JP4613887B2 - Wireless communication device - Google Patents

Description

  The present invention relates to an improvement of a wireless communication apparatus having a cancel circuit for suppressing a sneak signal from a transmission side.

  2. Description of the Related Art A wireless communication device is known that includes a transmission unit that transmits a predetermined transmission signal from a transmission antenna and a reception unit that receives a reply signal returned in response to the transmission signal by a reception antenna. For example, an RFID (Radio Frequency Identification) system RFID tag communication device (interrogator) that reads information without contact from a small RFID tag (responder) in which predetermined information is stored. This RFID system is capable of reading information stored in a wireless tag by communication with the wireless tag communication device even when the wireless tag is dirty or disposed at an invisible position. Therefore, practical use is expected in various fields such as merchandise management and inspection processes.

  By the way, normally, the wireless tag communication device transmits a predetermined transmission signal (question wave) from the antenna toward the wireless tag, and a reply signal (response wave) returned from the wireless tag that has received the transmission signal. Is received by the antenna, and information is communicated with the wireless tag. However, a strong sneak signal (direct wave) from the transmission side is mixed in the received reply signal, increasing the overall received signal strength. There is a case. As a result, the allowable input intensity of the amplifier is exceeded, so that the received signal cannot be sufficiently amplified, and as a result, the return signal component from the wireless tag cannot be sufficiently amplified. There was a problem that the to-noise ratio decreased. Therefore, a technique for removing such a sneak signal from the transmission side has been proposed. For example, this is the carrier phase noise suppression circuit described in Patent Document 1. According to this technique, a part of the transmission signal output from the transmission system is distributed, the phase and amplitude are controlled, a cancel signal is generated and synthesized with the reception signal, so that the transmission included in the reception signal is transmitted. The sneak signal from the side can be preferably removed.

JP-A-10-62518

  By the way, the received signal, the cancel signal, and the like inevitably contain some noise, and the sneak signal included in the received signal is reduced by synthesizing the cancel signal with the received signal, but such noise is reduced. As a result, there was a limit to the improvement of the S / N ratio. Furthermore, there is a problem that the SN ratio is lowered by adding the noise included in the received signal and the noise included in the cancel signal. That is, there has been a demand for the development of a wireless communication apparatus that improves the S / N ratio while suitably removing the sneak signal from the transmission side included in the received signal.

  The present invention has been made in the background of the above circumstances, and the object of the present invention is to provide a wireless communication apparatus that improves the S / N ratio while preferably removing the sneak signal from the transmission side included in the received signal. It is to provide.

  In order to achieve such an object, the gist of the present invention is that a transmission signal is transmitted from a transmission antenna, and a return signal returned from a communication target according to the transmission signal is received by a reception antenna. A wireless communication device for communicating information with a communication target, a transmission amplifier for modulating a carrier wave with predetermined transmission data and outputting the transmission signal, and a phase of a cancel signal based on the carrier wave A cancellation signal generation unit including a cancellation phase shift unit for controlling the cancellation signal, and a cancellation amplifier having substantially the same characteristics as the transmission amplifier for amplifying the cancellation signal, and the cancellation signal generation unit A cancellation signal combining unit that adds the generated cancellation signal to the reception signal received by the reception antenna. It is an butterfly.

  In this way, a transmission amplifier for modulating a carrier wave with predetermined transmission data and outputting the transmission signal, a cancellation phase shift unit for controlling the phase of the cancellation signal based on the carrier wave, and the cancellation signal A cancel signal generator including a cancel amplifier having substantially the same characteristics as the transmission amplifier, and the cancel signal generated by the cancel signal generator is received by the receiving antenna. Since the cancel signal synthesis unit for adding to the received signal is provided, a cancel amplifier having substantially the same characteristics as the transmission amplifier used in the transmission circuit is used in the cancellation circuit, so that The noise characteristics included in the sneak signal and the noise characteristics included in the cancellation signal are made as equal as possible. Be a thing, it is possible to suitably reduce such noise by summing the cancellation signals to the received signal. That is, it is possible to provide a wireless communication apparatus that improves the S / N ratio while suitably removing the sneak signal from the transmission side included in the received signal.

  Here, preferably, the transmission antenna is an array antenna including a plurality of antenna elements, and includes a transmission amplifier having substantially the same characteristics as the cancellation amplifier corresponding to each antenna element. is there. If it does in this way, regarding a radio communication apparatus provided with a practical array antenna, it is possible to improve the SN ratio while preferably removing the sneak signal from the transmission side included in the received signal.

  Preferably, the transmission amplifier and the cancellation amplifier are variable gain amplifiers capable of changing an amplification factor. In this way, by appropriately changing the amplification factor of each of the transmission amplifier and the cancellation amplifier, the SN ratio is improved as much as possible while further appropriately removing the sneak signal from the transmission side included in the reception signal. can do.

  Preferably, a transmission filter is provided in the signal transmission path between the transmission amplifier and the transmission antenna, and the transmission filter is substantially in the signal transmission path between the cancellation amplifier and the cancellation signal synthesis unit. A cancel filter having the same characteristics is provided. In this case, the cancel filter having substantially the same characteristics as the transmission filter used in the transmission circuit is provided in the cancellation circuit, so that the noise characteristics and the cancellation signal included in the sneak signal from the transmission side are provided. It is possible to make the characteristics of noise included in the same as possible.

  Preferably, the cancel signal generation unit generates the cancel signal by controlling an amplitude of a carrier wave component of a transmission signal transmitted from the transmission antenna via the cancel amplifier. This has the advantage that there is no need to provide a variable attenuator or the like as a configuration for controlling the amplitude of the cancel signal.

  Preferably, the cancellation signal generation unit generates the cancellation signal by modulating a carrier component of a transmission signal transmitted from the transmission antenna by the transmission data via the cancellation amplifier. . In this way, it is possible to make the noise characteristics included in the sneak signal from the transmission side equal to the noise characteristics included in the cancellation signal as much as possible.

  Preferably, a phase shift unit for controlling a phase of a transmission signal transmitted from the transmission antenna or a phase of a reception signal received by the reception antenna is provided. In this way, in a practical wireless communication apparatus capable of phased array control, it is possible to improve the SN ratio while preferably removing the sneak signal from the transmission side included in the received signal.

  Preferably, the phase shift section has substantially the same characteristics as the cancel phase shift section. In this way, by providing a phase shift unit having substantially the same characteristics as the cancel phase shift unit used in the cancel circuit, when performing phased array control, a sneak signal from the transmission side is generated. It is possible to make the characteristic of the noise included and the characteristic of the noise included in the cancel signal as equal as possible.

  Preferably, a cancel signal control unit is provided for controlling the phase and / or amplitude of the cancel signal so that the amplitude is the same as and opposite to the received signal received by the receiving antenna. In this way, the sneak signal from the transmission side included in the received signal can be removed as much as possible.

  Preferably, the wireless communication apparatus transmits a predetermined transmission signal to a wireless tag that is a communication target using a transmission antenna, and a reply signal returned from the wireless tag in response to the transmission signal. Is a wireless tag communication device that communicates information with the wireless tag by receiving the signal with the receiving antenna. In this way, the S / N ratio can be improved while suitably removing the sneak signal from the transmission side included in the received signal for the RFID tag communication apparatus that is particularly affected by the sneak signal from the transmission side.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a diagram for explaining a wireless tag communication system 10 in which the wireless communication apparatus of the present invention is preferably used. The wireless tag communication system 10 includes a wireless tag communication device 12 that is an embodiment of the wireless communication device of the present invention and a single or multiple (single in FIG. 1) wireless communication target of the wireless tag communication device 12. The RFID tag is a so-called RFID (Radio Frequency Identification) system. The RFID tag communication device 12 functions as an interrogator of the RFID system, and the RFID tag 14 functions as a responder. That is, when the interrogation wave F _c (transmission signal) is transmitted from the radio tag communication device 12 toward the radio tag 14, a predetermined information signal (transmission data) is transmitted in the radio tag 14 that has received the interrogation wave F _c. The interrogation wave F _c is modulated by the above and is returned as a response wave F _r (reply signal) to the RFID tag communication apparatus 12, so that information is transmitted between the RFID tag communication apparatus 12 and the RFID tag 14. Communication is performed. The wireless tag communication system 10 is used, for example, for managing articles in a predetermined communication area. The wireless tag 14 is preferably attached to an article to be managed, for example. And are provided integrally.

  FIG. 2 is a diagram illustrating the configuration of the wireless tag communication device 12. As shown in FIG. 2, the RFID tag communication apparatus 12 according to the present embodiment includes a local oscillator 20 that generates a predetermined local signal corresponding to a carrier wave, and a carrier wave amplifier that amplifies the carrier wave output from the local oscillator 20 22 and a plurality of (three in FIG. 2) transmission / reception for transmitting a transmission signal based on the carrier wave supplied from the carrier wave amplification unit 22 from the corresponding antenna element 26 and processing a reception signal received by the antenna element 26 Modules 24a, 24b, and 24c (hereinafter simply referred to as transmission / reception module 24 unless otherwise distinguished) and antenna elements 26a, 26b, and 26c for transmission / reception provided corresponding to the respective transmission / reception modules 24a, 24b, and 24c ( Hereinafter, the antenna elements 26 are simply referred to unless otherwise distinguished) and the plurality of transmission / reception modules 24 are referred to. A reception signal synthesis unit 28 that synthesizes (adds) the reception signals supplied from the receiver, and a cancel signal generation that generates a cancel signal for suppressing a sneak signal from the transmission side based on the carrier wave supplied from the local oscillator 20. Unit 30, a cancel signal combining unit 32 that combines (adds) the combined received signal supplied from the received signal combining unit 28 and the cancel signal supplied from the cancel signal generating unit 30, and the cancel signal combining unit 32, a variable amplifying unit 34 that amplifies the combined signal supplied from 32, a homodyne detection circuit 36 that performs homodyne detection on the combined signal supplied from the variable amplifying unit 34, and an I-phase signal output from the homodyne detection circuit 36 ( I-phase LPF (Low Pass Filter) 3 that passes only a signal in a predetermined frequency band including a DC component among the in-phase components) An I-phase A / D converter 40 that digitally converts the I-phase signal supplied from the I-phase LPF 38, and an I-phase memory unit that stores the I-phase signal supplied from the I-phase A / D converter 40 42, a Q-phase LPF (Low Pass Filter) 44 that passes only a signal in a predetermined frequency band including a DC component among Q-phase signals (orthogonal components) output from the homodyne detection circuit 36, and the Q-phase LPF 44 Q-phase A / D converter 46 for digitally converting the Q-phase signal supplied from the Q-phase, a Q-phase memory unit 48 for storing the Q-phase signal supplied from the Q-phase A / D converter 46, and transmission / reception phase control Unit 50, transmission data generation unit 52, cancellation phase control unit 54, and cancellation amplitude control unit 56. In the RFID tag communication apparatus 12 of the present embodiment, the antenna elements 26a, 26b, and 26c constitute an array antenna 18 that is shared for transmission and reception, and the array antenna 18 functions as a transmission antenna and a reception antenna.

  The cancel signal generation unit 30 is output from a cancel phase shift unit 58 which is a variable phase shifter for controlling the phase using the carrier wave supplied from the local oscillator 20 as a cancel signal, and the cancel phase shift unit 58. A cancel amplifier 60 that is a variable gain amplifier for amplifying the cancel signal to be amplified, and a cancel attenuator that is a variable attenuator for attenuating the cancel signal output from the cancel amplifier 60 and supplying it to the cancel signal combining unit 32 62. The cancellation phase control unit 54 outputs a phase control signal for controlling the phase of the cancellation signal generated by the cancellation signal generation unit 30, and the cancellation phase shift unit 58 includes the cancellation phase control unit. The phase (phase shift amount) of the carrier wave is controlled according to the phase control signal supplied from 54. The cancel amplitude controller 56 outputs an amplitude control signal for controlling the amplitude of the cancel signal generated by the cancel signal generator 30, and the cancel attenuator 62 includes the cancel amplitude controller The amplitude (attenuation amount) of the carrier wave is controlled according to the amplitude control signal supplied from 56. In the RFID tag communication apparatus 12 of the present embodiment, the cancel phase control unit 54 and the cancel amplitude control unit 56 correspond to a cancel signal control unit, and preferably the combined signal output from the reception signal combining unit 28 The phase and / or amplitude of the cancel signal is controlled via the cancel phase shifter 58 and the cancel attenuator 62 so that the amplitudes are equal and opposite in phase. Here, the cancel phase shift unit 58 has substantially the same characteristics as the transmission phase shift unit 66 included in the transmission / reception module 24, and the cancel amplifier 60 is a transmission unit included in the transmission / reception module 24. The amplifier 68 has substantially the same characteristics. This will be described in detail below.

  FIG. 3 is a diagram for explaining the configuration of the transmission / reception module 24 in detail. As shown in FIG. 3, the transmission / reception module 24 includes a transmission phase shifter 66 that is a variable phase shifter for controlling the phase of the carrier wave supplied from the carrier wave amplifier 22, and the transmission phase shifter 66. Provided in a signal transmission path between the transmission amplifier 68 and the antenna element 26, and a transmission amplifier 68 which is a variable gain amplifier for modulating the carrier wave output from the transmission data with predetermined transmission data and outputting the transmission signal. The transmission filter 70 and the transmission signal output from the transmission amplifier 68 are supplied to the antenna element 26 through the transmission filter 70, received by the antenna element 26, and supplied through the transmission filter 70. The transmission / reception separating unit 72 that supplies the received signal to the reception phase shifting unit 74 and the phase of the received signal supplied from the transmission / reception separating unit 72 are controlled. And a reception phase shifter 74 is a variable phase shifter of the eye, a. The transmission data generation unit 52 generates transmission data such as a command corresponding to transmission information, and supplies the transmission data to the transmission amplifier 68 via the switch 64. The transmission amplifier 68 includes the transmission data generation unit. The carrier wave is modulated by the transmission data supplied from 52. The switch 64 is controlled to be opened and closed by, for example, the transmission data generation unit 52, and is connected when the carrier wave is to be modulated by the transmission data generated by the transmission data generation unit 52. When there is no need (for example, when a carrier wave not including a command is transmitted), it is released. The transmission / reception phase control unit 50 outputs a phase control signal for controlling the phase of the transmission signal transmitted from the antenna element 26 and / or the reception signal received by the antenna element 26, The transmission phase shift unit 66 controls the phase (phase shift amount) of the transmission signal in accordance with the phase control signal supplied from the transmission / reception phase control unit 50. The reception phase shifter 74 controls the phase (phase shift amount) of the reception signal in accordance with the phase control signal supplied from the transmission / reception phase controller 50.

FIG. 4 is a diagram for explaining the configuration of the RFID circuit element 76 provided in the RFID tag 14. As shown in FIG. 4, the RFID circuit element 76 processes the signal received by the antenna unit 78 and the antenna unit 78 for transmitting and receiving signals to and from the RFID tag communication apparatus 12. And an IC circuit unit 80 for this purpose. The IC circuit unit 80 rectifies the interrogation wave F _c received from the RFID tag communication device 12 received by the antenna unit 78 and the energy of the interrogation wave F _c rectified by the rectification unit 82. Functions as a power supply unit 84 for storing, a clock extraction unit 86 that extracts a clock signal from the carrier wave received by the antenna unit 78 and supplies the clock signal to the control unit 92, and an information storage unit that can store a predetermined information signal The RFID circuit element 76 via the memory unit 88, the modulation / demodulation unit 90 connected to the antenna unit 78 to modulate and demodulate signals, the rectification unit 82, the clock extraction unit 86, the modulation / demodulation unit 90, and the like. And functionally includes a control unit 92 for controlling the operation. The control unit 92 performs control for storing the predetermined information in the memory unit 88 by communicating with the RFID tag communication device 12, and the modulation / demodulation unit 90 receives the interrogation wave F _c received by the antenna unit 78. Then, basic control such as control for reflecting and returning the response wave _Fr as the response wave _Fr is executed based on the information signal stored in the memory unit 88.

  In the wireless tag communication device 12 of the present embodiment, the cancel amplifier 60 provided in the cancel signal generation unit 30 and the transmission amplifier 68 provided in the transmission / reception module 24 have substantially the same characteristics. . Preferably, the cancel phase shift unit 58 provided in the cancel signal generation unit 30 and the transmission phase shift unit 66 provided in the transmission / reception module 24 have substantially the same characteristics. Preferably, the reception phase shifter 74 provided in the transceiver module 24 has substantially the same characteristics as the cancel phase shifter 58 and the transmission phase shifter 66. Here, the device having substantially the same characteristics refers to, for example, the same product having the same manufacturer and model number, the same standard product having the same standard although the manufacturer is the same, a compatible product, etc. The phase error of the output signal with respect to the same input signal with respect to the phase shift section is ± 1% or less, and the error of the amplification factor of the output signal with respect to the same input signal with respect to the amplifier is ± 1% or less.

FIG. 5 is a diagram showing signals (frequency bands in the vicinity of the center frequency f _{0 of the} carrier wave) in each part of the transmission / reception module 24. An input signal to the transmission / reception module 24, that is, an output signal from the carrier amplifier 22 is shown by a solid line a. The output signal from the transmission amplifier 68 is indicated by a one-dot chain line b, and the received signal received by the antenna element 26 is indicated by a two-dot difference line c. As shown in FIG. 5, the signal a input to the transmission / reception module 24 is phase-controlled by the transmission phase shifter 66 and amplified by the transmission amplifier 68, whereby the nonlinearity of the transmission amplifier 68 is obtained. As a result, the noise increases and is output from the transmission amplifier 68 as a signal such as b. Also, the received signal received by the antenna element 26 is transmitted from the antenna element 26 via the transmission filter 70, so that the frequency characteristic is changed by the transmission filter 70 and the antenna element 26, as shown by c. Signal. On the other hand, the cancellation of the cancel signal in the cancel signal combining unit 32 is performed by subtracting the cancel signal generated by the cancel signal generating unit 30 from the sneak signal obtained by combining the signals b and c shown in FIG. The cancel signal is preferably a signal having a strong correlation with the signals b and c by the amplification of the cancel amplifier 60. Here, since the input signal to the cancel phase shifter 58 of the cancel signal generator 30 is a carrier wave output from the local oscillator 20, it has substantially the same shape (amplitude is different) from the signal a shown in FIG. The cancel signal generation unit 30 includes a cancel phase shift unit 58 and a cancel amplifier 60 having substantially the same characteristics as the transmission phase shift unit 66 and the transmission amplifier 68 included in the transmission module 24. Therefore, a cancel signal having a strong correlation with the signals b and c shown in FIG. 5 can be generated by the cancel signal generating unit 30, and it is preferable to increase noise when the cancel signal is suppressed in the cancel signal combining unit 32. It can be suppressed to.

  FIG. 6 is a flowchart for explaining a main part of cancel signal control by the RFID tag communication apparatus 12, and is repeatedly executed at a predetermined cycle.

  First, in step (hereinafter step is omitted) S1, the amount of phase shift in the transmission phase shifter 66 and / or the reception phase shifter 74 of each transmission / reception module 24 is determined, and the transmission / reception direction (transmission / reception direction) of the array antenna 18 is determined. Sex) is determined. Next, in S2, after the cancel amplifier 60 in the cancel signal generator 30 is turned off or the attenuation amount of the cancel attenuator 62 is maximized, the switch 64 is opened, that is, the transmission data is not transmitted. The array antenna 18 transmits an unmodulated carrier wave, that is, an unmodulated carrier signal. Next, in S3, the received signal received by the array antenna 18 is detected by the homodyne detection circuit 36, and the DC output (DC component output) of the I-phase signal and Q-phase signal is converted to the I-phase memory unit 42 and / or Alternatively, it is stored in the Q phase memory unit 48. Preferably, the amplitude of the sneak signal is detected from the sum of squares of the I-phase signal and the Q-phase signal, and the phase of the sneak signal is detected from the ratio of the I-phase signal and the Q-phase signal. Next, in S4, the transmission amplifier 68 provided in each transmission / reception module 24 is turned off, and the sneak signal stored in the I-phase memory unit 42 and / or the Q-phase memory unit 48 has the same amplitude and the opposite phase. As described above, the phase and / or amplitude of the cancel signal is controlled via the cancel phase shifter 58 and the cancel attenuator 62. Next, in S5, the transmission amplifier 68 provided in each transmission / reception module 24 is turned on, and the switch 64 is connected, that is, the transmission data is transmitted, and the wireless communication object is transmitted from the array antenna 18. After the transmission signal is transmitted toward the tag 14, this routine is terminated.

  As described above, according to this embodiment, the transmission amplifier 68 for modulating the carrier wave with the predetermined transmission data and outputting the transmission signal, and the cancellation phase shift for controlling the phase of the cancellation signal based on the carrier wave Generated by the cancel signal generating unit 30 and the cancel signal generating unit 30. The cancel signal generating unit 30 includes a canceling amplifier 60 having substantially the same characteristics as the transmission amplifier 68 for amplifying the cancel signal. Since the cancel signal combining unit 32 for adding the cancel signal to the reception signal received by the array antenna 18 is provided, the cancel having substantially the same characteristics as the transmission amplifier 68 used in the transmission circuit is provided. By using the amplifier 60 in the cancel circuit, the characteristics of noise included in the sneak signal from the transmission side can be reduced. It can be equal as much as possible the characteristics of noise included in Yanseru signal, it is possible to suitably reduce such noise by summing the cancellation signals to the received signal. That is, it is possible to provide the wireless tag communication device 12 that improves the SN ratio while suitably removing the sneak signal from the transmission side included in the received signal.

  The transmitting antenna provided in the RFID tag communication device 12 is an array antenna 18 composed of a plurality of antenna elements 26, and has substantially the same characteristics as the cancel amplifier 60 corresponding to each antenna element 26. Since the transmission amplifier 68 is provided, the wireless tag communication device 12 having the practical array antenna 18 improves the SN ratio while suitably removing the sneak signal from the transmission side included in the reception signal. can do.

  Further, since the transmission amplifier 68 and the cancel amplifier 60 are variable gain amplifiers whose amplification factors can be changed, they are included in the reception signal by appropriately changing the amplification factors of the transmission amplifier 68 and the cancellation amplifier 60, respectively. It is possible to improve the SN ratio as much as possible while further suitably removing the sneak signal from the transmission side.

  Further, a transmission phase shifter 66 for controlling the phase of the transmission signal transmitted from the array antenna 18 and a reception phase shifter 74 for controlling the phase of the reception signal received by the array antenna 18 are provided. Therefore, in the practical RFID tag communication apparatus 12 capable of phased array control, it is possible to improve the SN ratio while preferably removing the sneak signal from the transmission side included in the received signal.

  Further, the transmission phase shifter 66 and the reception phase shifter 74 have substantially the same characteristics as the cancel phase shifter 58, and therefore substantially the same as the cancel phase shifter 58 used in the cancel circuit. Since the transmission phase shifter 66 and the reception phase shifter 74 having the same characteristics are provided, the noise characteristics included in the sneak signal from the transmission side and the cancellation signal are included when performing phased array control. Noise characteristics can be made as equal as possible.

  In addition, a cancel phase control unit 54 and a cancel amplitude function as a cancel signal control unit that controls the phase and / or amplitude of the cancel signal so that the amplitude is equal to and opposite to the reception signal received by the array antenna 18. Since the control unit 56 is provided, the sneak signal from the transmission side included in the reception signal can be removed as much as possible.

  In addition, the wireless communication apparatus according to the present embodiment transmits a predetermined transmission signal by the array antenna 18 toward the wireless tag 14 that is a communication target, and a reply that is returned from the wireless tag 14 in response to the transmission signal. Since the wireless tag communication device 12 communicates information with the wireless tag 14 by receiving a signal by the array antenna 18, the wireless tag communication device 12 that is particularly affected by the sneak signal from the transmission side. The SN ratio can be improved while preferably removing the sneak signal from the transmission side included in the received signal.

  Next, another preferred embodiment of the present invention will be described in detail with reference to the drawings. In addition, the Example shown below is a modification regarding the cancellation signal production | generation part 30 in the said RFID tag communication apparatus 12, Description is abbreviate | omitted about the part which is common in Example. Further, parts common to the above-described embodiments are denoted by the same reference numerals and description thereof is omitted.

  FIG. 7 is a diagram illustrating a configuration of a cancel signal generation unit 100 applied in place of the cancel signal generation unit 30 in the RFID tag communication apparatus 12. As shown in FIG. 7, the cancel signal generating unit 100 of this embodiment includes a cancel filter 102 in the signal transmission path between the cancel attenuator 62 and the cancel signal combining unit 32. The cancellation filter 102 has substantially the same characteristics as the transmission filter 70 provided in the transmission / reception module 24 and is generated by the cancellation phase shifter 58, the cancellation amplifier 60, and the cancellation attenuator 56. The cancel signal is input to the cancel signal synthesis unit 32 through the cancel filter 102. As described above, according to the present embodiment, the transmission filter 70 is provided in the signal transmission path between the transmission amplifier 68 and the array antenna 18, and the signal transmission between the cancellation amplifier 60 and the cancellation signal combining unit 32 is performed. Since the cancellation filter 102 having substantially the same characteristics as the transmission filter 70 is provided in the path, the cancellation filter 102 having substantially the same characteristics as the transmission filter 70 used in the transmission circuit is used as the cancellation circuit. By providing, the characteristic of the noise included in the sneak signal from the transmission side and the characteristic of the noise included in the cancellation signal can be made as equal as possible.

  FIG. 8 is a diagram illustrating a configuration of a cancel signal generation unit 104 applied in place of the cancel signal generation unit 30 in the RFID tag communication apparatus 12. As shown in FIG. 8, the cancel signal generator 104 of the present embodiment is configured by removing the cancel attenuator 62 from the cancel signal generator 30 described above, and the output of the cancel amplifier 60 is the cancel signal. The data is input to the combining unit 32. In the cancel signal generation unit 104 of this embodiment, the cancel amplifier 60 as a variable gain amplifier controls the amplitude of the cancel signal in accordance with the amplitude control signal supplied from the cancel amplitude control unit 56. As described above, the cancel signal generation unit 104 according to the present embodiment generates the cancel signal by controlling the amplitude of the carrier component of the transmission signal transmitted from the array antenna 18 via the cancel amplifier 60. Therefore, there is an advantage that it is not necessary to separately provide a variable attenuator or the like as a configuration for controlling the amplitude of the cancel signal.

  FIG. 9 is a diagram illustrating a configuration of a cancel signal generation unit 104 applied in place of the cancel signal generation unit 30 in the RFID tag communication apparatus 12. As shown in FIG. 9, the cancel signal generation unit 104 of the present embodiment is configured by removing the cancel attenuator 56 from the cancel signal generation unit 30 described above, and the output of the cancel amplifier 60 is the cancel signal. The data is input to the combining unit 32. In this embodiment, the amplitude control signal output from the cancellation amplitude control unit 56 and the transmission data output from the transmission data generation unit 52 are multiplied by the multiplication unit 106 and supplied to the cancellation amplifier 104. The cancel amplifier 104 as a variable gain amplifier controls the amplitude of the cancel signal in accordance with the signal supplied from the multiplication unit 106. As a result, the carrier wave is modulated by the transmission data via the cancel amplifier 60. The multiplication unit 106 is preferably functionally provided in a DSP (Digital Signal Processor) or the like, and the amplitude control signal and transmission data are multiplied by software processing. As described above, the cancel signal generation unit 104 according to the present embodiment generates the cancel signal by modulating the carrier wave with the transmission data via the cancel amplifier 60. Therefore, the wrap signal from the transmission side is generated. The noise characteristics included in the cancel signal and the noise characteristics included in the cancel signal can be made as equal as possible.

  FIG. 10 is a diagram illustrating a configuration of a cancel signal generation unit 108 applied in place of the cancel signal generation unit 30 in the wireless tag communication device 12. The cancel signal generator 108 is preferably applied when the transmission signal is 100% ASK (Amplitude Shift Keying) modulation, and a signal transmission path between the cancel attenuator 62 and the cancel signal synthesizer 32. RF switch 110 is provided. The RF switch 110 is controlled to open and close in accordance with transmission data output from the transmission data generation unit 52, and cancels generated by the cancel phase shift unit 58, the cancel amplifier 60, and the cancel attenuator 56. The signal is ASK modulated by the transmission data in the RF switch 110 and input to the cancel signal combining unit 32. As described above, the cancel signal generation unit 108 according to the present embodiment generates the cancel signal by performing ASK modulation on the carrier wave with the transmission data via the RF switch 110. The characteristic of noise included in the signal and the characteristic of noise included in the cancellation signal can be made as equal as possible.

  The preferred embodiments of the present invention have been described in detail with reference to the drawings. However, the present invention is not limited to these embodiments, and may be implemented in other modes.

  For example, in the above-described embodiment, the example in which the present invention is applied to the RFID tag communication device 12 that is an interrogator of the RFID system has been described. However, the present invention is not limited to this, and transmission is performed from a transmission antenna. The present invention can be widely applied to a wireless communication apparatus having a cancel circuit for suppressing a sneak signal from the transmission side based on the carrier component of the transmitted signal.

  Further, in the above-described embodiment, the example in which the present invention is applied to the wireless tag communication device 12 having the array antenna 18 for both transmission and reception has been described. However, the wireless communication device having the transmission antenna and the reception antenna individually. The present invention is also preferably applied. In addition, the present invention is preferably applied to a wireless communication apparatus including an antenna composed of a single antenna element that is not an array antenna.

  In the above-described embodiment, the transmission / reception phase control unit 50, the transmission data generation unit 52, the cancel phase control unit 54, and the cancel amplitude control unit 56 are provided independently as individual control units. However, these control units may be provided as software as a control function of a DSP (Digital Signal Processor), for example.

  In the above-described embodiment, the modulation unit based on the transmission data is provided in the transmission / reception module 24 and the cancel signal generation unit 108. For example, the modulation unit based on the transmission data is provided immediately after the local oscillator 20. May be.

  In the above-described embodiment, the RF switch 110 in the cancel signal generation unit 108 is controlled to be opened / closed according to transmission data. However, the RF switch 110 is controlled to be closed only while data is received. It may be a thing.

  In addition, although not illustrated one by one, the present invention is implemented with various modifications within a range not departing from the gist thereof.

It is a figure explaining the radio | wireless tag communication system with which the radio | wireless communication apparatus of this invention is used suitably. It is a figure explaining the structure of the radio | wireless tag communication apparatus which is one Example of the radio | wireless communication apparatus of this invention. It is a figure explaining in detail the structure of the transmission / reception module with which the RFID tag communication apparatus of FIG. 2 was equipped. It is a figure explaining the structure of the RFID circuit element with which the RFID tag which is a communication object of the RFID tag communication apparatus of FIG. 2 was equipped. FIG. 4 is a diagram illustrating signals in each part of the transmission / reception module of FIG. 3, wherein an input signal to the transmission / reception module is indicated by a solid line a, an output signal from the transmission amplifier is indicated by a one-dot chain line b, and a reception signal received by an antenna element is indicated by a two-dot difference line Indicated by c. 3 is a flowchart for explaining a main part of cancel signal control by the wireless tag communication device of FIG. 2. It is a figure explaining the structure of the cancellation signal production | generation part applied instead of the cancellation signal production | generation part in the RFID tag communication apparatus of FIG. It is a figure explaining the structure of the cancellation signal production | generation part applied instead of the cancellation signal production | generation part in the RFID tag communication apparatus of FIG. It is a figure explaining the structure of the cancellation signal production | generation part applied instead of the cancellation signal production | generation part in the RFID tag communication apparatus of FIG. It is a figure explaining the structure of the cancellation signal production | generation part applied instead of the cancellation signal production | generation part in the RFID tag communication apparatus of FIG.

Explanation of symbols

12: RFID tag communication device (wireless communication device)
14: Wireless tag (communication target)
18: Array antenna 26: Antenna elements 30, 100, 104, 108: Cancel signal generation unit 32: Cancel signal synthesis unit 54: Cancel phase control unit 56: Cancel amplitude control unit 58: Cancel phase shift unit 60: Cancel amplifier 66: Transmission phase shifter 68: Transmission amplifier 70: Transmission filter 74: Reception phase shifter 102: Cancel filter

Claims (10)

A wireless communication apparatus that transmits a transmission signal from a transmission antenna and receives a reply signal returned from a communication target according to the transmission signal by a reception antenna and communicates information with the communication target. And
A transmission amplifier for modulating the carrier wave with predetermined transmission data and outputting the transmission signal;
A cancellation signal generation unit including a cancellation phase shift unit for controlling the phase of the cancellation signal based on the carrier wave, and a cancellation amplifier having substantially the same characteristics as the transmission amplifier for amplifying the cancellation signal When,
A wireless communication apparatus, comprising: a cancellation signal combining unit that adds the cancellation signal generated by the cancellation signal generation unit to the reception signal received by the reception antenna.   2. The wireless communication according to claim 1, wherein the transmitting antenna is an array antenna composed of a plurality of antenna elements, and includes a transmission amplifier having substantially the same characteristics as the cancel amplifier corresponding to each antenna element. apparatus.   The wireless communication apparatus according to claim 1, wherein the transmission amplifier and the cancellation amplifier are variable gain amplifiers capable of changing an amplification factor.   A cancellation filter having a transmission filter in a signal transmission path between the transmission amplifier and the transmission antenna and having substantially the same characteristics as the transmission filter in a signal transmission path between the cancellation amplifier and a cancellation signal synthesis unit The wireless communication apparatus according to claim 1, further comprising a filter.   The wireless communication according to claim 3 or 4, wherein the cancel signal generation unit generates the cancel signal by controlling an amplitude of a carrier component of a transmission signal transmitted from the transmission antenna via the cancel amplifier. apparatus.   6. The wireless communication according to claim 5, wherein the cancel signal generation unit generates the cancel signal by modulating a carrier component of a transmission signal transmitted from the transmission antenna by the transmission data through the cancel amplifier. apparatus.   7. The wireless communication according to claim 1, further comprising a phase shift unit for controlling a phase of a transmission signal transmitted from the transmission antenna or a phase of a reception signal received by the reception antenna. apparatus.   The wireless communication apparatus according to claim 7, wherein the phase shift unit has substantially the same characteristics as the cancel phase shift unit.   A cancel signal control unit that controls the phase and / or amplitude of the cancel signal generated by the cancel signal generation unit so that the amplitude is equal to and opposite in phase to the reception signal received by the reception antenna. The wireless communication device according to claim 1.   The wireless communication device transmits a predetermined transmission signal to a wireless tag that is a communication target by a transmission antenna, and transmits a reply signal returned from the wireless tag in response to the transmission signal by the reception antenna. The wireless communication device according to claim 1, wherein the wireless communication device is a wireless tag communication device that communicates information with the wireless tag by receiving the information.

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