(x%2B3)(x%2B4)(x%2B5)-8.jpeg "(x+2)(x+3)(x+4)(x+5)-8")
Factoring the expression (x+2)(x+3)(x+4)(x+5)-8
The expression (x+2)(x+3)(x+4)(x+5)-8 might look intimidating at first glance, but we can factor it in a clever way to reveal its hidden beauty.
Step 1: Recognizing the Pattern
Observe that the first part of the expression is a product of four consecutive terms. This hints at a pattern that can be exploited for factorization.
Step 2: Introducing a "Middle Term"
Let's introduce a new variable, say 'y', to simplify our expression. Let:
y = (x+2)(x+5)
Notice that if we multiply out the terms of (x+3)(x+4), we get:
(x+3)(x+4) = x² + 7x + 12
Now, we can rewrite the original expression in terms of 'y':
(x+2)(x+3)(x+4)(x+5) - 8 = y(x² + 7x + 12) - 8
Step 3: Completing the Square
Let's focus on the quadratic term (x² + 7x + 12). We can manipulate it by completing the square. To do this:
- Take half of the coefficient of the x term (7/2) and square it (49/4).
- Add and subtract this value inside the parentheses:
(x² + 7x + 12) = (x² + 7x + 49/4 - 49/4 + 12)
- The first three terms now form a perfect square trinomial:
(x² + 7x + 49/4 - 49/4 + 12) = (x + 7/2)² - 1/4
Step 4: Substituting and Factoring
Substitute this back into our expression:
y(x² + 7x + 12) - 8 = y((x + 7/2)² - 1/4) - 8
Now, we can factor out a common factor of 'y':
y((x + 7/2)² - 1/4) - 8 = y(x + 7/2)² - y/4 - 8
We can rewrite the last two terms to get a difference of squares:
y(x + 7/2)² - y/4 - 8 = y(x + 7/2)² - (1/4)(y + 32)
Finally, we can factor this expression as a difference of squares:
y(x + 7/2)² - (1/4)(y + 32) = [√(y)(x + 7/2) + √(1/4)(y + 32)][√(y)(x + 7/2) - √(1/4)(y + 32)]
Step 5: Replacing 'y'
Remember that y = (x+2)(x+5). Substitute this back into the factored expression to get the final result:
[√((x+2)(x+5))(x + 7/2) + √(1/4)((x+2)(x+5) + 32)][√((x+2)(x+5))(x + 7/2) - √(1/4)((x+2)(x+5) + 32)]
Conclusion
This factorization might seem intricate, but it demonstrates the power of recognizing patterns, completing the square, and utilizing variable substitutions to simplify complex expressions.