DE102015200654B4 - Method for compensating parasitic inductances in current measuring resistors - Google Patents

Abstract

A method of compensating for the influence of a parasitic inductance of a current measuring resistor (10) having a known resistive component on the magnitude of a voltage drop across the current sensing resistor (10) determining the magnitude of a current having a time course comprising recurring periods of time within which the current falls and / or rises, wherein the current within a measurement interval which is equal to at least part of a time portion of the time course of the current is determined at a measurement time at which its value is substantially equal to the average value of the current within the measurement interval, wherein the procedure
the course of the voltage drop over a resistance through which the current to be measured has been measured with the above time characteristic has a purely ohmic resistance which is equal to the ohmic portion of the current measuring resistor (10),
- Wherein the determined course of the voltage drop from the above the current measuring resistor (10) adjusting, metrologically detected course of the voltage drop deviates by an offset resulting from the parasitic inductance,
- Wherein the measuring time point within the measuring interval is brought forward until the metrologically detected course of the voltage drop across the current measuring resistor (10) substantially equal to the determined course of the voltage drop across the resistor with pure ohmic proportion, equal to the ohmic portion of the current measuring resistor and thus to the offset is compensated, and
- wherein the metrologically detected voltage drop across the current measuring resistor (10) is filtered by means of a low-pass filter (18) having a group delay, wherein the measuring time is delayed by the size of the group delay.

Description

The invention relates to a method for compensating the influence of a parasitic inductance of a current resisting resistor having a known resistive component on the size of a voltage drop across the current measuring resistance determination of the size of a current with a time course having recurring periods, within which the current drops and The current within a measurement interval equal to at least a portion of a time portion of the current is determined at a measurement instant at which its value is substantially equal to the average of the current within the measurement interval.

Such a procedure is over DE 10 2006 047 707 A1 known.

For metrological detection of the supply current of an electrical component or an electrical device, it is known to use current measuring resistors (so-called shunts). In the case of current profiles with alternating components, one is sometimes not interested in the course of the current itself but in the mean value of the current. In order to avoid a more or less complex averaging, it is therefore sometimes the case that the size of the current is determined or sampled within a measuring interval at the time at which the sample provides the mean value of the current with respect to the measuring interval. In the case of a current profile which has a linearly rising or linearly decreasing period of time, it would therefore be necessary to sample at a measuring interval with a time span from T to the instant 1 / 2T.

A certain problem with the use of shunts may be their parasitic inductances. These lead to an offset in the course of time of the voltage drop across the SHUNT during current curves with alternating components. Even if this offset is in the sub-mV range, it can nonetheless be annoying.

Out WO 2005/031955 A1 It is known that parasitic inductances come into consideration as a possible reason for temporal errors of the current courses.

Finally it is over US 2004/0056661 A1 known to filter the voltage drop across a current sense resistor.

The object of the invention is thus to provide a method for compensating the influence of a parasitic inductance of a current measuring resistor.

To solve this problem, a method is proposed with the invention, with which the influence of a parasitic inductance of a known ohmic share current measuring resistor can be compensated for taking place on the basis of the size of a voltage drop across the current measuring resistor determination of the size of a current with a time course, the wherein the current within a measurement interval which is equal to at least part of a time segment of the current is determined at a measurement time at which its value is substantially equal to the mean value of the current Current within the measuring interval, the method according to a first variant having the features of claim 1.

According to this aforementioned first variant of the invention, the course of the voltage drop, which occurs during the measuring interval over the current measuring resistor having a parasitic inductance, is empirically compared with the profile of that voltage drop which can be determined by calculation or by simulation in the case that the current measuring resistor exclusively the known resistive component, so no parasitic inductance. It is also possible to determine this real current value by an additional measuring device, which is connected, for example, only during the commissioning or only for the adjustment. The deviation (offset) of the two voltage profiles over the measurement interval results from the parasitic inductance of the "real" current measuring resistor, provided that other sources / disturbances generating the offset are excluded or known. This offset can now be compensated by advancing the measurement time within the measurement interval relative to the measurement instant at which the value of the current profile is equal to the mean value of the current flowing during the measurement interval.

According to a variant of the invention, a method with the features of claim 2 is proposed to achieve the above object.

According to this variant of the invention, the period of time by which the measurement time required to compensate for the offset is shifted from the measurement time at which the sample of the current profile is equal to the mean value of the current within the measurement interval is computationally determined as the quotient the values of the parasitic inductance of the current measuring resistor and its ohmic component.

In both variants of the invention described above, it is provided in each case that the metrologically detected voltage drop across the current measuring resistor is filtered by means of a low-pass filter having a group delay, the measurement time is delayed by the size of the group delay. The known use of a filter, which is in particular a low-pass filter, causes a delay in the processing of the current profile. This delay is determined by the group delay of the filter used. In that regard, therefore, the "real" measurement time must be delayed compared to the "ideal" measurement time.

It may therefore be of particular advantage if the low-pass filter and / or the current measuring resistor is / are selected such that the group delay is substantially equal to the time span by which the measurement instant is to be advanced in order to compensate for the offset.

• 1 ein Schaltungsteildiagramm zur Verdeutlichung einer möglichen Applikation der Erfindung zur Strommessung bei einem Stepup/Stepdown-Konverter,
• 2. ein Schaltungsteildiagramm zur Verdeutlichung einer möglichen Applikation der Erfindung zur Strommessung bei einem Sperr-/Durchflusswandler, und
• 3 bis 5 verschiedene Strom- und Spannungsverlaufsdiagramme zur Verdeutlichung der Problemstellung und der erfindungsgemäßen Lösung.

The invention will be explained in more detail using an exemplary embodiment and with reference to the drawing. In detail, they show:

• 1 a circuit diagram illustrating a possible application of the invention for current measurement in a step-up / step-down converter,
• 2 , a circuit diagram illustrating a possible application of the invention for current measurement in a blocking / forward converter, and
• 3 to 5 various current and voltage waveform diagrams to illustrate the problem and the inventive solution.

The invention will be explained below with reference to a single half-bridge, but is equally valid for full-bridge systems, single-transistor systems (for example, flyback converters) and with small restrictions also for 3-phase systems. The invention can be used in all cases in which the electric current is to be determined within periods of time in which it varies in particular linearly.

In switching power supplies and inverters, especially in AC or inverters for controlling brushless servomotors often a current measurement is required, which is carried out in many cases due to the simple feasibility characterized in that in one or more switching element half-bridges or individual switching elements used (both preferably Transistors realized) between the supply voltage and the high-side switching element or the ground and the lowside switching element, a current measuring resistor 10 (Shunt) is inserted. This current measuring resistor 10 is, as long as the switching element connected to this is turned on, the current of the load 12 (eg motor inductance, storage choke, transformer) through which this current due to the current measuring resistor 10 resulting voltage drop can be measured (see 1 for the application with a Stepup / Stepdown converter for the scanning of an engine and 2 for a blocking or forward converter).

During operation, the highside and lowside switching elements switch 14 . 16 according to 1 alternately conducting, whereby (in the case of the half-bridge) once supply voltage and once ground on the connected (motor inductance applied., If one assumes approximately constant voltage at the downstream filter capacitor or briefly constant motor back voltage and negligible internal resistance of the (motor) inductance and the switching elements If one ignores saturation effects, then the current course through this inductance becomes triangular.This triangular rising and falling current, which is usually superimposed with a DC component, is in the current measuring resistor depending on the current flow direction 10 (because it is either switched off or switched on), either only the rising or falling ramp is visible (see 3 in which the motor coil current is a solid line and the current through the current sense resistor 10 shown as a dashed line).

The instantaneous current in the middle of a measuring time interval (eg a switch drive pulse) corresponds exactly to the average current through the motor inductance. This measured value, which is independent of the set pulse width, is used in the application of the invention described here by way of example for the control of inverters for brushless servomotors.

In order to achieve an acceptable system efficiency, it is preferable to use a current measuring resistor that is as low-impedance as possible, since this produces the lowest possible power loss due to the current flowing through it. However, the evaluable voltage drop is correspondingly small. In addition to the technical challenge to amplify this small voltage drop, the faulty measurement due to the parasitic inductance of the current measuring resistor with small resistances already plays a no longer negligible role. Even surface-mountable low-ohmic power resistors already have parasitic inductances in the range 1 until about 10nH. Current changes in the range of 1A / μs cause here voltage drops of 1mV or more, which is in the same order of magnitude as the voltage drop through the actual measuring current and thus the measurement considerably falsified. 4 shows the voltage drop at the current measuring resistor, if this has an internal resistance of 1mΩ and an inductance of 1nH. The ideal voltage curve on the purely resistive component is shown as a dashed line and the actual voltage drop resulting from ohmic resistance and parasitic inductance is shown as a solid line.

Based on the diagram of 4 Two effects can be observed. A first effect relates to the strong overshoot in the switching moment, which generates a high voltage drop at the inductance of the measuring resistor due to the rapid current change during switching. However, this effect has subsided quickly and is bypassed in the prior art in that at these times the signal is discarded. In addition, in practice, due to switching effects caused by the switching elements that are then no longer ideal after the switching points, there are additional disturbances which further worsen the measuring signal.

The second effect that stands out is an offset. This is caused by the ramp-changing current at the parasitic inductance of the measuring resistor. Thus, the measurement signal would not only depend on the actual current, but also of its change, but usually not exactly. is known, because the parameters of the connected (motor) inductance of a production serial spread, a temperature and a current dependence are subject, which makes modeling difficult.

In the following, a method or alternatively an arrangement is described, which can compensate for the measurement error by the additional current-change-dependent voltage drop through the measuring resistor with little effort and without knowledge of the connected inductance.

For the rest of the description, it is intended to consider, without limitation of generality, exactly the (ideal) sampling or measuring instant at which the instantaneous current equals the mean current through the inductance within a measuring interval. This current flows at the time centers of the measurement intervals (eg switch drive pulses) and is referred to below as I ₀ .

Under the above assumptions of the constant reverse voltage as well as the design of coil and switching elements without ohmic components, the current around this time around: $$I\left(t\right)=I_0+\frac{dI}{dT}t$$

The voltage across the current measuring resistor is composed of its resistive and inductive components: $$U_R=I\left(t\right)\cdot R+\frac{dI}{dT}\cdot L_R=I_0\cdot R+\frac{dI}{dT}\cdot t\cdot R+\frac{dI}{dT}\cdot L_R$$

It turns out that a voltage corresponding to the correct measured value can be obtained if the sampling of the signal takes place at a time advanced with respect to the middle of the pulse (measuring interval). This time is given when the two voltage change dependent terms of the previous equation compensate each other to zero: $$U_{R}sei{I}_0\cdot R\Rightarrow \frac{dI}{dT}\cdot t\cdot R+\frac{dI}{dT}\cdot L_R=0$$

verschoben werden. Kenntnisse über die angeschlossene (Motor-)Induktivität sind für die Kompensation nicht erforderlich. 5 zeigt das Ergebnis der zeitlichen Verschiebung. Die Kurve des resitiven Anteils der Messspannung und damit das eigentlich gewünschte Signal (siehe durchgezogene Line) und die verschobene Gesamtmessspannung (siehe gestrichelte Linie) liegen innerhalb des Messintervalls deckungsgleich übereinander.The sampling must therefore be around the time span $$t=-\frac{L_R}{R}$$

be moved. Knowledge of the connected (motor) inductance is not required for the compensation. 5 shows the result of the time shift. The curve of the resitive portion of the measuring voltage and thus the actual desired signal (see solid line) and the shifted total measuring voltage (see dashed line) are congruent one above the other within the measuring interval.

A further preferred embodiment is the group delay of a low-pass filter 18 (please refer 1 and 2 ) in the evaluation circuit for evaluating the voltage drop across the current measuring resistor to be selected so that the sum of group delay and required shift time is zero, so that as a sampling and then measuring time continues the pulse or measuring interval center can be used.

The concept according to the invention can be used, for example, to compensate for offset measuring voltages resulting from the parasitic inductances of current measuring resistors, for example in the case of inverters in brushless servomotors. It is true that other offset generating sources or disturbances are excluded or known (for example, a potential offset of a measuring amplifier or the like). In general, the invention can be used inter alia in robotics, namely in the control of brushless servomotors. Another application is conceivable in switched-mode power supplies or quite generally in the case of switched load inductors.

Claims (3)

A method of compensating for the influence of a parasitic inductance of a current measuring resistor (10) having a known resistive component on the magnitude of a voltage drop across the current measuring resistor (10) determining the magnitude of a current having a time characteristic which has recurring periods of time within which the current falls and / or rises, wherein the current within a measurement interval, which is equal to at least part of a time portion of the time course of the current is determined at a measurement time at which its value is substantially equal to the average value of the current within the measurement interval, wherein the procedure the course of the voltage drop over a resistance through which the current to be measured has been measured with the above time characteristic has a purely ohmic resistance which is equal to the ohmic portion of the current measuring resistor (10), - Wherein the determined course of the voltage drop from the above the current measuring resistor (10) adjusting, metrologically detected course of the voltage drop deviates by an offset resulting from the parasitic inductance, - Wherein the measuring time point within the measuring interval is brought forward until the metrologically detected course of the voltage drop across the current measuring resistor (10) substantially equal to the determined course of the voltage drop across the resistor with pure ohmic proportion, equal to the ohmic portion of the current measuring resistor and thus to the offset is compensated, and - wherein the metrologically detected voltage drop across the current measuring resistor (10) is filtered by means of a low-pass filter (18) having a group delay, wherein the measuring time is delayed by the size of the group delay. A method of compensating for the influence of a parasitic inductance of a current measuring resistor (10) having a known resistive component on the magnitude of a voltage drop across the current measuring resistor (10) determining the magnitude of a current having a time characteristic which has recurring periods of time within which the current falls and / or rises, wherein the current within a measurement interval, which is equal to at least part of a time portion of the time course of the current is determined at a measurement time at which its value is substantially equal to the average value of the current within the measurement interval, wherein the procedure the parasitic inductance and the resistive component of the current measuring resistor 10 are determined or provided, - The measuring time within the measuring interval is advanced by a period equal to the quotient of the value of the inductance and the value of the ohmic portion of the current measuring resistor (10), whereby the metrologically determined course of the voltage drop across the current measuring resistor (10) to the its offset resulting from its parasitic inductance is compensated, and - The metrologically detected voltage drop across the current measuring resistor (10) is filtered by means of a low-pass filter (18) having a group delay, wherein the measuring time is delayed by the size of the group delay. Method according to Claim 1 or 2 , characterized in that the low-pass filter (18) and / or the current measuring resistor (10) is / are chosen such that the group delay is substantially equal to the period by which the measurement time is advanced in order to compensate for the offset.

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