JP3931803B2 - Communication system and interrogator of communication system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a communication system including a plurality of interrogators and responders, and an interrogator constituting the communication system.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a mobile object detection system is known in which a plurality of interrogators are installed in close proximity, and each interrogator is connected to and controlled by another interrogator and a host in a wired manner to detect and identify adjacent mobile objects ( For example, see Patent Document 1.)
[0003]
Also, when multiple interrogators and responders are installed, each interrogator uses a different frequency to prevent possible interference when multiple interrogators communicate simultaneously towards a given responder. Communication systems that communicate with responders are also well known (see, for example, Patent Document 2).
[0004]
Further, as communication between radio base stations, communication methods such as FA (Frequency Modulation) method, AM (Amplitude Modulation) method, FSK (Frequency Shift Keying) method, ASK (Amplitude Shift Keying) method and the like are often used. Recently, an OFDM (Orthogonal Frequency Division Multiplex) scheme has been spotlighted and used as a communication scheme with good frequency utilization efficiency (see, for example, Patent Document 3).
[0005]
[Patent Document 1]
JP-A-6-68330
[Patent Document 2]
Japanese Patent No. 2624815
[Patent Document 3]
JP 11-298438 A
[0006]
[Problems to be solved by the invention]
However, when the interrogators are connected by a wired network, the wiring is troublesome, so the installation location is limited, the expansion is not easy, and the wiring is stretched everywhere, so the wiring is conspicuous and aesthetic The feeling was poor. In addition, the OFDM method is a promising method with excellent frequency utilization efficiency, but it has been put into practical use in the field of high-speed digital communication, but the efficiency of the entire system has progressed, such as the sharing of processing with other systems. Not.
[0007]
Accordingly, an object of the present invention is to provide a communication system and an interrogator of the communication system that are easy to change and add to the arrangement of the interrogator and have an excellent aesthetic feeling.
[0008]
[Means for Solving the Problems]
The communication system according to claim 1, in a communication system including a plurality of interrogators and a responder, transmits an interrogation wave from each interrogator between each interrogator and the responder, The responder that has received the interrogation wave performs communication by returning a reflected wave obtained by performing predetermined modulation on the interrogation wave to the interrogator, and the interrogator wirelessly uses a communication wave. Communication is performed. According to the first aspect, since communication between the interrogators is performed wirelessly, it is easy to change or increase the arrangement of the interrogators, and there is no wiring.
[0009]
The communication system according to claim 2 is the communication system according to claim 1, wherein a frequency band of the reflected wave and a frequency band of the communication wave are separated, and the reflected wave is separated from the frequency band of the communication wave. The frequency band is close to the frequency of the interrogation wave. According to claim 2, since the frequency band of the reflected wave reflected by the responder and the frequency band of the communication wave used for communication between the interrogators are separated, the reflected wave and the communication wave interfere with each other. Can be prevented. Furthermore, since the frequency band of the reflected wave is closer to the frequency of the interrogation wave than the frequency band of the communication wave, the power consumed by the responder can be reduced.
[0010]
The communication system according to claim 3 is the communication system according to claim 2, wherein a difference between the frequency of the frequency band of the communication wave closest to the frequency of the interrogation wave and the frequency of the interrogation wave is the reflected wave. The difference between the frequency farthest from the frequency of the interrogation wave and the frequency of the interrogation wave in the frequency band is substantially twice or more. According to claim 3, even if the communication wave used for communication between the interrogators is reflected by the responder, the frequency band of the reflected wave for the interrogation wave and the frequency band of the reflected wave for the communication wave overlap. Nothing will happen. As a result, since the interference between the interrogator and the responder can be suppressed, the reliability of the communication becomes high, and the communication between the interrogator and the responder and the communication between the interrogators are performed simultaneously and at a frequency. Can be used efficiently.
[0011]
The communication system according to claim 4 is the communication system according to claim 2, wherein a difference in frequency of interrogation waves transmitted from each of two interrogators that communicate with each other wirelessly among the plurality of interrogators is as follows: Substantially equal to a value obtained by adding four times the difference between the frequency of the reflected wave farthest from the frequency of the interrogation wave and the frequency of the interrogation wave and the frequency bandwidth of the communication wave Or larger. According to the fourth aspect, the reflected wave in the responder for the interrogation wave transmitted by each interrogator, the reflected wave in the responder for the communication wave, and the communication wave can be prevented from overlapping each other. As a result, since the interference between the interrogator and the responder can be suppressed, the reliability of communication and communication between the interrogators becomes high. In addition, the difference in the frequency of the interrogation wave transmitted by each of the two interrogators is four times the difference between the frequency of the interfering wave farthest from the frequency of the interrogation wave and the frequency of the interrogation wave, and the frequency of the communication wave. If the bandwidth is substantially equal to the value obtained by adding the bandwidth, the frequency utilization efficiency of each interrogator can be maximized.
[0012]
The communication system according to claim 5 is the communication system according to any one of claims 1 to 4, wherein the frequency band of the communication wave having the same information is a frequency region on both sides of the frequency of the interrogation wave. It exists in According to claim 5, since the communication wave having the same information exists on both sides of the interrogation wave, it is not necessary to switch the transmission of the communication wave, and transmission is performed simultaneously to two (or more) adjacent interrogators. And efficient communication is possible.
[0013]
A communication system according to a sixth aspect is the communication system according to any one of the first to fifth aspects, wherein the communication wave is modulated by an OFDM method. According to the sixth aspect, since the OFDM method is used as the modulation method, the frequency band can be effectively used as compared with the modulation method using a carrier wave of one frequency.
[0014]
The communication system according to claim 7 is the communication system according to claim 6, wherein the interrogator mainly uses OFDM signal generation means for generating an OFDM signal and the OFDM signal generated by the OFDM signal generation means. Mixer means for up-converting with a carrier wave to make the communication wave, and combining means to make the transmission wave by combining the communication wave from the mixer means and the interrogation wave obtained by modulating or not modulating the main carrier wave Detection means for detecting the received wave received by the interrogator, AD conversion means for converting the received wave detected by the detection means into a digital signal, and the reflected wave converted by the AD conversion means as the reflection A received wave separating means for separating a wave and a communication wave from the other interrogator, and a reflected wave demodulating means for demodulating the reflected wave separated by the received wave separating means; Characterized in that and a communication wave demodulating means for demodulating the communication wave from the other interrogator separated by the receiving wave separating means. According to the seventh aspect, the interrogation wave and the communication wave can be transmitted at the same time, and the reflection wave and the communication wave can be demodulated separately, so that the interrogation wave and the communication wave can be received simultaneously. Can be realized.
[0015]
The communication system according to an eighth aspect is the communication system according to the seventh aspect, wherein the reflected wave demodulation means and the communication wave demodulation means share a Fourier transform means. According to claim 8, by sharing the Fourier transform means, it is possible to perform efficient demodulation and to simplify the structure of the interrogator.
[0016]
In addition, you may make it provide the interrogator which comprises the communication system of any one of Claim 1 to Claim 8 alone (Claim 9).
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a communication system according to an embodiment of the present invention will be described with reference to the drawings.
[0018]
First, the configuration of a communication system according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a diagram illustrating a configuration example of a communication system according to an embodiment.
[0019]
The communication system 1 includes five interrogators 2a to 2e and three responders 3a to 3c. The interrogator 2a connected to the network has a processing function for performing various service processes, and information such as instructions addressed to at least one predetermined interrogator from the interrogator 2a passes through the adjacent interrogator. And various service processes are performed such that information such as predetermined response information obtained by the interrogator is transmitted to the interrogator 2a via the adjacent interrogator. Also, the interrogator does not have a service processing function, and the collected information may be sent to other devices on the network (not shown) between the interrogators and the service processing may be performed there. Since this service process is not directly related to the present invention, its description is omitted.
[0020]
In the communication between the interrogators 2a to 2e and the responders 3a to 3c, the interrogators 2a to 2e transmit interrogation waves whose main carriers are modulated with predetermined information, and the responders 3a to 3a that receive the interrogation waves. 3c is a reflected wave obtained by modulating the received interrogation wave with predetermined information (for example, the identification number (responder ID) of the responder given to identify the responder) (this reflected wave is a response wave) .) Is done by replying. Communication between the interrogators 2a to 2e is performed wirelessly, and the transmitting side transmits transmission information (for example, an identification number (interrogator for identifying the interrogator directly obtained from the responder and its own interrogator). ID), a communication wave (a radio wave transmitted / received by wireless communication between the interrogators) including the responder ID received from the adjacent interrogator and the interrogator ID of the interrogator that received the transponder ID from the responder. Transmission and reception are performed by receiving this communication wave. Note that the interrogators 2a to 2e may transmit the interrogation wave as it is without modulating the main carrier wave.
[0021]
Hereinafter, the electrical configurations of the interrogators 2a to 2e and the responders 3a to 3c constituting the communication system 1 shown in FIG. 1 will be described in order with reference to the drawings.
[0022]
First, the electrical configuration of the interrogator 2a will be described with reference to FIG. FIG. 2 is a block diagram showing an electrical configuration of the interrogator 2a. The electrical configuration of the interrogators 2b to 2e is substantially the same as that of the interrogator 2a, and the description of the interrogator 2a can be applied.
[0023]
As shown in FIG. 2, the interrogator 2a includes a DSP (Digital Signal Processor) 21, an oscillator 22, a DA converter 23, an up converter 24, a modulator 25, a multiplexer 26, a power amplifier 27, and the like. The circulator 28, a low noise amplifier (LNA) 29, a homodyne detector 30, an AD converter 31, and an antenna 32.
[0024]
In this embodiment, the DSP 21 functions as an OFDM signal generation unit 21a, a BS signal generation unit 21b, a separation unit 21c, an OFDM demodulation unit 21d, and a BS demodulation unit 21e.
[0025]
The OFDM signal generator 21a modulates the information received from the responder or other interrogator using the OFDM modulation method to generate an OFDM signal, and outputs the generated OFDM signal to the DA converter 23. In the ODFM method, a plurality of carriers having different frequencies are used, and the frequencies of the plurality of carriers used in the present embodiment are set to frequencies fs1, fs2,..., Fsn (fs1 <fs2 <... Fsn), respectively. . However, the interrogators 2b to 2e also use the same frequency. In addition, you may set the frequency of each carrier of the interrogators 2a-2e so that it may differ.
[0026]
The BS signal generation unit 21 b generates a BS (Backscatter) signal including information such as the ID number, hopping timing, or hopping pattern of the interrogator 2 itself, and outputs the generated BS signal to the modulator 25.
[0027]
The separation unit 21c separates a digital signal from the AD converter 31 (a radio wave received by the antenna 32) into a signal corresponding to a communication wave from an adjacent interrogator and a signal corresponding to a response wave from a responder. Then, a signal corresponding to the communication wave is output to the OFDM demodulator 21d, and a signal corresponding to the response wave is output to the BS demodulator 21e. The OFDM demodulator 21d demodulates the signal from the separator 21c and extracts information contained in the communication wave from the adjacent interrogator. The BS demodulator 21e demodulates the signal from the separator 21c and takes out information from the responder.
[0028]
The oscillator 22 oscillates a main carrier wave having a frequency such as 900 MHz, 2.4 GHz, and 5 GHz, and outputs the oscillated main carrier wave to the up converter 24, the modulator 25, and the homodyne detector 30. However, the frequency at which the oscillators of the interrogators 2a to 2e oscillate is different. Note that the frequencies of the main carriers oscillated by the oscillators of the interrogators 2a, 2b, 2c, 2d, and 2e are frequencies fca, fcb, fcc, fcd, and fce, respectively.
[0029]
The DA converter 23 converts the digital OFDM signal input from the OFDM signal generator 21 a of the DSP 21 into an analog signal and outputs the analog signal to the up converter 24. The up-converter 24 up-converts the OFDM signal converted into the analog signal by the DA converter 23 using the main carrier wave oscillated by the oscillator 22 and outputs the result to the multiplexer 26. As shown in FIG. 5, the frequency of the signal output from the up-converter 24 of the interrogator 2a is the frequencies fca-fsn,..., Fca-fs2, fca-fs1, fca + fs1, fca + fs2,.
[0030]
However, the frequency of the signal output from the up-converter of the interrogator 2b is the frequencies fcb-fsn,..., Fcb-fs2, fcb-fs1, fcb + fs1, fcb + fs2,..., Fcb + fsn. Further, the frequency of the signal output from the up-converter of the interrogator 2c is the frequency fcc-fsn,..., Fcc-fs2, fcc-fs1, fcc + fs1, fcc + fs2, ..., fcc + fsn. Further, the frequency of the signal output from the up-converter of the interrogator 2d is the frequency fcd-fsn,..., Fcd-fs2, fcd-fs1, fcd + fs1, fcd + fs2, ..., fcd + fsn. Furthermore, the frequency of the signal output from the up-converter of the interrogator 2e is the frequency fce-fsn, ..., fce-fs2, fce-fs1, fce + fs1, fce + fs2, ..., fce + fsn.
[0031]
The modulator 25 performs amplitude modulation (Amplitude Shift Keying: ASK) on the BS signal input from the BS signal generator 21 b of the DSP 21, modulates the main carrier wave input from the oscillator 22, and outputs the result to the multiplexer 26.
[0032]
The combiner 26 combines the signal from the up-converter 24 and the signal from the modulator 25 and outputs the combined signal to the power amplifier 27. The power amplifier 27 amplifies the signal from the multiplexer 26 and outputs the amplified signal to the circulator 28. The circulator 28 separates the output and the input so as to transmit the signal input from the power amplifier 27 to the antenna 32 and to transmit the radio wave received by the antenna 32 to the LNA 29. A signal transmitted to the antenna 32 is radiated from the antenna 32.
[0033]
The radio wave radiated from the antenna 32 from the OFDM signal generation unit 21a of the DSP 21 through the DA converter 23, the up converter 24, the multiplexer 26, the power amplifier 27, and the circulator 28 is used for communication between the interrogators. It is. Further, the radio wave radiated from the antenna 32 from the BS signal generation unit 21b of the DSP 21 through the modulator 25, the multiplexer 26, the power amplifier 27, and the circulator 28 is communicated between the interrogator 2a and the responders 3a to 3c. Is an interrogation wave transmitted from the interrogator 2a used to the responders 3a to 3c.
[0034]
As can be seen from the above, the frequency band (hereinafter, abbreviated as the band) of the communication wave transmitted by each interrogator to the adjacent interrogator exists on both sides of the frequency of the interrogation wave. The bands of the communication waves are frequencies fca-fsn to fca-fs1, fca + fs1 to fca + fsn, and the frequency of the interrogation wave is the frequency fca.
[0035]
Similarly, in the interrogator 2b, the band of the communication wave is the frequencies fcb-fsn to fcb-fs1, fcb + fs1 to fcb + fsn, and the frequency of the interrogation wave is the frequency fcb. In the interrogator 2c, the band of the communication wave is frequencies fcc-fsn to fcc-fs1, fcc + fs1 to fcc + fsn, and the frequency of the interrogation wave is the frequency fcc. Further, in the interrogator 2d, the band of the communication wave is the frequency fcd-fsn to fcd-fs1, fcd + fs1 to fcd + fsn, and the frequency of the interrogation wave is the frequency fcd. Further, in the interrogator 2e, the band of the communication wave is the frequency fce-fsn to fce-fs1, fce + fs1 to fce + fsn, and the frequency of the interrogation wave is the frequency fce.
[0036]
The LNA 29 amplifies the received signal from the interrogator or responder received by the antenna 32 input from the circulator 28 and outputs the amplified signal to the homodyne detector 30. The homodyne detector 30 mixes the received signal amplified by the LNA 29 with the main carrier wave input from the oscillator 22, performs homodyne detection, and outputs it to the AD converter 31. The AD converter 31 converts an analog signal input from the homodyne detector 30 into a digital signal and outputs the digital signal to the separation unit 21 c of the DSP 21.
[0037]
When a communication wave is received from an adjacent interrogator by the antenna 32, the received communication wave is transmitted to the OFDM demodulator of the DSP 21 via the circulator 28, the LNA 29, the homodyne detector 30, the AD converter 31, and the separation unit 21c of the DSP 21. 21d and demodulated by the OFDM demodulator 21d. When the response wave is received from the responders 3a to 3c by the antenna 32, the received response wave is transmitted to the DSP 21 via the circulator 28, the LNA 29, the homodyne detector 30, the AD converter 31, and the DSP 21 separation unit 21c. To the BS demodulator 21e and demodulated by the BS demodulator 21e.
[0038]
Here, an example of details of the separation unit 21c, the OFDM demodulation unit 21d, and the BS demodulation unit 21e in FIG. 2 will be described with reference to FIG. FIG. 3 is a block diagram illustrating an electrical configuration for explaining an example of details of the separation unit 21c, the OFDM demodulation unit 21d, and the BS demodulation unit 21e.
[0039]
Examples of details of the separation unit 21c, the OFDM demodulation unit 21d, and the BS demodulation unit 21e in FIG. 2 include an FIR filter 33, a decimation unit 34, a polyphase filter 35, a buffer 36, a buffer 37, an FFT unit 38, and a switch 39a. 39b.
[0040]
The output of the AD converter 31 is input to the FIR filter 33 and also input to the buffer 37, and the value of the output of the AD converter 31 is directly accumulated in the buffer 37. Then, the buffer 37 and the FFT unit 38 are appropriately connected by the switch 39a, and the signal accumulated in the buffer 37 is output to the FFT unit 38.
[0041]
The output of the AD converter 31 input to the FIR filter 33 is subjected to removal of the communication wave by the FIR filter 33, the sampling rate is lowered by the decimation unit 34, and after passing through the polyphase filter 35 used for the filter bank, the buffer 36 Accumulated in. Then, the buffer 36 and the FFT unit 38 are appropriately connected by the switch 39a, and the signal accumulated in the buffer 36 is output to the FFT unit 38 as appropriate.
[0042]
The FFT unit 38 obtains an OFDM demodulated signal by performing fast Fourier transform (FFT) on the data from the buffer 37, and the OFDM demodulated signal is sent to a signal processing unit in the DSP 21 (not shown) via the switch 39b. It is output and analyzed by the signal processor. Further, the FFT unit 38 performs FFT on the data from the buffer 36, that is, the polyphase filter 35 and the FFT unit 38 can form a filter bank, so that a BS demodulated signal can be obtained simultaneously for each hopping frequency. The BS demodulated signal is output to a signal processing unit in the DSP 21 (not shown) via the switch 39b and analyzed by the signal processing unit.
[0043]
The BS demodulated signal analyzed by the signal processing unit is separated into appropriate frames, sorted for each responder, and further demodulated by connecting to each responder to extract information from the responder. Here, the BS demodulated signal has a lower data rate than the OFDM demodulated signal, and the data amount and storage speed of the buffer 36 are also reduced by thinning. As a result, the rate at which the FFT is performed is much smaller than the rate at which the FFT is demodulated, and both the BS demodulation process and the OFDM demodulation process can be performed at a sufficient speed even if the FFT unit 38 is shared and switched. it can. By sharing the FFT unit 38, the system configuration is simplified, and the processing efficiency is improved. During OFDM demodulation, a reflected wave part is generated in the low frequency part due to FFT, but the signal level is low. Therefore, only the component corresponding to the OFDM carrier frequency may be extracted as a demodulated signal. Further, a filter for removing the reflected wave component may be added before the buffer 37.
[0044]
Next, the electrical configuration of the responder 3a will be described with reference to FIG. FIG. 4 is a block diagram showing an electrical configuration of the responder 3a. The electrical configuration of the responders 3b and 3c is substantially the same as that of the responder 3a. Since the explanation of the responder 3a can be applied, details are omitted.
[0045]
As shown in FIG. 4, the responder 3 a includes a modem 41, a digital circuit unit 42, and an antenna 43. The modem 41 demodulates the radio waves (interrogation waves of the interrogators 2a to 2e) received by the antenna 43 and outputs the demodulated waves to the controller 42a described later of the digital circuit unit 42. Further, the modem 41 modulates the interrogation wave with a subcarrier modulated by a subcarrier modulator 42c (to be described later) of the digital circuit unit 42, and the modulated wave is transmitted from the antenna 33 as a reflected wave. This reflected wave becomes a response wave.
[0046]
The digital circuit unit 42 includes a controller 42a, a subcarrier oscillator 42b, and a subcarrier modulator 42c. The controller 42a controls the responder 4a. The subcarrier oscillator 42b oscillates the subcarrier and outputs the oscillated subcarrier to the subcarrier modulator 42c. The subcarrier modulator 42c is controlled by the controller 42a, and an information signal (for example, transponder ID) or the like is phase-modulated (Phase Shift Keying: PSK) and is input from the subcarrier oscillator 42b as necessary. The carrier wave is modulated, and the modulated subcarrier wave is output to the modem 41. However, the frequency of the subcarrier oscillated by the subcarrier oscillator 42b is frequency hopped, the minimum hopping frequency is the frequency fl, and the maximum hopping frequency is the frequency fh. Note that the subcarrier oscillator 42b and the subcarrier modulator 42c may be configured in software using the clock of the controller 42a. The subcarrier modulation may be frequency modulation (FSK) in addition to phase modulation. Further, the subcarrier oscillator 42b and the subcarrier modulator 42c may be provided in the controller 42a and integrated into one chip.
[0047]
When the antenna 43 receives the interrogation waves from the interrogators 2a to 2e, it is demodulated by the modem 41 and output to the controller 42a of the digital circuit unit 42. Thereby, the controller 42a knows that the interrogation wave is being received. Controlled by the controller 42a, which has found that the interrogation wave is being received, the subcarrier modulator 42c modulates the subcarrier input from the subcarrier oscillator 42b with the information signal, and outputs the modulated subcarrier to the modem 41. To do. The modem 41 modulates the interrogation wave being received by the subcarrier modulated by the subcarrier modulator 42 c and transmits a response wave from the antenna 43.
[0048]
However, the frequency bands (hereinafter, abbreviated as “bands”) of response waves transmitted by the responders 3a to 3c that have received the interrogation wave from the interrogator 2a are frequency fca−fh to frequency fca−fl and frequency fca + fl to frequency fca + fh. It becomes. The response wave bands transmitted by the responders 3a to 3c that have received the interrogation wave from the interrogator 2b are fcb-fh to fcb-fl and fcb + fl to fcb + fh. The response wave bands transmitted by the responders 3a to 3c that have received the interrogation wave from the interrogator 2c are fcc-fh to fcc-fl and fcc + fl to fcc + fh. The response wave bands transmitted by the responders 3a to 3c that have received the interrogation wave from the interrogator 2d are fcd−fh to fcd−fl and fcd + fl to fcd + fh. The response wave bands transmitted by the responders 3a to 3c that have received the interrogation wave from the interrogator 2e are fce−fh to fce−fl, and frequency fce + fl to frequency fce + fh.
[0049]
Hereinafter, the relationship of the frequency arrangement of radio waves used for communication in the communication system 1 will be described with reference to FIG. FIG. 5 is an explanatory diagram for explaining the relationship of the frequency arrangement of radio waves used in the communication system 1.
[0050]
Point A (frequency fca) indicates the frequency of the interrogation wave transmitted by the interrogator 2a.
Point Aa (frequency fca-fh to frequency fca-fl) and point Ab (frequency fca + fl to frequency fca + fh) are response waves that are transmitted by modulating and reflecting the interrogation wave transmitted from the interrogator 2a by the responders 3a to 3c. Indicates the bandwidth.
Point AB (frequency fcb-fsn to frequency fcb-fs1: frequency fca + fs1 to frequency fca + fsn) indicates a band of communication waves used in communication between the interrogator 2a and the interrogator 2b.
[0051]
Point B (frequency fcb) indicates the frequency of the interrogation wave transmitted by the interrogator 2b.
Point Ba (frequency fcb-fh to frequency fcb-fl) and point Bb (frequency fcb + fl to frequency fcb + fh) are response waves that are transmitted by modulating and reflecting the interrogation wave transmitted from the interrogator 2b by the responders 3a to 3c. Indicates the bandwidth.
Point BC (frequency fcb + fs1 to frequency fcb + fsn: frequency fcc−fsn to frequency fcc−fs1) indicates a band of communication waves used in communication between the interrogator 2b and the interrogator 2c.
[0052]
Point C (frequency fcc) indicates the frequency of the interrogation wave transmitted by the interrogator 2c.
Point Ca (frequency fcc-fh to frequency fcc-fl) and point Cb (frequency fcc + fl to frequency fcc + fh) are response waves that are transmitted by modulating and reflecting the interrogation wave transmitted from the interrogator 2c by the responders 3a to 3c. Indicates the bandwidth.
[0053]
As can be seen from the point AB, when the adjacent interrogators 2a and 2b do not communicate at the same time but communicate with each other alternately, the communication wave band can be shared, so the communication transmitted by the interrogator 2b. The frequency fca of the interrogation wave of the interrogator 2a, the frequency fcb of the interrogation wave of the interrogator 2b, the minimum carrier frequency fs1, and the maximum carrier frequency fsn so that the wave band and the band of the communication wave transmitted by the interrogator 2a overlap. Is set. Similarly, each frequency is set so that communication waves transmitted by adjacent interrogators used for communication between adjacent interrogators 2b to 2e overlap each other.
[0054]
As can be seen from the points Ab and AB, the response wave band (Ab in the figure) transmitted by the interrogator 2a being modulated and reflected by the interrogators 2a to 3c, the interrogator 2a and the interrogator The lowest carrier frequency fs1, the highest carrier frequency fsn, the lowest hopping frequency fl, and the highest hopping frequency fh are set so as not to overlap with the communication wave band (AB in the figure) used for communication with 2b. Yes. Similarly, the response wave bands of the responders 3a to 3c with respect to the interrogation waves of the interrogators 2b, 2c, 2d, and 2e do not overlap with the communication wave band transmitted by the interrogator that transmitted the interrogation waves. The lowest carrier frequency fs1, the highest carrier frequency fsn, the lowest hopping frequency fl, and the highest hopping frequency fh are set.
In this way, the communication wave band and the response wave band do not overlap, that is, by separating, the communication wave and the response wave do not interfere with each other. It is possible to communicate between the two at the same time.
[0055]
Further, as can be seen from the points Ab and AB, the band of the response wave (Ab in the figure) transmitted by modulating and reflecting the interrogation wave transmitted from the interrogator 2a by the responders 3a to 3c is the interrogator 2a. The lowest carrier frequency fs1, the highest carrier frequency fsn, the lowest hopping frequency fl, and the highest hopping frequency fh so as to be closer to the frequency fca than the band of communication waves (AB in the figure) used for communication with the interrogator 2b. Is set. Similarly, the interrogator 2b, 2c, 2d, 2e responds to the interrogation waves transmitted by the interrogator that transmits the interrogation wave transmitted by the interrogator that transmitted the interrogation wave. The lowest carrier frequency fs1, the highest carrier frequency fsn, the lowest hopping frequency fl, and the highest hopping frequency fh are set so as to be close to the frequency of the interrogation wave.
By setting in this way, the frequency of the subcarrier oscillated by the subcarrier oscillator 42b of the responders 3a to 3c can be kept low, so that the power consumed by the responders 3a to 3c can be kept low. . Also, in general, many responders are installed, many move, and are often driven by batteries, so it is often difficult to supply power, so it is desirable to keep power consumption smaller than the interrogator. In this respect, the frequency setting described above is effective.
[0056]
In order to perform communication with less interference, the communication wave band does not overlap with the response wave band, and the communication wave transmitted along with the interrogation wave is modulated and reflected by the responder, and is also an unnecessary reflected wave band. It needs to be set not to overlap. Since the transponder indicated by the dotted line generates a reflected wave having the same bandwidth as that of the interrogation wave for each carrier of the frequencies fs1 to fsn of the communication wave, the frequency fsn + fl is generated from the frequency fs1−fh. Unnecessary reflected waves of up to the band are generated for each communication wave. In other words, the difference between the frequency of the interrogation wave farthest from the interrogation wave and the frequency of the interrogation wave reflected by the transponder modulated and reflected by the transponder is the frequency farthest from the communication wave of the interfering wave reflected by the transponder. And the frequency closest to the communication wave are the same (that is, fh).
Based on the above points, the lowest frequency of the communication wave band (AB in the figure) used for communication between the interrogator 2a and the interrogator 2b (the frequency closest to the interrogation wave transmitted by the interrogator 2a) The difference (fs1) between fca + fs1 and the frequency fca of the interrogation wave transmitted by the interrogator 2a is the band of the response wave transmitted by modulating and reflecting the interrogation wave transmitted from the interrogator 2a by the responders 3a to 3c (see FIG. The difference between the highest frequency (the frequency farthest from the interrogation wave transmitted by the interrogator 2a) fca + fh and the frequency fca of the interrogation wave transmitted by the interrogator 2a is substantially twice or more of the middle Ab) The lowest carrier frequency fs1 and the highest hopping frequency fh are set so that (fs1 ≧ 2 × fh). Similarly, in each interrogator and each responder, the frequency closest to the interrogation wave transmitted from the interrogator in the band of the communication wave transmitted from the interrogator and the frequency of the interrogation wave transmitted from the interrogator The difference is substantially more than twice the difference between the frequency of the interrogation wave farthest from the interrogation wave in the band of the reflected wave in which the interrogation wave transmitted by the interrogator is modulated and reflected by the responders 3a to 3c. The lowest carrier frequency fs1 and the highest hopping frequency fh are set so that
By setting in this way, even if the communication wave used for communication between the interrogators is reflected by the transponder, the reflected wave band for the interrogation wave and the reflected wave band for the communication wave overlap. As a result, the reliability of the communication between the interrogator and the responder becomes high, and the communication between the interrogator and the responder and the communication between the interrogators can be performed simultaneously. It becomes possible. Note that, from the viewpoint of increasing frequency efficiency, it is preferable to double (actually, double as much as possible).
[0057]
When adjacent interrogators generate and transmit communication waves using carriers of the same frequency, and when the bands of the reflected waves of the responders are the same, the frequency fca of the interrogation wave transmitted by the interrogator 2a and the interrogator The difference (fcb−fca) between the interrogation wave frequency fcb transmitted by the interrogator 2b is the band of the interrogation wave transmitted from the interrogator 2a; 2b after being modulated and reflected by the transponders 3a to 3c. The difference between the frequency fca + fh; fcb−fh farthest from the interrogation wave transmitted from the interrogator 2a; 2b (Ab; Ba in the figure) and the frequency fca; fcb of the interrogation wave transmitted from the interrogator 2a; 2b 4 times (fh = (fca + fh) −fh; fh = fcb− (fcb−fh))) and a band of communication waves (AB in the figure) used for communication between the interrogator 2a and the interrogator 2b. Width (fsn−f 1) and the sum (4 × fh + (fsn−fs1)) or larger (fcb−fca ≧ 4 × fh + (fsn−fs1)), the frequency fca of the interrogation wave of the interrogator 2a, the question The frequency fcb, the lowest carrier frequency fs1, the highest carrier frequency fsn, and the highest hopping frequency fh of the interrogator 2b are set. Similarly, in each interrogator and each responder, the difference between the frequency farthest from the interrogation wave and the frequency of the interrogation wave in the reflected wave band in which the interrogation wave transmitted from the interrogator is modulated and reflected by the transponder. Of the interrogator, the lowest carrier frequency fs1, and the highest carrier frequency so that it is substantially equal to or larger than the value obtained by adding four times the bandwidth and the bandwidth of the communication wave. fsn and the maximum hopping frequency fh are set.
By setting the frequency in this way, it is possible to prevent the reflected wave for the interrogation wave transmitted by each interrogator, the reflected wave for the communication wave, and the communication wave from interfering with each other. The communication between the responder and the communication between the interrogators becomes highly reliable. From the viewpoint of frequency efficiency, it is preferable to set each frequency so that fcb−fca = 4 × fh + (fsn−fs1) (actually as close as possible). The same applies to other cases.
[0058]
Since the communication system according to the embodiment described above performs communication between the interrogators 2a to 2e wirelessly, it is easy to change the arrangement of the interrogators 2a to 2e and add them, and there is no wiring and excellent aesthetics. Yes. Further, by setting each frequency as described above, the communication wave used for communication between the interrogators 2a to 2e, the reflected wave (response wave) with respect to the interrogation wave, and the reflected wave with respect to the communication wave interfere with each other. And the communication reliability is high.
[0059]
In addition, when transferring information from an interrogator located at a position apart from an interrogator having a service processing function to an interrogator having a service processing function, it is possible to transfer the information via an interrogator in between. The electric power required for the communication wave can be reduced.
[0060]
The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various design changes can be made as long as they are described in the claims. . For example, there may be a case where the reflected waves modulated and reflected by the interrogators have different bands, but in this case as well, the frequency farthest from the interrogator is selected among the frequencies of the reflected waves. Each frequency may be set so that the frequency arrangement described in the above embodiment is satisfied. In the above embodiment, the communication wave is described as an example using the OFDM method. However, if each frequency of the communication wave and the interrogation wave is set to satisfy the requirements of the present invention as described above, Needless to say, a general modulation (transmission) method such as FM (FSK) or spread spectrum communication (frequency hopping method) may be used. Further, the interrogation wave frequencies fca, fcb, fcc, fcd, fce, the lowest carrier frequency fs1, the highest carrier frequency fsn, the lowest hopping frequency fl, and the highest hopping frequency fh are not related as described in the above embodiment. However, it is sufficient that the frequency relationship as described in the claims is satisfied.
[0061]
【The invention's effect】
According to the first aspect, since communication between the interrogators is performed wirelessly, it is easy to change or increase the arrangement of the interrogators, and there is no wiring.
[0062]
According to claim 2, since the frequency band of the reflected wave reflected by the responder and the frequency band of the communication wave used for communication between the interrogators are separated, the reflected wave and the communication wave interfere with each other. Can be prevented. Furthermore, since the frequency band of the reflected wave is closer to the frequency of the interrogation wave than the frequency band of the communication wave, the power consumed by the responder can be reduced.
[0063]
According to claim 3, even if the communication wave used for communication between the interrogators is reflected by the responder, the frequency band of the reflected wave for the interrogation wave and the frequency band of the reflected wave for the communication wave overlap. Nothing will happen. As a result, since the interference between the interrogator and the responder can be suppressed, the reliability of the communication becomes high, and the communication between the interrogator and the responder and the communication between the interrogators are performed simultaneously and at a frequency. Can be used efficiently.
[0064]
According to the fourth aspect, the reflected wave in the responder for the interrogation wave transmitted by each interrogator, the reflected wave in the responder for the communication wave, and the communication wave can be prevented from overlapping each other. As a result, since the interference between the interrogator and the responder can be suppressed, the reliability of communication and communication between the interrogators becomes high. In addition, the difference in the frequency of the interrogation wave transmitted by each of the two interrogators is four times the difference between the frequency of the interfering wave farthest from the frequency of the interrogation wave and the frequency of the interrogation wave, and the frequency of the communication wave. If the bandwidth is substantially equal to the value obtained by adding the bandwidth, the frequency utilization efficiency of each interrogator can be maximized.
[0065]
According to claim 5, since the communication wave having the same information exists on both sides of the interrogation wave, it is not necessary to switch the transmission of the communication wave, and transmission is performed simultaneously to two (or more) adjacent interrogators. And efficient communication is possible.
[0066]
According to the sixth aspect, since the OFDM method is used as the modulation method, the frequency band can be effectively used as compared with the modulation method using a carrier wave of one frequency.
[0067]
According to the seventh aspect, the interrogation wave and the communication wave can be transmitted at the same time, and the reflection wave and the communication wave can be demodulated separately, so that the interrogation wave and the communication wave can be received simultaneously. Can be realized.
[0068]
According to claim 8, by sharing the Fourier transform means, it is possible to perform efficient demodulation and to simplify the structure of the interrogator.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a configuration example of a communication system according to an embodiment of the present invention.
2 is a block diagram showing an electrical configuration of an interrogator constituting the communication system of FIG. 1. FIG.
3 is a block diagram for explaining details of a part of the DSP shown in FIG. 2; FIG.
4 is a block diagram showing an electrical configuration of a responder constituting the communication system of FIG. 1. FIG.
5 is an explanatory diagram for explaining a frequency arrangement of radio waves used in the communication system of FIG. 1; FIG.
[Explanation of symbols]
1 Communication system
2a-2e Interrogator
3a-3c transponder
21 DSP
21a OFDM signal generator
21b BS signal generator
21c Separation part
21d OFDM demodulator
21e BS demodulator
22 Oscillator
23 DA converter
24 Upconverter
25 Modulator
26 MUX
27 Power Amplifier
28 Circulator
29 LNA
30 Homodyne detector
31 AD converter
32 Antenna
33 FIR filter
34 Thinning device
35 Polyphase filter
36, 37 buffers
38 FFT section
41 modem
42 Digital circuit
43 Antenna
42a controller
42b Subcarrier oscillator
42c Subcarrier modulator

Claims (9)

In a communication system comprising a plurality of interrogators and responders,
Between each interrogator and the transponder, an interrogation wave is transmitted from each interrogator, and a transponder that receives the interrogation wave transmits a reflected wave obtained by performing predetermined modulation on the interrogation wave to the interrogator. Communication is done by replying,
A communication system, wherein communication is performed between the interrogators by using communication waves. The frequency band of the reflected wave is separated from the frequency band of the communication wave, and the frequency band of the reflected wave is closer to the frequency of the interrogation wave than the frequency band of the communication wave. The communication system described. The difference between the frequency of the communication wave closest to the frequency of the interrogation wave and the frequency of the interrogation wave is the frequency farthest from the frequency of the interrogation wave in the frequency band of the reflected wave and the frequency of the interrogation wave The communication system according to claim 2, wherein the difference is substantially twice or more. The difference between the frequencies of the interrogation waves transmitted by two interrogators that communicate with each other wirelessly among the plurality of interrogators is the frequency farthest from the frequency of the interrogation wave in the frequency band of the reflected wave. The communication system according to claim 2, wherein the communication system is substantially equal to or larger than a value obtained by adding four times the difference between the wave frequency and the frequency bandwidth of the communication wave. The communication system according to any one of claims 1 to 4, wherein a frequency band of the communication wave having the same information is present in a frequency region on both sides of the frequency of the interrogation wave. The communication system according to any one of claims 1 to 5, wherein the communication wave is modulated by an OFDM method. The interrogator is
OFDM signal generating means for generating an OFDM signal;
Mixer means for up-converting the OFDM signal generated by the OFDM signal generation means with a main carrier to form the communication wave;
Combining means for combining the communication wave from the mixer means and the interrogation wave obtained by modulating or not modulating the main carrier wave into a transmission wave;
Detecting means for detecting the received wave received by the interrogator;
AD conversion means for converting the received wave detected by the detection means into a digital signal;
A received wave separating means for separating the received wave converted by the AD converting means into the reflected wave and a communication wave from the other interrogator;
Reflected wave demodulating means for demodulating the reflected wave separated by the received wave separating means;
The communication system according to claim 6, further comprising: a communication wave demodulating unit that demodulates a communication wave from the other interrogator separated by the received wave separating unit. The communication system according to claim 7, wherein the reflected wave demodulating means and the communication wave demodulating means share a Fourier transform means. The interrogator of the communication system according to any one of claims 1 to 8.

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