Compute and plot the response of a state-space ( ss ) model to specified initial state values using initial .
Revisit the optimal ITAE transfer function for step input using numerical optimization and digital computer.
Passive control is often part of the safety requirements in applications such as process control, tele-operation, human-machine interfaces, and system networks. A system is passive if it
In its simplest form, a conic sector is the 2-D region delimited by two lines, y=au and y=bu .
Obtain a step-response plot and step-response data for a discrete-time dynamic system model. Obtaining time-domain responses of discrete-time models is the same as for continuous-time
Obtain numeric values of step response characteristics such as rise time, settling time, and overshoot using stepinfo . You can use similar techniques with lsiminfo to obtain
Obtain step and impulse response data, as well as step and impulse response plots, from a dynamic system model.
Examine the pole and zero locations of dynamic systems both graphically using pzplot and numerically using pole and zero .
Plot the frequency response and obtain frequency response data for a single-input, single-output (SISO) dynamic system model.
Obtain numeric values of several frequency-domain characteristics of a SISO dynamic system model, including the peak gain, dc gain, system bandwidth, and the frequencies at which the
Examine the frequency response of a multi-input, multi-output (MIMO) system in two ways: by computing the frequency response, and by computing the singular values.
Illustrates the properties of a series interconnection of passive systems.
Obtain impulse response data and plots for a multi-input, multi-output (MIMO) model using impulse . You can use the same techniques to obtain other types of time-domain responses of MIMO
Examine the sensitivity of a closed-loop control system to time delays within the system.