SU949826A1 - Adaptive phase corrector - Google Patents

Description

(54) ADAPTIVE PHASE CORRECTOR

one

The invention relates to telecommunications and can be used in signal conversion devices (modems) operating at a manipulation speed of up to 1600POD.

An adaptive phase corrector is known, 5 containing n successively connected corrective units, each of which consists of a correction element and a delay unit, the inputs of which are combined, and the outputs are connected to the inputs of the Q, Q switch, and the clock selection unit, the error analyzer, the inputs which are combined and connected to the output of the last correction link, and the output of the clock extraction unit is connected to the second input of the error analyzer and the distributor whose outputs are connected to the control Switch inputs I.

However, the known device has the following drawbacks: the strong dependence of the correction accuracy, as well as the dependence of the stability of the tuning process on the type of frequency response of the corrective links.

The purpose of the invention is to improve the accuracy of the correction.

To achieve this goal, an adaptive phase corrector containing n series-connected correction links, each of which consists of a correction element and a delay unit, the inputs of which are combined, and the outputs are connected to the inputs of the switch, as well as the clock selection unit, the error analyzer, whose inputs combined and connected to the output of the last correction link, and the output of the clock extraction unit is connected to the second input of the error analyzer, and the distributor, the outputs of which are connected to the controlled inputs of the switches; two phase shifters, two multipliers, an adder and a frequency-dependent equalizer are introduced, the inputs of the first phase shifter and the frequency-dependent corrector are combined and connected to the input of the last corrective element, the output of the frequency-dependent corrector is connected through the second phase shifter, the first multiplier and the adder is connected to the input of the distributor, the outputs

the error analyzer is connected to the inputs of the first and second multipliers, the output of the first phase shifter is connected to the third input of the error analyzer, and the output of the frequency-dependent equalizer is connected to another input of the second multiplier, the output of which is connected to another input of the adder.

The drawing shows a structural diagram of the adaptive phase corrector.

The adaptive phase corrector contains serially connected correction elements 1 and switches 2, delay blocks 3 are connected in parallel to correction elements, parallel to the output of the last switch are included block 4 of clock selection, the second input of the error analyzer 5, the first phase shifter 6, the frequency-dependent equalizer 7, and the output the first phase shifter 6 is connected to the third input of the analyzing device, and the output of the clock extraction unit 4 is connected to the second input of the error analyzer 5. The output of the frequency-dependent equalizer 7 is connected to the input of the second multiplier 8 and to the input of the first multiplier 8 via the second phase shifter 9, the other inputs of the multipliers are connected to the corresponding outputs of the analyzer 5 errors. The outputs of the multipliers are connected to the corresponding inputs of the adder 10, the output of which is connected to the input of the distributor 11 whose outputs are connected to the corresponding inputs of the switches 2.

Adaptive phase corrector works as follows.

From the output of the last corrective link, the signal goes to one of the analyzer's inputs 5 errors, to the other input of which the same signal arrives, passing through the first phase shifter 6. Thus, the input and quadrature components of the signal go to the inputs of the error analyzer 5. In the analyzer 5 error, under the action of the control signal from the clock extraction unit 4, the output signal of the corrector is generated, as well as the in-phase and quadrature error signal components, which are fed to the first multiplier 8. To the input of the second multiplier. 8 simultaneously receives the in-phase component of the received signal, which is transmitted through a frequency-dependent equalizer 7, i.e., a signal proportional to the derivative of the quadrature error.

Thus, at the output of the second multiplier 8, the quadrature component of the gradient is formed. At the same time, the output of the first multiplier 8 forms an in-phase component of the gradient.

representing the multiplication of the common-mode component of the error and the signal proportional to the derivative of the common-mode error component. The in-phase derivative is formed from the signal passing through the frequency dependent equalizer 7 (i.e. from the signal proportional to the derivative of the quadrature error component) by means of the second phase shifter 9. The output signals of the multipliers are summed, and the output of the adder 10 shows a signal proportional to gradient. On this signal, in accordance with the algorithm of the adaptive phase corrector, the necessary switching of the corrective links is carried out.

The proposed adaptive phase corrector provides improved correction accuracy.

Claims (1)

Invention Formula An adaptive phase corrector containing n serially connected corrective units, each of which consists of a corrective element and a delay unit, the inputs of which are combined, and the outputs are connected to the inputs of the switch, as well as a clock extraction unit, an error analyzer, the inputs of which are combined and connected to the output the last corrective element, and the output of the clock extraction unit is connected to the second input of the analyzer error, and the distributor, whose outputs are connected to the controllable inputs switches, characterized in that, in order to improve the accuracy of the correction, two phase shifters, two multipliers, an adder and a frequency-dependent equalizer are entered into it, the inputs of the first phase shifter and the frequency-dependent equalizer are combined and connected to the input of the last correction link, the output frequency dependent corrector through serially connected second phase shifter, the first multiplier and the adder are connected to the distributor input, the outputs of the error analyzer are connected to the inputs of the first and second transducer multipliers, the output of the first phase shifter is connected to the third input of the error analyzer and the output frequency-dependent equalizer is connected to another input of the second multiplier, whose output is connected to another input of the adder. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 319092, cl. H 04 B 3/04, 1969 (prototype).