Question 10 CEL01 - Chief Engineer - Limited

The Correct Answer is B **Explanation for Option B (Correct Answer):** The proportional mode of control (P-control) is defined by a control action that is directly proportional to the current error (the difference between the desired Setpoint, SP, and the measured Process Variable, PV). Mathematically, the output of the proportional controller ($P_{out}$) is given by: $$P_{out} = K_p \times e(t) + P_{bias}$$ Where: * $e(t)$ is the error at time $t$. * $K_p$ is the proportional gain. * $P_{bias}$ is the controller output when the error is zero (often the output needed to maintain the process at the setpoint). This relationship confirms that the control action (the signal sent to the final control element, like a valve) scales linearly with the magnitude of the error. **Explanation for Incorrect Options:** **A) It is a control mode that produces a control action that is proportional to the accumulation of error over time.** This description defines the **Integral mode of control (I-control)**. Integral action accumulates the error over time to eliminate steady-state offset (error that remains after the process has stabilized). **C) It is a control mode that produces a control action that is proportional to the gain.** Gain ($K_p$) is a fixed or tuned parameter within the controller equation, not the variable the control action is proportional to. The control action is proportional to the *error*, and the *gain* is the constant of proportionality that determines how aggressively the controller responds to that error. **D) It is a control mode that produces a control action that is proportional to the rate at which the error is changing.** This description defines the **Derivative mode of control (D-control)**. Derivative action looks at the slope of the error curve (how fast the error is increasing or decreasing) to anticipate future error and dampen oscillations, thereby providing a braking effect.