Estimation of the error and interference immunity of the analog-to-digital conversion path in automatic control systems

A technique has been devised for determination of the error and interference immunity of the analog- to-digital conversion path in automatic control systems using moving digital averaging. The estimates of the errors and interference immunity of the analog-to-digital conversion path under the moving averaging have been analyzed and compared with the corresponding estimates obtained under averaging within the time-sampling interval and in the absence of averaging. Effective analytical expressions have been obtained to analyze the estimates of the errors and interference immunity of the analog-to-digital conversion of stationary random signals and additive interference. The calculated errors for various differentiable and nondifferentiable random signals given by autocorrelation functions have been analyzed. The influence of the number of the averaged readouts of the random signal and the time-sampling interval on the estimates of the errors and interference immunity have been investigated. The advantage of the moving averaging over the averaging within the time-sampling interval has been demonstrated. The calculated ratios allow, with the known signal and interference models and preset permissible-error estimate, selecting the parameters of the conversion path, i.e., the time-sampling interval, the number of the readouts of the converted sum of the random signal and interference under the averaging, and the effective number of bits of the analog-to-digital converter, under the conditions when the lag error cannot be excluded and the latter is excluded. The equations that allow the evaluation of the interference immunity of the conversion path are provided.