How Can I Calculate the Magnitude of Momentum in a Game of Pool?

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To calculate the magnitude of momentum in a game of pool, the equations for momentum components along the x and y axes are Px = mVcos(theta) and Py = mVsin(theta). The attempt at a solution yielded Px = 0.201 N*s and Py = 0.4233 N*s, leading to a calculated magnitude of 0.4686 N*s, which was identified as incorrect. The discussion clarified that part (b) requires finding the change in linear momentum, not just the magnitude, emphasizing that the direction of momentum changes after the ball hits the wall. The correct approach involves recognizing that the y-component of momentum changes sign, resulting in a change in momentum that reflects this directional shift. Understanding these aspects is crucial for accurately solving the problem.
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Homework Statement



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Homework Equations



Px = mVcostheta
Py = mVsintheta
Theta = tan-1(y/x)
Magnitude of P = (Px^2 + Py^2)^(1/2)

The Attempt at a Solution



Px = .165*2.84cos64.6 = .201 N*s
Py = .165*2.84sin64.6 = .4233 N*s
a) Theta2 = tan-1(-.4233/.201) = 64.6 degrees

b) (.201^2+.4233^2)^(1/2) = .4686 N*s

My work for part a may just have been luck or not needed but I obviously did something wrong since my answer in part b is wrong. Did I use wrong numbers for part b? Or am I supposed to calculate something else then find the magnitude?
 
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well, part (b) asks you to find change in linear momentum, not the magnitude of linear momentum (what you have done). See in the picture, linear momentum is a vector, those two arrows represent linear momentum before ball hits the wall and after. Directions are different, aren't they? ;] so linear momentum has changed, not in magnitude, but in direction. As problem statement says, only y part of momentum has changed. So just find this change in momentum
 
housemartin said:
well, part (b) asks you to find change in linear momentum, not the magnitude of linear momentum (what you have done). See in the picture, linear momentum is a vector, those two arrows represent linear momentum before ball hits the wall and after. Directions are different, aren't they? ;] so linear momentum has changed, not in magnitude, but in direction. As problem statement says, only y part of momentum has changed. So just find this change in momentum

Wait so if I get what you are saying. It is just putting a negative sign on the Momentum I found in the y direction of part a and having that be my answer for part b? To me that's the only logical answer unless I'm not understanding something. Is that right or wrong?
 
first, balls momentum along y-axis was directed in positive direction, after bounce - in negative. So Py(1) = +.4233 N*s and Py(2) = -.4233 N*s. What is the change in momentum then?
 
Is the change in momentum = P1*P2cos(theta)
 

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