Difference between revisions of "Lab 1 RS"

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Determine the maximum voltage of the DC power supply you will use. (ie, 30 Volts)
 
Determine the maximum voltage of the DC power supply you will use. (ie, 30 Volts)
  
;<math> P =I^2R = V^2/R \Rightarrow R = \frac{V^2}{P} > \frac{\left (30 V \right)^2}{1/4 \mbox{Watt}} > 3600 \Omega</math>
+
;<math> P =I^2R = V^2/R \Rightarrow R = \frac{V^2}{P} > \frac{\left (30 V \right)^2}{1/4\ \mbox{Watt}} > 3600 \Omega</math>
  
 
:By keeping your resistance values above 3600 <math>\Omega</math> you should be able to avoid burning up 1/4 Watt resistors when your max voltage is 30 Volts.
 
:By keeping your resistance values above 3600 <math>\Omega</math> you should be able to avoid burning up 1/4 Watt resistors when your max voltage is 30 Volts.
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c.) compare your predictions and measurements  by filling in the table below.
 
c.) compare your predictions and measurements  by filling in the table below.
  
{| border="3"  cellpadding="20" cellspacing="0"
+
{| border="1"  cellpadding="10" cellspacing="0"
 
|Variable ||Measured Value|| Predicted Value|| % Difference
 
|Variable ||Measured Value|| Predicted Value|| % Difference
 
|-
 
|-
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|-
 
|-
 
| <math>I_3</math> || <math>(0.144\pm 0.005)</math> mA|| <math>(0.144\pm 0.005)</math> mA|| 0.00 %  
 
| <math>I_3</math> || <math>(0.144\pm 0.005)</math> mA|| <math>(0.144\pm 0.005)</math> mA|| 0.00 %  
|}
+
|}<br>
  
 
= Internal resistance (30 pnts)=
 
= Internal resistance (30 pnts)=
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{| border="3"  cellpadding="20" cellspacing="0"
+
{| border="1"  cellpadding="10" cellspacing="0"
 
| <math>R_{Load}</math> (<math>\Omega</math>) || V (Volts)|| I (mA)
 
| <math>R_{Load}</math> (<math>\Omega</math>) || V (Volts)|| I (mA)
 
|-
 
|-
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[[File:RS lab1 pic4.png | 700px]]
[[File:RS lab1 pic4.png | 600px]]
+
<br>
  
 
=Questions (20 pnts)=
 
=Questions (20 pnts)=

Latest revision as of 06:49, 23 January 2011

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Kirchoff's Law (50 pnts)

Smokey Circuits

When doing these labs it is important to determine the limitations of your electrical components in order to avoid damaging them.

This lab uses resistors. Resistors are vulnerable to melting if you push too much current through them.

Resistors have power ratings ranging from 1/8 Watt up to several Watts. The common resistors are rated at 1/4 Watt. Let's assume this rating for the resistors in this lab.

Determine the maximum voltage of the DC power supply you will use. (ie, 30 Volts)

[math] P =I^2R = V^2/R \Rightarrow R = \frac{V^2}{P} \gt \frac{\left (30 V \right)^2}{1/4\ \mbox{Watt}} \gt 3600 \Omega[/math]
By keeping your resistance values above 3600 [math]\Omega[/math] you should be able to avoid burning up 1/4 Watt resistors when your max voltage is 30 Volts.

The next objective is to use resistors which allow currents that you can measure with your voltmeter.

Since [math]V=IR \Rightarrow I = V/R = 30 \mbox{Volts}/3600 \Omega = 8\mbox{mA}[/math]

Determine the range of currents which the voltmeter can measure. (ie 1 mA)

To get measurable currents you need low resistance BUT the lower resistances will need to have a high power rating. These two competing properties limit the range of resistances you can use.


Select the three resistors you should use for this experiment.

Construct the circuit below

TF EIM Lab1.png

Enter the values of the DC voltage and Resisters that you used.

Use a voltmeter to measure the potential difference and resistances.

Variable Measured Value
[math]V_A [/math] [math] (1.570 \pm 0.0005)[/math] V
[math]R_1[/math] [math] (99.4 \pm 0.05)[/math] [math]\Omega[/math]
[math]R_2[/math] [math] (0.99 \pm 0.005)[/math] k[math]\Omega[/math]
[math]R_3[/math] [math] (9.79 \pm 0.005)[/math] k[math]\Omega[/math]

Enter the measured and predicted quantities in the table below

Given [math]V_A[/math] and the values of all resistors, use Kirchoff's laws to predict

a.) Predict the value of [math]V_B[/math]

b.) Predict the values of the three currents.

Derivation.png

c.) compare your predictions and measurements by filling in the table below.

Variable Measured Value Predicted Value % Difference
[math]V_B[/math] [math](1.413\pm 0.0005)[/math] V [math](1.414\pm 0.0005)[/math] V 0.07 %
[math]I_1[/math] [math](1.57\pm 0.005)[/math] mA [math](1.57\pm 0.005)[/math] mA 0.00 %
[math]I_2[/math] [math](1.43\pm 0.005)[/math] mA [math](1.43\pm 0.005)[/math] mA 0.00 %
[math]I_3[/math] [math](0.144\pm 0.005)[/math] mA [math](0.144\pm 0.005)[/math] mA 0.00 %


Internal resistance (30 pnts)

Measure the internal resistance of a "D" cell battery by graphing the current on the x-axis and the measured voltage on the y-axis for several values of the resistance [math]R_L[/math] shown in the circuit below. Begin with [math]R_L = 1k\Omega[/math] and then decrease it by a factor of 5 for each subsequent measurement. You can use a volt meter to measure the current and potential difference.

TF EIM Lab1a fig.png


[math]R_{Load}[/math] ([math]\Omega[/math]) V (Volts) I (mA)
[math](990\pm 0.5)[/math] [math](1.581\pm 0.0005)[/math] [math](1.60\pm 0.005)[/math]
[math](99.4\pm 0.05)[/math] [math](1.570\pm 0.0005)[/math] [math](15.60\pm 0.005)[/math]
[math](46.3\pm 0.05)[/math] [math](1.560\pm 0.0005)[/math] [math](32.41\pm 0.005)[/math]
[math](10.3\pm 0.05)[/math] [math](1.505\pm 0.0005)[/math] [math](123.5\pm 0.05)[/math]
[math](0.47\pm 0.005)[/math] [math](0.960\pm 0.0005)[/math] [math](1210\pm 50)[/math]


RS lab1 pic4.png

Questions (20 pnts)

  1. What conservation law is involved in Kirchoff's Loop Theorem?
The Energy Conservation Law.
  1. What does the slope in the internal resistance plot above represent?
[math]V_{\mbox{terminal}} = V_{\mbox{bat}} - V_{\mbox{internal}} = V_{\mbox{bat}} - IR_{\mbox{internal}}[/math]
The slop of line will represent the internal resistance of battery with minus sign. 


Forest_Electronic_Instrumentation_and_Measurement

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