Power dissipation vs. resistor ratings: A 33 Ω 0.5 W resistor and a 330 Ω 0.5 W resistor are each connected across a 12 V source (parallel branches). Which resistor(s) will overheat based on power dissipation?
Electrical Engineering
Energy and Power
Difficulty: Easy
Choose an option
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A33 Ω
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B330 Ω
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Cboth resistors
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Dneither resistor
Answer
Correct Answer: 33 Ω
Explanation
Introduction / Context:Selecting safe resistor power ratings prevents failures and fire hazards. This problem reinforces the calculation of power from a fixed voltage across resistors and comparison with nameplate ratings.
Given Data / Assumptions:
- Two separate resistors are each placed directly across 12 V.
- Ratings: 0.5 W (half-watt) each.
- Resistances: 33 Ω and 330 Ω.
Concept / Approach:With a known voltage across a resistor, use P = V^2 / R to compute dissipation. If the computed power exceeds the rated wattage, the part is likely to overheat in continuous service.
Step-by-Step Solution:
For 33 Ω: P = 12^2 / 33 = 144 / 33 ≈ 4.36 W >> 0.5 W → overheats.For 330 Ω: P = 144 / 330 ≈ 0.436 W < 0.5 W → within rating.Conclusion: Only the 33 Ω resistor overheats.Verification / Alternative check:Check current for 33 Ω: I = V / R = 12 / 33 ≈ 0.364 A; P = V * I ≈ 12 * 0.364 ≈ 4.37 W. Consistent with the V^2 / R result.
Why Other Options Are Wrong:
- 330 Ω: Calculated power is below 0.5 W.
- Both resistors / neither resistor: Contradicted by the computed values.
Common Pitfalls:
- Forgetting that resistors in separate branches each experience the source voltage.
- Using P = I^2 * R without first finding I correctly.
Final Answer:33 Ω