3. The height H of an object t seconds after it is propelled upward with an initial velocity v is represented by , where g is the gravitational pull and h is the initial height. The gravitational pull of the moon is 1.6 meters per second squared. The gravitational pull of earth is 9.8 meters per second squared.
a. Define all variables:
Let
H=
t=
v=
g=
h=
On the Moon: g=
On Earth: g=
a. Define all variables:
Let:
H = height of the object in meters after t seconds
t = time in seconds
v = initial velocity in meters per second
g = gravitational pull in meters per second squared
h = initial height in meters
On the Moon:
g = 1.6 meters per second squared
On Earth:
g = 9.8 meters per second squared
a. Define all variables:
H = height of the object (in meters)
t = time (in seconds) after the object is propelled upward
v = initial velocity of the object (in meters per second)
g = gravitational pull (acceleration due to gravity, in meters per second squared)
h = initial height of the object (in meters)
On the Moon:
g = gravitational pull on the Moon = 1.6 meters per second squared
On Earth:
g = gravitational pull on Earth = 9.8 meters per second squared