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engineering
electrical engineering
Questions and Answers of
Electrical Engineering
Find Io in the circuit shown using linearity and the assumption that Io =1mA.
Find Io in the network shown using linearity and the assumption that Io=1mA.
Find Vo in the network shown using linearity and the assumption that Vo=1mV
Find in the circuit shown using linearity and the assumption that .
In the network shown find Io using superposition
Find Io in the circuit shown using superposition
In the network shown find Vo using superposition
Find Vo in the network shown using superposition
Find Io in the network shown using superposition
Find Io in the network shown using superposition
Find Io in the network shown using superposition.
Find Io in the network shown using superposition
Find Io in the circuit shown using superposition
Use superposition to find Io in the circuit shown
Find Io in the network shown using superposition
Find in the network shown using superposition.
Find in the network shown using superposition.
Find Vo in the network shown using superposition
Use source transformation to find Io in the circuit shown
Find Vo in the network shown using source transformation
Use source transformation to find in the network shown
Find Vo in the network shown using source transformation
Find Io in the circuit shown using source transformation
Find Io in the network shown using source transformation
Use source transformation to find Io in the circuit shown
Find Vo in the network shown using source transformation
Find Vo in the circuit shown using source transformation
Find Io in the network shown using source transformation
Find Io in the network shown using source transformation
Find Io in the network shown using source transformation
Find Io in the network shown using source transformation
Use Thevenins Theorem to find Vo in the network shown
Use Thevenins Theorem to find Vo in the network shown
Use Thevenins Theorem to find Io in the network shown
Find Io in the network shown using Thevenins Theorem
Find Vo in the circuit shown using Thevenins Theorem
Find in the circuit shown using Thévenins Theorem
Find Io in the network shown using Thevenins Theorem
Find Vo in the circuit shown using Thevenins Theorem
Find Vo in the circuit shown using Thevenins Theorem
Find Io in the network shown using Thevenins Theorem
Find Io in the network shown using Thevenins Theorem.
Find Io in the network shown using Thevenins Theorem.
Use mesh analysis to find Vo in the circuit shown
Find Vo in the network shown using Thevenins Theorem
Find Vo in the network shown using Thevenins Theorem
Use a combination of Thevenins Theorem and superposition to find Vo in the circuit shown.
In the network shown find Vo using Thevenins Theorem
Find the Thevenin equivalent of the network shown at the terminals A-B.
Find the Thevenin equivalent of the network shown at the terminals A-B.
Find Vo in the network shown using Thevenins Theorem
Find Vo in the network shown using Thevenins Theorem
Find Vo in the circuit shown using Thevenins Theorem
Use Thevenins Theorem to find Vo in the circuit shown
Use Thevenins Theorem to Find Io in the circuit shown
Find Vo in the network shown using Thevenins Theorem
Use Thevenins Theorem to find Vo in the network shown
Find Vo in the network shown using Thevenins Theorem
Use Thevenins Theorem to Find Vo in the circuit shown
Use Nortons Theorem to find Vo in the network shown
Find in the network shown using Nortons Theorem
Use Nortons Theorem to find Io in the circuit shown
Find Io in the network shown using Nortons Theorem
Use Nortons Theorem to find Vo in the network shown
Given the linear circuit shown, it is known that when a 2-K load is connected to the terminals A-B, the load current is 10mA. If a 10-K load is connected to the terminals the load
If an 8-K load is connected to the terminals of the network shown, VAB = 16V. If a 2-K load is connected to the terminals VAB = 8V. Find VAB if a 20K load is connected to
Find RL for maximum power transfer and the maximum power that can be transferred in the network shown.
Find for maximum power transfer and the maximum power that can be transferred in the network shown.
In the network shown find RL for maximum power transfer and the maximum power that can be transferred to this load.
Find RL for maximum power transfer and the maximum power that can be transferred in the network shown.
In the network shown find Io using PSPICE
In the network shown determine Vo using PSPICE.
Find in the network shown using PSPICE
Find in the network shown using PSPICE.
Determine the maximum power that can be delivered to the load RL in the network shown.
Find the value of the load RL in the network shown that will achieve maximum power transfer, and determine the value of the maximum power.
Find the value of RL in the network shown for maximum power transfer to this load.
A 12yF capacitor has an accumulated charge of 480yC. Determine the voltage across the capacitor after 4 s.
A capacitor has an accumulated charge of . Determine the voltage across the capacitor.
A capacitor has an accumulated charge of 600 with 5 V across it. What is the value of capacitance?
A 25- yF capacitor initially charged to –10V is charged by a constant current of 2.5 A. Find the voltage across the capacitor after 2 ½ minutes.
The energy that is stored in a 25-yF capacitor is w(t)=12sin2377t J. Find the current in the capacitor.
An uncharged 10-uF capacitor is charged by the current I(t)=10cos377t mA. Find (a) the expression for the voltage across the capacitor and (b) the expression for the power.
The voltage across a 100-uF capacitor is given by the expression v(t)=120sin(377t) V. Find (a)the current in the capacitor and (b) the expression for the energy stored in the element.
A capacitor is charged by a constant current of 2mA and results in a voltage increase of 12V in a 10-s interval. What is the value of the capacitance?
The current in a 100-uF capacitor is shown in Figure P5.9. Determine the waveform for the voltage across the capacitor if it is initially uncharged.
The voltage across a 100-F capacitor is shown in Figure P5.10. Compute the waveform for the current in the capacitor
The voltage across a 6-uF capacitor is shown in Figure P5.11. Compute the waveform for the current in the capacitor
The voltage across a 50-uF capacitor is shown. Determine the current waveform.
The voltage across a 2-yF capacitor is given by the waveform in Figure P5.13. Compute the current waveform.
The voltage across a 0.1-F capacitor is given by the waveform in Figure P5.14. Find the waveform for the current in the capacitor
The waveform for the current in a 200-yF capacitor is shown in Figure P5.15. Determine the waveform for the capacitor voltage.
Draw the waveform for the current in a 12-uF capacitor when the capacitor voltage is as described in Figure 5.16
Draw the waveform for the current in a 3-yF capacitor when the voltage across the capacitor is given in Figure P5.17
The waveform for the current in a 100-yF initially uncharged capacitor is shown. Determine the waveform for the capacitors voltage.
The voltage across a 6-yF capacitor is given by the waveform in Figure P5.19. Plot the waveform for the capacitor current.
The current in an inductor changes from 0 to 200mA in 4ms in 4 ms and induces a voltage of 100mV. What is the value of the inductor?
The current in a 100-mH inductor is i(t)=2sin(377t)A. Find (a) the voltage across the inductor and (b) the expression for the energy stored in the element
A 10-mH inductor has a sudden current change from 200mA to 100mA in 1ms. Find the induced voltage.
The induced voltage across a 10-mH inductor is v (t)=120cos(377t) V. Find (a) the expression for the inductor current and (b) the expression for the power.
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