JPH0817366B2 - Wireless communication system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial field of application) The present invention is a question that allows a question control unit to confirm whether or not a question signal transmitted from an inquiry apparatus is correctly received and demodulated by a response apparatus. The present invention relates to a wireless communication system comprising a device and a response device which takes in the inquiry signal in response control means when the inquiry signal can be correctly received and demodulated.

(Prior Art) In recent years, a response device is carried by a person or attached to a moving object, and appropriate information etc. of a person carrying the device or an attached moving object is stored in advance in this response device, and the question is fixed. The device transmits an interrogation signal to the responding device by microwave, and the responding device that receives the interrogation signal sends an appropriate response signal to the interrogating device by microwave, or rewrites information,
The interrogation device that has received the response signal has proposed a system for identifying a person or a moving object by collating the response signal. The personal information stored in the response device enables the response device to function as an ID card or the like. Also,
At a manufacturing plant that performs high-mix low-volume production, a response device that stores the specification data of semi-finished products on the production line is attached, and the inquiry device that is fixed in each process inquires the response device for the specifications. Responsive devices may function as electronic specification instructions if the work is to be done or new specifications are stored.

A communication system having such an inquiry device and a response device,
It is disclosed in JP-A-56-140486.

(Problems to be Solved by the Invention) In a communication system having the above-described conventional interrogation device and response device, the response device is caused by a cause of propagation of an interrogation signal such as fading or a cause of external noise. May receive the interrogation signal in error. And
If a response signal corresponding to the erroneous inquiry signal is transmitted from the answering device to the inquiry device, there is a possibility that a person is erroneously identified or erroneous work is performed. Further, when the information of the response device is rewritten by the wrong question signal, there is a possibility that the wrong answer signal may be output even for the proper question signal received thereafter.

The present invention has been made in view of the circumstances in the above-described conventional communication system, and the inquiry control unit can confirm whether or not the inquiry signal is correctly received and demodulated by the response device,
It is an object of the present invention to provide a wireless communication system composed of an interrogation device and a response device in which only the interrogation signal accurately received and demodulated is taken into the response control means.

(Means for Solving the Problem) In order to achieve such an object, the wireless communication system of the present invention is different from the energy transmitting means for transmitting the energy wave of the first frequency without modulation and the first frequency. An interrogation transmitting means for transmitting an interrogation signal wave in which a carrier wave of the second frequency is modulated by an interrogation signal or a use permission signal, and a response signal by receiving a response signal wave having the second harmonic wave of the first frequency as a carrier wave. And a response receiving means for demodulating the interrogation signal, and comparing the contents of the interrogation signal and the demodulated response signal, and if all bits match, output the use permission signal following the interrogation signal. An interrogation device including interrogation control means, interrogation reception means for receiving the interrogation signal wave and demodulating the interrogation signal or the use permission signal, and a buffer memory for the demodulated interrogation signal. And a response control means for storing the energy wave and outputting the response signal as it is as the response signal, and when the use permission signal is demodulated, the inquiry signal stored in the buffer memory is taken in and the second harmonic thereof is received. And a response transmitting unit that transmits a response signal wave that is modulated by the response signal using the wave as a carrier wave.

Then, if the contents of the inquiry signal and the demodulated response signal do not match in all bits, the inquiry signal may be output again.

Further, the interrogation control means outputs the interrogation signal bit by bit, compares the content with the demodulated response signal bit by bit, and outputs the next bit interrogation signal if they match. , If the contents of each bit do not match, the inquiry signal can be output again from the first bit.

(Operation) In the response device, since the second harmonic of the received energy wave is used as a carrier and the demodulated interrogation signal is used as a response signal to transmit the response signal wave which is obtained by modulating the carrier wave, the response signal wave is transmitted. The structure is simple, and the response signal wave is transmitted almost simultaneously with the demodulation of the interrogation signal.
In the interrogator, the transmitted interrogation signal is immediately received and demodulated as a response signal, and the interrogation signal and the demodulated response signal are compared in real time without any time delay.

If the contents of the interrogation signal and the demodulated response signal do not match in all bits, if the interrogation signal is output again, the interrogation signal is output repeatedly until the correct contents are transmitted and received, ensuring reliable communication. can get. Since the transmission of the inquiry signal and the response signal demodulated almost at the same time are compared here, the time until the retransmission of the inquiry signal can be extremely short, and reliable wireless communication can be achieved in that short time. .

In addition, if the inquiry signal is output bit by bit and compared with the demodulated response signal, and if they do not match, if the inquiry signal is transmitted again from the first bit, it is wasteful after the time when accurate wireless communication is not performed. Sending can be omitted.

(Embodiment) An embodiment of the present invention will be described below with reference to FIGS. 1 to 3. FIG. 1 is a block circuit diagram showing an embodiment of a wireless communication system comprising an interrogation device and a response device of the present invention, and FIG. 2 is a flowchart explaining an example of the operation of the interrogation device of FIG. FIG. 3 is a flow chart for explaining the operation of the response device of FIG.

First, in FIG. 1, the inquiry device 1, different first oscillation circuit 2, the first frequency f ₁ and slightly frequency for oscillating a first frequency f ₁ of the microwave band (e.g. 2440MH _z) a second oscillator circuit 3 for oscillating a second frequency f ₂ (e.g. 2455MH _z) is provided. Then, the first frequency f ₁ output from the first oscillation circuit 2 is amplified by the amplifier 4 and transmitted as it is unmodulated from the antenna 5 to the response device 6 as an energy wave in a vertically polarized wave, for example. It Also, the second
The second frequency f ₂ output from the oscillator circuit 3 is a question signal output from the microprocessor 8 in the modulation circuit 7.
The signal is A1 modulated, further amplified by the amplifier 9, and transmitted from the antenna 10 to the response device 6 as an interrogation signal wave with horizontal polarization. Further, the interrogation apparatus 1 is provided with an antenna 11 that receives a response signal wave having the second harmonic wave 2f ₁ of the first frequency f ₁ transmitted from the response apparatus 6 as a carrier. A response signal is demodulated from the response signal wave received by the antenna 11 through the bandpass filter 12, the low noise block down converter 13 and the detection circuit 14. The demodulated response signal is input to the microprocessor 8 and the comparison circuit 15. The comparison circuit 15 also receives the interrogation signal output from the microprocessor 8, and when the interrogation signal and the response signal match at the end of transmission of the interrogation signal, the coincidence signal is sent to the microprocessor 8. give. Then, when the coincidence signal is given, the microprocessor 8 outputs a use permission signal to the modulation circuit 7, and this use permission signal is transmitted from the antenna 10 to the response device 6. The first oscillation circuit 2, the amplifier 4 and the antenna 5 constitute energy transmission means, the second oscillation circuit 3, the modulation circuit 7, the amplifier 9 and the antenna 10 constitute question transmission means, and the antenna 11 and the band. The pass filter 12, the low noise block down converter 13 and the detection circuit 14 constitute a response receiving means, and the microprocessor 8 and the comparison circuit 15 constitute an inquiry control means.

The response device 6 is provided with an antenna 16 for receiving the energy wave transmitted from the antenna 5, the energy wave received by the antenna 16 is rectified by a rectifying and multiplying circuit 17, and output as DC power through a low-pass filter 18. To be done. Further, a harmonic is generated as the energy wave is rectified by the rectifying and multiplying circuit 17, but the second harmonic 2f ₁ thereof is extracted by the bandpass filter 19 and is transmitted to the modulating circuit 20 as a carrier wave of the response signal wave. Given as. Then, the response device 6 has an antenna 21 that receives the interrogation signal wave transmitted from the antenna 10.
Is provided, and the interrogation signal is demodulated from the interrogation signal wave received by the antenna 21 through the detection circuit 22, the high-pass filter 23, and the amplifier 24. The demodulated interrogation signal is input to and stored in the buffer memory 25, is also applied to the microprocessor 26, and is also applied to one connection terminal of the changeover switch 27. Furthermore, the detection circuit
The detection output of the interrogation signal wave in 22 is a low-pass filter
DC power is output by being supplied to 28. The direct-current power obtained from this interrogation signal wave and the direct-current power obtained from the energy wave are added together by the adder circuit 29 and used as the drive power source + B of the response device 6. The microprocessor 26 inputs the interrogation signal demodulated by the changeover switch 27 to the modulation circuit 20 as indicated by the solid line in FIG. 1 until the interrogation device 1 transmits the interrogation signal and then the use permission signal. Control to be done. The second harmonic 2f ₁ is A1 modulated by the interrogation signal input to the modulation circuit 20, and the antenna 3
A response signal wave is transmitted from 0 to the interrogation apparatus 1. Further, when the use permission signal is given, the microprocessor 26 takes in the interrogation signal stored in the buffer memory 25, calculates it appropriately and gives a response signal to the other connection terminal of the changeover switch 27. At the same time, the changeover switch 27 is changed over by the microprocessor 26 as shown by the broken line in FIG.
The second harmonic wave 2f ₁ is A1 modulated by the response signal output from the antenna 30 and transmitted from the antenna 30. The antenna 21, the detection circuit 22, the high-pass filter 23 and the amplifier 24 constitute a question receiving means, the rectifying and multiplying circuit 17, the band-pass filter 19, the modulation circuit 20 and the antennas 16 and 30 constitute a response transmitting means, and a buffer. The memory, the microprocessor 26, and the changeover switch 27 constitute a response control means.

Next, an example of the operation of the microprocessor 8 of the interrogation apparatus 1 will be described with reference to FIG. When the inquiry signal is output from the microprocessor 8 and the transmission of the inquiry signal is started (step), if the response device 6 correctly receives the response signal, the response device 6 transmits the same response signal to the inquiry device 1. Therefore, both the interrogation signal and the received and demodulated response signal are stored in the comparison circuit 15, and when the transmission of the interrogation signal is completed (step), it is compared (step) whether or not the two contents match. Here, if they match (step), it is because the response device 6 was able to correctly receive the inquiry signal, and the matching signal is given from the comparison circuit 15 to the microprocessor 8. When this coincidence signal is given, the microprocessor 8 outputs a use permission signal, and this use permission signal is transmitted from the antenna 10 to the response device 6 (step). This is because if the contents of the inquiry signal and the response signal do not match in the comparison circuit 15, the response device 6 could not correctly receive the inquiry signal, and the process returns to the step again and the transmission of the inquiry signal is repeated. After the transmission of the inquiry signal is completed, the response signal received and demodulated is fetched by the microprocessor 8 and collated appropriately.

Further, the operation of the microprocessor 26 of the response device 6 will be described with reference to FIG. The demodulated interrogation signal after the reception of the interrogation signal is started (step) is not taken into the microprocessor 26 but is stored in the buffer memory 25 for the time being (step). Then, when the reception of the inquiry signal is completed (step), the microprocessor 26 determines whether or not the use permission signal is continuously received (step). When the use permission signal is received, the interrogation signal stored in the buffer memory 25 has been correctly received and demodulated, is taken into the microprocessor 26 (step), and is appropriately processed. If the use permission signal is not received continuously after the end of reception, the buffer memory 25
The interrogation signal stored in (1) is erroneously received and demodulated, and the buffer memory 25 is cleared (step) without being taken into the microprocessor 26 to prepare for receiving the interrogation signal again.

Therefore, the interrogation signal is repeatedly transmitted until the interrogation signal is correctly received by the response device 6, and the exact interrogation signal can be transmitted to the response device 6. Then, since an incorrect inquiry signal is not taken into the microprocessor 26 of the response device 6, an incorrect answer signal is not output according to the incorrect inquiry signal, and it is rewritten with incorrect information. Nothing. As a result, highly reliable transmission is performed from the interrogation device 1 to the response device 6.

FIG. 4 is a flowchart explaining another example of the operation of the microprocessor 8 of the interrogation apparatus 1. In FIG. 4, before the inquiry signal is output from the microprocessor 8, first, the count value N for counting the number of bits of the output inquiry signal is set to 1 (step '). Then, the signal of the first bit of the inquiry signal is output (step '). Then, if the response device 6 correctly receives, the first bit signal of the response signal having the same content is transmitted from the response device 6 to the interrogation device 1. Therefore, the inquiry device 1
Detects the signal of the first bit of the response signal (step '), and compares the contents of the signal of the first bit of the response signal received and demodulated by the comparator circuit 15 (step'). ). Here, if the signal of the first bit matches (step '), the response device 6 can correctly receive the signal of the first bit of the interrogation signal, and the comparison circuit 15 sends the match signal to the microprocessor 8. Is given. Then, if they coincide with each other, then it is judged from the value of the count value N whether or not the output of the inquiry signal is completed (step '). In this step ', if the count value N matches the total number of bits forming the inquiry signal, it is determined that the inquiry signal has been transmitted. In the description so far, since the signal of the first bit of the inquiry signal has only been sent and the transmission has not been completed yet, 1 is added to the count value N in step 'and the process returns to step'. Then, the signal of the second bit of the interrogation signal is then output in step ', and the steps'to' are repeated in the same manner as described above until the transmission of all the bits of the interrogation signal is completed. And step ′
When it is determined that the transmission is completed, the microprocessor 8 outputs a use permission signal, and this use permission signal is transmitted from the antenna 10 to the response device 6 (step '). It is to be noted that, if the contents of the inquiry signal and the response signal do not match in the comparison circuit 15 in the step ', the response device 6 cannot correctly receive the signal of the corresponding bit of the inquiry signal, and the step' is repeated again. This is repeated from returning and outputting the signal of the first bit of the interrogation signal.

In this way, the interrogation signal from the microprocessor 8
In addition to outputting for each bit, it compares with the response signal for each bit and outputs the signal of the next bit when the contents match, so confirm in real time whether the interrogation signal was correctly received and demodulated by the response device. it can. And the response device 6
If the inquiry signal is erroneously received at, the signals arranged after the corresponding bit of the inquiry signal are not output. If the contents do not match, the question signal is output again from the first bit, so that useless signal transmission can be omitted and a correct question signal can be promptly sent to the response device 6.

Incidentally, in FIG.
Although 15 is provided outside the microprocessor 8,
Of course, the function of the comparison circuit 15 may be performed in the microprocessor 8. Further, in FIG. 1, the buffer memory 25 and the changeover switch 27 of the response device 6 are provided outside the microprocessor 26, but it goes without saying that these functions may be performed within the microprocessor 8. .

(Effects of the Invention) Since the wireless communication system of the present invention is configured as described above, it has the effects described below.

In the wireless communication system according to claim 1, the response device transmits a response signal wave in which the carrier wave is modulated with the second harmonic of the received energy wave as a carrier wave and the demodulated interrogation signal as a response signal. Therefore, the structure of the response device is simple, and the response signal wave is immediately transmitted by demodulating the interrogation signal. Then, in the interrogation apparatus, the response signal wave is received almost simultaneously with the transmission of the interrogation signal, and the interrogation signal and the demodulated response signal can be compared in real time.

Further, in the wireless communication system according to claim 2, when the transmission of the inquiry signal is completed, the comparison with the demodulated response signal is completed almost at the same time, and the inquiry signal is retransmitted due to communication error. The time until retransmission is extremely short, and the repetition cycle may be short.

Further, in the wireless communication system according to claim 3,
Since the question signal is compared bit by bit, when the correct communication is not performed, the output after the question signal can be stopped and unnecessary signal transmission after the relevant bit can be omitted, and the question signal is repeated accordingly. Can be done quickly.

[Brief description of drawings]

FIG. 1 is a block circuit diagram showing an embodiment of a wireless communication system of the present invention, FIG. 2 is a flowchart explaining an example of the operation of the interrogation apparatus of FIG. 1, and FIG. It is a flowchart explaining operation | movement of the response device of FIG. 1, and FIG. 4 is a flowchart explaining another example of operation | movement of the interrogation apparatus of FIG. 1: Interrogation device, 2, 3: Oscillation circuit, 6: Response device, 7,20: Modulation circuit, 8,26: Microprocessor, 4,9,24: Amplifier, 5,10,11,16,21,30 : Antenna, 12, 19: Band pass filter, 13: Low noise block down converter, 14, 22: Detection circuit, 15: Comparison circuit, 17: Rectification and multiplication circuit, 23: High pass filter, 25: Buffer memory, 27: Changeover switch .

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Inventor Yoshikazu Kawashima 1-12-2 Kawana, Fujisawa-shi, Kanagawa Yamatake Honeywell Co., Ltd. Fujisawa factory (72) Inventor Isao Ishikawa 1-2-12 Kawana, Fujisawa-shi, Kanagawa Yamatake Honeywell Co., Ltd. Fujisawa Factory (56) Reference JP 62-219730 (JP, A) JP 60-75142 (JP, A)

Claims (3)

[Claims] 1. An energy transmitting means for transmitting an energy wave of a first frequency without modulation, and an inquiry signal wave obtained by modulating a carrier wave of a second frequency different from the first frequency with an inquiry signal or a use permission signal. Question transmitting means for transmitting, and the first
Response receiving means for receiving a response signal wave having the second harmonic of the frequency as a carrier wave and demodulating the response signal, and outputting the interrogation signal and displaying the contents of the interrogation signal and the demodulated response signal. By comparing, if all the bits match, an interrogation device comprising an interrogation control unit that outputs the use permission signal following the interrogation signal, and demodulates the interrogation signal or the use permission signal by receiving the interrogation signal wave. An interrogation receiving means for storing the demodulated interrogation signal in a buffer memory and outputting the demodulated interrogation signal as a response signal as it is, and a response for fetching the interrogation signal stored in the buffer memory when the use permission signal is demodulated. Control means, and response transmitting means for receiving the energy wave and transmitting a response signal wave modulated with the response signal using the second harmonic thereof as a carrier wave, A wireless communication system, comprising a response device including: 2. The wireless communication system according to claim 1, wherein the inquiry control means outputs the inquiry signal again if the contents of the inquiry signal and the demodulated response signal do not match in all bits. A wireless communication system having the above structure. 3. The wireless communication system according to claim 1, wherein the interrogation control means outputs the interrogation signal bit by bit and the content of the demodulated response signal as one bit.
Each bit is compared, and if they match, the inquiry signal of the next bit is output. If the contents of each bit do not match, the inquiry signal is output again from the first bit. Wireless communication system.