energy conversion 1

Phy201

Your 'energy conversion 1' report has been received. Scroll down through the document to see any comments I might have inserted, and my final comment at the end.

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How far and through what angle did the block displace on a single trial, with rubber band tension equal to the weight of two dominoes?

8, 20

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of two dominoes:

8,20

6, 15

8, 20

7, 17

4, 10

Rubber band lengths resulting in 5 cm, 10 cm and 15 cm slides:

0, 3, 4

This you can tell a greater degree difference though not as much in cm

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of four dominoes:

10,25

8,20,

6,15

10 ,25

9, 22

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of six dominoes:

10,25

8,20,

6,15

10 ,25

9, 22

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of eight dominoes:

10,25

8,20,

6,15

10 ,25

9, 22

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of ten dominoes:

10,25

8,20,

6,15

10 ,25

9, 22

Rubber band length, the number of dominoes supported at this length, the mean and the standard deviation of the sliding distance in cm, and the energy associated with the stretch, for each set of 5 trials:

Slope and vertical intercept of straight-line approximation to sliding distance vs. energy, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature:

Lengths of first and second rubber band for (first-band) tensions supporting 2, 4, 6, 8 and 10 dominoes:

Mean sliding distance and std dev for each set of 5 trials, using 2 rubber bands in series:

Slope and vertical intercept of straight-line approximation to sliding distance vs. energy, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature:

1-band sliding distance and 2-band sliding distance for each tension:

Slope and vertical intercept of straight-line approximation to 2-band sliding distance vs. 1-band sliding distance, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature:

Discussion of two hypotheses: 1. The sliding distance is directly proportional to the amount of energy required to stretch the rubber band. 2. If two rubber bands are used the sliding distance is determined by the total amount of energy required to stretch them.

How long did it take you to complete this experiment?

20min

Optional additional comments and/or questions:

You have reported data that you have not reported any of your analysis.

&#Please see my notes and submit a copy of this document with revisions and/or questions, and mark your insertions with &&&& (please mark each insertion at the beginning and at the end). &#

energy conversion 1

Your 'energy conversion 1' report has been received. Scroll down through the document to see any comments I might have inserted, and my final comment at the end.

** Your optional message or comment: **

** How far and through what angle did the block displace on a single trial, with rubber band tension equal to the weight of two dominoes? **

** 5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of two dominoes: **

** Rubber band lengths resulting in 5 cm, 10 cm and 15 cm slides: **

** 5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of four dominoes: **

** 5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of six dominoes: **

** 5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of eight dominoes: **

** 5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of ten dominoes: **

** Rubber band length, the number of dominoes supported at this length, the mean and the standard deviation of the sliding distance in cm, and the energy associated with the stretch, for each set of 5 trials: **

** Slope and vertical intercept of straight-line approximation to sliding distance vs. energy, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature: **

** Lengths of first and second rubber band for (first-band) tensions supporting 2, 4, 6, 8 and 10 dominoes: **

** Mean sliding distance and std dev for each set of 5 trials, using 2 rubber bands in series: **

** Slope and vertical intercept of straight-line approximation to sliding distance vs. energy, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature: **

** 1-band sliding distance and 2-band sliding distance for each tension: **

** Slope and vertical intercept of straight-line approximation to 2-band sliding distance vs. 1-band sliding distance, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature: **

** Discussion of two hypotheses: 1. The sliding distance is directly proportional to the amount of energy required to stretch the rubber band. 2. If two rubber bands are used the sliding distance is determined by the total amount of energy required to stretch them. **

** How long did it take you to complete this experiment? **

** Optional additional comments and/or questions: **

You have reported data that you have not reported any of your analysis.

&#Please see my notes and submit a copy of this document with revisions and/or questions, and mark your insertions with &&&& (please mark each insertion at the beginning and at the end). &#

Your optional message or comment:

How far and through what angle did the block displace on a single trial, with rubber band tension equal to the weight of two dominoes?

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of two dominoes:

Rubber band lengths resulting in 5 cm, 10 cm and 15 cm slides:

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of four dominoes:

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of six dominoes:

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of eight dominoes:

5 trials, distance in cm then rotation in degrees, with rubber band tension equal to the weight of ten dominoes:

Rubber band length, the number of dominoes supported at this length, the mean and the standard deviation of the sliding distance in cm, and the energy associated with the stretch, for each set of 5 trials:

Slope and vertical intercept of straight-line approximation to sliding distance vs. energy, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature:

Lengths of first and second rubber band for (first-band) tensions supporting 2, 4, 6, 8 and 10 dominoes:

Mean sliding distance and std dev for each set of 5 trials, using 2 rubber bands in series:

Slope and vertical intercept of straight-line approximation to sliding distance vs. energy, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature:

1-band sliding distance and 2-band sliding distance for each tension:

Slope and vertical intercept of straight-line approximation to 2-band sliding distance vs. 1-band sliding distance, units of slope and vertical intercept, description of the graph and closeness to line, any indication of curvature:

Discussion of two hypotheses: 1. The sliding distance is directly proportional to the amount of energy required to stretch the rubber band. 2. If two rubber bands are used the sliding distance is determined by the total amount of energy required to stretch them.

How long did it take you to complete this experiment?

Optional additional comments and/or questions: