Constant Acceleration - Kinematics Problem Help

AI Thread Summary
A train is accelerating uniformly between two points, passing through velocities of 50 km/h and 80 km/h. To find the velocity at the halfway point, two simultaneous equations are set up using the kinematic formula V^2 = (V(0))^2 + 2as. The equations derived are 80^2 = 50^2 + 2as and M^2 = 50^2 + (1/2)*2as, where M represents the halfway velocity. Solving these equations simultaneously yields the result M = 5√178. The problem illustrates the application of kinematics in determining velocity during constant acceleration.
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Homework Statement



A train at constant acceleration is traveling in a straight line. It passes two points at a velocity of 50km/h and 80km/h respectively. What is the exact velocity of the train when it is halfway between these two points?

Let v be the exact velocity of the train when it is halfway between these two points

(Must be solved using two simultaneous equations)

Thanks! :)

Homework Equations





The Attempt at a Solution

 
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So what have you tried?
 
Using formula V^2=(V(0))^2+2*a*s
where a is acceleration, s is displacement, v is velocity, V(0) is initial velocity:

80^2=50^2+2as (1)
M^2=50^2+(1/2)*2*as (2)

where M is the velocity at halfway

Solved them simultaneously and got M=5*sqrroot(178)
 
You got the right answer...
 

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