01604nam0-2200541---450-99000006475020331620060818162215.01-86094-040-40006475USA010006475(ALEPH)000006475USA01000647520000914d1997----|||y0itay0103----baengGB||||||||001yyTolerance design of electronic circuitsRobert Spence, Randeep Singh SoinLondonImperial College Presscopyr. 1997XIII, 215 p.24 cm.20012001001-------2001Circuiti elettroniciProgettazione621. 3815SPENCE,Robert339761SINGH SOIN,Randeep746516ITSALBCISBD990000064750203316621. 3815 SPE13460 Ing.621.381500000066MF/941928MFBKDIMECTEC20000914USA01173020001019USA01105520001019USA01145320001019USA01150020001019USA01153820001024USA01151420001027USA01151820001027USA01152220001110USA01170920001124USA01120720020403USA011614PATRY9020040406USA011606DIMEC9020060818USA011622Tolerance design of electronic circuits1490145UNISA03018nam 2200613 450 99646676800331620220304103231.03-540-47388-210.1007/BFb0084432(CKB)1000000000437073(SSID)ssj0000323358(PQKBManifestationID)12042126(PQKBTitleCode)TC0000323358(PQKBWorkID)10296664(PQKB)11221879(DE-He213)978-3-540-47388-6(MiAaPQ)EBC5586053(Au-PeEL)EBL5586053(OCoLC)1066196574(MiAaPQ)EBC6842620(Au-PeEL)EBL6842620(OCoLC)793079251(PPN)155168630(EXLCZ)99100000000043707320220304d1991 uy 0engurnn|008mamaatxtccrFunctional differential equations with infinite delay /Yoshiyuki Hino, Satoru Murakami, Toshiki Naito1st ed. 1991.Berlin ;Heidelberg :Springer-Verlag,[1991]©19911 online resource (X, 318 p.) Lecture Notes in Mathematics ;1473Bibliographic Level Mode of Issuance: Monograph3-540-54084-9 Phase Spaces -- Fundamental theorems -- Stieltjes integrals and linear operators on ? -- General linear systems -- Linear autonomous systems -- Linear periodic systems -- Fading memory spaces and functional differential equations -- Stabilities in perturbed systems and limiting equations -- Existence of periodic solutions and almost periodic solutions.In the theory of functional differential equations with infinite delay, there are several ways to choose the space of initial functions (phase space); and diverse (duplicated) theories arise, according to the choice of phase space. To unify the theories, an axiomatic approach has been taken since the 1960's. This book is intended as a guide for the axiomatic approach to the theory of equations with infinite delay and a culmination of the results obtained in this way. It can also be used as a textbook for a graduate course. The prerequisite knowledge is foundations of analysis including linear algebra and functional analysis. It is hoped that the book will prepare students for further study of this area, and that will serve as a ready reference to the researchers in applied analysis and engineering sciences.Lecture notes in mathematics (Springer-Verlag) ;1473.Functional equationsFunctional equations.515.75Hino Yoshiyuki59918Murakami Satoru1950-Naitō Toshiki1944-MiAaPQMiAaPQMiAaPQBOOK996466768003316Functional differential equations with infinite delay262336UNISA05731nam 22007814a 450 991081707360332120200520144314.0978661027576297812802757601280275766978047036057604703605779780471726401047172640097804717263950471726397(CKB)1000000000239344(EBL)231450(OCoLC)607812606(SSID)ssj0000115128(PQKBManifestationID)11131717(PQKBTitleCode)TC0000115128(PQKBWorkID)10009076(PQKB)11254257(MiAaPQ)EBC231450(Au-PeEL)EBL231450(CaPaEBR)ebr10114212(CaONFJC)MIL27576(Perlego)2753446(EXLCZ)99100000000023934420041022d2005 uy 0engur|n|---|||||txtccrBroadband circuits for optical fiber communication /Eduard Sackinger1st ed.Hoboken, N.J. Wileyc20051 online resource (454 p.)Description based upon print version of record.9780471712336 0471712337 Includes bibliographical references (p. 407-424) and index.Broadband Circuits for Optical Fiber Communication; Preface; Contents; I Introduction; 2 Optical Fiber; 2.1 Loss and Bandwidth; 2.2 Dispersion; 2.3 Nonlinearities; 2.4 Pulse Spreading due to Chromatic Dispersion; 2.5 Summary; 2.6 Problems; 3 Photodetectors; 3.1 p-i-n Photodetector; 3.2 Avalanche Photodetector; 3.3 p-i-n Detector with Optical Preamplifier; 3.4 Summary; 3.5 Problems; 4 Receiver Fundamentals; 4.1 Receiver Model; 4.2 Bit-Error Rate; 4.3 Sensitivity; 4.4 Personick Integrals; 4.5 Power Penalty; 4.6 Bandwidth; 4.7 Adaptive Equalizer; 4.8 Nonlinearity; 4.9 Jitter4.10 Decision Threshold Control4.11 Forward Error Correction; 4.12 Summary; 4.13 Problems; 5 Transimpedance Amplifiers; 5.1 TIA Specifications; 5.1.1 Transimpedance; 5.1.2 Input Overload Current; 5.1.3 Maximum Input Current for Linear Operation; 5.1.4 Input-Referred Noise Current; 5.1.5 Bandwidth and Group-Delay Variation; 5.2 TIA Circuit Concepts; 5.2.1 Low- and High-Impedance Front-Ends; 5.2.2 Shunt Feedback TIA; 5.2.3 Noise Optimization; 5.2.4 Adaptive Transimpedance; 5.2.5 Post Amplifier; 5.2.6 Common-Base/Gate Input Stage; 5.2.7 Current-Mode TIA; 5.2.8 Active-Feedback TIA5.2.9 Inductive Input Coupling5.2.10 Differential TIA and Offset Control; 5.2.11 Burst-Mode TIA; 5.2.12 Analog Receiver; 5.3 TIA Circuit Implementations; 5.3.1 MESFET and HFET Technology; 5.3.2 BJT, BiCMOS, and HBT Technology; 5.3.3 CMOS Technology; 5.4 Product Examples; 5.5 Research Directions; 5.6 Summary; 5.7 Problems; 6 Main Amplifiers; 6.1 Limiting vs. Automatic Gain Control (AGC); 6.2 MA Specifications; 6.2.1 Gain; 6.2.2 Bandwidth and Group-Delay Variation; 6.2.3 Noise Figure; 6.2.4 Input Dynamic Range; 6.2.5 Input Offset Voltage; 6.2.6 Low-Frequency Cutoff; 6.2.7 AM-to-PM Conversion6.3 MA Circuit Concepts6.3.1 Multistage Amplifier; 6.3.2 Techniques for Broadband Stages; 6.3.3 Offset Compensation; 6.3.4 Automatic Gain Control; 6.3.5 Loss of Signal Detection; 6.3.6 Burst-Mode Amplifier; 6.4 MA Circuit Implementations; 6.4.1 MESFET and HFET Technology; 6.4.2 BJT and HBT Technology; 6.4.3 CMOS Technology; 6.5 Product Examples; 6.6 Research Directions; 6.7 Summary; 6.8 Problems; 7 Optical Transmitters; 7.1 Transmitter Specifications; 7.2 Lasers; 7.3 Modulators; 7.4 Limits in Optical Communication Systems; 7.5 Summary; 7.6 Problems; 8 Laser and Modulator Drivers8.1 Driver Specifications8.1.1 Modulation and Bias Current Range (Laser Drivers); 8.1.2 Output Voltage Range (Laser Drivers); 8.1.3 Modulation and Bias Voltage Range (Modulator Drivers); 8.1.4 Power Dissipation; 8.1.5 Rise and Fall Times; 8.1.6 Pulse-Width Distortion; 8.1.7 Jitter Generation; 8.1.8 Eye-Diagram Mask Test; 8.2 Driver Circuit Concepts; 8.2.1 Current-Steering Output Stage; 8.2.2 Back Termination; 8.2.3 Predriver; 8.2.4 Pulse-Width Control; 8.2.5 Data Retiming; 8.2.6 Automatic Power Control (Lasers); 8.2.7 End-of-Life Detection (Lasers)8.2.8 Automatic Bias Control (MZ Modulators)An expert guide to the new and emerging field of broadband circuits for optical fiber communicationThis exciting publication makes it easy for readers to enter into and deepen their knowledge of the new and emerging field of broadband circuits for optical fiber communication. The author's selection and organization of material have been developed, tested, and refined from his many industry courses and seminars. Five types of broadband circuits are discussed in detail:* Transimpedance amplifiers* Limiting amplifiers* Automatic gain control (AGC) amplifiers* Lasers driverFiber opticsOptical communicationsEquipment and suppliesBroadband amplifiersIntegrated circuitsVery large scale integrationFiber optics.Optical communicationsEquipment and supplies.Broadband amplifiers.Integrated circuitsVery large scale integration.621.382/75Sackinger Eduard1959-1620901MiAaPQMiAaPQMiAaPQBOOK9910817073603321Broadband circuits for optical fiber communication3953942UNINA