The backwards force affects a motion by slowing it down
Forcing backwards will result on a impulse forwards.
Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.
While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".
Force that did the work = (work done) divided by (distance the force acted through)
I usually start with the definition of work: Work = force * distance so... Force = work / distance Distance = work / force So, no. You had it backwards.
g- force ?
You are using your muscles to move water backwards, which causes you to move forwards. This is a simple application of the idea of a reaction force - just like if you push against your desk whilst sitting on a wheely chair, you will go backwards. Now we have the equation work done = force x distance moved meaning that the further you move or the bigger the force you use, the more work you have done. The distance is easy to measure, the force is going to be harder to figure out. Suggestions please!
The backwards force affects a motion by slowing it down
Action and reaction forces work while roller staking by the action force being that you and your roller skates move forward. The reaction force is when the roller skates slide backwards on the ground.
One way to think of the "g-force" is as a fictitious force - one that SEEMS to push you backwards, when you are being accelerated forward. Actually (from the point of view of an observer who is not accelerating with you), no backwards force is required - in fact, it is only by the fact that there is a forward force, NOT balanced by a backward force, that acceleration is possible in the first place.
The strategy of working backwards entails starting with the end results and reversing the steps you need to get those results, in order to figure out the answer to the problem. =D
yea because acceleration is force devised by mass
Forcing backwards will result on a impulse forwards.
Yes, but they work backwards.
Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.Yes, if no force is applied. Work = force x distance, so if the force is zero, no work is done.
While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".While an object falls faster and faster, the backwards force of air resistance will increase. Once the force of air resistance equals the force of gravitation, the object will no longer accelerate, and is said to have reached "terminal velocity".