Solving Projectile Motion: A Building 70.0 m High

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SUMMARY

The problem involves a ball thrown horizontally from a height of 70.0 m, landing 90.0 m away from the building's base. To solve this, the SUVAT equations are utilized. First, calculate the time of fall using the equation s = ut + 0.5at², where s = 70 m, u = 0 m/s, and a = 9.8 m/s². This yields the fall time, which is then used to determine the horizontal speed required to cover 90 m, leading to the calculation of both vertical and horizontal impact speeds and the resultant angle of impact.

PREREQUISITES
  • Understanding of projectile motion principles
  • Familiarity with SUVAT equations
  • Basic trigonometry for combining vectors
  • Knowledge of gravitational acceleration (9.8 m/s²)
NEXT STEPS
  • Study the derivation and application of SUVAT equations in various projectile motion scenarios
  • Learn how to apply trigonometric functions to resolve vector components
  • Explore the effects of air resistance on projectile motion
  • Practice similar problems involving different heights and distances in projectile motion
USEFUL FOR

Students studying physics, educators teaching projectile motion concepts, and anyone interested in applying mathematical principles to real-world motion problems.

ScienceGirl90
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Homework Statement



A ball is thrown horizontally from the top of a building 70.0 m high. The ball strikes the ground 90.0 m from the base of the building (Neglecting air resistance). How fast and at what angle (relative to horizontal) does the ball strike the ground?


Homework Equations


I'm not sure!


The Attempt at a Solution


My teacher briefly explained projectile motion but I don't understand it at all! Please help me.
 
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You should use the SUVAT equations.

First, calculate the time taking to fall the 70m from the top of the building using s= u*t + 0.5*a*(t^2).

Where s = distance, u = initial speed, v = final speed, a = acceleration and t = time.

(Can you see why they're called SUVAT equations?)

You know u = 0m/s, a = 9.8m/s^2, t = ? and s = 70m. Plug them in and rearrange to get the fall time t.

Then, using v = u + at with the values from above, you can get vertical impact speed v.

Because fall time vertically = flight time horizontally, you now know how long it took to travel the 90m horizontally. Because you are neglecting air resistance, for the horizontal flight u = v and a = 0.

So using s = u*t + 0.5*a*(t^2), where a = 0, s = 90 and t = answer from first section, you can plug in your values and get u = v.

You now have both vertical impact speed and horizontal impact speed. Combine the two using basic trigonometry and you get your impact speed and angle.

Jared
 

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