Oscillators and Oscillator Systems: Classification, Analysis and SynthesisSpringer Science & Business Media, 2013年4月17日 - 282页 In many electronic systems, such as telecommunication or measurement systems, oscillations play an essential role in the information processing. Each electronic system poses different requirements on these oscillations, depending on the type and performance level of that specific system. It is the designer's challenge to find the specifications for the desired oscillation and to implement an electronic circuit meeting these specifications. As the desired oscillations have to fulfill many requirements, the design process can become very complex. To find an optimal solution, the designer requires a design methodology that is preferably completely top-down oriented. To achieve such a methodology, it must be assured that each property of the system can be optimized independently of all other properties. Oscillators and Oscillator Systems: Classification, Analysis and Synthesis takes a systematic approach to the design of high-performance oscillators and oscillator systems. A fundamental classification of oscillators, based on their internal timing references, forms the basis of this approach. The classification enables the designer to make strategic design decisions at a high hierarchical level of the design process. Techniques, derived from the systematic approach, are supplied to the designer to enable him or her to bring the performance of the system as close as possible to the fundamental limits. Oscillators and Oscillator Systems: Classification, Analysis and Synthesis is an excellent reference for researchers and circuit designers, and may be used as a text for advanced courses on the topic. |
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active tuning amplifier amplitude modulation capacitor capture ranges carrier Chapter class of oscillators complex-pole timing reference correlated noise coupled oscillator coupled system crosstalk crystal oscillators current noise damping-control delay line depicted in figure duty cycle Electronics energy flow equal equation example filter first-order oscillator function harmonic oscillators high-performance imaginary axis implementation inductor influence input integrated constant integration/surge integrator output linear loop gain modulation negative feedback negative resistance noise behavior noise component noise measure noise performance noise sources noise voltage non-linear orthogonality oscilla oscillation frequency oscillator system output signal parallel resonance phase noise phase relation phase-locked loop pole pattern previous section quadrature relation quality factor real-pole one-zero relaxation oscillators resonance mode resonant frequency resonator oscillator root locus second-order complex-pole second-order oscillators second-order real-pole no-zero seen series resonator specific synchronization theorem threshold transfer transition tunable tuning circuit tuning method tuning range voltage noise zeroes ωο