You just stated the 3rd law of newton which states that every action has an equal and opposite reaction.
This basically means that anything you do has to be reacted upon back. even more simply put, if an action has to take place (like jumping from a boat) then an equal force of action acting in the opposite direction also has to take place (the boat moves back).
A force that does not result in movement is called a balanced force. In this scenario, the force applied in one direction is counteracted by an equal force acting in the opposite direction, resulting in no overall motion.
If there are unbalanced forces acting on an object with the bigger force in the opposite direction to its movement, the object will slow down or decelerate. The net force will oppose the object's motion, causing it to eventually come to a stop or change its direction.
The force acting on the book when it is resting on a table is the gravitational force pulling the book downwards. This force is equal in magnitude and opposite in direction to the normal force exerted by the table on the book, keeping it in equilibrium.
No, resultant forces acting in different directions are not equal. The resultant force is the net force that results from combining all the individual forces acting on an object, taking into account their direction and magnitude.
The force in an inflated balloon is exerted outward equally in all directions.
The upward force acting on an object is the normal force. It is equal in magnitude, but opposite in direction to the object's weight.
impulse is equal to force which is acting on the body and ti me in small interval which is equal to momentum.so impulse is equal to change in momentum and direction of impulse is consider the direction of force and change in momentum.
Inertia is a property of matter that makes it harder to move, so that is probably what you are thinking of, but technically, forces do not oppose motion. Depending upon the direction in which a force is applied, one force can oppose another force that is acting in an opposite direction, but forces are not opposed to motion as such.
A force that does not result in movement is called a balanced force. In this scenario, the force applied in one direction is counteracted by an equal force acting in the opposite direction, resulting in no overall motion.
The resultant force of a number of balanced forces acting on a body is zero force. The reason is because any force in one direction is always canceled out by another equal force but in the opposite direction. This is what is meant by balanced forces. For every force in the positive direction, there is also an equal negative force in the negative direction. So the forces all add up to Zero. No net force at all.
The resultant force of a number of balanced forces acting on a body is zero force. The reason is because any force in one direction is always canceled out by another equal force but in the opposite direction. This is what is meant by balanced forces. For every force in the positive direction, there is also an equal negative force in the negative direction. So the forces all add up to Zero. No net force at all.
If there are unbalanced forces acting on an object with the bigger force in the opposite direction to its movement, the object will slow down or decelerate. The net force will oppose the object's motion, causing it to eventually come to a stop or change its direction.
The force acting on the book when it is resting on a table is the gravitational force pulling the book downwards. This force is equal in magnitude and opposite in direction to the normal force exerted by the table on the book, keeping it in equilibrium.
No, resultant forces acting in different directions are not equal. The resultant force is the net force that results from combining all the individual forces acting on an object, taking into account their direction and magnitude.
The force in an inflated balloon is exerted outward equally in all directions.
The equilibrant is a force that exactly balances the net force acting on an object, resulting in a state of equilibrium where the object is not accelerating. It is equal in magnitude but opposite in direction to the net force, effectively cancelling it out.
The direction of the force acting on a load depends on the nature of the situation. If the load is being lifted upwards, the force is acting upwards. If the load is being pulled downwards, the force is acting downwards. The direction of the force is determined by the direction in which the load is being moved or supported.