Math 155, Lecture Notes- Bonds

Similar documents
Multivariable Calculus

Conic Sections and Analytic Geometry

Unit 12 Topics in Analytic Geometry - Classwork

Conic Sections. College Algebra

CHAPTER 8 QUADRATIC RELATIONS AND CONIC SECTIONS

Ex. 1-3: Put each circle below in the correct equation form as listed!! above, then determine the center and radius of each circle.

9.3 Hyperbolas and Rotation of Conics

Standard Equation of a Circle

Pre-Calculus Guided Notes: Chapter 10 Conics. A circle is

ALGEBRA II UNIT X: Conic Sections Unit Notes Packet

Chapter 10. Exploring Conic Sections

Pre-Calculus. 2) Find the equation of the circle having (2, 5) and (-2, -1) as endpoints of the diameter.

Algebra II. Slide 1 / 181. Slide 2 / 181. Slide 3 / 181. Conic Sections Table of Contents

Figures adapted from Mathworld.wolfram.com and vectosite.net.

Chapter 9 Topics in Analytic Geometry

The point (x, y) lies on the circle of radius r and center (h, k) iff. x h y k r

Mid-Chapter Quiz: Lessons 7-1 through 7-3

Chapter 8.1 Conic Sections/Parabolas. Honors Pre-Calculus Rogers High School

Rewrite the equation in the left column into the format in the middle column. The answers are in the third column. 1. y 4y 4x 4 0 y k 4p x h y 2 4 x 0

KEMATH1 Calculus for Chemistry and Biochemistry Students. Francis Joseph H. Campeña, De La Salle University Manila

What you will learn today

Name. Center axis. Introduction to Conic Sections

We start by looking at a double cone. Think of this as two pointy ice cream cones that are connected at the small tips:

1.) Write the equation of a circle in standard form with radius 3 and center (-3,4). Then graph the circle.

13.1 2/20/2018. Conic Sections. Conic Sections: Parabolas and Circles

Substituting a 2 b 2 for c 2 and using a little algebra, we can then derive the standard equation for an ellipse centred at the origin,

Conic Sections: Parabolas

Algebra II. Midpoint and Distance Formula. Slide 1 / 181 Slide 2 / 181. Slide 3 / 181. Slide 4 / 181. Slide 6 / 181. Slide 5 / 181.

, minor axis of length 12. , asymptotes y 2x. 16y

Summary of Formulas: see

Module 3: Stand Up Conics

Unit 8, Ongoing Activity, Little Black Book of Algebra II Properties

Conics. By: Maya, Dietrich, and Jesse

Name: Class: Date: Conics Multiple Choice Pre-Test. Multiple Choice Identify the choice that best completes the statement or answers the question.

MATH 110 analytic geometry Conics. The Parabola

DISCOVERING CONICS WITH. Dr Toh Pee Choon NIE 2 June 2016

Chapter. Implicit Function Graphs

2.) Write the standard form of the equation of a circle whose endpoints of diameter are (4, 7) and (2,3).

Name: Date: 1. Match the equation with its graph. Page 1

10.2: Parabolas. Chapter 10: Conic Sections. Conic sections are plane figures formed by the intersection of a double-napped cone and a plane.

Practice Test - Chapter 7

HYPERBOLA. Going off on a TANGENT!

Chapter 11. Parametric Equations And Polar Coordinates

Chapter 3: The Parabola

P.5 Rational Expressions

Unit 5: Quadratic Functions

Chapter 5: The Hyperbola

8.5 Graph and Write Equations of Hyperbolas p.518 What are the parts of a hyperbola? What are the standard form equations of a hyperbola?

8.3 Technology: Loci and Conics

We start by looking at a double cone. Think of this as two pointy ice cream cones that are connected at the small tips:

Study Guide and Review

Assignment 3/17/15. Section 10.2(p 568) 2 12 (E) (E)

Algebra II Chapter 10 Conics Notes Packet. Student Name Teacher Name

Accelerated Pre-Calculus Unit 1 Task 1: Our Only Focus: Circles & Parabolas Review

Put your initials on the top of every page, in case the pages become separated.

Algebra II Lesson 10-5: Hyperbolas Mrs. Snow, Instructor

CK 12 Algebra II with Trigonometry Concepts 1

Acc. Pre Calculus Day 5 - Parabolas Notesheet PARABOLAS

Conic Sections Parabola Objective: Define conic section, parabola, draw a parabola, standard equations and their graphs

Planes Intersecting Cones: Static Hypertext Version

PreCalculus Chapter 9 Practice Test Name:

Buds Public School, Dubai

Assignment Assignment for Lesson 11.1

Assignment Name MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Chapter 10: Parametric And Polar Curves; Conic Sections

Conic Sections. MATH 211, Calculus II. J. Robert Buchanan. Spring Department of Mathematics

Each point P in the xy-plane corresponds to an ordered pair (x, y) of real numbers called the coordinates of P.

Section 12.2: Quadric Surfaces

Geometry: Conic Sections

12.6 Cylinders and Quadric Surfaces

4 = 1 which is an ellipse of major axis 2 and minor axis 2. Try the plane z = y2

Warm-Up Exercises. Find the x-intercept and y-intercept 1. 3x 5y = 15 ANSWER 5; y = 2x + 7 ANSWER ; 7

Log1 Contest Round 2 Theta Circles, Parabolas and Polygons. 4 points each

Chapter 10 Test Review

ATHS FC Math Department Al Ain Remedial Plan

Common Core Cluster. Experiment with transformations in the plane. Unpacking What does this standard mean that a student will know and be able to do?

Assignment Assignment for Lesson 14.1

Paper Folding and Conic Sections

8.2 Graph and Write Equations of Parabolas

7. r = r = r = r = r = 2 5

Math 142 Fall 2000 Rotation of Axes. In section 11.4, we found that every equation of the form. (1) Ax 2 + Cy 2 + Dx + Ey + F =0,

Flash Light Reflectors. Fountains and Projectiles. Algebraically, parabolas are usually defined in two different forms: Standard Form and Vertex Form

Practice Test - Chapter 9

Find the midpoint of the line segment with endpoints at the given coordinates. 1. (8, 3), ( 4, 9) SOLUTION: Substitute 8, 4, 3 and 9 for x 1

Mathematics High School Geometry An understanding of the attributes and relationships of geometric objects can be applied in diverse contexts

Math 370 Exam 5 Review Name

SHORT ANSWER. Write the word or phrase that best completes each statement or answers the question.

Graph and Write Equations of Hyperbolas

K-12 Geometry Standards

Cylinders and Quadric Surfaces A cylinder is a three dimensional shape that is determined by

Montclair Public Schools Math Curriculum Unit Planning Template Unit # SLO # MC 2 MC 3

Chapter 15: Functions of Several Variables

PARABOLA SYNOPSIS 1.S is the focus and the line l is the directrix. If a variable point P is such that SP

MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

A function: A mathematical relationship between two variables (x and y), where every input value (usually x) has one output value (usually y)

Final Exam Review Algebra Semester 1

Analytic Geometry. Affine space. 3D y. Dimensions

Honors Precalculus: Solving equations and inequalities graphically and algebraically. Page 1

Appendix. Correlation to the High School Geometry Standards of the Common Core State Standards for Mathematics

A new CAS-touch with touching problems

Transcription:

Math 155, Lecture Notes- Bonds Name Section 10.1 Conics and Calculus In this section, we will study conic sections from a few different perspectives. We will consider the geometry-based idea that conics come from intersecting a plane with a double-napped cone, the algebra-based idea that conics come from the general second-degree equation in two variables, and a third approached based on the concept of a locus (collection) of points that satisfy a certain geometric property Three Standard Conics (a circle is a special ellipse) and Three Degenerate Forms General Second-degree Equation in Two Variables Ax 2 +Bxy +Cy 2 + Dx +Ey + F = 0 ellipse: Ax 2 + Cy 2 + Dx + Ey + F = 0, A = C and AC > 0 circle: Ax 2 +Cy 2 +Dx+Ey+F =0, A=C Hyperbola: Ax 2 Cy 2 + Dx + Ey + F = 0, or Ax 2 + Cy 2 + Dx + Ey + F = 0, where A and C are positive Parabola: Ax 2 +Dx+Ey+F =0, or Cy 2 +Dx+Ey+F =0

Parabolas-locus of points A parabola is the set of all points ( x, y) that are equidistant from a fixed line called a directrix and a fixed point called a focus, not on the line. The midpoint between the focus and the directrix is the vertex, and the line passing through the focus and the vertex is called the axis of the parabola. The parabola is symmetric with repsect to its axis. A line segment that passes through the focus of a parabola and has endpoints on the parabola is called a focal chord.the specific focal chord perpendicular to the axis of the parabola is the latus rectum.

How to sketch the graph of a parabola centered at (h, k), given a standard form equation. 1. Determine which of the standard forms applies to the given equation: (y k) 2 = 4p (x h) or (x h) 2 =4p(y k). 2. Use the standard form identified in Step 1 to determine the vertex, axis of symmetry, focus, equation of the directrix, and endpoints of the latus rectum. 1. If the equation is in the form (y k) 2 = 4p (x h), then: -use the given equation to identify h and k for the vertex, (h, k) -use the value of k to determine the axis of symmetry, y = k -set 4p equal to the coefficient of (x h) in the given equation to solve for p. If p > 0, the parabola opens right. If p < 0, the parabola opens left. -use h, k, and p to find the coordinates of the focus, (h + p, k) -use h and p to find the equation of the directrix, x = h p -use h, k, and p to find the endpoints of the latus rectum, (h + p, k ± 2p) 2. If the equation is in the form (x h) 2 = 4p (y k), then: -use the given equation to identify h and k for the vertex, (h, k) -use the value of h to determine the axis of symmetry, x = h -set 4p equal to the coefficient of (y k) in the given equation to solve for p. If p > 0, the parabola opens up. If p < 0, the parabola opens down. -use h, k, and p to find the coordinates of the focus, (h, k + p) -use k and p to find the equation of the directrix, y = k p -use h, k, and p to find the endpoints of the latus rectum, (h ± 2p, k + p) 3. Plot the vertex, axis of symmetry, focus, directrix, and latus rectum, and draw a smooth curve to form the parabola.

Ex. 1: Find the vertex, focus, and directrix of the parabola and sketch its graph. y 2 + 4y+ 8x 12 = 0

Ex. 2: Find the equation of the parabola with vertex at ( 1,2), and focus at ( 1,0). Ex. 3: Find an equation of the tangent line to the parabola y = ax 2 at x = x 0. x Prove that the x-intercept of this tangent line is 0 2,0.

Ex. 4: A solar collector for heating water is constructed with a sheet of steel that is formed into the shape of a parabola. The water will flow through a pipe that is located at the focus of the parabola. The parabolic collector is 6 meters wide and 12 meters long, with edges that have been shaped to a length of 1 meter. At what distance from the vertex is the pipe? The pipe is in the focus position because of the Reflective Property of a Parabola. The sun s rays are parallel to the axis of symmetry and at every point they are reflected and collected at the focus, heating the water.

Ellipse-locus of points A ellipse is the set of all points ( x, y) the sum of whose distances from two distinct fixed points called foci is constant. The line passing through the foci intersects the ellipse at two points called the vertices. The chord joining the vertices is the major axis, and its midpoint is the center of the elllipse. The chord perpendicular to the major axis at the center is the minor axis of the ellipse.

How to sketch the graph of an ellipse centered at (h, k), given a standard form equation. Use the standard forms of the equations of an ellipse to determine the center, position of the major axis, vertices, co-vertices, and foci. If the equation is in the form ( x h) 2 a 2 ( + y k ) 2 b 2 -the center is (h, k) -the major axis is parallel to the x-axis -the coordinates of the vertices are (h ± a, k) -the coordinates of the co-vertices are (h, k ± b) -the coordinates of the foci are (h ± c, k) If the equation is in the form ( x h) 2 b 2 ( + y k ) 2 a 2 -the center is (h, k) -the major axis is parallel to the y-axis -the coordinates of the vertices are (h, k ± a) -the coordinates of the co-vertices are (h ± b, k) -the coordinates of the foci are (h, k ± c) Solve for c using the equation b 2 + c 2 = a 2. = 1, where a > b, then = 1, where a > b, then Plot the center, vertices, co-vertices, and foci in the coordinate plane, and draw a smooth curve to form the ellipse.

Ex. 5: Write the equation of the ellipse in standard form. Find the center, vertices, foci, and sketch its graph. 16x 2 + 25y 2 64x+150y+ 279 = 0

The eccentricity of an ellipse is a number that describe the degree of roundness of the ellipse. For any ellipse, 0 e 1. The smaller the eccentricy, the rounder the ellipse. If e = 0, it is a circle and the foci are coincident. If e = 1, then the ellipse is a line segment, with foci at the two end points.

Ex. 6: Find the equation of the ellipse if the vertices are ( 0,2) and ( 4,2), and the eccentricity is e = 1 2. Sketch the graph of this ellipse.

Ex. 7: Find an equation of the tangent line to the ellipse x2 9 + y2 16 3 2 2, 4 2. Sketch the graph of the ellipse and the tangent line. 2 = 1 at the point

Hyperbola-locus of points A Hyperbola is the set of all points x, y ( ) for which the absolute value of the difference of the distances from two distinct fixed points called foci is constant. The line passing through the foci intersects a hyperbola at two points called the vertices. The segment connecting the vertices is the transverse axis, and the midpoint of the transverse axis is the center of the hyperbola. One distinguishing feature of a hyperbola is that the its graph has two serperate branches. An important aid in sketching the graph of a hyperbola is the determination of its asymptotes. Each hyperbola has two asymptotes that intersect at the center of the hyperbola. The asymptotes pass through the vertices of a rectangle of dimensions 2a by 2b, with it center at ( h,k). The line segment of length 2b joining h,k + b is refered to as the conjugate axis of the hyperbola. ( ) and ( h,k b)

(a) ( x h) 2 a 2 ( y k ) 2 = 1 (b) b 2 ( y k) 2 a 2 ( x h ) 2 = 1 b 2 How to sketch the graph of a hyperbola centered at (h, k), given a standard form equation. Convert the equation to the standard form. Determine which of the standard forms applies to the given equation. Use the standard form to determine the position of the transverse axis; coordinates for the center, vertices, co-vertices, foci; and equations for the asymptotes. Solve for c using the equation a 2 + b 2 = c 2. ( x h) 2 ( If the equation is in the form y k ) 2 a 2 b 2 -the center is (h, k) -the transverse axis is parallel to the x-axis -the coordinates of the vertices are (h ± a, k) -the coordinates of the co-vertices are (h, k ± b) -the coordinates of the foci are (h ± c, k) = 1, then ( ) + k -the equations of the asymptotes are y = ± b a x h If the equation is in the form ( y k) 2 a 2 ( x h ) 2 b 2 -the center is (h, k) -the transverse axis is parallel to the y-axis -the coordinates of the vertices are (h, k ± a) -the coordinates of the co-vertices are (h ± b, k) -the coordinates of the foci are (h, k ± c) = 1, then ( ) + k -the equations of the asymptotes are y = ± a b x h Plot the center, vertices, co-vertices, foci, and asymptotes in the coordinate plane and draw a smooth curve to form the hyperbola

Lampshade A household lamp casts hyperbolic shadows on a wall. Gear transmission Two hyperboloids of revolution can provide gear transmission between two skew axes. $The cogs of each gear are a set of generating straight lines. Sonic Boom In 1953, a pilot flew over an Air Force Base $flying faster than the speed of sound. He damaged every building on the base. As the plane moves faster than the speed of sound, you get a cone-like wave. $Where the cone intersects the ground, it is a hyperbola. The sonic boom hits every point on that curve at the same time. No sound is$ heard outside the curve. The hyperbola is known as the "Sonic Boom Curve." $

Reflecting Property of Hyperbolae A beam of light is directed at one of the foci (with the the curve "between" the source and the focus) then it will be reflected by the curve through the other focus! If F1 and F2 are the foci of a hyperbola, and P is a point on one of its branches, elementary geometry reveals that the tangent to the curve at P bisects the angle F1-P-F2. The reflecting property then follows from this fact. This property of the hyperbola has applications! It is used in radio direction finding (since the difference in signals from two towers is constant along hyperbolae), and in the construction of mirrors inside telescopes (to reflect light coming from the parabolic mirror to the eyepiece). The eccentricity of a hyperbola is a number that describes how narrow, or how wide the branches of the open. For any hyperbola with a smaller eccentricity, we can see the branches will open in a more narrow sense. If the eccentricity is larger, then the branches of the hyperbola will open in a wider sense.

Ex. 8: Write the equation of the hyperbola in standard form. Find the center, vertices, foci, and sketch its graph. Find the equations of the asymptotes and sketch the asymptotes. 3y 2 x 2 + 6x 12y = 0

Ex. 9: Find the equation of the hyperbola in standard form if a focus point is at ( 10,0) and the asymptotes are y =± 3 x. Sketch the graph of this hyperbola with 4 its asymptotes.

Ex. 10: Find an equations of the tangent lines to the hyperbola y2 4 x2 2 = 1 when x = 4. Sketch the graph of the hyperbola and the tangent lines.

2024 © technodocbox.com Privacy Policy | Terms of Service | Feedback