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This article explores the synchronization of timing and carrier signals in digital modems using band edge filters. It discusses the importance of timing accuracy and presents various techniques for achieving synchronization. The article also covers the concept of phase offset and its correction using PLLs and frequency matched filters. Additionally, it explains the use of band edge filters in frequency locked loops and provides insights into eye diagrams and spectral analysis.
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Timing Synchronization with Band Edge Filters fred harris 11-15 September, 2017
Timing and Carrier Synchronization of Digital Modems
Timing and Carrier Synchronization of Digital Modems Momma’s Middle name is Synchronizer
Find Peak of Correlation Function Filter can’t answer the question: “Am I standing at the highest level?” She can only see the level where you are standing. A Better question to ask. and one she can answer is: “What’s the slope where I am standing?” Zero Slope Negative Slope Positive Slope f<fopt f=fopt f>fopt
Maximizing Output of Correlation Receiver Same as Seeking Zero Derivative
To Determine Which Direction is the Peak of the Correlator, Qualify the Derivative with Polarity of the Correlator Output
Slide Sampler to Input and Perform Timing Offset with Polyphase Digital Filter
We can do the same for phase offsetswith a system that measures phase errors and adjusts a VCO to move the phase angle error towards 0. What is one to do when the phase offset is changing faster than the PLL can correct? You change loops to measure frequency offset and adjust VCO to move frequency error towards 0.
Frequency Matched Filter Matched Filter Output Times Derivative Matched Filter Output
Time and Frequency Response, Matched Filter and Frequency Derivative Matched Filter
Frequency Matched FilterNon Data Aided Frequency Acquisition
Frequency Locked Loop with Band Edge Filters Maximum Likelihood Minimum Variance
Spectra of Signals From Band Edges Combined to form Two New Signals
Conjugate Product of Sum and Difference Band Edge Filters Imaginary Part, Sinusoid at Symbol Frequency. Phase Related to Time offset between Samples and Signal. Real Part DC Proportional to Energy Difference
Eye Diagrams of Matched Filter, Band-Edge Filter Sum, Difference, and Product
Eye Diagrams of Matched Filter, Band-Edge Filter Sum, Difference, and Product with Timing Offset
Spectra of SQRT Nyquist Shaped Modulation Signals over Range of Excess BW
Cyclostationary Mean and Variance Eye Diagrams Magnitude Matched Filter Output
Spectral Lines from Excess BW: MF(t) x dMF(t)* Modulation Noise
Cyclostationary Mean and Variance Eye Diagrams Magnitude Band Edge Difference Filter
Spectra of BEsum(t) x BEdiff(t)* No Modulation Noise)