SU338898A1 - ADAPTIVE DEVICE FOR TRANSFERING MESSAGES - Google Patents

Description

The proposed device relates to the field of automation and telemechanics and can be used in the configuration of adaptive multichannel telemetry systems. Apparatus for transmitting messages of an adaptive multi-channel system are known, comprising a switch, an analog-to-digital converter, a redundancy reducer, an address block, a synchronizer, and logic circuits for adaddit. A disadvantage of the known devices is the uneven loading of the communication channel; due to the elimination of excess counts. The proposed device is characterized in that in it the first synchronizer output is connected to the parallel-connected inputs of the delay line and two switches, the first outputs of each of which are connected to the inputs of the address blocks, and the second outputs - to the inputs of analog-to-digital converters, the outputs of both address blocks and analog-to-digital the transducers are connected to the inputs of the sum signal unit; the second input of the first analog-digital converter is connected to the first branch of the delay line, and the second output is connected to the first input of the redundancy device, the second input of which is connected to the second branch of the specified delay line, and the output of the redundancy device is connected to parallel the inputs of the control and monitoring unit, the second input of which is connected with the second output of the synchronizer, the address block and analog-digital converter of the first group of parameters, as well as the first input of the "NO, second stroke which is connected to the output of the delay line, and an output connected in parallel to the second inputs of the address block and an analog-digital converter of the second group of parameters. Another difference of the proposed device is that in the monitoring and control unit, the input of the valve is connected to the output of the redundancy reduction device, the trigger input is connected to the synchronizer output, and the two outputs of the trigger are connected, respectively, through the valve and the differentiating circuit to the counter inputs, the outputs of which are connected to the inputs of the matrix, part of the located branches of which are connected to the first OR circuit, the other part located on one side of the indicated branches, is connected to the second OR circuit, t The part located on the other side of the first taps is connected to the third circuit to the fourth and subsequent OR taps with two taps, which are located at the same distance from the first group of taps of the matrix; the last outputs of the OR circuit are connected to the OR circuit, the output of which is connected in parallel to the inputs of two AND circuits, the second input of which is connected to the output of the second OR circuit, and the second input of the second circuit And it is connected to the output of the third OR circuit, and the outputs of the indicated AND circuits, as well as the output of the first circuit OR, are connected to the inputs of the control signal generator.

This allows the construction of an adaptive cyclic device, in which the role of the other buffer is performed by a group of parameters that are prepared for transmission with the cyclic onros and are not subject to redundancy elimination. This is achieved by uniformly loading the communication channel and automatically adjusting its parameters.

FIG. 1 is a block diagram of the device.

The principle of operation of the device is that there are two groups of parameters to be transmitted. The first group of parameters is alternately connected to the input of the first encoder, represented as a sequence of periodically repeating samples (pulses defined and amplitudes), which are then encoded. Excess counts are then discarded.

FIG. Figure 2a shows channel intervals during which samples of the first group of parameters can be transmitted (in this case, the nx number is 5). Border sections correspond to significant, i.e. transferable, counts.

The second group of parameters (in Fig. 2.6 nx, the number is 7) is subjected to cyclic polling, but is not processed in order to eliminate redundant data. The formed "windows (the open sections in Fig. 2, a) must be filled with readings from the second group, which coincide with the forming" windows. FIG. 2, the output signal of the system is shown, where the simultaneous transmission of the parameters, that are subject to compression, and the parameters that are interrogated cyclically.

Since the samples of both groups of parameters are randomly assigned to the output frame, each sample, as can be seen from FIG. 2.2, should be with the address part.

In order to preserve the accuracy of the recovery of the messages of the second group, when the intestine change in the flow of significant samples of the first group changes, it is necessary to control the degree of filling the frame with the samples of the first group and adjust the parameters of the transmission channel.

FIG. 3, and FIG. 3.6 shows the time diagrams of the sequence of forming information Ui and address L ,: groups for both groups of parameters.

The proposed device includes a synchronizer 1, the first switch 2, the first block of the address 3, the first analog-to-digital converter 4, the redundancy reduction device 5, the delay line 6, the second switch 7, the second analog-digital converter 8, the second address block 9, the circuit "NO 10, aggregate spgnal // block, control and monitoring unit 12, valve 13, counter 14, trigger 15, differentiating value 16, matrix 17, first 18, second 19, and third 20 shells" OR, fourth schemas. We " OR 21--23, first 24, second 25 n third 26 frequency dividers, fifth Scheme “OR 0 27, the first 28 and the second 29 AND schemes and the driver of the control signals 56.

The device works as follows.

The synchronous / pulses delivered by the inputs of the first switch 2, 5 linip for the hold 6, the second switch 7 and the control and control unit 12.

The signals of switch 2 in the form of switching pulses and elements of the functions of the first group of parameters arrive respectively at the inputs of the address block 3 and converter 4. The redundancy reduction device 5 issues a signal about the counting to the inputs of blocks 3, 4 and 10. With a significant count of the group displaying the count of any parameter of the first group is fed to the input of the sum signal block. The code group of the address (signals L; II Uj, An and Un, and others in Fig. 2.6) is also supplied there. Simultaneously, the input to the circuit is 0 10.

If the samples of the first group are redundant, then the pulses taken from the output of the delay line 6 pass through the circuit NO 10 to the inputs of the second converter 5-8 and the second address block 9, which are connected to the output of the switch 7. Irp code addresses combinations (Ly , Ar, Am, etc., fig. 2, 6) and information about the magnitude of the reference ON, AND ;, And /, fig. 2,6) are fed to the input of the block of the s. M. Signal 11.

The control unit p control 12 operates as follows.

The frame signals of the synchronizer 1 control the operation of the trigger 15, which generates a pulse equal to the frame duration with which the valve 13 is opened. Through the valve 13, the output of the counter 14 is pulsed from the output of the block 5. At the end of the frame, the readings of the counter 14 are read by the signals of the circuit 16. The number recorded on the counter 14 is equal to the number of significant samples in the frame. This number (code) is connected to the input of the matrix 17, to the output plugs of which the connected circuits

5 "P1LI 18-23. The “OR 18” circuit is connected in parts in such a way that the appearance of a signal from the high voltage output of any of them indicates a normal number of significant readings in the frame. The signal from the output of the circuit “OR 19” indicates that the number of significant samples in a frame is less than the norm, and the signal of the circuit “OR is 20 more than the norm. The signals of the circuit 21-23 indicate the degree of increase or decrease in the frame of the number of significant separation of the pulse frequency taken by the output of the circuits OR 21-25. The coefficient: the division divider 24 is larger than the divider coefficient 25, and the divider coefficient 25 is larger than the divider coefficient 26. This is done so that occasional small deviations from the norm do not cause the formation of the signal of its signal. The outputs of the OR 19 and 20 circuits are supplied respectively to the first inputs of the AND 28 and 29 circuits, and their second inputs receive a signal from the output of the OR 27 circuit, to the inputs of which are connected the outputs of dividers 24-26. The outputs of the circuits "And 28 and 29" are fed to the input of the formation of the control signal 30, where the output of the circuit "OR 18" is also supplied.

With an increase in the frequency of occurrence of significant samples, signals appear at the output of the circuit "OR 20, any of the icxeM" OR 21, 22 or 23. As a result, from the output of the circuit "AND 29, a signal is received that it is necessary to increase the frequency of the initial interrogation of parameters, transmitter power and channel bandwidth expansion. The signal from the output of the AND 28 circuit requires decreasing the same channel parameters. The signal from the output of the circuit OR 18 indicates the need to keep the parameters unchanged.

Thus, the device makes it possible to transmit information without delay and with a given recovery accuracy by adjusting the channel parameters. The second group of parameters, which are transmitted cyclically, may include those that do not contain significant redundancy.

Subject invention

Claims (2)

1. An adaptive device for transmitting messages containing a channel commutator, a digital-to-analog converter, a redundancy device connected to the output of a digital-to-analog converter; monitoring and control unit and synchronizer, characterized in that, in order to ensure uniformity of data transmission to the communication line, it contains a second channel switch, a second analog-to-digital converter, the first and second address blocks, the delay line, the "NO and total" circuit a signal whose first and second inputs are connected to the outputs of the first and second analog-to-digital converters, respectively, and the third and fourth inputs are connected to the outputs of the first and second address blocks, respectively; the first and second outputs of the switches are connected to the first inputs of the address blocks and analog-to-digital converters; The second input of the first analog-digital converter is connected to the cert output of the delay line, and the output is connected to the first input of the redundancy device, the second input of which is connected to the second output of the delay line, and the output is connected to the second input of the first address block, and to the first input of the control unit and control and the first input of the “PET” circuit, the second input of which is connected to the third output of the delay line, and the output - CO to the second input of the second analog-digital converter and to the second input of the second address block; the first output of the synchronizer is connected to the input of the delay line and to the inputs of the switches, the second output of the synchronizer is connected by a second input of the control and monitoring unit. 2. The device according to claim 1, characterized in that, in order to provide automatic discrete adjustment of the channel parameters, the control and control unit contains matrix, frequency dividers, a counter, an AND circuit, an OR circuit, a driver of control signals, a gate and the trigger, the outputs of which through the valve and the differentiating circuit are connected to the inputs of the counter, the outputs of which are connected to the inputs of the matrix, three groups of outputs of the matrix are connected to the inputs of the first, second and third circuits OR, respectively, the outputs of the first group are also connected to n rvymi input of the fourth circuit "OR, the second inputs. Which are connected to the third group of outputs of the matrix, and the outputs of the fourth circuits" OR are connected to the inputs of frequency dividers, the outputs of which through the fifth scheme "OR connected to the first, inputs of the first and second circuits" And, the second inputs of which are connected with the outputs of the first and third circuits "OR, respectively, and the outputs with the first and second inputs of the driver of control signals, the third input of which is connected to the output of the second circuit" OR. 45 b r frs Cs