A Novel Two-Channel Continuous-Time Time-Interleaved 3rd-order Sigma- Delta Modulator with Integrator-Sharing Topology

this paper presents a 3rd-order two-path Continuous-Time Time-Interleaved (CTTI) delta-sigma modulator which is implemented in standard 90nm CMOS technology. The architecture uses a novel method to resolve the delayless feedback path issue arising from the sharing of integrators between paths. By exploiting the concept of the time-interleaving techniques and through the use time domain equations, a conventional single path 3rd-order Discrete-Time (DT) ΔΣ modulator is converted into a corresponding two-path Discrete-Time Time-Interleaved (DTTI) counterpart. The equivalent Continuous-Time Time-Interleaved version derived from the DTTI ΔΣ modulator by determining the DT loop filters and converting them to the equivalent Continuous-Time (CT) loop filters through the use of the Impulse Invariant Transformation. Sharing the integrators between two paths of the reported modulator makes it robust to path mismatch effects compared to the typical Time-Interleaved (TI) modulators which have individual integrators in all paths. The modulator achieves a dynamic range of 12 bits with an OverSampling Ratio (OSR) of 16 over a bandwidth of 10MHz and dissipates only 28mW of power from a 1.8-V supply. The clock frequency of the modulator is 320MHz but integrators, quantizers and DACs operate at 160MHz

Resonation-based hybrid continuous-time/discrete-time cascade ΣΔ modulators: application to 4G wireless telecom

This paper presents innovative architectures of hybrid Continuous-Time/Discrete-Time (CT/DT) cascade ΣΔ Modulators (ΣΔMs) made up of a front-end CT stage and a back-end DT stage. In addition to increasing the digitized signal bandwidth as compared to conventional ΣΔMs, the proposed topologies take advantage of the CT nature of the front-end ΣΔM stage, by embedding anti-aliasing filtering as well as their suitability to operate up to the GHz range. Moreover, the presented modulators include multi-bit quantization and Unity Signal Transfer Function (USTF) in both stages to reduce the integrator output swings, and programmable resonation to optimally distribute the zeroes of the overall Noise Transfer Function (NTF), such that the in-band quantization noise is minimized for each operation mode. Both local and inter-stage (global) based resonation architectures are synthesized and compared in terms of their circuit complexity, resolution-bandwidth programmability and robustness with respect to circuit non-ideal effects. The combination of all mentioned characteristics results in novel hybrid ΣΔMs, very suited for the implementation of adaptive/reconfigurable Analog-to-Digital Converters (ADCs) intended for the 4th Generation (4G) of wireless telecom systems

A Low-Power Single-Bit Continuous-Time ΔΣ Converter with 92.5 dB Dynamic Range for Biomedical Applications

A third-order single-bit CT-ΔΣ modulator for generic biomedical applications is implemented in a 0.15 µm FDSOI CMOS process. The overall power efficiency is attained by employing a single-bit ΔΣ and a subthreshold FDSOI process. The loop-filter coefficients are determined using a systematic design centering approach by accounting for the integrator non-idealities. The single-bit CT-ΔΣ modulator consumes 110 µW power from a 1.5 V power supply when clocked at 6.144 MHz. The simulation results for the modulator exhibit a dynamic range of 94.4 dB and peak SNDR of 92.4 dB for 6 kHz signal bandwidth. The figure of merit (FoM) for the third-order, single-bit CT-ΔΣ modulator is 0.271 pJ/level

Design of a Comparator and an Amplifier in CMOS using standard logic gates

Using standard logic gates in CMOS, or standard-cells, has the advantage of full synthe- sizability, as well as the voltage scalability between technologies. In this work a general pur- pose standard-cell-based voltage comparator and amplifier are presented. The objective is to design a general purpose standard-cell-based comparator and ampli- fier in 130 nm CMOS by optimizing the already existing topologies with the aim of improving some of the specifications of the studied topologies. Various simulation testbenches were made to test the studied topologies of comparators and amplifiers, in which the results were compared. The top performing standard-cell com- parator and amplifier were then modified. After successfully designing the comparator, it was used in the design of an opamp-less Sigma-Delta modulator (ΣΔM). The proposed comparator is an OR-AND-Inverter-based comparator with dual inputs and outputs, achieving a delay of 109 ps, static input offset of 591 μV, and random offset of 10.42 μV, while dissipating 890 μW, when clocked at 1.5 GHz. The proposed amplifier is a single-path three-stage inverter-based operational transcon- ductance amplifier (OTA) with active common-mode feedback loop, achieving a DC gain of 63 dB, 1444 MHz of unity-gain bandwidth, 51º of phase margin while dissipating 1098 μW, considering a load of 1 pF. The proposed comparator was employed in the ΣΔM with a standard-cell based edge- triggered flip-flop. The ΣΔM, with a sampling frequency of 2 MHz and a signal bandwidth of 2.5 kHz, achieved a peak SNDR of 69 dB while dissipating only 136.7 μW.Utilizando portas lógicas básicas em CMOS oferece a vantagem de um circuito comple- tamente sintetizável, tal como o escalamento de tensão entre tecnologias. Neste trabalho são apresentados um comparador de tensão e um amplificador utilizando portas lógicas. O objetivo deste trabalho é desenhar um comparador e um amplificador utilizando por- tas lógicas através do estudo e otimização de topologias já existentes com a finalidade de me- lhoramento de algumas das especificações das mesmas. Foram realizados vários bancos de teste para testar as topologias estudadas de compa- radores e amplificadores, em que os resultados foram comparados. As topologias de compa- radores e amplificadores de portas lógicas com melhor performance foram então modificadas. Após o comparador ter sido projetado com sucesso, foi utilizado na projeção de um modula- dor Sigma-Delta (ΣΔM) opamp-less. O comparador proposto é um OR-AND-Inversor com duas entradas e saídas, que apre- senta um atraso de 109 ps, offset estático na entrada de 591 μV, offset aleatório de 10.42 μV, enquanto dissipando 890 μW, utilizando uma frequência de relógio de 1.5 GHz O amplificador proposto é um amplificador operacional de transcondutância single- path three-stage inverter-based com um loop ativo de realimentação do modo-comum, que apresenta um ganho DC de 63 dB, 1444 MHz de ganho-unitário de largura de banda, 51º de margem de fase e dissipando 1098 μW, considerando uma carga de 1 pF. O comparador proposto foi aplicado no ΣΔM com um flip-flop edge-triggered baseado em portas lógicas. O ΣΔM, com uma frequência de amostragem de 2 MHz e uma largura de banda de 2.5 kHz, apresentou um SNDR máximo de 69 dB enquanto dissipando apenas 136.7 μW

Jitter Tolerant Hybrid Sigma-Delta Modulator

Commonly used in wireless applications and consumer products, Continuous-time (CT) Sigma Delta (Σ∆) Analog to Digital Converter (ADC) stands out for its high resolution, less input signal conditioning and large incorporating with digital signal processing. The clock jitter impact on CT Σ∆ ADC is a critical issue as it will directly increase the noise floor within signal bandwidth. Thus, reducing jitter sensitivity is beneficial for improving the performance of CT Σ∆ ADC. This thesis presents a novel idea of reducing CT Σ∆ ADC jitter sensitivity by splitting one stage of continuous-time integrator into two parts - a gain stage and a digital low-pass filter. The gain stage remains prior to quantizer for compensating the loss of loop gain when removing the original continuous-time integrator. The digital filter is placed at the output of quantizer to suppress the out-of-band noise level. This hybrid Σ∆ ADC is implemented with two configurations in system level with TSMC 40nm CMOS technology at 20 MHz bandwidth and 640 MHz sampling frequency. The maximum SNR of the hybrid Σ∆ ADC is 69.18 dB. The proposed ADC achieves the maximum of 14 dB better SQNR than the conventional CT Σ∆ ADC at RMS jitter as high as 10% of the clock period. A negative resistor gain boosting single stage amplifier is also presented in this thesis

Design Considerations for Wide Bandwidth Continuous-Time Low-Pass Delta-Sigma Analog-to-Digital Converters

Continuous-time (CT) delta-sigma (ΔΣ) analog-to-digital converters (ADC) have emerged as the popular choice to achieve high resolution and large bandwidth due to their low cost, power efficiency, inherent anti-alias filtering and digital post processing capabilities. This work presents a detailed system-level design methodology for a low-power CT ΔΣ ADC. Design considerations and trade-offs at the system-level are presented. A novel technique to reduce the sensitivity of the proposed ADC to clock jitter-induced feedback charge variations by employing a hybrid digital-to-analog converter (DAC) based on switched-capacitor circuits is also presented. The proposed technique provides a clock jitter tolerance of up to 5ps (rms). The system is implemented using a 5th order active-RC loop filter, 9-level quantizer and DAC, achieving 74dB SNDR over 20MHz signal bandwidth, at 400MHz sampling frequency in a 1.2V, 90 nm CMOS technology. A novel technique to improve the linearity of the feedback digital-to-analog converters (DAC) in a target 11-bits resolution, 100MHz bandwidth, 2GHz sampling frequency CT ΔΣ ADC is also presented in this work. DAC linearity is improved by combining dynamic element matching and automatic background calibration to achieve up to 18dB improvement in the SNR. Transistor-level circuit implementation of the proposed technique was done in a 1.8V, 0.18μm BiCMOS process