Automatic Offset Cancellation and Time-Constant Reduction in Charge-Sensitive Preamplifiers

A circuit technique is presented which eliminates the offset at the output of charge-sensitive preamplifiers and optionally reduces the resistive reset time-constant. Offset cancellation as well as time-constant reduction are obtained with no trimming. Offset cancellation is obtained actively through a negative feedback path whose ¿error¿ variable is the offset itself. As a result the output voltage offset is automatically eliminated, irrespective of the bias point of the input transistor and the dark current of the sensor connected to the preamplifier. Using the proposed technique in low-noise charge preamplifiers for germanium detectors typical offsets in the range 100-300 mV are reduced to ±2 mV. The noise of the preamplifier is unaffected by the offset cancellation circuit. Moreover, by insertion of an optional resistor in the proposed circuitry the decay time-constant of the preamplifier is automatically reduced by a factor of up to 10, while leaving unchanged the noise and the sensitivity of the charge preamplifier. This improves pulse separation at the preamplifier's output, which can be particularly useful for pattern recognition at high event rates. The realized offset-free circuit features an equivalent noise of 650 eV fwhm in germanium at 3 ¿s shaping time, i.e. an Equivalent Noise Charge of ~ 94 electrons r.m.s. and a dynamic range in excess of 86 dB, which makes it perfectly suited for high-resolution gamma-ray spectrometry with large germanium detectors.

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