Assignment 14 qa

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course Phy 121

11/22 10 pm

014. Potential energy; conservative and non-conservative forces. *********************************************

Question: `q001. An automobile of mass 1500 kg coasts from rest through a displacement of 200 meters down a 3% incline. How much work is done on the automobile by its weight component parallel to the incline?

If no other forces act in the direction of motion (this assumes frictionless motion, which is of course not realistic but we assume it anyway because this ideal situation often gives us valuable insights which can then be modified to situations involving friction), what will be the final velocity of the automobile?

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Your solution:

First we must calculate weight.

weight = m * 9.8 m/s^2 = 1500 kg * 9.8 m/s^2 = 14700 Newtons

Now we must find the parallel weight component

Parallel weight component = weight * incline = 14700 Newtons * .03 = 441 Newtons

`dwnet = 441 Newtons * 200 m = 88200 Joules

Well since we know the mass and the Fnet we can find acceleration, which will ultimately give us vf through further analysis.

Fnet = m * a

a = Fnet / m = 441 kg * m/s^2 / 1500 kg = 0.29 m/s^2 (I think I am wrong here)

Now we know that v0 = 0, `ds = 200 m, and a = 0.29 m/s^2

vf^2 = v0^2 + 2 a `ds = 0 + 2 * 0.29 m/s^2 * 200 m = 116 m^2/s^2

vf = sqrt(116 m^2/s^2) = +-10.8 m/s

I am going to assume that it is moving in the deamed positive direction, therefore making it positive 10.8 m/s

confidence rating #$&*:

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Given Solution:

The weight of the automobile is 1500 kg * 9.8 m/s^2 = 14,700 Newtons. The weight component parallel to the incline is therefore very close to the small-slope approximation

weight * slope = 14700 Newtons * .03 = 441 Newtons (small-slope approximation).

If no other forces act parallel to the incline then the net force will be just before 441 Newtons and the work done by the net force will be

`dWnet = 441 Newtons * 200 meters = 88200 Joules.

[ Note that this work was done by a component of the gravitational force, and that it is the work done on the automobile by gravity. ]

The net work on a system is equal to its change in KE. Since the automobile started from rest, the final KE will equal the change in KE and will therefore be 88200 Joules, and the final velocity is found from 1/2 m vf^2 = KEf to be

vf = +_`sqrt(2 * KEf / m) = +-`sqrt(2 * 88200 Joules / (1500 kg) ) = +-`sqrt(2 * 88200 kg m^2/s^2 / (1500 kg) ) = +- 10.9 m/s (approx.).

Since the displacement down the ramp is regarded as positive and the automotive will end up with a velocity in this direction, we choose the +10.9 m/s alternative.

STUDENT QUESTION: I assume the perpendicular force is balanced beause of the normal force downward of gravity and mass and then upward from the road.

INSTRUCTOR RESPONSE:

Good, but there's a little more to it:

The normal force balances the component of the gravitational force which is perpendicular to the road. The component of the gravitational force parallel to the incline is the for that tends to accelerated objects downhill.

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Self-critique (if necessary):

I didn't even think to use the other equation, it would have been much simpler, but at any rate, given the way I solved my answer, I think I did everything correctly.

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Self-critique rating:3

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Question: `q002. If the automobile in the preceding problem is given an initial velocity of 10.9 m/s up the ramp, then if the only force acting in the direction of motion is the force of gravity down the incline, how much work must be done by the gravitational force in order to stop the automobile?

How can this result be used, without invoking the equations of motion, to determine how far the automobile travels up the incline before stopping?

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Your solution:

First I would take the parallel weight component of 441 Newtons and subtract the frictional force from it. I believe the frictional force would be 9.8 Newtons.

This would give you 431.2 Newtons, but I think I am doing this wrong and I am not sure what to do from here.

confidence rating #$&*:

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Given Solution:

This is an application of the work-kinetic energy theorem.

In words, this theorem says that

the change in KE is equal to the work done by the net force acting ON the system

In symbols, this is expressed

`dW_net = `d(KE).

KE is kinetic energy, equal to 1/2 m v^2.

The automobile starts out with kinetic energy

KEinit = 1/2 m v0^2 = 1/2 (1500 kg) ( 10.9 m/s)^2 = 88000 kg m^2/s^2 = 88000 Joules.

The gravitational force component parallel to the incline is in this case opposite to the direction of motion so that gravity does negative work on the automobile. Since the change in KE is equal to the work done by the net force acting ON the system, if the gravitational force component parallel to the incline does negative work the KE of the object will decrease. This will continue until the object reaches zero KE.

As found previously the gravitational force component along the incline has magnitude 441 Newtons. In this case the forces directed opposite to the direction motion, so if the direction up the incline is taken to be positive this force component must be -441 N. By the assumptions of the problem this is the net force exerted on the object.

Acting through displacement `ds this force will therefore do work `dWnet = Fnet * `ds = -441 N * `ds. Since this force must reduce the KE from 88,000 Joules to 0, `dWnet must be -88,000 Joules. Thus

`dW_net = -441 N * `ds = -88,000 Joules

and

`ds = -88,000 J / (-441 N) = 200 meters (approx.).

Had the arithmetic been done precisely, using the precise final velocity found in the previous exercise instead of the 10.9 m/s approximation, we would have found that the displacement is exactly 200 meters.

STUDENT QUESTION

I set `dKE = Fnet * `ds and had `dKE as negative so I came up with the correct solution

but just above you say that work is negative.

I don’t understand how work is negative, especially going by the equation because I thought work was opposite `dKE.

INSTRUCTOR RESPONSE

You're thinking about exactly the right things.

The specific statement of the work-KE theorem is that the work done by the net force acting ON the system is equal to the change in the kinetic energy of the system. This is abbreviated

`dW_ON_net = `dKE.

Rather that talking about 'the work', it's very important to get into the habit of labeling 'the work' very specifically. You have two basic choices. You can think in terms of

the work done on the system or object by a force

the work done by the system or object against a force

The two are equal and opposite.

Note that the words 'on' and 'by' modify the word 'system', not the word 'force'.

The key phrases are 'on the system' and 'by the system'.

In the present case if you were to choose to think in terms of the work done by the net force exerted by object, then this force would be labeled `dW_BY_net and would be equal and opposite to `dW_ON_net, the work exerted by the net force acting on the object. Formally we would have

`dW_BY_net = - `dW_ON_net so that

`dW_BY_net = - `dKE.

This last equation is often written

`dW_BY_net + `dKE = 0,

and is another equivalent formulation of the work-kinetic energy theorem.

STUDENT COMMENT

I am getting all the equations mixed up is there any way you can just send the different equations? I understand the 4 from the major quiz. I can do the algebra I just don’t know which equation to plug it in for.

INSTRUCTOR RESPONSE

Physics is about more than figuring out what to plug into what equation. It's necessary to understand the words and the concepts to know which equation to plug into. In other words, the concepts are what keep us from getting the equations mixed up.

However I have observed in your work that you do very well with the algebra. So the equations might well be your most appropriate starting point. You can use the equations to understand the words and the concepts, just as less algebraically adept students might use the words and concepts to understand the equations.

The relevant relationships here are

`dW_net = `dKE and

KE = 1/2 m v^2.

The relationship

`dW_BY_net = - `dW_ON_net

is also invoked in the additional comments at the end, which mention an alternative formulation of the work-kinetic energy theorem. However this relationship is not used in solving this particular problem.

STUDENT COMMENT

OK, I understand the solution and will use _on and _by descriptors in my

answers from now on.

INSTRUCTOR RESPONSE

Good.

Remember that ON and BY are adjectives applied to the word 'system', not to the word 'force'.

That is, you have to determine whether the force is acting ON the system, or is exerted BY the system.

Your choice of point of view will determine whether you use the equation

`dW_NC_ON = `dPE + `dKE

or

`dW_NC_BY + `dPE + `dKE = 0.

STUDENT COMMENT

Ok. I see why my ‘ds was negative. The F is negative in this system because it is working against the positive motion of the car UP the ramp. For every force, there is an equal and OPPOSITE force.

INSTRUCTOR RESPONSE

Good. If you assume the positive direction to be up the incline, F_net is negative, as you say, but the specific reason is slightly different than the one you give. It's good to think in terms of equal and opposite forces, but the motion of the car is not a force.

In this case it really just comes down to signs:

The force used to calculate `dW_net was the net force acting on the car. That force acts down the incline, in the direction opposite motion. Therefore F_net and `ds are of opposite sign, and the net force acting on the car does negative work. This decreases the KE, as your solution indicates.

The question of whether `ds is positive or negative depends on which direction you choose for the positive direction. In your solution you apparently thought of upward as the positive direction; you should have explicitly stated this. Relative to this choice F_net is negative.

As I mentioned, you should have declared the positive direction in your solution. You could have chosen either upward (which is the direction of the displacement, and is the direction you implicity chose) or downward (which is the direction of the net force) to be the positive direction.

Either choice of positive direction would have been perfectly natural. If you had chosen 'down the incline' to be the positive direction, then `ds would have been negative (therefore opposite to the downward direction, so up the incline). In either case, `ds would have been up the incline.

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Self-critique (if necessary):

Now I sort of understand what to do. This was a very elaborate problem and I will reference it from here on out if and when I have difficulties with other similar problems. I don't understand all of this completely yet, but I really am trying to grasp it to the best of my ability.

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Self-critique rating:3

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Keep working diligently and this should fall into place soon.

It will help if you keep track of work and energy relationships throughout.

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Question: `q003. If the automobile in the previous example rolls from its maximum displacement back to its original position, without the intervention of any forces in the direction of motion other than the parallel component of the gravitational force, how much of its original 88200 Joules of KE will it have when it again returns to this position?

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Your solution:

Okay, so in the last problem, I was not able to get the right answer, but in the given solution, the max displacement was 200 m and the direction of motion was down the ramp. The parallel force component was 441 in the positive direction as found in the first question.

The KE was 88,200 at this point.

In the second problem, the number of Joules accounted for was 88,000.

I am not sure how to solve for this problem, or those alike yet, but I would guess to say that 88,000 Joules would be left and 200 of them would be gone.

confidence rating #$&*:

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Given Solution:

In the first exercise in the present series of problems related to this ramp, we found that when the automobile coasts 200 meters down the incline its KE increases by an amount equal to the work done on it by the gravitational force, or by 88200 Joules. Thus the automobile will regain all of its 88200 Joules of kinetic energy.

To summarize the situation here, if the automobile is given a kinetic energy of 88200 Joules at the bottom of the ramp then if it coasts up the ramp it will coast until gravity has done -88200 Joules of work on it, leaving it with 0 KE. Coasting back down the ramp, gravity works in the direction of motion and therefore does +88200 Joules of work on it, thereby increasing its KE back to its original 88200 Joules.

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Self-critique (if necessary):

I see what the correct answer is here now, but it is still a bit of a mystery to me still.

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Self-critique rating:3

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The work done on the automobile going up the incline was done by the gravitational force. That work brought the automobile to a stop, so the original 88 200 Joules of kinetic energy was reduced to zero and the gravitational potential energy increased by 88 200 Joules.

Coming back down, the gravitational force was exactly that same as when the automobile went up the incline, and the automobile traveled the same distance but in the opposite direction. So the gravitational force did an equal and opposite amount of work, bringing the KE back up to 88 200 Joules.

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Question: `q004. Explain why, in the absence of friction or other forces other than the gravitational component parallel to incline, whenever an object is given a kinetic energy in the form of a velocity up the incline, and is then allowed to coast to its maximum displacement up the incline before coasting back down, that object will return to its original position with the same KE it previously had at this position.

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Your solution:

I would say that this is because the change in net work done ON the system doesn't change, therefore making the change in Kinetic energy stay the same as well.

confidence rating #$&*:

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Given Solution:

The car initially had some KE. The gravitational component parallel to the incline is in the direction opposite to the direction of motion up the incline and therefore does negative work ON the object as it travels up the incline.

The gravitational component is the net force on the object, so the work done by this net force on the system causes a negative change in KE, which eventually decreases the KE to zero so that the object stops for an instant. This happens at the position where the work done BY the net force is equal to the negative of the original KE.

The gravitational component parallel to the incline immediately causes the object to begin accelerating down the incline, so that now the parallel gravitational component is in the same direction as the motion and does positive work ON the system.

At any position on the incline, the negative work done by the gravitational component as the object traveled up the incline from that point, and the positive work done by this force as the object returns back down the incline, must be equal and opposite.

This is because the displacement up the incline and the displacement down the incline are equal and opposite, while the parallel gravitational force component remains the same. Thus the Fnet * `ds products for the motion up and the motion down equal and opposite.

When the object reaches its original point, the work that was done on it by the net force, as it rolled up the incline, must be equal and opposite to the work done on it while coasting down the incline. Since the work done on the object while coasting up the incline was the negative of the original KE, the work done while coasting down, being the negative of this quantity, must be equal to the original KE. Thus the KE must return to its original value.

STUDENT QUESTION

I still really don’t understand how it can return back to its original position because of what we saw

in class It never returned back to its original position.

INSTRUCTOR RESPONSE

There are a number of situations in which an object doesn't return to its original position.

The one that's relevant to this situation:

When you rolled the ball up the single incline, it slowed, came to rest for an instant, and then rolled back down. It did return to its initial position. Of course when it got there is was moving pretty fast so if you didn't stop it, it kept going until something else did.

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Self-critique (if necessary):

I believe I understand this concept a little better now.

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Self-critique rating:3

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Question: `q005. As the object travels up the incline, does gravity do positive or negative work on it? Answer the same question for the case when the object travels down the incline.

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Your solution:

As the object moves up the incline, gravity does negative work on it. As the object moves down, gravity does positive work on it.

confidence rating #$&*:

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Given Solution:

As the object travels up the incline the net force is directed opposite its direction of motion, so that Fnet_ON and `ds have opposite signs and as a result `dWnet = Fnet_ON * `ds must be negative.

As the object travels down the incline the net force is in the direction of its motion so that Fnet_ON and `ds have identical signs and is a result `dWnet = Fnet_ON * `ds must be positive.

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Self-critique (if necessary):OK

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Self-critique rating:OK

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Question: `q006. If positive work is done on the object by gravity, will it increase or decrease kinetic energy of the object?

Answer the same question if negative work is done on the object by gravity.

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Your solution:

I believe it will increase kinetic energy of the object.

I believe it will decrease kinetic energy of the object if negative work is done on the object by gravity.

confidence rating #$&*:

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Given Solution:

The KE change of an object must be equal to the work done ON the system by the net force. Therefore if positive work is done on an object by the net force its KE must increase, and if negative work is done by the net force the KE must decrease.

STUDENT QUESTION (instructor comments in parentheses)

Ok, after reading a couple of time I get it dw will be equal to KE. If dw is - Ke will be - .

KE can't be negative; `dW is not equal to KE, but to `dKE, the change in KE.

`dKE can certainly be positive or negative (or zero), depending on the situation.

I am still a little unclear about if the dw done on an object is negative then what direction is it

moving??

The sign of `dW by the net force does not determine the direction of motion of the object. It determines only the change in its kinetic energy.

In the present case, the net force is the component of gravity along the incline. The direction of motion of the object determines whether this force is in the direction of motion or opposite that direction, and so determines whether the displacement is in the direction of motion (implying positive work) or opposite the direction of motion (implying negative work).

The direction of motion thus determines, for this situation, whether `dW_net is positive or negative.

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Self-critique (if necessary):OK

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Self-critique rating:OK

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Question: `q007. While traveling up the incline, does the object do positive or negative work against gravity?

Answer the same question for motion down the incline.

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Your solution:

While traveling up the incline, I would assume that the object does positive work against gravity.

While traveling down the incline, I would assume that the object does negative work against gravity.

confidence rating #$&*:

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Given Solution:

If the object ends up in the same position as it began, the work done on the object by gravity and work done by the object against gravity must be equal and opposite. Thus when the object does positive work against gravity, as when it travels up the incline, gravity is doing negative work against the object, which therefore tends to lose kinetic energy.

When the object does negative work against gravity, as when traveling down the incline, gravity is doing positive work against the object, which therefore tends to gain kinetic energy.

STUDENT COMMENT:

A little shaky on this problem because I feel its easy to get confused on the positive and negative.

INSTRUCTOR RESPONSE

This is the most common point of confusion at this stage of the course.

To sort out positive and negative, you would answer the following questions:

Are you thinking about the work done ON the system or BY the system (i.e., are you thinking about the forces acting ON the system or a forces exerted BY the system)? The ON and the BY are equal and opposite.

Whichever force you are thinking about, it does positive work when it is in the direction of motion and negative work when it is opposite the direction of motion.

STUDENT QUESTION

Ok, so i get his really mixed up. The work done BY the object is positve, against gravity which is doing negative work ON

the object going up the inlcine. When going down the incline work done BY the object is negative as work done ON the object by gravity is positive.

Is this right?

INSTRUCTOR RESPONSE

Your statement is correct.

And, until it 'clicks', this is certainly confusing. It takes most students a few assignments before this becomes clear. You are progressing nicely.

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Self-critique (if necessary):

This is starting to clear up a little bit for me.

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Self-critique rating:3

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Question: `q008. Suppose that the gravitational force component exerted parallel to a certain incline on an automobile is 400 Newtons and that the frictional force on the incline is 100 Newtons. The automobile is given an initial KE of 10,000 Joules up the incline. How far does the automobile coast up the incline before starting to coast back down, and how much KE does it have when it returns to its starting point?

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Your solution:

I am going to make the positive direction as being downward.

if the parallel compenent is 400 N in the positive direction, and the automobile is moving in the negative direction, then the component will then be -400 N.

I am going to infer that the frictional force is positive when moving up the incline (since it works against the direction of motion). Therefore here it is +100 N.

Therefore Fnet = -400 N + 100 N = -300 N

Since we are wanting to know how far it travels before coasting back down, I am assuming that KEf = 0 Joules, while we are given KE0 = 10,000 Joules. The change in KE here will then be -10,000 Joules. We have been shown that the net work ON a system is equal to its change in KE, so `dW_net = -10,000 Joules.

From this we can find `ds.

`dW_net = Fnet * `ds

`ds = `dW_net / Fnet = -10,000 Joules / -300 N = 33.3 m

In the last few problems we established that the kE will be the same as when it first began, so I am going to say thtat the KE when it returns to the starting point is 10,000 Joules.

confidence rating #$&*:

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Given Solution:

The net force ON the automobile as it climbs the incline is the sum of the 400 Newton parallel component of the gravitational force, which is exerted down the incline, and the 100 Newton frictional force, which while the automobile is moving up the incline is also exerted down the incline. Thus the net force is 500 Newtons down the incline.

This force will be in the direction opposite to the displacement of the automobile up the incline, and will therefore result in negative work being done on the automobile.

When the work done by this force is equal to -10,000 Joules (the negative of the original KE) the automobile will stop for an instant before beginning to coast back down the incline. If we take the upward direction to be positive the 500 Newton force must be negative, so we see that

-500 Newtons * `ds = -10,000 Joules

so

`ds = -10,000 Joules / -500 Newtons = 20 Newtons meters / Newtons = 20 meters.

After coasting 20 meters up the incline, the automobile will have lost its original 10,000 Joules of kinetic energy and will for an instant be at rest.

The automobile will then coast 20 meters back down the incline, this time with a 400 Newton parallel gravitational component in its direction of motion and a 100 Newton frictional force resisting, and therefore in the direction opposite to, its motion. The net force ON the automobile will thus be 300 Newtons down the incline.

The work done by the 300 Newton force acting parallel to the 20 m downward displacement will be 300 Newtons * 20 meters = 6,000 Joules. This is 4,000 Joules less than the when the car started.

This 4,000 Joules is the work done during the entire 40-meter round trip against a force of 100 Newtons which every instant was opposed to the direction of motion (100 Newtons * 40 meters = 4,000 Newtons). As the car coasted up the hill the frictional force was downhill and while the car coasted down friction was acting in the upward direction.

Had there been no force other than the parallel gravitational component, there would have been no friction or other nongravitational force and the KE on return would have been 10,000 Joules.

STUDENT QUESTION

I’m still not sure how I would find the final KE with all the other forces. I read the given

solution multiple times but I am still really confused.

INSTRUCTOR RESPONSE

Your solution was fine for motion up the incline, and agreed with the given solution to that point.

The first line of the given solution that you didn't address in your solution begins

'The automobile will then coast 20 meters back down the incline, ... '

The point you need to understand is that the 400 N gravitational component is still there, but since the car is moving down the incline the 100 N frictional force is now directed up the incline. So the net force on the car is 300 N down the incline.

You therefore know the net force acting on the system, and you know the displacement, so you can easily calculate the work `dW_ON done by this net force. This is equal to the change in KE as the car travels down the ramp.

The car began with 0 KE at the top (it came to rest for an instant), so you can figure out its final KE.

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Self-critique (if necessary):

I messed up in one of the very first steps of my solution. I just assumed that when the positive direction was established to be downward, that the frictional force would be in the opposite direction. Am I right in now thinking that the frictional force is positive in the direction opposing gravity? Or is that an invalid and inaccurate assumption to make?

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Self-critique rating:3

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The direction of frictional force is opposite to the direction of motion, so it always does negative work.

Going up the frictional force is down the incline and the displacement is up the incline. Coming down the frictional force is up the incline and the displacement is down.

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Question: `q009. The 1500 kg automobile in the original problem of this section coasted 200 meters, starting from rest, down a 3% incline. Thus its vertical displacement was approximately 3% of 200 meters, or 6 meters, in the downward direction.

Recall from the first few problems in this q_a_ that the parallel component of the gravitational force did 88200 Joules of work on the automobile. This, in the absence of other forces in the direction of motion, constituted the work done by the net force and therefore gave the automobile a final KE of 88200 Joules.

How much KE would be automobile gain if it was dropped 6 meters, falling freely through this displacement?

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Your solution:

KE = .5 m v^2 In order to find what values match up with the variables, I need to find the velocity here.

If it is going 6 m at 9.8 m/s^2, then we can see that the time it took to travel this much would be at about 0.61 s.

Therefore vAve = 6 m / 0.61 s = 9.83 m/s

Now we can substitute this in for the formula.

KE = .5 * 1500 kg * (9.83 m/s)^2 = .5 * 1500 kg * 96.6 m^2/s^2 = 72,450 Joules

Therefore if I did this correctly, the automobile would gain 72,450 Joules if it was dropped 6 meters.

confidence rating #$&*:

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Given Solution:

Gravity exerts a force of

gravitational force = 1500 kg * 9.8 m/s^2 = 14700 N

on the automobile. This force acting parallel to the 6 meter displacement would do

`dW by gravitational force = 14700 N * 6 meters = 88200 Joules of work on the automobile.

This is the work done by the entire gravitational force, not just by its component parallel to the incline. It is multiplied by the 6 meter vertical displacement of the automobile, since it acts along the same line as that displacement.

However this is identical to the work done on the automobile by the parallel component of the gravitational force in the original problem. In that problem the parallel component was multiplied by the displacement along the incline (which was much more than 6 meters), since it acts along the same line as that displacement.

STUDENT QUESTION

I do not see how it’s the same amount of work? 88200 Joules

INSTRUCTOR RESPONSE

The first few problems in this qa obtained KE = 88200 Joules.

They also obtained the result that the work done by the parallel component of the gravitational force acting on the system was 88200 Joules.

In this problem we see that in a straight 6 meter drop the work done by gravity is the same, 88200 Joules.

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Self-critique (if necessary):

All of this is very confusing and a bit overwhelming, but I am starting to see a little bit more clearly now.

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Self-critique rating:3

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Question: `q010. When the automobile was 200 meters 'up the incline' from the lower end of the 3% incline, it was in a position to gain 88200 Joules of energy. An automobile positioned in such a way that it may fall freely through a distance of 6 meters, is also in a position to gain 88200 Joules of energy. The 6 meters is the difference in vertical position between start and finish for both cases.

How might we therefore be justified in a conjecture that the work done on an object by gravity between two points depends only on the difference in the vertical position between those two points?

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Your solution:

We found earlier that the Net work ON a system is equal to its change in kinetic energy, therefore we can say that this assumption or conclusion would therefore be justified.

confidence rating #$&*:

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Given Solution:

This is only one example, but there is no reason to expect that the conclusion would be different for any other small incline. Whether the same would be true for a non-constant incline or for more complex situations would require some more proof. However, it can in fact be proved that gravitational forces do in fact have the property that only change in altitude (or a change in distance from the source, which in this example amounts to the same thing) affects the work done by the gravitational force between points.

STUDENT QUESTION

I am not sure about this concept could you elaborate? I am not really even sure what the question is asking in the first

place.

INSTRUCTOR RESPONSE

Subsequent questions will also reinforce this idea.

It was shown in previous problems that an automobile at the top of the ramp is in a position to gain about 88000 J

of kinetic energy, by rolling without friction down the incline.

It was also shown that an automobile that falls freely from the top of the ramp to the level of the bottom of the ramp will gain the same amount of kinetic energy.

In both cases the vertical position of the automobile changed by the same amount.

We therefore conjecture that there's something in the change in the vertical position of the automobile that determines

how much energy it can gain or lose to gravity.

STUDENT QUESTION

I got it right. Still cant completely figure ou t the concept though.

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INSTRUCTOR RESPONSE

14 700 N raised 6 meters requires 88 200 Joules.

If you roll the car up a 3% incline you only have to exert 3% of the 14 700 N weight (provided friction is negligible), but you have to travel 200 meters in order to raise the car 6 meters. If you multiply force by displacement, you again get 88 200 Joules.

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Self-critique (if necessary):OK

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Question: `q011. If an object has a way to move from a higher altitude to a lower altitude then it has the potential to increase its kinetic energy as gravity does positive work on it. We therefore say that such an object has a certain amount of potential energy at the higher altitude, relative to the lower altitude. As the object descends, this potential energy decreases. If no nongravitational force opposes the motion, there will be a kinetic energy increase, and the amount of this increase will be the same as the potential energy decrease. The potential energy at the higher position relative to the lower position will be equal to the work that would be done by gravity as the object dropped directly from the higher altitude to the lower.

A person holds a 7-kg bowling ball at the top of a 90-meter tower, and drops the ball to a friend halfway down the tower. What is the potential energy of the ball at the top of the tower relative to the person to whom it will be dropped?

How much kinetic energy will a bowling ball have when it reaches the person at the lower position, assuming that no force acts to oppose the effect of gravity?

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Your solution:

If I understand it correctly, `dPE is equal and opposite to `dKE and `dW_net_ON.

Therefore assuming that the positive direction is when the ball is moving downward, the Fnet = 7 kg * 9.8 m/s^2 = 68.6 Newtons, now that we have this we can find `dW_net = Fnet * `ds = 68.6 Newtons * 45 m = 3087 Joules

Now that we know that `dPE at the halfway point is equal and opposite to `dW_net_ON, then I will assume that `dPE = -3087 Joules

Now we need to calculate `dW_net_ON when it falls the entire distance. `dW_net_ON = Fnet * `ds = 68.6 N * 90 m = 6,174 Joules

Therefore the `dKE here is the same as the net work and is equal to 6,174 Joules.

confidence rating #$&*:

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Given Solution:

The potential energy of the ball at the top of the tower is equal to the work that would be done by gravity on the ball in dropping from the 90-meter altitude at the top to the 45-meter altitude at the middle of the tower. This work is equal to product of the downward force exerted by gravity on the ball, which is 7 kg * 9.8 m/s^2 = 68.6 Newtons, and the 45-meter downward displacement of the ball. Both force and displacement are in the same direction so the work would be

work done by gravity if ball dropped 45 meters: 68.6 Newtons * 45 meters = 3100 Joules, approx..

Thus the potential energy of the ball at the top of the tower, relative to the position halfway down the tower, is 3100 Joules. The ball loses 3100 Joules of PE as it drops.

If no force acts to oppose the effect of gravity, then the net force is the gravitational force and the 3100 Joule loss of PE will imply a 3100 Joule gain in KE.

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Self-critique (if necessary):

I think I got the wrong answer for `dKE. I forgot what I originally stated that the `dPE was equal and opposite to not only `dW_net_ON, but also the `dKE.

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Self-critique rating:3

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Question: `q012. If a force such as air resistance acts to oppose the gravitational force, does this have an effect on the change in potential energy between the two points? Would this force therefore have an effect on the kinetic energy gained by the ball during its descent?

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Your solution:

Yes, I do believe it would have an effect on the change in potential energy, because upon calculating the `dW_net_ON, the Fnet would be a different value, therefore causing all other values to change as well.

Since `dPE is equal and opposite to the `dKE, then it would have an effect on the kinetic energy ganined by the ball during its descent.

confidence rating #$&*:

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Given Solution:

The change in potential energy is determined by the work done on the object by gravity, and is not affected by the presence or absence of any other force. However the change in the kinetic energy of the ball depends on the net force exerted, which does in fact depend on whether nongravitational forces in the direction of motion are present.

We can think of the situation as follows: The object loses gravitational potential energy, which in the absence of nongravitational forces will result in a gain in kinetic energy equal in magnitude to the loss of potential energy. If however nongravitational forces oppose the motion, they do negative work on the object, reducing the gain in kinetic energy by an amount equal to this negative work.

ADDITIONAL INSTRUCTOR COMMENT:

The PE change is the result of only conservative forces; in this case the PE change depends only on the vertical displacement and the gravitational force.

The force of air resistance is nonconservative and has no effect on PE change.

KE change depends on net force, which includes both conservative and nonconservative forces. So KE change is affected by both PE change and the work `dW_nc_ON done by nonconservative forces.

In this case PE change is negative, which tends to increase KE, while nonconservative forces do negative work on the mass, which tends to reduce KE.

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Self-critique (if necessary):

I am quite confused about this.

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Self-critique rating:3

@&

The change in PE is equal and opposite to the work done by gravity.

Since the gravitational force doesn't depend on air resistance, the change in PE will not be influenced by air resistance.

However the amount of KE change will, since air resistance affects net force and hence affects KE change (recall that KE change = work done by net force).

You're getting there. As you've seen, it does take awhile to sort all this out.

*@

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Question: `q014. If an average force of 10 Newtons, resulting from air resistance, acts on the bowling ball dropped from the tower, what will be the kinetic energy of the bowling ball when it reaches the halfway point?

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Your solution:

Fnet = 68.6 N - 10 N = 58.6 Newtons

`dW_net_ON = 58.6 N * 45 m = 2,637 Joules

Therefore the `dKE at the halway point will be 2,637 Joules.

confidence rating #$&*:

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Given Solution:

The ball still loses 3100 Joules of potential energy, which in the absence of nongravitational forces would increase its KE by 3100 Joules. However the 10 Newton resisting force does negative work -10 N * 45 m = -450 Joules on the object. The object therefore ends up with KE 3100 J - 450 J = 2650 J instead of the 3100 J it would have in the absence of a resisting force.

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Self-critique (if necessary):

I did it a bit differently, is my solution wrong?

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Self-critique rating:3

@&

Your explanation and that of the given solution are completely equivalent. Good work.

*@

If you understand the assignment and were able to solve the previously given problems from your worksheets, you should be able to complete most of the following problems quickly and easily. If you experience difficulty with some of these problems, you will be given notes and we will work to resolve difficulties.

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Question: `q015. An Atwood machine has a 5-kg mass on one side and a 6-kg mass on the other. If the 6 kg mass descends 2 meters:

Was its displacement in the same direction as the gravitational force exerted on it, or in the opposite direction?

What was the work done on it by gravity?

Was the displacement of the 5-kg mass in the same direction as the gravitational force exerted on it, or in the opposite direction?

What was the work done by gravity on this mass?

Did gravity do net positive or negative work on this system?

What was the change in the gravitational PE of each object, and of the system?

Assuming no frictional or other dissipative forces, what was the change in the KE of the system?

If the system started from rest, what was its velocity after having descended the 2 meters?

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Your solution:

I have spent a good half an hour trying to reason out where to start here first. I would really like to be able to get the right answer, but after putting in a lot of time, and realizing that this is a qa, and that I need to get on to other assignments, I can say I need help with this problem.

I am going to give it a try though.

I would say that its displacement was in the same direction as the gravitational force exerted on it.

The work done by gravity would be dWnet = Fnet * `ds, to find Fnet, we take m * a, I am going to assume that the mass here cancels out to leave 1 kg that descends 2 meters, therefore Fnet = 1 kg * 9.8 m/s^2 = 9.8 Newtons, therefore dWnet = 9.8 N * 2 m = 19.6 Joules.

I would say that this would be in the opposite direction.

I do not think I did the earlier question right. I am not sure what the answer to this is.

I would say that gravity did positive work on this system.

If my answer for the `dWnet was correct earlier, then the `dPE (I think) would be equal an opposite to this making it -19.6 Joules.

The `dKE would be equal to the `dWnet, making it 19.6 Joules.

@&

The question asked you to consider the 6 kg mass, then the 5 kg mass. You should answer those questions.

The masses don't cancel out, but the graviational forces on them are in opposite directions, and the difference in the gravitational forces is equal to the gravitational force on a 1 kg mass. So your intuition here is correct, as is your answer for `dW_net.

If you find the work done on each mass, you will find that positive work is done on one, negative work on the other, and that the total is indeed equal to -19.6 Joules.

*@

vf = sqrt(v0^2 + 2 a `ds) = sqrt(2 * 9.8 m/s^2 * 2 m) = sqrt(39.2 m^2/s^2) = 6.3 m/s

@&

The acceleration of this system is not 9.8 m/s^2. Counterbalanced weights in this sort of system do not acceleration at 9.8 m/s^2. If you put a marble next to the 6 kg weight and released them both, they would both accelerate downward. But the 6 kg weight is held back by the fact that it's attached to the 5 kg weight, and the marble will accelerate downward much more quickly. The acceleration of the marble will be 9.8 m/s^2. The acceleration of the 6 kg mass will be much less.

*@

Not sure if any of that is right, but I tried my best.

confidence rating #$&*:

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Self-critique (if necessary):

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Self-critique rating:

@&

In any case you shouldn't use the equations of uniformly accelerated motion here. You have a total of 11 kg, all being sped up to some common final speed, at which speed their KE will be 19.6 Joules.

Using just energy considerations (in this case the definition of KE) you can find their common speed after the 2 meter descent.

*@

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Self-critique (if necessary):

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#*&!

&#Good responses. See my notes and let me know if you have questions. &#