Particle Motion in a Straight Line: Deriving Velocity and Total Distance

In summary, the position function of a particle moving in a straight line is given by s(t) = t^2 e^-t where t is measured in seconds and s is measured in meters. The velocity of the particle at time t is v(t) = 2t e^(-t) - t^2 e^(-t). The particle is at rest when its velocity is 0, and this occurs when 2t - t^2 = 0. The total distance traveled by the particle during the first two seconds is 0.54 meters.
  • #1
naspek
181
0
Let s = s(t) be the position function of a particle moving in a straight line.
Suppose that the position of the particle is given by the formula
s (t) = t^2 e^-t ; t >= 0
where t is measured in seconds and s in meters.

(i) Find the velocity of the particle at time t.
* should i differentiate s(t) to get the velocity?

(ii) When is the particle at rest?
* when velocity = 0.. am i right?

(iii) Find the total distance traveled by the particle during the first two seconds.
*dont have any idea..
 
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  • #2
(i) yes. (ii) yes. (iii) you might have a more informed opinion about this after you do (i) and (ii). Get started.
 
  • #3
(i) Find the velocity of the particle at time t.
* should i differentiate s(t) to get the velocity?

answer--> (2t e^-t) - (t^2 e^-t)

(ii) When is the particle at rest?
* when velocity = 0.. am i right?

answer-->
(2t e^-t) - (t^2 e^-t) = 0
(2t e^-t) = (t^2 e^-t)
(2e^-t) = (t e^-t)
*how to solve t?

(iii) Find the total distance traveled by the particle during the first two seconds.
*dont have any idea..

at t = 2
s (t) = t^2 e^-t
s (2) = 2^2 e^-2
...= 0.54 meters

is my answer for (i) and (iii) is correct?
how am i going to solve (ii)?
 
  • #4
Are you just trying to solve (ii) for t?
 
  • #5
mg0stisha said:
Are you just trying to solve (ii) for t?

yes. because i need the value of 't' when the particle at rest..
 
  • #6
do you see anything you can factor out from both sides?
 
  • #7
mg0stisha said:
do you see anything you can factor out from both sides?

(2t e^-t) - (t^2 e^-t) = 0
(2t e^-t) = (t^2 e^-t)
(2e^-t) = (t e^-t)
e^-t(2) = e^-t (t)
(e^-t)/(e^-t) 2 = t

*(e^-t)/(e^-t) = 1?
 
  • #8
naspek said:
(i) Find the velocity of the particle at time t.
* should i differentiate s(t) to get the velocity?

answer--> (2t e^-t) - (t^2 e^-t)
You should write an equation; namely v(t) = 2te^(-t) - t^2*e^(-t)
naspek said:
(ii) When is the particle at rest?
* when velocity = 0.. am i right?
Yes.
naspek said:
answer-->
(2t e^-t) - (t^2 e^-t) = 0
I'm going to cut in here because the rest of your work doesn't help you get where you need to go. It's not wrong, but it isn't helpful either.
s'(t) = v(t) = 2t e^(-t) - t^2 e^(-t) = 0
v(t) = 0 ==> 2t e^(-t) - t^2 e^(-t) = 0 = 0 ==> (2t - t^2)e^(-t) = 0
e^(-t) is never 0. When is 2t - t^2 = 0? Those are the times when v(t) = 0.

naspek said:
(2t e^-t) = (t^2 e^-t)
(2e^-t) = (t e^-t)
*how to solve t?

(iii) Find the total distance traveled by the particle during the first two seconds.
*dont have any idea..
Integrate the velocity between t = 0 and t = 2.
naspek said:
at t = 2
s (t) = t^2 e^-t
s (2) = 2^2 e^-2
...= 0.54 meters

is my answer for (i) and (iii) is correct?
how am i going to solve (ii)?
 
  • #9
for (iii) 4e^-2
am i got it right?
 
Last edited:
  • #10
Yes, of course. You were told in the problem itself that s(t)= t2e-t. The answere to (iii) is just s(2).
 
  • #11
Thank u for the confirmation of my answer.. =)
 

What is a derivative?

A derivative is a mathematical concept that represents the instantaneous rate of change of a function at a specific point. It is the slope of the tangent line to the function at that point.

Why do we use derivatives?

Derivatives are used to solve a variety of problems in different fields such as physics, economics, and engineering. They allow us to analyze the behavior of a function and make predictions about its future values.

How do you find the derivative of a function?

The derivative of a function can be found using various methods such as the power rule, product rule, quotient rule, and chain rule. These rules involve taking the limit of a difference quotient as the change in input approaches zero.

What is the difference between a derivative and an antiderivative?

While a derivative represents the instantaneous rate of change of a function, an antiderivative is the inverse operation of differentiation. In other words, an antiderivative is a function whose derivative is equal to the original function.

Can you find the derivative of any function?

In most cases, yes. However, there are some functions that are not differentiable, such as those with sharp corners or discontinuities. Additionally, the derivative of some functions may not exist at certain points.

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