SU1170386A1 - Tolerance check device - Google Patents

Abstract

1. DEVICE OF ADMISSION CONTROL, containing the first conversion unit, switch, five null-organs, the outputs of which are connected respectively to the first, second, third, fourth and fifth inputs of the logic unit, trigger, the input of which is connected to the output of the third, zero-organ and the output is with the sixth input of the logic block, which is so that, in order to expand its functionality and application, a second conversion unit, the first and second adders, a signal generator, control block parameters polling, switch, prediction unit, registration unit, the inputs of which are connected respectively to the first output of the prediction block, the first, second and third outputs of the logic unit and the output of the parameter polling unit, the first input of which is connected to the first logic output, the second input The parameter polling unit is connected to the third output of the logic unit; the first input of the control unit is connected. The second input of the control unit is connected to the first output of the logic unit, the third input of the control unit is connected to the third output of the logical unit, the fourth input of the control unit is connected to the output of the trigger, the first output of the signal generator is connected to the first inputs of the first and second adders , the second output of the signal generator is connected to the first input of the prediction block, the second input of which is connected to the output of the first adder and the first input of the switch, and the third input is in hours the second input of the control unit, the second inputs of the first and second adders are connected to the outputs of the first and second conversion units, respectively, the input of the first conversion unit is connected to the first terminal for connecting the output of the test object, the input of the second conversion unit is connected to the output of the switch the input input of which is connected to the output of the parser polling unit, the switch inputs are connected to a terminal group for connecting the outputs of the test object, 00 05 the output of the second adder is connected to the first input The scaling unit's one, the second input of which is connected to the output of the parameter polling unit, the output of the scaling unit, is connected to the second input of the switch, the control input of which is connected to the output of the control unit, and the third input of the parameter polling unit, the output of the switch is connected to the inputs of all zero-organs. . A device according to claim 1, characterized in that the trigger is asymmetrical.

Description

3. The device according to claim 1, wherein the logical unit contains four AND elements, four inverters and two OR elements, the first input of the first AND element is connected to the first input of the logical block, the second input of the first AND element is connected to the third the input of the logic unit, the input of the first inverter is connected to the sixth input of the logic block, the first input of the second element I is connected to the second input of the logic unit, the second input is connected to the fourth input of the logical block, the output of the first element I is connected to the input of the second inverter and the first The first element OR, the output of which is connected to the first input of the third element AND, the output of which is connected to the first output of the logic unit, the output of the second inverter is connected to the second input of the first element OR, the input of the third inverter is connected to the fifth input of the logic unit and the first input the fourth element Hj and the output - with the second output of the logic unit; the output of the first inverter is connected to the first input of the second element OR, the second input of which is connected to the output of the second element AND, the output of the second element OR is connected to v eye input of the fourth AND gate and via a fourth inverter and a second input of the third AND gate, the output of the fourth AND gate oedinen third output logic block. 4. The device according to claim 1, characterized in that the prediction unit comprises a switch, a difference unit, an AND element, a pulse generator, a differentiation unit and a dividing unit, the output of which is connected to the second output of the prediction block and the first input of the AND element, the second input of which connected to the output of the pulse generator, and the output to the first output of the prediction block, the first and second inputs of the difference block are connected respectively to the first and second outputs of the switch, the control input of which is connected to the third input of the block the prediction, the first and second inputs of the switch are connected to the first and second inputs of the prediction unit, respectively, the input of the differentiation unit is connected to the second output of the switch, the first and second inputs of the division unit are connected respectively to the outputs of the difference unit and the differentiation unit. 5. The device according to claim 1, characterized in that the control unit comprises an AND element, a switch, a null organ, an OR-NOT element, a delay unit, first and second triggers, and an OR element whose first input is connected to the output of the AND element, the first the input of which is connected to the output of the zero-organ and the first input of the OR-NOT element, the second input of which is connected to the second input of the OR element and the output of the first trigger, whose single input through the delay unit is connected to the output of the switch, the input of which is connected to the third input of the control unit, control The main input of the switch is connected to the fourth input of the control unit, the second input of the element I is connected to the second input of the control unit, the output of the null organ is connected to. the zero input of the first trigger, and its input with the first input of the control unit, the output of the OR element and the output of the OR-NOT element are connected to the single and zero inputs of the second trigger, the output of which is connected to the output of the control unit. 6. The device according to claim 1, wherein the parameter polling unit comprises a single pulse generator, a buncher, a delay unit and an OR element, the first input of which is connected to the second input of the parameter polling unit through the delay unit, the switch input is connected to the output of the OR element, the second input of which is connected to the first input of the parameter polling unit, the control input of the switch is connected to the third input of the parameter polling unit, the output of the switch is connected to the input of the generator of single gpulses, the output of which nen to the output of the survey parameters. The invention relates to electronic measuring technology and can be used for functional and test control of systems. The purpose of the invention is to expand the functionality and application area of the device by checking the input circuit of the device for an open circuit during the entire monitoring cycle, as well as by allowing it to be used for monitoring the parameters of systems whose technical condition is determined by a large number of interrelated (and independent ) parameters, including systems with a hierarchical structure without increasing the number of information processing channels connected to the output of the logic block, with functional control e, when it is prohibited to change the structure of the object from the side of the control device and the device is turned on when the control object is working, and when the circuit is broken, signals about parameters (determination of the location of the break) are transmitted via KOTopbiM. FIG. 1 shows the tolerance control device; Fig. 2 is the same, variants of possible implementation of the prediction, control and polling units; Fig. 3 embodiment of the logical block. The device contains the first 1 and second 2 conversion blocks, the outputs of which are connected to the second inputs of the corresponding adders 3 and 4, and the signal generator 5, the first jBbixoins of which are connected to the first inputs of the adders 3 and 4. Output the first adder 3 is connected to the first input of the switch 6, the output of which is connected to the inputs of the zero-bodies 7-11. The outputs of the zero-bodies 7-11 are connected to the corresponding inputs of the logic unit 12. To the output of the zero-body 9 is connected; asymmetric trigger 13, the output of which is connected to the corresponding input of logic unit 12. The second output of the signal generator 5 is connected to the first input of prediction unit 14, the second input of which is connected to the output of the first adder 3, and the third to the output of the unbalanced trigger 13. First output of block 14 prediction is connected to the first input of the control unit 15, the second and third inputs of which are connected to the outputs of the logic unit 12, which receive signals about the results of control The norm of the object of control and the marriage of the object of control . The fourth input of the control unit 15 is connected to the trigger output 13. The first and third outputs of the logic unit 12 are respectively connected to the first and second inputs of the block 16, parameters polling, the third input of which is connected to the output, control unit 15, and the control input of the switch 6. The output of the parameter polling unit 16 is connected to the control inputs of the scaling unit 17 and the switch 18. The first input of the scaling unit 17 is connected to the HeH with the output of the second adder 4, and the output is connected to the second input of the switch 6. The output of the switch 18 is connected to the input th second conversion unit 2, input - with corresponding output terminals 19, a control object for which parameters received Xt - X control object. The input to the first control unit 1 of the transformation, connected to the output terminals of the control object 19, receives a parameter for the control object that carries information about its state. A complex two-level hierarchical system is considered as an object of control. In this case, the parameter y (the determining parameter) is associated with the parameters x - x by the dependence: y f (x, x, ..., xn). The function f (x, xj ,, .., x) is such that interdependent parameters x - x can go beyond the tolerances, and the parameter y can go beyond the tolerances, and remain in it, which is the most common case when monitoring complex systems. The output of the parameter x (i 1, ..., p) outside the tolerance limits corresponds to the faulty state of the control object, and the output of the parameter y outside the tolerance limits to the state of failure of the monitoring object. As a working range of parameters, the range-g and y are considered; Oh x; where i 1, ..., p. Zero units 7, 9, and 11 are set to the lower value of the range close to 3. The zero-bodies 8 and 10 are set to the upper value of the range у, corresponding to the result of the control. The marriage of the object of control, the upper value of the range i-ro of the parameter corresponding to the rejection of this parameter. The switch 18 is, in the simplest case, a step-by-step circuit finder whose (by the number of parameters) is switched sequentially each time the signal arrives at its control input from the output of the parameter polling unit 16. The order of switching is hard, predetermined. Scaling unit 17 is, for example, a set of resistances (in terms of the number of parameters). Switching resistances is carried out sequentially at each. The input to the control input of the block 17 is a signal from the output of the block 16 of the parameter survey. The switching order is hard, predetermined, according to (Vetuing order of switching carried out by switch 18. In the massing unit 17, the output signal of the second cooler 4 is multiplied by the scale factor where y is the upper range value corresponding to the result of control control, x. —the upper value of the range corresponding to the rejection of the i-th parameter. The scaling unit 17 allows using pre-configured null organs for monitoring the parameters x - Xf ,, tolerance ranges in which they are different and have the form (1). Prediction unit 14 contains (FIG. 2) a switch 20, the first and second inputs of which are the inputs of the prediction unit, and a difference unit 21, the first and second inputs of which are connected to the first and second the outputs of the switch 20. The output of the difference unit 21 is connected to the first input of the dividing unit 22, the second input of which is connected to the output of the differentiation unit 23, the input of which is connected to the second output of the switch 20. The output of the dividing unit 22 is connected to the first output of the 14th programer 864 and the first entrance m AND gate 24, a second input coupled to an output of the generator 25 pulses. The output of the AND 24 element is connected to the second output of the prediction unit 14, and the control input of the switch 20 is connected to its third input. At the output of dividing unit 22 and, respectively, at the first output of prediction unit 14 and the input of element 24, there is a signal corresponding to the dependence: I - --- p. (V), where y is the upper value of the range y, corresponding to the result of the control. The marriage of the object of control; y - the current value of the parameter; y is the first derivative of the parameter y over time; T is the time remaining until the moment at 5 у and corresponding to the result of the control. The marriage of the object of control. and - the value of the signal at the output of dividing unit 22. The control unit 15 (FIG. 2) contains a null-body 26, the input of which is connected to the first input of the control unit 15, and the output to the first element AND 27 and the first input of the RSHI-HE element 28. The second input of the element 27 And is connected to the second input control unit 15. The output of the element AND 27 is connected to the first input of the element OR 29, the output of which is connected to the single input of the trigger 30, the output of which is connected to the output of the control unit 15. The third input of the control unit 15 is connected to the input of the switch 31, the control input of which is connected to the fourth input of the control unit 15, and the output to the input of the delay unit 32, the output of which is connected to the single input of the trigger 33, the output of which is, in turn, connected to the second inputs of the elements OR NOT 28 and OR 29. The output of the element OR NOT 28 is connected to the zero input of the trigger 30. The zero input of the trigger 33 is connected to the output of the nullorgan 26. The parameter polling unit 16 (FIG. 2 contains a delay block 34 which is connected with the second input of block 16 poll parameters, and the output - to the first input of the Sh1I element 35, the second input of which is connected to the first input of the parameter polling unit 16. The output of the OR element 35 is connected to the input of the switch 36, the control input of which is connected to the third input of the parameter polling unit 16, and output - with the input of the generator 37 single pulses, the output of which is connected to the output of the block 16 of the survey parameters.

The pulse generator 25 of the prediction unit 14 (Fig. 2) generates a sequence of pulses of a certain frequency, arriving at the second input of the And 24 element. Since. at its first input there is a signal corresponding to the time T remaining with up to the moment y, then at the output of the element 24 and the second output of the prediction block 14 this signal is present at the moments of the presence of pulses of the generator 25 pulses at the second input of the element 24. pulse generator 25 is carried out based on operating conditions, control tasks and the object.

The second output of the prediction unit 14, the outputs of the logic unit 12 and the output of the interrogation unit 16 of the parameters of the proposed device can be connected to the corresponding inputs of the registration unit 38, which, depending on the operating conditions, can be an operator console, a conversion device, a logical unit.

Logic block 12 contains (fig.Z) elements And 39 - 42, elements: NOT 43 - 46, elements OR 47 and 48. Signals from null organs 7 and 9 (figure 2) are received at the first and third inputs of block 12, set to the lower value of the range close to 0. The output of the element AND 39 (FIG. 3) is connected to the inputs of the element OR 47 directly and through the element NOT 43. The output of the element OR 47 is connected to one of the inputs of the element 41, the output of which is connected with the first output of logic block 12, the presence of a signal on which carries information about the result of the control. The norm of the object of control. The second and fourth inputs receive signals from the null organs B and 10 (Fig. 2), which are set to the upper value of the y range. The output element And 40 (fig.Z) is connected to one of the inputs of the element OR 48, the output of which is connected to one of the inputs of the element And 42, the output of which is connected to the third output of the logic unit 12, the presence of a signal which carries information about the result of control control The output of the element 45 is connected to another input of the element OR 48, the input of which is connected to the sixth input of the block 12 to which the output of the unbalanced trigger 13 (figure 2) is connected, which gives permission to form the result of the control. The output of the element OR 48 (FIG. 3) through the element NOT 46 is connected to another input of the element AND 41. The input of the element 44 and the fifth input of the logic unit 12, which is connected to the output of the null organ 11, is connected to the other input of the element 42 (FIG. .2). The output of the element 44 is connected to the third output of the logic unit 12 (FIG. 3). The presence of a signal at this output carries information about the result of the control. The marriage of the tolerance control device.

The null organ 26 (Fig. 2) of the control unit 15 is set to the signal value corresponding to the time for switching (when returning to the initial state) switch 6, i.e.

f (t., + S) at t, 5: t

(3)

be

where UCJB is the signal setting value

null organ 26;

tg is the time from the actuation of the null organ 26 until the moment when the switch 6 is switched;

tjg is the time from the moment the null-organ 26 triggers until the moment when the switch 36 is opened,

B - small time value. I The delay block 34 of the parameter interrogation block 16 is tuned to the value of the time T.J4 necessary for fixing the malfunction associated with the output of one of the parameters x - x out of tolerance, and, if necessary, to make a decision.

The delay unit 32 of the 15 jrnpaB unit is set to a time value. Tj + where T 4 is the delay time of the signal by block 34; Tpg is the time from the moment the signal appears at the output of block 34 to the moment when the next circuit is selected in switch 18 and block 17 of scaling. The signal generator 5 generates two signals. The first output has a signal that is minimally necessary for the operation of the null organ 11 UQ, the null organ 9 is set to Uo +, where 1} o44 is the value of the zero organ set 11 close to O; 6 - the minimum excess of the signal value is higher than that distinguishable by the null organ 9. The zero organs 9 and 11 can be selected based on the scatter of the threshold of their response. The second output of the signal generator 5 has a signal with a value equal to U ,. - the threshold is set for the zero-bodies 8 and 10, which are set to the upper value of the range corresponding to the control result. The marriage of the control object. The proposed device tolerance control works as follows. When the device is turned on, the signal generator 5 generates signals with values and Uy. The signal Uo (from the first output of the generator 5 signals go to the first inputs the sum of tori 3 and 4, and from the second output of the generator 5 to the first input of prediction block 14. From the outputs, the sum of tori 3 and 4 signals go to the first input of switch 6 and input scaling unit 17. In the initial state, the output of switch 6 is connected to its first input, therefore the signal from the output of scaling unit 17 connected to the second input of switch 6 is not fed further to the circuit, and the signal from the output of adder 3 is fed to the inputs zero -organ 7 - 11 and leads to Wed batting a null organ 11, the output of which is fed to the fifth input of the logic unit 12 and further (Fig. 3) to the input of the HE element 44 and one of the inputs of the AND element 42. Until the signal arrives at the input of the HE element 44 from the moment the device is turned on The second output of the logic unit 12 contains a signal that carries information about the state of the device itself - the marriage of the tolerance control device.When a signal appears at the input of the HE44 element, the latter is triggered, and. at its output and at the second output of logic unit 12, the signal is lost. The marriage of the tolerance control device indicates that there is no open circuit in the device itself, from the signal generator 5 to the switch 6. The zero authority 9 tuned to the signal value Uog Uo + V does not work therefore, there is no signal at its output, as a result of which the asymmetrical trigger 13 is in an inoperative state and there are no signals at the sixth input of the logic unit 12, the fourth input of the control unit 15 and the third input of the prediction unit 14 . The absence of a signal at the fourth input of the control unit 15 results in the absence of a signal at the control input of the switch 31, with the result that the circuit from the third output of the logical LOCK 12 to the delay unit 32 and then becomes open. The absence of a signal at the sixth input of the logic unit 12 (FIG. 3) results in the presence of the HE 45 element at the output. A signal arriving at one of the inputs of the OR 48 element and, after it triggers, the appearance of signals at the inputs of the AND 42 and HE 46 elements. at the input of the element, HE 46 removes the signal from the corresponding input of the element AND 41 (removes permission to form the result of the control Norm. object of control). The presence of a signal at the corresponding input of the element 42, since after the signal appears at the fifth input, logic unit 12 (after the null-organ 11 triggers), a signal is received at the other input of the element 42, which triggers it and appears at the third output. logical block L2 of the signal about the control result This signal is received (Fig. 2) at the third input of control unit 15 and the second input of parameter polling unit 16. Since the switch 31 of the control unit 15 is open, this signal does not go further. The signal from the second input of the parameter polling block 16 through the delay block 34 and the OR element 35 is fed to the input of the switch 36, which is in its initial state - open. | 11 Therefore, the signal does not go further. The signals from the second output of the generator 5 with the value Uu not the output of the first adder 3 with the value Ui go to the first and second inputs of the prediction unit 14 and then to the first and second outputs of the switch 20. The absence of a signal at the third input of the prediction unit 14 leads to the absence of a control signal the input of switch 20, therefore, signals from the first and second inputs of prediction unit 14, then the first and second inputs of switch 20, do not pass. Thus, when the device is turned on, the tolerance control (with ekte 19) on the second output logic block 12 is a control signal Marriage object kotorm can only go into a block 38 of such registration. In the event of an open circuit in the device itself, from the 5-signal generator to the switch 6, the second output of the logic block 12 appears on the signal of the tolerance control device. In both cases, the signals on the other outputs are missing. When the control object 19 is connected to the device, the second input of the adder 3 through the conversion unit 1 receives a signal carrying information about the parameter y. At the same time, a signal is transmitted to the second input of the adder 4 through the conversion unit 2 and the switch 18 carrying information about one of the parameters previously connected to the output of the switch 18, for example, to. This signal through the scaling unit 17 (where its value is multiplied by the coefficient Kl selected in advance in accordance with the parameter x) selected in the switch goes to the second input of switch 6, which is not connected to its output. From the output of the adder 3, where the signals are summed from the output of the 886 signal of the 5 signals and the output of the conversion unit 1, the resulting signal through the switch 6 is fed to the inputs of the zero-organs 7-11. Since the additional zero-organ 9 is set to the value of expression (4) it is triggered, which leads to the triggering of unbalanced trigger 13 and the appearance of signals at the input of logic unit 12, the fourth input of control unit 15 and the third input of prediction unit 14. The appearance of the signal at the sixth input of the logic unit 12 (Fig. 3) results in its appearance at the input I of the element HE 45, which leads to the removal of the signal from the input of the element OR 48 and the input of the element 46 and correspond to the input of the element AND 42. This signal from the input of the element And 42 leads to the removal of the signal from its output and the third output of the logic block f2 of the signal Scrap control object. The removal of the signal from the input of the element NOT 46 results in the appearance of a signal at the corresponding input of the element AND 41 - permission to form the result of the control. The norm of the object of control. The appearance of a signal at the third input of prediction unit 14 results in the appearance of a signal at the control input of switch 20, which leads to its triggering (Fig. 2). Similarly, but the switch 31 is operated by the control units 15. When the circuit is broken from adder 3 to control object 19 connected to the device (Fig. 2), the asymmetric trigger 13 does not work (or is released) at any time of the control and the Scramble of the control object does not occur at the third input of the logic unit 12 - lib switch in device. In the absence of breaks and the appearance of a signal at the corresponding input of the And 41 element, the latter triggers (the signal at another input by wil. After the asymmetric trigger 13 triggers) and its output and the first output of the logic unit 12; The signal of the object of the control appears (when O y y.). This signal is fed to the second input of the control unit 15 and the first input of the parameter interrogation unit 16 (Fig. 2). From the input of the control unit 15, the signal goes to the second input of the element AND 27. From the first input of the highlight 16 polling, the parameter signal goes to the second input of the OR element 35, and from its output to the input of the open switch 36. Simultaneously with the described processes with the control object 19 connected On the first and second inputs of prediction block 14, signals with the upper value of the range y and the current value of the parameter y, respectively, occur. The signal from the first input of prediction unit 14 through the closed switch 20 is fed to the first input of difference block 21 (decreasing), to the second input of which the signal from the second input of prediction unit 14 is fed through this switch (subtracted). The difference is y, - y, is fed to the first input of dividing unit 22 (divisible), the second input of which receives a signal from the output of differentiation unit 23, corresponding to y (divider). At the output of dividing unit 22, the signal U takes place.

C2Z

UA U

 y 7-, whose value corresponds to the remaining time until the moment y takes

the value of its upper range of y, corresponding to the result of the control This signal is fed to the first input of the element 24 and the first input of the prediction block 15 and to the input of the null organ 26 adjusted for the signal value by the expression (3).

With crc Uc26, the null organ is triggered and at its output a signal appears that goes to the first

the input element And 27 and the first input of the second element SH-NOT 28, because at the second input of the element And 27 a signal is received after the appearance at the first output of the logic unit 12 of the signal about the result of monitoring the rate of the test object, it. it triggers and the signal from its output goes to the first input of the element OR 29, the triggering of which leads to the trigger 30 triggering. Reliability is triggered by the presence of a signal at the first input of the OR-NOT element 28, which leads to the removal of the signal from the zero input of the trigger 30 Trigger trigger 30 leads

JK signal appearing on control

I inputs of switch 6 and switch 36 of parameter polling unit 16 The operation of switch 6 leads to the connection of its input to the output and a signal carrying information about the parameter x is fed to the inputs of the null-bodies 7-11. During switching due to a brief break of the circuit, switch 6 occurs short-term release of asymmetric trigger 13, which leads to a short-term appearance at the second output of the logic block of the signal

and at the third output of logic block 12, the signal is a Scramble Control object, which is fed to the second input of the parameter polling unit 16 and the third input of the control unit 15. These signals do not cause any switching in the device as a result of the presence of delay blocks 32 and 34. At the same time, the signal is removed from the first output of logic block 12 about the result of monitoring. The norm of the control object, which leads to the removal of the signal from the second input of control unit AND 27 and the second input of OR 35 element of parameter polling unit. The second output element And 27 leads B to the final result of removing the signal from the trigger input 30. However, the latter has already remembered the state before it, and there is no signal at its zero input, which is provided by the signal at the first I input of the element W1NE 28. Thus, in As for the switching time of switch 6 and switch 36, no changes affecting the operation logic of the device occur.

The operation of the device when the output of the switch 6 is connected to its second input is similar to its operation, described above, in relation to the interaction of null-bodies 7-11, asymmetric trigger 13, logic unit 12, therefore the control results when the circuit in the device itself from the generator 5 signals to switch 6 and from adder 4 to control object 19 are formed in a similar way.

When a signal appears on the first output of logic block 1 about the result of the monitoring. The norm of the control object (at 0), the signal from this output goes to the second input of the AND 27 element (which does not change the state of the trigger 30) and the second input of the OR 35 element. block 16 poll parameters (through its first input). The operation of the element Shch1I 35 leads to the appearance of a signal at the generator input 37 of single pulses and the inclusion of the latter. The pulse from the output of the generator 37 is fed to the control inputs of the switch 18 and the scaling block 17, choosing the next parameter and its scaling factor. In this case, the switching time in blocks 18 and 17 is the same. The processes that occur during switching are similar to those described above. The output of the parameter interrogation unit 16 can be connected to the corresponding input of the registration unit 38, which finishes the number of the parameter being checked. The other parameters (Xp) are monitored in a similar way with the result of monitoring the Norm of the object of control on the previous napaMeTov. When the zero-organs 8 and 10 are set up, which are set to the upper value of the range y (which takes place at X | j), the second and fourth inputs of the logic unit 12 (Fig. 3) appear and the signals triggering the AND 40 element, the signal from the output of which triggers the element OR 48. The signal from the output of the element OR 48 enters the corresponding input of the element AND 42 and the input of the element NO 46, as a result, the signal from the input of the element And 41 is removed and the element 42 triggers, the signal from the output of which on the third. exit logical block 12, which shows It rains about the result of the control. This signal arrives at the second input of the parameter polling block 16 (Fig. 2, is delayed in the block 34 for the time needed to fix it and make a decision, and then it goes to the first input of the OR element 35, from which the signal goes through switch 36 The generator receives 37 single pulses, the output of which selects the next parameter in this way, with the result of the control, the object rate of the control, according to the parameter y, and with V, the parameters x - x are monitored to determine the manifestation of the defect at an early stage. 14 When polling the parameters x, the appearance of an open circuit from the control object 19 to the second adder 4 there is no signal at the second input about the second adder 4, which leads to the release of the zero-organ 9, the asymmetrical trigger 13, the switches 20 and 31. The release of the unbalanced trigger 13 leads (similarly to the described above) to the removal of the resolution on the formation of the control result. The norm of the control object and the appearance at the third output of the logic block 12 of the signal. The scoring of the control object that goes to the second input of the parameter polling block 16 and then to the input of the delay unit 34, from the output of which through the time interval T., the signal arrives at the first input of the OR element 35, and after it triggers to the input of the switch 36 key. Releasing the switch 20 causes the signal from the outputs of the block 14 prediction. Removing the signal from its first output results in releasing the nullorgan 26, which leads to the removal of the signal from the input of the OR-NOT 28 element, the output of which is a signal arriving at the zero input of the trigger 30 and leading to the release of the latter, which leads to return the switches 6 and 36 to its original state. Connecting the output of switch 6 to its first input leads to the input to the inputs of null-organs 7-11 of a signal carrying information about the parameter y, which ultimately results in the appearance at the first output of logic unit 12 of the signal. The norm of the control object that arrives at the second input of the AND element 27 control unit 15. Since the null organ 26 is in the initial state, the signal at the first input of the AND 27 element is absent and the trigger 30 does not trigger. Thus, when an open circuit in the control device from the control object 19 to the second adder 4 during the parameter polling occurs (after the result of the result of the control object is rejected), the control device switches to control parameter y while simultaneously removing the signal from the second output of prediction unit 14. In the event of an open circuit from the second adder 4 to the switch 6, similarly to that described above, the second output of the logic unit 12 appears on the signal. Rejection of the tolerance control device. The effect of short-duration signals on the second and third outputs of logic unit 12 when switching switches 18, scaling unit 17 and switch 6 to the device operation is compensated for by selecting inertial switch 20 of prediction unit 14 and, if necessary, setting the HE element 44 and And 42 element at the outputs. delay blocks. The presence of the signal at the first input of the element 24 leads to the appearance at the moments of the impulse output of the generator 24 pulses at its output and the second output of the prediction signal 14 of the signal corresponding to the time remaining until the moment у. This signal can be issued to the registration unit 38 to evaluate the nature of the processes in the control object and to ensure its operative control. With the result of control, the Norm of the object of control and the achievement of equality with 22 and. transmitting a zero-body 26 (FIG. 2), removing the signal from the first input of the element AND 27 of the control unit 15, as well as from the first input of the element OR NOT 28. Removing the signal from the input of the last leads to a signal at the zero input of the trigger 30 and return it to its original state. In this case, the absence of a signal at the second input of the second element OR 28 is provided by a delay unit 32. The return of the trigger 30 to the initial state leads to the removal of signals from the control inputs of the switch 6 and the switch 36 of the parameter polling unit 16, which leads to the return of the latter to the initial state (combining the first input of the switch 6 with its output and opening the switch 36) . Thus, the output of the adder 3 is connected to the null-bodies 7-11, to the second input of which a signal is received, corresponding to the parameter y. When the control result for this parameter is normal, and the continuation of the condition Upj, Uj-jc does not occur in the device, it monitors the determining parameter y, the value and rate of change of which in accordance with expression (2) indicates the proximity moment when y. If the control object N object of the control meets the condition J (Uj-jj, then the null-body 26 is triggered, a signal appears at its output, which, together with the signal from the first output of logic unit 12, in the same way as described, triggers trigger 30, switches 6 and 36. The polling of the parameters x - x, starting from the previously selected one, continues. If, with the fulfillment of the condition, the null organs 8 and 10 are triggered, then signals appear on the second and fourth inputs of logic unit 12 (FIG. H) to the operation of elements AND 40, OR 4 8, NOT 46 and I 42. This leads to the removal of the signal from the input of the element And 41 (permission to form the result of the control) and the appearance at the third output of the logical block T2 of the signal about the result of the control. Reject of the control object. This signal (Fig. 2) through the switch 31 and the delay unit 32 of the control unit 15 is fed to the input of the trigger 33 and triggers it, which leads to removing the signal from the zero input of the trigger 30 and sending a signal to its single input - triggering the trigger 30. Next, the switches 36 are switched as described above and 6, it leads to the survey parameters x - x "and the definition of those who came out of tolerance. In this case, the reliability of maintaining the triggered state of the trigger 30 is ensured by the absence of a signal at the zero input of the trigger 33. Parameters are polled before the trigger signal 33 is applied to the zero input, which allows, if necessary, the analysis of the control object in its development. When polling the parameters x - x, and the appearance of an open circuit from the control object 19 to the second adder, there is no signal at the second input of the second adder 4, which leads to the release of the zero-organ 9, the asymmetrical trigger 13 and the switches 20 and 31. Releasing the unbalanced trigger 13 leads to the appearance at the third output of the logic unit 12 of the signal of the control object, which is fed to the second input of the parameter polling unit 16 and then to the input of the delay unit 34, from whose output through the time interval Tj4. the signal arrives at the first input of the element OR 35, and after it. actuation - to the input of switch 36. This signal from the third output of logic unit 12 is fed to the third input of control unit 15 and further to the input of the open switch 31. Since the trigger 33 triggered earlier, it can only be returned to its initial state the signal input, therefore, the trigger 30 is in the same state, which causes the switches b and 36 to remain in the same state. Therefore, the process of polling the parameters continues until a signal 33 is applied to the zero input of the trigger 33.

Similar processes occur in the device and when the result is

Control A scrambled object of a control caused by the triggering of null organs 8 and 10 immediately after connecting the volume 19 of the control to the device.

The proposed device can be used to control the parameters of complex systems in which the dependence y f (x, k ..., x) does not occur. In this case, one of the most significant or alarm parameters is taken as a parameter. The device can also be used to control a large number (n + 1) of objects, the state of which is determined by one parameter, and the objects whose parameters are different.

When the device is operated in accordance with booting (2), there may be a case of dividing by O, therefore, in block 22 for dividing prediction block 14, a signal limiter is set at the output. This value is determined from the conditions of testing or functioning of the object of control, the nature of changes in its parameters.

15

2

-5J

irLin

28

K

one

J0

29

20

t

J3

there

"-H -KJJ

1J

Claims (6)

1. DEVICE DEVICE. CONTROL, containing the first conversion unit, switch, five zero-organs, the outputs of which are connected respectively to the first, second, third, fourth and fifth inputs of the logic block, a trigger, the input of which is connected to the output of the third, zero-organ, and the output - with the sixth the input of a logical unit, characterized in that, in order to expand the functionality and scope of application, a second conversion unit, first and second adders, a signal generator, a control unit, a parameter polling unit, a switch, a block a prediction unit, a recording unit, the inputs of which are connected respectively to the first output of the prediction unit, the first, second and third outputs of the logical unit and the output of the parameter polling unit, the first input of which is connected to the first output of the logical unit, the second input of the parameter polling unit is connected to the third output of the logical unit , the first input of the control unit is connected to the second output of the prediction unit, the second input of the control unit is connected to the first output of the logical unit, the third input of the control unit is connected n with the third output of the logic unit, the fourth input of the control unit is connected to the trigger output, the first output of the signal generator is connected to the first inputs of the first and second adders, the second output of the signal generator is connected to the first input of the prediction unit, the second input of which is connected to the output of the first adder and the first switch input, and the third input with the fourth input of the control unit, the second inputs of the first and second adders are connected to the outputs of the first and second conversion units, respectively, the input the first conversion unit is connected to the first terminal for connecting the output of the control object, the input of the second— conversion unit is connected to the output of the switch, the control input of which is connected to the output of the parameter polling unit, the inputs of the switch are connected to a group of terminals for connecting the outputs of the control object, the output of the second adder connected to the first input of the scaling unit, the second input of which is connected to the output of the parameter polling unit, the output of the scaling unit is connected to the second input of the switch, controlling the input coupled to an output of the control unit and the third input block survey parameters, the switch output is connected to the inputs of all zero-bodies. '' 2. The device according to π. 1, characterized in that the trigger is asymmetric. 3. The device according to p. ^ Characterized in that the logical unit contains four AND elements, four inverters and two OR elements, the first input of the first AND element is connected to the first input of the logical block, the second input of the first AND element is connected to the third input of the logical block, input the first inverter is connected to the sixth input of the logic unit, the first input of the second element And it is connected to the second input of the logic block, the second input is to the fourth input of the logic block, the output of the first AND element is connected to the input of the second inverter and the first input of the first OR element, the output of which is connected to the first input of the third AND element, the output of which is connected to the first output. logic block, the output of the second inverter is connected to the second input of the first OR element, the input of the third inverter is connected to the fifth input of the logic block and the first input of the fourth AND element, and the output is to the second output of the logical block, you One of the first inverter is connected to the first input of the second OR element, the second input of which is connected to the output of the second AND element, the output of the second OR element is connected to the second input of the fourth AND element and through the fourth inverter with the second input of the third AND element, the output of the fourth And element is connected to the third logic block output. 4. The device according to p. 1, characterized in that the prediction unit contains a switch, a difference unit, an element And, a pulse generator, a differentiation unit and a division unit, the output of which is connected to the second output of the prediction unit and to the first input of the element And, the second input of which connected to the output of the pulse generator, and the output to the first output of the prediction unit, the first and second inputs of the difference unit are connected respectively to the first and second outputs of the switch, the control input of which is connected to the third input of the unit forecasting, the first and second inputs connected to the switch lane vym and second inputs of the prediction block unit, respectively, the input differential output coupled to the second switch, the first and second inputs divider connected respectively to outputs of difference and differentiation block unit. 5. The device according to π. 1, characterized in that the control unit contains an AND element, a switch, a zero-organ, an OR-NOT element, a delay unit, the first and second triggers and an OR element, the first input of which is connected to the output of the element And, the first input of which is connected to the output of the zero-organ and the first input of the OR-HE element, the second input of which is connected to the second input of the OR element and the output of the first trigger, the single input of which is connected through the delay block to the output of the switch, the input of which is connected to the third input of the control unit, the control input of the switch is connected to the fourth input of the control unit, the second input of the element And is connected to the second input of the control unit, the output of the zero-organ is connected to. the zero input of the first trigger, and its input with the first input of the control unit, the output of the OR element and the output of the OR-HE element are connected respectively to the single and zero inputs of the second trigger, the output of which is connected to the output of the control unit. ₄ 6. The device according to p. ^ Characterized in that the parameter polling unit contains a single pulse generator, a switch, a delay unit and an OR element, the first input of which is connected to the second input of the parameter polling unit through a delay unit, the input of the switch is connected to the output of the OR element, the second the input of which is connected to the first input of the parameter polling unit, the control input of the switch is connected to the third input of the parameter polling unit, the output of the switch is connected to the input of the single pulse generator, the output of which is connected to Exit block survey parameters.