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Solving The Equation – x2 + (y – 3√2x)2 = 1:

Solving The Equation - x2 + (y – 3√2x)2 = 1:

Solving The Equation - x2 + (y – 3√2x)2 = 1:

Equation, x2 + (y – 3√2x)2 = 1. In the realm of mathematics, equations play a crucial role in describing the relationships between various variables. One such intriguing equation is x2 + (y – 3√2x)2 = 1, which has piqued the interest of mathematicians and enthusiasts alike. This article aims to shed light on this unique equation, its solution, graphical representation, applications, and its significance in modern mathematics.


Understanding the Equation x2 + (y – 3√2x)2 = 1

x2 + (y – 3√2x)2 = 1, this quadratic equation is typical we need to understand this first before solving.

What is x2 + (y – 3√2x)2 = 1?

The equation x2 + (y – 3√2x)2 = 1 is a mathematical expression involving two variables, x and y. The presence of square terms and a radical expression makes this equation intriguing yet challenging to decipher. It represents a conic section known as an ellipse, a closed curve that resembles a flattened circle.

Breaking down the equation

Before we delve into the complexities of solving this equation, let’s break it down to its fundamental components. The equation consists of three main terms:

  1. x2: This term represents the square of the variable x.
  2. (y – 3√2x)2: This term comprises the variable y and a radical expression involving 3 times the square root of 2x, all squared.
  3. 1: This is a constant term on the right-hand side of the equation.

Solving for x and y

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Now, lets solve the equation below in step by step range.

Step-by-step approach

Solving the equation x2 + (y – 3√2x)2 = 1 may seem daunting at first, but a systematic approach can make it more manageable. Let’s follow these steps to find the solutions for x and y.

Solving for x

To solve for x, we need to isolate x2 on one side of the equation. Here’s how we can do it:

Step 1: Move (y – 3√2x)2 to the other side by subtracting it from both sides of the equation:

x2 = 1 – (y – 3√2x)2

Step 2: Eliminate the square term on the right-hand side by taking the square root of both sides:

√x2 = √(1 – (y – 3√2x)2)

Step 3: Since √x2 is just |x| (the absolute value of x), we get:

|x| = √(1 – (y – 3√2x)2)

Step 4: Square both sides again to remove the square root:

x2 = 1 – (y – 3√2x)2

Step 5: Expand the expression on the right-hand side:

x2 = 1 – (y2 – 6√2xy + 9×2)

Step 6: Rearrange the terms and simplify:

10×2 – 6√2xy + y2 – 1 = 0

Solving for y

To solve for y, we follow a similar process as solving for x, but this time we isolate (y – 3√2x)2 and then solve for y.


Graphical Representation

Lets understand equation x2 + (y – 3√2x)2 = 1 graphically below.

Plotting the equation

Graphing the equation x2 + (y – 3√2x)2 = 1 allows us to visualize its shape and properties. When plotted on a coordinate plane, the equation represents an ellipse with specific characteristics.

Analyzing the graph

The graph of x2 + (y – 3√2x)2 = 1 reveals essential information about the equation. The center of the ellipse is at the point (0, 0), and its major and minor axes can be determined from the coefficients of x2 and y2. The graph also exhibits symmetry along the x and y-axes due to the squared terms.


Applications of the Equation

Real-life scenarios

The equation x2 + (y – 3√2x)2 = 1 finds applications in various real-life scenarios. One such example is in astronomy, where it can be used to model the orbits of celestial bodies under specific gravitational influences.

Scientific applications

In physics and engineering, this equation can describe certain physical phenomena involving curved trajectories or shapes.


Advantages and Limitations

Benefits of using the equation

The equation x2 + (y – 3√2x)2 = 1 has the advantage of representing an ellipse, a fundamental geometric shape with wide-ranging applications.

Restrictions and constraints

However, this equation also comes with limitations, as it can only describe specific types of curves, and not all possible shapes.


Mathematical Concepts

Quadratic equations

The equation x2 + (y – 3√2x)2 = 1 falls under the category of quadratic equations, where the highest power of the variable is two.

Radical expressions

The presence of the radical expression 3√2x adds complexity to the equation, requiring a more specialized approach to solve it.


Related Equations

Mathematics is rich with various equations that share similarities with x2 + (y – 3√2x)2 = 1. Exploring these related equations can provide further insights into the broader context of mathematical principles.


Historical Significance

Origins of the equation

The origins of x2 + (y – 3√2x)2 = 1 can be traced back to historical mathematical developments and the contributions of notable mathematicians.

Influential mathematicians

The equation’s exploration and significance have been shaped by the work of mathematicians throughout history, whose contributions have paved the way for modern mathematical concepts.

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Importance in Modern Mathematics

The equation x2 + (y – 3√2x)2 = 1 holds a special place in modern mathematics, as it represents a beautiful and intriguing conic section with practical applications.


Conclusion

In summary, the equation x2 + (y – 3√2x)2 = 1 presents an intriguing blend of quadratic and radical components, resulting in the formation of an ellipse. Through its solutions, graphical depiction, and practical applications, this equation underscores its importance not only within the realm of mathematics but also in broader real-world contexts.

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