Niccolò Rinaldi, University of Naples, Italy
Michael Schröter, Technical University Dresden, Germany
Chair for Electron Devices and Integrated Circuits, Technische UniversitÃ¤t Dresden, Germany
, Department of Electrical and Computer Engineering, University ofCalifornia at San Diego, USA, Institute for High-Frequency and Communication Technology (IHCT),University of Wuppertal, Germany
The semiconductor industry is a fundamental building block of the new economy, there is no area of modern life untouched by the progress of nanoelectronics. The electronic chip is becoming
an ever-increasing portion of system solutions, starting initially from less than 5% in the 1970 microcomputer era, to more than 60% of the final cost of a mobile telephone, 50% of the price of a personal computer (representing nearly 100% of the functionalities) and 30% of the price of a monitor in the early 2000's.
Interest in utilizing the (sub-)mm-wave frequency spectrum for commercial and research applications has also been steadily increasing. Such applications, which constitute a diverse but sizeable future market, span a large variety of areas such as health, material science, mass transit, industrial automation, communications, and space exploration.
Silicon-Germanium Heterojunction Bipolar Transistors for mm-Wave Systems Technology, Modeling and Circuit Applications provides an overview of results of the DOTSEVEN EU research project, and as such focusses on key material developments for mm-Wave Device Technology. It starts with the motivation at the beginning of the project and a summary of its major achievements. The subsequent chapters provide a detailed description of the obtained research results in the various areas of process development, device simulation, compact device modeling, experimental characterization, reliability, (sub-)mm-wave circuit design and systems.
Silicon-Germanium, Bipolar Transistors, mm-wave Systems Technology, HBT Technology; Device Simulation; Compact Modeling; mm-Wave Calibration; Reliability; Millimeter-wave circuits