- 1.1.1: Ohms law relates V, I, and R for a resistor. For each of the situat...
- 1.1.2: Measurements taken on various resistors are shown below. For each, ...
- 1.1.3: Ohms law and the power law for a resistor relate V, I, R, and P, ma...
- 1.1.4: You are given three resistors whose values are 10 k, 20k, and 40 k....
- 1.1.5: In the analysis and test of electronic circuits, it is often useful...
- 1.1.6: Figure P1.6(a) shows a two-resistor voltage divider. Its function i...
- 1.1.7: A two-resistor voltage divider employing a 3.3-k and a 6.8-k resist...
- 1.1.8: You are given three resistors, each of 10 k, and a 9-V battery whos...
- 1.1.9: Two resistors, with nominal values of 4.7 k and 10 k, are used in a...
- 1.1.10: Current dividers play an important role in circuit design. Therefor...
- 1.1.11: Design a simple current divider that will reduce the current provid...
- 1.1.12: A designer searches for a simple circuit to provide one-third of a ...
- 1.1.13: A particular electronic signal source generates currents in the ran...
- 1.1.14: For the circuit in Fig. P1.14, find the Thvenin equivalent circuit ...
- 1.1.15: Through repeated application of Thvenins theorem, find the Thvenin ...
- 1.1.16: For the circuit shown in Fig. P1.16, find the current in all resist...
- 1.1.17: The circuit shown in Fig. P1.17 represents the equivalent circuit o...
- 1.1.18: For the circuit in Fig. P1.18, find the equivalent resistance to gr...
- 1.1.19: The periodicity of recurrent waveforms, such as sine waves or squar...
- 1.1.20: Find the complex impedance, Z, of each of the following basic circu...
- 1.1.21: Find the complex impedance at 10 kHz of the following networks: (a)...
- 1.1.22: Any given signal source provides an open-circuit voltage, voc, and ...
- 1.1.23: A particular signal source produces an output of 30 mV when loaded ...
- 1.1.24: A temperature sensor is specified to provide 2 mV/C. When connected...
- 1.1.25: Refer to the Thvenin and Norton representations of the signal sourc...
- 1.1.26: The connection of a signal source to an associated signal processor...
- 1.1.27: To familiarize yourself with typical values of angular frequency , ...
- 1.1.28: For the following peak or rms values of some important sine waves, ...
- 1.1.29: Give expressions for the sine-wave voltage signals having: (a) 10-V...
- 1.1.30: Using the information provided by Eq. (1.2) in association with Fig...
- 1.1.31: Measurements taken of a square-wave signal using a frequency-select...
- 1.1.32: What is the fundamental frequency of the highestfrequency square wa...
- 1.1.33: What is the fundamental frequency of the highestfrequency square wa...
- 1.1.34: Give the binary representation of the following decimal numbers: 0,...
- 1.1.35: Consider a 4-bit digital word b3b2b1b0 in a format called signed-ma...
- 1.1.36: Consider an N-bit ADC whose analog input varies between 0 and VFS (...
- 1.1.37: Figure P1.37 shows the circuit of an N-bit digital-toanalog convert...
- 1.1.38: In compact-disc (CD) audio technology, the audio signal is sampled ...
- 1.1.39: Various amplifier and load combinations are measured as listed belo...
- 1.1.40: An amplifier operating from 3-V supplies provides a 2.2-V peak sine...
- 1.1.41: An amplifier using balanced power supplies is known to saturate for...
- 1.1.42: Symmetrically saturating amplifiers, operating in the so-called cli...
- 1.1.43: Consider the voltage-amplifier circuit model shown in Fig. 1.16(b),...
- 1.1.44: An amplifier with 40 dB of small-signal, open-circuit voltage gain,...
- 1.1.45: A 10-mV signal source having an internal resistance of 100 k is con...
- 1.1.46: A buffer amplifier with a gain of 1 V/V has an input resistance of ...
- 1.1.47: Consider the cascade amplifier of Example 1.3. Find the overall vol...
- 1.1.48: You are given two amplifiers, A and B, to connect in cascade betwee...
- 1.1.49: A designer has available voltage amplifiers with an input resistanc...
- 1.1.50: Design an amplifier that provides 0.5 W of signal power to a 100- l...
- 1.1.51: It is required to design a voltage amplifier to be driven from a si...
- 1.1.52: A voltage amplifier with an input resistance of 10 k, an output res...
- 1.1.53: A current amplifier for which Ri = 1 k, Ro = 10 k, and Ais = 100 A/...
- 1.1.54: A transconductance amplifier with Ri = 2 k, Gm = 40 mA/V, and Ro = ...
- 1.1.55: A designer is required to provide, across a 10-k load, the weighted...
- 1.1.56: Figure P1.56 shows a transconductance amplifier whose output is fed...
- 1.1.57: It is required to design an amplifier to sense the open-circuit out...
- 1.1.58: It is required to design an amplifier to sense the short-circuit ou...
- 1.1.59: It is required to design an amplifier to sense the open-circuit out...
- 1.1.60: It is required to design an amplifier to sense the short-circuit ou...
- 1.1.61: For the circuit in Fig. P1.61, show that
- 1.1.62: An amplifier with an input resistance of 10 k, when driven by a cur...
- 1.1.63: voltage gain, current gain, and power gain expressed as ratios and ...
- 1.1.64: Any linear two-port network including linear amplifiers can be repr...
- 1.1.65: Use the voltage-divider rule to derive the transfer functions of th...
- 1.1.66: Figure P1.66 shows a signal source connected to the input of an amp...
- 1.1.67: For the circuit shown in Fig. P1.67, find the transfer function and...
- 1.1.68: It is required to couple a voltage source Vs with a resistance Rs t...
- 1.1.69: Measurement of the frequency response of an amplifier yields the da...
- 1.1.70: Measurement of the frequency response of an amplifier yields the da...
- 1.1.71: The unity-gain voltage amplifiers in the circuit of Fig. P1.71 have...
- 1.1.72: A manufacturing error causes an internal node of a high-frequency a...
- 1.1.73: A designer wishing to lower the overall upper 3-dB frequency of a t...
- 1.1.74: An amplifier with an input resistance of 100 k and an output resist...
- 1.1.75: A voltage amplifier has the transfer functionUsing the Bode plots f...
- 1.1.76: For the circuit shown in Fig. P1.76 first, evaluate and the corresp...
- 1.1.77: A transconductance amplifier having the equivalent circuit shown in...
- 1.1.78: Use the voltage-divider rule to find the transfer function of the c...
- 1.1.79: An amplifier with a frequency response of the type shown in Fig. 1....

# Solutions for Chapter 1: Microelectronic Circuits 6th Edition

## Full solutions for Microelectronic Circuits | 6th Edition

ISBN: 9780195323030

Solutions for Chapter 1

Get Full SolutionsChapter 1 includes 79 full step-by-step solutions. Microelectronic Circuits was written by Sieva Kozinsky and is associated to the ISBN: 9780195323030. This textbook survival guide was created for the textbook: Microelectronic Circuits, edition: 6. Since 79 problems in chapter 1 have been answered, more than 10690 students have viewed full step-by-step solutions from this chapter. This expansive textbook survival guide covers the following chapters and their solutions.