Find the Thé venin equivalent network seen from node a tob in Figure P3.64. Let
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Principles and Applications of Electrical Engineering
- Q3) For the network shown in the figure below, determine the following: a) fe b) Zinl and Zin2 c) Zo1 and Zo2 d) Avı, Av2, and AVT +20 V 6.8 kQ 30 ka 6.8 ka 30 ka 0.5 F 0.5 uF P-150 B- 150 1.5 ka 50 uF 1.5 ka 50 uFarrow_forwardFind the Thévenin equivalent of the circuitconnected to RL in Figure P3.58, where R1 = 10Ω ,R2 = 20 Ω, Rg = 0.1 Ω, and Rp = 1 Ω.arrow_forward8-13 E (a) Formulate mesh-current equations for the cir- cuit in Figure P3-13. (b) Formulate node-voltage equations for the circuit in Figure P3-13. (c) Which set of equations would be easier to solve? Why? (d) Using MATLAB, find , and i, in terms of the mesh- current variables. SSarrow_forward
- Refer to the given circuit below. Using Superposition Theorem, determine the percent contribution of E₁ to the current through R3 (lbc)- R3E1 % contribution = x 100 R3E1+1R3E2+¹R31 R1 R2 R3 R4 E₁ E2 T 8 Ω 6Q 4Q 7 V 11 V 5 A R₂ C ΤΩ R₁ E₁ a b R3 RA E₂arrow_forwardRA R3 V2 D. R2 R1 For the above circuit, select ALL the extraordinary nodes that are part of a quasi-supernode. If there are none then select NONE. Note: a supernode is not a quasi-supernode. O NONE B. ODOarrow_forwardRefer to the given circuit below. Using Superposition Theorem, determine the percent contribution of I to the current through R3 (lbc). IR31 % contribution = x 100 1 +1 +1 R3E1 "R3E2 R3 R4 E1 E2 I 6Q 1Q 9 V 7V 3A a R31 R1 2Q R1 R2 1Q E₁ R2 C b R3 R4 E2arrow_forward
- O Given the information appearing in the Figure, Fird the level of resistance for Ri e R3. RI 3 o 14V Rgarrow_forward(b) In the circuit shown in Figure Q3(b), (i) Find the value of open circuit voltage, VTH and equivalent resistance, Rth at terminal a-b. (ii) Draw the Thevenin equivalent circuit at terminal a-b. 5000 a 6mA 5002 5V 4002 b Figure Q3(b)arrow_forward(b) Prove the circuit in Figure Q.5 can perform the operation of adder/subtractor by completing Table Q.5. -Sub FA FA FA FA Figure Q.5 Table Q.5 B[3:0] Sub A[3:0] C4 S[3:0] Operation 0111 1000 1 0111 1000arrow_forward
- 6. A Thevenin de equivalent circuit always consists of an equivalent.. a. AC voltage source b. capacitance c. DC voltage source d, resistance 7. The superposition theorem is useful for the analysis of. ***** a. single-source circuits. b. only two-source circuits. c. multi-source circuits. d. no source circuits.arrow_forwardWith reference to Figure P3.40, determine thecurrent through R1 due only to the source VS2.VS1 = 110 V VS2 = 90 VR1 = 560 Ω R2 = 3.5 kΩR3 = 810 Ωarrow_forwardfind Rt, It, Pt, P1, P2, P3P4,P5,P6arrow_forward
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