EBK PHYSICS FOR SCIENTISTS AND ENGINEER
EBK PHYSICS FOR SCIENTISTS AND ENGINEER
9th Edition
ISBN: 9781305804463
Author: Jewett
Publisher: CENGAGE LEARNING - CONSIGNMENT
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Chapter 32, Problem 32.30P

Two ideal inductors, L1 and L2, have zero internal resistance and are far apart, so their magnetic fields do not influence each other. (a) Assuming these inductors are connected in series, show that they are equivalent to a single ideal inductor having Leq = L1 + L2. (b) Assuming these same two inductors are connected in parallel, show that they are equivalent to a single ideal inductor having 1/Leq = 1/L1 + 1/L2. (c) What If? Now consider two inductors L1 and L2 that have nonzero internal resistances R1 and R2, respectively. Assume they are still far apart, so their mutual inductance is zero, and assume they are connected in series. Show that they are equivalent to a single inductor having Leq = L1 + L2 and Req = R1 + R2. (d) If these same inductors are now connected in parallel, is it necessarily true that they are equivalent to a single ideal inductor having 1/Leq = 1/L1 + 1/L2 and 1/Req = 1/R1 + 1/R2? Explain your answer.

(a)

Expert Solution
Check Mark
To determine

To show: The equivalent inductance is Leq=L1+L2 .

Answer to Problem 32.30P

The equivalent inductance in series combination is Leq=L1+L2 .

Explanation of Solution

Given info: The inductance of the inductor are L1 and L2 . The internal resistances of them are zero.

For a series connection, both inductor carry equal currents at every instant. So the change in current didt is same for both inductor.

Write the expression to calculate the voltage across the pair.

Leqdidt=L1didt+L2didtLeq=L1+L2

Conclusion:

Therefore, the equivalent inductance is Leq=L1+L2 .

(b)

Expert Solution
Check Mark
To determine

To show: The equivalent inductance in parallel combination is 1Leq=1L1+1L2 .

Answer to Problem 32.30P

The equivalent inductance in parallel combination is 1Leq=1L1+1L2 .

Explanation of Solution

Given info: The inductance of the inductor are L1 and L2 . The internal resistances of them are zero.

For a parallel connection, the voltage across each inductor is same for both.

Write the expression to calculate the voltage across each inductor.

Leqdidt=L2didt=L2didt=ΔVL

The current in the connection is,

didt=di1dt+di2dt (1)

Here,

i1 is the current in first inductor.

i2 is the current in second inductor.

The change in current in equivalent inductor is,

didt=ΔVLLeq

The change in current in first inductor is,

di1dt=ΔVLL1

The change in current in second inductor is,

di2dt=ΔVLL2

Substitute ΔVLLeq for didt , ΔVLL1 for di1dt and ΔVLL2 for di2dt in equation (1).

ΔVLLeq=ΔVLL1+ΔVLL21Leq=1L1+1L2

Thus, the equivalent inductance in parallel combination is 1Leq=1L1+1L2 .

Conclusion:

Therefore, the equivalent inductance in parallel combination is 1Leq=1L1+1L2 .

(c)

Expert Solution
Check Mark
To determine

To show: The equivalent inductance and resistance when their internal resistance is non zero in series combination is Leq=L1+L2 and Req=R1+R2 respectively.

Answer to Problem 32.30P

The equivalent inductance in parallel combination is 1Leq=1L1+1L2 .

Explanation of Solution

Given info: The inductance of the inductor are L1 and L2 . The internal resistances of them are R1 and R2 .

Write the expression to calculate the voltage across the connection.

Leqdidt+Reqi=L1didt+iR1+L2didt+iR2

Here, i and didt are independent quantities under our control so functional equality requires both Leq=L1+L2 and Req=R1+R2 conditions satisfied.

Thus, the equivalent inductance and resistance when their internal resistance is non zero in series combination is Leq=L1+L2 and Req=R1+R2 respectively.

Conclusion:

Therefore, the equivalent inductance and resistance when their internal resistance is non zero in series combination is Leq=L1+L2 and Req=R1+R2 respectively.

(d)

Expert Solution
Check Mark
To determine
Whether it is necessarily true that they are equivalent to a single ideal inductor having 1Leq=1L1+1L2 and 1Req=1R1+1R2 .

Answer to Problem 32.30P

It is necessarily true that they are equivalent to a single ideal inductor having 1Leq=1L1+1L2 and 1Req=1R1+1R2 .

Explanation of Solution

Given info: The inductance of the inductor are L1 and L2 . The internal resistances of them are R1 and R2 .

If the circuit elements are connected in parallel then two conditions always true.

The first condition is,

i=i1+i2ΔVLReq=ΔVLR1+ΔVLR21Req=1R1+1R2

The second condition is,

didt=di1dt+di2dtΔVLLeq=ΔVLL1+ΔVLL21Leq=1L1+1L2

Thus, it is necessarily true that they are equivalent to a single ideal inductor having 1Leq=1L1+1L2 and 1Req=1R1+1R2 .

Conclusion:

Therefore, it is necessarily true that they are equivalent to a single ideal inductor having 1Leq=1L1+1L2 and 1Req=1R1+1R2 .

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Chapter 32 Solutions

EBK PHYSICS FOR SCIENTISTS AND ENGINEER

Ch. 32 - Prob. 32.6OQCh. 32 - Prob. 32.7OQCh. 32 - Prob. 32.1CQCh. 32 - Prob. 32.2CQCh. 32 - A switch controls the current in a circuit that...Ch. 32 - Prob. 32.4CQCh. 32 - Prob. 32.5CQCh. 32 - Prob. 32.6CQCh. 32 - The open switch in Figure CQ32.7 is thrown closed...Ch. 32 - After the switch is dosed in the LC circuit shown...Ch. 32 - Prob. 32.9CQCh. 32 - Discuss the similarities between the energy stored...Ch. 32 - Prob. 32.1PCh. 32 - Prob. 32.2PCh. 32 - Prob. 32.3PCh. 32 - Prob. 32.4PCh. 32 - An emf of 24.0 mV Ls induced in a 500-turn coil...Ch. 32 - Prob. 32.6PCh. 32 - Prob. 32.7PCh. 32 - Prob. 32.8PCh. 32 - Prob. 32.9PCh. 32 - Prob. 32.10PCh. 32 - Prob. 32.11PCh. 32 - A toroid has a major radius R and a minor radius r...Ch. 32 - Prob. 32.13PCh. 32 - Prob. 32.14PCh. 32 - Prob. 32.15PCh. 32 - Prob. 32.16PCh. 32 - Prob. 32.17PCh. 32 - Prob. 32.18PCh. 32 - Prob. 32.19PCh. 32 - When the switch in Figure P32.18 is closed, the...Ch. 32 - Prob. 32.21PCh. 32 - Show that i = Iiet/ is a solution of the...Ch. 32 - Prob. 32.23PCh. 32 - Consider the circuit in Figure P32.18, taking =...Ch. 32 - Prob. 32.25PCh. 32 - The switch in Figure P31.15 is open for t 0 and...Ch. 32 - Prob. 32.27PCh. 32 - Prob. 32.28PCh. 32 - Prob. 32.29PCh. 32 - Two ideal inductors, L1 and L2, have zero internal...Ch. 32 - Prob. 32.31PCh. 32 - Prob. 32.32PCh. 32 - Prob. 32.33PCh. 32 - Prob. 32.34PCh. 32 - Prob. 32.35PCh. 32 - Complete the calculation in Example 31.3 by...Ch. 32 - Prob. 32.37PCh. 32 - A flat coil of wire has an inductance of 40.0 mH...Ch. 32 - Prob. 32.39PCh. 32 - Prob. 32.40PCh. 32 - Prob. 32.41PCh. 32 - Prob. 32.42PCh. 32 - Prob. 32.43PCh. 32 - Prob. 32.44PCh. 32 - Prob. 32.45PCh. 32 - Prob. 32.46PCh. 32 - In the circuit of Figure P31.29, the battery emf...Ch. 32 - A 1.05-H inductor is connected in series with a...Ch. 32 - A 1.00-F capacitor is charged by a 40.0-V power...Ch. 32 - Calculate the inductance of an LC circuit that...Ch. 32 - An LC circuit consists of a 20.0-mH inductor and a...Ch. 32 - Prob. 32.52PCh. 32 - Prob. 32.53PCh. 32 - Prob. 32.54PCh. 32 - An LC circuit like the one in Figure CQ32.8...Ch. 32 - Show that Equation 32.28 in the text Ls Kirchhoffs...Ch. 32 - In Figure 31.15, let R = 7.60 , L = 2.20 mH, and C...Ch. 32 - Consider an LC circuit in which L = 500 mH and C=...Ch. 32 - Electrical oscillations are initiated in a series...Ch. 32 - Review. Consider a capacitor with vacuum between...Ch. 32 - Prob. 32.61APCh. 32 - An inductor having inductance I. and a capacitor...Ch. 32 - A capacitor in a series LC circuit has an initial...Ch. 32 - Prob. 32.64APCh. 32 - When the current in the portion of the circuit...Ch. 32 - At the moment t = 0, a 24.0-V battery is connected...Ch. 32 - Prob. 32.67APCh. 32 - Prob. 32.68APCh. 32 - Prob. 32.69APCh. 32 - At t = 0, the open switch in Figure P31.46 is...Ch. 32 - Prob. 32.71APCh. 32 - Prob. 32.72APCh. 32 - Review. A novel method of storing energy has been...Ch. 32 - Prob. 32.74APCh. 32 - Review. The use of superconductors has been...Ch. 32 - Review. A fundamental property of a type 1...Ch. 32 - Prob. 32.77APCh. 32 - In earlier times when many households received...Ch. 32 - Assume the magnitude of the magnetic field outside...Ch. 32 - Prob. 32.80CPCh. 32 - To prevent damage from arcing in an electric...Ch. 32 - One application of an RL circuit is the generation...Ch. 32 - Prob. 32.83CP
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