Frequency Acquisition Techniques for Phase Locked Loops - by Daniel B Talbot (Hardcover)

Book Synopsis

How to acquire the input frequency from an unlocked state

A phase locked loop (PLL) by itself cannot become useful until it has acquired the applied signal's frequency. Often, a PLL will never reach frequency acquisition (capture) without explicit assistive circuits. Curiously, few books on PLLs treat the topic of frequency acquisition in any depth or detail. Frequency Acquisition Techniques for Phase Locked Loops offers a no-nonsense treatment that is equally useful for engineers, technicians, and managers.

Since mathematical rigor for its own sake can degenerate into intellectual "rigor mortis," the author introduces readers to the basics and delivers useful information with clear language and minimal mathematics. With most of the approaches having been developed through years of experience, this completely practical guide explores methods for achieving the locked state in a variety of conditions as it examines:

• Performance limitations of phase/frequency detector-based phase locked loops
• The quadricorrelator method for both continuous and sampled modes
• Sawtooth ramp-and-sample phase detector and how its waveform contains frequency error information that can be extracted
• The benefits of a self-sweeping, self-extinguishing topology
• Sweep methods using quadrature mixer-based lock detection
• The use of digital implementations versus analog

Frequency Acquisition Techniques for Phase Locked Loops is an important resource for RF/microwave engineers, in particular, circuit designers; practicing electronics engineers involved in frequency synthesis, phase locked loops, carrier or clock recovery loops, radio-frequency integrated circuit design, and aerospace electronics; and managers wanting to understand the technology of phase locked loops and frequency acquisition assistance techniques or jitter attenuating loops.
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From the Back Cover

How to acquire the input frequency from an unlocked state

A phase locked loop (PLL) by itself cannot become useful until it has acquired the applied signal's frequency. Often, a PLL will never reach frequency acquisition (capture) without explicit assistive circuits. Curiously, few books on PLLs treat the topic of frequency acquisition in any depth or detail. Frequency Acquisition Techniques for Phase Locked Loops offers a no-nonsense treatment that is equally useful for engineers, technicians, and managers.

Since mathematical rigor for its own sake can degenerate into intellectual "rigor mortis," the author introduces readers to the basics and delivers useful information with clear language and minimal mathematics. With most of the approaches having been developed through years of experience, this completely practical guide explores methods for achieving the locked state in a variety of conditions as it examines:

• Performance limitations of phase/frequency detector-based phase locked loops
• The quadricorrelator method for both continuous and sampled modes
• Sawtooth ramp-and-sample phase detector and how its waveform contains frequency error information that can be extracted
• The benefits of a self-sweeping, self-extinguishing topology
• Sweep methods using quadrature mixer-based lock detection
• The use of digital implementations versus analog

Frequency Acquisition Techniques for Phase Locked Loops is an important resource for RF/microwave engineers, in particular, circuit designers; practicing electronics engineers involved in frequency synthesis, phase locked loops, carrier or clock recovery loops, radio-frequency integrated circuit design, and aerospace electronics; and managers wanting to understand the technology of phase locked loops and frequency acquisition assistance techniques or jitter attenuating loops.

Review Quotes

"Frequency Acquisition Techniques for Phase Locked Loops is an good resource for RF/microwave engineers, in particular, circuit designers; practicing electronics engineers involved in frequency synthesis, phase locked loops, carrier or clock recovery loops, radio-frequency integrated circuit design, and aerospace electronics; and managers wanting to understand the technology of phase locked loops and frequency acquisition assistance techniques or jitter attenuating loops." (Microwave Journal, 1 April 2013)

About the Author

DANIEL B. TALBOT currently runs a product development business specializing in RF/analog engineering. He has years of industry experience as a chief technical engineer at DBX Corporation, LTX Corporation, and a principal or research engineer or equivalent at Raytheon, RCA David Sarnoff Labs, General Instrument, and several other aerospace and commercial electronics firms; has been granted eight U.S. patents in the field of RF/analog/fiber optic engineering; and is an elected Fellow of the Audio Engineering Society and a Life Member of the IEEE.