JPS6348022A - Automatic amplitude equalizer - Google Patents

Abstract

PURPOSE:To equalize the amplitude distortion of a primary component caused by a radio transmission line by using a variable attenuator so as to control either output of a positive slope primary amplitude equalizer and a negative slope primary amplitude equalizer and applying vector combination to both outputs. CONSTITUTION:Either output signal level of positive/negative slope primary amplitude equalizers 5, 6 is adjusted by a variable attenuator 7, the result is combined with the other output signal and the combined output signal is amplified to be a prescribed level by an automatic gain amplifier 2, the primary amplitude equalization residual is detected by a detection circuit 3, a control circuit 4 adjusts the attenuation of the variable attenuator 7 to control it so as to minimize the primary amplitude equalization residual. Even if an interference wave is larger than a direct wave, the primary component of the frequency amplitude characteristic is equalized without deteriorating the frequency group delay characteristic.

Description

[Detailed Description of the Invention] [Summary] Detecting frequency amplitude characteristics due to selective fading,
The output signal level of either the positive slope-order amplitude equalizer or the negative slope-order amplitude equalizer is controlled by a variable attenuator, and then vector synthesis is performed to equalize the amplitude distortion of the first-order component caused by the wireless transmission path. It is something that becomes.

[Industrial application field]

The present invention relates to an automatic amplitude equalizer that automatically equalizes negative-order component amplitude distortion of amplitude distortion due to selective fading occurring in a wireless transmission path.

In a digital radio transmission path in a microwave band or the like, selective fading results in uneven frequency and amplitude characteristics within the transmission band, which can be a factor that significantly degrades transmission quality depending on the modulation/demodulation method. Especially multilevel QAM
This has a great influence on the modulation method. Therefore, it is necessary to compensate for frequency amplitude characteristics due to selective fading.

[Conventional technology]

A variable resonant automatic equalizer is known as a frequency domain automatic equalizer that obtains and equalizes a frequency amplitude characteristic opposite to the frequency amplitude characteristic of fading based on a two-wave model of a direct wave and an interference wave. This variable resonant automatic equalizer detects, for example, the dip frequency of the frequency amplitude characteristic of the input signal due to selective fading using a sweep means, and also detects the dip frequency of the frequency amplitude characteristic of the input signal due to selective fading, and also detects the dip frequency at three points, approximately the center of the spectrum of the equalized output signal and on both sides thereof. Frequency components are extracted by a narrow band filter, detected by a wave detector to detect an equalization residual, and controlled so that the detected dip frequency matches the resonant frequency of the variable resonator, and the equalization residual is This is to control the sharpness Q of the variable resonator so as to minimize it.

Also, a transversal type automatic equalizer is known as an automatic equalizer in the time domain. For example, an input signal delayed by 1 bit from each tap of a tapped delay circuit is multiplied by a tap coefficient, The tap coefficients are changed based on an error signal indicating the difference between the added output signal and a predetermined level at the level discrimination point, and the control is performed so that the error signal becomes negative. Thereby, code amount interference can be suppressed.

[Problem that the invention seeks to solve]

The conventional variable resonant automatic equalizer described above controls the resonant circuit so that the frequency amplitude characteristic due to fading is opposite to that of the direct wave. If it is small, the frequency amplitude characteristics and frequency group delay characteristics can be equalized. However, on the other hand, if the interference wave with a time delay is larger than the direct wave, even if the frequency amplitude characteristics are equalized,
When the direct wave is larger than the interference wave, when the direct wave is smaller than the interference wave, the frequency group delay characteristics are reversed, so the delay characteristics due to the resonant circuit are added, further degrading the delay characteristics. do.

In digital wireless transmission channels, the probability of occurrence when the interference wave is smaller than the direct wave, as in the former case, and the probability of occurrence when the interference wave is larger than the direct wave, as in the latter case, are often almost the same. Therefore, in the conventional variable resonance type automatic equalization, the latter type of fading cannot be compensated for, and therefore, the effect of improving the error rate in the digital radio transmission path is reduced.

In addition, the transversal automatic equalizer can compensate for selective fading, where the interference wave is larger than the direct wave, but since the demodulator is vulnerable to the first-order frequency and amplitude characteristics, it is difficult to use the equalization ability sufficiently. There are drawbacks to not being able to perform.

Further, the variable resonance type automatic equalizer and the transversal type automatic equalizer have a drawback that the detection system and control system are jMJll.

An object of the present invention is to equalize the primary component of the frequency amplitude characteristic using a simple control system without deteriorating the frequency group delay characteristic.

[Means for solving problems]

The automatic amplitude equalizer of the present invention equalizes the first-order component of amplitude distortion using a positive slope-order amplitude equalizer and a negative slope-order amplitude equalizer, see FIG. and explain. An automatic gain control amplifier 2 that makes the level of the output signal of the variable amplitude equalization circuit 1 constant, and a narrow band filter, a wave detector, etc., for detecting the primary amplitude equalization residual of the frequency and amplitude characteristics of the output signal of the automatic gain control amplifier 2. The variable amplitude equalization circuit 1 includes a detection circuit 3 that performs detection using the positive slope-order amplitude, and a control circuit 4 that controls the variable amplitude equalization circuit 1 based on the detection output signal of the detection circuit 3. It has a variable attenuator 7 that adjusts the output signal level of either the equalizer 5 or the negative slope-order amplitude equalizer 6,
This variable attenuator 7 is controlled by the control J111 circuit 4, and the synthesized circuit 8 synthesizes and outputs the result.

[Effect]

The automatic gain control amplifier 2 amplifies the signal to a constant level and outputs it, the detection circuit 13 detects the primary amplitude equalization residual in the output signal, and the control circuit 4 adjusts the amplitude to a variable amplitude based on the detected output signal. In the variable amplitude equalization circuit 1, the output signal level of the positive slope and negative slope amplitude equalizers 5 and 6 is adjusted to perform vector synthesis. Therefore, if the two output signals have contradictory frequency and amplitude characteristics, vector synthesis will result in a flat frequency and amplitude characteristic, and if the amount of attenuation by the variable attenuator 7 is increased, the frequency and amplitude characteristics of the other output signal will be synthesized. This is a characteristic of the output signal. Therefore, by controlling the variable attenuator 7 so that the -order amplitude residual is minimized, the first-order component of the frequency amplitude characteristic due to fading can be equalized without deteriorating the group delay characteristic. Furthermore, the control system has a simple configuration because it controls one variable attenuator 7 by detecting the primary component.

〔Example〕

Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 2 is a block diagram of an embodiment of the present invention, in which 11 is a variable amplitude equalization circuit, 12 is an automatic gain control amplifier, 13 is a detection circuit, 14 is a control circuit, 15°20 is a hybrid circuit, and 16 is a positive control circuit. 17 is a negative slope-order amplitude equalizer; 18 is a fixed attenuator; 19 is a variable attenuator; 21
．． 22 is a narrowband filter, and 23 and 24 are detectors.

A received signal received via a digital wireless transmission path is, for example, frequency-converted to become an intermediate frequency signal, which is input to the variable amplitude equalization circuit 11 . This variable amplitude equalization circuit 11
In this case, the input signal is divided into two by the hybrid circuit 15.
It is branched and applied to the positive slope-order amplitude equalizer 16 and the negative slope-order amplitude equalizer 17, and the positive slope-order amplitude equalizer 16
The output signal of the negative slope-order amplitude equalizer 17 is applied to a fixed attenuator 18, and the output signal of the negative slope-order amplitude equalizer 17 is applied to a variable attenuator 19.
The output signals of the fixed attenuator 18 and the variable attenuator 19 are applied to a hybrid circuit 20 and vector-combined. In this case, by controlling the variable attenuator 19 by the control circuit 14, it is possible to obtain a desired positive and negative first-order slope characteristic as the composite output characteristic, so that it is possible to compensate for the first-order component of the frequency amplitude characteristic of the input signal. .

The output signal of the variable amplitude equalization circuit 11 is amplified by an automatic gain control amplifier 12 to a constant output signal level. A detection circuit 13 detects the negative amplitude equalization residual from the output signal of the automatic gain control amplifier 12 . In this detection circuit 13, different frequency components are extracted by bandpass filters 21 and 22, detected by detectors 23 and 24, and applied to the control circuit 14.

The control circuit 14 compares the detection output signal levels from the detectors 23 and 24 and controls the variable attenuator 19 in accordance with the negative amplitude equalization residual. When the signal levels are equal, the attenuation amount of the variable attenuator 19 is controlled to be the same as the attenuation amount of the fixed attenuator in one day,
Positive slope-order amplitude equalizer 16 and negative slope-order amplitude equalizer 17
The frequency amplitude characteristic becomes flat by vector synthesis of the characteristics.

In addition, if the higher frequency detection output signal level is higher than the lower frequency detection output signal level, the -order amplitude equalization residual has a positive slope -order amplitude characteristic, so the variable attenuator 1
The variable amplitude equalization circuit 11 can control the attenuation amount of 9 to be small, so that the variable amplitude equalization circuit 11 has a frequency amplitude characteristic with a negative slope, thereby equalizing the frequency amplitude characteristic due to fading.

The above embodiment shows a configuration in which the output signal of the negative slope-order amplitude equalizer 17 is applied to the variable attenuator 19, but the output signal of the positive slope-order amplitude equalizer 16 is applied to the variable attenuator 19. In addition, the output signal of the negative slope-order amplitude equalizer 17 may be added to the fixed attenuator 18. Also, positive slope and negative slope primary amplitude equalizers 16. , 17 can employ a well-known structure composed of a resistor, a capacitor, and the like.

〔Effect of the invention〕

As explained above, the present invention adjusts the output signal level of either one of the positive slope and negative slope primary amplitude equalizers 5 and 6 by the variable attenuator 7, and combines it with the output signal of the other, The combined output signal is amplified to a constant level by an automatic gain amplifier 2, and the -order amplitude equalization residual is detected by a detection circuit 3.
Detected and controlled? '[variable attenuator 7 by t1 circuit 4
This method controls the attenuation amount of It has the advantage of being able to equalize the primary components of.

Furthermore, since the detection circuit 3 detects the primary amplitude equalization residual, it is simpler than the configuration that detects the secondary equalization residual in a variable resonant automatic equalizer, and the control circuit is 4 is
Since only one variable attenuator 7 is controlled, there is an advantage of a simple configuration.

[Brief explanation of drawings]

FIG. 1 is a block diagram of the principle of the present invention, and FIG. 2 is a block diagram of an embodiment of the present invention. 1.11 is a variable amplitude equalization circuit, 2 and 12 are automatic gain control amplifiers, 3.13 is a detection circuit, 4.14 is a control circuit, 5
, 16 is a positive slope-order amplitude equalizer, 6.17 is a negative slope-order amplitude equalizer, 7 and 19 are variable attenuators, 8 is a synthesis circuit, 1
5.20 is a vibe lift circuit, 18 is a fixed attenuator, 21
．． 22 is a narrowband filter, and 23 and 24 are detectors.

Claims (1)

[Claims] A variable amplitude equalization circuit (1), an automatic gain control amplifier (2) that stabilizes the level of the output signal of the variable amplitude equalization circuit (1), and the automatic gain control amplifier (2). ); and a control circuit (4) that controls the variable amplitude equalization circuit (1) based on the detection output signal of the detection circuit (3). The variable amplitude equalization circuit (1) includes a variable attenuator (1) that adjusts the output signal level of either the positive slope primary amplitude equalizer (5) or the negative slope primary amplitude equalizer (6). 7), and the automatic amplitude equalizer is characterized in that the variable attenuator (7) is controlled by the control circuit (4).