6^2 = 130 - 2ab \Rightarrow 36 = 130 - 2ab \Rightarrow 2ab = 94 \Rightarrow ab = 47 - Appfinity Technologies
Understanding the Equation: From 6² = 130 – 2ab to ab = 47
Understanding the Equation: From 6² = 130 – 2ab to ab = 47
Mathematics is full of elegant transformations—where simple equations reveal deeper truths. One such example involves the expression 6² = 130 – 2ab, leading step-by-step to the elegant result ab = 47. This method showcases how algebraic manipulation unlocks insights in number theory and problem-solving. Let’s explore the derivation and its implications.
Understanding the Context
The Equation: 6² = 130 – 2ab
We begin with a carefully structured equation:
6² = 130 – 2ab
We know 6² = 36, so substitute to get:
36 = 130 – 2ab
This equation invites us to isolate the product term 2ab, a common algebraic technique used across math problems—from geometry to number theory.
Key Insights
Step 1: Rearranging to Isolate the Product
Subtract 130 from both sides:
36 – 130 = –2ab
–94 = –2ab
Multiply both sides by –1 to simplify:
94 = 2ab
Step 2: Solving for ab
Now divide both sides by 2:
2ab = 94 ⇒ ab = 47
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This final step reveals a simple yet powerful insight: the product of two variables, a and b, equals 47, given the constraint based on a = 6 and the equation 6² = 130 – 2ab.
Why This Matters: Algebraic Insight and Problem Solving
This derivation highlights key algebraic principles:
- Substitution: Replacing known values to simplify equations
- Isolation: Strategically rearranging terms to solve for unknown variables
- Simplification: Reducing expressions step-by-step for clarity
Such reasoning is essential in solving quadratic expressions, factoring, and balancing equations—skills foundational in algebra, calculus, and advanced math applications.
Real-World Context: Applications of ab = 47
In practical scenarios, knowing that ab = 47 under certain conditions helps in optimization problems, combinatorics, or factoring polynomials. For example:
- A rectangle with one side fixed at 6 and area derived from ab = 47 implies the other side is 47/6.
- In algebra, this might appear in expressions like (x – a)(x – b), where a = 6 and ab = 47 leads to a recognizable quadratic pattern.
