It shouldn't relate at all.
The period of a pendulum depends only on its length,
not on how far it swings side-to-side.
It shouldn't relate at all. The period of a pendulum depends only on its length, not on how far it swings side-to-side.
The longer the pendulum is, the greater the period of each swing. If you increase the length four times, you will double the period. It is hard to notice, but the period of a pendulum does depend on the angle of oscillation. For small angles, the period is constant and depends only on the length of the pendulum. As the angle of oscillation (amplitude) is increased, additional factors of a Taylor approximation become important. (T=2*pi*sqrt(L/g)[1+theta^2/16+...] and the period increases. (see hyper physics: http://hyperphysics.phy-astr.gsu.edu/hbase/pendl.html) Interestingly, if the pendulum is supported by a very light wire then the mass of the object at the end of the pendulum does not affect the period. Obviously, the greater the mass, the less any air friction or friction at the pivot will slow the pendulum. Also interestingly, the pendulum period is dependant on the force of gravity on the object (g). One must not assume that g is constant for all places on Earth.
- the payback period is to dependent on cash inflows which are hard to predict. - The payback period only considers revenue, does not consider profits.
They are usually easier to comprehend. Many people would find it hard to relate 639/852 to anything but most of them would be comfortable with 3/4, the reduced version of the fraction.
6/18
It shouldn't relate at all. The period of a pendulum depends only on its length, not on how far it swings side-to-side.
The longer the pendulum is, the greater the period of each swing. If you increase the length four times, you will double the period. It is hard to notice, but the period of a pendulum does depend on the angle of oscillation. For small angles, the period is constant and depends only on the length of the pendulum. As the angle of oscillation (amplitude) is increased, additional factors of a Taylor approximation become important. (T=2*pi*sqrt(L/g)[1+theta^2/16+...] and the period increases. (see hyper physics: http://hyperphysics.phy-astr.gsu.edu/hbase/pendl.html) Interestingly, if the pendulum is supported by a very light wire then the mass of the object at the end of the pendulum does not affect the period. Obviously, the greater the mass, the less any air friction or friction at the pivot will slow the pendulum. Also interestingly, the pendulum period is dependant on the force of gravity on the object (g). One must not assume that g is constant for all places on Earth.
yes it is hard and easy
Then you've pushed in to hard!
it is aload of wood pushed together hard with glue in it and that is how it is made
It means you pushed yourself to hard in and intense workout.
Yes, the heart of a horse CAN burst if it is pushed too hard. If you have seen the movie Secretariat, the horse Secretariat's jockey, Ronnie, pushes too hard in a race and its heart bursts. This is a true story of a race horse.
No, it is usually something your born with.
Probably not
Bop, hard bop, swing, hip, cat,
Your answer was in the question. You find it hard to relate to them because you are not used to them. If you don't really understand them and they know it, they will probably not open up but time will take it toll, if that is the case. Hope tis helps~
You have eat to much or could be pregnate