Conservation of Momentum question (find final velocities)

In summary: I thought there'd be 3 unknowns since we don't know v1 or v2.We know v_rel and v_cm, so I know that v1 + v2 = v_rel and v1 = v_cmI'm confused.You're on the right track. You have two equations and two unknowns. I was just kinda hinting at what to do next.You have$$\vec{v}_\text{cm} = \frac{m_1 \vec{v}_1 + m_2 \vec{v}_2}{m_1+m_2}$$and$$\vec{v}_1 + \vec{v}_2 = \vec{v}_\text{
  • #1
d3nat
102
0

Homework Statement



A boy and girl are standing on ice skates and pulling on opposite ends of a rope.

Find their velocities the instant they meet.
How long did it take?

Relative speed of approach is 2 m/s
mass of boy = 60kg
mass of girl = 50kg
distance = 5m


Homework Equations


m1v1 + m2v2 = (m1+m2)v


v1 & m1 = boy
v2 & m2 = girl

The Attempt at a Solution



I know that it takes them 2.5 seconds to meet (t = d/v).

I cannot figure out their individual final velocities.

v1+v2 = v_rel
v2 = v_rel - v1

m1(v_rel - v1) + m2v2 = (m1+m2)v

But this leaves me with 2 equations, three unknowns.
 
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  • #2
d3nat said:

Homework Statement



A boy and girl are standing on ice skates and pulling on opposite ends of a rope.

Find their velocities the instant they meet.
How long did it take?

Relative speed of approach is 2 m/s
mass of boy = 60kg
mass of girl = 50kg
distance = 5m

Homework Equations


m1v1 + m2v2 = (m1+m2)v
What does v represent here?

v1 & m1 = boy
v2 & m2 = girl

The Attempt at a Solution



I know that it takes them 2.5 seconds to meet (t = d/v).

I cannot figure out their individual final velocities.

v1+v2 = v_rel
v2 = v_rel - v1

m1(v_rel - v1) + m2v2 = (m1+m2)v

But this leaves me with 2 equations, three unknowns.
You substituted v2 in for v1 on the lefthand side.
 
  • #3
vela said:
What does v represent here?

Well, I'm assuming since they embrace that they must be as one body, so shouldn't they have one velocity?
I know this can't be true because it's asking for their individual final velocities.
You substituted v2 in for v1 on the lefthand side.

My mistake. That was simply a typing error I must have missed. I have it written correctly on my paper.

m1v1 + m2(v_rel - v1) = ?
 
Last edited:
  • #4
You also need to be a bit more careful with what ##v_1## and ##v_2## represent. Are those variables speeds or velocities? When you wrote ##m_1 v_1 + m_2 v_2##, it seems you're summing their momenta and are therefore assuming the ##v##'s are velocities. On the other hand, when you wrote ##v_1 + v_2 = v_\text{rel}##, it appears you're assuming they are speeds.
 
  • #5
vela said:
You also need to be a bit more careful with what ##v_1## and ##v_2## represent. Are those variables speeds or velocities? When you wrote ##m_1 v_1 + m_2 v_2##, it seems you're summing their momenta and are therefore assuming the ##v##'s are velocities. On the other hand, when you wrote ##v_1 + v_2 = v_\text{rel}##, it appears you're assuming they are speeds.

Okay, thanks.
I'm assuming they are velocities.
I'm not sure if the equation relating the velocities to the relative velocity is actually correct. I can't find anything like that in my textbook.
I'm assuming that the difference in the velocities is equal to the relative velocity. The reason they are being added is because they are headed in opposite directions (towards each other).

So v1 - (-v2) = v_rel
which gives me the the v1 + v2 = v_rel
 
  • #6
In terms of vectors, the sum of the momenta is given by ##m_1 \vec{v}_1 + m_2\vec{v}_2## and the relative velocity is ##\vec{v}_1 - \vec{v}_2##. When working in one dimension, sometimes we're sloppy and just drop the arrows. The sign of the answers we get for ##v_1## and ##v_2## tell us the directions. Often, though, it's easier to think about things in terms of speeds. We assume ##v_1## and ##v_2## to be positive and put the directions into the equations explicitly. In this case, you'd have ##m_1 v_1 + m_2 (-v_2) = m_1 v_1 - m_2 v_2## and ##v_1 - (-v_2) = v_1+v_2##. Either way is fine. You just have to be consistent.

Sticking with the vector notation for now, the velocity of the center of mass is given by
$$\vec{v}_\text{cm} = \frac{m_1 \vec{v}_1 + m_2 \vec{v}_2}{m_1+m_2}.$$ What's the center of mass doing in this problem?
 
  • #7
vela said:
In terms of vectors, the sum of the momenta is given by ##m_1 \vec{v}_1 + m_2\vec{v}_2## and the relative velocity is ##\vec{v}_1 - \vec{v}_2##. When working in one dimension, sometimes we're sloppy and just drop the arrows. The sign of the answers we get for ##v_1## and ##v_2## tell us the directions. Often, though, it's easier to think about things in terms of speeds. We assume ##v_1## and ##v_2## to be positive and put the directions into the equations explicitly. In this case, you'd have ##m_1 v_1 + m_2 (-v_2) = m_1 v_1 - m_2 v_2## and ##v_1 - (-v_2) = v_1+v_2##. Either way is fine. You just have to be consistent.

Sticking with the vector notation for now, the velocity of the center of mass is given by
$$\vec{v}_\text{cm} = \frac{m_1 \vec{v}_1 + m_2 \vec{v}_2}{m_1+m_2}.$$ What's the center of mass doing in this problem?

Hmmm, I'm not positive.
Would the center of mass be staying in the same spot?
 
  • #8
Yup. If it wasn't moving before, it would only begin moving in response to an external force acting on the boy-rope-girl system, but there aren't any in this situation.
 
  • #9
vela said:
Yup. If it wasn't moving before, it would only begin moving in response to an external force acting on the boy-rope-girl system, but there aren't any in this situation.

Maybe I'm just not seeing it, but how does this relate to their final velocities?
Do I need to find where the center of mass is and know they'll both meet there. Then try to use the time, the distance they each traveled, and their respective masses to figure out their final velocities?
 
  • #10
You seem to be thinking this is a collision problem. It's not, so there's no final velocity to speak of. The problem does involve conservation of momentum, however. No external forces means momentum of the system is conserved which means the center of mass doesn't move.

If the center of mass isn't moving, you have ##v_\text{cm} = 0##. So now you have two equations and two unknowns.
 
  • #11
vela said:
You seem to be thinking this is a collision problem. It's not, so there's no final velocity to speak of. The problem does involve conservation of momentum, however. No external forces means momentum of the system is conserved which means the center of mass doesn't move.

If the center of mass isn't moving, you have ##v_\text{cm} = 0##. So now you have two equations and two unknowns.

Okay, so to find the final velocity of the boy and the girl:

$$\vec{v}_\text{cm} = \frac{m_1 \vec{v}_1 + m_2 \vec{v}_2}{m_1+m_2} = 0$$

m1v1 +m2v2 = m1v`1 + m2v`2

(not a collision problem so not right hand side = (m1+m2)v)

and v1 = v_rel - v2
and then using from the COM equation that m1v1 = - m2v2 or v2 = - m1v1 / m2

so

v1 = v_rel - (- m1v1/m2)

v1 = m2*v_rel / m1

same process gives
v1 = -m2v2 / m1
v2 = v_rel - (-m2v2 / m1)

v2 = m1*v_rel/m2
so substituting that in gives:

m1* [m2*v_rel / m1] + m2* [m1*v_rel/m2] = m1v`1 + m2v`2

That still leaves me with two unknowns of v`1 and v`2.
Unless I am supposed to use the right hand side as some (m1+m2)*v and then use that total final v to find their respective v's.

Sorry I'm having such a mental block with this problem. I just can't get my answers to match the book.
 
  • #12
Solved it :)
 
  • #13
Congrats! I figured you just needed some time to futz around with it.
 
  • #14
vela said:
Congrats! I figured you just needed some time to futz around with it.

Thanks so much for your help!
 

What is the Conservation of Momentum?

The Conservation of Momentum is a fundamental principle in physics that states that the total momentum of a system of objects remains constant, unless acted upon by an external force. This means that in a closed system, the total momentum before an interaction is equal to the total momentum after the interaction.

How do you calculate momentum?

Momentum is calculated by multiplying an object's mass by its velocity. The equation for momentum is p = mv, where p is momentum, m is mass, and v is velocity. Momentum is measured in units of kilogram-meters per second (kg · m/s).

What is an elastic collision?

An elastic collision is a type of collision where the total kinetic energy of the system is conserved. In an elastic collision, the objects involved bounce off each other and the total momentum and kinetic energy of the system before and after the collision are equal.

How do you apply the Conservation of Momentum to a problem?

To apply the Conservation of Momentum to a problem, you first need to identify the system and any external forces acting on it. Then, you can use the equation p1i + p2i = p1f + p2f, where p1i and p2i are the initial momenta of the objects and p1f and p2f are the final momenta, to solve for the final velocities of the objects.

What is the difference between inelastic and elastic collisions?

In an inelastic collision, the objects involved stick together and the total kinetic energy of the system is not conserved. In an elastic collision, the objects bounce off each other and the total kinetic energy of the system is conserved. In both types of collisions, the total momentum of the system is conserved.

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