Acceleration Problem: Bike vs. Car - When Will They Meet?

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The discussion focuses on a physics problem involving the acceleration of a bike and a car, where the bike accelerates at 1 m/s² for 10 seconds before the car, which accelerates at 2 m/s², starts moving. Participants emphasize the importance of calculating the distance traveled by each vehicle over time to determine when they will meet. It is clarified that both vehicles start from the same location, and the bike has a 50-meter head start when the car begins to accelerate. The key to solving the problem lies in equating the distances traveled by both vehicles to find the time and distance at which they meet. The conversation concludes with encouragement to apply the discussed methods and formulas to arrive at a solution independently.
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Homework Statement


A bike accelerates at 1m/s^2 from rest. (0 meters per second) After 10 seconds a car accelerates at 2m/s^2 from rest.


Homework Equations



When are they going to meet, and where?

The Attempt at a Solution

 
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Another piece of info.

When the car starts accelerating, the bike is 50 meters away and has a velocity of 10 meters/sec.
 
Just FYI, it's against forum rules to post a problem without showing what attempt you've made so far. Other people doing your homework for you does not help you in any way whatsoever (in addition to being tantamount to cheating).

Did the bike and car start from the same location? That seems like necessary information for this problem. Under the assumption that they did, how can you figure out the distance traveled by each vehicle at any moment in time? There is a simple way to do this for this type of motion under constant acceleration. Assuming you calculate that (i.e. know the positions of both vehicles at any moment in time), what fact is true about those positions when the vehicles "meet?"
 
Oh, i didn't know about that sorry.

Well they indeed start from the same location.
I have been trying to solve this problem for the last 25 minutes but I can't find a soultion. I have been trying with these formulas:

Final Velocity = (Acceleration)(Time)
Distance = (Final Velocity/2) Time
Distance =(Acceleration x Time^2)/2
Final Velocity^2 = 2(Acceleration)(Distance)

(The formulas include Starting Velocity, but as it is ZERO, I just ignored them; also if you don't understand something please let me now, I'm not used to write Physics in English)
 
cepheid said:
what fact is true about those positions when the vehicles "meet?"

That's maybe what I'm missing, what is that fact?
 
igurmendez said:
Oh, i didn't know about that sorry.

Well they indeed start from the same location.
I have been trying to solve this problem for the last 25 minutes but I can't find a soultion. I have been trying with these formulas:

Final Velocity = (Acceleration)(Time)
Distance = (Final Velocity/2) Time
Distance =(Acceleration x Time^2)/2
Final Velocity^2 = 2(Acceleration)(Distance)

Right. So with this third formula, since you know the acceleration of the vehicle, you know how far it has traveled at any time. (Meaning that if you substitute a specific time value into the equation, you can calculate the distance traveled at that time).

igurmendez said:
(The formulas include Starting Velocity, but as it is ZERO, I just ignored them;

Not necessarily. The easiest way to solve this problem is to start at the instant the car begins to move. That's t = 0. This means that, at t = 0, the bike has some initial position (50 m) and some initial velocity (10 m/s). You can use those in the equation for the distance of the bike vs. time.


igurmendez said:
That's maybe what I'm missing, what is that fact?

If we are both at the starting line of a race and I start running first, and then you start running later, but you're going faster, then you are going to catch up to me. At the point when you catch up to me, our distances from the starting line are the same, right? In other words, our positions are equal. The same thing is true when car catches up to the bike. The two vehicle's positions are equal at that instant.
 
Yes yes, I already knew that, that's the way I'm handling the problem; but after that I don't know what to do after that :S

I have tried substituting those values on all formulas but it seems I'm missing something!
 
As far as I know, you have two equations and two unknowns. This means you can arrive at an exact solution. If you have indeed equated the two expressions for the distance of the car and distance of the bike, then you should be able to solve for the time value t at which the equality holds true. Once you know t, then you can compute d. Once you equate the two expressions, all of the physics is done. Short of actually doing the algebra for you, there is no real further help anyone can provide. If you are having trouble with the algebra, you could always post it to see if people can track down any errors.
 
draw graphics it will be useful.
 
  • #10
Thank you very much man!

This will be very useful, I'll go alone from here!

Thanks
 

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