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GATE EC 2010 Official Paper

Option 4 : \(G_e(s) = 1+ \dfrac{2}{s} + 3s\)

__Concept:__

The steady-state error for the second-order system when the input is unit step is defined as:

\(e_{ss}=\dfrac{1}{1+k_p}\)

Where the positional error constant is:

\(\mathop {\lim }\limits_{s \to 0} G\left( s \right)H\left( s \right) = {k_p}\)

G(s): Forward path gain

H(s): Feedback gain

To have the less steady-state error the positional error constant must be high.

__Calculation:__

Check the options and whichever gives the high K_{p} that is the answer for less error.

Forward gain = G(s) × G_{C}(s)

Feedback gain = H(s) = 1

**Option 1:**

\(\mathop {\lim }\limits_{s \to 0} \dfrac{1}{s^2+2s+2}\dfrac{s+1}{s+2} \\= {k_p}=\frac{1}{4}\)

**Option 2:**

\(\mathop {\lim }\limits_{s \to 0} \dfrac{1}{s^2+2s+2}\dfrac{s+2}{s+1} \\= {k_p}=1\)

**Option 3:**

**\(\mathop {\lim }\limits_{s \to 0} \dfrac{1}{s^2+2s+2}\dfrac{(s+1)(s+4)}{(s+2)(s+3)} \\= {k_p}=\dfrac{2}{6}\)**

**Option 4:**

\(\mathop {\lim }\limits_{s \to 0} \dfrac{1}{s^2+2s+2}{\left(1+\dfrac{2}{s}+3s\right)} \\= {k_p}=\infty\)

If we select controller 4 then the steady-state error will be less.

**e _{ss} = 0**