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No, the acceleration of an object is in the direction of the net force applied to it. If the net force is in the same direction as the object's motion, the acceleration will be in the same direction. If the net force is opposite to the object's motion, the acceleration will be in the opposite direction.
What else can I help you with?
What is the relationship between an object's acceleration and the direction of the force on the object?
If an object is increasing in speed, the acceleration is positive and the force is in the direction of travel. If the object is slowing down, the acceleration is negative and the force is acting against the direction of movement.
What can you say about the direction of the acceleration and the force that produces it?
Acceleration always occurs in the direction of the net force acting on an object. If the net force and acceleration have the same direction, the object speeds up; if they have opposite directions, the object slows down. The relationship between acceleration and the force that produces it is described by Newton's second law of motion.
How an object changes direction when a force is applied to it is called what?
The change in direction of an object when a force is applied to it is called "acceleration." The acceleration of an object depends on the magnitude and direction of the force, as well as the mass of the object.
If the net force of an object is negative direction what will be the direction resulting acceleration be?
If the net force of an object is in the negative direction, the resulting acceleration will also be in the negative direction. This means that the object will be accelerating in the opposite direction of the applied force.
Is acceleration due to change in direction?
Acceleration is defined as the change in velocity, and is a result of a force being applied on the object in question. Acceleration will not always result in an object changing direction, but it is capable of it (in the case of centripetal acceleration, all it does is change the direction.) Acceleration is a vector, therefore a direction must always be given when a value is stated.
What is the relationship between an object's acceleration and the direction of the force on the object?
If an object is increasing in speed, the acceleration is positive and the force is in the direction of travel. If the object is slowing down, the acceleration is negative and the force is acting against the direction of movement.
What can you say about the direction of the acceleration and the force that produces it?
Acceleration always occurs in the direction of the net force acting on an object. If the net force and acceleration have the same direction, the object speeds up; if they have opposite directions, the object slows down. The relationship between acceleration and the force that produces it is described by Newton's second law of motion.
How an object changes direction when a force is applied to it is called what?
The change in direction of an object when a force is applied to it is called "acceleration." The acceleration of an object depends on the magnitude and direction of the force, as well as the mass of the object.
If the net force of an object is negative direction what will be the direction resulting acceleration be?
If the net force of an object is in the negative direction, the resulting acceleration will also be in the negative direction. This means that the object will be accelerating in the opposite direction of the applied force.
If a non zero net force acts on an object what does the object do?
-- When the net force on an object is not zero, the object undergoes accelerated motion.-- The magnitude of the acceleration is the ratio of the net force to the object's mass.-- The direction of the acceleration is the same as the direction of the net force.
Is acceleration due to change in direction?
Acceleration is defined as the change in velocity, and is a result of a force being applied on the object in question. Acceleration will not always result in an object changing direction, but it is capable of it (in the case of centripetal acceleration, all it does is change the direction.) Acceleration is a vector, therefore a direction must always be given when a value is stated.
What determines your acceleration?
Acceleration is determined by the net force acting on an object and the object's mass, as described by Newton's second law of motion (F=ma). The greater the force applied to an object, or the lighter the object's mass, the greater the acceleration. Acceleration always occurs in the direction of the net force.
How is direction of acceleration related to direction of momentum?
It isn't. The direction of momentum is the same as the direction of the velocity - of the movement. The direction of acceleration, on the other hand, is the same as the direction of the net force that acts on an object - and this force can be in any direction.
When the net force an object is greater than zero the object will accelerate in the direction of the?
The acceleration will be in the direction of the net force.
How does the direction of acceleration compare with the direction of the net force that produces it?
Acceleration is proportional to net force.That means that acceleration is equal to (net force) times (something).The 'something' is [ 1 / (the mass of the object being accelerated by the force) ].
How are the direction of the an objects acceleration and direction of the same object change in velocity related?
The direction of an object's acceleration is determined by the direction of the net force acting on it. The change in velocity of the object is also influenced by this net force. Therefore, the direction of the object's acceleration and the direction of its change in velocity are related in that they are both affected by the net force acting on the object.
Can an object have a net force opposite to the direction of its acceleration?
No. Acceleration is always in the direction of net force.The deceptively simple equation that shows this is [ F = m A ].' F ' (force) and ' A ' (acceleration) are vectors. The equation says that not only isthe size of ' F ' equal to the sizeof ' mA ', but their directions are also the same.
