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38. Determine the voltage between points A and B in each voltage divider of Figure 5–80....
Determine the voltage with respect to ground at each point shown in the figure. Consider the practical model D R D2 А B с D 1.0k12 VSI 25 V 8V =
can you solve this 5 problem please Q2. Using voltage divider and/or current divider to find the unknown on each of the circuits: 40 V -) ) ξR, υ ξR, 6 Ω 20 Ωξυ, 2.4A 1) 1890 Ω ξ10Ω 10 Ω ξ5 kΩ 360 kΩ 45 VI + υ, ξ 20 kΩ ξ90 ΚΩ Q3. Using a Y to delta transformation find the currents il, i2, and i3. And the power delivered by the source. 56 Ω 44Ω 80 Ω...
In the voltage-divider circuit shown in the figure, the no-load value of vo is 5 V When the load resistance RI is attached across the terminals a and b, vo drops to 3 V.(Figure 1) PartA Find RL Express your answer with the appropriate units RI-7.28 Submit Previous Answers Request Answer Incorrect, Try Again: One attempt remaining Provide Feedback igure 1 of 1 40Ω 20 V R2 vo
(a) Explain physically how ap-n junction functions as a rectifier diode. (5 marks) Figure Q5(b) shows a Voltage divider bias circuit for a BJT. Given that; Vcc 18 V, BDC (b) 120. 18 V 3.3 kQ C2 39.0 kO 10 μF C1 B 120 10 μΕ 1.0 kQ 8.2 kQ Figure Q5(b) Voltage divider bias configuration of BJT Calculate Ic and VCE using exact method. (i) (5 marks) Repeat the calculation of Ic and VCE using approximate method. (ii) (3...
Given: IDSS 15mA; VGS(off)-8v, determine the a. ID b. VGS c. VDS d. Av (voltage gain) +5 V 1.2kn 2.2 kn 0.1 μF -3.8 mS 22 kΩ 0.1 μF 0.1 μF 4.7 MII o kn 10 MI 560 Ω 0.1 μF Given: IDSS 15mA; VGS(off)-8v, determine the a. ID b. VGS c. VDS d. Av (voltage gain) +5 V 1.2kn 2.2 kn 0.1 μF -3.8 mS 22 kΩ 0.1 μF 0.1 μF 4.7 MII o kn 10 MI 560 Ω...
Q1. (3 marks) In the circuit shown below, R-1.5KO and the voltage drop across Ri is 4.5V. (1 pt.) A. What is the voltage drop across R? (1 pt.) B. What is the value of the resistance R? (1 pt.) C. What is the power delivered by the source voltage? S Answer: wwiw R Ri Vs=15V Q2. (3 marks) Refer to the circuit below. A. Using the voltage divider law, find the voltage between the points A and B. B....
3. A) Use node-voltage analysis to determine the Thevenin voltage between points A and B in this circuit. B) determine the Thevenin resistance between points A and B. 9.00V 14.0V 一日 <5602 S8102 47021 10000
Problem 3. (38% ) Determine the internal normal force, shear force, and moment at points A and B in the frame. The supports at C and D are both pins. Present a F.B.D. for each analysis performed. KN 4(3)-12KN 4 kN/m Cak Cy 2 m 12, KN A 1.5 1-5m 1m- 1 m m. Crt (タニP× 1Z k Thar EMC-0 -12 (1.5) P (2) =o Bh-C=O Dry. -9KN FrD A-(121-6 EMc-o (e.6) M Problem 3. (38% ) Determine the internal...
Determine the voltage between nodes A and B in the circuit shown in the given figure. Given: Vs - 12 V Ry - 13 kg Ry - 221 ko R3 = 7,1 ko RA - 0.22 MO АС VO -OB The voltage between nodes A and B in the circuit is V. (Round the final answer to three decimal places.)
b) For the circuit shown in Figure Q1(b) below, the voltage source is 18 V. Determine Vo, Voz and /. [CO2/PO3/C4] (10 marks) Vo1 0.47 k 1 ka Vo2 Si 18 V Si Figure Q1(b) For the circuit shown in Figure Q1(b) below, the voltage source is 18 V. Determine b) Vot, Voz and / [CO2/PO3/C4] (10 marks) Vof 1 ka 0.47 kn Vo2 ZSI 18 V Figure Q1(b) ) Figure Q1(c) shows a basic voltage regulator circuit. Determine Vi,...