College Physics
7th Edition
ISBN: 9780321601834
Author: Jerry D. Wilson, Anthony J. Buffa, Bo Lou
Publisher: Addison-Wesley
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Textbook Question
Chapter 17, Problem 1MCQ
When a battery with a significant internal resistance is part of a complete circuit, the voltage across its terminals is its (a) emf, (b) terminal voltage, (c) power output, (d) all of the preceding.
Expert Solution & Answer
To determine
The voltage across the battery with internal resistance.
Answer to Problem 1MCQ
The voltage across the battery with internal resistance is
Explanation of Solution
Terminal voltage is expressed as,
Here,
Conclusion:
Voltage across the battery when it is not connected to a circuit is referred as emf. Therefore, option (a) is incorrect.
Power output doesn’t correspond to the voltage of the battery. Therefore, option (c) is incorrect.
When the battery has internal resistance, the total voltage across its terminals is equal to the terminal voltage given by equation (1). Therefore, option (b) is correct.
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During an experiment to verify Ohm's law, the voltage supplied and the current through a circuit are measured.
[Voltage is measured in Volt (V) and current in Ampere (A)].
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R
on
Battery
The measured value of the current is I = 3.1 ± 0.2 A and that of the voltage is V = 14 0.5 V. The resistance of
the circuit (in N) can be calculated using the formula, R = V/I,
Calculate the,
a) Resistance (in 2) =
b) Fractional uncertainty in the resistance =
c) Absolute uncertainty (in 2) in the resistance=
(a) What is the current in a 5.60-Ω resistor connected to a battery that has a 0.200-Ω
internal resistance if the terminal voltage of the battery is 10.0 V? (b) What is the
emf of the battery? (c) Construct a simple circuit diagram.
Consider the electric circuit shown in the sketch, consisting of a 12.0-V battery and three capacitors connected partly inseries and partly in parallel. Find (a) the equivalent capacitance of this circuit and (b) the total energy stored in the circuit.
Chapter 17 Solutions
College Physics
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