JP2008234523A - Position detector, display device and information processing system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technology for detecting a position with a configuration suitable to carry. <P>SOLUTION: An information display system 100 comprises an instructing device 10 and a display device 20. The instructing device 10 supplies electric power and information through an exciting coil part 14. The display device 20 comprises a position specifying coil part 21, an electric power extracting coil part 22, an electric power extracting part 23, a communication control part 24, a storage part 25, a display control part 26 and a display part 27. The position specifying coil part 21 comprises a plurality of coils. The position specifying coil part 21 is electromagnetically connected to the exciting coil part 14 and outputs information indicating a connected position. The electric power extracting coil part 22 is electromagnetically connected to the exciting coil part 14 together with the position specifying coil part 21. The electric power extracting part 23 extracts electric power from an electric current generated in the electric power extracting coil part 22, and supplies the electric power to the communication control part 24 and the display control part 26. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a technique for detecting a position and receiving power from the outside.

  A display carrier called electronic paper is known (for example, see Patent Documents 1 and 2). This display carrier is required to have a characteristic that it can be freely carried and rewritten easily like paper. Further, the display carrier is advantageous in that it has low power consumption in consideration of portability. This is because low power consumption makes it easy to reduce the size of the battery or to supply power from the outside without contact.

Further, in this type of display carrier, it is convenient if various inputs can be made with a pen-type pointing device. It would be more convenient if this input could be made on the display surface of the display carrier. As a technique capable of realizing such an input, for example, a technique for detecting a position (coordinates) using an electromagnetic induction phenomenon is known. The techniques described in Patent Documents 3 and 4 are an example of such a technique and relate to a so-called tablet (pen tablet).
JP 2005-181436 A JP 2006-277261 A Japanese Examined Patent Publication No. 2-53805 Japanese Patent Publication No. 3-19565

The techniques described in Patent Documents 3 and 4 detect a tuning circuit provided in a pen-type pointing device on the tablet side, and the tablet actively operates. In this case, the device on the side that detects the position (that is, the tablet) consumes a corresponding amount of power, so that a sufficient power supply is required. Therefore, it can be said that it is not appropriate to apply such a technique to a display carrier because it hinders downsizing of the display carrier. In particular, since a plurality of display carriers such as electronic paper are often used at the same time, portability is required to be easily carried even when there are a plurality of display carriers.
The present invention has been made in view of such circumstances, and an object thereof is to provide a technique for detecting a position with a configuration suitable for carrying.

The position detection device according to the present invention is arranged in a planar shape, and is arranged so as to overlap at least one of the plurality of position specifying coils that generate a current corresponding to a change in magnetic flux and the plurality of position specifying coils. Based on the magnitude of the currents generated in the plurality of position specifying coils and the power extraction coil that generates a current corresponding to the change, the position of one position in the plane where these are arranged is specified, and position information indicating the position is obtained. Information output means for outputting, and power output means for extracting and outputting power from the current generated in the power extraction coil.
According to such a position detection device, when a change in magnetic flux occurs at a certain position, it is possible to supply power and specify the position in accordance with the change in magnetic flux.

In the position detection device according to the present invention, the plurality of position specifying coils includes a first coil group that is a plurality of position specifying coils arranged in a first direction, and a second coil that intersects the first direction. A second coil group that is a plurality of position specifying coils that are arranged in a direction and overlaps the first coil group, wherein the information output means is based on the magnitude of the current generated in the first coil group. When specifying the coordinates when the first coordinate axis is set in the first direction, and setting the second coordinate axis in the second direction based on the magnitude of the current generated in the second coil group The coordinates may be specified, and position information indicating one position represented by these coordinates may be output. In this way, the position can be specified as coordinates in a certain coordinate system. In this way, the position can be specified even if the number of turns of the position specifying coil is reduced, and the position specifying coils can be arranged relatively densely.
Note that the second direction is preferably orthogonal to the first direction, but the “intersection” here is not limited to orthogonal.

In the position detection apparatus according to the present invention, the information output means uses the current level of the position specifying coil where the generated current is maximum and the current level of the position specifying coil in the vicinity of the position specifying coil. The configuration may be such that interpolation is performed and one position is specified from the region formed by these position specifying coils based on the result of the interpolation. In this way, it is possible to specify the position more accurately than when adjacent position specifying coils do not overlap.
In this case, it is more desirable that the plurality of position specifying coils have a configuration in which a part of each of the position specifying coils overlaps with another position specifying coil. In this way, the position can be accurately specified in the entire region where the position specifying coil is formed.

  In the position detection device according to the present invention, the information output unit may output a signal representing the position information via the power extraction coil or the position specifying coil. In this way, position information can be output electromagnetically. In addition, the power extraction coil or the position specifying coil can also serve as an interface for outputting position information.

In the position detection device according to the present invention, there are a plurality of the power extraction coils, and the information output means includes a first specifying means for specifying a first region using the plurality of power extraction coils, and the plurality of the power extraction coils. A second specifying unit that specifies a second area using a position specifying coil, and outputs position information that is included in the first area and that indicates a position included in the second area It may be.
Alternatively, there are a plurality of the power extraction coils, and the information output unit specifies a region formed by one power extraction coil based on the magnitude of current generated in the plurality of power extraction coils, and overlaps the region. The configuration may be such that one position is specified based on the magnitude of the current generated in the position specifying coil.
If it does in this way, it will become possible to extract electric power and specify a position using the electric current which arose in the electric power extraction coil.

The present invention is specified not only as the position detection device described above but also as an information processing system that combines a display device including the position detection device, and a position detection device and a device that supplies power to the position detection device. It can be done. For example, the display device according to the present invention is arranged in a planar shape, and is arranged so as to overlap at least one of the plurality of position specifying coils that generate a current corresponding to a change in magnetic flux, and the plurality of position specifying coils. Position information indicating the position of the power extraction coil for generating a current corresponding to the change of the position and specifying one position in the plane where these are arranged based on the magnitude of the current generated in the plurality of position specifying coils Information output means for outputting power, power extraction means for extracting power from the current generated in the power extraction coil, and the position information output by the information output means using the power extracted by the power extraction means. Display means for performing a corresponding display.
In addition, an information processing system according to the present invention includes a first device that supplies power and a second device that receives power from the first device when approaching the first device. In the processing system, the first device includes power supply means for supplying electric power by changing the magnetic flux, and the second device is arranged in a planar shape and generates a current corresponding to the change of the magnetic flux. A plurality of position specifying coils to be generated, a power extraction coil that is arranged to overlap at least one of the plurality of position specifying coils and generates a current according to a change in magnetic flux, and a current generated in the plurality of position specifying coils Based on the size of the information, a position in the surface where these are arranged is specified, information output means for outputting position information indicating the position, and power extracted from the current generated in the power extraction coil and output That is intended and a power output means.

Embodiments of the present invention will be described below with reference to the drawings.
[Embodiment]
FIG. 1 is a diagram schematically showing an information display system according to an embodiment of the present invention. As shown in FIG. 1, the information display system 100 according to the present embodiment includes an instruction device 10 and a plurality of display devices 20. The instruction device 10 is a pen-type processing device that supplies various display-related instructions and power for operation to a plurality of display devices 20. The display device 20 is so-called electronic paper, and performs display in accordance with the instruction supplied from the instruction device 10 based on the power supplied from the instruction device 10. In the present embodiment, the pointing device 10 and the display device 20 communicate using a predetermined frequency band by an electromagnetic coupling method.

The display device 20 has a rectangular display surface. For convenience of explanation, in the following, the surface on which the display surface of the display device 20 is provided is referred to as the front. Also, the short side of the display surface is the top and bottom, and the long side is the left and right. Further, a direction parallel to the short side of the display surface is referred to as “X direction”, and a direction orthogonal to the X direction and parallel to the long side of the display surface is referred to as “Y direction”.
Of course, the shape of the display surface is not limited to this.

  FIG. 2 is a block diagram showing the overall configuration of the information display system 100. In addition, since all the display apparatuses 20 are the same structures, the overlapping description is abbreviate | omitted here. As shown in FIG. 1, the instruction device 10 includes a power supply unit 11, a control unit 12, a storage unit 13, and an excitation coil unit 14. The display device 20 includes a position specifying coil unit 21, a power extraction coil unit 22, a power extraction unit 23, a communication control unit 24, a storage unit 25, a display control unit 26, and a display unit 27. .

The power supply unit 11 supplies power for operating the pointing device 10 and the display device 20. The power supply unit 11 includes a battery such as a dry battery or a storage battery as a power supply source. The power supply unit 11 preferably includes a switch for switching on / off of power supply. It is more desirable that this switch is provided at a position where the user can operate with a finger. The control unit 12 includes a CPU (Central Processing Unit) and a memory, and controls the operation of the pointing device 10. The control unit 12 includes a signal generation circuit such as a modulation circuit, and supplies a predetermined alternating current corresponding to power and information to the excitation coil unit 14.

The storage unit 13 includes, for example, a rewritable storage medium such as a flash memory, and stores display data. Here, the display data is information representing characters and images displayed on the display device 20 and is information in page units displayed on the display surface of the display device 20. In the present embodiment, the display data constitutes one document with a plurality of pages, and a plurality of display data corresponding to the plurality of documents can be supplied from the instruction device 10. The display data includes information for specifying the document represented by each. This information is hereinafter referred to as “title information”.
The storage unit 13 stores information (look-up table) related to a sensing area, which will be described later. Details of this information will be described later.

The exciting coil unit 14 is an interface for supplying power and information to the display device 20 and generates a magnetic flux corresponding to the current.
FIG. 3 is a diagram illustrating a configuration of the exciting coil unit 14. The exciting coil unit 14 includes a magnetic core 141 and a coil 142 wound around the magnetic core 141. The magnetic core 141 preferably has a cone-shaped tip in order to efficiently perform electromagnetic coupling with the position specifying coil unit 21 and the power extraction coil unit 22.

  The position specifying coil unit 21 includes a plurality of coils for specifying positions indicated by the user using the pointing device 20 and a plurality of determination circuits for determining the magnitude of current generated in the plurality of coils. The plurality of coils are regularly arranged in a predetermined direction. The coil has a substantially rectangular shape. Note that the number of turns (turns) of the coil is arbitrary, and may be one turn, for example.

  FIG. 4 is a diagram illustrating the configuration of the position specifying coil unit 21 from the front side, and FIG. 5 is a diagram schematically illustrating the circuit configuration of the position specifying coil unit 21. As shown in FIG. 4, the position specifying coil unit 21 includes a first coil group 211 and a second coil group 212. The first coil group 211 is a plurality of coils arranged at equal intervals in the X direction, and the second coil group 212 is a plurality of coils arranged at equal intervals in the Y direction. Each of the coils of the first coil group 211 is provided so as not to generate a gap with an adjacent coil. Each of the coils of the second coil group 212 is also provided so as not to create a gap with the adjacent coil. Each of the first coil group 211 and the second coil group 212 forms one plane as a whole. This plane is a plane parallel to the display surface.

  As shown in FIG. 5, the position specifying coil unit 21 includes coils 2111, 2112,..., 211m, coils 2121, 2122, ..., 212n, a first determination circuit 213, and a second determination circuit 214. The coils 2111 to 211 m are coils constituting the first coil group 211, and the coils 2121 to 212 n are coils constituting the second coil group 212. Here, “m” and “n” are arbitrary integers, which are values that may be appropriately determined according to the size of the display device 20 and the like. The coils 2111 to 211m and the coils 2121 to 212n generate currents corresponding to changes in the magnetic flux therein. One end of each of the coils 2111 to 211m is connected to the ground potential (Gnd), and the other end is connected to the first determination circuit 213. The coils 2121 to 212n have one end connected to the ground potential (Gnd) and the other end connected to the second determination circuit 214.

The first discrimination circuit 213 discriminates the current generated in each of the coils 2111 to 211m, and specifies the magnitude. The first determination circuit 213 outputs a signal indicating the coil that has generated the maximum current to the communication control unit 24. This signal is hereinafter referred to as an “X coordinate signal”. The second determination circuit 214 determines the current generated in each of the coils 2121 to 212n and specifies the magnitude thereof. The second determination circuit 214 outputs a signal indicating the coil that has generated the maximum current to the communication control unit 24. This signal is hereinafter referred to as a “Y coordinate signal”. These signals are collectively referred to as “coordinate signals”.
The coordinate signal is information indicating a certain position in a plane formed by the first coil group 211 and the second coil group 212. That is, the coordinate signal is information representing coordinates on each coordinate axis when an orthogonal coordinate system having the X direction and the Y direction as coordinate axes is defined.

  The power extraction coil unit 22 includes a plurality of coils for extracting power. These coils are arranged so as to overlap at least one of the coils 2111 to 211m and the coils 2121 to 212n. The number of turns of the power extraction coil unit 22 is preferably larger than the number of turns of the position specifying coil unit 21. Moreover, when setting it as such a structure, when the front surface of the display apparatus 20 is turned up, the coil of the electric power extraction coil part 22 is desirably provided below (lower layer) the coil of the position specific coil part 21. .

FIG. 6 is a diagram illustrating a part of the configuration of the power extraction coil unit 22 from the front side. As shown in the figure, the power extraction coil unit 22 includes a plurality of coils 221. In this embodiment, the coil 221 has a substantially square shape, and is arranged so that each side thereof is adjacent to another coil. The coil 221 is classified into an upper layer side and a lower layer side. The center of the upper layer side coil 221 is in a positional relationship such that it overlaps the apex of the lower layer side coil 221. An area inside the upper coil 221 is in a positional relationship such that it overlaps with each of the four lower coil 221 areas overlapping with each other by a quarter. ""
The reason why the power extraction coil unit 22 of this embodiment is configured as described above is to extract power more efficiently. That is, by making the coil 221 square and arranging each side adjacent to other coils, it is possible to reliably include a region where the change in magnetic flux is greatest inside any one of the coils 221. Further, by arranging the coils 221 in a plurality of layers, it is possible to increase the number of coils from which power can be extracted.

The power extraction unit 23 includes a plurality of rectifier circuits, capacitors, and a stabilization circuit, and extracts power from the current generated in the coil 221 of the power extraction coil unit 22. The power extraction unit 23 supplies the extracted power to the communication control unit 24 and the display control unit 26 as operating power.
FIG. 7 is a diagram partially showing a circuit configuration of the power extraction unit 23. As shown in the figure, the power extraction unit 23 includes a plurality of rectifier circuits 231, a capacitor 232, and a stabilization circuit 233.

The rectifier circuit 231 is a circuit connected to each of the plurality of coils 221 and includes diodes D ₁₁ , D ₁₂ , D ₁₃ and D ₁₄ . The diodes D ₁₁ , D ₁₂ , D ₁₃ and D ₁₄ constitute a bridge circuit. One end of the coil 221 is connected to the cathode side of the anode side and the diode D ₁₃ of the diode D _11, the other end of the coil 221 is connected to the cathode side of the anode side and the diode D ₁₄ of the diode D ₁₂ . Incidentally, the anode side of the diode D ₁₃ and D ₁₄ are connected to a ground potential (Gnd). The capacitor 232 reduces and smoothes the ripple of the current (pulsating flow) rectified by the rectifier circuit 231. The stabilization circuit 233 is a so-called DC stabilized power supply, and outputs the current smoothed by the capacitor 232 as more stable power.

  The communication control unit 24 transmits / receives information to / from the instruction device 10 via the coil 221 of the power extraction coil unit 22. The communication control unit 24 operates using the power extracted by the power extraction unit 23. The communication control unit 24 includes a demodulation circuit and the like, and extracts a signal representing predetermined information from the current generated in the coil 221 of the power extraction coil unit 22. Note that the information extracted by the communication control unit 24 includes display data. The communication control unit 24 causes the storage unit 25 to store display data in a state where title information can be identified. Further, when the communication control unit 24 acquires the coordinate signal from the position specifying coil unit 21, the communication control unit 24 converts the coordinate signal into a signal suitable for communication with the pointing device 10, and changes the load impedance of the coil 221 corresponding to this signal. It outputs to the indicating device 10 by a method (load modulation method) or the like.

  The storage unit 25 stores display data. The storage unit 25 includes a rewritable storage medium such as a flash memory, for example. This storage medium is preferably a detachable structure such as a so-called memory card. The display data stored in the storage unit 25 is read to the display control unit 26 as necessary.

The display control unit 26 includes a memory for temporarily storing display data and a drive circuit for driving the display unit 27, and controls display on the display unit 27. The display control unit 26 acquires display data from the storage unit 25 and supplies a drive voltage corresponding to the display data to the display unit 27.
The display unit 27 displays characters and images on a predetermined display surface. The display surface of the display unit 27 is composed of a plurality of pixels that each exhibit a gradation corresponding to the supplied drive voltage. In the present embodiment, each pixel of the display unit 27 has a liquid crystal layer made of memory liquid crystal. Here, the memory liquid crystal is a liquid crystal that can maintain a display state (that is, gradation) without continuing to apply a voltage. As the memory liquid crystal, for example, cholesteric liquid crystal is used.

  FIG. 8 is a diagram showing the appearance of the display device 20 from the front. As shown in the figure, the display device 20 includes a display surface 27D and a plurality of operation points P1, P2, and P3 on the front thereof. Each of the operation points P1 to P3 is assigned to a predetermined operation in advance. The operations assigned to the operation points P1 to P3 include, for example, changing display data to be displayed (page transition), various settings, instructions, and the like. It should be noted that characters and images indicating the operation points are preferably printed at the positions corresponding to the operation points P1 to P3 so that the user can recognize them. In the present embodiment, it is assumed that the operation point P1 is assigned to an operation for shifting the page to be displayed to the previous one, and the operation point P3 is assigned to an operation for changing the page to be displayed to the next. Further, it is assumed that the operation point P2 is assigned to an operation for closing the document being displayed, that is, an operation for returning the display state to the state before the document is displayed.

  The coils 2111 to 211m, 2121 to 212n, and the coil 221 are disposed so as to be substantially parallel to the front surface of the display device 20 over substantially the entire front surface. A region where the coils 2111 to 211m, 2121 to 212n and the coil 221 are arranged (hereinafter referred to as “sensing region”) is a region indicated by a broken line in FIG. That is, the display device 20 can extract power and detect a position when the pointing device 10 is instructed within the sensing area. The display device 20 is configured to include at least the display surface 27D and the operation points P1 to P3 in the sensing area.

  FIG. 9 is a cross-sectional view of the display device 20, and is a cross-sectional view taken along line AA in FIG. This figure is a cross-sectional view with the front face upward, and shows the thickness of the cross section with emphasis. As shown in the figure, a first coil group 211, a second coil group 212, and a coil 221 are provided inside the display device 20 so as to overlap each other. The first coil group 211 and the second coil group 212 are on the front side of the coil 221. With such a configuration, the current generated in the first coil group 211 and the second coil group 212 is not easily affected by the coil 221.

  A magnetic absorption layer S1 is provided below these coils. The magnetic absorption layer S1 is a sheet-like object that absorbs electromagnetic waves, and includes, for example, a soft magnetic material. The magnetic absorption layer S1 is sufficient if it is provided at least under the coil, but may be provided in a wider range.

  Based on the above configuration, the information display system 100 displays characters and images on the plurality of display devices 20. In the information display system 100, the user holds the pointing device 10 with his hand and performs an operation using a writing instrument such as a pen. The operation is to hit the tip of the pointing device 10 against the center or the display surface of the operation points P1 to P3. In this case, it is desirable that the tip portion of the pointing device 10 is in contact with the surface of the display device 20, but may be separated as long as it is about several mm.

When the distal end portion of the pointing device 10 and the surface of the display device 20 come close to each other and become a predetermined distance or less, the primary coil portion 13 and the first coil group 211, the second coil group 212, and the coil 221 are electromagnetically coupled. . As a result, the display device 20 receives power and information and displays on the display unit 28. That is, in order for the display device 20 to start some display, the user needs to bring the pointing device 10 closer to the sensing area. At this time, the control unit 12 of the pointing device 10 continuously supplies current to the exciting coil unit 14. In addition, if the power supply part 11 is a structure which has a switch, it is also possible to supply electric power only when the user recognizes that it is necessary.

  FIG. 10 is a sequence diagram showing a series of operations related to display on the display device 20. This sequence diagram shows an operation from a state in which nothing is displayed on the display device 20. Below, the process which the instruction | indication apparatus 10 and the display apparatus 20 perform is demonstrated along the same figure.

  When the user brings the pointing device 10 close to the display device 20, the excitation coil unit 14 of the pointing device 10 and the power extraction coil unit 22 of the display device 20 are electromagnetically coupled, and power is transmitted from the pointing device 10 to the display device 20. Is supplied (step S1). When power is supplied to the display device 20, the control unit 12 of the instruction device 10 transmits display data representing a screen for allowing the user to select a document to be displayed to the display device 20 (step S2). This screen is hereinafter referred to as “menu screen”, and the display data representing this menu screen is hereinafter referred to as “menu data”.

  FIG. 11 is a diagram illustrating an example of a menu screen. This figure exemplifies a case where display data with title information “Document A”, “Document B”, and “Document C” is stored in the instruction device 10. As described above, the menu screen includes button-like image areas B1, B2, and B3 representing "Document A", "Document B", and "Document C", respectively.

  The control unit 12 of the pointing device 10 refers to the display data stored in the storage unit 13 and generates and supplies such menu data. At this time, the control unit 12 specifies each of the regions occupied by the image regions B1, B2, and B3, and specifies which position in the sensing region of the display device 20 these image regions correspond to. In order to specify this correspondence, the control unit 12 stores a lookup table (reference table) that describes which position in the sensing area each position of the display surface 27D or the operation points P1 to P3 corresponds to. Yes. That is, the control unit 12 can identify an arbitrary point in the display surface 27D and the position where the operation points P1 to P3 overlap in the sensing area by referring to the lookup table. The lookup table is preferably described using the coordinates of the coordinate system used in the X coordinate signal and the Y coordinate signal.

  Returning to the description of FIG. When the menu data is supplied, the communication control unit 24 of the display device 20 stores it in the storage unit 25 (step S3). Next, the display control unit 26 reads the menu data from the storage unit 25 and causes the display unit 27 to display an image corresponding to the menu data (step S4). That is, the screen displayed at this time is a screen as shown in FIG.

When the menu screen is displayed on the display device 20, the user performs an operation of selecting a desired document. That is, for example, when the user wants to display “document A”, the user performs an operation of bringing the tip of the pointing device 10 into contact with the image area B1.
When the user performs an operation of selecting a document, the excitation coil unit 14 of the pointing device 10 and the power extraction coil unit 22 of the display device 20 are electromagnetically coupled, and power is supplied from the pointing device 10 to the display device 20. . Simultaneously with the supply of current, current is generated in the first coil group 211 and the second coil group 212 of the position specifying coil unit 21. At this time, the first determination circuit 213 and the second determination circuit 214 output a coordinate signal indicating the coil that generates the maximum current. Since the current is maximized in the coil closest to the tip of the pointing device 10, the signal output at this time is information indicating the position selected by the user.

  The communication control unit 24 supplies the coordinate signal output in this way to the pointing device 10 (step S5). The control unit 12 of the pointing device 10 specifies the position represented by this coordinate signal (step S6), and specifies the operation corresponding to the specified position (step S7). Specifically, the control unit 12 first specifies the position represented by the coordinate signal by referring to a lookup table. Subsequently, when the specified position is a position included in the display surface, the control unit 12 refers to the menu data and determines which image area on the menu screen has been selected, whereby the user operation Is identified. In addition, when the specified position is an operation point, the control unit 12 specifies an operation assigned to the operation point.

  The control unit 12 supplies display data corresponding to the specified operation to the display device 20 (step S8). For example, if the user selects “Document A” as described above, display data including this as title information is supplied. In the display device 20, the communication control unit 24 receives display data and stores it in the storage unit 25, and the display control unit 26 reads out the display data and displays it on the display unit 27 (step S9).

  In the information display system 100, the same processing as steps S5 to S9 is repeatedly executed thereafter, and the document desired by the user is displayed. For example, if the operation point P1 or P3 is selected, the display device 20 performs page transition, and if the operation point P2 is selected, the display device 20 displays a menu screen. In addition, the instruction | indication apparatus 10 should just supply only electric power, when the operation corresponding to the position selected by the user cannot be specified.

  As described above, the information display system 100 of the present embodiment can perform power supply and position specification in an electromagnetic manner. Therefore, the information display system 100 of the present embodiment does not need to use another method (for example, optical position specification) to specify the position, and has a configuration as compared with the case where a plurality of methods are used in combination. It can be simplified.

  In addition, the display device 20 according to the present embodiment can more efficiently extract power by providing a plurality of coils 221 for extracting power in two layers. In addition, by providing the coil 221 on the lower layer side than the coil of the position specifying coil portion 21, it is possible to reduce the influence on the position specifying even if the number of turns of the coil 221 is increased. On the other hand, since the position specifying coil unit 21 has a configuration that can sufficiently determine the position even with a one-turn coil, even if it is provided on the upper layer side, there is little interference with power extraction.

Furthermore, the information display system 100 of the present embodiment can operate the display device 20 passively. The display device 20 according to the present embodiment only performs transmission / reception and display control of information according to an instruction from the instruction device 10, and can cause the instruction device 10 to perform other processing. Therefore, the display device 20 can sufficiently operate with a small amount of power.
In addition, since the display device 20 of the present embodiment can be operated with a small amount of power, the display device 20 can be configured without a power source, and the individual display devices 20 can be easily downsized. That is, it can be said that the configuration of the information display system 100 of the present embodiment is a particularly preferable configuration when a plurality of display devices 20 are used.

[Modification]
The present invention can be implemented not only in the embodiment described above but also in other forms. For example, in the above-described embodiment, the display device 20 that performs display processing using the extracted power is exemplified as the position detection device according to the present invention, but the extracted power may be used for other processing. Further, a configuration that realizes power extraction and position specification, that is, a configuration corresponding to the above-described position specification coil unit 21, power extraction coil unit 22, and power extraction unit 23 is an independent position detection device. The device may be configured to supply power and coordinate signals to an external device.

  The above-described embodiment is a particularly preferable embodiment for using a plurality of display devices 20, but it is needless to say that a configuration using one indication device 10 and one display device 20 may be adopted. In addition, when a plurality of display devices 20 are used, it is more preferable that identification information for identifying the display device 20 is transmitted and received between the instruction device 10 and the display device 20.

  In the embodiment described above, the display device 20 only outputs information (coordinate signals) for specifying the position, and the indication device 10 specifies the actual position, that is, the position of the display surface or the operation point. However, the process of specifying the position may be performed on the display device side. The coordinate signal does not need to be information defined in an orthogonal coordinate system, and may be in any format as long as the position can be specified.

Various modifications can be made to the configuration of the coil. For example, the coil 221 of the power extraction coil unit 22 may be multilayered from two layers or may be one layer.
In addition, the position specifying coil unit 21 is not configured to specify the position by the combination of the first coil group 211 and the second coil group 212. For example, a small square coil is arranged in the X direction and the Y direction. It may be. However, if it is desired to further improve the accuracy of position identification, it can be said that the configuration of the above-described embodiment is more advantageous.

A configuration in which a resonance capacitor is connected in parallel with the coil 221 of the power extraction coil unit 22 may be employed. The resonant frequency of this resonant capacitor can be determined according to the frequency band used for communication.
FIG. 12 is a diagram illustrating a case where a resonant capacitor is connected. As shown in the figure, the resonant capacitor 222 is connected in parallel to the coil 221 in the previous stage of the rectifier circuit 231.

In the embodiment described above, the position specifying coil unit 21 is configured to simultaneously detect the currents of the respective coils in the X direction or the Y direction, but may be configured to sequentially switch the coils to be detected.
FIG. 13 is a diagram illustrating a modification of the position specifying coil unit. As shown in the figure, the position specifying coil unit 21a includes a first coil group 211, a second coil group 212, a first switching circuit 213, a second switching circuit 214, a first peak detection circuit 215, And a second peak detection circuit 216. The first switching circuit 213 sequentially switches the coils connected to the first peak detection circuit 215. Further, the second switching circuit 213 sequentially switches the coils connected to the second peak detection circuit 216. The first peak detection circuit 215 and the second peak detection circuit 216 determine the magnitude of the input current, and output a coordinate signal indicating the coil that has generated the maximum current to the communication control unit 24.

In the above-described embodiment, the output of the coordinate signal is performed using only the position specifying coil unit 21, but the power extraction coil unit may be used in combination. For example, the position may be specified in more detail using the position specifying coil unit based on the result of specifying the position roughly using the power extraction coil unit.
FIG. 14 is a diagram illustrating a first modification in which the power extraction coil unit is used in combination, and is a diagram illustrating a part of the position specifying coil unit and the power extraction coil unit. Here, the position specifying coil unit 21 b includes coils 2111, 2112, 2113, and 2114, coils 2121, 2122, 2123, and 2124, a first determination circuit 215, and a second determination circuit 216. The power extraction coil unit 22 b includes coils 2211, 2122, 2213, and 2214 and a determination circuit 223. Here, it is assumed that the positional relationship between the coils is associated in advance. That is, for example, the coil 2211 overlaps with the coils 2111 and 2112, and is configured so that it can be specified that the coil 2211 overlaps with the coils 2121 and 2122.

The discrimination circuit 223 is connected to each of the coils 2211 to 2214, and discriminates the magnitude of the current generated in each. The determination circuit 223 specifies the coil that has generated the maximum current, and outputs a signal indicating the region occupied by the coil to the first determination circuit 215 and the second determination circuit 216. The first determination circuit 215 and the second determination circuit 216 specify the region indicated by the signal supplied from the determination circuit 223, and overlap the coil (any one of 2211 to 2214) in this region (any of the 2111 to 2114) Or any of 2121 to 2124), and the other coils are excluded from the determination target. The determination of the determination target is made based on the association described above.
An example of the operation in this modification is as follows. For example, if the user brings the pointing device 10 into contact with the area occupied by the coil 2214, the current generated in the coil 2214 is maximized. Then, the determination circuit 223 supplies a signal indicating a region corresponding to the coil 2214. The first discriminating circuit 215 identifies the coils 2113 and 2114 as discriminating targets based on the supplied signal, and identifies the maximum one from the current generated in these coils. Similarly, the second discriminating circuit 216 identifies the coils 2123 and 2124 as discriminating targets, and identifies the maximum one from the current generated in these coils.

  According to the configuration of this modification, the position can be specified to some extent using the power extraction coil unit 22b. Further, the power extraction coil unit 22b specifies the position to some extent, so that the position specifying coil unit 21b can omit the process related to the coil that does not need to be determined. In addition, you may implement the structure of this modification in combination with the structure (refer FIG. 13) which switches the coil to detect sequentially.

Furthermore, the structure which pinpoints a position using an electric power extraction coil part and a position specific coil part is also realizable as follows.
FIG. 15 is a diagram illustrating a second modification in which the power extraction coil unit is used in combination. In the figure, the position specifying coil unit 21 c includes a coil group 217 arranged in the X direction, and a determination circuit 218 connected to each coil constituting the coil group 217. The power extraction coil unit 22 c includes a coil group 227 arranged in the Y direction and a determination circuit 228 connected to each coil constituting the coil group 227. The discriminating circuits 218 and 228 discriminate each connected coil and output a signal specifying the coil that has generated the maximum current to the communication control unit 24.

  The configuration shown in FIG. 15 has a function in which the power extraction coil unit 22c has a function of specifying a position (region) in the Y direction. That is, in such a configuration, the power extraction coil unit 22c specifies a position (region) in the Y direction, the position specifying coil unit 21c specifies a position (region) in the X direction, and a combination of these specifies a more specific position. It is something to identify. In other words, this configuration specifies the first region using the power extraction coil unit 22c, specifies the second region using the position specifying coil unit 21c, and includes the first region and the second region. It can be said that it is the structure which specifies the area | region contained in both as the position which the user instruct | indicated.

  In the above-described embodiment, the first coil group 211 and the second coil group 212 have a configuration in which adjacent coils are not overlapped, but may be configured to overlap adjacent coils. In such a case, interpolation may be performed on the determined current, and the position may be specified based on the result of the interpolation.

FIG. 16 is a diagram illustrating a modification in which adjacent coils are overlapped. In the figure, only the main part of this modification is shown, and other configurations are omitted. The position specifying coil unit 21d shown in the figure includes coils 2111, 2112, and 2113, and a determination circuit 219. The coil 2111 overlaps with the coil 2112, and the coil 2112 overlaps with the coils 2111 and 2113. The discrimination circuit 219 is connected to the coils 2111, 2112, and 2113, and specifies the current generated in each of them. The determination circuit 219 specifies the coordinate in the X direction based on the magnitude of the current generated in the coils 2111 to 2113.

Here, the specification of the coordinates by the determination circuit 219 will be described with a specific example. Here, it is assumed that the discrimination circuit 219 detects a current that is not “0” for the coils 2111, 2112, and 2113, and the coil having the maximum detected current is the coil 2112. The detected current level is “0.2” for the coil 2111 and “0.8” for the coil 2113 when the level of the coil 2112 is “1”.
FIG. 17 is a schematic diagram for explaining an interpolation method by the discrimination circuit 219. In the figure, the horizontal axis represents the coordinates in the X direction, and the vertical axis represents the current level. Here, the coordinate of the center of the coil 2111 is “x ₁ ”, and similarly, the coils 2112 and 211 are arranged.
The coordinates of the center of 3 are “x ₂ ” and “x ₃ ”, respectively (see FIG. 16). The determination circuit 219 regards the current level as indicating a predetermined distribution curve in the X direction, applies the detected current level to the distribution curve, and specifies coordinates corresponding to the peak position as coordinates in the X direction. For example, in the example shown in FIG. 17, the coordinates specified by the determination circuit 219 are “x _i ”. That is, in this case, the determination circuit 219 specifies coordinates between the center of the coil 2112 and the center of the coil 2113 as coordinates in the X direction.

Although only the configuration for specifying the coordinates in the X direction is shown here, the Y direction can also be specified using the same configuration. Further, the interpolation method is not limited to the above-described method, and various methods may be used. For example, not only the coil adjacent to the coil with the maximum detected current but also the vicinity of the coil with the maximum detected current and interpolation using the current levels of all the coils where the current is generated. May be performed.
In addition, here, the interpolation method has been described using a modification in which adjacent coils are overlapped. However, even when adjacent coils do not overlap, the position is specified in the same manner by interpolation. Can do.

  When the specified position is a position corresponding to the display surface of the display device 20, the display control unit 26 may change the gradation of the pixel at the position. Alternatively, the pointing device 10 may supply image data in which the gradation of the pixel at the position is changed. In this way, the user can clearly recognize the position selected by the user. In this way, it is also possible to draw characters and figures on the display surface by moving the user so as to trace the pointing device 10.

In the above-described embodiment, the memory liquid crystal is shown as an example of the memory display body. However, other memory display bodies can be used. Examples of the other display body having a memory property include a microcapsule type electrophoresis display body, a so-called EPD (ElectroPhoretic Display), and the like.
Note that the present invention can also be implemented using a display body having no memory. However, especially in a display device such as electronic paper, the user often keeps looking at the display surface without operating for a long time. Therefore, it can be said that it is more advantageous to employ a memory display when applied to such a device that does not operate for a long time.

It is a figure showing roughly the information display system which is one embodiment of the present invention. It is a block diagram which shows the whole structure of an information display system. It is a figure which shows the structure of an exciting coil part. It is a figure which shows the structure of a position specific coil part. It is a figure which shows the structure of a position specific coil part. It is a figure which shows the structure of an electric power extraction coil part. It is a figure which shows the structure of an electric power extraction part. It is a figure which shows the external appearance of a display apparatus. It is sectional drawing of a display apparatus. It is a sequence diagram which shows operation | movement of an instruction | indication apparatus and a display apparatus. It is a figure which shows an example of a menu screen. It is a figure which shows the modification which connected the resonant capacitor. It is a figure which shows the modification of a position specific coil part. It is a figure which shows the modification which uses an electric power extraction coil part for position specification. It is a figure which shows the modification which uses an electric power extraction coil part for position specification. It is a figure which shows the modification which piled up adjacent coils. It is a schematic diagram for demonstrating the method of interpolation by a discrimination circuit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Information display system, 10 ... Instruction device, 11 ... Power supply part, 12 ... Control part, 13 ... Memory | storage part, 14 ... Excitation coil part, 20 ... Display apparatus, 21 ... Position specific coil part, 22 ... Power extraction coil part , 23 ... Power extraction unit, 24 ... Communication control unit, 25 ... Storage unit, 26 ... Display control unit, 27 ... Display unit

Claims (9)

A plurality of positioning coils arranged in a plane and generating a current corresponding to a change in magnetic flux;
A power extraction coil that is arranged to overlap at least one of the plurality of position specifying coils and generates a current according to a change in magnetic flux;
Information output means for specifying one position in a plane where these are arranged based on the magnitude of current generated in the plurality of position specifying coils, and outputting position information indicating the position;
And a power output means for extracting and outputting power from the current generated in the power extraction coil. The plurality of positioning coils are:
A first coil group that is a plurality of position specifying coils arranged in a first direction;
A second coil group that is arranged in a second direction intersecting the first direction and is a plurality of position specifying coils that overlap the first coil group;
The information output means includes
Based on the magnitude of the current generated in the first coil group, the coordinates when the first coordinate axis is set in the first direction are specified, and based on the magnitude of the current generated in the second coil group. 2. The position according to claim 1, wherein coordinates are determined when a second coordinate axis is set in the second direction, and position information indicating one position represented by these coordinates is output. Detection device. The information output means includes
Interpolation is performed using the current level of the positioning coil where the generated current is maximum and the current level of the positioning coil near the positioning coil, and these positioning coils are determined according to the result of the interpolation. The position detection device according to claim 1, wherein one position is specified from a region formed by   The position detection device according to claim 3, wherein each of the plurality of position specifying coils overlaps with an adjacent position specifying coil. The information output means includes
The position detection device according to claim 1, wherein a signal representing the position information is output via the power extraction coil or the position specifying coil. There are a plurality of the power extraction coils,
The information output means includes
First specifying means for specifying a first region using a plurality of the power extraction coils;
A second specifying means for specifying a second region using the plurality of position specifying coils,
The position detection device according to claim 1, wherein position information indicating a position included in the first area and included in the second area is output. There are a plurality of the power extraction coils,
The information output means includes
A region formed by one power extraction coil is specified based on the magnitude of current generated in the plurality of power extraction coils, and one position is specified based on the magnitude of current generated in the position specifying coil overlapping the region. The position detection device according to claim 1, wherein: A plurality of positioning coils arranged in a plane and generating a current corresponding to a change in magnetic flux;
A power extraction coil that is arranged to overlap at least one of the plurality of position specifying coils and generates a current according to a change in magnetic flux;
Information output means for specifying one position in a plane where these are arranged based on the magnitude of current generated in the plurality of position specifying coils, and outputting position information indicating the position;
Power extraction means for extracting power from the current generated in the power extraction coil;
A display device comprising: display means for performing display in accordance with the position information output by the information output means using the power extracted by the power extraction means. An information processing system comprising: a first device that supplies power; and a second device that receives supply of power from the first device when approaching the first device,
The first device includes:
Power supply means for supplying power by changing the magnetic flux,
The second device includes:
A plurality of positioning coils arranged in a plane and generating a current corresponding to a change in magnetic flux;
A power extraction coil that is arranged to overlap at least one of the plurality of position specifying coils and generates a current according to a change in magnetic flux;
Information output means for specifying one position in a plane where these are arranged based on the magnitude of current generated in the plurality of position specifying coils, and outputting position information indicating the position;
An information processing system comprising: power output means for extracting and outputting power from a current generated in the power extraction coil.

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