Physics Initial Questions

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course PHY 201

09/01 1:24pm

006. Physics

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Question: `q001. There are two parts to this problem. Reason them out using

common sense.

If the speed of an automobile changes by 2 mph every second, then how long

will it take the speedometer to move from the 20 mph mark to the 30 mph

mark?

Given the same rate of change of speed, if the speedometer initially reads

10 mph, what will it read 7 seconds later?

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Your solution:

First problem:

Rate is 2mph / second

Distance is 30 - 20 = 10

Since Rate * time = distance, then 2*x = 10 or x = 5

It takes the speedometer five seconds to make it from 20mph to 30mph.

Second problem:

Rate is still 2mph / second

rate*time=distance

2*7=x

14=x

However, the needle starts at 10mph

14+10 = 24

The speedometer will read 24mph.

confidence rating #$&*:3

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Given Solution:

`aIt will take 5 seconds to complete the change. 30 mph - 20 mph = 10 mph

change at 2 mph per second (i.e., 2 mph every second) implies 5 seconds to

go from 20 mph to 30 mph

Change in speed is 2 mph/second * 7 seconds = 14 mph Add this to the initial

10 mph and the speedometer now reads 24 mph.

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Self-critique (if necessary): OK

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Self-critique Rating: OK

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Question: `q002. An automobile traveling down a hill passes a certain

milepost traveling at a speed of 10 mph, and proceeds to coast to a certain

lamppost further down the hill, with its speed increasing by 2 mph every

second. The time required to reach the lamppost is 10 seconds.

It then repeats the process, this time passing the milepost at a speed of 20

mph. This time:

Will the vehicle require more or less than 10 seconds to reach the

lamppost?

Since its initial speed was 10 mph greater than before, does it follow

that its speed at the lamppost will be 10 mph greater than before?

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Your solution:

Because Velocity = (Change in Position) / (Change in Clock Time), and the

change in position is identical between the two trials, then the smaller the

velocity, then the faster the velocity, the smaller the time interval.

The first trial had an initial velocity of 10mph, a final velocity of 30mph,

and a time interval of 10 seconds.

Thus, it stands to reason that if the second time interval starts at 20mph,

the second time interval will be shorter than the first time interval of 10

seconds.

In response to the second question, the answer is no. I already established

that the second time interval must be shorter than the first. Assuming the

rate of acceleration is the same, then

20 mph + 2(s)mph = final mph.

If 20mph + 2(10)mph = 40 mph. And s < 10, then the final speed of must be <

40mph.

For the first trial, the final speed was 30mph. For the second trial, the

final speed must be < 40 mph, an thus cannot be 10mph greater than before.

confidence rating #$&*: 3

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Given Solution:

`aIf it starts coasting down the same section of road at 20 mph, and if

velocity changes by the same amount every second, the automobile should

always be traveling faster than if it started at 10 mph, and would therefore

take less than 10 seconds.

The conditions here specify equal distances, which implies less time on the

second run. The key is that, as observed above, the automobile has less than

10 seconds to increase its speed. Since its speed is changing at the same

rate as before and it has less time to change it will therefore change by

less.

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Self-critique (if necessary): OK

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Self-critique Rating: OK

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Question: `q003. The following example shows how we can measure the rate at

which an automobile speeds up: If an automobile speeds up from 30 mph to 50

mph as the second hand of a watch moves from the 12-second position to the

16-second position, and its speed changes by 20 mph in 4 seconds. This gives

us an average rate of velocity change equal to 20 mph / 4 seconds = 5 mph /

second.

We wish to compare the rates at which two different automobiles increase

their speed:

Which automobile speeds up at the greater rate, one which speeds up from 20

mph to 30 mph in five seconds or one which speeds up from 40 mph to 90 mph

in 20 seconds?

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Your solution:

For the example:

30 to 50 mph

12 to 16 seconds

50 - 30 = 20

16 - 12 = 4

20 / 4 = 5 mph / sec

Automobile one:

20 to 30 mph

0 to 5 seconds

30 - 20 = 10

5 - 0 = 5

10 / 5 = 2 mph / sec

Automobile two:

40 to 90 mph

0 to 20 secconds

90 - 40 = 50

20 - 0 = 20

50 / 20 = 2.5 mph / sec

The second automobile speeds up at a faster rate.

confidence rating #$&*: 3

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Given Solution:

The first automobile's speed changes from 20 mph to 30mph, a 10 mph

difference, which occurs in 5 seconds. So the rate of chage in 10 mph / (5

sec) = 2 mph / sec. = rate of change of 2 mph per second.

The second automobile's speed changes from 40 mph to 90 mph, a 50 mph

difference in 20 seconds so the rate of change is 50 mph / (20 sec) = 2.5

mph per second.

Therefore, the second auto is increasing its velocity ar a rate which is .5

mph / second greater than that of the first.

Self-critique: OK

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Self-critique Rating: OK

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Question: `q004. If an automobile of mass 1200 kg is pulled by a net force

of 1800 Newtons, then the number of Newtons per kg is 1800 / 1200 = 1.5. The

rate at which an automobile speeds up is determined by the net number of

Newtons per kg. Two teams pulling on ropes are competing to see which can

most quickly accelerate their initially stationary automobile to 5 mph. One

team exerts a net force of 3000 Newtons on a 1500 kg automobile while

another exerts a net force of 5000 Newtons on a 2000 kg automobile.

Which team will win and why?

If someone pulled with a force of 500 Newtons in the opposite direction on

the automobile predicted to win, would the other team then win?

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Your solution:

F = m*a

Team one:

F = 3000 Newtons

m = 1500 kg

3000 = 1500 * a

3000 / 1500 = 1500 * a / 1500

a = 2 newtons / kg

Team two:

F = 5000

m = 2000

5000 = 2000 * a

5000 / 2000 = 2000 * a / 2000

a = 2.5 newtons / kg

Team two will win, as their rate of acceleration is .5 newtons/kg faster

than team one.

If someone pulls with a force of 500 newtons in the opposite direction of

the Team Two car, it will cancel out 500 newtons of force in the other

direction, giving the car 4500 newtons of force towards the goal.

4500 = 2000 * a

4500 / 2000 = 2000 * a / 2000

a = 2.25 newtons /kg

The team two car will still win.

confidence rating #$&*: 3

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Given Solution:

`aThe first team's rate is 3000 Newtons divided by 1500 kg or 2 Newtons per

kg, while the second team's rate is 5000 Newtons divided by 2000 kg or 2.5

Newtons per kg. The second team therefore increases velocity more quickly.

Since both start at the same velocity, zero, the second team will

immediately go ahead and will stay ahead.

The second team would still win even if the first team was hampered by the

500 Newton resistance, because 5000 Newtons - 500 Newtons = 4500 Newtons of

force divided by 2000 kg of car gives 2.25 Newtons per kg, still more than

the 2 Newtons / kg of the first team

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Self-critique (if necessary): OK

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Self-critique Rating: OK

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Question: `q005. Both the mass and velocity of an object contribute to its

effectiveness in a collision. If a 250-lb football player moving at 10 feet

per second collides head-on with a 200-lb player moving at 20 feet per

second in the opposite direction, which player do you precidt will be moving

backward immediately after the collision, and why?

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Your solution:

Momentum of Player One:

250 * 10 = 2500 lb*f/s

Momentum of Player Two

200 * 20 = 4000 lb*f/s

When the two players collide, Player One will be moving backward

immediately, as his momentum is much less than that of Player Two.

confidence rating #$&*: 3

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Given Solution:

`aGreater speed and greater mass both provide advantages. In this case the

player with the greater mass has less speed, so we have to use some

combination of speed and mass to arrive at a conclusion.

It turns out that if we multiply speed by mass we get the determining

quantity, which is called momentum. 250 lb * 10 ft/sec = 2500 lb ft / sec

and 200 lb * 20 ft/sec = 4000 lb ft / sec, so the second player will

dominate the collision.

In this course we won't use pounds as units, and in a sense that will become

apparent later on pounds aren't even valid units to use here. However that's

a distinction we'll worry about when we come to it.

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Self-critique (if necessary): OK

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Self-critique Rating: OK

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Question: `q006. Two climbers eat Cheerios for breakfast and then climb up a

steep mountain as far as they can until they use up all their energy from

the meal. All other things being equal, who should be able to climb further

up the mountain, the 200-lb climber who has eaten 12 ounces of Cheerios or

the 150-lb climber who has eaten 10 ounces of Cheerios?

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Your solution:

We are given: Mass, and a Cheerio quantity. The only formulas I have right

now for mass are Force = mass * acceleration, and Momentum = mass *

velocity.

After deciding Cheerios are best expressed, from the above choices, as an

expression of momentum,

12 = 200 * v

12 / 200 = v

3 / 50 = v

v = .06

10 = 150 * v

10 / 150 = v

1 / 15 = v

v = .06666666

The smaller climber who ate 10 ounces of Cheerios will be able to go

further.

confidence rating #$&*: 2

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Given Solution:

`aThe comparison we make here is the number of ounces of Cheerios per pound

of body weight. We see that the first climber has 12 oz / (200 lb) = .06 oz

/ lb of weight, while the second has 10 0z / (150 lb) = .067 oz / lb. The

second climber therefore has more energy per pound of body weight.

It's the ounces of Cheerios that supply energy to lift the pounds of

climber. The climber with the fewer pounds to lift for each ounce of

energy-producing Cheerios will climb further.

STUDENT COMMENT

I am satisfied with how I worked out the problem, though it would be nice to

know what formulas to use in case my instinct is wrong. I should have got

the energy used per pound by rereading the question.

INSTRUCTOR RESPONSE

There are two points to these problems:

1. You can go a long ways with common sense, intuition or instinct, and you

often don't need formulas.

2. Common sense, intuition and instinct aren't the easiest things to apply

correctly, and it's really easy to get things turned around.

A corollary: When we do use formulas it will be important to understand

them, as best we can, in terms of common sense and experience.

Either way, practice makes the process easier, and one of the great benefits

of studying physics is that we get the opportunity to apply common sense in

situations where we can get feedback by experimentally testing our thinking.

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Self-critique (if necessary): I believe I missed the point of this problem

entirely. I spent a long time trying to find a suitable formula for this

problem, and missed the obvious common-sense answer. I need to slow down

and try to think these things through, instead of relying solely on

formalas.

I did reach the right conclusion, I believe, however.

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Self-critique Rating: 3

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Question: `q007. Two automobiles are traveling up a long hill with an

steepness that doesn't change until the top, which is very far away, is

reached. One automobile is moving twice as fast as the other. At the instant

the faster automobile overtakes the slower their drivers both take them out

of gear and they coast until they stop.

Which automobile will take longer to come to a stop? Will that automobile

require about twice as long to stop, more than twice as long or less than

twice as long?

Which automobile will have the greater average coasting velocity? Will its

average coasting velocity by twice as great as the other, more than twice as

great or less than twice as great?

Will the distance traveled by the faster automobile be equal to that of the

slower, twice that of the slower or more than twice that of the slower?

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Your solution:

The automobile going faster will take about twice as long to stop. Because

their rate of decceleration is the same, and one cars speed is twice the

other, it will take twice as long to stop.

The faster automobile will have a greater average coasting velocity. It

will be a little less than twice as great.

The distancce if the faster automobile will be twice the distance of the

slower automobile.

confidence rating #$&*: 3

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Given Solution:

`aIt turns out that, neglecting air resistance, since the slope is the same

for both, both automobiles will change velocity at the same rate. So in this

case the second would require exactly twice as long.

If you include air resistance the faster car experiences more so it actually

takes a bit less than twice as long as the slower.

For the same reasons as before, and because velocity would change at a

constant rate (neglecting air resistance) it would be exactly twice as great

if air resistance is neglected.

Interestingly if it takes twice as much time and the average velocity is

twice as great the faster car travels four times as far.

If there is air resistance then it slows the faster car down more at the

beginning than at the end and the average velocity will be a bit less than

twice as great and the coasting distance less than four times as far.

STUDENT COMMENT: I do not understand why the car would go four times as far

as the slower car.

INSTRUCTOR RESPONSE: The faster car takes twice as long to come to rest,

and have twice the average velocity.

If the car traveled at the same average velocity for twice as long it would

go twice as far.

If it traveled at twice the average velocity for the same length of time it

would go twice as far.

However it travels at twice the average velocity for twice as long, so it

goes four times as far.

STUDENT COMMENT:

it�s hard to know this stuff without having first discussed it in notes or

read it in the book, or

have an equation handy. I guess this will all come with the class.

INSTRUCTOR RESPONSE

One purpose of this and similar exercises is to get students into the habit

of thinking for themselves, as opposed to imitating what they see done in a

textbook. You're doing some good thinking. When you get to the text and

other materials, ideally you'll be better prepared to understand them as a

result of this process.

This works better for some students than others, but it's beneficial to just

about everyone.

STUDENT COMMENT

I understand, it seems as though it would be easier if there were formulas

to apply. I used a little common sense on all but

the last one. Reading the responses I somewhat understand the last one.

?????The problem doesn�t indicate the vehicle

travels twice the average velocity for twice as long. Should I have known

that by reading the problem or should that have

become clear to me after working it some?????

INSTRUCTOR RESPONSE

You did know these things when you thought about the problem.

You concluded that the automobile would take twice as long to come to rest,

and that it would have twice the coasting velocity. You just didn't put the

two conclusions together (don't feel badly; very few students do, and most

don't get as close as you did).

You should now see how your two correct conclusions, when put together using

common sense, lead to the final conclusion that the second automobile

travels four times as far.

No formula is necessary to do this. In fact if students are given a formula,

nearly all will go ahead and use it without ever thinking about or

understanding what is going on.

In this course we tend to develop an idea first, and then summarize the idea

with one or more formulas. Once we've formulated a concept, the formula

gives us a condensed expression of our understanding. The formula then

becomes a means of remembering the ideas it represents, and gives us a tool

to probe even more deeply into the relationships it embodies.

There are exceptions in which we start with a formula, but usually by the

time we get to the formula we will understand, at least to some extent, what

it's about.

I suppose this could be put succinctly as 'think before formulating'.

STUDENT COMMENT

I feel that I did decent on the problem, but I am the student that likes to

have formulas. Your insight has opened my eyes to a different way of looking

at this problem. I like the comment �Think before Formulate�

INSTRUCTOR RESPONSE

Your solution was indeed well thought out.

I should probably add another comment:

'Think after formulating.'

Formulas are essential, but can't be applied reliably without the thinking,

which should come first and last.

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Self-critique (if necessary): The importance of thinking is becoming more

and more clear to me. I believe I have been relying on formulas too much in

the past.

I understand where I went wrong with the problem.

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Self-critique Rating: 2

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Question: `q008. When a 100 lb person hangs from a certain bungee cord, the

cord stretches by 5 feet beyond its initial unstretched length. When a

person weighing 150 lbs hangs from the same cord, the cord is stretched by 9

feet beyond its initial unstretched length. When a person weighing 200 lbs

hangs from the same cord, the cord is stretched by 12 feet beyond its

initial unstretched length.

Based on these figures, would you expect that a person of weight 125 lbs

would stretch the cord more or less than 7 feet beyond its initial

unstretched length?

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Your solution:

I would expect the cord to stretch a little bit more than seven feet.

confidence rating #$&*: 3

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Given Solution:

`aFrom 100 lbs to 150 lbs the stretch increased by 4 feet, from 150 lbs to

200 lbs the increase was only 3 feet. Thus it appears that at least in the

100 lb - 200 lb rands each additional pound results in less increase in

length than the last and that there would be more increase between 100 lb

and 125 lb than between 125 lb and 150 lb. This leads to the conclusion that

the stretch for 125 lb would be more than halfway from 5 ft to 9 ft, or more

than 7 ft.

A graph of stretch vs. weight would visually reveal the nature of the

nonlinearity of this graph and would also show that the stretch at 125 lb

must be more than 7 feet (the graph would be concave downward, or increasing

at a decreasing rate, so the midway stretch would be higher than expected by

a linear approximation).

STUDENT COMMENT

I feel like I nailed this one. Probably just didn�t state things very

clearly.

INSTRUCTOR RESPONSE

You explanation was very good.

Remember that I get to refine my statements, semester after semester, year

after year. You get one shot and you don't have time to hone it to

perfection (not to say that my explanations ever achieve that level).

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Self-critique (if necessary): I found this solution by plotting the points

on a graph and noticing the concave nature of the curve. If it was a

perfectly straight line, it would have been at 7 exactly, however, due to

the curve of the line, it had to be slightly above that.

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Self-critique Rating: 3

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Question: `q009. When given a push of 10 pounds, with the push maintained

through a distance of 4 feet, a certain ice skater can coast without further

effort across level ice for a distance of 30 feet. When given a push of 20

pounds (double the previous push) through the same distance, the skater will

be able to coast twice as far, a distance of 60 feet. When given a push of

10 pounds for a distance of 8 feet (twice the previous distance) the skater

will again coast a distance of 60 feet.

The same skater is now accelerated by a sort of a slingshot consisting of a

bungee-type cord slung between two posts in the ice. The cord, as one might

expect, exerts greater and greater force as it is pulled back further and

further. Assume that the force increases in direct proportion to pullback

(ie.g., twice the pullback implies twice the force).

When the skater is pulled back 4 feet and released, she travels 20 feet.

When she is pulled back 8 feet and released, will she be expected to travel

twice as far, more than twice as far or less than twice as far as when she

was pulled back 4 feet?

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Your solution:

As doubling the distance pushed doubles the distance travelled, and doubling

the force doubles the distance travelled, then with both doubled she would

travel 4 times the distance she did before. 80 ft.

confidence rating #$&*: 3

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Given Solution:

`aThe distance through which the force acts will be twice as great, which

alone would double the distance; because of the doubled pullback and the

linear proportionality relationship for the force the average force is also

twice as great, which alone would double the distance. So we have to double

the doubling; she will go 4 times as far

STUDENT COMMENT: I do not understand the linear proportionality

relationship for the force.

If the skater is pulled back an extra four feet, does that mean that the

amount of pounds propelling her is also doubled?

INSTRUCTOR COMMENT: That is so. However the force propelling her isn't the

only thing that influences how far she slides. The distance through which

the force is applied is also a factor.

Doubling the force alone would double the sliding distance.

Doubling the distance through which the force is applied would double the

sliding distane.

Doubling both the applied force and the distance through which it is applied

quadruples the sliding distance.

STUDENT SOLUTION AND QUESTION

She should travel three times as far. The first four feet pulled back yield

20 feet of travel. The second four feet (i.e., feet 5 through 8) will propel

her with twice the force as the first four feet. So this interval, by

itself, would propel her 40 feet. The 20 feet of the first four-foot

interval plus the 40 feet of the second four-foot interval is 60 feet total.

But wouldn�t it be the case that by the time the slingshot reaches the

four-foot position, the force exerted on the skater would only be half of

that exerted when she was eight feet out? I understand why it would be a

multiplier of four if the force were the same throughout, but I�m assuming

that the force will decrease as the slingshot is contracts.

I would appreciate help with this question. Thanks.

INSTRUCTOR RESPONSE

The average force for the entire 8-foot pull would be double the average

force for the 4-foot pull. At this point we don't want to get too

mathematical so we'll stick to a numerical plausibility argument. This

argument could be made rigorous using calculus (just integrate the force

function with respect to position), but the numerical argument should be

compelling:

Compare the two pulls at the halfway point of each. For a convenient number

assume that the 4-foot pull results in a force of 100 lb. Then the 8-foot

pull will therefore exert a force of 200 lb.

When released at the 4-foot mark, the skater will be halfway back at the 2-

foot mark, where she will experience a 50-lb force.

When released at the 8-foot mark, the skater will be halfway back at the 4-

foot mark, where she will experience a 100-lb force.

Since the force is proportional to pullback, the halfway force is in fact

the average force.

Note that during the second 4 ft of the 8 ft pull the force goes from 100 lb

to 200 lb, so the average force for the second 4 ft is 150 lb, three times

as great as the average force for the first 4 ft. The max force for the

second 4 ft is double that of the first 4 ft, but the second 4 ft starts out

with 100 lbs of force, while the first 4 ft starts out with 0 lbs.

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Self-critique (if necessary): OK

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Self-critique Rating: OK

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Question: `q010. Two identical light bulbs are placed at the centers of

large and identically frosted glass spheres, one of diameter 1 foot and the

other of diameter 2 feet.

To a moth seeking light from half a mile away, unable to distinguish the

difference in size between the spheres, will the larger sphere appear

brighter, dimmer or of the same brightness as the first?

To a small moth walking on the surface of the spheres, able to detect from

there only the light coming from 1 square inch of the sphere, will the

second sphere appear to have the same brightness as the first, twice the

brightness of the first, half the brightness of the first, more than twice

the brightness of the first, or less than half the brightness of the first?

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Your solution:

From a vast distance, the larger sphere will appear to be the same

brightness as the smaller sphere.

From walking on the spheres, the smaller sphere will appear to be twice as

bright as the larger sphere.

This is because the light in the larger sphere is distributed over a larger

amount of glass, thus making any one square inch on the glass half as bright

as the smaller sphere. From a distance, the differences in size and light

distribution equal out and the spheres appear the same brightness.

confidence rating #$&*: 3

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Given Solution:

`aBoth bulbs send out the same energy per second. The surface of the second

bulb will indeed be dimmer than the first, as we will see below. However the

same total energy per second reaches the eye (identically frosted bulbs will

dissipate the same percent of the bulb energy) and from a great distance you

can't tell the difference in size, so both will appear the same. The second

sphere, while not as bright at its surface because it has proportionally

more area, does have the extra area, and that exactly compensates for the

difference in brightness. Specifically the brightness at the surface will be

1/4 as great (twice the radius implies 4 times the area which results in 1/4

the illumination at the surface) but there will be 4 times the surface area.

Just as a 2' x 2' square has four times the area of a 1' x 1' square, a

sphere with twice the diameter will have four times the surface area and

will appear 1 / 4 as bright at its surface. Putting it another way, the

second sphere distributes the intensity over four times the area, so the

light on 1 square inch has only 1 / 4 the illumination.

STUDENT COMMENT: I understand the first part of the problem about the

distances. But the second part really confuses me. Looking straight down

from the top of the spheres, the bulb is the same intensity and the frosted

glass is exactly the same, so why would it seem dimmer? I would think that

if a person was standing in front of the spheres, that person would be able

to tell a difference, but not extremely close.

INSTRUCTOR RESPONSE: Imagine a light bulb inside a frosted glass lamp of

typical size. Imagine it outside on a dark night. If you put your eye next

to the glass, the light will be bright. Not as bright as if you put your eye

right next to the bulb, but certainly bright. The power of the bulb is

spread out over the lamp, but the lamp doesn't have that large an area so

you detect quite a bit of light.

If you put the same bulb inside a stadium with a frosted glass dome over it,

and put your eye next to the glass on a dark night, with just the bulb lit,

you won't detect much illumination. The power of the bulb is distributed

over a much greater area than that of the lamp, and you detect much less

light.

STUDENT COMMENT:

I also didn�t get the second part of the question. I still don�t really see

where the � comes from.

INSTRUCTOR RESPONSE:

First you should address the explanation given in the problem:

'Just as a 2' x 2' square has four times the area of a 1' x 1' square, a

sphere with twice the diameter will have four times the surface area and

will appear 1 / 4 as bright at its surface. Putting it another way, the

second sphere distributes the intensity over four times the area, so the

light on 1 square inch has only 1 / 4 the illumination. '

Do you understand this explanation?

If not, what do you understand about it and what don't you understand?

This simple image of a 2x2 square being covered by four 1x1 squares is the

most basic reason the larger sphere has four time the area of the smaller.

There is, however, an alternative explanation in terms of formulas:

The surface area of a sphere is 4 pi r^2.

If r is doubled, r^2 increases by factor 2^2 = 4.

So a sphere with double the radius has four time the area.

If the same quantity is spread out over the larger sphere, it will be

1/4 as dense on the surface.

STUDENT COMMENT:

I also have no clue why the extra area doesn�t take away some brightness.

INSTRUCTOR RESPONSE:

All the light produced by the bulb is passing through either of the spheres.

From a distance you see all the light, whichever sphere you're looking at;

you see just as much light when looking at one as when looking at the other.

From a distance you can't tell whether you're looking at the sphere with

larger area but less intensity at its surface, or the sphere with lesser

area and greater intensity at its surface.

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Self-critique (if necessary): I had everything except for the 1/4th. I

neglected to account for the ratio between areas being different than the

ration between diameters. I understand my mistake now.

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Self-critique Rating: 3

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Question: `q011. The water in a small container is frozen in a freezer until

its temperature reaches -20 Celsius. The container is then placed in a

microwave oven, which proceeds to deliver energy at a constant rate of 600

Joules per second. After 10 seconds the ice is still solid and its

temperature is -1 Celsius. After another 10 seconds a little bit of the cube

is melted and the temperature is 0 Celsius. After another minute most of the

ice is melted but there is still a good bit of ice left, and the ice and

water combination is still at 0 Celsius. After another minute all the ice is

melted and the temperature of the water has risen to 40 degrees Celsius.

Place the following in order, from the one requiring the least energy to the

one requiring the most:

Increasing the temperature of the ice by 20 degrees to reach its melting

point.

Melting the ice at its melting point.

Increasing the temperature of the water by 20 degrees after all the ice

melted.

At what temperature does it appear ice melts, and what is the evidence for

your conclusion?

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Your solution:

The order is as follows:

Increasing the temperature of the water by 20 degrees after all the ice

melted.

Increasing the temperature of the ice by 20 degrees to reach its melting

point.

Melting the ice at its melting point.

Ice appears to melt at 0 degrees Celsius. It did not melt at all before this temperature was reached, and it did not move away from this temperature until after it was melted.

confidence rating #$&*: 3

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Given Solution:

Since the temperature is the same when a little of the ice is melted as when

most of it is melted, melting takes place at this temperature, which is 0

Celsius.

The time required to melt the ice is greater than any of the other times so

melting at 0 C takes the most energy. Since we don't know how much ice

remains unmelted before the final minute, it is impossible to distinguish

between the other two quantities, but it turns out that it takes less energy

to increase the temperature of ice than of liquid water.

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Self-critique (if necessary): I did not realize that the two quantities were indistinguishable. Because of how fast the temperature rose after the water was melted, I assumed it took less energy. I realize now my error.

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Self-critique Rating: 2

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Question: `q012. Suppose you are in the center of a long, narrow swimming

pool (e.g., a lap pool). Two friends with kickboards, one at either end of

the pool, are using them to push waves in your direction. Their pushes are

synchronized, and the crests of the waves are six feet apart as they travel

toward you, with a 'valley' between each pair of crests. Since your friends

are at equal distances from you the crests from both directions always reach

you at the same instant, so every time the crests reach you the waves

combine to create a larger crest. Similarly when the valleys meet you

experience a larger valley, and as a result you bob up and down further than

you would if just one person was pushing waves at you.

Now if you move a bit closer to one end of the pool the peak from that end

will reach you a bit earlier, and the peak from the other end will reach you

a little later. So the peaks won't quite be reaching you simultaneously, nor

will the valleys, and you won't bob up and down as much. If you move far

enough, in fact, the peak from one end will reach you at the same time as

the valley from the other end and the peak will 'fll in' the valley, with

the result that you won't bob up and down very much.

If the peaks of the approaching waves are each 6 inches high, how far would

you expect to bob up and down when you are at the center point?

How far would you have to move toward one end or the other in order for

peaks to meet valleys, placing you in relatively calm water?

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Your solution:

At the center point, 12 inches up, then 12 inches down, for a total of 24 inches.

If the period of the waves is 6 feet, you would need to move 3 feet in either direction.

confidence rating #$&*:

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Given Solution:

`aIf the two 6-inch peaks meet and reinforce one another completely, the

height of the 'combined' peak will be 6 in + 6 in = 12 in.

If for example you move 3 ft closer to one end you move 3 ft further from

the other and peaks, which are 6 ft apart, will still be meeting peaks. [

Think of it this way: If you move 3 ft closer to one end you move 3 ft

further from the other. This shifts your relative position to the two waves

by 6 feet (3 feet closer to the one you're moving toward, 3 feet further

from the other). So if you were meeting peaks at the original position,

someone at your new position would at the same time be meeting valleys, with

two peaks closing in from opposite directions. A short time later the two

peaks would meet at that point. ]

However if you move 1.5 ft the net 'shift' will be 3 ft and peaks will be

meeting valleys so you will be in the calmest water.

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Self-critique (if necessary): Oh! I neglected to account for the shift of the other waves as well. 1.5 makes much more sense.

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Self-critique Rating: 2

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Question: `q013. This problem includes some questions that are fairly

straightfoward, some that involve more complicated considerations, and

possibly some that can't be answered without additional information.

We're hoping for some correct answers, but we expect that few students

coming into this course will be able to think correctly through every nuance

of the more complex situations. On these questions we are hoping for your

best thinking without being particularly concerned with the final answer.

A steel ball and a wood ball are both thrown upward and, between release and

coming to rest at maximum height, both rise with the same average speed. If

not for air resistance they would both come to rest at the same time, at the

same height. However air resistance causes the wood ball to stop rising

more quickly than the steel ball.

Each ball, having risen to its maximum height, then falls back to the

ground.

Which ball would you expect to have the greater average velocity as it

falls?

Which ball would you expect to spend the greater time falling?

Which ball would you expect to hit the ground first?

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Your solution:

I would expect the steel ball to have a greater average velocity, for two reasons. One, it has less air resistance against it, as demonstrated by the fact it rose higher than the wooden ball. Two, it has a further distance to fall and gain speed.

I would expect the wooden ball to have a greater time falling, due to its slower velocity and increased air resistance. However, it is entirely possible that the metal ball would have a greater time. The metal ball must fall a longer distance to reach the ground.

Which ball hits the ground first would depend entirely on the respective heights and velocities of the balls. The steel ball will fall with a greater velocity than the wooden ball, but it also has less distance to cover, and the wooden ball gains a head start by beginning its descent while the metal ball is still rising to its maximum height.

confidence rating #$&*: 2

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Question: `q014. If you double the voltage across a certain circuit you

double the current passing through it. The power required to maintain the

circuit is equal to the product of the current and the voltage. How many

times as much power is required if the voltage is doubled?

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Your solution: 4 times as much power.

confidence rating #$&*: 3

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Self-critique (if necessary):

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Self-critique rating: