JP2000209121A - Mobile body identification device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely realize a communicating operation with a plurality of responders within a communication area by a simple method without causing crosstalk. SOLUTION: An interrogator 1 is provided with a communication request signal generating section 12 that generates plurality of communication request signals and with a communication discrimination section 17 that selects a responder 2 that is communicative on the basis of the response request signal from a plurality of responders 2 received by a plurality of time slots synchronously with the communication start request signals. A sure communication operation with a plurality of the responders 2 can be realized by changing number of the time slots depending on number of the responders 2 within the communication area 3 through the decision of the communication decision section 17.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an interrogator for identifying a moving transponder in a non-contact manner when a moving body having the transponder passes near the interrogator. The present invention relates to a mobile object identification device that exchanges information.

[0002]

2. Description of the Related Art A conventional moving object identification apparatus is disclosed in Japanese Patent Laid-Open No.
One using radio waves described in No. 2778 is known. Hereinafter, a conventional method will be described with reference to the drawings.

FIG. 10 is a configuration diagram of a conventional moving object identification device. 10, reference numeral 100 denotes an interrogator, 101 denotes a communication area which is a transmission / reception range of the interrogator, and 102 denotes a transponder. In FIG. 10, two transponders 102a and 102b exist in the communication area 101. Is communicating without contact.

FIG. 11 is a timing chart for explaining the lapse of time in the communication state between the interrogator 100 and the responder 102. Interrogator 100 transmits communication start request signal R0 continuously or intermittently. The transponder 102a is in the communication area 101
The transponder 102a receives the communication start request signal R0
At time t1, and the interrogator 100 receives a response signal A0
To start communication. The interrogator 100 is a transponder 1
When terminating or temporarily interrupting communication with 02a, a communication end request signal RN is transmitted, and again, a communication start request signal R0 is transmitted continuously or intermittently. The transponder 102a receiving the communication end request signal RN at time ts
Suspends the communication operation for a fixed time Δt. At this time, the transponder 1 not communicating with the interrogator 100
02b has entered the communication area 101, the responder 1 responds to the communication start request signal R0 of the interrogator 100.
02b transmits a response signal A0 and starts a communication operation with the interrogator 100. As described above, the interrogator 100 can perform transmission / reception operations in time series with the plurality of transponders 102 in the communication area 101.

[0005]

In the above-mentioned conventional configuration,
When a plurality of transponders 102 are simultaneously present in the communication area 101 and each transponder 102 transmits a response signal A0 in response to the communication start request signal R0 from the interrogator 100,
There is a problem that communication becomes impossible. On the other hand, Interrogator 1
00 in synchronization with the communication start request signal R0
A method has been considered in which a plurality of time slots are provided for receiving a response signal A0 from the PC, and each transponder 102 randomly selects a time slot. However, depending on the number of transponders 102 present in the communication area 101,
You need to determine the number of time slots. That is, if the number of time slots is too small with respect to the number of transponders 102, communication becomes impossible, and if the number of time slots is too large, there is a problem that extra time unrelated to communication is provided.

[0006] In particular, in a non-contact type mobile object identification device in which the power of the electronic circuit of the transponder 102 is obtained by the transmission radio wave from the interrogator 100, the power obtained by the transponder 102 is weak. Complicated calculations, such as providing a frequency channel and selecting time slots by advanced signal processing, increase power consumption. Therefore, it is necessary to shorten the distance between the interrogator and the transponder in order to obtain sufficient power, and as a result, the communication area becomes narrow.

The present invention solves the above-mentioned problems, and realizes a reliable communication operation by eliminating interference with a plurality of transponders in a communication area by a simple method.

[0008]

In order to solve this problem, the present invention provides an interrogator provided with a communication request signal generator for generating a plurality of communication request signals, and a plurality of time slots synchronized with the communication start request signal. The transponder selects a transponder which can communicate with the response request signal from the plurality of transponders received in step (1).

First, the interrogator generates a first communication start request signal from the communication request signal generator and transmits it to the responder.
The communication determiner selects a transponder that can communicate with the response request signal from the plurality of transponders received in the N time slots synchronized with the first communication start request signal, and determines all the times by the communication determination unit. When the response request signal from the transponder is interfered with in the slot, the second communication start request signal is output again, and the response request signal from the transponder is received in the N × M timeslot. A possible transponder is selected by the communication determination unit, and necessary information is communicated with the transponder.

The transponder is provided with two random number generators which can be calculated by simple processing and a response communication request signal generator. The transponder controller determines a communication start request signal from the interrogator,
In the case of the first communication start request signal, one response of the random number generator is used to generate a delay timing synchronized with the first communication start request signal from the response request signal generator, and the response request signal is transmitted to the interrogator. In the case of the second communication start request signal, the time slot can be varied according to the number of transponders in the communication area by transmitting the response request signal at a timing obtained by combining the outputs of the two random number generators. It is possible to realize a reliable communication operation with a plurality of transponders with a simple configuration.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The invention according to claim 1 of the present invention has a mobile unit having a transponder and an interrogator communicating with the transponder, and the interrogator transmits a communication start request signal. A communication determination unit for selecting a transponder capable of communication from a response request signal from the transponder received in a time slot synchronized with the generating unit and the communication start request signal, wherein the interrogator transmits the first communication start request signal When the communication determination unit receives a response request signal from one transponder, the communication determination unit communicates with the transponder. When the communication determination unit receives response request signals from a plurality of transponders, a second communication start request signal. And transmits a response request signal from the transponder in a plurality of time slot groups, and selects a transponder that can communicate.The time is determined according to the number of transponders in the communication area. Slots can be changed, It is possible to realize a plurality of responders and reliable communication operation in Do configuration.

According to a second aspect of the present invention, there is provided the communication system according to the first aspect, wherein the plurality of time slot groups include a plurality of slot groups each including a plurality of time slots. The time slot can be freely changed according to the number of transponders in the area.

According to a third aspect of the present invention, in the first aspect of the present invention, the first communication start request signal is synchronized with the first communication start request signal by outputting a first random number. The response request signal is transmitted at the
For the communication start request signal of No. 2, a response request signal is transmitted at a timing combining the first and second random number outputs, and each responder responds to the communication start request signal from the interrogator. Can be transmitted at various timings.

According to a fourth aspect of the present invention, in the first aspect of the invention, an interrogator generates a plurality of communication request signals, and a transmission unit for transmitting the communication request signal. Unit, a reception demodulation unit that receives and demodulates a signal received from the transponder, a communication determination unit that is connected to the reception demodulation unit and selects a transponder that can communicate from communication request signals from a plurality of transponders, and an interrogator And a timing signal generating section for generating the wireless communication timing of the present invention, so that the interrogator can be configured with a simple configuration.

According to a fifth aspect of the present invention, in the first aspect of the present invention, the transponder includes a reception demodulation section for receiving and demodulating a transmission signal from the interrogator, and a random number generation section for generating a random number. A memory unit holding information unique to the transponder, a response request signal generation unit that determines the timing of a signal transmitted by the output of the random number generation unit, and an output of the response request signal generation unit together with data of the memory unit. It is configured to include a transmission unit that transmits to the interrogator and a power generation unit that generates power to drive each unit from the radio wave transmitted from the interrogator, so that the transponder can be configured with a simple configuration. I can do it.

According to a sixth aspect of the present invention, in the fifth aspect of the present invention, there are provided two random number generators, and the transponder transmits a response request signal to the communication start request signal from the interrogator. It can be created at various timings.

According to a seventh aspect of the present invention, in the invention according to the sixth aspect, one output of the random number generation section is a predetermined fixed pattern, and the response request signal has a simple configuration. Can be created.

According to an eighth aspect of the present invention, in the first aspect of the invention, there is provided a single random number generator, and the output of the random number generator and the communication start request signal from the interrogator are included. The response codes are compared with each other, and if they are the same, the response request signal is output with the delay time of the output of the random number generation unit, and the response request signal can be created with a simple configuration.

According to a ninth aspect of the present invention, there is provided a moving object identification apparatus having a communication area in which a plurality of transponders can exist and wherein the interrogator identifies the plurality of transponders. An antenna that wirelessly communicates by radio waves, a receiving unit connected to the antenna for receiving and demodulating a transmission signal from an interrogator, a transponder control unit connected to the reception demodulation unit, and a random number connected to the transponder control unit , A memory unit that previously holds information unique to the transponder, and one or two of the outputs of the random number generator connected to the transponder control unit and interrogated. A response request signal generator that determines the timing of a signal to be transmitted to the transmitter, and a transmitter that transmits the data of the memory unit to the interrogator from the antenna according to the output of the response request signal generator.
A power generation unit connected to the antenna and configured to generate power consumption of each electronic circuit from transmission radio waves from the interrogator,
An interrogator control unit in which the interrogator controls various functions of the interrogator; a communication request signal generation unit connected to the interrogator control unit to generate a plurality of signals; and a transmission connected to the communication request signal generation unit Unit, a transmission antenna connected to the transmission unit and wirelessly transmits a signal to a transponder in a communication area, a reception antenna for receiving a signal from the transponder, a reception demodulation unit connected to the reception antenna, The interrogator is configured by a communication determination unit that is connected to the reception demodulator and selects a transponder that can communicate from transmission signals from a plurality of transponders, and a timing signal generator that generates wireless communication timing of the interrogator. The number of time slots may be increased from N to N × M according to the determination result of the communication determination unit when transmitting the first communication start request signal, that is, according to the number of transponders in the communication area. Becomes possible The transponder generates a delay timing from the response request signal generator in synchronization with the communication start request signal and in synchronization with N or N × M time slots in response to the communication start request signal, and transmits the response request signal to the interrogator. This has the effect that a reliable communication operation with a plurality of transponders in the communication area can be realized by a simple method.

According to a tenth aspect of the present invention, in the configuration according to the ninth aspect, one of the random number generators of the transponder and the output of the transponder controller are input signals and the result is a response request signal. By providing a comparison unit that outputs to the generation unit, it is possible to limit the transmission of the response request signal of the transponder, and it is possible to communicate with multiple transponders in the communication area without increasing the time slot This has an effect that a reliable communication operation with a plurality of transponders in the communication area can be realized by a simple method.

According to an eleventh aspect of the present invention, in the configuration according to the ninth aspect, one of the random number generation units of the transponder is a constant generation unit that generates a predetermined fixed pattern. Thus, it is possible to reduce the number of random number generators consuming a large amount of power and to achieve a reliable communication operation with a plurality of transponders in the communication area by a simple method.

According to a twelfth aspect of the present invention, in addition to the configuration of the ninth aspect, a random number generator of the transponder is provided with one unit.
A sub-antenna is provided in the transponder, a sub-antenna power generator connected to the sub-antenna and generating power from a transmission signal from the interrogator, and a sub-antenna power generator and a power generator connected to the sub-antenna power generator. A power difference detection unit that detects a difference in power value; and a data conversion unit that is connected to the power difference detection unit and that generates a pattern according to an output of the power difference detection unit, wherein a response request signal generation unit includes the random number generation unit. By determining the timing of the signal to be transmitted to the interrogator by combining one or two of the outputs of the data converter and the data converter, a delay timing synchronized with the communication start request signal is generated only by the shape of the two antennas formed in advance. This has an effect that a reliable communication operation with a plurality of transponders in the communication area can be realized by a simple method.

According to a thirteenth aspect of the present invention, in contrast to the configuration of the twelfth aspect, the sub-antenna and the coil forming the antenna have the same winding direction to be obtained by two antennas. It is possible to improve the accuracy of detecting the power difference, and it is possible to realize a reliable communication operation with a plurality of transponders in the communication area by a simple method.

According to a fourteenth aspect of the present invention, the configuration of the twelfth aspect is obtained by two antennas by reversing the winding directions of the coil forming the sub-antenna and the antenna. It is possible to improve the accuracy of detecting the power difference, and it is possible to realize a reliable communication operation with a plurality of transponders in the communication area by a simple method.

Hereinafter, an embodiment of the present invention will be described with reference to FIG.
This will be described with reference to FIG.

(Embodiment 1) In FIG. 1, 1 is an interrogator, 2a to 2e are transponders, and 3 is a communication area where the interrogator 1 can communicate.

FIG. 2 is a diagram showing the configuration of the interrogator 1 and the responder 2. Reference numeral 11 denotes an interrogator control unit for controlling various functions of the interrogator 1, and reference numeral 12 denotes a plurality of communication start requests by the interrogator control unit 11. A communication request signal generator 13 for generating a signal is provided by a transmission amplifier 14 to output the output of the communication request signal generator 12 to the communication area 3.
, 15 is a receiving antenna for receiving a transmission radio wave from the transponder 2 in the communication area 3, 16 is a receiving demodulation unit connected to the receiving antenna 14, 17 is connected to the receiving demodulation unit 16, A communication determination unit 18 outputs a determination result as to whether communication is possible to the device control unit 11, and a timing signal generation unit 18 generates a timing of a communication operation of the interrogator 1 with the transponder 2.

Reference numeral 23 denotes a transponder control unit for performing various controls of the transponder 2, reference numeral 20 denotes an antenna for transmitting and receiving radio waves to and from the interrogator 1, and reference numeral 21 denotes a transponder control unit connected to the antenna 20.
, A reception demodulation unit connected to the switch 21, 24 a first random number generation unit, 25 a second random number generation unit, and 26 a first random number generation unit 24 and a second random number generation unit. The output of the random number generator 25 is transmitted to the transponder controller 23.
A response request signal generating unit that generates a timing for transmitting a response request signal alone or in combination with a memory unit 27 in which data to be communicated to the interrogator 1 is stored;
Is a transmission unit that transmits data in the memory unit 27 from the antenna 20 in accordance with the output of the response request signal generation unit. 29 is a power generation unit that is connected to the antenna 20 and generates power of each electronic circuit. Power can be obtained by detecting transmission radio waves or by electromagnetic induction.

The operation of the above configuration will be described below with reference to FIG. FIG. 3 is a timing chart showing a communication operation between the interrogator 1 and the responders 2a to 2e, and is a diagram in a case where, for example, five responders 2a to 2e exist in the communication area 3. First, the communication request signal generator 12 synchronizes with the timing signal T1 of the timing signal generator 18 to
Is transmitted to the communication area 3 through the transmission amplifier 14 and the transmission antenna 13. The interrogator 1 that has transmitted the first communication start request signal R1 is provided with, for example, N time slots 30, and receives the response request signal A1 from the transponders 2a to 2e.

The transponders 2a to 2e in the communication area 3 obtain the first communication start request signal R1 from the interrogator 1 via the antenna 20, the switch 21, and the reception demodulator 22. The transponder control unit 23 outputs to the response request signal generation unit 26 that the first communication start request signal R1 has been received. The response request signal generator 26 outputs a response request signal A1 at a timing synchronized with the communication start request signal R1. This timing is the first
Generated using only the output of the random number generator 24 of
Is a delay time from the communication start request signal R1 corresponding to a discrete value corresponding to the N number of time slots 30. In accordance with the delay time, the transmission unit 28 transmits the ID codes and the like of the transponders 2a to 2e stored in the memory unit 27 to the response request signal A1 and transmits the same from the antenna 20.

All the transponders 2a existing in the communication area 3
2e transmit the response request signal A1 in different time slots 30 according to the first random number generator 24 by the above operation. In FIG. 3, in time slot 1, the transponders 2a and 2c transmit the response request signal A1,
In the time slot 3, the transponders 2b and 2d transmit the response request signal A1. Time slot 2
, Only the transponder 2e transmits the response request signal A1.

The reception demodulation unit 16 of the interrogator 1 receives and demodulates the response request signals A1 from the plurality of transponders 2 and performs demodulation.
7 is output. The communication determination unit 17 determines the transponders 2a to 2e that can communicate based on the output signal of the reception demodulation unit 16.
That is, in each time slot 30, time slot 2, in which the plurality of transponders 2a and 2c transmitted the response request signal A1,
The time slot 3 in which the response request signal A1 is transmitted by the second and second response signals 2b and 2d cannot obtain the response request signal A1 from the specific transponders 2a to 2d due to interference. But,
One transponder 2e like time slot 2 shown in FIG.
In the slot in which only the response request signal is transmitted, the ID code of the transponder 2e can be obtained from the response request signal A1, and this information is output to the interrogator control unit 1.

The interrogator control unit 11 outputs the ID of the transponder 2 e from the communication request signal generation unit 12 to the communication determination unit 17.
The communication signal C1 including the code is transmitted into the communication area 3. The plurality of transponders 2a to 2e in the communication area 3 receive and demodulate the communication signal C1 and terminate predetermined communication with the interrogator 1 in the communication frame 31 only when their own ID code is included. At this time, the transponder that has completed the communication, that is, the transponder 2e in the example of FIG. 3, does not transmit the response request signal A1 to the new communication start request signal R1.

Next, the interrogator 1 again outputs the communication start request signal R
1 and receives the response request signals A1 from the plurality of transponders 2a to 2d,
To 2d, and predetermined communication with the responders 2a to 2d is performed in the communication frame 31. As described above, Interrogator 1
Transmits the communication start request signal R1 repeatedly and sequentially communicates with the transponders 2a to 2e determined by the communication determining unit 17, and finally all the transponders 2a to 2e in the communication area 3
Communication operation can be performed.

With respect to N, which is a preset number of time slots 30, the transponders 2a, 2a,
When the number of b, 2c... is extremely large, a plurality of transponders 2a, 2b, 2
The transmission probability of the transmission of the transmission request signal A1 is increased, and the transponders 2a, 2
b, 2c ..... ID code cannot be obtained,
Communication between the interrogator 1 and the responders 2a, 2b, 2c... For a continuous communication start request signal R1,
The transponders 2a, 2b, 2c,...
If it cannot be determined, the interrogator control unit 11 transmits the communication start request signal R2 of the second a, 2b, 2c... From the communication request signal generation unit 12 to the communication area 3 through the transmission amplifier 14 and the transmission antenna 13. Let it. The interrogator 1 that has transmitted the second communication start request signal R2 converts the N time slots 30 into one slot group 32 as shown in FIG.
N × M time slots composed of a plurality of slot groups 32 are provided, and response request signals A1 from the transponders 2a, 2b, 2c... Are received.

The transponders 2a, 2b, 2c... Are transmitted via an antenna 20, a switch 21, and a reception demodulation unit 22 to the interrogator 1.
From the second communication start request signal R2. The transponder controller 23 outputs to the response request signal generator 26 that the second communication start request signal R2 has been received. The response request signal generator 26 generates a delay time synchronized with the communication start request signal R2 by combining the output of the first random number generator 24 and the output of the second random number generator 25. For example, a delay time corresponding to the time interval of the block 32 is generated in accordance with the output of the second random number generator 25, and the delay time corresponding to the time slot 30 which is the output of the first random number generator 24 is added. By doing so, it is possible to generate a delay time from the reception of the communication start request signal R2 to the transmission of the response request signal A1. In accordance with this delay time, the transmission unit 28
Of the transponders 2a, 2b, 2c,.
A response request signal A1 to which a code and the like are added is transmitted from the antenna 20.

All the transponders 2a, 2b, 2c,... Existing in the communication area 3 receiving the communication start request signal R2 perform the above-described operations, and thereby, the first random number generator 24 and the second random number generator 25. The response request signal A1 is transmitted in a different slot group 32 and time slot 30 according to the time slot 30 in which the interrogator 1 is received.
1, the number of responders 2a, 2
b, 2c.... If the number of time slots 30 in the communication start request signal R1 is increased in advance, it becomes possible to communicate with a plurality of transponders 2. However, the number of transponders 2a, 2b , 2c... Are small, only a very small number of time slots 30 are transmitted to the response request signal A1.
Is used, and the useless time not related to communication increases.

The time intervals of the time slots 30, the number N of the time slots 30, and the number M of the slot groups 32 are stored in advance in the interrogator 1 and the transponders 2a, 2b, 2c. In the interrogator 1, the timing signal generator 18
The interrogator 2a, 2b, 2c... Synchronizes the transmission of the response request signal with the communication start request signal R1 or R2 transmitted by the interrogator 1, 1 and the transponder 2 can be synchronized with each other.

As described above, the time slot 30 for receiving the response request signal from the transponders 2a, 2b, 2c... In response to the communication start request signal from the interrogator 1 is determined by the communication determination unit 17 The interrogator 1 reliably communicates with the plurality of transponders 2a, 2b, 2c,... In the communication area 3 by using a simple communication method without using unnecessary communication time. A mobile object identification device that can operate can be realized.

(Second Embodiment) FIG. 5 is a schematic configuration diagram of a transponder 2 according to a second embodiment. In FIG. 5, reference numeral 50 denotes a comparison unit which is connected to the second random number generation unit 25 and the transponder control unit 23 and outputs a result to the response request signal generation unit 26.
Other configurations and functions are the same as those of the transponder 2 shown in FIG.

Embodiment 2 having the above configuration will be described below. As shown in FIG. 4, in the first embodiment, the interrogator 1
When there are a large number of transponders 2a, 2b, 2c... In the communication area 3, the number of the time slots 30 is multiplied by M, so that an uncommunicated response to the repetition of the communication start request signal R2 is obtained. , While all the transponders 2a, 2b, 2c in the communication area 3 are reduced in number.
Communication with However, by repeating the communication start request signal R2, the uncommunicated transponders 2a, 2a
b, 2c..., but the untransmitted transponder 2
a, 2b, 2c... time slot 30 for the number
Becomes excessive, and as a result, wasteful time for communication increases.

The transponders 2a, 2b, 2c which can communicate with the continuous communication start request signal R1 in the communication judging section 17.
.. Cannot be determined, the interrogator control unit 11 sends the third communication start request signal R3 (M) from the communication request signal generation unit 12.
Is transmitted through the transmission amplifier 14 and the transmission antenna 13.
The communication start request signal R3 (M) is a signal including a communication code from 1 to M with respect to the communication start request signal R1. First, the interrogator control unit 11 sets the communication request signal generation unit 1
2 repeatedly transmits a communication start request signal R3 (1),
It communicates with a plurality of transponders 2. The time chart at this time is different from the time chart shown in FIG. 3 only in that the communication start request signal R1 is changed to R3 (1), and the time slot 30 corresponding to the communication start request signal R3 (1) is changed.
Is N.

The transponders 2a, 2b, 2c,... Receiving the communication start request signal R3 (M) receive the second random number generator 2
At 5, a random number from 1 to M is generated. The random number generated by the second random number generation unit 25 is held until the communication with the interrogator 1 ends. The transponder control unit 23 uses the demodulated signal output from the reception demodulation unit 22 to output a communication start request signal R3 (M).
Is output to the comparing unit 50. The comparison unit 50 compares the communication code output from the transponder control unit 23 with the random number generated by the second random number generation unit 25,
For example, in the case of the same, “1” is output to the response request signal generating unit 26 as a digital signal, and in the case of different, “0” is output.
The response request signal generator 26 responds to the output of the comparator 50,
That is, when the output of the comparison unit 50 is "1", the response request signal A1 is output to the transmission unit 28 with the delay time which is the output of the first random number generation unit 24, and when the output is "0", the response Does not output the request signal A1. That is, the responders 2a, 2b, 2c
In the case of ..., the transmission of the response request signal is restricted according to the communication code included in the communication start request signal R3 of the interrogator 1.

The communication operation between the interrogator 1 and the transponder 2 determines the transponders 2a, 2b, 2c,... Which can be communicated by the communication determining unit 17 of the interrogator 1 as described in the first embodiment. , The communication signals C1 including the ID codes of the transponders 2a, 2b, 2c... Are transmitted into the communication area 3 and the communication frame 31 is used. The interrogator 1 repeatedly transmits a communication start request signal R3 (1), and sends a plurality of responders 2a, 2b,
The response request signal A1 from the communication devices 2a, 2b, 2c,... Is determined by the communication determination unit 17, and predetermined communication with the response devices 2a, 2b, 2c,. Is performed in the communication frame 31 so that all of the transponders 2a, 2b, 2c,... In which the random number generated by the second random number generator 25 among the transponders 2a, 2b, 2c. 2c
……… can be communicated sequentially.

Next, the interrogator 1 sends the communication start request signal R3
After the communication determination unit 17 determines that the response request signal A1 from the transponder 2 for (1) has disappeared, the communication start request signal R3 (1) including a different communication code is used as the communication start request signal R3 (2). And all the transponders 2a, 2b,... In the communication area 3 where the output of the second random number generator 25 is "2".
2c... Are sequentially communicated. As described above, the responder 2a responds to the communication start request signal R3 (M) from 1 to M,
By sequentially communicating with 2b, 2c,..., All the transponders 2a, 2b, 2c in the communication area 3 are finally obtained.
.. Can perform a communication operation.

As described above, the transponders 2a, 2b, 2c,... Which can respond in response to the communication start request signal from the interrogator 1.
.. Can be automatically controlled in accordance with the determination result of the communication determination unit 17, and the interrogator 1 uses a simple communication method and the plurality of transponders 2a, 2b, 2c in the communication area 3. It is possible to realize a mobile object identification device that can reliably perform a communication operation without using unnecessary communication time.

(Third Embodiment) FIG. 6 is a schematic configuration diagram of a transponder 2 according to a third embodiment. In FIG. 6, reference numeral 51 denotes a constant generation unit provided in place of the second random number generation unit 25 in FIG. 2, and any one of numbers from 1 to M is fixedly stored in advance.

Embodiment 3 having the above configuration will be described below. In a transponder 2 that supplies power to the electronic circuit of the transponder 2 by the power generation unit 29, for example, in a non-contact type IC card without a battery, the power generated by the power generation unit 29 is limited. Become. However, in the configuration of FIG. 2, the first and second random number generators 24 and 25 require signal processing for generating random numbers, and power consumption increases. On the other hand, in the configuration of FIG. 6, the constant generation unit 51 in which one of the numbers from 1 to M is stored in advance is electrically set to “High” or “Lo” in accordance with, for example, each bit of a plurality of digital signals.
Since it can be composed of a switch or a ROM connected to w ", the function of the second random number generation unit 25 in FIG. 2 can be achieved with low power consumption.

A specific communication operation between the interrogator 1 and all the transponders 2 in the communication area 3 can be performed by the method described in the first and second embodiments.

As described above, the transponder 2 which can respond in response to the communication start request signal from the interrogator 1 can be automatically controlled according to the determination result of the communication determination unit 17, and
Can realize a mobile object identification device capable of reliably performing a communication operation with a simple communication method and a low power consumption with the plurality of transponders 2 in the communication area 3.

(Fourth Embodiment) FIG. 7 is a schematic configuration diagram of a transponder 2 according to a fourth embodiment. In FIG. 7, reference numeral 60 denotes a sub-antenna, 61 denotes a sub-antenna power generator connected to the sub-antenna, and 62 denotes a power of the power generated by the two power generators connected to the power generator 29 and the sub-antenna power generator 61. A power difference detection unit 63 for detecting a difference is connected to the power difference detection unit 62 and outputs an output of the power difference detection unit 62 from 1 to M
This is a data conversion unit for converting the number into any of the above numbers, and is provided instead of the second random number generation unit 25 in FIG.

FIG. 8 is a diagram showing an arrangement of the antenna 20 and the sub-antenna 60 when the transponder 2 in the fourth embodiment is applied to a non-contact type IC card. The antenna 20 is formed of a large loop antenna that makes full use of the area of the IC card 64 in order to transmit / receive to / from the interrogator 1 and to obtain power supply from the interrogator 1. The sub-antenna 60 is a small loop antenna. It is formed inside the antenna 20. A plurality of sizes of the sub-antenna 60 are prepared in advance. 65 is
An electronic circuit chip in which electronic circuits other than the antenna 20 and the sub-antenna 60 are integrated into an IC.

Embodiment 4 will be described below with the above configuration. As described in the first and second embodiments, the interrogator 1
Transmits a communication start request signal R1 and the communication determination unit 17 cannot determine a transponder 2 that can communicate with the continuous communication start request signal R1. Alternatively, R3 (M) is transmitted. When the transponder 2 receives the communication start request signal R2 or R3 (M), the power difference detection unit 62 determines the difference between the powers obtained by the antenna 20 and the sub-antenna 60 by using the power generation unit 29 and the sub-antenna power generation unit. Detected from the output of 61 and output to the data converter 63. The data converter 63 converts the output of the power difference detector 62 into data of 1 to M and outputs the data to the response request signal generator 26. Response request signal generator 26
Selects the time slot 30 according to the data of the data conversion unit 63 and transmits a response request signal A1 to the interrogator 1.

With respect to a specific communication operation between the interrogator 1 and all the transponders 2 in the communication area 3, the first and second embodiments are described.
This can be achieved by the method described in (1).

As described above, also in the fourth embodiment, the transponder 2 which can respond in response to the communication start request signal from the interrogator 1 can be automatically controlled in accordance with the determination result of the communication determination unit 17. In addition, the interrogator 1 can realize a mobile object identification device that can communicate reliably with a plurality of transponders 2 in the communication area 3 by a simple communication method and with low power consumption.

(Embodiment 5) Transponder 2 of Embodiment 5
FIG. 7 shows a schematic configuration of the IC card 64, and FIG. The difference from the fourth embodiment is that the winding directions of the antenna 20, which is a loop antenna, and the sub-antenna 60 are reversed.

Embodiment 5 having the above configuration will be described below. As described in Embodiment 4, with respect to communication start request signal R2 or R3 (M) of interrogator 1, power difference detection section 62 of transponder 2 determines the difference between the power obtained by antenna 20 and sub-antenna 60. Detected from the outputs of the power generation unit 29 and the sub-antenna power generation unit 61, converted by the data conversion unit 63 into data from 1 to M according to the output of the power difference detection unit 62, and output to the response request signal generation unit 26 By doing so, even if a large number of transponders 2 exist in the communication area 3, the interrogator 1
And each transponder 2 can communicate with each other. In the fifth embodiment, the winding directions of the conductive wires of the antenna 20 and the sub-antenna 60 are reversed from those in the fourth embodiment, so that the power generation unit 29 and the sub-antenna power generation unit 6
1 can be reversed in polarity, and even when the shape of the sub-antenna 60 is reduced, the power difference can be detected by the power difference detection unit 62 with high accuracy.

As described above, the transponder 2 which can respond in response to the communication start request signal from the interrogator 1 can be automatically controlled according to the judgment result of the communication judging section 17.
Can realize a mobile object identification device capable of reliably performing a communication operation with a simple communication method and a low power consumption with the plurality of transponders 2 in the communication area 3.

[0059]

As described above, according to the present invention, the interrogator generates the first communication start request signal from the communication request signal generator and transmits it to the responder. A transponder that can communicate with the response request signal is selected from a plurality of transponders received in N time slots synchronized with the start request signal, and a response request signal from the transponder in all time slots is determined by the communication determination unit. , The second communication start request signal is output again, and a response request signal from the transponder is received in N × M timeslots. Select,
Necessary information is communicated with the transponder, and the transponder is provided with two random number generators and a response communication request signal generator which can be calculated by simple processing, and transmits a communication start request signal from the interrogator to the transponder controller. In the case of the first communication start request signal, the response request signal generation unit generates a delay timing synchronized with the first communication start request signal using one output of the random number generation unit, and sends a response request to the interrogator. A signal is transmitted, and in the case of the second communication start request signal, the response request signal is transmitted at a timing obtained by combining the outputs of the two random number generators, so that a simple communication method and low power consumption within the communication area can be achieved. An advantageous effect is obtained that a time slot can be varied according to the number of transponders, and a mobile object identification device that performs reliable communication operation with a plurality of transponders can be realized.

[Brief description of the drawings]

FIG. 1 is a conceptual diagram showing a relationship between a communication area of an interrogator and a transponder according to an embodiment of the present invention.

FIG. 2 is a schematic configuration diagram of an interrogator and a transponder according to the first embodiment of the present invention;

FIG. 3 is a timing chart showing a communication operation between the interrogator and the transponder according to the embodiment of the present invention.

FIG. 4 is a timing chart showing a communication operation between the interrogator and the transponder according to the embodiment of the present invention.

FIG. 5 is a schematic configuration diagram of a transponder according to a second embodiment of the present invention.

FIG. 6 is a schematic configuration diagram of a transponder according to a third embodiment of the present invention.

FIG. 7 is a schematic configuration diagram of a transponder according to a fourth embodiment of the present invention.

FIG. 8 shows a transponder IC according to a fourth embodiment of the present invention.
Plan view showing antenna layout on card

FIG. 9 shows a transponder IC according to a fourth embodiment of the present invention.
FIG. 7 is a plan view showing another embodiment of the arrangement of the antenna in the card.

FIG. 10 is a conceptual diagram for explaining a conventional moving object identification device.

FIG. 11 is a timing chart for explaining a communication method of a conventional mobile object identification device.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 interrogator 2, 2 a to 2 e transponder 3 communication area 11 interrogator control unit 12 request signal generation unit 13 transmission antenna 14 transmission amplifier 15 reception antenna 16 reception demodulation unit 17 communication determination unit 18 timing signal generation unit 20 antenna 21 switch 22 Reception demodulation unit 23 transponder control unit 24 first random number generation unit 25 second random number generation unit 26 response request signal generation unit 27 memory unit 28 transmission unit 29 power generation unit 30 time slot 31 communication frame 32 slot group 50 comparison unit Reference Signs List 51 constant generation unit 60 sub-antenna 61 sub-antenna power generation unit 62 power difference detection unit 63 data conversion unit 64 IC card

 ──────────────────────────────────────────────────続 き Continued on the front page F-term (reference)

Claims (14)

[Claims] 1. An interrogator for communicating between a mobile having a transponder and the transponder, wherein the interrogator generates a communication start request signal and a time synchronized with the communication start request signal. A communication determining unit for selecting a transponder capable of communication from a response request signal from the transponder received in the slot, wherein the interrogator transmits a first communication start request signal, and the communication determining unit transmits the first communication start request signal from one transponder. When receiving the response request signal, the communication unit communicates with the transponder.When the communication determination unit receives the response request signal from the plurality of transponders, the communication determination unit transmits the second communication start request signal. A mobile object identification device, which receives a response request signal from a transponder and selects a transponder capable of communication. 2. The mobile object identification device according to claim 1, wherein the plurality of time slot groups include a plurality of slot groups including a plurality of time slots. 3. The transponder transmits a response request signal to the first communication start request signal at a delay timing synchronized with the first communication start request signal by outputting a first random number, and responds to the second communication start request signal. The mobile object identification device according to claim 1, wherein a response request signal is transmitted to the request signal at a timing obtained by combining the first and second random number outputs. 4. An interrogator, comprising: a communication request signal generator for generating a plurality of communication request signals; a transmitter for transmitting the communication request signal; a reception demodulator for receiving and demodulating a signal received from a transponder; 2. The communication device according to claim 1, further comprising: a communication determination unit connected to the reception demodulation unit for selecting a transponder capable of communication from communication request signals from the plurality of transponders; and a timing signal generation unit for generating wireless communication timing of the interrogator. Moving object identification device. 5. A transponder comprising: a receiving and demodulating section for receiving and demodulating a transmission signal from an interrogator; a random number generating section for generating a random number; a memory section holding information unique to the transponder; A response request signal generator that determines the timing of a signal to be transmitted by the transmitter, a transmitter that transmits the output of the response request signal generator together with the data of the memory unit to the interrogator, and drives each unit from a radio wave transmitted from the interrogator. The mobile object identification device according to claim 1, further comprising: a power generation unit configured to generate power. 6. The mobile object identification device according to claim 5, wherein there are two random number generation units. 7. The mobile object identification device according to claim 6, wherein one output of the random number generator is a predetermined fixed pattern. 8. A single random number generator, which compares the output of the random number generator with the communication code included in the communication start request signal from the interrogator. The mobile object identification device according to claim 1, wherein the mobile object identification device outputs a response request signal in time. 9. A mobile object identification device in which an interrogator identifies a plurality of transponders in a communication area in which a plurality of transponders may exist, wherein the transponder includes an antenna for wirelessly communicating with the interrogator by radio waves, and A reception demodulation unit connected to receive and demodulate a transmission signal from the interrogator, a transponder control unit connected to the reception demodulation unit, and two random number generation units connected to the transponder control unit and generating random numbers, A memory unit for storing information unique to the transponder, and a response request signal generation unit connected to the transponder control unit and determining the timing of a signal transmitted by combining one or two of the outputs of the random number generation unit A transmitting unit for transmitting the data of the memory unit from the antenna to the interrogator in accordance with an output of the response request signal generating unit; and an electronic circuit connected to the antenna and transmitting electric waves from the interrogator. The interrogator includes an interrogator controller for controlling various functions of the interrogator, and a communication request signal generator connected to the interrogator controller for generating a plurality of signals. A transmission unit connected to the communication request signal generation unit, a transmission antenna connected to the transmission unit for wirelessly transmitting a signal to a transponder in a communication area, and a reception antenna for receiving a signal from the transponder. ,
A reception demodulation unit connected to the reception antenna, a communication determination unit connected to the reception demodulation unit and selecting a transponder capable of communicating from transmission signals from a plurality of transponders, and generating a radio communication timing of the interrogator. A moving object identification device including a timing signal generator. 10. The moving object identification device according to claim 9, further comprising a comparison unit that receives one of the random number generation units of the transponder and an output of the transponder control unit as an input signal and outputs a result to the response request signal generation unit. 11. The moving object identification apparatus according to claim 9, wherein one of the random number generators of the transponder is a constant generator that generates a predetermined fixed pattern. 12. A mobile object identification device in which an interrogator identifies a plurality of transponders in a communication area where a plurality of transponders may exist, wherein the transponder includes an antenna that wirelessly communicates with the interrogator by radio waves, A receiving and demodulating unit connected and receiving and demodulating a transmission signal from the interrogator; a transponder control unit connected to the receiving and demodulating unit; a random number generating unit connected to the transponder control unit and generating a random number; A memory unit holding unique information, a power generation unit connected to the antenna and generating power consumed by each electronic circuit from a transmission radio wave from an interrogator, a sub-antenna, and a query connected to the sub-antenna. A sub-antenna power generation unit that generates power from a transmission signal from a transmitter, a power difference detection unit that is connected to the sub-antenna power generation unit and the power generation unit, and detects a difference between respective power values, A data conversion unit connected to the power difference detection unit and generating a pattern according to the output of the power difference detection unit;
A response request signal generation unit connected to the transponder control unit and determining the timing of a signal to be transmitted to the interrogator by combining one or two of the outputs of the random number generation unit and the data conversion unit; A transmitting unit for transmitting the data of the memory unit from the antenna to the interrogator in accordance with an output of the generating unit, wherein the interrogator is an interrogator control unit that controls various functions of the interrogator; A communication request signal generator connected to the controller for generating a plurality of signals, a transmitter connected to the communication request signal generator, and wirelessly transmitting a signal to a transponder connected to the transmitter and in a communication area A transmitting antenna, a receiving antenna for receiving a signal from the transponder, a receiving demodulator connected to the receiving antenna, and a transponder connected to the receiving demodulator and capable of communicating from transmission signals from a plurality of transponders. A communication determination section for constant, mobile identification device having a timing signal generator for generating a radio communication timing of the interrogator. 13. The moving object identification device according to claim 12, wherein the sub-antenna and the antenna are formed of loop antennas, and each of the loops has the same winding direction. 14. The moving object identification device according to claim 12, wherein the sub-antenna and the antenna are configured by loop antennas, and the winding directions of the respective loops are opposite.