ac = v2/r, where the variables are: * 'a' is the centripetal acceleration in metres per second per second; * 'v' is the tangential velocity in metres per second; and * 'r' is the radius of motion in metres.
Two formulae can be useful. Use one or the other, depending on what data you have:
a = v2/r
a = omega2 r
a is the acceleration, v the speed, r the radius, omega (Greek lowercase omega) is the angular speed in radians/second.
Here are two formulae for centripetal acceleration:a = velocity squared / radius
a = omega squared x radius
(where omega - that's the Greek lower-case omega - is angular speed, in radians per second)
a=omega^2*r
Where
omega= angular velocity
r=Radius
a = w2r = v2/r
where
a is acceleration
w is angular velocity
r is radius of orbit
v is velocity.
The centripetal acceleration is the square of the speed divided by the radius.
acceleration (a) = velocity squared divided by radius
a = v^2/R
acceleration is gravity (32 feet/sec/sec) and R is radius of the earth you get a bout 17,500 miles per hour
That's called 'centripetal acceleration'. It's the result of the centripetal forceacting on the object on the curved path.
The centripetal acceleration is equal to velocity squared over radius. a=v^2/r
centripetal acceleration
Change the magnitude of the force attracting the object toward the center.
And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.
That's called 'centripetal acceleration'. It's the result of the centripetal forceacting on the object on the curved path.
centripetal acceleration
The centripetal acceleration is equal to velocity squared over radius. a=v^2/r
Centripetal Acceleration is the ratio of the square of the velocity and radius ac=v2/r So if we change the velocity of the circulating object or change the radius of the revolution, centripetal acceleration is changed
centripetal acceleration
If an object follows a circular path, it must have a centripetal force on it to keep it moving in a circle. Centripetal means "toward the center of the circle". The force causes Centripetal acceleration toward the center witch is along the radius of the circular path. Tangential acceleration occurs at a Tangent to the circular path and is always perpendicular to the centripetal acceleration. Always perpendicular to the radius of the circle.
I guess you mean the centripetal acceleration in its orbit around the Sun. That's not something that will usually be found in references such as the Wikipedia, but you can calculate it in several ways. 1) Use the law of gravitation to calculate the force between an object of mass 1 kg. at Mercury's distance from the Sun, and the Sun. Any other mass will do as well, but after calculating the force, you need to calculate the acceleration, so the mass of Mercury (or another object at the same distance) cancels in the calculation. 2) Look up Mercury's orbital data. Assuming a circular orbit, calculate the centripetal acceleration as v2/r.
Use the formula for centripetal acceleration: velocity squared / radius.
Change the magnitude of the force attracting the object toward the center.
acceleration is never a scalar...it describes in what direction is the motion of an object changing, so it can't be a scalar...
And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.
246.74 or the rounded answer is 247