I won't do that again.Problem: Integrating Kinematic Equations to Find Position

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A car accelerates with a variable acceleration of a = (3s^-1/3) m/sec^2, starting from rest. To find the car's position, integration of the acceleration is necessary, but the original poster lacks knowledge in integrals. The discussion emphasizes using known kinematic equations, noting that the initial position can be simplified to zero for calculation purposes. The correct approach involves recognizing that the acceleration is not constant due to its dependence on position. Ultimately, the car's acceleration at t=4 seconds is calculated to be 1.06 m/sec^2.
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Problem: A car starts from rest and moves along a straight line with an acceleration of a=(3s^-1/3)m/sec^2, where s is in metres. Determine the car's acceleration when t=4sec. ANS: 1.06 m/sec^2

Alright...I know nothing about integrals...really, nothing. I was never taught anything about integrals even though I've taken calculus courses before.

Here's what I think I should do.

Take the equation a = d^2s/dt^2 and INTEGRATE it to find the position (s). But how do you do this.
 
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Forget numbers for a minute.

If ao is acceleration, vo is initial velocity, xo is initial position, then,

Acceleration at time t is: a(t) = ao
Velocity at time t is: v(t) = vo + ao * t
Position at time t is: x(t) = xo + vo * t + (ao * t^2)/2


They haven't taught you integration yet. Maybe you've been given these formulae, though, or something similar.
 
what's the initial position (xo)?
 
You don't need to know to answer the question. It's the distance, d, that's needed ...
d = x(4) - xo
= ...
 
d = 24s^-1/3

Sorry, I'm still not understanding.
I really appreciate your help, though.
 
How far you go doesn't depend on where you start from, so take xo to be as simple as possible ... xo = 0.
 
Originally posted by pnaj
Forget numbers for a minute.

If ao is acceleration, vo is initial velocity, xo is initial position, then,

Acceleration at time t is: a(t) = ao
Velocity at time t is: v(t) = vo + ao * t
Position at time t is: x(t) = xo + vo * t + (ao * t^2)/2


They haven't taught you integration yet. Maybe you've been given these formulae, though, or something similar.

The equations are valid only when a is constant
 
Thanks for that, himanshu121, I didn't notice the 's' sitting in the expression for a.

I just assumed that it was just a simple problem that didn't need integration and got side-tracked into seeing if jimmy had seen these equations before.
 

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