History of Analytic Geometry PDF

Summary

This document provides a historical overview of analytic geometry, tracing its development from ancient times to modern applications. It explores key figures like Euclid and Descartes and explains fundamental concepts such as vectors, projections, and conic sections. The document also details important formulas like the distance and midpoint formulas, and demonstrates their use.

Full Transcript

HISTORY OF ANALYTIC
GEOMETRY
Analytic Geometry
Analytic geometry is the algebraic study of geometry using a
coordinate plane. Employing the concept of the Cartesian
coordinate system, it established the relationship between
geometry and algebra making way for the development of
mathematics. It provides the identity of points, lines, and curves
by defining their relationship through algebraic equations,
describing measurements and locations of geometric figures,
and providing proofs to certain existing theorems. Thus, analytic
geometry is useful in both Euclidian and non-Euclidian geometry.
The application of analytic geometry with the aid of a Cartesian
coordinate system starts with giving a unique identity to each
point on a cartesian plane. The cartesian plane consists of two
perpendicular lines called the axes; one is horizontal or the x-
axis, and the other is vertical or the y-axis. The point at which
these axes intersect at (0, 0), is called the origin. It is where the
horizontal and vertical distances of a point are referenced. The
horizontal distance from the origin is the x-coordinate while the
vertical distance from the origin is the y-coordinate, collectively
known as the coordinates of the point, represented by an
ordered pair (x, y).
The cartesian plane is divided into four quadrants. A point
located to the right and above the origin has both positive values
of x and y coordinates and can be found on the 1st Quadrant. A
point to the left and above the origin has a negative x-coordinate
and positive y-coordinate and can be found on the 2nd Quadrant.
A point to the left and below of the origin has both negative
values of x and y coordinates, and can be found on the 3rd
Quadrant. A point to the right and below the origin has a positive
x-coordinate and negative y-coordinate, and can be found on the
4th Quadrant. The x-coordinate is also called the abscissa while
the y-coordinate is called the ordinate.
Ancient Foundations (c. 250 BCE - 1st Century CE)

Euclid (c. 300 BCE): His Elements formalized many geometric
principles but lacked algebraic representation.

Apollonius of Perga (c. 262–190 BCE): Known as the "Great
Geometer," he studied conic sections (ellipse, parabola,
hyperbola) and derived properties of these curves,
foreshadowing analytic geometry
Islamic Golden Age (8th–14th Century)

Omar Khayyam (1048–1131 CE): Solved cubic equations using
geometric methods involving conic sections.

Al-Khwarizmi: Advanced algebra, laying the foundation for later
connections between algebra and geometry.
Renaissance & Early Algebra (16th Century)

François Viète (1540–1603): Introduced symbolic algebra,
using letters for variables and constants, enabling the connection
between algebra and geometry.
The Birth of Analytic Geometry (17th Century)

René Descartes (1596–1650): His work La Géométrie (1637)
introduced the Cartesian coordinate system, marking the formal
beginning of analytic geometry. He used algebra to study curves
and solved geometric problems through equations.
Pierre de Fermat (1601–1665): Independently developed similar
methods, analyzing conic sections and establishing algebraic
approaches to geometry.
John Wallis (1616–1703): Introduced negative coordinates and
expanded Descartes’ work on conic sections.
19th Century: Vector Analysis & Higher Dimensions

William Rowan Hamilton (1805–1865): Introduced quaternions,
extending coordinate geometry to four dimensions.

Julius Plücker (1801–1868): Unified analytic and projective
geometry through homogeneous coordinates.
20th Century & Modern Applications

Computer Graphics and CAD: Analytic geometry is essential in
3D modeling, video games, and engineering.

Robotics & Machine Learning: Used in motion planning, data
visualization, and high-dimensional projections.
 Key Concepts in
Analytic Geometry
1. Vectors: Quantities with magnitude and direction, analyzed in
2D or 3D coordinate systems.
2. Projections: Representation of figures on a surface, used in
applications like perspective drawings.

3. Conics: Geometric shapes derived from intersecting a plane
with a cone, including:

Circle
Ellipse
Parabola
Hyperbola
Each conic is represented by a unique algebraic equation.
 FORMULAS FOR
ANALYTIC GEOMETRY
The main formulas used in analytic geometry give appropriate
importance to the properties of geometric figures. Among these
are the distance formula, midpoint formula, and slope
formula. Other formulas in analytic geometry can be derived
with the aid of these formulas.

Distance formula – This is useful in defining the separation of
two given points. It can also be used in identifying the location of
a point given the coordinate of the other point along with the
distance between them. The distance can be solved with this
formula:
The midpoint formula is used to find the midpoint between two
points whose coordinates are known to us. The midpoint formula
is also used to find the coordinates of the endpoint if we know
the coordinates of the other endpoint and the midpoint. In the
coordinate plane, if a line is drawn to connect two points (4, 2),
and (8, 6), then the coordinates of the midpoint of the line joining
these two points are ({4 + 8}/2, {2 + 6}/2) = (12/2, 8/2) = (6, 4).
Midpoint refers to a point that is exactly in the middle of the line
segment joining two points. The two reference points are the
endpoints of a line segment, and the midpoint is lying in between
the two points. The midpoint divides the line joining these two
points into two equal halves. Further, if a line is drawn to bisect a
line segment joining these two points, the line passes through
the midpoint.
Example: Using the midpoint formula, find the midpoint between
points X(5, 3) and Y(7, 8).

Solution: Let M be the midpoint between X and Y.

M = ((5 + 7)/2, (3 + 8)/2) = (6, 11/2)

Therefore, the coordinates of the midpoint between X and Y is
(6, 11/2).
Slope Formula is used to calculate the inclination or steepness
of a line. It finds application in determining the slope of any line
by finding the ratio of the change in the y-axis to the change in
the x-axis. The slope of a line is defined as the change in the “y”
coordinate with respect to the change in the “x” coordinate of
that line.
Examples Using Slope Formula
Example 1: Find the slope of a line whose coordinates are (2,9)
and (4,1)?

Solution:
To find: The slope of the line with coordinates (2,9) and (4,1)
Given, (x1, y1) = (2, 9) and (x2, y2) = (4, 1)

The slope formula is m = (y2 – y1)/(x2 – x1)

m = (1 − 9)/(4 − 2)
m = -8/2 = -4
Example 2: Determine the value of b, if the slope of a line
passing through the points (b, 7) and (8, -5) is 6.

Solution:
To find: the value of b
Given, Slope = m = 6, Points: (x1, y1) = (b, 7) and (x2, y2) = (8, -5)
We know that Slope (m) = (y2 – y1)/(x2 – x1)
6 = (-5-7)/(8-b)
6 = (-12)/(8-b)
-2= (8-b)
-2-8 = -b,
b = 10
Answer: The value of b = 10.
THANK YOU!