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Showing below up to 78 results in range #1 to #78.
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- (hist) 30 Oct 2020: Notes on Linear Systems Theory updated (release 0.2.2) [186 bytes]
- (hist) Supplement: Networked Control Systems [192 bytes]
- (hist) 12 Mar 2023: A new version of the Optimization-Based Control (OBC) supplement is now complete and posted [200 bytes]
- (hist) 24 Jul 2020: Copyedited version of FBS2e now available for download [201 bytes]
- (hist) Figure 4.2: Torque curves for typical car engine [202 bytes]
- (hist) Question: What is "closed form"? [203 bytes]
- (hist) Figure 4.3: Car with cruise control encountering a sloping road [217 bytes]
- (hist) FBS release 3.1.5 [218 bytes]
- (hist) Errata: 'a' in equation (14.13) should be 's' [232 bytes]
- (hist) Question: In the predator prey example, where is the fox birth rate term? [269 bytes]
- (hist) 28 Aug 2021: Links to first edition supplemental information added to chapter pages [286 bytes]
- (hist) Question: Why isn't there a term for the rabbit death rate besides being killed by the foxes? [290 bytes]
- (hist) LST release 0.2.2 [291 bytes]
- (hist) Question: How can we tell from the phase plots if the system is oscillating? [521 bytes]
- (hist) OBC: Archived news [637 bytes]
- (hist) Question: What is a stochastic system? [649 bytes]
- (hist) Domitilla Del Vecchio [778 bytes]
- (hist) Question: What is the definition of a system? [819 bytes]
- (hist) Question: Can a control system include a human operator as a component [859 bytes]
- (hist) Fbs.py [918 bytes]
- (hist) Question: How can I go from a continuous time linear ODE to a discrete time representation? [956 bytes]
- (hist) Question: Why does the effective service rate f(x) go to zero when x = 0 in the example on queuing systems? [1,048 bytes]
- (hist) Examples [1,049 bytes]
- (hist) Frequency Domain Analysis [1,129 bytes]
- (hist) Main Page [1,147 bytes]
- (hist) Lecture: Introduction to Feedback and Control (Caltech, Fall 2008) [1,174 bytes]
- (hist) Frequency Domain Design [1,200 bytes]
- (hist) Question: How are stability, performance and robustness different? [1,210 bytes]
- (hist) Transfer Functions [1,240 bytes]
- (hist) PID Control [1,268 bytes]
- (hist) Fundamental Limits [1,306 bytes]
- (hist) Question: How do you know when your model is sufficiently complex? [1,436 bytes]
- (hist) Exercise: Popular articles about control [1,456 bytes]
- (hist) Robust Performance [1,507 bytes]
- (hist) Figure 5.1: Response of a damped oscillator [1,615 bytes]
- (hist) Architecture and System Design [1,651 bytes]
- (hist) Karl J. Åström [1,725 bytes]
- (hist) Feedback Principles [1,752 bytes]
- (hist) Figure 4.12: Internet congestion control [1,774 bytes]
- (hist) Question: What is the advantage of having a model? [1,898 bytes]
- (hist) Question: What is a state? How does one determine what is a state and what is not? [1,935 bytes]
- (hist) Bibliography [1,980 bytes]
- (hist) Errata: Example 8.10 missing factor of v, a1 and a2 flipped [2,002 bytes]
- (hist) Admin [2,061 bytes]
- (hist) Supplement: Linear Systems Theory [2,095 bytes]
- (hist) Figure 3.24: Consensus protocols for sensor networks [2,126 bytes]
- (hist) Figure 3.8: Discrete-time simulation of the predator–prey model [2,317 bytes]
- (hist) Figure 3.28: Response of a neuron to a current input [2,319 bytes]
- (hist) Figure 3.4: Input/output response of a linear system [2,462 bytes]
- (hist) Exercise: Exploring the dynamics of a rolling mill [2,755 bytes]
- (hist) Biomolecular Feedback Systems [2,836 bytes]
- (hist) Figure 4.20: Simulation of the predator-prey system [2,931 bytes]
- (hist) Software [2,940 bytes]
- (hist) Figure 2.12: Responses of a static nonlinear system [2,966 bytes]
- (hist) Figure 2.11: Response to a step change in the reference signal for a system with a PI controller having two degrees of freedom [3,006 bytes]
- (hist) Figure 4.13: Internet congestion control for N identical sources across a single link [3,107 bytes]
- (hist) Figure 3.2: Illustration of a state model [3,118 bytes]
- (hist) Figure 1.11: A feedback system for controlling the velocity of a vehicle [3,185 bytes]
- (hist) Figure 2.8: Step responses for a first-order, closed loop system with proportional and PI control [3,197 bytes]
- (hist) Figure 2.9: Responses to a unit step change in the reference signal for different values of the design parameters [3,218 bytes]
- (hist) Figure 3.11: Simulation of the forced spring–mass system with different simulation time constants [3,330 bytes]
- (hist) Figure 3.22: Queuing dynamics [3,440 bytes]
- (hist) Figure 2.14: Responses of the systems with integral feedback [3,661 bytes]
- (hist) Supplement: Optimization-Based Control [3,665 bytes]
- (hist) Figure 1.18: Air–fuel controller based on selectors [3,872 bytes]
- (hist) Introduction [4,022 bytes]
- (hist) Figure 3.12: Frequency response computed by measuring the response of individual sinusoids [4,329 bytes]
- (hist) System Modeling [4,670 bytes]
- (hist) Figure 2.19: System with positive feedback and saturation [4,898 bytes]
- (hist) Figure 3.26: The repressilator genetic regulatory network [5,157 bytes]
- (hist) Feedback Systems: An Introduction for Scientists and Engineers [5,378 bytes]
- (hist) State Feedback [5,394 bytes]
- (hist) Output Feedback [5,459 bytes]
- (hist) Linear Systems [6,134 bytes]
- (hist) Figure 8.13: Vehicle steering using gain scheduling [6,583 bytes]
- (hist) Dynamic Behavior [7,224 bytes]
- (hist) Preface [14,279 bytes]
- (hist) Cruise control [37,378 bytes]