(x + y)2 = x2 + y2 + 2xy
prove the given identity
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(x + y)2 = x2 + y2 + 2xy
prove the given identity
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(x + y)² = x² + 2xy + y²
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The second option is true , that is: The square of the sum of two quantities is equal to the square of the first term, plus twice the product of the two terms, plus the square of the second term.
We can arrive at the result in the following two ways.
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●Proof 1: Involution Method
The problem here is one of involution, that is raising a quantity to a power. To raise a quantity to a second power is to multiply the quantity by itself. In the given problem, the quantity is (x + y). Therefore,
(x + y)² = (x+y) (x+y)
- Multiplying term by term_
(x + y)² = x² + xy + yx + y²
- Using the commutative property of algebra,
xy = yx
Hence, (x + y)² = x² + xy + xy + y²
Or, (x + y)² = x² + 2xy + y² which proves our assertion
●Proof 2: Binomial Method
The Binomial Theorem states that
(x + a)^n = x^n + n a x^(n-1) + [n(n-1)/1.2] a² x^(n-2) + ………
Now put a = y and n = 2 (number of terms = n+1 = 3) to obtain
(x + y)² = x² + 2 y x^(2-1) + (2.1/1.2) y² x^(0) + 0
which on simplification gives,
(x + y)² = x² + 2 y.x¹ + 1. y². 1 (since x^(0) = 1)
Or, (x + y)² = x² + 2xy + y² (Proved)
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:) may its help
ANSWER:-(x + y)² = x² + 2xy + y²
The square of the sum of two quantities is equal to the square of the first term, plus twice the product of the two terms, plus the square of the second term.
We can arrive at the result in the following two ways.
Proof 1: Involution Method
The problem here is one of involution, that is raising a quantity to a power. To raise a quantity to a second power is to multiply the quantity by itself. In the given problem, the quantity is (x + y). Therefore,
(x + y)² = (x+y) (x+y)
Multiplying term by term
(x + y)² = x² + xy + yx + y²
Using the commutative property of algebra,
xy = yx
Hence, (x + y)² = x² + xy + xy + y²
Or, (x + y)² = x² + 2xy + y² which proves our assertion
Proof 2: Binomial Method
The Binomial Theorem states that
(x + a)^n = x^n + n a x^(n-1) + [n(n-1)/1.2] a² x^(n-2) + ………
Now put a = y and n = 2 (number of terms = n+1 = 3) to obtain
(x + y)² = x² + 2 y x^(2-1) + (2.1/1.2) y² x^(0) + 0
which on simplification gives,
(x + y)² = x² + 2 y.x¹ + 1. y². 1 (since x^(0) = 1)
Or, (x + y)² = x² + 2xy + y² (Proved)