A phase response curve (PRC) illustrates the transient change (phase response) in the cycle period of an oscillation induced by a perturbation as a function of the phase at which it is received. PRCs are used in various fields; examples of biological oscillations are the heartbeat, circadian rhythms, and the regular, repetitive firing observed in some neurons in the absence of noise. (Wikipedia).
The Step Response | Control Systems in Practice
Check out the other videos in this series: https://www.youtube.com/playlist?list=PLn8PRpmsu08pFBqgd_6Bi7msgkWFKL33b This video covers a few interesting things about the step response. We’ll look at what a step response is and some of the ways it can be used to specify design requirements f
From playlist Control Systems in Practice
Characterizing Filter Phase Response
http://AllSignalProcessing.com for more great signal processing content, including concept/screenshot files, quizzes, MATLAB and data files. Principal value of phase, unwrapped phase, generalized linear phase, and group delay.
From playlist Introduction to Filter Design
(8.1.102) Creating Phase Portraits for Nonlinear Autonomous Systems of ODEs
This video explains how to use an online tool to create a phase portrait or phase diagram for given nonlinear system of differential equation. https://mathispower4u.com
From playlist Differential Equations: Complete Set of Course Videos
Frequency Response Descriptions for LTI Systems
http://AllSignalProcessing.com for free e-book on frequency relationships and more great signal processing content, including concept/screenshot files, quizzes, MATLAB and data files. An introduction to the description of the input output characteristics of linear time-invariant systems b
From playlist Introduction and Background
Transfer Functions, Resonance, and Frequency Response. My Patreon page is at: https://www.patreon.com/EugeneK
From playlist Physics
For more content: https://www.dev-mind.blog/ The wood circles represents the terms in the series. The "size" of the circle is the magnitude of the corresponding coefficient. The initial angle is the phase of the coefficient. Each circle spins with an increasing speed (frequency). In this
From playlist Fourier
Electrical Engineering: Ch 15: Frequency Response (7 of 56) Phase Response in RC Circuit
Visit http://ilectureonline.com for more math and science lectures! In this video I will explain the phase response in a RC circuit using a simple RC circuit with a voltage source where the transfer function is the ratio of the output voltage over the input voltage. http://www.ilectureon
From playlist ELECTRICAL ENGINEERING 15 FREQUENCY RESPONSE
MIT Electronic Feedback Systems (1985) View the complete course: http://ocw.mit.edu/RES6-010S13 Instructor: James K. Roberge License: Creative Commons BY-NC-SA More information at http://ocw.mit.edu/terms More courses at http://ocw.mit.edu
From playlist MIT Electronic Feedback Systems (1985)
Electrical Engineering: Ch 15: Frequency Response (6 of 56) Amplitude vs Phase Response
Visit http://ilectureonline.com for more math and science lectures! In this video we will take a closer look at the difference between amplitude vs phase response using a simple RL circuit with a voltage source. http://www.ilectureonline.com/donate https://www.patreon.com/user?u=3236071
From playlist ELECTRICAL ENGINEERING 15 FREQUENCY RESPONSE
MIT Electronic Feedback Systems (1985) View the complete course: http://ocw.mit.edu/RES6-010S13 Instructor: James K. Roberge License: Creative Commons BY-NC-SA More information at http://ocw.mit.edu/terms More courses at http://ocw.mit.edu
From playlist MIT Electronic Feedback Systems (1985)
Differential Equations: Direction Fields and the Phase Line
Direction fields are useful tools for visualizing the flow of solutions to differential equations. Unfortunately, drawing line segments and calculating their slopes at every point on a grid is painfully slow and boring. There are more efficient ways to sketch direction fields. In this vide
From playlist Differential Equations
Exploration of the Amplitude and Phase: Second Order II Applet
Instructor: Prof. Haynes Miller View the complete course: http://ocw.mit.edu/18-03SCF11 License: Creative Commons BY-NC-SA More information at http://ocw.mit.edu/terms More courses at http://ocw.mit.edu
From playlist MIT 18.03SC Mathlet Videos, Fall 2011
16. Auditory nerve; psychophysics of frequency resolution
MIT 9.04 Sensory Systems, Fall 2013 View the complete course: http://ocw.mit.edu/9-04F13 Instructor: Chris Brown This video covers the auditory nerves and frequency resolution, including tuning and tonotopy, frequency discrimination and phase locking. License: Creative Commons BY-NC-SA M
From playlist MIT 9.04 Sensory Systems, Fall 2013
Gain and Phase Lag | MIT 18.03SC Differential Equations, Fall 2011
Gain and Phase Lag Instructor: David Shirokoff View the complete course: http://ocw.mit.edu/18-03SCF11 License: Creative Commons BY-NC-SA More information at http://ocw.mit.edu/terms More courses at http://ocw.mit.edu
From playlist MIT 18.03SC Differential Equations, Fall 2011
The characterization of dense jammed matter: by Hisao Hayakawa
Program Entropy, Information and Order in Soft Matter  ORGANIZERS Bulbul Chakraborty, Pinaki Chaudhuri, Chandan Dasgupta, Marjolein Dijkstra, Smarajit Karmakar, Vijaykumar Krishnamurthy, Jorge Kurchan, Madan Rao, Srikanth Sastry and Francesco Sciortino DATE & TIME 27 August 2018 to
From playlist Entropy, Information and Order in Soft Matter
EE102: Introduction to Signals & Systems, Lecture 15
These lectures are from the EE102, the Stanford course on signals and systems, taught by Stephen Boyd in the spring quarter of 1999. More information is available at https://web.stanford.edu/~boyd/ee102/
From playlist EE102: Introduction to Signals & Systems
7. Stability via Frequency Response
MIT Electronic Feedback Systems (1985) View the complete course: http://ocw.mit.edu/RES6-010S13 Instructor: James K. Roberge License: Creative Commons BY-NC-SA More information at http://ocw.mit.edu/terms More courses at http://ocw.mit.edu
From playlist MIT Electronic Feedback Systems (1985)
16. Describing Functions (continued)
MIT Electronic Feedback Systems (1985) View the complete course: http://ocw.mit.edu/RES6-010S13 Instructor: James K. Roberge License: Creative Commons BY-NC-SA More information at http://ocw.mit.edu/terms More courses at http://ocw.mit.edu
From playlist MIT Electronic Feedback Systems (1985)
MIT Electronic Feedback Systems (1985) View the complete course: http://ocw.mit.edu/RES6-010S13 Instructor: James K. Roberge License: Creative Commons BY-NC-SA More information at http://ocw.mit.edu/terms More courses at http://ocw.mit.edu
From playlist MIT Electronic Feedback Systems (1985)
Convolution and Unit Impulse Response
The Dirac delta function, the Unit Impulse Response, and Convolution explained intuitively. Also discusses the relationship to the transfer function and the Laplace Transform. Signal Analysis for Linear Systems. My Patreon page is at https://www.patreon.com/EugeneK
From playlist Physics