DE3322483A1 - Measuring arrangement for detecting current or voltage values - Google Patents

Abstract

The invention relates to a measuring arrangement for current or voltage measurement in accordance with the charge balance method. The integration arrangement (1) necessary in this method activates oscillation-generating switching means. To ensure accurate and rapid detection even at low currents or voltages, capacitors (C1, C2) for setting a particular discharge time are added or disconnected in the integration arrangement (1). The invention can be primarily used for measuring low currents in neutron flux measurement. <IMAGE>

Description

SIEMENS AKTIENGESELLSCHAFT Our mark Berlin and Munich VPA 83 P 4419 DE

Measuring arrangement for the acquisition of current or voltage values

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The invention relates to a measuring arrangement for recording current or voltage values with an integration arrangement, in which the discharge time dependent on the value of the current or voltage to be detected is at least one Capacitor is evaluated, and with at least one connected to the output of the integration arrangement Comparator whose switching thresholds are suitable for recording the start or end of the charging or discharging times the comparator having pulse generating circuit means whose pulse frequency depends on the discharge time.

In a known measuring arrangement of this type ("electron." 74, issue 12, pages 469 - 472) is a capacitor of the integration arrangement according to a so-called charge balance method charged with a constant amount of charge and then discharged by the current to be measured. The time difference between the state of charge and discharge is used to determine the level of the current to be measured. For example, if the current increases, the capacitor is discharged faster and the time difference becomes smaller. With decreasing currents, it takes a longer time until the discharge state. Thus, such changes are made recognized later. If the currents to be measured are low, this is the time until a change is detected relatively large. The time spans of the discharge time used for the measurement are therefore based on the respective value of the current or the voltage and thus allow changes in the current or voltage value to be detected.

Ag 4 Bz / June 16, 1983

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The invention is based on the object of providing a measuring arrangement for detecting current or voltage values in which the acquisition of even low current or voltage values in a relatively short measuring time high accuracy can be achieved.

To solve this problem, at least two comparators are used in a measuring arrangement of the type specified at the outset the integration arrangement is switched on, the respective threshold values of which are so differently dimensioned that the time interval between exceeding the threshold values depending on the slope of the charging or discharging curve the integration arrangement can be evaluated.

The inventive arrangement of at least two comparators with different threshold values allows one Detection of the slope of the discharge curve, so that the time between the response of the first comparator and, for example, the response of the second comparator, an auxiliary variable can be obtained, the one Provides information about the size of the measured current or voltage. Especially when capturing extremely low currents, in which the time span of the response of the threshold values exceeds the specified limit value exceeds, an improved evaluation of the discharge time can be achieved with the auxiliary variable.

A particularly advantageous evaluation of the signal at the output of the integration arrangement is achieved when the capacitive elements of the integration arrangement consist of a number of capacitors connected in parallel, of at least one of which can be separated or connected from the parallel circuit by switching means, and at least a switchover module is available which, in the event of a

'35 determination of the time interval between two threshold values being exceeded from a given area the dividing

VPA 83 P 4419 DE activation or connection of the at least one parallel-connected Capacitor causes.

By evaluating the time span between the response of the at least two comparators and the one resulting therefrom Connection or disconnection of further capacitors to the integration arrangement can be the charging resp. Discharge curves are adapted so that an acceptable discharge time even with extremely low currents to be measured is achieved, so that a fast current measurement is possible.

Further advantageous developments of the measuring arrangement according to the invention are given in the subclaims.

The invention is explained with reference to the figures, where FIG. 1 shows a basic circuit diagram of a known measuring arrangement,
FIG. 2 shows the pulse diagrams occurring in the known measuring arrangement and

FIG. 3 shows a basic circuit diagram of the measuring arrangement with additional evaluation of the output signals of several comparators shows.

FIG. 1 shows a known measuring arrangement in which a detector current I, to be detected, is applied to an input 1, which is fed to an input 2 of an integration arrangement I. A constant current source IK via a switch S and a diode D is also connected to input 2. The constant current source IK emits a constant current I ~ . The integration circuit I contains an operational amplifier OP, which has a capacitor C in its return and is connected at its first input 3 to the input 2 of the integration arrangement I and at its second input 4 to ground. The output 5 is led to a first input 6 of a comparator K, to the second input thereof

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Ground is switched on. The comparator K is on the output via a timer TI (for example a monoflop) out of the known measuring arrangement. A switching contact of the switch S is also connected to the output 8.

In the circuit arrangement according to FIG. 1, the detector current I ^ to be measured is fed to the input 2 of the integration arrangement I, at whose output 5 a negative ramp is thus created. The following comparator K, the threshold of which is 0 volts here, has a very small hysteresis and controls the timer TI. The time base of the timer TI is fixed (for example 1 yus). The timer TI closes the switch S during this fixed time, as a result of which a reference current I _ref generated by the constant current source IK can reset the integration arrangement I at the input 2 via the diode D. The discharge portion As is given here by the constant reference current I _re f and by the fixed time At of the timer TI:

I _ref . At = As

Because of the repetitive process of charging and discharging the capacitor C in the integration arrangement I creates a pulse train at the output 8 of the circuit arrangement, the pulse train frequency of which depends on the Discharge time and thus on the size of the current I to be measured.

In FIG. 2, the voltage curves occurring in the measuring arrangement are shown over time t. In the diagram a) shows the course of the current I, to be detected, which occurs at time t ,. a jump in its absolute Greatness makes. In diagram b) are the charge pulses

shown over the time with which the capacitor C the integration arrangement I is charged. In diagram c) the course of the integration voltage U at the input

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gear 6 of the comparator K shown. It can be seen here that the time course of the discharge curve changes at the point in time t ^, so that overall there is a change in the discharge period from At ^ to At ₂ . As can be seen from diagram d), this change in the discharge time results in a change in the pulse repetition frequency at the output 8 of the measuring arrangement.

In the measuring arrangement shown in FIG. 3, those are the same as in the measuring arrangement according to FIG Components designated in the same way. In this arrangement there is between the output 5 of the integration arrangement I and the comparators KO ... K5 also have a limiter B switched. The outputs of the comparators * "£ ...

K5 are led to an output 10 via a summing element SU and a timer TU. The outputs of the comparators KO and K1 are routed to inputs 11 and 12 of a switchover module UB, the output of which is output 13 of the measuring arrangement represents. This output 13 is connected to switches S1 and S2, the switch S1 being a capacitor C2 can be connected or disconnected in parallel with a capacitor C1 and the switch S2 in parallel with a resistor R1 can connect a resistor R2 in series with the diode D. Resistors R1 and R2 are across a Pulse shaper module IF connected to the constant current source IK. The pulse shaper module IF is via a Switch S3 controlled in such a way that it only delivers predetermined charge portions to the integration arrangement I. can. The control of the switch S3 is effected by the output of the comparator KO via a timer TI2. The exit of the comparator KO also represents the output 14 of the measuring arrangement.

The measuring arrangement according to FIG. 3 initially works as already described in '35 for the measuring arrangement according to FIG. The current I ^ to be measured flows into the integration arrangement I, whose sawtooth output voltage is here al-

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However, it is limited in the limiter B. At a level of 0 volts, the comparator KO switches from "low" to "high". The timer TI2 is started with the rising edge of KO (time base for example 5 / us). During this time, the switch S3, designed for example as a MOS switch, is closed; The current I _re f thus flows into the pulse shaper IF and resets the integration arrangement I and the comparators KO ... K5 there via R1 and D. The circuit is dimensioned so that a negative ramp from +1 volt to 0 volt is present at the input of the comparators KO ... K5 during the integration time. The reset frequency f1, which is proportional to the current I i to be measured, is thus present at the output of KO (output 14 of the measuring arrangement). This signal can be fed to digitization and display, for example, via an optocoupler, not shown here.

The threshold value of the comparator K1 is, for example, + 50 mV, as a result of which the two comparators KO and K1 respond with a time delay. The time period At between these response points is strictly proportional to the current I, to be measured. This time span between the two positive rising edges is compared in the switchover module UB, for example, with two fixed monoflops (time bases for example 1 / us and 10 ms) and the criterion for a measuring range switchover is derived from this. Switching takes place by connecting R2 to R1 and C2 to C1 via the z. B. designed as a MOS switch switches S1 and S2. The capacitor C2 is advantageously connected to the low-resistance part of the integration arrangement, that is to say at the output 5. switched on. The switchover signal of the switchover module UB is present at the output 13 of the measuring arrangement and is also fed to the digitization as a weighting of the output signal f1. ^r 35

The comparators K2 ... K5 also serve to measure the level of the integration arrangement I when the

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ongoing integration cycles, i.e. when measuring very small currents («£ 1 pA integration time = 100 s). the Response thresholds can be graded as follows:

K2 <^ 200 mV
K3 A 400 mV
K4 <% 600 mV
K5 <a 800 mV

The edges of the comparator output signals are transmitted via the Summing element SU a timer TU (monoflop or time base circuit) supplied, which each pulses from a gives off a predetermined length. These signals present at the output 10 can also be used, for example, via an optocoupler be fed to a digitization.

4 claims
3 figures

Claims (4)

VPA 83 P 4419 DE claims 1. Measuring arrangement for the acquisition of current or voltage values with - an integration arrangement (i) in which the discharge time of at least one capacitor (C, C1, C2), which is dependent on the value of the current or voltage to be detected, is evaluated,
and with - At least one comparator (K) connected to the output of the integration arrangement (I), the switching thresholds of which are used to detect the beginning or end of the charging or Discharge times are suitable, whereby - the comparator (K) controls pulse-generating circuit means, the pulse frequency of which depends on _{the discharge time (At 1} , At ₂ ),
characterized in that - At least two comparators (KO, K1) to the integration arrangement (i) are switched on, the respective threshold values of which are dimensioned differently in such a way that the time interval between exceeding the threshold values depending on the gradient of the charging or Discharge curve of the integration arrangement (I) can be evaluated. 2. Measuring arrangement according to claim 1, characterized in that - the capacitive elements of the integration arrangement (i) consist of a number of capacitors (C1, C2) connected in parallel, at least one of which through Switching means (S1) can be separated or connected from the parallel circuit, and that - At least one switchover module (UB) is available which, if the time interval deviates, two '35 If the threshold value is exceeded by a specified range, the at least one is disconnected or switched on parallel capacitor (C1, C2) causes. - & - VPA 83 P 4419 DE
3. Measuring arrangement according to claim 2 with - A constant current source (IK), which the integration arrangement (I) with a charging current for a predetermined charging time supplied, whereby - the current to be measured for the discharge with one of the Value of the current-dependent discharge time ensures,
characterized in that - the constant current source via at least one switchable resistor (R2) with the integration arrangement (i) connected, where - the at least one resistor (R2) via the switching means (S2) controlled by the switchover module (UB)
can be switched on or off. 4. Measuring arrangement according to claim 2 or claim 3, characterized in that - The switching means (S1, S2) are MOS switches.