Is Using the Tangent Direction to Determine dl in Work Calculation Incorrect?

In summary, Niles was confused about the difference between potential and kinetic energy. In order for work to be done, you must be careful about which energy you are talking about. When discussing the work done on a system, the work done by gravity is -ΔU.
  • #1
Niles
1,866
0

Homework Statement


Hi all.

We have that the work W equals Ui - Uf (respectively the initial and final potential energy). Let us say that a stone has a height 10 m, and falls down. We say that positive x is upwards.

Now W = [itex]\int F \cdot dl = F(x_f-x_i)=U_f-U_i[/itex], since F and dl both point downwards. But this result does not correspond to what I wrote above. What am I doing wrong here?

Thanks in advance.Niles.
 
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  • #2
If positive x is upwards, the vector F carries a negative sign doesn't it? It's pointing - X.
 
  • #3
Yes, but so does dl (i.e. dl points from x_initial to x_final, which is the same direction as for F).
 
  • #4
When considering work, you must be careful whether you are talking about the work done on the system or the work done by the system. Both these meanings are subject to how you wish to define work, both are equally valid but you must stick to the same one. Your first statement describes the work done by the system whereas your second, derived, statement describes the work done on the system.
 
  • #5
It's the Force in the direction of the motion.

When you move it upwards, the work supplied is a force against gravity pointing down. You're going positive x and your work has increased potential energy.

W = ΔU

Going down reduces potential energy. When you let it fall, the work by gravity - not you by you - is negative because it returns the work as kinetic energy.

W = -ΔU
 
  • #6
In my first post, I was talking about the work done on the system in both cases. The work done on a system equals -ΔU, where U is the internal (potential) energy. This is why I am confused.

And I can't see why the work done by gravity is negative, when the object falls. Gravity points downwards just like dl does. So where does this extra minus come from?
 
  • #7
The work done on the system by gravity is W = -ΔU, whether you are moving the stone up or down a gravitational potential, you just get either a positive or negative answer. When you were performing the calculation of the work you should have noted that F.x is the kinetic energy, thus:

F(xf-xi) = KEf - KEi = Ui - Uf = -ΔU

by conservation of energy, i haven't been using this site long and don't know how to type equations yet, do you know where I can learn?
 
  • #8
Just write:

[*tex]

Write equations here...

[* /tex].

But remove the asterix's (i.e. *).

I will think about your reply.
 
  • #9
Prosthetic Head said:
When you were performing the calculation of the work you should have noted that F.x is the kinetic energy, thus:
F(xf-xi) = KEf - KEi = Ui - Uf = -ΔU

by conservation of energy

Hmm, I thought mgh ('h' for height) was the potential energy, and not kinetic?
 
  • #10
Niles said:
In my first post, I was talking about the work done on the system in both cases. The work done on a system equals -ΔU, where U is the internal (potential) energy. This is why I am confused.
The change in gravitational PE when you move a mass from one point to another equals the work done against gravity (not by gravity). (Think of it as the work you have to do to lift the mass.) So if F is the gravitational force, -F is the force you must exert against gravity. Thus when a stone drops 10 m, the change in PE is negative since the force opposing gravity is positive but the displacement is negative.
And I can't see why the work done by gravity is negative, when the object falls. Gravity points downwards just like dl does. So where does this extra minus come from?
The work done by gravity is positive; thus the change in PE is negative.
 
  • #11
Ok, I will take this from the very top, since I am getting confused with the signs. I think the easiest is if you can point out where I am wrong in this analysis, please:

1) The work done by a conservative force on a system equals the minus of the change in the systems potential energy.

2) Thus when I lift a book with constant velocity against gravity from point A to point B (B>A), I get:

[tex]
W = \int_A^B F\cdot dl = \int_A^B Fdl = F(B-A) = mg(B-A).
[/tex]

Now this has to equal the minus of the change in potential energy of the system (i.e. book):

[tex]
-\delta U = - mg(B-A).
[/tex]

Where is my reasoning wrong?
 
  • #12
Niles said:
Yes, but so does dl (i.e. dl points from x_initial to x_final, which is the same direction as for F).

Assuming x increases in the upward direction,
[tex]W_{\vec W}=\int_A^B \vec W\cdot d\vec l=\int_{x_A}^{x_B} (-mg \hat x)\cdot (\hat x dx)=\int_{x_A}^{x_B} (-mg ) dx= (-mg )(x_B-x_A)
[/tex]

When it "falls" to a lower position, [tex]x_B-x_A<0[/tex]... thus [tex]W_{\vec W} > 0[/tex]. (The work done by gravity is positive in this case.)

In short, when writing the integrand in terms of chosen coordinate system, [tex]d\vec l[/tex] in terms of the coordinate system... is [tex]\hat x dx[/tex]... that is... upward, in the direction of increasing x. Let the endpoints handle whether the "actual" displacement is "up" or "down".
 
  • #13
robphy said:
Assuming x increases in the upward direction,
[tex]W_{\vec W}=\int_A^B \vec W\cdot d\vec l=\int_{x_A}^{x_B} (-mg \hat x)\cdot (\hat x dx)=\int_{x_A}^{x_B} (-mg ) dx= (-mg )(x_B-x_A)
[/tex]

I don't agree with your signs based on the following explanation: Shouldn't [itex]dl[/itex] be tangent to the path from A to B? Thus it must also point in [itex]-\hat x dx[/itex].

(Using your explanation, everything is OK, but this is how I learned vector calculus, and I would just like to see my math courses coincide with my physics course).
 
  • #14
Niles said:
Ok, I will take this from the very top, since I am getting confused with the signs. I think the easiest is if you can point out where I am wrong in this analysis, please:

1) The work done by a conservative force on a system equals the minus of the change in the systems potential energy.
OK.

2) Thus when I lift a book with constant velocity against gravity from point A to point B (B>A), I get:

[tex]
W = \int_A^B F\cdot dl = \int_A^B Fdl = F(B-A) = mg(B-A).
[/tex]
You are calculating the work done by gravity. mg is just the magnitude of the force--gravity acts down, of course. Using up as positive, F = -mg.

Now this has to equal the minus of the change in potential energy of the system (i.e. book):

[tex]
-\delta U = - mg(B-A).
[/tex]

Where is my reasoning wrong?
You had the sign of the gravitational force wrong.

Read what robphy says; that's the way I think of it when doing these kinds of integrals. I let the coordinate system dictate the sign convention. In this case, +dl is up, so gravity = -mg (down).
 
  • #15
Ok, so we found my problem: I am letting the sign of [itex]dl[/itex] be determined by the direction of the tangent from A -> B instead of letting the coordinate system determine it

But why is this wrong? In my math-course, this was how I was told to determine the direction of dl. On this forum, I am being told both things (see post #6: https://www.physicsforums.com/showthread.php?t=283845 for the contrary of what you are saying).

Using your method, it all works out.
 

1. What is work in classical mechanics?

In classical mechanics, work is defined as the product of the magnitude of a force and the distance over which the force acts. It is a measure of the energy transfer that occurs when an object is moved by a force.

2. How is work calculated in classical mechanics?

Work is calculated by multiplying the force applied to an object by the displacement of the object in the direction of the force. Mathematically, it is represented as W = F * d, where W is work, F is force, and d is displacement.

3. What are the units of work in classical mechanics?

The SI unit of work is joule (J), which is equivalent to kg*m^2/s^2. In the English system, the unit of work is foot-pound (ft-lb) or pound-force foot (lbf-ft).

4. Can work be negative in classical mechanics?

Yes, work can be negative in classical mechanics. This occurs when the force and displacement are in opposite directions. For example, when a person walks down a hill, the force of gravity is acting in the opposite direction of the person's displacement, resulting in negative work.

5. What is the relationship between work and energy in classical mechanics?

In classical mechanics, work is directly related to energy. Work done on an object causes a change in its energy, whether it is kinetic or potential energy. According to the work-energy theorem, the net work done on an object is equal to the change in its kinetic energy.

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