An object accelerates in the direction of the net applied force, which is the vector sum of all applied forces.
Force does have direction as it is a vector, meaning it has both magnitude and direction. Force is due to an x and a y component which are both perpendicular to each other. yes a force always has a partticular diraction. e.g;if u r pushing a box in some direction it will accelerate in the direction of force yes a force always has a partticular diraction. e.g;if u r pushing a box in some direction it will accelerate in the direction of force
Energy enough to accelerate the object to an orbital velocity.
2
The phrase "change in motion" is rather slippery.The size of the change in the object's position, per unit time, in a specifieddirection, is the component of its velocity in that direction.The size of the change in the object's velocity, per unit time, in a specifieddirection, is the component of its acceleration in that direction.
It is exactly the same as momentum and covered by Newton's first law of motion. Inertia is a way of expressing the force required to get an object to move from rest, or the force required to change the velocity or direction of an object in motion. Anything that has mass will have inertia - a "resistance to move or change velocity or direction of motion".
An object will accelerate in the direction of the net force acting on that object.
An object will accelerate in the direction of net force
Yes. If there is an unbalanced force on an object, the object will always accelerate in the direction of the force.
in terms of speed and direction , in what ways can an object accelerate
When the forces on an object are unbalanced, the object will accelerate in the direction of the net force.
an object can accelerate both up and down
an object can accelerate both up and down
The way it starts
The way it starts
Accelerate it! If the forces are unbalanced, the object will accelerate in the direction the uneven force is pushing on.
Change in direction
The acceleration will be in the direction of the net force.