1. Find the Thévenin equivalent of the circuit below by calculating the open-circuit voltage and the...
The circuit below can be used to simulate/measure the equivalent resistance of a circuit. The voltage from V, to ground will be the equivalent resistance because V-IR and in this case the current source ll is equal to 1 Amp. Note that in general Amp.s not used by a resistance meter as it can cause a too much power to be dissipated by the resistor which can burn out the resistor or change its value.) Create the circuit shown below...
In this procedure, you get to write and execute an experimental procedure to find a Thévenin equivalent model for a Light Emitting Diode (LED) The simplest model for a diode is as a switch that is on (short circuit) when current tries to flow in the direction of the arrow in the diode symbol, and off (open circuit) when the current ties to flow in the direction opposite to the arrow. This model doesn't work all that well for an...
1) enin equivalent. one source. The purpose of this part is to find the Thévenin cquivalent of a circuit with one source by measuring find Vo and Isc a) Construct the circuit of Figure 7. Choose R1 = R2 R, 히0kΩ and set the value ofl.-6V using the 10V b) Measure the open-circuit voltage, V and the short-circuit current, I se, and thereby find Vy,and Rm Note: Do c) Using PSpice, create a simulation of the circuit. Attach a current...
Find the Thévenin equivalent with respect to the terminals a,b for the circuit in (Figure 1) if v = 360 V, i = 4 A. Figure 1 of 1The figure shows a rectangular circuit. A vertical cross wire connects the top and bottom wires. An 8-ohm resistor is located on this cross wire. A 40-ohm and a 10-ohm resistors are located on the top wire to the left and right from the cross wire, respectively. Independent voltage source v, with...
Find the Thevenin equivalent with respect to the terminals a, b of the circuit shown using node analysis. The voltage-dependent current source G1 depends on the voltage across a and b and has a gain of 0.01. Units for R1 R2 L1 C1 are Ohms, H and F, respectively. The linear frequency is 50Hz. 1-1 Derive a formula for Vth in terms of all of the variables in the circuit. Please upload a file showing all your work for this...
Find the Thevenin equivalent with respect to the terminals a, b of the circuit shown using node analysis. The voltage-dependent current source G1 depends on the voltage across a and b and has a gain of 0.01. Units for R1 R2 L1 C1 are Ohms, H, and F, respectively. The linear frequency is 50Hz. 1-1 Derive a formula for Vth in terms of all of the variables in the circuit. Please upload a file showing all your work for this...
2. (2000) Electromagnetics (DC Circuit) Problem a. Calculate the voltages across all resistors and the currents through all the resistors and voltage sources in the following circuit using Kirchhoff's junction rule (nodal analysis). Show the directions initially assumed for the junction (node) currents. Use the minimum number of junctions (nodes) necessary to accomplish this b. Calculate the power dissipation in each resistor and the sum (or total) of these individual power dissipation values c. Calculate the power associated with each...
Please find the thevenin equivalent first as suggested 3. In the circuit below, R1 10k, R2 20k and C 0.1uF. At t0, a step function of 10 V magnitude is applied to the input. Find V(t) at the output and sketch it. Your sketch should be quantitatively correct, that is, it should have labeled V and t axes. Strongly suggested: solve by first finding the Thévenin equivalent of the source voltage and resistor network Input (problem 3) 10V IN R2...
1) In the circuit below the currents are named A, and lc The current direction is determined by the source (out of positive terminal) in the middle and right branches and is clockwise in the left branch · IA flows through R2 and R1 Is flows through R4 and Vb cflows through R3, Vc AB R2 R3 R4 R1 Vb a) Draw the circuit and show the 3 currents described above, including arrows showing the current direction. Show the voltage...
Apply the following questions to both the circuit shown in Figure (a) (resistors in series) and the circuit shown in Figure (b) (resistors in parallel). (a) Use Ohm's law with Kirchhoff's current and voltage laws to derive equations for currents i1, i2 and i (through Resistor R1, resistor R2, and the voltage source , respectively) in terms of R1, R2, and v. (b) R1 and R2 can be interchanged with an equivalent resistor rith resistance R without changing the values...