JPH07174845A - Code responding method, core responder, and code responding system using the code responder - Google Patents

Abstract

PURPOSE:To surely return a code in response to the transmitted electromagnetic wave. CONSTITUTION:The electromagnetic wave from an interrogator 1 is received by a responder antenna 5, converted into a single pulse by a demodulating circuit 7, and fed to a pulse train generating section 8. Delay elements 9a-9z of the pulse train generating section 8 delay the fed pulse in sequence to generate a pulse train staggered in time, and a coding section 11 generates a specific coded pulse train from this pulse train. When pulses of this coded pulse train are inputted, the impedance characteristics of a modulating circuit 14 and a matching circuit 15 are changed, and the responder antenna 5 reflects the electromagnetic wave from the interrogator 1.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a code response method for generating and responding to a received electromagnetic wave by generating a unique or variable code, and a code response for implementing the code response method. And a code response system in which the code response device is used, and in particular, the present invention relates to a code response device by performing wireless communication with a mobile body in which the code response device is mounted. The present invention relates to a technique for reading a code such as an assigned ID code to identify a moving body in a non-contact manner.

[0002]

2. Description of the Related Art Conventionally, a code response in which an ID code is given to a code transponder mounted on a mobile body and the ID code is identified by causing the code transponder to respond by an electric wave emitted from an interrogator. Several systems have been proposed. As the code response method, there are a method of storing an ID code in a semiconductor memory provided in the code responder and making it respond, a method of causing a resonance circuit provided in the code responder to resonate at a unique resonance frequency, and making it respond. is there.

However, for those using a normal semiconductor memory, for backup, and for E ² P
In the case of using the ROM, batteries are required for writing and reading, respectively, and therefore there is a problem that the code transponder becomes large and costly. It is conceivable to supply energy to the memory and CPU inside the code transponder by radio waves from outside without installing a battery, but due to legal restrictions on radiated power, sufficient energy cannot be supplied. It is difficult to extend the distance and not practical. On the other hand, in the case of using the resonance circuit, if the number of code transponders to be identified increases, there is a problem that many resonance frequencies are required for setting the ID code.

In order to solve the above problems, the applicant has recently identified a delay element for receiving a pulse signal from an interrogator in a code transponder to generate a time-series pulse train and a pulse train from the delay element. Has proposed a code transponder which is compact and does not require a battery, which is provided with a code generator for generating the code (Japanese Patent Laid-Open No. 4-259876).

[0005]

However, in the above configuration, the pulse signal from the interrogator received by the code transponder is attenuated in the code transponder, and the final output becomes weak, so that the interrogator is weakened. If the distance between the transponder and the transponder becomes long, there is a problem that the interrogator side cannot accurately read the code received from the transponder.

The present invention has been made in view of the above problems, and changes the reflectance of the electromagnetic wave from the interrogator in accordance with the unique or variable code generated by the code transponder to change the interrogator. It is an object of the present invention to provide a code response method for improving the reading accuracy of a code on the side, a code response device for implementing the method, and a code response system using the code response device.

[0007]

According to a first aspect of the present invention, there is provided a code response method for generating a code and responding to the reception of an electromagnetic wave sent thereto. After the pulse is generated, the pulse is converted into a time-series pulse train, the pulse train is encoded to generate the code, and the reflectance of the electromagnetic wave is changed in accordance with the code to thereby generate the electromagnetic wave. It is characterized in that it responds to the reception of.

In the invention of claim 2, the code is a fixed unique code, and in the invention of claim 3, it is a variable code which is not fixed.

According to a fourth aspect of the present invention, there is provided a code transponder for generating and responding to a received electromagnetic wave by receiving a code, the receiving means receiving the electromagnetic wave, and the electromagnetic wave generated by the receiving means. Pulse generation means for generating a single pulse for the reception of, pulse train generation means for sequentially delaying the pulses generated by the pulse generation means to generate a time-series pulse train, and the pulse train generation means. Coding means for performing coding with the pulse train to generate a coded pulse train corresponding to the code, and changing the impedance viewed from the receiving means in correspondence with the coded pulse train obtained by the coding means. Control means for changing the reflectance of the electromagnetic wave.

The encoding means is means for generating an encoded pulse train corresponding to a fixed unique code in the invention of claim 5, and corresponds to a variable code which is not fixed in the invention of claim 6. It is a means for generating a coded pulse train. In the invention of claim 7, the encoding means is means for generating an encoded pulse train corresponding to the code set according to the change of the external factor, and in the invention of claim 8,
It is a means that includes a plurality of bimetal contacts that respond to temperature changes, and that generates a coded pulse train corresponding to a code that is set by a combination of ON and OFF states of each bimetal contact.

A ninth aspect of the present invention is a code response system comprising an interrogator for transmitting an electromagnetic wave and a code responder for generating and responding to a reception of an electromagnetic wave transmitted from the interrogator. The code transponder includes a receiving unit that receives the electromagnetic wave, a pulse generating unit that generates a single pulse for reception of the electromagnetic wave by the receiving unit, and a pulse that the pulse generating unit generates. Pulse train generating means for sequentially delaying and generating a time-series pulse train; coding means for performing coding with the pulse train generated by the pulse train generating means to generate a coded pulse train corresponding to the code; Reflectivity control for changing the reflectivity of the electromagnetic wave by changing the impedance viewed from the receiving means corresponding to the encoded pulse train obtained by the converting means. The interrogator, on the other hand, receives the reflected wave from the code transponder, and the interrogator demodulates the time change of the reflected wave received by the receiving means to read the code. And a reading means.

In the invention of claim 10, the encoding means is means for generating an encoded pulse train corresponding to a fixed unique code, and in the invention of claim 11, it corresponds to a variable code which is not fixed. It is a means for generating a coded pulse train. In the invention of claim 12, the encoding means is means for generating an encoded pulse train corresponding to the code set according to the change of the external factor, and in the invention of claim 13, the encoding means responds to the temperature change. It is a means that includes a plurality of bimetal contacts and that generates a coded pulse train corresponding to a code set by a combination of ON and OFF states of each bimetal contact.

[0013]

According to the code generated by the code transponder, the reflectance of the transmitted electromagnetic wave is changed to respond to the reception of the electromagnetic wave. Therefore, the code is the time of the reflected wave. And the accuracy of reading the code in the interrogator is improved.

According to the present invention, the coded pulse train corresponding to the code is generated, and the impedance seen from the receiving means is changed corresponding to the coded pulse train to reflect the electromagnetic wave transmitted. Change the rate, so
The reflected wave changes greatly even with a pulse having a small amplitude.

In the inventions of claims 2, 5 and 10, the fixed code is sent, and in the inventions of claim 3, 6 and 11, the variable code which is not fixed is sent. It responds by changing the reflectance of incoming electromagnetic waves.

In the seventh and twelfth aspects of the present invention, the code responder generates and responds to a code that changes in response to changes in external factors, so that the interrogator side can obtain information relating to changes in external factors.

In particular, in the inventions of claims 8 and 13, the code responder generates and responds to a variable code set by a combination of a plurality of bimetal contacts, so that the interrogator side obtains information relating to temperature changes. obtain.

[0018]

FIG. 1 shows the overall construction of a code response system according to an embodiment of the present invention. This code response system is for performing wireless communication between an interrogator 1 and a code transponder 4 that is mounted on a mobile body and moves, and the interrogator 1 controls the modulation and demodulation. An interrogator control unit 2 for performing the above and an interrogator antenna 3 for radiating electromagnetic waves are provided.

The code transponder 4 is provided with a transponder antenna 5 for receiving the electromagnetic wave from the interrogator antenna 3, and the received electromagnetic wave is demodulated through an impedance matching circuit 6 (hereinafter simply referred to as "matching circuit 6"). Given to the circuit 7. The demodulation circuit 7 generates a single pulse based on this electromagnetic wave and gives it to the pulse train generation unit 8. The pulse train generation unit 8 includes a plurality of delay elements 9a to 9z that sequentially delay the single pulse, and generates a pulse train composed of a plurality of pulses that are temporally displaced at the output taps 10a to 10z.

Reference numeral 11 in the drawing denotes an encoding unit for performing encoding from the pulse train to generate a code given to the code responder 4, and each pulse from the output taps 10a to 10z is given. Opened / closed terminal portions 12a to 12
with z. The open / close terminal portions 12a, 12c, 12z are closed, the open / close terminal portion 12b is open, and the pulse given to the closed open / close terminal portion appears on the output line 13.
The pulse given to the open / closed terminal portion does not appear on the output line 13. In this way, the output line 13 is connected to the switching terminal portion 1
A pulse train corresponding to the open / closed state of 2a to 12z appears, and thereby the encoding of the pulse on the time axis is executed.

The modulation circuit 14 and the impedance matching circuit 15 (hereinafter simply referred to as "matching circuit 15") are for controlling the impedance viewed from the transponder antenna 5, and the modulation circuit 14 has a code from the output line 13. The impedance of the matching circuit 15 viewed from the transponder antenna 5 is changed when the pulse of the pulse train is input, and the impedance of the matching circuit 15 is held when the pulse is not input.

When the impedance of the matching circuit 15 viewed from the transponder antenna 5 changes, the reflectance of the electromagnetic wave received by the transponder antenna 5 changes, and the interrogator antenna 3 in the interrogator 1 changes this reflected wave. When receiving, the interrogator control unit 2 demodulates the temporal change of the reflected wave and reads the impedance change of the matching circuit 15 of the code responder 4, that is, the code generated by the encoding unit 11.

FIG. 2 shows a concrete example of a code response system which handles a 5-bit code, and FIG. 3 shows a timing chart of the circuit of FIG. In the system illustrated example, interrogator 1, 10 as shown in FIG. 3 (a), usually has outputs a carrier wave 19 of a predetermined frequency from the interrogator antenna 3, at time t _1, for example by a rectangular pulse
By applying 0% amplitude modulation, the transmission of the carrier wave 19 is temporarily stopped. The time interval t ₀ for interrupting the carrier wave 19 is set to a time shorter than the delay time of each of the delay elements 9a to 9e so that the output pulses from the pulse train generation unit 8 of the code responder 4 will not overlap. To be done.

Each of the matching circuits 6 and 15 of the code transponder 4 is composed of a passive element which does not particularly require a power source, and is normally set to maintain a constant impedance. FIG. 4 is a Smith chart showing impedances of the matching circuit 6 and the matching circuit 15 viewed from the transponder antenna 5. The impedance of the matching circuit 6 is normally adjusted to the position of the point A to achieve matching, and the impedance of the matching circuit 15 is set to the position of the point B, that is, infinity. Thus, the electromagnetic wave received from the transponder antenna 5 is matched with the matching circuit 6
Is absorbed non-reflectively toward and is input to the demodulation circuit 7.

The demodulation circuit 7 is a low pass filter including a diode 7a and a high impedance line 7b,
The high frequency component of the carrier wave received by the transponder antenna 5 is removed, and in response to the interruption of the carrier wave, as shown in FIG.
As shown in (b), a single rectangular pulse p ₁ is generated at the corresponding time t ₁ , and this is given to the pulse train generation unit 8.
The high impedance line 7b is composed of a microstrip line or the like and can be sufficiently miniaturized.

The pulse train generator 8 includes five delay elements 9a.
Is constituted by ～9E, FIG 3 (c) ~ (g), the single pulse p ₂ at time t ₂ ~t ₆ respectively
-P ₆ are generated at the corresponding output taps 10a-10e.

The encoding section 11 includes five open / close terminal sections 12a ...
12e, each of the open / close terminal portions 12a-12
An ID code corresponding to this code responder 4 is generated by e. In the illustrated example, the switching terminal portions 12a, 12d, 12
Since e is closed and the open / close terminal portions 12b and 12c are open, the open / close terminal portions 12a and 1c are opened as shown in FIG.
The pulses p _2, p ₅ and p ₆ given to 2d and 12e appear on the output line 13. In this embodiment, the state in which the open / close terminal unit is closed and the pulse of the pulse train generation unit 8 is transmitted to the output line 13 is data “1”, the open / close terminal unit is open and the pulse of the pulse train generation unit 8 is output line. The state that does not appear in 13 is set as the data “0”, and by this, the encoding unit 1
1 generates an ID code "10011".

The modulation circuit 14 includes a diode 14a and a high impedance line 14b,
When each pulse of the encoded pulse train is given from the output line 13, the diode 14a is biased and its impedance characteristic is changed.
In response to this, the impedance of the matching circuit 15 side viewed from the transponder antenna 5 also changes. In the present embodiment, the impedance of the matching circuit 15 is set so as to be in the state of point C on the Smith chart of FIG. 4, that is, 0 when the diode 14a is biased.

When the impedance of the matching circuit 15 becomes 0, the combined impedance of the matching circuit 6 and the matching circuit 15 connected in parallel also becomes 0 when viewed from the transponder antenna 5, so that there is no carrier wave due to the aforementioned impedance matching. The reflection condition is broken, and the transponder antenna 5 becomes the interrogator antenna 3
Reflects the carrier from.

On the other hand, when no pulse is input from the encoding section 11, the diode 14a of the modulation circuit 14 is not biased, so that the matching circuit 15 holds a normal impedance and the carrier reflection-free condition by impedance matching is satisfied. Is also retained. FIG. 3 (i) shows the output state of the reflected wave from the transponder antenna 5, and corresponds to the appearance of the pulses p ₂ , p ₅ , p ₆ at times t ₂ , t ₅ ,
The carrier wave is reflected at t ₆ . After this reflected wave is received by the interrogator antenna 3, it is demodulated by the interrogator control unit 2,
The code generated by the encoding unit 11 is read.

FIG. 5 shows the overall construction of a code response system according to another embodiment of the present invention.
The code responder 4 outputs the modulated wave modulated by a specific code.
To send to.

The code transponder 4 receives the modulated wave from the interrogator antenna 3 at the transponder antenna 5, and the received modulated wave is given to the correlator 16 via the matching circuit 6. An identification code that matches the code of the modulated wave transmitted from the interrogator 1 is given to the correlator 16, and the correlator 16 receives the modulated wave to generate a pulse, and the pulse train generation unit 8
Given to.

Similar to the first embodiment, the pulse train generation unit 8 sequentially delays the given pulse by the delay elements 9a to 9z, and outputs a pulse train composed of a plurality of time-shifted pulses to the output taps 10a to 10z. To generate. Output tap 1
The pulse train input to the encoding unit 11 from 0a to 10z is encoded on the time axis according to the open / closed state of each open / close terminal unit 12a to 12z.

The pulse train generated on the output line 13 is input to the signal conversion circuit 17. This signal conversion circuit 17
Removes high-frequency components from the pulse appearing on the output line 13 and converts the pulse into a regular pulse. The modulation circuit 14 and the matching circuit 15 have the same configuration as that of the first embodiment, and when receiving a pulse from the signal conversion circuit 17, change the impedance of the matching circuit 15 viewed from the transponder antenna 5. Based on this impedance change, the reflectivity of the electromagnetic wave received by the transponder antenna 5 changes, and the interrogator control unit 2 of the interrogator 1 demodulates the temporal change of the reflected wave to obtain the code of the code transponder 4. The code generated by the conversion unit 11 is read.

FIG. 6 shows a specific example of handling the 5-bit code in the code response system shown in FIG. 5, and FIG. 7 shows a timing chart of the circuit shown in FIG. The setting of the impedance characteristics of the matching circuit 6 and the matching circuit 15 is similar to that of the embodiment shown in FIG. 2 described above, and corresponds to each point on the Smith chart of FIG.

The interrogator antenna 3 of the interrogator 1 is shown in FIG.
As shown in (a), after outputting the PSK wave 20 modulated by the specific identification code, the carrier wave 21 is output at a time interval corresponding to the response time from the code responder 4.

The code responder 4 uses S as the correlator 16.
It has an AW correlator 16 '. An identification code according to the characteristics of the PSK wave 20 output from the interrogator 3 is set in the SAW correlator 16 ', and FIG.
As shown in (b), at time T ₂ delayed by a predetermined time from time T _{0 when} transmission of all bits of PSK wave 20 is completed, SA
A pulse modulated wave P ₁ containing a high frequency burst signal is output from the W correlator 16 '.

This pulse modulated wave P ₁ is generated by the pulse train generator 8
Given to, and sequentially delayed by the delay element predetermined time 9a~9e the pulse train generating unit 8 as shown in FIG. 7 (c) ~ (g) , at time T ₂ through T _6, respectively, pulse modulation wave P ₂
~ P ₆ is generated at output taps 10a-10e.

Each of the open / close terminal portions 12a to 12 of the encoding portion 11
Similarly to the embodiment shown in FIG. 2, e is set so as to generate an ID code corresponding to the code responder 4, and based on this, as shown in FIG. The pulse-modulated waves P ₂ , P ₅ , and P ₆ given to 12a, 12d, and 12e appear on the output line 13, and a pulse train representing the ID code "10011" is generated.

FIG. 8 shows the configuration of the signal conversion circuit 17.
The signal conversion circuit 17 is composed of a diode 17a and a high impedance line 17b, removes a high frequency burst signal from each pulse modulated wave P appearing on the output line 13, and outputs a pulse P'having only a positive voltage. To generate. As a result, as shown in FIG. 7 (i), the pulse-modulated waves P ₂ , P ₅ , P ₆ have pulses P ₂ ′, P ₅ having a positive voltage while maintaining temporal continuity.
′, P ₆ ′ and supplied to the modulation circuit 14.

The modulation circuit 14 has the same configuration as that of FIG. 2, and the diode 14a is biased according to the input of each pulse P ₂ ′, P ₅ ′, P ₆ ′, and its impedance characteristic changes. . As a result, the impedance when the matching circuit 15 side is viewed from the transponder antenna 5 becomes "0", the non-reflection condition of the carrier wave is broken, and the transponder antenna 5 reflects the carrier wave 21 from the interrogator 1. Interrogator control unit 2
Reads the code generated by the code transponder 4 by demodulating the time change of the reflected wave. The signal conversion circuit 1
It is also possible to reverse the direction of the diode 17a of No. 7 and convert the pulse from the output line 13 into a pulse having a negative voltage. In this case, by also reversing the direction of the diode 14a of the conversion circuit 14, The same operation as can be obtained.

In the code transponder 4 described above, the SAW correlator 16 is set so as to respond only to the PSK wave modulated by the specific code, so that the code transponders 4 of a plurality of systems are mixed. Even if the PSK wave code is assigned to each system in advance, a response can be obtained only from the code responder 4 of the desired system by controlling the PSK wave code emitted from the interrogator 1. . In this way, the individual code transponders 4 can be identified for each system, and CDMA (code sequence multi-access) can be performed. SAW correlator 1
Since the call code of the system can be determined by the structure of 6, it is difficult to forge and a highly confidential system can be constructed.

Note that the above shows an embodiment in which a fixed unique code is generated and responds, but the present invention is not limited to this, and it is also possible to generate a variable code that is not fixed and respond. Yes, a specific example is shown in FIG.

The code response system shown in FIG. 9 has substantially the same configuration as the code response system shown in FIG. 1, except that a plurality of bimetal contacts which are opened / closed as the opening / closing terminal portions 12a to 12z of the encoding unit 11 by temperature change. 24a to 24z are used.

Among these bimetal contacts, for example, the first bimetal contact 24a is 0 ° C., and the second bimetal contact 2 is
4b is 5 ° C, third bimetal contact 24c is 10 ° C
, And the like, which respond to different temperatures, and the open / closed state of each open / close terminal unit changes in response to a temperature change, a code that changes in response to a temperature change is generated. The bimetal contacts 24a to 24z
Can also be introduced into the second embodiment shown in FIG.

Further, as the open / close terminal portions 12a to 12z, not only the bimetal contact but also semiconductors having different impurity concentrations and different conductivity depending on temperature can be used. In addition to the means for responding to temperature changes, the open / close terminal portions 12a to 12z include phototransistors, CdS, etc.
It is also possible to use a means that responds to a change in the amount of received light, or a means that responds to an external force, such as a thin plate-shaped vibration sensor.

[0047]

As described above, according to the present invention, a unique or variable code is generated in response to the received electromagnetic wave, and the reflectance of the sent electromagnetic wave is changed according to the code. By doing so, since it responds to the reception of the electromagnetic wave, it is possible to replace the code with the temporal change of the reflected wave and transmit it, so that the accuracy of reading the code in the interrogator is improved.

According to the present invention, the coded pulse train corresponding to the code is generated, and the impedance seen from the receiving means is changed corresponding to the coded pulse train to reflect the electromagnetic wave transmitted. Change the rate,
The reflected wave can be greatly changed even with a pulse having a small amplitude.

According to the seventh and twelfth aspects of the invention, the code responder generates and responds to a code that changes in response to changes in external factors, so that the interrogator side can obtain information relating to changes in external factors. Particularly, in the inventions of claims 8 and 13, the code responder generates and responds to a variable code set by a combination of a plurality of bimetals, so that the interrogator side can obtain information relating to the temperature change.

[Brief description of drawings]

FIG. 1 is a block diagram showing an overall configuration of a code response system according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a specific example of the code response system in FIG.

FIG. 3 is a timing chart showing the operation of the circuit shown in FIG.

FIG. 4 is a Smith chart showing the impedance of each matching circuit.

FIG. 5 is a block diagram showing an overall configuration of a code response system according to another embodiment of the present invention.

FIG. 6 is a block diagram showing a specific example of the code response system of FIG.

FIG. 7 is a timing chart showing the operation of the circuit shown in FIG.

FIG. 8 is a circuit diagram showing a configuration of a signal conversion circuit.

FIG. 9 is a block diagram showing an overall configuration of a code response system according to another embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Interrogator 4 Code responder 5 Responder antenna 6,15 Impedance matching circuit 7 Demodulation circuit 8 Pulse train generation unit 11 Encoding unit 14 Modulation circuit 24a-24z Bimetal contact

Claims (13)

[Claims] 1. A code response method for generating a code and responding to reception of an electromagnetic wave transmitted, wherein a single pulse is generated by the reception of the electromagnetic wave, and the pulse is generated in a time series. After being converted into a pulse train, encoding is performed by the pulse train to generate the code, and the reflectance of the electromagnetic wave is changed corresponding to the code to respond to reception of the electromagnetic wave. Code response method. 2. The code response method according to claim 1, wherein the code is a fixed unique code. 3. The code response method according to claim 1, wherein the code is a variable code that is not fixed. 4. A code transponder for generating a code and responding to the reception of an electromagnetic wave sent thereto, the receiving means receiving the electromagnetic wave, and the reception of the electromagnetic wave by the receiving means. Pulse generation means for generating a single pulse, pulse train generation means for sequentially delaying the pulses generated by the pulse generation means to generate a time-series pulse train, and encoding by the pulse train generated by the pulse train generation means And encoding means for generating an encoded pulse train corresponding to the code, and reflection of the electromagnetic wave by changing the impedance seen by the receiving means in correspondence with the encoded pulse train obtained by the encoding means. And a control means for changing the rate. 5. The code responder according to claim 4, wherein the coding means is means for generating a coded pulse train corresponding to a fixed unique code. 6. The code responder according to claim 4, wherein the coding means is means for generating a coded pulse train corresponding to a variable code which is not fixed. 7. The code transponder according to claim 4, wherein the coding means is means for generating a coded pulse train corresponding to a code set according to a change in an external factor. 8. The encoding means includes a plurality of bimetal contacts that respond to temperature changes, and means for generating an encoded pulse train corresponding to a code set by a combination of ON and OFF states of each bimetal contact. The code transponder according to any one of claims 4, 6, and 7. 9. A code response system comprising an interrogator for transmitting an electromagnetic wave and a code transponder for generating and responding to a reception of an electromagnetic wave transmitted from the interrogator, the code response system comprising: The code transponder is a receiving unit that receives the electromagnetic wave, a pulse generating unit that generates a single pulse for receiving the electromagnetic wave by the receiving unit, and sequentially delays the pulse generated by the pulse generating unit, A pulse train generating means for generating a time-series pulse train; an encoding means for encoding the pulse train generated by the pulse train generating means to generate an encoded pulse train corresponding to the code; and Reflectance control means for changing the reflectance of the electromagnetic wave by changing the impedance viewed from the receiving means in accordance with the encoded pulse train. The interrogator includes a receiving unit that receives the reflected wave from the code responder, and a reading unit that demodulates the temporal change of the reflected wave received by the receiving unit and reads the code. A code response system comprising. 10. The code response system according to claim 9, wherein the encoding means is means for generating an encoded pulse train corresponding to a fixed unique code. 11. The code response system according to claim 9, wherein the coding means is means for generating a coded pulse train corresponding to a variable code that is not fixed. 12. The code response system according to claim 9, wherein the coding means is means for generating a coded pulse train corresponding to a code set according to a change in an external factor. 13. The encoding means includes a plurality of bimetal contacts that respond to temperature changes, and means for generating an encoded pulse train corresponding to a code set by a combination of ON and OFF states of each bimetal contact. The code response system according to any one of claims 9, 11, and 12.