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statHelpers.h	2021-01-29	2021-01-29 12:31:58 +01:00

README.md

statHelpers

Arduino library with a number of statistic helper functions.

Description

This library contains functions that have the goal to help with some basic statistical calculations.

Functions

Permutation

returns how many different ways one can choose a set of k elements from a set of n. The order does matter. The limits mentioned is the n for which all k still work.

uint32_t permutations(n, k) exact up to 12
uint64_t permutations64(n, k) exact up to 20
double dpermutations(n, k) not exact up to 34 (4 byte) or 170 (8 byte)

If you need a larger n but k is near 0 the functions will still work, but to which k differs per value for n. (no formula found, and an overflow detection takes overhead).

nextPermutation(array, size) given an array of type T it finds the next permutation of that array in a lexicographical way. ABCD --> ABDC. Based upon // http://www.nayuki.io/page/next-lexicographical-permutation-algorithm although other same code examples exist.

Factorial

uint32_t factorial(n) exact up to 12!
uint64_t factorial64(n) exact up to 20! (Print 64 bit ints with my printHelpers)
double dfactorial(n) not exact up to 34! (4 byte) or 170! (8 byte)
double stirling(n) approximation function for factorial (right magnitude)

dfactorial() is quite accurate over the whole range. stirling() is up to 3x faster for large n (> 100), but accuracy is less than the dfactorial(), see example.

Combination

returns how many different ways one can choose a set of k elements from a set of n. The order does not matter. The number of combinations grows fast so n is limited per function. The limits mentioned is the n for which all k still work.

uint32_t combinations(n, k) n = 0 .. 30 (iterative version)
uint64_t combinations64(n, k) n = 0 .. 61 (iterative version)
uint32_t rcombinations(n, k) n = 0 .. 30 (recursive version, slightly slower)
uint64_t rcombinations64(n, k) n = 0 .. 61 (recursive version, slightly slower)
double dcombinations(n, k) n = 0 .. 125 (4bit) n = 0 .. 1020 (8 bit)

If you need a larger n but k is near 0 or near n the functions will still work, but for which k differs per value for n. (no formula found, and an overflow detection takes overhead).

combPascal(n, k) n = 0 .. 30 but due to double recursion per iteration it takes time and a lot of it for larger values. Added for recreational purposes, limited tested.

Notes

perm1 is a sketch in the examples that shows a recursive permutation algorithm. It generates all permutations of a given char string. It allows you to process every instance. It is added to this library as it fits in the context.

Future

code & example for get Nth Permutation
investigate valid range detection for a given (n, k) for combinations and permutations.

Operation

See examples