1. 6.3 Vectors in the Plane
Ref. p. 424

2. 6.3 Vectors in the Plane
Many quantities in geometry and physics, such as area, time,
and temperature, can be represented by a single real number.
Other quantities, such as force and velocity, involve both
magnitude and direction and cannot be completely
characterized by a single real number.
To represent such a quantity, we use a directed line segment.
The directed line segment PQ has initial point P and terminal
point Q and we denote its magnitude (length) by Q
Terminal Point P PQ
Initial Point

3. Vector Representation by Directed Line Segments
Let u be represented by the directed line segment from
P = (0,0) to Q = (3,2), and let v be represented by the directed
line segment from R = (1,2) to S = (4,4). Show that u = v.
Using the distance formula, show
that u and v have the same length.
Show that their slopes are equal. S 4 v 3 R Q 2 u 1
Slopes of u and v are both P

4. Component Form of a Vector
The component form of the vector with initial point P = (p1, p2)
and terminal point Q = (q1, q2) is PQ
The magnitude (or length) of v is given by

5. Find the component form and length of the vector v that has
initial point (4,-7) and terminal point (-1,5) 6
Let P = (4, -7) = (p1, p2) and
Q = (-1, 5) = (q1, q2). 4
Then, the components of v =
are given by 2
v1 = q1 – p1 =
-1 – 4 = -5 -2 -2
v2 = q2 – p2 =
5 – (-7) = 12 -4
Thus, v = -6
and the length of v is -8

6. Vector Operations
The two basic operations are scalar multiplication and vector
addition. Geometrically, the product of a vector v and a scalar
k is the vector that is times as long as v. If k is positive,
then kv has the same direction as v, and if k is negative, then
kv has the opposite direction of v. v
½ v 2v -v

7. Definition of Vector Addition & Scalar Multiplication
Let u = and v = be vectors and let k be a
scalar (real number). Then the sum of u and v is
u + v =
and scalar multiplication of k times u is the vector

8. Vector Operations
Ex. Let v = and w = Find the following vectors.
a. 2v b. w – v 10 4 8 2v 6 3 w 4 2 -v v 2 1 -4 -2 2 -2 5 -1
w - v

9. Writing a Linear Combination of Unit Vectors
Let u be the vector with initial point (2, -5) and terminal point
(-1, 3). Write u as a linear combination of the standard unit
vectors of i and j. 6
Solution 10 4
(-1, 3) 8 2 6 -2 u 8j -2 4 -4 2
(2, -5)
-3i
Graphically,
it looks like… -6 -4 -2 2 -8 -2

10. Writing a Linear Combination of Unit Vectors
Let u be the vector with initial point (2, -5) and terminal point
(-1, 3).Write u as a linear combination of the standard unit
vectors i and j.
Begin by writing the component form of the vector u.

11. Unit Vectors
u = unit vector
Find a unit vector in the direction of v =

12. Vector Operations
Let u = -3i + 8j and let v = 2i - j. Find 2u - 3v.
2u - 3v = 2(-3i + 8j) - 3(2i - j)
= -6i + 16j - 6i + 3j
= -12i + 19 j

13. 6.3 Homework
Page 433 Every other odd 3 – 59 and 67, 71, 73 & 79
3, 7, 11, 15, 19, 23, 27, 31, 35, 39, 43, 47, 51, 55, 59, 67, 71, 79.