A body effect compensated switch for low voltage switched-capacitor circuits

为了减少NMOS开关阈值电压变化引起的信号失真,设计了一种适用于低压开关电容电路的体效应补偿开关,并利用该电路实现了一阶非反相开关电容(SC)低通滤波器。基于0.5μm标准CMOS工艺(Vtno=0.7 V,Vtpo=1.0 V)的SPICE仿真和总谐波失真(THD)的仿真结果表明:该电路具有很好的线性特性,采用该电路能够达到更优越的性能。Aimed at reducing distortion due to the threshold voltage variations of an NMOS switch,the paper introduces the design of a body effect compensated switch applicable to low voltage switched capacitor circuits.The simulation using SPICE,based on 0.5μm standard CMOS technology(V_(tno)=0.7V,V_(tpo)=1.0V) indicates that the better performance of the total harmonic distortion(THD) is attributed to the use of the designed circuit in a first-order non-inverting switched-capacitor(SC) low pass filter.厦门市科技计划项目资助(3502Z20031089

High speed – energy efficient successive approximation analog to digital converter using tri-level switching

This thesis reports issues and design methods used to achieve high-speed and high-resolution Successive Approximation Register analog to digital converters (SAR ADCs). A major drawback of this technique relates to the mismatch in the binary ratios of capacitors which causes nonlinearity. Another issue is the use of large capacitors due to nonlinear effect of parasitic capacitance. Nonlinear effect of capacitor mismatch is investigated in this thesis. Based on the analysis, a new Tri-level switching algorithm is proposed to reduce the matching requirement for capacitors in SAR ADCs. The integral non-linearity (INL) and the differential non-linearity (DNL) of the proposed scheme are reduced by factor of two over conventional SAR ADC, which is the lowest compared to the previously reported schemes. In addition, the switching energy of the proposed scheme is reduced by 98.02% compared with the conventional SAR architecture. A new correction method to solve metastability error of comparator based on a novel design approach is proposed which reduces the required settling time about 1.1τ for each conversion cycle. Based on the above proposed methods two SAR ADCs: an 8-bit SAR ADC with 50MS/sec sampling rate, and a 10-bit SAR split ADC with 70 MS/sec sampling rate have been designed in 0.18μm Silterra complementary metal oxide semiconductor (CMOS) technology process which works at 1.2V supply voltage and input voltage of 2.4Vp-p. The 8-bit ADC digitizes 25MHz input signal with 48.16dB signal to noise and distortion ratio (SNDR) and 52.41dB spurious free dynamic range (SFDR) while consuming about 589μW. The figure of merit (FOM) of this ADC is 56.65 fJ/conv-step. The post layout of the 10-bit ADC with 1MHz input frequency produces SNDR, SFDR and effective number of bits (ENOB) of 57.1dB, 64.05dB and 9.17Bit, respectively, while its DNL and INL are -0.9/+2.8 least significant bit (LSB) and -2.5/+2.7 LSB, respectively. The total power consumption, including digital, analog and reference power, is 1.6mW. The FOM is 71.75fJ/conv. step

Novel techniques for the design and practical realization of switched-capacitor circuits in deep-submicron CMOS technologies

Dissertação apresentada para obtenção do Grau de Doutor em Engenharia Electrotécnica e de Computadores pela Universidade Nova de Lisboa, Faculdade de Ciências e TecnologiaSwitches presenting high linearity are more and more required in switched-capacitor circuits,namely in 12 to 16 bits resolution analog-to-digital converters. The CMOS technology evolves continuously towards lower supply voltages and, simultaneously, new design techniques are necessary to fulfill the realization of switches exhibiting a high dynamic range and a distortion compatible with referred resolutions. Moreover, with the continuously downing of the sizes, the physic constraints of the technology must be considered to avoid the excessive stress of the devices when relatively high voltages are applied to the gates. New switch-linearization techniques, with high reliability, must be necessarily developed and demonstrated in CMOS integrated circuits. Also, the research of new structures of circuits with switched-capacitor is permanent. Simplified and efficient structures are mandatory, adequate to the new demands emerging from the proliferation of portable equipments, necessarily with low energy consumption while assuring high performance and multiple functions. The work reported in this Thesis comprises these two areas. The behavior of the switches under these new constraints is analyzed, being a new and original solution proposed, in order to maintain the performance. Also, proposals for the application of simpler clock and control schemes are presented, and for the use of open-loop structures and amplifiers with localfeedback. The results, obtained in laboratory or by simulation, assess the feasibility of the presented proposals