SU886012A1 - Function generator - Google Patents

Description

(54) FUNCTIONAL CONVERTER

Claims (2)

This invention relates to functional transducers of electrical signals and can be used in analog computers. A signal converter is known by law, containing a control unit of a linear voltage generator, a power converter and an amplifying unit of a power supply unit. However, the known device converts the signal only according to a power law. The closest to the proposed is a functional converter containing keys, integrators, comparator, control unit and reference voltage source 1.21. The specified device allows only a time interval proportional to the power polynomial from the input voltage to be obtained. The purpose of the invention is to expand the class of reproducible 1x functions. The goal is achieved by the fact that in a functional converter containing a first key connected in series and a first integrator, a second integrator, a comparator whose input is connected to the output of a reference voltage source, a control unit, a second key, first and second bit switches, connected respectively the input and output of the first and second integrators, BXOjVd of the first and second keys are connected to the input of the functional converter, the first output of the control unit is connected to the control input of the first A second key, the second output of the control unit is connected to the control input of the first bit key, a voltage converter in the pulse capacity, a memory unit, a trigger, an adder and the first and second additional keys are entered, the comparator output is connected to the trigger input, the inverse trigger output connected to the auxiliary control input of the first key and to the control input of the second auxiliary key, the forward output of the trigger is connected to the control inputs of the second key and the second bit of the key, you move the first input through the first additional key is connected to the first input of the memory block, to the second input of which the output of the second key is connected, the output of the memory block to the second additional key is connected to the input of the converter for voltage to the pulse width and to the second input of the comparator, the output of the converter The pulse width is connected to the input of the control unit, the third output of which is connected to the ugravluyu input of the first additional key, the first input of the adder is connected to the input of the functionally a transducer output of the second integrator is connected to the second input of the adder, whose output is the second output unit and the memory are respectively first and second outputs of the function generator, the second input latch podklyuchen.ko triggering input converters are functional inputs of the first and second integrators connected. In addition, the control unit contains a counting trigger and the first and second elements of NAND, the input of the counting trigger is connected to the input of the control unit and the first input of the first NAND element, the second input of which is connected to the first input of the second element NAND, the second input which is connected to the output of the first element IS-NOT, which is the first output (5 control box, the output of the second IS-element is the second output of the control unit, the first input of the second AND-NO element is the third output of the control unit. The functional circuit of the proposed converter.The functional converter contains first and second and 11 integrators 1 and 2, control block 3, comparator 4, voltage converter 5 to pulse width, trigger 6, adder 7, memory block 8, first key 9, first key 10, second class | 8h 11, second bit key 12, first and second additional keys 13 and 14, voltage source 15, input 16, start input 17, first and second outputs 18 and 19 of the functional converter, counting trigger 20, the first and second elements AND-NOT 21 and 22. Functional the inverter works as follows. Before the pulse is applied to the start input 17, the comparator 4 sets the trigger 6 to a state in which the high potential at its inverse output opens the keys 9 and 14, and the low potential of the direct output closes the keys P and 12. The signal from input 16 through the key I1 is memorized in memory block 8 and simultaneously applied to the adder 7. At the moment of arrival of the pulse to the input 17, the trigger 6 switches, the keys 1I and 12 open, the key 14 closes, and the additional control input of the key 9 decreases the disconnect signal. The memorized input voltage in the memory unit 8 through the closed key 14 is applied to the input of the unit 5, at the output of which rectangular pulses are formed with a duration proportional to the input voltage. These pulses go to control unit 3 at the input of counting trigger 20. Counting trigger 20 is thrown at the negative front of each pulse and at the moment when a single state is set at its direct output, key 10 closes and the first integrator zeroes. In this case, the voltages corresponding to the magnitude of the input signal are set at the first and second outputs 18 and 19. At the time the key 10 is opened, the key 9 closes and the input voltage is integrated by the first and BTopbiM integrators i and 2. At the time of the key 9 is opened, the outputs of the first and second integrators 1 and 2 are set to a voltage proportional to the ratio of the square of the input voltage to a constant time integrating the appropriate integrator. At the same time, the key 13 closes and the output voltage of the first integrator 1 is stored in memory block 8, and the output of the adder 7 sets a voltage equal to the sum of the input voltage rt of the output voltage of the second integrator 2. Block 5 generates pulses, the first of which is negative front 58 closes the key IO and zeroes the first integrator 1, and the second opens the key 10 and closes the key 9, thereby integrating the input voltage during the generated pulses. The negative edge of the third pulse opens the key 9 and switches on the key 13. The output voltage of the memory block 8 is again applied to the input of the block 5, and the operation cycle repeats. When t is repeated, similar cycles on the first and second outputs 18 and 19 are set to voltage where Ujx - voltage on input l - scale factor of voltage converter 5 to pulse width} T / | HTjj - constant integration times of first and second integrators respectively 1 and 2. When the voltage at the output of the memory block 8 reaches a value equal to the voltage of the source 15 of the reference voltage, the comparator 4 is triggered and the trigger 6 is transferred to the zero state, as a result of which the functional converter is set injecting into the initial state. The proposed functional transformer allows one to solve a wider class of problems in comparison with the known one. Claim 1. Functional converter comprising connected sequences, first key and first integrator, second integrator, comparator, the first input of which is connected to the output of the reference voltage source, control unit the second key, first and second bit switches connected between the input and output of the first and the second integrator, the inputs of the first and second keys are connected to the input of the functional converter, the first output of the control unit,. 4. connected to the control input of the first key, the second output of the control unit is connected to the control input of the first bit switch, characterized in that, in order to expand the class of reproduced functions, a voltage to pulse converter, a memory unit, the trigger, the adder and the first and second additional keys, the comparator output connected to the trigger input, the inverse trigger output connected to the additional control input of the first key and to the control input of the second additional key a, the direct output of the trigger is connected to the control inputs of the second key and the second bit key, the output of the first integrator through the first additional key is connected to the first input of the memory unit, to the second input of which the output of the second key is connected, the output of the memory unit through the second additional the key is connected to the input of the voltage converter in the pulse duration and to the second input of the comparator, the output of the voltage converter in the pulse duration is connected to the input of the control unit, the third output of which is connected Yuchen to the control input of the first additional key, the first input of the adder is connected to the input of the functional converter, the output of the second integrator is connected to the second input of the adder, the output of which and the output of the memory unit are respectively the first and second outputs of the functional converter, the second trigger input is connected to the input start the functional converter, the inputs of the first and second integrators are connected. 2. The converter according to claim 1, in that the control unit comprises a counting trigger and the first and second elements of NAND, the input of the counting trigger is connected to the input of the control unit and the first input of the first NAND element, the second input of which is connected to the first input of the second IS-NOT element, the second input of which is connected to the output of the first AND-NOT element, which is the first output of the control unit {w, the output of the second AND-NO element is the second output of the control unit, the first input of the second acenthe IS-NOT It is the third output of the control unit. and. Sources of information taken into account in the examination USSR certificate 06 Q 7/20, 1977. USSR certificate 06Q 7/26, 1974.