Abstract—61-modulation is a proven method to realize high- and very high-resolution analog-to-digital converters. A particularly efficient way to implement such a modulator uses double-sampling where the circuit operates during both clock phases of the master-clock. Hence, the sampling frequency is twice the master-clock frequency. Unfortunately, path mismatch between both sampling branches causes a part of the quantization noise to fold from the Nyquist frequency back in the signal band. Therefore, the performance is severely degraded. In this paper, we show that the problem is reduced but not eliminated by employing multibit quantization. Next, we present an indepth solution for the problem. The approach consists of modifying the quantization noise transfer function of the overall modulator to have one or several zeros at the Nyquist frequency. This way the effect of noise folding can nearly be eliminated. It is shown that this can be implemented by a simple modification of one of the integrators of the overall modulator circuit. Finally, several design examples of single-bit and multibit modulators are discussed. Index Terms—Analog-to-digital conversion, double-sampling, spectral shaping.

Abstract—This work presents a study of the extended counting technique for a 1.2-V micropower voice-band A/D converter. This extended counting technique is a blend of 61 modulation with its high resolution but relatively low speed and algorithmic conversion with its higher speed but lower accuracy. To achieve this, the converter successively operates first as a first-order 61 modulator to convert the most significant bits, and then the same hardware is used as an algorithmic converter to convert the remaining least significant bits. An experimental prototype was designed in 0.8- m CMOS. With a 1.2-V power supply, it consumes 150 W of power at a 16-kHz Nyquist sampling frequency. The measured peak ƒ @x C „rhA was 80 dB and the dynamic range 82 dB. The converter core including the controller and all reconstruction logic occupies about I Q I mmP of chip area. This is considerably less than a complete 61 modulation A/D converter where the digital decimation filter would occupy a significant amount of chip area. Index Terms—Analog-to-digital, extended counting, low power, low voltage. I.

Abstract—Extended-counting analog-to-digital conversion combines the accuracy of 61 modulation with the speed of algorithmic conversion. In this paper, a double-sampling technique is introduced for this type of converter. It is based on a variant of the fully floating bilinear integrator. This way, the clock frequency of the converter is almost halved. An experimental converter was designed in a 0.6- m CMOS technology for a bandwidth of 500 kHz at a 3.3-V supply. In the switched-capacitor implementation, the hardware is extensively reused. This way, the converter can be realized with only one operational amplifier. On the other hand, compared to alternative implementations, the amount of switches is increased. These are designed carefully in order not to degrade the performance. The converter converts a sample in 24 clock cycles and achieves a dynamic range of 87 dB. The peak signal-to-noise ratio (SNR) and signal-to-noise-plus-distortion ratio (SNDR) were measured to be 82 and 81 dB, respectively. The power consumption was 28-mW analog and 20-mW digital. The converter core occupies 0.7 mmP including digital logic. Index Terms—Analog-to-digital conversion, double sampling, extended counting. I.