For the first-order transfer function G(s) = K/(τs+1), what is the steady-state gain and what does τ represent?

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Study for the Instrumentation Controls Lab Exam (EE2327L) with flashcards and multiple choice questions. Each question includes hints and explanations to help you prepare effectively for your exam.

Multiple Choice

For the first-order transfer function G(s) = K/(τs+1), what is the steady-state gain and what does τ represent?

Explanation:
In a first-order system, the long-term (steady-state) response to a constant input is determined by the DC gain, which is G(0). For G(s) = K/(τs+1), G(0) = K, so the steady-state gain is K—the output scales with the input by that factor regardless of τ. The parameter τ is the time constant. It sets how fast the system responds: the step response is y(t) = K[1 − e^(−t/τ)], so after a time equal to τ, the output has reached about 63% of its final value. The pole sits at s = −1/τ, so larger τ means a slower response. It doesn’t represent damping or frequency, which belong to different concepts.

In a first-order system, the long-term (steady-state) response to a constant input is determined by the DC gain, which is G(0). For G(s) = K/(τs+1), G(0) = K, so the steady-state gain is K—the output scales with the input by that factor regardless of τ.

The parameter τ is the time constant. It sets how fast the system responds: the step response is y(t) = K[1 − e^(−t/τ)], so after a time equal to τ, the output has reached about 63% of its final value. The pole sits at s = −1/τ, so larger τ means a slower response. It doesn’t represent damping or frequency, which belong to different concepts.

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