Well, isn't that just a happy little question! To find the acceleration of the canoe, we can use Newton's second law, which states that acceleration is equal to the force applied divided by the mass of the object. So, in this case, the acceleration of the 100kg canoe experiencing a force of 1000N would be 10 m/s^2. Just remember, there are no mistakes, just happy little accidents!
When experiencing acceleration, 1g feels like the normal force of gravity pulling you down. It is the same feeling as standing on the ground without any additional forces acting on you.
An object that experiences an unbalanced force will accelerate in the direction of the force. This acceleration can lead to a change in the object's speed, direction, or both.
-- putting the brakes on, in order to slow the car down; -- lifting the spoilers on the airplane wing, in order to reduce airspeed OR stop on the runway; -- firing rockets forward in the direction the Space Shuttle is moving, in order to reduce velocity and drop out of orbit; -- tossing a rock or a ball straight up in the air; the acceleration of gravity is downward, so the ball slows down and stops, before it starts falling; -- Just before the rock hits the ground, it has some speed. When it hits the ground, it feels a large acceleration UPWARD against its motion, and a split second later, its speed is zero.
A fictitious force caused by rotation - it feels as if a force pushes you towards the outside. The magnitude of the ficticious acceleration is equal to the real centripetal acceleration: a = v2/r. The corresponding force can be obtained from Newton's Second Law.
the acceleration of gravity on earth is one gravity. A G force is mass x acceleration so if you are accelerating at 5 gravity, as in a rocket takeoff, you experience a 5G force. If you weigh 100 pounds, a 5G force feels like 500 pounds. Those upside down roller coasters can give you up to 3G force.
4m /s
If the lift is in free fall, any riders will feel "weightless". Uniform downward acceleration will *only* produce "weightlessness" if the acceleration is equal to the acceleration due to gravity (id est, acceleration in free fall).
When experiencing acceleration, 1g feels like the normal force of gravity pulling you down. It is the same feeling as standing on the ground without any additional forces acting on you.
Einstein explored how force is related to acceleration in relativity. In general relativity, a force is a direct result of acceleration. For example, when one feels an acceleration or deceleration, they are actually feeling a force exerted on them. Under this reasoning, the force that an accelerating elevator exerts on your body is synonymous to the force that gravity exerts on your body.As for an equation, F=(γ3) ma
The acceleration of gravity on the moon is about 1/6th the acceleration of gravity on earth. Any mass on the earth's surface feels about 6 times the downward force that it would feel on the surface of the moon.
A space shuttle feels like a smooth ride during liftoff with a sense of acceleration and increased G-forces. Once in space, the shuttle feels weightless and the sensation is often described as floating. Reentry can feel turbulent and intense as the shuttle reenters the Earth's atmosphere.
check transmission fluid level
2nd: F = m *a The force an object feels is equal to its mass times its acceleration. 3rd: For every action there is an equal and opposite reaction.
An object that experiences an unbalanced force will accelerate in the direction of the force. This acceleration can lead to a change in the object's speed, direction, or both.
Free fall. The acceleration is perfectly balanced by the force, so it feels like being completely at rest, with everything else moving.
mass air flow sensor is bad - my guess is
i like the way it feels i like the way it feels i like the way it feels i like the way it feels