SU1176441A2 - Redundant generator - Google Patents

Abstract

RESERVED.GENERATOR on author. St. No. 868993, distinguishing with the fact that, in order to increase the reliability of the generator, it introduced the fifth and test elements OR, the third counter, the state decoder, the second, third and fourth elements AND, the three elements EXCLUSIVE OR, the output of the first element And it is connected to the zeroing input of the third counter, the counting input of which is connected to the first inputs of the second, third and fourth elements of AND, and to the output of the sixth OR element, whose inputs are connected to the outputs of the channels of the redundant generator and to the first inputs of the first, second and third About the elements EXCLUSIVE OR, to the second inputs of which the corresponding outputs of the state decoder are connected, the inputs of which are connected to the corresponding outputs of the third counter, the outputs of the elements EXCLUSIVE OR are connected to the second inputs of the second, third and fourth elements AND, respectively, the outputs of which are connected to the inputs The fifth element OR, the output of the fourth element OR is connected to the input of the power switch through the fifth element OR.

Description

J The invention relates to a pulse technique and can be used in synchronizing devices as a common-mode frequency generator. The purpose of the invention is to increase the efficiency of the generator. The drawing shows a diagram of a redundant generator. The redundant generator contains a power switch 1, the outputs of which are connected to the power control buses of the multichannel generators 2, 3 and 4, one of which is in the working state and the rest in the cold standby state. The outputs of the same-name channels of each of the generators are connected to the inputs of the first 5, second 6, and third 7 elect; mentop OR, the outputs of which are connected to outputs 8, 9 and. 10 channels of the reserved generator and with the inputs of the And-11 element. The output of the autonomous generator 12 is connected to the counting input of the first counter 13, the zero input of which is connected to the output of the first element 11. The output of the pre-last bit of the first counter 13 is connected to the zeroing input of the second counter 14, the counting input of which is also connected to the output of the first element AND 11. The outputs of the last bit before the first 13 and second 14 counters are connected to the inputs of the fourth element OR 15, the output which through the fifth element OR 16 is connected to the input of the power switch, the output of the first element AND 11 is connected to the zero input of the third counter 17, the counting input of which is connected to the first inputs of the second - fourth 18 to 20 elements AND OR 21. The outputs of the channels of the redundant generator are connected to the inputs of the sixth element OR 21 and to the first inputs of the first - third 22-24 elements EXCLUSIVE ISH, the outputs of the state decoder 25 are respectively connected to the second inputs, and its inputs 17 are connected to the outputs of the third counter 17. The outputs of the first - and third elements of the EXCLUSIVE EXISTING OR are connected to the second inputs of the second - fourth 18 - 20 And elements, the outputs of which are connected with inputs of the fifth element OR 16. The redundant generator operates as follows. When the redundant generator is operating properly, the power is connected, for example, to generator 2, and generators 3 and 4 are in cold standby. The third counter 17 is controlled at the counting input by the highest frequency (allocated by the sixth element OR 21), and is nullified by the lowest frequency (separated by the first element 11) from the shaped common-mode frequency grid. This counter supplies to the inputs of the 25 state decoder a sequence of binary numbers that correspond to a priori information about the distribution of pulses in the common-mode, frequency grid channels. In accordance with these binary numbers, the 25 state decoder at its outputs generates a sequence of codes that are compared on the EXCLUSIVE OR elements with the signals of the common-mode frequency grid. When the redundant generator operates correctly, these signals are the same, therefore, the output of the fifth element And 16, and therefore, at the input of the power switch 1, there is no fault signal. Due to the fact that the duty cycle of the signals of the frequency grid can be arbitrary in the general case, it is necessary to timing in time the moments of comparison of the pulse signals of the frequency grid and the potential signals from the output of the decoder of 25 states. This gating is carried out with the help of the second - fourth 18-20 elements AND, the permitting inputs of which receive signals of the highest frequency from the sixth element OR 21. As in the redundant generator circuit there are recalculation circuits, they must be zeroed at the initial moment of time. Resetting is done on a common bus, resetting the entire system (not shown). In addition, zeroing is performed after switching the multichannel generators. Thus, when the redundant generator is working properly, there is no mismatch signal at the outputs of the second - fourth 18-20 elements. In this case, the power switch 1 leaves the generator 2 turned on. When the redundant generator is operating, there may be cases of failures of multichannel generators, expressed in

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increase, decrease or loss of frequency. Due to the fact that multichannel generators contain scaling circuits in the divider channels, it is possible, for example, to increase the frequency due to the fact that the trigger of one of the bits stops working in the division mode, and its valves continue to work only as amplifiers supplied on them signals. At the same time, a redundant oscillator on this channel has a double frequency signal, which practically means the failure of a redundant oscillator. I

If a backup generator fails (loss, reduction or increase in frequency) in one of the generator channels, the output signal of the EXCLUSIVE OR element corresponding to the given channel is a mismatch signal. The appearance of this signal is caused by the fact that the distribution of pulses in the frequency grid is disturbed. Moreover, this distribution is different from the distribution of signals, which forms the decoder of 25 states. The logic of operation of the state decoder is based on the fact that the distribution of pulses at each time point in the generator channels is known in advance. The position of the pulses with each period of the highest frequency varies in a certain way. The third counter 17, starting from zero time, generates at the output some binary number, in accordance with which the decoder of 25 states generates a sequence of codes. These codes, when the generator operates correctly at the times determined by the highest frequency, coincide with the pulses of the frequency grid. If in one of the channels working | generator signal failure occurs (loss, decrease or increase in frequency), then in the circuit, as

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as indicated above, a mismatch signal is generated. This signal, if there is a resolution at the second input, passes through one of the AND elements (18, 19 and 20) and then through the fifth element OR 16 enters the power switch 1, which disconnects the power from the generator 2 and supplies it to the generator 3.

As indicated above, the third count JO chip 17 is controlled at the counting input by the highest frequency, and zeroed by the lowest of the frequency grid formed by the operating oscillator. Any of the failures of these two frequencies are not

12 leads to disruption of the entire device. Indeed, signal failure; the lowest frequency, as follows from the work of a known redundant generator, leads to the appearance of a fault signal at the output of the fourth element OR 15. The change in the signal of the highest frequency is recorded on the corresponding element EXCLUSIVE OR, as described above. In this case, the highest input from the remaining frequencies enters the counting input of the counter 17.

Thus, in the event of a failure at least in one of the channels of the redundant generator, the circuit switches from the operating generator to one of the backup ones. Due to this, it is possible to avoid the occurrence of spurious signals in higher frequency channels.

 The proposed redundant generator is much more reliable than the known one, since it is possible to control the signals in all its channels.

The proposed device can be used as a common-mode grid generator in synchronized devices, which allows to increase the efficiency of solving navigation and radio targets by increasing the reliability of the formation, nor the common-mode grid.

Claims (1)

RESERVED. GENERATOR St. No. 868993, characterized in that, in order to increase the reliability of the generator, the fifth and test elements OR, the third counter, state decoder, the second, third and fourth elements AND, the three elements EXCLUSIVE OR, the output of the first element AND are connected to the input of zeroing the third counter, the counting input of which is connected to the first inputs of the second, third and fourth elements AND and the output of the sixth element OR, the inputs of which are connected to the outputs of the channels of the redundant generator and to the first inputs of the first, second and third elements comrade exclusive OR, to second inputs _x which are connected to respective outputs of the decoder states, the inputs of which are connected to respective third counter outputs, the outputs of the exclusive OR gates connected to the second inputs of the second, third and fourth AND gates, respectively, the outputs of which are connected to the fifth element inputs OR the output of the fourth OR element is connected to the input of the power switch through the fifth OR element. I * ω s