Electric Circuits, Student Value Edition Format: Unbound (saleable)
11th Edition
ISBN: 9780134747170
Author: NILSSON, James W.^riedel, Susan
Publisher: Prentice Hall
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Chapter 6, Problem 26P
a.
To determine
Derive the expression of the current
b.
To determine
Derive the expression of the current
c.
To determine
Derive the expression of the current
d.
To determine
Calculate the energy delivered to the black box in the interval
e.
To determine
Calculate the energy stored initially in the parallel inductors.
f.
To determine
Calculate the energy trapped in the ideal inductors.
g.
To determine
Verify that the solutions of
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Chapter 6 Solutions
Electric Circuits, Student Value Edition Format: Unbound (saleable)
Ch. 6.1 - The current source in the circuit shown generates...Ch. 6.2 - Prob. 2APCh. 6.2 - The current in the capacitor of Assessment Problem...Ch. 6.3 - The initial values of i1 and i2 in the circuit...Ch. 6.3 - Prob. 5APCh. 6.4 - Write a set of mesh-current equations for the...Ch. 6.5 - Consider the magnetically coupled coils described...Ch. 6 - Prob. 1PCh. 6 - The voltage at the terminals of the 200 μH...Ch. 6 - The triangular current pulse shown in Fig. P6.3 is...
Ch. 6 - The current in a 200 mH inductor is
The voltage...Ch. 6 - The current in a 20 mH inductor is known to...Ch. 6 - Assume in Problem 6.5 that the value of the...Ch. 6 - Evaluate the integral
for Example 6.2. Comment on...Ch. 6 - Find the inductor current in the circuit in Fig....Ch. 6 - The current in and the voltage across a 5 H...Ch. 6 - The current in the 2.5 mH inductor in Fig. P6.11...Ch. 6 - Initially there was no energy stored in the 5 H...Ch. 6 - The voltage across a 5 μF capacitor is known to...Ch. 6 - The triangular voltage pulse shown in Fig. P6.15...Ch. 6 - The expressions for voltage, power, and energy...Ch. 6 - A 20µF capacitor is subjected to a voltage pulse...Ch. 6 - The initial voltage on the 0.5 μF capacitor shown...Ch. 6 - The current shown in Fig. P6.20 is applied to a...Ch. 6 - The rectangular-shaped current pulse shown in Fig....Ch. 6 - Use realistic inductor values from Appendix H to...Ch. 6 - For the circuit shown in Fig. P6.24, how many...Ch. 6 - The two parallel inductors in Fig. P6.26 are...Ch. 6 - Derive the equivalent circuit for a series...Ch. 6 - Derive the equivalent circuit for a parallel...Ch. 6 - Use realistic capacitor values from Appendix H to...Ch. 6 - Prob. 30PCh. 6 - The two series-connected capacitors in Fig. P6.31...Ch. 6 - The four capacitors in the circuit in Fig, P6.32...Ch. 6 - For the circuit in Fig. P6.32, calculate
the...Ch. 6 - At t = 0. a series-connected capacitor and...Ch. 6 - The current in the circuit in Fig. P6.35 is known...Ch. 6 - Show that the differential equations derived in...Ch. 6 - Prob. 37PCh. 6 - Prob. 38PCh. 6 - Let υg represent the voltage across the current...Ch. 6 - Prob. 40PCh. 6 - Prob. 41PCh. 6 - Prob. 42PCh. 6 - Prob. 43PCh. 6 - Prob. 44PCh. 6 - Prob. 45PCh. 6 - Prob. 46PCh. 6 - Prob. 47PCh. 6 - Prob. 48PCh. 6 - The self-inductances of two magnetically coupled...Ch. 6 - Prob. 50PCh. 6 - Prob. 51PCh. 6 - Prob. 52PCh. 6 - Prob. 53P
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- 11-2) Now consider that white noise (i.e., noise with a PSD that is constant with frequency) is introduced in the channel of the system described in the previous problem. An ideal low pass filter is used at the receiver input to reduce the noise as much as possible, while transmitting the desired signal. (a) By what factor should the cutoff frequency of the noise reduction filter be reduced in the 16-PAM case, compared to binary? (b) By what factor will the noise power at the decision circuit be reduced in the 16-PAM case? (c) By what factor will the noise amplitude at the decision circuit be reduced in the 16-PAM case? (d) To obtain the same symbol error rate for 16-PAM as for binary, how should the minimum level spacing for 16-PAM compare to binary? (e) If the 16-PAM level spacing is adjusted according to part (d) above, by what factor will the average signal power be increased in the 16-PAM case, compared to binary?arrow_forward11-1) similar to Lathi & Ding, Prob. P.6.7-5 Data at a bit rate Rb must be transmitted using either binary NRZ polar signaling or 16-ary PAM NRZ polar signaling. (a) By what factor will the symbol rate be reduced in the 16-PAM case? (b) By what factor will bandwidth required from the (lowpass) channel be reduced in the 16-PAM case? (c) Assuming the minimum spacing between pulse levels must be the same in both cases, by what factor will the average power be increased in the 16-PAM case? [Hint: take the pulse amplitudes to be ±A in the binary case, and ±A, ±3A, ±5A,..., ±154, and recall that scaling pulse amplitude by a factor k scales the pulse energy by a factor R². Assume that the data is random, so that all 16 levels are equally likely, and that the same pulse shape is used in both cases.] Warning: Solutions to the textbook problem that are posted online are mostly wrong. Work it out for yourself.arrow_forward11-3) similar to Lathi & Ding, Prob. P.6.8-1 Consider the carrier modulator shown in the figure below, which transmits a binary carrier signal. The baseband generator uses polar NRZ signaling with rectangular pulses. The data rate is 8 Mbit/s. (a) If the modulator generates a binary PSK signal, what is the bandwidth of the modulated output? (b) If the modulator generates FSK with the difference fel - fco = 6 MHz (cf. Fig 6.32c), determine the modulated signal bandwidth. Binary data source Baseband signal generator Modulated output Modulator N-E---arrow_forward
- For the circuit shown, find (i) closed-loop voltage gain (ii) Z i of the circuit (iii) f_max. The slew rate is 0.6V/us. ((write your answer in Kilo ohm)) 2Vpp R ww 20 kQ R₁ ww 200 ΚΩ 9+18 V - 18 V 10 kn R₁₂ ΚΩ ((write your answer in KHz))arrow_forwardillustrate the phenomenon of phase reversal in CE amplifier i- When signal current =OA, so IB-8uA ii- When input signal reaches positive peak, so IB=16uA ii- When input signal reaches negative peak, so IB=4uA R₁ www + Vcc = 12V Rc=6kn 16 A 8 μA 4 μА 0 www RE ẞ = 100 VCarrow_forwardIn the circuit shown, find the voltage gain. Given that ẞ = 80 and input resistance Rin=2kQ. SIGNAL +10 V Rc=6kn 4-2 210arrow_forward
- For the transistor amplifier shown, R₁-11kQ, R2=6kQ, Rc=2kQ, RE-3kQ and R₁=2k0. (i) Draw d.c. load line (ii) Determine the DC operating point (iii) Draw a.c. load line. Assume V_BE = 0.7 V. and determine the new operating point + Vcc = 15 V RC Cc Cin R1 wwwwww wwwww R₁₂ RE CE RLarrow_forwardthe first part is the second part write your answer such as: (AND, OR, INVERTER, NAND, NOR) D₁ AK D, R₁ B K First Part? the third part is , and the total are R4 R7 Output R5 R₁ T R6 R3 -UBB Second Part? Third Part? Total?arrow_forwardA multistage amplifier has six stages each of which has a power gain of 40. what is the - Total gain of the amplifier in db ? ii- If the negative feedback of 15db is employed, find the resultant gainarrow_forward
- 9.36 Consider the finite-state machine logic implementation in Figure P9.36. (a) Determine the next-state and output logic expressions. (b) Determine the number of possible states. J1 Clk K₁ 101 Ут J2 Clk K₂ Clk Figure P9.36 0 y2 10arrow_forward9.34 Consider the finite-state machine logic implementation in Figure P9.34. (a) Determine the next-state and output logic expressions. (b) Determine the number of possible states. (c) Construct a state assigned table. (d) Construct a state table. (e) Construct a state diagram. (f) Determine the function of the finite-state machine. T₁ x Clk Figure P9.34 Q Clk Q الا T₂ Q 32 Clk Q T3 Q Clk Q Узarrow_forward9.35 Consider the finite-state machine logic implementation in Figure P9.35. (a) Determine the next-state and output logic expressions. (b) Determine the number of possible states. (c) Construct a state assigned table. (d) Construct a state table. (e) Construct a state diagram. (f) Determine the function of the finite-state machine. Clk J Clk K₁ 10 Ут J2 Clk K₂ 10 32 Figure P9.35arrow_forward
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