Oscillator circuits : frontiers in design, analysis and applications /

An electronic oscillator is an electronic circuit that produces a periodic (often a sine wave, a square wave, or a pulse trains) or a non-periodic (a double-mode wave or a chaotic wave) oscillating electronic signal. Oscillators convert direct current from a power supply to an alternating current si...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Otros Autores: Nishio, Yoshifumi (Editor )
Formato: Electrónico eBook
Idioma:Inglés
Publicado: London, United Kingdom : The Institution of Engineering and Technology, 2016.
Colección:Materials, circuits and devices series ; 32.
Temas:
Oscillators, Electric.
Electronic circuits.
Electronic circuit design.
Oscillateurs.
Circuits électroniques.
Circuits électroniques > Calcul.
TECHNOLOGY & ENGINEERING > Mechanical.
TECHNOLOGY & ENGINEERING > Electronics > Circuits > General.
Electronic circuit design
Electronic circuits
Oscillators, Electric
bifurcation.
chaos.
coupled circuits.
memristor circuits.
multivibrators.
oscillators.
random number generation.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • 1. Introduction / Yoshifumi Nishio; References; 2. Analysis of bifurcations in oscillatory circuits / Hiroyuki Asahara, Takuji Kousaka and Tetsushi Ueta; 2.1 Introduction; 2.2 Analysis of bifurcations of autonomous systems; 2.2.1 Stability of equilibrium point; 2.2.2 Bifurcation at equilibrium point; 2.2.3 Stability of fixed point; 2.2.4 Bifurcation of fixed point; 2.3 Example of bifurcation analysis applied to an autonomous system; 2.3.1 Single BVP oscillator; 2.3.2 Coupled BVP oscillators; 2.4 Conclusions; Acknowledgments; References.
  • 3. Fractional-order oscillators / Ahmed G. Radwan, Brent J. Maundy and Ahmed S. Elwakil3.1 Fractional-order sinusoidal oscillators; 3.1.1 Fractional-order linear time invariant systems (FLTI); 3.1.2 Stability analysis; 3.1.3 Stability analysis examples; 3.1.4 General theorems of fractional-order LTI systems; 3.2 Fractional-order relaxation oscillators; 3.2.1 The fractional multivibrator; 3.2.2 Verification via simulation and experimentation; 3.2.3 Multivibrator with biological tissues; 3.3 Conclusion; References.
  • 4. Memristive and memcapacitive astable multivibrators / Dongsheng Yu, Herbert Ho-Ching Iu, Tyrone Fernando and Jason Eshraghian4.1 Introduction; 4.2 Circuit schematic of floating memristor emulator; 4.3 Theoretical analysis of memristive astable multivibrator; 4.3.1 Discharging interval; 4.3.2 Charging interval; 4.4 Simulation validation for memristive astable multivibrator; 4.4.1 Testing the memristor emulator; 4.4.2 Observing the oscillation of memristive astable multivibrator; 4.5 Memcapacitor-based astable oscillator circuit.
  • 4.6 Simulation validation for memcapacitive astable multivibrator4.7 Conclusion; References; 5. Piecewise-constant oscillators and their applications / Tadashi Tsubone, Keisuke Suzuki and Takahiro Aoki; 5.1 Basic concept of piecewise-constant oscillations; 5.2 Example 1: a piecewise-constant chaotic spiking oscillator; 5.2.1 Circuit and dynamics; 5.2.2 Embedded return map; 5.3 Example 2: coupled systems of piecewise-constant oscillators; 5.3.1 A piecewise-constant oscillator exhibiting limit cycle; 5.3.2 Coupled system of piecewise-constant oscillators; 5.3.3 Analysis of PWC oscillators.
  • 5.4 ConclusionsReferences; 6. Master-slave synchronization of hysteresis neural-type oscillators / Kenya Jin'no, Takuya Kurihara and Toshimichi Saito; 6.1 Introduction; 6.2 Relaxation oscillator with a time-variant threshold; 6.2.1 Periodic fluctuation threshold; 6.2.2 Period adjustment capability; 6.3 The response to non-periodic external force; 6.3.1 Without external force; 6.3.2 Periodic external force; 6.3.3 Uniform random period external force; 6.4 Conclusions; References; 7. Multimode oscillations in coupled hard oscillators / Kuniyasu Shimizu and Tetsuro Endo; 7.1 Introduction.

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