Reduced residue system: Difference between revisions

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	Any subset ''R'' of the integers is called a '''reduced residue system''' modulo ''n'' if:		Any subset ''R'' of the integers is called a '''reduced residue system''' modulo ''n'' if:<ref>{{harvtxt\|Long\|1972\|p=85}}</ref><ref>{{harvtxt\|Pettofrezzo\|Byrkit\|1970\|p=104}}</ref>

	#gcd(''r'', ''n'') = 1 for each ''r'' contained in ''R'';		#gcd(''r'', ''n'') = 1 for each ''r'' contained in ''R'';
	#''R'' contains φ(''n'') elements;		#''R'' contains φ(''n'') elements;
	#no two elements of ''R'' are congruent modulo ''n''.~~<ref>{{harvtxt\|Long\|1972\|p=85}}</ref><ref>{{harvtxt\|Pettofrezzo\|Byrkit\|1970\|p=104}}</ref>~~		#no two elements of ''R'' are congruent modulo ''n''.

	Here <math>\varphi</math> denotes ].		Here <math>\varphi</math> denotes ].

Revision as of 06:56, 4 April 2016

Any subset R of the integers is called a reduced residue system modulo n if:

gcd(r, n) = 1 for each r contained in R;
R contains φ(n) elements;
no two elements of R are congruent modulo n.

Here $\varphi$ denotes Euler's totient function.

A reduced residue system modulo n can be formed from a complete residue system modulo n by removing all integers not relatively prime to n. For example, a complete residue system modulo 12 is {0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11}. 1, 5, 7 and 11 are the only integers in this set which are relatively prime to 12, and so the corresponding reduced residue system modulo 12 is {1,5,7,11}. The cardinality of this set can be calculated with the totient function: $\varphi (12)=4$ . Some other reduced residue systems modulo 12 are:

{13,17,19,23}
{−11,−7,−5,−1}
{−7,−13,13,31}
{35,43,53,61}

Facts

If {r₁, r₂, ... , r_φ(n)} is a reduced residue system with n > 2, then $\sum r_{i}\equiv 0{\pmod {n}}$ .
Every number in a reduced residue system mod n is a generator for the additive group of integers modulo n.

Notes

Long (1972, p. 85)
Pettofrezzo & Byrkit (1970, p. 104)

References

Long, Calvin T. (1972), Elementary Introduction to Number Theory (2nd ed.), Lexington: D. C. Heath and Company, LCCN 77171950
Pettofrezzo, Anthony J.; Byrkit, Donald R. (1970), Elements of Number Theory, Englewood Cliffs: Prentice Hall, LCCN 71081766

External links

Residue systems at PlanetMath
Reduced residue system at MathWorld

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Revision as of 06:56, 4 April 2016

Facts

See also

Notes

References

External links