Number Theory: An Introduction to Mathematics

IV Continued Fractions and Their Uses............................

1 TheContinuedFractionAlgorithm.............................

Letξ=ξ 0 be an irrational real number. Then we can write

ξ 0 =a 0 +ξ 1 −^1 ,

wherea 0 =ξ 0 is the greatest integer≤ξ 0 and whereξ 1 >1 is again an irrational
number. Hence the process can be repeated indefinitely:

ξ 1 =a 1 +ξ 2 −^1 ,(a 1 =ξ 1 ,ξ 2 > 1 ),

ξ 2 =a 2 +ξ 3 −^1 ,(a 2 =ξ 2 ,ξ 3 > 1 ),

···

By construction,an∈Zfor alln≥0andan≥1ifn≥1. The uniquely determined
infinite sequence [a 0 ,a 1 ,a 2 ,...] is called thecontinued fraction expansionofξ.The
continued fraction expansion ofξnis [an,an+ 1 ,an+ 2 ,...].
For example, the ‘golden ratio’τ = ( 1 +

√

5 )/2 has the continued fraction
expansion [1, 1 , 1 ,...], sinceτ= 1 +τ−^1. Similarly,

√

2 has the continued fraction
expansion [1, 2 , 2 ,...], since

√

2 + 1 = 2 + 1 /(

√

2 + 1 ).

The relation betweenξnandξn+ 1 may be written as a linear fractional transforma-
tion:

ξn=(anξn+ 1 + 1 )/( 1 ξn+ 1 + 0 ).

An arbitrary linear fractional transformation

ξ=(αξ′+β)/(γξ′+δ)

is completely determined by its matrix

T=

(

αβ

γδ

)

.

This description is convenient, because if we make a further linear fractional transfor-
mation

ξ′=(α′ξ′′+β′)/(γ′ξ′′+δ′)

W.A. Coppel, Number Theory: An Introduction to Mathematics, Universitext,
DOI: 10.1007/978-0-387-89486-7_4, © Springer Science + Business Media, LLC 2009

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