JPH11145874A - Saw-id-tag device using chirp signal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain improvement in S/N ratio in SAW-ID-TAG which utilizes a surface acoustic wave(SAW) element. SOLUTION: A SAW converting electrode is formed from a chirp electrode. In place of a single RF pulse, this chirp signal SAW-ID-TAG is transmitted. Then, the chirp signal is converted into a SAW of a single RF pulse stream at the SAW converting electrode. This SAW is converted into an RF pulse stream at an encoding electrode 68. On the side of a receiver, this RF pulse stream is detected by a detection circuit 28, and its code is detected by a code detector 30 so that the code can be read out. As a result, since the pulse stream compressed by a compression gain corresponding to a BT as a product of distribution time T and distribution band width B for the chirp signal can be transmitted by the chirp signal, the S/N ratio can be improved only for this compression gain. Further, a third person, who does not know that this is a chirp signal, is unable to read the code, and the privacy of the code can be kept.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to an ID-TAG device using a SAW element.

[0002]

2. Description of the Related Art A SAW (Surface Acoustic Wave) surface acoustic wave (SAW) element is used as a delay line utilizing the fact that the propagation speed of a SAW is about 10 ^-5 times slower than that of a radio wave.

[0003] By connecting a plurality of SAW delay lines having different delay times in parallel, it is possible to constitute an element for converting a single RF pulse into a plurality of pulse trains, that is, an RF pulse train.

Specifically, the input terminals and output terminals of a plurality of SAW delay lines are connected in parallel. When a single RF pulse is applied to the parallel-connected input terminals, the parallel-connected output terminals of the SAW delay line
Pulses having different delay times via SAW delay lines are superimposed and output. That is, each SAW
Each pulse delayed by the delay time of the delay line is output from an output terminal connected in parallel. Thus, an RF pulse train can be generated.

Now, connect an input antenna to the input terminal,
If an output antenna is connected to the output terminal, when an RF pulse directed to this input antenna is transmitted from outside, this R
The F-pulse signal is received by the input antenna and input to a plurality of SAW delay lines connected in parallel. As a result, an RF pulse train corresponding to the delay time of each SAW delay line is generated, and this RF pulse train is output from the output terminals connected in parallel. Then, this RF pulse train is transmitted from the output antenna to the air.

Here, if a plurality of combinations of delay times of a plurality of SAW delay lines are prepared, an RF pulse train according to the combination can be obtained. Then, it has been proposed to use this combination of delay times as a verification code. According to such a configuration, an RF pulse train of a code to be collated can be obtained only by transmitting a single RF pulse from an external transmitter, and thus is used as a SAW-ID-TAG.

FIG. 3 is a block diagram showing the configuration of such a conventional SAW-ID-TAG. As shown in this figure, first, the RF pulse generator 10 generates a single pulse. This single pulse is applied to the RF amplifier 12
, And then supplied to the coupler 14. In the coupler 14, the RF pulse supplied from the RF amplifier 12 is transmitted from the antenna 16 to the SAW-ID-TA
It is emitted toward G18.

As described above, the SAW-ID-TAG 18 includes a plurality of SAW delay lines 20a, 20b, 20c, 2
0d are connected in parallel. SAW-ID
-The RF pulse received from the receiving antenna 22 of the TAG 18 includes a plurality of SAW delay lines 20a, 20b, 2
0c and 20d are supplied simultaneously. From each of the SAW delay lines 20a, 20b, 20c, and 20d, an RF pulse is output from each output terminal after each delay time has elapsed. All SAW delay lines 20a, 20b,
The output terminals of 20c and 20d are connected in parallel to the transmitting antenna 24.
, The transmitting antenna 24 superimposes and outputs the temporally shifted RF pulses output from the respective SAW delay lines 20a, 20b, 20c, and 20d. As a result, the transmitting antenna 24 shown in FIG.
, Four SAW delay lines 20a, 20b, 20
c, RF pulse signals output from 20d are superimposed,
RF pulse trains are emitted.

[0009] The RF pulse train radiated from the transmitting antenna 24 is received by the antenna 16. The received RF pulse train is converted into an LNA (Low No.
iseAmplifier). The LNA 26 amplifies the RF pulse train, and outputs the amplified RF pulse train to a detection circuit 28.
To supply. The detection circuit 28 restores the code from the received RF pulse train, and supplies the code to the code detector 30. The code detector 30 determines whether this code is a desired code.

Thus, if the structure as shown in FIG. 3 is used,
Since the SAW-ID-TAG 20 itself is composed of only passive elements, the SAW-ID-TAG 20 does not require components such as a battery and a power supply and a circuit. In addition, since the structure uses only the received RF single frequency, there is no need for a frequency conversion unit such as a mixer for converting the frequency to the baseband for processing. Further, there is no need for a band-pass filter for removing frequency spurious generated at the time of mixing or an amplifier for compensating for signal attenuation in the constituent circuit elements. Therefore, an ID-TAG that operates semipermanently with no power supply can be configured with a very simple structure.

Prior Art 2 FIG. 4 is a block diagram showing a configuration example in which the configuration shown in FIG. 3 is simplified. This configuration has existed conventionally, and as in FIG.
The ID-TAG is configured using a SAW element.

A feature of the prior art shown in FIG. 4 is that the input / output antenna is a single common antenna 4.
0 is used. Further, what is characteristic in the prior art of FIG. 4 is that one SAW delay line 42 replaces a plurality of SAW delay lines prepared in FIG.

In order for one SAW delay line to perform the same function as a plurality of delay lines, in the configuration example of FIG. 4, one SAW conversion electrode 46 and a plurality of SAW conversion electrodes 46 are provided on one SAW propagation path of the SAW delay line. Encoding electrodes 44 are provided. With such a structure, signals having different delay times can be extracted from the encoding electrodes 44 of the plurality of SAWs. By adopting such a structure,
Without preparing multiple SAW delay lines with different delay times,
With a single SAW delay line, delayed outputs having different delay times are obtained from a plurality of encoding electrodes 44, which contributes to downsizing of the device. The example shown in FIG. 4 relates to a system for reading a product code attached to a product without contact,
A single RF pulse emitted from the outside is converted into an RF pulse train corresponding to a predetermined code by a SAW-ID-TAG device attached to a product. By detecting the code from the pulse train, the code can be restored and the product code can be detected in a non-contact manner with the product.

In FIG. 4, the RF pulse from the common antenna 40 is supplied to the SAW conversion electrode provided on the piezoelectric substrate of the SAW delay line. Then, the plurality of encoding electrodes 44 output R R with different delay times.
An F pulse is output, and an RF pulse train is generated. The RF pulse train thus obtained returns to the antenna 40 again and is radiated from the antenna 40.

The RF signal received by the antenna 40
The pulse is also supplied to the encoding electrode 44 side. Then, the light is distributed to the plurality of encoding electrodes 44 and reaches the SAW conversion electrode 46 after propagating through different delay distances. Then, R, which is a train of pulses corresponding to each delay time,
An F pulse train is generated. The generated RF pulse train is transmitted from the common antenna 40.

Here, since the SAW delay line 42 has the characteristic that the same characteristics can be obtained even if the input / output terminals are reversely connected, the SAW delay line 42 passes through any one of the two paths having different directions from the common antenna 40. Thus, the same RF pulse train can be obtained. Therefore, the same RF pulse train that has passed through the two paths is superimposed at the output terminal without any change in its waveform, and is radiated from the common antenna 40. Therefore, it is possible to generate an RF pulse train exactly the same as the case of FIG. Here, the encoding electrode 44 in FIG. 4 performs phase modulation or the like on the input RF pulse.
This is an electrode for performing code phase modulation by, for example, reversely connecting an electrode finger to a common electrode.

Prior Art 3 FIG. 5 is an explanatory diagram showing another configuration of a conventional SAW-ID-TAG. A single RF pulse received at the antenna 50 is converted to a SAW signal at the SAW electrode 52 on the piezoelectric substrate. The converted SAW signal is S
It propagates on the AW propagation path. And the SAW signal is
A plurality of SAW reflection structures 5 existing on this SAW propagation path
4 and is again received by the SAW electrode 52 and converted into an RF pulse. Since there are a plurality of SAW reflection structures 54 and the positions where the reflections are different from each other, the time required to reach the SAW electrode 52 again differs. As a result, similar to the above-described prior arts 1 and 2, R
An F pulse train is generated. This RF pulse train is radiated from the antenna 50. Here, the SAW-ID-TAG can be realized by providing the SAW reflection structure 54 formed on the SAW propagation path at a position where the reciprocating distance between the SAW electrode 52 and the SAW electrode 52 has a predetermined propagation delay. it can. In the conventional technology 3, the conventional technology 2 is used.
Unlike the phase modulation in the above, encoding is performed by on / off keying based on the presence or absence of the SAW reflection structure 54 at a predetermined position.

[0018]

In such a SAW-ID-TAG having a conventional structure, conversion loss from an electric signal to SAW and conversion loss from an SAW to an electric signal are generally large in a SAW delay line. Therefore, when the RF pulse received by the antenna is converted into SAW and returned to the antenna as an RF pulse train again, the signal level corresponding to the insertion loss of the SAW delay line is reduced. Therefore, there has been a problem that the S / N ratio when detecting the RF pulse train is deteriorated.

When the RF pulse converted to SAW reaches the output electrode, it becomes SAW again due to the re-excitation effect of SAW and propagates on the piezoelectric substrate. Then, since the re-excitation RF pulse that has reached the input electrode is transmitted from the antenna, an RF pulse is generated other than the RF pulse train originally generated by the electrode position or the reflection structure. That is, this is due to the re-excitation effect of the SAW.
This is because the SAW is excited again from the electrode. This re-excitation SAW is converted into an unnecessary RF pulse, and an extra RF pulse is emitted from the antenna.

As described above, according to the conventional technique, an undesired RF pulse train is added to a desired RF pulse train. In the conventional technique, there is a problem that the added pulse train is difficult to distinguish from the original RF pulse train.

In order to avoid this problem, as shown in FIG. 4, the distance between the SAW conversion electrode 46 and the coding electrode 44 is made longer than the entire length of the coding electrode, thereby reducing
Various measures have been taken such as delaying the RF pulse train by re-excitation of the AW much more than the original pulse train. But,
With the structure as shown in FIG. 4, an unnecessary space other than the SAW conversion electrode 46 and the encoding electrode 44 is required, which causes a problem that the element becomes large. Furthermore, when manufacturing the SAW-ID-TAG, the number of SAW-ID-TAGs that can be manufactured from one piezoelectric substrate wafer decreases, so that the manufacturing cost per SAW-ID-TAG increases. The problem arises. Furthermore, the code set in the SAW-ID-TAG (often using the expression "engraved code".
As shown in the above, the code that can be detected by the SAW-ID-TAG is determined by the structure (position and the like) of the coding electrode, and the structure of the coding electrode is determined at the time of manufacture and cannot be changed later. ) Can be easily read by an unspecified third party by inputting an RF pulse to the TAG. Therefore, there was a problem in security.

[0022]

In order to solve these problems, the present invention utilizes a chirp electrode as a SAW conversion electrode. The chirp electrode is an electrode in which the frequency of the converted SAW gradually varies depending on the location. By using this chirp electrode, a chirp signal whose frequency changes with time can be used. The time change of the chirp signal used corresponds to the structure of the chirp electrode.

When a chirp signal is applied to the SAW conversion electrode constituted by the chirp electrode, the RF pulse SAW is propagated. The RF pulse-shaped SAW is converted into an RF pulse train by a plurality of encoding electrodes. The converted RF pulse train is transmitted from the antenna.

Alternatively, an RF pulse may be transmitted, and a SAW conversion electrode composed of a chirp electrode may generate a chirp signal-like SAW whose frequency changes with time. Then, a signal obtained by superimposing the chirp signal with a delay time corresponding to the position of the encoding electrode is transmitted from the antenna. Then, the receiver converts the signal into an RF pulse train using a matched filter including a SAW element corresponding to the chirp signal.

Specifically, the present invention has the following configuration.

According to a first aspect of the present invention, there is provided a transmitting means for transmitting a chirp signal whose frequency changes with time, a receiving antenna means for receiving the chirp signal transmitted by the transmitting means, an RF signal pulse train of a signal to be collated. ID-
In a SAW-ID-TAG device including a TAG unit and a receiving unit that receives an RF pulse train output from the ID-TAG device and detects and demodulates the received RF pulse train, in particular, the ID-TAG unit includes the following. It includes such matters as:

That is, the ID-TAG means is a piezoelectric substrate, and a SAW conversion electrode provided on the piezoelectric substrate for converting the chirp signal into an RF pulsed SAW, and a delay for a frequency of the chirp signal. A SAW conversion electrode formed of a chirp electrode having a frequency delay time gradient opposite to the time gradient, and a SA on the piezoelectric substrate
A plurality of encoding electrodes provided on the W propagation path, wherein the plurality of encoding electrodes arranged at a predetermined distance from the SAW conversion electrode and an RF pulse train generated by the plurality of encoding electrodes are transmitted. The transmission means for transmitting to the antenna, and the transmission antenna to which the RF pulse train is supplied by the transmission means.

According to a second aspect of the present invention, there is provided a transmitting means for transmitting an RF pulse signal, a receiving antenna means for receiving the RF pulse signal transmitted by the transmitting means, and an ID-TAG for obtaining a chirp signal of a signal to be compared. Means and the ID-T
Receiving means for receiving a chirp signal output from the AG device, converting the chirp signal into an RF pulse train, and detecting and demodulating the signal.
In the ID-TAG device, the ID-TAG means includes the following items.

That is, the ID-TAG means is a piezoelectric substrate, and a SAW conversion electrode provided on the piezoelectric substrate for converting the RF signal into a chirped SAW whose frequency changes with time. A SAW conversion electrode formed of a chirp electrode having a frequency delay time gradient opposite to the delay time gradient with respect to the frequency of the signal, and a plurality of encoding electrodes provided on the SAW propagation path on the piezoelectric substrate, A plurality of encoding electrodes each arranged at a predetermined distance from the SAW conversion electrode; a transmitting unit for transmitting an RF pulse train generated by the plurality of encoding electrodes to a transmitting antenna; and the chirp signal is transmitted by the transmitting unit. And the transmitting antenna to be supplied.

Further, the receiving means is a matched filter corresponding to the chirp signal, and converts the signal into a plurality of pulse trains with a delay time defined by an arrangement position of the encoding electrode of the ID-TAG means. A matched filter.

A third aspect of the present invention is the SAW-ID-TAG device, wherein the transmitting antenna and the receiving antenna share the same antenna.

According to a fourth aspect of the present invention, the coding electrode is a coding electrode corresponding to phase modulation by changing a connection polarity of an electrode finger.
TAG device.

According to a fifth aspect of the present invention, the encoding electrode shifts the position of the electrode finger in the SAW propagation direction,
A SAW-ID-TAG device, which is an encoding electrode corresponding to phase modulation.

According to a sixth aspect of the present invention, the encoding electrode is an encoding electrode in which the interval between electrode fingers is changed to correspond to encoding of an inter-pulse interval.
An AW-ID-TAG device.

According to a seventh aspect of the present invention, the coding electrode is a coding electrode corresponding to ON / OFF keying depending on the presence / absence of an electrically connected electrode finger. Device.

An eighth aspect of the present invention is characterized in that the SAW conversion electrode is weighted so as not to generate a time side lobe in the converted RF pulse. TAG device.

The ninth invention is characterized in that the weighting is performed based on a predetermined window function.
It is an ID-TAG device.

According to a tenth aspect of the present invention, the predetermined window function is a Hamming window.
Device.

An eleventh invention is characterized in that the pass characteristic of the ID-TAG means has a matched filter characteristic for the input chirp signal.
-ID-TAG device.

By using such means, when a chirp signal is transmitted, the signal is compressed with a compression gain corresponding to the product (BT) of the dispersion time (T) and the dispersion bandwidth (B) of the chirp signal. Pulse train can be transmitted.
Alternatively, when the RF pulse is transmitted, the SAW-I
When the superimposed chirp signal returned from the D-TAG is converted into an RF pulse train by a matched filter, the S / N for the compression gain can be improved. Therefore, according to the present invention, there is an advantage that reception with good S / N can be performed despite the use of a SAW element having generally large insertion loss.

Further, when a chirp signal is transmitted, the SW-ID-TAG re-transmits the signal at the encoding electrode.
There is no RF pulse effect due to the re-excitation effect converted to AW. This is because a re-excitation RF pulse is converted into an electric signal at a SAW conversion electrode composed of a chirp electrode, and the electric signal is a chirp signal. Therefore, no RF pulse train is generated by the re-excitation effect. When an RF pulse is input, the RF pulse becomes a chirp signal at the SAW conversion electrode composed of the chirp electrode. Since the coded electrode is re-excited as a chirp signal, the chirp signal resulting from the re-excitation is transmitted from the antenna as a chirp signal extended in the time direction by a factor of two. This is because the SAW conversion electrode is constituted by a chirp electrode. Therefore, even if the signal by this re-excitation is received and passed through the matched filter, the re-excitation chirp signal which is doubled in the time direction only returns to the conventional length chirp signal, and an RF pulse train is generated. Never.
Therefore, there is an advantage that the re-excitation signal can be made different from the original signal shape, and the signal can be easily distinguished from the original signal.

Unspecified third parties, unless they know that the chirp signal is being used, have the SAW-ID-T
Even if the code written in the AG cannot be read, and even if this chirp signal is used, it is not easy to generate the same chirp signal. It is still difficult to read the written code. Therefore, the present invention has an excellent security.

It should be noted that, in any of the configurations of the present invention for transmitting a chirp signal and for transmitting an RF pulse train, various configurations can be used as the encoding electrodes. For example, the electrode fingers may be arranged for the phase modulation signal, or may be configured depending on the presence or absence of the electrode fingers to support on / off keying. Also, the same effect can be obtained by using an encoded electrode that is encoded by the mutual distance between the electrode fingers.

Further, with respect to the chirp electrode, the frequency characteristic of the chirp electrode is weighted by differentiating the frequency change rate of the chirp electrode depending on the place, so that the compressed RF pulse does not have time side lobes. For example, weighting such as a Hamming window function may be performed. Also, Dolph-cheb
yshev window function or Taylor window function or cos ²
Weighting such as a window function, a cos ³ window function, or a cos ⁴ window function may be used. Further, the SAW conversion electrode for transmitting the chirp signal may have a matched filter characteristic for the input chirp signal. Conversely, the transmission characteristics between the SAW conversion electrode and each encoding electrode may be matched filter characteristics.

[0045]

1 and 2 are explanatory views showing an embodiment of the present invention. Hereinafter, embodiments will be described in detail with reference to the drawings.

Embodiment 1 FIG. 1 is an explanatory diagram showing an embodiment of the present invention when transmitting a chirp signal. RF generated by RF pulse generator 10
The pulse is a SAW distributed delay line (SAW-DDL) 60
Is converted into a chirp signal whose frequency gradually changes with time. In the first embodiment shown in FIG. 1, the chirp signal is generated using SAW-DDL 60, but may be directly generated by a digital synthesizer or the like.

The chirp signal generated in this manner is amplified by the RF amplifier 12 and then
Is transmitted from the antenna 16 via. This chirp signal is received by a SAW-IN-TAG antenna 62, and the frequency of the received input chirp signal and a SAW chirp electrode SAW having a delay slope reverse to the delay time slope.
The conversion electrode 64 compresses the RF pulse (SAW corresponding to a single RF pulse). This RF pulse (SA
W) propagates on the piezoelectric substrate 66, and the compressed SA
The electric signals are converted again as RF pulse trains corresponding to the respective delay times by the plurality of encoding electrodes 68 arranged on the propagation path through which W propagates. Here, the delay time of each encoding electrode 68 is determined by the respective encoding electrodes 68a and 68a.
It is determined according to the positions of b, 68c, and 68d, specifically, the distance from the SAW conversion electrode 64. Then, the converted electric signal is transmitted from the antenna 62. Route 1
Call.

In addition to the path 1, there are the following paths that can be taken by the chirp signal input from the antenna 62. The chirp signal input from the antenna 62 is converted to SAW while maintaining the form of the chirp signal at each of the encoding electrodes 68a, 68b, 68c, 68d. The plurality of encoding electrodes 68 are formed to have different structures according to the chirp signal. A chirp signal (SAW) superimposed with a delay time corresponding to the propagation distance of each encoding electrode 68 propagates on the piezoelectric substrate, and is converted into an RF pulse train electric signal compressed by the SAW conversion electrode 64. This SAW conversion electrode 64 is constituted by a chirp electrode. As described above, the superimposed chirp signal is compressed in the SAW conversion electrode 64. The RF pulse train obtained by compression is
The SAW is converted into an electric signal, and the electric signal is transmitted from the antenna 62. This route is referred to as route 2 in the first embodiment.

In any case, the signals returning to the antenna 62 are transmitted with the same amplitude and the same phase.
This is because, as described above, the transmission characteristics of the SAW delay line do not differ even when the input / output terminals are replaced. Replacing an input / output terminal means reversing the input / output relationship. The paths 1 and 2 are paths for transmitting signals in the opposite direction to the SAW delay line, and the input / output relationship is reversed.

The signals returning to the antenna 62 in these two paths have the same amplitude and the same phase, and are transmitted after being superimposed and increasing only the amplitude. This RF pulse train is received by the antenna 16 on the receiver side,
It is supplied to NA16. The LNA 16 amplifies the RF pulse train, and the amplified RF pulse train is detected by the detection circuit 28. The code obtained by the detection is reproduced by the code detector, so that the code written in the SAW-ID-TAG is read.

Embodiment 2 FIG. 2 is an explanatory diagram showing an embodiment of the present invention when transmitting an RF pulse. The RF pulse generated by the RF pulse generator 10 is amplified in the RF amplifier 12 and supplied to the antenna 16 via the coupler 14. The antenna 16 transmits the supplied RF pulse.

SAW-ID-T according to the second embodiment
The RF signal received by the AG antenna 70 has the following 2
Through two paths.

In route 1 in the present embodiment,
The RF signal received by the antenna 70 is converted by the SAW conversion electrode 72 into SAW on the piezoelectric substrate. This SAW conversion electrode 72 is constituted by a chirp electrode in the present embodiment. Therefore, the SAW obtained by the SAW conversion electrode 72 takes the form of a chirp signal. A plurality of encoding electrodes 74 are provided on the SAW propagation path. These encoding electrodes 74a, 7
Each of the encoding electrodes 74a, 74b, 74c, 74d according to the distance between the SAW conversion electrode 72 and each of the encoding electrodes 74a, 74b, 74c, 74d.
Have different SAW reception times, which determine the delay time. As a result, a chirp signal is received corresponding to the delay time of each of the encoding electrodes, and is converted into an electric signal. In this way, the path on which the SAW becomes a superimposed electric signal and returns to the antenna 70 again is the path 1.

In route 2 in the present embodiment,
The RF pulse signal received by the antenna 70 is converted into a SAW as an RF pulse at each of the plurality of encoding electrodes 74. The converted SAW is a distance (SA) between the plurality of encoding electrodes 74 and the SAW conversion electrode 72.
The signal is received as an RF pulse train at the SAW conversion electrode with a delay time corresponding to the W propagation distance).

Here, in the second embodiment, as described above, the SAW conversion electrode 72 is constituted by a chirp electrode. Therefore, each RF pulse is converted into a chirp signal, and a signal on which the converted signal is superimposed returns to the antenna. Such a route is called a route 2.

The signals passing through the paths 1 and 2 have the same amplitude and the same phase, and the superposed signal is transmitted from the antenna 70. Here, the antenna 70
Superimposed signal transmitted from the encoding electrode 74
These are chirp signals superimposed with delay times corresponding to a, 74b, 74c, and 74d. The superimposed chirp signal is received by the antenna 16 and passed through the coupler 14 to the LN
A26. The LNA 26 amplifies the received signal and supplies it to the SAW matched filter 76. SAW
The matched filter 76 is a matched filter composed of a SAW element or the like corresponding to the chirp signal, and the matched filter 76 converts the received chirp signal into an RF signal.
Compress into pulses. As a result of this compression, the encoding electrode 7
An RF pulse train having a delay time corresponding to the delay times of 4a, 74b, 74c, and 74d is generated. This RF pulse train is detected and demodulated in a detection circuit. The sign value of the signal obtained as a result of the demodulation is read by the sign detector 30.

As described above, in the second embodiment, the code written in the SAW-ID-TAG is read.

In each of the configurations for transmitting the chirp signal and the example for transmitting the RF pulse train in the first and second embodiments, various configurations can be used as the encoding electrodes. For example, the electrode fingers may be arranged for the phase modulation signal, or may be configured depending on the presence or absence of the electrode fingers to support on / off keying. Also, the same effect can be obtained by using an encoded electrode that is encoded by the mutual distance between the electrode fingers.

For the chirp electrode, the frequency characteristics of the chirp electrode are weighted by differentiating the frequency change rate of the chirp electrode depending on the location, so that the compressed RF pulse does not have a time side lobe. For example, weighting such as a Hamming window function may be performed. Also, Dolph-cheb
yshev window function or Taylor window function or cos ²
Weighting using a window function, a cos ³ window function, a cos ⁴ window function, or the like may be used. Further, the SAW conversion electrode for transmitting the chirp signal may have a matched filter characteristic for the input chirp signal. Conversely, SA
The transmission characteristics between the W conversion electrode and each encoding electrode may be matched filter characteristics.

[0060]

According to the configuration of the present invention, when a chirp signal is transmitted, the signal is compressed with a compression gain corresponding to the product (BT) of the dispersion time (T) and the dispersion bandwidth (B) of the chirp signal. It is possible to transmit a pulse train.

When an RF pulse is transmitted, S
When converting the superimposed chirp signal returned from the AW-ID-TAG into an RF pulse train with a matched filter,
It is possible to improve the S / N for the compression gain.

Accordingly, SAW having a large insertion loss is generally used.
Despite the use of elements, improved S / N and S
This has the advantage that the code of AW-ID-TAG can be read.

When a chirp signal is transmitted, S
In the AW-ID-TAG, the RF pulse due to the re-excitation effect, which is converted again into SAW at the encoding electrode, is converted into an electric signal again at the SAW conversion electrode formed of the chirp electrode. The pulse is converted back to a chirp signal. Therefore, the RF pulse train due to the re-excitation effect does not occur, and the code can be easily identified.

When an RF pulse is input, a chirp signal (SAW) is generated at a SAW conversion electrode composed of a chirp electrode, and the encoding electrode is re-excited as a chirp signal. Therefore, for the chirp signal due to this re-excitation, S
At the AW conversion electrode, the chirp signal is extended twice in the time direction. Since the extended signal is transmitted from the antenna, the signal due to the re-excitation is received, and the chirp signal for the re-excitation that is extended twice in the time direction is passed through the matched filter. Returning only to the length of the chirp signal does not produce an RF pulse train. Therefore, the signal of the re-excitation is different from the original signal shape and has an advantage that it can be easily distinguished from the original signal.
This advantage is a new effect that cannot be realized by the conventional technology.

In addition, the SAW-ID-T having this structure
The AG does not generate an RF pulse train even when an RF pulse is applied to the input, and a superimposed chirp signal is transmitted.

In order to transmit a pulse train, SAW
Since a chirp signal corresponding to the chirp electrode constituting the conversion electrode is required, it is extremely difficult for a third party to read the code. Therefore, it is possible to maintain the secret of the code by simple means. It is also difficult for the third party to generate the generated signal, and after all, according to the present invention, it has excellent security characteristics.

Here, a configuration for transmitting a chirp signal,
Also, in any of the examples of transmitting the RF pulse train, various configurations can be used as the encoding electrode. For example, the electrode fingers may be arranged for the phase modulation signal, or may be configured depending on the presence or absence of the electrode fingers to support on / off keying. Also, the same effect can be obtained by using an encoded electrode that is encoded by the mutual distance between the electrode fingers.

Further, with respect to the chirp electrode, the frequency characteristics of the chirp electrode are weighted by varying the frequency change rate of the chirp electrode depending on the location, so that the RF pulse to be compressed does not have time side lobes. For example, weighting such as a Hamming window function may be performed. Further, the SAW conversion electrode for transmitting the chirp signal may have a matched filter characteristic for the input chirp signal. Conversely, the transmission characteristics between the SAW conversion electrode and each encoding electrode may be matched filter characteristics.

Specifically, the present invention has the following effects.

According to the first and second aspects of the present invention, it is possible to achieve an improvement in the S / N ratio corresponding to the compression gain, and it is possible to read a code with high accuracy.

According to the third aspect of the present invention, since the transmitting and receiving antennas are shared, the SAW-ID-TAG has a simpler configuration.
Can be configured.

According to the fourth aspect of the present invention, the phase modulation is supported by changing the connection polarity of the electrode fingers.
It is possible to detect the sign of the phase-modulated signal without increasing the area of the AW element.

According to the fifth aspect of the present invention, since the position of the electrode finger is shifted to cope with the phase modulation, it is possible to detect the sign of the phase-modulated signal with a simple configuration.

According to the sixth aspect of the present invention, since the interval between the electrode fingers is shifted, it is possible to cope with the encoding based on the pulse interval.

According to the seventh aspect of the present invention, since encoding is performed depending on the presence or absence of an electrode finger, it is possible to cope with ON / OFF keying.

According to the eighth aspect of the present invention, since the weighting is performed, the time side rope can be effectively prevented.

According to the ninth aspect of the present invention, since the weighting is performed by the window function, the time side rope can be more effectively prevented.

According to the tenth aspect of the present invention, the weighting is performed by the Hamming window and other various window functions, so that the time side rope can be more effectively prevented with simple weighting.

According to the eleventh aspect of the present invention, since the pass characteristic of the ID-TAG has the filter characteristic of the matched filter, the SAW-ID-ID has a simpler configuration and a simpler configuration.
A TAG can be configured.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram illustrating a configuration of a SAW-ID-TAG when transmitting a chirp signal according to a preferred embodiment 1 of the present invention.

FIG. 2 is an explanatory diagram showing a configuration of a SAW-ID-TAG when transmitting an RF pulse according to a preferred embodiment 2 of the present invention.

FIG. 3 shows a conventional SAW-ID-TA using a SAW.
FIG. 4 is an explanatory diagram illustrating a configuration of G.

FIG. 4 shows a conventional SAW-I sharing an input / output antenna.
FIG. 3 is an explanatory diagram illustrating a configuration of a D-TAG.

FIG. 5: SAW-ID-TA using a conventional reflector
FIG. 4 is an explanatory diagram illustrating a configuration of G.

[Explanation of symbols]

10 RF pulse generator, 12 RF amplifier, 14 coupler, 16 antenna, 18 SAW-ID-TAG,
Reference Signs List 20 SAW delay line, 22 receiving antenna, 24 transmitting antenna, 26 LNA, 28 detection circuit, 30
Code detector, 40 common antenna, 42 SAW delay line, 44 coding electrode, 46 SAW conversion electrode, 50
Antenna, 52 SAW electrode, 54 SAW reflection structure,
60 SAW distributed delay line, 62 antennas, 64 S
AW conversion electrode, 66 piezoelectric substrate, 68 encoding electrode, 7
0 antenna, 72 SAW conversion electrode, 74 coding electrode, 76 matched filter.

Claims (11)

[Claims] A transmitting means for transmitting a chirp signal whose frequency changes with time; a receiving antenna means for receiving the chirp signal transmitted by the transmitting means; and an ID-TAG for obtaining an RF signal pulse train of a signal to be compared.
A SAW-ID-TAG device comprising: a receiving unit that receives an RF pulse train output by the ID-TAG device and detects and demodulates the received RF pulse train. A SAW conversion electrode provided on the piezoelectric substrate and configured to convert the chirp signal into a SAW in the form of an RF pulse, wherein the chirp electrode has a frequency delay time gradient opposite to a delay time gradient with respect to a frequency of the chirp signal. A formed SAW conversion electrode, a plurality of coded electrodes provided on a SAW propagation path on the piezoelectric substrate, and a plurality of coded electrodes each arranged at a predetermined distance from the SAW conversion electrode; Transmitting means for transmitting an RF pulse train generated by the plurality of encoding electrodes to a transmitting antenna; A SAW-ID-TAG device, comprising: 2. A transmitting means for transmitting an RF pulse signal; a receiving antenna means for receiving the RF pulse signal transmitted by the transmitting means; an ID-TAG means for obtaining a chirp signal of a signal to be compared; A receiving means for receiving a chirp signal output from the TAG device, converting the chirp signal into an RF pulse train, and detecting and demodulating the chirp signal, wherein the ID-TAG means comprises: a piezoelectric substrate; That converts the RF signal into a chirped SAW whose frequency changes with time.
A SAW conversion electrode formed of a chirp electrode having a frequency delay time gradient opposite to the tilt of the delay time with respect to the frequency of the chirp signal, and a plurality of SAW conversion electrodes provided on a SAW propagation path on the piezoelectric substrate. A plurality of coding electrodes, each of which is disposed at a predetermined distance from the SAW conversion electrode, and a transmitting unit that transmits an RF pulse train generated by the plurality of coding electrodes to a transmitting antenna; The transmitting antenna to which the chirp signal is supplied by the transmitting means, and wherein the receiving means is a matched filter corresponding to the chirp signal, and is provided at a position where the encoding electrode of the ID-TAG means is arranged. SAW-ID-TAG, comprising: a matched filter that converts a plurality of pulse trains with a prescribed delay time. apparatus. 3. The SAW-ID-TA according to claim 1 or 2.
In the G device, the transmission antenna and the reception antenna share the same antenna.
apparatus. 4. The SAW-ID-TA according to claim 1,
The SAW-ID-TAG device according to claim G, wherein the coding electrode is a coding electrode corresponding to phase modulation by changing a connection polarity of an electrode finger. 5. SAW-ID-TA according to claim 1 or 2
In the G device, the SAW-ID-TAG device is characterized in that the encoding electrode is an encoding electrode corresponding to phase modulation by shifting the position of an electrode finger in the SAW propagation direction. 6. The SAW-ID-TA according to claim 1 or 2.
In the G device, the SAW-ID-TAG device is characterized in that the encoding electrode is an encoding electrode in which the interval between electrode fingers is changed in order to cope with encoding of a pulse interval. 7. The SAW-ID-TA according to claim 1 or 2.
The SAW-ID-TAG device according to claim G, wherein the coding electrode is a coding electrode corresponding to ON / OFF keying depending on the presence / absence of an electrically connected electrode finger. 8. The SAW-ID-TAG device according to claim 1, wherein the SAW conversion electrode is weighted so as not to generate a time side lobe in the converted RF pulse. SAW-ID-T characterized by:
AG device. 9. The SAW-ID-TAG device according to claim 8, wherein the weighting is performed based on a predetermined window function. 10. The SAW-ID-TAG device according to claim 9, wherein the predetermined window function is a Hamming window or a Dolph-ch.
ebyshev window function or Taylor window function or co
A SAW-ID-TAG device, which is an s ² window function, a cos ³ window function, or a cos ⁴ window function. 11. The SAW-ID device according to claim 1, wherein the pass characteristic of the ID-TAG means has a matched filter characteristic for the input chirp signal. -TAG device.