Ph1 Query 3

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course Pht 121

003. `Query 3 Question: What do the coordinates of two points on a graph of position vs. clock time tell you about the motion of the object? What can you reason out once you have these coordinates?

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Your solution:

confidence rating #$&*: Each point is represented by the coordinate of position and clock time. When you compare two points, you are comparing the difference in these points or the average velocity. In addition, we can determine rise, run, and slope.

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Given Solution: The coordinates a point on the graph include a position and a clock time, which tells you where the object whose motion is represented by the graph is at a given instant. If you have two points on the graph, you know the position and clock time at two instants.

Given two points on a graph you can find the rise between the points and the run.

On a graph of position vs. clock time, the position is on the 'vertical' axis and the clock time on the 'horizontal' axis.

• The rise between two points represents the change in the 'vertical' coordinate, so in this case the rise represents the change in position.

• The run between two points represents the change in the 'horizontal' coordinate, so in this case the run represents the change in clock time.

The slope between two points of a graph is the 'rise' from one point to the other, divided by the 'run' between the same two points.

• The slope of a position vs. clock time graph therefore represents rise / run = (change in position) / (change in clock time).

• By the definition of average velocity as the average rate of change of position with respect to clock time, we see that average velocity is vAve = (change in position) / (change in clock time).

• Thus the slope of the position vs. clock time graph represents the average velocity for the interval between the two graph points.

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Self-critique (if necessary): I did not mention motion is my answer. I also did not mention what the vertical or horizontal axis mean.

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self-critique rating #$&*: 2

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Question:

Pendulums of lengths 20 cm and 25 cm are counted for one minute. The counts are respectively 69 and 61. To how many significant figures do we know the difference between these counts?

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Your Solution: One significant figure

confidence rating #$&*:

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Question:

What are some possible units for position? What are some possible units for clock time? What therefore are some possible units for rate of change of position with respect to clock time?

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Your Solution: Possible units for position include units that represents length or distance, such as cm, meter, km, or inch. Possible units for clock time include seconds, minutes, and hour. Possible units for the rate of position with respect to clock time include unit or length or distance over units of time, such as mph

confidence rating #$&*:

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Question: `qQuery Principles of Physics and General College Physics: Summarize your solution to Problem 1.19 (1.80 m + 142.5 cm + 5.34 * 10^5 `micro m to appropriate # of significant figures)

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Your solution: 1.80 m + 142.5 cm + 5.34 * 10^5 micrometers

1,800,000 micrometers + 1,425,000 micrometers + 534,000 micrometers

3,759,000 micrometers

3.759 * 10^6 micrometers

confidence rating #$&*: 3

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Given Solution:

`a** 1.80 m has three significant figures (leading zeros don't count, neither to trailing zeros unless there is a decimal point; however zeros which are listed after the decimal point are significant; that's the only way we have of distinguishing, say, 1.80 meter (read to the nearest .01 m, i.e., nearest cm) and 1.000 meter (read to the nearest millimeter).

Therefore no measurement smaller than .01 m can be distinguished.

142.5 cm is 1.425 m, good to within .00001 m.

5.34 * `micro m means 5.34 * 10^-6 m, so 5.34 * 10^5 micro m means (5.34 * 10^5) * 10^-6 meters = 5.34 + 10^-1 meter, or .534 meter, accurate to within .001 m.

Then theses are added you get 3.759 m; however the 1.80 m is only good to within .01 m so the result is 3.76 m. **

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Self-critique (if necessary): I used micrometers instead of meters.

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self-critique rating #$&*: 2

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Question: For University Physics students: Summarize your solution to Problem 1.31 (10th edition 1.34) (4 km on line then 3.1 km after 45 deg turn by components, verify by scaled sketch).

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Your solution: N/A

confidence rating #$&*:: N/A

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Given Solution:

`a** THE FOLLOWING CORRECT SOLUTION WAS GIVEN BY A STUDENT:

The components of vectors A (2.6km in the y direction) and B (4.0km in the x direction) are known.

We find the components of vector C(of length 3.1km) by using the sin and cos functions.

Cx was 3.1 km * cos(45 deg) = 2.19. Adding the x component of the second vector, 4.0, we get 6.19km.

Cy was 2.19 and i added the 2.6 km y displacement of the first vector to get 4.79.

So Rx = 6.19 km and Ry = 4.79 km.

To get vector R, i used the pythagorean theorem to get the magnitude of vector R, which was sqrt( (6.29 km)^2 + (4.79 km)^2 ) = 7.9 km.

The angle is theta = arctan(Ry / Rx) = arctan(4.79 / 6.19) = 37.7 degrees. **

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Self-critique (if necessary): N/A

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self-critique rating #$&*: N/A

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Question:

A ball rolls from rest down a book, off that book and onto another book, where it picks up additional speed before rolling off the end of that book.

Suppose you know all the following information:

• How far the ball rolled along each book.

• The time interval the ball requires to roll from one end of each book to the other.

• How fast the ball is moving at each end of each book.

How would you use your information to determine the clock time at each of the three points, if we assume the clock started when the ball was released at the 'top' of the first book?

How would you use your information to sketch a graph of the ball's position vs. clock time?

(This question is more challenging that the others): How would you use your information to sketch a graph of the ball's speed vs. clock time, and how would this graph differ from the graph of the position?

confidence rating #$&*: In this problem we know about the change in position from start to end. We also know the change in position on each book. We know the change in clock time from start to finish as well as each book. We know the rate of the object at each book. From this data, we can determine the initial velocity, average velocity, and final velocity. We can determine the average velocity of each book. Since we know the rate at each book, we can also determine average acceleration. We could create a graph with the change in position on the vertical axis and the change in time on the horizontal axis. A graph of speed would also have the change in time on the horizontal, but the speed would be on the vertical. If the speed is constant, the slope would be a straight line. If we assume that the object starts slow, gains speed, and come to a stop, the slope would curve up and then down.

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&#This looks good. Let me know if you have any questions. &#

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