Procedure:
Open Multisim Software
Program Files -> National Instruments (folder) -> Circuit Design Suite -> Multisim
START A NEW PROJECT BY GOING TO FILE>NEW>NI ELVIS I Design. You will get a workspace that has the connections you will find on our ELVIS board. Later we will see a 3-D Model of the ELVIS Board.
On every Design sheet from the top menu “Place” find “Text” and write your:
Name
ENGR 2140A
Date
YOU WILL LOSE POINTS FOR EVERY CIRCUIT IMAGE THAT DOES NOT HAVE THIS
Part 1: Build a Voltage Divider and Test it with Loads.
Construct a voltage divider with a 12V source and use 1000, 2000 and 3000 Ohms to divide the voltage into 10V and 6V at nodes in the circuit. Va, Vb, Vc are the connection points you will use to load to the circuit at 12, 10 and 6V. You will want to put voltage indicators on each one connected between ground and each test point. This will save you time when you put the load on the circuit, to see the voltage change at the connection point when you add a load. To get the 12 V source, can go to Simulate > Instruments >NI ELVIS mx instruments > NI ElVIS Variable Power Supply just like you would see in the ELVIS Instrument panel. But to simplify this circuit INSTEAD USE DC POWER SUPPLY FOR 12V SO YOU HAVE A BATTERY ON THE BOARD. This will make the 3-D circuit construction easier later.
Insert the image of your voltage divider circuit here. It does not need the extra labels that mine has, but make sure the voltage indicators are included and show that you have the correct voltages. Do NOT have a load resistor yet on this circuit:
To load the circuit you will place one resistor between ground and either Va, Vb or Vc. You will only have one load resistor on the circuit at any one time, unused connection points remain unattached!!!
You can use Excel to do the calculations to save time filling in the chart.
Location to measure Voltage
Load Resistor connected at that location
Expected voltage (with no load)
Measured voltage (with specified load)
% difference (Difference divided by expected)
Power delivered to load resistor using measured voltage.
P = (V^2)/R
Vc
1kOhm
6 V
Vc
4.7 kOhm
6 V
Vc
10 kOhm
6 V
Vc
20 kOhm
6 V
Vc
100 kOhm
6 V
Vb
1kOhm
10 V
Vb
4.7 kOhm
10 V
Vb
10 kOhm
10 V
Vb
20 kOhm
10 V
Vb
100 kOhm
10 V
Va
1kOhm
12 V
Va
4.7 kOhm
12 V
Va
10 kOhm
12 V
Va
20 kOhm
12 V
Va
100 kOhm
12 V
Which load affected the voltage divider the most (highest % difference)? ____________________
Why? ________________________________________________________________________
Which load value resulted in the highest power dissipated in the load resistor at Va?_____________
Why? _______________________________________________________________________________
Which load value resulted in the highest power dissipated in the load resistor at Vb? ____________
Which load value resulted in the highest power dissipated in the load resistor at Vc?_____________
Is it the same load resistor for max power transfer for Vb and Vc? _________________
We will eventually learn how to calculate the load resistance that allows maximum power transfer. But for now, you should see that if the battery is not controlling the voltage directly, adding a load to a voltage divider changes the circuit, and each connection point in the voltage divider has a different load resistance value for maximum power transfer.
USE EXCEL TO MAKE A GRAPH OF THE DATA IN YOU COLLECTED THAT MEETS THE FOLLOWING CRITERIA:
· Your graph should be a scatter plot and show measured voltage on the Y axis and Load Resistance on the X Axis
· Each axis is labeled and shows the units.
· The graph should have 3 lines on it, representing the measured values at Va, Vb and Vc at the different load resistances.
· Have a legend so that each line has its own color and is clearly labeled Va, Vb, Vc.
· Have your Name, Date and ENGR 2140 in the title of the graph.
· If you don’t know how to make a graph in excel, use this reference. I recommend http://www.excel-easy.com/examples/scatter-chart.html as a simple example. You can look up others.
· PASTE THE GRAPH HERE:
Part 2. Building a virtual circuit on a breadboard.
Remember how the holes in the board are connected as you build the circuit (as seen below). THE ENDS OF A 2-TERMINAL COMPONENT SHOULD NEVER BE CONNECTED TOGETHER, YOU JUST BYPASSED IT AND MAY HURT YOUR CIRCUIT OR DEVICES.
http://mbed.org/media/uploads/mbedofficial/breadboardconnections.jpg
A VOLTAGE SHOULD NEVER BE CONNECTED DIRECTLY TO GROUND!!!
Take your voltage divider circuit and put it in a configuration with a 1.5 kOhm load resistor attached to Vc as your load. Remove all multimeters and indicators from your circuit. Look for an option at the center top of the program to construct a breadboard layout of your circuit (it will be an icon that looks like a breadboard and say “view breadboard” when you hover over it. Selecting it will give you a 3D breadboard and the parts you need to populate your board. Add the components to the breadboard and include wires by clicking on blank holes to add any additional connections. The battery can be placed anywhere, but it is recommended that you connect the positive side to the red bus and the negative side to the blue bus. On some boards the busses break in the middle of the board. You need to add jumpers to activate the full bus if this happens (with standard bread board, but not ELVIS). When you hover over a point to place connector, green squares will appear to show you the other connection points for that hole. Once you have placed everything on the board, go to Tools and select “DRC and Connectivity check” this will tell you if you have any errors. Check to make sure your resistors are in the right order. Pay attention to device names and the order to be error free. The breadboard must be exactly like your diagram to be error free. Pay close attention to every detail, component name and connection. Also make sure you connect your circuit to the board’s ground.
TAKE A SCREENSHOT OF YOUR completed 3-D BREADBOARD CIRCUIT AND ATTACH HERE:
(Make sure I can see at the bottom the display that says “Design Rule Check – 0 Design Rule Errors Found” so I know you did it correctly)
When done, submit this assignment in Blackboard, in the Labs folder.