Low Power Emerging Wireless Technologies Devices, Circuits, and Systems Series

Advanced concepts for wireless communications offer a vision of technology that is embedded in our surroundings and practically invisible, but present whenever required. Although the use of deep submicron CMOS processes allows for an unprecedented degree of scaling in digital circuitry, it complicates the implementation and integration of traditional RF circuits. The requirement for long operating life under limited energy supply also poses severe design constraints, particularly in critical applications in commerce, healthcare, and security. These challenges call for innovative design solutions at the circuit and system levels. Low Power Emerging Wireless Technologies addresses the crucial scientific and technological challenges for the realization of fully integrated, highly efficient, and cost-effective solutions for emerging wireless applications.

Get Insights from the Experts on Wireless Circuit Design

The book features contributions by top international experts in wireless circuit design representing both industry and academia. They explore the state of the art in wireless communication for 3G and 4G cellular networks, millimeter-wave applications, wireless sensor networks, and wireless medical technologies. The emphasis is on low-power wireless applications, RF building blocks for wireless applications, and short-distance and beam steering. Topics covered include new opportunities in body area networks, medical implants, satellite communications, automobile radar detection, and wearable electronics.

Exploit the Potential behind Emerging Green Wireless Technologies

A must for anyone serious about future wireless technologies, this multidisciplinary book discusses the challenges of emerging power-efficient applications. Written for practicing engineers in the wireless communication field who have some experience in integrated circuits, it is also a valuable resource for graduate students.

Large Signal and Small Signal Building Blocks for Cellular Infrastructure. Efficient MIMO Receiver Design for Next Generation Wireless Systems. A Low Noise, Low Distortion Radio Design. Radio Frequency (RF) Radiation Exposure and Health. Multifunctional Software-Defined Radar Sensors for Detection, Imaging, and Navigation. Ultrawide Bandwidth Radio Frequency Identification and Localization. Passive Imaging in Silicon Technologies. Ultralow Power Radio Design for Emerging Healthcare Applications. Ultralow Power Techniques in Small Autonomous Implants and Sensor Nodes. An Open-Loop Multiphase Local-Oscillator Generation Technique. On-Chip Accelerometers Using Bondwire Inertial Sensing. Design of a Frequency-Shift-Based CMOS Magnetic Sensor Array for Point-of-Care (PoC) Biomolecular Diagnosis Applications. Receiver Front Ends with Robustness to Process Variations.

Krzysztof (Kris) Iniewski manages R&D at Redlen Technologies, Inc., a startup company in Vancouver, Canada. He is also a president of CMOS Emerging Technologies, an organization of high-tech events covering communications, microsystems, optoelectronics, and sensors. Dr. Iniewski has held numerous faculty and management positions at the University of Toronto, University of Alberta, SFU, and PMC-Sierra, Inc. He has published more than 100 research papers in international journals and conferences. He holds 18 international patents granted in the United States, Canada, France, Germany, and Japan. He is a frequent invited speaker, has consulted for multiple organizations internationally, and has written and edited several books.

Reza Mahmoudi is currently an associate professor in the field of ultrahigh frequency front-end electronics in the Department of Electrical Engineering at Eindhoven University of Technology, the Netherlands. He earned his Ph.D. from the Delft University of Technology, the Netherlands, in 2001. He has worked for Philips Discrete Semiconductors in Nijmegen, the Netherlands, and Advanced Wave Research in El Segundo, California. Dr. Mahmoudi’s research efforts concentrate on the areas of ultrahigh speed communication as well as high resolution imaging systems. He has contributed to 85 academic publications.