JPH0534708U - Signal input / output device - Google Patents

Abstract

(57) [Abstract] [Purpose] A signal input / output device that communicates with a ferrite antenna having directivity, capable of covering a range where communication has been impossible up to now, and performing communication independent of directionality. To be able to [Structure] An antenna unit 1 in which a plurality of ferrite antennas are arranged at a constant angle is connected to an antenna control unit 2. The antenna control means 2 selects only one of the plurality of ferrite antennas based on the antenna control signal from the antenna control signal generation circuit 9. The selected antenna is connected to the transmission / reception switching circuit 10. The antenna that is not selected performs antenna resonance point conversion processing such as short-circuiting both ends of the antenna or adjusting the capacitor forming the resonance point of the antenna.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a signal input / output device that performs contactless input / output of signals by electromagnetic coupling.

[0002]

[Prior Art]

 FIG. 9 shows the arrangement of antennas of a signal input / output device having a conventional ferrite antenna. To improve the directivity of a ferrite antenna, an L-shaped antenna formed of a high-permeability material and a low-permeability antenna in which its core is joined in an L-shape, which are arranged orthogonally to the X-axis direction and the Y-axis direction. One antenna was used, or one antenna was composed of a ferrite antenna and a rod antenna standing vertically to the ferrite antenna.

For example, it is disclosed in JP-A-63-171016 and JP-A-62-24705.

[0004]

[Problems to be solved by the device]

 However, in the conventional configuration as shown above, in the case of the L-type antenna, the directivity is improved only for the X and Y axis direction components, but is not improved for the Z axis direction. Also, an antenna that combines a ferrite antenna and a rod antenna has a problem that the characteristics of the ferrite antenna do not improve in all X, Y, and Z axis directions even if the directivity is improved. I had.

Further, the ferrite antenna has a drawback that the characteristics of the antenna change when the antennas having the same resonance frequency are brought close to each other. 4 to 7 show impedance characteristic diagrams of the ferrite antenna. 4 and 5 show impedance characteristics with respect to the frequencies of the antenna and B, respectively, and the antennas A and B have the same resonance frequency. Here, when the antenna A and the antenna B are brought close to each other, the impedance characteristics of the antennas A and B become the characteristics shown in FIGS. 6 and 7, respectively. Due to the impedance characteristics shown in FIGS. 6 and 7, the resonance frequency characteristics of the ferrite antenna are changed and the sharpness Q is lowered, so that the original performance cannot be exhibited.

Therefore, generally, the ferrite antenna has a problem that it has to be used alone or arranged at a distance that does not affect each other. Therefore, an object of the present invention is to provide a signal bar input / output device using a ferrite bar antenna, which has a ferrite bar antenna that exhibits uniform performance in all of the X, Y, and Z-axis directions regardless of directivity. To obtain a signal input / output device.

[0007]

[Means for Solving the Problems]

 Therefore, in order to solve the above-mentioned problems, in the present invention, an antenna section in which a plurality of independent ferrite bar antennas having the same resonance frequency are arranged so as to form a constant angle with each other and a resonance point conversion process of the antenna are performed. By providing the antenna control means to perform the signal transmission, one antenna is configured to be optimal when transmitting or receiving a signal.For the antennas not selected, both ends of the antenna are short-circuited or the resonance of the antenna is By changing the resonance point of the antenna, such as adjusting the capacitor forming the point, the characteristics of the selected ferrite antenna are changed to prevent the phenomenon of communication failure.

[0008]

[Action]

 According to the above configuration, by providing the antenna control means, one antenna that is most suitable for communication is selected from among a plurality of antennas when transmitting or receiving a signal. For antennas that are not selected, antenna resonance point conversion processing is performed, such as short-circuiting both ends of the antenna or adjusting the capacitor that forms the antenna resonance point. Even if a ferrite antenna having the same resonance frequency is brought close to it, as shown in the impedance characteristic diagrams of the antennas in FIGS. 6 and 7, the ferrite antennas are not affected by each other, and the ferrite antennas exhibit the original performance. You will be able to do it.

Therefore, a signal input / output device that performs communication with a ferrite antenna having directivity can cover a range where communication cannot be performed up to now. In addition, this makes it possible to perform communication regardless of the directionality.

[0010]

【Example】

 Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of this embodiment. In the antenna unit 1, a plurality of ferrite antennas are arranged so as to form a constant angle with each other, and are connected to the antenna control means 2.

FIG. 8 is a perspective view of an antenna arrangement according to an embodiment of the present invention. The three ferrite antennas A23, the ferrite antenna B24, and the ferrite antenna C25 are arranged so as to form an angle of 90 degrees with each other at a certain distance. The directions of the antennas are the X-axis direction, the Y-axis direction, and the Z-axis direction, respectively. The angle between the antennas may be 45 degrees or more depending on the number and characteristics of the antennas.

The antenna control means 2 selects only one of the plurality of ferrite antennas based on the antenna control signal from the antenna control signal generation circuit 9 and connects the selected antenna and the transmission / reception switching circuit 10. To do. Furthermore, for unselected antennas, antenna resonance point conversion processing such as short-circuiting both ends of the antenna and adjusting the capacitor forming the antenna resonance point is performed.

The transmission / reception switching circuit 10 inputs the transmission / reception switching signal from the control circuit 16, and selects the antenna selected by the antenna control means 2 based on the signal and the transmission signal creation circuit 12 or the reception signal conversion circuit. The circuit 13 is connected. The antenna control signal generation circuit 9 inputs the antenna switching signal from the control means 16 and outputs the antenna control signal to the antenna control means 2 based on the signal.

The transmission signal generation circuit 12 receives the transmission signal output of the carrier frequency transmission circuit 11, puts the transmission data from the control circuit 16 on the carrier frequency, and transmits the signal to another communication medium through the selected antenna. Send. The carrier frequency transmitting circuit 11 creates a carrier frequency required for transmission and outputs it to the transmission signal creating circuit 12.

The reception signal conversion circuit 13 inputs a transmission signal of another communication medium through the selected antenna, amplifies and detects the input signal, performs analog / digital conversion, and compares the result with a comparison operation. Output to the circuit 14. The comparison operation circuit 14 receives the reception data converted into the digital signal from the reception signal conversion circuit 13, calls the comparison target information from the memory, performs the comparison operation, outputs the comparison operation result to the control circuit 16, and receives the reception operation. The signal is stored in the memory 15. Further, the comparison operation circuit 14 outputs a reception end signal to the timer circuit 18. The switch circuit 17 outputs a communication start signal to the control circuit 16.

The timer circuit 18 inputs the transmission end signal from the control circuit 16, and the reply signal waiting time timer from another communication medium is set by this signal, and when the time is up, the time-up signal is sent to the control circuit 16. Is output. Further, the timer circuit 18 inputs the reception end signal from the comparison arithmetic circuit 14, and resets the reply signal waiting time timer from another communication medium by this signal.

The control circuit 16 inputs the communication start signal from the switch circuit 17, the time-up signal from the timer circuit 18, and the comparison calculation result from the comparison calculation circuit 14, and the antenna control signal generation circuit 9 receives an antenna. A switching signal is output, an antenna is selected, and a transmission / reception switching signal is output to the transmission / reception switching circuit 10. Further, the control circuit 16 reads out the transmission data information to be transmitted to another communication medium from the memory 15, outputs the transmission data in parallel to the transmission signal generating circuit 12, and outputs the transmission end signal to the timer circuit 18.

The operation of this embodiment will be briefly described below. The control circuit 16 outputs an antenna switching signal to the antenna control signal generation circuit 9 based on the communication start signal from the switch circuit 17, selects an antenna to be used, and sends a transmission / reception switching signal to the transmission / reception switching circuit 10. Is output and the transmission status is set.

Here, the antenna not selected by the antenna control means 2 is subjected to antenna resonance point conversion processing such as short-circuiting both ends of the antenna or adjusting the capacitor forming the resonance point of the antenna. Further, the control circuit 16 reads out the transmission data information from the memory 15 and outputs the transmission data to the transmission signal generating circuit 12 in parallel.

The transmission signal creation circuit 12 puts the transmission data sent from the control circuit 16 in parallel on the carrier frequency, and sends the signal to another communication medium through the selected antenna. Further, the control circuit 16 outputs a transmission end signal to the timer circuit 18 after setting the output of the transmission data, sets the timer circuit 18, and again outputs the transmission / reception switching signal to the transmission / reception switching circuit 10 to put it in the receiving state. ..

Here, when a reply signal from another communication medium is input, the comparison operation circuit 14 outputs a reception end signal to the timer circuit 18 and resets the timer circuit 18. If the comparison calculation result from the comparison calculation circuit 14 is not correct, the control circuit 16 outputs an antenna switching signal to the antenna control signal generation circuit 9 to switch the antenna. Alternatively, if the received signal is not input, the comparison operation circuit 14 does not reset the timer circuit 18, so the control circuit 16 receives the time-up signal of the timer circuit 18 and outputs the antenna switching signal to the antenna control signal generation circuit 9. Switch the antenna and output the transmission data to another communication medium again.

If the comparison calculation result from the comparison calculation circuit 14 is correct, the control circuit 16 does not switch the antenna, the selected antenna is fixed, and the subsequent communication is performed. By performing the above operation at the initial stage of communication, it is possible to select the antenna most suitable for communication with other communication media and perform communication. FIG. 2 is a detailed circuit diagram of an embodiment of the present invention of the antenna unit 1 and the antenna selection means 2 of FIG. 1 using the resonance point conversion processing for short-circuiting both ends of the antenna.

The antennas A3, B4 and C5 having the same resonance frequency are arranged so as to form a constant angle with each other. The antenna A3, antenna B4, and antenna C5 are connected to an antenna A control circuit 6, an antenna B control circuit 7, and an antenna C control circuit 8, respectively. The antenna control means 2 is composed of a switch, and is conductive when the switch control signal is at "H" level and non-conductive when it is at "L" level.

Therefore, in the antenna control circuit, when the antenna control signal from the antenna control signal generation circuit is the “H” level signal, the switch on the side of the transmission / reception switching circuit 10 becomes conductive, and the antenna transmits / receives the switching circuit 10. The switch connected to the GND side is non-conductive because the control signal is inverted through the inverter. When the antenna control signal is the "L" level signal, the antenna control circuit turns on the switch on the transmission / reception switching circuit 10 side, and the switch connected on the GND side turns on because the control signal is inverted through the inverter. The antenna is connected to GND, and both ends of the antenna are short-circuited. By short-circuiting both ends of the antenna, the resonance point conversion process is performed, and the ferrite antenna loses its resonance characteristics and does not adversely affect the selected antenna.

Table 1 shows the control states of the antenna control means.

[0026]

[Table 1]

FIG. 3 is a detailed circuit diagram of the present embodiment of the antenna unit 1 and the antenna control means 2 of FIG. 1 using the frequency conversion process using the adjustment of the capacitor forming the resonance point of the antenna. By performing the same control as described in the circuit diagram of FIG. 2, the selected antenna is connected to the transmission / reception switching circuit 10, and the unselected antenna is further connected to the capacitor forming the resonance point. The addition of the capacitor significantly changes the resonance point of the antenna and does not adversely affect the controlled antenna.

By performing the above control, the antenna control circuit of the plurality of antennas always selects only one antenna and the other antennas perform the resonance point conversion processing.

[0029]

[Effect of the device]

 As described above, the signal input / output device of the present invention can be used when the plurality of ferrite antennas are arranged close to each other, and the ferrite antennas can be used without affecting each other. Each property can be used effectively. Therefore, it became possible to have a wide communication area that could not be realized with conventional ferrite antennas, and it became possible to carry out communication that was not affected by directionality.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention.

FIG. 2 is a circuit diagram of an embodiment of the present invention in which both ends of the antenna are short-circuited.

FIG. 3 is a circuit diagram of an embodiment of adjusting a capacitor according to the present invention.

4 is an impedance characteristic diagram of antenna A. FIG.

5 is an impedance characteristic diagram of antenna B. FIG.

FIG. 6 is an impedance characteristic diagram of the antenna A when the antennas A and B are brought close to each other.

FIG. 7 is an impedance characteristic diagram of the antenna B when the antennas A and B are brought close to each other.

FIG. 8 is a perspective view of an embodiment of the arrangement of the antenna of the present invention.

FIG. 9 is a perspective view showing the arrangement of a conventional antenna.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 antenna part 2 antenna control means 3 antenna A 4 antenna B 5 antenna C 6 antenna A control circuit 7 antenna B control circuit 8 antenna C control circuit 9 antenna control signal generation circuit 10 transmission / reception switching circuit 11 carrier frequency transmission circuit 12 transmission Signal generation circuit 13 Received signal conversion circuit 14 Comparison arithmetic circuit 15 Memory 16 Control circuit 17 Switch circuit 18 Timer circuit 20 Antenna A control circuit 21 Antenna B control circuit 22 Antenna C control circuit 23 Antenna A 24 Antenna B 25 Antenna C

Claims (1)

[Scope of utility model registration request] 1. An antenna unit comprising a plurality of ferrite antennas arranged so as to form a constant angle with each other, and connecting to the plurality of ferrite antennas, selecting only one of the ferrite antennas, and not selecting a ferrite A signal input / output device comprising an antenna control means for performing a resonance point conversion process of an antenna.