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8.4 Vectors

8.4 Vectors. A vector is a quantity that has both magnitude and direction. Vectors in the plane can be represented by arrows. The length of the arrow represents the magnitude of the vector. The arrowhead indicates the direction of the vector. Q. Terminal Point. Initial Point. P.

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8.4 Vectors

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  1. 8.4Vectors

  2. A vector is a quantity that has both magnitude and direction. Vectors in the plane can be represented by arrows. The length of the arrow represents the magnitude of the vector. The arrowhead indicates the direction of the vector.

  3. Q Terminal Point Initial Point P Directed line segment

  4. The magnitude of the directed line segment PQ is the distance from point P to the point Q. The direction of PQ is from P to Q. If a vector v has the same magnitude and the same direction as the directed line segment PQ, then we write v = PQ

  5. The vector v whose magnitude is 0 is called the zero vector, 0. Two vectors v and w are equal, written if they have the same magnitude and direction.

  6. v w v = w

  7. Terminal point of w v + w w v Initial point of v

  8. Vector addition is commutative. v+w = w + v Vector addition is associative. v+ (u +w) = (v + u) + w v+0 = 0 + v =v v+(-v) = 0

  9. Multiplying Vectors by Numbers

  10. v 2v -v

  11. Properties of Scalar Products

  12. Use the vectors illustrated below to graph each expression. w v u

  13. v + w

  14. 2v -w v w 2v and -w

  15. -w 2v 2v-w

  16. An algebraic vector v is represented as v = < a, b > where a and b are real numbers (scalars) called the components of the vector v.

  17. If v = < a, b > is an algebraic vector with initial point at the origin O and terminal point P = (a, b), then v is called a position vector.

  18. y P = (a, b) v = < a, b > O x

  19. The scalars a and b are called components of the vector v = < a, b >.

  20. Theorem Suppose that v is a vector with initial point P1=(x1, y1), not necessarily the origin, and terminal point P2=(x2, y2). If v=P1P2, then v is equal to the position vector

  21. Find the position vector of the vector v=P1P2 if P1 =(-2, 1)and P2 =(3,4).

  22. P2 =(3,4). v = < 5, 3 > P1 =(-2, 1) O

  23. Theorem Equality of Vectors Two vectors v and w are equal if and only if their corresponding components are equal. That is,

  24. Let i denote a unit vector whose direction is along the positive x-axis; let j denote a unit vector whose direction is along the positive y-axis. Any vector v = < a, b >can be written using the unit vectors i and j as follows:

  25. Theorem Unit Vector in Direction of v For any nonzero vector v, the vector is a unit vector that has the same direction as v.

  26. Find a unit vector in the same direction as v = 3i - 5j.

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