Here is that funny long division-like method for finding square and cube roots generalized to nth roots. These are all really extensions of the Binomial Theorem.

Steps

  1. Separate the number you want to find the nth root of into n-digit intervals before and after the decimal. If there are fewer than n digits before the decimal, then that is the first interval. And if there are no digits or fewer than n digits after the decimal, fill in the spaces with zeroes.
  2. Find a number (a) raised to the nth power closest to the first n digits (or the fewer than n digits before the decimal) as a base-ten number without going over. This is the first and only digit of your estimate so far.
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  3. Subtract your estimate to the nth power (a n ) from those first n digits and bring down the next n digits next to that difference to form a new number, a modified difference. (Or multiply the difference by 10 n and add the next n digits as a base-ten number.)
  4. Find a number b such that  ( n C 1 a n - 1 (10 n-1 ) + n C 2 a n - 2 b (10 n - 2 ) ) + . . . +  n C n - 1   a b n - 2 (10 )  +  n C n b n - 1 (10 0 ) )b  is less than or equal to the modified difference above (10 n (d ) + d 1 d 2 . . . d n ).  This becomes the second digit of your estimate so far.
    • The combinations notation n C r represents n! divided by the product of (n - r)! and r!, where n! = n(n - 1)(n - 2)(n - 3) . . . (3)(2)(1). The notation n C r is sometimes expressed as n over r within tall parentheses without a division bar, and it can be calculated simply as the first r factors of n! divided by r!, which is often written as n P r divided by r!
  5. Subtract the two quantities in the last step above (10 n (d ) + d 1 d 2 . . . d n minus n C 1 a n - 1 (10 n-1 ) + n C 2 a n - 2 b (10 n - 2 ) ) + . . . +  n C n - 1   a b n - 2 (10 )  +  n C n b n - 1 (10 0 ) )b) to form your new modified difference by bringing down the next set of n digits next to that result. (Or multiply the difference by 10 n and add the next n digits as a base-ten number.)
  6. Find a new number c and use your estimate so far, a (which is now 2 digits), such that  ( n C 1 a n - 1 (10 n - 1 ) + n C 2 a n - 2 c (10 n - 2 ) + . . . +  n C n - 1   a c n - 2 (10 )  +  n C n c n - 1 (10 0 ) ) c  is less than or equal to the new modified difference in above (10 n (d ) + d 1 d 2 . . . d n ). This becomes the third digit of your estimate so far.
  7. Keep repeating the last two steps above to find more digits of your estimate.
    • This is basically a rolling binomial expansion minus the lead term, where the two terms involved are the prior estimate multiplied by 10 and the next digit to improve the estimate.
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  • Question
    How do I find the 7th root of 4 without using a calculator?
    Community Answer
    You must follow the steps for the seventh root, grouping 4 as 4. 0000000 0000000, etc. And you'll likely need a 4-function calculator. "By Hand" here really means, without using the nth-root function on a scientific calculator. Though, with a lot of work, it could be done by hand.
  • Question
    The equation to find the second digit of your estimate as described in step 4 is too vaguely defined for me to even devise a clearly defined equation from it. Could you define it as a summation?
    Keith Raskin
    Community Answer
    Yes, we can. As a sum: Sum 1 through k of n_C_k a^(n - k)b^(k - 1)10^(n - k).
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