(3) The circuit below operates in steady-state. R-10 22.7.- 5 us. Calculate I., II, and
18. The circuit of Figure P10.18 operates in the sinusoidal steady state at a frequency of (1), = 2000 rad/sec, R, = R, = 10 S2, V:,, = 50 V, and I. = 22 - 53.13º A. Compute the phasor volt- age across R2 and then find the impedance Z(w). Now construct a simple series circuit that represents this impedance at (1) N Figure P10.18 ANSWER: 2 = 2.5 + 710 12
1) Calculate the steady state expression for V, in the circuit below if ig = 500 cos 2000t mA. 12012 403 12.5 uF 60 mH 3
suppose Vs = 10 cos(10t) in the circuit below. Find L(t) in steady state. (R=10Ω , C=0.2F , L=0.5H) v, (7) 0.912-24° A 0.91 2+ 12 A 9.1 2-12 A 9.1 -24 A 9.1 24A 0.912-12 A 0.91 24 A 9.1 2+12 A
250 mH Vi Given: The circuit shown above operates in steady state over a range of frequencies. Vj is the input voltage and Vo is the output voltage. a. Determine the resistance value in K2 for which the half-power frequency, ??.s 10 krad/s. b. Using the value of R found in part a, determine the radian frequency (01 at which Vo lags V, by 40 c. Is this a High-pass or a Low-pass filter? Solution R= krad/s, and the filter...
14. Problem For the circuit in figure below, find the steady-state output voltage vo (t). The input signal is v (t) and C = 5 μF 4-2 cos 100t, R 1 kΩ Do C R 12 U) 14. Problem For the circuit in figure below, find the steady-state output voltage vo (t). The input signal is v (t) and C = 5 μF 4-2 cos 100t, R 1 kΩ Do C R 12 U)
A control operates at steady state as shown in the diagram below. For the control volume, determine the volumetric flow rate of steam at the exit, in m/s. 4-3. H20 10 bar (3) sat. vapor 90°C 10 bar 10 bar 320oC n1-50 kg/s m2/m, = 0.131
The circuit below is operating in steady state. Find the output voltage (Xo). 6k92 5 mH 10 v 2 uF 2 uF 4k2 ya Vo =
QUESTION 5 The circuit below is operating in steady state. Find the output voltage (yo). 6k 2 5 mH 10 V 2 F 2 LF 4k92 Vo = __V
[10marks] Question 3 The circuit in figure below has reached steady state at t-o. If the make-before- break switch moves to position b at t- o calculate a. i(t) fortO b. v(t) fort s 0 C. p(t) for tso 10Ω 60 Ω 40 2 2.5 H 10marks
The Class Name is: MAE 318 System Dynamics and Control I Problem 1: Steady-state error analvsis (a) A block diagram of a feedback control system is given below. Assuming that the tunable constant Khas a value that makes this closed-loop system stable, find the steady-state error of the closed-loop system for (a a step reference input with amplitude R, r(t)- R u(t) (ii) a ramp reference input with slope R, r(t) = Rt-us(t) R(s) Y(s) (s+2)(s +5) (b) A block...