True!.
Sierra Ambrosio"))
True
False. You will know nothing at all about any force acting perpendicular to the direction of motion.
The only "weigh" to determine the mass of an object is to compare it with the mass of a known object. The mass of an object is determined by force and acceleration.
the mass (m) of an object times its acceleration (a) is the force (f) exerted on the object. f=ma
inertial mass
True
True!. Sierra Ambrosio"))
False. You will know nothing at all about any force acting perpendicular to the direction of motion.
If you meant to say mass instead of weight, the acceleration of an object is inversely proportional to mass, because F=ma. However for falling objects where acceleration is equal to gravity, the weight is not a variable.
an object's mass
-- the object's mass -- the net force acting on it
That's the object's acceleration.
The only "weigh" to determine the mass of an object is to compare it with the mass of a known object. The mass of an object is determined by force and acceleration.
Changing the magnitude or direction of forces exerted on an object changes the net force (sum of all forces) exerted on the object. The net force exerted on an object is defined as mass times acceleration (F = ma), where mass, m, is constant. This means that when the net force exerted on the object changes in magnitude (or direction), its acceleration will also change in magnitude (or direction). In addition, acceleration is defined as the change in velocity, so when the magnitude (or direction) of acceleration changes, the magnitude (or direction) of velocity will also change.
the mass (m) of an object times its acceleration (a) is the force (f) exerted on the object. f=ma
inertial mass
The upward force exerted on an object in a fluid is buoyancy.