Pendulum Mock Lab. Part 1: Experimental Design Focused Research Question: I will investigate how the...

Pendulum Mock LabPendulum Mock Lab

Part 1: Experimental DesignPart 1: Experimental Design

Focused Research Question:

I will investigate how the period of a pendulum depends on its length

Variables:

Independent - L = length of the pendulum string (m)

Dependent - t = time for one swing (s)

Controlled - angle of swing (degrees), mass of the bob (g),

Equipment:

Ceiling hook, string, hanging mass, stopwatch, electronic scale, protractor, meter stick marked in mm, scissors, paper

Part 1: Experimental DesignPart 1: Experimental Design

Method:

The hook is attached to the ceiling and string is cut to make ten lengths differing by 25cm from over two meters in length to under half a meter in length. The pendulum bob is massed and the string is tied to the ceiling hook at one end and to the bob at the other. The distance from the pivot position at the hook to the center of the bob is taken as the pendulum length.

The angle of swing is set at five degrees. To do this repeatedly, a sheet of paper is marked with a vertical plumb line and five degrees is marked with reference to that line. The paper is taped to the ceiling behind the string when in its relaxed vertical position.

The bob is pulled back from it’s relaxed position to five degrees and the timer is started on release. The time for five complete back and forth motions of the pendulum bob is recorded. This is repeated three times. The pendulum is then adjusted for a new length and the process is repeated.

Length of Pendulum

L / cm

L = 1cm

Time For 5 Cycles

Trial 1 Trial 2 Trial 3

t / s

t = 0.6s

Average Time For 5 Cycles

t / s

t = 0.6s

Period

t / s

t = 0.1 s

215 14.3 14.4 14.4 14.4 2.9

195 13.8 13.6 14.0 13.8 2.8

175 13.1 13.1 13.2 13.1 2.6

155 12.2 12.4 12.5 12.4 2.5

135 11.5 11.6 11.7 11.6 2.3

115 10.7 10.8 10.8 10.8 2.2

95 9.9 9.8 9.9 9.9 2.0

75 8.8 8.8 8.9 8.8 1.8

55 7.6 8.0 7.7 7.8 1.6

35 6.3 6.4 6.3 6.3 1.3

Table 1. Length vs. Period For a Pendulum

Mass of the pendulum bob is 103 1 g

The angle of swing is 5 1 degrees

Identifying, specific title

Multiple tables must be numbered

Constants are listed above the table

Units given per measured quantity

Uncertainty recorded to 1 SF

Part 2: Data Collection and ProcessingPart 2: Data Collection and Processing

Data Table:

Appropriate data set

Large spread of data

Processing Raw Data:

Average for 5 cycles = time1 + time2 + time3

3

(Example calculations put under the data table)

= 14.3 s + 14.4 s + 14.4 s = 14.4 s

3

Period = Av. Time for 5 swings

5

= 14.4 s = 2.9 ± 0.1 s

5

Calculated uncertainty in the period:

Determining the period:

T = t / number of swings = 0.6 s / 5 = 0.1 s

Graph:Full descriptive title

Axes labels with units

Data, column options, options to select error bars

Type in value

Curve-fit your data

No dot-to-dot

Using (0,0) shows data does not fit a straight line

Language of physics

- Uncertainties in Graphs

Because all data contains uncertainties at the very least data points should be marked as small circles or crosses. If the absolute uncertainty in each measurement is known then uncertainty bars should be used to turn the data point into a data area. Never connect data points “dot to dot”.

Language of physics

- Graphs (recognizing functions)

So you’ve found a question that needs to be answered, identified variables, restricted them, produced a mathematical model and devised an experiment that will collect data. How do you know that your data supports or refutes your model?

The answer lies in graphs – It is important to be able to recognize the shape of a graph and be able to relate that shape to a mathematical function. You can then compare this function to your model. Some functions found in physics are shown on the next two slides!

Independent

y = k

y does not depend on x

Direct

y x

y = kx

k = slope of the line

y is directly proportional to x

Note: If the line does not go through (o,o) it is linear

y = kx + b

b = y intercept

b

Language of physics


Inverse Proportional

y 1/x

y = k/x

y = k x-1

y is inversely proportional to x

Square

y x2

y = kx2

y is proportional to the square of x

Square root

y √x

y = k √ x

Y = k x1/2

Y is proportional to the square root of x

Note: all these functions are all power functions as they fit the general expression, y = A xB where A and B are constants

Language of physics


Exponential Growth

y = anbx

y increases exponentially with x

Exponential Decay

y = an−bx

Y decreases exponentially with x

Periodic

y = A sin (Bx + C)

Y varies periodically with x

Language of physics


Let’s say that you are investigating how the period (T) of a pendulum (time for one swing) depends on the length (l) of the pendulum and you have come up with a mathematical model that says, T = 2 ( L/ g). You then test this model experimentally and plot a graph of T vs. L (shown below). Which function best describes your data?

The curve through the data can’t be a straight line because as the length decreases, the period decreases so at zero length we would expect the pendulum to take no time to swing back and forth.

The model says that T L or T L1/2

This suggests that we should look at a power function and in particular a square root function (y=kx1/2)

You can see that the computer generated power function fit is a good fit to our model as the data fits T = (2.06) L0.44

The power 0.44 is close to 0.5 (1/2)

We can also use our data to verify the constant g because

Comparing our model with the fit equation we find

2 / g = 2.06 so g = (2 / 2.06)2 = 9.3

Language of physics

- Graphs (turning a curve into a straight line)

Sometimes its nicer to see a relationship from a straight line graph rather than a curved graph, especially when we use uncertainty bars (next slide). To turn a curve into a straight line you look at the proportional statement. If you wanted to turn the pendulum curved graph into a straight line graph what would you plot on each axis?

Now T L so our data should fit a straight line if we plot T vs. L instead of T vs. l

Length of Pendulum

L/m ± 0.01 2.15 1.95 1.75 1.55 1.35 1.15 0.95 0.75 0.55 0.35

Length

L1/2 / m1/2 1.47 1.40 1.32 1.24 1.16 1.07 0.97 0.87 0.74 0.59

Period

t/s ± 0.1 2.9 2.8 2.6 2.5 2.3 2.2 2.0 1.8 1.6 1.3

Processing Raw Data:

Length = (2.15m) = 1.47 m1/2

You can see that the data now fits a nice straight line

The slope (1.8) can be related back to the proportionality constant which is 2 / g

Straight Line Graph:

The graph opposite shows possible slopes within an uncertainty range

We can easily sketch the best-fit line (black) and the two worst (min slope (blue) and the max slope (green)) acceptable lines by using the extremes of the uncertainty bars on the first and last points.

The graph thus performs the function of averaging the data.

Analyzing Straight Line Graph:

Determining uncertainty in the slope:

Determining max slope:

mmax = (Tmax + T) – (Tmin - T)

Lmax1/2 – Lmin

1/2

mmin = (Tmax - T) – (Tmin + T)

Lmax1/2 – Lmin

1/2

= (2.9s+0.1s) – (1.3s-0.1s)

(1.47 m1/2 – 0.59 m1/2)

mmax = 1.8 s / 0.88 m1/2 = 2.0 sm-1/2

= (2.9s-0.1s) – (1.3s+0.1s)

(1.47 m1/2 – 0.59 m1/2)

mmin = 1.4 s / 0.88 m1/2 = 1.6 sm-1/2

So slope of the graph is 1.8 ± 0.2 sm-1/2

Determining min slope:

Part 3: Conclusion and EvaluationPart 3: Conclusion and Evaluation

Concluding:

The slope of the graph represents 2 / g

gmax = (2 / mmin)2 = (2 / 1.6 sm-1/2)2 = 15 m/s2

gmin = (2 / mmax)2 = (2 / 2.0 sm-1/2)2 = 9.9 m/s2

gfit = (2 / m)2 = (2 / 1.8 sm-1/2)2 = 12 m/s2

gactual = 9.81 m/s2

g can thus be quoted as 12 ± 3 m/s2. The actual value of g (9.81 m/s2) is within this range. It can be seen that small differences in the slope can lead to large differences in the value of g because of the squaring operation.


Concluding:

I’ll show you another way another way of determining g without using graphical interpretation. This method is limited in that it is based on one point and so doesn’t reflect the range of your data.

T = 2 (L/g) so…. g = L (2 / T)2

g / g = L / L + 2 (T / T)

= 9.4 m/s2

gav can thus be quoted as 9.4 ± 0.9 m/s2. The actual value of g (9.81 m/s2) is within this range.

From your table choose a mid point, L = 115 ± 1cm, T = 2.2 ± 0.1s.

so…. gav = L (2 / T)2 = (1.15m) (2 / (2.2s))2

Using uncertainty rules for multiplication and powers….

= (1 / 115) + 2 (0.1 / 2.2) = 0.0996

g = (0.0996) x g = (0.0996) x 9.4 m/s2 = 0.93 m/s2


Concluding:

You can calculate a percentage difference between the accepted value of g and your calculated average value using..

This shows a good correlation but it doesn’t reflect the larger range in possible values of g that 12 ± 3 m/s shows.

100%value Actual

value Actual-value YourDifference Percent

9.4 - 9.8

Percent Difference 100% 4.1%9.8


Concluding: The direction of systematic errors

Looking at the Period vs. Square Root of the Length Graph, it can be seen that the best-fit line does not go through the origin, (0,0). It gives a positive y intercept. If the slope (gradient) was steeper, gfit would have been smaller than 12 m/s2.

If the string length was measured before being hung from the ceiling support with the mass attached, the mass could have stretched the string giving rise to a systematic uncertainty in the length of the string. This would be more significant for shorter lengths.


Evaluating Procedure(s):

Although the mass of the pendulum bob should not be a factor in this experiment, air drag on the string and bob might increase the period of swing thus giving a non-zero y intercept on the straight-line graph.

Timing the swing time of shorter pendulum lengths gives a larger uncertainty in determining g than for longer lengths. String lengths are limited by the height of the room.


Improving the Investigation:

Use of as thin a string as possible, such as fishing line and a lead weight as the bob with large mass and small volume should offer the least amount of aerodynamic drag.

To reduce reaction-time random uncertainties, a photogate timer may be used at the bottom of the pendulum swing. Again, a series of swings should be timed and the average time for one swing should be determined

The string length should be measured after the bob is mounted before and after taking a series of measurements. A higher ceiling room giving rise to longer pendulum lengths would reduce the effects of uncertainty in L and t but swinging through more air would cause drag to factor more.

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