JP4717557B2 - Communication system and transmitter / receiver - Google Patents

Description

  The present invention relates to a communication system and a transmission / reception device in optical communication and wireless communication, and more particularly to a communication system and a transmission / reception device using a precoding technique for removing part or all of transmission path distortion on the transmission side. It is.

  A conventional communication system (see Non-Patent Document 1 below) that performs precoding will be described below. In a conventional communication system that performs precoding, for example, a transmission signal generation circuit that generates a transmission signal from transmission information, and a transmission signal that is generated by the transmission signal generation circuit pass through a filter corresponding to the inverse characteristic of transmission path distortion. An inverse characteristic filter to be transmitted, a transmission path that receives a transmission signal that has passed through the inverse characteristic filter, and a determination circuit that determines transmission information using a signal output from the transmission path.

  In the conventional communication system configured as described above, when the transmission path distortion is known in advance, the transmission side has no transmission path distortion by preparing a filter corresponding to the reverse characteristic of the transmission path distortion on the transmission side. A simple receiver in the environment can be used.

  Here, the operation principle of the conventional communication system will be briefly described.

  First, a transmission signal creation circuit creates a transmission signal for transmission to a transmission line from transmission information. Next, the created transmission signal is passed through an inverse characteristic filter that realizes a known inverse characteristic of transmission path distortion.

  Next, the transmission signal after passing through the inverse characteristic filter is output to the transmission line. The signal after passing through the transmission line is input to a determination circuit on the receiving side. Since the signal input to the determination circuit is a signal without transmission path distortion, the determination circuit can have a simple configuration.

  Thus, in a conventional communication system, a simple determination circuit can be used on the receiving side by preparing an inverse characteristic filter on the transmitting side. In addition, it is possible to avoid the problem of noise enhancement that becomes a problem when a linear equalizer is used on the receiving side.

Combined Equalization and Coding Using Precoding, in IEEE Communications Magazine, pp. 25-34, December 1991.

  However, the conventional communication system disclosed in the above document has a problem that the reception characteristic deteriorates for the transmission line characteristic in which it is difficult to realize the inverse characteristic filter.

  In addition, there is a problem that the characteristics deteriorate when there is an error in the assumed transmission path characteristics or when the transmission path characteristics fluctuate with time.

  The present invention has been made in view of the above, and is a transmission line characteristic in which it is difficult to realize an inverse characteristic filter, there is an error in the assumed transmission line characteristic, or the transmission line characteristic is temporally different. It is an object of the present invention to provide a communication system and a transmission / reception apparatus that can realize excellent characteristics even when they fluctuate.

  In order to solve the above-described problems and achieve the object, a communication system according to the present invention is a communication system including a transmission unit and a reception unit, wherein the transmission unit generates a transmission signal based on transmission information. Signal generation means, and transmission equalization means that takes the transmission signal as an input and realizes filter characteristics determined from transmission path distortion and receiver configuration information that are known in advance. Receiving equalization means for determining transmission information based on a received signal of a transmission path distortion signal in which a transmission signal after passing through the equalization section is output to the transmission path and subjected to transmission path distortion.

  According to the present invention, instead of preparing an inverse characteristic filter on the transmission side, a part thereof is prepared on the transmission side as feedforward filter means, and the remaining transmission path distortion is removed by the feedback filter means on the reception side. Therefore, it is not necessary to use an inverse characteristic filter for the feedforward filter means, and even if it is difficult to realize an inverse characteristic filter, an excellent characteristic can be realized. Play. In addition, by adaptively estimating the filter characteristics of the feedback filter means with respect to transmission path fluctuations, it is excellent even when there are errors in the assumed transmission path characteristics or when the transmission path characteristics fluctuate over time. The effect that the characteristic which was able to be implement | achieved is show | played. Furthermore, providing the feed-forward filter means on the transmission side has the effect of eliminating the problem of noise enhancement as in the linear equalizer.

  Embodiments of a communication system and a transmission / reception apparatus according to the present invention will be described below in detail with reference to the drawings. In addition, this invention is not limited by this embodiment.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating a configuration of a communication system using precoding that includes an inverse characteristic filter that realizes an inverse characteristic of transmission path distortion on the transmission side and a simple determination circuit on the reception side. Transmission information 1, a transmission signal generation circuit 2 that generates a transmission signal from transmission information 1, an inverse characteristic filter 3 that receives an output of the transmission signal generation circuit 2 and realizes an inverse characteristic of transmission path distortion, and a transmission path 4 And a determination circuit 5 that determines transmission information 1 from a reception signal that is an output of a transmission path and outputs a determination value 6. In these configurations, the transmission signal generation circuit 2 and the inverse characteristic filter 3 located on the input side of the transmission line 4 constitute a transmission side circuit, and the determination circuit 5 located on the output side receives the signal. Configure the side circuit.

  Here, the operation of the communication system configured as described above will be described.

  First, the transmission signal creation circuit 2 creates a transmission signal to be sent from the transmission information 1 to the transmission line. The created transmission signal is input to the inverse characteristic filter 3. Here, it is assumed that the inverse characteristic filter 3 is a filter having an inverse characteristic of transmission path distortion, and the transmission path distortion is known in advance. The output of the inverse characteristic filter 3 is input to the transmission line 4.

  Next, the determination circuit 5 determines the transmission information 1 from the received signal that is the output of the transmission path 4 and outputs a determination value 6. Here, since the output of the transmission line 4 is a signal that is not subjected to transmission line distortion, the determination circuit 5 can have a simple configuration.

  FIG. 2 is a configuration diagram in which a configuration unit having a timing reproduction function is added to the reception side of the communication system of FIG. In the configuration illustrated in FIG. 2, a BTR (Bit Timing Recovery) circuit 7 that extracts symbol timing and a sampling circuit 8 that samples a reception signal based on the extracted symbol timing are added on the reception side. . As the BTR circuit 7, a multiplying tank system, which is a known technique, can be adopted.

  The communication system of FIGS. 1 and 2 has an advantage that the reception side can be realized with a simple determination circuit 5 by including the inverse characteristic filter 3 on the transmission side. On the other hand, as described above, there is a problem that the characteristics are deteriorated for the transmission line characteristics in which it is difficult to realize the inverse characteristic filter. In addition, there is a problem that the characteristics deteriorate when there is an error in the assumed transmission path characteristics or when the transmission path characteristics fluctuate with time.

  FIG. 3 is a diagram illustrating a configuration of a communication system that does not include an inverse characteristic filter on the transmission side and includes a decision feedback equalizer including a feedforward filter 9 and a feedback filter 10 on the reception side. In the communication system shown in FIG. 2, the feedforward filter 9 has a characteristic close to the reverse characteristic of the transmission line distortion to remove a part of the transmission line distortion, and the feedback filter 10 removes the remaining transmission line distortion. It is characterized by providing the feedforward filter 9 and the feedback filter 10 on the receiving side, so that excellent characteristics can be achieved even for transmission path characteristics where it is difficult to realize an inverse characteristic filter. There are advantages you can do. Further, by changing the characteristics of the feedback filter 10 adaptively according to the transmission line fluctuation, it is excellent even when there is an error in the assumed transmission line characteristic or the transmission line characteristic fluctuates with time. There is an advantage that the characteristics can be realized. However, since the feed-forward filter 9 is provided on the receiving side, the problem of noise enhancement caused by using a linear equalizer on the receiving side as described above occurs.

  Therefore, in the present embodiment, a communication system having the configuration shown in FIG. 4 is proposed. Here, FIG. 4 is a diagram showing a configuration of the communication system according to the first exemplary embodiment of the present invention. The communication system shown in FIG. 1 includes transmission information 1, a transmission signal generation circuit 2 that generates a transmission signal from transmission information 1, and transmission equalization means that receives the transmission signal and removes part of the transmission path distortion in advance. One form of the feed forward filter 9 which is one form, the transmission line 4, and the reception equalization means which judges the transmission information 1 from the received signal which received the transmission line distortion which is the output of the transmission line 4, and outputs the judgment value 6 And a feedback filter 10.

  Next, the configuration and operation of the communication system configured as described above will be described.

  First, the transmission signal generation circuit 2 generates a transmission signal for outputting from the transmission information 1 to the transmission path 4. Here, for optical communication, for example, an NRZ (Non Return to Zero) signal or an RZ (Return to Zero) signal is generated. For wireless communication, for example, a BPSK (Binary Phase Shift Keying) signal or a QPSK (Quadrature Phase Shift Keying) signal is generated.

  FIG. 5 is a diagram illustrating an internal configuration example of the feedforward filter 9, and includes a shift register unit 51, multipliers 52 to 57, and an adder 58. The feedforward filter 9 shown in the figure is a circuit configured to remove in advance a part of transmission path distortion from information of transmission path distortion known in advance, and the circuit having such a configuration is referred to as FIR (Finite). This is called an “Impulse Response” filter.

  In FIG. 5, the shift register unit 51 shifts the input signal by delaying, for example, by 1/2 symbol (T / 2). The multipliers 52 to 57 multiply the input signal or the output of the shift register unit 51 by a specific coefficient (tap coefficient). These tap coefficients are set so as to remove a part thereof according to the transmission path distortion. The adder 58 adds all the outputs of the multipliers 52 to 57. The output of the adder 58 becomes the output of the feedforward filter 9.

  As a result of the processing as described above, the output of the feedforward filter 9 is input to the transmission path 4, and a reception signal subjected to transmission path distortion is output from the transmission path 4.

  On the other hand, FIG. 6 is a diagram illustrating an internal configuration example of the feedback filter 10, and includes a subtractor 61, a determination circuit 62, a shift register unit 63, multipliers 64 to 69, and an adder 70. Yes. The feedback filter 10 shown in the figure is a circuit configured to remove transmission path distortion from the reception signal output from the transmission path 4, determine transmission information 1, and output a determination value 6. A circuit having such a configuration is called an IIR (Infinite Impulse Response) filter.

  In FIG. 6, a subtractor 61 subtracts the output of the adder 70 from the received signal output from the transmission path 4. Here, the output of the adder 70 outputs a transmission line distortion component. Therefore, the output of the subtractor 61 is a signal from which transmission line distortion has been removed. The determination circuit 62 determines the transmission information 1 from the signal from which the transmission path distortion has been removed, and outputs a determination value 6. On the other hand, the determination value 6 is input to the shift register unit 63 in order to calculate the transmission path distortion component. The shift register unit 63 delays the input signal, for example, by one symbol (T) and shifts it. The multipliers 64 to 69 multiply the output of the shift register unit 63 by a specific coefficient (tap coefficient). These tap coefficients are set so as to be removed according to the transmission path distortion. The adder 70 adds all the outputs of the multipliers 64 to 69. The output of the adder 70 is input to the subtractor 61 as a transmission path distortion component.

  Note that the communication system of the first embodiment is completely different from the method of providing a dispersion compensating fiber widely used in optical communication on the transmission side or the reception side as well as an implementation means. This is true not only for the present embodiment but also for the present invention.

  In this embodiment, a communication system using precoding has been described in which a transmission characteristic is provided with an inverse characteristic filter that realizes an inverse characteristic of transmission path distortion, and a simple determination circuit is provided on the reception side. Of course, it is also possible to configure as a transmission / reception device having the same configuration in the same device.

  As described above, in the present embodiment, the feed forward filter is provided on the transmission side and the feedback filter is provided on the reception side, so that it is difficult to realize the reverse characteristics of the transmission path distortion. Even so, transmission path distortion can be effectively removed, and excellent characteristics can be realized.

  Further, in this embodiment, since the feed forward filter is provided on the transmission side, it is possible to avoid the problem of noise enhancement that becomes a problem when the linear equalizer is provided on the reception side. Characteristics can be realized.

  In this embodiment, if the tap coefficient of the feedback filter is adaptively estimated, excellent characteristics can be obtained even when there is an error in the assumed transmission path or the transmission path fluctuates. Can be realized.

  The communication system according to the first embodiment has been described assuming optical communication or wireless communication. However, the communication system is not necessarily optical communication or wireless communication, and can be applied to, for example, general wired communication. is there.

  In the communication system according to the first embodiment, the feedback filter is a fixed filter. However, the feedback filter is not necessarily fixed. For example, the tap coefficient of the filter is adaptively estimated according to the transmission path fluctuation. The characteristics may be changed. At this time, as a tap coefficient estimation method, an LMS (Least Mean Square) algorithm or the like may be used.

  Further, the communication system of the first embodiment may be configured with either an analog circuit or a digital circuit.

  Further, the communication system of the first embodiment is configured to share the role of removing transmission path distortion between the transmission side and the reception side, and remove the final transmission path distortion by using a feed-forward filter on the transmission side. Since the operation is given, the filter provided on the reception side is not necessarily a feedback filter having the above-described configuration, and may be a linear equalizer such as a feedforward filter.

Embodiment 2. FIG.
FIG. 7 is a diagram showing a configuration of a communication system according to the second exemplary embodiment of the present invention. The communication system shown in FIG. 1 includes a BTR circuit 7 that extracts the symbol timing using the output of the transmission line 4 as an input, a timing shift circuit 11 that shifts the symbol timing extracted by the BTR circuit 7 by a specific shift amount, A sampling circuit 8 that samples the output of the transmission line 4 based on the output of the shift circuit 11 is provided. Note that components that are the same as or equivalent to those of the first embodiment described above are denoted by the same reference numerals and description thereof is omitted, and only processes different from those of the first embodiment are described here.

  In FIG. 7, the BTR circuit 7 adopts a circuit configuration using, for example, a multiplying tank system as in the first embodiment, and extracts symbol timing from the output of the transmission line 4. The timing shift circuit 11 shifts the symbol timing extracted by the BTR circuit 7 by a specific shift amount. This shift amount is determined by transmission path distortion.

  The sampling circuit 8 samples the output of the transmission line 4 at the symbol period based on the output of the timing shift circuit 11. As a result, the feedback filter 10 can operate based on the signal of the symbol period that is the output of the sampling circuit 8.

  In this embodiment, a communication system using precoding has been described in which a transmission characteristic is provided with an inverse characteristic filter that realizes an inverse characteristic of transmission path distortion, and a simple determination circuit is provided on the reception side. Of course, it is also possible to configure as a transmission / reception device having the same configuration in the same device.

  As described above, in the present embodiment, the feedforward filter is provided on the transmission side and the feedback filter is provided on the reception side, as in the first embodiment. Thereby, even when it is difficult to realize the reverse characteristic of the transmission path distortion, the transmission path distortion can be appropriately removed, and an excellent characteristic can be realized.

  Also, in this embodiment, by providing a feedforward filter on the transmission side, it is possible to avoid the noise enhancement problem that becomes a problem when a linear equalizer is provided on the reception side, and to realize excellent characteristics Can do.

  In the present embodiment, it is possible to realize excellent characteristics even when there is an error in the assumed transmission path or the transmission path fluctuates by adaptively estimating the tap coefficient of the feedback filter. .

  In the present embodiment, the sampling circuit is used to sample the received signal at the symbol period, so that the feedback filter can operate at the symbol period.

  The communication system according to the second embodiment has been described assuming optical communication or wireless communication. However, the communication system is not necessarily optical communication or wireless communication, and can be applied to, for example, general wired communication. is there.

  In the communication system according to the second embodiment, the feedback filter is a fixed filter. However, the feedback filter is not necessarily fixed. For example, the tap coefficient of the filter is adaptively estimated according to transmission path fluctuation. The characteristics may be changed. At this time, an LMS algorithm or the like may be used as a tap coefficient estimation method.

  Further, the communication system of the second embodiment may be configured with either an analog circuit or a digital circuit.

  Further, the communication system according to the second embodiment is configured to share the role of removing transmission path distortion between the transmission side and the reception side, and remove the final transmission path distortion by using a feed-forward filter on the transmission side. Since the operation is given, the filter provided on the reception side is not necessarily a feedback filter having the above-described configuration, and may be a linear equalizer such as a feedforward filter.

Embodiment 3 FIG.
FIG. 8 is a diagram showing a configuration of a communication system that does not include an inverse characteristic filter on the transmission side, and includes a Viterbi equalizer that includes a feedforward filter 9 and a Viterbi equalizer 12 on the reception side. In the communication system shown in the figure, the feedforward filter 9 has a characteristic close to the reverse characteristic of the transmission line distortion to remove a part of the transmission line distortion and the remaining transmission line distortion is removed by the Viterbi equalizer 12. By providing the feedforward filter 9 and the Viterbi equalizer 12 on the receiving side, it is excellent even for transmission line characteristics in which it is difficult to realize an inverse characteristic filter. There is an advantage that can realize the characteristics. Further, even when the Viterbi equalizer 12 adaptively changes the characteristics according to the transmission line fluctuation, there is an error in the assumed transmission path characteristics, or even when the transmission path characteristics fluctuate with time, There is an advantage that excellent characteristics can be realized. However, since the feed-forward filter 9 is provided on the receiving side, the problem of noise enhancement caused by using a linear equalizer on the receiving side as described above occurs.

  Therefore, in this embodiment, a communication system having the configuration shown in FIG. 9 is proposed. Here, FIG. 9 is a figure which shows the structure of the communication system concerning Embodiment 3 of this invention. The communication system shown in FIG. 1 includes transmission information 1, a transmission signal generation circuit 2 that generates a transmission signal from transmission information 1, a feedforward filter 9 that receives the transmission signal and removes part of the transmission path distortion in advance. A transmission path 4 and a Viterbi equalizer 12 that determines transmission information 1 from a received signal subjected to transmission path distortion, which is an output of the transmission path 4, and outputs a determination value 6. Note that components that are the same as or equivalent to those in the first or second embodiment described above are denoted by the same reference numerals and description thereof is omitted, and only processing that is different from that in the first or second embodiment is described here. To do.

  Next, the operation of the communication system configured as described above will be described.

  In FIG. 9, the transmission signal generation circuit 2 generates a transmission signal to be output from the transmission information 1 to the transmission path 4. Here, for optical communication, for example, an NRZ signal or an RZ signal is created. For wireless communication, for example, a BPSK signal or a QPSK signal is created.

  Next, the feedforward filter 9 is configured to remove a part of the transmission path distortion in advance from information on the transmission path distortion known in advance, and processes the transmission signal. An example of the internal configuration of the feedforward filter 9 is as shown in FIG.

  FIG. 10 is a diagram illustrating an internal configuration example of the Viterbi equalizer 12. The Viterbi equalizer 12 shown in the figure includes a branch metric creation circuit 101, an ACS (Add Compare Select) processing circuit 102, a path metric memory 103, a path memory 104, and a determination circuit 105.

  FIG. 11 is a diagram illustrating an example of a trellis diagram when the memory length of the Viterbi algorithm is 2 in the BPSK modulation method. In the figure, the horizontal direction represents a change in time, and the vertical white circle (◯) represents one state, and these states represent a set of past transmission signals. For example, in the BPSK modulation method, there are two transmission signals, 0 and 1, and if the memory length of the Viterbi algorithm (the length of the past transmission signal to be stored) is 2, the number of states is 4, The four states A, B, C, and D are shown in order from the top in the vertical direction. In addition, a line is drawn from each state (◯) to two states toward the next time, and this line is called a branch indicating a change in state accompanying a change in time. As the time changes, the state changes and follows the branch. This miracle is called a path (thick line in FIG. 11). If this path can be determined on the receiving side, transmission information can be determined.

Next, the operating principle of the Viterbi equalizer will be described with reference to FIGS. For simplicity of explanation, it is assumed that the received signal is modulated by the BPSK modulation method. In the branch metric generating circuit 101, from the received signal, branch metrics E _n of 2 ^V as corresponding to each branch in the trellis diagram (k) (k = 1,2, ···, 2 V) is calculated, the output Is done. Here, V-1 is the memory length of the Viterbi algorithm, and is 2 in FIG.

In the branch metric creation circuit 101, V = 3 for the sake of simplicity. Assuming that the received signal is r _n (n represents time), the branch metric creation circuit 101 creates a branch metric represented by equation (1) for each branch.

E _n (k) = | r _n −c ₀ * J _n −c ₁ * J _n−1 −c ₂ * J _n−2 | ² (1)

Here, in Equation (1), c ₀ , c ₁ , c ₂ are tap coefficients determined from transmission path distortion, and J _n , J _n-1 , J _n-2 correspond to each branch. It is a candidate for a transmission signal.

The ACS processing circuit 102 selects a path that enters each state (white circle) in the trellis diagram at each time. The number of states if ^{_{N S (= 2 V-1}} ), N S number of paths corresponding to each state is selected at each time. These N _S selected paths are called surviving paths and are stored in the path memory 104. However, the path memory 104 stores transmission signal sequence candidates up to the past U time corresponding to the surviving path. U is called the path memory length. The sum of branch metrics of all branches included in the surviving path is called a surviving path metric and is stored in the path metric memory 103.

Since the ACS processing circuit 102 performs a process corresponding to each state, in the following description, a state that could be taken, the state m (m = 1,2, ···, N S) in a generalized form described To do.

Branch metrics E _n (p) and E _n (q) corresponding to two branches connected to the state m are input to the ACS processing circuit 102 from the branch metric creation circuit 101. In addition, surviving path metrics PM _n-1 (i) and PM _n-1 (j) of one time past corresponding to two states i, j of one time past connected by two branches connected to the state m are path metrics. Input from the memory 103. Further, surviving paths PT _n-1 (i) and PT _n-1 (j) past one time corresponding to two states i and j past one time connected by two branches connected to the state m are the path memory 104. Is input. Then, branch metrics E _n (p), E _n (q) and survivor path metrics PM _n-1 (i), PM _n-1 (j) are added and compared, and the smaller one corresponds to state m Is selected as the surviving path metric PM _n (m) at the current time. That is, PM _n (m) is expressed by the following equation.

PM _n (m) = min [E _n (p) + PM _n-1 (i), E _n (q) + PM _n-1 (j)] (2)

The updated surviving path metric PM _n (m) at the current time is stored in the path metric memory 103. Further, E _n (p) + PM _n−1 (i) and E _n (q) + PM _n−1 (j) are compared, and a survival path is determined based on the comparison result. That is, when E _n (p) + PM _n-1 (i) is small, PT _n-1 (i) is selected. On the other hand, when E _n (q) + PM _n−1 (j) is small, PT _n−1 (j) is selected. While removing the oldest transmission signal candidate from the selected one-time past surviving path, a new transmission signal is added to which the transmission signal candidate at the current time determined by the path selected by the comparison result is added. Is a surviving path PT _n (m) at the current time corresponding to the state m. Further, the updated surviving path PT _n (m) at the current time is stored in the path memory 104.

In the determination circuit 105, among the surviving paths corresponding to the states stored in the path memory 104, the oldest transmission signal candidate of the surviving path corresponding to the maximum likelihood state (referred to as the maximum likelihood path) is determined as the transmission signal. To a determination value of 6. Here, the maximum likelihood state is the largest value among the surviving path metrics PM _n (m) (m = 1, 2,..., N _S ) corresponding to each state output from the ACS processing circuit 102. Is a state m ₁ defined by a small surviving path metric PM _n (m ₁ ). In the example shown in FIG. 11, the maximum likelihood path at the determination time n is indicated by a bold line.

  In this embodiment, a communication system using precoding has been described in which a transmission characteristic is provided with an inverse characteristic filter that realizes an inverse characteristic of transmission path distortion, and a simple determination circuit is provided on the reception side. Of course, it is also possible to configure as a transmission / reception device having the same configuration in the same device.

  As described above, in this embodiment, the feedforward filter is provided on the transmission side, and the Viterbi equalizer is provided on the reception side. Thereby, even when it is difficult to realize the reverse characteristic of the transmission path distortion, the transmission path distortion can be appropriately removed, and an excellent characteristic can be realized.

  Also, in this embodiment, by providing a feedforward filter on the transmission side, it is possible to avoid the noise enhancement problem that becomes a problem when a linear equalizer is provided on the reception side, and to realize excellent characteristics Can do.

  Further, in the present embodiment, by adaptively estimating the tap coefficient of the branch metric creation circuit of the Viterbi equalizer, even in the case where there is an error in the assumed transmission line or the transmission line fluctuates. , Can achieve excellent characteristics.

  The communication system according to the third embodiment has been described assuming optical communication or wireless communication. However, the communication system is not necessarily optical communication or wireless communication, and can be applied to, for example, general wired communication. is there.

  In the communication system according to the third embodiment, the tap coefficient in the branch metric creation circuit of the Viterbi equalizer is a fixed filter. However, the tap coefficient is not necessarily fixed. For example, according to transmission path fluctuation, The characteristic may be changed by estimating the tap coefficient of the filter adaptively. At this time, an LMS algorithm or the like may be used as a tap coefficient estimation method.

  Further, the communication system according to the third embodiment may be configured with either an analog circuit or a digital circuit.

Embodiment 4 FIG.
FIG. 12 is a diagram showing a configuration of a communication system according to the fourth exemplary embodiment of the present invention. The communication system shown in FIG. 1 includes a BTR circuit 7 that extracts the symbol timing using the output of the transmission line 4 as an input, a timing shift circuit 11 that shifts the symbol timing extracted by the BTR circuit 7 by a specific shift amount, A sampling circuit 8 that samples the output of the transmission line 4 based on the output of the shift circuit 11 is provided. Note that components that are the same as or equivalent to those of the above-described first to third embodiments are denoted by the same reference numerals and description thereof is omitted, and only processes different from those of the first embodiment are described here.

  In FIG. 12, the BTR circuit 7 employs, for example, a circuit configuration using a multiplying tank system as in the first and second embodiments, and extracts the symbol timing from the output of the transmission line 4. The timing shift circuit 11 shifts the symbol timing extracted by the BTR circuit 7 by a specific shift amount. This shift amount is determined by transmission path distortion.

  The sampling circuit 8 samples the output of the transmission line 4 at the symbol period based on the output of the timing shift circuit 11. As a result, the Viterbi equalizer 12 can operate based on the signal of the symbol period that is the output of the sampling circuit 8.

  In this embodiment, a communication system using precoding has been described in which a transmission characteristic is provided with an inverse characteristic filter that realizes an inverse characteristic of transmission path distortion, and a simple determination circuit is provided on the reception side. Of course, it is also possible to configure as a transmission / reception device having the same configuration in the same device.

  As described above, in the present embodiment, as in the third embodiment, the feedforward filter is provided on the transmission side, and the Viterbi equalizer is provided on the reception side. Thereby, even when it is difficult to realize the reverse characteristic of the transmission path distortion, the transmission path distortion can be appropriately removed, and an excellent characteristic can be realized.

  Also, in this embodiment, by providing a feedforward filter on the transmission side, it is possible to avoid the noise enhancement problem that becomes a problem when a linear equalizer is provided on the reception side, and to realize excellent characteristics Can do.

  Further, in the present embodiment, by adaptively estimating the tap coefficient of the branch metric creation circuit of the Viterbi equalizer, even in the case where there is an error in the assumed transmission line or the transmission line fluctuates. , Can achieve excellent characteristics.

  In the present embodiment, the Viterbi equalizer can operate at the symbol period by sampling the received signal at the symbol period by the sampling circuit.

  The communication system according to the fourth embodiment has been described assuming optical communication or wireless communication. However, the communication system is not necessarily optical communication or wireless communication, and can be applied to, for example, general wired communication. is there.

  In the communication system of the fourth embodiment, the tap coefficient in the branch metric creation circuit of the Viterbi equalizer is a fixed filter. However, the tap coefficient is not necessarily fixed. For example, according to the transmission path fluctuation, The characteristic may be changed by estimating the tap coefficient of the filter adaptively. At this time, an LMS algorithm or the like may be used as a tap coefficient estimation method.

  As described above, the communication system and the transmission / reception apparatus according to the present invention are useful for a communication system and a transmission / reception apparatus that perform precoding.

It is a figure which shows the structure of the communication system by precoding which is provided with an inverse characteristic filter and is provided with a simple determination circuit on the receiving side. It is the block diagram which added the structure part which has a timing reproduction | regeneration function to the receiving side of the communication system of FIG. It is a figure which shows the structure of the communication system which is not provided with the reverse characteristic filter in the transmission side, and is provided with the decision feedback equalizer on the reception side. It is a figure which shows the structure of the communication system concerning Embodiment 1 of this invention. It is a figure which shows the internal structural example of a feedforward filter. It is a figure which shows the internal structural example of a feedback filter. It is a figure which shows the structure of the communication system concerning Embodiment 2 of this invention. It is a figure which shows the structure of the communication system which is not provided with an inverse characteristic filter on the transmission side, and is equipped with a Viterbi equalizer on the reception side. It is a figure which shows the structure of the communication system concerning Embodiment 3 of this invention. It is a figure which shows the internal structural example of a Viterbi equalizer. It is a figure which shows an example of the trellis diagram in case the memory length of a Viterbi algorithm is 2 in a BPSK modulation system. It is a figure which shows the structure of the communication system concerning Embodiment 4 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Transmission information 2 Transmission signal preparation circuit 3 Inverse characteristic filter 4 Transmission path 5 Judgment circuit 6 Judgment value 7 BTR circuit 8 Sampling circuit 9 Feedforward filter 10 Feedback filter 11 Timing shift circuit 12 Viterbi equalizer 51, 63 Shift register part 52, 53, 54, 55, 56, 57, 64, 65, 66, 67, 68, 69 Multiplier 58, 70 Adder 61 Subtractor 62 Determination circuit 101 Branch metric creation circuit 102 ACS processing circuit 103 Path metric memory 104 Path memory 105 judgment circuit

Claims (22)

In a communication system including a transmission unit and a reception unit,
The transmitter is
Transmission signal creation means for creating a transmission signal based on transmission information;
Transmission equalization means for realizing the filter characteristics determined from the transmission path distortion and receiver configuration information known in advance, with the transmission signal as input,
The receiver is
A reception equalization means for determining transmission information based on a reception signal of a transmission path distortion signal that has been transmitted through the transmission equalization section and that has been transmitted to the transmission path is subjected to transmission path distortion,
The reception equalization means includes
Symbol timing reproduction means for extracting symbol timing from the received signal;
A timing shift means for determining a shift amount for the symbol timing extracted by the symbol timing reproduction means based on the transmission path distortion, and shifting the symbol timing by the determined shift amount;
Sampling means for sampling the received signal subjected to transmission path distortion based on the output of the timing shift means,
The communication system, wherein the reception equalization means determines transmission information based on an output of the sampling means.   The communication system according to claim 1, wherein each component of the transmission unit and the reception unit includes an analog circuit.   The communication system according to claim 1, wherein a part or all of the components of the transmission unit and the reception unit are configured by digital circuits.   The communication system according to claim 1, wherein the reception equalization unit adaptively changes a filter characteristic inside itself according to transmission path fluctuation.   The transmission equalization means adaptively changes its own filter characteristics according to transmission line fluctuations, and the reception equalization means adaptively changes its own internal filter characteristics according to transmission line fluctuations. The communication system according to claim 1.   The communication system according to claim 1, wherein the reception equalization unit includes a non-linear reception equalization unit.   The communication system according to claim 1, wherein the reception equalization unit includes a linear reception equalization unit.   6. The transmission equalization unit is configured using a feed forward filter unit, and the reception equalization unit is configured using a feedback filter unit. The communication system according to one. In a communication system including a transmission unit and a reception unit,
The transmitter is
Transmission signal creation means for creating a transmission signal based on transmission information;
Transmission equalization means configured using feedforward filter means that receives the transmission signal as input and realizes filter characteristics determined from information on transmission path distortion and receiver configuration known in advance;
With
The receiver is
Comprising a receiving equalizing means you determine transmission information based on the received signal of the transmission path distortion signal transmitting signal of the transmitting equalization means after passing receives the transmission path distortion is output to the transmission path,
The reception equalization means includes
Symbol timing reproduction means for extracting symbol timing from the received signal;
A timing shift means for determining a shift amount for the symbol timing extracted by the symbol timing reproduction means based on the transmission path distortion, and shifting the symbol timing by the determined shift amount;
Sampling means for sampling the received signal subjected to transmission path distortion based on the output of the timing shift means,
The communication system, wherein the reception equalization means determines transmission information based on an output of the sampling means . The communication system according to claim 9, wherein the reception equalization unit is a Viterbi equalization unit .   The communication system according to any one of claims 1 to 10, wherein the transmission equalization unit is configured using a FIR (Finite Impulse Response) filter.   The communication system according to any one of claims 1 to 10, wherein the transmission equalization means is configured using an IIR (Infinite Impulse Response) filter. In a transmission / reception device including a transmission unit and a reception unit,
The transmitter is
Transmission signal creation means for creating a transmission signal based on transmission information;
Transmission equalization means that takes the transmission signal as input and realizes filter characteristics determined from transmission path distortion and receiver configuration information known in advance;
With
The receiver is
A reception equalization means for determining transmission information based on a reception signal of a transmission path distortion signal that is output to the transmission path and is subjected to transmission path distortion is output to the transmission path as a signal equivalent to the transmission signal created by the transmission equalization section,
The reception equalization means includes
Symbol timing reproduction means for extracting symbol timing from the received signal;
A timing shift means for determining a shift amount for the symbol timing extracted by the symbol timing reproduction means based on the transmission path distortion, and shifting the symbol timing by the determined shift amount;
Sampling means for sampling the received signal subjected to transmission path distortion based on the output of the timing shift means,
The transmission / reception apparatus, wherein the reception equalization means determines transmission information based on an output of the sampling means.   The transmission / reception apparatus according to claim 13, wherein each component of the transmission unit and the reception unit is configured by an analog circuit.   The transmission / reception apparatus according to claim 13, wherein a part or all of the configuration units of the transmission unit and the reception unit are configured by a digital circuit.   The transmission / reception apparatus according to claim 13, wherein the reception equalization unit adaptively changes a filter characteristic inside itself according to transmission path fluctuation.   The transmission equalization means adaptively changes its own filter characteristics according to transmission line fluctuations, and the reception equalization means adaptively changes its own internal filter characteristics according to transmission line fluctuations. The transmission / reception apparatus according to claim 13.   The transmission / reception apparatus according to claim 13, wherein the reception equalization unit includes a nonlinear reception equalization unit.   The transmission / reception apparatus according to claim 13, wherein the reception equalization unit includes a linear reception equalization unit.   18. The transmission equalization unit is configured using a feedforward filter unit, and the reception equalization unit is configured using a feedback filter unit. Transmitter / receiver described in 1. In a transmission / reception device including a transmission unit and a reception unit,
The transmitter is
Transmission signal creation means for creating a transmission signal based on transmission information;
Transmission equalization means configured using feedforward filter means that receives the transmission signal as input and realizes filter characteristics determined from information on transmission path distortion and receiver configuration known in advance;
With
The receiver is
Comprising a receiving equalizing means you determine transmission information based on the received signal of the transmission path distortion signal transmitting signal of the transmitting equalization means after passing receives the transmission path distortion is output to the transmission path,
The reception equalization means includes
Symbol timing reproduction means for extracting symbol timing from the received signal;
A timing shift means for determining a shift amount for the symbol timing extracted by the symbol timing reproduction means based on the transmission path distortion, and shifting the symbol timing by the determined shift amount;
Sampling means for sampling the received signal subjected to transmission path distortion based on the output of the timing shift means,
The transmission / reception apparatus, wherein the reception equalization means determines transmission information based on an output of the sampling means . The transmission / reception apparatus according to claim 21, wherein the reception equalization means is a Viterbi equalization means .

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