Query 2

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course PHY 121

6/11 12

002. `ph1 query 2#$&* delim

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Question: Explain how velocity is defined in terms of rates of change.

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Your solution:

Velocity is the amount of distance traveled over a unit of time. For example, you may

tell how many miles per hour are traveled or how many centimeters per second are

covered. Velocity has both movement and elapsed time. It is the average rate of change

of A with respect to B on an interval, or (change in A)/(change in B)

confidence rating #$&*: 3

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Given Solution: Average velocity is defined as the average rate of change of position

with respect to clock time.

The average rate of change of A with respect to B is (change in A) / (change in B).

Thus the average rate of change of position with respect to clock time is

ave rate = (change in position) / (change in clock time).

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Self-critique (if necessary): OK

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Self-critique Rating: 3

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Question: Why can it not be said that average velocity = position / clock time?

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Your solution:

It has to be a change in position and elapsed time. It is not just the time that

something was at a certain position. The object has to move and time has to pass for

velocity.

confidence rating #$&*: 3

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Given Solution: The definition of average rate involves the change in one quantity, and

the change in another.

Both position and clock time are measured with respect to some reference value. For

example, position might be measured relative to the starting line for a race, or it

might be measured relative to the entrance to the stadium. Clock time might be measure

relative to the sound of the starting gun, or it might be measured relative to noon.

So position / clock time might, at some point of a short race, be 500 meters / 4 hours

(e.g., 500 meters from the entrance to the stadium and 4 hours past noon). The quantity

(position / clock time) tells you nothing about the race.

There is a big difference between (position) / (clock time) and (change in position) /

(change in clock time).

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Self-critique (if necessary): OK

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Self-critique Rating: 3

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Question: Explain in your own words the process of fitting a straight line to a graph

of y vs. x data, and briefly discuss the nature of the uncertainties encountered in the

process. For example, you might address the question of how two different people, given

the same graph, might obtain different results for the slope and the vertical intercept.

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Your solution:

When you have a graph with scattered points and you have to fit a straight line to the

data, you do not just connect the points. You have to try to place a line that is

equidistant from the points (like an average or down the middle). It is difficult to do

this because it is not easy to judge just how to place the line so that it is optimal.

You can make the line too far away from or too close to an existing point, which will

not result in a line that it different from where another person would place the line.

Two different people, given the same graph, might give their line a slightly different

slope or they might place it higher or lower than the other person, which would change

the y-intercept.

confidence rating #$&*: 2

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Question:

(Principles of Physics and General College Physics students) What is the range of

speeds of a car whose speedometer has an uncertainty of 5%, if it reads 90 km / hour?

What is the range of speeds in miles / hour?

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Your solution:

5% of 90 is 4.5. This means that the range in km/hour would be between 85.5 and 94.5

km/hour.

To find miles per hour:

85.5 km/hour * (1000m/km) * (100 cm/m) * (1 in/2.54 cm) * (1 ft/12 in) * (1 mi/5280 ft)

This would be about 53 mph

94.5 km/hour * (1000m/km) * (100 cm/m) * (1 in/2.54 cm) * (1 ft/12 in) * (1 mi/5280 ft)

This would be about 58.7 or 59 mph

confidence rating #$&*: 2

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Given Solution: 5% of 90 km / hour is .05 * 90 km / hour = 4.5 km / hour. So the

actual speed of the car might be as low as 90 km / hour - 4.5 km / hour = 85.5 km /

hour, or as great as 90 km / hour + 4.5 km / hour = 94.5 km / hour.

To convert 90 km / hour to miles / hour we use the fact, which you should always know,

that 1 inch = 2.54 centimeters. This is easy to remember, and it is sufficient to

convert between SI units and British non-metric units.

Using this fact, we know that 90 km = 90 000 meters, and since 1 meter = 100 centimeter

this can be written as 90 000 * (100 cm) = 9 000 000 cm, or 9 * 10^6 cm.

Now since 1 inch = 2.54 cm, it follows that 1 cm = (1 / 2.54) inches so that 9 000 000

cm = 9 000 000 * (1/2.54) inches, or roughly 3 600 000 inches (it is left to you to

provide the accurate result; as you will see results in given solutions are understood

to often be very approximate, intended as guidelines rather than accurate solutions).

In scientific notation, the calculation would be 9 * 10^6 * (1/2.54) inches = 3.6 * 10^6

inches.

Since there are 12 inches in a foot, an inch is 1/12 foot so our result is now 3 600 000

*(1/12 foot) = 300 000 feet (3.6 * 10^6 * (1/12 foot) = 3 * 10^5 feet).

Since there are 5280 feet in a mile, a foot is 1/5280 mile so our result is 300 000 *

(1/5280 mile) = 58 miles, again very approximately.

So 90 km is very roughly 58 miles (remember this is a rough approximation; you should

have found the accurate result).

Now 90 km / hour means 90 km in an hour, and since 90 km is roughly 58 miles our 90

km/hour is about 58 miles / hour.

A more formal way of doing the calculation uses 'conversion factors' rather than common

sense. Common sense can be misleading, and a formal calculation can provide a good

check to a commonsense solution:

We need to go from km to miles. We use the facts that 1 km = 1000 meters, 1 meter = 100

cm, 1 cm = 1 / 2.54 inches, 1 inch = 1/12 foot and 1 foot = 1 / 5280 mile to get the

conversion factors (1000 m / km), (100 cm / m), (1/2.54 in / cm), (1/12 foot / in) and

(1/5280 mile / ft) and string together our calculation:

90 km / hr * (1000 m / km) * (100 cm / m) * (1/2.54 in / cm) * (1/12 foot / in) *

(1/5280 mile / ft) = 58 mi / hr (again not totally accurate).

Note how the km divides out in the first multiplication, the m in the second, the cm in

the third, the inches in the fourth, the feet in the fifth, leaving us with miles /

hour.

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Self-critique (if necessary): OK

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Self-critique Rating: 3

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Question: (Principles of Physics students are invited but not required to submit a

solution) Give your solution to the following: Find the approximate uncertainty in the

area of a circle given that its radius is 2.8 * 10^4 cm.

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Your solution:

The book says that the uncertaintly is assumed to be one or two units of the last digit specified. This means that it would be plus or minus 1 or 2 (but that doesn't make sense to me for such a large number).

confidence rating #$&*: 1

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Given Solution:

** Radius 2.8 * 10^4 cm means that the radius is between 2.75 * 10^4 cm and 2.85 * 10^4

cm.

We regard 2.75 *10^4 cm as the lower bound and 2.85 *10^4 cm as the upper bound on the

radius. 2.75 is .05 less than 2.8, and 2.85 is .05 greater than 2.8, so we say that the

actual number is 2.8 +- .05.

Thus we express the actual radius as (2.8 +- .05) * 10^4 cm, and we call .05 * 10^4 cm

the uncertainty in the measurement.

The area of a circle is pi r^2, with which you should be familiar (if for no reason

other than that you used it and wrote it down in the orientation exercises)..

With this uncertainty estimate, we find that the area is between a lower area estimate

of pi * (2.75 * 10^4 cm)^2 = 2.376 * 10^9 cm^2 and and upper area estimate of pi * (2.85

* 10^4 cm)^2 = 2.552 * 10^9 cm^2.

The difference between the lower and upper estimate is .176 * 10^9 cm^2 = 1.76 * 10^8

cm^2.

The area we would get from the given radius is about halfway between these estimates, so

the uncertainty in the area is about half of the difference.

We therefore say that the uncertainty in area is about 1/2 * 1.76 * 10^8 cm^2, or about

.88 * 10^8 cm^2.

Note that the .05 * 10^4 cm uncertainty in radius is about 2% of the radius, while the

.88 * 10^8 cm uncertainty in area is about 4% of the area.

The area of a circle is proportional to the squared radius.

A small percent uncertainty in the radius gives very nearly double the percent

uncertainty in the squared radius. **

STUDENT COMMENT:

I don't recall seeing any problems like this in any of our readings or assignments to

this point

INSTRUCTOR RESPONSE:

The idea of percent uncertainty is presented in Chapter 1 of your text.

The formula for the area of a circle should be familiar.

Of course it isn't a trivial matter to put these ideas together.

STUDENT COMMENT:

I don't understand the solution. How does .176 * 10^9 become 1.76 * 10^8? I understand

that there is a margin of error because of the significant figure difference, but don't

see how this was calculated.

INSTRUCTOR RESPONSE:

.176 = 1.76 * .1, or 1.76 * 10^-1.

So .176 * 10^9 = 1.76 * 10^-1 * 10^9. Since 10^-1 * 10^9 = 10^(9 - 1) =10^8, we have

.176 * 10^9 = 1.76 * 10^8.

The key thing to understand is the first statement of the given solution:

Radius 2.8 * 10^4 cm means that the radius is between 2.75 * 10^4 cm and 2.85 * 10^4 cm.

This is because any number between 2.75 and 2.85 rounds to 2.8. A number which rounds

to 2.8 can therefore lie anywhere between 2.75 and 2.85.

The rest of the solution simply calculates the areas corresponding to these lower and

upper bounds on the number 2.8, then calculates the percent difference of the results.

STUDENT COMMENT: I understand how squaring the problem increases uncertainty and I

understand the concept of

a range of uncertainty but I am having trouble figuring out how the range of 2.75 * 10^4

and 2.85*10^4 were established

for the initial uncertainties in radius.

INSTRUCTOR RESPONSE:

The key is the first sentence of the given solution:

'Radius 2.8 * 10^4 cm means that the radius is between 2.75 * 10^4 cm and 2.85 * 10^4

cm.'

You know this because you know that any number which is at least 2.75, and less than

2.85, rounds to 2.8.

Ignoring the 10^4 for the moment, and concentrating only on the 2.8:

Since the given number is 2.8, with only two significant figures, all you know is that

when rounded to two significant figures the quantity is 2.8. So all you know is that

it's between 2.75 and 2.85.

STUDENT QUESTION

I honestly didn't consider the fact of uncertainty at all. I misread the problem and

thought I

was simply solving for area. I'm still not really sure how to determine the degree of

uncertainty.

INSTRUCTOR RESPONSE

Response to Physics 121 student:

This topic isn't something critical to your success in the course, but the topic will

come up. You're doing excellent work so far, and it might be worth a little time for you

to try to reconcile this idea.

Consider the given solution, the first part of which is repeated below, with some

questions (actually the same question repeated too many times). I'm sure you have

limited time so don't try to answer the question for every statement in the given

solution, but try to answer at least a few. Then submit a copy of this part of the

document.

Note that a Physics 201 or 231 student should understand this solution very well, and

should seriously consider submitting the following if unsure. This is an example of how

to break down a solution phrase by phrase and self-critique in the prescribed manner.

##&*

** Radius 2.8 * 10^4 cm means that the radius is between 2.75 * 10^4 cm and 2.85 * 10^4

cm.

Do you understand what this is saying, and why it is so? If not, tell me what you think

you understand, what you are pretty sure you don't understand, and what you think you

might understand but aren't sure.

##&*

We regard 2.75 *10^4 cm as the lower bound and 2.85 *10^4 cm as the upper bound on the

radius. 2.75 is .05 less than 2.8,

and 2.85 is .05 greater than 2.8, so we say that the actual number is 2.8 +- .05.

Do you understand what this is saying, and why it is so? If not, tell me what you think

you understand, what you are pretty sure you don't understand, and what you think you

might understand but aren't sure.

##&*

Thus we express the actual radius as (2.8 +- .05) * 10^4 cm, and we call .05 * 10^4 cm

the uncertainty in the measurement.

Do you understand what this is saying, and why it is so? If not, tell me what you think

you understand, what you are pretty sure you don't understand, and what you think you

might understand but aren't sure.

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The area of a circle is pi r^2, with which you should be familiar (if for no reason

other than that you used it and wrote it

down in the orientation exercises).

With this uncertainty estimate, we find that the area is between a lower area estimate

of pi * (2.75 * 10^4 cm)^2 = 2.376 *

10^9 cm^2 and and upper area estimate of pi * (2.85 * 10^4 cm)^2 = 2.552 * 10^9 cm^2.

Do you understand what this is saying, and why it is so? If not, tell me what you think

you understand, what you are pretty sure you don't understand, and what you think you

might understand but aren't sure.

##&*

The difference between the lower and upper estimate is .176 * 10^9 cm^2 = 1.76 * 10^8

cm^2.

Do you understand what this is saying, and why it is so? If not, tell me what you think

you understand, what you are pretty sure you don't understand, and what you think you

might understand but aren't sure.

##&*

The area we would get from the given radius is about halfway between these estimates, so

the uncertainty in the area is about

half of the difference.

We therefore say that the uncertainty in area is about 1/2 * 1.76 * 10^8 cm^2, or about

.88 * 10^8 cm^2.

Note that the .05 * 10^4 cm uncertainty in radius is about 2% of the radius, while the

.88 * 10^8 cm uncertainty in area is

about 4% of the area.

Do you understand what this is saying, and why it is so? If not, tell me what you think

you understand, what you are pretty sure you don't understand, and what you think you

might understand but aren't sure.

##&*

The area of a circle is proportional to the squared radius.

A small percent uncertainty in the radius gives very nearly double the percent

uncertainty in the squared radius.

Do you understand what this is saying, and why it is so? If not, tell me what you think

you understand, what you are pretty sure you don't understand, and what you think you

might understand but aren't sure.

##&*

If you wish you can submit the above series of questions in the usual manner.

STUDENT QUESTION

I said the uncertainty was .1, which gives me .1 / 2.8 = .4.

INSTRUCTOR RESPONSE

A measurement of 2.8 can be taken to imply a number between 2.75 and 2.85, which means

that the number is 2.8 +- .05 and the uncertainty is .05. This is the convention used in

the given solution.

(The alternative convention is that 2.8 means a number between 2.7 and 2.9; when in

doubt the alternative convention is usually the better choice. This is the convention

used in the text.

It should be easy to adapt the solution given here to the alternative convention, which

yields an uncertainty in area of about 8% as opposed to the 4% obtained here).

Using the latter convention, where the uncertainty is estimated to be .1:

The uncertainty you calculated would indeed be .04 (.1 / 2.8 is .04, not .4), or 4%.

However this would be the percent uncertainty in the radius.

The question asked for the uncertainty in the area. Since the calculation of the area

involves squaring the radius, the percent uncertainty in area is double the percent

uncertainty in radius. This gives us a result of .08 or 8%. The reasons are explained

in the given solution.

NOTE FOR UNIVERSITY PHYSICS STUDENTS (calculus-based answer):

Note the following:

A = pi r^2, so the derivative of area with respect to radius is

dA/dr = 2 pi r. The differential is therefore

dA = 2 pi r dr.

Thus an uncertainty `dr in r implies uncertainty

`dA = 2 pi r `dr, so that

`dA / `dr = 2 pi r `dr / (pi r^2) = 2 `dr / r.

`dr / r is the proportional uncertainty in r.

We conclude that the uncertainty in A is 2 `dr / r, i.e., double the uncertainty in r.

STUDENT QUESTION

I looked at this, and not sure if I calculated the uncertainty correctly, as the radius

squared yields double the uncertainty. I know where this is in the textbook, and do ok

with uncertainty, but this one had me confused a bit.

INSTRUCTOR RESPONSE:

In terms of calculus, since you are also enrolled in a second-semester calculus class:

A = pi r^2

The derivative r^2 with respect to r is 2 r, so the derivative of the area with respect

to r is dA / dr = pi * (2 r).

If you change r by a small amount `dr, the change in the area is dA / dr * `dr, i.e.,

rate of change of area with respect to r multiplied by the change in r, which is a good

commonsense notion.

Thus the change in the area is pi * (2 r) `dr. As a proportion of the original area this

is pi ( 2 r) `dr / (pi r^2) = 2 `dr / r.

The change in the radius itself was just `dr. As a proportion of the initial radius this

is `dr / r.

The proportional change in area is 2 `dr / r, compared to the proportional change in

radius `dr / r.

That is the proportional change in area is double the proportional change in radius.

STUDENT COMMENT

I used +-.1 instead of using +-.05. I understand why your solution used .05 and will use

this method in the future.

INSTRUCTOR RESPONSE

Either way is OK, depending on your assumptions. When it's possible to assume accurate

rounding, then the given solution works. If you aren't sure the rounding is accurate,

the method you used is appropriate.

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Self-critique (if necessary):

I was at first uncertain where the .05 came from, but the explanation that adding or subtracting 0.05 would yield the smallest and largest number that would round to 2.8 makes sense. And this answer made a lot more sense than what I (mis)understood from the reading.

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Self-critique Rating: 3

@&

For some reason this is always tough for students. I'm glad if my explanation helped.

*@

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Question: What is your own height in meters and what is your own mass in kg (if you

feel this question is too personal then estimate these quantities for someone you know)?

Explain how you determined these.

What are your uncertainty estimates for these quantities, and on what did you base these

estimates?

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Your solution:

5'9"" would be 69 inches.

If the uncertainty is plus or minus one inch, the range would be 68-70. This uncertainty is based on plus or minus one of the unit being used.

There are 2.54 cm in one inch, so to find the number of cm in 68 inches, you would multiply by 2.54. This would give you 172.72 cm. To find the number of cm in 70 inches, you would multiply 70 by 2.54. This would yield 177.8 cm.

160 pounds

If the uncertainty is plus or minus one pound, which is plus or minus one of the unit being used, the range would be 159-161. There are 2.2 pounds per kilogram. This means that you have to divide the pounds by the number of pounds in a kilogram. For 159, you would get 72.2 kg. For 161, you would get 73.1 kg.

confidence rating #$&*: 2

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Given Solution:

Presumably you know your height in feet and inches, and have an idea of your ideal

weight in pounds. Presumably also, you can convert your height in feet and inches to

inches.

To get your height in meters, you would first convert your height in inches to cm, using

the fact that 1 inch = 2.54 cm. Dividing both sides of 1 in = 2.54 cm by either 1 in or

2.54 cm tells us that 1 = 1 in / 2.54 cm or that 1 = 2.54 cm / 1 in, so any quantity can

be multiplied by 1 in / (2.54 cm) or by 2.54 cm / (1 in) without changing its value.

Thus if you multiply your height in inches by 2.54 cm / (1 in), you will get your height

in cm. For example if your height is 69 in, your height in cm will be 69 in * 2.54 cm /

(1 in) = 175 in * cm / in.

in * cm / in = (in / in) * cm = 1 * cm = cm, so our calculation comes out 175 cm.

STUDENT SOLUTION

5 feet times 12 inches in a feet plus six inches = 66 inches. 66inches * 2.54 cm/inch =

168.64 cm. 168.64 cm *

.01m/cm = 1.6764 meters.

INSTRUCTOR COMMENT:

Good, but note that 66 inches indicates any height between 65.5 and 66.5 inches, with a

resulting uncertainty of about .7%.

168.64 implies an uncertainty of about .007%.

It's not possible to increase precision by converting units.

STUDENT SOLUTION AND QUESTIONS

My height in meters is - 5’5” = 65inches* 2.54cm/1in = 165cm*1m/100cm = 1.7m. My weight

is 140lbs*

1kg/2.2lbs = 63.6kg. Since 5’5” could be anything between 5’4.5 and 5’5.5, the

uncertainty in height is ???? The

uncertainty in weight, since 140 can be between 139.5 and 140.5, is ??????

INSTRUCTOR RESPONSE

Your height would be 5' 5"" +- .5""; this is the same as 65"" +- .5"".

.5"" / 65"" = .008, approximately, or .8%. So the uncertainty in your height is +-0.5"",

which is +-0.8%.

Similarly you report a weight of 140 lb +- .5 lb.

.5 lb is .5 lb / (140 lb) = .004, or 0.4%. So the uncertainty is +-0.5 lb, or +-

0.4%.

STUDENT QUESTION

I am a little confused. In the example from another student her height was 66 inches and

you said that her height could be between 65.5 and 66.5 inches. but if you take the

difference of those two number you get 1, so why do you divide by .5 when the difference

is 1

INSTRUCTOR RESPONSE

If you regard 66 inches as being a correct roundoff of the height, then the height is

between 65.5 inches and 66.5 inches. This makes the height 66 inches, plus or minus .5

inches. This is written as 66 in +- .5 in and the percent uncertainty would be .5 / 66 =

.007, about .7%.

If you regard 66 inches having been measured only accurately enough to ensure that the

height is between 65 inches and 67 inches, then your result would be 66 in +- 1 in and

the percent uncertainty would be 1 / 66 = .015 or about 1.5%.

STUDENT QUESTION

If a doctor were to say his inch marker measured to the nearest 1/4 inch, would that be

the uncertainty?

Meaning, would I only have to multiply that by .0254 to find the uncertainty in meters,

dividing that by my height to find the percent

uncertainty?

INSTRUCTOR RESPONSE

That's pretty much the case, though you do have to be a little bit careful about how the

rounding and the uncertainty articulate.

For example I'm 72 inches tall. That comes out to 182.88 cm. It wouldn't make a lot of

sense to say that I'm 182.88 cm tall, +- .64 cm. A number like 182.88 has a ridiculously

high number of significant figures.

It wouldn't quite be correct to just round up and say that I'm 183 cm tall +- .64 cm. We

might be able to say that I'm 183 cm tall, +- .76 cm, but that .76 cm again implies more

precision than is present.

We would probably end up saying that I""m 183 cm tall, +- 1 cm.

Better to overestimate the uncertainty than to underestimate it.

As far as the percent uncertainty goes, we wouldn't need to convert the units at all.

In my case we would just divide 1/4 in. by 72 in., getting about .034 or 3.4%.

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Self-critique (if necessary):

I hesitated about whether to use 1 or .5 for the uncertainty. I guess .5 would have been preferable. This would have made my answers:

68.5 in * 2.54 cm/in = 173.99, or approx. 174 cm.

69.5 in * 2.54 cm/in = 176.53, or approx. 177 cm.

159.5 lb * (1 kg/2.2lb) = 159.5/2.2 = 72.5 kg.

160.5 lb * (1 kg/2.2lb) = 160.5/2.2 = 72.95 kg, or 73 kg.

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Self-critique Rating: 2

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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 calculate the ball's average velocity on each

book?

How would you use your information to calculate how quickly the ball's speed was

changing on each book?

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Your solution:

You would take the length of the first book and divide it by the amount of time it took to get from one end of the book to the other to find the velocity for the first book.

You would take the length of the second book and divide it by the amount of time it took to get from one end of the book to the other to find the velocity for the second book.

You could take the velocity on the first book and compare it to the velocity on the second book to see how much faster it went on the second.

confidence rating #$&*: 2

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Self-critique (if necessary):

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Self-critique rating:

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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 calculate the ball's average velocity on each

book?

How would you use your information to calculate how quickly the ball's speed was

changing on each book?

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Your solution:

You would take the length of the first book and divide it by the amount of time it took to get from one end of the book to the other to find the velocity for the first book.

You would take the length of the second book and divide it by the amount of time it took to get from one end of the book to the other to find the velocity for the second book.

You could take the velocity on the first book and compare it to the velocity on the second book to see how much faster it went on the second.

confidence rating #$&*: 2

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Self-critique (if necessary):

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Self-critique rating:

#*&!

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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 calculate the ball's average velocity on each

book?

How would you use your information to calculate how quickly the ball's speed was

changing on each book?

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Your solution:

You would take the length of the first book and divide it by the amount of time it took to get from one end of the book to the other to find the velocity for the first book.

You would take the length of the second book and divide it by the amount of time it took to get from one end of the book to the other to find the velocity for the second book.

You could take the velocity on the first book and compare it to the velocity on the second book to see how much faster it went on the second.

confidence rating #$&*: 2

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Self-critique (if necessary):

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Self-critique rating:

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