Wiki User
∙ 14y ago60 Km/h = 60 × 1000 = 60,000 m/s
Acceleration = Change in velocity / Change in time
so , a = v - u / t
.'. a = 60,000 - 0 / 10
.'. a = 60,000 / 10
.'. a = 6,000 / 1
.'. a = 6,000
Then the Acceleration is 6,000 m/s2 ..........
OR :-
10 seconds = 10'÷ 60 = 1/6 hours
Acceleration = Change in velocity / Change in time
so , a = v - u / t
.'. a = 60 - 0 / (1/6)
.'. a = 60 / (1/6)
.'. a = 60 × 6
.'. a = 360
Then the Acceleration is 360 km/h2 ..........
So the Acceleration is either 6,000 m/s2 or 360 Km/h2
Wiki User
∙ 14y agoThe gravitational acceleration would be the change in velocity divide by the time required. For this example 8.15 m/sec divided by 5 seconds yields 1.63 m/s2. (The actual average lunar gravity is estimated at 1.622 m/sec2.)
In two seconds of fall, the speed increases 19.6 meters (64.4 feet) per second. The magnitude of velocity increases by that amount, while the direction of velocity doesn't change.
Acceleration has a dimensionality of length/time^2, so if you were measuring the distance in meters and the time in seconds, the acceleration would be m/s^2.
The acceleration of the roller coaster would be 88 MPH. This was figured out by doing math.
Answer: v=u + at v (Velocity) = u (Starting velocity) + a (acceleration) x t (time) So, starting from stationary (u=0), the velocity is simply a x t e.g. if the acceleration is 5mph per second per second, after 10 seconds you would be travelling at 50mph. Answer: The above is for constant acceleration. In the case of variable acceleration, integration has to be used.
It is 0.1 metre per second-squared.
The gravitational acceleration would be the change in velocity divide by the time required. For this example 8.15 m/sec divided by 5 seconds yields 1.63 m/s2. (The actual average lunar gravity is estimated at 1.622 m/sec2.)
In two seconds of fall, the speed increases 19.6 meters (64.4 feet) per second. The magnitude of velocity increases by that amount, while the direction of velocity doesn't change.
Acceleration = Change in speed/Time Time = Change in Speed/Acceleration = 65mph/20mph per s = 65/20 seconds = 3.25 seconds
It is 0.1 metre per second-squared.
Acceleration has a dimensionality of length/time^2, so if you were measuring the distance in meters and the time in seconds, the acceleration would be m/s^2.
To answer this question we would need to know the acceleration, which is not provided.
known to be seconds pendulum,the length would be almost 1m when acceleration due to gravity is 9.8m/s2
Divide the difference in speed by the time it takes. This will give you the average acceleration for that time period.
After 15 seconds, the train's speed would be 7.5 miles per second. This can be calculated by multiplying the acceleration (0.5 miles per second) by the time (15 seconds).
If mass increases and there is no friction, the acceleration of an object on an inclined plane would remain constant, assuming the incline angle and applied force remain the same. The acceleration is determined by the net force acting on the object, which in this case is equal to the component of the gravitational force parallel to the incline.
The acceleration of the car can be calculated using the formula: acceleration = (final velocity - initial velocity) / time. Given the initial velocity (A), final velocity (B), and time (8 seconds), you can substitute the values into the formula to find the acceleration.