DC Circuits and Ohm’s Law - Memorial University of ... 1051 Laboratory #4 DC Circuits and Ohm’s...
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Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law DC Circuits and Ohm’s Law
Transcript of DC Circuits and Ohm’s Law - Memorial University of ... 1051 Laboratory #4 DC Circuits and Ohm’s...
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
DC Circuits and Ohm’s Law
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Contents
Part I: Objective Part II: Introduction Part III: Apparatus and
Setup
Part IV: Measurements Part V: Analysis Part VI: Summary and
Conclusions
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part I: Objective
In this experiment, you will measure electric potential as a function of current through two different objects. You will use the data to determine which object is ohmic and which is non ohmic. For the ohmic object, you will use your results to find resistance.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part II: Introduction DC Circuits
A DC (direct current) circuit is a circuit in which electric current flows in one direction only.
Current is the time rate of flow of electric charge. The direction of current flow is from positive to negative.
! Current has symbol I
! Current is measured in amperes (A)
Electric potential (or voltage) is a measure of the electric potential energy per unit charge.
! Electric potential has symbol V
! Electric potential is measured in volts (V)
Resistance is a measure of the difficulty of the flow of electric charge.
! Resistance has symbol R
! Resistance is measured in ohms (Ω)
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part II: Introduction Ohm’s Law
The class of materials referred to as ohmic follow Ohm’s Law which states The electric potential V across a conductor is proportional to the current I
through it. The constant of proportionality is the resistance R. In equation form: V = IR
Materials which do not follow Ohm’s law are referred to as non-ohmic.
Examples of ohmic materials are copper and aluminum. Examples of non-ohmic elements are diodes and transistors.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Apparatus
You have been provided with:
! Power suppy ! Multimeters ! Electrical leads (banana-
alligator and banana-banana)
! LED light bulb ! Alligator clips ! Resistor
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Setup circuit
Turn off the power supply and both multimeters. Connect the negative terminal of the power supply to the COM port of the first multimeter. This multimeter will measure the current through the circuit and can be called an ammeter.
Begin to assemble the circuit:
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Setup circuit
Connect the VΩmA port of the first multimeter to one end of the resistor.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Setup circuit Connect the remaining free end of the resistor to the positive terminal of the power supply.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Setup circuit
Connect the COM port of the second multimeter to one end of the resistor.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Setup circuit
Connect the VΩmA port of the second multimeter to the other end of the resistor. This multimeter will measure the potential across the resistor and can be called a voltmeter.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Completed circuit
The circuit is now complete.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Power on Turn down both the voltage and current by turning both the voltage and current control knobs on the power supply all the way counterclockwise.
Turn the power supply on.
Turn the first multimeter (the ammeter) to 200m DCA.
Turn the second multimeter (the voltmeter) to 20 DCV.
It is OK if the readings are negative.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Power up
Turn the current control knob on the power supply about halfway up. Turn up the voltage control knob on the power supply until the power supply reads 20.0 Volts. The multimeters should read
approximately 67 mA and 20 V.
Have an instructor check your setup and initial your lab report.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Caution!
The resistor may get very hot!
Turn the power supply off whenever you are not collecting data.
CAUTION!
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Lab Report
Lab Report 1: Write the objective of your experiment. Lab Report 2: Write the relevant theory of this experiment. Lab Report 3: List your apparatus and sketch your setup.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part IV: Measurements
Turn the power on the power supply.
Record the voltage and current in a table in your lab report.
Turn down the voltage slightly so that it decreases by about 1 V.
Record the voltage and current in your lab report.
By turning the voltage slightly, continue to decrease the voltage in increments of about 1 V recording the voltage and current in your lab report.
When you have finished recording data, turn off the power supply and the multimeters.
Read voltage and current from the multimeters.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part V: Analysis Click the icon to launch Graphical Analysis. Use Graphical Analysis to plot voltage as a function of current for the resistor.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part V: Analysis Lab Report 4: Are the data linear?
Lab Report 5: Is the resistor ohmic or non-ohmic? How can you tell?
In Graphical Analysis, click Analyze then Linear Fit to obtain a linear fit to your data. Double click on the pop-up box and turn on Show Uncertainties.
Print your graph and include it with your lab report.
Lab Report 6: What does the slope of a voltage vs current graph represent? Explain.
Lab Report 7: Using the information from your graph, record the resistance of the resistor with its uncertainty. Compare this value to the value stamped on the resistor. Do they agree? Comment on any differences.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Using the LED
Next we will replace the resistor with the LED-resistor combination. Instructions for the circuit are on the following slides.
Do not disassemble the circuit.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Using the LED Carefully remove the resistor from the circuit without disassembling the remainder of the circuit.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Make sure the power supply and both multimeters are turned off. Connect the lead from the ammeter to the LED bulb side.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Make sure the power supply and both multimeters are turned off. Connect the lead from the positive terminal of the power supply to the resistor side.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Setup circuit
Connect the COM port of the second multimeter to the LED bulb side. Connect the VΩmA port to the resistor side.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Completed circuit
The circuit is now complete.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Power on
Turn the power supply on.
Turn the first multimeter (the ammeter) to 20m DCA.
Turn the second multimeter (the voltmeter) to 20 DCV.
It is OK if the readings are negative.
Turn down both the voltage and current by turning both the voltage and current control knobs on the power supply all the way counterclockwise.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part III: Apparatus and setup Power up
Turn the current control knob on the power supply about halfway up. Do not adjust the voltage control yet.
The multimeters should read approximately 0 mA and 0 V.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part IV: Measurements LEDs are strange
Record the voltage and current in a table in your lab report.
Turn up the voltage slightly so that the voltage increases by about 0.5 V.
Record the voltage and current in your lab report.
Continue to increase the voltage in increments of about 0.5 V until the LED lights or the current is non zero.
Record the voltage and current in your lab report.
You will notice that as you initially increase voltage, the current remains at zero. Once current begins to flow, the LED will light and the current will vary with voltage.
Read voltage and current from the multimeters.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part IV: Measurements LEDs are strange
Once the LED lights, increase voltage in increments of 0.1 V.
Record the current and voltage in your lab report.
Continue to increase the voltage in increments of about 0.1 V until a maximum value is reached.
Do not exceed 3.5 V or 15 mA.
Turn off the power supply and the multimeters once you are finished collecting data.
Read voltage and current from the multimeters.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part V: Analysis
Lab Report 7: Are the data linear?
Lab Report 8: Is the LED bulb ohmic or non-ohmic? How can you tell?.
Print your graph and include it with your lab report.
Click the icon to launch Graphical Analysis. Use Graphical Analysis to plot voltage as a function of current for the LED.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Part VI: Summary and Conclusions Lab Report 9: Outline briefly the steps of your experiment. Lab Report 10: List your experimental results and comment on
how they agreed with the expected results. Lab Report 11: List at least three sources of experimental
uncertainty and classify them as random or systematic.
Physics 1051 Laboratory #4 DC Circuits and Ohm’s Law
Wrap it up!
Check that you have completed your Lab Report.
Your report should include copies of the voltage vs current graphs.
