JPH0629784A - Transversal automatic equalizer - Google Patents

Abstract

PURPOSE:To improve the convergence without degrading the equalizing characteristic. CONSTITUTION:An A-D conversion part 1 converts a base band signal Sb demodulated by a demodulator (omitted in the figure) to a digital signal Sd. A transversal filter 2 eliminates distortion of the digital signal Sd to send an output signal So. A step out detecting part 4 receives a carrier reproducing control signal Sc from the demodulator to detect the synchronous state of the demodulator and sends a synchronous state signal Ss. Integrating circuits 36 to 38 of a tap coefficient control part 3 are so constituted that their time constants are varied in accordance with a time constant setting signal St from a time constant control circuit 39, and correlation values C1 to C3 are averaged with respect to time to generate tap coefficients E1 to K3, and they are sent to the transversal filter 2. The time constant control circuit 39 generates the time constant setting signal St based on the synchronous state signal Ss.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transversal type automatic equalizer, and more particularly to a transversal type automatic equalizer for compensating for distortion of a multilevel baseband signal demodulated by a demodulator.

[0002]

2. Description of the Related Art In recent years, multi-level quadrature modulation has been adopted in digital wireless communication in order to increase the frequency utilization efficiency. However, a signal subjected to multi-level quadrature modulation is susceptible to waveform distortion due to fading or the like and interference between cross-polarized waves and other channels, and an automatic equalizer has been developed to remove such distortion. As one of the automatic equalizers, a transversal type automatic equalizer that adaptively controls tap coefficients of a transversal filter has been put into practical use.

FIG. 2 is a block diagram showing an example of a conventional transversal type automatic equalizer. Although the case of a one-dimensional baseband signal is shown as an input signal, by combining such an automatic equalizer, it is possible to deal with a multilevel baseband signal having in-phase and quadrature two-dimensional components.

Here, the transversal type automatic equalizer includes an A / D converter 1 for converting the baseband signal Sb demodulated by a demodulator (not shown) into a digital signal Sd, a transversal filter 2 and the like. , A tap coefficient control unit 5 for controlling the tap coefficient of the transversal filter
And have.

The transversal filter 2 is composed of delay circuits 21 and 22, multiplication circuits 23, 24 and 25, and an addition circuit 26. Multiplier circuits 23 to 25
Is the tap coefficient K for the tap output signals S1, S2, S3.
1, K2 and K3 are respectively multiplied, and the adder circuit 26 removes the distortion by adding the outputs of the multiplier circuits and sends it as the output signal So.

The tap coefficient controller 5 includes delay circuits 51, 5
2, multiplication circuits 53, 54 and 55, and integration circuits 56 and 5
It is composed of 7, 58. Multiplier circuits 53 to 55
Are correlation values C1, C2, C3 from the error component included in the output signal So and the determination component included in the digital signal Sd.
Are calculated respectively. The integrating circuits 56 to 58 have a correlation value C
1 to C3 are time-averaged to obtain tap coefficients K1 to K3
As the multiplication circuits 23 to 2 of the transversal filter 2
5 respectively.

[0007]

In the above-described conventional transversal type automatic equalizer, the tap value is generated by averaging the correlation values by the integrating circuit. However, since the time constant of the integrator circuit is fixed, when waveform distortion occurs due to large fading, it takes time from the out-of-sync state to the sync-pull-in state, and there is the problem of poor convergence. There is.

An object of the present invention is to provide a transversal type automatic equalizer capable of improving the convergence without deteriorating the equalization characteristic.

[0009]

A transversal type automatic equalizer according to the present invention is a transversal type automatic equalizer for compensating for distortion of a multilevel baseband signal demodulated by a demodulator. A transversal filter that has taps and automatically equalizes the multilevel baseband signal according to tap coefficients, and generates a correlation value for each of the plurality of taps based on an output signal and an input signal of the transversal filter. Means, a plurality of integrating circuits for respectively integrating the correlation values according to a time constant set by a time constant setting signal and sending out the tap coefficients as a tap coefficient, and determining whether the tap coefficient is at an optimum value or near the optimum value. And a time constant setting means for detecting and generating the time constant setting signal. Further, the time constant setting means,
An out-of-sync detection circuit that detects the synchronization state of the demodulator and sends out a signal indicating the synchronization state, and a signal indicating the synchronization state, and when in synchronization, the time constant of the integration circuit is set to a large value. And a time constant control circuit for generating the time constant setting signal so as to set the time constant of the integrating circuit to a small value when out of synchronization.

[0010]

The present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing an embodiment of the present invention. The same components as those of the conventional transversal type automatic equalizer shown in FIG. 2 are designated by the same reference numerals, and are the same as those of the conventional example except for the tap coefficient control unit 3 and the out-of-sync detection unit 4. The description is omitted.

Here, the baseband signal Sb demodulated by a demodulator (not shown) is converted into a digital signal Sd by the AD converter 1. Digital signal S
Distortion of d is removed by the transversal filter 2 and is sent as the output signal So.

The carrier recovery control signal Sc is input to the out-of-synchronization detection section 4. This carrier wave reproduction control signal S
c is a signal generated when a carrier wave is reproduced in a carrier wave reproduction circuit (not shown) of the demodulator. The out-of-sync detector 4 receives the carrier wave reproduction control signal Sc, detects the synchronization state between the received signal in the demodulator and the reproduced carrier wave, and outputs the synchronization state signal Ss indicating the synchronization state. For such an out-of-sync detection circuit, for example,
It is described in JP-A-48-17661.

The tap coefficient control unit 3 includes delay circuits 31, 3
2, multiplication circuits 33, 34 and 35, and integration circuits 36 and 3
7, 38 and a time constant control circuit 39. The multiplying circuits 33 to 35 respectively calculate the correlation values C1, C2, C3 from the error component included in the output signal So and the determination component included in the digital signal Sd. The integrating circuits 36 to 38 are configured so that the time constant can be varied according to the time constant setting signal St sent from the time constant control circuit 39, and the correlation values C1 to C3 are time-averaged with the set time constant. Then, the tap coefficients K1 to K3 are sent to the multiplication circuits 23 to 25 of the transversal filter 2, respectively.

The time constant control circuit 39 controls the synchronization state signal Ss.
The time constant setting signal St is generated based on
8 is sent. By the way, the state where the tap coefficient of the transversal filter is at or near the optimum value is called the convergent state, and the other states are called the divergent state. Generally, the time constant of the integrating circuit is Is smaller, and it is better to set larger in the converged state.

Therefore, the time constant control circuit 39 determines that the synchronization state signal Ss is in the converged state when the synchronization state signal Ss indicates the synchronization, and the divergence state when the synchronization state signal Ss indicates the synchronization state, and the predetermined time constant. The time constant setting signal St is generated so as to be set respectively, that is, small in the divergent state and large in the convergent state.

To change the time constant in this manner, for example, a 20-stage reversible counter may be used as the integrating circuits 36 to 38, and the number of stages of the reversible counter may be switched according to the time constant setting signal St. . That is, in the convergent state, the reversible counter is set to 20 stages to increase the time constant,
In the divergent state, the reversible counter may be switched to, for example, 10 stages to reduce the time constant.

By doing so, when a very large fading occurs or when the system is started up, there is a divergence state, the time constant of the integrating circuit is set small, and the tap coefficient quickly approaches the optimum value. The convergence can be improved.

The same applies to the case where the input signal is a multi-valued baseband signal of one or more dimensions or the number of taps of the transversal filter is 3 or more.

[0020]

As described above, according to the present invention, an integrator circuit having a variable time constant is provided, and the time constant of the integrator circuit is controlled to generate the tap coefficient of the transversal filter. By detecting whether the tap coefficient is in the optimal value or in the convergent state near the optimal value or in the divergent state, the time constant is increased in the convergent state, and the time constant is decreased in the divergent state. , The convergence can be improved without degrading the equalization characteristic.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention.

FIG. 2 is a block diagram showing an example of a conventional transversal type automatic equalizer.

[Explanation of symbols]

 1 AD conversion unit 2 Transversal filter 3 Tap coefficient control unit 4 Out-of-sync detection unit 21, 22, 31, 32 Delay circuit 23-25, 33-35 Multiplication circuit 26-28, 36-38 Integration circuit 39 Time constant Control circuit C1 to C3 Correlation value K1 to K3 Tap coefficient Sb Baseband signal Sc Carrier wave reproduction control signal Sd Digital signal So output signal Ss Synchronization state signal St Time constant setting signal

Claims (2)

[Claims] 1. A transversal type automatic equalizer for compensating for distortion of a multi-valued baseband signal demodulated by a demodulator, the multi-valued baseband signal having a plurality of taps, the multi-valued baseband signal being obtained according to a tap coefficient. A transversal filter for automatic equalization, a means for generating a correlation value for each of the plurality of taps based on an output signal and an input signal of the transversal filter, and the correlation according to a time constant set by a time constant setting signal. A plurality of integrating circuits for respectively integrating values and sending them as the tap coefficient, and a time constant setting means for detecting whether the tap coefficient is at an optimum value or in the vicinity of the optimum value and generating the time constant setting signal. A transversal-type automatic equalizer, characterized by comprising: 2. The time constant setting means detects an out-of-sync state of the demodulator and sends out a signal indicating the in-sync state, and an out-of-sync detection circuit that receives the signal indicating the in-sync state and is in a synchronized state. And a time constant control circuit that generates the time constant setting signal so that the time constant of the integration circuit is set to a large value and the time constant of the integration circuit is set to a small value when the synchronization is out of sync. The transversal type automatic equalizer according to claim 1, wherein