SU995030A1 - Logic probe - Google Patents

Description

(Sk) LOGICAL PROBE

The invention relates to instrumentation engineering and can be used to conduct inspections in chains of logic devices. A state indicator is known that contains the first AND-NE element, the first input of which is connected to the indicator input and the inputs of the second INE element, and the second input - to the first input of the third AND-NOT element and control bus, the second input of the third AND-NOT element is connected to the output of the second element is NAND, and its output is at the first input of the display circuit, the output of the first element NAND is connected to the second input of the display circuit. The known device can distinguish and indicate the logic levels O and 1, the state of Break, i.e. the absence at a controlled point of a logic voltage circuit is indicated in the same way as level 1. However, the known device does not allow distinguishing and indicating the presence of a continuous pulse sequence. A disadvantage of the known device is also the limited functionality due to the lack of unambiguity of the level 1 reading and the condition of the break and due to the lack of possibility to distinguish and indicate the presence of a continuous pulse sequence. It is also known a device comprising two series-connected resistors connected between the power bus and the common bus to the connection point of which the device input is connected, the inverter input of the first comparator and the inverting input of the second comparator are connected, the non-inverting input of the first comparator is connected to the output of the first voltage source, and the inverting input of the second comparator - to the output of the second source. the reference voltage, the outputs of the comparators are connected via the display elements to the power bus. This device can distinguish and indicate the logic levels O and and: the state is Open, but does not allow to distinguish and indicate the presence of a continuous pulse sequence, which limits its functionality. The closest technical solution to the invention is a logic probe containing the first and second transistors, the first resistor and the second diode, the second resistor, the first inverter, the third resistor, the first indication element, the second inverter, the third diode, the third inverter, the first and second elements 2I-2ILI, fourth resistor; torus, second indication, fourth, fifth and sixth inverters, element 2I-NO, fifth resistor, third indication element, capacitor. The known device makes it possible to distinguish and indicate logical levels O and 1, the presence of a continuous pulse sequence, and the condition of Break 3. The disadvantage of the known device is its complexity, which makes it difficult to place it in the body of a small probe head. The purpose of the invention is to simplify the device. The goal is achieved in that a logical probe containing a first resistor connected between the common bus and the input of the first inverter, the output of which is connected to the first output of the first display element connected to the second output via the second resistor with the power bus, connection of the second display element and the third resistor connected to the common bus, the third inverter, the output of which is connected through the third display element and the fourth resistor connected in series A common capacitor, fifth and sixth resistors, a first capacitor, a diode, a second capacitor and a seventh resistor, the first output of which is connected to the power supply bus, and the second to the input of the second inverter and the first output of the sixth resistor connected to the second output the output of the fifth resistor, the second output of which is connected to the input of the first inverter, the capacitor is connected parallel to the first display element, the second output of which is connected to the cathode of the diode connected by the anode to the input of the third inverter, and the first output is second capacitor, a second terminal connected to the common bus, the findings point compound and shestogo- fifth resistor coupled to an input of the logic probe. FIG. 1 shows the basic scheme of the probe; in fig. 2-.time diagrams of his work. Logic probe contains the first resistor 1, the first inverter 2, the first element 3 of the display, the first capacitor k, the second resistor 5 the second inverter 6, the second element 7 of the display, the third resistor 8, the third inverter 9. the third element 10 of the display, the fourth resistor 11, diode , 12, fifth 13, sixth 14 and seventh 15 resistors and second capacitor 16. FIG. 2 shows timing diagrams of signal 17 at the probe input, signal 18 at the cathode of diode 12 and signal 19 at the input of the third inverter 9In the display elements 3, 7 and 10, LEDs can be used (Fig. 1) or incandescent bulbs. As an inverter 9, for example, a MOS-type gate is used, having a practically infinite input resistance and a certain input capacitance (from several units to several tens of picofarads), equivalent to capacitor 16. Resistance of resistors 1, 13) 1 and 15 are chosen as so that the following conditions are met. if the probe input is not connected to the monitored device, the voltage at the input of inverter 2 must be below the permissible level of logic zero. and, and the input voltage of the inverter 6 must be higher than the permissible level of the logical unit C | ; If the voltage of the logical zero of the device under test is acting at the input of the probe, andog, the voltage at the input of the inverter 6 must be less if the input voltage of the logical unit of the device under test is applied, the voltage at the input of the inverter 2 must be greater than Y. The logical probe works as follows. When the probe input is not connected to anything, i.e. has a status of

dug, voltage at the input of inverter 2 is less than Ujj, and at the input of inverter 6 is greater than U |. Then, the output of the inverter 2 is set to a voltage close to the voltage of the power source E, and the output of the inverter 6 is close to zero (respectively, the logical unit and the logical zero). The current through the elements 3 and 7 of the display does not leak, and they are not illuminated. The voltage on the cathode of diode 12 is close to E. Also close to E is the voltage at the input of the inverter 9, since its input capacitance on the capacitor 16 is charged to E through the reverse resistance of the diode 12. At the same time, the voltage at the output of the inverter 9 is close to zero , the current through the display element 10 does not flow and it does not light up. Thus, by the absence of luminescence of all elements of the indication, the condition of the break is indicated. If O is input to the probe, a voltage less than U is set up at the inputs of inverters 2 and 6, and a voltage close to E is set at their outputs. At the same time, display elements 3 and 10 are not illuminated. Through the display element 7, the current flowing is determined by the magnitude of the resistor 8, and it is lit. Thus, the presence of a luminescence of the display element 7 and the absence of luminescence of the elements 3 and 10 of the display indicate O at the probe input.

If the input to the probe arrives at the input of the inverters 2 and 6, a voltage greater than U is set, and a voltage close to zero at the outputs. In this case, the display element 7 does not light up, but the current determined by the magnitude of the resistor 5 flows through the display element 3, and it is lit. The pair of the display element 3 - resistor 5 is chosen so that the voltage at the point of their connection and more than UJ when current flows through the resistor 5 when the signal 1 is applied to the probe input. At the same time, the voltage at the input of the inverter 9 is equal to Ui., Because The input capacitor 16 is charged to this voltage through the reverse resistance of the diode 12. At the same time, the output voltage of the inverter E is close to zero, and the display element 10 does not light up. Thus, the presence of the luminous element of the indication 3 and the absence of the luminous elements 7 and 10 of the indication are indicated by 1 at the input of the probe.

If a pulse train acts at the probe input (essentially, this is alternation of O and 1 signals), elements 3 and 7 of the display alternately light up. With a pulse frequency of more than 25-30 Hz, their luminescence is perceived by the eye as continuous. In this case, the intensity of luminescence of each element 3 and 7 of the display depends on the duty ratio of the pulse sequence. When the duty cycle is equal to two, the intensity of both elements 3 and 7 of the display is the same. At higher duty cycles, only the display element 7 is lit, and at lower ones, only the display element 3 is lit.

at the time of the 0/1 drop of each output pulse, a voltage close to zero is generated at the cathode of diode 12 (Fig. 2). This occurs because during the action at the input of the probe signal O, the voltage at the output of inverter 2 is close to E, and the capacitor is discharged, and at the time of formation to b (during the inverter 2, the voltage close to zero, the cathode of diode 12 - connected via an uncharged capacitor k to the output of the inverter 2. Then the capacitor k starts to charge to a voltage equal to the voltage drop on the display element 3 in the on state, while the voltage on the cathode of the diode 12 increases and tends to its steady-state value .

At the instant of a drop of 1/0 of each input pulse, a voltage is formed at the cathode of diode 12, greater than E by the amount of voltage drop across the display element 3 in the on state, SRI (Fig. 2). This is because during the action on the input of signal 1 the capacitor is charged to a voltage equal to the voltage drop on the display element 3 in the on state, and during the action on the input of signal O on the output of inverter 2 a voltage close to E, which is added to the voltage to which capacitor k is charged. Then the capacitor C begins to discharge to zero, with the voltage. at the cathode of diode 12 it decreases and tends to its installed value, close to E.

During operation, the 0/1 drop at the probe input, the capacitor 16 almost instantaneously discharges to a voltage close to zero through diode 12, which at this point in time turns on in the forward direction (Fig. 2). To quickly discharge the capacitor 16 to a voltage close to zero, it is necessary that its capacitance be much less than the capacitance of the capacitor. Then, for the entire time until the differential 0/1 of the next input pulse, capacitor 16 is slowly charged through the reverse resistance of diode 12, which immediately after discharge of capacitor 16 is turned on in the reverse direction. The charge rate of the capacitor 16 under the action at the input of the probe 1 is lower than under the action O, since in the first case the voltage across the capacitor k tends to and, and in the case of the accelerator to E. During the action of the differential 0/1 of the next pulse, the capacitor 16 is again discharged through the reverse resistance of diode 12. If the frequency of the input pulse sequence is high enough, during the pulse period the capacitor 16 does not have time to charge to UQ (Fig. 2, signal 19). At the output of the inverter 9, a voltage close to to E, cher of element 10 indicating a current flows defined by the resistor 1, and the indicating element 10 s.vetits. At low frequencies of the input pulse sequence, capacitor 1b may have time to charge up to and above during the pulse period. In this case, the display element 10 is lighted only in the time intervals when the voltage on the capacitor 1b is less than Ud, but this luminescence is perceived by the eye as continuous. It is almost always possible to achieve that the display element 10 is normally luminous at frequencies of the input sequence 25-30 Hz and above. At lower frequencies, the presence of the input pulse sequence - CAN OP-. To be determined by the intermittent luminescence of elements 3 and 7 of the display, since at these frequencies their luminescence is no longer perceived by the eye as being more continuous. Thus, the presence of a continuous pulse sequence at the probe input is indicated by the glow of the display element TO, and the duty cycle of this sequence can be assessed by the intensity of luminescence of the display elements 3 and 7. 9 30 Introduction of a new element and connections to the probe significantly simplifies it, and also increases its reliability. ProbHHt can be placed in a very small probe body, which increases the usability of it. The logic probe was used to monitor the circuits of logic devices made on 133 and 13 series microcircuits (Uue; K 0.8 V, 2.0 V). Resistance values of the resistors were as follows: resistor 1 39 kΩ, resistors 5 8 and 11 - 510 Ohm, resistor 14 - 15 kΩ, resistor 15 62 kΩ. Capacitor 4 had a capacitance kj pF. AL102A LEDs were used as indication elements, and diode 12 was used as КД514А type. CMOS-type gates included in the microcircuit were used as inverters. These valves had an input capacitance of about 30 pF, and the values of U and U are respectively 1.7 and 1.9 V with a supply voltage of +5 V. The invention is a logical probe containing a first resistor connected between a common bus and the input of the first inverter, an output which is connected to the first output of the first display element connected to the second output through the second resistor to the power bus, the second inverter, the output of which is connected through the second display element connected in series and the third resistor is connected to the common bus, the third inverter whose output through the third display element connected in series and the fourth resistor is connected to the common bus-. Fifth and sixth resistors, the first is a capacitor, a diode, in order to simplify the probe, a second capacitor and a seventh resistor are inserted into it, the first output of which is connected to the power bus, and the second to the input of the second inverter and the first output of the sixth resistor connected by the second output to the first output of the fifth resistor, the second output of which is connected to the input of the first inverter, the capacitor is connected parallel to the first display element, the second output of which is connected to the cathode of the diode connected by the anode to the input m of the third inverter and the first vy999503 vodom vtorogochkondensatora connected to the second terminal sobschey bus, the junction terminals of the fifth and sixth resistors is connected to the house WMOs logic probe. Sources of information taken into account during the examination 5

. / 010 1. Logical circuit status indicator. - Electronics, No. t, 1975i p. 6G. 2. For the application of the Federal Republic of Germany No. 2030122, cl. 21 19/16, 197. 3. The logical probe. - Radio, No. 9, 1978, p. kB (prototype).

Claims (1)

Claim A logic probe containing a first resistor connected between the common bus and the input of the first inverter, the output of which is connected to the first output of the first indication element connected by the second output through the second resistor to the power bus, the second inverter, the output of which is connected through the second indication element and the third resistor in series connected to a common bus, a third inverter, the output of which through a third indication element and a fourth resistor connected in series is connected to a common bus, not the fifth and sixth resistors, ne the first is a capacitor, a diode, in that, in order to simplify the probe, a second capacitor and a seventh resistor are introduced into it, the first output of which is connected to the power bus, and the second to the input of the second inverter and the first output of the sixth resistor connected the second terminal with the first terminal of the fifth resistor, the second terminal of which is connected to the input of the first inverter, the capacitor is connected in parallel with the first indication element, the second terminal of which is connected to the cathode of the diode connected by the anode to the input of the third inverter, and the first 995030 vodom second chkondensatora connected to the second terminal of the common bus, tochko compound terminals of the fifth and sixth resistors is connected to the input of the logic probe.