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Week 5

Week 5. Experiments 8 and 9. Lecture Schedule. Next week (9/29/2011) Topics of lectures are: Design a Voltmeter You have two weeks to perform this lab Make-up Lab #1 Pre-Lab Report due 10/4/2011 Validation due 10/5/2011 Post-Validation Report due 10/7/2011 Following week (10/6/2011)

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Week 5

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  1. Week 5 Experiments 8 and 9

  2. Lecture Schedule • Next week (9/29/2011) • Topics of lectures are: • Design a Voltmeter • You have two weeks to perform this lab • Make-up Lab #1 • Pre-Lab Report due 10/4/2011 • Validation due 10/5/2011 • Post-Validation Report due 10/7/2011 • Following week (10/6/2011) • No lab lecture

  3. Same Circuit: Experiment 8 and 9 You should use the +5V and +9V supplies on the ANDY board. You should use red wire to bring the +5V and +9V from the block terminals to the breadboard.

  4. Shared and Distributed Nodes X and Y are distributed nodes. The voltage is the same at all points along the wires. Since there is a dot where the horizontal wire crosses the vertical wire between the +5V supply and R3, the wires are connected.

  5. Redrawing the Circuit

  6. Labeling Nodes Left click on the wire attached to the node that you want to label. Go to Edit/Label and enter the name of the node in the Set Attribute Value pop-up window and click OK. Alternatively, just double click on the wire and the Set Attribute Value window will open.

  7. Setting Resistor Tolerance - Schematics • Double click on the resistor • In the pop-up window entitled Part Name, click on the part attribute called Tolerance. • In the window below VALUE, enter 5% and then click Save Attr and then click OK. • 5% will appear next to the resistor symbol.

  8. Setting Resistor Tolerance - Capture • Double click on a resistor, which launched a pop-up window entitled Property Editor. • Change the entry after Filtered by: to <Current Properties> if not already set to this. • Scroll across the properties until you find TOLERANCE. • Type 5% into the window below TOLERANCE and then close the pop-up window.

  9. For all Pspice Programs • If you make the change to the TOLERANCE on the first resistor that you place in the circuit and then copy the resistor to place the other resistors into the circuit, you only need to modify the TOLERANCE of the resistors once. • If you place all of the resistors into the circuit before changing the properties, you will need to click on each resistor and enter ‘5%’ into TOLERANCE.

  10. To Find How PSpice has Labeled Nodes • Open a Netlist • This is created automatically when you run a simulation. You can generate it before running a simulation by: • In Capture • Select PSpice/Create Netlist • Then select PSpice/View Netlist • In Schematics • Select Analysis/Create Netlist • Then select Analysis/Examine Netlist

  11. Netlist • Listed are all of the components in the circuit • The strings starting with an N are the number of the nodes that the component is attached to. • For example, R3 is connected to nodes N00043 and 0 (ground). The node N00043 is shared with R4 and R5. • Note that the list also shows which of the resistors have had the tolerance changed.

  12. Setting up a Monte Carlo Simulation • Monte Carlo simulations in PSpice can be run as either: • a worst case analysis where the maximum deviation from the nominal values of each component are used in the calculations • a statistically-driven variation from the nominal values of the components using a bell shaped curve for the distribution of deviations.

  13. Monte Carlo • Set up a Simulation Run • You must select one of the other types of analysis first • Click on DC Sweep • Pick either of the voltage sources to sweep • Make both the start and end values equal to the value of the voltage source, pick any value for the increment, and click OK. • Then, select Monte Carlo/Worst Case • Enter V(node name) or V(component:node) • Note that you will also have to put a voltage marker on to the circuit schematic no matter what you put as the output variable • Enter the number of runs (500 is recommended) • In Capture, pick a random number between 1 and 32767 and select uniform for the distribution. • Do not unselect the Bias Point Detail

  14. Output Plot

  15. Finding the Thevenin Equivalent Resistance • There are several methods that can be used to determine the Thevenin equivalent resistance, RTH, of a circuit. • Find the open circuit voltage and short circuit current: RTH = VOC/ISC Also used in calculating the Load Line of a circuit, which will be used frequently in ECE 2204 and 3204. • Source transformation Norton/Thevenin Conversions - emphasized in the lecture portion of the course.

  16. Determine VOC Replace R5 with an open circuit and determine the voltage across the nodes where R5 had been attached (Nodes X and Y).

  17. The polarity of VOC is not important when calculating RTH. However, the way you orient the +/_ signs for VOC will determine the direction of the short circuit current, which will be calculated next. The value of VOC is the final Thevenin equivalent voltage source for the circuit.

  18. Determine ISC Replace R5 with a short circuit and determine the current that flows through the short circuit between the nodes where R5 had been attached (Nodes X and Y).

  19. The short circuit current should flow out of the – side of the open circuit voltage. RTH = VOC /ISC The value of ISC is the final Norton equivalent current source for circuit.

  20. Thevenin Equivalent Circuit • For this week’s experiment, we will use the function generator with constant.lib to create a d.c. voltage for Vth, which is equal to the open circuit voltage Voc. • Rth is: • the equivalent resistance of the circuit without the 680 W resistor in it and with the two voltage supplies replaced with short circuits. • equal to Voc/ Isc.

  21. Creating Vth • One technique is to use a voltage divider.

  22. Source Transformations By choosing appropriate values for R1 and R2, the Thevenin resistor, Rth, in the final transformation will have the same value as Rth calculated for the circuit in Experiment 8 and 9.

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