JP2017021864A - cartridge - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve mass productivity of a position indicator and to enable a user to determine a cartridge provided with what kind of function is stored in a position indicator.SOLUTION: A cartridge is detachably stored in the housing of a pen-like position indicator. A core body is provided so as to extend to the outside from a side of one end part in a center axis direction of a cylindrical body having a hallow part. A first circuit generating a signal for detecting an indication position by a position detection device is stored in the cylindrical body. The first circuit is electrically connected with a second circuit. The second circuit is stored in a package and connected to the first circuit via at least one connection end. The second circuit is provided with information specifying a position detection system of the cartridge, and the information specifying the position detection system of the cartridge is transmitted to the position detection device corresponding to the signal transmitted from the position detection device.SELECTED DRAWING: Figure 21

Description

  The present invention relates to a pen-shaped position indicator used with a position detection device, and more particularly to a cartridge housed in a housing of the position indicator.

  In recent years, position input devices have been used as input devices for portable devices, tablet PCs (personal computers), and the like. This position input device includes, for example, a pen-shaped position indicator and a position detection device having an input surface for inputting a pointing operation and characters and drawings using the position indicator. As this type of position input device, various detection methods such as an electromagnetic induction method and an electrostatic coupling method have been proposed.

  In a recent position input device, a pen-shaped position indicator is provided with a pressure-sensitive sensor that senses the pressure applied to the core serving as the pen tip, and the user can connect the position indicator to the position detection device. Pen pressure detection function that can detect whether the user touches the input surface (pen down) or how much pressure the user is operating the position indicator on the input surface after pen down Is provided.

  The pressure sensor provided in this position indicator is of the type that senses the pressure applied to the core body as a change in inductance, and the type that senses the pressure applied to the core body as a change in capacitance. There are various sense systems.

  For example, Patent Document 1 (Japanese Patent Laid-Open No. 2002-244806) is provided with a pressure-sensitive sensor that changes the inductance of a coil that constitutes a resonance circuit, and the pressure applied to the core body is set to the resonance frequency (or the resonance frequency of the resonance circuit). A position indicator is disclosed in which a pen pressure can be detected by the position detection device by transmitting the change to the position detection device as a change in phase.

  FIG. 22 is a cross-sectional view of a conventional position indicator 100 that detects writing pressure based on a change in inductance. As shown in FIG. 22, the position indicator 100 has a ferrite core 104 around which a coil 105 is wound and a ferrite chip 102 opposed to each other through an O (O) ring 103 and pressed against the core body 101. By applying (writing pressure), the ferrite chip 102 approaches the ferrite core 104. The O-ring 103 used here is a ring-shaped elastic member made of an elastic material such as a synthetic resin or synthetic rubber and having a cross section of the letter “O”.

  Further, in the case 111 of the position indicator 100, in addition to the above-described components, a plurality of resonance capacitors 115a for setting the resonance frequency of the resonance circuit when a pressure is not applied to the core body to a desired value. Printed circuit board 114 on which .about.115h are arranged, a substrate holder 113 for holding this printed circuit board 114, and a connection for connecting the coil 105 to the resonance capacitors 115a to 115h on the printed circuit board 114 to form a resonance circuit. The line 116 and the buffer member 117 are accommodated, and their positions are fixed by the cap 112.

  When the ferrite chip 102 with which the core body 101 abuts approaches the ferrite core 104 according to the pressing force applied to the core body 101, the inductance of the coil 105 wound around the ferrite core 104 changes accordingly. The phase (resonance frequency) of the electromagnetic induction signal transmitted from the coil 105 of the resonance circuit is changed. The position detection device detects the writing pressure applied to the core of the position indicator by receiving the change of the phase (resonance frequency) of the electromagnetic induction signal from the position indicator by the loop coil.

  In addition, by providing a pressure-sensitive sensor that changes the capacitance of the capacitor constituting the resonance circuit, the pressure applied to the core is transmitted to the position detection device as a change in the resonance frequency (or phase) of the resonance circuit. A position indicator adapted to do so is also known.

  For example, Patent Document 2 (Japanese Patent Laid-Open No. 4-96212) uses a variable capacitance capacitor that changes the capacitance according to the pressure applied to the core body as the capacitor constituting the resonance circuit. A position indicator is disclosed in which a change in capacitance is transmitted to a position detection device as a change in the resonance frequency (or phase) of a resonance circuit so that the writing pressure can be detected by the position detection device.

  The variable capacitance type capacitor described in Patent Document 2 is a first conductor attached to one end face of a cylindrical dielectric as a mechanical structural component housed in an elongated cylindrical casing. And a second conductor having flexibility and capable of elastic biasing disposed on the other end face facing the one end face of the dielectric. The surface of the second conductor facing the dielectric is, for example, in the shape of a dome, and has a shape that bulges toward the dielectric.

  The variable capacitance capacitor described in Patent Document 2 includes spacer means for separating the second conductor and the other end face of the dielectric by a small distance except for a part thereof, and second conductive And a component that applies relative pressure or displacement between the body and the dielectric. The component that applies this relative pressure or displacement is coupled to the core of the pen-shaped position indicator. When a writing pressure is applied to the position indicator from one end of the casing, the flexible second conductor is displaced to the dielectric side by the axial force applied to the core, and the second The conductor is biased so as to contact the other end face of the dielectric. The dome-shaped bulging end surface of the flexible second conductor comes into contact with the other end surface of the dielectric with an area corresponding to the pressing force. For this reason, the electrostatic capacitance comprised between the 2nd conductor and 1st conductor through a dielectric material changes.

JP 2002-244806 A JP-A-4-96212

  As described above, in the position indicator described in Patent Document 1, the ferrite in which the core body 101, the ferrite chip 102, the O-ring 103, and the coil 105 are wound in the space inside the cylindrical casing 111. Components such as the core 104, the printed board 114, and the board holder 113 that holds the printed board 114 are directly and sequentially stored and assembled. Similarly, in the position indicator described in Patent Document 2, a core, a ferrite core around which a coil is wound, a printed board, a board holder for holding the printed board, in the space inside the cylindrical casing, In addition to the components described above, the components of the variable capacitor are stored and assembled directly and sequentially.

  As described above, conventionally, in order to assemble the position indicator, the above-described components must be assembled in the central axis direction in the casing, which is not suitable for mass production. .

  In addition, it is applied when using either a pressure sensor that senses the pressure applied to the core as a change in inductance or a type that senses the pressure applied to the core as a change in capacitance. It is necessary to adjust the change characteristics of the inductance and the capacitance with respect to the pressure to obtain a desired pen-down detection characteristic and writing pressure characteristic. However, conventionally, it has been necessary to adjust these characteristics after assembling the components in the housing of the position indicator, which is very troublesome.

  In addition, if each component housed in the casing is misaligned in the casing, there is a problem that the circuit constants are changed and cannot be used normally. That is, in the case of Patent Document 1, for example, the center constant of both the ferrite chip 102 and the ferrite core 104 is shifted, so that the circuit constant changes and the change in inductance due to the proximity of the ferrite chip 102 is desired. There is a risk of becoming lost. Similarly, in the case of Patent Document 2, the circuit constant is changed between the flexible second conductor and the dielectric so that the center axis of the both is shifted and applied to the core. There is a risk that the change in capacitance with respect to the applied pressure will not be as desired.

  In view of this, a method of modularizing and assembling a part group of elastically biased parts such as an O-ring and a conductor can be considered. In recent years, however, pen-shaped position indicators have been required to have a thinner shape as the size of portable electronic devices such as PDAs and high-function mobile phone terminals has decreased. When the parts of the biased parts are assembled in advance to make a modular part, it is difficult to downsize the modular part, and there is a problem that it becomes a hindrance when thinning the pen-shaped position indicator there were.

  Further, when creating a modular part by assembling a predetermined part group, it takes time to assemble the part. Therefore, an operator has to assemble modularized parts over time and then combine them with other parts so that they are arranged in the case 111, resulting in a problem that productivity deteriorates.

  In view of the above points, an object of the present invention is to make it possible to solve the above-mentioned problems concerning the position indicator.

In order to solve the above problems, the present invention provides:
A cartridge that is used in a position detection device having an input surface and is housed in a housing of a pen-shaped position indicator that performs position indication on the input surface,
While being detachably housed in the housing of the position indicator,
A cylindrical body having a hollow portion;
A core body arranged to extend to the outside from one end side in the central axis direction of the cylindrical body;
A first circuit that is housed in the cylindrical body and that generates a signal for detecting the indicated position on the input surface by the position detection device;
A second circuit electrically connected to the first circuit;
With
The second circuit is housed in a package, and the second circuit is connected via at least one connection end connected to the first circuit,
The second circuit includes information for specifying a position detection method of the cartridge, and the cartridge position detection method provided in the second circuit corresponding to a signal transmitted from the position detection device. The cartridge is characterized in that information for specifying the position is transmitted to the position detection device.

  Here, in this specification, the electronic ink cartridge means that at least the core body and the pressure-sensitive sensor among the components of the position indicator are housed in the hollow portion of the cylindrical body, and are placed in the casing of the position indicator. It is a structure for storing. The electronic ink cartridge that houses all the main components of the position indicator in the hollow part of the cylindrical body is housed in the housing of the position indicator just like the ballpoint ink cartridge of the writing instrument. Can be configured. Therefore, in this specification, a part in which a part of the position indicator or main components are accommodated in the cylindrical body is referred to as an electronic ink cartridge.

  In the cartridge having the above-described configuration, the second circuit includes information for specifying the position detection method, and detects the position of the cartridge provided in the second circuit corresponding to the signal transmitted from the position detection device. Information specifying the method is transmitted to the position detection device.

  Therefore, according to the cartridge of the present invention, the information for specifying the position detection method of the cartridge is transmitted to the position detection device corresponding to the signal transmitted from the position detection device. It is possible to determine whether the cartridge having the function is accommodated in the cylindrical body of the position indicator.

  In the cartridge according to the present invention, since the second circuit is housed in the package, the position indicator can be easily configured. Therefore, mass production of the position indicator becomes easy.

  By using the cartridge according to the present invention, the position indicator can be easily manufactured, so that mass productivity can be improved. In the position detecting device, what kind of function the cartridge has in the cylindrical body of the position indicator. Can be discriminated. Further, by using the cartridge according to the present invention, it is possible to cope with the narrowing of the position indicator.

It is a figure for demonstrating 1st Embodiment of the electronic ink cartridge by this invention. It is a figure for demonstrating the structure of embodiment of the position indicator by which the electronic ink cartridge of embodiment is mounted. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 1st Embodiment. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 1st Embodiment. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 1st Embodiment. FIG. 3 is a circuit diagram illustrating an example of an equivalent circuit of the electronic ink cartridge according to the first embodiment. It is a figure for demonstrating the equivalent circuit of a position indicator provided with the electronic ink cartridge of 1st Embodiment with a position detection apparatus. It is a figure for demonstrating the modification of the electronic ink cartridge of 1st Embodiment. It is a figure for demonstrating 2nd Embodiment of the electronic ink cartridge by this invention. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 2nd Embodiment. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 2nd Embodiment. It is a figure for demonstrating the equivalent circuit of a position indicator provided with the electronic ink cartridge of 2nd Embodiment with a position detection apparatus. It is a figure which shows the flowchart for demonstrating the processing operation of the principal part of the position indicator of 2nd Embodiment by this invention. It is a figure which shows the flowchart for demonstrating the processing operation of the principal part of the position detection apparatus used with the position indicator of 2nd Embodiment by this invention. It is a figure for demonstrating 3rd Embodiment of the electronic ink cartridge by this invention. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 3rd Embodiment. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 3rd Embodiment. It is a figure for demonstrating the example of the component of the electronic ink cartridge of 3rd Embodiment. It is a circuit diagram which shows the example of the equivalent circuit of the electronic ink cartridge of 3rd Embodiment. It is a figure for demonstrating the modification of the electronic ink cartridge of 3rd Embodiment. It is a figure for demonstrating the electronic ink cartridge of 4th Embodiment. It is a figure which shows the structural example of the conventional electromagnetic induction type position indicator.

[First Embodiment]
In the first embodiment, the electronic ink cartridge according to the present invention is applied to an electromagnetic induction type position indicator. As an example of the pressure-sensitive sensor, there is a case where the inductance constituting the resonance circuit provided in the electromagnetic induction type position indicator changes according to the pressure applied to the core body. And in this 1st Embodiment, the structure of the pressure sensor which changes the inductance which comprises a resonance circuit is the same as that of the prior art example shown in above-mentioned FIG.

  1 to 8 are views for explaining a configuration example of a first embodiment of an electronic ink cartridge according to the present invention and a position indicator using the electronic ink cartridge of the first embodiment.

  The position indicator of the first embodiment includes a push switch that can be operated while the user is holding the casing of the position indicator, and the resonance circuit is turned on and off by the push switch. The resonance frequency can be changed. In addition, this push switch is provided in the peripheral part of the housing | casing in the position close | similar to a core, and is also called the side switch. The push switch ON / OFF operation is detected by the position detection device as described later. For example, it is determined by an electronic device such as a personal computer with the position detection device built in or externally connected. It is assigned to various functions such as operation input.

  FIG. 2A shows an outline of the entire configuration of the position indicator 1 of the first embodiment, which has a pen shape and a cylindrical housing 2. Then, the components of the position indicator 1 are accommodated in the internal space in the housing 2. In FIG. 2 (A), only the housing 2 of the position indicator 1 is shown in cross section in order to facilitate understanding of the internal configuration of the housing 2.

  The housing 2 of the position indicator 1 of the first embodiment is made of a nonmagnetic material, for example, resin, and has a cylindrical lower half 3 having an opening 3a on the pen tip side of the housing 2, and the lower portion It consists of a cylindrical upper half 4 that is concentrically fitted and joined to the half 3.

  A hollow portion 3b having a circular cross section, for example, is provided inside the lower half 3, and a basic portion of an electromagnetic induction type position indicator is provided in the hollow portion 3b as shown in FIG. An electronic ink cartridge 10 in which various components are housed in the cylindrical body 5 is disposed. In addition, a through hole 3d is formed in a part of the peripheral side surface of the lower half 3, and a pressing operation element 8 is provided in the through hole 3d. The push switch 7 can be pressed. Details of the internal configuration of the position indicator 1 will be described later.

[Configuration Example of Electronic Ink Cartridge 10]
A configuration example of the electronic ink cartridge 10 according to the first embodiment will be described with reference to FIGS. 1 and 3 to 6. FIG. 1A is a cross-sectional view for explaining the internal configuration of the electronic ink cartridge 10. In the electronic ink cartridge 10 of this example, a basic component of an electromagnetic induction type position indicator, that is, a core 11, a coil 16 whose inductance is variable, and the coil 16 are disposed in a hollow portion of the cylindrical body 5. And a capacitor circuit 18 including a capacitor constituting a resonance circuit. The diameter (inner diameter) of the hollow portion of the cylindrical body 5 is constant. In this example, the outer diameter of the cylindrical body 5 is also constant. The cylindrical body 5 is made of a nonmagnetic material such as a nonmagnetic metal, a resin material, glass, or ceramic, and in this example, a material such as SUS305 or SUS310S. As shown in FIG. 2, the cylindrical body 5 is stored in a state where the central axis direction thereof is the central axis direction of the housing 2 of the position indicator 1.

  For convenience of explanation, some components (a connecting member 17 and a capacitor circuit 18 described later) inside the cylindrical body 5 of the electronic ink cartridge 10 are not shown in FIG. 1A and will be described later. Separately, a sectional view was prepared. FIG. 1B is an exploded perspective view for explaining the overall configuration of the electronic ink cartridge 10.

  In the first embodiment, the cylindrical body 5 includes a first cylindrical body 5A and a second cylindrical body 5B that are divided into two in the central axis direction. In this example, each of the first cylindrical body 5A and the second cylindrical body 5B has a narrow shape with an outer diameter of, for example, 2.5 mm and an inner diameter of, for example, 1.5 mm to 2 mm.

  An opening 5Aa for extending the tip of the core body 11 is provided on one end side in the central axis direction (axial core direction) of the first cylindrical body 5A. The diameter of the opening 5Aa is smaller than the inner diameter of the first cylindrical body 5A. Therefore, a step portion 5As is formed on one end side in the central axis direction of the first cylindrical body 5A. On the other hand, the entire inner diameter of the other end side in the central axis direction of the first cylindrical body 5A is an opening 5Ab. Further, the entire inner diameter of the second cylindrical body 5B is open at both ends in the central axis direction.

  And as shown to FIG. 1 (A), the thread part formed in the inner wall face of the opening of the one end side of 2nd cylindrical body 5B in the outer peripheral side surface of opening 5Ab of 1st cylindrical body 5A A screw portion 5Ac that is screwed with 5Ba is formed. Further, on the inner wall surface in the vicinity of the opening on the other end side of the second cylindrical body 5B, a ring-shaped protrusion that fits with a ring-shaped groove 19a formed on the outer periphery of the cap 19 made of a non-magnetic material such as resin. 5Bb is formed by, for example, the second cylindrical body 5B being squeezed at the position.

  Further, as shown in FIG. 1B, a circumferential positioning groove 5Bc is provided along the central axis direction at a predetermined position in the circumferential direction of the opening end on the other end side of the second cylindrical body 5B. Is formed. The cap 19 is formed with a protrusion 19c that engages with the groove 5Bc of the second cylindrical body 5B. The cap 19 is pushed into the second cylindrical body 5B so that the protrusion 19c is inserted into the groove 5Bc, so that the ring-shaped groove 19a and the ring-shaped protrusion 5Bb are fitted to each other. The second cylindrical body 5B is locked.

  As shown in FIGS. 1 (A) and 1 (B), the first cylindrical body 5A has an example of a coil spring 12, a core body 11, and a second magnetic body as viewed from the opening 5Aa. The ferrite core 13, the O-ring 14, and the ferrite core 15 as an example of the first magnetic body around which the coil 16 is wound and the connecting member 17 are sequentially arranged so that the central axes of these components coincide with each other. And stored.

  The core body 11 in this embodiment is made of, for example, resin, and includes a tip portion having a diameter extending from the opening 5Aa of the first cylindrical body 5A, and a flange portion 11a, and an upper surface of the flange portion 11a. A protrusion 11b is provided at substantially the center. The flange portion 11a has a diameter slightly smaller than the inner diameter of the first cylindrical body 5A so as to be movable in the central axis direction within the first cylindrical body 5A.

  The ferrite chip 13 has a columnar shape slightly smaller than the inner diameter of the first cylindrical body 5A so that the ferrite chip 13 can move in the central axis direction within the first cylindrical body 5A. The ferrite chip 13 includes a recess 13a on the end surface on the core body 11 side in the central axis direction, and a protrusion 11b formed on the upper surface of the flange portion 11a of the core body 11 is fitted into the recess 13a. . The core body 11 is joined to the ferrite chip 13 with an adhesive or the like in a state where the protrusion 11b and the recess 13a are fitted. A protrusion 13b is formed at the center of the end surface of the ferrite chip 13 on the ferrite core 15 side in the central axis direction.

  The O-ring 14 includes an outer diameter smaller than the inner diameter of the first cylindrical body 5A and an elastic body having an inner diameter larger than the diameter of the protrusion 13b of the ferrite chip, for example, elastic rubber. In this case, the cross section of the O-ring 14 has a circular shape, and the diameter thereof is selected to be larger than the height of the protrusion 13b of the ferrite chip 13.

  The ferrite core 15 has a columnar shape, and the diameter including the wound coil 16 is slightly smaller than the inner diameter of the first cylindrical body 5A. On the end surface of the ferrite core 15 on the side of the connecting member 17 in the central axis direction, a concave portion 15a is formed in which a positioning projection 17c at the central axis position formed on the connecting member 17 is fitted.

  The connecting member 17 mechanically connects the ferrite core 15 and the capacitor circuit 18 and electrically connects the coil 16 wound around the ferrite core 15 and the capacitor of the capacitor circuit 18.

  FIG. 3 is a diagram for explaining a configuration example of the connecting member 17. 3A is a view of the connecting member 17 as viewed from the side where it is connected to the ferrite core 15, and FIG. 3B is a cross-sectional view taken along line BB of FIG. 3A. FIG. 3C is a view of the connecting member 17 as viewed from the side where it is connected to the capacitor circuit 18.

  As shown in FIGS. 3A and 3B, the connecting member 17 is a non-magnetic body having a cylindrical shape whose outer diameter is substantially equal to the inner diameter of the first cylindrical body 5A, in this example, a main body portion made of resin. 171 are inserted terminal members 172 and 173 made of an elastic conductor for electrically connecting one end 16a and the other end 16b of the coil 16 to one end and the other end of the capacitor circuit 18, respectively. And molded.

  Ring-shaped concave grooves 17 a and 17 b are formed at predetermined positions on the outer peripheral surface of the main body 171 of the connecting member 17. On the other hand, as shown in FIG. 1A, the first cylindrical body 5A has, for example, an outer peripheral surface at a position where the ring-shaped grooves 17a and 17b correspond when the connecting member 17 is accommodated. The ring-shaped protrusions 5Ad and 5Ae that protrude toward the inner wall surface are formed by being narrowed to a shape. When the connecting member 17 is inserted in the direction of the central axis in the first cylindrical body 5A, the connecting member 17 is connected to the ring-shaped concave grooves 17a and 17b on the outer peripheral surface and the inner wall surface of the first cylindrical body 5A. The ring-shaped protrusions 5Ad and 5Ae are fixed to the first cylindrical body 5A by fitting.

  The positioning protrusion 17c described above is formed at the center of the end face of the main body 171 of the connecting member 17 on the ferrite core 15 side. In this example, the protrusion 17c has a quadrangular prism shape. The protrusion 17c of the connecting member 17 is fitted into the recess 15a formed on the end surface of the ferrite core 15, and the end surface of the ferrite core 15 and the flat surface of the main body portion 171 of the connecting member 17 are bonded with, for example, an adhesive. Thus, the ferrite core 15 and the connecting member 17 are coupled.

  Further, as shown in FIG. 3A, in this example, the circumferential side surface of the main body portion 171 of the connecting member 17 has a groove 174 in the central axis direction of the cylinder at a position spaced apart by an angular interval of 180 degrees. 175 is formed. In the concave grooves 174 and 175, one end portions 172a and 173a of the terminal members 172 and 173 are planted in a direction orthogonal to the circumferential direction. Then, as shown in FIG. 3A, V-shaped cuts 172b and 173b are formed at one end portions 172a and 173a of the terminal members 172 and 173 in the planted state.

  Then, as shown in FIG. 3B, one end 16a of the coil 16 is press-fitted into a V-shaped notch 172b of one end 172a of the terminal member 172, and is electrically connected to each other. The other end 16b of the terminal member 173 is press-fitted into the V-shaped notch 173b of the one end 173a of the terminal member 173 so as to be electrically connected to each other. Thus, what connected the ferrite core 15 and the connection member 17 in which the coil 16 is wound can be handled as one ferrite core module. One end 16a and the other end 16b of the coil 16 are one end of the terminal members 172 and 173 which are planted in the concave grooves 174 and 175 of the connecting member 17 without protruding from the outer peripheral surface of the connecting member 17. It is connected to the sections 172a and 173a. Accordingly, the one end 16a and the other end 16b of the coil 16 do not contact the inner wall surface of the first cylindrical body 5A.

  As shown in FIGS. 3B and 3C, the other end of the terminal member 172 of the connecting member 17 is formed as a ring-shaped electrode conductor 172c on the end face facing the end face of the capacitor circuit 18. Then, at the center of the end face of the connecting member 17 facing the end face of the capacitor circuit 18, as shown in FIGS. 3B and 3C, a ring-shaped electrode conductor constituting the other end of the terminal member 172 is provided. A concave hole 17d is formed in a state separated from 172c.

  The other end 173c of the terminal member 173 of the connecting member 17 is located in the recessed hole 17d. An insertion hole 173d made of a bent portion having elasticity formed in the terminal member 173 is formed in a portion of the other end 173c of the terminal member 173 located in the concave hole 17d. The ring-shaped electrode conductor 172c at the other end of the terminal member 172 configured as described above and the other end 173c of the terminal member 173 are connected to one and the other terminals of the capacitor circuit 18, as will be described later. Terminal.

[Containment of components in first cylindrical body 5A of electronic ink cartridge 10]
Each component is assembled and stored in the first cylindrical body 5A of the electronic ink cartridge 10 as follows.

  1B, first, the connecting member 17 and the ferrite core 15 around which the coil 16 is wound are connected. Specifically, the projection 17c for positioning at the central axis position formed in the connecting member 17 and the recess 15a formed in the ferrite core 15 are fitted, and one end of the coil 16 wound around the ferrite core 15 is fitted. 16 a and the other end 16 b are connected to one end portions 172 a and 173 a of terminal members 172 and 173 provided on the connecting member 17, respectively.

  Next, the recess 13a formed in the ferrite chip 13 and the protrusion 11b formed on the upper surface of the flange portion 11a of the core body 11 are fitted, and the coil spring 12 is attached to the distal end side of the core body 11, An O-ring 14 is disposed around the protrusion 13b of the ferrite chip 13, and is inserted into the hollow portion of the first cylindrical body 5A from the opening 5Ab side in the central axis direction with the opening 5Aa side as a tip. The core body 11 is always urged by the coil spring 12 to the side opposite to the tip end side, and the tip end side is extended from the opening 5Aa of the first cylindrical body 5A.

  The connecting member 17 connected to each other and the ferrite core 15 around which the coil 16 is wound are disposed in the first cylindrical body 5A so that the ferrite core 15 faces the ferrite chip 13 via the O-ring 14. Is inserted in the direction of the central axis.

  At this time, the ring-shaped concave grooves 17a and 17b on the outer peripheral surface of the connecting member 17 are fitted into the ring-shaped protrusions 5Ad and 5Ae provided on the inner wall surface of the first cylindrical body 5A. Is fixed to the first cylindrical body 5A. In this embodiment, the coil spring 12 is disposed on the distal end side of the core body 11 in the hollow portion of the first cylindrical body 5A, and one end of the coil spring 12 is disposed on the distal end side of the core body 11 in the hollow portion of the first tubular body 5A. It arrange | positions in the state engaged with step part 5As. For this reason, the flange portion 11a of the core body 11, the ferrite chip 13, and the O-ring 14 disposed on the other end side of the coil spring 12 are always in contact with the first cylindrical body 5A by the elastic biasing force of the coil spring 12. By urging the connecting member 17 fixed to the side, rattling of these members is prevented.

  In this state, the end surface of the connecting member 17 opposite to the joint portion of the ferrite core 15 is exposed at the opening 5Ab of the first cylindrical body 5A. Therefore, the ring-shaped electrode conductor 172c of the terminal member 172 formed on the end face of the connecting member 17 and the end 173c of the terminal member 173 are also exposed at the opening 5Ab and can be contacted from the outside (FIG. 1). And FIG. 3 (C)).

  In addition, in this example, the formation positions of the ring-shaped protrusions 5Ad and 5Ae on the inner wall surface of the first cylindrical body 5A are such that the end surface on the side where the connecting member 17 is coupled to the capacitor circuit 18 is the first cylindrical shape. The position is such that it is flush with the end face of the opening 5Ab of the body 5A.

  In this embodiment, the ferrite chip 13, the O-ring 14, and the ferrite core 15 around which the coil 16 is wound constitute a pressure-sensitive sensor that senses the pressure applied to the core body 11. As described above, the ring-shaped electrode conductor 172c of the terminal member 172 formed on the end surface exposed at the opening 5Ab of the connecting member 17 and the end portion 173c of the terminal member 173 are a coil wound around the ferrite core 15. 16 is connected to one end 16 a and the other end 16 b of the coil 16, and is a connection terminal for making an electrical connection between the one end 16 a and the other end 16 b of the coil 16 and one end and the other end of the capacitor circuit 18.

  Accordingly, the ring-shaped electrode conductor 172c of the terminal member 172 as the connection terminal formed on the end surface exposed at the opening 5Ab of the connecting member 17 and the end 173c of the terminal member 173 have electrical characteristics of the pressure sensor. Thus, an inductance value that changes in accordance with the pressure applied to the core body 11 is exposed.

  Therefore, the probe terminal connected to the inductance measuring device is brought into electrical contact with each of the ring-shaped electrode conductor 172c of the terminal member 172 provided on the end surface of the connecting member 17 and the end portion 173c of the terminal member 173. Thus, the inductance value of the coil 16 can be measured. In this case, the inductance of the coil 16 measured by the inductance measuring device is an inductance in a state where no pressing force is applied to the core body 11.

  Then, by determining the capacitance value of the capacitor circuit 18 according to the measured inductance value of the coil 16, the resonance frequency of the resonance circuit composed of the coil 16 and the capacitor circuit 18 is set to a desired frequency. Can be set. That is, even if the inductance values of the coils 16 vary, the resonance frequency of the resonance circuit composed of the coils 16 and the capacitor circuit 18 is determined by determining the capacitance of the capacitors 18 according to the inductance values of the respective coils 16. Can be set to a desired frequency.

  As described above, the variation in the inductance value of the coil 16 is compensated by the capacitance value set in the capacitor circuit 18. As shown in FIG. 1, the capacitor circuit 18 whose capacitance value is set so that the resonance frequency becomes a desired one is connected to the connecting member 17 in the direction of the central axis. Then, in a state where the capacitor circuit 18 is housed, the second cylindrical body 5B is screwed with the first cylindrical body 5A at the screw portions 5Ac and 5Ba. And the cap 19 is inserted in the 2nd cylindrical body 5B, the opening of the 2nd cylindrical body 5B is obstruct | occluded, and the assembly of the cylindrical body 5 is completed.

  Next, the configuration of the capacitor circuit 18 will be described. FIG. 4 is a diagram for explaining a configuration example of the capacitor circuit 18 in this embodiment.

  In the first embodiment, the capacitor circuit 18 has a configuration in which a first capacitor circuit 181 and a second capacitor circuit 182 are coupled in the central axis direction, as shown in FIGS. 1 and 4. The first capacitor circuit 181 is connected in parallel with the coil 16 to form a resonance circuit when the push switch 7 is in one state, for example, OFF. Further, the second capacitor circuit 182 is connected in parallel with the coil 16 and the first capacitor circuit 181 to constitute a resonance circuit when the push switch 7 is turned on. The capacitance values of the first capacitor circuit 181 and the second capacitor circuit 182 are set so that the resonance frequency of the resonance circuit formed by each of them is a desired frequency.

  As shown in FIG. 4, the first capacitor circuit 181 and the second capacitor circuit 182 are housed by stacking a plurality of chip capacitors 183 inside each of cylindrical holders 1810 and 1820 made of, for example, resin. Are connected in parallel.

  In the case of this example, each of the chip capacitors 183 is, for example, a multilayer ceramic capacitor described in JP 2009-124155 A. The chip capacitor 183 in this example is formed in a rectangular parallelepiped shape, and as shown in black in FIG. 4, the end surfaces in the direction perpendicular to the capacitor stacking direction and facing each other are disposed on the stacked layers. One electrode 184 and the other electrode 185 of the chip capacitor 183 are exposed and formed over the entire direction.

  Therefore, by stacking the chip capacitors 183, all of the plurality of stacked chip capacitors are connected to one electrode 184 and the other electrode 185, and the chip capacitors 183 are connected to each other in parallel. It will be. The capacitance values of the first capacitor circuit 181 and the second capacitor circuit 182 are set according to the capacitance values of the chip capacitors 183 accommodated in the holders 1810 and 1820 and the number thereof. The

  The depths of the hollow portions 1811 and 1821 of the holders 1810 and 1820, that is, the number of chip capacitors 183 to be stacked are set in consideration of the degree of variation in the inductance value of the coil 16 described above. When the number of chip capacitors 183 accommodated in the hollow portions 1811 and 1821 is less than a predetermined number as a result of optimizing the capacitance value by stacking the chip capacitors 183, the inside of the hollow portions 1811 and 1821 In this example, dummy chip capacitors having substantially no capacitance value are accommodated so that the predetermined number is always provided.

  In this example, elastically deformable claw portions 1812 and 1813 are formed on the opening side of the hollow portions 1811 and 1821 of the holders 1810 and 1820 so as to protrude toward the hollow portions 1811 and 1821 from the opposing wall surfaces. , 1822, and 1823 are provided. The chip capacitor 183 is accommodated in the hollow portions 1811 and 1821 so as to overcome the claw portions 1812 and 1813 and 1822 and 1823 by elastically biasing. The claw portions 1812, 1813 and 1822, 1823 engage with the upper surface of the uppermost one of the plurality of chip capacitors 183 accommodated in the hollow portions 1811 and 1821, and a plurality of the claw portions 1812, 1813 and 1822, 1823 The entire chip capacitor 183 is locked.

  The holder 1810 of the first capacitor circuit 181 is provided with a pair of terminal members 1814 and 1815 so as to penetrate between both end faces in the central axis direction as indicated by a dotted line in FIG. The terminal member 1814 is provided so as to be connected to all the electrodes 184 of the chip capacitor 183 accommodated in the hollow portion 1811. The terminal member 1815 is provided so as to be connected to all the other electrodes 185 of the chip capacitor 183 housed in the hollow portion 1811.

  4, one end 1814a of the terminal member 1814 is led out to the end surface side facing the connecting member 17, and is in contact with the ring-shaped electrode conductor 172c at the other end of the terminal member 172 of the connecting member 17. And are configured to be electrically connected. Further, the other end 1814b of the terminal member 1814 is provided to be bent outward from the opening of the hollow portion 1811 on the end face side facing the second capacitor circuit 182 as shown in FIG.

  In addition, as shown in FIG. 4, one end 1815 a of the terminal member 1815 is led out as a rod-like body protruding from the central portion of the end surface facing the connecting member 17 and inserted into an insertion hole 173 d formed in the connecting member 17. Thus, the terminal member 173 is configured to be electrically connected to the end portion 173c of the terminal member 173. Further, the other end 1815b of the terminal member 1815 is provided to be bent outward from the opening of the hollow portion 1811 on the end face side facing the second capacitor circuit 182 as shown in FIG.

  Further, terminal members 1824 and 1825 are provided on the holder 1820 of the second capacitor circuit 182 so as to penetrate between both end faces in the central axis direction, as indicated by a dotted line in FIG. Further, the holder 1820 is further provided with a terminal member 1826.

  The terminal member 1824 is provided so as to be connected to all the electrodes 184 of the chip capacitor 183 accommodated in the hollow portion 1821. The terminal member 1825 is provided so as to penetrate between both end surfaces of the holder 1820 in the central axis direction without being connected to the chip capacitor 183 of the hollow portion 1821. Further, the terminal member 1826 is provided so as to be connected to all the other electrodes 185 of the chip capacitor 183 housed in the hollow portion 1821. However, one end of the terminal member 1826 exists in the holder 1820 and is not exposed to the outside, and only the other end 1826b is exposed to the outside.

  One end 1824a of the terminal member 1824 is led out to the end face side facing the first capacitor circuit 181 and is abutted with the other end 1814b of the terminal member 1814 of the first capacitor circuit 181 as shown by a dotted line in FIG. And are configured to be electrically connected. Further, the other end 1824b of the terminal member 1824 is provided to be bent outward from the opening of the hollow portion 1821 on the end face side facing the end face of the cap 19 as shown in FIG.

  One end 1825a of the terminal member 1825 is led out to an end face side facing the first capacitor circuit 181 as shown by a dotted line in FIG. 4, and abuts with the other end 1815b of the terminal member 1815 of the first capacitor circuit 181. And are configured to be electrically connected. Further, the other end 1825b of the terminal member 1825 is provided so as to be exposed to the side of the opening of the hollow portion 1821 on the end face side facing the cap 19, as shown in FIG.

  The other end 1826b of the terminal member 1826 connected to all the other electrodes 185 of the chip capacitor 183 housed in the hollow portion 1821 has a hollow portion on the end surface side facing the end surface of the cap 19, as shown in FIG. 1821 is bent and provided outside the opening.

  In addition, a protrusion 182a along the central axis direction is formed at a predetermined position on the outer periphery of the holder 1820 of the second capacitor circuit 182. The protrusion 182a is for positioning the second capacitor circuit 182 in the circumferential direction in the second cylindrical body 5B. As described above, the groove 5Bc is formed in the cylindrical body 5B in the axial direction from the opening end on the other end side, and the protrusion 182a of the second capacitor circuit 182 is inserted into the groove 5Bc. Thus, circumferential positioning is performed.

  Further, fitting concave holes 1816 and 1817 are formed on the end surface of the holder 1810 of the first capacitor circuit 181 facing the holder 1820 of the second capacitor circuit 182 as shown in FIG. Further, the end face of the holder 1820 of the second capacitor circuit 182 that faces the holder 1810 of the first capacitor circuit 181 is not shown, but the protrusion that fits into the fitting concave holes 1816 and 1817 of the holder 1810. Part is formed.

  In this case, although not shown, the fitting concave holes 1816 and 1817 of the holder 1810 are bent in an L shape, and the protrusion of the holder 1820 has a tip bent in an L shape. When the protrusions of the holder 1820 are fitted into the fitting concave holes 1816 and 1817 of 1810, the protrusions of the holder 1820 are elastically biased and inserted into the fitting concave holes 1816 and 1817, The first capacitor circuit 181 and the second capacitor circuit 182 are coupled so that the mutual coupling is not easily released.

  As described above, when the inductance value of the coil 16 accommodated in the first cylindrical body 5A is measured, an electrostatic capacitance that forms a parallel resonance circuit with the coil 16 having the inductance and has a desired resonance frequency is obtained. A capacitance value is calculated, and a plurality of chip capacitors 183 are housed in the holder 1810 of the first capacitor circuit 181 so that the calculated capacitance value is obtained.

  When the capacitance value of the first capacitor circuit 181 is set based on the measured inductance value so as to obtain a desired resonance frequency, the capacitance value of the second capacitor circuit 182 is then set. Is set. The capacitance value of the first capacitor circuit 181 is determined based on the desired resonance frequency and the measured inductance when the push switch (side switch) 7 is not operated (either the switch off state or the on state). It is set from the value of.

  On the other hand, the capacitance value of the second capacitor circuit 182 is set to a desired resonance frequency when the push switch (side switch) 7 is operated (the other of the switch off state and the on state). Therefore, the value depends on the measured inductance value and the capacitance value of the first capacitor circuit 181.

  That is, the inductance value of the coil housed in the first cylindrical body 5A is measured in the same state as the actual use state. Since the resonance frequency of the resonance circuit composed of the coil 16 and the first capacitor circuit 181 is known, the capacitance value of the first capacitor circuit 181 can be calculated. Therefore, the capacitance value of the first capacitor circuit 181 is set to a value that is the same as or close to the calculated capacitance value.

  Further, since the resonance frequency to be changed by operating the push switch (side switch) 7 is known, the first frequency depends on the measured inductance value and the capacitance value of the first capacitor circuit 181. The value of the capacitance that should be included in the second capacitor circuit 182 connected in parallel to one capacitor circuit 181 can also be calculated.

More specifically, in the same state as the actual use state, the inductance of the coil housed in the first cylindrical body 5A is L1, the resonance frequency when the push switch 7 is not operated is f1, and the first When the capacitance of the capacitor circuit 181 is C1,
Since f1 = 1 / {2 · π · (L1 · C1) ^1/2 }, the capacitance C1 is
Calculated as C1 = 1 / {4 · π ² · f1 ^{2 ·} L1}.

That is, the resonance frequency is f1, and the inductance of the coil housed in the first cylindrical body 5A is measured as L1 in the same state as the actual use state, so that the capacitance C1 of the first capacitor circuit 181 is measured. Can be calculated. Also, assuming that the value actually set as the capacitance of the first capacitor circuit 181 is C11 approximated to C1 by measuring the capacitance, the resonance frequency when the push switch 7 is operated is f2, if the capacitance of the second capacitor circuit 182 is C2,
f2 = 1 / {2 · π · (L1 · (C11 + C2)) ^1/2 }, and the value C2 to be set as the capacitance of the second capacitor circuit 182 is:
C2 = 1 / {4 · π ² · f2 ^{2 ·} L1} −C11.

  Next, FIG. 5 shows a configuration example of the cap 19. 5A is a view of the cap 19 as viewed from the side facing the capacitor circuit 18, and FIG. 5B is a cross-sectional view taken along the line CC in FIG. 5A. FIG. 5C is a view of the cap 19 as viewed from the side opposite to the surface facing the capacitor circuit 18.

  The cap 19 is formed by inserting terminal members 192 and 193 made of a conductor into a main body 191 made of a non-magnetic material, in this example, a resin. The cap 19 includes a connector 194 to which the tip of the flexible lead portion 9 led out from the push switch 7 described later is fitted.

As shown in FIGS. 1 and 5C, the main body 191 of the cap 19 has a columnar shape as a whole, and the surface facing the capacitor circuit 18 is the second cylindrical body of the electronic ink cartridge 10. A small diameter portion 195 having a diameter inserted into 5B is used, and the others are a large diameter portion 196 having a diameter larger than the outer diameter of the cylindrical body 5. A portion of the large diameter portion 196 of the cap 19 on the side opposite to the surface facing the capacitor circuit 18 has a shape in which a cylindrical portion is partially cut out in the central axis direction. In the example of the figure, the large diameter portion 196 is formed by cutting out half of the cylindrical shape portion and forming a plane 197 parallel to the central axis direction. The small diameter portion 195 of the cap 19 is as described above. In addition, a ring-shaped groove 19a that fits into the ring-shaped protrusion 5Bb provided on the inner wall of the opening of the second cylindrical body 5B is formed. Further, the small-diameter portion 195 of the cap 19 is formed with a protrusion 19c that engages with the positioning groove 5Bc formed on the opening end side of the second cylindrical body 5B in the direction of the central axis of the cap 19. ing. Further, the large-diameter portion 196 of the cap 19 is formed with a screw portion 19b that engages with a screw portion formed on the inner wall surface of the casing of the position indicator 1, as will be described later.

  The terminal members 192 and 193 are provided so as to make an electrical connection between the capacitor circuit 18 and a connector 194 provided on a plane 197 formed in the large diameter portion 196. That is, one end 192 a of the terminal member 192 elastically abuts with the other end 1826 b of the terminal member 1826 on the end surface of the second capacitor circuit 182 on the surface of the small diameter portion 195 of the cap 19 facing the capacitor circuit 18. To be derived. The other end 192 b of the terminal member 192 is connected to one end of the connector 194. Also, one end 193a of the terminal member 193 elastically abuts with the other end 1825b of the terminal member 1825 on the end surface of the second capacitor circuit 182 on the surface of the small diameter portion 195 of the cap 19 facing the capacitor circuit 18. To be derived. The other end 193 b of the terminal member 193 is connected to the other end of the connector 194. One end of the connector 194 is connected to one end of a push switch 7 described later, and the other end of the connector 194 is connected to the other end of the push switch 7.

[Assembly of second cylindrical body 5B of electronic ink cartridge 10]
In the first embodiment, first, the first capacitor circuit 181 having the capacitance value set as described above is connected to the connecting member 17. Specifically, one end 1815a of the terminal member 1815 of the first capacitor circuit 181 formed in a rod-like body is inserted into the insertion hole 173d of the connecting member 17, and the other end of the terminal member 173 provided in the connecting member 17 In addition to being connected to the portion 173c, the one end 1814a of the terminal member 1814 is connected so as to abut the ring-shaped electrode conductor 172c of the connecting member 17.

  Next, the first capacitor circuit 181 connected to the connecting member 17 is housed in the hollow portion of the second cylindrical body 5B, and formed on the inner wall surface of the opening on one end side of the second cylindrical body 5B. The screw portion 5Ba and the screw portion 5Ac formed on the outer peripheral side surface of the opening 5Ab of the first cylindrical body 5A are screwed together to form an integral cylindrical body. At this time, the fitting concave holes 1816 and 1817 on the end surface of the first capacitor circuit 181 facing the second capacitor circuit 182 are positioned so as to engage with the fitting protrusions of the second capacitor circuit 182. As described above, the first capacitor circuit 181 is rotated to determine the circumferential position in advance.

  Then, refer to FIG. 4 while engaging the protrusion 182a with the positioning groove 5Bc of the second cylindrical body 5B of the second capacitor circuit 182 having the capacitance value set as described above. As described above, the first capacitor circuit 181 is mechanically and electrically connected.

  Next, the small-diameter portion 195 of the cap 19 is inserted into the second cylindrical body 5B so that the protrusion 19c is engaged with the positioning groove 5Bc. Then, the ring-shaped groove 19a of the cap 19 and the ring-shaped protrusion 5Bb of the second cylindrical portion 5B are fitted, and the cap 19 is locked to the inside of the second cylindrical body 5B. At this time, the other end 1825b of the terminal member 1825 of the second capacitor circuit 182 and the other end 1826b of the terminal member 1826 are connected to one end 193a of the terminal member 193 of the cap 19 and one end 192a of the terminal member 192, respectively.

  The electronic ink cartridge 10 is assembled as described above. In this electronic ink cartridge 10, the resonance frequency of the parallel resonance circuit composed of the coil 16 and the capacitor circuit 18 to be accommodated is adjusted in both the state where the push switch 7 is off and on. Therefore, in this embodiment, when the electronic ink cartridge 10 is housed in the housing 2 of the position indicator 1, adjustment of the resonance frequency is no longer necessary.

[Equivalent circuit of electronic ink cartridge 10]
FIG. 6 shows an equivalent circuit of the electronic circuit portion including the coil 16, the capacitor circuit 18, and the push switch 7 of the electronic ink cartridge 10 described above. In this case, as described above, the one end 16 a and the other end 16 b of the coil 16 are connected to the one end 172 a of the terminal member 172 of the connecting member 17 and the one end 173 a of the terminal member 173.

  As described above, in the state where the first capacitor circuit 181 of the capacitor circuit 18 is coupled to the connecting member 17, the one end 172a of the terminal member 172 of the connecting member 17 is connected via the ring-shaped electrode conductor 172c. The capacitor circuit 18 is connected to one end 1814 a of the terminal member 1814 of the first capacitor circuit 181. Further, one end 173a of the terminal member 173 of the connecting member 17 is connected to one end 1815a of the terminal member 1815 of the first capacitor circuit 181 via the end 173c.

  Therefore, as shown in FIG. 6, the plurality of chip capacitors 183 housed in the first capacitor circuit 181 are connected in parallel to the coil 16. FIG. 6 shows a state where the capacitances Ca to Ce of the five chip capacitors 183 are connected in parallel to the inductance of the coil 16. The capacitances Ca to Ce of the plurality of chip capacitors 183 may be equal to each other or different from each other. Since the capacitances Ca to Ce are connected in parallel to each other, the overall capacitance of the first capacitor circuit 181 is determined by the static capacitance of each of the plurality of chip capacitors 183 accommodated in the first capacitor circuit 181. It is a simple addition of the capacitance.

  Next, in a state where the second capacitor circuit 182 is further coupled to the first capacitor circuit 181, the other end 1814 b of the terminal member 1814 of the first capacitor circuit 181 and the terminal of the second capacitor circuit 182. One end 1824a of the member 1824 is electrically connected, and the other end 1815b of the terminal member 1815 of the first capacitor circuit 181 and one end 1825a of the terminal member 1825 of the second capacitor circuit 182 are electrically connected. Is done. As shown in FIG. 6, the push switch 7 is connected between the other end 1826 b of the terminal member 1826 of the second capacitor circuit 182 and the other end 1825 b of the terminal member 1825 through the connector 194 of the cap 19. The

  Therefore, when the other end 1826b of the terminal member 1826 and the other end 1825b of the terminal member 1825 are short-circuited, the push switch 7 is in an equivalent state to the ON state. In addition to the plurality of chip capacitors 183 of the first capacitor circuit 181, the plurality of chip capacitors 183 housed in the capacitor circuit 182 are connected to each other in parallel. In FIG. 6, electrostatic capacitances Cf to Ci of four chip capacitors 183 are housed in the second capacitor circuit 182 and are connected in parallel to the inductance of the coil 16. . Also in this case, the capacitances Cf to Ci of the plurality of chip capacitors 183 may be equal to each other or different from each other.

  As described above, in the first embodiment, in the hollow portion of the first cylindrical body 5A, the core body 11 and the variable inductance coil 16 (ferrite chip 13 and O ring 14 constituting the pressure sensor). And a ferrite core 15) and a connecting member 17 are sequentially arranged and stored in the central axis direction, and are connected to one end 16 a and the other end 16 b of the coil 16 on the end surface of the connecting member 17. The ring-shaped electrode conductor 172c and the end 173c are formed as a connection terminal so as to be accessible from the outside. Therefore, when a pressure is applied to the core body 11, the inductance of the coil 16 corresponding to the applied pressure appears at this connection terminal. For this reason, by measuring the electrical characteristic (inductance) obtained at the connection terminal, it is possible to know the change characteristic of the inductance with respect to the pressure applied to the core body 11, and the electronic ink cartridge 10 has a desired writing pressure. It is possible to confirm whether or not the detection characteristic is satisfied.

  Further, in this embodiment, the connection terminal provided on the coupling member 17 connected to the one end 16a and the other end 16b of the coil 16 is configured to be exposed from the first cylindrical body 5A. Therefore, the first capacitor circuit 181 is connected so that one electrode and the other electrode of the first capacitor circuit 181 constituting the capacitor circuit 18 in which a desired capacitance value is set are connected to the connection terminal. The position indicator can be configured simply by coupling to the connecting member 17, and the configuration becomes very simple.

  Further, in this embodiment, the core body 11, the inductance variable coil 16, the connecting member 17, and the capacitor circuit 18 are all inserted into the electronic ink cartridge 10, and the electronic ink cartridge 10 has a resonance frequency. It has been assembled in the state that has already been adjusted. Therefore, the position indicator 1 can be configured simply by storing the electronic ink cartridge 10 in the housing of the position indicator 1. For this reason, the position indicator 1 which can handle the electronic ink cartridge 10 like a replacement core such as a so-called ballpoint pen can be realized.

  Further, as described above, in this embodiment, in the cylindrical body 5 of the electronic ink cartridge 10, all the components are arranged side by side in the central axis direction and sequentially arranged, and are electrically connected. Since the mechanical coupling is also performed, it is possible to easily realize a configuration of a thin electronic ink cartridge having a diameter of, for example, 2.5 mm as in the above example. The second capacitor circuit 182 is required when the position indicator 1 is provided with the push switch 7. When the position indicator 1 is not provided with the push switch 7, the second capacitor circuit 182 is provided. The other end 1826b of the terminal member 1826 and the other end 1825b of the terminal member 1825 can be used by being short-circuited. Alternatively, the capacitor circuit 18 can be constituted by the first capacitor circuit 181 alone without connecting the second capacitor circuit 182.

[Storing the electronic ink cartridge in the position indicator housing]
As shown in FIG. 2A, the electronic ink cartridge 10 of this embodiment is mounted on the lower half 3 of the housing 2 of the position indicator 1 and stored in the housing 2. Before the electronic ink cartridge 10 is inserted, the push switch 7 is provided on the lower half 3 of the housing 2 as described below.

  That is, a part of the peripheral side surface of the lower half 3 is provided with, for example, a circular or elliptical through hole 3d, and a pressing operator 8 for pressing the push switch 7 is disposed in the through hole 3d. The The pressing operator 8 is made of an elastic body such as elastic rubber.

  As shown in FIG. 2 (B), the push switch 7 is disposed in a portion 6a of the ring-shaped member 6 whose outer diameter is substantially equal to the inner diameter of the lower half 3 and in which a part in the circumferential direction is cut away. . The ring-shaped member 6 includes a through hole 6 b having a diameter larger than the outer diameter of the cylindrical body 5 of the electronic ink cartridge 10.

  Here, in this embodiment, the step portion 3e is formed by making the diameter of the hollow portion 3b of the lower half 3 on the side of the opening 3a slightly smaller than other portions. The ring-shaped member 6 is engaged with the step portion 3e so that its position in the central axis direction is regulated, and is fixed to the lower half 3 with an adhesive, for example. As a result, the ring-shaped member 6 is positioned such that the pressed surface 7a (see FIG. 2B) of the push switch 7 is positioned in the central axis direction corresponding to the pressing operator 8.

  In the case of this example, as shown in FIG. 2B, a lead portion (hereinafter referred to as a flexible lead portion) 9 made of a flexible wiring substrate for electrical connection is led out from the push switch 7. Then, as shown in FIG. 2C, which is a cross-sectional view taken along the line A-A of FIG. 2A, a part of the peripheral portion screwed with the cap 19 of the electronic ink cartridge 10 of the lower half 3 is provided. A guide groove 3f is formed so that a gap is formed between the guide groove 3f and the guide groove 3f. As shown in FIGS. 2A and 2C, the flexible lead portion 9 led out from the push switch 7 can be led out of the lower half 3 through the guide groove 3f.

  As described above, in the first embodiment, the electronic ink cartridge 10 is opposed to the core 11 side in the central axis direction of the lower half 3 of the housing 2 in which the push switch 7 is attached. Insert from the side. In this case, as shown in FIG. 2A, in the electronic ink cartridge 10, the core body 11 extending from the cylindrical body 5 extends to the outside from the opening 3 a of the lower half 3 of the housing 2. As shown in FIG. 6, the lower half 3 is inserted in the central axis direction through the through hole 6 b of the ring-shaped member 6.

  The opening 3 a of the lower half 3 is larger than the diameter of the core body 11 but smaller than the diameter of the cylindrical body 5 of the electronic ink cartridge 10. Accordingly, in the electronic ink cartridge 10, the core body 11 side of the cylindrical body 5 is engaged with the end portion of the inner wall on the opening 3a side of the lower half 3, and the position in the central axis direction is regulated.

  In inserting the electronic ink cartridge 10 into the lower half 3, the flexible lead portion 9 led out from the push switch 7 is led out to the cap 19 side of the electronic ink cartridge 10 through the guide groove 3f. To. The electronic ink cartridge 10 is fixed to the lower half 3 by screwing the screw portion 19 b of the cap 19 of the electronic ink cartridge 10 into the screw portion 3 c of the lower half 3.

  Thereafter, the leading end of the flexible lead portion 9 led out from the push switch 7 is fitted into a connector 194 formed on the cap 19 of the electronic ink cartridge 10 to be electrically connected. Then, the position indicator 1 of this embodiment is completed by press-fitting the upper half 4 to the lower half 3.

  As described above, in this embodiment, the position indicator 1 can detachably attach the electronic ink cartridge 10 to the lower half 3, and as described above, the electronic ink cartridge 10 can be easily replaced. It becomes. The push switch 7 can be connected after the electronic ink cartridge 10 is attached to the lower half 3, and the connection is also easy.

[Circuit configuration of indication position detection and writing pressure detection]
In the position indicator 1 of this embodiment, when a pressing force (writing pressure) is applied to the core body 11, the ferrite chip 13 is biased toward the ferrite core 15 via the O-ring 14, thereby causing the coil 16. And the resonance frequency changes according to the change in the inductance. That is, the resonance frequency (phase) of the electromagnetic induction signal transmitted from the coil 16 of the resonance circuit changes. Therefore, by using the position indicator 1 of this example, in the position detection device having the circuit configuration shown in FIG. 7 as described below, the indication position of the position indicator 1 and the writing pressure of the position indicator 1 are changed. Detection is possible.

  A circuit configuration example in the position detection apparatus 200 that detects the indicated position and the writing pressure using the position indicator 1 described above will be described with reference to FIG. FIG. 7 is a block diagram illustrating a circuit configuration example of the position indicator 1 and the position detection device 200.

  As described above, the position indicator 1 changes the resonance frequency of the resonance circuit by changing the capacitance value of the capacitor circuit 18 connected in parallel to the coil 16 in accordance with the ON / OFF of the push switch 7. Changes. In the position detection device 200, the detection of the pen pressure as described later and the operation state of the push switch 7 are detected by detecting the frequency shift (phase) of the resonance frequency of the resonance circuit of the position indicator 1. .

  In the position detection device 200, an X-axis direction loop coil group 211X and a Y-axis direction loop coil group 212Y are stacked to form a position detection coil. Each of the loop coil groups 211X and 212Y includes, for example, n and m rectangular loop coils. The loop coils constituting the loop coil groups 211X and 212Y are arranged so as to be sequentially overlapped at equal intervals.

  The position detection apparatus 200 is provided with a selection circuit 213 to which the X-axis direction loop coil group 211X and the Y-axis direction loop coil group 212Y are connected. The selection circuit 213 sequentially selects one loop coil of the two loop coil groups 211X and 212Y.

  Further, the position detection device 200 includes an oscillator 221, a current driver 222, a switching connection circuit 223, a reception amplifier 224, a detector 225, a low-pass filter 226, a sample hold circuit 227, and an A / D conversion. A circuit 228, a synchronous detector 229, a low-pass filter 230, a sample hold circuit 231, an A / D conversion circuit 232, and a processing control unit 233 are provided. The processing control unit 233 is configured by a microcomputer, for example.

  The oscillator 221 generates an AC signal having a frequency f0. The AC signal generated by the oscillator 221 is supplied to the current driver 222 and the synchronous detector 229. The current driver 222 converts the AC signal supplied from the oscillator 221 into a current and sends it to the switching connection circuit 223. The switching connection circuit 223 switches the connection destination (transmission side terminal T, reception side terminal R) to which the loop coil selected by the selection circuit 213 is connected under the control of the processing control unit 233. Among the connection destinations, a current driver 222 is connected to the transmission side terminal T, and a reception amplifier 224 is connected to the reception side terminal R.

  The induced voltage generated in the loop coil selected by the selection circuit 213 is sent to the reception amplifier 224 via the selection circuit 213 and the switching connection circuit 223. The reception amplifier 224 amplifies the induced voltage supplied from the loop coil and sends it to the detector 225 and the synchronous detector 229.

  The detector 225 detects the induced voltage generated in the loop coil, that is, the received signal, and sends it to the low-pass filter 226. The low-pass filter 226 has a cutoff frequency sufficiently lower than the above-described frequency f0, converts the output signal of the detector 225 into a DC signal, and sends it to the sample hold circuit 227. The sample hold circuit 227 holds a voltage value at a predetermined timing of the output signal of the low-pass filter 226, specifically, a predetermined timing during the reception period, and sends it to an A / D (Analog to Digital) conversion circuit 228. . The A / D conversion circuit 228 converts the analog output of the sample hold circuit 227 into a digital signal and outputs the digital signal to the processing control unit 233.

  On the other hand, the synchronous detector 229 synchronously detects the output signal of the reception amplifier 224 with the AC signal from the oscillator 221, and sends a signal having a level corresponding to the phase difference therebetween to the low-pass filter 230. The low-pass filter 230 has a cutoff frequency sufficiently lower than the frequency f 0, converts the output signal of the synchronous detector 229 into a DC signal, and sends it to the sample hold circuit 231. The sample hold circuit 231 holds the voltage value at a predetermined timing of the output signal of the low-pass filter 230 and sends it to an A / D (Analog to Digital) conversion circuit 232. The A / D conversion circuit 232 converts the analog output of the sample hold circuit 231 into a digital signal and outputs the digital signal to the processing control unit 233.

  The process control unit 233 controls each unit of the position detection device 200. That is, the processing control unit 233 controls the selection of the loop coil in the selection circuit 213, the switching of the switching connection circuit 223, and the timing of the sample hold circuits 227 and 231. Based on the input signals from the A / D conversion circuits 228 and 232, the processing control unit 233 causes the X-axis direction loop coil group 211X and the Y-axis direction loop coil group 212Y to transmit electromagnetic induction signals with a certain transmission duration.

  An induced voltage is generated in each loop coil of the X-axis direction loop coil group 211X and the Y-axis direction loop coil group 212Y by an electromagnetic induction signal transmitted from the position indicator 1. The processing control unit 233 calculates the coordinate value of the indicated position of the position indicator 1 in the X-axis direction and the Y-axis direction based on the level of the voltage value of the induced voltage generated in each loop coil. Further, the processing control unit 233 detects whether or not the push switch 7 is pressed based on the level of the signal corresponding to the phase difference between the transmitted electromagnetic induction signal and the received electromagnetic induction signal.

  In this manner, in the position detection device 200, the position of the approaching position indicator 1 can be detected by the processing control unit 233. Moreover, the processing control unit 233 of the position detection device 200 can detect the writing pressure applied to the core of the position indicator 1 by detecting the phase (frequency shift) of the received signal, Whether or not the push switch 7 is turned on in the position indicator 1 can be detected.

[Modification of First Embodiment]
In the electronic ink cartridge 10 according to the first embodiment described above, the cylindrical body 5 is structured to connect the first cylindrical body 5A and the second cylindrical body 5B. As the first cylindrical body 5A alone, the core body 11, the pressure sensitive sensor (coil spring 12, ferrite chip 13, O-ring 14, and ferrite core 15 around which the coil 16 is wound) and the connecting member 17 are connected to the cylindrical body. 5 may be configured to be housed.

  FIG. 8 is a diagram for explaining a configuration example of an electronic ink cartridge 10A according to a modification of the first embodiment. The same reference numerals are given to the same portions as those of the electronic ink cartridge 10 of the first embodiment described above. It is attached. As shown in FIG. 8, in the electronic ink cartridge 10A of this example, the cylindrical body 5A ′ has a configuration in the vicinity of the opening 5Ab ′ on the side to which the connecting member 17 is fixed, as in the first embodiment described above. Different from the first cylindrical body 5A.

  That is, in this example, the threaded portion that engages with the second tubular body 5B is not formed in the tubular body 5A ′ in the vicinity of the opening 5Ab ′. Instead, the cylindrical body 5A ′ is slightly longer in the central axis direction than the first cylindrical body 5A, and an end surface on which a connection terminal of the coupling member 17 to the capacitor circuit 18 ′ is formed. A recess 5AH is formed between the end face of the opening 5Ab ′ of the cylindrical body 5A ′. A ring-shaped protrusion 5Af is formed on the inner wall surface of the recess 5AH.

  On the other hand, on the peripheral side surface of the first capacitor circuit 181 ′ of the capacitor circuit 18 ′, in the vicinity of the end surface on the connection side with the connection member 17, a ring-shaped groove 181 a that fits with the ring-shaped protrusion 5 Af of the recess 5 AH. Is formed.

  In this modification, the core 11, the coil spring 12, the ferrite chip 13, the O-ring 14, the ferrite core 15 around which the coil 16 is wound, and the connecting member 17 are inserted into the cylindrical body 5 </ b> A ′. The connecting member 17 is fixed to the cylindrical body 5A ′ by fitting the 17 ring-shaped concave grooves 17a and 17b with the ring-shaped protrusions 5Ad and 5Ae.

  Thereafter, the first capacitor circuit 181 ′ of the capacitor circuit 18 ′ is inserted into the recess 5AH, and the rod-shaped one end 1815a of the terminal member 1815 is inserted into the insertion hole 173d of the terminal member 173 in the recess hole 17d of the connecting member 17. The terminal member 1814 is connected to the ring-shaped electrode conductor 172c of the connecting member 17 while the one end 1814a of the terminal member 1814 is abutted with the ring-shaped electrode conductor 172c. Then, the ring-shaped concave groove 181a is fitted to the ring-shaped protrusion 5Af and locked.

  In this example, in this state, as shown in FIG. 2A, the cap 19 is housed in the lower half 3 of the casing 2 of the position indicator 1, and then the cap 19 is screwed on the lower half 3. The electronic ink cartridge 10A can be fixed and accommodated in the position indicator 1 by screwing into the portion 3c. In this case, a recess in which a part of the second capacitor circuit 182 of the capacitor circuit 18 in the central axis direction is fitted is formed on the end surface of the cap 19 facing the capacitor circuit 18. It is preferable to form the ends 192a and 193a of the terminal members 192 and 193 of the cap 19 in the first embodiment described above at the bottom.

  In addition, although the above modification is a case where the position indicator 1 is provided with the push switch (side switch) 7, when the push switch 7 is not provided, the cap 19 is connected to the push switch 7. No connector is required. In that case, the cap 19 may be provided with a connection terminal for connecting the first capacitor circuit 181 and the second capacitor circuit 182 in parallel. That is, when the second capacitor circuit 182 is used as the capacitor circuit 18 together with the first capacitor circuit 181, the connection terminal that conducts the one end 1825 a of the terminal member 1825 and the other end 1826 b of the terminal member 1826 shown in FIG. The cap 19 is provided.

  In the case of a position indicator configuration that does not include the push switch 7, the capacitor circuit 18 may be the first capacitor circuit 181 alone or in parallel with the first capacitor circuit 181 and the first capacitor circuit 181. You may comprise by the 2nd capacitor circuit 182 connected. In that case, without providing the cap 19, the end of the capacitor circuit 18 is abutted against the wall formed inside the housing 2 of the position indicator 1, and the electronic ink cartridge You may make it not move in the axial direction in the vessel 1. In this case, of course, the end of the capacitor circuit 18 in the direction of the central axis may be covered with a protective cap so as to abut against the wall formed inside the housing 2 of the position indicator 1. .

[Second Embodiment]
In the pressure sensor provided in the electronic ink cartridge of the first embodiment described above, the position of the ferrite core as the first magnetic body is fixed, and the ferrite chip as the second magnetic body is pressed to the core body. The inductance of the coil wound around the ferrite core is changed according to the pressing force by changing the distance between the ferrite core and the ferrite chip by biasing in the central axis direction according to the pressure. did.

  The pressure-sensitive sensor provided in the electronic ink cartridge according to the second embodiment described below biases the ferrite core as the first magnetic body in the direction of the central axis according to the pressing force applied to the core body. The distance between the ferrite core and the ferrite chip is changed, and the inductance of the coil wound around the ferrite core is changed according to the pressing force.

  Further, in the second embodiment, by providing an information transmission circuit in the position indicator, as information related to the electronic ink cartridge and the position indicator, for example, identification information (ID) of the electronic ink cartridge and the position indicator Is transmitted to the position detecting device. The identification information (ID) is an example of information related to the electronic ink cartridge. The identification information includes a manufacturer, a product number, a manufacturing date, a manufacturing lot number, an electromagnetic induction method, or an electromagnetic induction method regarding the electronic ink cartridge or the position indicator. Information for specifying a position detection method such as a capacitance method, a writing pressure detection method based on variable inductance or variable capacitance is registered in a semiconductor element such as a memory or a register.

  The position indicator of the second embodiment described below is a case where the identification information of the electronic ink cartridge is transmitted to the position detection device. For this reason, in the second embodiment, the position indicator includes an ID transmission circuit 300 as an information transmission circuit. In the second embodiment, the ID transmission circuit 300 is housed in a cylindrical ID package 320, and the ID package 320 is housed in a cylindrical body.

  FIG. 9 is a diagram showing a configuration example of the electronic ink cartridge 20 which is a main part of the position indicator of the second embodiment. FIG. 9A is a cross-sectional view for explaining the internal configuration of the electronic ink cartridge 20. Also in this example, for convenience of explanation, a part of the components inside the cylindrical body 50 of the electronic ink cartridge 20 is not shown in FIG. 9A, but a sectional view is prepared separately as will be described later. did. FIG. 9B is an exploded perspective view for explaining the overall configuration of the electronic ink cartridge 20. In the second embodiment, the same reference numerals are assigned to the same components as those in the first embodiment.

  In addition, since the structure of the housing | casing of the position indicator of this 2nd Embodiment and the attachment structure to the said housing | casing of the push switch 7 are the same as that of 1st Embodiment, the illustration and description are abbreviate | omitted. To do.

  As shown in FIGS. 9A and 9B, also in the electronic ink cartridge 20, the main parts constituting the electromagnetic induction type position indicator are accommodated in the cylindrical body 50. In this embodiment, the cylindrical body 50 is not divided and has a single structure. The cylindrical body 50 of the second embodiment is also of a thin shape having an outer diameter of, for example, 2.5 mm and an inner diameter of, for example, 1.5 mm to 2 mm. The cylindrical body 50 is made of a nonmagnetic material such as a nonmagnetic metal, a resin material, glass, or ceramic, for example, a material such as SUS305 or SUS310S.

  An opening 50 a for extending the tip of the core body 21 is provided on one end side in the central axis direction of the cylindrical body 50. The diameter of the opening 50 a is smaller than the inner diameter of the cylindrical body 50. Further, the entire inner diameter of the other end side in the central axis direction of the cylindrical body 50 is an opening 50b. On the opening 50b side, a groove 50f along the central axis direction is formed for positioning in the circumferential direction, like the second cylindrical body 5B in the first embodiment described above.

  Then, as shown in FIGS. 9 (A) and 9 (B), the coil spring 22, the core body 21, and the coil 24 are wound around the cylindrical body 50 when viewed from the opening 50 a side. A ferrite core 23 as an example of a magnetic body, an O-ring 25, a ferrite chip 26 as an example of a second magnetic body, a connecting member 27, a capacitor circuit 28, and an ID package 320 are arranged in the order of the central axes thereof. The cylinders 50 are sequentially arranged and stored in the state of being in the central axis direction of the cylindrical body 50. And the cap 19 is inserted in the opening 50b of the cylindrical body 50, and the opening 50b of the cylindrical body 50 is obstruct | occluded.

  In the second embodiment, unlike the case of the first embodiment, when the connecting member 27 is stored at a predetermined position in the central axis direction of the cylindrical body 50, the side peripheral surface of the connecting member 27. By forming the protrusions on the inner peripheral surface of the cylindrical body 50 by narrowing the side peripheral surface positions 50c and 50d of the cylindrical body 50 corresponding to the above, the pressing member 27 is pressed and fixed to the cylindrical body 50. The position of the connecting member 27 is restricted so as not to move in the central axis direction.

  Further, the inner wall surface of the cylindrical body 50 in the vicinity of the opening 50b on the other end side is fitted with a ring-shaped groove portion 19a formed on the outer periphery of the small-diameter portion 195 of the cap 19 made of a nonmagnetic material such as resin. For example, the cylindrical protrusion 50e is formed by narrowing the cylindrical body 50 at the position. Therefore, when the cap 19 is inserted into the cylindrical body 50, the ring-shaped groove 19a formed on the outer periphery of the small-diameter portion 195 of the cap 19 and the ring-shaped protrusion 50e formed on the inner wall surface of the cylindrical body 50 are fitted. By joining, the cap 19 is pressed and clamped so that the cap 19 is not detached from the opening 50 b of the cylindrical body 50.

  The configuration of each part housed in the cylindrical body 50, the assembly of the electronic ink cartridge 20, and the adjustment of the resonance frequency will be further described.

  The core body 21 in the second embodiment is made of resin, for example, and has a bar shape extending from the opening 50a of the cylindrical body 50 as shown in FIG. 9B. And in this 2nd Embodiment, the recessed part 23a which the core 21 fits is formed in the approximate center of the end surface of the central axis direction at the side of the core 21 of the ferrite core 23 in which the coil 24 is wound. ing. The core body 21 is coupled to the ferrite core 23 by press-fitting the side 21 a opposite to the side extending from the opening 50 a into the recess 23 a of the ferrite core 23. In this embodiment, the core body 21 can be inserted into and removed from the ferrite core 23, and therefore can be inserted into and removed from the electronic ink cartridge 20.

  A concave portion 23b for alignment is formed at substantially the center of the end surface opposite to the core body 21 side of the ferrite core 23 in the central axis direction. As shown in FIG. 9A, the recess 23b of the ferrite core 23 has a protrusion formed from the end face of the connecting member 27 via an O-ring 25 made of an elastic material such as rubber and a ferrite chip 26, for example. Part 27a is inserted. In this example, the ferrite chip 26 is formed with a through hole 26a through which the protrusion 27a of the connecting member 27 is inserted. The length of the projection 27a of the connecting member 27 in the central axis direction is a length inserted into the recess 23b of the ferrite core 23 via the O-ring 25 and the ferrite chip 26, and the ferrite core 23 is According to the pressing force applied to the core body 21, the length can be biased toward the connecting member 27 in the central axis direction.

  FIG. 10 is a diagram illustrating a configuration example of the connecting member 27. 10A is a view of the connecting member 27 as viewed from the side facing the end face of the ferrite core 23, and FIG. 10B is a cross-sectional view taken along the line DD in FIG. 10A. FIG. 10C is a view of the connecting member 27 as viewed from the side where it is connected to the capacitor circuit 28.

  Similarly to the connecting member 17 in the first embodiment, the connecting member 27 is connected to a main body portion 271 made of a cylindrical resin member, as shown in FIGS. 10 (A) and 10 (B), with one end 24a of the coil 24 and This is formed by inserting elastic terminal members 272 and 273 for electrical connection between the other end 24b and one end and the other end of the capacitor circuit 28, respectively. A positioning protrusion 27a is formed at the center of the end face of the main body 271 on the ferrite core 23 side. In this example, the protrusion 27a has a rod-like cross section.

  Then, as shown in FIGS. 10A and 10B, in this example, the circumferential side surface of the main body portion 271 of the connecting member 27 is spaced apart from each other by an angular interval of 180 degrees in the direction of the central axis of the cylinder. Concave grooves 274 and 275 are formed along the direction. In the recessed grooves 274 and 275, one end portions 272a and 273a of the terminal members 272 and 273 are planted in a direction orthogonal to the circumferential direction. Then, as shown in FIG. 10A, V-shaped cuts 272b and 273b are formed in one end portions 272a and 273a of the terminal members 272 and 273 in the planted state. As shown in FIG. 10B, one end 24a of the coil 24 is press-fitted into a V-shaped notch 272b of one end 272a of the terminal member 272 to be electrically connected to each other. The end 24b is press-fitted into the V-shaped notch 273b of one end 273a of the terminal member 273 so as to be electrically connected to each other.

  The other end of the terminal member 272 of the connecting member 27 is formed as a ring-shaped electrode conductor 272c on the end surface facing the end surface of the capacitor circuit 28, as shown in FIGS. .

  In addition, the other end of the terminal member 273 of the connecting member 27 is disconnected from the ring-shaped electrode conductor 272c at the other end of the terminal member 272, and the circular conductor 273c inside the ring-shaped electrode conductor 272c Is done. The ring-shaped electrode conductor 272c at the other end of the terminal member 272 configured as described above and the circular conductor 273c at the other end of the terminal member 273 are connected to one and the other terminals of the capacitor circuit 28, as will be described later. Connected.

  In this case, one end 24 a and the other end 24 b of the coil 24, a V-shaped cut 272 b at one end 272 a of the terminal member 272 of the connecting member 27, and a V-shaped cut at one end 273 a of the terminal member 273. The connection with the 273b is performed in a state where the protrusion 27a of the connecting member 27 is inserted into the recess 23b of the ferrite core 23 through the through hole 26a of the ferrite chip 26 and the through hole of the O-ring 25. Accordingly, the ferrite core 23 around which the coil 24 is wound and the connecting member 27 are connected via the O-ring 25 and the ferrite chip 26 can be handled as one unitized component.

  The one end 24 a and the other end 24 b of the coil 24 are connected to the one end portions 272 a and 273 a of the terminal members 272 and 273 in the concave grooves 274 and 275 of the connecting member 27, respectively. And the other end 24 b does not contact the inner wall surface of the cylindrical body 50.

  In the second embodiment, in addition to the ferrite core 23 in which the coil 24 is wound from the opening 50b side, with the opening 50a side as a tip, in the hollow portion of the cylindrical body 50 into which the coil spring 22 is inserted in advance. A unitized component group in a state in which the connecting member 27 faces the end face through the O-ring 25 and the ferrite chip 26 and the protrusion 27a formed from the end face of the connecting member 27 is inserted into the concave portion 23b of the ferrite core 23. Inserted. The core body 21 is press-fitted and fitted into the ferrite core 23 in a state where the tip end side is extended from the opening 50 a of the cylindrical body 50. The core body 21 may be press-fitted into the ferrite core 23 in advance and accommodated in the cylindrical body 50, or after the ferrite core 23 and the like are accommodated in the cylindrical body 50, the cylinder 21 is The opening 50a of the body 50 may be passed through and press-fitted into the ferrite core 23.

  In the second embodiment, a predetermined position in the central axis direction in the cylindrical body 50 in which the connecting member 27 is slightly pressed into the hollow portion of the cylindrical body 50 against the biasing force of the coil spring 22. When the connecting member 27 is inserted, the connecting member 27 is fixed to the cylindrical body 50 by caulking (squeezing) the cylindrical body 50 at the above-described positions 50c and 50d with a predetermined jig. 27 is prevented from moving in the central axis direction within the cylindrical body 50.

  In this state, the ferrite core 23, the O-ring 25, and the ferrite chip 26 to which the core body 21 is coupled by the coil spring 22 disposed on the core body 21 side in the hollow portion of the cylindrical body 50 are always connected to the connecting member 27. It is biased to the side, and rattling of each member constituting the position indicator is prevented.

  At this time, the ring-shaped electrode conductor 272c and the circular conductor 273c as connection terminals are exposed in the cylindrical body 50 on the end surface of the connecting member 27 in the cylindrical body 50 on the capacitor circuit 28 side. .

  For this reason, in this second embodiment, in order to measure the inductance of the coil 24 in this state, the measurement is provided with electrode terminals that are electrically connected to the ring-shaped electrode conductor 272c and the circular conductor 273c of the connecting member 27, respectively. A jig is inserted into the cylindrical body 50. This measuring jig is connected to an inductance measuring device, and the inductance of the coil 24 in a state where no pressing force is applied to the core body 21 is measured.

  When the inductance of the coil 24 is measured in this way, in the same manner as in the first embodiment described above, a capacitance is calculated so as to form a parallel resonance circuit with the coil 24 of that inductance and to obtain a desired resonance frequency. The capacitor circuit 28 set to the calculated capacitance value is housed in the cylindrical body 50.

  The capacitor circuit 28 includes a first capacitor circuit 281 and a second capacitor circuit 282. The capacitor circuit includes the first capacitor circuit 181 and the second capacitor circuit 182 in the first embodiment. 18 is provided with substantially the same configuration. However, as shown in FIG. 10C, the ring-shaped electrode conductor 272c and the circular conductor 273c are formed on the end face of the connecting member 27. Therefore, the first capacitor circuit 281 constituting the capacitor circuit 28 is The difference is that a terminal member having a shape different from the shape of the terminal member formed on the end face of the connecting member 17 of the first capacitor circuit 181 shown in FIG. 3 is provided.

  That is, as shown in FIG. 10D, one end 1814a of the terminal member 1814 of the first capacitor circuit 281 provided on the end surface of the holder 1810 facing the connecting member 27 of the first capacitor circuit 281 is Although the terminal member 1815 has a shape corresponding to the width of the ring-shaped electrode conductor 272c of the connecting member 27, the one end 1815a 'of the terminal member 1815 has a circular shape and is elastically abutted with the circular conductor 273c of the connecting member 27. Yes. Other configurations of the first capacitor circuit 281 are the same as those of the first capacitor circuit 181.

  In the end face of the second capacitor circuit 282 facing the ID package 320, in this example, a fitting concave hole 2821 that fits into fitting protrusions 3251 and 3252 formed on the end face of the ID package 320 described later, and 2822 is formed (see FIG. 9B). Other configurations of the second capacitor circuit 282 are the same as those of the capacitor circuit 182 of the first embodiment.

  Next, FIG. 11 shows a configuration example of the ID package 320, and FIG. 11A is a diagram showing an end face of the ID package 320 on the second capacitor circuit 282 side. FIG. 11B is a cross-sectional view taken along line EE in FIG. FIG. 11C is a diagram showing an end surface of the ID package 320 on the cap 19 side.

  As shown in FIG. 11B, the ID package 320 accommodates the ID transmission circuit 300 in a package 321 made of a cylindrical resin and has three terminal members 322, 323, and 324. One end of the ID transmission circuit 300 is electrically connected to the terminal member 322, and the other end of the ID transmission circuit 300 is electrically connected to the terminal member 324.

  As shown in FIG. 11A, one end 322a of the terminal member 322 is formed on the end surface of the second capacitor circuit 282 on the ID package 320 side on the end surface of the ID package 320 on the second capacitor circuit 282 side. A terminal that is exposed so as to abut against the other end 1824b of the formed terminal member 1824, and one end 323a of the terminal member 323 is formed on the end surface of the second capacitor circuit 282 on the ID package 320 side. The other end 1826b of the member 1826 is exposed. Further, one end 324a of the terminal member 324 is exposed so as to abut against the other end 1825b of the terminal member 1825 formed on the end surface of the second capacitor circuit 282 on the ID package 320 side.

  As shown in FIG. 11C, the other end 323b of the terminal member 323 and the other end 324b of the terminal member 324 are exposed on the end surface of the ID package 320 on the cap 19 side. The terminal member 322 is merely connected to one end of the ID transmission circuit 300 in the ID package 320, and the other end is not led out to the end surface of the ID package 320 on the cap 19 side, and is in the ID package 320. ing.

  In addition, a protrusion 320a is formed on the peripheral portion of the ID package 320 along the central axis direction to engage with the axial groove 50f formed on the opening 50b side of the cylindrical body 50. In this example, on the end surface of the second capacitor circuit 282 on the ID package 320 side, fitting concave holes 1816 and 1817 (see FIG. 4) formed on the end surface of the first capacitor circuit 181 described above are provided. Similar fitting concave holes 2821 and 2822 are formed.

  Further, as shown in FIGS. 11A and 11B, the end surface of the ID package 320 on the second capacitor circuit 282 side is formed on the end surface of the second capacitor circuit 282 on the ID package 320 side. Fitting protrusions 3251 and 3252 that fit into the fitting concave holes 2821 and 2822 are formed. These fitting protrusions 3251 and 3252 and fitting concave holes 2821 and 2822 are fitting protrusions and fitting concave holes for coupling the first capacitor circuit 181 and the second capacitor circuit 182 described above. The ID capacitor 320 has the same structure, and the fitting protrusions 3251 and 3252 are fitted in the fitting concave holes 2821 and 2822 of the second capacitor circuit 282, so that the second capacitor circuit 282.

  In this case, the protrusions 182a of the second capacitor circuit 282 and the protrusions 320a of the ID package 320 are engaged with the grooves 50f of the cylindrical body 50, thereby positioning in the circumferential direction. Thus, the other end 1824b of the terminal member 1824, the other end 1826b of the terminal member 1826, and the other end 1825b of the terminal member 1825 on the end face of the second capacitor circuit 282 are connected to one end 322a of the terminal member 322 of the ID package 320, and the terminal member. The one end 323a of the H.323 and the one end 324a of the terminal member 324 are abutted and electrically connected.

  Thereafter, the small-diameter portion 195 of the cap 19 is inserted into the cylindrical body 50, and the ring-shaped protrusion 50e of the cylindrical body 50 is fitted into the ring-shaped groove portion 19a of the small-diameter portion 195, whereby the cap 19 is removed. Fix to the cylindrical body 50. Then, the other end 324b of the terminal member 324 and the other end 323b of the terminal member 323 on the end surface on the cap 19 side of the ID package 320 are connected to one end 192a of the terminal member 192 and one end 193a of the terminal member 193. . In this case, the length of the small diameter portion 195 of the cap 19 in the central axis direction is adjusted according to the thickness of the ID package 320 in the central axis direction.

  The electronic ink cartridge 20 is assembled as described above. In the electronic ink cartridge 20, when a pressing force in the central axis direction is applied to the core body 21, the ferrite core 23 is biased toward the ferrite chip 26 via the O-ring 25, thereby the ferrite core 23. And the ferrite chip 26 change, and the inductance of the coil 24 changes. In the same manner as in the first embodiment, the resonance frequency (phase) of the electromagnetic induction signal transmitted from the coil 24 of the resonance circuit of the position indicator changes according to the change in the inductance of the coil 24. As a result, the position indicated by the position indicator and the writing pressure can be detected.

  The electronic ink cartridge 20 is housed in the housing 2 in the same manner as the electronic ink cartridge 10 of the first embodiment.

  The position indicator of the second embodiment is exactly the same as the first embodiment described above except that the configuration for making the inductance of the coil for detecting the pen pressure variable is different from that of the first embodiment. The effect is obtained.

  In the electronic ink cartridge 20 of the second embodiment, the ID transmission circuit 300 is arranged in parallel between both ends of the coil 16 by storing the ID package 320 in the cylindrical body 50 as described above. It will be in the state connected to. The ID package 320 can be connected so as to be exposed from the cylindrical body 50.

[Information transmission using ID transmission circuit 300]
FIG. 12 is a diagram illustrating a circuit configuration of the position indicator 1B and the position detection device 200B when configured to transmit identification information (ID) of the electronic ink cartridge and the position indicator to the position detection device. . In FIG. 12, the electronic ink cartridge 20 has a first capacitor circuit 281 connected in parallel to the coil 24 whose inductance is variable according to the writing pressure, and is further pushed with the second capacitor circuit 282. A series resonant circuit 20R is shown as a parallel resonant circuit 20R connected in parallel. The push switch 7 is connected to the connector 194 of the cap 19 of the electronic ink cartridge 10 as shown in FIG.

  As shown in FIG. 12, the ID transmission circuit 300 of the position indicator 1B includes an IC (Integrated Circuit) 301 as an ID generation control circuit. The IC 301 uses a power supply voltage Vcc obtained by rectifying an AC signal received by electromagnetic coupling from the position detection device 200B in the parallel resonance circuit 20R by a rectifier circuit (power supply circuit) 304 including a diode 302 and a capacitor 303. It is configured to work. In the ID transmission circuit 300 of this example, a switch circuit 305 that is normally open (normally open) is provided between the connection end (1824b) of the parallel resonance circuit 20R and the power supply circuit 304. ing. The switch circuit 305 is composed of, for example, a semiconductor switch circuit, and is in a high impedance state in the open state.

  The switch circuit 305 is controlled to be turned on by a switch control signal from the switch control circuit 306. The switch control circuit 306 generates a switch control signal from the AC signal received by electromagnetic coupling from the position detection device 200B in the parallel resonance circuit 20R.

  In the ID transmission circuit 300, a switch circuit 307 is connected in parallel to the parallel resonance circuit 20R configured by the coil 24 and the capacitor circuit 28 (281, 282). The switch circuit 307 is configured to be turned on / off by the IC 301.

  In this example, the IC 301 stores a manufacturer number and a product number of the electronic ink cartridge 20 or the position indicator 1B, and an ID signal including the manufacturer number and the product number is turned on / off for the switch circuit 307. By controlling, for example, it is transmitted to the position detection device 200B as an 8-bit digital signal.

  On the other hand, in the position detection device 200B of the example of FIG. 12, in the configuration of the position detection device 200 shown in FIG. 7, the gain can be variably adjusted by an external gain control signal instead of the current driver 222 having a fixed gain. A possible current driver 222B is provided, and a processing control unit 233B is provided instead of the processing control unit 233. Other parts are the same as those of the position detection apparatus 200 shown in FIG.

  The current driver 222B is configured to be able to change the signal level of the transmission signal in response to the gain control signal from the processing control unit 233B.

  Further, the processing control unit 233B is configured by, for example, a microcomputer, and is instructed by the position indicator 1B by transmitting and receiving an electromagnetic induction signal to and from the position indicator 1B in the same manner as the processing control unit 233 described above. In addition to detecting the position and the pen pressure applied to the position indicator 1B, a signal for controlling the transmission signal level is supplied to the current driver 222B, and the transmission signal is controlled intermittently. An on / off control signal is supplied to the switch circuit 307. Further, the reception processing of the ID signal from the position indicator 1B is performed. As will be described later, the processing control unit 233B detects the intermittent signal from the position indicator 1B as a digital signal of several bits, for example, 8 bits, and detects the ID signal.

  Hereinafter, transmission / reception of an ID signal between the position indicator 1B and the position detection device 200B, a position detection operation, and a writing pressure detection operation will be described. FIG. 13 is a flowchart for explaining the processing operation of the IC 301 of the position indicator 1B. As will be described later, the switch circuit 305 is turned on, and the power supply voltage Vcc is supplied to the IC 301 from the power supply circuit 304. Sometimes start the process from the start.

  In a state where the switch circuit 305 is off and the power supply voltage Vcc is not supplied from the power supply circuit 304, the IC 301 stops operating. At this time, the connection end with the parallel resonance circuit 20R, in this example, the capacitor circuit 18 When viewed from the other end 1824b of the terminal member 1824 of the second capacitor circuit 182 and the other end 1825b of the terminal member 1825, the ID transmission circuit 300 has a high impedance and is substantially not connected to the connection end with the parallel resonance circuit 20R. Equivalent to a state where nothing is connected. Therefore, at this time, the capacitance component is not connected in parallel to the parallel resonance circuit 20R, and the resonance frequency of the parallel resonance circuit 20R is not affected by the ID transmission circuit 300. Yes. The IC 301 is supplied with the electromagnetic induction signal transmitted from the position detection device 200B via the capacitor 308 as a synchronization signal for exchanging the electromagnetic induction signal with the position detection device 200B.

  FIG. 14 is a flowchart for explaining the processing operation of the processing control unit 233B of the position detection device 200B. When the position detection device 200B is powered on, the processing of FIG. 14 is repeatedly executed.

  That is, the processing control unit 233B first supplies a gain control signal that increases the signal level of the transmission signal to the current driver 222B. As a result, the AC signal having the frequency f0 from the oscillator 221 is set to a large level by the current driver 222B, and is supplied to the loop coil groups 211X and 212Y via the selection circuit 213 (step S21 in FIG. 14).

  In the position indicator 1B, the parallel resonance circuit 20R receives an electromagnetic induction signal based on a large-level AC signal from the position detection device 200B. At this time, in response to the high signal level of the AC signal from the position detection device 200B, the switch control circuit 306 generates a switch control signal for turning on the switch circuit 305 from the AC signal received by the parallel resonance circuit 20R. Generate. As a result, when the switch circuit 305 is turned on, the power supply voltage Vcc generated by rectifying the AC signal received by the parallel resonant circuit 20R is supplied from the power supply circuit 304 to the IC 301.

  When the power supply voltage Vcc is supplied to the IC 301, the IC 301 starts operation. The IC 301 generates an ID signal including a manufacturer number and a product number of the electronic ink cartridge 20 as a digital signal. The electromagnetic induction signal in which the switch circuit 307 is controlled to be turned on / off by the digital signal is transmitted from the position indicator 1B to the position detection device 200B (step S11 in FIG. 13).

  That is, when the switch circuit 307 is off, the parallel resonance circuit 20R can perform a resonance operation on the AC signal transmitted from the position detection device 200B and return the electromagnetic induction signal to the position detection device 200B. . The loop coil of the position detection device 200B receives the electromagnetic induction signal from the parallel resonance circuit 20R of the position indicator 1B. On the other hand, when the switch circuit 307 is on, the parallel resonance circuit 20R is in a state in which the resonance operation with respect to the AC signal from the position detection device 1B is prohibited. For this reason, the position detection from the parallel resonance circuit 20R is performed. The electromagnetic induction signal is not returned to the device 200B, and the loop coil of the position detection device 200B does not receive the signal from the position indicator 1B.

  In this example, the processing control unit 233B of the position detection device 200B receives an 8-bit digital signal by detecting the presence / absence of a reception signal from the position indicator 1B eight times. That is, in step S21, the process control unit 233B controls the gain of the current driver 222B so that the signal level of the transmission signal is set to a large level and transmits the signal, and the 8-bit ID signal from the position indicator 1B is transmitted. In order to detect, transmission / reception is continuously performed 8 times at the same timing as the coordinate detection.

  On the other hand, the IC 301 of the position indicator 1B generates an 8-bit digital signal corresponding to the ID signal to be transmitted, and synchronizes the electromagnetic induction signal transmission / reception with the position detection device 200B by the 8-bit digital signal. The switch circuit 307 is turned on / off. For example, when the bit of the ID signal is “1”, the switch circuit 307 is turned on. Then, as described above, the electromagnetic induction signal is not returned to the position detection device 200B from the position indicator 1B. On the other hand, when the bit of the ID signal is “0”, the switch circuit 307 is turned off. Then, as described above, an electromagnetic induction signal is returned to the position detection device 200B from the position indicator 1B.

  Therefore, the processing control unit 233B of the position detection device 200B can receive an ID signal that is an 8-bit digital signal by detecting the presence / absence of a reception signal from the position indicator 1B eight times.

  The processing control unit 233B of the position detection device 200B determines whether or not the ID signal from the position indicator 1B has been received by performing the above processing (step S22), and the ID signal is received within a predetermined time. When it is determined that the signal could not be received, the process returns to step S21, and transmission of a transmission signal at a large level is continuously performed a predetermined number of times. If the ID signal cannot be received even if the ID signal reception process is continued a predetermined number of times, it is determined that the position indicator 1B does not have a function of transmitting the ID signal, and the ID signal is received. Skip processing.

  When it is determined in step S22 that the ID signal has been received, the processing control unit 233B lowers the gain of the current driver 222B and sets the signal level of the transmission signal to a predetermined level (usually higher than the large level in step S21). The transmission level is lowered to a usage level) (step S23). The predetermined level at this time is that the position indicator 1B can detect the indicated position and the writing pressure with the parallel resonance circuit 20R of the position indicator 1B, but the switch control circuit of the position indicator 1B. 306 is a level at which the switch circuit 305 cannot be turned on.

  Thus, when the signal level of the electromagnetic induction signal transmitted from the position detection device 200B is set to a predetermined level (normal use state), the switch control circuit 306 of the position indicator 1B turns on the switch circuit 305. Is not output. For this reason, the supply of the power supply voltage Vcc from the power supply circuit 304 to the IC 301 is stopped, and the IC 301 becomes inoperable. Therefore, the processing of the flowchart of FIG. 13 ends, and the position indicator 1B transmits the ID signal. To stop.

  However, since the state in which the signal level of the electromagnetic induction signal transmitted from the position detection device 200B is set to a predetermined level (normal use state) is the same state as in FIG. 7, the processing of the position detection device 200B The control unit 233B sends and receives the electromagnetic induction signal to and from the parallel resonance circuit 20R of the position indicator 1B, thereby changing the indicated position and writing pressure by the position indicator 1B as described in the first embodiment. A detection process is performed (step S24).

  Then, the processing control unit 233B monitors the return of the electromagnetic induction signal from the parallel resonance circuit 20R of the position indicator 1B, and has not been able to detect the position indicator 1B because the return of the electromagnetic induction signal has been lost. It is determined whether or not (step S25). If it is determined in step S25 that the position indicator 1B has been detected, the process control unit 233B returns the process to step S24. If it is determined in step S25 that the position indicator 1B can no longer be detected, the process control unit 233B returns the process to step S21 and causes the current driver 222B to perform gain control for increasing the signal level of the transmission signal. By supplying the signal, the signal level of the transmission signal supplied to the loop coil groups 211X and 212Y is increased. And the process control part 233B repeats the process after this step S21.

  According to the second embodiment shown in FIGS. 11 to 14 described above, the position indicator 1B transmits an ID signal for identifying the electronic ink cartridge 20 and the position indicator 1B to the position detection device 200B. can do. Therefore, in an electronic apparatus including the position detection device 200B, a predetermined process corresponding to each electronic ink cartridge or position indicator can be assigned by detecting the ID signal of the electronic ink cartridge 20 or the position indicator 1B. It is possible and very convenient. Further, by detecting the ID signal of the electronic ink cartridge 20 or the position indicator 1B, there is a merit that management of the failure of the electronic ink cartridge 20 or the position indicator 1B becomes easy.

  In addition, when the position detection device 200B starts to operate, the position indicator 1B is prompted to transmit an ID signal included in the position indicator 1B. In addition to being electrically separated from the circuit, operation control is performed so as to detect the indicated position and the writing pressure by the position indicator 1B in the normal use state. Further, when it is determined that the ID signal cannot be received as a result of urging the position indicator 1B to transmit the ID signal included in the position indicator 1B a predetermined number of times, the indication by the position indicator 1B in the normal use state Operation control is performed so as to detect the position and the pen pressure. Therefore, even when using the position indicator 1B that does not have an ID signal transmission function, a special processing operation is not required and the operation can be performed without any sense of incongruity.

  In the above example, when the parallel control circuit 20R receives the high level electromagnetic induction signal from the position detection device 200B, the switch control circuit 306 of the position indicator 1B receives the received high level electromagnetic induction signal. Based on the above, a switch control signal for turning on the switch circuit 305 is generated, whereby the power supply voltage Vcc is supplied to the IC 301.

  However, the method in which the switch control circuit 306 of the position indicator 1B turns on the switch circuit 305 to supply the power supply voltage Vcc to the IC 301 is not limited to such a method.

  For example, as another example, a predetermined digital signal is sent from the position detection device 200B to the position indicator 1B, and the switch control circuit 306 that has received this digital signal is caused to generate a switch control signal for turning on the switch circuit 305. It can also be configured.

  That is, for example, when the position detection device 200B does not detect the presence of the position indicator 1B because the position indicated by the position indicator 1B cannot be detected, the predetermined digital signal is transmitted through the loop coil groups 211X and 212Y. Send out as an electromagnetic induction signal. The parallel resonant circuit 20R of the position indicator 1B receives an electromagnetic induction signal having a signal envelope corresponding to the digital signal and supplies the electromagnetic induction signal to the switch control circuit 306.

  The switch control circuit 306 extracts a digital signal by, for example, shaping this signal and performing envelope detection, and turns on the switch circuit 305 when the digital signal matches the preset digital signal. A switch control signal is generated. As a result, the power supply voltage Vcc is supplied to the IC 301.

  The IC 301 starts to operate when the power supply voltage Vcc is turned on, and transmits the ID signal of the position indicator 1B to the position detection device 200B through the parallel resonance circuit 20R. When the position detection device 200B receives the ID signal, the position detection device 200B stops sending the predetermined digital signal, shifts from the ID signal detection mode to the normal use mode for detecting the position indicated by the position indicator 1B, and the position indicator The detection operation of the designated position 1B is performed. When the switch control circuit 306 of the position indicator 1B cannot receive a predetermined digital signal, the switch circuit 305 is turned off and the supply of the power source Vcc to the IC 301 is stopped. As a result, transmission of the ID signal is stopped, the ID transmission circuit 300 becomes high impedance, and the ID transmission circuit 300 is electrically separated from the connection end with the parallel resonance circuit 20R.

  The position detection device 200B starts sending the predetermined digital signal again when the position indicator 1B cannot be detected.

  Note that the ID transmission circuit 300 only needs to be connected in parallel to the coil 24, and thus the ID package 320 is not limited to being provided between the capacitor circuit 28 and the cap 19. For example, the ID transmission circuit 300 can be provided between the connecting member 27 and the capacitor circuit 28.

  Further, in addition to the connector 194, the cap 19 is provided with another connector connected to the other end 1824b of the terminal member 1824 of the second capacitor circuit 282 and the other end 1825b of the terminal member 1825. A circuit portion similar to an ID package including the ID transmission circuit 300 in the connector may be provided outside the cylindrical body 50.

[Third Embodiment]
In the first and second embodiments described above, the pressure-sensitive sensor is a case where the inductance constituting the resonance circuit is changed according to the pressure applied to the core body. On the other hand, in the third embodiment described below, the pressure-sensitive sensor is a case where the capacitance of the capacitor constituting the resonance circuit is changed according to the pressure applied to the core body. is there. In the position indicator of the third embodiment, the pressure-sensitive sensor whose capacitance changes according to the pressing force applied to the core is an electrostatic sensor manufactured by MEMS (Micro Electro Mechanical System) technology. It is composed of a capacitive pressure sensing semiconductor device.

  FIG. 15 is a diagram illustrating a configuration example of the electronic ink cartridge 30 of the position indicator according to the third embodiment. FIG. 15A is a cross-sectional view for explaining the internal configuration of the electronic ink cartridge 30. FIG. 15B is an exploded perspective view for explaining the overall configuration of the electronic ink cartridge 30. Also in this example, for convenience of explanation, some of the components inside the cylindrical body 5 ′ of the electronic ink cartridge 30 are not shown as a cross section in FIG.

  The configuration of the position indicator housing of the third embodiment and the structure for attaching the push switch 7 to the housing are the same as those of the first embodiment, and illustration and description thereof are omitted. To do. Also in the description of the third embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted.

  Similarly to the first embodiment, the cylindrical body 5 ′ is composed of a first cylindrical body 5C and a second cylindrical body 5D that are divided into two in the central axis direction, and the first cylindrical body 5C. The second cylindrical body 5D has a thin shape with an outer diameter of, for example, 2.5 mm and an inner diameter of, for example, 1.5 mm to 2 mm. The cylindrical body 5 'is made of a nonmagnetic material such as a nonmagnetic metal, a resin material, glass, or ceramic, and in this example, a material such as SUS305 or SUS310S having conductivity.

  The configuration of the first cylindrical body 5C is the same as that of the first cylindrical body 5A of the first embodiment described above, and the tip of the core body 31 is provided at one end side in the central axis direction. An opening 5Ca for extending is provided, and a screw portion 5Cc for screwing with the second cylindrical body 5D is formed in the opening 5Cb on the other end side. Further, the configuration of the second cylindrical body 5D is the same as that of the second cylindrical body 5B of the first embodiment described above, and the first cylindrical shape is formed in the opening on one end side thereof. A screw portion 5Da for screwing with the body 5C is formed, and a groove 5Db formed in the central axis direction is formed on the other end side, and a small diameter portion 195 of the cap 19C is formed. A ring-shaped protrusion 5Dc that fits into the ring-shaped groove 19a is formed.

  As shown in FIG. 15, also in the electronic ink cartridge 30 of the third embodiment, all the main components constituting the electromagnetic induction type position indicator are accommodated in the cylindrical body 5 ′. As shown in FIG. 15A and FIG. 15B, a coil spring 32, a core body 31, a pressure sensing semiconductor device 35, and a coil 33 are wound in the first cylindrical body 5C when viewed from the opening 5Ca side. The ferrite core 34 as an example of the rotated magnetic body and the connecting member 36 are provided in the second cylindrical body 5D with the capacitor circuit 18C, and the central axis directions of these components are the cylindrical bodies 5C and 5D. In a state of being in the direction of the central axis, they are sequentially arranged and stored. Then, the cap 19C is inserted into the opening on the other end side of the second cylindrical body 5D, and the opening of the cylindrical body 5 ′ is closed. The capacitor circuit 18C includes a first capacitor circuit 181C and a second capacitor circuit 182C. The capacitor circuit 18C has a diameter smaller than that of the capacitor circuit 18 of the first embodiment. This is exactly the same as the capacitor circuit 18 of the embodiment.

  In the third embodiment, the first cylindrical body 5C accommodates the coil spring 32, the core body 31, the pressure sensing semiconductor device 35, the ferrite core 34 around which the coil 33 is wound, and the connecting member 36. At the time, the inner peripheral surface of the first cylindrical body 5C is narrowed (caulked) in the central axis direction at the position of the side peripheral surface of the first cylindrical body 5C corresponding to the side peripheral surface of the connecting member 36. By forming the protrusions 5Cd and 5Ce, the connecting member 36 is pressed and clamped by the first cylindrical body 5C, and the position of the connecting member 36 is restricted so as not to move in the central axis direction. And the ferrite core 34 around which the pressure sensing semiconductor device 35 and the coil 33 are wound by the biasing force of the coil spring 32 arranged between the opening 5Ca side of the first cylindrical body 5C and the pressure sensing semiconductor device 35. Is not rattled in the direction of the central axis.

  Thereafter, in the same manner as in the first embodiment described above, the capacitor circuit 18C is coupled to the connecting member 36, and the second cylindrical body 5D is screwed into and coupled to the first cylindrical body 5C. The opening at the other end of the second cylindrical body 5D is closed by the cap 19C.

  The configuration of each part housed in the cylindrical body 5 ′, the assembly of the electronic ink cartridge 30, and the adjustment of the resonance frequency will be further described.

  As shown in FIGS. 15A and 15B, the core body 31 in the third embodiment is formed of, for example, a rod-shaped member made of resin. In the third embodiment, the rod-shaped core body 31 is inserted into the pressure sensing semiconductor device 35 as a pressing member.

  In the third embodiment, the ferrite core 34 has a cylindrical shape with a constant diameter, and the coil 33 is wound around the ferrite core 34. A recess 352 is provided on the bottom surface 351b side of the package member 351 of the pressure sensing semiconductor device 35 opposite to the top surface 351a into which the core body 31 is inserted, and one end of the ferrite core 34 in the central axis direction is provided. The side is fitted into the recess 352.

  Further, the other end side of the ferrite core 34 in the central axis direction is fitted and connected to a connecting member 36 made of, for example, resin. In the center of the end surface of the ferrite core 34 on the side of the connecting member 36, a concave hole 34a into which a projection 361 of the connecting member 36 described later is fitted is formed.

[Configuration Example of Pressure Sensing Semiconductor Device 35]
As described above, the position indicator of the third embodiment detects the writing pressure as a change in the capacitance of the capacitor constituting the resonance circuit together with the coil. The position indicator of the third embodiment Then, the semiconductor device (pressure sensing chip) manufactured by the MEMS technology previously proposed by the applicant as Japanese Patent Application No. 2012-15254 is used as a pressure sensitive sensor whose capacitance changes according to writing pressure.

  The pressure sensing semiconductor device 35 is configured such that, for example, a pressure sensing chip 400 is accommodated in a package member 351 made of resin in a state where the pressure sensing chip 400 can be pressed by an external pressing member. The pressing member is a core body 31 in this example. And the pressure sensing semiconductor device 35 of this example hold | maintains the core 31 so that insertion or removal is possible, and the ferrite core 34 by which the coil 33 was wound is hold | maintained at the package member 351, and was integrated into the united structure It is said that.

  FIG. 16 is a diagram for explaining the configuration of the pressure sensing semiconductor device 35 of this example. FIG. 16A is a longitudinal sectional view of the pressure sensing semiconductor device 35. FIG. 16B is a diagram for explaining the pressure sensing chip 400 housed in the pressure sensing semiconductor device 35.

  The pressure sensing semiconductor device 35 has elasticity and is made of a resin member that is an electrically insulating material, for example, silicon rubber. For example, the pressure sensing semiconductor device 35 is configured by sealing the pressure sensing chip 400 in a cylindrical package member 351.

In this example, as shown in FIG. 16B, the pressure sensing chip 400 includes a first electrode 401, a second electrode 402, and an insulating layer (between the first electrode 401 and the second electrode 402). Dielectric layer) 403. The first electrode 401 and the second electrode 402 are made of a conductor made of single crystal silicon (Si). In this example, the insulating layer 403 is composed of an insulating film made of an oxide film (SiO ₂ ).

  In this insulating layer 403, for example, a circular recess 404 is formed, and a space 405 is formed between the insulating layer 403 and the first electrode 401. The bottom surface of the recess 404 is a flat surface, and its diameter R is, for example, R = 1 mm. Further, the depth of the concave portion 404 is about several tens of microns to several hundreds of microns in this example. When pressed from the surface 401 a side, the first electrode 401 can be displaced so as to bend in the direction of the space 405.

  The pressure sensing chip 400 configured as described above is a capacitor in which a capacitance Cv is formed between the first electrode 401 and the second electrode 402. Then, as shown in FIG. 16B, when the pressure P is applied to the first electrode 401 from the surface 401a side of the first electrode 401, the first electrode 401 has the structure shown in FIG. In FIG. 5, the distance between the first electrode 401 and the second electrode 402 is shortened and the value of the capacitance Cv is increased. The amount of bending of the first electrode 401 changes according to the magnitude of the applied pressure P. Accordingly, the capacitance Cv changes according to the magnitude of the pressure P applied to the pressure sensing chip 400. The pressure can be detected based on the change in the capacitance Cv.

  In the pressure sensing semiconductor device 35 of this embodiment, in the pressure sensing chip 400 having the above-described configuration, the surface 401a of the first electrode 401 that receives pressure is the top surface of the package member 351 in FIG. It is accommodated in the package member 351 in a state facing the 351a.

  A communication hole 353 having a circular cross section, for example, is formed in the package member 351 so as to communicate from the upper surface 351a to the vicinity of the surface 401a of the first electrode 401 of the pressure sensing chip 400. As shown in FIGS. 15 and 16A, the core body 31 is inserted into the communication hole 353 as a pressing member that presses the pressure sensing chip 400. A tapered portion 351c is formed on the opening side (upper surface 351a side) of the communication hole 353 of the package member 351. The opening portion of the communication hole 353 has a trumpet shape, and the core 31 as a pressing member is formed in the communication hole. It is configured to be easily inserted into 353.

  As shown in FIG. 16A, O-ring-shaped protrusions 354 a and 354 b for holding the round bar-shaped core body 31 are provided on the inner wall surface of the communication hole 353. In this case, the inner diameter of the communication hole 353 is equal to or slightly larger than the diameter of the portion where the round bar-shaped core body 31 abuts, and the inner diameter of the O-ring-shaped protrusions 354a and 354b is the same as that of the core body 31. It is selected to be smaller than the diameter of the contacting part.

  Therefore, when the core body 31 is guided by the taper portion 351c provided on the opening side (upper surface 351a side) of the package member 351 and inserted into the communication hole 353, the core body 31 is protruded in an O-ring shape. It is held by the portions 354a and 354b. However, the core body 31 can be pulled out from the communication hole 353 with a predetermined force. Therefore, the core body 31 can be easily replaced.

  The first electrode 401 of the pressure sensing chip 400 is connected to a first lead terminal 356 made of a conductor by a gold wire 355, and the second electrode 402 is a second lead made of a conductor. The lead terminal 357 is contacted and connected. In the third embodiment, the tip portions of the first and second lead terminals 356 and 357 are orthogonal to the bottom surface 351b of the package member 351, as shown in FIGS. Is derived as follows.

  A circular recess 352 having a diameter substantially equal to the diameter of the ferrite core 34 is formed on the bottom surface 351 b of the package member 351. The depth of the recess 352 is set to a depth at which one end of the ferrite core 34 around which the coil 33 is wound is fitted in the central axis direction. The ferrite core 34 is inserted into the recess 352 and coupled to the package member 351 by, for example, an adhesive. The first and second lead terminals 356 and 357 are led out from the periphery of the recess 352 on the bottom surface 351b.

  As will be described later, the first lead terminal 356 and the second lead terminal 357 are electrically connected to the terminal members 362 and 363 of the connecting member 36 by gold wires, lead wires, or the like. Further, one end 33 a and the other end 33 b of the coil 33 wound around the ferrite core 34 are also electrically connected to the terminal members 362 and 363 of the connecting member 36.

  Next, a configuration example of the connecting member 36 is shown in FIG. 17A is a view showing an end surface of the connecting member 36 viewed from the side coupled to the ferrite core 34 in the central axis direction, and FIG. 17B is a cross-sectional view taken along line FF in FIG. FIG. 17C is a diagram showing an end face of the connecting member 36 viewed from the capacitor circuit 18C side in the central axis direction.

  As described above, the connecting member 36 includes the main body 360 made of, for example, a resin that is an electrically insulating material and having an outer diameter that is the same as the inner diameter of the first cylindrical body 5C. 17A and 17B, a part of the cylindrical portion of the ferrite core 34 is fitted to the end surface of the main body 360 of the connecting member 36 on the side coupled to the ferrite core 34. A concave hole 364 is formed, and a protrusion 361 is formed in the center of the bottom surface of the concave hole 364 so as to be fitted into the concave hole 34 a formed in the end face of the ferrite core 34.

  Also, as shown in FIGS. 17A and 17B, in this example, the circumferential side surface of the main body portion 360 of the connecting member 36 is spaced apart from each other by a 180-degree angular interval in the direction of the central axis of the cylinder. Concave grooves 365 and 366 are formed along the direction. In the concave grooves 365 and 366, one end portions 362a and 363a of the terminal members 362 and 363 are planted in a direction orthogonal to the circumferential direction. Then, as shown in FIG. 17 (A), V-shaped cuts 362c, 362d and 363c, 363d are formed in one end portions 362a and 363a of the terminal members 362 and 363 in the planted state, respectively. Is formed.

  The V-shaped cuts 362 c and 362 d of the terminal member 362 are for connecting the first electrode 401 of the pressure sensing chip 400 of the pressure sensing semiconductor device 35 and the one end 33 a of the coil 33. Further, the V-shaped cuts 363 c and 363 d of the terminal member 363 are for connecting the second electrode 402 of the pressure sensing chip 400 of the pressure sensing semiconductor device 35 and the other end 33 b of the coil 33.

  As shown in FIG. 17B, a concave portion 368 into which a part of the capacitor circuit 18C is fitted is provided on the end surface of the coupling member 36 on the side of the main body 360 that is connected to the capacitor circuit 18C. A ring-shaped groove 368a into which a ring-shaped protrusion 181Ca (see FIG. 15B) formed on the periphery of the first capacitor circuit 181C of the capacitor circuit 18C is fitted on the side peripheral surface of the recess 368. Is formed.

  Further, as shown in FIGS. 17B and 17C, a ring-shaped electrode conductor 362 b is formed on the bottom surface of the recess 368 as the other end of the terminal member 362 of the connecting member 36. The ring-shaped electrode conductor 362b abuts with one end 1814a of the terminal member 1814 of the first capacitor circuit 181C of the capacitor circuit 18C (see FIG. 4).

  Further, a concave hole 367 is formed in the center of the bottom surface of the concave portion 368 of the connecting member 36 in a state of being separated from the ring-shaped electrode conductor 362b. The other end portion 363b of the terminal member 363 of the connecting member 36 is formed so as to be positioned in the recessed hole 367, and the end portion 363b of the terminal member 363 positioned in the recessed hole 367 has an elastic property. An insertion hole 363e formed of a bent portion having a shape is formed. The rod-shaped one end 1815a of the terminal member 1815 of the first capacitor circuit 181C of the capacitor circuit 18C is inserted into the insertion hole 363e and connected to the other end 363b of the terminal member 363.

  The connecting member 36 is bonded and bonded to the ferrite core 34 with, for example, an adhesive material in a state in which the protrusion 361 is fitted in the concave hole 34a on the end face of the ferrite core 34. The lead wires connected to the lead terminals 356 and 357 connected to the first electrode 401 and the second electrode 402 of the pressure sensing chip 400 of the pressure sensing semiconductor device 35 are connected to one of the terminal members 362 of the connecting member 36. The V-shaped cut 362c or 362d of the end portion 362a and the V-shaped cut 363c or 363d of one end portion 363a of the terminal member 363 are connected by being sandwiched. Further, one end 33 a and the other end 33 b of the coil 33 are connected to the V-shaped cut 362 c or 362 d of one end 362 a of the terminal member 362 of the connecting member 36 and the V-shaped cut 363 c of one end 363 a of the terminal member 363. Or it connects by pinching between 363d.

  Thus, in the third embodiment, the pressure sensing semiconductor device 35, the ferrite core 34 around which the coil 33 is wound, and the connecting member 36 are combined and handled as one unitized component. It has been made possible.

  In the third embodiment, the coil spring 32 is inserted into the hollow portion of the first cylindrical body 5C with the opening 5Ca side as the tip and the opening 5Cb on the opposite side, and then the pressure sensing semiconductor device 35. And the ferrite core 34 around which the coil 33 is wound and the connecting member 36 are connected and integrated as a single unit, and the one end side of the coil spring 32 is connected to the upper surface 351a side of the pressure sensing semiconductor device 35. Inserted to collide. The core body 31 may be inserted into and fitted in the pressure sensing semiconductor device 35 in advance and stored in the first cylindrical body 5C, or later inserted into the pressure sensing semiconductor device 35 from the opening 5Ca side. You may make it fit.

  Note that the first electrode 401 and the second electrode 402 of the pressure sensing chip 400 of the pressure sensing semiconductor device 35 and the one end 33 a and the other end 33 b of the coil 33 are terminals in the concave grooves 365 and 366 of the connecting member 36. Since the members 362 and 363 are connected to, for example, one end portions 362a and 363a, the lead portions of the first electrode 401 and the second electrode 402 of the pressure sensing chip 400 and the one end 33a and the other end 33b of the coil 33 are used. Does not come into contact with the inner wall surface of the first cylindrical body 5C.

  As described later, a capacitor circuit that forms a parallel resonant circuit with the coil 33 and the capacitor formed by the pressure sensing chip 400 with respect to the connecting member 36 housed in the first cylindrical body 5C as described above. 18C is connected. The capacitance of the capacitor circuit 18C is set to a predetermined value as will be described later.

  In this case, a part of the first capacitor circuit 181C of the capacitor circuit 18C is housed in the recess 368 of the connecting member 36, and the ring-shaped protrusion 181Ca of the first capacitor circuit 181C is the ring-shaped groove of the recess 368. The capacitor circuit 18C is coupled to the coupling member 36 by fitting with 368a. In this coupled state, one end 1814a of the terminal member 1814 of the first capacitor circuit 181C abuts and is electrically connected to the ring-shaped electrode conductor 362b at the other end of the terminal member 362 of the coupling member 36, and The rod-shaped one end 1815a of the terminal member 1815 of the first capacitor circuit 181C is inserted into the insertion hole 363e of the terminal member 363 of the connecting member 36 and is electrically connected to the other end 363b.

  Next, in the second cylindrical body 5D, the screw portion 5Da formed on the inner wall surface of the opening on one end side and the opening of the first cylindrical body 5C so as to house the capacitor circuit 18C therein. A threaded portion 5Cc formed on the outer peripheral side surface of 5Cb is screwed together to form an integral cylindrical body 5 '.

  Next, the protrusion 19c is engaged with the positioning groove 5Db in the small diameter portion 195 of the cap 19C in the second cylindrical body 5D. At this time, in the third embodiment, a part of the second capacitor circuit 182C of the capacitor circuit 18C is inserted into the recess 198 provided in the small-diameter portion 195 of the cap 19C so as to be electrically connected to each other. Connections are also made.

  A configuration example of the cap 19C in the third embodiment is shown in FIG. 18A is a view of the cap 19C viewed from the side facing the capacitor circuit 18C. FIG. 18B is a view of the cap 19C viewed from the side opposite to the side facing the capacitor circuit 18C. FIG. FIG. 18C is a cross-sectional view taken along the line GG in FIG.

  The cap 19C has the same configuration as the cap 19 in the first embodiment, but the configuration of the connecting portion with the capacitor circuit 18C having a diameter smaller than that of the capacitor circuit 18 in the first embodiment is different. In FIG. 18, the same components as those of the cap 19 in the first embodiment are given the same reference numerals.

  That is, on the end surface of the small diameter portion 195 of the cap 19C in the third embodiment facing the second capacitor circuit 182C, as shown in FIGS. A recess 198 is formed in which a part of the second capacitor circuit 182C is fitted. The recess 198 is a circular recess having a diameter substantially equal to the diameter of the second capacitor circuit 182C. A ring-shaped groove 198a into which the ring-shaped protrusion 182b of the second capacitor circuit 182C is fitted is formed on the side wall of the recess 198, and the central axis direction formed in the second capacitor circuit 182C A central axial groove 198b with which the protrusion 182a engages is formed.

  Further, one end portions 192a and 193a of the terminal members 192 and 193 are provided on the bottom surface of the recess 198 of the cap 19C, and the other end 1825b of the terminal member 1825 and the other end of the terminal member 1826 on the end surface of the second capacitor circuit 182C. Exposed so as to elastically abut against 1826b. Similarly to the first embodiment, the other end 192 b of the terminal member 192 is connected to one end of the connector 194, and the other end 193 b of the terminal member 193 is connected to the other end of the connector 194.

  The small-diameter portion 195 of the cap 19C configured as described above is engaged with the protrusion 19c in the positioning groove 5Db in the second cylindrical body 5D, and the protrusion 182a of the second capacitor circuit 182C. However, it inserts so that it may engage with the groove | channel 198b of the recessed part 198 of the cap 19C. Then, the ring-shaped groove portion 19a of the cap 19C and the ring-shaped protrusion 5Dc of the second cylindrical portion 5D are fitted, and the cap 19C is locked with respect to the second cylindrical body 5D. At this time, the end of the second capacitor circuit 182C is inserted into the recess 198 of the cap 19C, the ring-shaped protrusion 182b is fitted into the ring-shaped recess 198a of the recess 198, and the capacitor circuit 18C is connected to the cap 19C. Is combined with. In this coupled state, the other end 1825b of the terminal member 1825 and the other end 1826b of the terminal member 1826 of the second capacitor circuit 182C are connected to one end 193a of the terminal member 193 and the terminal member 192 on the bottom surface of the recess 198 of the cap 19C. Are connected to one end 192a. The electronic ink cartridge 30 is assembled as described above.

[Setting of capacitance value of capacitor circuit 18C]
As described above, on the opening 5Cb side of the first cylindrical body 5C in which the connecting member 36 is accommodated, the ring-shaped electrode conductor 362b at the other end of the terminal member 362 of the connecting member 36 and the terminal member 363 The end portion 363b is exposed to be accessible from the outside. The ring-shaped electrode conductor 362b and the other end 363b are connected to one end and the other end of a parallel resonance circuit including a capacitor including the coil 33 and the pressure sensing chip 400. Therefore, the electrical characteristics of the parallel resonant circuit composed of the capacitor constituted by the coil 33 and the pressure sensing chip 400 can be extracted from the ring-shaped electrode conductor 362b of the terminal member 362 and the other end 363b of the terminal member 363. Is done.

  In this embodiment, using the ring-shaped electrode conductor 362b of the terminal member 362 and the other end 363b of the terminal member 363 that can be contacted from the outside as described above, the capacitor circuit 18C is configured as follows. The capacitance of the capacitor circuit 181C and the capacitance of the second capacitor circuit 182C are set. .

  The setting of the capacitance value of the capacitor circuit 18C will be described with reference to the equivalent circuit of FIG. As described above, between the ring-shaped electrode conductor 362b at the other end of the terminal member 362 of the connecting member 36 and the other end 363b of the terminal member 363, the coil 33 wound around the farite core 34 and A parallel circuit is connected to a variable capacitance capacitor 400C constituting the pressure sensing chip 400 housed in the pressure sensing semiconductor device 35. At this time, the writing pressure is not applied to the core 31, and the inductance Lc of the coil 33 and the electrostatic capacity CVo of the capacitor 400 </ b> C configured by the pressure sensing chip 400 at that time are caused by the manufacture. It is assumed that the value includes variation.

Therefore, first, the resonance frequency f ₁ of the resonance circuit constituted by the inductance Lc of the coil 33 and the capacitance CVo of the capacitor 400C constituted by the pressure sensing chip 400 is used as the ring-shaped electrode conductor at the other end of the terminal member 362. 362b and the other end 363b of the terminal member 363 are used for measurement. Next, a capacitance value Co is known, to connect to the other end 363b of the ring-shaped electrode conductor 362b and the terminal member 363 of the other end of the terminal member 362, similarly, to measure the resonance frequency f ₂ . Note that the resonance frequency f ₀ to be set is known, and the capacitance value to be set by the first capacitor circuit 181C of the capacitor circuit 18C is Cx.

f ₁ ² = 1 / {4 · π ² · Lc · CVo}
f ₂ ² = 1 / {4 · π ² · Lc · (CVo + Co)}
f ₀ ² = 1 / {4 · π ² · Lc · (CVo + Cx)}
From these equations,
Cx = Co · (f ₂ / f ₀ ) ² · (f ₁ ² −f ₀ ² ) / (f ₁ ² −f ₂ ² )
It becomes.

As described above, even if the inductance Lc of the coil 33 and the capacitance of the capacitor 400C configured by the pressure sensing chip 400 are unknown or include a variation, this coil corresponds to the resonance frequency fo to be set. The capacitance value Cx connected in parallel to the parallel circuit of 33 and the capacitor 400C can be calculated. In other words, the capacitance (first electrostatic capacitor circuit 181C of the capacitor circuit 18C for the push switch 7 so as to the frequency f ₀ of the object resonance frequency of the resonance circuit of the position indicator of when it is turned off The number of chip capacitors 183 having the calculated capacitance is stored in the first capacitor circuit 181C of the capacitor circuit 18C, and the capacitance of the first capacitor circuit 181C is set.

Similarly, the resonance frequency of the resonance circuit of the position indicator when the push switch 7 is on with respect to the resonance circuit composed of the coil 33, the pressure sensing chip 400, and the first capacitor circuit 181C is set as a target. capacitance to such a frequency f ₄ (the capacitance value to be set in the second capacitor circuit 182C of the capacitor circuit 18C and Cx2) is calculated as follows.

The capacitance value set in the first capacitor circuit 181C is assumed to be Cx1 (this value is the same value or approximate value as Cx), and the capacitance value is changed to Cx1 instead of a capacitor having a known capacitance value Co. a first capacitor circuit 181C that has been set, connected to the other end 363b of the ring-shaped electrode conductor 362b and the terminal member 363 of the other end of the terminal member 362, similarly, to measure the resonance frequency _{f 3.}

f ₁ ² = 1 / {4 · π ² · Lc · CVo}
f ₃ ² = 1 / {4 · π ² · Lc · (CVo + Cx1)}
f ₄ ² = 1 / {4 · π ² · Lc · (CVo + Cx1 + Cx2)}
From these equations,
Cx2 = Cx1 · (f ₁ / f ₄ ) ² · (f ₃ ² −f ₄ ² ) / (f ₁ ² −f ₃ ² )
It becomes.

  Then, the capacitance value Cx2 of the second capacitor circuit 182C of the capacitor circuit 18C is set so that the calculated capacitance Cx2 is obtained.

  As described above, by measuring the resonance frequency in the same state as the actual use state, the capacitance value of the first capacitor circuit 181C of the capacitor circuit 18C can be calculated. The same or close value is set.

  Further, since the resonance frequency to be changed by operating the push switch (side switch) 7 is known, the second capacitor having a dependency on the capacitance value of the first capacitor circuit 181C of the capacitor circuit 18C. The value of the capacitance of the circuit 182C can also be calculated.

  The electronic ink cartridge 30 according to the third embodiment includes a coil 33 housed in a cylindrical body 5 ', a capacitance 400C of the pressure sensing chip 400, and capacitances (Cx1, Cx2) set in the capacitor circuit 18C. The resonance frequency of the parallel resonance circuit consisting of is adjusted in both the off state and the on state of the push switch 7. Therefore, also in the case of the third embodiment, when the electronic ink cartridge 30 is housed in the housing 2 of the position indicator, adjustment of the resonance frequency is no longer necessary.

  In the third embodiment, the core 31, the ferrite core 34 around which the coil 33 is wound, and the pressure sensing semiconductor device 35 are combined in the hollow portion of the first cylindrical body 5C. The unit is housed as an integrated structure, and is connected to the capacitor circuit 18C on the end face of the connecting member 36. The capacitor has a variable capacity and is constituted by one end and the other end of the coil 33 and the pressure sensing chip 400. The connection terminals to which one end and the other end of 400C are connected are exposed in a state where they can be contacted from outside.

  For this reason, the resonance frequency of the resonance circuit including the coil 33 housed in the first cylindrical body 5C and the capacitance of the pressure sensing chip 400 housed in the pressure sensing semiconductor device 35 is set to the connection member. Measurement can be performed using the connection terminals provided on the 36 end faces. As a result, the capacitance value of the capacitor circuit 18C, which is connected in parallel to the parallel resonance circuit of the coil 33 and the pressure sensing chip 400 and constitutes the parallel resonance circuit, is set as described above so that the resonance frequency becomes a desired value. It can be calculated.

  In the above-described embodiment, the capacitor circuit 18C is connected so that the one electrode and the other electrode of the capacitor circuit 18C whose capacitance is set to a desired value are connected to the connection terminal of the connection member 36. The electronic ink cartridge 30 can be configured simply by coupling to the member 36, and the configuration becomes very simple.

  Further, in the third embodiment, the core 31, the ferrite core 34 around which the coil 33 is wound, the pressure sensing semiconductor device 35 as a pressure sensitive sensor, and the capacitor circuit 18 </ b> C are included in the electronic ink cartridge 30. While being inserted, the electronic ink cartridge 30 is assembled with the resonance frequency already adjusted. Therefore, the position indicator can be configured simply by storing the electronic ink cartridge 30 in the housing of the position indicator. Therefore, it is possible to realize a position indicator that can handle the electronic ink cartridge 30 like a replacement core such as a so-called ballpoint pen.

  Similarly to the above-described embodiment, in the cylindrical body 5 ′ of the electronic ink cartridge 30, components are arranged side by side in the central axis direction and sequentially arranged, and electrically connected. Since the coupling is also performed, it is possible to easily realize a configuration of a thin electronic ink cartridge having a diameter of, for example, 2.5 mm.

[Modification of Third Embodiment]
Also in the third embodiment described above, an ID package that houses the same ID transmission circuit 300 as in the second embodiment is housed in the cylindrical body 5 ′, so that it is the same as in the second embodiment. Information such as identification information of the electronic ink cartridge 30 can be transmitted to the position detection device. In this case, the ID package that houses the ID transmission circuit 300 only needs to be connected in parallel to the coil 33. Therefore, as can be seen from the equivalent circuit of FIG. It may be at any position between the circuit 18C or between the capacitor circuit 18C and the cap 19C.

  In the third embodiment described above, the pressure sensing chip 400 of the pressure sensing semiconductor device 35 is pressed by the core body 31, but the pressure sensing chip 400 of the pressure sensing semiconductor device 35 is connected to the core body. The configuration for transmitting the pressure applied to is not limited to this. For example, although not shown, the core body is provided to be coupled to the ferrite core as in the second embodiment, and the pressure sensing semiconductor device is provided on the opposite side of the ferrite core from the coupling side. Place. Then, a pressure sensing chip pressing member may be provided on the opposite side of the ferrite core from the coupling side, and the pressure sensing chip of the pressure sensing semiconductor device may be pressed by the pressing member. .

  In the third embodiment described above, the pressure sensing semiconductor device 35 and the ferrite core 34 around which the coil 33 is wound are integrally coupled, but the pressure sensing semiconductor device 35 and the coil 33 are wound. You may comprise so that the made ferrite core 34 may be connected via the further connection member.

  FIG. 20 is a diagram illustrating a configuration example of a main part of the electronic ink cartridge 30A in that case.

  That is, in the example of FIG. 20, in addition to the connecting member 36, a further connecting member 38 is provided between the pressure sensing semiconductor device 35 and the ferrite core 34 around which the coil 33 is wound. The connecting member 38 includes a protrusion 381 that is accommodated in the recess 352 of the pressure sensing semiconductor device 35, and a cylindrical portion 382 in which a hollow portion that accommodates the ferrite core 34 around which the coil 33 is wound is formed. Is provided. The cylindrical portion 382 has a length such that the end face on the opening side abuts on the connecting member 36 connected to the capacitor circuit 18C.

  The connecting member 38 includes fitting portions 383 and 384 that fit the lead terminals 356 and 357 of the pressure sensing semiconductor device 35 on the end surface of the cylindrical portion 382 facing the pressure sensing semiconductor device 35, respectively.

Further, the end surface of the cylindrical portion 382 formed on the connecting member 38 that abuts the connecting member 36 is
Fitting portions 383 and 384 fitted to the lead terminals 356 and 357 of the pressure sensing semiconductor device 35, and connection terminals 385 and 386 that are electrically connected by, for example, a gold wire are provided. For example, gold wires are connected to the connection terminals 385 and 386, respectively, and the gold wires are electrically connected to the V-shaped notches 362c and 363c of the terminal members 362 and 363 of the connecting member 36. Yes.

  The connecting member 38 includes ring-shaped grooves 38a and 38b, and the ring-shaped grooves 38a and 38b are fitted into ring-shaped protrusions 5Cf and 5Cg formed in the first cylindrical body 5C. Thus, it is fixed to the first cylindrical body 5C so as not to move in the central axis direction. Therefore, in the example of FIG. 20, the pressure sensing chip 400 of the pressure sensing semiconductor device 35 has the connecting member 38 fixed to the first cylindrical body 5 </ b> C, so that the pressure sensing semiconductor device 35 has the central axis. Since it does not move against the pressure applied to the core body 31 in the direction, the pressure applied to the core body 31 can be detected. In addition, the ferrite core 34 around which the coil 33 that forms the resonance circuit together with the pressure sensing semiconductor device 35 is wound is housed in a cylindrical portion 382 formed in the connecting member 38, and is electrically connected to the pressure sensing semiconductor device 35. Are connected in parallel, and further connected to terminal members 362 and 363 provided on the connecting member 36, respectively.

  In the third embodiment described above, the pressure sensing semiconductor device is used as the pressure sensitive sensor that changes the capacitance according to the pressure (writing pressure) applied to the core body. However, it is not limited to this. For example, the variable-capacitance type capacitor in which the electrostatic capacity is changed in accordance with the pressure (writing pressure) applied to the core body, which the applicant of the present application filed as Japanese Patent Application No. 2012-151357, is used as the pressure-sensitive sensor. You can also.

  In the variable capacitance capacitor described in Japanese Patent Application No. 2012-151357, a film electrode having a predetermined shape is deposited on the inner wall surface of the hollow portion of the outer member formed of a cylinder having a hollow space. On the other hand, a film electrode having a predetermined shape is also formed on the outer peripheral surface of the columnar inner member. Then, the inner member is accommodated in the hollow space of the outer member so as to be movable in the central axis direction. In this case, the electrode on the inner wall surface of the outer member and the electrode on the outer peripheral surface of the inner member are opposed to each other via a dielectric so as to form a capacitor exhibiting a capacitance according to the opposed area. To.

  According to this configuration, when pressure is applied from the outside to the inner member in the central axis direction, the inner member moves in the central axis direction with respect to the outer member, so that the outer surface that opposes the dielectric member. The area of the electrode on the inner wall surface of the member and the electrode on the outer peripheral surface of the inner member changes. Therefore, the capacitance of the capacitor formed between the electrode of the outer member and the electrode of the inner member exhibits a capacitance corresponding to the applied pressure due to a change in the facing area of both electrodes.

  The variable capacitance capacitor having the above-described configuration can be formed in a thin rod shape, and an electronic ink cartridge used as a pressure-sensitive sensor can be configured in place of the pressure sensing semiconductor device 35 described above.

[Fourth Embodiment]
In the above embodiment, the pressure-sensitive sensor for detecting the writing pressure is realized by using an inductance circuit or a capacitor circuit that constitutes a resonance circuit included in the position indicator, and the position indicator on the position detection device side. The pen pressure at the position indicator is detected by detecting the frequency shift (phase shift) of the electromagnetic induction signal from.

  However, by using the IC circuit of the information transmission circuit in the above-described embodiment, the writing pressure information is converted into the position of the digital pressure signal as a digital signal, similar to the identification information (ID) of the electronic ink cartridge and the position indicator in the above-described example. It can also be transmitted from the indicator to the position detector. The position indicator of the fourth embodiment is an example of such a configuration.

  The circuit shown on the upper side of FIG. 21 is an equivalent circuit of the position indicator 1D of the fourth embodiment. The position detection apparatus that performs position detection and writing pressure detection by electromagnetic coupling with the position indicator 1D is the position detection apparatus 200 shown in FIG. 7 in the case of the first embodiment described above.

  The mechanical arrangement of the main components of the electronic ink cartridge 30D constituting the position indicator 1D of the fourth embodiment is the same as that of the electronic ink cartridge 30 of the third embodiment shown in FIG. This is the same as the electronic ink cartridge 30A of the modified example of the third embodiment shown in FIG. However, in the fourth embodiment, the ID package 320 in the example of FIG. 9 shown as a modification of the first embodiment is provided between the capacitor 18C and the cap 19C, and the pressure sensing semiconductor. In the package member 351 of the device 35, a control circuit 500 for controlling the pressure sensing chip 400 and writing pressure information detected by the pressure sensing chip 400 to be sent to the position detection device 200 by electromagnetic coupling is housed. This is different from the electronic ink cartridges 30 and 30A of the third embodiment and the modified example of the third embodiment.

  In the electronic ink cartridge 30D of the fourth embodiment, as shown in FIG. 21, the coil 33 in the cylindrical body 5 'of the electronic ink cartridge 30D, the first capacitor circuit 181C and the second capacitor circuit 18C The capacitor circuit 182C forms a parallel resonance circuit 20R ′, and one end and the other end of the parallel resonance circuit 20R ′ are connected to one end and the other end of the ID package 320, respectively.

  In the electronic ink cartridge 30D of the fourth embodiment, the control circuit 500 is provided between one end and the other end of the coil 33 as shown in FIG. The control circuit 500 includes a control IC 501. The IC 501 is connected to a capacitor (capacitance Cv) constituted by the pressure sensing chip 400, and the IC 501 can detect a variable capacitance Cv corresponding to the writing pressure. The IC 501 detects the writing pressure in the position indicator 1D from the value of the variable capacitance Cv.

  The IC 501 is a power supply voltage Vcc obtained by rectifying an AC signal received by electromagnetic coupling from the position detection device 200 by the parallel resonance circuit 20R ′ by a drive signal generation circuit 504 including a rectifier circuit including a diode 502 and a capacitor 503. It is comprised so that it may operate | move. In the control circuit 500, a switch circuit 505 is connected in parallel with the parallel resonant circuit 20R ′. The switch circuit 505 is configured to be on / off controlled by the IC 501. The IC 501 is supplied with the electromagnetic induction signal transmitted from the position detection device 200 via the capacitor 506 as a synchronization signal for exchanging the electromagnetic induction signal with the position detection device 200.

  Then, the IC 501 of the control circuit 500 according to the fourth embodiment detects the value of the capacitance Cv of the variable capacitor formed by the pressure sensing chip 400 as information on the writing pressure in the position indicator 1D, and The detected writing pressure is converted into, for example, an 8-bit digital signal, and the switch 505 is controlled by the digital signal corresponding to the writing pressure.

  A position detection operation and a pen pressure detection operation of the position indicator 1D and the position detection device 200 configured as described above will be described.

  First, the processing control unit 233 performs driving of the drive circuit 222, selection control of the selection circuit 213, and switching control of the switching connection circuit 223 in the same manner as in the above-described embodiment, and the position controller 1D, The electromagnetic induction signal is transmitted and received to obtain the X coordinate value and the Y coordinate value of the position indicated by the position indicator 1D.

  When the position indicated by the position indicator 1D is detected as described above, the processing control unit 233 detects the 8-bit writing pressure information from the position indicator 1D, and therefore a loop near the position where the position indicator 1D exists. In the coil, after transmitting a signal for synchronization for a predetermined time, transmission / reception is continuously performed 8 times at the same timing as the coordinate detection. In other words, the processing control unit 233 controls the selection circuit 213, and according to the detected coordinate value of the position indicator 1D, the loop coil closest to the position indicator 1D (either the X-axis direction loop coil or the Y-axis direction loop coil). You can send and receive signals.

  On the other hand, the IC 501 of the control circuit 500 of the position indicator 1D converts the writing pressure obtained corresponding to the electrostatic capacitance Cv of the pressure sensing chip 400 into an 8-bit digital signal, and the 8-bit digital signal The switch circuit 505 is controlled to be turned on / off in synchronization with transmission / reception of a signal from the position detection device 200. When the switch 505 circuit is off, the resonance circuit 20R ′ can return the signal transmitted from the position detection device 200 to the position detection device 200, so that the loop coil of the position detection device 200 receives this signal. . On the other hand, when the switch circuit 505 is on, the operation of the resonance circuit 20R ′ is prohibited. For this reason, no signal is returned from the resonance circuit 20R ′ to the position detection device 200, and the position detection device. The 200 loop coils do not receive signals.

  The processing control unit 233 of the position detection apparatus 200 receives the 8-bit digital signal corresponding to the writing pressure by detecting the presence / absence of the received signal eight times, and detects the writing pressure information from the position indicator 1D. be able to.

[Other Embodiments or Modifications]
In the above first to third embodiments, the capacitor circuits 18 and 18C have a configuration in which chip capacitors are stacked and a configuration in which the capacitance is set according to the number of capacitors to be stacked. It is not limited to this. For example, a capacitor having a configuration in which a dielectric sheet on which an electrode having a predetermined pattern shape is applied, which is filed as Japanese Patent Application No. 2012-128834 by the present applicant, is wound in a rod shape can be used. In the capacitor described in Japanese Patent Application No. 2012-128834, in the case of a rod-shaped capacitor, the capacitance can be set afterwards by adopting a configuration in which a part of electrode patterns can be cut or joined afterwards. It is possible.

  Further, in the above-described embodiment, the coupling member 17, 27, or 36 disposed between the coil 16, 24, or 33 and the capacitor circuit 18, 28, or 18C has an end face on the capacitor circuit 18, 28, or 18C side. Are provided with two connection terminals for electrically connecting one end and the other end of the coil 16, 24 or 33 and one end and the other end of the capacitor circuit 18, 28 or 18C. However, when the cylindrical body 5, 50 or 5 ′ is a non-magnetic material such as SUS310 and a conductive material such as the above example, the two end surfaces of the connecting members 17, 27, or 36 It is also possible to arrange only at least one of the connection terminals and use the conductive cylindrical body 5, 50 or 5 'for the other.

  For example, in the first embodiment described above, only the end portion 173c of the terminal member 173 is provided on the end surface of the connecting member 17 facing the capacitor circuit 18 so as to expose the insertion hole 173d, and the terminal The ring-shaped electrode conductor 172c of the member 172 is configured not to be exposed to the end face but to the peripheral portion of the main body 171 of the connecting member 17 so as to be electrically coupled to the first cylindrical body 5A.

  On the other hand, in the first capacitor circuit 181 of the capacitor circuit 18, the one end 1815 a of the rod-shaped body of the terminal member 1815 is formed in the same manner as in the above embodiment, but the one end 1814 a of the terminal member 1814 is the peripheral portion of the holder 1810. It exposes to and is comprised so that it may couple | bond electrically with the 2nd cylindrical body 5B.

  In this case, the capacitor circuit 18 and the connecting member are connected, and the first cylindrical body 5A and the second cylindrical body 5B are screwed and connected to each other. A connection is made. In this case, the cylindrical body 5 is preferably a ground electrode, for example.

  Similarly, in the second embodiment, for example, on the end surface of the coupling member 27 on the capacitor circuit 28 side, the other end of the terminal member 273 is a circular conductor 273c as in the above-described embodiment. At the same time, the other end 272 c of the terminal member 272 is exposed not on the end face but on the peripheral portion of the main body 271 so as to be electrically coupled to the cylindrical body 50.

  The one end 1815a ′ of the terminal member 1815 of the first capacitor circuit 281 of the capacitor circuit 28 is formed as a circular electrode that abuts the circular conductor 273c on the end surface of the connecting member 27 as in the above example. The one end 1814a of the terminal member 1814 is configured to be exposed to the peripheral portion of the holder 1810 and electrically coupled to the cylindrical body 50.

  In the case of the second embodiment, by inserting the capacitor circuit 28 into the cylindrical body 50, one end 1814 a of the terminal member 1814 exposed to the peripheral portion of the holder 1810 is electrically connected to the cylindrical body 50. Connected.

  In the third embodiment, the connecting member 36 and the capacitor circuit 18C are modified in the same manner as the connecting member 17 and the capacitor circuit 18 of the first embodiment, so that the cylindrical body 5 ′ is formed. Can be configured as one of the electrical connection electrodes.

  Further, as described above, in the electronic ink cartridge of the present invention, the cylindrical body includes a ferrite core in which a coil is wound between the end portion on the side where the core body is located and the connecting member, and a sensor. And a pressure sensor. As described in the first embodiment and the second embodiment, the arrangement order in the central axis direction of the cylindrical body of the ferrite core around which the coil is wound and the pressure sensor is any. It may be on the connecting member side. Further, the three members of the connecting member, the ferrite core around which the coil is wound, and the pressure-sensitive sensor may be connected as independent members, or may be integrated by combining three members. Alternatively, two of the three may be combined and integrated.

That is, as an electronic ink cartridge,
(1) Connected by independent members in the order of ferrite core wound with coil → pressure sensor → connecting member (2) Independent members connected in order of pressure sensor → ferrite core wound with coil → connected member (3) Ferrite core around which coil is wound → Pressure sensor → Connecting member is unitized as an integrated structure. (4) Pressure sensor → Ferrite core around which coil is wound → Connecting member (5) Ferrite core around which coil is wound → Pressure-sensitive sensor united as a unitary unit with a united structure (separately connecting members) 6) Pressure sensor → Connect the ferrite core around which the coil is wound in the unit as an integrated structure and connect the connection member separately. Coil is wound around a pressure sensitive sensor in which a connecting member is integrally provided on a pressure sensitive sensor and arranged as a unit with respect to a ferrite core wound with a (8) core. It is possible to have a combination of eight combinations of a unit obtained by integrally providing a connecting member on a ferrite core.

  As described above, the electronic ink cartridge of the present invention can be handled in the same manner as an ink cartridge (replacement core) housed in a housing, such as a ballpoint pen of a writing instrument. In a ballpoint pen, the ink cartridge is switched between a state in which the pen tip is housed in the housing and a state in which the pen tip is extended out of the housing by a so-called knock type or a rotary type. One having a structure in which a plurality of ink cartridges having different colors is switched to extend a pen tip from a casing is known.

  Therefore, in the position indicator of the present invention, similarly, the electronic ink cartridge is stored in the housing in a so-called knock type or rotational manner, and the core body is extended out of the housing. It can be set as the structure which switches to the made state. In addition, the position indicator of the present invention may be configured to switch, for example, a plurality of electronic ink cartridges having different core thicknesses or to switch between a ballpoint pen ink cartridge and an electronic ink cartridge.

DESCRIPTION OF SYMBOLS 1 ... Position indicator, 2 ... Case, 5, 5 ', 50 ... Cylindrical body, 7 ... Push switch (side switch) 10, 20, 30 ... Electronic ink cartridge 11, 11, 21, 31 ... Core body, DESCRIPTION OF SYMBOLS 13,26 ... Ferrite chip, 14, 25 ... O-ring, 15, 23, 34 ... Ferrite core, 16, 24, 33 ... Coil, 17, 27, 36, 38 ... Connection member, 18, 18C ... Capacitor circuit, 19 , 19C ... Cap, 35 ... Pressure sensing semiconductor device

Claims (13)

A cartridge that is used in a position detection device having an input surface and is housed in a housing of a pen-shaped position indicator that performs position indication on the input surface,
While being detachably housed in the housing of the position indicator,
A cylindrical body having a hollow portion;
A core body arranged to extend to the outside from one end side in the central axis direction of the cylindrical body;
A first circuit that is housed in the cylindrical body and that generates a signal for detecting the indicated position on the input surface by the position detection device;
A second circuit electrically connected to the first circuit;
With
The second circuit includes information for specifying a position detection method of the cartridge, and the cartridge position detection method provided in the second circuit corresponding to a signal transmitted from the position detection device. The cartridge is configured to transmit information specifying the position to the position detection device. A cartridge that is used in a position detection device having an input surface and is housed in a housing of a pen-shaped position indicator that performs position indication on the input surface,
While being detachably housed in the housing of the position indicator,
A cylindrical body having a hollow portion;
A core body arranged to extend to the outside from one end side in the central axis direction of the cylindrical body;
A first circuit that is housed in the cylindrical body and that generates a signal for detecting the indicated position on the input surface by the position detection device;
A second circuit electrically connected to the first circuit;
With
The second circuit is housed in a package, and the second circuit is connected via at least one connection end connected to the first circuit,
The second circuit includes information for specifying a position detection method of the cartridge, and the cartridge position detection method provided in the second circuit corresponding to a signal transmitted from the position detection device. The cartridge is configured to transmit information specifying the position to the position detection device. A cartridge that is used in a position detection device having an input surface and is housed in a housing of a pen-shaped position indicator that performs position indication on the input surface,
While being detachably housed in the housing of the position indicator,
A cylindrical body having a hollow portion;
A core body arranged to extend to the outside from one end side in the central axis direction of the cylindrical body;
A first circuit that is housed in the cylindrical body and includes a pressure-sensitive sensor that senses a pressure applied to the core;
A second circuit electrically connected to the first circuit;
With
The second circuit includes information for specifying a pressure detection method of the pressure sensor housed in the cylindrical body of the cartridge, and the second circuit corresponds to a signal transmitted from the position detection device. A cartridge configured to transmit information specifying a pressure detection method of the pressure sensor included in the circuit of 2 to the position detection device. A cartridge that is used in a position detection device having an input surface and is housed in a housing of a pen-shaped position indicator that performs position indication on the input surface,
While being detachably housed in the housing of the position indicator,
A cylindrical body having a hollow portion;
A core body arranged to extend to the outside from one end side in the central axis direction of the cylindrical body;
A first circuit that is housed in the cylindrical body and includes a pressure-sensitive sensor that senses a pressure applied to the core;
A second circuit electrically connected to the first circuit;
With
The second circuit is housed in a package, and the second circuit is connected via at least one connection end connected to the first circuit,
The second circuit includes information for specifying a pressure detection method of the pressure sensor housed in the cylindrical body of the cartridge, and the second circuit corresponds to a signal transmitted from the position detection device. A cartridge configured to transmit information specifying a pressure detection method of the pressure sensor included in the circuit of 2 to the position detection device.   The cartridge according to claim 1 or 2, wherein the cartridge position detection method is an electromagnetic induction method or an electrostatic coupling method.   The pressure detection method of the pressure sensor is a pressure detection method based on a capacitance that changes corresponding to the pressure applied to the core or an inductance that changes according to the pressure applied to the core. 5. The cartridge according to claim 3, wherein the cartridge is based on a pressure detection method.   The second circuit is connected to the first circuit through the at least one connection end by storing the package in which the second circuit is stored in the cylindrical body. The cartridge according to claim 2 or 4.   The package containing the second circuit is connected to the other end side in the central axis direction of the cylindrical body, so that the second circuit is connected to the first circuit via the at least one connection end. The cartridge according to claim 2, wherein the cartridge is connected to one circuit.   The at least one connection end is disposed in a state exposed to the outside of the cylindrical body, and the package containing the second circuit is engaged with the cylindrical body, The cartridge according to claim 2 or 4, wherein the second circuit is connected to the first circuit via at least one connection end.   A connecting member is provided on the other end side in the central axis direction of the cylindrical body, and the at least one connecting end connected to the first circuit is provided via the connecting member. The cartridge according to claim 2 or 4, wherein the cartridge is provided.   The at least one connection end is a surface portion of the coupling member in a direction intersecting with a central axis direction of the cylindrical body, and is exposed and disposed on an outer surface portion exposed to the outside of the cylindrical body. The cartridge according to claim 10.   The at least one connection end is exposed to an outer surface portion of the coupling member, and a central electrode disposed corresponding to a central axis of the cylindrical body, and a periphery formed around the central electrode The cartridge according to claim 10, comprising an electrode. The cylindrical body is a non-magnetic body having conductivity, and the second circuit includes the at least one connection end and the cylindrical body disposed in a state of being exposed to the outside of the cylindrical body. The cartridge according to claim 12, wherein the cartridge is connected to the first circuit via the first circuit.

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