Benford's Law
Take a big pile of really random numbers.
If they are truly random, the first digit in each number will NOT be randomly distributed from 1-9. In fact, about 30% of the time, the first digit will be 1.
The number 2 will be the first digit a little over 17% of the time, and the probability drops and drops until you get to 9, which is the first digit only about 4.5% of the time.
This is used by the IRS in forensic accounting and fraud detection.
Truly random data showing extremely predictable behaviour? Fucking awesome.
Describe something awesome from mathematics
2If you plot natural numbers in a spiral grid, the primes start to appear in diagonals.
WTF, Ulam?
WTF, Ulam?
Describe something awesome from mathematics
3stewie wrote:Benford's Law
Take a big pile of really random numbers.
If they are truly random, the first digit in each number will NOT be randomly distributed from 1-9. In fact, about 30% of the time, the first digit will be 1.
The number 2 will be the first digit a little over 17% of the time, and the probability drops and drops until you get to 9, which is the first digit only about 4.5% of the time.
This is used by the IRS in forensic accounting and fraud detection.
Truly random data showing extremely predictable behaviour? Fucking awesome.
So that's why my iPod plays three Tiny Tim songs in a row.
Describe something awesome from mathematics
4Add any single digit number to the number 9 and the the resulting digits in the sum added to each another are the same as the original single digit number.
Ex:
7+9= 16
1+6= 7
4+9= 13
1+3= 4
The same holds true with double digit numbers, though they have to be reduced to a single digit number first.
Ex:
44*+9= 53
[*where 4+4= 8]
5+3= 8
25*+9= 34
[*where 2+5=7]
3+4= 7
If you do the same thing with multiplication, the end result will always be 9.
Ex:
4*9= 36
3+6= 9
50*9= 450
4+5+0= 9
465*9= 4185
4+1+8+5= 18
1+8= 9
Ex:
7+9= 16
1+6= 7
4+9= 13
1+3= 4
The same holds true with double digit numbers, though they have to be reduced to a single digit number first.
Ex:
44*+9= 53
[*where 4+4= 8]
5+3= 8
25*+9= 34
[*where 2+5=7]
3+4= 7
If you do the same thing with multiplication, the end result will always be 9.
Ex:
4*9= 36
3+6= 9
50*9= 450
4+5+0= 9
465*9= 4185
4+1+8+5= 18
1+8= 9
"To be stupid, selfish, and have good health are three requirements for happiness, though if stupidity is lacking, all is lost."
-Gustave Flaubert
-Gustave Flaubert
Describe something awesome from mathematics
6I've seen a special case of one of Gauss' many things in the user description things... but e^(i*x) = cos(x) + i*sin(x)... where
e is Euler's number, the base of the natural logarithm, 2.718... you know
i is the "square root of negative 1"
x is an angle, in radians (2*pi of those in a circle, as opposed to 360 degrees in a circle. Really handy unit for math and physics and electronics)
^ is exponentiation (2^3 = 2*2*2, for example)
Use x = pi. The sine of pi is zero, and the cosine of pi is -1. Hence, e^(i*pi)=-1. It all seems very abstract (how do you multiply a number by itself an imaginary number of times? Let alone pi times?) but it's really really nice to work with instead of trig, and the special case is often mentioned as the most beautiful expression in math, for bringing a whole lot of seemingly totally unconnected mathematical concepts together.
e is Euler's number, the base of the natural logarithm, 2.718... you know
i is the "square root of negative 1"
x is an angle, in radians (2*pi of those in a circle, as opposed to 360 degrees in a circle. Really handy unit for math and physics and electronics)
^ is exponentiation (2^3 = 2*2*2, for example)
Use x = pi. The sine of pi is zero, and the cosine of pi is -1. Hence, e^(i*pi)=-1. It all seems very abstract (how do you multiply a number by itself an imaginary number of times? Let alone pi times?) but it's really really nice to work with instead of trig, and the special case is often mentioned as the most beautiful expression in math, for bringing a whole lot of seemingly totally unconnected mathematical concepts together.
Describe something awesome from mathematics
7104(# of views of this thread) is 20.8 times >>>>>>>than 5(# of replies)
Describe something awesome from mathematics
8Can anybody give me a concise description of Ramsey Number Theory?
steve albini
Electrical Audio
sa at electrical dot com
Quicumque quattuor feles possidet insanus est.
Electrical Audio
sa at electrical dot com
Quicumque quattuor feles possidet insanus est.
Describe something awesome from mathematics
9steve wrote:Can anybody give me a concise description of Ramsey Number Theory?
Have you read this?
Is this to determine how many players must be seated at the table to be sure there'll be at least one fish?
Describe something awesome from mathematics
10I still think the multiples of nine finger trick is really awesome. It's still quite HANDY for those who are mathematically incompetent.
I'm assuming everyone already knows it so I won't bother trying to explain...
I'm assuming everyone already knows it so I won't bother trying to explain...