Engineering, 10.04.2020 18:37, michelle230

Find the steady-state time-domain quantities for the circuit

We used the node-voltage method in the frequency domain to identify the node voltages: We chose a reference node; wrote a KCL equation at the nonreference node; wrote a constraint equation for the dependent source that defines its controlling variable in terms of the node-voltage phasor; solved the equations simultaneously for the unknown node-voltage phasor and constrained current phasor; and calculated the current phasor through the inductive impedance. The final step is to use the inverse phasor-transform operation to transform the phasor voltage and current values in the frequency domain to the steady-state voltage and current values in the time domain.

Express your answers to three significant figures, separated by a comma. Note that all angles entered will be considered to be in degrees

Answers: 1

Show answers

Other questions on the subject: Engineering

Engineering, 03.07.2019 15:10, EmilySerna

Heat is added to a piston-cylinder device filled with 2 kg of air to raise its temperature 400 c from an initial temperature of t1 27 cand pressure of pi 1 mpa. the process is isobaric process. find a)-the final pressure p2 b)-the heat transfer to the air.

Answers: 1

continue

Engineering, 04.07.2019 18:10, settasav9641

Abrake has a normal braking torque of 2.8 kip in and heat-dissipating cast-iron surfaces whose mass is 40 lbm. suppose a load is brought to rest in 8.0 s from an initial angular speed of 1600 rev/min using the normal braking torque; estimate the temperature rise of the heat dissipating surfaces.

Answers: 3

continue

Engineering, 04.07.2019 19:20, rida10309

At steady state, air at 200 kpa, 325 k, and mass flow rate of 0.5 kg/s enters an insulated duct having differing inlet and exit cross-sectional areas. the inlet cross-sectional area is 6 cm2. at the duct exit, the pressure of the air is 100 kpa and the velocity is 250 m/s. neglecting potential energy effects and modeling air as an 1.008 kj/kg k, determine ideal gas with constant cp = (a) the velocity of the air at the inlet, in m/s. (b) the temperature of the air at the exit, in k. (c) the exit cross-sectional area, in cm2

Answers: 2

continue

Engineering, 04.07.2019 19:20, holaadios222lol

Apiping systems consists of 6 m of 6-std type k and 12 m of 4-std type k, both drawn copper tubing. the system conveys ethylene glycol at a rate of 0.013 m3/s. the pressure drop across the system is to be calculated. there are two 90° elbows in the 6-in pipe, a reduction from the 6-in pipe to the 4-in pipe and four 90° elbows in the 4-in pipe. all fittings are soldered (same as flanged) and regular. the inlet and outlet of the system are at the same height.

Answers: 1

continue

Do you know the correct answer?

Find the steady-state time-domain quantities for the circuit

We used the node-voltage me...