The ability to apply a change in velocity on an object is known as acceleration. Acceleration can be positive (speeding up), negative (slowing down), or changing direction. It is a vector quantity with both magnitude and direction.
To change an object's velocity, you need to apply a force to it. The force will cause the object to accelerate, thus changing its velocity. The magnitude and direction of the force will determine the extent and direction of the velocity change.
No, internal forces can't change the velocity of a body. Because if we want to change the velocity of a body we must apply a external force or an unbalanced force. Ex:- if we travel in a bus , if we apply some forces inside the bus the velocity of the bus can't change.so internal forces can not change the velocity of body ---- ----
The answer is velocity.
No, momentum is a property of an object in motion that is determined by its mass and velocity. It does not apply a force itself, but can be used to analyze how forces acting on an object change its motion.
If unbalanced forces are applied to an object, the object will experience acceleration in the direction of the net force. This acceleration will cause the object's velocity to change, leading to either an increase or decrease in speed or a change in direction. The object will continue to move until the forces acting on it are balanced.
To change an object's velocity, you need to apply a force to it. The force will cause the object to accelerate, thus changing its velocity. The magnitude and direction of the force will determine the extent and direction of the velocity change.
The second law of motion states that the acceleration of an object is directly proportional to the net force acting on it and inversely proportional to its mass. The equation F = ma represents this relationship, where F is the net force applied, m is the mass of the object, and a is the acceleration produced. So, mass multiplied by acceleration is the ability to change the velocity of an object by applying a force to it.
No, internal forces can't change the velocity of a body. Because if we want to change the velocity of a body we must apply a external force or an unbalanced force. Ex:- if we travel in a bus , if we apply some forces inside the bus the velocity of the bus can't change.so internal forces can not change the velocity of body ---- ----
The answer is velocity.
No, momentum is a property of an object in motion that is determined by its mass and velocity. It does not apply a force itself, but can be used to analyze how forces acting on an object change its motion.
That will never happen - it can't happen actually. Any time you apply a force to an object, it will accelerate - its velocity will change.
If unbalanced forces are applied to an object, the object will experience acceleration in the direction of the net force. This acceleration will cause the object's velocity to change, leading to either an increase or decrease in speed or a change in direction. The object will continue to move until the forces acting on it are balanced.
To change an object's velocity, you can apply a force in the direction you want it to accelerate. This force can be produced by pushing, pulling, or using any other method of applying force to the object. Additionally, altering the mass of the object or the direction of the force can also change its velocity.
With changing the "state of motion", I assume you want to change the velocity. What you need here is a force, applied on the object. The amount of acceleration is given by Newton's Second Law.
The second law of motion states that the force acting on an object is equal to the mass of the object multiplied by its acceleration. This means that an applied force will cause an object to accelerate in the direction of the force. The relationship between force, mass, and acceleration can be expressed mathematically as F = ma.
Yes. If it weren't so, an object that isn't moving could never be made to move at all! Of course, once you apply acceleration (which implies a change of velocity), the object's velocity won't stay zero. But for a brief instant, the velocity can be zero while accelerating.
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