DE4445285A1 - Code response system that uses a change in reflectance of a transmitted electromagnetic wave - Google Patents

Abstract

An electromagnetic wave transmitted from an interrogator 1 is converted into a single pulse (P1, Figs. 3, 7) by circuits 6, 7 in a code responder 4. Delay elements 9a - 9z in a delayed pulse generator 8 delay the single pulse (P1) to generate a series of pulses (P2, P3, P4...) deviated in time from each other. Selected ones of the delayed pulses are combined according to the state of switching elements 12a- 12z in a coder 11 to form a serial bit code. Each pulse in the serial bit code causes the impedance of a circuit 15 to change from an infinite value state, in which a carrier wave transmitted from interrogator 1 is absorbed by responder 4 with no reflection, to a zero value state in which the carrier wave is reflected by responder 4. The single pulse (P1) may be produced by a demodulator 7 in response to an interruption in the interrogator's carrier wave, or only when the carrier wave is modulated by a specific code detected by a SAW correlator (16', Fig. 6) in the responder. The code produced by coder 11 may be fixed or may vary in dependence on external factors. For example the coder switches 12a - 12z may be temperature responsive bimetallic or semiconductor elements, or light responsive elements, or vibration sensors responsive to external force. <IMAGE>

Description

The invention relates to a code response system, where a code answer to one from an interrogator transmitted electromagnetic wave upon receipt Generating a fixed or variable code replies. in the individual, the invention relates to a technique for Identification of a moving body in a be contactless way by adding a code, such as an ID code, the code attached to the moving body answer is assigned via performing at for example radio communication with the moving body is provided.

Conventionally, there are already several code answers Systems have been proposed in which an ID code is sent to you a code answer attached to a moving body is assigned and an interrogator the moving body,  the electromagnetic wave sent by the interrogator answers, can identify by its ID code. In One of the code response methods is an ID code in an in Semiconductor memory contained code answer stored. Another method causes one in the Code response included resonant circuit on its own Resonance frequency with oscillates.

In the case of using a conventional semiconductor memory However, a battery is required for support purposes. In case of using an E²PROM a battery is for Write and read operations are also required. The one circuit of a battery increases the dimensions and the costs of the code answer. It would be conceivable to go to a battery do without energy by a memory and a CPU in the Code answering machine using an external electromagnetic table wave is fed. Regarding regulations this is about the electrical radiant power not appropriate; d. that is, a sufficient amount of energy not get what long distance communication prohibits.

On the other hand, the method of using one Resonance circuit also defective in that with increasing number of code responders to be identified the number of reso required to set ID codes frequency increases.

The applicant has already solved the above problems proposed a code answerer that is compact and none Battery needed and made up of delay elements Generation of time-serial pulses in response to a pulse signal from an interrogator and from a code generator for Generation of a special code based on the time rial impulses composed (JP-A-4-259876).

With the above structure, however, this is weakened by the interrogator  emitted pulse signal in the code answer, so that eventual output signal is very weak. Therefore, if the The interrogator and the responder are far apart, the interrogator can write a code based on a response from the Do not determine the answer correctly.

The invention has been made in view of the above problems of the state of the art, whereby the task is based on creating a code response system which Code determination accuracy on the interrogator side verbes can learn by reflecting one of the interrogators transmitted electromagnetic wave in accordance with an inherent or variable code that is in the code responder is generated, is changed.

According to a first aspect of the invention, a code response method comprises the steps of
Generating a single pulse with reception of an electromagnetic wave,
Converting the single pulse into time-serial pulses, generating an encoded signal based on the time-serial pulses in accordance with a code assigned to a code answering machine, and
Responding to the electromagnetic wave by changing a reflectance of the electromagnetic wave in accordance with the encoded signal.

According to a second aspect of the invention comprises a code answering machine
Means for receiving an electromagnetic wave,
Means for generating a single pulse when the receiving means receive the electromagnetic wave,
Means for generating time-serial pulses by sequentially delaying the individual pulse,
Coding means for generating an encoded pulse train based on the time-serial pulses in accordance with a code assigned to the code answering machine, and
Means for changing a reflectance of the electromagnetic wave by changing an impedance, seen by the receiving means, of the code answer in accordance with the encoded pulse train.

According to a third aspect of the invention comprises a code response system
at least one code answer
Means for receiving an electromagnetic wave,
Means for generating a single pulse when the receiving means receive the electromagnetic wave,
Means for generating time-serial pulses by sequentially delaying the individual pulse,
Coding means for generating a coded pulse based on the time-serial pulses in accordance with a code assigned to the code answering machine, and
Means for changing a reflectance of the electromagnetic wave by changing an impedance seen by the receiving means, the code answer in accordance with the encoded pulse train, and
with an interrogator
Means for transmitting an electromagnetic wave,
Means for receiving a reflection wave reflected by the code answerer, and
Means for determining the code by demodulating a temporal change in the received reflection wave.

In the following the invention with reference to the attached Drawings explained in detail. On this is

Fig. 1 is a block diagram showing the overall structure of a code response system according to an embodiment of the invention,

FIG. 2 is a block diagram showing a specific example of the code answer system of FIG. 1.

Fig. 3 is a timing diagram illustrating the operation of the Sy stems of Fig. 2,

Fig. 4 is a Smith chart showing an impedance matching circuit each,

Fig. 5 is a block diagram form the overall structure of a code response system according to another execution of the invention,

Fig. 6 is a block diagram showing a specific example 5 of the code response system of FIG.

Fig. 7 is a timing diagram illustrating the operation of the Sy stems of Fig. 6,

Fig. 8 is a circuit diagram showing a structure of a Si gnalumwandlungsschaltung, and

Fig. 9 is a block diagram showing the overall structure of a code response system according to another embodiment of the invention.

Fig. 1 shows the overall structure of a code response system according to an embodiment of the invention. In this code response system, radio communication is carried out between an interrogator 1 and a code answerer 4 , which moves together with, for example, a moving body on which it is attached. The interrogator 1 is equipped with an interrogator control 2 for controlling modulation, demodulation and other processes and an interrogation antenna 3 for emitting an electromagnetic wave.

The code answerer 4 has a response antenna 5 for receiving an electromagnetic wave transmitted by the interrogator antenna 3 . The received electromagnetic wave is applied to a demodulation circuit 7 via an impedance matching circuit 6 (hereinafter simply referred to as "matching circuit 6 "). Based on the electromagnetic wave to be fed in this way, the demodulation circuit 7 generates a single pulse which is given to a generator 8 for delayed pulses. Since he deceleration several elements Ver 9 a- 9 z for sequentially delaying the individual pulse contains, the generator 8 for deferrers siege pulses at outputs 10 a- 10 for a number of Impul sen, which are offset from one another in time.

Intended to generate a code assigned to the code answerer 4 by performing a coding operation based on the pulses generated above, an encoder 11 has switching connections 12 a- 12 c to which the relevant pulses are given from the outputs 10 a- 10 z. In Fig. 1, the connections 12 a, 12 c and 12 z are closed, while the connection 12 c is open. While a pulse supplied to a closed switching connection appears on an output line 13 , this does not give a pulse given to an open switching connection. In this way, a pulse train on the output line 13 appears in accordance with the switching states of the switching connections 12 a- 12 z; that is, pulse encoding is performed on the time axis.

A modulation circuit 14 and an impedance matching circuit 15 (hereinafter simply referred to as "matching circuit 15 ") are provided for controlling the impedance seen by the response antenna 5 . The modu lationsschaltung 14 changes the impedance seen by the Antworterantenne 5 ago, the matching circuit 15 when circuit a pulse of a coded pulse train from the output 13 here receives and obtains the impedance of the ANPAS sungsschaltung 15 upright when it receives no pulse.

When viewed from the Antworterantenne 5 impedance of the matching circuit 15 is changed, the Refle xionsgrad is an electromagnetic wave that is received by the straight Antworterantenne 5, hereby amended accordingly. In interrogator 1 , interrogator antenna 3 receives a reflected wave, and interrogator controller 2 demodulates a temporal change in the reflected wave so as to determine a change in the impedance of matching circuit 15 of code responder 4 , that is, the code generated by encoder 11 .

FIG. 2 shows a specific example of the code response system of FIG. 1, which example uses 5-bit codes, and FIG. 3 is a timing diagram illustrating an operation of the system of FIG. 2. In the system of FIG. 2, as shown in part a of FIG. 3, the query antenna 3 normally outputs a carrier wave 19 with a specific frequency, and the transmission of the carrier wave 19 is temporarily suspended by a 100% at time t 1 . -Amplitudenmo dulation is carried out using a rectangular pulse as example. A time interval t₀ the interruption of the carrier wave 19 is set shorter than the delay time in each of the delay elements 9 a- 9 e in order to avoid an overlap of pulses which are output by the (later described) delay pulse generator 8 of the code answer 4 .

The matching circuits 6 and 15 of the code responder 4 are composed of passive elements that do not require any voltage supply, and are usually set so that they maintain a certain impedance.

Fig. 4 is a Smith chart showing the impedance characteristics of the matching circuits 6 and 15 as seen from the response antenna 5 . Normally, the impedance of the matching circuit 6 is set so that it lies in point A (impedance-adjusted state). On the other hand, the impedance of the matching circuit 15 is set to a point B (infinite value). As a result, an electromagnetic wave received by the response antenna 5 , which is in an adapted state, is received by the matching circuit 6 without reflection; that is, the entire electromagnetic wave of the demodulation circuit 7 is entered.

Since the demodulation circuit 7 is a low-pass filter consisting of a diode 7 a and a high-impedance line 7 b, it removes a high-frequency component of the carrier wave received by the response antenna 5 and generates a single square-wave pulse p 1 at the time t 1 in response to the above-described switching off of the carrier wave ( see part (b) of Fig. 3). The single rectangular pulse generated in this way is input to the delay pulse generator 8 .

As a microstrip line or the like, the high impedance line 7 b can be made sufficiently small.

The five delay elements 9 a- 9 e of the delayed pulse generator 8 generates individual pulses p₂-p₆ at the outputs 10 a- 10 e at times t₂-t₆ (see parts (c) - (g) of FIG. 3).

The five switching connections 12 a- 12 e of the encoder 11 generate an ID code that corresponds to the code answer 4 . In the example of FIG. 2, the connections 12 a, 12 d and 12 e are closed, while the connections 12 b and 12 c are open. Therefore, the pulses p₂, p₅ and p₆ appear, which have been given to the switching connections 12 a, 12 d and 12 e, also on the output line 13 , as shown in part (h) of FIG. 3. In this embodiment, a state in which a switching terminal is closed and a pulse is transmitted from the delay pulse generator 8 to the output line 13 is indicated by the data "1" and a state in which a switching terminal is open and a pulse is not transmitted from the delay pulse generator 8 to the Output line 13 is carried over, represented by the date "0". Therefore, the encoder 11 generates an ID code "10011".

The modulation circuit 14 is composed of a diode 14 a and a high impedance line 14 b. If the modulation circuit 14 receives the individual pulses of the coded pulse train from the output line 13 , the diode 14 a provides a load that changes the impedance characteristic of the modulation circuit 14 . The impedance of the matching circuit 15 seen from the response antenna 5 is accordingly changed accordingly. In this embodiment, the impedance of the matching circuit 15 is adjusted so that it lies at the point C (zero impedance) of the Smith chart of Fig. 4, when the load is caused by the diode 14 a.

When the impedance of the matching circuit 15 becomes 0, the combined impedance of the parallel connection of the matching circuits 6 and 15 also becomes 0. As a result, the non-reflected carrier wave state established by the impedance matching described above is lost and the response antenna 5 reflects the carrier wave transmitted from the interrogator antenna 3 .

Conversely, if the modulation circuit 14 receives no pulse from the encoder 11 , the diode 14 a provides no load. The matching circuit 15 therefore maintains the impedance of the normal state, and the non-reflected carrier wave state remains established by the impedance matching.

Part (i) of FIG. 3 shows outputs of waves reflected by the answering antenna 5 . The carrier wave is reflected at times t₂, t₅ and t₆, which correspond to the appearance of the pulses p₂, p₅ and p₆. The reflected waves are received by the interrogator antenna 3 and demodulated by the interrogator controller 2 . The code generated in the encoder 11 is therefore decoded.

Fig. 5 shows the overall structure of a Codewtwortersy stems according to another embodiment of the invention. An interrogator 1 'sends a modulated wave, which has been generated by modulation using a specific code, to a code answer 4 '.

In the code answerer 4 ', the modulated wave transmitted by the interrogator antenna 3 is received by the answering antenna 5 and fed to a correlator 16 via an adaptation circuit 6 . The correlator 16 has an ID code that coincides with the code of the modulated wave that is sent by the interrogator 1 '. Upon receipt of the modulated wave, the correlator 16 generates a pulse which is fed to the delayed pulse generator 8 .

In the delay pulse generator 8 , the delay elements 9 a- 9 z sequentially delay the pulses supplied by the correlator 16 and generate at the outputs 10 a- 10 z a number of pulses which are offset in time, in the same manner as in the first off management form. In the encoder 11 , the coding operation on the time axis is carried out using the pulses supplied from the outputs 10 a- 10 z in accordance with the switching states of the switching connections 12 a- 12 z.

A pulse train generated on the output line 13 is input to a signal converting circuit 17 , which converts the pulse train into a shaped pulse by removing the high frequency component. The modulation circuit 14 and the matching circuit 15 have the same structure as in the first embodiment. If an impulse from the. Signal conversion circuit 17 is supplied to the modulation circuit 14 , the impedance of the matching circuit 15 , seen from the response antenna 5 , is changed. The reflectance of the electromagnetic wave received by the response antenna 5 changes in accordance with the change in impedance of the matching circuit 15 . The interrogation control 2 'of the interrogator 1 ' determines the code generated in the encoder 11 by demodulating a temporal change in the reflected wave.

FIG. 6 shows a specific example of the code response system of FIG. 5, which example uses 5-bit codes, and FIG. 7 is a timing diagram showing an operation of the system of FIG. 6. The impedance characteristics of the matching circuits 6 and 15 , which are set the same as those of the example shown in FIG. 2, are represented by the points indicated on the Smith chart of FIG. 4.

As shown in part (a) of Fig. 7, after outputting a PSK (phase shift keying) wave 20 , which is obtained by modulation using a specific ID code, the interrogator antenna 3 of the interrogator 1 ' a carrier wave 21 for a period of time that corresponds to the Ant word duration of the code answer 4 '. The Codeant words 4 'has a SAW correlator 16 ', which serves as the correlator 16 . An ID code corresponding to the characteristic of the PSK wave 20 output from the interrogator antenna 3 is input to the SAW correlator 16 '. As shown in parts (a) and (b) of FIG. 7, the SAW correlator 16 'outputs a pulse-modulated wave P₁ which outputs a high-frequency wave packet signal at a time T₁ which is compared to the time T₀ (the time at which the transmission of all bits of the PSK wave 20 is completed) a certain time is delayed.

The pulse-modulated wave P 1 is supplied to the delay pulse generator 8 . As shown in parts (c) - (g) of Fig. 7, the delay elements 9 a- 9 e of the delay pulse generator 9 sequentially delay the pulse-modulated wave P₁ by a certain time, so that pulse-modulated waves P₂-P₆ at the outputs 10 a- 10 e are generated at times T₂-T₆.

As in the case of the example of Fig. 2, the switching connections 12 a- 12 e of the encoder 11 are set so that they generate an ID code, which is the code answer 4 'inherently rent. As shown in part (h) of FIG. 7, only the pulse-modulated waves P₂, P₅ and P₆, which have been fed to the closed connections 12 a, 12 d and 12 e, appear on the output line 13 and generate a pulse train represents an ID code "10011".

Fig. 8 shows a structure of the signal conversion TIC 17th Since it is composed of a diode 17 a and a high impedance line 17 b, the signal conversion circuit 17 removes the high frequency packet signal from each pulse P that appears on the output line 13 , and it thus generates a pulse P 'with a positive voltage. This has the consequence that, as shown in part (i) of Fig. 7, the pulse-modulated waves P₂, P₆ and P₆ in pulses P _{2 '} , P _5' and P _{6 'are converted} with a positive voltage, the time relationship between the pulse-modulated waves P₂, P₅ and P₆ is maintained. The positive pulses P _{2 '} , P _5' and P _{6 '} are input to the modulation circuit 14 .

The modulation circuit 14 has the same structure as that of Fig. 2. When the pulses P _{2 '} , P _5' and P _{6 'of} the modulation circuit 14 are input, the diode generates a load and the impedance characteristic of the modulation circuit 14 is changed. As a result, the impedance of the matching circuit 15 becomes 0 when viewed from the response antenna 5 . Since the non-reflection state is lost for the carrier wave, the response antenna 5 reflects the carrier wave 21 , which is sent by the interrogator 1 '. The interrogator control 2 'determines the code 4 ' generated code by demodulating the change in time of the reflected wave.

The polarity of the diode 17 a in the signal conversion circuit 17 can be reversed to convert a pulse-modulated wave, which is supplied from the output line 13 , into a pulse with a negative voltage, in which case the polarity of the diode 14 a in the modulation circuit 14 also should be reversed to maintain the work described above.

In this embodiment, the SAW correlator 16 'of the code responder 4 ' is set to respond only to the PSK wave generated by modulation using a special code. Therefore, even if code answerers 4 'of a plurality of systems are mixed, it is possible to obtain a response from only one code answerers 4 ' of a particular system by appropriately controlling the code of the PSK wave transmitted by interrogator 1 'if Codes of PSK waves are assigned to the relevant systems in advance. In this way, the code responders 4 'can be identified individually for the individual systems, so as to enable CDMA (code series multiple access). Further, since the system call code can be determined by the structure of the SAW correlator 16 , the invention enables the construction of a system that is difficult to copy and superior in secrecy.

In the above embodiments, the response is to generate a fixed, inherent code, but the invention is not limited to such a case. The answer may be with the generation of a variable code, as in another embodiment shown in FIG. 9.

A code answer system of Fig. 9 has in principle the same structure as that of Fig. 1 and differs from this in that switching connections 12 a'- 12 z 'of an encoder 11 ' are bimetallic contacts 24 a- 24 z, which according to the Open or close temperature.

The bimetallic contacts 24 a- 24 z open or close at different temperatures, for example so that the first bimetallic contact 24 a opens or closes at 0 ° C, the second bimetallic contact 24 b at 5 ° C, the third bimetallic contact 24 c at 10 ° C etc. . Since the switching states of the individual switching connections 12 a'- 12 z change according to the temperature, the code generated also changes with the temperature.

The bimetal contacts 24 a- 24 z can also be used in the second embodiment shown in FIG. 5.

Semiconductors, which differ for example in the foreign matter concentration and their conductivities change with temperature, can also be used as the switching connections 12 a'- 12 z ', in the same way as the bimetal tall contacts 24 a- 24 z. In addition to the means that respond to a temperature change, means that respond to a change in a received amount of light, such as phototransistors and CdS cells, and means that respond to a change can also be used as the switching terminals 12 a'- 12 z ' respond to external forces, such as vibration sensors with thin platelets.

As described above, according to the invention, a Response to a transmitted electromagnetic wave their reception so that the reflectance of the electromagnetic wave in accordance with an inherent or variable code that is generated in the code answer changed becomes. Since the code is sent to the interrogator in the form of a temporal Variation of a reflected wave can be sent  Detection accuracy in the interrogator can be improved.

The reflectance of a transmitted electromagnetic Wave is changed by generating an encoded pulse train that corresponds to the code, and then the impedance, like it is seen by the receiving means, according to the coding ten pulse train is changed. The reflected wave changes therefore also strongly with pulses of very small amplitudes.

Where the code responder responded by generating a code that changes with the state of an external factor, the query page can receive information that is on relates to a change in the external factor. For example where the code answerer can be by generating a variable Codes by a combination of on / off states a number of bimetal contacts is set, answer the query page receives temperature-related information ten.

Claims (16)

1. code response method with the method steps of generating a single pulse with reception of an electromagnetic wave,
Converting the single pulse into time-serial pulses,
Generating a coded signal based on the time-serial pulses according to a code assigned to a code answering machine, and
Responding to the electromagnetic wave by changing a reflectance of the electromagnetic wave according to the encoded signal. 2. The method of claim 1, wherein the code is fixed code inherent in the code answering machine. 3. The method of claim 1, wherein the code is one is variable code. 4. The method of claim 1, in which in the process step of generating the individual pulse of the individual im pulse is only generated when the received electromagnetic cal wave is encoded with a certain code. 5. Code answer with
Means for receiving an electromagnetic wave,
Means for generating a single pulse when the receiving means receive the electromagnetic wave,
Means for generating time-serial pulses by sequentially delaying the individual pulse,
Coding means for generating an encoded pulse train based on the time-serial pulses according to a code assigned to the code answering machine, and
Means for changing a reflectance of the electromagnetic wave by changing an impedance, as seen by the receiving means, of the code answering machine in accordance with the encoded pulse train. 6. Code answerer according to claim 5, wherein the code is a fixed code that is inherent in the code answering machine is. 7. Code answering machine according to claim 5, wherein the code is a variable code. 8. Code answerer according to claim 7, wherein the code is set according to a state of an external factor. 9. Code answering machine according to claim 7, in which the coding means contain a number of bimetallic contacts ( 24 a- 24 z) which open or close in accordance with a temperature, and in which the code by a combination of on / off states of the concerned Bimetal contacts is set. 10. Code answering machine according to claim 5, in which the Single pulse generating means only generate the single pulse if the received electromagnetic wave with a be agreed code is encoded. 11. Code answer system with at least one code answer
Means for receiving an electromagnetic wave,
Means for generating a single pulse when the receiving means receive the electromagnetic wave,
Means for generating time-serial pulses by sequentially delaying the individual pulse,
Coding means for generating a coded pulse based on the time-serial pulses according to a code assigned to the code answering machine, and
Means for changing a reflectance of the electromagnetic wave by changing an impedance, as seen by the receiving means, of the code answering machine according to the encoded pulse train, and
with an interrogator
Means for transmitting the electromagnetic wave,
Means for receiving a reflection wave reflected by the code answering machine, and
Means for determining the code by demodulating a temporal change in the received reflection wave. 12. The code response system of claim 11, wherein the Code is a fixed code that belongs to the code answerer rent is. 13. The code response system of claim 11, wherein the Code is a variable code. 14. The code response system of claim 13, wherein the Code set according to an external factor state is. 15. Code response system according to claim 13, in which the coding means contain a number of bimetallic contacts ( 24 a- 24 z) which open and close according to a temperature, and in which the code is set by a combination of on / off states of the bimetallic contacts concerned is. 16. Code answering machine according to claim 11, wherein the Single pulse generating means only generate the single pulse if the received electromagnetic wave with a be agreed code is encoded.