JPH07140236A - Radio response system - Google Patents

Abstract

PURPOSE:To prevent response waves from interfering with each other by causing the control portions of responders to generate response signals in different timing, and causing the transmitting portions of response portions to transmit response waves in response to the response signals. CONSTITUTION:When interrogation is made to responders 2, 3, the control portion of an interrogator 1 generates interrogation signals a predetermined number of times. A transmitting portion transmits an interrogation wave (a) from an antenna in response to the interrogation signal. When the antenna of the responder 2 receives the first signal of the interrogation wave (a), the control portion and a transmitter circuit are operated on D.C. power; a CPU then generates random numbers and generates a response signal corresponding to the random numbers; when the response signal from the CPU is received, a response wave (b) is generated from the antenna. When the responder 3 receives the interrogation wave (a), the CPU also generates random numbers and generates a response signal corresponding to the random numbers. The responder 3 transmits a response wave (c) in response to the response signal. The response wave (c) is transmitted in different timing from that of the response wave (b).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless response system for wirelessly checking the condition of a remote place.

[0002]

2. Description of the Related Art A wireless response system includes an interrogator that wirelessly transmits an inquiry wave for an inquiry, and a transponder that transmits a response wave to the interrogator in response to the inquiry wave. The transponder is installed in the communication area of the interrogator, and when receiving the interrogation wave from the interrogator, the transponder starts its operation by using the power of the interrogation wave and transmits the response wave to the interrogator.

With this wireless response system, the state of a remote installation place can be monitored without supplying power to the responder. Such a wireless response system is disclosed in Japanese Patent Application Laid-Open No. 4-147082.

[0004]

When monitoring a plurality of places using this wireless response system, it is conceivable to install a plurality of responders in the communication area. However, in response to the interrogation wave from the interrogator, a plurality of transponders transmit the response wave, so that the interrogation waves interfere with each other, and the interrogator cannot normally receive the data from the transponder.

The object of the present invention is to eliminate the above drawbacks and to provide a wireless response system in which an interrogator can normally receive data from each responder even if a plurality of responders are installed in a communication area. Especially.

[0006]

In order to achieve the object, the present invention has an interrogator for transmitting an interrogation wave for an inquiry, and a plurality of transponders for transmitting an answer wave to the interrogator when the interrogation wave is received. Each responder includes an antenna that generates a reception signal when receiving an interrogation wave, a power supply unit that generates power based on the reception signal from the antenna, and a response signal that starts operating with the power of the power supply unit. In a wireless response system including a control unit that generates a response wave from the antenna and a transmission unit that transmits a response wave from the antenna using a response signal from the control unit, each control unit generates a response signal at a different timing.

[0007]

With this configuration, a plurality of transponders are installed for one interrogator. When making an inquiry to a transponder,
The interrogator sends an interrogation wave.

The antenna of each transponder generates a reception signal when receiving the interrogation wave, and the power supply section generates electric power based on the reception signal. The control unit starts operation with this power, generates a response signal, and sends it to the transmission unit. At this time, the control unit of each transponder generates a response signal at different timing. The transmission unit transmits a response wave from the antenna to the interrogator by using the response signal from the control unit.

The interrogator receives the response waves transmitted from the transponders at different timings.

[0010]

Embodiments of the present invention will now be described with reference to the drawings.

[First Embodiment] FIG. 1 shows a first embodiment of the present invention.
It is a block diagram showing. This wireless response system includes an interrogator 1 that transmits an inquiry wave a for an inquiry, and responders 2 and 3 that respectively transmit response waves b and c to the interrogator 1 when the inquiry wave a is received. The transponders 2 and 3 are installed in different places within the communication area of the interrogator 1 and monitor the state of the installation place.

As shown in FIG. 2, the interrogator 1 of the wireless response system includes a control unit 11, a transmission unit 12, and an antenna 13.
And a receiving unit 14.

The control unit 11 of the interrogator 1 generates an inquiry signal for inquiry and sends it to the transmission unit 12. Control unit 11
Sends the inquiry signal a predetermined number of times to the transmitting unit 12.
Send to. Further, when the control unit 11 receives the reception signal from the reception unit 14, the control unit 11 extracts data from this signal.

Upon receiving the interrogation signal from the control unit 11, the transmission unit 12 transmits a high frequency signal from the antenna 13 as the interrogation wave a. At this time, since the number of times of transmitting the transmission signal is determined, the transmitter 12 transmits the interrogation wave a for this number of times.

In the receiving unit 14, the antenna 13 has the transponders 2,
When the response waves b and c from 3 are received, a reception signal is generated and sent to the control unit 11.

The interrogator 1 has such a structure.

As shown in FIG. 3, the transponder 2 of the wireless response system includes an antenna 21, a power supply section 22, and a control section 23.
And a transmission circuit 24 as a transmission unit. Power supply 2
2 includes a rectifier circuit 22A and a power supply circuit 22B, and the control unit 23 includes a ROM (Read Only Memory) 23A and a CPU.
(Central Processing Unit) 23B.

The rectifier circuit 22A of the transponder 2 is the antenna 2
1 rectifies the interrogation wave a received, that is, the high frequency power.

The power supply circuit 22B converts the high frequency power rectified by the rectification circuit 22A into DC power. Then, the DC power is supplied to the ROM 23A, the CPU 23B, and the transmission circuit 24.

The ROM 23A stores in advance data relating to the place where the device is installed. ROM23A
Is supplied to the CPU 23 by the DC power from the power supply circuit 22B.
The data can be read by B.

The CPU 23B starts its operation by the DC power from the power supply circuit 22B and generates a random number. CPU23B
Responds to the interrogation wave a having a rank corresponding to the generated random number. That is, when the antenna 21 receives the interrogation wave of the order corresponding to the random number, the CPU 23B reads the data from the ROM 23A and sets it as the response signal. Also, the CPU 23B
Stands by until the antenna 21 receives all of the determined number of interrogation waves a.

The transmission circuit 24 transmits from the antenna 21 the response wave b modulated by the response signal from the CPU 23B.

The transponder 2 has such a structure. The responder 3 has the same configuration as the responder 2.

Next, the operation of the first embodiment will be described.

When making an inquiry to the responders 2 and 3, the control unit 11 of the interrogator 1 generates an inquiry signal as shown in FIG. At this time, the control unit 11 generates the inquiry signal a predetermined number of times. When the transmitter 12 receives the inquiry signal, the transmitter 13 transmits the inquiry wave a from the antenna 13.

When the antenna 21 of the transponder 2 receives the first signal 101 of the interrogation wave a, the rectifier circuit 22A rectifies the high frequency power of the interrogation wave a and the power supply circuit 22B converts it into DC power. The control unit 23 and the transmission circuit 24 operate with this DC power.

The CPU 23B generates a random number and responds with the third signal 103 of the inquiry signal corresponding to this random number. That is, the CPU 23B ignores the second signal 102 of the inquiry signal, and the ROM after the end of the third signal 103.
Data is read from 23A and a response signal is generated. Upon receiving the response signal from the CPU 23B, the transmission circuit 24 generates the response wave b from the antenna 21.

On the other hand, when the interrogator 3 also receives the interrogation wave a, the CPU 23B produces a random number and produces a response signal after the fourth signal 104 of the interrogation signal corresponding to the random number is finished. Then, the responder 3 transmits a response wave c by this response signal. At this time, the response wave c is transmitted at a different timing from the response wave b.

The receiver 14 of the interrogator 1 generates received signals from the response waves b and c received by the antenna 13 and sends them to the controller 11. The control unit 11 reads out the data of the responders 2 and 3 from the received signal.

As described above, according to the first embodiment, the transponder 2,
The CPU 23B of No. 3 generates a random number and generates a response signal corresponding to each random number.
Thus, the interference between the response wave b and the response wave c can be prevented. As a result, the interrogator 1 can normally receive the data from the responders 2 and 3.

In addition, the question by the interrogator 1 and the responder 2,
By repeating the response by 3, the probability that the interrogator 1 can normally receive the response waves b and c approaches 1 and reliable communication between the interrogator 1 and the responders 2 and 3 is enabled. .

Although the two transponders 2 and 3 are installed in the communication area of the interrogator 1 in the first embodiment, the present invention is not limited to this. At this time, the number of transponders installed can be increased or decreased by adjusting the number of digits of the random number of the control unit of each transponder.

[Second Embodiment] In the wireless response system of the second embodiment, the control of the control unit 11 of the interrogator 1 of the first embodiment and the control of the CPU 23B of the responders 2 and 3 are different from those of the first embodiment. Is. That is, in the second embodiment, as shown in FIG. 5, the timing of signal generation, that is, the time slots 201 to 206 for signal generation are set.
When making an inquiry to the responders 2 and 3, the control unit 11 of the interrogator 1 generates an inquiry signal in the time slots 201 and 204. The interrogator 1 transmits an interrogation wave a by this interrogation signal.

A time slot 205 is assigned to the responder 2. That is, in the responder 2, when the interrogation wave a is received, the CPU 23B waits until the time slot 204 and generates a response signal in the time slot 205. As a result, the response wave b is transmitted from the transponder 2.

On the other hand, the responder 3 has a time slot 20
6 is assigned. The CPU 23B of the responder 3
Wait until time slot 205, time slot 20
At 6, a response signal is generated. As a result, the response wave c is transmitted from the transponder 3.

When the interrogator 1 receives the response waves b and c,
The data of the responders 2 and 3 are read from the received signal.

As described above, different time slots are assigned to the responders 2 and 3, and the responders 2 and 3 are assigned different time slots.
Since the response waves b and c are transmitted in the time slot of the own device, it is possible to prevent interference between the response waves b and c.

In the second embodiment, two transponders 2 and 3 are installed in the communication area of the interrogator 1, but the number of transponders installed is not limited to this. At this time, the number of time slots is increased by the number of responders.

[Third Embodiment] In the wireless response system of the third embodiment, the control of the control unit 23 of the transponders 2 and 3 is different from that of the first embodiment. That is, in the third embodiment, the ROM 23A of the responder 2 stores the waiting time T1 until the response signal is generated in advance, and the ROM 23A of the responder 3 stores the waiting time T2 in advance.

When making an inquiry, the interrogator 1 is shown in FIG.
The interrogation wave a is transmitted by the interrogation signal as shown in FIG. Transponder 2
Starts operation when it receives the interrogation wave a, and the CPU 23B
Reads the standby time T1 from the ROM 23A. CPU
23B reads the data from the ROM 23A when the waiting time T1 elapses after the end of the inquiry signal. Transponder 2
Causes the response wave b to be transmitted.

When the interrogator 3 receives the interrogation wave a, the transponder 3 starts its operation, and the CPU 23B reads the waiting time T2 from the ROM 23A. Similar to the transponder 2, the CPU 23B reads the data from the ROM 23A when the waiting time T2 elapses. As a result, the transponder 3 transmits the response wave c.

When the interrogator 1 receives the response waves b and c,
The data of the responder 2 is read from the received signal.

As described above, the responder 2 and the responder 3 store different waiting times T1 and T2, and when the waiting times T1 and T2 elapse, the responding waves b and c are respectively transmitted, so that the responding waves b and It is possible to prevent interference with the response wave c.

In the third embodiment, the two responders 2 and 3 are installed in the communication area of the interrogator 1, but the invention is not limited to this. At this time, the number of waiting times is increased by the number of responders.

[0045]

As described above, according to the present invention, the control unit of each transponder generates a response signal at different timing, and the transmission unit of each transponder transmits the response wave by this response signal. It is possible to prevent the response waves from interfering with each other. As a result, even if a plurality of transponders are installed for one interrogator, the interrogator can normally receive the response wave from each transponder.

[Brief description of drawings]

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

FIG. 2 is a block diagram showing an example of an interrogator.

FIG. 3 is a block diagram showing an example of a transponder.

FIG. 4 is a waveform diagram for explaining the first embodiment.

FIG. 5 is a waveform diagram for explaining the second embodiment.

FIG. 6 is a waveform diagram for explaining the third embodiment.

[Explanation of symbols]

 1 Interrogator 2,3 Responder a Interrogation wave b, c Response wave

Claims (4)

[Claims] 1. An interrogator that transmits an interrogation wave for an inquiry, and a plurality of transponders that transmit an interrogation wave to the interrogator when the interrogation wave is received. Each of the transponders receives the interrogation wave. Then, an antenna that generates a reception signal, a power supply unit that generates electric power based on the reception signal from the antenna, a control unit that starts an operation by the electric power of the power supply unit and generates a response signal, and the control unit A radio response system comprising: a transmission unit that transmits a response wave from the antenna using a response signal, wherein each of the control units generates a response signal at a different timing. 2. The wireless response system according to claim 1, wherein each of the control units generates a random number by receiving an interrogation wave and generates a response signal at a timing corresponding to the random number. 3. The control unit is pre-assigned a time slot for generating a response signal, and each control unit generates a response signal at its own time slot. The wireless response system described. 4. The wireless response system according to claim 1, wherein each of the control units stores different standby times in advance and generates a response signal after the standby time from the reception of the interrogation wave.