A selectable-bandwidth 3.5 mW, 0.03 mm(2) self-oscillating Sigma Delta modulator with 71 dB dynamic range at 5 MHz and 65 dB at 10 MHz bandwidth

In this paper we present a dual-mode third order continuous time Sigma Delta modulator that combines noise shaping and pulse-width-modulation (PWM). In our 0.18 micro-m CMOS prototype chip the clock frequency equals 1 GHz, but the PWM carrier is only around 125 MHz. By adjusting the loop filter, the ADC bandwidth can be set to 5 or 10 MHz. In the 5 MHz mode the peak SNDR equals 64 dB and the dynamic range 71 dB. In the 10 MHz mode the peak SNDR equals 58 dB and the DR 65 dB. This performance is achieved at an attractively low silicon area of 0.03 mm^2 and a power consumption of 3.5 mW

Prediction of the Spectrum of a Digital Delta–Sigma Modulator Followed by a Polynomial Nonlinearity

This paper presents a mathematical analysis of the power spectral density of the output of a nonlinear block driven by a digital delta-sigma modulator. The nonlinearity is a memoryless third-order polynomial with real coefficients. The analysis yields expressions that predict the noise floor caused by the nonlinearity when the input is constant

A 13-bit, 2.2-MS/s, 55-mW multibit cascade ΣΔ modulator in CMOS 0.7-μm single-poly technology

This paper presents a CMOS 0.7-μm ΣΔ modulator IC that achieves 13-bit dynamic range at 2.2 MS/s with an oversampling ratio of 16. It uses fully differential switched-capacitor circuits with a clock frequency of 35.2 MHz, and has a power consumption of 55 mW. Such a low oversampling ratio has been achieved through the combined usage of fourth-order filtering and multibit quantization. To guarantee stable operation for any input signal and/or initial condition, the fourth-order shaping function has been realized using a cascade architecture with three stages; the first stage is a second-order modulator, while the others are first-order modulators - referred to as a 2-1-1mb architecture. The quantizer of the last stage is 3 bits, while the other quantizers are single bit. The modulator architecture and coefficients have been optimized for reduced sensitivity to the errors in the 3-bit quantization process. Specifically, the 3-bit digital-to-analog converter tolerates 2.8% FS nonlinearity without significant degradation of the modulator performance. This makes the use of digital calibration unnecessary, which is a key point for reduced power consumption. We show that, for a given oversampling ratio and in the presence of 0.5% mismatch, the proposed modulator obtains a larger signal-to-noise-plus-distortion ratio than previous multibit cascade architectures. On the other hand, as compared to a 2-1-1single-bit modulator previously designed for a mixed-signal asymmetrical digital subscriber line modem in the same technology, the modulator in this paper obtains one more bit resolution, enhances the operating frequency by a factor of two, and reduces the power consumption by a factor of four.Comisión Interministerial de Ciencia y Tecnología TIC97-0580European Commission ESPRIT 879

A 3.3 V two-stage fourth-order sigma-delta modulator with gain compensation technique

[[abstract]]We propose a multistage fourth order sigma-delta (ΣΔ) modulator with reduced sensitivity to the gain of operating amplifier. In the low voltage high order ΣΔ modulator, the gain of the operating amplifier is usually the most critical problem of the design. In order to overcome the difficulties of the high gain low voltage operating amplifier, we try to use medium gain operating amplifiers to design a fourth order multistage ΣΔ modulator, and find that it functions very well. The modulator is realized in a 0.5 μm DPDM process with an active area of 1.8 mm2. The HSPICE simulation shows this ΣΔ modulator with a maximum signal-to-noise-ratio (SNR) of 91 dB.[[conferencetype]]國際[[conferencedate]]19981124~19981127[[booktype]]紙本[[conferencelocation]]Chiangmai, Thailan

Coding, Decoding, and Recovery of Clock Synchronization in Digital Multiplexing System

High-speed broadband digital communication networks rely on digital multiplexing technology where clock synchronization, including processing, transmission, and recovery of the clock, is the critical technique. This paper interprets the process of clock synchronization in multiplexing systems as quantizing and coding the information of clock synchronization, interprets clock justification as timing sigma-delta modulation (TΔ-ΣM), and interprets the jitter of justification as quantization error. As a result, decreasing the quantization error is equivalent to decreasing the jitter of justification. Using this theory, the paper studies the existing jitter-reducing techniques in transmitters and receivers, presents some techniques that can decrease the quantization error (justification jitter) in digital multiplexing systems, and presents a new method of clock recovery

A GUI driven Σ-Δ modulator design, evaluation and measurement tool with a view to practical implementation

A user-friendly design tool created in the MATLAB/Simulink environment to speed up the design, analysis, evaluation and measurement of single-loop and multistage sigma-delta (Sigma-Delta) modulators at the system level is presented in this paper. The tool covers a variety of Simulink-based design topologies of low-pass, band-pass and high-pass Sigma-Delta modulators

Design and Analysis of a Low-Power 8-Bit 500 KS/S SAR ADC for Bio-Medical Implant Devices

This thesis project involves the design and analysis of an 8-bit Successive Approximation Register (SAR) Analog to Digital Convertor (ADC), designed for low- power applications such as bio-medical implants. The sampling rate for this ADC is 500 KS/s. The power consumption for the whole SAR ADC system was measured to be 2.1 uW. The novelty of this project is the proposal of an extremely energy efficient comparator architecture. The result is the design of a final ADC with reasonable sampling speed, accuracy and low power consumption. In this project, all the different subsystems have been designed at the transistor level with 45 nm CMOS technology. The logical circuit was designed using Verilog language. It was then synthesized and integrated in the overall system