a = F/M = 2,580/654 = 3.945 meters/second2 . . . about 0.4 G
You twice it.
Yea, they have a cruising speed of 45 mph, and accelerate during the chase :) pretty darn fast, though not as fast as a Peregrine
Newton stated that an object will change velocity if you push it or pull it - it accelerates in the direction you push it. If you push it twice as hard, it will accelerate twice as fast (acceleration is directly proportional to force). If the object has twice the mass, it will accelerate half as much (acceleration is inversely proportional to mass)
Newtons are a unit of force. A force of 1 Newton acting on a mass of 1 kilogram causes it to accelerate by 1 metre/second every second by Newton second law: force = mass x acceleration. A 1-kg mass that is dropped will accelerate down at 9.81 metres per second per second before it hits the floor, therefore the force acting it, which is its weight, is 9.81 Newtons. But the same 1-kg mass, on the Moon, accelerates one sixth as fast, and its weight is less, one sixth of the old weight, so its weight is only 1.63 Newtons.
F = m aa = F/m = 100/20 = 5 meters per second2 .
You twice it.
Acceleration. Force is equal to mass times the acceleration, so in this case, acceleration is how fast an object increases its velocity.
A.) They accelerate by there bones and your heart. If your heart is fast you will be fast, if your heart is slow you will go slow.
Really fast
g force is the force exerted on a body in the opposite direction to which said body is accelerating. if you're on a rollercoaster and your going not too fast and you suddenly change direction and accelerate quickly, you get pushed back into your seat. g force gets its name as 1g is the equivilent of the force of gravity on the earths surface. That's why when individuals experience g forces greater than 1 or 2, they experience a heavy, weighty feeling and do indeed for a brief moment weigh heavier.Sudden Change In Direction
acceleration
Accelerate around the corners
45mph
Air resistance is always a resisting force. No matter where a person or object is and no matter how fast or slow that object is moving relative to something, air resistance will always be there, provided that you are on Earth. In space, there is no resisting force.
Let's assume that the 2 pound payload is on frictionless wheels and the suction cup is horizontal so that the force acting to separate it from the payload is entirely due to the acceleration of the car and the inertia of the payload. In that case: You can accelerate at 100 G before the force is sufficient to pull the payload loose. Note that this is a limitation on how fast you can accelerate, not how fast you can drive; you can drive as fast as your car will go as long as you accelerate at less than 100 G to get there (this shouldn't be a problem, as no car can accelerate at anywhere near 10 G, let alone 100 G). 100 G corresponds to 3200 ft/sec/sec, or "zero to sixty" in about three-hundredths of a second.
0 to 87 in about 12 seconds
Force (F) = mass (m) times acceleration (a); F = ma; a = F/m = 2/2 = 1 meter per second per second