Natural Numbers: Tools for Understanding

NATURAL NUMBERS

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intelligence of the numberverse

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Proximate-Prime Polynomials

A proximate-prime polynomial is simply a quadratic equation - a finite polynomial of the second degree - that is derived from four successive (proximate, or neighboring) primes. Proximate-prime polynomials are interesting because they exhibit much greater prime densities than other polynomials.

The high primality of prime-derived quadratic sequences

What is a "perfect prime polynomial"?

What is polynomial pronic alignment?

Use an Excel spreadsheet to explore polynomial primes!

Catch the Wave...

When you graph primes against an X-axis that treats the expanding interval between successive perfect squares as a constant unit subdivided into equal parts, you produce a distinctive wave form for primes and prime factors.

Try out an ingenious Excel worksheet to see the wave!

Counting primes by quadratic interval

Fixing Fermat’s Factorization Method

How do you make Fermat's method of factorization faster than trial division...?

The Magic Square of Subtraction...

For every composite number that is not itself a perfect square there exists a pair of nonconsecutive perfect squares whose difference is equal to the composite. Even before we get to the subject of factorization, the consequences of this observation are fascinating and far-reaching.

Part 1 - A 'Classic Discovery'

Part 2 - A Deterministic Test

Q-Paired Primes...

It began with an exploration of biquadratic paired primes: 2 primes separated by the equivalent of exactly 2 quadratic intervals.... Then the investigation took the logical next level by asking the question: Are there prime pairs that are separated by other, greater multiples of the quadratic interval? And if there are, what are the frequency characteristics by interval size and perfect square offset? The results are in, with charts, an Excel visualization, and masses of half-digested data...!

Read about the latest findings

What are Biquadratic Paired Primes?

Two "new" rules of perfect squares

How I learned not to be afraid of big numbers!

It's a question of magnitude...

The inspiration for this site...

The Sacks Number Spiral

Using Excel as a tool for number theory

Find examples throughout this site that demonstrate using VBA code with worksheets and graphing - including generating primes, perfect squares, and composites, doing modular arithmetic, calculating GCDs, and more....

November 17th, 2011
What has 6 got to do with it?

Here is a little discovery: The difference between the first and fourth prime number of a proximate-prime polynomial is ALWAYS A MULTIPLE OF 6.

For example:

Prox. Prime Poly.	1st Term	4th Term	4t-1t	7th Term	7t-1t	10th Term	10t-1t	13th Term	13t-1t
n^2 + n + 10157	10159	10177	18	10213	54	10267	108	10339	180
n^2 - n + 10331	10331	10343	12	10373	42	10421	90	10487	156
2n^2 - 2n + 10627	10627	10651	24	10711	84	10807	180	10939	312
n^2 - n + 11777	11777	11789	12	11819	42	11867	90	11933	156
n^2 - n + 12107	12107	12119	12	12149	42	12197	90	12263	156
2n^2 - 2n + 12277	12277	12301	24	12361	84	12457	180	12589	312
2n^2 - 2n + 12409	12409	12433	24	12493	84	12589	180	12721	312
3n^2 - 3n + 12653	12653	12689	36	12779	126	12923	270	13121	468
n^2 + 5n + 12785	12791	12821	30	12869	78	12935	144	13019	228
n^2 + n + 12887	12889	12907	18	12943	54	12997	108	13069	180

Surprisingly, this divisibility by 6 does not stop with the fourth term. It recurs with the polynomial's 7th term, 10th term, 13th term, and so on ad infinitum.

Lots more data available: PPPs < 50000, t1 - t15 ("T" denotes each t value divisible by 6) Download (115KB)

Do you know why?
Is it related to the Euler and Riemann zeta functions?

August 25th, 2009
Factoring in Polynomial Time: A Pronic Solution...

Sometimes the best things in life are free - well, almost free... and very simple... and blindingly obvious. A single GCD calculation using the closest pronic number to N will produce a factor for one-third of composites not divisible by 2 or 5 up to any size. For example, the nearest pronic to 898097881 is 898110992, and these numbers share a GCD of 1873 - a prime factor of both numbers.

An analysis of N < 10,000,000 shows that 35.8% of the nonobvious composites are factorable with a single GCD calculation. What is the common characteristic of this huge class of numbers? They appear to conform to rational angles in the Sacks number spiral. Such numbers can be generated with RadiusTest using the Lines option and produce polynomials with a third coefficient of 0.

Expanding the GCD calculation to pronic numbers within 6 quadratic intervals of N provides a nearly instantaneous factorization test for more than two-thirds of composites ending in 1, 3, 7, or 9 regardless of magnitude. Here is an analysis of composites less than 10⁷ with GCDs calculated for pronics from 6 quadratic intervals less than N through 6 quadratic intervals greater than N. It shows a 74.4% success rate.

Analysis for N<10⁷ Download (11MB)

Previous Articles
Instantly factor a semiprime!
Reveal the DNA of semiprimes
The Q square of factoring

Tools for Testing Natural Numbers
Tools are digitally signed for security: Wordwise Solutions


	MinusSquare
	Miller-Rabin
	FermaticTest
	QTest
	RadiusTest
	ZetaTest
	PrimeTest

	MinusSquare: A New Factoring Algorithm (beta: 26-Apr-08)
	The magic square of subtraction has given birth to a baby factoring algorithm. Download Program (25KB)

	Miller-Rabin Demo with source code (beta: 2-Feb-08)
	Desktop program and complete project source code for what is possibly the only available Visual Basic (VB6) implementation of the gold standard in primality testing. A fast and reliable test for numbers up to 10²⁷-1 (that's 1 with 26 9s - a prime number...!). (Modular exponentiation code provided by DI Management Cryptography Software.) Download Project (10KB) Download Program (17KB)
	FermaticTest (beta: 23-Jan-08)
	"Fermatic" is a made-up word: Fermat + Automatic. This tool takes Fermat's great theorem to the limit, with some experiments to weed out pesky pseudoprimes. Rapidly generate prime, pseudoprime, and composite data. Download (34KB)
	QTest (beta: 21-Jul-08)
	Enter 3 or 4 numbers in a sequence and find out what the next 10, next 1,000, or next 10,000 values are. QTest lets you derive a quadratic equation from the values you input (and solve the equation's roots). Then you can use this polynomial to generate and analyze long number sequences for primality. (See Robert Sacks' method for quadratic derivation, used in Vortex.) Download (35KB) How to Use QTest
	RadiusTest (beta: 23-Jan-08)
	Calculate prime and composite distribution in the Sacks Number Spiral by offset (curved series) and angle (straight series). Download (22KB)
	ZetaTest (beta: 4-Feb-08)
	Calculate the products of infinite series using almost any inputs you can think of. Generates real number zeta series, demonstrating the calculation of many important constants - including e, pi, and phi, the Basel equality and Apéry's constant. Download (23KB)
	PrimeTest (beta: 23-Jan-08)
	Prime and composite number calculator (with prime and nonprime factor analyzer and prime number generator). Download (31KB)

This site is dedicated to exploring the undesigned intelligence of the numberverse
Undesigned intelligence proposes that the universe is the way it is neither by accident nor by design. The axioms of mathematics, the laws of physics are what they are innately and without reference to percepted existent reality. The intelligence inheres in and is nonreferentially existent without regard to the observer. Undesigned intelligence is uncreated.