The two square roots are -1 and +1.
For any real number, x, other than 0, if y is the square root of x then so is -y.
1 and -1.
Perfect square roots are the counting numbers {1, 2, 3, ...} The squares of the perfect square roots are the perfect squares, namely 1² = 1, 2² = 4, 3² = 9, etc.
The Pythagorean theorem states that the square of the hypotenuse of a right triangle is equal to the sum of the squares of the other two sides. 1. squares, not square roots 2. right triangle, not isosceles 3. sides opposite the hypotenuse, not any two 4. What are the mistakes, not what is
3 squares: 36 + 4 + 1 2 squares: 25 + 16
8 squares x 2/3 = 16/3 squares = 5 1/3 squares
if the squares can't overlap then: 36 one by one squares 9 two by two squares 4 three by three squares 1 four by four squares 1 five by five squares 1 six by six square a total of 52 then if they can overlap then: 36 one by one 25 two by two 16 three by three 9 four by four 4 five by five 1 six by six a total of 91 then
The two real roots are -1 and +1.There are also two roots in the complex field and these are ±i where i is the imaginary square root of -1.
-1 and +1.
Difference of two squares.
169 and 196 are perfect squares. Their square roots are 13 and 14 respectively. The perfect squares from 1^2 to 16^2 are: 1,4, 9, 16, 25, 36, 49, 64, 81, 100, 144, 169, 196, 225, 256. It is useful to memorize the perfect squares, as it makes estimating square roots easier. In case you wanted to find the square root of 169,196, the answer is roughly 411.334414... The square roots of integers which are not perfect squares are irrational, so they can not be expressed exactly as a sequence of digits.
If you mean: y = x squared-2x+1 then it has two equal roots of 1
It is Fermat's theorem on the sum of two squares. An odd prime p can be expressed as a sum of two different squares if and only if p = 1 mod(4)