Analytics Geometry of Two and Three Dimensions
Analytic Geometry is an invention of Descartes and Fermat. It is also referred to as coordinate geometry. It is a mathematical subject where algebraic symbolism and methods are used to represent and solve geometry problems.
Analytic geometry basically establishes a connection between geometric curves and algebraic equations. It is often referred to as a branch of algebra that is used to model geometric objects. It helps in the reformulation of algebraic problems in geometry and vice versa, where the methods and principles of both fields can be used to solve the problems in the other.
Analytical geometry of three dimensions forms the foundation of various modern fields of geometry that include algebraic, differential, discrete, and computational geometry. The application of Analytic geometry spreads across a wide range of fields including physics and engineering, and also in aviation, rocketry, space science, and spaceflight.
Trigonometry and analytic geometry encompass some very important subjects such as midpoints and distance, parallel and perpendicular lines on the coordinate plane, dividing line segments, distance between the line and a point, etc. This field is often deemed as the next level of mathematics, that helps in the field of learning logical thinking and improving problem-solving skills of an individual.
In this article, we will discuss the most important aspects of analytic geometry including formulas, cartesian plane, analytic geometry in three dimensions, its applications, and some solved sums for a better and more in depth understanding.
What is Analytic Geometry?
In analytic geometry, points are defined as ordered pairs of numbers, for instance, (x, y), and the straight lines are consequently defined as the sets of points that satisfy linear equations.
Analytic geometry defines geometric axioms as derivable theorems.
Here is an example, for any two distinct points, say (x1, y1) and (x2, y2), there is a single line ax + by + c = 0 that passes through these points. The coefficients (a, b, c) can be found (up to a constant factor) from a linear system of two equations:
ax1 + by1 + c = 0
ax2 + by2 + c = 0,
or directly from the determinant equation. It is a contradiction to symmetric geometry, where no candidates or formulas are used.
Both two dimensional and three-dimensional geometry are used in coordinate geometry. The most common terms used in analytic geometry are:
Planes
Coordinates
Planes
For a clear understanding of analytical geometry of three dimensions or two, and the importance and applications of analytic geometry, we need to be clear about the definition of a plane. A plane is a flat surface that continues infinitely in both directions. Analytic Geometry helps locate any point on this plane with the coordinates of the point in the X and Y plane.
Coordinates
Two ordered pairs which define the location of any given point in a plane can be defined as coordinates. The box below will help us get a better understanding.
In this grid, the location of letter x is B2 i.e. Column B and row 2. So, B and 2 are the coordinates of this box, x.
Analytical Geometry of three dimensions has different kinds of coordinates. The most important ones are:
Cartesian Coordinates
The Cartesian coordinate is the most well-known coordinate system in which every point has an x-coordinate and y-coordinate which represents its horizontal position, and vertical position respectively.
Polar Coordinates
A coordinate system where each point in a plane is denoted by the distance ‘r’ from the origin and the angle θ from the polar axis is known as the polar coordinates.
Cylindrical Coordinates
In cylindrical coordinates, all the points are expressed by their height, radius from z-axis, and the angle projected on the xy-plane with respect to the horizontal axis. The height, radius, and angle are denoted by h, r, and θ, respectively.
Spherical Coordinates
In this type of coordinates the point in space is denoted by its distance from the origin ( ρ), the angle projected on the xy-plane with respect to the horizontal axis (θ) and also another angle, with respect to the z-axis (φ).
Did you Know?
The origin is the point of intersection of the axis(x-axis and y-axis). Both x and y-axis are zero at this point.
x-axis – The values at the right-hand side of the x-axis are positive and ones on the left-hand side are negative.
y-axis – The values above the origin are positive and the ones below the origin are negative.
You need two numbers to locate a plane in the order of writing the location of the X-axis first and Y-axis after that. This denotes a unique position on the plane.
Analytic Geometry Formulas
To find measurements of geometric figures, formulas for analytic geometry are extremely useful. Graphs and coordinates are the vast fields of application of analytic geometry. Application of analytic geometry in the engineering field and sciences involves the study of the rate of change in varying quantities and helps to show the relationship between the quantities involved. Check out the analytic geometry formulas here.
Distance Formula
Let the two points be A and B, having coordinates to be (x1,y1) and (x2,y2) respectively.
Thus, the distance between two points is given as-
d = √[(x2-x1)2+(y2-y1)2]
Midpoint Theorem Formula
Let A and B are some points in a plane, which is joined to form a line, having coordinates (x1,y1) and (x2,y2), respectively. Suppose, M(x,y) is the midpoint of the line connecting the point A and B then its formula is given by;
M(x,y) = [(x1+x2/2),(y1+y2/2)]
Angle Formula
Let two lines have slope = m1 and m2, and θ be the angle formed between the two lines, A and B. This is represented as;
tan θ = m1-m2/1+m1m2
Solved Examples
How to find the distance between two points A and B such that the coordinates of A and B are (5, -3) and (2, 1)?
Given that, the coordinates are:
A = (5, -3) = (x1, y1)
B = (2, 1) = (x2,y2)
The formula to find the distance between two points is given as:
Distance,d = √[(x2-x1)2+(y2-y1)2]
d = √[(2-5)2+(1- (-3))2]
d =√[(-3)2+(4)2]
d =√[9+16]
d =√(25)
d = 5
Thus, the distance between two points A and B is 5.
FAQs on Analytic Geometry
1. What is analytic geometry in simple terms?
Analytic geometry, also known as coordinate geometry, is a branch of mathematics that uses a coordinate system to study geometry. It builds a bridge between algebra and geometry, allowing us to represent geometric shapes like lines, circles, and parabolas as algebraic equations. This enables solving geometric problems using algebraic methods.
2. Who is considered the father of analytic geometry and what was his key contribution?
René Descartes, a French mathematician and philosopher, is credited as the father of analytic geometry. His groundbreaking contribution in the 17th century was the development of the Cartesian coordinate system (the familiar x-y plane). This system made it possible to assign a unique pair of coordinates (x, y) to every point in a plane, fundamentally linking geometric points to algebraic pairs of numbers.
3. How does analytic geometry connect algebra and geometry?
Analytic geometry connects algebra and geometry by establishing a two-way relationship: every geometric figure can be described by an algebraic equation, and every algebraic equation can be represented as a geometric figure. For example, a straight line is represented by a linear equation like y = mx + c, and a circle is represented by an equation like x² + y² = r². This allows us to use algebraic manipulations to analyse geometric properties, such as finding the intersection point of two lines by solving their equations simultaneously.
4. What are the fundamental formulas used in 2D analytic geometry?
Several fundamental formulas are the building blocks for solving problems in 2D analytic geometry. The most essential ones include:
- Distance Formula: To calculate the distance between two points (x₁, y₁) and (x₂, y₂).
- Section Formula: To find the coordinates of a point that divides the line segment joining two points in a given ratio.
- Mid-Point Formula: A special case of the section formula to find the exact centre of a line segment.
- Slope Formula: To determine the steepness or gradient of a line.
- Area of a Triangle Formula: To calculate the area of a triangle given the coordinates of its three vertices.
5. How do you determine the points where a straight line intersects the x-axis and y-axis?
To find the intersection points, known as intercepts, you use the property of the axes themselves:
- X-intercept: This is the point where the line crosses the x-axis. At any point on the x-axis, the y-coordinate is always 0. So, you set y = 0 in the line's equation and solve for x.
- Y-intercept: This is the point where the line crosses the y-axis. At any point on the y-axis, the x-coordinate is always 0. So, you set x = 0 in the line's equation and solve for y.
6. What is the significance of the slope of a line in real-world scenarios?
The slope of a line is not just a mathematical concept; it represents a rate of change, which has numerous real-world applications. For instance:
- In Physics, the slope of a distance-time graph represents the object's speed.
- In Engineering, slope is used to define the gradient of a road or the pitch of a roof for proper drainage.
- In Economics, it can represent the rate of change in cost, revenue, or profit with respect to production or time.
7. What is a conic section, and what are the four main types?
A conic section is a curve formed by the intersection of a plane and a double-napped cone. The type of curve created depends on the angle at which the plane intersects the cone. The four main types of conic sections are:
- Circle: Formed when the plane is perpendicular to the cone's axis.
- Ellipse: Formed when the plane is tilted and cuts through one nappe of the cone.
- Parabola: Formed when the plane is parallel to the side (generator) of the cone.
- Hyperbola: Formed when the plane is steep enough to intersect both nappes of the cone.
8. How can you differentiate between a parabola, ellipse, and hyperbola from their general second-degree equation?
You can identify the type of conic section by examining its general second-degree equation, Ax² + Bxy + Cy² + Dx + Ey + F = 0, and calculating the value of its discriminant, which is B² - 4AC.
- If B² - 4AC < 0, the conic is an ellipse (or a circle if A=C and B=0).
- If B² - 4AC = 0, the conic is a parabola.
- If B² - 4AC > 0, the conic is a hyperbola.
