SU960833A1 - Device for transportation system operation probabilistic simulation - Google Patents

Description

one

Simulation refers to the computing technique and can be used in dp studies of transport systems using instrumental physical modeling.

A device for simulating an incoming flow of a flow is known, comprising shift registers and AND and OR 1 elements.

However, this device does not allow modeling of the transport system as a whole.

The closest technical solution to the invention is a device for probabilistic modeling of the transport system, comprising blocks for modeling the incoming and outgoing flows of the application and a block for modeling the transport system 2.

A disadvantage of this device is that it does not accurately model incoming and outgoing passenger flows.

The aim of the invention is to improve the accuracy of the simulation.

This goal is achieved by the fact that, in a device for probabilistic modeling of the operation of transport systems, comprising a block for modeling the incoming flow, a group of outputs and a group of inputs of which are connected respectively to the group of inputs and the first

to a group of outputs of a group of simulators of transport authorities, the inputs and the second group of outputs of which are connected respectively to the group of outputs and the group of inputs of the simulation block of the outgoing flow 5 applications, each simulator of the transport authority contains two reversible counters, two clock generators, two signal delays, three element NOT, three elements OR and

Claims (3)

20 six AND elements, inputs of the first OR element, are a group of simulator inputs and are connected respectively to the first inputs of the first and second 9 AND elements, the second inputs of which are combined and connected to the output of the first clock generator, whose input is connected to the output of the third And element, three whose inputs are connected respectively to the output of the first delay element of the signal, to the output of the first element OR, and to the output of the first element NOT, whose input is connected to the i-My output of the first reversible through the second delay element The remaining outputs of which, together with the outputs of the second reversible counter, form a group of outputs of the simulator, the output of the first OR element is connected to the first inputs of the fourth and fifth AND elements and the second OR element, the output of which is through the second element is NOT connected to the input of the first signal delay element , the input of the unit is connected to the second input.  the second OR element, with the first inputs of the third OR element and the sixth AND element, and through the third element is NOT connected to the second input of the fourth AND element, the output of which is connected to the second input of the third OR element, the output of which is connected to the input of the second clock generator, the output of which is connected to the second inputs of the fifth and sixth elements AND, the outputs of which are connected respectively to the summing and subtracting inputs of the second reversible counter, the outputs of the first and second elements AND are connected respectively to the sum The primary and subtractive inputs of the first reversible counter, the input flow simulation block contains fvl reversible counters, OR elements, N elements, AND, probability (1, K) -pole, switch, generator of stochastic pulses, random number generator, and generator a random stream of pulses, the output of which is connected to the input of the generator of slz ayin numbers, the output of which is connected to the first inputs of the elements And the second inputs of which are connected to the corresponding outputs of the probabilistic (1, K) -pump, l stochastic imputses connected to the corresponding inputs of the switch, the outputs of which are connected to the third inputs of the corresponding elements And, the outputs of which are connected to the summing inputs of the corresponding reversible meters, subtracting inputs xc-ory connected to the outputs of the corresponding elements OR, whose inputs 34 form a group of inputs of the block, the group of outputs of which are the outputs of reversible counters, in addition, the block for modeling the output flow of the application consists of a group of output generators, each The first of which contains a counter, a generator of regular pulses, an element NOT, eight elements AND, and a driver of stochastic constants, the output of which is connected to the first input of the first element AND, the second input of which is connected to the output of the generator of regular pulses and the second input of which is combined with the third input of the first element AND, and through the element is NOT connected to the code of the third element AND whose inputs are connected to the discharge outputs of the counter, the subtracting input of which is connected to the output of the second The first element And, the output of the first element And is the output of the simulator, the group of inputs of which are the first inputs of the fourth, fifth, sixth, seventh, eighth elements And, the second inputs of which are combined with the inputs of the simulator, and the output connected to the corresponding bottom inlets.  dam counter, In addition, the stochastic constant driver includes N elements AND, N + 1 OR elements, a reverse shift register, a switch and a stochastic pulse driver, the outputs of which are connected to the corresponding inputs of the switch, the outputs of which are connected to the inputs of the corresponding first N elements OR, outputs which are connected to the nepBbnvra inputs of the corresponding elements AND, the inputs of which are connected to the corresponding inputs of the (M + 1) -th element OR whose input code is the output of the former, whose input is The summing and subtracting inputs of the reverse shift register, the outputs of which are connected to the second inputs of the corresponding elements I.  In this case, the stochastic pulse shaper contains seven delay lines, four NOT elements, three OR elements and nine AND elements, the outputs of which, as well as the outputs of all NOT elements, the outputs of the first four delay lines and the output of the first OR element, form a group of shaper outputs, the input of which is connected to the first inputs of the second I / O element and the third OR element, the output of which is connected via its fifth and sixth delay lines to its second input and to the input of the seventh delay line, the output of which is connected to the first inputs of all EX elements And, the output of the second element OR is connected to the input of the first delay line, the output of which is connected to the second input of the first element.  And, through the first element NOT - with the second input of the second element And directly with the input of the second delay line, the output of which is connected to the second input of the third element And, through the second element NOT to the second input of the fourth element And, and directly with the first input of the first ele OR, whose output is connected to the second code of the fifth element AND, the output of the second delay line is also connected to the input of the third delay line, the output of which through the third element is NOT connected to the second input of the sixth element and directly to the second input the seventh element AND, the second input of the first OR element and the input of the fourth delay line, the output of which through the fourth element is NOT connected to the second input of the eighth AND element and directly to the second inputs of the ninth AND element and the second OR element.  FIG.  1 shows a block diagram of the device; in fig.  2 is a diagram of a transport authority simulator; in fig.  3 - block diagrams of the simulation of the input flow rate; pas figs.  4 - diagram of the simulator for quitting the wok; in fig.  5 is a diagram of a shaper of stochastic constants; in fig.  6 is a diagram of a shaper of stochastic pulses; in fig.  7 - times for a plot showing the work of transport of someone in charge.  Device (.  1) contains an input flow simulation block 1, a group of outputs and a group of inputs of which are connected respectively to the first group of inputs and the first group of outputs of a group of simulators 2 transport authorities, the inputs and the second group of outputs of which are connected respectively to the group of outputs and the group of inputs of the block 3 modes of lirani downstream flow.  Each vehicle simulator (FIG.  2) contains two reversible counters 4 and 5, two oscillators 6 and 7 clock pulses, two elements 8 and 9 of the delay signal, three elements NOT 1О12, three elements OR 13-15, and six elements AND 16-21, the inputs of the element OR 13 are, respectively, the first and second inputs of the simulator and are connected respectively to the first inputs of the elements AND 16 and 17, the second inputs, which are combined and connected to the output of the first generator 6 clock pulses.  The input of which is connected to the output of the element 18 and the three inputs of which are connected respectively to the output of the first element 8 of the delay of the sirnal, to the output of the element OR 13 and to the output of the first element NOT 10, whose input through the second delay 9 connected to the 1st output of the first reversible counter 4, the remaining outputs of which, together with the outputs of the second reversible counter 5, form a group of outputs of the simulator, the output of the first Element OR 13 is connected to the first inputs of elements AND 19 and 20 and the second element OR 14, the output of which through the second ele ment NOT 11 is connected to the input of the first element 8 of the signal delay, the input of the block is connected to the second input of the second element OR 14, to the first inputs of the third element OR 15 and the element AND 21 and through the third element NOT 12 connected to the second input of the element 19, whose output connected to the second input of the third element OR 15, the output of which is connected to the input of the second oscillator 7 clock pulses, the output of which is connected to the second inputs of the elements AND 20 and 21, the outputs of which are connected with the summing and wiping inputs of the second reverse vnogo counters.  5, the outputs of the gmev terminals AND 16 and 17 are connected respectively to the sutramming and subtractive inputs of the first reversible counter 4.  The unit 1 modulates the incoming flow of flow (FIG.  3) contains N reversible counters 22 ,, - 22, VI elements OR, N elements AND 24. 24 J, a probabilistic (1, K) -pass 25, a switch 26, a stochastic pulse generator 27, a random number generator 28 and a random pulse generator 29, the output of which is connected to the input of the random number generator 28, the output of which is connected to the first inputs of the AND elements 24, the second inputs of which are connected to the corresponding inputs of a probabilistic (1, K) -period 25, the forkshreater 27 outputs of stochastic pulses are connected to the corresponding BxonaNni switch 26, the outputs of which are connected to the third inputs of the corresponding: element And 24, the outputs, which are connected to the summing inputs of the corresponding reversing K) counters 22, the subtractive inputs of which are connected to the outputs of the corresponding elements OR 23, the inputs of which form the group of inputs of the block, the group of outputs of which are the outputs of the reversible counters 22.  The unit 3 for simulating the outgoing flow is quitted, out of the group of simulators AOR, go beyond the wok (Fig.  2), each of which contains (FIG.  4) a counter 31, a generator of 32 regular pulses, an element NOT 33, eight elements AND 34-41 and a generator 42 of stochastic constants, the output of which is connected to the first input of the element 34, the second input of which is connected to the output. generator 32 regular pulses and with the first input element I.  35, second entrance KOTOp6. ro is combined with the third input of the AND 34 element and through the NE 33 element is connected to the output of the AND 36 element, whose inputs are connected to the bit outputs of the counter 31 of which is the subtracting input. It is connected to the output of element 35, and the output of element 34 is the output of a simulator, the group of inputs of which is the first inputs of elements AND 37–41, the second input of which is combined and is the input of the simulator, and the outputs are connected to the corresponding digit inputs of the counter 31.  .  The shaper 42 of stochastic constants contains (FIG.  5) N elements And 43. -43. ,,.  M + 1 elements OR.  lN / IN reverse shift register 45, switch 46 and shaper 47 stochastic pulses, the outputs of which are connected to the corresponding inputs of the switch 46, the output of which is connected to the inputs of the corresponding first I elements OR 44, the output of which is connected to the first inputs of the corresponding elements And 43, the outputs of which are connected to the corresponding inputs of the (L + 1) -th element OR 44, the output of which is the output of the former, the inputs of which are the summing and subtracting inputs of the reverse shift retter 45, the outputs of which go connected with the second in; moves respectively.  elements And, Shaper 47 stochastic pulses (fi. year  6) contains seven delay lines 48-54, four elements HEi 55-58, three elements OR 59-61 and nine elements AND 62-70, the outputs of which, as well as the outputs of all elements NOT 55-58, the outputs of the first four delay lines 48-51 and the output of the element OR 59 form a group of outputs of the drivers, the input of which is connected to the first inputs of the element OR 60 and the element OR 61, the output of which is connected through its fifth 52 and sixth 53 delay lines to its second input and to the seventh difference 54 , the output of which is connected to the first inputs of all elements AND 62-7O, the output of the element OR 60 connect ene to the input of the first delay line; the output of which is connected to the second input of the element 62 and through the element NOT 55 to the second input of the element 63 and directly to the input of the second delay line 49, the output of which is connected to the second input of the element 64 and through the element 56 to the second input of the element II 65 and directly to the first input of the OR element 59, the output of which is connected to the second input of the AND 66 element, the output of the second delay line 49 is also connected to the input of the third delay line 50, the output of which through the NOT 57 element is connected to the second input of the And 67 element and directly with the second entrance u ementa and 68; with the second input of the element OR 59 and with the input of the fourth line 51 of the delay, the output of which through the element NOT 58 is connected to the second input And 69 and directly to the second inputs of the element And 70 and the element OR 60.  This device allows you to simulate any transport system.  For definiteness, the description below for the most specific transport system is for the elevator.  The system works as follows.  The reproducible process can be interpreted as a temporal plot of modeling the accumulation processes of a queue on the floor, waiting. . lift cabin passengers, for. loads of cabins and trips of passengers to the specified floors (FIG.  7).  Suppose that at the time point A on the first floor the first passenger prische to take the trip up and pressed the call button.  From this moment, the waiting time begins for this passenger.  Suppose further that at this moment the booths of the lifters and II are free and in a state of downward movement.  After a certain period of time (point 5 on the time axis), due to the speed and distance traveled, cabin i will arrive on the first floor.  During this period of time on the first floor it is possible that new passengers will arrive in order to travel upwards.  We denote them by numbers 2, 3. . . , eight.  Suppose you are lifting (x: 6 people cabins).  Then at time B, passengers with numbers 1, 2, will enter the cabin. . .  6, the waiting time for them at that moment ends and the journey time (service) begins.  Waiting times for passengers with numbers 7 and 8 will end at time B, when on the first floor there will be a cabin.  At the same time, the waiting time will also end for passengers who came to the floor after the departure of cabin I, t. e.  in the time span FB (passengers with numbers 9, 10 and 11).  Enter the cabin, passengers give. orders (push buttons) ride to pre-set floors.  Suppose that passengers 2 and 6, caught in the cabin I, natcff go to the 4th floor.  On this floor, the cabin will arrive at an interval of time p.  T, determined by the distance to 4-. of the first floor and the speed of the cab.  At time T, the journey time (service Zhiwaki) of passengers 2 and 6 ends.  Similarly, suppose that passengers 1, 3 and 5 wish to go to the last floor. The cabin will arrive at this floor after the time interval of the BR, determined by distance, skrost, number of stops and loss of time for stops, acceleration and deceleration of the cabin. 3 trip times for passengers 1, 3 and 4 end.  Similarly, according to the diagram, it is possible to determine waiting times and trips for anyone. go the passenger.  The time interval In I rai time, circulation (round trip) cab II.  The considered work cycle is one of the simplest; and only aims to show the flow of all simulated npoiueccoB in time.  In fact, the cycle of operation of vertical transport is much more complicated (passing calls are serviced, their priority is determined, and so on. d. ).  The device works as follows.  Blocks 1 and 3 simulations of the input and output flow are simulated. random flows arriving at the inputs of simulators of 2 transport agencies (for example, elevator cars) and specifying moments and.  the number of logged in and out of the system for wok (passengers).  Consider the work of the simulator 2 of the transport authority (Article. As such, for example, an elevator car can be considered; FIG.  2).  All the terminology described below specifically characterizes an elevator, but the principle of operation is valid for any transport authority.  The cockpit simulator reproduces the launch of the cab, motion up and down, counting the number of passed egas, osganov exit and entry of passengers, loss. time for acceleration, deceleration, door operations, movement in the express zone.  The principle of operation of the unit is to follow.  Counter 4 together with generator 6 imitates the movement of the cabin, the elements 16 and 17 show the direction of movement of the cabin, and the elements NOT 1O and delay 9 9 its movement in the express zone.  Counter 5 together with generator 7 simulate loading and unloading of the cab.  Elements And 20 and And 21 distinguish between loading and pa; cabin load  The operation of the circuit proceeds in the following sequence.  When a call occurs on any floor, the Up or Down command appears.  Any of these commands through the elements OR 10 and AND 18 starts the generator 6, which through one of the elements AND 16 and 17 starts the counter 4.  The latter simulates the movement of the cabin from floor to floor.  The cabin can be stopped due to the execution of the call or due to the execution of the order.  When the call is executed, the Call command arises, which through the elements OR 14, NOT 11, delays 8 and AND 18 stops the generator 6 for the time of the standing of the branch and switches on the generator 7 through elements AND 19 and OR 15.  The latter, through element 20, turns on the addition counter 5, which imitates the entrance of passengers into the cabin.  Simulation of passenger exit from the cabin is based on specifying the probabilities of the R-code of one passenger on the –N floor with subsequent modeling of each exit.  is located in the passenger cabin with a probability of P-j when the cabin arrives at the j-th floor.  Yelok 1 simulation of the entry flow of the application (all terminology in describing it is from the elevator hex, but its work is valid for any type of transport) simulates the process of passengers coming to the elevator hall, the emergence of calls, the formation of queues on the floors, the processes of passenger entry in cabins, bursts downs and ex.  Calling.  A specific feature of the elevator system is the presence of a large number of independent parallel passages.  In the general case, to simulate them, it is necessary to have the same generators of the incoming flow of passages.  A natural way to simplify a scheme is to try to use not one common to all input channels (floors) of the passenger flow generator.  For this, the so-called P-conversion of the incoming passenger flow can be applied whereby each approach of the flow with probability P is sent to the -f channel and with probability P-j is not sent to this channel, t. e.  sent to some other channel.  The intensity of the generator of the incoming passenger flow is determined by the expression 1.  where is the passenger flow rate on the 1st floor; N is the number of channels.  The generator 29 models the simplest noiOK approaches.  The flow parameter on the vy run of this generator is determined by the relation - / Z; i; (2) where X. J is the approach flow parameter on the i-th floor.  Each K and (, 2, 3. . . The pulse of the generator 29 is a polling number for the random number generator 28, according to which a random number W1 is formed at the output of the random number generator 28.  Each successive random number from the output of the generator 28 through the element AND 24 - (, 2,3. . . ,) enters cy. vfM is the input of the i-th counter 22 with probability P, which is formed in the following way.  Elements And 24 open the signal with the output of the probable (1, K) by. cku nickname 2S.  At the moment of occurrence of a random random number at the output of the generator 28 with equal probability P, one of the elements AND 24 is opened, and the random number is fed through this element AND to the input of the counter 22.  The accuracy of P is determined by how the intensity of A is determined If the simplest flow (in this case of approaches) is subjected to a P-conversion.  In addition, the transformed flow is also simple with the parameter Γ - P. In solving practical problems, both the case and the case of Li can occur.  or any combination of conditions (5) and (6).  if necessary, simulate the condition (6) is chosen A. -J. , X, it is determined by the value of L.   for other channels, a reduction factor is introduced (which is generated by the shaper of 27 stochastic pulses.  At the third entrance of the element And 24.  The resolution of the slc is present during the time-fc C – T, which leads to a decrease in the intensity X to the value X. , yy, aX Hence, the validity of the sign is clear.  in vfhenzhen x (1) and (2).  Subtracting B (the moves of the SI counters through the elements OR from the simulators of the booths receive impulses imitating the entrance of passengers into the cabins  The non-zero state of any counter simulates the presence of a call in the data. ; i channel (floor).  The simulator 30 go behind the wok works in the following way.  At the moment the cab approaches the i-th floor of the readout impulse SI, the cab load code through elements C 3741 is transferred to counter 31, as a result of which AND 36 closes, a high level of signal appears at the output of HE 33 and elements AND 34 and 35 are unlocked .  Clock pulses from the output of the generator of 32 pulses, open the element And 34 and through the element 35 and arrive at the subtractive input of the counter SI.  Random pulses from the output of the generator of 42 stochastic constants occur at the clocked times of Bpe meni with probability P and pass through the And 34 element to the output of the circuit.  The drawing process continues until the counter 31 arrives in the zero state, at which the AND 36 element operates, as a result of which the AND 34 and 35 elements are closed.  The number of impulses generated at the output of the circuit imitates the number of outgoing passengers.  When the simulator of the cabin moves from floor to floor, the described process is repeated.  Only the probability Pj of the occurrence of pulses at the output of the driver 42 varies.  Functional diagram of the change in the probabilities Pj when the cabin moves from floor to floor for a twenty four-storey building (Fig.  5) works as follows.  The movement of the cockpit is monitored by a reverse counter 45.  At the same time, when the cabin moves from the floor to the floor, the output signals of the reversible counter 42 successively open the E 43 elements.  The second inputs of these elements receive signals, the durations of which are proportional to the specified probability values from the outputs of the elements OR 4 Pulse sequences from the output of the shift register 45 are pulses that occur at random points in time.  Consequently, the pulses at the outputs of the elements And 43j also appeared to be accidental and temporarily.  The probability of occurrence of these pulses at the time of polling elements AND 43V signals from the outputs of register 45 is determined by the duration of the signals at the outputs of the elements OR 44 By setting these durations, you can set the values of P: the probability of an exit of one passenger on the j-th floor.  The signals from the outputs of the elements And 43j with probabilities P; through the element OR 44 arrive at the output of the circuit.  Shaper of stochastic pulses (FIG.  6) works in the following way.  The task of this block is to form at its outputs a time interval of a predetermined duration, reflecting the probability value for use in subsequent blocks.  Since the instants of time for the occurrence of these time intervals are not synchronized with the operation of those blocks where og is used, they occur randomly in mjc.  The duration of the intervals determines the probability of their presence at a given time.  The basis of the block was Kug line 4854 delay.  The first four lugnii 48-51 delays through the element OR 60 are closed in a ring.  One cycle of triggering these latencies is conditionally taken as one.  The time intervals at the outputs of the delay lines are chosen in such a way that they comprise, respectively, the following fractions: at the output of the first delay line 0.4; the second is 0.3; third 0, 2; fourth - OD.  All these internals of time are delivered to the shaper output.  The output of the imager also receives signals from the outputs of the delay lines passed through the HE elements 55-58, at the outputs of which time intervals are formed, which consist of 1 unit of the following, respectively: the output element HE 55 - 0.6; He element 56 0, 7; the element HE 57 - 0.8; element HE 58 - 0.9.  The signals from the outputs of the second and third delay lines add up to the element OR 59, as a result of which the output of the latter has a time interval of 0.5 of one.  The first and sixth lines 52 and 53 of the delay through the element OR 61 are closed into a ring, the period of which is not a multiple of the period of the first ring.  At the output of the seventh delay line, a time interval is formed once per period, the duration of which is 0.1 of one.  Since the periods of the first and second rings are not multiples, the coincidence of any of the signals of the first ring with the signal from the output of the delay line 54 is random, if we consider an arbitrary time instant.  This coincidence takes place at the inputs of the AND elements, which, in essence, multiply the probabilities, and therefore on them.  outputs form hundredths of probabilities, which also arrive at the generator output.  The first inputs of the elements OR 60 and 61 are given triggering impulses.  The effect of the application of the invention is achieved by increasing the accuracy of modeling passenger traffic.  Claim 1.  A device for probabilistic modeling of transport systems containing an input flow modeling block of a flow, a group of outputs and a group of inputs of which are connected respectively to a group of inputs and the first group of outputs of a group of transport authority simulators, the inputs and the second group of outputs are connected respectively to a group of outputs and a group of inputs of the output flow simulation unit behind the codody assembly of the transport unit contains two reversible counters, two clock generators, two elements This delay, three NOT elements, three OR elements and the AND elements, the inputs of the first OR element are a group of simulator inputs and are connected respectively to the first inputs of the first and second AND elements, the second inputs of which are combined and connected to the output of the first generator of pulses; which is connected to the output of the third element And, the three inputs of which are connected respectively to the output of the first delay element, to the output of the first element OR and the output of the first element NOT, whose input through the second delay element n dk; poken to the i-th output of the first reversible counter, the remaining outputs of which form the first group of outputs of the simulator, the outputs of the second reversible counter form the second group of outputs of the simulator, the output of the first element OR is connected to the first inputs of the fourth and p Togo elements And and the second element OR, the output of which through the second element is NOT connected to the input of the first delay element, the input of the simulator is connected to the second input second. th element OR. The first element was the input of the third element OR and the generic element AND, and the third element is NOT connected to the second input of the fourth AND element, the output of which is connected to the second input of the third OR element, whose output is connected to the input of the second clock generator, the output of which is connected to The second inputs of the fifth and sixth elements AND, the outputs of which are connected respectively with the summing and subtracting inputs of the second reversible counter, the outputs of the first and second elements And are connected respectively with the sum of the aggregation and the calculation by melting inputs of the first reversible counter, characterized in that, in order to increase the accuracy of the simulation, the input flow modeling block contains N reversible counters, N OR elements, N And elements, probability (1, K) -plot, switch, shaper of stochastic pulses, random generator and generator of random pulse flow, the output of which is connected to the input of a random number generator, the output of which is connected to the first inputs of the And elements, the second inputs of which are connected to the corresponding outputs probabilistic (1, K) -polar, the shaper outputs of the stochastic stubs are connected to the corresponding inputs of the switch, the outputs of which are connected to the third inputs of the corresponding I elements, the outputs of which are connected to the summing inputs of the corresponding reversible counters, the subtracting inputs of which are connected to the outputs of the corresponding elements OR, the inputs of which form a group of inputs of a block, a group of outputs of which are outputs of reversible counters, 1 of which is the output flow simulator block It is from a group of output generators, each of which contains a counter, a generator of regular pulses, an element NOT, eight elements AND, and a generator of stochastic constants, the output of which is connected to the first input of the first element And, the second input of which is connected to the output of the generator of regular pulses and with the first input of the second element And, the second input of which is combined with the third input of the first element And, and through the element is NOT connected to the output of the third element And whose inputs are connected to the discharge outputs of the counter, subtract The input of which is connected to the output of the second element I, the output of the first element I is the output of the simulator, the group of inputs of which are the first inputs of the fourth, fifth, sixth, seventh, eighth elements AND, the second inputs of which are combined and are the input of the simulator the outputs are connected to the corresponding bit inputs of the counter. 2. The device according to Claim 1, that is, that the driver of the stochastic constants contains N elements AND, N + 1 OR elements, the reverse shift register, the switch and the driver of the stochastic pulses, the outputs of which are connected to the corresponding inputs of the switch, the outputs of which are connected to the inputs of the corresponding first N elements OR whose outputs are connected to the first inputs of the corresponding AND elements, the outputs of which are connected to the corresponding inputs of the (N + l) -ro OR element whose output is the form output bodies, whose input is kpgs summing and subtracting inputs of the reversible shift register outputs are connected to second inputs of corresponding elements I. 3. Device according to Claims 1 and 2, characterized in that the driver of stochastic pulses contains seven delay lines, four NOT elements, three OR elements, and nine AND elements, the outputs of which, as well as the outputs of all the NOT elements, the first couple outputs . The dex delay lines and the output of the first OR element form a group of outputs of the imaging unit whose input is connected to the first inputs of the second OR element and the third OR element, the output of which is connected to its second input and the seventh delay line through the fifth and sixth delay lines. The output of which is connected to the first inputs of all elements AND, the output of the second element OR is connected to the input of the first delay line, the output of which is connected to the second input of the first element AND, through the first element NOT to the second input of the second element AND, and directly to the input of the second, line delay, the output of which is connected to the second input of the third element AND, through the second element NOT to the second input of the fourth element AND, and directly to the first input of the first OR element, the output of which is connected to the second input of the fifth And element, output to The delay line is also connected to the input of the third delay line, whose output through the third element is NOT connected to the second input of the sixth AND element and directly to the second input of the seventh AND element, to the second input of the first OR element and to the fourth delay line input, the output of which is through the fourth the element is NOT connected to the second input of the eighth element AND, and directly to the second inputs of the nineth element AND and the second element OR. Sources of information taken into account in the examination 1. USSR author's certificate number 438988, cl. G About F 7/58, 1973. 2. Authors svdet.-lionstvo USSR №.446885, cl. G About G 7/48, 1973 (prototype). 1 Fig 2 phage.5 H: II L I I Oww oHueI Service  I I l Offcji fKuSoHue Dmuoafiue. FIG. 7