1). First of all, in order to make an object rise at all, an upward force must be applied to it, and the force must be greater than the object's weight. 2). If an upward force exactly equal to the object's weight is applied to it, then the object can "hover" wherever you put it, as if it is weightless, but it can't rise. 3). If the upward force is greater than the object's weight, then the object can rise to any desired height. It will continue to rise, and its speed will increase, as long as the upward force continues. 4). When the upward force stops, then the object will continue to rise, but it's upward speed will begin to decrease. When the upward speed decreases to zero, the object stops rising and begins to fall. It's downward speed then increases continually, until it hits the ground.
When the distance between the two object increases the gravitational force increases because gravitational force is inversely proportional to distance and also the mass of the object increases than force also increases because this force is directly proportional to mass.
This depends on the type of force. The force of gravity, for example, is inversely proportional to the SQUARE of the distance between the two bodies. On the other hand, the force exerted by a lever is directly proportional to the distance from the fulcrum. You should repost your question with a little more detail. What forces, and where?
No, the measured weight of an object WILL change but the mass of an object will never change regardless of the gravitational force on object.
Gravitational force depends on the masses of both objects and the distance between them. The formula is Gravitational Force = 6.67428 * 10^-11 * Mass of First Object * Mass of Second Object / Distance^2.
The gravitational force depends on the masses involved and on the distance between them. In the case of an object close to Earth's surface, the force is approximately 9.8 newton per kilogram.
you divide distance over time
Any force with a vertical component that equals or exceeds the weight of the object.
How you calculate the input force that you apply to bike pedals involves multiplying the force by the distance the object moves in the direction of the force. This is a part of the law of the lever.
The equation to calculate the work done is: Work done (J) = force applied (n) x distance moved of force (m)
To calculate work done on an object one needs to use the following equation; work = force x distance or W = F x d
How you calculate the input force you apply to bike pedals involves the use of the law of the lever. In this case, the force must be multiplied by the distance that the object moves in the direction of the force.
Work = (Force) x (Distance the object moves) x (cosine of the angle between force and motion)
spin it. Torque is a rotational force applied to an object. It is measured on a tangent to the centerline of the rotation in force-distance from that center. ie: foot-pounds, newton-meter, etc..
The object's mass and weight determines the force and distance, the greater the force, the less distance it covers. However, when a knife cuts the object, it covers less force and more distance.
When the Force increases on an Object, the Distance it travels INCREASES, as does its Velocity.
W=Fd Where F is the force on the object and d is that distance that the object traveled. If F is in Newtons and d is in meters, then works will be in joules.
From that information, we can't calculate the mass of the object. But we can calculate the strength of the force that was used to move it. Work = (force) times (distance) 372 = (force) times (16) Force = 372 / 16 = 23.25 newtons