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Vectors in the Plane

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Title: Vectors in the Plane


1
Vectors in the Plane
  • 8.4

2
Scalar
  • A single real number that indicates magnitude or
    size of a given quantity. Temperature, distance
    height, area, volume can be represented by
    scalars.

3
Directed Line Segments
  • Used to represent a magnitude and a direction or
    quantities such as force, velocity, and
    acceleration.

4
Directed Line Segments
  • Named just like a ray in geometry. The initial
    point (P) is listed first, then the terminal
    point (Q). PQ

5
Magnitude or Length of Directed Line Segments
  • PQ is the symbol for the magnitude. The
    distance formula will be used to find this value.
  • D v(x2-x1)2 (y2-y1)2

6
Equivalent Directed Line Segments
  • Two directed line segments with the same length
    and direction.

7
Vectors
  • The set of all directed line segments equivalent
    to the directed line segment PQ is the vector v
    PQ.

8
Equal Vectors
  • Two vectors are equal if their corresponding
    directed line segments are equivalent.

9
Example
  • Showing that vectors are equal
  • Show that the magnitude of each is equal.
  • Show that the slopes of the vectors are equal.
  • Note the vectors are not in the same spot, yet
    they will be equivalent.

10
Proving Vectors Equal
  • R (7,-3), S (4,-5), O (0,0), and P
    (-3,-2). Prove that u v where u is the vector
    represented by the directed line segment RS and v
    is the vector represented by the directed line
    segment OP.

11
Component Form of a Vector
  • If v is a vector in the plane equal to the vector
    with initial point (x1,y1) and terminal point
    (x2,y2), then the component form of v is
  • vlt(x2x1), (y2y1)gtltv1,v2gt

12
Vector Operations
  • Vector Addition
  • uvltu1,u2gtltv1,v2gt
  • ltu1v1,u2v2gt
  • Scalar Multiplication
  • ku kltu1,u2gt ltku1,ku2gt

13
Parallelogram Law for Vector Addition
  • u v can be obtained geometrically by joining
    the terminal point of the first vector to the
    initial point of the second vector. The directed
    line segment that joins the initial point of the
    first and the terminal point of the second is
    called the sum.

14
Parallelogram Law for Vector Addition
v
u
u v
15
Magnitude or Length of a Vector
  • Let vlt(x2x1), (y2y1)gtltv1,v2gt The distance
    formula will be used to find this value if given
    P and Q where vPQ.
  • v v(x2-x1)2 (y2-y1)2
  • v(v1)2 (v2)2

16
Unit Vector
  • A vector with length one that is in the direction
    of the original vector. To find the unit vector,
    take the vector and divide each of its components
    by its magnitude.
  • u v/v

17
Write the Linear Combination of the standard unit
vectors i and j
  • Given a vector v
  • V (v cos ?)i (vsin ? )j
  • The unit vector in the direction of v is
  • U v/v (cos ?)i (sin ? )j

18
Direction Angles
  • The angle used to specify the direction of the
    vector.
  • The angle is the one that the vector makes with
    the positive x-axis.
  • Using sohcahtoa, we can determine that
  • vcos ? gives the horizontal component and
    v sin ? gives the vertical component.

19
Applications
  • Velocity is a vector because it has a magnitude
    and direction. The magnitude is called the
    speed.
  • BearingAn angle measured from straight north in
    the clockwise direction.
  • The new velocity or force vector will be the sum
    of the two given.

20
Applications
  • The actual direction of the force or the velocity
    can be found by taking the arctan(y/x). You may
    have to add 180 to this result depending on the
    quadrant that your resultant vector is in.
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