Originally posted by BishopcrwYou're always makin these crazy numbers but FACT IS , ONE IS ALWAYS HALF WAY THERE NO MATTER WHAT THE DISTANCE!!!
Mathematically, And those who are closer to it are more than welcome to correct me. I believe it is called effective numbering.
As I stated above it is not just a scientific rounding but mathematical fact.
3 x 1/3 = 1 obviously and 1/3= .333... abv. by .3_
accordingly .3_ x 3 = .9_
Since they are identical formulas they must have the same result.
...[text shortened]... . Maybe when I become a member one of these days you will grace me with a gameπ
Edit -Sp
Originally posted by TRAINS44Yes, he can Mr. T. As much as it pains me to say it, Bowmann's right.
Yes SJ247,......NEVER! No matter what Bowmann says! He cant weasel outta this one, no he cant,
can he?
Consider the case of a bishop dropped onto the floor. It must follow the pattern mentioned, first travelling half the distance to the floor, then travelling half of the remaining distance, and so forth....
The answer is simply that as the bishop approaches the floor, and you keep dividing by two, the "halves" get infinitely small, the bishop starts knockin' off halves at an infinite rate, and sure as heck that bishop's gonna hit the floor.
The moral of the story is, don't drop your bishops. π³
Originally posted by leisurelyslothGravity wasn't a factor in original question. The point I believe was can something move from point A and reach point B if advancing in half-distances of last change in distance.
Yes, he can Mr. T. As much as it pains me to say it, Bowmann's right.
Consider the case of a bishop dropped onto the floor. It must follow the pattern mentioned, first travelling half the distance to the floor, then travelling half of the remaining distance, and so forth....
The answer is simply that as the bishop approaches the floor, and y ...[text shortened]... bishop's gonna hit the floor.
The moral of the story is, don't drop your bishops. π³
Originally posted by leisurelyslothThats a DROP, not a controled " moving halfway only" thing.
Yes, he can Mr. T. As much as it pains me to say it, Bowmann's right.
Consider the case of a bishop dropped onto the floor. It must follow the pattern mentioned, first travelling half the distance to the floor, then travelling half of the remaining distance, and so forth....
The answer is simply that as the bishop approaches the floor, and y ...[text shortened]... bishop's gonna hit the floor.
The moral of the story is, don't drop your bishops. π³
Originally posted by SJ247Oh, I get it now. Each "half" step requires an equal amount of time. My bad. You and Mr. T are quite right. Carry on....
Gravity wasn't a factor in original question. The point I believe was can something move from point A and reach point B if advancing in half-distances of last change in distance.
Originally posted by dertsUntil it would break eh?
Does anyone know how far you can lower a never ending piece of string into a bottomless pit?
Well if we take that in mind;
the string would take up an infinite amount of space before you'd lower it into the pit. Where would you leave it?
To answer your question: No.
No-one knows, since it's impossible.
EDIT: Such a shame I didn't read the whole thread first...
Originally posted by iamatigerYou wouldn't "be able to tell", meaning visually? We're talking beyond the scope of visualizing a distance here. Why is it so difficult to reach agreement here, why continue to duel back and forth for the sake of arguing? You cannot reach zero by halving. Period. One does not need a degree in mathematics to know this. And, please, degreed individuals, just admit it. Admit that the only argument you have is dependent on some mathematical rule created for the sake of rounding numbers to keep the mind intact. Answer with your best argument as to why one CAN reach zero by halving a number over and over, then prove it. Result MUST be ZERO, not 0.000000000000000000000000000000000000000000000000000001_ to the stinking millionth Nth degree, or something.
Eventually you would be so close that given the quantum uncertainty in your position you wouldn't be able to tell that you weren't there,