Optimized circuit architecture for VLSI ROTOR processors

The principle of operation of rotational trapezoidal readout (ROTOR), a novel processor of nuclear signals. has been recently demonstrated. Nevertheless the prototypes realized so far are affected by limiting factors that do not permit to fully exploit the potentialities of the ROTOR principle. For example, currently the weighting function is trapezoidal, which is not optimal for low-rate operation and/or when the 1/f noise of the preamplifier is not negligible. Furthermore, a very precise timing must be supplied for proper operation. In this paper, we suggest that these limitations can be overcome by: 1) shrinking the analog pulses provided by the preamplifier; 2) supplying them to the reference input of a digital-to-analog converter (DAC) used as a multiplier, whose digital-input tracks the wanted weighting function; and 3) integrating the signal at the DAC output. In this way, on the one hand the weighting function may be shaped so as to match the optimal profile, on the other hand precision is no longer required in the gating intervals, where the flat top and the shoulders of the weighting function lay. Eventually, the proposed solution is shown to be less sensitive to the parameter-matching accurateness of the used technology