Draw the force vector diagram to scale and measure (or calculate) the resultant
= .----> -16 + 20 =+4
Drawing a free body diagram, the forces you care for are the ones in the same direction. Now drawing a vector addition diagram, we know that the first force vector plus the second force vecotr equals the resultant force vector. Therefore, the net force is equal to the value of the first force plus the value of the second force.
Net Force, Or Net Resultant Force, or Resultant force
Force vectors are represented by arrows in a force diagram.
Draw the force vector diagram to scale and measure (or calculate) the resultant
= .----> -16 + 20 =+4
it is a net diagram heheheheh :P
Drawing a free body diagram, the forces you care for are the ones in the same direction. Now drawing a vector addition diagram, we know that the first force vector plus the second force vecotr equals the resultant force vector. Therefore, the net force is equal to the value of the first force plus the value of the second force.
This would be known as the net-force.
Inertia will not be affected when "net" or "net force" is zero.
Net Force, Or Net Resultant Force, or Resultant force
Force vectors are represented by arrows in a force diagram.
I'd call it the resultant, but "net force" is a good name too.
Net force and interference are related because net force is a force and interference is putting a force on something.
force is a push or pull. net force is the overall force on an object.
-- A car accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the car. -- A stone accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the stone. -- A Frisbee accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the Frisbee. -- A baseball accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the baseball. -- A dog accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the dog. -- A book accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the book. -- A canoe accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the canoe. -- An airplane accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the airplane. -- A planet accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the planet. -- A cow accelerates in the direction of the net force on it, at a rate equal to the magnitude of the net force divided by the mass of the cow.