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Basics of Analytical Geometry

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Parabola - Section inclined to the base of the cone and intersecting the base of ... Parabola: y2 = 4ax or x2 = 4ay. Ellipse: x2/a2 y2/b2 =1, a is major axis ... – PowerPoint PPT presentation

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Title: Basics of Analytical Geometry


1
Basics of Analytical Geometry
  • By
  • Kishore Kulkarni

2
Outline
  • 2D Geometry
  • Straight Lines, Pair of Straight Lines
  • Conic Sections
  • Circles, Ellipse, Parabola, Hyperbola
  • 3D Geometry
  • Straight Lines, Planes, Sphere, Cylinders
  • Vectors
  • 2D 3D Position Vectors
  • Dot Product, Cross Product Box Product
  • Analogy between Scalar and vector representations

3
2D Geometry
  • Straight Line
  • ax by c 0
  • y mx c, m is slope and c is the y-intercept.
  • Pair of Straight Lines
  • ax2 by2 2hxy 2gx 2fy c 0
  • where abc 2fgh af2 bg2 ch2 0

4
Conic Sections
  • Circle, Parabola, Ellipse, Hyperbola
  • Circle Section Parallel to the base of the cone
  • Parabola - Section inclined to the base of the
    cone and intersecting the base of the cone
  • Ellipse - Section inclined to the base of the
    cone and not intersecting the base of the cone
  • Hyperbola Section Perpendicular to the base of
    the cone

5
Conic Sections
  • Circle x2 y2 r2 , r gt radius of circle
  • Parabola y2 4ax or x2 4ay
  • Ellipse x2/a2 y2/b2 1, a is major axis b
    is minor axis
  • Hyperbola x2/a2 - y2/b2 1.
  • In all the above equation, center is the origin.
  • Replacing x by x-h and y by y-k, we get equations
  • with center (h,k)

6
Conic Sections
  • In general, any conic section is given by
  • ax2 by2 2hxy 2gx 2fy c 0
  • where abc 2fgh af2 bg2 ch2 ! 0
  • Special cases
  • h2 ab, it is a parabola
  • h2 lt ab, it is an ellipse
  • h2 gt ab, it is a hyperbola
  • h2 lt ab and ab, it is a circle

7
3D Geometry
  • Plane - ax by cz d 0
  • Sphere - x2 y2 z2 r2
  • (x-h)2 (y-k)2 (z-l)2 r2 , if center is (h,
    k, l)
  • Cylinder - x2 y2 r2, r is radius of the base.
  • (x-h)2 (y-k)2 r2 , if center is (h, k, l)

8
3D Geometry
  • Question
  • What region does this inequality represent in a
    3D space ?

9 lt x2 y2 z2 lt 25
9
3D Geometry
  • Straight Lines
  • Parametric equations of line passing through (x0,
    y0, z0)
  • x x0 at, y y0 bt, z z0 ct
  • Symmetric form of line passing through (x0, y0,
    z0)
  • (x - x0)/a (y - y0)/b (z - z0)/c
  • where a, b, c are the direction numbers of the
    line.

10
Vectors
  • Any point in P in a 2D plane or 3D space can be
    represented by a position vector OP, where O is
    the origin.
  • Hence P(a,b) in 2D corresponds to position vector
    lt a, bgt and Q(a, b, c) in 3D space corresponds to
    position vector lt a, b, cgt
  • Let P ltx1, y1, z1gt and Q lt x2, y2, z2 gt then
    vector PQ OQ OP lt x2 x1, y2 y1, z2
    z1gt
  • Length of a vector v lt v1, v2, v3gt is given by
  • v sqrt(v12 v22 v32)

11
Dot (Scalar) Product of vectors
  • Dot product of two vectors a a1i a2j a3k
  • and b b1i b2j b3k is defined as
  • a.b a1b1 a2b2 a3b3.
  • Dot Product of two vectors is a scalar.
  • If ? is the angle between a and b, we can write
  • a.b abcos?
  • Hence a.b 0 implies two vectors are orthogonal.
  • Further a.b gt 0 we can say that they are in the
    same general direction and a.b lt 0 they are in
    the opposite general direction.
  • Projection of vector b on a a.b / a
  • Vector Projection of vector b on a (a.b / a)
    ( a / a)

12
Direction Angles and Direction Cosines
  • Direction Angles a, ß, ? of a vector a a1i
    a2j a3k are the angles made by a with the
    positive directions of x, y, z axes respectively.
  • Direction cosines are the cosines of these
    angles. We have
  • cos a a1/ a, cos ß a2/ a, cos ? a3/
    a.
  • Hence cos2 a cos2 ß cos2 ? 1.
  • Vector a a ltcos a, cos ß, cos ?gt

13
Cross (Vector) Product of vectors
  • Cross product of two vectors a a1i a2j a3k
  • and b b1i b2j b3k is defined as
  • a x b (a2b3 a3b2)i (a3b1 a1b3)j (a1b2
    a2b1)k.
  • a x b is a vector.
  • a x b is perpendicular to both a and b.
  • a x b a b sin? represents area of
    parallelogram.

14
Cross (Vector) Product
  • Question
  • What can you say about the cross product of
    two vectors in 2D ?

15
Box Product of vectors
  • Box Product of vectors a, b and c is defined as
  • V a.(b x c)
  • Box Product is also called Scalar Tripple Product
  • Box product gives the volume of a parallelepiped.

16
Vector Equations
  • Equation of a line L with a point P(x0, y0, z0)
    is given by
  • r r0 tv
  • where r0 lt x0, y0, z0gt, r lt x, y, zgt, v
    lta, b, cgt is a vector parallel to L, t is a
    scalar.
  • Equation of a plane is given by
  • n.(r - r0) 0
  • where n is a normal vector, which is analogous
    to the scalar equation
  • a (x- x0) b (y- y0) c (z- z0) 0

17
Vector Equations
  • Let a and b be position vectors of points
  • A(x1, y1,z1) and B(x2, y2,z2). Then position
    vector of the point P dividing the vector AB in
    the ratio mn is given by
  • p (mb na) / (mn)
  • which corresponds to
  • P ((mx2 nx1)/(mn), (my2 ny1)/(mn), (mz2
    nz1)/(mn))
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