It depends ... If the body is accelerating uniformly with a constant acceleration a ....then the Force is a constant force.... But if it is accelerating non uniformly....then the Force is not constant...The 2nd law says F=m*a where m is mass of the body...
You can't tell from the information given. All you know is that the average acceleration is (change in speed) divided by (time for the change) = (6/8) = 0.75 meters per second2. The force required depends on the mass of the object to be accelerated by the force.
An accelerating force is a force that causes an object to change its speed or direction of motion, resulting in acceleration. It can be exerted by various means, such as gravity, friction, or propulsion systems, and its magnitude is directly related to the object's acceleration according to Newton's second law of motion.
The Maxximus G-Force can do 0-60mph in 2.134 seconds. which is At the moment the fastest accelerating road-legal car!
Uniformly accelerated motion is governed by Newton's laws of motion, particularly the second law (F = ma) which relates acceleration, force, and mass. Additionally, the equations of motion derived from kinematics, such as s = ut + (1/2)at^2, can be used to describe the motion of an object experiencing constant acceleration.
Please someone answer!!!!!
Force is directly proportional to mass. Therefore, even both the car and bicycle are being accelerated to the same velocity, accelerating a car would require more force since it has a greater mass.
To study the acceleration of a freely-falling body, we can modify the uniformly accelerated motion equations to account for the gravitational force acting on the object. This involves incorporating the acceleration due to gravity (9.81 m/s^2) into the equations of motion and considering the initial conditions of the freely-falling object. By doing this, we can analyze the motion of the object under the influence of gravity.
When an object is accelerated, its velocity changes. The velocity can increase if the object is accelerating in the direction of its initial velocity, or decrease if the object is decelerating or accelerating in the opposite direction. The change in velocity is directly proportional to the acceleration applied to the object.
One way to think of the "g-force" is as a fictitious force - one that SEEMS to push you backwards, when you are being accelerated forward. Actually (from the point of view of an observer who is not accelerating with you), no backwards force is required - in fact, it is only by the fact that there is a forward force, NOT balanced by a backward force, that acceleration is possible in the first place.
Accelerated particles gain kinetic energy as they move faster due to the work done on them by the accelerating force. This increase in kinetic energy is a result of the particle's velocity increasing.
A force is not measured in kilograms. The kilogram is a unit of mass; forces are measured in newtons. You can get the force with Newton's Second Law. In this problem, you will need some additional information, specifically, the object's mass.