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Electronics --- Electronic noise --- Bruit électronique --- 621.391.8 --- Noise, Electronic --- Signal theory (Telecommunication) --- Electric noise --- Quality of the received signal. Signal strength. Interference --- 621.391.8 Quality of the received signal. Signal strength. Interference --- Bruit électronique

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Electronic noise --- -621.391.8 --- Noise, Electronic --- Signal theory (Telecommunication) --- Electric noise --- Congresses --- Quality of the received signal. Signal strength. Interference --- Congresses. --- 621.391.8 Quality of the received signal. Signal strength. Interference --- 621.391.8

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Electronic noise --- Fluctuations (Physics) --- 621.391.8 --- 621.391.822 --- Variations (Physics) --- Stochastic processes --- Noise, Electronic --- Signal theory (Telecommunication) --- Electric noise --- Quality of the received signal. Signal strength. Interference --- Interference due to noise --- Conferences - Meetings --- 621.391.822 Interference due to noise --- 621.391.8 Quality of the received signal. Signal strength. Interference --- Electronic noise - Congresses --- Fluctuations (Physics) - Congresses

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Low Noise Amplifiers (LNAs) are commonly used to amplify signals that are too weak for direct processing for example in radio or cable receivers. Traditionally, low noise amplifiers are implemented via tuned amplifiers, exploiting inductors and capacitors in resonating LC-circuits. This can render very low noise but only in a relatively narrow frequency band close to resonance. There is a clear trend to use more bandwidth for communication, both via cables (e.g. cable TV, internet) and wireless links (e.g. satellite links and Ultra Wideband Band). Hence wideband low-noise amplifier techniques are very much needed. Wideband Low Noise Amplifiers Exploiting Thermal Noise Cancellation explores techniques to realize wideband amplifiers, capable of impedance matching and still achieving a low noise figure well below 3dB. This can be achieved with a new noise cancelling technique as described in this book. By using this technique, the thermal noise of the input transistor of the LNA can be cancelled while the wanted signal is amplified! The book gives a detailed analysis of this technique and presents several new amplifier circuits. This book is directly relevant for IC designers and researchers working on integrated transceivers. Although the focus is on CMOS circuits, the techniques can just as well be applied to other IC technologies, e.g. bipolar and GaAs, and even in discrete component technologies.

Broadband amplifiers. --- Electronic noise --- Prevention. --- Noise, Electronic --- Signal theory (Telecommunication) --- Electric noise --- Wide-band amplifiers --- Amplifiers (Electronics) --- Computer engineering. --- Electronics. --- Systems engineering. --- Engineering design. --- Electrical Engineering. --- Electronics and Microelectronics, Instrumentation. --- Circuits and Systems. --- Engineering Design. --- Design, Engineering --- Engineering --- Industrial design --- Strains and stresses --- Engineering systems --- System engineering --- Industrial engineering --- System analysis --- Electrical engineering --- Physical sciences --- Computers --- Design --- Design and construction --- Electrical engineering. --- Microelectronics. --- Electronic circuits. --- Electron-tube circuits --- Electric circuits --- Electron tubes --- Electronics --- Microminiature electronic equipment --- Microminiaturization (Electronics) --- Microtechnology --- Semiconductors --- Miniature electronic equipment --- Electric engineering

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Noisy data appears very naturally in applications where the authentication is based on physical identifiers, such as human beings, or physical structures, such as physical unclonable functions. This book examines how the presence of noise has an impact on information security, describes how it can be dealt with and possibly used to generate an advantage over traditional approaches, and provides a self-contained overview of the techniques and applications of security based on noisy data. Security with Noisy Data thoroughly covers the theory of authentication based on noisy data and shows it in practice as a key tool for preventing counterfeiting. Part I discusses security primitives that allow noisy inputs, and Part II focuses on the practical applications of the methods discussed in the first part. Key features: • Contains algorithms to derive secure keys from noisy data, in particular from physical unclonable functions and biometrics - as well as the theory proving that those algorithms are secure • Offers practical implementations of algorithms, including techniques that give insight into system security • Includes an overview and detailed description of new applications made possible by using these new algorithms • Discusses recent theoretical as well as application-oriented developments in the field, combining noisy data with cryptography • Describes the foundations of the subject in a clear, accessible and reader-friendly style • Presents the principles of key establishment and multiparty computation over noisy channels • Provides a detailed overview of the building blocks of cryptography for noisy data and explains how these techniques can be applied, (for example as anti-counterfeiting and key storage) • Introduces privacy protected biometric systems, analyzes the theoretical and practical properties of PUFs and discusses PUF based systems • Addresses biometrics and physical unclonable functions extensively This comprehensive introduction offers an excellent foundation to graduate students and researchers entering the field, and will also benefit professionals needing to expand their knowledge. Readers will gain a well-rounded and broad understanding of the topic through the insight it provides into both theory and practice. Pim Tuyls is a Principal Scientist at Philips Research and a Visiting Professor at the COSIC Department of the Katholieke Universiteit of Leuven, Dr Boris Skoric and Dr Tom Kevenaar are research scientists at Philips Research Laboratories, Eindhoven.

Data encryption (Computer science) --- Electronic noise. --- Data encoding (Computer science) --- Encryption of data (Computer science) --- Computer security --- Cryptography --- Noise, Electronic --- Signal theory (Telecommunication) --- Electric noise --- Data encryption (Computer science). --- Biometrics. --- Data structures (Computer scienc. --- Computer software. --- Cryptology. --- Data Structures and Information Theory. --- Algorithm Analysis and Problem Complexity. --- Software, Computer --- Computer systems --- Biometrics (Biology). --- Data structures (Computer science). --- Algorithms. --- Algorism --- Algebra --- Arithmetic --- Information structures (Computer science) --- Structures, Data (Computer science) --- Structures, Information (Computer science) --- Electronic data processing --- File organization (Computer science) --- Abstract data types (Computer science) --- Biological statistics --- Biology --- Biometrics (Biology) --- Biostatistics --- Biomathematics --- Statistics --- Foundations --- Statistical methods --- Electronic noise