Example 10.3-2 (See Example 10.3-2 in the textbook for the solution to a similar problem.) Consider...
Example 10.3-2 (See Example 10.3-2 in the textbook for the solution to a similar problem.) Consider these phasors: VI: 16 /126-v and V2 -54+j 18 V Convert V1 to rectangular form and V2 to polar form to get Determine the values of a and b, the real and imaginary parts of V1 v and b( Determine the values of A and e, the magintude and angle of V2
Example 10.3-2 (See Example 10.3-2 in the textbook for the solution to a similar problem.) Consider these phasors: V, = 17 (106° V and V2 = -42 +j15 V Convert V, to rectangular form and V, to polar form to get Vi = a + b V and V, = A/ V Determine the values of a and b, the real and imaginary parts of V: V and b = Determine the values of A and e, the magintude and...
Example 10.3-3 (See Example 10.3-3 in the textbook for the solution to a similar problem.) Consider these phasors: V1 = 32.51 116 o V and v, = 50.6 / 163 ° V =-14.2 +j 29.2 V =-48.3 +/ 15.1 V The sum of these phasors can be represented as Determine the values of a and b, the real and imaginary parts of V1 + V2: lv V and b- Determine the values of A and θ, the magnitude and angle...
Example 10.3-3 (Companion Problem 2) (See Example 10.3-3 in the textbook for the solution to a similar problem.) Consider these phasors: v,-41.1 142 V 398 10.1 V and V2 23.2 79.8 V 4.10 22.8v The product of these phasors can be represented as Determine the values of a and b, the real and imaginary parts of V1/V2: Vand b Determine the values of A and θ, the magnitude and angle of V1 /V2 : V and θ 0 Question Attempts:...
Example 10.5-3 (See Example 10.5-3 in the textbook for the solution to a similar problem.) 2 mF 13o This circuit is at steady state. The input to this circuit is the voltage source voltage, vs(t), given by Vs(t) = 45cos(20t + (-50° ) | V The output voltage, Vo(t), can be expressed as Vo (t) = A cos(20t+ θ) v where A and θ are constants such that A > 0 and-180° < θ < 180°. Determine the values of...
(See Example 10.2-1 in the textbook for the solution to a similar problem.) Consider the sinusoids o V and V2 113 Determine the time in ms, ta, by which v2(t) is advanced with respect to vi(t) 13.89 ms the tolerance is +/-3%
Example 10.5-1 (See Example 10.5-1 in the textbook for the solution to a similar problem.) 68Ω i(t) yso) 6.0H This circuit is at steady state. The input to this circuit is the voltage source voltage, vs(t), given by Vs(t) = 22cos(12t + (35° ) v The steady-state mesh current, (t), can be expressed as i(t)-A cos(12t + θ) mA 1809. Determine the values of the constants A and θ: where A and θ are constants such that A > 0...
Example 7.2-3 See Example 7.2-3 in the textbook for the solution to a similar problem. (See Example Z.2-3 in the textbook for the solution to a similar problem.) i(), mA 1 23 (S) -6 123(S) -9 is figure shows a circuit together with two plots. The plots represent the current and voltage of the capacitor in the circuit. Determine the value of the capacitance, C, in mF. 50 c= mF the tolerance is +/-2%
Example 8.3-3 (Companion Problems) (See Example 8.3-3 in the textbook for the solution to a similar problem.) 1-0 50 kQ 20 k2 24 V ( The switch in this circuit has been closed for a long time, and the circuit has reached steady state before the switch opens at time t-0. After the switch opens, the capacitor voltage is given by v)A+ Be v where A, B and a are constants. Determine the values of A, B and a. V...
Please use MATLAB for the specified parts, I appreciate the help! 1. Complex Numbers and phasor analysis can be used to solve many problems. For example if we want to determine the currents of each of the voltage sources in the following circuit, VI ov then we can use a technique called mesh analysis to write mesh equations that involve the currents of each source. Let libe the current of the voltage source vl = 2 cos(t), I be the...