JP4796212B1 - Receiving apparatus and receiving method - Google Patents

Abstract

A receiving apparatus and a receiving method for improving frequency offset estimation accuracy even in a fading environment without increasing the circuit scale.
A training unit 104 of a forward equalization processing unit 103 trains a synchronization word in the forward direction, and a frequency offset estimation unit 109 uses a synchronization word trained in the forward direction to estimate a forward frequency offset. Ask for. The training unit 107 of the backward equalization processing unit 106 trains the synchronization word in the backward direction, and the frequency offset estimation unit 110 obtains the backward frequency offset estimation value using the synchronization word trained in the backward direction. The selection unit 111 selects a frequency offset estimation value in the equalization direction with a small equalization error, and the frequency offset compensation unit 101 compensates the frequency offset of the received signal based on the selected frequency offset estimation value.
[Selection] Figure 2

Description

  The present invention relates to a receiving apparatus and a receiving method that perform equalization processing and frequency offset compensation.

0. Technical background and issues 0.1. Conventional Device Configuration Generally, it is known that a radio communication system is distorted in received signal and deteriorated in communication quality due to the influence of a frequency offset. The cause of the frequency offset includes a deviation in oscillation frequency between the local oscillator of the transmitter and the local oscillator of the receiver, and a Doppler shift due to movement of the terminal. For this reason, it is necessary to compensate for the frequency offset in order to reduce the influence of the frequency offset.

  On the other hand, wireless communication systems are also known to suffer from intersymbol interference due to the effects of multipath, resulting in degradation of communication quality. In order to reduce the influence of multipath, a delay equalizer (hereinafter simply referred to as “equalizer”) is required, but the equalizer is very vulnerable to frequency offset. For example, in a decision feedback equalizer (DFE: Decision Feedback Equalizer) which is a typical equalizer, tap coefficients are formed so as to have an inverse characteristic of an impulse response due to frequency selective fading in a training process. However, when a frequency offset occurs, the tap coefficient rotates in phase so as to compensate for the frequency offset.

  In particular, in a frequency fading environment and in a multi-station simultaneous transmission environment with a transmission timing offset, the frequency offset estimation accuracy deteriorates due to intersymbol interference.

  For this reason, Patent Documents 1 and 2 disclose techniques for performing equalization while compensating for the frequency offset in order to avoid degradation of communication quality.

0.2. Receiver disclosed in Patent Document 1 The receiver disclosed in Patent Document 1 includes two equalization circuits, equalizes a reception signal by the first equalization circuit, and estimates a frequency offset from a signal in which intersymbol interference is suppressed. This improves the frequency offset estimation accuracy. Also, equalization performance is improved by equalizing the signal compensated for the frequency offset by the second equalization circuit.

0.3. Receiver disclosed in Patent Document 2 In addition, the receiver disclosed in Patent Document 2 receives a signal including two types of fixed patterns and uses the received set of fixed patterns to estimate two types of frequency offsets. A value is acquired, and one frequency offset estimated value with high accuracy is selected according to the state of the transmission path. Based on the selected frequency offset estimated value, the frequency offset is compensated and equalized to the compensated signal. Thereby, good communication quality can be realized.

JP 2006-238091 A JP 2002-44176 A

0.4. However, in the receiver disclosed in Patent Document 1 described above, the first equalization circuit performs equalization using a known sequence in the received signal, but the reception quality of the known sequence is poor due to fading. In this case, intersymbol interference cannot be reduced, and the frequency offset estimation accuracy is lowered. Further, since two equalizers are required, the circuit scale (computation amount) increases.

  In the receiver disclosed in Patent Document 2 described above, the determination of the transmission path condition requires estimation of the delay amount of the delayed wave and noise power estimation, so that the circuit scale (computation amount) increases.

0.5. An object of the present invention is to provide a receiving apparatus and a receiving method that improve the frequency offset estimation accuracy even in a fading environment without increasing the circuit scale.

  The receiving apparatus of the present invention performs training in the forward direction using the known symbol arranged at the head of the current frame, and the forward direction is an error between the known symbol trained in the forward direction and the known symbol replica for the forward direction. A forward equalization unit that obtains an equalization error, and a known symbol placed at the head of the next frame, performs training in the reverse direction, and the known symbol trained in the reverse direction and the known symbol replica for the reverse direction Reverse equalization means for obtaining a reverse equalization result as an error, forward frequency offset estimation means for estimating a frequency offset using the known symbol trained in the forward direction, and the trained in the reverse direction A reverse frequency offset estimating means for estimating a frequency offset using a known symbol, the forward equalization error and the previous A selection unit that selects a frequency offset estimation value in an equalization direction with a small equalization error among reverse direction equalization errors, and a compensation unit that compensates the frequency offset of the received signal based on the selected frequency offset estimation value The structure which comprises these is taken.

  The receiving method of the present invention performs forward training using a known symbol arranged at the head of the current frame, and the forward direction is an error between the known symbol trained in the forward direction and the known symbol replica for the forward direction. A forward equalization step for obtaining an equalization error, and training in the reverse direction using the known symbol arranged at the head of the next frame, and the known symbol trained in the reverse direction and the known symbol replica for reverse direction A reverse equalization step for obtaining a reverse equalization result as an error; a forward frequency offset estimation step for estimating a frequency offset using the known symbol trained in the forward direction; and the trained in the reverse direction. A reverse frequency offset estimation step for estimating a frequency offset using a known symbol, and the forward equalization error and the previous A selection step of selecting a frequency offset estimation value in an equalization direction having a small equalization error among the reverse direction equalization errors, and a compensation step of compensating the frequency offset of the received signal based on the selected frequency offset estimation value It was made to comprise.

  According to the present invention, it is possible to improve the frequency offset estimation accuracy even in a fading environment without increasing the circuit scale.

The figure which shows the flame | frame structure which concerns on Embodiment 1 of this invention. The block diagram which shows the structure of the receiver which concerns on Embodiment 1 of this invention. The block diagram which shows the structure of the receiver which concerns on Embodiment 2 of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, in the embodiment, components having the same function are denoted by the same reference numerals, and redundant description is omitted.

(Embodiment 1)
1. Embodiment 1
1.1. Frame Configuration of Embodiment 1 FIG. 1 is a diagram showing a frame configuration according to Embodiment 1 of the present invention. As shown in FIG. 1, a synchronization word (known symbol) is arranged at the head of the frame, and data is arranged following the synchronization word. In such a frame configuration, training is performed from the head to the rear end (forward direction) using the synchronization word of the current frame, and tracking is performed in the forward direction for the data section of the current frame. On the other hand, training is performed from the rear end to the head (in the reverse direction) using the synchronization word of the next frame, and the data section of the current frame is tracked in the reverse direction. Thereby, two equalization results of a forward equalization result and a reverse equalization result can be obtained in the same data section. For this reason, even when the reception state of one synchronization word section is poor and the accuracy of one equalization result is poor, the other equalization result may be good.

1.2. Configuration of Receiving Device in Embodiment 1 FIG. 2 is a block diagram showing a configuration of receiving device 100 according to Embodiment 1 of the present invention. Hereinafter, the configuration of the receiving apparatus 100 will be described with reference to FIG. In FIG. 2, a frequency offset compensation unit 101 receives a received signal and compensates the frequency offset of the received signal using a frequency offset compensation amount output from a delayer 114 described later. Specifically, the frequency offset compensation unit 101 obtains a phase rotation amount per sample based on the frequency offset compensation amount output from the delay device 114, and reversely rotates the phase of the received signal by the obtained phase rotation amount. To compensate. The received signal whose frequency offset is compensated is output to the received signal buffer 102.

  The reception signal buffer 102 temporarily stores the reception signal output from the frequency offset compensation unit 101, and the training unit 104 and the tracking unit 105 of the forward equalization processing unit 103 in the order in which the stored signals are input (forward direction). Output to. The received signal buffer 102 outputs the stored signals to the training unit 107 and the tracking unit 108 of the reverse equalization processing unit 106 in the reverse order (reverse direction) to the input order.

  The forward equalization processing unit 103 includes a training unit 104 and a tracking unit 105, and performs equalization processing (training and tracking) on the reception signal output in the forward direction from the reception signal buffer 102. Specifically, it is as follows.

  The training unit 104 performs training using the synchronization word included in the reception signal output in the forward direction from the reception signal buffer 102 and the synchronization word replica for forward direction prepared in advance, and obtains the tap coefficient. The tap coefficient is output to the tracking unit 105. In addition, the training unit 104 outputs the trained synchronization word to the frequency offset estimation unit 109. Further, the training unit 104 outputs an error (forward equalization error) between the vector of the synchronization word replica and the vector of the synchronization word soft decision obtained during training to the selection unit 111.

  The tracking unit 105 performs tracking processing on the reception signal output from the reception signal buffer 102 using the tap coefficient output from the training unit 104, and outputs a forward equalization result.

  The reverse equalization processing unit 106 includes a training unit 107 and a tracking unit 108, and performs equalization processing (training and tracking) on the reception signal output in the reverse direction from the reception signal buffer 102. Specifically, it is as follows.

  The training unit 107 performs training using the synchronization word included in the reception signal output in the reverse direction from the reception signal buffer 102 and the synchronization word replica for reverse direction prepared in advance to obtain the tap coefficient. The tap coefficient is output to the tracking unit 108. In addition, the training unit 107 outputs the trained synchronization word to the frequency offset estimation unit 110. Further, the training unit 107 outputs an error (reverse equalization error) between the vector of the synchronization word replica and the vector of the synchronization word soft decision obtained during training to the selection unit 111.

  The tracking unit 108 performs tracking processing on the reception signal output from the reception signal buffer 102 using the tap coefficient output from the training unit 107, and outputs a reverse equalization result.

  The frequency offset estimation unit 109 performs a complex correlation operation between the synchronization word (synchronization word soft decision value) output from the training unit 104 and a synchronization word replica for forward direction prepared in advance, and the amount of phase rotation in the synchronization word section (Hereinafter, referred to as “forward frequency offset estimated value”) is obtained, and the obtained forward frequency offset estimated value is output to the selection unit 111.

  The frequency offset estimation unit 110 performs a complex correlation operation between the synchronization word (synchronization word soft decision value) output from the training unit 107 and a synchronization word replica for reverse direction prepared in advance, and the amount of phase rotation in the synchronization word section (Hereinafter, referred to as “reverse frequency offset estimated value”) is obtained, and the obtained reverse frequency offset estimated value is output to the selection unit 111.

  The selection unit 111 at the end of training in the training units 104 and 107 or at any timing during training (arbitrary timing means the (N-1) th symbol of the synchronization word of N symbol length) The forward equalization error output from the training unit 104 and the reverse equalization error output from the training unit 107 are compared, and the frequency offset estimation value in the equalization direction with a small equalization error is used as the frequency offset of the current frame. Select as an estimate. That is, either the forward frequency offset estimated value or the backward frequency offset estimated value is selected. The selected frequency offset estimated value is output to multiplication section 112.

  Multiplier 112 multiplies the frequency offset estimation value output from selector 111 with a forgetting factor and outputs the result to adder 113. The addition unit 113 adds the frequency offset compensation amount of the current frame output from the delay unit 114 to the frequency offset estimation value output from the multiplication unit 112, and outputs the result to the delay unit 114 as the frequency offset compensation amount of the next frame.

1.3. As described above, according to the first embodiment, the frequency offset is estimated by using the trained forward and backward synchronization words, respectively, and the frequency offset in the equalization direction with a small equalization error is estimated. By selecting an estimated value, a synchronization word in which intersymbol interference is suppressed can be used for estimating a frequency offset, and a more reliable frequency offset estimated value is selected from two frequency offset estimated values. Therefore, the frequency offset estimation accuracy can be improved.

(Embodiment 2)
2. Embodiment 2
2.1. Configuration of Receiving Device according to Embodiment 2 FIG. 3 is a block diagram showing a configuration of receiving device 200 according to Embodiment 2 of the present invention. FIG. 3 differs from FIG. 2 in that the selection unit 111 is changed to the selection unit 201.

  The selection unit 201 includes a forward equalization error output from the training unit 104 and a reverse equalization error output from the training unit 107 at the end of training in the training units 104 and 107 or at an arbitrary timing during training. And the threshold value determination between the smaller equalization error and the predetermined first threshold value is performed. If the smaller equalization error is greater than or equal to the first threshold, the estimated frequency offset value of the current frame is set to 0 and output to the multiplier 112. As a result, the frequency offset compensation amount of the current frame stored in the delay unit 114 is maintained as the frequency offset compensation amount of the next frame.

  On the other hand, when the smaller equalization error is less than the first threshold, the selection unit 201 selects the frequency offset estimation value in the equalization direction with the smaller equalization error as the frequency offset estimation value of the current frame. The selected frequency offset estimated value is output to multiplication section 112.

2.2. As described above, according to the second embodiment, the reception level of the synchronization word section due to fading drops, and when the training is not sufficient, the error of the frequency offset estimation value also increases. If the smaller equalization error is greater than or equal to the first threshold, the frequency offset estimation value of the current frame is set to 0, thereby avoiding the use of the frequency offset estimation value with a large error and preventing the equalization performance from being degraded. can do.

  Even if the estimated frequency offset is far from the actual frequency offset, the equalization error may be small depending on the phase conditions of the preceding wave and the delayed wave. In consideration of such a case, the selection unit 201 may set the frequency offset estimation value of the current frame to 0 even when the frequency offset estimation value in the equalization direction with a small equalization error is equal to or greater than a predetermined second threshold value. . As a result, it is possible to avoid using a frequency offset estimation value with a large error and prevent deterioration in equalization performance. However, the second threshold is the absolute value of the frequency offset or the difference between the previous frequency offset estimated value and the current frequency offset estimated value.

  In each of the above embodiments, a case has been described in which the receiving apparatus has two equalization processing units, a forward equalization processing unit and a reverse equalization processing unit. However, the present invention is not limited to this, and one The equalization processing unit may be used in a time division manner.

  The receiving apparatus and receiving method according to the present invention can be applied to, for example, a wireless communication apparatus.

100, 200 Receiver 101 Frequency offset compensation unit 102 Received signal buffer 103 Forward equalization processing unit 104, 107 Training unit 105, 108 Tracking unit 106 Reverse equalization processing unit 109, 110 Frequency offset estimation unit 111, 201 Selection unit 112 multiplier 113 adder 114 delay

Claims (4)

The forward direction is trained in the forward direction using the known symbol arranged at the head of the current frame, and a forward equalization error that is an error between the known symbol trained in the forward direction and the known symbol replica for the forward direction is obtained. Equalization means;
Reverse direction is obtained by training in the reverse direction using the known symbol arranged at the head of the next frame, and obtaining a reverse equalization result which is an error between the known symbol trained in the reverse direction and the known symbol replica for reverse direction Equalization means;
Forward frequency offset estimation means for estimating a frequency offset using the known symbol trained in the forward direction;
Reverse frequency offset estimation means for estimating a frequency offset using the known symbol trained in the reverse direction;
A selection means for selecting a frequency offset estimate value in an equalization direction with a small equalization error among the forward direction equalization error and the reverse direction equalization error;
Compensation means for compensating the frequency offset of the received signal based on the selected frequency offset estimate;
A receiving apparatus comprising:   The selection unit sets a frequency offset estimation value of a current frame to 0 when a smaller equalization error of the forward direction equalization error and the reverse direction equalization error is equal to or greater than a predetermined first threshold value. Item 4. The receiving device according to Item 1.   When the frequency offset estimation value in the equalization direction with a small equalization error among the forward equalization error and the reverse equalization error is equal to or greater than a predetermined second threshold, The receiving apparatus according to claim 1, wherein the estimated value is set to zero. The forward direction is trained in the forward direction using the known symbol arranged at the head of the current frame, and a forward equalization error that is an error between the known symbol trained in the forward direction and the known symbol replica for the forward direction is obtained. An equalization process;
Reverse direction is obtained by training in the reverse direction using the known symbol arranged at the head of the next frame, and obtaining a reverse equalization result which is an error between the known symbol trained in the reverse direction and the known symbol replica for reverse direction An equalization process;
A forward frequency offset estimation step of estimating a frequency offset using the known symbol trained in the forward direction;
A reverse frequency offset estimation step of estimating a frequency offset using the known symbol trained in the reverse direction;
A selection step of selecting a frequency offset estimate value in an equalization direction having a small equalization error among the forward direction equalization error and the reverse direction equalization error;
A compensation step for compensating for the frequency offset of the received signal based on the selected frequency offset estimate;
A receiving method comprising:

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