JP2007158942A - Card type device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a card type device in which convenience is improved by automating the turning action of an antenna body structure. <P>SOLUTION: In a card type device 1 with a radio communication function configured by housing a circuit board 2 within a casing 3, an antenna body structure 4 is provided outside the casing 3 so as to be turned and displaced. A motor 17 adding rotary torque is provided on a turning shaft 12 of the antenna body structure 4. A motor driving circuit part provided in the card type device 1 includes a circuit part for electrifying an antenna body structure erection current to the motor 17 in response to a radio communication start signal to turn and displace the antenna body structure 4 in an erecting direction, a circuit part for controlling a turning position of the antenna body structure 4 by controlling a direction of the electrification current to the motor 17 in order to keep a high level of radio communication sensitivity receiving radio communication sensitivity information, and a circuit part for turning and displacing the antenna body structure 4 in a housing direction by electrifying a current inverse to the antenna body structure erection current to the motor 17 in response to a radio communication end signal. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a card type device such as a PC card or a CF card having a wireless communication function. CF (compact flash) is a registered trademark.

  FIG. 13 is a schematic perspective view showing an example of a card-type device. The card-type device 40 has a wireless communication function. The card-type device 40 includes a circuit board 41, a flat housing 42 that houses the circuit board 41, and a radio wave that is disposed outside the housing 42. And an antenna structure 43 that performs wireless communication. An antenna rotation shaft 44 is formed on the base end side of the antenna structure 43, and a through hole for inserting the antenna rotation shaft 44 from the outside to the inside of the housing 42 is provided in the side wall portion of the housing 42. Yes. A bearing portion (not shown) that receives the antenna rotation shaft 44 is provided inside the housing 42. In the configuration of the card-type device 40, the antenna structure 43 can be rotated about the antenna rotation shaft 44 as a rotation shaft. For example, when the card-type device 40 is used by being inserted into a card slot provided in an information terminal device such as a personal computer, the antenna structure 43 is attached to the housing 42 as shown by a chain line in FIG. It is rotated and displaced in the direction to stand up with respect to the upper surface of the. Thereby, the sensitivity of transmission / reception of radio waves can be increased. Further, when the card-type device 40 is taken out from the card slot of the information terminal device, for example, to be carried, the antenna structure 43 is rotationally displaced and stored in a tilted state as shown by a solid line in FIG. The card-type device 40 can be easily carried.

JP 2001-69029 A JP 2003-92504 A JP 2003-318767 A

  In the configuration of the card-type device 40 shown in FIG. 13, for example, when the card-type device 40 is inserted into a card slot of an information terminal device and used, the antenna structure 43 is rotated in the direction in which the antenna structure 43 is manually raised. For example, when the use of the card-type device 40 is finished, the antenna structure 43 is manually rotated and displaced in the direction of tilting. As described above, since the antenna structure 43 is rotationally displaced manually, it is troublesome.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a card type device that improves the usability by automating the turning operation of the antenna structure.

In order to achieve the above object, the present invention has the following configuration as means for solving the above problems. That is, this invention
In a card type device with a wireless communication function in which a circuit board having a high-frequency circuit for wireless communication is housed in a flat housing,
An antenna structure provided with an antenna body for performing radio communication of radio waves and disposed outside the housing;
A feeding shaft for electrically connecting the antenna main body of the antenna structure projectingly formed on the antenna structure to a high-frequency circuit for wireless communication on a circuit board in the housing;
Separately from the feeding shaft, the antenna structure is formed so as to protrude from the stowed state in which the antenna structure is tilted with respect to the upper surface of the housing and to the standing state and vice versa. A pivot shaft that pivots and displaces,
An antenna driving motor that applies rotational torque to the rotational shaft to rotationally displace the antenna structure;
An antenna standing-up circuit unit that receives a wireless communication start signal and energizes the antenna driving motor with a current for raising the antenna structure to rotate and displace the antenna structure in the standing direction;
While receiving a wireless communication sensitivity information signal output from a high frequency circuit for wireless communication and detecting that a temporal change in the wireless communication sensitivity information signal is a direction in which the wireless communication sensitivity increases, the current in the same direction When the antenna drive motor continues to be energized, and it is detected that the temporal change of the wireless communication sensitivity information signal is in the direction of worsening the wireless communication sensitivity, the direction of the energization current to the antenna drive motor is reversed and the antenna An antenna control unit for controlling the rotation position of the antenna structure so that the wireless communication sensitivity of the main body is maintained at a high level;
An antenna storage circuit unit that receives a radio communication end signal and applies a current in a direction opposite to the current for standing up the antenna structure to the antenna drive motor to rotate and displace the antenna structure in a retracted direction; ,
It is characterized by being provided.

  According to the present invention, the antenna driving motor that applies the rotational torque to the rotating shaft of the antenna structure is provided, and the antenna driving motor is energized by receiving a wireless communication start signal to enclose the antenna structure. An antenna standing circuit portion that automatically rotates and displaces in the direction to stand up with respect to the upper surface of the antenna, and an antenna structure that receives a wireless communication end signal and applies a current in the direction opposite to that at the time of standing up and turning to the antenna driving motor. An antenna housing circuit portion that automatically rotates and displaces the body in the housing direction is provided. With this configuration, the card-type device of the present invention automatically rotates in the direction in which the antenna structure rises when starting wireless communication, and automatically when wireless communication ends. Therefore, the antenna structure is collapsed and stored. Therefore, there is no hassle of manually raising the antenna structure when starting wireless communication or manually retracting and storing the antenna structure when wireless communication is terminated, improving the usability of the card-type device Can be made.

  Further, in the card type device of the present invention, the antenna structure is automatically rotated and displaced, so there is no need to manually rotate and displace the antenna structure. For this reason, a structure for facilitating gripping the antenna structure and facilitating the manual rotation of the antenna structure is unnecessary, and the card-type device has a structure that is more than that provided with such a structure. The structure can be simplified.

  Furthermore, when the antenna structure is manually rotated and displaced, a situation may occur in which the antenna structure is damaged due to an error in force adjustment or the like. On the other hand, in the card-type device of the present invention, it is not necessary to manually rotate the antenna structure by automatically rotating and displacing the antenna structure. Thereby, the failure occurrence rate of the antenna structure resulting from the above-described manual operation can be reduced.

  Furthermore, according to the present invention, an antenna control unit is provided, and the current supplied to the antenna drive motor is maintained by the operation of the antenna control unit so that the wireless communication sensitivity of the antenna body is maintained based on the wireless communication sensitivity information signal. Is controlled to control the rotation position of the antenna structure. For this reason, wireless communication using the card-type device of the present invention can be performed with a better wireless communication sensitivity state. Thereby, the reliability with respect to the radio | wireless communication of the card-type apparatus of this invention can be improved.

  Furthermore, by providing the antenna driving motor, there is a concern that noise caused by the rotation driving of the antenna driving motor may be added to the signal that is energized between the antenna body and the radio communication high frequency circuit. The On the other hand, in the present invention, a structure is provided in which the power feeding shaft for electrically connecting the antenna body of the antenna structure to the high frequency circuit for wireless communication is provided in the antenna structure separately from the rotating shaft. It was. For this reason, noise caused by the antenna driving motor in the signal between the antenna main body and the high frequency circuit for wireless communication can be reduced, and the antenna main body and the wireless communication due to the rotation driving of the antenna driving motor can be suppressed. It is possible to prevent the signal-to-noise ratio of the signal with the high frequency circuit for use from deteriorating. Since the signal-to-noise ratio of the signal between the antenna main body and the radio communication high-frequency circuit is related to the radio communication sensitivity of the card-type device, as described above, the antenna main body and the radio communication high-frequency circuit By preventing the signal-to-noise ratio of the signal from deteriorating, it is possible to avoid a decrease in the reliability of the card-type device with respect to wireless communication due to the rotational drive of the antenna driving motor.

  Furthermore, by providing a configuration that automatically stops the current supply to the antenna driving motor when the antenna structure is tilted by the rotational displacement in the storage direction of the antenna structure and the rotational displacement to the storage position is completed, The antenna driving motor can be energized only for a short period of time necessary to house the antenna structure. Thereby, the power consumption of the antenna driving motor can be suppressed, and power saving can be achieved.

  Embodiments according to the present invention will be described below with reference to the drawings.

  FIG. 1 (a) shows a simplified perspective view of an embodiment of a card-type device according to the present invention. FIG. 1 (b) shows the card-type device of FIG. 1 (a) as viewed from above. A schematic plan view is shown, and FIG. 2 shows a schematic exploded view of the card type apparatus shown in FIG. The card-type device 1 has a wireless communication function. The card-type device 1 includes a circuit board 2, a flat housing 3 that accommodates the circuit board 2, and a wireless radio wave that is disposed outside the housing 3. And an antenna structure 4 for performing communication. The card-type device 1 is inserted into a card slot provided in an information terminal device such as a personal computer, for example, and can be electrically connected to the information terminal device to exchange signals. That is, the card type device 1 is provided with external connection means (not shown) for electrically connecting to the information terminal device when inserted into the card slot of the information terminal device. The external connection means has various configurations such as a connector, for example, and the card type apparatus 1 is provided with an external connection means having an appropriate configuration according to, for example, specifications. The card-type device 1 has, for example, a function for transmitting a wireless transmission signal received from an information terminal device via an external connection means from the antenna structure 4 to a wireless communication partner, and a signal received by the antenna structure 4 Is provided to the information terminal device via an external connection means.

  In this embodiment, the housing 3 includes a front side cover portion 5 that covers the front side of the circuit board 2 and a back side cover portion 6 that covers the back side of the circuit board 2. The front-side cover 5 has a side edge on one end that is the rear end of the card-type device 1 inserted into the card slot of the information terminal device, and is located above the upper surface of the front-side cover 5. A protruding wall 5A is formed.

  The antenna structure 4 includes an antenna body (not shown) that performs radio wave radio communication (transmission and reception) and an antenna cover 7 that protects the antenna body. Note that the antenna main body has a configuration capable of performing wireless communication of radio waves in a predetermined frequency band. There are various antenna configurations for performing radio communication of such radio waves. Here, the antenna body may have any of these configurations, and the description thereof is omitted.

  In this embodiment, the antenna structure 4 has a shape that extends in the lateral width direction orthogonal to the insertion direction of the card-type device 1. Mounting portions 4a and 4b projecting in the orthogonal direction are formed. The length dimension in the width direction from the left end surface of the mounting portion 4a shown in FIG. 1 or 2 to the right end surface of the mounting portion 4b is from the left protruding wall 5A of the front cover portion 5 to the right protruding wall 5A. It is shorter than the length dimension. A protrusion 8a (see, for example, FIG. 1B) protruding leftward is formed on the left end surface of the attachment portion 4a, and a protrusion 8b protruding rightward is formed on the right end surface of the attachment portion 4b. . In addition, the left protruding wall 5A of the front cover portion 5 is formed with a recess or hole 9a that fits into the protrusion 8a of the attachment portion 4a. Further, the right protruding wall 5A is formed with a recess or hole 9b that fits into the protrusion 8b of the mounting portion 4b.

  By fitting the protrusions 8a and 8b of the mounting portions 4a and 4b of the antenna structure 4 into the corresponding recesses or holes 9a and 9b of the protruding wall 5A, the antenna structure 4 is rotated as shown below. It is attached to the front side cover part 5 in a freely movable state. That is, in this embodiment example, the antenna structure 4 is changed from the housed state where the antenna structure 4 is lying down on the upper surface of the housing 3 as shown in the perspective view of FIG. 3A to the perspective view of FIG. As shown in the figure, it can be freely rotated and displaced toward the state of standing up with respect to the upper surface of the housing 3 and in the opposite direction.

  A feeding shaft 11 extending in the rightward width direction is formed on the right end surface of the mounting portion 4a of the antenna structure 4, and a rotating shaft extending in the leftward width direction is formed on the left end surface of the mounting portion 4b. 12 are provided with their central axes positioned on the same straight line. The front cover portion 5 is provided with a bearing portion (not shown) of the power feeding shaft 11 and a bearing portion (not shown) of the rotating shaft 12. In this embodiment, a protective cover 14 that protects the power feeding shaft 11 and the rotating shaft 12 is attached to the front cover portion 5 in an area between the attachment portions 4a and 4b.

  In this embodiment, the feeding shaft 11 is electrically connected to the antenna body of the antenna structure 4. A high frequency circuit 15 for wireless communication is provided on the circuit board 2 accommodated in the housing 3. For example, the radio communication high-frequency circuit 15 converts (modulates) a radio transmission signal supplied from an information terminal device into a signal suitable for radio communication, or supplies a signal received by radio to the information terminal device. It has a circuit configuration for converting (demodulating) it into a signal suitable for this. The circuit board 2 is provided with power supply means 16 for electrically connecting the power supply shaft 11 to the radio communication high frequency circuit 15. That is, the antenna body of the antenna structure 4 and the radio communication high-frequency circuit 15 of the circuit board 2 are electrically connected via the rotating shaft 11 and the power feeding means 16. As a result, the radio transmission signal output from the radio communication high-frequency circuit 15 is transmitted to the antenna body of the antenna structure 4 via the power feeding means 16 and the power feeding shaft 11 and is wirelessly transmitted by the antenna body. The signal received by the antenna body is transmitted to the radio communication high-frequency circuit 15 via the power feeding shaft 11 and the power feeding means 16 and converted into a signal suitable for supply to the information terminal device, and after the conversion. Is output to the information terminal device. Note that there are various configurations of the power supply means 16, and the configuration is not particularly limited as long as the power supply shaft 11 and the radio communication high-frequency circuit 15 can be electrically connected. The power supply means 16 having an appropriate configuration is provided.

  In this embodiment, the circuit board 2 is provided with an antenna driving motor 17. The rotating shaft 17a of the antenna driving motor 17 is connected to the rotating shaft 12 of the antenna structure 4 via a shaft coupling device (coupling (not shown)). For this reason, the rotational torque by the rotational drive of the antenna drive motor 17 is transmitted to the rotating shaft 12 of the antenna structure 4 via the shaft coupling device. Thereby, the rotation shaft 12 rotates and the antenna structure 4 is rotationally displaced.

  In this embodiment example, the antenna structure 4 is configured to rotate and displace with respect to the card-type device 1 in the horizontal direction. Therefore, the antenna structure 4 rotates when the antenna structure 4 is rotated and displaced. The radius is shorter than the turning radius of the antenna structure 43 as shown in FIG. Thereby, even if the rotational torque transmitted from the antenna drive motor 17 to the rotation shaft 12 of the antenna structure 4 is small, the antenna structure 4 can be favorably displaced. For this reason, a motor having a small driving force, that is, a small motor can be provided as the antenna driving motor 17. In the card type device 1 whose size is limited by a standard such as a PC card or the like, the antenna driving motor 17 cannot be installed unless it is small, but in this embodiment, as described above, the antenna driving motor 17 is small. Thus, even with a motor having a small driving force, the antenna structure 4 can be driven to rotate without worrying about insufficient power.

  The circuit board 2 is provided with a motor control circuit unit 20 for controlling the rotational drive of the antenna driving motor 17. As shown in the block configuration diagram of FIG. 4, the motor control circuit unit 20 includes an antenna standing circuit unit 21, an antenna storage circuit unit 22, an antenna control unit 23, a storage completion motor energization stop unit 24, and the like. It is comprised. The antenna rising circuit unit 21 has received the wireless communication start signal from the information terminal device via the external connection means in a state where the card type device 1 is inserted into the card slot of the information terminal device such as a personal computer. When detected, the power supply power supplied via the power input unit Vcc is used to supply a current for raising the antenna structure to the antenna drive motor 17. By rotating the antenna driving motor 17 by the circuit operation of the antenna rising circuit unit 21, the antenna structure 4 stands up with respect to the upper surface of the housing 3 from the storage position lying down on the upper surface of the housing 3. Rotating displacement in the direction to do.

  The antenna control unit 23 controls the rotation position of the antenna structure 4 by using a wireless communication sensitivity information signal output from the receiving unit as shown below of the high frequency circuit 15 for wireless communication during wireless communication. It has the composition to do.

  FIG. 5 shows a circuit configuration example of a receiving unit provided in the radio communication high-frequency circuit 15. 5 includes an amplifier 27, a first stage mixer 28, a filter (for example, a bandpass filter) 29, a second stage mixer 30, an amplifier 31, and a filter (for example, a bandpass filter). 32 and an amplifier 33. In the configuration of the receiving unit 26, for example, only the signal component in the frequency band for wireless communication that has passed through the filter (for example, a bandpass filter) 35 among the signals received by the antenna body 34 of the antenna structure 4 is the receiving unit. 26. The received signal applied from the antenna body 34 side is amplified by the amplifier 27, and the amplified received signal is a circuit operation of the first stage mixer 28 using the first oscillation signal supplied from the frequency synthesizer unit S. Is lowered to a predetermined frequency. Then, the output signal of the first stage mixer 28 passes through the filter 29 and is applied to the second stage mixer 30 in a state where signal components of frequencies other than the set frequency band are attenuated by the filter 29. The second-stage mixer 30 creates and outputs a reception signal that has been lowered to a lower set frequency based on a second oscillation signal that is different from the first oscillation signal applied from the frequency synthesizer S. The output received signal is amplified by the amplifier 31, and a signal component of an unnecessary frequency is attenuated by the filter 32. The amplifier 33 amplifies the received signal and outputs the amplified signal as an IF signal from the receiving unit 26. In addition, the amplifier 33 outputs the amplified reception signal from the reception unit 26 as a wireless communication sensitivity information signal (RSSI) signal that represents wireless communication sensitivity based on the signal strength.

  In the example shown in FIG. 5, the reception signal of the antenna main body 34 has a circuit configuration that lowers the frequency band of the IF signal in two stages. A circuit configuration may be adopted in which the received signal is lowered to the IF signal frequency band at one time. Thus, the circuit configuration of the receiving unit 26 is not limited to the circuit configuration example shown in FIG.

  During wireless communication, the antenna control unit 23 receives a wireless communication sensitivity information signal (RSSI) signal output from the above-described high frequency circuit 15 for wireless communication, and the time change of the wireless communication sensitivity information signal is wireless. While detecting the direction in which the communication sensitivity is increased, the current in the same direction is continuously supplied to the antenna driving motor 17. Further, when the antenna control unit 23 detects that the temporal change in the wireless communication sensitivity information signal is in a direction in which the wireless communication sensitivity is deteriorated during wireless communication, the antenna control unit 23 determines the direction of the energization current to the antenna driving motor 17. The rotation position of the antenna structure 4 is controlled so as to be reversed and to maintain a high wireless communication sensitivity of the antenna body.

  When the antenna housing circuit unit 22 detects that the card-type device 1 has received a wireless communication end signal from the information terminal device via the external connection means, the antenna storage circuit unit 22 supplies the power source power supplied via the power source input unit Vcc. Utilizing the circuit structure, the antenna driving motor 17 is energized with a current in the direction opposite to the current for raising the antenna structure. By driving the antenna driving motor 17 by the circuit operation of the antenna housing circuit section 22, the antenna structure 4 is rotated and displaced toward the housed state where the antenna structure 4 is lying down on the upper surface of the housing 3.

  The storage completion motor energization stop unit 24 outputs a motor energization stop signal toward the antenna storage circuit unit 22 when it is detected that the antenna structure 4 has been rotated and displaced to the set storage position as will be described later. The antenna housing circuit unit 22 has a configuration to stop current energization to the antenna driving motor 17 in response to the motor energization stop signal.

  FIG. 6 shows a specific example of the motor control circuit unit 20. In the circuit configuration of the motor control circuit unit 20 shown in FIG. 6, a comparison operation circuit 37 is provided. One input portion (37a) of the comparison operation circuit 37 is connected to a signal input portion P3 to which a wireless communication sensitivity information signal output from the high frequency circuit 15 for wireless communication is added. Further, another input portion 37 b of the comparison operation circuit 37 is connected to the signal input portion P 3 via the delay circuit 38. Further, the output section of the comparison operation circuit 37 is connected to one input section (39b) of the AND circuit 39. Another input section 39a of the AND circuit 39 is connected to the signal input section P2. A signal from an information terminal device such as a personal computer to which the card type device 1 is mounted is applied to the signal input unit P2. The output section of the AND circuit 39 is connected to the base of the NPN transistor element Tr1 and the base of the PNP transistor element Tr2. The output section of the AND circuit 39 is also connected to the base of the NPN transistor element Tr3 and the base of the PNP transistor element Tr4 via the NOT circuit 36.

  The emitter of the NPN transistor element Tr1 is connected to the emitter of the PNP transistor element Tr4 via the antenna driving motor 17. The emitter of the NPN transistor element Tr3 is connected to the emitter of the PNP transistor element Tr2 via the antenna driving motor 17. The collectors of the PNP transistor elements Tr2 and Tr4 are each grounded. Further, the collector of the NPN transistor element Tr1 and the collector of the NPN transistor element Tr3 are commonly connected to the collector of the PNP transistor element Tr0. The emitter of the PNP transistor element Tr0 is connected to the power input part Vcc, and the base of the PNP transistor element Tr0 is connected to the signal input part P1 through the resistor part R. The signal input unit P1 receives a signal different from the signal applied to the signal input unit P2 from an information terminal device such as a personal computer to which the card type device 1 is mounted.

  The motor control circuit unit 20 shown in FIG. 6 is configured as described above. The motor control circuit unit 20 performs circuit operations as follows. For example, the card-type device 1 is mounted on an information terminal device such as a personal computer but is not performing wireless communication and is waiting for wireless communication for the next wireless communication, and the antenna structure 4 is a housing. 3, the signal input unit P1 receives a high level (H) voltage level signal, and the signal input unit P2 receives no signal. The voltage level of the signal input part P2 is low level (L). Further, even during standby for wireless communication, the wireless communication sensitivity information signal is output from the high-frequency circuit 15 for wireless communication, and the wireless communication sensitivity signal is continuously supplied to the signal input unit P3. In this state, as shown in FIG. 7A, the base voltage level of the PNP transistor element Tr0 becomes H based on the voltage level H of the signal input part P1, so that the PNP transistor element Tr0 is switched off. For this reason, no current flows from the power input portion Vcc side to the antenna driving motor 17 side via the PNP transistor element Tr0.

  When the information terminal device starts wireless communication using the card type device 1, a wireless communication start signal is output from the information terminal device to the card type device 1. In the motor control circuit unit 20 of FIG. 6, based on the wireless communication start signal, as shown in FIG. 7B, the voltage level of the signal input unit P1 becomes L and the voltage level of the signal input unit P2 is H. It becomes the composition which becomes. At the start of wireless communication, the voltage level of the output signal of the comparison operation circuit 37 is set to be H. In such a state, the base voltage level of the PNP transistor element Tr0 is L based on the voltage level (L) of the signal input part P1, and the PNP transistor element Tr0 is switched on. Further, since the voltage level of both the input parts 39a and 39b of the AND circuit 39 is H, the voltage level of the output part of the AND circuit 39 is also H. Due to the voltage level H of the output part of the AND circuit 39, the voltage level of both the base of the NPN transistor element Tr1 and the base of the PNP transistor element Tr2 becomes H, and the NPN transistor element Tr1 is switched on. The PNP transistor element Tr2 is switched off. Further, the voltage level of the output part of the NOT circuit 36 becomes L based on the voltage level H of the output part of the AND circuit 39. Based on this voltage level L, both the base of the NPN type transistor element Tr3 and the base of the PNP type transistor element Tr4 have the voltage level L, whereby the NPN type transistor element Tr3 is switched off, and the PNP type transistor element Tr4 Is switched on. Therefore, when the wireless communication start signal is applied, the current based on the power source power applied to the power source input unit Vcc is changed to the PNP transistor element Tr0 and the NPN as shown in the current path I of FIG. A current is passed through the type transistor element Tr1, the antenna driving motor 17, and the PNP type transistor element Tr4 in this order. By energizing the antenna driving motor 17, the antenna driving motor 17 is driven to apply a rotating torque for raising the antenna structure to the rotating shaft 12. Thereby, the antenna structure 4 starts to be rotationally displaced in the standing direction.

  That is, in the motor control circuit unit 20 shown in FIG. 6, at the start of wireless communication, the PNP type transistor element Tr0, the NPN type transistor element Tr1, the antenna driving motor 17, and the PNP type transistor element Tr4 from the power input part Vcc side. The antenna standing-up circuit part (21) for causing the antenna driving motor 17 to pass the current for standing up the antenna structure and turning the antenna structure 4 in the standing direction by the circuit part through which the current is passed. Is configured.

  When the antenna structure 4 is rotationally displaced in the standing direction by energization of the antenna driving motor 17 as described above, for example, as shown in the graph of FIG. The wireless communication sensitivity increases with the passage of time.

  A wireless communication sensitivity information signal is added to the input unit 37a of the comparison operation circuit 37 via the signal input unit P3 every moment. The input unit 37b of the comparison operation circuit 37 has a time ΔT predetermined by the delay circuit 38. A radio communication sensitivity information signal that is delayed only by time is added every moment. The comparison operation circuit 37 is based on the wireless communication sensitivity information (signal strength) based on the wireless communication sensitivity information signal applied to the input unit 37a and the delayed wireless communication sensitivity information signal applied to the input unit 37b. The wireless communication sensitivity information (signal strength) is compared. Then, the comparison operation circuit 37 is higher when the wireless communication sensitivity obtained from the wireless communication sensitivity information signal of the input unit 37a is higher than the wireless communication sensitivity obtained from the delayed wireless communication sensitivity information signal of the input unit 37b (that is, wireless communication). When the sensitivity information signal temporally changes in the direction in which the wireless communication sensitivity increases, the H level voltage signal is continuously output. For this reason, for example, the period during which the wireless communication sensitivity is increased after the start of energization of the antenna driving motor 17 in response to the wireless communication start signal and the antenna structure 4 starts to be rotationally displaced in the standing direction is shown in FIG. The current continues to be supplied to the antenna driving motor 17 from the power input unit Vcc side through the same current path I as the current path I at the start of wireless communication as shown in FIG.

  Thereafter, for example, at the time T1 shown in FIG. 8, the wireless communication sensitivity obtained from the wireless communication sensitivity information signal of the input unit 37a of the comparison operation circuit 37 is the time T applied to the input unit 37b of the comparison operation circuit 37. It is worse than the wireless communication sensitivity obtained from the wireless communication sensitivity information signal of '(T' = T1-ΔT). In other words, the temporal change of the wireless communication sensitivity information signal is in the direction of worsening the wireless communication sensitivity. At this time, the comparison operation circuit 37 outputs an L level voltage signal.

  As a result, the voltage level of the input section 39b of the AND circuit 39 becomes L based on the L level voltage signal output from the comparison operation circuit 37, and as shown in FIG. 7C, the output section of the AND circuit 39. The voltage level of L becomes L. Therefore, the voltage level of the base of the NPN transistor element Tr1 and the base of the PNP transistor element Tr2 is L, the NPN transistor element Tr1 is switched off, and the PNP transistor element Tr2 is switched on. . Further, the voltage level L of the output part of the NOT circuit 36 becomes H due to the voltage level L of the output part of the AND circuit 39, whereby the voltage level of the base of the NPN transistor element Tr3 and the base of the PNP transistor element Tr4 are H levels. Thus, the NPN transistor element Tr3 is switched on and the PNP transistor element Tr4 is switched off. Therefore, the current based on the power supply power applied to the power supply input section Vcc is, as shown in the current path I ′ of FIG. 7C, the PNP transistor element Tr0, the NPN transistor element Tr3, and the antenna driving The antenna driving motor 17 is energized through a path that passes through the motor 17 and the PNP transistor element Tr2 in order. That is, a current in the direction opposite to the current path I in FIG. Thereby, the antenna driving motor 17 is rotationally driven in a direction opposite to that at the start of wireless communication, and the antenna structure 4 is rotationally displaced in a direction opposite to the standing direction at the start of wireless communication.

  Thereafter, for example, at time T2 in FIG. 8, the wireless communication sensitivity obtained from the wireless communication sensitivity information signal of the input unit 37a of the comparison operation circuit 37 is determined from the delayed wireless communication sensitivity information signal of the input unit 37b of the comparison operation circuit 37. It is higher than the obtained wireless communication sensitivity. That is, the time change of the wireless communication sensitivity information signal is in the direction of increasing the wireless communication sensitivity. At this point, the comparison operation circuit 37 outputs an H level voltage signal. As a result, the voltage levels of both the input portions 39a and 39b of the AND circuit 39 become H, and the voltage level of the output portion of the AND circuit 39 becomes H. Therefore, in the state shown in FIG. 7B described above, a current is passed through the antenna driving motor 17 through the current path I. As a result, the antenna driving motor 17 is rotationally driven in the same direction as when wireless communication is started, and the antenna structure 4 is rotationally displaced in the same direction as the standing direction when wireless communication is started.

  As described above, in the motor control circuit unit 20, current is continuously supplied to the antenna driving motor 17 during wireless communication, and the current supplied to the antenna driving motor 17 based on the wireless communication sensitivity information signal is supplied. By controlling the direction, the rotational position of the antenna structure 4 is controlled so as to maintain a high wireless communication sensitivity state. That is, in the circuit shown in FIG. 6, the transistor elements Tr0, Tr1, Tr2, Tr3, Tr4, the NOT circuit 36, the comparison operation circuit 37, the delay circuit 38, and the AND circuit 39 are used for wireless communication sensitivity information. An antenna control unit (23) that receives the signal and controls the rotation position of the antenna structure 4 is configured to maintain a high wireless communication sensitivity based on a temporal change of the wireless communication sensitivity information signal. .

  When the information terminal device performing wireless communication by the card type device 1 ends the wireless communication, a wireless communication end signal is added from the information terminal device. In the motor control circuit unit 20, the voltage levels of the signal input units P1 and P2 are both L based on the wireless communication end signal. As a result, the PNP transistor element Tr0 is in the switch-on state, and the voltage level of the input part 39a of the AND circuit 39 is L, so that the voltage level of the output part of the AND circuit 39 is L. As a result, the NPN transistor element Tr1 is switched off, the PNP transistor element Tr2 is switched on, the NPN transistor element Tr3 is switched on, and the PNP transistor element Tr4 is switched off. For this reason, the antenna drive motor 17 is energized through a current path I ′ as shown in FIG. That is, the antenna drive motor 17 is energized with a current in a direction opposite to the current for raising the antenna structure. As a result, the antenna driving motor 17 is rotationally driven in the direction opposite to that at the start of the wireless communication, and gives a rotational torque for housing the antenna structure to the rotating shaft 12 of the antenna structure 4. Thereby, the antenna structure 4 starts to be rotationally displaced in the storage direction.

  That is, in the motor control circuit unit 20 shown in FIG. 6, a current is supplied in order from the power input unit Vcc side through the PNP transistor element Tr0, the NPN transistor element Tr3, the antenna driving motor 17, and the PNP transistor element Tr2. The antenna housing circuit portion (in which the antenna driving motor 17 is rotated and displaced in the direction in which the antenna structure 4 is stowed down by energizing the antenna driving motor 17 with a current in a direction opposite to the current for raising the antenna structure body). 22) is configured.

  For example, when a predetermined antenna storage completion time has elapsed since the wireless communication end signal was output, the voltage level of the signal applied to the signal input unit P1 is changed from L as shown in FIG. The configuration is switched to H. Note that the antenna housing completion time is, for example, the antenna structure 4 is tilted with respect to the upper surface of the housing 3 after receiving the wireless communication end signal and starting the rotational displacement of the antenna structure 4 in the housing direction. This is the time required to reach the storage state, and is a time determined in advance by experiments, simulations, and the like.

  A signal of voltage level H from the signal input part P1 is applied to the base of the PNP transistor element Tr0 as a motor energization stop signal, and the PNP transistor element Tr0 is switched off. As a result, the current supply from the power input portion Vcc side to the antenna drive motor 17 via the PNP transistor element Tr0 is stopped, and the rotation drive of the antenna drive motor 17 is stopped. That is, in the motor control circuit unit 20 of FIG. 6, when the signal input unit P2 detects that the housing of the antenna structure 4 is completed, the housing completion motor that stops the current supply to the antenna driving motor 17 is stopped. An energization stop unit is configured.

  The card type apparatus 1 of the first embodiment is configured as described above. With such a configuration, the antenna structure 4 can be automatically erected when starting wireless communication, and the antenna structure 4 can be automatically tilted and stored when wireless communication is terminated. Can improve usability. In addition, during wireless communication, the rotation position of the antenna structure 4 is controlled by controlling the direction of the energization current to the antenna driving motor 17 in order to maintain a state of high wireless communication sensitivity. Thus, the reliability of the card-type device 1 for wireless communication can be improved.

  In addition, this invention is not limited to the form of this embodiment, Various embodiment can be taken. For example, in the motor control circuit unit 20 shown in FIG. 6, when the wireless communication is ended, the energization current to the antenna driving motor 17 is passed when the set storage completion time has elapsed after the wireless communication end signal is output. However, for example, a means for detecting the completion of housing of the antenna structure 4 as shown below is provided, and the antenna is driven when it is detected that the housing of the antenna structure 4 is completed by the means. The energization current to the motor 17 may be stopped. For example, when the antenna structure 4 falls to the upper surface of the housing 3 due to the rotational displacement of the antenna structure 4 in the housing direction, the antenna structure 4 engages with the upper surface of the housing 3 and rotates. The dynamic displacement cannot be continued. As a result, the load on the antenna driving motor 17 increases, the power consumption of the antenna driving motor 17 changes, and the amount of current in the antenna driving motor 17 increases. From this, for example, the amount of current flowing to the antenna drive motor 17 is detected, and it is detected that the detected current amount has increased beyond the threshold value for detecting the completion of antenna storage obtained in advance through experiments or the like. Means for detecting that the housing of the antenna structure 4 has been completed. On the basis of the detection operation of this means, the energization current to the antenna driving motor 17 in the storing direction of the antenna structure 4 by the antenna storing circuit unit may be stopped.

  In this embodiment, the current is continuously supplied to the antenna driving motor 17 while wireless communication is performed. For example, wireless communication is performed within the same wireless communication period. In the case where it is assumed that the direction in which the sensitivity increases is not substantially changed, the antenna structure 4 is controlled by the control operation of the antenna control unit after the antenna structure 4 starts to be displaced in the upright direction in response to the wireless communication start signal. A time Tst until it is assumed that the standing position is almost stabilized is obtained by experiment or simulation and set. And it is also possible to measure the time from the start of the rotational displacement of the antenna structure 4 in the standing direction, and to stop the current supply to the antenna driving motor 17 when the measurement time reaches the time Tst. Good. In this case, means are provided for stopping and maintaining the antenna structure 4 at the position when the current supply to the antenna driving motor 17 is stopped.

  In addition, during wireless communication, current is intermittently supplied to the antenna driving motor 17, and the antenna control unit performs the antenna structure 4 during the intermittent current supply period to the antenna driving motor 17. It is good also as a structure which controls a rotation position. In this case as well, every time the supply of current to the antenna driving motor 17 is stopped, a means for stopping and maintaining the antenna structure 4 at that position is taken.

  Furthermore, in the configuration example of the motor control circuit unit 20 shown in FIG. 6, the comparison operation circuit 37 and the delay circuit 38 are used to obtain temporal changes in the wireless communication sensitivity information signal. Instead of the circuits 37 and 38, a differential circuit may be provided to obtain a temporal change in the wireless communication sensitivity information signal.

  Furthermore, in this embodiment example, the antenna structure 4 can be rotated and displaced within an angle range of about 180 °. For example, the antenna structure 4 can be rotated in the standing direction from the storage position of the antenna structure 4. When the angular range for setting the rotational displacement of the antenna structure 4 is narrower than 180 °, such as the angle range up to the final displacement position is set to about 135 °, the antenna structure 4 is determined in advance. A stopper may be provided that stops the rotational displacement of the antenna structure 4 in the standing direction when it is pivoted to the final position of the set rotational displacement in the standing direction. For example, as shown in the schematic cross-sectional view of FIG. 10, a protruding wall 5 </ b> A as a stopper may be provided on the insertion rear end side of the housing 3 of the card type device 1.

  Furthermore, in this embodiment example, the antenna structure 4 is in the stowed state in which the antenna structure 4 is lying down on the upper surface of the housing 3. For example, as shown in the dotted line of the schematic cross-sectional view of FIG. 11. It is good also considering the state which has fallen on the back as a storage state.

  Further, in this embodiment, the antenna structure 4 has a substantially U-shape. However, for example, the antenna structure 4 may have a shape as shown in FIG. 12A or as shown in FIG. The shape of the antenna structure 4 is not particularly limited. In addition, the feeding shaft 11 and the rotating shaft 12 of the antenna structure 4 shown in FIGS. 12A and 12B are arranged with their central axes on the same straight line. In the example of FIG. 12B, the housing 3 is provided with an antenna structure holding portion 19 as indicated by a dotted line for holding the antenna structure 4 on the housing 3.

  Further, the card-type device 1 may be provided with a rotational torque amplification transmission unit that amplifies the rotational torque from the antenna driving motor 17 and transmits the amplified rotational torque to the rotating shaft 12. Thus, by providing the rotational torque amplification transmission unit, a much smaller motor can be provided as the antenna driving motor 17.

  Furthermore, in this embodiment, the antenna structure 4 is erected at the start of wireless communication, and the rotational position of the antenna structure 4 is controlled so that the communication sensitivity is optimal during wireless communication. An example in which the structural body 4 is accommodated will be described, and the antenna structural body 4 is in the accommodated state during standby for wireless communication in preparation for the next wireless communication. On the other hand, for example, when the card-type device 1 is mounted on the information terminal device and power is input and the card-type device 1 is turned on, the card-type device 1 sends the supplied power to the wireless communication start signal. The antenna structure 4 is raised and the wireless communication sensitivity is maintained not only during the wireless communication but also during the wireless communication standby until the power supply from the information terminal device to the card type device 1 is stopped. It is good also as a structure which controls the rotation position of the antenna structure 4 so that is optimal. In this case, for example, the power supply stop from the information terminal device to the card type device 1 is received as a wireless communication end signal, and the antenna structure 4 is accommodated.

  Further, for example, when the information terminal device checks the sensitivity of wireless communication at a time other than the period during which wireless communication is performed, a wireless communication sensitivity check start signal output from the information terminal device to the card type device 1 The mold apparatus 1 may receive the radio communication start signal and erect the antenna structure 4. Then, after checking whether the radio wave state is appropriate for wireless communication, or if the radio wave state is capable of performing wireless communication, after checking the direction of the optimum wireless communication sensitivity, from the information terminal device The wireless communication sensitivity check end signal output toward the card-type device 1 may be received by the card-type device 1 as a wireless communication end signal to accommodate the antenna structure 4. In this way, even when wireless communication is not performed, the card-type device 1 may stand the antenna structure 4 or store the antenna structure 4 based on a signal from the information terminal device. Further, for example, the card-type device 1 receives the wireless communication start signal output from the information terminal device to the card-type device to start the wireless communication, and erects the antenna structure 4. In some cases, the information terminal device determines that wireless communication is not performed by determining that only wireless communication sensitivity inappropriate for wireless communication can be obtained in spite of having been set. In such a case, when a signal indicating that wireless communication is not performed from the information terminal device to the card type device 1 is output, the card type device 1 receives the signal as a wireless communication end signal and receives the antenna structure 4. It is good also as a structure which accommodates.

It is a figure for demonstrating one embodiment of the card-type apparatus which concerns on this invention. It is a typical exploded view of the card type device of FIG. It is a figure for demonstrating the example of rotation displacement of the antenna structure of the card-type apparatus shown by FIG. It is a block block diagram for demonstrating the example of a circuit structure for performing drive control of the motor for antenna drive provided in the card-type apparatus of FIG. It is a figure for demonstrating the circuit structural example of the receiving part of the high frequency circuit for radio | wireless communication provided in a card type apparatus. It is a circuit diagram showing the specific example of the circuit structure for performing drive control of the motor for antenna drive. FIG. 7 is a diagram for explaining a circuit operation example of the circuit of FIG. 6. It is the graph showing an example of the time change of the radio | wireless communication sensitivity by rotation control of an antenna structure. FIG. 7 is a diagram for explaining an example of the circuit operation of the circuit of FIG. 6 together with FIG. 7. It is a figure for demonstrating other example embodiments. It is a figure for demonstrating another example of another embodiment. It is a figure for demonstrating the other example of a form of an antenna structure. It is a model figure for demonstrating the example of 1 form of a card-type apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Card type apparatus 2 Circuit board 3 Housing | casing 4 Antenna structure 11 Feeding shaft 12 Rotating shaft 21 Antenna standing-up circuit part 22 Antenna storage circuit part 23 Antenna control part 24 Storage completion motor energization stop part

Claims (2)

In a card type device with a wireless communication function in which a circuit board having a high-frequency circuit for wireless communication is housed in a flat housing,
An antenna structure provided with an antenna body for performing radio communication of radio waves and disposed outside the housing;
A feeding shaft for electrically connecting the antenna main body of the antenna structure projectingly formed on the antenna structure to a high-frequency circuit for wireless communication on a circuit board in the housing;
Separately from the feeding shaft, the antenna structure is formed so as to protrude from the stowed state in which the antenna structure is tilted with respect to the upper surface of the housing and to the standing state and vice versa. A pivot shaft that pivots and displaces,
An antenna driving motor that applies rotational torque to the rotational shaft to rotationally displace the antenna structure;
An antenna standing-up circuit unit that receives a wireless communication start signal and energizes the antenna driving motor with a current for raising the antenna structure to rotate and displace the antenna structure in the standing direction;
While receiving a wireless communication sensitivity information signal output from a high frequency circuit for wireless communication and detecting that a temporal change in the wireless communication sensitivity information signal is a direction in which the wireless communication sensitivity increases, the current in the same direction When the antenna drive motor continues to be energized, and it is detected that the temporal change in the wireless communication sensitivity information signal is in the direction of worsening the wireless communication sensitivity, the direction of the energization current to the antenna drive motor is reversed and the antenna is reversed. An antenna control unit for controlling the rotation position of the antenna structure so that the wireless communication sensitivity of the main body is maintained at a high level;
An antenna storage circuit unit that receives a radio communication end signal and applies a current in a direction opposite to the current for standing up the antenna structure to the antenna drive motor to rotate and displace the antenna structure in a retracted direction; ,
A card-type device characterized in that a card-type device is provided. Means for detecting completion of housing of the antenna structure during energization in the antenna housing direction to the antenna driving motor by the antenna housing circuit unit;
A storage completion motor energization stop unit for stopping current energization to the antenna drive motor when it is detected that the antenna structure has been stored;
The card-type device according to claim 1, wherein the card-type device is provided.

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