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Analytic Geometry

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Analytic Geometry Chapter 5 – PowerPoint PPT presentation

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Title: Analytic Geometry


1
Analytic Geometry
  • Chapter 5

2
Analytic Geometry
  • Unites geometry and algebra
  • Coordinate system enables
  • Use of algebra to answer geometry questions
  • Proof using algebraic formulas
  • Requires understanding of points on the plane

3
Points
  • Consider Activity 5.1
  • Number line
  • Positive to right, negative left (by convention)
  • 11 correspondence between reals and points on
    line
  • Some numbers constructible, some not (what?)

4
Points
  • Distance between points on number line
  • Now consider two number lines intersecting
  • Usually ? but not entirely necessary
  • Denoted by Cartesian product

5
Points
  • Note coordinate axis from Activity 5.2
  • Note non- ? axes
  • Units on each axis need not be equal

6
Distance
  • How to determine distance?
  • Use Law of Cosines
  • Then generalize for any two ordered pairs
  • What happens when ? 90? ?

7
Midpoints
  • Theorem 5.1The midpoint of the segment between
    two points P(xP, yP) and Q(xQ, yQ) is the point
  • Prove
  • For non ? axes
  • For ? axes

8
Lines
  • A one dimensional object which has both
  • Location
  • Direction
  • Algebraic description must give both
  • Matching
  • Slope-intercept
  • General form
  • Intercept form
  • Point-slope

9
Slope
  • Theorem 5.2For a non vertical line the slope is
    well defined. No matter which two points are
    used for the calculation, the value is the same

10
Slope
  • What about a vertical line?
  • The ?x value is zero
  • The slope is undefined
  • Should not say slope is infinite
  • Positive? Negative?
  • Actually infinity is not a number

11
Linear Equation
  • Theorem 5.3A line can be described by a linear
    equation, and a linear equation describes a
    line.
  • Author suggestsgeneral form is most versatile
  • Consider the vertical line

12
Alternative Direction Description
  • Consider Activity 5.4
  • Specify direction with angle of inclination
  • Note relationship between slope and tan ?
  • Consider what happens with vertical line

13
Parallel Lines
  • Theorem 5.4Two lines are parallel iff the two
    lines have equal slopes
  • ProofUse x-axis as a transversal
    corresponding angles

14
Perpendicular Lines
  • Theorem 5.5Two lines (neither vertical) with
    slopes m1 and m2 are perpendicular iff m1 ? m2
    -1
  • Equivalent to saying(the slopes arenegative
    reciprocals)

15
Perpendicular Lines
  • Proof
  • Use coordinatesand resultsof PythagoreanTheorem
    for?ABC
  • Also representslopes of AC and CB using
    coordinates

16
Distance
  • Circle
  • Locus of points, same distance from fixed center
  • Can be described by center and radius

17
Distance
  • For given circle with
  • Center at (2, 3)
  • Radius 5
  • Determine equationy ?

18
Distance
  • Consider the distance between a point and a line
  • What problems exist?
  • Consider thecircle centeredat C, tangentto the
    line

19
Distance
  • Constructing the circle
  • Centered at C
  • Tangent to the line

20
Using Analysis to Find Distance
  • Given algebraic descriptions of line and point
  • Determine equationof line PQ
  • Then determineintersection oftwo lines
  • Now use distanceformula

21
Using Coordinates in Proofs
  • Consider Activity 5.7
  • The lengths ofthe three segmentsare equal
  • Use equations,coordinates to prove

22
Using Coordinates in Proofs
  • Set one corner at (0,0)
  • Establish arbitrarydistances, c and d
  • Determine midpointcoordinates

23
Using Coordinates in Proofs
  • Determine equationsof the lines AC, DE, FB
  • Solve for intersections at G and H
  • Use distanceformula to findAH, HG, and GC

24
Using Coordinates in Proofs
  • Note figure for algebraic proof that
    perpendiculars from vertices to opposite sides
    are concurrent (orthocenter)
  • Arrange one ofperpendicularsto be the y-axis
  • Locate concurrencypoint for the linesat x 0

25
Using Coordinates in Proofs
  • Recall the radical axis of two circles is a line
  • We seek points where
  • We calculate
  • Set these equal to each other, solve for y

26
Polar Coordinates
  • Uses
  • Origin point
  • Single axis (a ray)
  • Describe a point P by giving
  • Distance to the origin (length of segment OP)
  • Angle OP makes with polar axis
  • Point P is

27
Polar Coordinates
  • Try it out
  • Locate these points(3, ?/2), (2, 2?/3),
    (-5, ?/4), (5, -?/3)
  • Note
  • (x, y) ? (r, ?) is not 11
  • (r, ?) gives exactly one (x, y)
  • (x, y) can be many (r, ?) values

28
Polar Coordinates
  • Conversion formulas
  • From Cartesian to polar
  • Try (3, -2)
  • From polar to Cartesian
  • Try (2, ?/3)

29
Polar Coordinates
  • Now Use these to convert
  • Ax By C to r f(?)
  • Try 3x 5y 2
  • Convert to polar equation
  • Also r sec ? 3
  • Convert to Cartesian equation

30
Polar Coordinates
  • Recall Activity 5.11
  • Shown on the calculator
  • Graphing y sin (6?)

31
Polar Coordinates
  • Recall Activity 5.11
  • Change coefficient of ?
  • Graphing y sin (3?)

32
Polar In Geogebra
  • Consider graphing r 1 cos (3?)
  • Define f(x) 1 cos(3x)
  • Hide the curve that appears.
  • Define Curvef(t) cos(t), f(t) sin(t), t, 0, 2
    pi

33
Polar In Geogebra
  • Consider these lines
  • They will display polar axes
  • Could be made into a custom tool

34
Nine Point Circle, Reprise
  • Recall special circle which intersects special
    points
  • Identify thepoints

35
Nine Point Circle
  • Circle contains
  • The foot of each altitude

36
Nine Point Circle
  • Circle contains
  • The midpoint of each side

37
Nine Point Circle
  • Circle contains
  • The midpoints of segments from orthocenter to
    vertex

38
Nine Point Circle
  • Recall we proved it without coordinates
  • Also possible to prove by
  • Represent lines as linear equations
  • Involve coordinates and algebra
  • This is an analytic proof

39
Nine Point Circle
  • Steps required
  • Place triangle on coordinate system
  • Find equations for altitudes
  • Find coordinates of feet of altitudes,
    orthocenter
  • Find center, radius of circum circle of pedal
    triangle

40
Nine Point Circle
  • Steps required
  • Write equation for circumcircle of pedal triangle
  • Verify the feet lie on this circle
  • Verify midpoints of sides on circle
  • Verify midpoints of segments orthocenter to
    vertex lie on circle

41
Analytic Geometry
  • Chapter 5
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