RU2661354C1 - Generator control device - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to impulse technology and can be used to improve the reliability of digital systems of transport devices under conditions of impact of mechanical shocks. Device for monitoring the operation of the generator contains the main and backup generators, the first and second logic elements, the first and second pulse counters, the first and second decoders, the trigger, the switching element, the output of which is the output of the device, and the first and second information inputs are connected to the outputs of the main and standby generators respectively, the output of the high bit of the first pulse counter is connected to the first input of the first logic element whose output is connected to the count input of the first pulse counter, the first input of the second logic element is connected to the initial setting bus and the initial setting inputs of the second pulse counter and the trigger whose output is connected to the control input of the switching element, the output of the second logic element is connected to the input of the initial setting of the first pulse counter, whose outputs are connected to the inputs of the first decoder, the output of which is connected to the information input of the flip-flop, the count input of the second pulse counter is connected to the output of the backup generator, and the outputs to the inputs of the second decoder whose first output is connected to the clock input of the trigger and the second output to the second input of the second logic element, the second input of the first logic element is connected to the output of the main generator, the time-setting element of the main oscillator is a quartz resonator, and the time-consuming element of the backup generator is a capacitor.

EFFECT: improving the reliability of the pulse generator under the impact of mechanical shocks.

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Description

The invention relates to a pulse technique and can be used to improve the reliability of digital systems of transport devices under the influence of mechanical shocks.

Known redundant pulse generator (see USSR author's certificate No. 1192177, "Redundant pulse generator", VP Ponomarenko, SP Kovita and AN Medvedev, published 11/15/1985, BI No. 42), containing the main reference a generator connected by the output to the first input of the phasing unit, to the second input of which the output of the backup generator is connected, and to the input of the switching unit, the output of which is connected to the control input of the switch. The first information input of the switch is connected to the output of the phasing unit, and the second information input is connected to the output of the main reference generator, a frequency divider connected by the input to the output of the switch. The output of the phasing unit is connected to its third input. The switching unit contains a key amplifier, the input of which is the input of the unit, the output of the key amplifier is connected to the first output of the storage capacitor connected by the second output to the common bus, and the output key element, the output of which is the output of the unit, and the input is connected to the first output of the storage capacitor.

The disadvantage of this device is the lack of reliability under the conditions of mechanical shocks, because due to the break of the quartz holder in the quartz resonator of the main reference oscillator, which occurred as a result of a strong shock, the reference generator switches to another frequency determined by the parameters of the parasitic capacitances of the circuit, and the switching unit does not reveals, since it does not have a band-pass filter. In this case, switching to the backup generator will not occur.

Known redundant pulse generator (see USSR author's certificate No. 610289, "Redundant pulse generator", NB Blank, L.Ya. Kuzmenko and VP Yakovlev, published 05.06.1978, BI No. 21) containing a power source and two channels, each of which contains a pulse generator, the output of which is connected to the input of the bandpass filter, the output of which is connected to the input of the integrating stage, the output of which is connected to the control input of the key, the output of which is connected to the power bus of the adjacent pulse generator, and the power supply It is connected to power supply buses of integrating stages and keys of both channels.

The disadvantage of this device is its low reliability under the influence of mechanical shocks, which is due to its symmetry, since with high demands on the stability of the generated frequency it involves the use of master quartz resonators in both generators. This leads to insufficient stability of the device against mechanical shocks, since a strong mechanical shock can lead to the breakdown of quartz crystals from quartz holders in both generators. Using different generators in the device (one with a quartz resonator to ensure the required stability of the generated frequency in the absence of strong shocks, and the other using a timing RC circuit with a high level of resistance to mechanical shocks) does not make sense, since when the power is turned on, RC will take the initiative -generator, which does not need time to build up the quartz resonator, and the quartz generator will be in reserve. Another disadvantage of this device is its unsuitability for miniaturization by implementing on the basis of the FPGA chip, since the device uses analog elements: bandpass filters and integrating cascades. In addition, during the operation of the device, part of its elements are not powered (located in the cold reserve), which cannot be implemented on the basis of a single FPGA chip. The third disadvantage of this device is a long pause in the formation of pulses when switching to a backup channel, due to the need to build up a quartz resonator in a backup generator when power is supplied to it.

A known device for monitoring the operation of the generator (see the book "Microelectronic circuits of digital devices", Bukreev IN, Goryachev VI, Mansurov BM - M: TECHNOSPHERE, 2009 - S. 394, Fig. 10.46a), comprising a main pulse generator, the output of which is connected to the first information input of the switching element and the input of the edge selection circuit, a backup pulse generator, whose output is connected to the second information input of the switching element and the first input of the OR-NOT logical element, the output of which is connected to the clock input of the counter and pulses, the reset input of which is connected to the output of the edge selection circuit, and the high-order output of the pulse counter is connected to the control input of the switching element and to the second input of the logic element OR-NOT, the output of the switching element is the output of the device.

The disadvantage of this device is the inability to detect the frequency output of the main oscillator beyond the allowable interval, since the front allocation circuit only detects generation disruption (cessation), but does not detect the transition of the main oscillator to spurious oscillation when the resonator quartz holder breaks.

The above device is the closest in technical essence to the claimed device and therefore is selected as a prototype.

The technical task to be solved is the creation of a device for monitoring the operation of the generator, which increases the reliability of control by detecting both the cessation of the generation of the main generator and the output of the pulse frequency it generates outside the allowable range.

Achievable technical result is to increase the reliability of the pulse generator under the influence of mechanical shocks.

To achieve a technical result, the generator operation control device containing the main and backup generators, the first logic element, the switching element, the output of which is the output of the device, and the first and second information inputs are connected to the outputs of the main and backup generators, respectively, the first pulse counter, the senior output the discharge of which is connected to the first input of the first logic element, the output of which is connected to the counting input of the first pulse counter, w A second pulse counter, the first and second decoders trigger and the second logic element, the first input of which is connected to the initial setup bus and the initial inputs of the second counter and trigger, the output of which is connected to the control input of the switching element, the output of the second logic element is connected to the input of the first installation counter, the outputs of which are connected to the inputs of the first decoder, the output of which is connected to the information input of the trigger, the counting input of the second pulse counter is connected to ode to the backup generator, and the outputs to the inputs of the second decoder, the first output of which is connected to the clock input of the trigger, and the second output to the second input of the second logic element, the second input of the first logic element is connected to the output of the main generator, the timing element of the main generator is a quartz resonator , and the timing element of the backup generator is a capacitor.

The indicated set of essential features makes it possible to increase the reliability of the pulse generator under the influence of mechanical shocks by monitoring the operation of the main generator and, in case of failure, switching to the backup generator.

In FIG. 1 shows a diagram of a device for monitoring the operation of the generator, FIG. 2 timelines explaining his work.

The generator operation control device contains a primary 1 and a backup 2 generators, a first logic element 3, a switching element 4, the output of which is the output 5 of the device, and the first and second information inputs are connected to the outputs of the primary 1 and backup 2 generators, respectively, the first pulse counter 6, the output of the high order of which is connected to the first input of the first logic element 3, the output of which is connected to the counting input of the first pulse counter 6, characterized in that a second counter is additionally introduced pulses 7, first 8 and second 9 decoders, trigger 10 and second logic element 11, the first input of which is connected to the initial setup bus 12 and the initial setup inputs of the second pulse counter 7 and trigger 10, the output of which is connected to the control input of the switching element 4, the output the second logic element 11 is connected to the input of the initial installation of the first pulse counter 6, the outputs of which are connected to the inputs of the first decoder 8, the output of which is connected to the information input of the trigger 10, the counting input of the second counter and pulses 7 are connected to the output of the backup generator 2, and the outputs are connected to the inputs of the second decoder 9, the first output of which is connected to the clock input of the trigger 10, and the second output is connected to the second input of the second logic element 11, the second input of the first logic element 3 is connected to the output the main generator 1, the timing element of the main generator 1 is a quartz resonator 13, and the timing element of the backup generator 2 is a capacitor 14.

The device for monitoring the operation of the generator (see Fig. 1) works as follows.

When you turn on the power on the initial setup bus 12 receives a reset pulse R _pit. (see Fig. 2, cycle 1), which resets both counters 5 and 7 and trigger 10. The main generator 1 will start after some time, which is necessary for the buildup of the quartz resonator 13. Depending on the type of generator and resonator, this time can be several units up to several hundred ms. During this time, the first counter 6 remains in its original state, and at the output of the first decoder 8, traffic accident pulses 1 are not generated (see Fig. 2, cycle 1). Immediately after turning on the power, the backup generator 2 starts to generate pulses that are fed to the counting input of the second counter 7. After the reset pulse R _{stops, the pit} counter 7 starts continuous operation, while at the outputs of the second decoder 9, pulses of ДШ2-С are generated, which arrive at the trigger input of the trigger 10, and pulses ДШ2-R, coming through the second logic element 11 to the reset input of the first counter 6 (see Fig. 2).

Until the resonator 13 of the main generator 1 swings, a low logic level is kept at the information input of the trigger 10 and pulses DSh-S (see Fig. 2, cycle 1) confirm the initial (zero) state of the trigger 10, in which through the switching element 4 to the output 5 devices pass pulses of the backup generator 2. Pulses ДШ2-R periodically confirm the initial (zero) state of the first counter 6.

When the resonator 13 swings, pulses will appear at the output of the main generator 1, which will begin to flow through the first logic element 3 to the counting input of the first counter 6. As a rule, the moment of the beginning of the formation of these pulses does not coincide with the pulse ДС2-R, therefore, in the corresponding operation cycle ( see Fig. 2, cycle N-1) pulses DSh1 and DSh2-C do not coincide, and trigger 10 remains in the zero state. However, in the next cycle (see Fig. 2, cycle N), the pulse front ДШ2-С coincides with the DNI pulse generated by the first decoder 8, and the trigger 10 switches to a single state, in which pulses begin to pass through the switching element 4 to the output 5 of the device main generator 1.

If, as a result of a strong mechanical shock, the crystal of the resonator 13 breaks off the quartz holder, the main generator 1 ceases to generate pulses, the first counter 6 will be reset to the next pulse ДШ2-R and will remain in this state due to the absence of counting pulses. At the information input of trigger 10, a low logic level will be present and the next impulse DSH-C will switch it to the zero state, in which pulses of the backup generator 2 will begin to pass through the switching element 4 to the output 5 of the device.

Thus, the pulses of the backup generator 2 pass to the output 5 of the device after turning on the power until it reaches the generation mode of the main generator 1, and in case of failure of the main generator due to mechanical shock or for other reasons. The instability of the time for reaching the generation mode of the main generator 1 is very large and depends on the activity of the quartz resonator, the gain of the active element of the generator, and a number of other factors. In cases where the pulse generator clocks the device forming the time intervals counted from the moment of power supply, the error due to the instability of the time the main generator goes into the generation mode is included in the additive part of the total error. In the inventive device, the time interval between the moment of power supply and the moment of entering the generation mode of the main generator 1 is filled with pulses generated by the backup generator 2. If you take measures to stabilize the frequency of the backup generator 2 (to stabilize its supply voltage, use precision elements during the RC-circuit) , then the additive part of the total error can be reduced several times. This is an additional positive result of the claimed device.

A prototype of the generator operation control device was carried out using the FPGA ARA 150 chip, the RK486-8TS-10000K quartz resonator, the KM-5 capacitor in a package (version “c”) with a tolerance of ± 2% and the temperature instability group MP0 and precision resistor C2- 29 with a tolerance of ± 0.1%. Tests of the layout confirmed the operability of the claimed device and its practical value. The additive component of the total error of the quartz oscillator, due to the instability of the build-up time of the quartz resonator, is reduced by a factor of 6 due to the filling of the indicated time with pulses of the backup RC oscillator.

Claims (1)

A generator operation control device comprising a primary and backup generators, a first logical element, a switching element whose output is the output of the device, and the first and second information inputs are connected to the outputs of the primary and secondary generators, respectively, the first pulse counter, the senior discharge of which is connected to the first the input of the first logic element, the output of which is connected to the counting input of the first pulse counter, characterized in that the second pulse counter is additionally introduced s, the first and second decoders, the trigger and the second logic element, the first input of which is connected to the initial installation bus and the initial installation inputs of the second pulse counter and trigger, the output of which is connected to the control input of the switching element, the output of the second logic element is connected to the input of the initial installation of the first a pulse counter, the outputs of which are connected to the inputs of the first decoder, the output of which is connected to the information input of the trigger, the counting input of the second pulse counter is connected to the backup generator, and the outputs - to the inputs of the second decoder, the first output of which is connected to the clock input of the trigger, and the second output - to the second input of the second logic element, the second input of the first logic element is connected to the output of the main generator, the timing element of the main generator is a quartz resonator , and the timing element of the backup generator is a capacitor.

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