Geometric Applications of Dot/Cross Products

Geometric Applications of Dot/Cross Products

algebraic vectors algebraic vectors Projections MCV4U: Calculus & Vectors In the real world, a projection occurs when an object casts its shadow or image onto another object. Mathematically, a projection of one vector onto another object (such as a vector, a line, or a plane) involves dropping Applications of the Dot and Cross Products a perpendicular line from the head of the vector to the object. Part 1: Geometric Applications J. Garvin The magnitude of the projection (or scalar projection) of ~u onto ~v is proj~v~u = ~u cos θ (sometimes denoted ~u ~v ). J. Garvin— Applications| of the Dot| and Cross| | Products | ↓ | Slide 1/16 Slide 2/16 algebraic vectors algebraic vectors Projections Projections By expressing a projection using the dot product, we can use The scalar projection can be positive or negative, depending algebraic vectors in our calculations. on the value of θ. ~v If 0◦ < θ < 90◦, then proj ~u > 0. proj ~u = ~u cos θ | | • ~v | ~v | | | × ~v If 90 < θ < 180 , then proj ~u < 0. | | • ◦ ◦ ~v ~u ~v cos θ If θ = 90 , then proj ~u = 0. = | || | • ◦ ~v ~v | | ~u ~v = · ~v | | Scalar Projection of ~u Onto ~v ~u ~v The scalar projection of ~u onto ~v is proj ~u = · . | ~v | ~v | | J. Garvin— Applications of the Dot and Cross Products J. Garvin— Applications of the Dot and Cross Products Slide 3/16 Slide 4/16 algebraic vectors algebraic vectors Projections Projections The vector projection of ~u onto ~v is a vector with the same Example direction as ~v and a magnitude equal to the scalar projection. Calculate the scalar and vector projections of ~a = (3, 0, 5) Thus, multiplying the scalar projection with a unit vector in onto ~b = (7, 1, 2). − the direction of ~v produces the vector projection. ~u ~v 1 proj ~u = · ~v ~v ~v × ~v ~a ~b | | | | proj~~a = · ~u ~v | b | ~b = · ~v | | ~v 2 3(7) + 0( 1) + 5(2) | | = − 72 + ( 1)2 + 22 − = 31 or 31√54 Vector Projection of ~u Onto ~v √p54 54 ~u ~v The vector projection of ~u onto ~v is proj ~u = · ~v. ~v ~v 2 | | J. Garvin— Applications of the Dot and Cross Products J. Garvin— Applications of the Dot and Cross Products Slide 5/16 Slide 6/16 algebraic vectors algebraic vectors Projections Area of a Parallelogram Recall that the magnitude of the cross product is given by ~u ~v = ~u ~v sin θ. ~ | × | | || | ~a b~ proj~~a = · b Consider the following diagram of a parallelogram. b ~b 2 | | ~b = proj~~a | b | × ~b | | 31(7, 1, 2) = − 54 = 217 , 31 , 31 54 − 54 27 Since the area of a parallelogram is given by A = bh, the area of the parallelogram is the magnitude of the cross product. J. Garvin— Applications of the Dot and Cross Products J. Garvin— Applications of the Dot and Cross Products Slide 7/16 Slide 8/16 algebraic vectors algebraic vectors Area of a Parallelogram Area of a Parallelogram Example Determine the area of a parallelogram with one vertex at the ~u ~v = ( 5, 5, 10) origin and two others at (3, 5, 1) and (2, 0, 1). | × | | − − | − = ( 5)2 + 52 + ( 10)2 − − = 5q√6 units2 ~u ~v = (5( 1) 1(0), 1(2) 3( 1), 3(0) 5(2)) × − − − − − = ( 5, 5, 10) − − J. Garvin— Applications of the Dot and Cross Products J. Garvin— Applications of the Dot and Cross Products Slide 9/16 Slide 10/16 algebraic vectors algebraic vectors Triple Scalar Product Triple Scalar Product A calculation involving both the dot and cross products is the Example triple scalar product. Determine the TSP of ~p = (1, 2, 0), ~q = (4, 0, 3) and − ~r = (3, 1, 2). Triple Scalar Product − − For vectors ~u, ~v and w~ , the triple scalar product (TSP) is ~u ~v w~ . · × ~p ~q ~r = (1, 2, 0) (4, 0, 3) (3, 1, 2) As its name suggests, the TSP produces a scalar value. · × · − × − − = (1, 2, 0) ( 3, 1, 4) Since the dot and cross products both operate on vectors, · − − − = 5 the cross product must be performed first. − Note that the TSP can be positive or negative. J. Garvin— Applications of the Dot and Cross Products J. Garvin— Applications of the Dot and Cross Products Slide 11/16 Slide 12/16 algebraic vectors algebraic vectors Volume of a Parallelepiped Volume of a Parallelepiped A parallelepiped is a six-faced, three-dimensional solid where Like all prisms, the volume of a parallelepiped can be opposite faces are parallel.Let ~b and ~c form the base of a calculated as the product of the area of its base and its parallelepiped, and ~a a non-coplanar edge, as shown. height. Since the base is a parallelogram, the area of its base is ~b ~c . | × | The height of the parallelepiped is the magnitude of ~a projected onto the vector produced by ~b ~c. × The volume, v, of the parallelepiped is ~a ~b ~c V = ~b ~c | · × | | × | ~b ~c | × | = ~a ~b ~c | · × | The volume of a parallelepiped is the magnitude of the TSP. J. Garvin— Applications of the Dot and Cross Products J. Garvin— Applications of the Dot and Cross Products Slide 13/16 Slide 14/16 algebraic vectors algebraic vectors Volume of a Parallelepiped Questions? Example Determine the volume of the parallelepiped defined by ~u = (1, 0, 3), ~v = (4, 1, 0) and w~ = (2, 1, 1). − ~u ~v w~ = (1, 0, 3) (4, 1, 0) (2, 1, 1) | · × | | · × − | = (1, 0, 3) (1, 4, 6) | · − − | = 17 units3 J. Garvin— Applications of the Dot and Cross Products J. Garvin— Applications of the Dot and Cross Products Slide 15/16 Slide 16/16.

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