Integrating Velocity: Distance = bt^3/3

Qube
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Homework Statement



A drag racing car starts from rest at t = 0 and moves along a straight line with velocity given
by v = bt^2, where b is a constant. The expression for the distance traveled by this car from its
position at t = 0 is:

A. bt3
B. bt^3/3

Homework Equations



Velocity is change in position divided by change in time.

The Attempt at a Solution



Three questions:

1) Is this a bad question? I don't see how we can get distance traveled from what's given in this problem unless we make the assumption that distance = displacement in this problem.

2) If velocity is displacement / time, then why isn't the answer according to the problem v * time or bt^2 * t = bt^3?

3) Why is the integral of the velocity function in the question bt^3/3 - or different from simply velocity * time? Isn't the integral the area under the curve on a velocity time graph, or simply the y-axis * the x-axis (velocity * time)?
 
on Phys.org
You are correct; the answer is ##\frac{bt^3}{3}##. Try integrating ##bt^2##, treating ##b## as the constant, by calculus. Which rule do you need to use to integrate such an expression? This is one of the elementary derivative rules.
 
Qube said:
1) Is this a bad question? I don't see how we can get distance traveled from what's given in this problem unless we make the assumption that distance = displacement in this problem.
It does say the motion is in a straight line. The quantity bt2 is ≥0 or ≤0 throughout the motion depending on the sign of b.
2) If velocity is displacement / time, then why isn't the answer according to the problem v * time or bt^2 * t = bt^3?
This is only true if the body is moving at constant velocity. Is this the case here?
 
Qube said:
2) If velocity is displacement / time,
That's average velocity.
 
CAF123 said:
It does say the motion is in a straight line. The quantity bt2 is ≥0 or ≤0 throughout the motion depending on the sign of b.
This is only true if the body is moving at constant velocity. Is this the case here?

You are correct; I cannot use the usual kinematic equations here since they all assume that acceleration is constant, and taking the derivative of the velocity function (given) results in an expression with a variable.
 
If dx/dt = bt2, have you learned how to integrate this equation?
 

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