SU1025015A1 - Redundancy device for synchronizing input signals - Google Patents

Description

This invention relates to computer math in computing technology and can be implemented in digital multi-channel devices of reliability. A known redundant OLYA realisin signal device containing in each of the recording trigger channels, data storage and information output, a majority ticket and a clock bus. The device’s disadvantage is that it can generate asynchronous information output signals to the inputs of the asynchronous information circuit. the device has a poor reliability with respect to impulse noise, since, if present, memory elements are triggered, which can lead to a false output of the output from Ignalov. A three-channel redundant signal synchronization device is also known, containing three channels, each of which includes recording, storing and transmitting triggers, connected to the corresponding logical AND and OR elements and a major trigger element, to three buses of clock pulses 2 they are associated with large instrumental hardware and low functional reliability associated with the need for each channel to have three clock frequencies that are shifted relative to each other. The most technical solution to the present invention is a device for synchronizing the input signals of a multichannel discrete system, which contains recording and storage triggers connected to logical elements And and OR in a channel and connected to a majority element to two; bus clock pulses. The disadvantages of a news device include its considerable complexity and low fustoshonalny reliability associated with two clock buses poured into each channel. The invention of the invention is the simplification and increased reliability of the device. The goal is achieved due to the fact that the first and second triggers are byzoliens as J K-triggers, the R-inputs of the first and second 3 K-riggers are communicated and connected to the input, these devices, inputs from these triggers are connected to each other . , 1) impulses, the second 3 K-trigger triggered with & dinene with the input of the 3-first 3 K-trigger, the unit output of the First D of the K-trigger through the majority element is connected to the input 5 of the third 3 K-trigger, input K f of the first 3 K - shtgera and to the output bus device, and the input K of the second LK-flip-flop grounded. Fig. 1 is a functional block diagram of a redundant device for synchronizing input signals for the case of a three-channel implementation; in fig. 2-4 - timing diagrams, according to the device operation. The device contains the same type channels 1,2 and 3. Each of the channels contains the first and second D K-triggers 4 and 5, respectively, the majority element 6, the bus 7 clock pulses, the information input bus 8, the output bus 9, the output of the majority connection 10 and Majority connections 11,12. The device works as follows. The input signals to the input information buses 8 are asynchronous. The device is operational if the continuous coincidence in time of asynchronous information signals over two any channels overlaps at least two clock drops. In the initial STATE, there is a zero potential on the input data bus 8, which, acting on the inputs of the flip-flops 4 and 5, forcibly installs on their individual ones; the outputs, the output bus 9 and the input O of the trigger 5 zero potential. The output signal arrives in each channel of the device over a width of 8 unit potential and enables the operation of the triggers 4 and 5 via inputs 3, K, C. According to the decay of the first clock pulse after that which has passed over the bus 7 at the output output of the trigger 4, the unit has a single trigger and the trigger 5 has its own. the state will not change, since at its input 3 there was a zero potential at the time of the fall of this clock pulse. Due to the fact that the information signals are fed to the inputs 8 of the HecimxpoHHO device relative to each other / clock and to the clock pulses, it is possible that the trigger 4 in one of the channels will be set to one state one clock period earlier or later than triggers 4 in the remaining channels. In order for triggers aneNejrroB 6 to be triggered and the output of the flash output signals from all three channels, it is necessary for switching to single state of trigger 4 at least in two channels to occur. For non-remote reception of asynchronous information and its attachment to clock pulses, time diagrams of the device operation are shown in FIG. 2-4 where 7. are the signals on the tires of the clock pulses entering the channels, 8 i -8 l are the signals on the input pins 8 channels 1,2 and 3, respectively, 4jt415 are the signals on the single outputs of the triggers 4 channels 1,2 and 3 sootvetsko: 9 J - signals at the output shi.na 9 channels 1.2 and 3, respectively; 5 - 50 signals on single outputs of the triggers 5 channels 1,2 and 3, respectively. The diagrams show input information consisting of one pulse. In FIG. 2 information imputs on the input buses of 8 channels 1,2 and 3 non-simultaneously. In this case, in channel 1, the information pulse arrives at the end of the pulse -f + 1 clock frequency 7 4., and in channels 2 and 3 after the end of this pulse. In this case, by the pulse of 1 + 1 clock frequency 7. j will be set to the master state of Trigs. the ger 4 only in channel 1,. a in channels 2 and 3. the trigger 4 will be set to one by the pulse decay + 2. After the decline of the clock frequency is 7. the output of the major element 6 channels 1,2 and 3 coxpamiTct. zero potential, which does not allow changing the state of trigger 4 in channel 1 and triggers 5 in all three channels after the arrival of the hash drop. + 2 clock frequency 7. With the arrival of this pulse decay, only triggers 4 in channels 2 and 3 change their state from zero to unit, and output of the majority elements 6, input 3 and 5, Krygger's input to 4 Tire 9 will establish a single potential level in all three channels. Due to this, after the arrival of the decline of the pulse i + 3 clock frequency 7. All kangshah trigger 5 is set to one, and trigger 4 is set to zero. This will end the output signal. Zero potentials, which when this becomes on the inputs of 3 flip-flops 4 and 5, block these triggers in the zero and common states, respectively, so that the incoming 7 - 3 clock pulses cannot exhaust) P1e of these flip-flops until the end of the input signal on the bus 8. At the end of the input signal, the device is given the initial state by the zero potential supplied to the inputs R of the flip-flops 4 and 5. In FIG. 3, the master pulse) is fed to the input bus 8 of channel 1 later than in channels 2 and .3. As a result of this, the decay pulse i + 1 clock frequency 7, the trigger 4 in channels 1 and 2 will be set to one, and the channel 3 trigger 4 will be set to the decay state by the decay pulse i + 2 clock frequency on incoming buses, 9 all three channels will start on i + 1 pulse decay and end on f + 2 pulse decay at a frequency of 7.5. If there is no data signal on the input bus 8 of one of the channels of the present device (by selecting one of the information sources) yoke between information signals at vhotsnyh, tire 8 Vdvuh other channels (. Figure 4), the device operates similarly Opis - Nome. At the same time, in channel 1, the input 8 of which does not receive the information signal, the triggers 4 and 5 do not change their initial states, and the signals on the output buses 9 channels 1, 2 and 3 are generated from signals jnocry connected to the majority elements from the channels 2 and 3. The device is resistant to interference on the incoming bus 8 due to the fact that the first 1format 1O1 signals reach the inputs i D of the K-igger 4 and 5. Moreover, in order to prevent interference from the tires on the tires 9, channels 1, 2 and 3 the signal was formed must be the same as mgshmum in avuh of the canopic signal by, mech on input GOVERNMENTAL tire 9 with their decay pulses, postupayuidah bus clock 7 apparatus has high rapidity. action, since the formation of signals on the output bus 9 channels 1.2 into 3 begins after the arrival of the falling edge of the information pulse TaraiM, the redundant device for synchronizing the inputs and signals has an increased reliability due to simplifying the device and using the clock bus in it.

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Claims (1)

A RESERVED DEVICE FOR SYNCHRONIZING INPUT SIGNALS, containing two triggers in each channel, a major element, an hour of clock pulses, and the rest of the clock, which, in order to simplify the reliability of the device, the first and second triggers are made as 3 K-trnggers, R-inputs of the first and second ZK-triggers are combined and connected to. the input bus of the device, C - the inputs of the first I of the second, jK-triggers are combined, connected to the clock bus, the inverse output of the second E K-trigger is connected to the 3-input of the first 3 K-trigger,. a single output of the first 3 K-trigger through a majority element is connected to the 3-input of the second 3 K-trigger, input to the first .3 K-trigger and to the output. the device bus, and the input K of the second 3 K-TRGH, the hera is grounded.