Long Division Method to find Square root with Examples
Given an integer X which is a perfect square, the task is to find the square root of it by using the long division method.
Examples:
Input: N = 484
Output: 22
222 = 484Input: N = 144
Output: 12
122 = 144
Approach:
Long division is a very common method to find the square root of a number. The following is the stepwise solution for this method:
1. Divide the digits of the number into pairs of segments starting with the digit in the units place. Let’s identify each pair and the remaining final digit(in case there is an odd count of digits in the number) as a segment.
For example:
1225 is divided as (12 25)
2. After dividing the digits into segments, start from the leftmost segment. The largest number whose square is equal to or just less than the first segment is taken as the divisor and also as the quotient (so that the product is the square).
For example:
9 is the closest perfect square to 12, the first segment 12
3. Subtract the square of the divisor from the first segment and bring down the next segment to the right of the remainder to get the new dividend.
For example:
12 - 9 = 3 is concatenated with next segment 25. New dividend = 325
4. Now, the new divisor is obtained by taking two times the previous quotient(which was 3 in the above example as 32 = 9) and concatenating it with a suitable digit which is also taken as the next digit of the quotient, chosen in such a way that the product of the new divisor and this digit is equal to, or just less than the new dividend.
For example:
Two times quotient 3 is 6.
65 times 5 is 325 which is closest to the new dividend.
5. Repeat steps (2), (3) and (4) till all the segments have been taken up. Now, the quotient so obtained is the required square root of the given number.
Below is the implementation of the above approach:
CPP
// C++ program to find the square root of a // number by using long division method #include <bits/stdc++.h> using namespace std; #define INFINITY_ 9999999 // Function to find the square root of // a number by using long division method int sqrtByLongDivision( int n) { int i = 0, udigit, j; // Loop counters int cur_divisor = 0; int quotient_units_digit = 0; int cur_quotient = 0; int cur_dividend = 0; int cur_remainder = 0; int a[10] = { 0 }; // Dividing the number into segments while (n > 0) { a[i] = n % 100; n = n / 100; i++; } // Last index of the array of segments i--; // Start long division from the last segment(j=i) for (j = i; j >= 0; j--) { // Initialising the remainder to the maximum value cur_remainder = INFINITY_; // Including the next segment in new dividend cur_dividend = cur_dividend * 100 + a[j]; // Loop to check for the perfect square // closest to each segment for (udigit = 0; udigit <= 9; udigit++) { // This condition is to find the // divisor after adding a digit // in the range 0 to 9 if (cur_remainder >= cur_dividend - ((cur_divisor * 10 + udigit) * udigit) && cur_dividend - ((cur_divisor * 10 + udigit) * udigit) >= 0) { // Calculating the remainder cur_remainder = cur_dividend - ((cur_divisor * 10 + udigit) * udigit); // Updating the units digit of the quotient quotient_units_digit = udigit; } } // Adding units digit to the quotient cur_quotient = cur_quotient * 10 + quotient_units_digit; // New divisor is two times quotient cur_divisor = cur_quotient * 2; // Including the remainder in new dividend cur_dividend = cur_remainder; } return cur_quotient; } // Driver code int main() { int x = 1225; cout << sqrtByLongDivision(x) << endl; return 0; } |
Java
// Java program to find the square root of a // number by using long division method import java.util.*; class GFG{ static final int INFINITY_ = 9999999 ; // Function to find the square root of // a number by using long division method static int sqrtByLongDivision( int n) { int i = 0 , udigit, j; // Loop counters int cur_divisor = 0 ; int quotient_units_digit = 0 ; int cur_quotient = 0 ; int cur_dividend = 0 ; int cur_remainder = 0 ; int a[] = new int [ 10 ]; // Dividing the number into segments while (n > 0 ) { a[i] = n % 100 ; n = n / 100 ; i++; } // Last index of the array of segments i--; // Start long division from the last segment(j=i) for (j = i; j >= 0 ; j--) { // Initialising the remainder to the maximum value cur_remainder = INFINITY_; // Including the next segment in new dividend cur_dividend = cur_dividend * 100 + a[j]; // Loop to check for the perfect square // closest to each segment for (udigit = 0 ; udigit <= 9 ; udigit++) { // This condition is to find the // divisor after adding a digit // in the range 0 to 9 if (cur_remainder >= cur_dividend - ((cur_divisor * 10 + udigit) * udigit) && cur_dividend - ((cur_divisor * 10 + udigit) * udigit) >= 0 ) { // Calculating the remainder cur_remainder = cur_dividend - ((cur_divisor * 10 + udigit) * udigit); // Updating the units digit of the quotient quotient_units_digit = udigit; } } // Adding units digit to the quotient cur_quotient = cur_quotient * 10 + quotient_units_digit; // New divisor is two times quotient cur_divisor = cur_quotient * 2 ; // Including the remainder in new dividend cur_dividend = cur_remainder; } return cur_quotient; } // Driver code public static void main(String[] args) { int x = 1225 ; System.out.print(sqrtByLongDivision(x) + "\n" ); } } // This code is contributed by Rajput-Ji |
Python3
# Python3 program to find the square root of a # number by using long division method INFINITY_ = 9999999 # Function to find the square root of # a number by using long division method def sqrtByLongDivision(n): i = 0 udigit, j = 0 , 0 # Loop counters cur_divisor = 0 quotient_units_digit = 0 cur_quotient = 0 cur_dividend = 0 cur_remainder = 0 a = [ 0 ] * 10 # Dividing the number into segments while (n > 0 ): a[i] = n % 100 n = n / / 100 i + = 1 # Last index of the array of segments i - = 1 # Start long division from the last segment(j=i) for j in range (i, - 1 , - 1 ): # Initialising the remainder to the maximum value cur_remainder = INFINITY_ # Including the next segment in new dividend cur_dividend = cur_dividend * 100 + a[j] # Loop to check for the perfect square # closest to each segment for udigit in range ( 10 ): # This condition is to find the # divisor after adding a digit # in the range 0 to 9 if (cur_remainder > = cur_dividend - ((cur_divisor * 10 + udigit) * udigit) and cur_dividend - ((cur_divisor * 10 + udigit) * udigit) > = 0 ): # Calculating the remainder cur_remainder = cur_dividend - ((cur_divisor * 10 + udigit) * udigit) # Updating the units digit of the quotient quotient_units_digit = udigit # Adding units digit to the quotient cur_quotient = cur_quotient * 10 + quotient_units_digit # New divisor is two times quotient cur_divisor = cur_quotient * 2 # Including the remainder in new dividend cur_dividend = cur_remainder return cur_quotient # Driver code x = 1225 print (sqrtByLongDivision(x)) # This code is contributed by mohit kumar 29 |
C#
// C# program to find the square root of a // number by using long division method using System; class GFG { static readonly int INFINITY_ =9999999; // Function to find the square root of // a number by using long division method static int sqrtBylongDivision( int n) { int i = 0, udigit, j; // Loop counters int cur_divisor = 0; int quotient_units_digit = 0; int cur_quotient = 0; int cur_dividend = 0; int cur_remainder = 0; int []a = new int [10]; // Dividing the number into segments while (n > 0) { a[i] = n % 100; n = n / 100; i++; } // Last index of the array of segments i--; // Start long division from the last segment(j=i) for (j = i; j >= 0; j--) { // Initialising the remainder to the maximum value cur_remainder = INFINITY_; // Including the next segment in new dividend cur_dividend = cur_dividend * 100 + a[j]; // Loop to check for the perfect square // closest to each segment for (udigit = 0; udigit <= 9; udigit++) { // This condition is to find the // divisor after adding a digit // in the range 0 to 9 if (cur_remainder >= cur_dividend - ((cur_divisor * 10 + udigit) * udigit) && cur_dividend - ((cur_divisor * 10 + udigit) * udigit) >= 0) { // Calculating the remainder cur_remainder = cur_dividend - ((cur_divisor * 10 + udigit) * udigit); // Updating the units digit of the quotient quotient_units_digit = udigit; } } // Adding units digit to the quotient cur_quotient = cur_quotient * 10 + quotient_units_digit; // New divisor is two times quotient cur_divisor = cur_quotient * 2; // Including the remainder in new dividend cur_dividend = cur_remainder; } return cur_quotient; } // Driver code public static void Main(String[] args) { int x = 1225; Console.Write(sqrtBylongDivision(x) + "\n" ); } } // This code is contributed by Rajput-Ji |
Javascript
<script> // Javascript program to find the square root of a // number by using long division method let INFINITY_ =9999999; // Function to find the square root of // a number by using long division method function sqrtByLongDivision(n) { let i = 0, udigit, j; // Loop counters let cur_divisor = 0; let quotient_units_digit = 0; let cur_quotient = 0; let cur_dividend = 0; let cur_remainder = 0; let a = new Array(10); // Dividing the number into segments while (n > 0) { a[i] = n % 100; n = Math.floor(n / 100); i++; } // Last index of the array of segments i--; // Start long division from the last segment(j=i) for (j = i; j >= 0; j--) { // Initialising the remainder to the maximum value cur_remainder = INFINITY_; // Including the next segment in new dividend cur_dividend = cur_dividend * 100 + a[j]; // Loop to check for the perfect square // closest to each segment for (udigit = 0; udigit <= 9; udigit++) { // This condition is to find the // divisor after adding a digit // in the range 0 to 9 if (cur_remainder >= cur_dividend - ((cur_divisor * 10 + udigit) * udigit) && cur_dividend - ((cur_divisor * 10 + udigit) * udigit) >= 0) { // Calculating the remainder cur_remainder = cur_dividend - ((cur_divisor * 10 + udigit) * udigit); // Updating the units digit of the quotient quotient_units_digit = udigit; } } // Adding units digit to the quotient cur_quotient = cur_quotient * 10 + quotient_units_digit; // New divisor is two times quotient cur_divisor = cur_quotient * 2; // Including the remainder in new dividend cur_dividend = cur_remainder; } return cur_quotient; } // Driver code let x = 1225; document.write(sqrtByLongDivision(x) + "<br>" ); // This code is contributed by unknown2108 </script> |
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Time Complexity: O((log100n)2 * 10)
Auxiliary Space: O(1)
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