High speed floating analog to digital converter and interpolating digital to analog converter. / CUHK electronic theses & dissertations collection / Digital dissertation consortium

January 2001

Wang Hongwei. / "February 2001." / Thesis (Ph.D.)--Chinese University of Hong Kong, 2001. / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Mode of access: World Wide Web. / Abstracts in English and Chinese.

High performance SAR-based ADC design in deep sub-micron CMOS. / CUHK electronic theses & dissertations collection

January 2013

Sun, Lei. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2013. / Includes bibliographical references. / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

Low voltage integrated circuits

Analog-to-digital converters

RF Frontend for Spectrum Analysis in Cognitive Radio

Jayaraman, Karthik

January 2014

Advances in wireless technology have sparked a plethora of mobile communication standards to support a variety of applications. FCC predicts a looming crisis due to the exponentially growing demand for spectrum and it recommends to increase the efficiency of spectrum utilization. Cognitive Radio (CR) is envisioned as a radio technology which detects and exploits empty spectrum to improve the quality of communication. Spectrum analyzer for detecting spectrum holes is a key component required for implementing cognitive radio. Mitola's vision of using an RF Analog-to-Digital (ADC) to digitize the entire spectrum is not yet a reality. The traditional spectrum analysis technique based on a RF Front end using an LO Sweep is too slow, making it unsuitable to track fast hopping signals. In this work, we demonstrate an RF Frontend that can simplify the ADC's requirement by splitting the input spectrum into multiple channels. It avoids the problem of PLL settling by incorporating LO synthesis within the signal path using a concept called Iterative Down Converter. An example 0.75GHz-11.25GHz RF Channelizer is designed in 65nm Standard CMOS Process. The channelizer splits the input spectrum (10.5GHz bandwidth) into seven channels (each of bandwidth 1.5GHz). The channelizer shows the ability to rapidly switch from one channel to another (within a few ns) as well as down-converting multiple channels simultaneously (concurrency). The channelizer achieves a dynamic range of 54dB for a bandwidth of 10.5GHz, while consuming 540mW of power. Harmonic rejection mixer plays a key role in a broadband receiver. A novel order scalable harmonic rejection mixer architecture is described in this research. A proof-of-principle prototype has been designed and fabricated in a 45nm SOI technology. Experimental results demonstrate an operation range of 0.5GHz to 1.5GHz for the LO frequency while offering harmonic rejection better than 55dB for the 3rd harmonic and 58dB for the 5th harmonic across LO frequencies. While cognitive radio solves the spectrum efficiency problem in frequency domain, the electronic beam steering provides a spatial domain solution. Electronic beam forming using phased arrays have been claimed to improve spectrum efficiency by serving more number of users for a given bandwidth. A LO path phase-shifter with frequency-doubling is demonstrated for WiMAX applications.

Cognitive radio networks

Analog-to-digital converters

Wireless communication systems

Electrical engineering

Compressive Sampling as an Enabling Solution for Energy-Efficient and Rapid Wideband RF Spectrum Sensing in Emerging Cognitive Radio Systems

Yazicigil, Rabia Tugce

January 2016

Wireless systems have become an essential part of every sector of the national and global economy. In addition to existing commercial systems including GPS, mobile cellular, and WiFi communications, emerging systems like video over wireless, the Internet of Things, and machine-to-machine communications are expected to increase mobile wireless data traffic by several orders of magnitude over the coming decades, while natural resources like energy and radio spectrum remain scarce. The projected growth of the number of connected nodes into the trillions in the near term and increasing user demand for instantaneous, over-the-air access to large volumes of content will require a 1000-fold increase in network wireless data capacity by 2020. Spectrum is the lifeblood of these future wireless networks and the ’data storm’ driven by emerging technologies will lead to a pressing ’artificial’ spectrum scarcity. Cognitive radio is a paradigm proposed to overcome the existing challenge of underutilized spectrum. Emerging cognitive radio systems employing multi-tiered, shared-spectrum access are expected to deliver superior spectrum efficiency over existing scheduled-access systems; they have several device categories (3 or more tiers) with different access privileges. We focus on lower tiered ’smart’ devices that evaluate the spectrum dynamically and opportunistically use the underutilized spectrum. These ’smart’ devices require spectrum sensing for incumbent detection and interferer avoidance. Incumbent detection will rely on database lookup or narrowband high-sensitivity sensing. Integrated interferer detectors, on the other hand, need to be fast, wideband, and energy efficient, while requiring only moderate sensitivity. These future 'smart' devices operating in small cell environments will need to rapidly (in 10s of μs) detect a few (e.g. 3 to 6) strong interferers within roughly a 1GHz span and accordingly reconfigure their hardware resources or request adjustments to their wireless connection consisting of primary and secondary links in licensed and unlicensed spectrum. Compressive sampling (CS), an evolutionary sensing/sampling paradigm that changes the perception of sampling, has been extensively used for image reconstruction. It has been shown that a single pixel camera that exploits CS has the ability to obtain an image with a single detection element, while measuring the image fewer times than the number of pixels with the prior assumption of sparsity. We exploited CS in the presented works to take a ’snapshot’ of the spectrum with low energy consumption and high frequency resolutions. Compressive sampling is applied to break the fixed trade-off between scan time, resolution bandwidth, hardware complexity, and energy consumption. This contrasts with traditional spectrum scanning solutions, which have constant energy consumption in all architectures to first order and a fixed trade-off between scan time and resolution bandwidth. Compressive sampling enables energy-efficient, rapid, and wideband spectrum sensing with high frequency resolutions at the expense of degraded instantaneous dynamic range due to the noise folding. We have developed a quadrature analog-to-information converter (QAIC), a novel CS rapid spectrum sensing technique for band-pass signals. Our first wideband, energy-efficient, and rapid interferer detector end-to-end system with a QAIC senses a wideband 1GHz span with a 20MHz resolution bandwidth and successfully detects up to 3 interferers in 4.4μs. The QAIC offers 50x faster scan time compared to traditional sweeping spectrum scanners and 6.3x the compressed aggregate sampling rate of traditional concurrent Nyquist-rate approaches. The QAIC is estimated to be two orders of magnitude more energy efficient than traditional spectrum scanners/sensors and one order of magnitude more energy efficient than existing low-pass CS spectrum sensors. We implemented a CS time-segmented quadrature analog-to-information converter (TS-QAIC) that extends the physical hardware through time segmentation (e.g. 8 physical I/Q branches to 16 I/Q through time segmentation) and employs adaptive thresholding to react to the signal conditions without additional silicon cost and complexity. The TS-QAIC rapidly detects up to 6 interferers in the PCAST spectrum between 2.7 and 3.7GHz with a 10.4μs sensing time for a 20MHz RBW with only 8 physical I/Q branches while consuming 81.2mW from a 1.2V supply. The presented rapid sensing approaches enable system scaling in multiple dimensions such as ADC bits, the number of samples, and the number of branches to meet user performance goals (e.g. the number of detectable interferers, energy consumption, sensitivity and scan time). We envision that compressive sampling opens promising avenues towards energy-efficient and rapid sensing architectures for future cognitive radio systems utilizing multi-tiered, shared spectrum access.

Cognitive radio networks

Analog-to-digital converters

Electrical engineering

Wireless communication systems

Engineering

Power reduction techniques for CMOS current mode pipelined ADCs. / CUHK electronic theses & dissertations collection

January 2007

In addition, we can further reduce the power consumption by reducing the number of interconnects. We propose to use a quaternary (4-level) logic output to replace the binary (2-level) logic output, which will reduce the number of interconnect by half. A 6-bit current mode analog-to-quaternary converter (AQC) test chip is designed with special current mode quaternary logic functions. / The power reduction techniques are carried out in both circuit and system levels. At the circuit level, a new sub-stage design using voltage comparator is proposed to reduce power consumption without any performance degradation. At the system level, we observe that the signal-to-noise ratio (SNR) of a current mode pipelined ADC is proportional to the input current level, and the SNR of a pipelined ADC is dominated by the first few stages. Thus, it is possible to reduce the power consumption without significantly degrading the SNR by gradually reducing the current level of each stage along the pipeline. A 12-bit CMOS current mode pipelined ADC test chip is designed with a 0.35mum CMOS digital process. The measured signal-to-noise and distortion ratio (SNDR), spurious free dynamic range (SFDR) and total harmonic distortion (THD) are 64.90dB, 67.79dB and -67.02dB, respectively. The effective number of bit (ENOB) achieved is 10.49-bit and the calculated FOM is 1.31pJ, which has the lowest power consumption among reported current mode ADCs. / The supply voltage of advanced CMOS technology is reduced to 1V or less. It is very difficult to design high performance analog circuit at this supply voltage because of the limited dynamic range. One possible solution is to use current mode circuit technique which is less sensitive to the limited dynamic range. Moreover, current mode circuit is more suitable for low voltage applications compare to the conventional voltage mode circuit. This research uses analog-to-digital converter (ADC) as a vehicle to investigate current mode design techniques with a main focus on power reduction. / Chan Chi Hong. / "September 2007." / Adviser: C. F. Chan. / Source: Dissertation Abstracts International, Volume: 69-08, Section: B, page: 4923. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2007. / Includes bibliographical references. / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstracts in English and Chinese. / School code: 1307.

Analog-to-digital converters

Design techniques for low voltage wideband delta-sigma modulator. / CUHK electronic theses & dissertations collection / Digital dissertation consortium

January 2010

Finally, another new 0.5V fully differential wideband amplifier, which can be used in the wideband modulator, has been proposed. The gate-input two-stage amplifier employs a DC common-mode feedback circuit that uses a Miller-amplified capacitor for its frequency compensation. With the proposed technique, the power consumption of the low-voltage amplifier is drastically reduced. / Furthermore, a new dynamic CM level shifting technique for low-voltage CT delta-sigma modulators that employ a return-to-open feedback DAC is reported in the thesis. The technique maintains a stable CM level at the amplifier's inputs for this type of modulators. Simulation results show that it improves the modulator's SNDR by 11%. / In this thesis, we present research works on developing a low-voltage delta-sigma modulator with a wide signal bandwidth. Specifically, a 0.5V complex low-pass continuous-time (CT) third-order delta-sigma modulator that has a single-sided signal bandwidth of 1MHz, targeting for application in Bluetooth receivers, is presented without using any internal voltage boosting techniques which are potentially harmful to the reliability of the device. The wide bandwidth of the modulator at this low supply voltage is enabled by a special common-mode (CM) level arrangement in the system level and by new low-voltage amplifies. Realized in a 0.13mum CMOS process the proposed modulator achieves a 61.9-dB peak signal-to-noise-and-distortion ratio at the nominal supply of 0.5V with 3.4mW consumption, and occupies an active area of 0.9mm2. The modulator achieves the best figure-of-merit among its class. / The development of low-voltage design techniques for analog circuits has recently received a lot of attention due to the continuous shrinking of the supply voltage in modern CMOS technologies, which is projected to reduce to 0.5V for low power applications within ten years in the International Technology Roadmap for Semiconductor. This thesis focuses on developing circuit techniques for low-voltage delta-sigma modulator, a functional block that is widely used in mixed-signal integrated circuits. Several delta-sigma modulators operating at supply voltages below 0.9V have been reported in the open literature. However, none of them supports a signal bandwidth wider than 100kHz with a reasonable performance. / He, Xiaoyong. / Adviser: Kong Pang Pun. / Source: Dissertation Abstracts International, Volume: 72-01, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 104-111). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

High-performance delta-sigma analog-to-digital converters

da Silva, Jose Barreiro

14 July 2004

Graduation date: 2005

Signal processing -- Digital techniques

High efficiency wideband low-power delta-sigma modulators

Lee, Sang Hyeon

19 June 2013

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, 0.18μm 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. / Graduation date: 2012 / Access restricted to the OSU Community at author's request from June 19, 2012 - June 19, 2013

delta sigma

analog to digital converter

ADC

wideband

double sampling

Modulators (Electronics)

Analog-to-digital converters

A study of basic building blocks of analog-to-digital delta-sigma modulators

Guo, Yuhua

09 January 2004

In this thesis, a novel Direct-Charge-Transfer (DCT) integrator structure is proposed, which can settle much faster than regular switch-capacitor integrators. A new Spread-Spectrum Dynamic Element Matching (SS-DEM) algorithm is also introduced, which can effectively spread or shape the nonlinearity error of multi-bit DAC in the feedback path, thus improve the SNDR and THD performance of overall delta-sigma modulators. A three-bit quantizer design example is presented, which is embedded in a MASH2-0 structure delta-sigma modulator prototype and has been fabricated in AMI CMOS 1.5μm technology. Testing results indicate this quantizer works well. / Graduation date: 2004

Signal processing

Design techniques for low-voltage analog-to-digital converter

Chang, Dong-Young

15 November 2002

Continuous process scale-down and emerging markets for low-power/low-voltage mobile systems call for low-voltage analog integrated circuits. Switched-capacitor circuits are the building blocks for analog signal processing and will encounter severe overdrive problems when operating at low-voltage conditions. There are several well-known techniques to bypass the problem. These approaches include: (1) The clock boosting schemes (e.g. 2VDD clock signal) which cannot be used in submicron low-voltage CMOS processes as gate oxide can only tolerate the technology's maximum voltage (VDD). (2) The use of scaled/lower threshold transistors, which are not always scalable to very low voltage supplies as it could suffer from an unacceptable amount of leakage current (e.g. the switch may not be fully turned off). (3) The use of bootstrapped clocking, which has added loading and possible reliability issues. (4) The switched-opamp (SO) technique which is fully compatible with low-voltage submicron CMOS processes but the operating speed limited due to slow transients from the opamp being switched off and on. In this thesis, the Opamp-Reset Switching Technique (ORST) topology is proposed for low-voltage operation. Instead of opamps being turned on and off as in the switched-opamp technique, the sourcing amplifier is placed in the unity-gain reset configuration to provide reset level at the output. In this way, high-speed operation is possible. The technique is applied to two ADCs as examples of low-voltage design. The first design is a 10-bit 25MSPS pipelined ADC using pseudo-differential structure. It is fabricated in a 0.35-��m CMOS process. It operates at 1.4V and consumes 21mW of total power. The second design is a two-stage algorithmic ADC with highly linear input sampling circuit. In addition to the low-voltage design techniques used in the pipelined ADC, radix-based digital calibration technique for multi-stage ADC is also proposed. The ADC uses a 0.18-��m CMOS technology. It operates at 0.9V supply with total power consumption of 9mW. Experimental results show that the proposed calibration technique reduces spurious free dynamic range from 47dB to 75dB and improves signal-to-noise and distortion ratio from 40dB to 55dB after calibration. / Graduation date: 2003