What maximum power can a silicon transistor (TJmax = 200°C) dissipate into free air at an ambient temperature of 80°C?
> Calculate the operating frequency of a BJT phase-shift oscillator as in Fig. 14.21b for R = 6 kΩ, C = 1500 pF, and RC = 18 kΩ.
> An FET phase-shift oscillator having gm = 6000 mS, rd = 36 kΩ, and feedback resistor R = 12 kΩ is to operate at 2.5 kHz. Select C for specified oscillator operation.
> For a circuit as in Fig. 14.11 and the following circuit values, calculate the circuit gain and the input and output impedances with and without feedback: RB = 600 kΩ, RE = 1.2 kΩ, RC = 4.7 kΩ, and b = 75. Use VCC = 16 V.
> Calculate the gain with and without feedback for an FET amplifier as in Fig. 14.7 for circuit values R1 = 800 kΩ, R2 = 200 Ω, Ro = 40 kΩ, RD = 8 kΩ, and gm = 5000 mS.
> Calculate the gain, input, and output impedances of a voltage-series feedback amplifier having A = - 300, Ri = 1.5 kΩ, Ro = 50 kΩ, and b = —1/15.
> If the gain of an amplifier changes from a value of —1000 by 10%, calculate the gain change if the amplifier is used in a feedback circuit having b = —1/20.
> Determine the range of possible values for VC for the network of Fig. 4.132 using the 1-MΩ potentiometer.
> Design a unijunction oscillator circuit for operation at (a) 1 kHz and (b) 150 kHz.
> Draw circuit diagrams of (a) a series-operated crystal oscillator and (b) a shunt-excited crystal oscillator.
> Calculate the oscillation frequency for the transistor Hartley circuit of Fig. 14.30 and the following circuit values:
> Calculate the oscillator frequency for an FET Hartley oscillator as in Fig. 14.29 for the following circuit values:
> For the transistor Colpitts oscillator of Fig. 14.27 and the following circuit values, calculate the oscillation frequency:
> Calculate the gain of a negative-feedback amplifier having A = —2000 and b = —1/10.
> For a reference voltage of 16 V, calculate the output voltage for an input of 11010 to the circuit of Problem 8.
> Sketch a five-stage ladder network using 15-kΩ and 30-kΩ resistors.
> Describe the operation of the circuit in Fig. 13.43.
> Sketch the output waveform for the circuit of Fig. 13.42.
> a. Determine the levels of IC and VCE for the network of Fig. 4.131. b. Change  to 135 (50% increase), and calculate the new levels of IC and VCE. c. Determine the magnitude of the percentage change in IC and VCE using the following equ
> Draw the circuit diagram of a zero-crossing detector using a 339 comparator stage with {12-V supplies.
> Draw the resulting output waveform for the circuit of Fig. 13.41.
> Draw a circuit diagram of a 311 op-amp showing an input of 10 V rms applied to the inverting input and the plus input to ground. Identify all pin numbers.
> What is the difference between open-collector and tri-state output?
> What is a data bus?
> Describe the signal conditions for current-loop and RS-232C interfaces.
> What is the lock range of the PLL circuit in Fig. 13.26b for
> What value of capacitor C1 is required in the circuit of Fig. 13.26b to obtain a center frequency of 100 kHz?
> Calculate the VCO free-running of Fig. 13. frequency for the circuit 26b with
> Sketch the output waveform for the circuit of Fig. 13.40.
> a. Compare levels of R' = RC + RE to RF> for the network of Fig. 4.131. b. Is the approximation ICQ ÷ V'>R' valid?
> If a transistor amplifier has more than one dc source, can the superposition theorem be applied to obtain the response of each dc source and algebraically add the results?
> Determine the capacitor needed in the circuit of Fig. 13.22 to obtain a 200-kHz output.
> What frequency range results in the circuit of Fig. 13.23 for
> Calculate the center frequency of a VCO using a 566 IC as in Fig. 13.22 for
> Sketch the input and output waveforms for a one-shot using a 555 timer triggered by a 10-kHz clock for
> Draw the circuit of a one-shot using a 555 timer to provide one time period of 20ms. If What value of C is needed?
> Sketch the circuit of a 555 timer connected as an astable multivibrator for operation at 350 kHz. Determine the value of capacitor C needed using
> What is the maximum count interval using a 12-stage counter operated at a clock rate of 20 MHz?
> How many count steps occur using a 12-stage digital counter at the output of an ADC?
> For a dual-slope converter, describe what occurs during the fixed time interval and the count interval.
> What voltage resolution is possible using a 12-stage ladder network with a 10-V reference voltage?
> For the voltage feedback network of Fig. 4.130, determine: a. IC. b. VC. c. VE. d. VCE.
> Draw the diagram of a 741 op-amp operated from {15-V supplies with Vi (-) = V and Vi (+) = + 5 V. Include terminal pin connections.
> Calculate the efficiency of the circuit of Problem 8 if the bias current is ICQ = 150 mA.
> A transformer-coupled class A amplifier drives a 16-Ω speaker through a 3.87:1 transformer. Using a power supply of VCC = 36 V, the circuit delivers 2 W to the load. Calculate: a. P(ac) across transformer primary. b. VL (ac). c. V(ac) at transformer prim
> Calculate the transformer turns ratio required to connect four parallel 16-Ω speakers so that they appear as an 8-kΩ effective load.
> What turns ratio transformer is needed to couple to an 8-Ω load so that it appears as an 8-kΩ effective load?
> A class A transformer-coupled amplifier uses a 25:1 transformer to drive a 4-Ω load. Calculate the effective ac load (seen by the transistor connected to the larger turns side of the trans- former).
> If the circuit of Fig. 12.35 is biased at its center voltage and center collector operating point, what is the input power for a maximum output power of 1.5 W?
> What maximum output power can be delivered by the circuit of Fig. 12.35 if RB is changed to 1.5 kΩ?
> A 160-W silicon power transistor operated with a heat sink (uSA = 1.5°C>W) has uJC = 0.5°C>W and a mounting insulation of uCS = 0.8°C>W. What maximum power can be handled by the transistor at an ambient temperature of 80°C? (The junction temperature shou
> For the network of problem 27 a. Determine ICQ using the equation ICQ b. Compare with the results of problem 27 for ICQ. c. Compare R’ to RF/. d. Is the statement valid that the larger R’ is compa
> Determine the maximum dissipation allowed for a 100-W silicon transistor (rated at 25°C) for a derating factor of 0.6 W>°C at a case temperature of 150°C.
> For distortion readings of D2 = 0.15, D3 = 0.01, and D4 = 0.05, with I1 = 3.3 A and RC = 4 Ω, calculate the total harmonic distortion fundamental power component and total power.
> Calculate the second harmonic distortion for an output waveform having measured values of VCEmin = 2.4 V, VCEQ = 10 V, and VCEmax = 20 V.
> Calculate the total harmonic distortion for the amplitude components of Problem 19.
> Calculate the input power dissipated by the circuit of Fig. 12.35 if RB is changed to 1.5 kΩ.
> Calculate the harmonic distortion components for an output signal having fundamental amplitude of 2.1 V, second harmonic amplitude of 0.3 V, third harmonic component of 0.1 V, and fourth harmonic component of 0.05 V.
> For the power amplifier of Fig. 12.37, calculate: a. Po(ac). b. Pi(dc). c. %h. d. Power dissipated by both output transistors.
> If the input voltage to the power amplifier of Fig. 12.36 is 8-V rms, calculate: a. Pi(dc). b. Po(ac). c. %h. d. Power dissipated by both power output transistors.
> For the class B power amplifier of Fig. 12.36, calculate: a. Maximum Po(ac). b. Maximum Pi(dc). c. Maximum %h. d. Maximum power dissipated by both transistors.
> Sketch the circuit diagram of a quasi-complementary amplifier, showing voltage waveforms in the circuit.
> For the collector-feedback configuration of Fig. 4.129, determine: a. IB. b. IC. c. VC.
> Calculate the efficiency of a class B amplifier for a supply voltage of VCC = 22 V driving a 4-Ω load with peak output voltages of: a. VL(p) = 20 V. b. VL(p) = 4 V.
> For a class B amplifier with VCC = 25 V driving an 8-Ω load, determine: a. Maximum input power. b. Maximum output power. c. Maximum circuit efficiency.
> For a class B amplifier providing a 22-V peak signal to an 8-Ω load and a power supply of VCC = 25 V, determine: a. Input power. b. Output power. c. Circuit efficiency.
> Draw the circuit diagram of a class B npn push–pull power amplifier using transformer- coupled input.
> Draw the circuit diagram of a class A transformer-coupled amplifier using an npn transistor.
> Calculate the input and output power for the circuit of Fig. 12.35. The input signal results in a base current of 5 mA rms.
> Show the connection (including pin information) of an LM124 IC stage connected as a unity- gain amplifier.
> Determine the output voltage for the circuit of Fig. 11.52.
> Determine the output voltage for the circuit of Fig. 11.51.
> Calculate the output voltage for the circuit of Fig. 11.50 with inputs of V1 = 40 mV rms and V2 = 20 mV rms.
> a. Repeat parts (a) through (e) of Problem 25 for the network of Fig. 4.128. Change to 180 in part (b). b. What general conclusions can be made about networks in which the condition RE > 10R2 is satisfied and the quantities IC and VCE are to be determ
> Show the connection of two op-amp stages using an LM358 IC to provide outputs that are 15 and —30 times larger than the input. Use a feedback resistor, RF = 150 kΩ, in all stages.
> Show the connection of an LM124 quad op-amp as a three-stage amplifier with gains of +15, —22, and —30. Use a 420-kΩ feedback resistor for all stages. What output voltage results for an input of V1 = 80 mV?
> Calculate the output voltage in the circuit of Fig. 11.49.
> Calculate the output voltage of the circuit of Fig. 11.48 for an input of 150 mV rms.
> Calculate the lower and upper cutoff frequencies of the bandpass filter circuit in Fig. 11.59.
> Calculate the cutoff frequency of the high-pass filter circuit in Fig. 11.58.
> Calculate the cutoff frequency of a first-order low-pass filter in the circuit of Fig. 11.57.
> Calculate Vo in the circuit of Fig. 11.56.
> Calculate the output current Io in the circuit of Fig. 11.55.
> Calculate Vo for the circuit of Fig. 11.54.
> a. Determine IC and VCE for the network of Fig. 4.125. b. Change  to 120 (50% increase), and determine the new values of IC and VCE for the net- work of Fig. 4.125. c. Determine the magnitude of the percentage change in IC and VCE using
> For the circuit of Fig. 11.53, calculate IL.
> Show the connection (including pin information) of two LM358 stages connected as unity-gain amplifiers to provide the same output.
> Calculate the output voltage for the circuit of Fig. 11.47 for an input of Vi = 3.5 mV rms.
> Calculate the output voltage of the circuit in Fig. 10.68 for Rf = 68 kΩ.
> Calculate the output voltage developed by the circuit of Fig. 10.68 for Rf = 330 kΩ.
> What range of output voltage is developed in the circuit of Fig. 10.67?
> What input must be applied to the input of Fig. 10.66 to result in an output of 2.4 V?
> What output voltage results in the circuit of Fig. 10.66 for an input of V1 = —0.3 V?
> What is the range of the output voltage in the circuit of Fig. 10.65 if the input can vary from 0.1 to 0.5 V?
> What input voltage results in an output of 2 V in the circuit of Fig. 10.64?
> a. Using the characteristics of Fig. 4.121, determine RC and RE for a voltage-divider network having a Q-point of ICQ = 5 mA and VCEQ = 8 V. Use VCC = 24 V and RC = 3RE. b. Find VE. c. Determine VB. d. Find R2 if R1 = 24 kΩ assuming that RE 10R2. e. C
> Determine the output voltage of an op-amp for input voltages of Vi1 = 200 mV and Vi2 = 140 mV. The amplifier has a differential gain of Ad = 6000 and the value of CMRR is: a. 200. b. 105.
> Calculate the CMRR (in dB) for the circuit measurements of VD = 1 mV, VO = 120 mV, VC = 1 mV, and VO = 20 mV.
> For the typical characteristics of the 741 op-amp, calculate the following values for the circuit of Fig. 10.75: a. ACL. b. Zi. c. Zo.
> Using the specifications listed in Table 10.3; calculate the typical offset voltage for the circuit connection of Fig. 10.75.
> For an input of V1 = 50 mV in the circuit of Fig. 10.75, determine the maximum frequency that may be used. The op-amp slew rate SR = 0.4 V>ms.
