SOLUTION: An engineer in a locomotive sees a car stuck on the track at a railroad crossing in front of the train. When the engineer first sees the car, the locomotive is 160 m from the cr

Algebra ->  Customizable Word Problem Solvers  -> Travel -> SOLUTION: An engineer in a locomotive sees a car stuck on the track at a railroad crossing in front of the train. When the engineer first sees the car, the locomotive is 160 m from the cr      Log On

Ad: Over 600 Algebra Word Problems at edhelper.com


    

Question 1165530: An engineer in a locomotive sees a car stuck
on the track at a railroad crossing in front of
the train. When the engineer first sees the
car, the locomotive is 160 m from the crossing
and its speed is 29 m/s.
If the engineer’s reaction time is 0.22 s,
what should be the magnitude of the minimum deceleration to avoid an accident?
Answer in units of m/s^2
.
Answer by ikleyn(52782) About Me  (Show Source):
You can put this solution on YOUR website!
.
An engineer in a locomotive sees a car stuck on the track at a railroad crossing
in front of the train. When the engineer first sees the car, the locomotive
is 160 m from the crossing and its speed is 29 m/s.
If the engineer’s reaction time is 0.22 s, what should be the magnitude
of the minimum deceleration to avoid an accident?
Answer in units of m/s^2
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ 

In 0.22 of a second, the locomotive moves forward 29*0.22 = 6.38 meters.


The remaining distance to the car is 160 - 6.38 = 153.62 meters.


At the time moment t= 0.22 s, the locomotive starts decelerating.


We assume that the deceleration value remains constant.

At this condition, the average rate to the stop is  29/2 = 14.5 m/s.


Thus the time decelerating to the full stop is  153.62%2F14.5 = 10.59448276 seconds.


The uniform deceleration value is  29%2F10.59448276 = 2.737273792.


ANSWER.  The minimum uniform deceleration is about 2.74 m/s^2.

Solved.