if A is closer to the x-axis then its "faster"
Answer:
a = 50 [m/s²]
Explanation:
This type of problem can be solved using Newton's second law, which tells us that the sum of forces on a body is equal to the product of mass by acceleration.
∑F = m*a
where:
F = force =25 [N] (units of Newtons)
m = mass = 0.5 [kg]
a = acceleration [m/s²]
![a=F/m\\a=25/0.5\\a= 50 [m/s^{2}]](https://tex.z-dn.net/?f=a%3DF%2Fm%5C%5Ca%3D25%2F0.5%5C%5Ca%3D%2050%20%5Bm%2Fs%5E%7B2%7D%5D)
Answer:
<u>NORMAL DRIVER: </u>d = 73.3 ft
<u>DRUNK DRIVER: </u>d = 172.3
Explanation:
<u>NORMAL DRIVER:</u>
Distance covered in initial 0.75s = 0.75s *44 = 33ft
USING THE THIRD EQUATION OF MOTION
V^2-U^2 = 2as
0-(44)^2 = 2 (-24) s
s = 1936/48 =40.3 ft
d = 33 + 40.3 = 73.3 ft
<u>DRUNK DRIVER:</u>
Distance covered in initial 3s = 3s *44 = 132 ft
USING THE THIRD EQUATION OF MOTION
V^2-U^2 = 2as
0-(44)^2 = 2 (-24) s
s = 1936/48 =40.3 ft
d = 132 + 40.3 = 172.3 ft
Answer:
Satellites don't fall from the sky because they are orbiting Earth. Even when satellites are thousands of miles away, Earth's gravity still tugs on them. Gravity--combined with the satellite's momentum from its launch into space--cause the satellite go into orbit above Earth, instead of falling back down to the groundv
Explanation:
