CS259841B1 - Connection of distributing for transmission equipment's receiver - Google Patents

Abstract

The wiring relates to transmission distribution circuits pulse code modulation device - PCM. The incoming signal is, after amplification, amplifier to analog multiplexer input. Overcharging extension time and ensuring a defined current limit allows you to increase the memory value capacitor. Frequency correction is provided pass band attenuation channel filter. The wiring is suitable for all transmission first order PCM systems with group kodekem.

Description

The invention relates to the distribution circuitry of a receiver of a pulse code modulation (PCM) transmission device.

In the PCM receiver, the instantaneous value of the input analog signals is restored from the received digital signal, which is fed to the individual channel units where the original low frequency signal is reconstructed by the synchronously operating receiver switches. The distribution circuitry is the part of the receiver that includes the output of the common * decoder, the common distribution amplifier, the individual channel switches and the channel units containing the channel filters and the output circuits.

It is known to extend the signal recovery, where memory capacitors and individual frequency-dependent low-frequency amplifiers are connected to the channel switches, correcting the sin x x transfer function.

The disadvantage of this circuit is that there must be a separate correction amplifier in each channel. This results in greater complexity of the device, deterioration of the long-term stability of the output level, deterioration of the frequency response and hence reliability of the device. Another known circuit uses a common power distribution amplifier for all channels. The channel filters are pulse-charged via the power switches to the desired low-frequency output signal. The disadvantage is that the switches have to transmit large output voltages and currents that adversely affect the values of intelligible crosstalk to adjacent channels and the noises of cooperating systems. In the function of a channel switch, either known transistor-controlled diode bridges or symmetrical pairs of transistors are used in known circuits, but require a isolation transformer to galvanically separate the control pulses from the time base.

The purpose of the invention is to overcome these disadvantages. The principle of the invention is that the output of the distribution amplifier is connected to the analog input of the n-multiplex multiplexer, whose control inputs are connected to the output of the time base.

The analog outputs of the multiplexer are connected to the corresponding inputs of the same channel blocks. The input of each channel block always consists of a non-inverting input of the operational amplifier and a memory capacitor, the other end of which is grounded. The output of the operational amplifier is connected to the inverting input of this amplifier and through a series resistor to the input of the channel filter, the output of which is connected to the output circuits.

The wiring of the distribution circuits according to the invention is simpler than the hitherto known wiring. It has lower power consumption. The isolation transformers are eliminated, the susceptibility to mutual interference is reduced, the switch does not introduce a DC component. The amplifiers are frequency independent, the number of passive components is minimized.

An example of the invention is further described by means of a drawing. The output of the decoder 1 is connected to the input of the distribution amplifier 2. The output of the distribution amplifier 2 is connected to the analog input of an eight-fold analog multiplexer 3, whose control inputs are connected to the outputs of the time base 4. 18. The input of channel block 11 to 18 is connected to the non-inverting input of the operational amplifier 5 and simultaneously via the memory capacitor C to the ground terminal. The inverting input of the operational amplifier 5 is connected to its output, which is also connected via a resistor R to the input of the channel filter 8, the output of which is connected to the output circuits 7.

The output signal from the decoder 1 is amplified by the distribution amplifier 2 and fed to the analog input of the eight-fold multiplexer 3. The multiplexer 3 is controlled by logic signals from the time base 4. A decoder 1 for a group of eight channels is used instead of the central codec. * nx 4) -th, (n + 8) -th etc. channel. This increases the time for one channel interval four times. Further, more energy-efficient current charging of the memory capacitor C is used instead of exponential charging. That is, a distribution amplifier 2 with an optional output current limitation is used, the value of which must not exceed the permissible current of the multiplexer 3. Extending the overcharging time and providing a defined current limit allows increasing the value of the memory capacitor C thereby ensuring a satisfactory level of understandable crosstalk between channels. The transfer function sin x x is defined by the current charge of the memory capacitor C. The desired frequency correction can be ensured by the attenuation of the passband of the channel filter 6, which is perfectly impedance matched by the resistor R. From the output of the channel filter 6 the signal is routed to the output circuits 7.

The connection is suitable for all first order PCM transmission systems with group codec. The channel blocks can be arranged in parallel and controlled from the control bus in the construction of a 30-channel system. By connecting suitable multiplexer outputs to a single channel block input, it is possible to increase the sampling rate as required by the radio modulation transmission.

Claims (1)

SUBJECT Connection of the distribution circuits of a receiver of a pulse code modulation (PCM) transmission device with a common decoder and a distribution amplifier, characterized in that the output of the distribution amplifier (2) is connected to an analog input n multiplier or multiplexer (3) whose control inputs are connected a time base (4), wherein the analog outputs of the multiplexer (3) are connected n> and corresponding inputs of the same channel blocks (11 to 18), where OF THE INVENTION each channel block (11-18) consists of a non-inverting input of the opamp (5) and a memory capacitor (C), the other end of which is grounded, while the output of the opamp (5) is connected to the inverting input of the opamp. ) and on the other hand through a series resistor (R) with the input of the channel filter (6), the output of which is connected to the output circuits (7).