RU2034399C1 - Test sequence generator - Google Patents

Abstract

FIELD: pulse technique. SUBSTANCE: generator has timing resistors 1-7, isolating diodes 8-14, first MIS transistor 15, seventh MIS transistor 2 with induced n-channel whose drains are connected, respectively, to first output 22 and seventh output 28 of generator, first 2NOR gate 29, second 2NOR gate 30, pulse generator 31, chatter-free button 32, pulse distributor 33; pulse generator 31 has BISPIN device 34, first MIS transistor 35 with induced n-channel, second n-p-n transistor 36, diode 37, timing capacitor 38, eighth resistor 39, eleventh resistor 42. Chatter-free button 32 has third 2NOR gate 43 and fourth 2NOR gate 44 both connected into RS flip-flop circuit, twelfth and thirteenth resistors 45, 47, power supply 48, common bus 49. EFFECT: improved design. 2 cl, 1 dwg

Description

 The invention relates to a pulse technique and can be used in automation devices.

 Known three-phase pulse generator (Handbook of microelectronic pulsed technology. / Edited by V.N. Yakovlev. K. Technique, 1983, p.146, Fig. 6.12).

 However, in such a generator, the pulse of subsequent phases coincide in time with the pulses of the previous phases, which does not allow the use of such generators to control processes whose coincidence in time is unacceptable or impossible.

Also known is a generator of test sequences, consisting of series-connected single vibrators [1]
However, with the number of single vibrators more than five, such a generator becomes bulky (contains a significant number of elements), labor-consuming to manufacture and consumes a significant current from the power source.

 Closest to the proposed solution is a pulse-width modulator [2] next, a test sequence generator, consisting of a master oscillator, counter, switch and output driver with switched commutator, timing resistors, with the switch inputs connected to the counter outputs and the output of the master oscillator (hereinafter pulse generator) is connected to the input of the counter directly and through the first logic element to the input of the output driver. Hereinafter, the counter and the switch will be referred to as a pulse distributor, because perform a similar function in the prototype and in the claimed solution: connecting the timing resistors to the timing capacitor.

 The disadvantage of this solution is the increased complexity due to the presence of a pulse generator and an output driver (single vibrator).

 The aim of the invention is the expansion of functionality and simplification of the device.

 This goal is achieved by the fact that in the test sequence generator containing the first and second logic elements, a pulse generator, a pulse distributor with connected to its outputs, in addition to zero 1.N, timing resistors, the control input of which is connected to a common bus, N diodes are additionally introduced connected by cathodes to the integrating input of the pulse generator, and by anodes to the second terminals 1.N of timing resistors, respectively, N MOS transistors with an induced n-channel, connected by gate outputs s, respectively, to 1.N outputs of the pulse distributor, outputs of the sources to the common bus, and outputs of drains, respectively, to the outputs 1. N of the device, a bounce-free button, the output of which is connected to the input of the zero setting of the pulse distributor and to the first input of the first logic element 2, OR NOT, the output of which is connected to the synchronization input of the pulse distributor, and the second input to the output of the pulse generator and to the inputs of the second logic element 2 OR NOT, the output of which is the N + 1 output of the device; in addition, the introduced switch is connected by inputs to the outputs 0.N of the pulse distributor, and by the output to the anode of the inserted N + 1 diode, the cathode of which is connected through the entered N + 1 resistor to the control input of the pulse generator.

 In addition, the pulse generator contains a BISPIN device, a first MOS transistor with an induced p-channel, a second npn transistor, a diode timing the capacitor, the first, second, third and fourth resistors, and the BISPIN device is connected by the output of the locking contact to the common bus , by outputting an ohmic contact to the gate of the first transistor directly and through the first and second resistors, respectively, to the power bus and to the common bus, and by outputting the substrate to the cathode of the diode, the anode of which is connected to the integrating input of the pulse generator and to to the lecturer of the second transistor, the emitter of which is connected to the common bus, and the base through the third and fourth resistors respectively to the common bus and to the drain terminal of the first transistor, the source of which is connected to the power bus, and the timing capacitor is connected between the diode anode and the common bus, and the drain terminal the first transistor and the base terminal of the second transistor are respectively the output and control input of the pulse generator.

 The claimed solution differs from the known ones by the introduction of the BISPIN device, isolation diodes, MOS transistors, the start-up unit of the device, and new interconnections. These differences are new because they are not in the prototype.

 The claimed solution has common features with a pulse-width modulator BISPIN device, a diode and a timing capacitor and an n-p-n-transistor. However, the introduction of a new switching circuit for the BISPIN device (with a locking contact connected to the common bus), new elements of the pulse generator: the first and second resistors and the MOS transistor, as well as new interconnections of the pulse generator, significantly reduced the minimum switching current of the BISPIN device and obtained a significant increase in the maximum pulse width of the generator and thereby expand the scope of the claimed device. The introduction of a pulse distributor, the first logical element 2 OR NOT, the device start-up unit, isolation diodes made it possible to convert the pulse-width modulator into a test sequence generator, i.e. give it new properties that are absent from the analogue. Since the claimed solution meets the criterion of "significant differences".

 The drawing shows a diagram of the generator of test sequences for the case when the pulse distributor, which is part of the device, has 8 outputs.

RS-триггера является выходом бездребезговой кнопки 32 и подключен к входу установки нуля распределителя 33 и к первому входу первого логического элемента 29, выход которого подключен к входу синхронизации распределителя 33. БИСПИН-прибор 34 подключен выводом запирающего контакта к общей шине 49, выводом омического контакта к затвору транзистора 35 непосредственно и через резисторы 39 и 40 соответственно к шине 48 питания и к общей шине 49, а выводом подложки к катоду диода 37, анод которого подключен к интегрирующему входу генератора 31 и к коллектору транзистора 36, эмиттер которого подключен к общей шине 49, а база через резисторы 41 и 42 соответственно к общей шине 49 и к стоку транзистора 35, исток которого подключен к шине 48 питания. Хронирующий конденсатор 38 генератора 31 подключен между анодом диода 37 и общей шиной 49, а сток транзистора 35, являющийся выходом генератора 31, подключен к второму входу элемента 29 и к входам элемента 30, выход которого является восьмым выходом 50 устройства. Транзисторы 15-21 подключены выводами истоков к общей шине 49, а выводами затворов соответственно к выходам 1-7 распределителя 33.The device contains the first 1 seventh 7 timing resistors, the first 8 seventh 14 isolation diodes, the first 15 seventh 21 MOS transistors with an induced n-channel, the drains of which are connected respectively to 1 output 22-7 of the output 28 of the device, the first logic element 2 OR NOT 29 , the second logical element 2 OR NOT 30, a pulse generator 31, the timing resistors 1-7 of which, to simplify the description, are moved outside the generator 31, a bounce button 32 and a pulse distributor 33. The generator 31 contains a BISPIN device 34, a first MOS transistor 35 with an induced p-channel, a second npn transistor 36, a diode 37, a timing capacitor 38, and an eighth 39 eleventh 42 resistors. The ratchet-free button 32 contains the third 43rd and fourth 44th logical elements 2OR-NOT connected according to the RS-trigger circuit, and its input S is connected to the first output of the twelfth resistor 45 and the normally open contact of the button 46, the input R is connected to the first output of the thirteenth resistor 47 and to the normally closed contact of the button 46, the middle contact of which is connected to the power bus 48 (level generator log. 1). The second terminals of resistors 45 and 47 are connected to a common bus 49, and the output

The RS flip-flop is the output of the bounce-free button 32 and is connected to the zero-input of the distributor 33 and to the first input of the first logic element 29, the output of which is connected to the synchronization input of the distributor 33. The BISPIN device 34 is connected by the output of the locking contact to the common bus 49, by the output of the ohmic contact to the gate of the transistor 35 directly and through resistors 39 and 40, respectively, to the power bus 48 and to the common bus 49, and the output of the substrate to the cathode of the diode 37, the anode of which is connected to the integrating input of the generator 31 and to the collector ranzistora 36, the emitter of which is connected to the common bus 49, and the base through the resistors 41 and 42 respectively to a common bus 49 and to the drain of transistor 35, whose source is connected to the power bus 48. The timing capacitor 38 of the generator 31 is connected between the anode of the diode 37 and the common bus 49, and the drain of the transistor 35, which is the output of the generator 31, is connected to the second input of the element 29 and to the inputs of the element 30, the output of which is the eighth output 50 of the device. Transistors 15-21 are connected by the terminals of the sources to the common bus 49, and by the terminals of the gates, respectively, to the outputs 1-7 of the distributor 33.

 The switch 51 with its N + 1 inputs is connected to the N + 1 outputs of the distributor 33. The output of the switch 51 is connected through a diode 52 and a resistor 53 to the control input of the generator 31.

 The device operates as follows.

 After applying the supply voltage (positive potential to bus 48), the distributor 33 is set to an arbitrary state and, if it is not a zero state, initiates the generation of a sequence of N- (K-1) pulses, where N 7, and K is an arbitrary state of the distributor, and K > 0. If such a start of operation of the device is unacceptable, then the power supply of the device must be turned on after pressing button 46, keeping the latter in this state during the transition process of turning on the power source. In this case, the distributor 33 is set to zero by acting on its input R unit level of the output signal of the button 32. Since at the outputs 1-7 of the distributor 33 are allocated logical zero levels, the capacitor 38 of the generator 31 cannot be charged. As a result, the BISPIN device 34 remains in a non-conductive (closed) state. The transistor 35 is closed, because the output voltage of the divider formed by the resistors 39 and 40 is lower than the opening threshold of the transistor 35. Therefore, a logic zero level is supplied from the output of the generator 31 to the input of the element 29, and the logic level is allocated at its output and the synchronization input of the distributor 33 zero, determined by the effect on the input of the element 29 of the output signal of the button 32. After releasing the button 46 from the input R of the distributor 33, the signal is set to zero, and the synchronization input of the distributor 33 receives a positive the edge (edge) of the signal, delayed relative to the cutoff of the pulse of the button 32, and causes the allocation of the signal of the logical unit at the output 1 of the distributor 33. From this moment, the charging of the timing capacitor 38 through the resistor 1 and the diode 8. The BISPIN device 34 remains in non-conductive (off) state until a forward bias occurs of the diode 37 and the pn junction, the ohmic contact of the BISPIN device 34 as a result of an increase in the voltage across the capacitor 38. Turning on the BISPIN device 34 causes the transistors to turn on 35 and 36 and discharge by the collector current of the last capacitor 38. At the output of the BISPIN device 34 and the generator 31, a short pulse of negative and positive polarity is allocated, respectively, the pulse of the generator 31 passes through element 29, inverting to the synchronization input of the distributor 33 and causes the excitation of output 2 the latter (the appearance at the output of 2 signals of a logical unit). Next, the charge of the capacitor 38 through the resistor 2 and the diode 9 begins and the processes are repeated, formed at the output of the generator 31 after charging its capacitor 38 through the resistor 7 and the diode 14, puts the distributor 33 into zero state and stops (completes) the formation of the test pulse sequence. The start of the next test pulse sequence is initiated by pressing button 46.

 Transistors 15-21 are keys designed for switching external actuators connected to the outputs 22-28 of the device, in which in these cases signals are inverted with respect to the corresponding signals of the distributor 33. At the output 50 of the device, signals are allocated in standard levels logic inverse to the output signals of the generator 31.

 Elements 51-53 together with the transistor 36 determine the number of pulses in the generated test sequence, and also exclude the possibility of charging the capacitor 38 with leakage currents, which ensures the calculated duration of the first pulse of the generated sequence during long pauses between test sequences.

 In the position of the switch 51 shown in the diagram, the device generates a sequence of seven pulses, and when the distributor 33 is zeroed, a high signal level at the output 0 of the distributor 33 causes the transistor 36 to turn on, the capacitor 38 is shunted by the latter, and the leakage current can be charged with the latter. In the process of generating pulses, the elements 51-53 do not affect the operation of the device.

 If it is necessary to obtain, in the generated sequence, for example, only the first five pulses, the switch 51 is set to 6. In this case, after the fifth pulse of the test sequence is completed, a high signal level at the output 6 of the distributor 33 causes the transistor 36 to turn on, the capacitor 38 is shunted by the saturated transistor 36, and cessation of pulse generation. The device saves this state until the next pulse sequence is initiated by pressing button 46.

 The duration of the excited (active) state of the outputs 1-7 of the distributor 33 is equal to the total duration of the time interval of the charge of the capacitor 38 through the resistors 1-7, respectively, and the pulse duration of the BISPIN device 34 and is determined mainly by the resistance value of the resistors 1-7, because the pulse duration of the BISPIN device 34 does not exceed tens of microseconds. By adjusting the resistance value of resistors 1-7, you can change the ratio of the pulse durations in the test sequence.

 Application in the device diodes must have a minimum value of the reverse current, and the transistor 36 minimum value of the leakage current. To increase the efficiency of using the timing elements (resistors 1-7 and capacitor 38), the output voltage of the divider formed by resistors 39 and 40 should be as close as possible to the supply voltage and at the same time provide the enable current of the BISPIN device 34 through the diode 37 and pn junction substrate ohmic contact of the BISPIN device 34.

 In order to check the operability of the device, a model was assembled in which the distributor 33 was implemented by the integrated circuit (IC) 564IE9, the logic elements 29, 30, 43, 44 were implemented by the IC 564 LE5, and also a transistor 35 of the type KP301V, a transistor 36 of the type KT3102 and diodes 8-14, 37 type KD102A. At a supply voltage of 9 V, capacitor capacitance 38 0.01 μF and resistances of the resistor 39-33 kΩ, resistor 40-66 kΩ and resistors 1-7 1 mΩ, the pulse duration at the outputs 1-7 of the distributor 33 was at least 6 ms. The device remained operational while increasing the resistance of the resistor 1 to 20 mOhm.

 The diode 37 eliminates the charge of the capacitor 38 with the leakage current of the BISPIN device 34 through its ohmic contact and substrate terminals and turns off the BISPIN device 34 at the time of turning on the transistor 36, however, the device remains operational even with a shorted diode 37.

 The collector current of the transistor 36 should provide a full discharge of the capacitor 38 during the pulse duration of the BISPIN device 34.

 The application of the claimed solution will allow you to get the following advantages compared to the prototype: to expand the functionality of the device by creating additional outputs that can be used to control processes (devices); to simplify the device by excluding from its structure one functional unit single-vibrator.

 Because in the prototype, the pulse repetition period of the master oscillator must exceed the maximum pulse duration in the generated sequence, then the duration of the pauses between pulses will be excessive in all cases when the duration of the pauses is arbitrary and the duration of one of the pulses in the generated sequence is much less (or more) than the duration of the others pulses, which reduces the overall speed of the device.

Claims (2)

 1. TEST SEQUENCE GENERATOR, comprising a pulse distributor, the outputs of which are connected to the first outputs of the corresponding timing resistors, and a control input with a common bus, an inverter, a pulse duration shaper, characterized in that, in order to expand the functionality and simplify, a generator is introduced into it a single pulse at the RS-trigger, a group of MOS transistors with an induced n-channel and a group of diodes according to the number of chrome-plating resistors, an OR element, a switch, a diode and a resistor, output r a single pulse generator on the RS-trigger is connected to the installation input of the pulse distributor and the first input of the element OR NOT, the second input of which is connected to the inverter input and the output of the pulse shaper, the timing input of which is connected to the cathodes of the group of diodes, the anodes of which are connected to the second outputs of the corresponding timing resistors, the output of the element OR is NOT connected to the synchronization input of the pulse distributor, the outputs of which are connected to the gates of the corresponding MOS transistors with induction a n-channel, the sources of which are connected to the common bus, drains with the terminals of the group of output terminals of the test sequence generator, the inverter output is connected to the output terminal of the test sequence generator, the installation output and the outputs of the pulse distributor with the corresponding inputs of the switch, the output of which is through the diode and the resistor is connected to the reset input of the pulse shaper.  2. The generator according to claim 1, characterized in that the pulse width former comprises a BISPIN device, the locking contact of which is connected to a common bus, the output of the substrate with the cathode of the diode, the ohmic contact of the gate of an MOS transistor with an induced p-channel and through the first and second resistors respectively with a power bus and a common bus, the source of an MOS transistor with an induced p-channel is connected to a power bus, the drain is through a third resistor with an np base of an n-transistor, the emitter of which is connected to a common bus, the collector with the diode anode and through the condensate OR with a common bus, the base through the fourth resistor is connected to a common bus, the anode of the diode, the base n p - n-transistor and the drain of an MOS transistor with an induced p-channel are connected respectively to the timing input, reset input and output of the pulse shaper.