position below the point U serving as the reflection position is superimposed on the reflected light from the positions L1 and L2, and is received by the light receiving unit 40. Therefore, the received light is compared with the configuration of FIG. The amount increases. Since the reflected light from the point U being the reflection position to the point R being the reflection position is only the light beam projected from the position L1 of the infrared LED 31-1 and the position L2 of the infrared LED 31-2, The amount of received light is the same as in the case of the 16 configuration. Actually, the received light quantity distribution related to the reflected light from the point U which is the reflection position to the point R which is the reflection position includes a slight amount of diffracted light in the indicator 911 and shows a gradual change.

  Further, regarding the other optical path L2Z which is a light shielding light beam for the indicator 911, if the reflected light to the light receiving unit 40 similar to QL1 is considered, the return optical path is ZL1, but of course the return optical path ZL1 is indicated. It is blocked by the tool 911 and does not reach the light receiving unit 40. Accordingly, in the drawing, L2Z and ZL1 are indicated by broken lines as optical paths that do not actually exist. All the reflected light from the point Z to the point Q, which is the reflection position related to the position L3 of the infrared LED 31-3 that is the light source, is blocked by the pointing tool 911 and does not reach the light receiving unit 40. The reflected light from the position L2 of the infrared LED 31-2 at the point Q that is the reflection position is the same as the return optical path of the retroreflected light from the position L1 of the infrared LED 31-1 in FIG. 40. At this time, the reflected light of the outgoing optical path L3Q and the returning optical path QL1 is the same as that of the outgoing optical path L3U and the returning optical path UL1. Compared with the retroreflected light corresponding to the distance, the received light amount of 50% or more can be superimposed and increased.

  The received light quantity distribution at the line CCD 41 at this time is shown in FIG. A portion indicated by C in the figure is a light shielding portion. The central pixel of the two pixels that intersects the lowest threshold value V1 shown in the figure with respect to the falling part and the rising part of the light shielding part is indicated by O in the figure. As in the case of FIG. 16B, the shape of the light shielding portion is such that the light shielding width changes in the light shielding depth direction, and the portion where the light shielding is deep with respect to the center pixel O is symmetric, but the shallow portion. (Threshold values V4 to V5) are asymmetric. As shown in FIG. 17A, this is because the optical path of the position L1 of the infrared LED 31-1 related to the indicator 911, the position L2 of the infrared LED 31-2, and the position L3 of the infrared LED 31-3 is superimposed. It is a result of the state.

  That is, the light-shielding portions corresponding to the points Q to P that are the reflection positions of the reflection surface 910 are indicated by the pixel width WL1 from the rising pixel that intersects the threshold value V3 to O in FIG. Here, it can be seen that the threshold value for detection increases from the threshold value V1 to the threshold value V3 as compared to the case of FIG. In FIG. 16B, the light beam QL1 to the position L1 of the light receiving unit 40 is only projected from the position L1, whereas in FIG. 17B, the light projection path from the position L3. This is because the L3Q reflected light is superimposed and the light quantity is increased. As described above, in the case of the configuration of the first embodiment, an accurate indication position is calculated at the threshold V3 higher than the conventional threshold V1 and the midpoint between the intersections of the rising and falling portions (circles in the figure). Therefore, the S / N is excellent or the amount of light can be increased when the size is increased.

  Similarly, the light-shielding portion corresponding to the points P to R that are the reflection positions of the reflection surface 910 is indicated by a pixel width WR1 from the pixel at the rising portion that intersects the threshold value V3 to O in FIG. Again, the threshold value for detection increases from the threshold value V1 to the threshold value V3 as compared to the case of FIG. 16B. The amount of reflected light RL1 is not the same as the amount of light QL1. This is the same as the case of FIG. 16, but because it is equivalent to QL1. The pixel width WL1 and the pixel width WR1 are the same because symmetry is maintained with respect to the center O of the pointing tool 911 as in the case of FIGS. That is, in the case of FIG. 16, regarding the pixel width WL1, in the light shielding boundary region corresponding to the point Q, the light shielding is performed only by the amount of light emitted from the position L1, while in the light shielding boundary region related to the point R, the position L1. The light is blocked by the amount of light obtained by adding light from the position L2 in addition to light from the light.

  On the other hand, in the case of the configuration of FIG. 17, the optical paths at the time of retroreflecting and receiving light from the unit light projecting units on both sides overlap in both line segments L1Q and L1R, which are optical paths that maintain symmetry with respect to the center position. Therefore, the falling part of the light-shielding part has no deviation on the light beam and shows a simple edge state close to a clear straight line.

  A light-shielding portion corresponding to the points Q to S that are reflection positions is indicated by a pixel width WL2 in FIG. The amount of light at this light-shielding portion is reached only by the projections from the position L1 and the position L3, and the projection from the position L2 is blocked by the indicator 911 (indicated by a cross-sectional circle). Is the amount of light. Actually, since there is light that circulates around the indicator 911 (indicated by a cross-sectional circle), even in the pixel width WL2, the light quantity increases as it approaches the end of the light-shielding portion. Same as the case. In the light amount distribution corresponding to the point S that is the reflection position, as described above, the light amount from the position L1, the light amount from the position L2, and the light amount from the position L3 are superimposed, and the level of the threshold V5 is reached. It becomes.

  The light-shielding portion corresponding to the points R to U that are reflection positions is indicated by the pixel width WR2 in FIG. The amount of light in this light shielding portion is reached only by the light projections from the position L1 and the position L2, and the light projection from the position L3 is blocked by the pointing tool 911 (cross-sectional circle display). Is the amount of light. Actually, since there is light that circulates around the indicator 911 (indicated by a cross-sectional circle), even with the pixel width WR2, there is an oblique distribution in which the amount of light increases as it approaches the end of the light shielding portion. In the light amount distribution corresponding to the point U that is the reflection position, similarly to the case of the point S that is the reflection position, the amount of light emitted from the position L1, the light emission from the position L2, and the light amount from the position L3 are superimposed. And reaches the level of the threshold V5.

If the center of a pixel (a circle in the figure) that intersects the rising and falling portions of the light shielding portion is detected by the threshold value V5, the center of the pixel width defined by WL1 + WR1 + WL2 + WR2 is detected. The detected pixel detected in this case is a pixel different from the pixel O corresponding to the point O that is the designated position of the original pointing tool 911 (cross-sectional circle display), and a detection error occurs. Both １７SL1Q corresponding to the reflection points Q to S in FIG. 17A and ∠RL1U corresponding to the reflection points RU to U vary depending on the positional relationship between the sensor unit 2001 and the reflection surface 910. ,Normal,
∠SL1Q ≒ ∠RL1U (12)
It is. Therefore, correspondingly,
WL2 ≒ WR2 (13)
It becomes.

  That is, with respect to the original detection pixel O in FIG. 17B, the pixel width (WL1 + WR1) and the pixel width (WL2 + WR2) generate an asymmetric light shielding portion. Therefore, when the center of the intersecting pixel (circle in the figure) of the rising and falling portions of the light shielding portion is detected by the threshold V5 for the light shielding portion having a pixel width of WL1 + WR1 + WL2 + WR2, the value including an error is detected. Become. Therefore, in order to calculate the original accurate designated position from the light-shielding portion of FIG. 17B, it is necessary to perform the following processing. That is, it is necessary to detect a pixel that intersects the falling portion and the rising portion of the light-shielding portion with the threshold value V3 instead of the threshold value V5, and to calculate the center pixel (black circle in the figure) having a pixel width defined by them. is there. The calculation process for calculating the optimum detection point by changing the threshold value at this time will be described with reference to the flowchart of FIG.

  In particular, FIG. 18 is a flowchart showing details of a subroutine process for detecting a pixel corresponding to a designated position by a plurality of threshold values in step S1814, which is the main object of the present invention, among the steps of the flowchart of FIG. This subroutine is arithmetic processing mainly performed in the CPU 83 in FIG.

  When each detection routine starts, in step 18141, first, the counter for counting the value of the threshold value Vn is returned to n = 1. In step S1842, the table stored in the memory 82 is referred to, and the value of V1 corresponding to n = 1 is input as a threshold value. In step S18143, intersection pixels Ln and Rn (circles in the figure) of the falling part and rising part of the light-shielding part C in FIG. 17 are detected with respect to the input threshold value Vn, and the center from the middle point between the intersections is detected. Pixel Sn is calculated. That is, in the case of n = 1, the intersection pixels L1 and R1 (circles in the drawing) of the falling portion and the rising portion of the light shielding portion C in FIG. 17 are detected with respect to the input threshold value V1, and further, between the intersection points The center pixel S1 is calculated from the middle point.

  Next, in step S18144, the central pixel S1 when n = 1 is stored in the memory 82. In step S18145, differential values DLn and DRn based on a predetermined number of pixels before and after the intersection pixels L1 and R1 of the falling portion and the rising portion, or neighboring pixels are calculated. Then, an absolute value Δn of the difference is calculated.

Δn = | DLn−DRn | (14)
Therefore, when n = 1,
Δ1 = | DL1−DR1 | (15)
To calculate Δ1. Here, the slope corresponds to the difference in the sign of the differential value between the slope of the falling portion and the slope of the rising portion.

  Next, in step S18146, it is determined whether or not Δn, that is, Δ1 when n = 1 exceeds a predetermined value Δe. This predetermined value Δe is selected to be a value at which there is a sufficient difference between the slope of the falling portion and the rising portion of the light shielding portion C in the light amount distribution diagram shown in FIG. In the case of FIG. 17B, Δn = | DLn−DRn | is almost zero in the thresholds V1 to V3, but in the case of the threshold V4, the difference between DL4 and DR4 is remarkably large. FIG. 19 shows the relationship between the threshold value Vn and Δn.

  The reason is as follows. The pixel width (WL1 + WR1) corresponding to the light receiving angle range of ∠PL1Q + ∠PL1R, which is a complete light shielding portion of the pointing tool 911, and the pixel width WL2 corresponding to the light receiving angle range of ∠SL1Q and ∠RL1U described in FIG. This is because the shading depth of the pixel width WR2 is different. That is, the change in the slope of the rising portion and the falling portion becomes large at the boundary between the two light receiving angle ranges, the boundary between WL1 and WL2 and the boundary between WR1 and WR2. Therefore, the difference value of the slope is also maximum at this boundary. Inside the boundary, the midpoint of the rising and falling portions indicates a pixel corresponding to the angle of the correct designated position, but outside the boundary, the midpoint is the correct designated position as illustrated in FIG. The value deviates from.

  A maximum value Δemax of the difference value of the slope is calculated in advance, and Δe is set to a value slightly smaller than this value. The value of Δemax−Δe to be set is calculated in consideration of fluctuations due to the S / N of the device itself, noise environment, etc., even if the difference in the boundary between the thresholds V3 and V4 is affected. To be set.

Next, in step S18146,
Δn <Δe (16)
Whether or not is true. For example, when n = 1, from the setting of Δe,
Δ1 <Δe (17)
It is. In this case (YES in step S18146), the process proceeds to step S18147. In step S18147, n is incremented by 1, and the process returns to step S18142.

  From the description in FIG. 17A and FIG. 17B, Δn <Δe when n = 1 to 3, and thus Step S18142 to Step S18146 are repeated.

  On the other hand, in the case of n = 4, since the fluctuation of the rising part and the falling part occurs as described above, Δ4> Δe. In this case (NO in step S18146), the process proceeds to step S18148.

  FIG. 19 shows the relationship between the thresholds V1 to V4 at n = 1 to 4 in this series of processing and the threshold V5 and Δe that do not appear in this processing. The center pixel S4, which is the midpoint between the threshold value V4 at n = 4 and the intersection pixels L4 and R4 at the rising and falling parts, includes an error, and the center pixel S3 with respect to the threshold value V3 at n = 3 is the correct designated position. . In addition, since the pixel is an intersection pixel where the light amount level is higher than the threshold values V1 and V2, the S / N is large. Accordingly, in step S18148, the central pixel S3 of n = 3, which is n-1 with respect to n = 4, is acquired from the memory 82 and used as a detection point (pixel corresponding to the designated position). Thus, the subroutine processing for detecting the pixel corresponding to the designated position by the plurality of threshold values is completed.

  In addition, although the value of several threshold value Vn has demonstrated in five steps of the threshold values V1-V5 above, you may increase or decrease a level more than this. By increasing the level of the threshold value Vn, it is possible to calculate the pixel at the indicated position with higher accuracy and greater light quantity. On the other hand, by reducing the threshold Vn stage, the processing load is reduced, the processing time is shortened, the configuration of the control / arithmetic unit 20 is simplified, and the number of input samplings is increased. Further, in order to reduce the processing load, this processing need not always be performed when an instruction is input. In other words, this process is performed only when the power is turned on, when there is a large fluctuation in the light amount distribution, or only at the timing set at a long-term interval. Otherwise, the threshold value set at that time is repeatedly used. You may do it. Further, the step interval for setting the threshold value Vn does not have to be constant, and may be variable based on a constant condition.

  As described above, in the first embodiment, the designated position is the midpoint of the intersection pixels L1 and R1 of the falling portion and the rising portion of the light shielding portion corresponding to the maximum value of ΔN that satisfies the expression (16), that is, the intermediate pixel. The structure which calculates the pixel corresponding to is demonstrated. However, the method for calculating the pixel corresponding to the designated position is not limited to this.

  For example, a method may be used in which a pixel corresponding to the indicated position is calculated by interpolating the deepest peak of the light-shielding portion by interpolation processing based on the values of DLn and DRn corresponding to the calculated threshold value Vn. Originally, if there is no problem in S / N, when the horizontal axis is the pixel number and the vertical axis is the differential value D, the zero cross point is the central pixel of the light-shielding portion to be calculated. However, in the present invention, when the received light amount level is low, it is premised on shading information having a poor S / N. Therefore, the zero cross pixel of the differential value includes an error as it is.

  Therefore, in the present invention, the differential value D corresponding to the threshold value Vn that ensures the symmetry with respect to the indicated position is calculated, and this is used. Specifically, when the horizontal axis is the pixel number and the vertical axis is the differential value D, DLn and DRn corresponding to the set threshold value Vn are respectively interpolated to calculate the peak (pixel) of the differential value, and the peak ( The pixel at the indicated position is calculated from (pixel). At this time, the values of DLn and DRn are not necessarily one, but the peak of the differential value, that is, the pixel corresponding to the indicated position is calculated by interpolating from a plurality of DLn and DRn satisfying the predetermined S / N condition. May be. Such a method of calculating the pixel corresponding to the designated position from the peak of the differential value has a feature that it is possible to stably obtain the designated position detection according to the actual shape of the light shielding portion.

  By the subroutine processing for detecting the pixel corresponding to the above-described designated position, it is possible to detect the designated position accurately even in the case of the configuration in which the three unit light projecting units in FIG. 17 are arranged. And then. Since detection is always performed in the light quantity distribution region with the largest light quantity in the accurate designated position, detection with a large S / N and resistance to noise is possible. Alternatively, when the same S / N is maintained, the amount of light can be increased by increasing the unit light projecting unit, and the size of the apparatus can be increased.

  As described above, in the first embodiment, the unit light projecting unit is symmetrical with respect to the optical axis of the light receiving unit 40 in the direction parallel to the surface of the coordinate input effective area 300 on the left and right of the central unit light projecting unit serving as a reference. A configuration in which the left and right equidistant distances d are arranged is shown. By adopting this configuration, the distance between the light receiving unit 40 and the unit light projecting unit can be reduced as compared with the case where the unit light projecting unit is arranged with the light receiving unit 40 sandwiched in the same horizontal direction as the light receiving unit 40. can do.

  That is, in general, the light receiving unit 40, particularly the condenser lens 42, has a predetermined light receiving range without distortion in a direction substantially parallel to the surface of the coordinate input effective region 300 and the coordinate input effective region 300. Requires a certain width in the direction parallel to Therefore, the width dimension including the condensing lens 42 and the mounting member becomes large, and when the unit light projecting portions are arranged on both sides thereof, the distance between the light receiving portion 40 and the unit light projecting portion is increased. The configuration in which the unit light projecting units are arranged on both sides of the light receiving unit 40 is temporarily axisymmetric with respect to the optical axis of the light receiving optical system, and therefore combined with the light shielding part detection processing of the present invention. As a result, it is possible to detect a light-shielding portion that maintains symmetry with respect to the pixel corresponding to the designated position.

  However, the objective cannot be achieved in terms of increasing the amount of received light. That is, the total amount of received light is reduced by the absence of the central unit light projecting portion corresponding to the infrared LED 31-1 and the light projecting lens 32-1 in FIG. The configuration in which the unit light projecting units are arranged on both sides of the light receiving unit 40 in terms of the observation angle in the retroreflection characteristic has a low light quantity increasing effect. This is a reduction in the amount of light due to an increase in the distance between light reception and emission in the sensor unit 2001. A further description will be given of the reduction in the amount of light due to the increase in the distance between light emission. Now, let D be the distance between the light receiving unit 40 and the unit light projecting unit related to the observation angle in the case where the unit light projecting units are arranged on both sides of the light receiving unit 40 in the horizontal direction. As described above, this distance D is larger than the distance d in FIG. Accordingly, the observation angle is increased accordingly, and the amount of received light is greatly reduced.

  On the other hand, the configuration of the present invention is a configuration in which the light projecting unit 30 is arranged in the vertical direction away from the light receiving unit 40 with respect to the coordinate input effective area 300, and the center is directly above the optical axis of the light receiving unit 40. Basically, the unit floodlight is arranged. Assuming that the distance between the light receiving and emitting in the vertical direction is L as described above, this distance L is a relatively small value due to the optical characteristics of the condenser lens and the light projecting lens. Therefore, first, in the configuration in which the light receiving portions are stacked in the vertical direction, the observation angle can be made smaller than in the configuration in which the unit light projecting portions are arranged on both sides of the light receiving portion 40 in the horizontal direction. The substantial distance is sufficiently possible to set the distance L to 5 mm, for example. Incidentally, the observation angle between light reception and light emission in this case is about 0.14 ° for the coordinate input range of the apparatus of 40 inches and 0.09 ° or less for the size of 60 inches.

  On the other hand, in the configuration in which the unit light projecting units are arranged on both sides of the light receiving unit 40, the distance D between the light receiving and emitting in the horizontal direction is increased due to structural limitations. For example, if it is 15 mm on both sides from the optical axis of the light receiving unit 40, for example, the coordinate input range of the apparatus is about 0.42 ° for the 40 inch size and about 0.28 ° for the 60 inch size. The difference between the distance between the light receiving and emitting and the observation angle is about 1.7 to 1.8 times for the 40 inch size and about 1.4 to 1.5 times for the 60 inch size (the range is (There is a difference in characteristics depending on the incident angle). Therefore, the total light quantity can be estimated as follows. Here, for the sake of simplicity, assuming that the distance d and the distance D of the unit light projecting units of the present invention are approximately equal to 15 mm, the amount of light received by the unit light projecting units on both sides of the present invention is substantially equal to the unit light projecting unit. Assuming that the amount of light in the configuration in which the light is disposed on both sides of the light receiving unit is the same, it can be estimated as follows.

In the case of 40-inch size
= Center unit light projecting unit + unit light projecting units on both sides × 2 = 1.7 + 1 × 2 = 3.7
Light intensity with a configuration where unit light emitters are arranged on both sides of the light receiver
= 1x2 = 2
In case of 60-inch size
= Center unit light projecting unit + unit light projecting units on both sides × 2 = 1.4 + 1 × 2 = 3.4
Light intensity with a configuration where unit light emitters are arranged on both sides of the light receiver
= 1x2 = 2
The above is due to the characteristics of a certain retroreflective material, and the actual value differs if the retroreflective material is different. However, the central unit light projecting unit is placed close to the coordinate input area away from the light receiving unit in the vertical direction, and the left and right sides of the unit light projecting part are parallel to the coordinate input effective area plane and symmetrical with respect to the optical axis of the light receiving unit. The effect of increasing the amount of light when the components are arranged at equal distances is great. In the above description, the distance D between the light receiving and emitting in the horizontal direction in the configuration in which the unit light sources are arranged on both sides of the light receiving unit is set to 15 mm. There is a possibility of a large value, and the superiority in the configuration of the present invention becomes more remarkable.

As described above, according to the first embodiment, the light-shielding portion that maintains symmetry with respect to the center pixel at the designated position is detected using a plurality of threshold values, and the detected threshold value and its threshold value are detected. A rising part and a falling part where the part intersects are detected. Then, the designated position is calculated with the middle point of the rising and falling portions as the central pixel. Thereby, even when the size is increased, it is possible to perform highly accurate coordinate detection with excellent S / N and no error.
<Embodiment 2>
In the second embodiment, an application example of the process of step S1814 will be described. In the second embodiment, description of common parts with the first embodiment is omitted. In the first embodiment, the range of the threshold value Vn in which an accurate designated position can be detected is detected by paying attention to the shape change of the falling part and the rising part of the light shielding part of the received light amount distribution. On the other hand, in the second embodiment, the range of the threshold value Vn in which an accurate designated position can be detected is detected by paying attention to the change of the midpoint between the falling portion, the rising portion, and the intersection of the threshold values. Specifically, the flowchart shown in FIG.

  In each detection routine, the process starts from step S18141 to step S18144. The process up to this point is the same as in the first embodiment. Next, in step S181441, it is determined whether n = 1. If n = 1 (YES in step S181441), the flow advances to step S18147, n is incremented by 1, and the flow returns to step S18142.

After that, when n = 2, in step S18143, the intersection pixels L2 and R2 (circles in the figure) of the falling part and the rising part of the light shielding part C in FIG. The center pixel S2 is calculated from the midpoint between the intersections. Next, in step S18144, the central pixel S2 in the case of n = 2 is stored in the memory 82. Next, in step S181441, when n = 2 (NO in step S18551), the process proceeds to step S181451. here,
Δmn = | Sn−Sn−1 | (18)
Calculate That is, in this case, Δm2 = | S2−S1 | (19)
Calculate

In step S181461,
Δmn <Δf (20)
Or whether it is true. The value of Δf is set in advance in the memory 82 to the following value.

  In FIG. 17B, the center pixels S1 and S2 at the thresholds V1 and V2 are both rising and falling portions that accurately reflect the edges of the indicator 911 in the optical paths L1Q and L1R in FIG. It is a value calculated on the basis of, and is almost the same value. Therefore, Δm2 is an extremely small value. However, since the center pixel S1 is a value detected with a threshold value V1 lower than S2, it may be affected by noise from the center pixel S2. Therefore, in consideration of such a fluctuation value of Sn due to the influence of noise, Δf (predetermined difference value) in step S181461 is set to a value larger than Δm2 = | S2−S1 |.

  Similarly, in FIG. 17B, the center pixels S2 and S3 at the thresholds V2 and V3 are both rising portions and standing points that accurately reflect the edges of the indicator 911 in the optical paths L1Q and L1R in FIG. It is a value calculated based on the falling part and is almost the same value. Therefore, Δm3 is an extremely small value. However, since the center pixel S2 is a value detected at a threshold value V2 lower than S3, there is a possibility that the center pixel S2 is affected by noise from the center pixel S3. Therefore, in consideration of such a fluctuation value of Sn due to the influence of noise, Δf in step S181461 is set to a value larger than Δm3 = | S3−S2 |.

In FIG. 17B, the center pixel S3 at the threshold V3 is a value calculated based on the rising and falling portions that accurately reflect the edges of the indicator 911 in the optical paths L1Q and L1R in FIG. is there. On the other hand, in FIG. 17B, the center pixel S4 at the threshold value V4 has a rising portion and a falling portion that do not accurately reflect the edges of the indicator 911 in the optical paths L1S and L1U in FIG. It is a value calculated based on this. This value is a value shifted from the pixel O corresponding to the designated position. Therefore, Δm4 = | S4−S3 | is larger than Δm2 and Δm3. That means
Δm2, Δm3 <Δf <Δm4 (21)
Δf is set in advance so that

  Due to the above Δf, when n = 2, Δm2 <Δf (YES in step S181461), and the process proceeds to step S18147. In step S18147, n is incremented by 1, and the process returns to step S18142.

  In the case of n = 2 and 3, since Δmn <Δf is true, Steps S18142 to S181461 are repeated.

  On the other hand, if n = 4, Δm4> Δf (NO in step S181461), and the flow advances to step S18148.

  FIG. 21 shows the relationship between the thresholds V2 to V4 at n = 2 to 4 in this series of processes and the threshold V5 and Δf that do not appear in this process. The center pixel S4, which is the midpoint between the threshold value V4 at n = 4 and the intersection pixels L4 and R4 at the rising and falling portions, includes an error, and the center pixel S3 with respect to the threshold value V3 at n = 3 is the correct designated position. In addition, since the pixel is an intersection pixel where the light amount level is higher than the threshold values V1 and V2, the S / N is large. Accordingly, in step S18148, the central pixel S3 of n = 3, which is n-1 with respect to n = 4, is extracted from the memory 82 and used as a detection point (pixel corresponding to the designated position). This completes the subroutine processing for detecting the pixel corresponding to the designated position by the plurality of threshold values.

  In the second embodiment, as in the case of the first embodiment, the unit light projecting unit is set to the left and right of the central unit light projecting unit serving as a reference, with respect to the optical axis of the light receiving unit 40 in the direction parallel to the plane of the coordinate input effective region 300 In other words, they are arranged at equal distances d from each other so as to be line symmetric. Further, it is possible to accurately detect the designated position also by the above-described subroutine processing of the second embodiment.

As described above, according to the second embodiment, the detection can be performed in the region of the light amount distribution with the largest light amount in the accurate designated position based on the change of the center pixel, so that the S / N is large. Detection that is resistant to noise becomes possible. In addition, when the same S / N is maintained, the amount of light can be increased by increasing the unit light projecting unit, and the size of the apparatus can be increased.
<Embodiment 3>
In the first and second embodiments, the light receiving unit 40 is premised on a configuration in which one light receiving imaging lens is arranged for one light receiving device. However, it is possible to cope with the light receiving unit 40 (first light receiving unit and second light receiving unit) having a compound eye configuration in which two light receiving imaging lenses are arranged for one light receiving device. One. Since the configuration itself of the light receiving unit 40 in which two light receiving imaging lenses are arranged for one light receiving device overlaps with Patent Document 5, detailed description thereof is omitted here. A configuration adapted to the configuration of the optical unit is shown in FIGS.

  FIG. 22A is a front view of the sensor units 2001L and 2001R in the assembled state, and the arrows in FIG. 22 indicate that the light from the light projecting unit 30 constituted by four unit light projecting units is light for each unit light projecting unit. Fig. 6 shows a state in which the coordinate input effective area 300 is distributed in a fan shape in the in-plane direction. FIG. 22B is a view of FIG. 22A viewed from the side. Similarly, the light is projected as a light beam restricted in the vertical direction substantially parallel to the surface of the coordinate input effective area 300, and is mainly displayed. FIG. 9 shows a state in which light is projected to the retroreflective portion 400. Further, FIG. 22C shows a cross-sectional view of the arrangement configuration of the light projecting unit 30 and the light receiving unit 40.

  First, with respect to the condenser lens 42-1 (FIG. 22C), an infrared LED 31-1 that is a unit light projecting unit disposed on the same optical axis as viewed from the direction perpendicular to the coordinate input surface. Consider the projection lens 32-1 as a reference. Similarly to the case of FIG. 17, the light of the light receiving unit 40, that is, the light of the condensing lens 42-1, is separated from the reference unit light projecting unit by an equal distance d to the left and right and parallel to the surface of the coordinate input effective area 300. Unit light projecting portions are arranged on both sides so as to be line-symmetric with respect to the axis (FIG. 22A). The unit projectors here are an infrared LED 31-2 and a projector lens 32-2, and an infrared LED 31-3 and a projector lens 32-3. Up to this point, the configuration is the same as that of the first embodiment shown in FIGS. 2, 3, and 17.

  Next, when the condenser lens 42-2 (FIG. 22C), which is the other light receiving optical system of the compound eye, is used as a reference, the condenser lens 42-2 can be seen from the direction perpendicular to the coordinate input surface. Consider the infrared LED 31-3 and the light projection lens 32-3, which are unit light projecting units arranged on the same optical axis. It is axisymmetric with respect to the optical axis of the light receiving unit 40, that is, the condensing lens 42-2 in the direction parallel to the surface of the coordinate input effective region 300, with the left and right equidistant distances d beside the reference unit light projecting unit. As shown in FIG. In this case, the unit light projecting units to be arranged are the infrared LED 31-1 and the light projecting lens 32-1, and the infrared LED 31-4 and the light projecting lens 32-4.

  Here, the infrared LED 31-1 and the light projecting lens 32-1, and the infrared LED 31-3 and the light projection lens 32-3, which are unit light projecting units, are respectively a condensing lens 42-1. This is a light projection unit serving as a reference for the lens 42-2. In addition, at the same time, the adjacent light projecting units of the light projecting units that are adjacent to each other have an overlapping function. As a result, the infrared LEDs 31-1 to 4 and the light projecting lenses 32-1 to 4 as the unit light projecting units are arranged at equal intervals with a predetermined distance d. Furthermore, assuming that each unit light projecting unit has a light projecting range as indicated by an arrow in the figure, it is possible to ensure an original light projecting field of 90 ° without causing the projected light beams to be vignetted. FIG. 23 shows an example of a drive timing chart of each unit light projecting unit at that time.

  As in the case of FIG. 7 of the first embodiment, reference numerals 91, 92, and 93 are control signals for controlling the line CCD 41, and the shutter release time of the line CCD 41 is determined by the interval of the Sh signal 91. In FIG. 7, the left and right sensor units are described. Here, a timing chart regarding the sensor unit 2001L will be described individually. The same applies to the sensor unit 2001R. First, as the timing of the first half, in order to perform detection by one light receiving unit 40 in the sensor unit 2001L on the reading head side of the line CCD 41 in the sensor unit 2001L, the LEDL signal 94 is infrared with respect to the Sh signal 91. The LED 31 is supplied. As shown in the drawing, the LEDL signal 94 is supplied to the infrared LEDs 31 of the infrared LEDs 31-1, 31-2, and 31-3. Next, the signal of the line CCD 41 is read by the ICGL signal 92. At this time, the pixel data as the light amount distribution signal of the light receiving range on the head side of the line CCD 41 related to the condenser lens 42-1 is read.

  Next, the Sh signal 91 is given to the same line CCD 41 as the second half timing, and the LEDL signal 94 is supplied to the infrared LED 31 for detection by the other light receiving unit 40 in the sensor unit 2001L. The The supply destination of the LEDL signal 94 at this timing is the infrared LED 31 of the infrared LEDs 31-1, 31-3, 31-4 as shown in the figure. As for this output, the received signal related to the condensing lens 42-2 is output to an area that does not overlap with the light amount distribution signal of the head portion detected previously.

  The drive timing has the following characteristics. Among the four unit light projecting units (infrared LEDs 31-1 to 4 and light projecting lenses 32-1 to 4), two unit light projecting units (infrared LED 31-1 and light projecting lens 32-1; The infrared LED 31-3 and the light projecting lens 32-3) project light in synchronism with both the first and second drive timings. This can reduce the number of parts, reduce the size, and reduce the cost as compared with the case where six unit light projecting units are provided independently for each light receiving system for compound eyes.

  By driving the other sensor unit 2001R in the same manner at different timings, the detection signals of the line CCD 41 are read out from the respective sensors. In the third embodiment, detection signals from a maximum of four light receiving units are acquired. become. Since the processing of these four detection signals is as described in Patent Document 5, the description thereof will be omitted. However, according to the third embodiment relating to the increase of the light projecting unit of the present invention, the S / N ratio can be increased by increasing the amount of received light. A plurality of instruction inputs can be detected while increasing or increasing the size.

Of course, the configuration in which a plurality of unit light projecting units are arranged in the compound eye configuration of the third embodiment is a characteristic configuration that cannot be realized by the configuration in which the unit light projecting units are arranged on both sides of the light receiving unit 40. <Embodiment 4>
In the first to third embodiments, the unit light projecting unit includes an infrared LED (light emitting diode) 31 and a light projecting lens 32. However, the light projecting lens 32 is omitted and the infrared LED (light emitting diode) is provided. ) Only 31 may be used. In that case, the distance and arrangement between the unit light projecting portions are determined in consideration of the light projecting range characteristics of the infrared LED (light emitting diode) 31 itself. According to this configuration, the distance d between unit light projecting units described in FIG. 17 of the first embodiment can be significantly reduced. Therefore, the distance between the light receiving unit 40 and the unit light projecting unit related to the observation angle in the configuration in which the unit light projecting units are arranged on both sides of the light receiving unit 40 is d <D in relation to D, and more The effect of increasing the amount of light of the present invention will stand out.

  In the above embodiment, the unit light projecting unit of the present invention is symmetrical with respect to the optical axis of the light receiving unit 40 in the direction parallel to the plane of the coordinate input effective area 300 on the left and right of the central unit light projecting unit serving as a reference. In this way, the unit light projecting portions are arranged one by one at equal distances from the left and right. However, the configuration of the present invention is not limited to this, and a plurality of unit light projecting units may be arranged on both sides.

  The present invention can also be realized by executing the following processing. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, or the like) of the system or apparatus reads the program. It is a process to be executed.

Claims (8)

A coordinate input device for calculating a pointing position by a pointing tool for a coordinate input effective area,
A light receiving means provided at a corner of the coordinate input effective area;
A plurality of light projecting means provided at corners of the coordinate input effective area;
Reflecting means provided around the coordinate input effective region and recursively reflecting incident light;
Control means for controlling driving of the light receiving means and the plurality of light projecting means;
Calculation means for calculating the indicated position of the coordinate input effective area based on a variation in the light amount distribution obtained from the light receiving means when the coordinate input effective area is indicated by the pointing tool;
In the direction perpendicular to the coordinate input effective area, the plurality of light projecting means are arranged at a predetermined distance from the light receiving means,
Of the plurality of light projecting means, the reference light projecting means is arranged at a position where the light projecting position coincides with the optical axis of the light receiving means in the horizontal direction with respect to the coordinate input effective area, and the remaining light projecting means. The plurality of light projecting means are arranged at positions that are line symmetric with respect to the optical axis of the light receiving means,
The control means drives the plurality of corresponding light projecting means in synchronization with the drive timing of the light receiving means, and a rising portion and a falling portion of a light shielding portion included in the light amount distribution obtained from the light receiving means, However, the threshold is set at a level where symmetry is maintained with respect to the center position between the two,
The calculation means calculates the indicated position based on a pixel number corresponding to a center position between a rising portion and a falling portion of the light-shielding portion corresponding to a point that crosses the light amount distribution at the threshold value. A coordinate input device characterized by that. A storage means for storing a plurality of threshold values;
The control means includes
It is determined whether or not the rising portion and the falling portion of the light-shielding portion corresponding to the points crossing each of the plurality of threshold values with respect to the light amount distribution are symmetrical with respect to the center position between them. Determination means to perform,
Setting means for setting, based on the determination result of the determination means, the largest threshold value that maintains the symmetry from the plurality of threshold values;
The calculation means is based on a pixel number corresponding to a center position between a rising portion and a falling portion of the light shielding portion corresponding to a point that crosses the light amount distribution at the threshold set by the setting means. The coordinate input device according to claim 1, wherein the designated position is calculated. The determination means maintains the symmetry based on a differential value obtained by a predetermined number of pixels before and after a pixel corresponding to each of the rising and falling portions of the light shielding portion at a point crossing the light amount distribution by the threshold value. The coordinate input device according to claim 2, wherein it is determined whether or not it is struck. A storage means for storing a plurality of threshold values;
The control means includes
A predetermined difference value is exceeded from a variation value between pixel numbers corresponding to a center position between the rising portion and the falling portion of the light-shielding portion corresponding to a point crossing each of the plurality of threshold values with respect to the light amount distribution. Setting means for setting a threshold value in the case from the plurality of threshold values,
The calculation means is based on a pixel number corresponding to a center position between a rising portion and a falling portion of the light shielding portion corresponding to a point that crosses the light amount distribution at the threshold set by the setting means. The coordinate input device according to claim 1, wherein the designated position is calculated. The light receiving means has first and second light receiving means,
In the direction perpendicular to the coordinate input effective area, the plurality of light projecting means are arranged at a predetermined distance from the light receiving means,
With respect to the horizontal direction with respect to the coordinate input effective area, the plurality of light projecting means are arranged at positions that are line-symmetric with respect to the respective optical axes of the first and second light receiving means,
The control means drives a plurality of light projecting means arranged at line-symmetric positions with respect to the optical axes of the first and second light receiving means in synchronization with the drive timing of the corresponding light receiving means. The coordinate input device according to claim 1, wherein: The control means drives a part of the plurality of light projecting means in synchronism with the drive timing of the first and second light receiving means. 5. The coordinate input device according to 5. As a coordinate input device for calculating the pointing position by the pointing tool for the coordinate input effective area, a light receiving unit provided at a corner of the coordinate input effective area and a plurality of light projections provided at the corner of the coordinate input effective area And a control method of a coordinate input device having a reflection part that is provided in the periphery of the coordinate input effective area and recursively reflects incident light,
A control process for controlling driving of the light receiving unit and the plurality of light projecting units;
A calculation step of calculating the indicated position of the coordinate input effective area based on a variation in a light amount distribution obtained from the light receiving unit when the coordinate input effective area is indicated by the pointing tool;
In the direction perpendicular to the coordinate input effective area, the plurality of light projecting units are arranged at a predetermined distance from the light receiving unit,
Of the plurality of light projecting units in the horizontal direction with respect to the coordinate input effective area, the reference light projecting unit is disposed at a position where the light projecting position coincides with the optical axis of the light receiving unit, and the rest The plurality of light projecting units are arranged at positions that are line symmetric with respect to the optical axis of the light receiving unit,
The control step drives the plurality of corresponding light projecting units in synchronization with the drive timing of the light receiving unit, and rises and falls portions of the light shielding part included in the light amount distribution obtained from the light receiving unit, However, the threshold is set at a level where symmetry is maintained with respect to the center position between the two,
The calculation step calculates the indication position based on a pixel number corresponding to a center position between a rising portion and a falling portion of the light shielding portion corresponding to a point that crosses the light amount distribution at the threshold value. A control method for a coordinate input device. As a coordinate input device for calculating the pointing position by the pointing tool for the coordinate input effective area, a light receiving unit provided at a corner of the coordinate input effective area and a plurality of light projections provided at the corner of the coordinate input effective area And a program for causing a computer to control a coordinate input device provided in a peripheral portion of the coordinate input effective area and having a reflection portion that recursively reflects incident light,
The computer,
Control means for controlling driving of the light receiving unit and the plurality of light projecting units;
When the coordinate input effective area is instructed by the pointing tool, it functions as a calculation means for calculating the indicated position of the coordinate input effective area based on a variation in a light amount distribution obtained from the light receiving unit,
In the direction perpendicular to the coordinate input effective area, the plurality of light projecting units are arranged at a predetermined distance from the light receiving unit,
Of the plurality of light projecting units in the horizontal direction with respect to the coordinate input effective area, the reference light projecting unit is disposed at a position where the light projecting position coincides with the optical axis of the light receiving unit, and the rest The plurality of light projecting units are arranged at positions that are line symmetric with respect to the optical axis of the light receiving unit,
The control means drives the plurality of corresponding light projecting units in synchronization with the drive timing of the light receiving unit, and a rising part and a falling part of a light shielding part included in the light amount distribution obtained from the light receiving unit, However, the threshold is set at a level where symmetry is maintained with respect to the center position between the two,
The calculation means calculates the indicated position based on a pixel number corresponding to a center position between a rising portion and a falling portion of the light-shielding portion corresponding to a point that crosses the light amount distribution at the threshold value. A program characterized by that.

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