Motion with constant acceleration problem

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SUMMARY

The forum discussion revolves around solving a motion problem involving two particles on an inclined plane with constant acceleration. The first particle (V01) is launched upwards with an initial speed of 5.00 m/s, while the second particle is released from rest at the top of the slope, which is 1.28 m long with an acceleration of 4.00 m/s². The solution involves setting up equations of motion for both particles, leading to a quadratic equation that determines the time of collision. The final calculations yield two potential collision times, 0.36 seconds and 0.89 seconds, which require further verification for accuracy.

PREREQUISITES
  • Understanding of kinematic equations, specifically X = X0 + V0t + (1/2)at²
  • Knowledge of initial velocity (V0) and acceleration (a) concepts
  • Ability to solve quadratic equations
  • Familiarity with motion on inclined planes
NEXT STEPS
  • Review kinematic equations in detail, focusing on their application in different scenarios
  • Practice solving quadratic equations to enhance problem-solving skills
  • Explore the effects of varying initial velocities and accelerations on particle motion
  • Investigate real-world applications of motion on inclined planes in physics
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Students studying physics, particularly those focusing on kinematics and motion problems, as well as educators seeking to clarify concepts related to inclined planes and particle dynamics.

flanders
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Homework Statement


Hi. I've had some trouble solving this exercise, and I simply can't find the right solution. Hopefully you might help me out...?

Here's the task:

A plane (not airplane) has an inclination that allows a particle sliding on the slippery slope, and has an acceleration of 4.00 m / s ^ 2 The sloping surface is 1.28 m long.
The task:

Particle (V01) will be sent straight up the inclined plane with an initial speed of 5.00 m /s. Another particle is released at the same time without starting speed from the top of the inclined plane. See figure (Particle 1 is the red dot, particle 2 is the green one)

1. Where will the particles collide?
2. What kind of speed must the lower particle have if both particles were to collided in the middle of the slippery slope?

Homework Equations


X = X0 + V0t + (1/2)at^2
V = V0 + at

The Attempt at a Solution



In my mind, I think that both time and where they collide must be the same. Therefore X(particle1) = X(particle 2)

I've tried to solve it like this, particle 1 to the left, particle 2 to the right:

X0 + volt + (1/2)at^2 = X0 + volt + (1/2)at^2

This will leave me with a time, let's call it T. To make sure that it's the correct answer, I've tried to put T into both equations separately, to check if they collide at the same X. As you've probably understood, they don't.

Homework Statement


Homework Equations


The Attempt at a Solution

 

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flanders said:
I've tried to solve it like this, particle 1 to the left, particle 2 to the right:

X0 + volt + (1/2)at^2 = X0 + volt + (1/2)at^2

But the particles are not starting with the same Vo and X0. You need to put your given data for each particle into the appropriate places to form the required equation.
 
Okay, here is my solution:

Particle 1:
a = -4
v0 = 5
x0 = 0

Particle 2:
a = 4
v0 = 0
x0 = 1,28

Therefore;

Particle 1 to the left, particle 2 is on the right:


0 + 5t + 0,5*(-4)t^2 = 1,28 + 0t + 0,5*4t^2


5t - 2t^2 = 2t + 1,28


-4t^2 + 5t - 1,28 = 0

This leaves me with t = 0,36 or t = 0,89.

If I then put the t into X=X0 + V0t + 0,5at^2 to find the X, the result seems to be out of range...

Help? :)
 
Particle 1:
a = -4 ---> acceleration is leftwards. Okay.
v0 = 5 ---> inital velocity is rightwards. Okay.
x0 = 0 ---> starting at origin. Okay.

Particle 2:
a = 4 ---> acceleration is rightwards! Oops!
v0 = 0 ---> initial velocity is zero. Okay.
x0 = 1,28 ---> starting position, to the right of origin. Okay.
 
Oh my! :redface:

THANK YOU SO MUCH! You don't know how confused I was over this 'easy' task... God bless you!
 

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