Resistance, inductance and capacitance measurement method based on damping oscillatory wave in oscillation circuit

Abstract

The invention provides a resistance, inductance and capacitance measurement method based on damping oscillatory wave in an oscillation circuit. According to the method, an improved discrete Fourier algorithm is used to realize high-precision measurement of resistance, inductance and capacitance parameters; window function processing is carried out on a detection voltage signal; the influence of a truncation effect in standard discrete Fourier transformation can be effectively suppressed; the accuracy of Fourier transformation is improved; the measurement accuracy of resistance, inductance and capacitance parameters is improved; on the basis that window function processing is carried out on the detection voltage signal, a single spectral line interpolation algorithm is further used; frequency calculation errors caused by non-integer number cycle sampling are corrected; spectral amplitude errors caused by the truncation effect are corrected; and the accuracy of the measurement method is further improved.

Description

technical field [0001] The invention belongs to the technical field of sensor measurement, in particular to a method for measuring resistance, inductance and capacitance based on damped oscillation waves in an oscillation circuit. Background technique [0002] Resistors, inductors and capacitors are the three most basic electronic components. In the field of sensor measurement, many physical quantities can be transformed into measurements of resistance, inductance and capacitance. For example, the temperature can be measured by measuring the resistance of the thermistor; the distance between the coil and the metal object can be calculated by measuring the inductance of the coil; the distance between two metal plates can be obtained by measuring the capacitance. Typically, resistance, inductance, and capacitance can be accurately measured using bridge circuits. However, in some special occasions, such as the occasions where the resistance value is very small or the measured...

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Problems solved by technology

However, this measurement method has certain limitations: since this method directly calculates the sampled voltage information in the time domain, the sampled voltage itself is small and is easily affected by noise and parasitic parameters, which affects the measurement accuracy; in addition, the algorithm is effective The number of sampling points used is small, which is greatly affected by random errors, which limits the measurement accuracy

However, this frequency-domain algorithm based on standard discrete Fourier transform still has limitations: due to the limitation of sampling frequency and synchronous sampling, there must be cases of non-integer period sampling, that is, the detection voltage signal period is not an integer of the sampling period At this time, the standard discrete Fourier transform will have a truncation effect. The truncation effect includes spectrum leakage and inter-spectrum interference, resulting in errors in the calculated detection voltage frequency and spectrum amplitude, which limits the improvement of resistance (temperature) measurement accuracy.

[0005] The above two methods can be used for non-contact measurement of resistance, but the measurement accuracy is limited

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