Working with vectors in a plane is easier when we are working in a coordinate system. When the initial points and terminal points of vectors are given in Cartesian coordinates, computations become straightforward.

Example: Comparing Vectors

Are [latex]\bf{v}[/latex] and [latex]\bf{w}[/latex] equivalent vectors?

1. a. [latex]\bf{v}[/latex] has initial point [latex](3,2)[/latex] and terminal point [latex](7,2)[/latex]

    [latex]\bf{w}[/latex] has initial point [latex](1,−4)[/latex] and terminal point [latex](1,0)[/latex]

1. b. [latex]\bf{v}[/latex] has initial point [latex](0,0)[/latex] and terminal point [latex](1,1) [/latex]

    [latex]\bf{w}[/latex] has initial point [latex](−2,2)[/latex] and terminal point [latex](−1,3)[/latex]

Show Solution

a. The vectors are each [latex]4[/latex] units long, but they are oriented in different directions. So [latex]\bf{v}[/latex] and [latex]\bf{w}[/latex] are not equivalent (Figure 2.10).

Figure 1. These vectors are not equivalent.

b. Based on Figure 2.11, and using a bit of geometry, it is clear these vectors have the same length and the same direction, so [latex]\bf{v}[/latex] and [latex]\bf{w}[/latex] are equivalent.

Figure 2. These vectors are equivalent.

Try It

Which of the following vectors are equivalent?

Figure 3. Determine which vectors are equivalent.

Show Solution

Vectors [latex]\bf{a}[/latex], [latex]\bf{b}[/latex], and [latex]\bf{e}[/latex] are equivalent.

We have seen how to plot a vector when we are given an initial point and a terminal point. However, because a vector can be placed anywhere in a plane, it may be easier to perform calculations with a vector when its initial point coincides with the origin. We call a vector with its initial point at the origin a standard-position vector. Because the initial point of any vector in standard position is known to be [latex](0,0)[/latex], we can describe the vector by looking at the coordinates of its terminal point. Thus, if vector [latex]\bf{v}[/latex] has its initial point at the origin and its terminal point at [latex](x,y)[/latex], we write the vector in component form as

Recall that vectors are named with lowercase letters in bold type or by drawing an arrow over their name. We have also learned that we can name a vector by its component form, with the coordinates of its terminal point in angle brackets. However, when writing the component form of a vector, it is important to distinguish between [latex]\langle x,y \rangle[/latex] and [latex](x,y)[/latex]. The first ordered pair uses angle brackets to describe a vector, whereas the second uses parentheses to describe a point in a plane. The initial point of [latex]\langle x,y \rangle[/latex] is [latex](0,0)[/latex]; the terminal point of [latex]\langle x,y \rangle[/latex] is [latex](x,y)[/latex].

When we have a vector not already in standard position, we can determine its component form in one of two ways. We can use a geometric approach, in which we sketch the vector in the coordinate plane, and then sketch an equivalent standard-position vector. Alternatively, we can find it algebraically, using the coordinates of the initial point and the terminal point. To find it algebraically, we subtract the [latex]x[/latex]-coordinate of the initial point from the [latex]x[/latex]-coordinate of the terminal point to get the [latex]x[/latex] component, and we subtract the [latex]y[/latex]-coordinate of the initial point from the [latex]y[/latex]-coordinate of the terminal point to get the [latex]y[/latex] component.

Example: Expressing Vectors in Component Form

Express vector [latex]\bf{v}[/latex] with initial point [latex](−3,4)[/latex] and terminal point [latex](1,2)[/latex] in component form.

Show Solution

1. a. Geometric
   1. 1. Sketch the vector in the coordinate plane (Figure 13).
      2. The terminal point is [latex]4[/latex] units to the right and [latex]2[/latex] units down from the initial point.
      3. Find the point that is [latex]4[/latex] units to the right and [latex]2[/latex] units down from the origin.
      4. In standard position, this vector has initial point [latex](0,0)[/latex] and terminal point [latex](4,−2)[/latex]:

[latex]\bf{v}[/latex] [latex] = \langle4,−2\rangle.[/latex]

Figure 4. These vectors are equivalent.

 

1. b. Algebraic

1. In the first solution, we used a sketch of the vector to see that the terminal point lies [latex]4[/latex] units to the right. We can accomplish this algebraically by finding the difference of the [latex]x[/latex]-coordinates:

[latex]x_t - x_i = 1 - (-3) = 4[/latex]

1. Similarly, the difference of the y-coordinates shows the vertical length of the vector.

[latex]y_t - y_i = 2 - 4 = -2[/latex]

1. So, in component form,

[latex]\bf{v}[/latex] [latex]=\langle x_t − x_i,y_t − y_i\rangle[/latex] 

[latex]=\langle 1 - (-3), 2 - 4\rangle[/latex] 

[latex]=\langle 4, -2\rangle[/latex]

To find the magnitude of a vector, we calculate the distance between its initial point and its terminal point. The magnitude of vector
[latex]\bf{v}[/latex][latex]=\langle x,y\rangle[/latex] is denoted [latex]\bf{||v||}[/latex], or [latex]\bf{|v|}[/latex], and can be computed using the formula

Note that because this vector is written in component form, it is equivalent to a vector in standard position, with its initial point at the origin and terminal point [latex](x,y)[/latex]. Thus, it suffices to calculate the magnitude of the vector in standard position. Using the distance formula to calculate the distance between initial point [latex](0,0)[/latex] and terminal point [latex](x,y)[/latex], we have

Based on this formula, it is clear that for any vector [latex]\bf{v}[/latex], [latex]\bf{||v||}[/latex][latex] \geq 0[/latex], and [latex]\bf{||v||}[/latex][latex] = 0[/latex] if and only if [latex]\bf{v}[/latex][latex] = 0[/latex].

The magnitude of a vector can also be derived using the Pythagorean theorem, as in the following figure.

Figure 5. If you use the components of a vector to define a right triangle, the magnitude of the vector is the length of the triangle’s hypotenuse.

We have defined scalar multiplication and vector addition geometrically. Expressing vectors in component form allows us to perform these same operations algebraically.

Example: Performing Operations in Component Form

Let [latex]\bf{v}[/latex] be the vector with initial point [latex](2,5)[/latex] and terminal point [latex](8,13)[/latex], and let [latex]\bf{w}[/latex][latex] = \langle−2,4\rangle[/latex].

a. Express [latex]\bf{v}[/latex] in component form and find [latex]\bf{||v||}[/latex]. Then, using algebra, find

b. [latex]\bf{v + w}[/latex],

c. [latex]3[/latex][latex]\bf{v}[/latex], and

d. [latex]\bf{v}[/latex][latex]−2[/latex][latex]\bf{w}[/latex].

Show Solution

1. a. To place the initial point of [latex]\bf{v}[/latex] at the origin, we must translate the vector [latex]2[/latex] units to the left and [latex]5[/latex] units down (Figure 2.15). Using the algebraic method, we can express [latex]\bf{v}[/latex] as [latex]\bf{v}[/latex] [latex] = \langle 8 − 2,13 − 5\rangle = \langle6,8\rangle[/latex]:

[latex]\bf{||v||}[/latex] [latex]=\sqrt{6^2 + 8^2} = \sqrt{36+64} = \sqrt{100} = 10[/latex].

Figure 6. In component form, [latex]{\bf{v}}=\langle{6,8}\rangle[/latex].

1. b. To find [latex]\bf{v + w}[/latex], add the [latex]x[/latex]-components and the [latex]y[/latex]-components separately:

[latex]\bf{v + w}[/latex][latex]=\langle6,8\rangle + \langle−2,4\rangle = \langle4,12\rangle[/latex].

1. c. To find [latex]3[/latex][latex]\bf{v}[/latex], multiply [latex]\bf{v}[/latex] by the scalar [latex]k=3[/latex]:

[latex]3[/latex][latex]\bf{v}[/latex][latex]=3\cdot\langle6,8\rangle = \langle3\cdot6,3\cdot8\rangle = \langle18,24\rangle[/latex].

1. d. To find [latex]\bf{v}[/latex][latex]−2[/latex][latex]\bf{w}[/latex], find [latex]−2[/latex][latex]\bf{w}[/latex] and add it to [latex]\bf{v}[/latex]:

[latex]\bf{v}[/latex][latex]−2[/latex][latex]\bf{w}[/latex][latex]=\langle6,8\rangle − 2 \cdot \langle−2,4\rangle = \langle6,8\rangle + \langle4,−8\rangle = \langle10,0\rangle[/latex].

Watch the following video to see the worked solution to the above Try IT.

Proof of Cummutative Property

Let [latex]{\bf{u}}=\langle x_1, y_1\rangle[/latex] and [latex]{\bf{v}}=\langle x_2, y_2\rangle[/latex]. Apply the commutative property for real numbers:

Proof of Distrubutive Property

Apply the distributive property for real numbers:

[latex]_\blacksquare[/latex]

We have found the components of a vector given its initial and terminal points. In some cases, we may only have the magnitude and direction of a vector, not the points. For these vectors, we can identify the horizontal and vertical components using trigonometry (Figure 16).

Figure 7. The components of a vector form the legs of a right triangle, with the vector as the hypotenuse.

Consider the angle [latex]\theta[/latex] formed by the vector [latex]{\bf{v}}[/latex] and the positive [latex]x[/latex]-axis. We can see from the triangle that the components of vector [latex]{\bf{v}}[/latex] are [latex]\langle ||{\bf{v}}||\cos{\theta},||{\bf{v}}||\sin{\theta} \rangle[/latex]. Therefore, given an angle and the magnitude of a vector, we can use the cosine and sine of the angle to find the components of the vector.

Example: Finding the Component Form of a Vector Using Trigonometry

Find the component form of a vector with magnitude [latex]4[/latex] that forms an angle of [latex]−45°[/latex] with the [latex]x[/latex]-axis.

Show Solution

Let [latex]x[/latex] and [latex]y[/latex] represent the components of the vector (Figure 2.16). Then [latex]x = 4\cos({−45°}) = 2\sqrt{2}[/latex] and [latex]y = 4\sin({−45°}) = −2\sqrt{2}[/latex]. The component form of the vector is [latex]\langle 2\sqrt{2},−2\sqrt{2} \rangle[/latex].

Figure 8. Use trigonometric ratios, [latex]x=||{\bf{v}}||\cos{\theta}[/latex] and[latex]y=||{\bf{v}}||\sin{\theta}[/latex], to identify the components of the vector.