An RF CMOS Q-Enhanced LC Resonator

This paper investigates a Q-enhanced LC resonator implemented with a Q-enhancement circuit based on both active and reactive components. An analytical expression is presented for the Q-enhancement circuit and simulations are compared with measurements on a differential Q-enhanced LC tank operating at 1779–1870 MHz. Sensitive circuits and inaccurate models leads to inaccurate simulations. To improve the accuracy of simulations, S-parameter measurements of components and sub-circuits are included in the simulations whereby an accuracy of 3 MHz in the estimate of the resonator center frequency results. Per Madsenreceived his M.Sc.E.E degree in 1997 from Aalborg University, Denmark. In 2005 he received his Industrial PhD degree, also from Aalborg University. He is currently working with development of reference designs for GSM and UMTS at Texas Instruments Denmark A/S. Jan Hvolgaard Mikkelsenreceived his M.Sc.E.E. degree in 1995 from Aalborg University, Denmark. In 2005 he received his PhD degree, also from Aalborg University. He is currently employed as an Assistant Professor at Aalborg University where he is working as an IC design manager for the large scale RF IC design efforts at Aalborg University. His research interests include both RF and LF CMOS design as well as transceiver architectures. Jens Christian Lindofreceived his M.Sc.E.E. degree in electrical engineering in 1991 from Aalborg University, Denmark, in 1991. He is currently R&D Director at Texas Instruments Denmark A/S, where he is responsible for all HW and SW developed for Texas Instrument's cellular reference designs for GSM, GPRS, EDGE and UMTS. Torben Larsenreceived his M.Sc.E.E. degree in electrical engineering from Aalborg University, Denmark, in 1988, and the Dr. Techn. degree from Aalborg University in 1998. He has been employed as full Professor at Aalborg University since 2001. Dr. Larsen serves as reviewer for IEE, IEEE and Wiley. Areas of specialized research interests include noise theory, nonlinear analysis techniques, RF techniques, RF CMOS technology, and digital modulation techniques.     

Dose control circuit for digital electrostatic electron-beam array lithography

This paper demonstrates a technique for controlling the electron emission of an array of field emitting vertically aligned carbon nanofibers (VACNFs). An array of carbon nanofibers (CNF) is to be used as the source of electron beams for lithography purposes. This tool is intended to replace the mask in the conventional photolithography process by controlling their charge emission using the “Dose Control Circuitry” (DCC). The large variation in the charge emitted between CNFs grown in identical conditions forced the controller design to be based on fixed dose rather than on fixed time. Compact digital control logic has been designed for controlling the operation of DCC. This system has been implemented in a 0.5 μm CMOS process. Chandra Sekhar A. Durisety received his B.E. (Hons.) Instrumentation from Birla Institute of Technology and Sciences, Pilani, India in 1997 and his M.S in Electrical Engineering from University of Tennessee, Knoxville in 2002. Since 2003, he has been working towards his Ph.D degree also in Electrical Engineering at Integrated Circuits and Systems Lab (ICASL), University of Tennessee, Knoxville. He joined Wipro Infotech Ltd, Global R & D, Bangalore, India in 1997, where he designed FPGA based IPs for network routers. Since 1999, he was involved in the PCI bridge implementation at CMOS chips Inc, Santa Clara, CA, and the test bench development for Sony’s MP3 player, while at Toshiba America Electronic Components Inc., San Jose, CA. His research interests include multi-stage amplifiers, data converters, circuits in SOI and Floating Gate Devices. Rajagopal Vijayaraghavan received the B.E degree in electronics and communication engineering from Madras University in 1998 and the M.S degree in electrical engineering from the University of Texas, Dallas in 2001.He is currently working towards the Ph.D degree in electrical engineering at the University of Tennessee. His research interest is in the area of CMOS Analog and RF IC design. His current research focuses on LNAs and VCOs using SOI based MESFET devices. Lakshmipriya Seshan was born in Trivandrum, India on April 30, 1979. She received her B.tech in Electronincs & Communication Engg from Kerala University, India in June 2000 and M.S in Electrical Engg from University of Tennessee in 2004. In 2004, she joined Intel Corporation as an Analog Engineer, where she is engaged in the design of low power, high speed analog circuits for various I/O interface topologies. Syed K. Islam received his B.Sc. in Electrical and Electronic Engineering from Bangladesh University of Engineering and Technology (BUET) and M.S. and Ph.D. in Electrical and Systems Engineering from the University of Connecticut. He is presently an Associate Professor in the Department of Electrical and Computer Engineering at the University of Tennessee, Knoxville. Dr. Islam is leading the research efforts of the Analog VLSI and Devices Laboratory at the University of Tennessee. His research interests are design, modeling and fabrication of microelectronic/optoelectronic devices, molecular scale electronics and nanotechnology, biomicroelectronics and monolithic sensors. Dr. Islam has numerous publications in technical journals and conference proceedings in the areas of semiconductors devices and circuits. Benjamin J. Blalock received his B.S. degree in electrical engineering from The University of Tennessee, Knoxville, in 1991 and the M.S. and Ph.D. degrees, also in electrical engineering, from the Georgia Institute of Technology, Atlanta, in 1993 and 1996 respectively. He is currently an Assistant Professor in the Department of Electrical and Computer Engineering at The University of Tennessee where he directs the Integrated Circuits and Systems Laboratory (ICASL). His research focus there includes analog IC design for extreme environments (both wide temperature and radiation immune), multi-gate transistors and circuits on SOI, body-driven circuit techniques for ultra low-voltage analog, mixed-signal/mixed-voltage circuit design for systems-on-a-chip, and bio-microelectronics. Dr. Blalock has co-authored over 60 published refereed papers. He has also worked as an analog IC design consultant for Cypress Semiconductor Corp. and Concorde Microsystems Inc.     

New Four-Quadrant CMOS Current-Mode and Voltage-Mode Multipliers

In this paper, a four-quadrant current-mode multiplier based on a new squarer cell is proposed. The multiplier has a simple core, wide input current range with low power consumption, and it can easily be converted to a voltage-mode by using a balanced output transconductor (BOTA) [1]. The proposed four-quadrant current-mode and voltage-mode multipliers were confirmed by using PSPICE simulation and found to have good linearity with wide input dynamic range. For the proposed current-mode multiplier, the static power consumption is 0.671 mW, the maximum power consumption is 0.72 mW, the input current range is ± 60 μ A, the bandwidth is 31 MHz, the input referred noise current is 46 pA/√Hz, and the maximum linearity error is 3.9%. For the proposed voltage-mode multiplier, the static power consumption is 1.6 mW, the maximum power consumption is 1.85 mW, the input voltage range is ± 1V from ± 1.5V supply, the bandwidth is 25.34 MHz, the input referred noise voltage is 0.85 μV/√Hz, and the maximum linearity error is 4.1%. Mohammed A. Hashiesh was born in Elkharga, New Valley, Egypt, in 1979. He received the B.Sc. degree with honors from the Electrical Engineering Department, Cairo University, Fayoum-Campus, Egypt in 2001, and he received the M.Sc. degree in 2004 from the Electronics and Communication Engineering Department, Cairo University, Egypt. He is currently a Teacher Assistant at the Electrical Engineering Department, Cairo University, Fayoum-Campus. His research interests include analog CMOS integrated circuit design and signal processing, and digitally programmable CMOS analog building blocks. Soliman A. Mahmoud was born in Cairo, Egypt, in 1971. He received the B.Sc. degree with honors, the M.Sc. degree and the Ph.D. degree from the Electronics and Communications Department, Cairo University—Egypt in 1994, 1996 and 1999 respectively. He is currently an Assistant Professor at the Electrical Engineering Department, Cairo University, Fayoum-Campus. He has published more than 50 papers. His research and teaching interests are in circuit theory, fully integrated analog filters, high frequency transconductance amplifiers, low voltage analog CMOS circuit design, current-mode analog signal processing and mixed analog/digital programmable analog blocks. Ahmed M. Soliman was born in Cairo Egypt, on November 22, 1943. He received the B.Sc. degree with honors from Cairo University, Cairo, Egypt, in 1964, the M.S. and Ph.D. degrees from the University of Pittsburgh, Pittsburgh, PA., U.S.A., in 1967 and 1970, respectively, all in Electrical Engineering. He is currently Professor Electronics and Communications Engineering Department, Cairo University, Egypt. From September 1997–September 2003, Dr Soliman served as Professor and Chairman Electronics and Communications Engineering Department, Cairo University, Egypt. From 1985–1987, Dr. Soliman served as Professor and Chairman of the Electrical Engineering Department, United Arab Emirates University, and from 1987–1991 he was the Associate Dean of Engineering at the same University. He has held visiting academic appointments at San Francisco State University, Florida Atlantic University and the American University in Cairo. He was a visiting scholar at Bochum University, Germany (Summer 1985) and with the Technical University of Wien, Austria (Summer 1987). In 1977, Dr. Soliman was decorated with the First Class Science Medal, from the President of Egypt, for his services to the field of Engineering and Engineering Education. Dr Soliman is a member of the Editorial Board of Analog Integrated Circuits and Signal Processing. Presently Dr. Soliman is Associate Editor of the IEEE Transactions on Circuits and Systems I (Analog Circuits and Filters).     

CMOS image sensors for sensor networks

We report on two generations of CMOS image sensors with digital output fabricated in a 0.6 μm CMOS process. The imagers embed an ALOHA MAC interface for unfettered self-timed pixel read-out targeted to energy-aware sensor network applications. Collision on the output is monitored using contention detector circuits. The image sensors present very high dynamic range and ultra-low power operation. This characteristics allow the sensor to operate in different lighting conditions and for years on the sensor network node power budget. Eugenio Culurciello (S’97–M’99) received the Ph.D. degree in Electrical and Computer Engineering in 2004 from Johns Hopkins University, Baltimore, MD. In July 2004 he joined the department of Electrical Engineering at Yale University, where he is currently an assistant professor. He founded and instrumented the E-Lab laboratory in 2004. His research interest is in analog and mixed-mode integrated circuits for biomedical applications, sensors and networks, biological sensors, Silicon on Insulator design and bio-inspired systems. Andreas G. Andreou received his Ph.D. in electrical engineering and computer science in 1986 from Johns Hopkins University. Between 1986 and 1989 he held post-doctoral fellow and associate research scientist positions in the Electrical and Computer engineering department while also a member of the professional staff at the Johns Hopkins Applied Physics Laboratory. Andreou became an assistant professor of Electrical and Computer engineering in 1989, associate professor in 1993 and professor in 1996. He is also a professor of Computer Science and of the Whitaker Biomedical Engineering Institute and director of the Institute’s Fabrication and Lithography Facility in Clark Hall. He is the co-founder of the Johns Hopkins University Center for Language and Speech Processing. Between 2001 and 2003 he was the founding director of the ABET accredited undergraduate Computer Engineering program. In 1996 and 1997 he was a visiting professor of the computation and neural systems program at the California Institute of Technology. In 1989 and 1991 he was awarded the R.W. Hart Prize for his work on mixed analog/digital integrated circuits for space applications. He is the recipient of the 1995 and 1997 Myril B. Reed Best Paper Award and the 2000 IEEE Circuits and Systems Society, Darlington Best Paper Award. During the summer of 2001 he was a visiting professor in the department of systems engineering and machine intelligence at Tohoku University. In 2006, Prof. Andreou was elected as an IEEE Fellow and a distinguished lecturer of the IEEE EDS society. Andreou’s research interests include sensors, micropower electronics, heterogeneous microsystems, and information processing in biological systems. He is a co-editor of the IEEE Press book: Low-Voltage/Low-Power Integrated Circuits and Systems, 1998 (translated in Japanese) and the Kluwer Academic Publishers book: Adaptive Resonance Theory Microchips, 1998. He is an associate editor of IEEE Transactions on Circuits and Systems I.     

Pipeline of Successive Approximation Converters with Optimum Power Merit Factor

In this paper, we present a low power 12 bit 5 MSPS, successive approximation converter architecture using pipeline technique. The converter consumes 4 mW at the Nyquist rate input with 1.8 V power supply. By combination of pipeline and successive architecture, the entire circuit, simulated at the transistor level in a 0.18 μ CMOS process, achieves a FoM (Figure of Merit) of 0.19 pJ/conversion. Jinghua Li was born in 1973. He received the MSEE and BSEE Degree from College of Electronics and information, Shanghai Jiaotong University and Harbin Engineering University in 1997 and 1994 respectively. He is currently pursuing Ph.D degree in Department of Electrical Engineering, Texas A&M University, College Station, TX, USA. In 1997, he joined Bell Laboratory (China), Lucent Technologies as a member of technical staff. He worked on single-chip HDTV decoder IC and Sonet/SDH SoC for various projects in Murray Hill, NJ, USA and Shanghai China. He also finished projects on hardware implementation of Video conference/Phone based on H.263 standard as his master thesis. Since 2000, he has been a research assistant in Analog Mixed Signal center, TAMU. Most currently his research interests are focused on low power analog to digital conversion IC design, CMOS implementation of 10 G/2.5 G clock data recovery IC for high speed serial communications. Franco Maloberti received the Laurea Degree in Physics (Summa cum Laude) from the University of Parma, Parma Italy, in 1968 and the Dr. Honoris Causa degree in electronics from the Instituto Nacional de Astrofisica, Optica y Electronica (Inaoe), Puebla, Mexico in 1996. In 1993 he was a Visiting Professor at ETH-PEL, Zurich. He was Professor of Microelectronics and Head of the Micro Integrated Systems Group University of Pavia, Pavia, Italy and the TI/J.Kilby Analog Engineering Chair Professor at the Texas A&M University. He is currently the Distinguished Microelectronic Chair Professor at University of Texas at Dallas and part-time Professor at the University of Pavia, Italy. His professional expertise is in the design, analysis and characterization of integrated circuits and analogue digital applications, mainly in the areas of switched capacitor circuits, data converters, interfaces for telecommunication and sensor systems, and CAD for analogue and mixed A-D design. He has written more than 250 published papers, three books and holds 15 patents. He was in 1992 recipient of the XII Pedriali Prize for his technical and scientific contributions to national industrial production. He was co-recipient of the 1996 Institute of Electrical Engineers (U.K.) Fleming Premium for the paper “CMOS Triode Transistor Transconductor for high-frequency continuous time filters.” He has been responsible at both technical and management levels for many research programs including ten ESPRIT projects and has served the European Commission as ESPRIT Projects' Evaluator, Reviewer and as European Union expert in many European Initiatives. He served the Academy of Finland on the assessment of electronic research in Academic institutions and on the research programs' evaluations. Dr. Maloberti was Vice-President, Region 8, of the IEEE Circuit and Systems Society from 1995 to 1997 and an Associate Editor of IEEE-Transaction on Circuit and System-II. He received the 1999 IEEE CAS Society Meritorious Service Award, the 2000 CAS Society Golden Jubilee Medal, and the IEEE Millenium Medal. He is the President of the IEEE Sensor Council and member of the Board of Governors of the IEEE CAS Society. He is a member of the Italian Electrothecnical and Electronic Society (AEI), the Editorial Board of Analog Integrated Circuits and Signal Processing, and Fellow of IEEE.     

Reduced Impact of Induced Gate Noise on Inductively Degenerated LNAs in Deep Submicron CMOS Technologies

Designers of radio-frequency inductively-degenerated CMOS low-noise-amplifiers have usually not followed the guidelines for achieving minimum noise figure. Nonetheless, state-of-the-art implementations display noise figure values very close to the theoretical minimum. In this paper, we point out that this is due to the effect of the parasitic overlap capacitances in the MOS device. In particular, we show that overlap capacitances lead to a significant induced-gate-noise reduction, especially when deep sub-micron CMOS processes are used.Paolo Rossi was born in Milan, Italy, in 1975. He received the Laurea degree (summa cum laude) in electrical engineering from the University of Pavia, Pavia, Italy, in 2000, where he is currently working toward the Ph.D. degree. His research interests are in the field of analog integrated circuits for wireless transceivers in CMOS and BiCMOS technology, with particular focus on the analysis and design of LNA and mixer for multi-standard applications.Francesco Svelto received the Laurea and Ph.D. degrees in electrical engineering from the University of Pavia, Pavia, Italy, in 1991 and 1995, respectively. From 1996 to 1997, he held a grant from STMicroelectronics to design CMOS RF circuits. In 1997, he was appointed Assistant Professor at the University of Bergamo, Italy, and in 2000, he joined the University of Pavia, where he is an Associate Professor. His current research interests are in the field of RF design and high-frequency integrated circuits for telecommunications. Dr. Svelto has been a member of the technical program committee of the IEEE Custom Integrated Circuits Conference since 2000 and the Bipolar/BiCMOS Circuits and Technology Meeting (BCTM) since 2003, and the European Solid State Circuits Conference in 2002. He served as Guest Editor of the March 2003 special issue of the IEEE Journal of Solid-State Circuits, of which he is currently an Associate Editor.Andrea Mazzanti was born in Modena (Italy) in 1976. He received the Laurea degree (summa cum Laude) in Electrical Engineering from the University of Modena and Reggio Emilia, Modena, Italy in 2001. Since 2001 he is pursuing his PhD in Electrical Engineering at University of Modena and Reggio Emilia, Italy. His major research interest are modelling of microwave semiconductor devices and design of CMOS RF integrated circuits, with particular focus on low noise oscillators and analog frequency dividers. During the summer of 2003 he was with Agere Systems, Allentown, PA as an internship student, working on the design of an highly integrated CMOS FM transmitter.Pietro Andreani received the M.S.E.E. from the University of Pisa, Italy, in 1988. He joined the Dept. of Applied Electronics, Lund University, Sweden, in 1990, where he contributed to the development of software tools for digital ASIC design. After working at the Dept. of Applied Electronics, University of Pisa, as a CMOS IC designer during 1994, he rejoined the Dept. of Applied Electronics in Lund as an Associate Professor, where he was responsible for the analog IC course package between 1995 and 2001, and where he received the Ph.D. degree in 1999. He is currently a Professor at the Center for Physical Electronics, ØrstedDTU, Technical University of Denmark, Kgs. Lyngby, Denmark, with analog/RF CMOS IC design as main research field.     

Impact of Body Bias on Delay Fault Testing of Sub-100 nm CMOS Circuits

A Body biasing technique has recently been proposed for microprocessors in sub-100 nm technology generations [11, 12]. It is shown that forward body bias (FBB) reduces the leakage power and suppresses the effect of process variation while reducing the complexity of dualV_th technology. In this paper, we study the effect of body bias on the delay fault testing of CMOS circuits. We analyze the impact of both fixed and adaptive body biasing techniques on test cost and the quality of test. Statistical analysis on several benchmark circuits shows that the adaptive body biasing design will have the most effective impact on delay fault by maintaining the test cost at its minimum under process variation while ensuring the test quality at its highest level. Bipul C. Paul received B.Tech. and M.Tech. degrees in radiophysics and electronics, from the University of Calcutta and the Ph.D. degree from Indian Institute of Science (IISc), Bangalore, India. After his graduation, he joined Alliance Semiconductor (India), where he worked on synchronous DRAM design. In 2000, he joined Purdue University, West Lafayette, USA, as a Post Doctoral Fellow, where he worked on low-power electronic design of nanoscale circuits (both bulk and SOI technologies), statistical design under process variation, VLSI testing, verification and noise analysis. He has also developed device and circuit optimization techniques for ultra-low power digital sub-threshold operation. Dr. Paul is presently with Toshiba Research, where he is working on post-silicon devices and technology and nano-architecture. He is also a Visiting Scientist at Stanford University, USA. Dr. Paul received National scholarship (India) in 1984, the senior research fellowship award from CSIR, India in 1995 and the Best Thesis of the Year award in 1999. He is a senior member of IEEE. Kaushik Roy received B.Tech. degree in electronics and electrical communications engineering from the Indian Institute of Technology, Kharagpur, India, and Ph.D. degree from the electrical and computer engineering department of the University of Illinois at Urbana-Champaign in 1990. He was with the Semiconductor Process and Design Center of Texas Instruments, Dallas, where he worked on FPGA architecture development and low-power circuit design. He joined the electrical and computer engineering faculty at Purdue University, West Lafayette, IN, in 1993, where he is currently a Professor. His research interests include VLSI design/CAD with particular emphasis in low-power electronics for portable computing and wireless communications, VLSI testing and verification, and reconfigurable computing. Dr. Roy has published more than 200 papers in refereed journals and conferences, holds 5 patents, and is a co-author of a book on Low Power CMOS VLSI Design (John Wiley). Dr. Roy received the National Science Foundation Career Development Award in 1995, IBM faculty partnership award, ATT/Lucent Foundation award, best paper awards at 1997 International Test Conference and 2000 International Symposium on Quality of IC Design, and is currently a Purdue University faculty scholar professor. He is in the editorial board of IEEE Design and Test, IEEE Transactions on Circuits and Systems, and IEEE Transactions on VLSI Systems. He was Guest Editor for Special Issue on Low-Power VLSI in the IEEE Design and Test (1994) and IEEE Transactions on VLSI Systems (June 2000). Dr. Roy is fellow of IEEE.     

Sub-mA single ended CMOS low noise amplifier with 2.41 dB noise figure

This paper presents a single ended low noise amplifier (LNA) using 0.18 μm CMOS process packed and tested on a printed circuit board. The LNA is powered at 1.0 V supply and drains 0.95 mA only. The LNA provides a forward gain of 11.91 dB with a noise figure of only 2.41 dB operating in the 0.9 GHz band. The measured value of IIP3 is 0.7 dBm and of P1dB is −12 dBm. Zhang Liang is currently with Cyrips, Singapore. Ram Singh Rana was born in Delhi (India). Having primary education in Bijepur, Dwarahat(India), he received the B.Tech. (hons.) degree in Computer Engineering from G.B. Pant University, Pantnagar, India in 1988 and the Ph.D degree from the Indian Institute of Techonology (IIT), Delhi, India in 1996. He worked for his Ph.D in the Centre for Applied Research in Electronics, IIT Delhi in close interaction with the Semiconductor Complex Limited, Mohali, India. He was with ESPL, Mohali(India) in 1988 for a very short period and then served IIT Delhi as Senior Research Associate (88-90) and Senior Scientific Officer (90-95) where his main contributions were on CMOS analog IC design in subthreshold operation. He was a Lecturer in the Kumaon Engg. College, Dwarahat (India) before serving the IIT Roorkee (Formerly Univ. of Roorkee) in 1998 as assistant Professor. In 1999, he was a Manager (Engineering), Semiconductor Product Sector of the Motorola, Noida, India. Since joining the Institute of Microelectronics, Singapore in 2000, he worked mostly on RFICs, Fractional-N PLLs, ADCs. During 2001-2004, he worked there as IC Design Research and Training Program Manager. Currently, he is serving the institute as Senior Research Engineer in CMOS IC design (below 1V) for biomedical and bio-sensors. His current interests include design and consultancy for CMOS ICs/systems for the biomedical and high speed communication applications. Dr. Rana received Young Teacher Career Award from the All India Council for Technical Education in 1997. He was an Adjunct Asstt. Professor with the National University of Singapore (NUS), Singapore in 2004. He is sole inventor of two US granted patents and has filed several other patents. He has authored/co-authored about 40 publications. He has been reviewer for several IEEE journals and conference papers. Dr Rana is a senior member of IEEE and a member of Graduate Program in BioEngineering, NUS Singapore. He has chaired /co-chaired sessions in many international conferences. Zhang Liang was born in China in June 1978. He received the Bachelor degree and the Master degree in Electrical Engineering from the Xi’an JiaoTong University, Xi’an, China, in 2000 and 2003 respectively. Since 2003, he has been a postgraduate student in the Electrical and Computer Engineering department, National University of Singapore(NUS), Singapore and has successfully completed M.Engg degree program of the NUS. He is currently working on RFICs as a design engineer in Cyrips, Singapore. His design and research interests include integrated circuit design for communications. He has authored/co-authored several publications of international standard. Hari K Garg obtained his BTech degree in EE from IITDelhi in 1981. Subsequently, he obtained his MEng & PhD degrees from Concordia University in 1983 & 1985, and MBA from Syracuse University in 1985. He was a faculty member at Syracuse University from 1985 till 1995. He has been with the National University of Singapore since 1995 till present with the exception of 1998-1999 when he was with Philips. Hari’s research interests are in the area of digital signal/image processing, wireless communications, coding theory and digital watermarking. He has published extensively on these and related topics. He is also founder of several companies in the space of mobile telephony. In his spare time, Hari enjoys singing and a good game of Squash.     

Simplified Modeling of a Multipole Amplifier Using All-Pass Network Functions

This paper presents a system model for the representation of amplifiers that cannot be accurately characterized by a classical two pole transfer function. The effects of higher order poles are modeled by an all-pass function added to the conventional two pole model. The accuracy of the model is demonstrated by comparing the results for a typical CMOS amplifier to those obtained from device level simulations using SPICE. This model can be easily implemented in a standard simulator and is shown to achieve fast simulation time. This model is expected to have application in system level modelling of mixed-signal circuits using conventional SPICE simulators.Yihong Dai received his B.S. and M.Eng. degrees in Electrical Engineering from Shanghai JiaoTong University, Shanghai, China in 1993 and 1996, respectively. From 1996 to 1998, he enjoyed his industrial experiences in Shanghai with semiconductor companies like Shanghai Nortel Semiconductor and Motorola Electronics (China) Shanghai Branch. Since 1998, he has been a research assistant at the Analog and Mixed-signal Laboratory of the Electrical Engineering Department of Brigham Young University working toward his Ph.D. During the summer of 1999, he was with AMI semiconductor Utah Research and Design Center where he developed a threshold voltage based CMOS voltage reference architecture. In the summer of 2001, he was with Ultra Design where he designed a reference amplifier for high speed digital-to-analog converters. His research interest includes voltage reference, reference amplifier and high speed data converters in both CMOS and GaAs processes.Donald T. Comer received the B.S, M.S., and Ph.D. degrees from San Jose State University, the University of California (Berkeley), and the University of Santa Clara, respectively, all in electrical engineering. He began teaching at San Jose State University in 1961 and mixed his teaching and industrial work until he left San Jose State University in 1979. He has worked for California Technical Industries, IBM Corp., Mobility Systems, Precision Monolithics, Storage Technology Corp., and Analog Devices during his career. He founded the AMI Utah Research and Design Center in 1998 that specializes in MOS design. In 2002, Dr. Comer founded Ultra Design, a design center that specializes in high-frequency heterojunction circuit designs. He holds fifteen patents and has published over 50 articles dealing with solid-state and integrated circuits. He has published five textbooks in the field of large-signal and integrated circuits. He formerly held the Quentin Berg Chair at Penn State Harrisburg from 1990 to 1995. He is now a professor of electrical and computer engineering at Brigham Young University where he held the Endowed Chair of Engineering from 1995 to 1998.David J. Comer received the B.S., M.S., and Ph.D. degrees from San Jose State University, the University of California (Berkeley), and Washington State University, respectively, all in electrical engineering. He has worked for IBM Corp., Pacific Electromagnetics, Lawrence Livermore Laboratories, and Intel Corporation. He began his teaching career at the University of Idaho and has taught at the University of Calgary and California State University, Chico. He is presently a professor of electrical and computer engineering at Brigham Young University. He served as Chairman of the Division (Dean) of Engineering at CSU, Chico and as Department Chair at BYU.While at CSU, Chico, Dr. Comer served on the statewide Engineering Liaison Committee and served as Chair of the Council of California State University Deans of Engineering.Dr. Comer has published twelve textbooks and over 60 articles in the field of circuit design. He has contributed sections to the Encyclopedia of Physical Science and Technology and holds seven patents. He was given the Professional Achievement Award at CSU, Chico and was named the Outstanding Teacher of Engineering at BYU. He has also held the College of Engineering Research Chair at Brigham Young University.Darren Korth received the B.S. and M.S. degrees in electrical engineering at Brigham Young University, Provo, Utah in 1999. He is currently pursuing a Ph.D. in electrical engineering. He served as an instructor for the Department of Electrical and Computer Engineering at Brigham Young University from 2000 to 2002. From 2001 to 2003, he also worked as a senior design engineer at UltraDesign, LLC, Provo, Utah where he researched high-speed data converter circuits. He is currently with AMI Semiconductor in their RF CMOS group.     

Opamp gain insensitive MASH sigma delta modulator for wide bandwidth applications

This work presents a means to enhance the immunity of non-ideal opamp gain effect of the fourth order multi-stage noise shaped (MASH) sigma-delta modulator (SDM) for wide bandwidth applications. The first stage of the SDM is a low-distortion single-loop second order SDM, while the second stage is a low-distortion interpolative second order SDM with Chebyshev type II filter technique. Theoretically, the conventional MASH SDM is impacted by the nonlinear finite gain of the operational amplifier. This impact may have two main phenomena. First, it leaks the incompletely corrected quantization error to the output. Secondly, the nonlinearity causes the harmonic distortion of the input signal. The proposed architecture can reduce the distortion and the sensitivity of the nonlinear finite opamp gain to improve the performance by using low-distortion technique in the MASH SDM. Furthermore, the lower power budget and simplified digital cancellation logic can be achieved. The experimental results indicate that the dynamic range (DR) can reach 87dB with power dissipation of 65 mW. A test SDM chip for Asymmetric Digital Subscriber Line (ADSL) application is designed and implemented by TSMC 0.25 um 1P5M process. Jen-Shiun Chiang was born in Taichung Taiwan, ROC in 1960. He received the B.S. degree in electronics engineering from Tamkang University, Taipei, Taiwan in 1983. In 1988, he received the M.S. degree in electrical engineering from University of Idaho, Moscow Idaho, USA. In 1992, he received the Ph.D. degree in the electrical engineering from Texas A & M University, College Station Texas, USA. He joined the faculty member of the Department of Electrical Engineering at Tamkang University in 1992. Currently, he is a Professor and Department Chair of the Department of Electrical Engineering at Tamkang University. Dr. Chaings research interest includes computer arithmetic, computer architecture, digital signal processing for VLSI architecture, architecture for image data compressing, analog to digital data conversion, and low power circuit design. Hsin-Liang Chen was born in Taipei, Taiwan, in 1974. He received the B.S. degree and M.S. degree in the electrical engineering from Tamkang University, Taipei, Taiwan, in 1997 and 2003, respectively. He is currently working toward the Ph.D. degree at Tamkang University. His research interest focuses on mixed-signal CMOS circuit, sigma delta ADC, and low power circuit.     

Defect Oriented Testing of Analog Circuits Using Wavelet Analysis of Dynamic Supply Current

In recent years, Defect Oriented Testing (DOT) has been investigated as an alternative testing method for analog circuits. In this paper, we propose a wavelet transform based dynamic supply current (IDD) analysis technique for detecting catastrophic and parametric faults in analog circuits. Wavelet transform has the property of resolving events in both time and frequency domain simultaneously unlike Fourier transform which decomposes a signal in frequency components only. Simulation results on benchmark circuits show that wavelet transform has higher fault detection sensitivity than Fourier or time-domain methods and hence, can be considered very promising for defect oriented testing of analog circuits. Effectiveness of wavelet transform based DOT amidst process variation and measurement noise is studied.This research is supported in part by MARCO GSRC under contract number SA3273JB.A paper based on this work was presented at the Fourth IEEE Latin American Test Workshop, Natal, Brazil, February 2003.Swarup Bhunia received the undergraduate degree from Jadavpur University, Calcutta, India, and the Masters degree from the Indian Institute of Technology (IIT), Kharagpur. He is currently working toward the Ph.D. degree in the Department of Electrical Engineering, Purdue University, West Lafayette, IN.He has worked in the EDA industry on RTL synthesis and verification since 2000. His research interest includes defect-based testing, diagnosis, noise analysis, and noise-aware design.Arijit Raychowdhury received the B.E. degree in 2001 in electronics and telecommunication engineering from Jadavpur University, India. He is currently pursuing the Ph.D. degree in electrical and computer engineering in Purdue University, West Lafayette, IN.He has worked as an analog circuit designer in Texas Instruments India. His research interests include device/circuit design for scaled silicon and nonsilicon devices. He has received academic excellence awards in 1997, 2000, and 2001 and Messner Fellowship from Purdue University in 2002. Mr. Raychowdhury has been awarded the Best Student Paper Award in the IEEE Nanotechnology Conference, 2003.Kaushik Roy received the B.Tech. degree in electronics and electrical communications engineering from the Indian Institute of Technology, Kharagpur, India, and the Ph.D. degree from the Electrical and Computer Engineering Department, University of Illinois, Urbana, in 1990. He was with the Semiconductor Process and Design Center of Texas Instruments, Dallas, TX, where he worked on FPGA architecture development and low-power circuit design. He joined the electrical and computer engineering faculty, Purdue University, West Lafayette, IN, in 1993, where he is currently a Professor. His research interests include VLSI design/CAD with particular emphasis in low-power electronics for portable computing and wireless communications, VLSI testing and verification, and reconfigurable computing. He has published more than 250 papers in refereed journals and conferences, holds six patents, and is Co-Author of a book on Low Power CMOS VLSI Design (New York: Wiley). He was Guest Editor for a Special Issue on Low-Power VLSI in IEE Proceedings—Computers and Digital Techniques (July 2002). Dr. Roy received the National Science Foundation Career Development Award in 1995, the IBM Faculty Partnership Award, AT&T/Lucent Foundation Award, Best Paper Awards at the 1997 International Test Conference and 2000 International Symposium on Quality of IC Design, 2003 IEEE Latin American Test Workshop, and 2003 IEEE Nano. He is on the Editorial Board of IEEE Design and Test, IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS, and IEEE TRANSACTIONS ON VLSI SYSTEMS. He was Guest Editor for a Special Issue on Low-Power VLSI in IEEE DESIGN AND TEST (1994), and for the IEEE TRANSACTIONS ON VLSI SYSTEMS (June 2000).     

CMOS Digital Time Amplifiers for High Resolution Timing Measurement

In this paper the concept of time amplification in the digital domain is introduced along with a simple CMOS implementation. The time amplifier is presented in the context of a high resolution time-to-digital converter. The issue of limited linearity of the time amplifier is addressed through the utilization of an efficient calibration technique that allows for the correction of such non-ideality. Experimental data validates the design of a resistively loaded time amplifier with a gain of 182 Second/Second. Also, simulations suggest that the time amplifier can be designed for gains up to a few thousands with input dynamic ranges in excess of a few hundred picoseconds. Also, some figures of merit and performance are introduced along with a discussion on some of the trade-offs involved in the design of a time amplifier.Mourad Oulmane received the B.A.Sc. degree from the University of Constantine, Algeria, in 1995, and the M.A.Sc. degree in physics from the Institut National Polytechnique de Grenoble, France, in 1997, the M.Eng. Degree from McGill University in 2001 where he is pursuing a PhD Degree. His research interests include analog/mixed-signal/RF IC design as well as interconnect and semiconductor technologies design and modeling.Gordon W. Roberts received the B.A.Sc. degree from the University of Waterloo, Canada, in 1983, and the M.A.Sc. and Ph.D. degrees from the University of Toronto, Canada, in 1986 and 1989, respectively, all in electrical engineering. He is currently on leave from McGill University as a co-founder of DFT Microsystems, Inc., where he holds the position of Chief Technical Officer. At McGill University he is a full professor where he holds the James McGill Chair in Electrical and Computer Engineering. He has published numerous papers in scientific journals and conferences, and he has contributed chapters to various industrially focused textbooks. In addition, he has co-written five textbooks related to analog IC design and mixed-signal test for undergraduate and graduate engineering programs. Dr. Roberts has held many administration roles within conference organizations; most recently he was the 2003 program chair of the IEEE International Test Conference. Dr. Roberts is a Fellow of the IEEE.     

A new CMOS multimode digital pixel sensor dedicated to an implantable visual cortical stimulator

We describe in this paper a new CMOS multimode image pixel sensor (MIPS) dedicated to an implantable visual cortical stimulator. Each 16 μm × 16 μm pixel area contains a photodiode, with a fill factor of 22%, a comparator used to convert the pixel level from analog to digital (A/D) values and an 8-bit DRAM, resulting in a total of 44 transistors per pixel. The A/D conversions use one common digital to analog converter to deliver the voltage reference needed to determine the pixel voltage. Three selectable operation modes are combined in the proposed MIPS: A high dynamic range logarithmic mode, a linear integration mode, and a novel differential mode between two consecutive images. This last mode that allows 3D information is required for a visual cortical stimulator. A test chip has been fabricated in CMOS 0.18 μm technology and tested to validate the full operation of the different proposed modes. Mohamad Sawan received the B.Sc. degree in electrical engineering from Université Laval, Canada in 1984, the M.Sc. and Ph.D. degrees, both in electrical engineering, from Université de Sherbrooke, Canada, in 1986 and 1990 respectively, and postdoctorate training from McGill University, Canada in 1991. He joined Ecole Polytechnique de Montréal in 1991 where he is currently a Professor in Microelectronics. His scientific interests are the design and test of mixed-signal (analog, digital and RF) circuits and systems, the digital and analog signal processing, the modeling, design, integration, assembly and validation of advanced wirelessly powered and controlled monitoring and measurement techniques. These topics are oriented toward the biomedical implantable devices and telecommunications applications. Dr. Sawan is a holder of a Canadian Research Chair in Smart Medical Devices. He is leading the Microelectronics Strategic Alliance of Quebec (Regroupement stratégique en microélectronique du Québec – ReSMiQ). He is founder of the Eastern Canadian IEEE-Solid State Circuits Society Chapter, the International IEEE-NEWCAS conference, and Polystim neurotechnologies laboratory at the Ecole Polytechnique de Montreal. He is cofounder of the International Functional Electrical Stimulation Society (IFESS), and the IEEE International Conference on Electronics, Circuits and Systems (ICECS). Dr. Sawan is involved in the committees of many national and international conferences and other scientific events. He published more than 350 papers in peer reviewed journals and conference proceedings and is awarded 6 patents. He is editor of the Springer Mixed-signal Letters, Distinguished Lecturer for the IEEE CAS Society, President of the biomedical circuits and systems (BioCAS) technical committee of the IEEE CAS Society, and he is representative of IEEE-CAS in the International Biotechnology council. He received the Barbara Turnbull 2003 award for spinal cord research, the Medal of Merit from Lebanon, and the Bombardier Medal from the French Association for the advancement of sciences. Dr. Sawan is Fellow of the Canadian Academy of Engineering, and Fellow of the IEEE. Annie Trépanier received her Bachelor of Engineering Degree in Electrical Engineering in 2002 and her Master of Applied Sciences Degree in Microelectronics in 2005 from the Ecole Polytechnique de Montreal as a member of the Cortivision team in the Polystim Neurotechnologies Laboratory. She held a summer job at Nortel Networks and trained at Mindready. She is currently employed at Matrox, Montreal. Jean-Luc Trépanier received his Bachelor of Engineering Degree in Electrical Engineering in 2000 and his Master of Applied Sciences Degree in Microelectronics in 2003 from the Ecole Polytechnique de Montreal where he was a member of the Cortivision team in the Polystim Neurotechnologies Laboratory. He started his first company, Olyxia inc., where he developed the soon to be released Cute Spider VoIP Network. He is also the founder and CEO of Nexyrius inc. which develops a new generation of embedded systems. Yves Audet received his M.Sc. degree from a joint program between the University of Sherbrooke, QC, Canada and Université Joseph Fourier in Grenoble, France. He completed his Ph.D. at Simon Fraser University, BC, Canada. He has been working for three years in Research and Development with Mitel Corporation before being hired as assistant professor at école Polytechnique of Montreal, QC, Canada, in 2001. His research interests are CMOS sensor arrays and mixed signal circuits. Roula Ghannoum received her Bachelor of Engineering Degree in Computer and Communications Engineering from the Lebanese American University, Byblos—Lebanon, in July 2005. She is currently pursuing her Master of Applied Sciences in Microelectronics at the Ecole Polytechnique de Montreal as a member of the Cortivision team in the Polystim Neurotechnologies Laboratory working on image sensors as part of a global project that aims at restoring sight to the visually incapacitated.     

A Fast Settling HBT Reference Amplifier for High Speed Digital-to-Analog Converters

This paper proposes a fast settling reference amplifier for use with a current-steering Digital-to-Analog Converter (DAC). The reference amplifier utilizes an open loop architecture, resulting in a bandwidth of 2.5 GHz, small chip area and low power. The wide bandwidth of the reference amplifier is shown to be important for fast settling of DAC current output. The reference amplifier is also able to generate a reference current that tracks fast changes of reference voltage, thus is useful in applications such as multiplying DACs and transversal filters. The proposed design was fabricated using a 1 μm GaAs HBT process. The prototype reference amplifier achieves a temperature coefficient of 92 ppm/°C over a temperature range of 0–100°C and the reference current changes only ±2.14% when the power supply varies ±0.2 V.Yihong Dai received his B.S. and M.Eng. degrees in Electrical Engineering from Shanghai JiaoTong University, Shanghai, China in 1993 and 1996, respectively. From 1996 to 1998, he enjoyed his industrial experiences in Shanghai with semiconductor companies like Shanghai Nortel Semiconductor and Motorola Electronics (China) Shanghai Branch. Since 1998, he has been a research assistant at the Analog and Mixed-signal Laboratory of the Electrical Engineering Department of Brigham Young University working toward his Ph.D. During the summer of 1999, he was with AMI semiconductor Utah Research and Design Center where he developed a threshold voltage based CMOS voltage reference architecture. In the summer of 2001, he was with Ultra Design LLC where he designed a reference amplifier for high speed digital-to-analog converters. His research interest includes voltage reference, reference amplifier and high speed data converters in both CMOS and GaAs processes.Donald T. Comer received the B.S., M.S., and Ph.D. degrees from San Jose State University, the University of California (Berkeley), and the University of Santa Clara, respectively, all in electrical engineering. He began teaching at San Jose State University in 1961 and mixed his teaching and industrial work until he left San Jose State University in 1979. He has worked for California Technical Industries, IBM Corp., Mobility Systems, Precision Monolithics, Storage Technology Corp., and Analog Devices during his career. He founded the AMI Utah Research and Design Center in 1998 that specializes in MOS design. In 2002, Dr. Comer founded Ultra Design, a design center that specializes in high-frequency heterojunction circuit designs. He holds fifteen patents and has published over 50 articles dealing with solid-state and integrated circuits. He has published five textbooks in the field of large-signal and integrated circuits. He formerly held the Quentin Berg Chair at Penn State Harrisburg from 1990 to 1995. He is now a professor of electrical and computer engineering at Brigham Young University where he held the Endowed Chair of Engineering from 1995 to 1998.David J. Comer received the B.S., M.S., and Ph.D. degrees from San Jose State University, the University of California (Berkeley), and Washington State University, respectively, all in electrical engineering. He has worked for IBM Corp., Pacific Electromagnetics, Lawrence Livermore Laboratories, and Intel Corporation. He began his teaching career at the University of Idaho and has taught at the University of Calgary and California State University, Chico. He is presently a professor of electrical and computer engineering at Brigham Young University. He served as Chairman of the Division (Dean) of Engineering at CSU, Chico and as Department Chair at BYU.While at CSU, Chico, Dr. Comer served on the statewide Engineering Liaison Committee and served as Chair of the Council of California State University Deans of Engineering.Dr. Comer has published twelve textbooks and over 60 articles in the field of circuit design. He has contributed sections to the Encyclopedia of Physical Science and Technology and holds seven patents. He was given the Professional Achievement Award at CSU, Chico and was named the Outstanding Teacher of Engineering at BYU. He has also held the College of Engineering Research Chair at Brigham Young University.     

A low-power, second-order Δ/Σ modulator using a single class-AB op-amp for voice-band applications

The design of a power-efficient second-order Δ/Σ modulator for voice-band is presented. At system level, a new single-loop, single-stage modulator is proposed. The modulator employs only one class-AB op-amp to realize a second-order noise shaping for voice-band applications. The modulator is designed in a 0.25μm standard CMOS process, and exhibits 86 dB dynamic range (DR) for a 4 kHz voice-bandwidth. The proposed modulator consumes 125μW from a 2.5 V supply. Aminghasem Safarian received the B.S. and M.S. degrees in electrical engineering from the Sharif University of Technology, in 2000, 2002, respectively. Since 2003 he is a research assistant at University of California, Irvine, working toward his Ph.D. degree in electrical engineering emphasizing on RF IC design for wireless communication systems. During the summer of 2005, he was with Broadcom Corporation, Irvine, CA, where he developed integrated receivers for RFID and WCDMA applications. Farzad Sahandiesfanjani was born in Tabriz, Iran in 1976. He received the B.S. and M.S. degrees in electronics from Sharif University of Technology, Tehran, Iran, in 1998 and 2000, respectively. The subject of his thesis was the design of 4th order cascade delta-sigma modulator for ADSL Analog Front End. From 1998 to 2003, he was with Emad Semicon Co., Tehran, Iran, where he designed circuits for voice application such as CODEC and SLIC chip. He also designed a 3rd order single loop class-D delta-sigma modulator for audio application. He joined Tripath Technology Inc., San Jose, CA, in 2003 and has been working on the design of analog and mixed-signal circuits for class-T audio power amplifier. He is also author of one patent for inductor-less switching audio power amplifier and also co-author of 3 more pending patents and 4 papers. Payam Heydari (S'98–M'00) received the B.S. and M.S. degrees (with honors) in electrical engineering from the Sharif University of Technology, in 1992, 1995, respectively. He received the Ph.D. degree in electrical engineering from the University of Southern California, in 2001. During the summer of 1997, he was with Bell-Labs, Lucent Technologies, Murray Hill, NJ, where he worked on noise analysis in deep submicron very large-scale integrated (VLSI) circuits. During the summer of 1998, he was with IBM T. J. Watson Research Center, Yorktown Heights, NY, where he worked on gradient-based optimization and sensitivity analysis of custom-integrated circuits. Since August 2001, he has been an Assistant Professor of Electrical Engineering at the University of California, Irvine, where his research interest is the design of high-speed analog, radio-frequency (RF), and mixed-signal integrated circuits. Dr. Heydari has received the 2005 National Science Foundation (NSF) CAREER Award, the 2005 IEEE Circuits and Systems Society Darlington Award, the 2005 Henry Samueli School of Engineering Teaching Excellence Award, the Best Paper Award at the 2000 IEEE International Conference on Computer Design (ICCD), the 2000 Honorable Award from the Department of EE-Systems at the University of Southern California, and the 2001 Technical Excellence Award in the area of Electrical Engineering from the Association of Professors and Scholars of Iranian Heritage (APSIH). He was recognized as the 2004 Outstanding Faculty at the EECS Department of the University of California, Irvine. His name was included in the 2006 Who's Who in America. Dr. Heydari is an Associate Editor of the IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS—part I. He currently serves on the Technical Program Committees of Custom Integrated Circuits Conference (CICC), International Symposium on Low-Power Electronics and Design (ISLPED), International Symposium on Quality Electronic Design (ISQED), and the Local Arrangement Chair of the ISLPED conference. He was the Student Design Contest Judge for the DAC/ISSCC Design Contest Award in 2003, the Technical Program Committee member of the IEEE Design and Test in Europe (DATE) from 2003 to 2004, and International Symposium on Physical Design (ISPD) in 2003. Mojtaba Atarodi received his Ph.D degree from USC (the University of Southern California, Los Angeles), in electrical engineering Electro-physics in 1993, his M.S from University of California at Irvine, and his B.SEE from the Tehran Polytechnic University with first Grade honor. Following his Ph.D completion, he was with Linear Technology Corporation from 1993 to 1996 as an analog design engineer. He has been with Sharif University of Technology as an Assistant and Visiting Professor since 1997. The Author of more than 50 technical journal and conference papers an a book on Analog CMOS IC Design, Dr Atarodi’s main research interests are analog and RF IC system, circuit, and signal processing design as well as analog synthesis tools. Having held several management and consulting positions during the last 15 years in the US industry, he holds one US patent in analog highly linear tunable Operational Transconductance Amplifiers and has applied for 5 more US patents as well.     

New 1.5-V CMOS second generation current conveyor based on wide range transconductor

This paper presents a novel CMOS low-voltage and low-power positive second-generation current conveyor (CCII+). The proposed CCII+ uses two n-channel differential pairs instead of the complementary differential pairs; i.e. (n-channel and p-channel), to realize the input stage. This solution allows almost a rail-to-rail input and output operation; also it reduces the number of current mirrors needed in the input stage. The CCII+ is operating at supply voltages of ±0.75 V with a total standby current of 133 μA. The application of the proposed CCII+ to realize a MOS-C second order maximally flat low-pass filter is given. PSpice simulation results for the proposed CCII+ and its application are given. Ahmed H. Madian was born in Jeddah, Saudi Arabia in 1975. He received the B.Sc. degree with honors, and the M.Sc. degree in electronics and communications from Cairo University, Cairo, Egypt, in 1997, and 2001 respectively. He is currently a Research Assistant in the Electronics Engineering Department, Micro-Electronics Design Center, Egyptian Atomic Energy Authority, Cairo, Egypt. His research interests are in circuit theory; low-voltage analog CMOS circuit design, current-mode analog signal processing, and mixed/digital applications on filed programmable gate arrays. Soliman A. Mahmoud was born in Cairo, Egypt, in 1971. He received the BSc degree with honors in 1994, the MSc degree in 1996, and the PhD degree in 1999, all from the Electronics and Communications Department, Cairo University, Egypt. He is currently an Associate Professor at the Electrical Engineering Department, Fayoum University, Egypt. He is currently also a visiting Associate Professor at the Electrical and Electronics Engineering Department, German University in Cairo, Egypt. In 2005, He was decorated with the Science Prize in Advanced Engineering Technology from the Academy of Scientific Research and technology. His research and teaching interests are in circuit theory, fully-integrated analog filters, high-frequency transconductance amplifiers, low-voltage analog CMOS circuit design, current-mode analog signal processing, and mixed analog/digital programmable analog blocks. Ahmed M. Soliman was born in Cairo Egypt, on November 22, 1943. He received the B.Sc. degree with honors from Cairo University, Cairo, Egypt, in 1964,the M.S. and Ph.D. degrees from the University of Pittsburgh, Pittsburgh, PA., U.S.A., in 1967 and 1970, respectively, all in Electrical Engineering. He is currently Professor Electronics and Communications Engineering Department, Cairo University, Egypt. From September 1997-September 2003, Dr Soliman served as Professor and Chairman Electronics and Communications Engineering Department, Cairo University, Egypt. From 1985-1987, Dr. Soliman served as Professor and Chairman of the Electrical Engineering Department, United Arab Emirates University, and from 1987-1991 he was the Associate Dean of Engineering at the same University. He has held visiting academic appointments at San Francisco State University, Florida Atlantic University and the American University in Cairo.He was a visiting scholar at Bochum University, Germany (Summer 1985) and with the Technical University of Wien, Austria (Summer 1987). In November 2005, Dr Soliman gave a lecture at Nanyang Technological University, Singapore.Dr Soliman was also invited to visit Taiwan and gave lectures at Chung Yuan Christian University and at National Central University of Taiwan. In 1977, Dr. Soliman was decorated with the First Class Science Medal, from the President of Egypt, for his services to the field of Engineering and Engineering Education. Dr Soliman is a Member of the Editorial Board of the IEE Proceedings Circuits, Devices and Systems. Dr Soliman is a Member of the Editorial Board of Analog Integrated Circuits and Signal Processing. Dr Soliman served as Associate Editor of the IEEE Transactions on Circuits and Systems I (Analog Circuits and Filters) from December 2001 to December 2003 and is Associate Editor of the Journal of Circuits, Systems and Signal Processing from January 2004-Now.     

Localized algorithms for coverage boundary detection in wireless sensor networks

Connected coverage, which reflects how well a target field is monitored under the base station, is the most important performance metric used to measure the quality of surveillance that wireless sensor networks (WSNs) can provide. To facilitate the measurement of this metric, we propose two novel algorithms for individual sensor nodes to identify whether they are on the coverage boundary, i.e., the boundary of a coverage hole or network partition. Our algorithms are based on two novel computational geometric techniques called localized Voronoi and neighbor embracing polygons. Compared to previous work, our algorithms can be applied to WSNs of arbitrary topologies. The algorithms are fully distributed in the sense that only the minimal position information of one-hop neighbors and a limited number of simple local computations are needed, and thus are of high scalability and energy efficiency. We show the correctness and efficiency of our algorithms by theoretical proofs and extensive simulations. Chi Zhang received the B.E. and M.E. degrees in Electrical Engineering from Huazhong University of Science and Technology, Wuhan, China, in July 1999 and January 2002, respectively. Since September 2004, he has been working towards the Ph.D. degree in the Department of Electrical and Computer Engineering at the University of Florida, Gainesville, Florida, USA. His research interests are network and distributed system security, wireless networking, and mobile computing, with emphasis on mobile ad hoc networks, wireless sensor networks, wireless mesh networks, and heterogeneous wired/wireless networks. Yanchao Zhang received the B.E. degree in computer communications from Nanjing University of Posts and Telecommunications, Nanjing, China, in July 1999, the M.E. degree in computer applications from Beijing University of Posts and Telecommunications, Beijing, China, in April 2002, and the Ph.D. degree in electrical and computer engineering from the University of Florida, Gainesville, in August 2006. Since September 2006, he has been an Assistant Professor in the Department of Electrical and Computer Engineering, New Jersey Institute of Technology, Newark. His research interest include wireless and Internet security, wireless networking, and mobile computing. He is a member of the IEEE and ACM. Yuguang Fang received the BS and MS degrees in Mathematics from Qufu Normal University, Qufu, Shandong, China, in 1984 and 1987, respectively, a Ph.D. degree in Systems and Control Engineering from Department of Systems, Control and Industrial Engineering at Case Western Reserve University, Cleveland, Ohio, in January 1994, and a Ph.D. degree in Electrical Engineering from Department of Electrical and Computer Engineering at Boston University, Massachusetts, in May 1997. From 1987 to 1988, he held research and teaching position in both Department of Mathematics and the Institute of Automation at Qufu Normal University. From September 1989 to December 1993, he was a teaching/research assistant in Department of Systems, Control and Industrial Engineering at Case Western Reserve University, where he held a research associate position from January 1994 to May 1994. He held a post-doctoral position in Department of Electrical and Computer Engineering at Boston University from June 1994 to August 1995. From September 1995 to May 1997, he was a research assistant in Department of Electrical and Computer Engineering at Boston University. From June 1997 to July 1998, he was a Visiting Assistant Professor in Department of Electrical Engineering at the University of Texas at Dallas. From July 1998 to May 2000, he was an Assistant Professor in the Department of Electrical and Computer Engineering at New Jersey Institute of Technology, Newark, New Jersey. In May 2000, he joined the Department of Electrical and Computer Engineering at University of Florida, Gainesville, Florida, where he got early promotion to Associate Professor with tenure in August 2003, and to Full Professor in August 2005. His research interests span many areas including wireless networks, mobile computing, mobile communications, wireless security, automatic control, and neural networks. He has published over one hundred and fifty (150) papers in refereed professional journals and conferences. He received the National Science Foundation Faculty Early Career Award in 2001 and the Office of Naval Research Young Investigator Award in 2002. He also received the 2001 CAST Academic Award. He is listed in Marquis Who’s Who in Science and Engineering, Who’s Who in America and Who’s Who in World. Dr. Fang has actively engaged in many professional activities. He is a senior member of the IEEE and a member of the ACM. He is an Editor for IEEE Transactions on Communications, an Editor for IEEE Transactions on Wireless Communications, an Editor for IEEE Transactions on Mobile Computing, an Editor for ACM Wireless Networks, and an Editor for IEEE Wireless Communications. He was an Editor for IEEE Journal on Selected Areas in Communications:Wireless Communications Series, an Area Editor for ACM Mobile Computing and Communications Review, an Editor for Wiley International Journal on Wireless Communications and Mobile Computing, and Feature Editor for Scanning the Literature in IEEE Personal Communications. He has also actively involved with many professional conferences such as ACM MobiCom’02 (Committee Co-Chair for Student Travel Award), MobiCom’01, IEEE INFOCOM’06, INFOCOM’05 (Vice-Chair for Technical Program Committee), INFOCOM’04, INFOCOM’03, INFOCOM’00, INFOCOM’98, IEEE WCNC’04, WCNC’02, WCNC’00 Technical Program Vice-Chair), WCNC’99, IEEE Globecom’04 (Symposium Co-Chair), Globecom’02, and International Conference on Computer Communications and Networking (IC3N) (Technical Program Vice-Chair).     

A low-cost programmable clock generator for switched-capacitor circuit applications

This paper presents two improved circuit techniques that allow the design of a low-cost programmable clock generator using a ring oscillator for low-frequency switched-capacitor applications. The first technique aims at reducing the frequency of the oscillator with small capacitors by proposing a Miller current-starved inverter ring oscillator. For identical values of integrated components in implementation, the proposed ring oscillator reduces the oscillation frequency by 5 times over the conventional ring oscillator and 3 times over the conventional current-starved inverter ring oscillator. This benefits the relaxation of PSRR requirement and the reduction of substrate noise coupling in mixed-signal circuits. The second technique aims at enhancing the reliability of the programmed data by proposing orthogonal fusible link trimming circuit. The experimental results have verified that the programming range of 56 kHz to 1.042 MHz is achieved using discrete-step tuning on small capacitor values from 0.375 pF to 5.625 pF together with frequency division by four divider stages, whilst the jitter is less than 300 ps at ±10% variation in a 5 V supply in the entire tuning range. Wing Foon Lee was born in Singapore. He had worked as an application engineer for more than two years. He received his B.Eng., M.Eng. and Ph.D. degrees in Electrical & Electronic Engineering from Nanyang Technological University, Singapore in 1996, 1999 and 2005 respectively. His research interest is on low power analog circuit design, high precision readout circuits and signal-conditioning circuits for sensor applications. P. K. Chan was born in Hong Kong. He received the B.Sc. (Hons) degree from the University of Essex, Colchester, U.K., in 1987, the M.Sc. degree from the University of Manchester, Institute of Science and Technology (U.M.I.S.T.), Manchester, U.K., in 1988, and the PhD degree from the University of Plymouth, U.K. in 1992. From 1989 to 1992, he was a Research Assistant with the University of Plymouth, working in the area of MOS continuous-time filters. In 1993, he joined the Institute of Microelectronics (IME) as a Member Technical Staff, where he designed CMOS sensor interfaces for industrial applications. In 1996, He was a Staff Engineer with Motorola, Singapore where he developed the magnetic write channel for Motorola 1st generation hard-disk preamplifier. He joined Nanyang Technological University (NTU), Singapore in 1997, where he is currently an Associate Professor in the School of Electrical and Electronic Engineering and Program Director [analog/mixed-signal IC and applications] for the Center for Integrated Circuits and Systems (CICS). He holds four patents and is an IC Design Consultant to local and multi-national companies in Singapore. He has also conducted numerous IC design short courses to the industrial companies and design centers. His research interests include circuit theory, amplifier frequency compensation techniques, sensing interfaces for integrated sensors, biomedical circuits and systems, integrated filters and data converters.     

Frequency Specification Testing of Analog Filters Using Wavelet Transform of Dynamic Supply Current

Wavelet transform has the property of resolving signal in both time and frequency unlike Fourier transform. In this work, we show that time-domain information obtained from wavelet analysis of supply current can be used to test the frequency specification of analog filters efficiently. The pole/zero locations in the frequency response of analog filters shift due to change in component values with process variations. It is essential to test the filters for the shift in frequency response and fix it during production test. Wavelet analysis of supply current can be a promising alternative to test frequency specification of analog filters, since it needs only one AC stimulus and is virtually unaffected by transistor threshold variation. Simulation results on two test circuits demonstrate that we can estimate pole/zero shift with less than 3% error using only one measurement, which requires about 18 measurements in the conventional technique.Swarup Bhunia received the undergraduate degree from Jadavpur University, Calcutta, India, and the Masters degree from the Indian Institute of Technology (IIT), Kharagpur. He is currently working toward the Ph.D. degree in the Department of Electrical Engineering, Purdue University, West Lafayette, IN, USA. He has worked in the EDA industry on RTL synthesis and verification for about three years. His research interest includes design methodologies for high-performance low-power testable VLSI system, defect-based testing, noise analysis, and noise-aware design.Arijit Raychowdhury received the B.E. degree in 2001 in electronics and telecommunication engineering from Jadavpur University, India. He is currently pursuing the Ph.D. degree in electrical and computer engineering in Purdue University, West Lafayette, IN, USA. He has worked as an analog circuit designer in Texas Instruments India. His research interests include device/circuit design for scaled silicon and nonsilicon devices. He has received academic excellence awards in 1997, 2000, and 2001 and Messner Fellowship from Purdue University in 2002. Mr. Raychowdhury has been awarded the Best Student Paper Award in the IEEE Nanotechnology Conference, 2003.Kaushik Roy received the B.Tech. degree in electronics and electrical communications engineering from the Indian Institute of Technology, Kharagpur, India, and the Ph.D. degree from the Electrical and Computer Engineering Department, University of Illinois, Urbana, in 1990. He was with the Semiconductor Process and Design Center of Texas Instruments, Dallas, TX, where he worked on FPGA architecture development and low-power circuit design. He joined the electrical and computer engineering faculty, Purdue University, West Lafayette, IN, in 1993, where he is currently a Professor. His research interests include VLSI design/CAD with particular emphasis in low-power electronics for portable computing and wireless communications, VLSI testing and verification, and reconfigurable computing. He has published more than 250 papers in refereed journals and conferences, holds six patents, and is Co-Author of a book on Low Power CMOS VLSI Design (New York: Wiley). He was Guest Editor for a Special Issue on Low-Power VLSI in IEE Proceedings Computers and Digital Techniques (July 2002). Dr. Roy received the National Science Foundation Career Development Award in 1995, the IBM Faculty Partnership Award, AT&T/Lucent Foundation Award, Best Paper Awards at the 1997 International Test Conference and 2000 International Symposium on Quality of IC Design, 2003 IEEE Latin American Test Workshop, and 2003 IEEE Nano. He is on the Editorial Board of IEEE Design and Test, IEEE TRANSACTIONS ON CIRCUITS AND SYSTEMS, and IEEE TRANSACTIONS ON VLSI SYSTEMS. He was Guest Editor for a Special Issue on Low-Power VLSI in IEEE DESIGN AND TEST (1994), and for the IEEE TRANSACTIONS ON VLSI SYSTEMS (June 2000).     

1.1 V Low-Power ΣΔ Modulator for 14-bit, 16 KHz A/D Conversion Using a New Low-Voltage Class-AB Op-amp

This paper presents the implementation of a second order modulator for a 1.1 V supply voltage. A new class-AB CMOS operational amplifier has been designed in order to achieve high-resolution under very-low-voltage operation. The modulator has been implemented using a 0.35 m CMOS technology with 0.65 V transistor threshold voltage. Experimental results show 14 bits of resolution over 16 kHz nyquist rate with an oversampling ratio of 160.Fernando Muñoz Chavero was born in El Saucejo, Sevilla, Spain. He received the Telecommunications Engineering and Ph.D. degrees from the University of Seville, Seville, Spain, in 1998 and 2002, respectively. Since 1997, he has been with the Department of Electronic Engineering, School of Engineering, University of Seville, where he has been an Associate Professor (1999). His research interests are related to low-voltage low-power analog circuit design, A/D and D/A conversion, and analog and mixed signal processing.Alfredo Pérez Vega-Leal was born in Seville, Spain. He received the Telecommunications Engineering and Ph.D. degrees from the University of Seville, Seville, Spain, in 1998 and 2003, respectively. Since 1995, he has been with the Department of Electronic Engineering, School of Engineering, University of Seville, as research student and became an Associate Professor in 1999. His research interests are related to low-voltage low-power analog circuit design, A/D and D/A conversion.Ramón González Carvajal was born in Seville, Spain. He received the Electrical Engineering and Ph.D. degrees from the University of Seville, Seville, Spain, in 1995 and 1999, respectively. Since 1996, he has been with the Department of Electronic Engineering, School of Engineering, University of Seville, where he has been an Associate Professor (1996), and Professor (2002). He has published more than 100 papers in International Journals and Conferences. His research interests are related to low-voltage low-power analog circuit design, A/D and D/A conversion, and analog and mixed signal processing.Antonio Torralba was born in Seville, Spain. He received the electrical engineering and Ph.D. degrees from the University of Seville, Seville, Spain, in 1983 and 1985, respectively. Since 1983, he has been with the Department of Electronic Engineering, School of Engineering, University of Seville, where he has been an Assistant professor, Associate Professor (1987), and Professor (1996). He has published 30 papers in journals and more than 80 papers in conferences. His research interests are in the design and modeling of low-voltage analog circuits, analog and mixed-signal design, analog to digital conversion, and electronic circuits and systems with application to control and communication.Jonathan Noel Tombs was born in Oxford, UK. He received the Electrical Engineering and Ph.D. degrees from Oxford University, UK, in 1987 and 1991, respectively. Since 1993, he has been with the Department of Electronic Engineering, School of Engineering, University of Seville, where he has been an Associate Professor (1997), and Professor (2002). He has published more than 50 papers in International Journals and Conferences. His research interests are related to Digital Design and system verification with VHDL, low-voltage low-power analog circuit design, A/D and D/A conversion and analog and mixed signal processing.Jaime Ramírez-Angulo is currently Klipsch Distinguished Professor, IEEE fellow and Director of the Mixed-Signal VLSI lab at the Klipsch School of Electrical and Computer Engineering, New Mexico State University (Las Cruces, New Mexico), USA. He received a degree in Communications and Electronic Engineering (Professional degree), a M.S.E.E. from the National Polytechnic Institute in Mexico City and a Dr.-Ing. degree form the University of Stuttgart in Stuttgart, Germany in 1974, 1976 and 1982 respectively. He was professor at the National Institute for Astrophysics Optics and Electronics (INAOE) and at Texas A&M University. His research is related to various aspects of design and test of analog and mixed-signal Very Large Scale Integrated Circuits.