The square root of 2 can be written as an infinite continued fraction.
| √2 = 1 + | 1 |
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| 2 + | 1 |
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| 2 + | 1 |
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| 2 + | 1 |
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| 2 + ... | ||||
The infinite continued fraction can be written, √2 = [1;(2)], (2) indicates that 2 repeats ad infinitum. In a similar way, √23 = [4;(1,3,1,8)].
It turns out that the sequence of partial values of continued fractions for square roots provide the best rational approximations. Let us consider the convergents for √2.
| 1 + | 1 |
= 3/2 |
2 |
| 1 + | 1 |
= 7/5 | |
| 2 + | 1 |
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2 |
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| 1 + | 1 |
= 17/12 | ||
| 2 + | 1 |
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| 2 + | 1 |
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2 |
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| 1 + | 1 |
= 41/29 | |||
| 2 + | 1 |
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| 2 + | 1 |
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| 2 + | 1 |
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2 |
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Hence the sequence of the first ten convergents for √2 are:
What is most surprising is that the important mathematical constant,
e = [2; 1,2,1, 1,4,1, 1,6,1 , ... , 1,2k,1, ...].
The first ten terms in the sequence of convergents for e are:
The sum of digits in the numerator of the 10th convergent is 1+4+5+7=17.
Find the sum of digits in the numerator of the 100th convergent of the continued fraction for e.