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Chinese Remainder

Tool to compute congruences with the chinese remainder theorem. The Chinese Remainder Theorem helps to solve congruence equation systems in modular arithmetic.

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Chinese Remainder -

Tag(s) : Arithmetics

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Chinese Remainder

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Tool to compute congruences with the chinese remainder theorem. The Chinese Remainder Theorem helps to solve congruence equation systems in modular arithmetic.

Answers to Questions

What is the Chinese Remainder Theorem ?

The Chinese remainder theorem is the name given to a system of congruances (modular equations). The original problem is to calculate a number of elements which remainders (of their Euclidean division) are known.

Example: If they are arranged by 3 there remains 2. If they are arranged by 5, there remain 3 and if they are arranged by 7, there remain 2. How many objects are there?

Take a list of \( k \) coprimes integers \( n_1, ..., n_k \) and their product \( n = \prod_{i=1}^k n_i \). For all integers \( a_1, ... , a_k \), it exists another integer \( x \) which is unique modulo \( n \), such as :

$$ \begin{matrix} x \equiv a_1\pmod{n_1} \\ \ldots \\ x \equiv a_k\pmod{n_k} \end{matrix} $$

How to calculate chinese remainder?

To find a solution of the congruence system, take the numbers \( \hat{n}_i = \frac n{n_i} = n_1 \ldots n_{i-1}n_{i+1}\ldots n_k \) which are also coprimes. To find the modular inverses, use the Bezout theorem to find integers \( u_i \) and \( v_i \) such as \( u_i n_i + v_i \hat{n}_i = 1 \). Here, \( v_i \) is the modular inverse of \( \hat{n}_i \) modulo \( n_i \).

Take then the numbers \( e_i = v_i \hat{n}_i \equiv 1 \mod{n_i} \). A particular solution of the Chinese remainders theorem is $$ x = \sum_{i=1}^k a_i e_i~ $$

dCode accepts numbers as pairs (remainder, modulo) or written x = A mod B

Example: \( (2,3),(3,5),(2,7) \iff \left\{ \begin{array}{ll} x = 2 \mod 3 \\ x = 3 \mod 5 \\ x = 2 \mod 7 \end{array} \right. \Rightarrow x = 23 \)

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