Difference between revisions of "Frequency Domain Analysis"

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{{Chapter
 
{{Chapter
 
|Chapter number=10
 
|Chapter number=10
 +
|Short name=loopanal
 
|Previous chapter=Transfer Functions
 
|Previous chapter=Transfer Functions
 
|Next chapter=PID Control
 
|Next chapter=PID Control
|Chapter contents=# Basic Control Functions
+
|First edition URL=https://www.cds.caltech.edu/~murray/amwiki/index.php?title=Frequency_Domain_Analysis#Frequently_Asked_Questions
# Simple Controllers for Complex Systems
+
|Chapter summary=In this chapter we study how the stability and robustness of closed loop systems can be determined by investigating how sinusoidal signals of different frequencies propagate around the feedback loop. This technique allows us to reason about the closed loop behavior of a system through the frequency domain properties of the open loop transfer function. The Nyquist stability theorem is a key result that provides a way to analyze stability and introduce measures of degrees of stability.
# PID Tuning
+
|Chapter contents=# The Loop Transfer Function
#* Ziegler--Nichols' Tuning
+
# The Nyquist Criterion
#* Tuning Based on the FOTD Model
+
#* The Nyquist Plot
#* Relay Feedback
+
#* The General Nyquist Criterion
# Integral Windup
+
#* Conditional Stability
#* Avoiding Windup
+
# Stability Margins
#* Manual Control and Tracking
+
# Bode's Relations and Minimum Phase Systems
#* Anti-Windup for General Controllers
+
# Generalized Notions of Gain and Phase
# Implementation
+
#* System Gain and Passivity
#* Filtering the Derivative
+
#* Extensions of the Nyquist Criterion
#* Setpoint Weighting
+
#* Describing Functions
#* Implementation Based on Operational Amplifiers
 
#* Computer Implementation
 
 
# Further Reading
 
# Further Reading
 
:: Exercises
 
:: Exercises
 
}}
 
}}

Latest revision as of 21:34, 28 August 2021

Prev: Transfer Functions Chapter 10 - Frequency Domain Analysis Next: PID Control
Loopanal-firstpage.png

In this chapter we study how the stability and robustness of closed loop systems can be determined by investigating how sinusoidal signals of different frequencies propagate around the feedback loop. This technique allows us to reason about the closed loop behavior of a system through the frequency domain properties of the open loop transfer function. The Nyquist stability theorem is a key result that provides a way to analyze stability and introduce measures of degrees of stability.