Solving Collisions with angles problem

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The discussion focuses on solving a physics problem related to collisions using the conservation of momentum. The initial momentum is identified as being directed to the right, and the user plans to break down the momentum into X and Y components for analysis. Calculations show the momentum of one object (puck 1) as 1.2 kg•m/s and the other (puck 2) as 0.416 kg•m/s in the horizontal direction. Suggestions are made to simplify the problem by considering components in the Y direction or the final direction of puck 2 to streamline the calculations. The conversation emphasizes the importance of correctly applying vector equations in momentum conservation problems.
AceInfinity
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First off, i'd like to note that this isn't homework, and I've seen other threads in here that deal with question/equation/problems, so I hope this isn't against the rules. I found this on a practice physics test online. I'm just using it for the benefit of my knowledge, nothing more.

I can provide the link if necessary for proof.

Heres the question I want to know how to solve:
[PLAIN]http://k.min.us/ibDXoi.jpg
 
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ohhh... I think you put me on the right track for beginning to solve this. The initial momentum was
in this case. Therefore the conservation of momentum is seen for that X component, I'll have to split them off into the X and Y components of momentum and look specifically at the X/horizontal component of momentum to use the conservation of momentum, if I'm not mistaken?

4.85 Cos(36o) = 3.92m/s

p = mv
p = (0.200kg)(3.92m/s)
p = 1.2kg•m/s

Solve for momentum of that object.

p = mv
p = (0.200kg)(3.92m/s)
p = 0.784kg•m/s

Momentum of the other object (puck 2) is: 1.2kg•m/s - 0.784kg•m/s

= 0.416kg•m/s [Important: in the x/horizontal direction. need to solve for the angle'd direction]

0.416kg•m/s ÷ [cos(54o)] =

0.707741472...kg•m/s !

I think with "their" answer, they rounded a bit too early.​
 
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Hi AceInfinity! :smile:
AceInfinity said:
Momentum of the other object (puck 2) is: 1.2kg•m/s - 0.784kg•m/s

= 0.416kg•m/s [Important: in the x/horizontal direction. need to solve for the angle'd direction]

0.416kg•m/s / [cos(54o)] =

0.707741472...kg•m/s !

yes that's fine :smile:

but there are quicker ways of doing it …

you could take components in the y direction or in the final direction of puck 2 …

(both are quicker because they reduce the number of terms)

try both of those :wink:
 

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