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MARC Lista (tabellare)
Information technology--Smart transducer interface for sensors and actuators . Part 7, Transducers to radio frequency identification (RFID) systems communication protocols and transducer electronic data sheet (TEDS) formats / / IEEE
Information technology--Smart transducer interface for sensors and actuators . Part 7, Transducers to radio frequency identification (RFID) systems communication protocols and transducer electronic data sheet (TEDS) formats / / IEEE
Edizione [(Revision of 1451.7-2010).]
Pubbl/distr/stampa New York, N.Y. : , : IEEE, , 2012
Descrizione fisica 1 online resource (92 pages) : illustrations
Disciplina 621.3
Collana ISO/IEC/IEEE
Soggetto topico Microwave transistors
ISBN 0-7381-6693-6
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Altri titoli varianti 21451-7-2011 - Information technology--Smart transducer interface for sensors and actuators--Part 7
ISO/IEC/IEEE 21451-7:2011(E) (Revision of 1451.7-2010: Information technology--Smart transducer interface for sensors and actuators--Part 7: Transducers to radio frequency identification (RFID) systems communication protocols and transducer electronic da
ISO/IEC/IEEE 21451-7
Record Nr. UNINA-9910135327603321
New York, N.Y. : , : IEEE, , 2012
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Information technology--Smart transducer interface for sensors and actuators . Part 7, Transducers to radio frequency identification (RFID) systems communication protocols and transducer electronic data sheet (TEDS) formats / / IEEE
Information technology--Smart transducer interface for sensors and actuators . Part 7, Transducers to radio frequency identification (RFID) systems communication protocols and transducer electronic data sheet (TEDS) formats / / IEEE
Edizione [(Revision of 1451.7-2010).]
Pubbl/distr/stampa New York, N.Y. : , : IEEE, , 2012
Descrizione fisica 1 online resource (92 pages) : illustrations
Disciplina 621.3
Collana ISO/IEC/IEEE
Soggetto topico Microwave transistors
ISBN 0-7381-6693-6
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Altri titoli varianti 21451-7-2011 - Information technology--Smart transducer interface for sensors and actuators--Part 7
ISO/IEC/IEEE 21451-7:2011(E) (Revision of 1451.7-2010: Information technology--Smart transducer interface for sensors and actuators--Part 7: Transducers to radio frequency identification (RFID) systems communication protocols and transducer electronic da
ISO/IEC/IEEE 21451-7
Record Nr. UNISA-996280983603316
New York, N.Y. : , : IEEE, , 2012
Materiale a stampa
Lo trovi qui: Univ. di Salerno
Opac: Controlla la disponibilità qui
RF and microwave transistor oscillator design [[electronic resource] /] / Andrei Grebennikov
RF and microwave transistor oscillator design [[electronic resource] /] / Andrei Grebennikov
Autore Grebennikov Andrei <1956->
Pubbl/distr/stampa Chichester ; ; Hoboken, N.J., : John Wiley, c2007
Descrizione fisica 1 online resource (457 p.)
Disciplina 621.38133
621.38412
Soggetto topico Microwave transistors
Radio frequency oscillators
Oscillators, Transistor
Soggetto genere / forma Electronic books.
ISBN 1-280-85601-7
9786610856015
0-470-51209-1
1-60119-522-2
0-470-51208-3
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Contents; About the Author; Preface; Acknowledgements; 1 Nonlinear circuit design methods; 1.1 SPECTRAL-DOMAIN ANALYSIS; 1.1.1 Trigonometric identities; 1.1.2 Piecewise-linear approximation; 1.1.3 Bessel functions; 1.2 TIME-DOMAIN ANALYSIS; 1.3 NEWTON-RAPHSON ALGORITHM; 1.4 QUASILINEAR METHOD; 1.5 VAN DER POL METHOD; 1.6 COMPUTER-AIDED ANALYSIS AND DESIGN; REFERENCES; 2 Oscillator operation and design principles; 2.1 STEADY-STATE OPERATION MODE; 2.2 START-UP CONDITIONS; 2.3 OSCILLATOR CONFIGURATIONS AND HISTORICAL ASPECTS; 2.4 SELF-BIAS CONDITION
2.5 OSCILLATOR ANALYSIS USING MATRIX TECHNIQUES2.5.1 Parallel feedback oscillator; 2.5.2 Series feedback oscillator; 2.6 DUAL TRANSISTOR OSCILLATORS; 2.7 TRANSMISSION-LINE OSCILLATOR; 2.8 PUSH-PUSH OSCILLATOR; 2.9 TRIPLE-PUSH OSCILLATOR; 2.10 OSCILLATOR WITH DELAY LINE; REFERENCES; 3 Stability of self-oscillations; 3.1 NEGATIVE-RESISTANCE OSCILLATOR CIRCUITS; 3.2 GENERAL SINGLE-FREQUENCY STABILITY CONDITION; 3.3 SINGLE-RESONANT CIRCUIT OSCILLATORS; 3.3.1 Series resonant circuit oscillator with constant load; 3.3.2 Parallel resonant circuit oscillator with nonlinear load
3.4 DOUBLE-RESONANT CIRCUIT OSCILLATOR3.5 STABILITY OF MULTI-RESONANT CIRCUITS; 3.5.1 General multi-frequency stability criterion; 3.5.2 Two-frequency oscillation mode and its stability; 3.5.3 Single-frequency stability of oscillator with two coupled resonant circuits; 3.5.4 Transistor oscillators with two coupled resonant circuits; 3.6 PHASE PLANE METHOD; 3.6.1 Free-running oscillations in lossless resonant LC circuits; 3.6.2 Oscillations in lossy resonant LC circuits; 3.6.3 Aperiodic process in lossy resonant LC circuits; 3.6.4 Transformer-coupled MOSFET oscillator
3.7 NYQUIST STABILITY CRITERION3.8 START-UP AND STABILITY; REFERENCES; 4 Optimum design and circuit technique; 4.1 EMPIRICAL OPTIMUM DESIGN APPROACH; 4.2 ANALYTIC OPTIMUM DESIGN APPROACH; 4.3 PARALLEL FEEDBACK OSCILLATORS; 4.3.1 Optimum oscillation condition; 4.3.2 Optimum MOSFET oscillator; 4.4 SERIES FEEDBACK BIPOLAR OSCILLATORS; 4.4.1 Optimum oscillation condition; 4.4.2 Optimum common base oscillator; 4.4.3 Quasilinear approach [23]; 4.4.4 Computer-aided design [24]; 4.5 SERIES FEEDBACK MESFET OSCILLATORS; 4.5.1 Optimum common gate oscillator; 4.5.2 Quasilinear approach [15]
4.5.3 Computer-aided design [28]4.6 HIGH-EFFICIENCY DESIGN TECHNIQUE; 4.6.1 Class C operation mode; 4.6.2 Class E power oscillators; 4.6.3 Class DE power oscillators; 4.6.4 Class F mode and harmonic tuning; 4.7 PRACTICAL OSCILLATOR SCHEMATICS; REFERENCES; 5 Noise in oscillators; 5.1 NOISE FIGURE; 5.2 FLICKER NOISE; 5.3 ACTIVE DEVICE NOISE MODELLING; 5.3.1 MOSFET devices; 5.3.2 MESFET devices; 5.3.3 Bipolar transistors; 5.4 OSCILLATOR NOISE SPECTRUM: LINEAR MODEL; 5.4.1 Parallel feedback oscillator; 5.4.2 Negative resistance oscillator; 5.4.3 Colpitts oscillator
5.5 OSCILLATOR NOISE SPECTRUM: NONLINEAR MODEL
Record Nr. UNINA-9910143583803321
Grebennikov Andrei <1956->  
Chichester ; ; Hoboken, N.J., : John Wiley, c2007
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
RF and microwave transistor oscillator design [[electronic resource] /] / Andrei Grebennikov
RF and microwave transistor oscillator design [[electronic resource] /] / Andrei Grebennikov
Autore Grebennikov Andrei <1956->
Pubbl/distr/stampa Chichester ; ; Hoboken, N.J., : John Wiley, c2007
Descrizione fisica 1 online resource (457 p.)
Disciplina 621.38133
621.38412
Soggetto topico Microwave transistors
Radio frequency oscillators
Oscillators, Transistor
ISBN 1-280-85601-7
9786610856015
0-470-51209-1
1-60119-522-2
0-470-51208-3
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Contents; About the Author; Preface; Acknowledgements; 1 Nonlinear circuit design methods; 1.1 SPECTRAL-DOMAIN ANALYSIS; 1.1.1 Trigonometric identities; 1.1.2 Piecewise-linear approximation; 1.1.3 Bessel functions; 1.2 TIME-DOMAIN ANALYSIS; 1.3 NEWTON-RAPHSON ALGORITHM; 1.4 QUASILINEAR METHOD; 1.5 VAN DER POL METHOD; 1.6 COMPUTER-AIDED ANALYSIS AND DESIGN; REFERENCES; 2 Oscillator operation and design principles; 2.1 STEADY-STATE OPERATION MODE; 2.2 START-UP CONDITIONS; 2.3 OSCILLATOR CONFIGURATIONS AND HISTORICAL ASPECTS; 2.4 SELF-BIAS CONDITION
2.5 OSCILLATOR ANALYSIS USING MATRIX TECHNIQUES2.5.1 Parallel feedback oscillator; 2.5.2 Series feedback oscillator; 2.6 DUAL TRANSISTOR OSCILLATORS; 2.7 TRANSMISSION-LINE OSCILLATOR; 2.8 PUSH-PUSH OSCILLATOR; 2.9 TRIPLE-PUSH OSCILLATOR; 2.10 OSCILLATOR WITH DELAY LINE; REFERENCES; 3 Stability of self-oscillations; 3.1 NEGATIVE-RESISTANCE OSCILLATOR CIRCUITS; 3.2 GENERAL SINGLE-FREQUENCY STABILITY CONDITION; 3.3 SINGLE-RESONANT CIRCUIT OSCILLATORS; 3.3.1 Series resonant circuit oscillator with constant load; 3.3.2 Parallel resonant circuit oscillator with nonlinear load
3.4 DOUBLE-RESONANT CIRCUIT OSCILLATOR3.5 STABILITY OF MULTI-RESONANT CIRCUITS; 3.5.1 General multi-frequency stability criterion; 3.5.2 Two-frequency oscillation mode and its stability; 3.5.3 Single-frequency stability of oscillator with two coupled resonant circuits; 3.5.4 Transistor oscillators with two coupled resonant circuits; 3.6 PHASE PLANE METHOD; 3.6.1 Free-running oscillations in lossless resonant LC circuits; 3.6.2 Oscillations in lossy resonant LC circuits; 3.6.3 Aperiodic process in lossy resonant LC circuits; 3.6.4 Transformer-coupled MOSFET oscillator
3.7 NYQUIST STABILITY CRITERION3.8 START-UP AND STABILITY; REFERENCES; 4 Optimum design and circuit technique; 4.1 EMPIRICAL OPTIMUM DESIGN APPROACH; 4.2 ANALYTIC OPTIMUM DESIGN APPROACH; 4.3 PARALLEL FEEDBACK OSCILLATORS; 4.3.1 Optimum oscillation condition; 4.3.2 Optimum MOSFET oscillator; 4.4 SERIES FEEDBACK BIPOLAR OSCILLATORS; 4.4.1 Optimum oscillation condition; 4.4.2 Optimum common base oscillator; 4.4.3 Quasilinear approach [23]; 4.4.4 Computer-aided design [24]; 4.5 SERIES FEEDBACK MESFET OSCILLATORS; 4.5.1 Optimum common gate oscillator; 4.5.2 Quasilinear approach [15]
4.5.3 Computer-aided design [28]4.6 HIGH-EFFICIENCY DESIGN TECHNIQUE; 4.6.1 Class C operation mode; 4.6.2 Class E power oscillators; 4.6.3 Class DE power oscillators; 4.6.4 Class F mode and harmonic tuning; 4.7 PRACTICAL OSCILLATOR SCHEMATICS; REFERENCES; 5 Noise in oscillators; 5.1 NOISE FIGURE; 5.2 FLICKER NOISE; 5.3 ACTIVE DEVICE NOISE MODELLING; 5.3.1 MOSFET devices; 5.3.2 MESFET devices; 5.3.3 Bipolar transistors; 5.4 OSCILLATOR NOISE SPECTRUM: LINEAR MODEL; 5.4.1 Parallel feedback oscillator; 5.4.2 Negative resistance oscillator; 5.4.3 Colpitts oscillator
5.5 OSCILLATOR NOISE SPECTRUM: NONLINEAR MODEL
Record Nr. UNINA-9910830356403321
Grebennikov Andrei <1956->  
Chichester ; ; Hoboken, N.J., : John Wiley, c2007
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
RF and microwave transistor oscillator design [[electronic resource] /] / Andrei Grebennikov
RF and microwave transistor oscillator design [[electronic resource] /] / Andrei Grebennikov
Autore Grebennikov Andrei <1956->
Pubbl/distr/stampa Chichester ; ; Hoboken, N.J., : John Wiley, c2007
Descrizione fisica 1 online resource (457 p.)
Disciplina 621.38133
621.38412
Soggetto topico Microwave transistors
Radio frequency oscillators
Oscillators, Transistor
ISBN 1-280-85601-7
9786610856015
0-470-51209-1
1-60119-522-2
0-470-51208-3
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Contents; About the Author; Preface; Acknowledgements; 1 Nonlinear circuit design methods; 1.1 SPECTRAL-DOMAIN ANALYSIS; 1.1.1 Trigonometric identities; 1.1.2 Piecewise-linear approximation; 1.1.3 Bessel functions; 1.2 TIME-DOMAIN ANALYSIS; 1.3 NEWTON-RAPHSON ALGORITHM; 1.4 QUASILINEAR METHOD; 1.5 VAN DER POL METHOD; 1.6 COMPUTER-AIDED ANALYSIS AND DESIGN; REFERENCES; 2 Oscillator operation and design principles; 2.1 STEADY-STATE OPERATION MODE; 2.2 START-UP CONDITIONS; 2.3 OSCILLATOR CONFIGURATIONS AND HISTORICAL ASPECTS; 2.4 SELF-BIAS CONDITION
2.5 OSCILLATOR ANALYSIS USING MATRIX TECHNIQUES2.5.1 Parallel feedback oscillator; 2.5.2 Series feedback oscillator; 2.6 DUAL TRANSISTOR OSCILLATORS; 2.7 TRANSMISSION-LINE OSCILLATOR; 2.8 PUSH-PUSH OSCILLATOR; 2.9 TRIPLE-PUSH OSCILLATOR; 2.10 OSCILLATOR WITH DELAY LINE; REFERENCES; 3 Stability of self-oscillations; 3.1 NEGATIVE-RESISTANCE OSCILLATOR CIRCUITS; 3.2 GENERAL SINGLE-FREQUENCY STABILITY CONDITION; 3.3 SINGLE-RESONANT CIRCUIT OSCILLATORS; 3.3.1 Series resonant circuit oscillator with constant load; 3.3.2 Parallel resonant circuit oscillator with nonlinear load
3.4 DOUBLE-RESONANT CIRCUIT OSCILLATOR3.5 STABILITY OF MULTI-RESONANT CIRCUITS; 3.5.1 General multi-frequency stability criterion; 3.5.2 Two-frequency oscillation mode and its stability; 3.5.3 Single-frequency stability of oscillator with two coupled resonant circuits; 3.5.4 Transistor oscillators with two coupled resonant circuits; 3.6 PHASE PLANE METHOD; 3.6.1 Free-running oscillations in lossless resonant LC circuits; 3.6.2 Oscillations in lossy resonant LC circuits; 3.6.3 Aperiodic process in lossy resonant LC circuits; 3.6.4 Transformer-coupled MOSFET oscillator
3.7 NYQUIST STABILITY CRITERION3.8 START-UP AND STABILITY; REFERENCES; 4 Optimum design and circuit technique; 4.1 EMPIRICAL OPTIMUM DESIGN APPROACH; 4.2 ANALYTIC OPTIMUM DESIGN APPROACH; 4.3 PARALLEL FEEDBACK OSCILLATORS; 4.3.1 Optimum oscillation condition; 4.3.2 Optimum MOSFET oscillator; 4.4 SERIES FEEDBACK BIPOLAR OSCILLATORS; 4.4.1 Optimum oscillation condition; 4.4.2 Optimum common base oscillator; 4.4.3 Quasilinear approach [23]; 4.4.4 Computer-aided design [24]; 4.5 SERIES FEEDBACK MESFET OSCILLATORS; 4.5.1 Optimum common gate oscillator; 4.5.2 Quasilinear approach [15]
4.5.3 Computer-aided design [28]4.6 HIGH-EFFICIENCY DESIGN TECHNIQUE; 4.6.1 Class C operation mode; 4.6.2 Class E power oscillators; 4.6.3 Class DE power oscillators; 4.6.4 Class F mode and harmonic tuning; 4.7 PRACTICAL OSCILLATOR SCHEMATICS; REFERENCES; 5 Noise in oscillators; 5.1 NOISE FIGURE; 5.2 FLICKER NOISE; 5.3 ACTIVE DEVICE NOISE MODELLING; 5.3.1 MOSFET devices; 5.3.2 MESFET devices; 5.3.3 Bipolar transistors; 5.4 OSCILLATOR NOISE SPECTRUM: LINEAR MODEL; 5.4.1 Parallel feedback oscillator; 5.4.2 Negative resistance oscillator; 5.4.3 Colpitts oscillator
5.5 OSCILLATOR NOISE SPECTRUM: NONLINEAR MODEL
Record Nr. UNINA-9910840511803321
Grebennikov Andrei <1956->  
Chichester ; ; Hoboken, N.J., : John Wiley, c2007
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui