SU1128224A1 - Device for tolerance checking of currents - Google Patents

Abstract

A DEVICE FOR ENTRY CONTROL CURRENTS containing a control unit, a programmable voltage source, a source of limit values, a current-measuring resistor, a large-scale resistor, a comparator and a controlled electronic circuit, the first output of the control unit connected to the first input of a programmable voltage source, the output of which is through a current-measuring resistor connected to the controlled electronic circuit and the first input of the comparator, the second output of the control unit is connected to the input of the source of the boundary characters , in- out koto-. It is connected to the second input of the comparator and through a large-scale resistor to the output of a programmable voltage source, characterized in that, in order to increase its speed, it contains a second programmable voltage source, a voltage follower, the first and second programmable resistors, first, second and the third keys, and the output of the second programmable voltage source through the first key is connected to a controlled electronic circuit and to the input of a voltage follower, the output of which through the second key and the first The programmable resistor is connected to the second input of the first programmable voltage source, the output of which is connected to the first input of the comparator and through the third switch and the second programmable resistor to the second (L input of the first programmable voltage source, while the third, fourth, fifth, The sixth, seventh, O, and eighth and ninth outputs of the control unit are connected respectively to the coupler inputs of the second programmable voltage source, the first, second, and third keys, CX CX) of the first and second programs iruemyh resistors, current-measuring rezisyu torus control unit podklyuN input) to the output of the comparator chen and program4 ble voltage sources, switches and programmable resistors are controlled by respective outputs of the control unit.

Description

111 The invention relates to electrical measuring equipment and can be used for controlling the currents of electronic circuits, in particular, at the input control of microcircuits. A high-speed low-current meter is known, which contains a DC amplifier, a measuring resistor, two correction links, in which the inverting input of the DC amplifier is connected to the output terminal and to the measuring resistor, non-inverting input is connected to the output of the first amplifier, inverting the Auxiliary input of the amplifier is connected the total rest, the input of the first corrective link is connected to the output of the first amplifier, and the output of the first corrective link is connected via a measuring resistor to the input second terminal, the second input of the correction link connected to the output of the second amplifier, and the output of this unit is connected to the inverting input of a second amplifier whose output is the output of the l J.. The disadvantage of the device is low speed. The closest in technical essence to the invention is a device for monitoring parameters of electronic circuits, comprising a control unit, the output of which is connected to the inputs of:; see; a unit for setting control limits and a programmable voltage source, the first output of which is directly, and the second through current-measuring resis the torus is connected to the input of a controlled electronic circuit, and a voltage comparator, the output of which is connected to the output by a device terminal, as well as a large-scale resistor and a controlled oscillator then A cable whose input is connected to the output of the control boundary setting unit and the output to one of the inputs of a voltage comparator and through a large-scale resistor to the second output of a programmable voltage source, while the other input to the voltage parametrator is connected to the input of a controlled electronic circuit 2 The drawback of the device is the low speed at monitoring small currents, which is determined by the constant charging time of the total capacitance of the monitored electronic circuit and measuring lines of the device through current measurement. th resistor and the time constant of the correcting capacitance that is generally parallel to a current detection resistor is included to provide a stable operation of the device. The purpose of the invention is to increase the speed of the device. The goal is achieved by the fact that the device for current control includes a control unit, a programmable voltage source, a source of limit values, a current-measuring resistor, a scale resistor, a comparator and a controlled electronic circuit, the first output of the control unit connected to the first input of the programmable source. the output of which through a current-measuring resistor is connected to a controlled electronic circuit. and the first input of the comparator, the second output of the control unit is connected to the input of the source of limit values, the output of which is connected. with a second comparator input, and through a large-scale resistor with an nporpaNWHpyeMoro voltage source output, a second programmable voltage source, a voltage follower, the first and second programmable resistors, the first, second and third switches, are introduced. than the output of the second programmable voltage source through the first switch is connected to the controlled electronic circuit and to the input of the voltage follower, the output of which is connected via the second switch and the first programmable resistor to the second input of the first programmable voltage source, whose output is connected to the first input of the comparator and through the third switch and the second programmable resistor to the second input of the first programmable voltage source, with the third, quarter, fifth, sixth, seventh, eighth and nine the outputs of the control unit are connected respectively to the control inputs of the second programmable voltage source, the first, second and third keys, the first and second programmable resistors, the current-measuring resistor, the input of the control unit is connected to the output of the comparator, and the programmable voltage sources, keys and programmable resistors the respective outputs of the control unit. The drawing shows a block diagram of the device. The device for tolerance control includes a control unit 1, connected by output 2 with a second programmable voltage source 3, including force 4, with resistors 5 and 6 that determine the transmission coefficient of source 3, source 7 of limit values amplifier 8 with resistor 1 and 9 and W, which determine the transmission coefficient, is input connected to output 11 of control unit 1, and output to the first input of comparator 12, containing zero-in indicator 13 and summing resistors 14 and 15. The device also contains the first a programmable voltage source 16 comprising an amplifier and an input resistor 18, the first input of the first programmable voltage source 16 being connected to the output 19 of the control unit 1, and the output to the measurement resistor 20, the second input of the comparator 12 and the key 21 connected via the second programmable resistor 22 with the second input of the first programmable voltage source 16 and the first programmable resistor 2 connected via a second switch 24 to the output of the voltage follower 25, the input of which is connected to the first switch m 26, and controlled circuitry 27. In addition, the device contains a load capacitance and a measuring line (C |) and a correction capacitance (Sc), which ensures stable operation of the device. The control unit 1 by its output 28 controls the operation of the key 26, the output 29 controls the key 24, the output 30 controls the resistor 23, the output 3 controls the key 21, the output 32 controls the resistor 22, and the output 3 resistor 20.. The device works as follows. In the initial state of the first. KEY 26 is open, the second 24 and third 21 keys are closed. The output voltage of the second programmable source 3 is zero, which is provided by the corresponding signal from output 2 of control unit 1, namely, zero voltage from output 2 of control unit 1 is applied to the output of resistor 6 of the second programmable voltage source 3. The voltage at the output of the current-measuring resistor 20 connected to the controlled electronic circuit 27 is also set to zero. This is ensured by the fact that the second 24 and third 21 keys are closed by commands from the outputs 29 and 31 of the control unit 1, and the output of the first programmable voltage source 16 (to the output of the resistor 10) o, the output 11 of the control unit 1 is zero voltage. In this case, the feedback circuit from the current supply resistor 20 output voltage follower 25, the second switch 24 and the resistor 23 compensate for the voltage change on the current measuring resistor 20. Similarly, a zero voltage is also set at the output of the boundary value source 7. I A monitored circuit 27 is connected to the device. With the help of resistors 5 and .6, at the command of output 32, control unit 1 (according to the data in control unit 1) the transmission coefficient of the second programmable voltage source 3 is set so that the input (output of resistor 6) of the reference voltage from control block 1, the voltage at the output of the programmable voltage source 3 is set equal to the required voltage and for the controlled electronic circuit 27. (The reprogramming of resistors 5 and 6 walks at zero voltage at the input of the second programmable source 3 voltage). On commands from outputs 19 and 30 of control unit I, the values of resistors 18 and 23 are set so as to provide the specified test voltage at the output of the controlled electronic circuit 27 (the output of the current-measuring resistor 20). At the same time, on command from the output 32 of the control unit 1, the value of the resistor 22 is set such that, together with / resistor 18, at the output of the first programmable source 16, provide the voltage Uf corresponding to the limit value J of the controlled electronic circuit 27 Ur RT Cr ± and . where the resistance of the measuring resistor is 20. Since all switches of 23,22 and 18 relays occur at a zero voltage at the input of the first programmable voltage source 16, the voltage at the output of the controlled electronic 27 remains zero and the voltage the presence of capacitance (Cn), in the controlled electronic circuit 27, there are practically no voltage surges arising at the time of possible feedback circuit: a repeater 25, a second switch 24, and a resistor 23 when the resistor is reprogrammed. (The reprogramming time of the resistors 12,22 and 23 is much less than the time for setting the mode at the output of the controlled chip 27 if the first key 26 is open). The current measuring resistor 20 is set by a command from the control unit 1 to a value that corresponds to the required range of the monitored current. Upon a command from the control unit I, the first key 26 is closed, after which the second key 24 is opened, then the reference voltage from the control unit 1 is supplied to the inputs of the second programmable voltage source 3, the first programmable voltage source 16 and the limit value source 7. In this case, the output of the second programmable source. 3, a necessary voltage appears. A test voltage U, which through a closed first switch 26 goes to a controlled electronic circuit 27 and charges the load capacitance and the measuring line (Cn). The voltage setting time U is determined mainly by the own voltage setting time at the output of the second programmable voltage source 3, the output resistance of which is close to zero (the setting time may be less than 0 ms, 1 ms). At the same time, the voltage Up 246 corresponding to the limit value of the controlled current is set at the output of the first programmable voltage source 16. The set-up time is equal to the own set-up time of the first programmable voltage source 16, and the correction capacitance (Sc) is charged along the circuit: the output of the first programmable voltage source 16, the first switch 26 and the output of the second programmable voltage source 3. The circuit has near zero resistance. At the output of the source 7 of the boundary values, the voltage U appears, which goes to the first input of the comparator 12, the second input of which also receives the voltage Up from the output of the first programmable voltage source 16. In this case, a current SG flows through the current-measuring resistor 20, which is closed through the output resistance of the second programmable voltage source 3. Then, the second switch 24 is closed, and a negative feedback circuit is formed through the voltage follower 25, the second switch 24 and the resistor 23 to the second input of the first programmable voltage source 16. At the same time, taking into account the ratio of the resistors Vekhshchin: 23 and 18 (the voltage U should appear at the output of the controlled electronic circuit 27) and the fact that the voltage U is already present at the output of the monitored circuit 27, the feedback signal does not form In this case, it is small and the first programmable voltage source 16 will remain in active mode) and the voltage U does not change or it changes at a rate determined by the time constant of the circuit formed by the current-measuring resistor 20 and the correction capacitor (CK). The indicated time constant is ten ms. Therefore, the high-speed second programmable voltage source 3 keeps the voltage U unchanged, especially since after less than 1 the first key 26 is opened by the command from control unit 1 (the time less than 1 ms will be used when the first key 26 is reed. The voltage U is maintained by the negative 711282

circuit feedback: repeater 25, second switch 24, and resistor 23

If the current of the monitored electronic circuit 27 differs from the boundary value Jp, the voltage at the output of the first programmable voltage source 16 begins to change at a rate determined by the time constant of the circuit formed by the current-measuring resistor 20, the correction capacitance (C), the load capacitance and the measuring line (C) and the resistance of the monitored electronic circuit 27 (10-100 ms), as well as the transfer coefficient of the first programmable voltage source 16, defined by the resistance ratio 18 and 22 (the third switch 21 is closed).

Further, the third key 21 is opened, and the rate of change of voltage on

eight.

the output of the first programmable voltage source 16 is increased. The direction of change of voltage U (. Depends on whether the controlled current is greater than Jp, or less).

Through the time determined by the specified control error, the sensitivity of the comparator 12 ,. the noise level at the output of the first programmable voltage source 16, as well as the scattering voltage change, at its output, the control unit 1 interrogates the comparator 12 at the input 33,

Compared with the known device, the proposed device allows to increase the speed and reduce the time of control of microcircuits in the range of 10-100nA by 10 times (from 500 ms to 50 ms in one dimension).

Claims (1)

DEVICE FOR ACCESS CONTROL OF CURRENTS, comprising a control unit, a programmable voltage source, a source of boundary values, a current-measuring resistor, a scale resistor, a comparator and a controlled electronic circuit, the first output of the control unit being connected to the first input of the programmable Voltage Source, the output of which is connected to the current-measuring resistor to controlled electronic circuit and the first input of the comparator, the second output of the control unit is connected to the input of the source of boundary values, the output of which is connected to the second input of the comparator and through a large-scale resistor with the output of a programmable voltage source, characterized in that, in order to increase its speed, it contains a second programmable voltage source, a voltage follower, the first and second programmable resistors, the first, second and third keys, and the output of the second programmable voltage source through the first switch is connected to a controlled electronic circuit and to the input of the voltage follower, the output of which through the second switch and the first programmable resistor is connected to the second input of the first programmable voltage source, the output of which is connected to the first input of the comparator g and through the third key and the second programmable resistor to the second input of the first programmable voltage source, while the third, fourth, fifth, sixth, seventh , the eighth and ninth outputs of the control unit 5 are connected respectively to the compartment - equal to the inputs of the second programmable voltage source, the first, second and third switches, the first and second programmable resistors, a current-measuring resistor, the input of the control unit is connected to the output of the comparator * and programmable voltage sources, switches and programmable resistors are controlled by the corresponding outputs of the control unit.