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MAYURBHANJ SCHOOL OF ENGINEERING�ELECTRICAL ENGINEERING DEPARTMENT

6^TH Semester

Control System Engineering

Unit – 7

FREQUENCY RESPONSE OF SYSTEM

By

Er.Gurupada Mishra

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CORRELATION BETWEEN TIME RESPONSE AND FREQUENCY RESPONSE

For unit step system,

The magnitude of G(jω) becomes unity when

Phase margin is

Phase margin and damping ratio are correlated.

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POLAR PLOTS

Polar plot is the plot of magnitude of sinusoidal transfer function versus the phase angle.

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POLAR PLOTS

To draw polar plot

ω increases, M decreases, φ increases negatively

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POLAR PLOTS

The polar plot starts at a particular value when ω = 0 and ends at 0 when ω → ∞.
The shape of polar plot depends on damping ration ( ).

(

).

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POLAR PLOTS

The intersection point on negative imaginary axis is nothing but the undamped natural frequency ω_n.
For high damping ratio, the plot is closer to the real axis.
The plot tends to become semicircle for overdamped system. Advantage It incorporates entire frequency range in the same plot. Disadvantage It does not clearly indicates the contribution of individual factors.
Integral and derivative factor : → The polar plot G(jω) = 1/jω is the negative imaginary axis.

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BODE PLOTS

The Bode plot for a linear time-invarient system with transfer function H(s) consists of a magnitude plot and a phase plot.
The Bode magnitude plot is the graph of the function

of frequency . The axis of the magnitude plot is logarithmic and the magnitude is given in decibels, i.e., a value for the magnitude |H| is plotted on the axis at

The Bode phase plot is the graph of the phase, commonly expressed in degrees, of the transfer function as a function of .The phase is plotted on the same logarithmic - axis as the magnitude plot, but the value for the phase is plotted on a linear vertical axis.

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BODE PLOTS

The Bode plot or the Bode diagram consists of two plots

Magnitude plot
Phase plot

The magnitude of the open loop transfer function in dB is

The phase angle of the open loop transfer function in degrees is

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BODE PLOTS

The following table shows the slope, magnitude and the phase angle values of the terms present in the open loop transfer function.

Type of term	G(jω)H(jω)	Slope(dB/dec)	Magnitude (dB)	Phase angle(degrees)
Constant	K	0		0
Zero at origin		20		90
‘n’ zeros at origin
Pole at origin				or 270
‘n’ poles at origin				or
Simple zero		20
Simple pole
Second order derivative term		40
Second order integral term

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Rules for Construction of Bode Plots

Represent the open loop transfer function in the standard time constant form.
Substitute, in the above equation.
Find the corner frequencies and arrange them in ascending order.
Consider the starting frequency of the Bode plot as 1/10^th of the minimum corner frequency or 0.1 rad/sec whichever is smaller value and draw the Bode plot up to 10 times maximum corner frequency.
Draw the magnitude plots for each term and combine these plots properly.
Draw the phase plots for each term and combine these plots properly.

Note − The corner frequency is the frequency at which there is a change in the slope of the magnitude plot.

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Phase Cross over Frequency & Gain Margin

The frequency at which the phase plot is having the phase of -180⁰ is known as phase cross over frequency. It is denoted by . The unit of phase cross over frequency is rad/sec.
Gain margin GM is equal to negative of the magnitude in dB at phase cross over frequency.

Where, is the magnitude at

phase cross over frequency.

The unit of gain margin (GM)

is dB.

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GAIN CROSS OVER FREQUENCY & PHASE MARGIN

Gain cross over frequency is the frequency at which the magnitude of the G(s)H(s) becomes 1.

Phase margin is the phase that can be varied before the system becomes just stable (i.e., after varying the phase up to a certain threshold, the system becomes marginally stable and then further variation of phase leads to instability). Phase margin occurs at Gain Cross over frequency.

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STABILITY OF CONTROL SYSTEM

If phase margin and Gain margin both are positive, the system is stable.
If phase margin and Gain margin both are negative, the system is unstable.

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Performance Specification in Frequency

Transfer function of the second order closed loop control system

where

Magnitude of T(jω) is ,

Phase of T(jω) is,

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Performance Specification in Frequency

Resonant Frequency: It is the frequency at which the magnitude of the frequency response has peak value for the first time.

Resonant Peak: It is the maximum value of the magnitude of T(jω).

Resonant peak in frequency response corresponds to the peak overshoot in the time domain transient response for certain values of damping ratio δ. So, the resonant peak and peak overshoot are correlated to each other.

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Performance Specification in Frequency

Bandwidth: It is the range of frequencies over which, the magnitude of T(jω) drops to 70.7% from its zero frequency value.

At

At 3-dB frequency, the magnitude of T(jω) will be 70.7% of magnitude of T(jω) at ω = 0.

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Thank You