other effects in pllsexample of multiplying pll with fm input the input to a multiplying pll is a...
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![Page 1: Other Effects in PLLsExample of Multiplying PLL with FM Input The input to a multiplying PLL is a sinusoid with two small “close-in” FM sidebands, i.e., the modulation frequency](https://reader036.vdocuments.site/reader036/viewer/2022081616/6006ab3c39ab5b0c876908b8/html5/thumbnails/1.jpg)
Other Effects in PLLs
Behzad RazaviElectrical Engineering Department
University of California, Los Angeles
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Example of Up and Down Skew and Width Mismatch
Approximating the pulses on the control line by impulses, determine the magnitude of the resulting sidebands at the output of the VCO.
Sidebands at fc ± n fin are scaled down by a factor of n.
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Circuit Techniques to Deal with Channel Length Modulation: Use of a Servo Loop
A0 need not provide a fast responsePerformance limited by random mismatches between NMOS current sources and between PMOS current sources. Op amp must operate with a nearly rail-to-rail input common-mode range.
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Gate Switching
Voltage headroom savedBut exacerbates the problem of Up and Down arrival mismatch. Op amp must operate with a wide input voltage range.
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Another Example that Cancels Both Random and Deterministic Mismatches
The accuracy of the circuit is ultimately limited by the charge injection and clock feedthrough mismatch between M1 and M5 and between M2 and M6
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Puzzle
Solution:
The phase offset of a CPPLL varies with the output frequency. Explain why.
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Example of Divider Response to FM Sidebands
The control voltage of a VCO experiences a small sinusoidal ripple of amplitude Vm at a frequency equal to ωin. Plot the output spectra of the VCO and the divider.
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Closed-Loop Freq. Response
Solution:
Plot the magnitude of the closed-loop transfer function as a function of ω if ζ = 1
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Example of Multiplying PLL with FM Input
The input to a multiplying PLL is a sinusoid with two small “close-in” FM sidebands, i.e., the modulation frequency is relatively low. Determine the output spectrum of the PLL.
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Example of Topology to Reject Supply Noise
Solution:
Consider the two filter/VCO topologies shown in figure below and explain which one is preferable with respect to supply noise.
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Alternative Second-Order Loop Filter
The ripple at node X may be large but it is suppressed as it travels through the low-pass filter consisting of R2 and C2
(R2C2)-1 must remain 5 to 10 times higher than ωz so as to yield a reasonable phase margin.
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Puzzle
Solution:
A PLL having a reference frequency of fREF and a divide ratio of N exhibits reference sidebands at the output that are 60 dB below the carrier. If the reference frequency is doubled and the divide ratio is halved (so that the output frequency is unchanged), what happens to the reference sidebands? Assume the CP nonidealities are constant and the time during which the CP is on remains much shorter than TREF = 1/fREF .
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Phase Noise in PLLs: VCO Phase Noise
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Another Example of VCO Phase Noise(Ⅰ)
Consider a PLL with a feedback divide ratio of N. Compare the phase noise behavior of this case with that of a dividerless loop. Assume the output frequency is unchanged.Redrawing the loop above as shown below on the left, we recognize that the feedback is now weaker by a factor of N. The transfer function still applies, but both ζ and ωn are reduced by a factor of .
What happens to the magnitude plot? We make two observations. (1) To maintain the same transient behavior, ζ must be constant; e.g., the charge pump current must be scaled up by a factor of N. Thus, the poles given by previous equation simply decrease by factor of . (2)For s → 0, Φout/ΦVCO ≈ s2/ωn
2, which is a factor of N higher than that of the dividerless loop. The magnitude of the transfer function thus appears as depicted below on the right.
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Time-Domain Perspective
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VCO Phase Noise: White Noise and Flicker Noise
low offset frequencies high offset frequencies
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Shaped VCO Noise Summary
The overall PLL output phase noise is equal to the sum of SA and SB
The actual shape depends on two factors: (1) the intersection frequency of α/ω3 and β/ω2
(2) the value of ωn
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Reference Phase Noise: the Overall Behavior
Crystal oscillators providing the reference typically display a flat phase noise profile beyond an offset of a few kilohertz
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Reference Phase Noise: Two Observations
PLLs performing frequency multiplication “amplify” the low-frequency reference phase noise proportionally.The total phase noise at the output increases with the loop bandwidth
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Loop Bandwidth