GATE ECE 1994 | Stability Question 33 | Control Systems

GATE ECE 1994

True or False

-0

If G(s) is a stable transfer function, then $$F\left(s\right)=\frac1{G\left(s\right)}$$ is always a stable transfer function.

TRUE

FALSE

GATE ECE 1993

MCQ (Single Correct Answer)

-0.6

If $$s^3+\;3s^2\;+\;4s\;+A\;=\;0$$ ,then all the roots of this equation are in the left half plane provided that

A > 12

-3 < A < 4

0 < A < 12

5 < A < 12

GATE ECE 1990

MCQ (Single Correct Answer)

-0.6

An electromechanical closed-loop control system has the following characteristic equation $$s^3+6Ks^2+\left(K+2\right)s+8\;=\;0$$, where K is the forward gain of the system.The condition for closed loop stability is

K = 0.528

K = 2

K = 0

K = -2.258

GATE ECE 1989

MCQ (Single Correct Answer)

-0.6

In order to stabilize the system shown in fig. T_i should satisfy: GATE ECE 1989 Control Systems - Stability Question 17 English

$${\mathrm T}_\mathrm i=-\mathrm T$$

$${\mathrm T}_\mathrm i=\mathrm T.$$

$${\mathrm T}_\mathrm i<\mathrm T.$$

$${\mathrm T}_\mathrm i>\mathrm T.$$

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Network Theory

State Equations For Networks Network Elements Network Theorems Two Port Networks Transient Response Sinusoidal Steady State Response Network Graphs Miscellaneous

Control Systems

Basic of Control Systems Signal Flow Graph and Block Diagram Time Response Analysis Stability Root Locus Diagram Frequency Response Analysis Compensators State Space Analysis

Electronic Devices and VLSI

Semiconductor Physics PN Junction BJT and FET IC Basics and MOSFET

Analog Circuits

Bipolar Junction Transistor FET and MOSFET Oscillators Operational Amplifier 555 Timer Frequency Response Diodes Feedback Amplifier Power Amplifier

Digital Circuits

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Microprocessors

Instruction Set and Programming with 8085 Pin Details of 8085 and Interfacing with 8085

Signals and Systems

Representation of Continuous Time Signal Fourier Series Discrete Time Signal Fourier Series Fourier Transform Discrete Time Signal Z Transform Continuous Time Linear Invariant System Transmission of Signal Through Continuous Time LTI Systems Discrete Time Linear Time Invariant Systems Sampling Continuous Time Signal Laplace Transform Discrete Fourier Transform and Fast Fourier Transform Transmission of Signal Through Discrete Time Lti Systems Miscellaneous Fourier Transform

Communications

Analog Communication Systems Digital Communication Systems Random Signals and Noise Fundamentals of Information Theory Noise In Digital Communication

Electromagnetics

Waveguides Antennas Miscellaneous Transmission Lines Maxwell Equations Uniform Plane Waves

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