Design Techniques for Wideband Low-power Delta-Sigma Analog-to-digital Converters - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Design Techniques for Wideband Low-power Delta-Sigma Analog-to-digital Converters write by Yan Wang. This book was released on 2010. Design Techniques for Wideband Low-power Delta-Sigma Analog-to-digital Converters available in PDF, EPUB and Kindle. Delta-Sigma analog-to-digital converters (ADCs) are traditionally used in high quality audio systems, instrumentation and measurement (I&M) and biomedical devices. With the continued downscaling of CMOS technology, they are becoming popular in wideband applications such as wireless and wired communication systems,high-definition television and radar systems. There are two general realizations of a [Delta-Sigma] modulator. One is based on the discrete-time (DT) switched-capacitor (SC) circuitry and the other employs continuous-time (CT) circuitry. Compared to a CT structure, the DT [Delta-Sigma] ADC is easier to analyze and design, is more robust to process variations and jitter noise, and is more flexible in the multi-mode applications. On the other hand, the CT [Delta-Sigma] ADC does not suffer from the strict settling accuracy requirement for the loop filter and thus can achieve lower power dissipation and higher sampling frequency than its DT counterpart. In this thesis, both DT and CT [Delta-Sigma] ADCs are investigated. Several design innovations, in both system-level and circuit-level, are proposed to achieve lower power consumption and wider signal bandwidth. For DT [Delta-Sigma] ADCs, a new dynamic-biasing scheme is proposed to reduce opamp bias current and the associated signal-dependent harmonic distortion is minimized by using the low-distortion architecture. The technique was verified in a 2.5MHz BW and 13bit dynamic range DT [Delta-Sigma] ADC. In addition, a second-order noise coupling technique is presented to save two integrators for the loop filter, and to achieve low power dissipation. Also, a direct-charge-transfer (DCT) technique is suggested to reduce the speed requirements of the adder, which is also preferable in wideband low-power applications. For CT [Delta-Sigma] ADCs, a wideband low power CT 2-2 MASH has been designed. High linearity performance was achieved by using a modified low-distortion technique, and the modulator achieves higher noise-shaping ability than the single stage structure due to the inter-stage gain. Also, the quantization noise leakage due to analog circuit non-idealities can be adaptively compensated by a designed digital calibration filter. Using a 90nm process, simulation of the modulator predicts a 12bit resolution within 20MHz BW and consumes only 25mW for analog circuitry. In addition, the noise-coupling technique is investigated and proposed for the design of CT [Delta-Sigma] ADCs and it is promising to achieve low power dissipation for wideband applications. Finally, the application of noise-coupling technique is extended and introduced to high-accuracy incremental data converters. Low power dissipation can be expected.
High Efficiency Wideband Low-power Delta-sigma Modulators
High Efficiency Wideband Low-power Delta-sigma Modulators - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook High Efficiency Wideband Low-power Delta-sigma Modulators write by Sang Hyeon Lee. This book was released on 2012. High Efficiency Wideband Low-power Delta-sigma Modulators available in PDF, EPUB and Kindle. Delta-sigma analog-to-digital converters traditionally have been used for low speed, high resolution applications such as measurements, sensors, voice and audio systems. Through continued device scaling in CMOS technology and architectural and circuit level design innovations, they have even become popular for wideband, high dynamic range applications such as wired and wireless communication systems. Therefore, power efficient wideband low power delta-sigma data converters that bridges analog and digital have become mandatory for popular mobile applications today. In this dissertation, two architectural innovations and a development and realization of a state-of-the-art delta-sigma analog to digital converter with effective design techniques in both architectural and circuit levels are presented. The first one is timing-relaxed double noise coupling which effectively provides 2nd order noise shaping in the noise transfer function and overcomes stringent timing requirement for quantization and DEM. The second one presented is a noise shaping SAR quantizer, which provides one order of noise shaping in the noise transfer function. It uses a charge redistribution SAR quantizer and is applied to a timing-relaxed lowdistortion delta-sigma modulator which is suitable for adopting SAR quantizer. Finally a cascade switched capacitor delta-sigma analog-to-digital converter suitable for WLAN applications is presented. It uses a noise folding free double sampling technique and an improved low-distortion architecture with an embedded-adder integrator. The prototype chip is fabricated with a double poly, 4 metal, 0.18[micro]m CMOS process. The measurement result achieves 73.8 dB SNDR over 10 MHz bandwidth. The figure of merit defined by FoM = P/(2 x BW x 2[superscript ENOB]) is 0.27 pJ/conv-step. The measurement results indicate that the proposed design ideas are effective and useful for wideband, low power delta-sigma analog-to-digital converters with low oversampling ratio.
Sigma-Delta Converters: Practical Design Guide
Sigma-Delta Converters: Practical Design Guide - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Sigma-Delta Converters: Practical Design Guide write by Jose M. de la Rosa. This book was released on 2018-11-05. Sigma-Delta Converters: Practical Design Guide available in PDF, EPUB and Kindle. Thoroughly revised and expanded to help readers systematically increase their knowledge and insight about Sigma-Delta Modulators Sigma-Delta Modulators (SDMs) have become one of the best choices for the implementation of analog/digital interfaces of electronic systems integrated in CMOS technologies. Compared to other kinds of Analog-to-Digital Converters (ADCs), Σ∆Ms cover one of the widest conversion regions of the resolution-versus-bandwidth plane, being the most efficient solution to digitize signals in an increasingly number of applications, which span from high-resolution low-bandwidth digital audio, sensor interfaces, and instrumentation, to ultra-low power biomedical systems and medium-resolution broadband wireless communications. Following the spirit of its first edition, Sigma-Delta Converters: Practical Design Guide, 2nd Edition takes a comprehensive look at SDMs, their diverse types of architectures, circuit techniques, analysis synthesis methods, and CAD tools, as well as their practical design considerations. It compiles and updates the current research reported on the topic, and explains the multiple trade-offs involved in the whole design flow of Sigma-Delta Modulators—from specifications to chip implementation and characterization. The book follows a top-down approach in order to provide readers with the necessary understanding about recent advances, trends, and challenges in state-of-the-art Σ∆Ms. It makes more emphasis on two key points, which were not treated so deeply in the first edition: It includes a more detailed explanation of Σ∆Ms implemented using Continuous-Time (CT) circuits, going from system-level synthesis to practical circuit limitations. It provides more practical case studies and applications, as well as a deeper description of the synthesis methodologies and CAD tools employed in the design of Σ∆ converters. Sigma-Delta Converters: Practical Design Guide, 2nd Edition serves as an excellent textbook for undergraduate and graduate students in electrical engineering as well as design engineers working on SD data-converters, who are looking for a uniform and self-contained reference in this hot topic. With this goal in mind, and based on the feedback received from readers, the contents have been revised and structured to make this new edition a unique monograph written in a didactical, pedagogical, and intuitive style.
Understanding Delta-Sigma Data Converters
Understanding Delta-Sigma Data Converters - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Understanding Delta-Sigma Data Converters write by Shanthi Pavan. This book was released on 2017-01-24. Understanding Delta-Sigma Data Converters available in PDF, EPUB and Kindle. This new edition introduces operation and design techniques for Sigma-Delta converters in physical and conceptual terms, and includes chapters which explore developments in the field over the last decade Includes information on MASH architectures, digital-to-analog converter (DAC) mismatch and mismatch shaping Investigates new topics including continuous-time ΔΣ analog-to-digital converters (ADCs) principles and designs, circuit design for both continuous-time and discrete-time ΔΣ ADCs, decimation and interpolation filters, and incremental ADCs Provides emphasis on practical design issues for industry professionals
Wideband Discrete-time Delta-sigma Analog-to-digital Converters with Shifted Loop Delays
Wideband Discrete-time Delta-sigma Analog-to-digital Converters with Shifted Loop Delays - read free eBook in online reader or directly download on the web page. Select files or add your book in reader. Download and read online ebook Wideband Discrete-time Delta-sigma Analog-to-digital Converters with Shifted Loop Delays write by Xin Meng. This book was released on 2015. Wideband Discrete-time Delta-sigma Analog-to-digital Converters with Shifted Loop Delays available in PDF, EPUB and Kindle. Low-distortion architecture is widely used in wideband discrete-time switched-capacitor delta-sigma ADC design. However, it suffers from the power-hungry active adder and critical timing for quantization and dynamic element matching (DEM). To solve this problem, this dissertation presents a delta-sigma modulator architecture with shifted loop delays. In this project, shifted loop delays (SLD) technique can relax the speed requirements of the quantizer and the dynamic element matching (DEM) block, and eliminate the active adder. An implemented 0.18 um CMOS prototype with the proposed architecture provided 81.6 dB SNDR, 81.8 dB dynamic range, and -95.6 dB THD in a signal bandwidth of 4 MHz. It dissipates 19.2 mW with a 1.6 V power supply. The conventional low-distortion ADC was also implemented on the same chip for comparison. The new circuit has superior performance, and dissipates 25% less power (19.2 mW vs. 24.9 mW) than the conventional one. The figure-of-merit for the ADC with SLD is among the best reported for wideband discrete-time ADCs, and is almost 40% better than that of the conventional ADC. The second project describes two techniques to enhance the noise shaping function in the proposed low-distortion [delta sigma] modulator with shifted loop delays. One is self-noise coupling based on low-distortion [delta sigma] structure; the other is noise-coupled time-interleaved [delta sigma] modulator. Both architectures use shifted loop delays to relax the critical timing constraints in the modulator feedback path, then to save power consumption of each block in the modulators. Two [delta sigma] ADCs were analyzed and simulated in a 0.18 um CMOS technology. The simulation results highly verify the effectiveness of the proposed structure. The third system describes the design technique for double-sampled wideband [delta sigma] ADCs with shifted loop delays (SLD). The added loop delay in the feedback branch relaxes the critical timing for DEM logic. Delay shifting can be combined with such useful techniques as low-distortion circuitry and noise coupling for wideband [delta sigma] modulators. The presented techniques relax the timing for inherent quantization delay, reduce the speed requirements for the critical circuit blocks, and achieve power efficiency by replacing the power-hungry blocks normally used in the modulators. Analysis of all architectures allows the choice of the most power-efficient topology for a wideband [delta sigma] modulator. The proposed second-order and third-order [delta sigma] modulators were designed and simulated to verify the effectiveness of the shifted loop delays techniques.
