Patent Application
20190199556
The disclosure of Japanese Patent Application No. 2017-249362 filed on Dec. 26, 2017 including the specification, drawings and abstract is incorporated herein by reference in its entirety.
The present invention relates to a receiving device, an equalization processing program, and a signal receiving method, and more particularly relates to a receiving device, an equalization processing program, and a signal receiving method that perform an equalizing process that compensates distortion generated in a propagation path and reduces noise for a received signal, for example.
In recent years, a transmission speed is being improved in communication standards in a radio communication system in which a mobile phone, a smart meter, or the like is coupled. However, characteristics of a signal transmission path are deteriorated because of a situation of the transmission path, for example, radio-wave interference or a multipath. This deterioration prevents improvement of the transmission speed in an actual use state. Further, there is noise such as thermal noise or another radio signal on a transmission path. This noise causes deterioration of signal quality, which in turn prevents improvement of the transmission speed. Therefore, a technique for compensating signal distortion generated in a transmission path is disclosed in Japanese Patent No. 3794622.
A receiving device described in Japanese Patent No. 3794622 includes a receiving unit, an estimating unit, a compensating unit, a demodulating unit, and a modulating unit. The receiving unit receives a result of transmission of a transmitted signal that is obtained by modulating a known signal and a data signal in a predetermined modulation method, and outputs the result as a received signal. The estimating unit estimates transmission-path characteristics. The compensating unit compensates a portion of the received signal, which corresponds to the data signal and has not been compensated yet, with an already-estimated portion of the transmission-path characteristics and outputs a compensation result as a compensated data signal. The demodulating unit demodulates the compensated data signal and outputs a demodulation result as a demodulated data signal. The modulating unit modulates the demodulated data signal in the predetermined modulation method and outputs a modulation result as a modulated data signal.
The receiving device described in Japanese Patent No. 3794622 compensates a portion that has not been compensated with an already-estimated portion of the transmission-path characteristics, and outputs the compensation result as a compensated data signal. That is, the receiving device described in Japanese Patent No. 3794622 aims to follow a change in the characteristics of the transmission path, but cannot reduce thermal noise or the like other than the transmission-path characteristics of the transmission path.
Other objects and novel features will be apparent from the description of this specification and the accompanying drawings.
According to an embodiment, a receiving device performs, in an equalization processing circuit that performs an equalizing process for a received signal sequence and outputs a sequence to be demodulated, a first transmission-path estimating process of generating a first compensation coefficient indicating a propagation coefficient of a transmission path of a received signal based on a preamble sequence, a second transmission-path estimating process of generating a second compensation sequence from a received header-replica sequence generated by performing demodulation and modulation for a header sequence included in a first equalizer-compensated output sequence in which distortion has been compensated based on the first compensation coefficient, a third transmission-path estimating process of generating a third compensation coefficient by synthesizing the first compensation coefficient and the second compensation coefficient with each other, and a propagation-path compensating process of performing a distortion compensating process for a payload sequence included in the received signal sequence based on the third compensation coefficient.
According to the embodiment, the receiving device can obtain a high noise reduction effect for a received signal.
For clarifying explanation, omission and simplification are made in the following description and the drawings as appropriate. Each of elements illustrated in the drawings as functional blocks performing various processes can be configured by a CPU, a memory, or another circuit if being achieved by hardware, and can be implemented by a program loaded to a memory if being implemented by software. Therefore, a person skilled in the art would understand that these functional blocks can be implemented by hardware only, software only, or a combination of hardware and software in various ways, and implementation is not limited to any of them. Throughout the drawings, the same element is labeled with the same reference sign, and redundant description is omitted as necessary.
The above-described program can be stored in various types of non-transitory computer-readable media and can be supplied to a computer. The non-transitory computer-readable media include various types of tangible storage media. Examples of the non-transitory computer-readable medium include a magnetic recording medium (for example, a flexible disk, a magnetic tape, and a hard disk drive), a magneto-optical recording medium (for example, a magneto-optical disk), a CD-ROM (Read Only Memory), a CD-R, a CD-R/W, and a semiconductor memory (for example, a mask ROM, a PROM (Programmable ROM), an EPROM (Erasable ROM), a flash ROM, and a RAM (Random Access Memory)). Also, the program can be supplied to the computer by various types transitory computer readable media. Examples of the transitory computer-readable medium include an electric signal, an optical signal, and an electromagnetic wave. The transitory computer-readable medium can supply the program to the computer via a wired communication path, such as an electric wire and an optical fiber, or a wireless communication path.
First, a communication system is described to which a receiving device described in an embodiment is applied.
As illustrated in the upper portion of
RX=TX×H+N (1)
As illustrated in the middle portion of
In the communication system illustrated in
A compensation process in an equalizer is briefly described here. The equalizer estimates the propagation-path characteristics H by using the preamble sequence that is a known signal sequence, and compensates signal distortion caused by the propagation-path characteristics H. For example, assuming that a preamble sequence included in a received signal sequence converted into a frequency domain is RXpre and a preamble sequence in a frequency domain of a transmitted signal TX that has been transmitted from a transmitting device (the transmitted signal TX before being subjected to inverse Fourier transform) is TXpre, the propagation-path characteristics H are estimated by Expression (2).
H=RXpre/TXpre (2)
Because TXpre is known, the equalizer applies TXpre already held therein to RXpre obtained from the received signal sequence, thereby estimating the propagation-path characteristics H. The equalizer then divides the received signal sequence by the estimated propagation-path characteristics H, thereby compensating distortion caused by the propagation-path characteristics H included in the received signal RX. If there is no noise N, the propagation-path characteristics H can be obtained with high accuracy. However, noise N actually causes deterioration of estimation accuracy of the propagation-path characteristics H.
Therefore, deterioration of accuracy of the propagation-path characteristics H is described. A relation between a transmitted signal and a received signal of a preamble sequence is represented by Expression (3).
RXpre=TXpre×H+N (3)
When Expression (3) is substituted into Expression (2), actually estimated propagation-path characteristics H′ are represented by Expression (4).
H′=(TXpre×H+N)/TXpre=H+N/TXpre (4)
Because TXpre has constant magnitude, the magnitude of an estimation error (N/TXpre) of the propagation-path characteristics H depends on the magnitude of noise N. However, it is known that noise N has a Gaussian distribution (average 0, dispersion σ). Further, in the preamble sequence, symbols of the same data sequence are repeated more than once. Therefore, the equalizer compresses noise N by synthesizing the estimated propagation-path characteristics H′ for every symbol by in-phase addition (averaging).
However, there is a tendency in recent years that the number of symbols included in a preamble sequence is reduced in order to improve a data transfer efficiency. For example, in IEEE 802.11ah that is one of radio communication standards, the number of symbols included in a preamble sequence is two, that is, very small.
A receiving device described in the following embodiment is configured to achieve compression of noise N, the number of compression times being more than the number of symbols included in a preamble sequence. The receiving device according to the following embodiment is described in detail below.
The transmitting device 2 includes a modulation processing circuit 15, an IFET circuit 16, and a GI (guard interval) adding circuit 17. The modulation processing circuit 15 modulates the transmitted data S106 to generate a transmitted signal sequence S107. It is assumed that modulation performed by the modulation processing circuit 15 includes coding. The IFET circuit 16 performs inverse Fourier transform for the transmitted signal sequence S107 that has been coded, to convert the transmitted signal sequence S107 that is a signal in a frequency domain to a signal in a time domain (for example, a transmitted signal before GI addition S108). The GI adding circuit 17 adds a guard interval component to the transmitted signal before GI addition S108, and outputs the transmitted signal S109. The modulation processing circuit 15 of the transmitting device 2 is also used by the receiving device 3. When being used as a portion of the receiving device 3, the modulation processing circuit 15 performs coding and modulation for the received data S105 and outputs the transmitted signal sequence S107.
The receiving device 3 includes a GI removing circuit 11, an FET circuit 12, an equalization processing circuit 13, a demodulation processing circuit 14, and the modulation processing circuit 15. The GI removing circuit 11 removes the guide interval component included in the received signal S101 and outputs a GI-removed received signal S102. The FET circuit 12 performs Fourier transform for the GI-removed received signal S102 to convert the GI-removed received signal S102 that is a signal in a time domain to a signal in a frequency domain (for example, a received signal sequence S103). The equalization processing circuit 13 performs an equalizing process for the received signal sequence S103 and outputs a sequence to be demodulated S104. In this process, the equalization processing circuit 13 uses the transmitted signal sequence S107 generated by the modulation processing circuit 15 from the received data S105. The demodulation processing circuit 14 performs demodulation for the sequence to be demodulated S104 to generate the received data S105, and outputs the received data S105 to the signal processing circuit 100. It is assumed that demodulation performed by the demodulation processing circuit 14 includes decoding.
In the communication system according to the first embodiment, a received signal sequence has the frame format illustrated in the lower portion of
Further, the receiving device 3 according to the first embodiment generates the header-replica sequence used in the second propagation-path estimating process, based on a header sequence that has been determined as including no error in demodulation in the demodulation processing circuit 14. The details of the process of generating this header-replica sequence will be described later.
The transmitting and receiving device 1 has a feature in the configuration and the operation of the receiving device 3 and those of the equalization processing circuit 13 in the receiving device 3. Thus, the receiving device 3 is described in detail below.
As illustrated in
The first delay buffer 21 temporarily holds a payload sequence of a signal sequence included in the received signal sequence S103. The input selecting circuit 22 provides the received signal sequence S103 to the equalizer 23 in a period from the first transmission-path estimating process to the third transmission-path estimating process, and provides the payload sequence S201 stored in the first delay buffer 21 to the equalizer 23 in the propagation-path compensating process.
The tracking processing circuit 24 compensates phase rotation of the equalizer-compensated output sequence S203 and outputs the sequence to be demodulated S104. The tracking processing circuit 24 also outputs phase amount information S204 to the second delay buffer 25. The phase amount information S204 indicates the magnitude of phase compensation applied to the equalizer-compensated output sequence S203. The second delay buffer 25 temporarily holds the phase amount information S204. The third delay buffer 26 temporarily holds a header sequence S205 included in the received signal sequence S103. The phase compensating circuit 27 applies phase amount information S206 to the header sequence S205, and generates a phase-compensated header sequence S207 in which phase rotation of the header sequence S106 has been compensated.
In the equalization processing circuit 13, the equalizer 23 generates the third compensation coefficient H3 by using the received signal sequence S103, the header-replica sequence included in the transmitted signal sequence S107, and the phase-compensated header sequence S207. The equalization processing circuit 13 also performs an equalizer compensating process for the payload sequence S201 included in the sequence to be subjected top equalization S202 by using the generated third compensation coefficient H3.
As illustrated in
The preamble register 30 stores therein preamble information that indicates a preamble sequence. This preamble information is stored in the preamble register 30 from the overall control unit 18 or the like before start of a propagation-path characteristics estimating process. The preamble information has a different value in every communication standard, for example.
The first selecting circuit 31a selects and outputs the preamble sequence S103 in the first transmission-path estimating process and selects and outputs the phase-compensated header sequence S107 in the second transmission-path estimating process. A selecting signal sell provided from the overall control unit 18 switches the sequence selected and output by the first selecting circuit 31a. The second selecting circuit 31b selects and outputs the preamble information stored in the preamble register 30 in the first transmission-path estimating process, and selects and outputs a header-replica sequence (hereinafter, the header-replica sequence is also labeled with S107) included in the transmitted signal sequence S107 output from the modulation processing circuit 15 in the second transmission-path estimating process. A selecting signal sel2 provided from the overall control unit 18 switches the sequence selected and output by the second selecting circuit 31b.
The propagation-path-characteristics estimating circuit 32 generates the first compensation coefficient H1 based on the preamble sequence output from the first selecting circuit 31a and the preamble information output from the second selecting circuit 31b in the first transmission-path estimating process. The propagation-path characteristics estimating circuit 32 also generates the second compensation coefficient H2 based on the phase-compensated header sequence S207 output from the first selecting circuit 31a and the header-replica sequence S107 output from the second selecting circuit 31b in the second transmission-path estimating process. The propagation-path characteristics estimating circuit 32 divides an output value of the first selecting circuit 31a input to a port a by an output value of the second selecting circuit 31b input to a port b to calculate the compensation coefficient.
The first coefficient holding circuit 33 stores a value input thereto when an enable signal en1 is in an enable state, and holds a previously stored value when the enable signal en1 is in a disenable state. The first coefficient holding circuit 33 is controlled by the enable signal en1 to hold the first compensation coefficient H1. The second coefficient holding circuit 34 stores a value input thereto when an enable signal en2 is in an enable state, and holds a previously stored value when the enable signal en2 is in a disenable state. The second coefficient holding circuit 34 is controlled by the enable signal en2 to hold the second compensation coefficient H2.
The synthesizing circuit 35 synthesizes the first compensation coefficient H1 and the second compensation coefficient H2 with each other to generate the third compensation coefficient H3. The synthesizing circuit 35 outputs an average value or a weighted average value of the two compensation coefficients as the third compensation coefficient H3, for example. The third coefficient holding circuit 36 stores a value input thereto when an enable signal en3 is in an enable state, and holds a previously stored value when the enable signal en3 is in a disenable state. The third coefficient holding circuit 36 is controlled by the enable signal en3 to hold the third compensation coefficient H3.
The third selecting circuit 37 switches the compensation coefficient to be output, based on the selecting signal sel3. The third selecting circuit 37 selects and outputs the first compensation coefficient H1 until the third compensation coefficient H3 is generated, and selects and outputs the third compensation coefficient H3 after the third compensation coefficient H3 is generated.
The inverse calculating circuit 38 calculates an inverse of the compensation coefficient output from the third selecting circuit 37. The propagation-path compensating circuit 39 performs a distortion compensating process for the received signal sequence by using the inverse of the compensation coefficient output from the inverse calculating circuit 38, and outputs the equalizer-compensated output sequence S203.
Next, the tracking processing circuit 24 is described in detail.
The pilot-signal-information holding unit 41 is a pilot register that stores therein pilot-signal information that is to be a reference for a delay amount of a header sequence. This pilot-signal information is stored in the pilot-signal-information holding unit 41 before the overall control unit 18 or the like performs phase estimation by the phase estimating circuit 42 to conform to a communication standard, for example.
The phase estimating circuit 42 compares the pilot-signal information and a header sequence in the equalizer-compensated output sequence S203 with each other to estimate a phase amount, and generates the phase amount information S204 that indicates the magnitude of phase rotation. The phase compensating circuit 43 compensates the phase of the equalizer-compensated output sequence S203 based on the phase amount information S204, and outputs a compensated signal as the sequence to be demodulated S104.
Next, the phase compensating circuit 27 is described in detail.
Next, the demodulation processing circuit 14 and the modulation processing circuit 15 are described in detail.
As illustrated in
The modulation processing circuit 15 includes a header-frame generating circuit 71, a CRC generating circuit 72, a scramble setting circuit 73, a convolutional coding circuit 74, an interleaving processing circuit 75, and a constellation-mapping processing circuit 76. In the modulation processing circuit 15, the header-frame generating circuit 71 generates a header frame and adds it to a payload sequence. The CRC generating circuit 72 then generates a CRC for random data stored in the header frame and stores the CRC in the header frame. Thereafter, the scramble setting circuit 73, the convolutional coding circuit 74, the interleaving processing circuit 75, and the constellation-mapping processing circuit 76 perform processing in that order, so that the modulation processing circuit 15 outputs the transmitted signal sequence S107.
Next, an operation of the receiving device 3 according to the first embodiment is described. The receiving device 3 according to the first embodiment has a feature in an operation of the equalizer 23.
As illustrated in
Subsequently, in a period in which a header sequence is input, propagation-path compensation for the header sequence is performed based on the first compensation coefficient H1 obtained in the first propagation-path estimating process. Further, demodulation is performed for an equalizer-compensated output sequence that has been compensated with the first compensation coefficient H1 in this period. After all of the header sequence has been input, modulation is performed for the demodulated header sequence in the receiving device 3. By this modulation, the header-replica sequence S107 is generated. Further, the phase-compensated header sequence S207 is generated by the phase compensating circuit 27 at a timing of generation of the header-replica sequence S107. The second propagation-path estimating process (a period of propagation estimation (H2) in
In the second propagation-path estimating process, the overall control unit 18 places the selecting signals sel1 and sel2 at a high level and places the selecting signal sel3 at a low level, and the equalizer 23 generates the second compensation coefficient H2 based on the header sequence S207 and the transmitted signal sequence S107. In this generation, the enable signal en2 is placed in an enable state (for example, at a high level). This causes the second coefficient holding circuit 34 to output the second compensation coefficient H2 after the second compensation coefficient H2 has been generated. Also, because the selecting signal sel3 is at a low level in this period, the first compensation coefficient H1 stored in the first coefficient holding circuit 33 is transferred to the propagation-path compensating circuit 39.
Subsequently, the equalizer 23 performs the third propagation-path estimating process (a period of synthesizing (H3) in
Next, an operation of the equalization processing circuit 13 is described.
Thereafter, when a header sequence is input, the equalization processing circuit 13 writes the header sequence into the third delay buffer 26 and performs a compensating process that applies the first compensation coefficient H1 to the input header sequence (the propagation-path compensation (H1)). Demodulation and modulation are then performed for the header sequence that has been subjected to the compensating process, so that a header-replica sequence is generated. In this demodulation, the phase amount information S204 is generated by the tracking processing circuit 24 and is written into the second delay buffer 25. At a timing of generation of the header-replica sequence, the delay header sequence S205 is read out from the third delay buffer 26, and the phase amount information S206 is read out from the second delay buffer 25. Then, the phase compensating circuit 27 generates the header sequence S207.
The equalization processing circuit 13 then performs the second propagation-path estimating process (propagation estimation (H2)), which generates the second compensation coefficient H2, by using the header sequence S107 and the header-replica sequence. Thereafter, the third propagation-path estimating process (synthesizing (H3)) is performed, which generates the third compensation coefficient H3 by synthesizing the first compensation coefficient H1 and the second compensation coefficient H2 with each other. Modulation for the header sequence, generation of the header-replica sequence, generation of the header sequence S207, the second propagation-path estimating process, and the third propagation-path estimating process are performed in a period in which a payload sequence is input.
The third compensation coefficient H3 has not been generated yet at a time of input of the payload sequence in the equalization processing circuit 13. Thus, the equalization processing circuit 13 accumulates the input payload sequence in the first delay buffer 21 and, at a time when the third compensation coefficient H3 has been generated, reads out the accumulated payload sequence from the first delay buffer 21 in the order of accumulation. The equalization processing circuit 13 then performs a propagation-path compensating process that applies the third compensation coefficient H3 to the read payload sequence.
Next, an operation flow illustrated in
Subsequently, when a header sequence is input, the equalization processing circuit 13 performs a propagation-path compensating process that applies the first compensation coefficient H1 to that header sequence. By using the header sequence generated in this propagation-path compensating process, the equalization processing circuit 13 generates a header-replica sequence. Further, the phase amount information S204 is generated in generation of the header-replica sequence. The equalization processing circuit 13 performs a phase compensating process that compensates phase rotation of the input header sequence by using this phase amount information S204. The equalization processing circuit 13 also performs the second propagation-path estimating process by using the phase-compensated header sequence and the header-replica sequence. This second propagation-path estimating process synthesizes the second compensation coefficient H2 to generate the second compensation coefficient H2 that is a synthesized value, because the second compensation coefficient H2 is in the format of a data sequence.
Subsequently, the equalization processing circuit 13 synthesizes the first compensation coefficient H1 and the second compensation coefficient H2 with each other to generate the third compensation coefficient H3. The equalization processing circuit 13 then performs a propagation-path compensating process for a payload sequence by using the third compensation coefficient H3. In a period after the third transmission-path estimating process, that is, a period after the above-described processes has been performed, the transmitting and receiving device 1 according to the first embodiment operates in the following manner. The demodulation processing circuit 14 demodulates the sequence to be demodulated S103 and outputs the received data sequence S105 that is generated to the signal processing circuit 100 in a later stage. The modulation processing circuit 15 modulates the transmitted data sequence S106 output from the signal processing circuit 100 to generate a transmitted signal sequence S107, and outputs the generated transmitted signal sequence S107 to a transmission processing circuit provided in a later stage.
The receiving device 3 according to the first embodiment has a feature in a generation method of a header-replica sequence. Specifically, the receiving device 3 according to the first embodiment operates in the following manner in a period after the first transmission-path estimating process and before the third transmission-path estimating process. The demodulation processing circuit demodulates the aforementioned sequence to be demodulated, which includes a header sequence, and outputs the demodulated header sequence to the modulation processing circuit. The modulation processing circuit performs modulation for the received demodulated header sequence and outputs a header-replica sequence. Thus, a generation method of the header-replica sequence is described.
As illustrated in
That is, the header-replica sequence is generated only from the header sequence without an error, and therefore the second compensation coefficient H2 does not include an error component (noise). Thus, the receiving device 3 according to the first embodiment can estimate highly accurate propagation-path characteristics.
As described above, the receiving device 3 according to the first embodiment calculates the second compensation coefficient H2 estimated from a header sequence, in addition to the first compensation coefficient H1 estimated from a preamble sequence, and generates the third compensation coefficient H3 to be applied to a payload sequence by synthesizing the first compensation coefficient H1 and the second compensation coefficient H2 with each other. Therefore, the receiving device 3 according to the first embodiment can make the number of compensation coefficients to be subjected to weighted averaging larger than the number of symbols included in the preamble sequence, which results in a high noise compression effect.
Further, the receiving device 3 according to the first embodiment generates a header-replica sequence to be used for estimation of the second compensation coefficient H2, from a header sequence not including an error in decoding. Therefore, the estimation accuracy of the second compensation coefficient H2 cannot be deteriorated because of an influence of noise included in the header sequence. That is, the second compensation coefficient H2, which is highly accurate, is increased in the receiving device 3 according to the first embodiment, so that it is possible to further enhance the compression effect. Meanwhile, the receiving device described in Japanese Patent No. 3794622 uses a replica for estimation of transmission-path characteristics even if the replica includes an error component (noise), and therefore has a problem that accuracy of an estimated value of the transmission-path characteristics is low and a noise compression effect is significantly deteriorated in an environment including many error components (noise).
Here, noise characteristics of the receiving device 3 according to the first embodiment are described.
By reducing the influence of noise on the compensation coefficient in this manner, a reaching distance of a radio signal can be made longer. In recent years, devices using a radio signal are increasing, and it becomes important to cover more areas by less base stations. In particular, in a case of a non-mobile station, such as a smart meter, a transmission path to a base station is fixed, and use of the receiving device 3 according to the first embodiment enables communication even if the non-mobile station is arranged at a position far away from the base station.
Processing of the equalization processing circuit 13 can be also achieved by a program. In this case, the equalization processing circuit 13 is configured by an arithmetic processing unit that can execute a program, and a register, a memory, or the like is used as a circuit for holding a value, such as a delay buffer or a holding circuit, in the equalization processing circuit 13. In this case, the transmitting and receiving device 1 according to the first embodiment includes the equalization processing circuit 13 that performs an equalizing process for the received signal sequence S103 generated from a received signal and outputs the sequence to be demodulated S104, the demodulation processing circuit 14 that demodulates the sequence to be demodulated S104 and outputs the received data sequence S105, and the modulation processing circuit 15 that modulates the received data sequence S105 and generates the transmitted signal sequence S107. In the equalization processing circuit 13, an equalization processing program is executed. The equalization processing circuit that executes the equalization processing program performs the first transmission-path estimating process of generating the first compensation coefficient H1 indicating a propagation coefficient of a transmission path of a received signal, based on a preamble sequence included in the received signal sequence S103 and having a predetermined value, the first propagation-path compensating process of applying the first compensation coefficient H1 to a header sequence included in the received signal sequence S103 to generate the first equalizer-compensated output sequence S203 in which distortion has been compensated, the second transmission-path estimating process of generating the second compensation coefficient H2 from the header-replica sequence S107 generated by performing demodulation and modulation for a header sequence included in the first equalizer-compensated output sequence S203, the third transmission-path estimating process of synthesizing the first compensation coefficient H1 and the second compensation coefficient H2 with each other to generate the third compensation coefficient H3, and the second propagation-path compensating process of performing a distortion compensating process for a payload sequence included in the received signal sequence S103 based on the third compensation coefficient H3.
Further, the equalization processing circuit 13 includes the first delay buffer 21, the second delay buffer 25, and the third delay buffer 26. The equalization processing circuit 13 performs an equalizing process of performing a distortion compensating process for the received signal sequence S201 and outputting the equalizer-compensated output sequence S203, a tracking process of compensating phase rotation of the equalizer-compensated output sequence S203 and outputting the sequence to be demodulated S104, a phase-amount information holding process of temporarily holding the phase amount information S204 indicating the magnitude of phase rotation applied to the equalizer-compensated output sequence S203 in the second delay buffer 25, a header-sequence holding process of temporarily holding a header sequence in the third delay buffer 26, the first phase compensating process of applying the phase amount information S206 for the header sequence to generate the phase-compensated header sequence S207 in which the phase rotation of the header sequence has been compensated, a payload holding process of temporarily holding a payload sequence in the first delay buffer 21, and an input selecting process of selecting the received signal sequence S103 as an object of equalization in a period from the first transmission-path estimating process to the third transmission-path estimating process and selecting the payload sequence S201 stored in the first delay buffer 21 as the object of equalization in the second propagation-path compensating process.
In the tracking process, the equalization processing circuit 13 performs a phase estimating process of comparing pilot-signal information that is a reference of a phase rotation amount of a header sequence and a header sequence in the equalizer-compensated output sequence S203 to each other to estimate a phase rotation amount and generating phase amount information indicating the magnitude of phase rotation, and the second phase compensating process of compensating phase rotation of the equalizer-compensated output sequence S203 based on the phase amount information and outputting a compensated signal as a sequence to be demodulated.
In the second embodiment, an equalization processing circuit 13a is described, which is another example of the equalization processing circuit 13 in the first embodiment. In the second embodiment, the same component as that described in the first embodiment is labeled with the same reference sign as that in the first embodiment and the description thereof is omitted.
That is, the equalization processing circuit 13a according to the second embodiment includes the first delay buffer 21, the input selecting circuit 22, the equalizer 81, the tracking processing circuit 82, the second delay buffer 25, and the equalizer-compensation cancelling circuit 83. The first delay buffer 21 temporarily holds a payload sequence. The equalizer 81 performs a distortion compensating process for the received signal sequence S103 and outputs the equalizer-compensated output sequence S203. The equalizer 81 also outputs the first compensation coefficient H1 as a first coefficient signal S301. The tracking processing circuit 82 compensates phase rotation of the equalizer-compensated output sequence S203 and outputs the sequence to be demodulated S104. The second delay buffer 25 temporarily holds the sequence to be demodulated S104. The equalizer-compensated cancelling circuit 83 applies the first compensation coefficient H1 to a portion of the sequence to be demodulated S104, which corresponds to a header sequence, to generate a phase-rotation-compensated header sequence S302 in which an equalizer compensation effect of the header sequence has been cancelled. The input selecting circuit 22 provides the received signal sequence S103 to the equalizer 81 in a period from the first transmission-path estimating process to the third transmission-path estimating process, and provides the payload sequence stored in the first delay buffer 21 to the equalizer 81 in a propagation-path compensating process.
Here, the equalizer 81 is described in detail.
Subsequently, the tracking processing circuit 82 is described in detail.
Subsequently, the equalizer-compensation cancelling circuit 83 is described in detail.
Next, an operation of the equalizer 81 according to the second embodiment is described.
Here, a relation between the phase-compensated header sequence S207 and the equalizer-compensation-cancelled header sequence S302 is described. The phase-compensated header sequence S207 is obtained by phase rotation of the header sequence S205 input to the equalization processing circuit 13. Meanwhile, the equalizer-compensation-cancelled header sequence S302 is obtained by equalizer compensation using the first compensation coefficient H1 by the equalizer 81, followed by compensating phase rotation by the tracking processing circuit 82, and thereafter cancelling equalizer compensation by using the first compensation coefficient H1. That is, an effect applied to the equalizer-compensation-canceled header sequence S302 is only compensation of phase rotation by the tracking processing circuit 82, and the phase-compensated header sequence S207 and the equalizer-compensation-canceled header sequence S302 are substantially the same signal as each other.
Next, an operation of the equalization processing circuit 13a according to the second embodiment is described.
Next, an operation flow illustrated in
As described above, the equalization processing circuit 13a according to the second embodiment generates the equalizer-compensation-cancelled header sequence S302 that have equivalent characteristics to those of the phase-compensated header sequence S207 without using the second delay buffer 25. Therefore, the equalization processing circuit 13a according to the second embodiment can obtain the same noise compression effect as a receiving device including the equalization processing circuit 13 according to the first embodiment, by a small number of circuit elements than in the transmitting and receiving device 1 according to the first embodiment.
Further, processing of the equalization processing circuit 13a according to the second embodiment can be also achieved by a program. In this case, the equalization processing circuit 13a is configured by an arithmetic processing unit that can execute a program, and a register, a memory, or the like is used as a circuit for holding a value, such as a delay buffer or a holding circuit, in the equalization processing circuit 13a. In this case, the equalization processing circuit 13a according to the second embodiment includes the first delay buffer 21 and the second delay buffer 25. The equalization processing circuit 13a performs an equalizing process of performing a distortion compensating process for the received signal sequence S202 and outputting the equalizer-compensated output sequence S203, a tracking process of compensating phase rotation of the equalizer-compensated output sequence S203 and outputting the sequence to be demodulated S104, a demodulation-object sequence holding process of temporarily holding the sequence to be demodulated S104 in the second delay buffer 25, an equalizer-compensation cancelling process of applying the first compensation coefficient H1 to a portion of the sequence to be demodulated S104, which corresponds to a header sequence, to generate a phase-compensated header sequence in which phase rotation of the header sequence has been canceled, a payload holding process of temporarily holding a payload sequence in the first delay buffer 21, and an input selecting process of selecting the received signal sequence S103 as an object of an equalizing process in a period from the first transmission-path estimating process to the third transmission-path estimating process and selecting the payload sequence S201 stored in the first delay buffer as the object of the equalizing process in the second propagation-path compensating process.
In the third embodiment, the synthesizing circuit 35 included in the equalizer 23 or the equalizer 81 is described.
The fading-strength determining circuit 91 determines the fading strength of the received signal RX based on the first compensation coefficient H1, the second compensation coefficient H2, and an operation parameter provided in advance. When the fading strength has been determined to be smaller than a preset threshold value, the fading-strength determining circuit 91 places an enable signal en4 in an enable state, synthesizes the first compensation coefficient H1 and the second compensation coefficient H2 with each other to generate the third compensation coefficient H3 by the simple synthesizing circuit 92, and causes the coefficient selecting circuit 94 to select the third compensation coefficient H3 generated by the simple synthesizing circuit 92. When the fading strength has been determined to be equal to or larger than the preset threshold value, the fading-strength determining circuit 91 places an enable signal en5 in an enable state, synthesizes the first compensation coefficient H1 and the second compensation coefficient H2 with each other to generate the third compensation coefficient H3 by the weighted synthesizing circuit 93, and causes the coefficient selecting circuit 94 to select the third compensation coefficient H3 generated by the weighted synthesizing circuit 93.
The simple synthesizing circuit 92 calculates an average value of the first compensation coefficient H1 and the second compensation coefficient H2 as the third compensation coefficient H3. The third compensation coefficient H3 calculated by the simple synthesizing circuit 92 is represented by Expression (5).
H3=(H1+H2)/2 (5)
The weighted synthesizing circuit 93 applies predetermined weights to the first compensation coefficient H1 and the second compensation coefficient H2 and calculates a weighted average value of these weighted compensation coefficients as the third compensation coefficient H3. Assuming that the weight applied to the first compensation coefficient H1 is w1 and the weight applied to the second compensation coefficient H2 is w2, the third compensation coefficient H3 generated by the weighted synthesizing circuit 93 is represented by Expression (6).
H3=(w1×H1+w2×H2)/(w1+w2) (6)
The coefficient selecting circuit 94 selects the third compensation coefficient H3 generated based on the fading strength determined by the fading-strength determining circuit 91, from the output of the simple synthesizing circuit 92 and the output of the weighted synthesizing circuit 93, and outputs the selected third compensation coefficient H3 to the third coefficient holding circuit 36.
As described above, the synthesizing circuit 35 according to the third embodiment can switch a method of synthesizing the third compensation coefficient H3 in accordance with the fading strength. In a multipath fading environment, there is a trade-off relation that weighted synthesizing provides a better synthesizing result, while power consumption becomes larger. Therefore, as in the synthesizing circuit 35, the degree of multipath fading is determined, simple synthesizing is performed under a condition of weak fading, and weighted synthesizing is performed under a condition of strong fading. This makes it possible to balance the characteristics and the power consumption.
When the operation of the synthesizing circuit 35 is executed by a program, the equalization processing circuit 13 that executes an equalization processing program performs, in the third transmission-path estimating process, a fading-strength determining process of determining the fading strength of a received signal based on the first compensation coefficient H1, the second compensation coefficient H2, and an operation parameter provided in advance, a simple synthesizing process of calculating an average value of the first compensation coefficient H1 and the second compensation coefficient H2 as the third compensation coefficient H3 when the fading strength has been determined to be smaller than a preset threshold value in the fading-strength determining process, a weighted synthesizing process of applying predetermined weights to the first compensation coefficient H1 and the second compensation coefficient H2 and calculating a weighted average value of these weighted compensation coefficients as the third compensation coefficient when the fading strength has been determined to be equal to or larger than the preset threshold value in the fading-strength determining process, and a coefficient selecting process of selecting the third compensation coefficient H3 generated based on the fading strength determined in the fading-strength determining process from a calculation result of the simple synthesizing process and a calculation result of the weighted synthesizing process.
In the fourth embodiment, an example of a communication system using any of the received devices described in the first to third embodiments is described.
In a radio system, when the positional relation between the base station and the mobile station is not largely changed, deterioration of accuracy of a compensation coefficient by fading is small, and an influence of the fading on accuracy of estimation of propagation-path characteristics is small. Meanwhile, when the positional relation between the base station and the mobile station is not largely changed, thermal noise has a large influence on the accuracy of estimation of the propagation-path characteristics.
Therefore, when any of the receiving devices described in the first to third embodiments is used, it is possible to prevent deterioration of accuracy of estimation caused by thermal noise and to largely extend a communication distance from a base station, such as an access point router, to a mobile station especially in a fixed communication system.
In the above, the invention made by the inventors of the present application has been specifically described byway of the embodiments. However, it is naturally understood that the present invention is not limited to the aforementioned embodiments, and can be changed in various ways within the scope not departing from the gist thereof.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2017-249362 | Dec 2017 | JP | national |
