graphing
DESCRIPTION
Physics lab. introduction and how to graphingTRANSCRIPT
General Physics Lab.
Dr. Said Azar
Experiments Outline
➲ Exp. 1: Measurements in Physics
➲ Exp. 2: Errors and Uncertainty
➲ Exp. 3: Simple Pendulum
➲ Exp. 4: Force Table
➲ Exp. 5: Hook’s Law
➲ Exp. 6:Ohm’s Law ➲ Exp. 7: Viscosity
➲ Exp. 8: Prism and Refraction
Report
➲ Experiment Title (عنوان التجربة)
➲ Experiment Purposes (Goals) (اهداف التجربة)
➲ Experiment Procedure (اجراءات التجربة)
➲ Experiment Theory (نظرية التجربة)
➲ Data Analysis and Interpretation (تحليل و تفسير النتائج)
➲ Conclusion (االستنتاج)
Graphing
Most people at one time or another during their careers will have to interpret data presented in graphical form.
This means of presenting data allows one to discover trends, make predictions, etc.
To take seemingly unrelated sets of numbers (data) and make sense out of them is important to a host of disciplines.
An example of graphing techniques used in physics follows.
➲ When weight is added to a spring hanging from the ceiling, the spring stretches.
➲ How much it stretches depends on how much weight is added.
➲ The following slide depicts this experiment.
Starting levelAdd a mass
We control the mass that is added.It is the independent variable.The stretch is dependent on what mass is added.It is the dependent variable.
Stretch is now hereAdd another massStretch is now here
➲ The following data were obtained by adding several different amounts of weight to a spring and measuring the corresponding stretch.
Stretch (meters)
Weight (Newtons)
0.1240 6.0
0.1475 14.0
0.1775 22.0
0.1950 30.0
0.2195 38.0
0.2300 40.0
0.2525 47.0
0.2675 54.0
0.2875 58.0
The Newton is a
unit of force or weight
➲ There are two variables or parameters that can change during the experiment, weight and stretch.
➲ As mentioned earlier the experimenter controls the amount of weight to be added.
➲ The weight is therefore called the independent variable.
➲ Again as mentioned before the amount that the spring stretches depends on how much weight is added. Hence the stretch is called the dependent variable.
➲ The dependent variable is the quantity that depends on the independent variable.
➲ A graph of this experimental data is shown on the next slide.
➲ The independent variable is always plotted on the horizontal axis, the abscissa.
➲ The dependent variable is plotted on the vertical axis, the ordinate.
➲ Notice that each axis is not only labeled as to what is plotted on it, but also, the units in which the variable is displayed.
➲ Units are important.
Each graph should be identified with a title and the experimenter's name.Weight, the independent variable, will be plotted along the horizontal axis (the abscissa).
Weight (Newtons)
0 10 20 30 40 50 60
Stretch, the dependent variable, will be plotted along the vertical axis (the ordinate).
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30Stretch Versus Weight - Mohmmad
The graph should be made so that the data fills as much of the page as possible. To do this, sometimes it is better not to start numbering an axis at zero, but rather a value near the first data point.
Each data point should be circled, so that it can be easily found and distinguished from other dots on the paper.
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30Stretch Versus Weight - Mohmmad
This is not a connect-the-dot exercise.
The data appears to fit a straight line somewhat like this one.
Let’s plot the data.
(6.0, 0.1240)
(14.0, 0.1475)
(22.0, 0.1775)
(38.0, 0.2195)(40.0, 0.2300)
(47.0, 0.2525)
(54.0, 0.2675)
(58.0, 0.2875)
(30.0, 0.1950)
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30Stretch Versus Weight - Susie Que
If there is a general trend to the data, then a best-fit curve describing this trend can be drawn. In this example the data points approximately fall along a straight line. This implies a linear relationship between the stretch and the weight.A wealth of information can be obtained if the equation that describes the data is known. With an equation one is able to predict what values the variables will have well beyond the scope or boundaries of the graph. A timid mathematician should not be scared away, since finding the equation is not hard and requires very little knowledge of math.
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30Stretch Versus Weight - Susie Que
If data points follow a linear relationship (straight line), the equation describing this line is of the form
y = mx + b
where y represents the dependent variable
(in this case, stretch), and
x represents the independent variable (weight).
A very importantequation.
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30Stretch Versus Weight - Susie Que
y = mx + b
The value of the dependent variable when x = 0
is given by b and is known as the y-intercept.
The y-intercept is found graphically by finding
the intersection of the y-axis (x = 0) and the
smooth curve through the data points.
(From the equation y = mx + b, if we set x = 0
then y = b.)
In this case b = 0.11 meters.
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30Stretch Versus Weight - Susie Que
The quantity m is the slope of the best-fit line.
It is found by taking any two points,
for instance (x2, y2) and (x1, y1), on the straight
line and subtracting their respective x and y values.
Note
y2 = mx2 + b
y1 = mx1 + b
Subtracting one equation from the other yields
y2 - y1 = mx2 - mx1
y2 - y1 = m(x2 -x1) 12
12
xx
yy=m
run
rise=
We’ll call this
y = mx + b
Therefore
slope
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30
y-intercept = 0.11 meters
Stretch Versus Weight - Mohmmad
run = (34.0 – 17.0) Newtons = 17.0 Newtons
rise = (0.21 – 0.16) meters = 0.05 meters
Newtons
meters=17.0
0.05Newtonmeters= /0.00294
run
rise=
To find the slope of this line pick a couple of points on the line that are somewhat separated from each other.
17.0
0.16
34.0
0.21
Y1 =
Y2 =
X2 =X1 =
Point 2
Point 1
y = mx + bb+
+ ( 0 . 11 meters )
slope
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30
y-intercept = 0.11 meters
Stretch Versus Weight - Mohammad
Newtons
meters=17.0
0.05Newtonmeters= /0.00294
run
rise=
At this point everything needed to write the
equation describing the data has been found.
Recall that this equation is of the formy = mx
Stretch =( 0 . 00294 meters / Newton ) ¿ Weight
0.11 meters
b+
+ ( 0 . 11 meters )
Weight (Newtons)
0 10 20 30 40 50 60
Stre
tch
(mete
rs)
0.10
0.14
0.18
0.22
0.26
0.30Stretch Versus Weight - Mohammad
Here are two ways we can gain useful
information from the graph and from the
equation of the line.
If we wanted to know how much weight
would give us a 0.14 m stretch, we could
read it from the plot thusly.
This would be about 10.2 Newtons.
Solving the equation for x when y=0.14 m
gives
x=10.2 Newtons.
y = mx
Stretch =( 0 . 00294 meters / Newton ) ¿ Weight
A curve through this data is not straight and x and y are not linearly related. Their relationship could be complicated.
y2y
x0 10 20 30 40 50 60
0
1
2
3
4
5
6
Suppose you have some x and y data related to each other in the following way.
A replot of this data might straighten this line some to give a linear relationship.
Let’s try y2 versus x.
This relationship would be
b+mx=y2
In the earlier example of stretch vs. weight
one over the slope of this curve is called
the spring constant of the spring.
This method of determining the spring constant of a spring is better than alternate methods such as
calculating the spring constants of individual measurements and taking an average or
taking an average of weights and dividing by an average of the stretches.
Graphing is a powerful analytical tool.
The information on this slide will most likely be on the lab final exam.