Which controller switches abruptly between two states with hysteresis to avoid high-frequency switching?

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Study for the Instrumentation Controls Lab Exam. Use flashcards and multiple-choice questions, each with hints and explanations. Prepare efficiently and perform confidently on your upcoming test.

Multiple Choice

Which controller switches abruptly between two states with hysteresis to avoid high-frequency switching?

Explanation:
This question tests bang-bang control with hysteresis, where the actuator flips between two extreme states to keep the process value within a band and avoid rapid relay switching. In this approach, two thresholds are set: when the measured variable falls below the lower limit, the actuator turns fully on; when it rises above the upper limit, it turns fully off. The gap between these thresholds—the hysteresis band—means small fluctuations near the setpoint don’t cause constant on-off cycling, reducing high-frequency switching. This is why it’s the best fit here: the output is not a continuous scale but two discrete states, chosen specifically to prevent rapid switching that could wear relays or cause instability. Proportional, integral, and derivative controllers modulate the output in a continuous range based on error (and its history or rate of change), which can still produce chattering or smoother control rather than abrupt two-state behavior.

This question tests bang-bang control with hysteresis, where the actuator flips between two extreme states to keep the process value within a band and avoid rapid relay switching. In this approach, two thresholds are set: when the measured variable falls below the lower limit, the actuator turns fully on; when it rises above the upper limit, it turns fully off. The gap between these thresholds—the hysteresis band—means small fluctuations near the setpoint don’t cause constant on-off cycling, reducing high-frequency switching.

This is why it’s the best fit here: the output is not a continuous scale but two discrete states, chosen specifically to prevent rapid switching that could wear relays or cause instability. Proportional, integral, and derivative controllers modulate the output in a continuous range based on error (and its history or rate of change), which can still produce chattering or smoother control rather than abrupt two-state behavior.

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