don't know, only three though
An object can accelerate by speeding up (increasing velocity) or by changing direction (experiencing a change in acceleration).
an object can accelerate both up and down
No, it is not harder to accelerate a moving object. The initial motion of the object does not affect the force required to accelerate it further. The force required to accelerate an object depends on its mass and the desired acceleration.
Objects can accelerate through forces like gravity, friction, and applied external forces. Acceleration can also occur from changes in an object's direction or speed.
An object will accelerate in the direction of the net force acting upon it. If multiple forces are acting on the object, the net force is the vector sum of all the individual forces, and the object will accelerate in the direction of this net force.
in terms of speed and direction , in what ways can an object accelerate
An object can accelerate by speeding up (increasing velocity) or by changing direction (experiencing a change in acceleration).
an object can accelerate both up and down
An object will accelerate in the direction of the net force acting on that object.
No, it is not harder to accelerate a moving object. The initial motion of the object does not affect the force required to accelerate it further. The force required to accelerate an object depends on its mass and the desired acceleration.
Accelerate, motion is generated by applying force to mass.
... to accelerate.... to accelerate.... to accelerate.... to accelerate.
Objects can accelerate through forces like gravity, friction, and applied external forces. Acceleration can also occur from changes in an object's direction or speed.
Velocity must be changing in order for an object to accelerate or decelerate.
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 will accelerate in the direction of the net force acting upon it. If multiple forces are acting on the object, the net force is the vector sum of all the individual forces, and the object will accelerate in the direction of this net force.