SU736372A1 - Digital-analogue converter of differential pulse-code modulation signal - Google Patents

Description

In order to reduce the distortion in case of abrupt changes in the DPCM transmitted in the known system, the number of quantization levels increases, which, in turn, leads to an increase in the transmission code bit and the need to use communication channels with higher bandwidth. The aim of the invention is to reduce the quantization error of the transmitted signal skews without increasing the DPCM code size. The goal is achieved by the fact that in a digital-to-analog converter a differential pulse-to-ninth modulation signal converter, containing an analog adder and a differential pulse code-code modulator code, an amplitude-to-pulse modulation signal, all of which are outputs except you. the smallest quantization steps are connected to the corresponding inputs of the analog adder, the shaper of the weighing functions and the analog signal multiplier unit are introduced, and the output of the converter is a pulse-modulated differential pulse code — an amplitude-pulse modulation signal corresponding to The smallest quantization steps are connected to one of the inputs of the analog signal multiplication block, the other input of which is connected to the output of the weighting function generator, the inputs of which are with the rest of the converter outputs; differential pulse code-modulation code; pulse-amplitude modulation signal; and the output of the analog signal multiplier block is connected to the analog cyMiv-curtain input. In FIG. 1 shows a block diagram of the device on; FIG. 2 is a chart showing his work. The device contains the conversion of the differential pulse code-modulation code (DPCM) into the AMS pulse modulated (AIM) signal, all outputs except the younger one, connected to the corresponding inputs of the analog adder 2 and the imaging unit 3 of the weighing functions and the analog multiplication unit 4 signals, the first input is connected to the lower output of converter 1, the second input to the output of shaper 3 and the output to the lower input of adder 2. The converter operates as follows. In the absence of differences in the original video signal, the code combinations corresponding to the positive or negative least quantization step are received at the input of the converter 1 of the DICM code of the PIM signal. A output B of converter 1 generates pulses that are fed through block 4 to the adder 2, and a constant voltage V, is supplied to the other input of block 4, since the outputs B, B,. . ,, In W / 2 converter 1, the signals are not present at this moment, the process of forming a copy of the signal in this case is carried out in the same way as in the prototype. When a drop is detected in the source signal, input of the converter 1 is followed by code combinations corresponding to positive or negative large quantization step, and at its outputs BI, BZ,. .. , BN / 2, pulses with amplitude l / j appear, which are simultaneously applied to adder 2 and ({terminal 3) At the output of the latter, a voltage jump appears, the amplitude of which is determined by the value of the incoming AIDA signal. KTg time interval in accordance with the VII with a given function, for example, exponential L cm, Fig. 2) for flashing constant voltage EUT. The output signal of the imaging unit 3 is fed to black 4, to the second input of which from В | the transducer 1 is supplied with impulses equal to the smallest quantization step 1 (Y). As a result of multiplication, the smallest pitch tamely increases in steps and decreases to the initial value of ± 8 during the time interval 1I kTo. Thus, the small-sized quantization step + S turns out to be variable, depending on the nominal value of the large steps used at previous times. Ego pozvag; It is not necessary to reduce the time during which the signal copy is different from the input signal. The advantages of the proposed device in comparison with the prototype are the reduction of the error in quantizing the differences of the transmitted signal without increasing the code width of the DPCM of the research institute for reducing the code width of the jUlKAi code.

with the same error quantization of differences, which leads to a decrease in the cost of equipment for the compression of communication channels or to a decrease in the cost of communication lines.

Claims (2)

Invention Formula The digital-to-analog converter of the differential pulse-code modulation signal containing the analog adder and the converter differential pulse-code modulation code — a signal of amplitude-pulse modulation, all of which, except for the output corresponding to the smallest quanti- fication steps, are connected to the corresponding analog inputs adder, characterized in that, in order to reduce the error in quantizing the differences of the transmitted signal without increasing the code width of the differential pulse code howl modulation, it soaerZh P shaper weighting function multiplying unit and analog signals, the output of the code converter differ- of the potential impulse-code modulus f .imi - the signal of amplitude-impulse modulation corresponding to the smallest quantization steps is connected to one of the inputs of the analog signal multiplying unit, the other input of which is connected to the output of the formavaged weighting functions, the inputs of which are connected to the remaining outputs of the converter code differential pulse code modulation is an amplitude-pulse modulation signal, and the output of the analog signal multiplying block is connected to the input of an analog adder. Sources of information taken into account in the examination 1.1.O. Jimb, C.B.Ru 3wsbeAn, Ken H.v / a & sU.TiiyitaE, Codings oiCoEor Picturephone (t) M E & Dt erentiat Quohtixqt-ion, tttt Trans, ott CommuMcafcion Tectmoto,, 6 2. tl.Iieeeeddm. Javery cord nor s-ss evn or the dig-itaC Trarv mission o4T.N Phone SYnaCs ATR ,, N.5, ... 3.1. B- Nxietarot, fA.I.Nvannsete, Dwitae tnoordAng o -tVie siprtiaCbSTQ 19H, i.50, I ° 2 (prototype). ML Stixo Voltage on field former J g -5 & - -Ж