9.2 Dot Products and Projections

In Section 9.1, we learned how add and subtract vectors and how to multiply vectors by scalars. In this section, we define a product of vectors. We begin with the following definition.

Definition 9.7

Given vectors \vec{v} = \left<v_{1},v_{2}\right> and \vec{w} = \left<w_{1},w_{2}\right>, the dot product of \vec{v} and \vec{w} is given by

    \[ \vec{v} \cdot \vec{w} = \left<v_{1},v_{2}\right> \cdot \left<w_{1},w_{2}\right> = v_{1}w_{1} + v_{2}w_{2} \]

For example, if \vec{v} = \left<3,4\right> and \vec{w} = \left<1,-2\right>,then

    \[ \begin{array}{rcl} \vec{v} \cdot \vec{w} &=& \left<3,4\right> \cdot \left<1,-2\right>\\ &=& (3)(1) + (4)(-2) \\ &=& -5 \end{array} \]

Note that the dot product takes two vectors and produces a scalar. For that reason, the quantity \vec{v} \cdot \vec{w} is often called the scalar product of \vec{v} and \vec{w}. The dot product enjoys the following properties.

Theorem 9.5  Properties of the Dot Product

  • Commutative Property: For all vectors \vec{v} and \vec{w}, \vec{v} \cdot \vec{w} = \vec{w} \cdot \vec{v}
  • Distributive Property: For all vectors \vec{u}, \vec{v} and \vec{w}, \vec{u} \cdot \left(\vec{v} + \vec{w}\right) = \vec{u} \cdot \vec{v} + \vec{u} \cdot \vec{w}
  • Scalar Property: For all vectors \vec{v} and \vec{w} and scalars k, (k \vec{v}) \cdot \vec{w} = k(\vec{v} \cdot \vec{w}) = \vec{v} \cdot (k \vec{w})
  • Relation to Magnitude: For all vectors \vec{v}, \vec{v} \cdot \vec{v} = \| \vec{v} \|^2

Like most of the theorems involving vectors, the proof of Theorem 9.5 amounts to using the definition of the dot product and properties of real number arithmetic.

For example, to show the commutative property, let \vec{v} = \left<v_{1},v_{2}\right> and \vec{w} = \left<w_{1},w_{2}\right>. Then

    \[ \begin{array}{rcll} \vec{v} \cdot \vec{w} & = & \left<v_{1},v_{2}\right> \cdot \left<w_{1},w_{2}\right> & \\ [3pt] & = & v_{1}w_{1} + v_{2}w_{2} & \text{Definition of Dot Product} \\ [3pt] & = & w_{1}v_{1} + w_{2}v_{2} & \text{Commutativity of Real Number Multiplication} \\ [3pt] & = & \left<w_{1},w_{2}\right> \cdot \left<v_{1},v_{2}\right> & \text{Definition of Dot Product} \\ [3pt] & = & \vec{w} \cdot \vec{v} & \\ \end{array} \]

The distributive property is proved similarly and is left as an exercise.

For the scalar property, assume that \vec{v} = \left<v_{1},v_{2}\right> and \vec{w} = \left<w_{1},w_{2}\right> and k is a scalar. Then

    \[ \begin{array}{rcll} (k\vec{v}) \cdot \vec{w} & = & \left(k \left<v_{1},v_{2}\right> \right) \cdot \left<w_{1},w_{2}\right> & \\ [3pt] & = & \left<kv_{1},kv_{2}\right> \cdot \left<w_{1},w_{2}\right> & \text{Definition of Scalar Multiplication} \\ [3pt] & = & (kv_{1})(w_{1}) + (kv_{2})(w_{2}) & \text{Definition of Dot Product} \\ [3pt] & = & k(v_{1}w_{1}) + k(v_{2}w_{2}) & \text{Associativity of Real Number Multiplication} \\ [3pt] & = & k(v_{1}w_{1} + v_{2}w_{2}) & \text{Distributive Law of Real Numbers} \\ [3pt] & = & k \left<v_{1},v_{2}\right> \cdot \left<w_{1},w_{2}\right> & \text{Definition of Dot Product} \\ [3pt] & = & k (\vec{v} \cdot \vec{w}) & \\ \end{array} \]

We leave the proof of k(\vec{v} \cdot \vec{w}) = \vec{v} \cdot (k \vec{w}) as an exercise.

For the last property, we note that if \vec{v} = \left<v_{1},v_{2}\right>, then \vec{v} \cdot \vec{v} = \left<v_{1},v_{2}\right> \cdot \left<v_{1},v_{2}\right> = v_{1}^2 + v_{2}^2 = \|\vec{v}\|^2, where the last equality comes courtesy of Definition 9.4.

The following example puts Theorem 9.5 to good use. As in Example 9.2.1, we work out the problem in great detail and encourage the reader to supply the justification for each step.

Example 9.2.1

Example 9.2.1

Prove the identity: \| \vec{v} - \vec{w} \|^2 = \|\vec{v}\|^2 -2 (\vec{v}\cdot\vec{w}) + \|\vec{w}\|^2.

Solution:

We begin by rewriting \| \vec{v} - \vec{w} \|^2 in terms of the dot product using Theorem 9.5.

    \[ \begin{array}{rcl} \| \vec{v} - \vec{w} \|^2 & = & (\vec{v} - \vec{w}) \cdot (\vec{v} - \vec{w}) \\ [3pt] & = & (\vec{v} + [-\vec{w}]) \cdot (\vec{v} + [-\vec{w}]) \\ [3pt] & = & (\vec{v} + [-\vec{w}]) \cdot \vec{v} +(\vec{v} + [-\vec{w}]) \cdot [-\vec{w}] \\ [3pt] & = & \vec{v} \cdot (\vec{v} + [-\vec{w}]) + [-\vec{w}] \cdot (\vec{v} + [-\vec{w}]) \\ [3pt] & = & \vec{v} \cdot \vec{v} + \vec{v} \cdot [-\vec{w}] + [-\vec{w}]\cdot \vec{v} + [-\vec{w}]\cdot[-\vec{w}] \\ [3pt] & = & \vec{v} \cdot \vec{v} + \vec{v} \cdot [(-1)\vec{w}] + [(-1)\vec{w}]\cdot \vec{v} + [(-1)\vec{w}]\cdot[(-1)\vec{w}] \\ [3pt] & = & \vec{v} \cdot \vec{v} + (-1)(\vec{v} \cdot \vec{w}) + (-1)(\vec{w} \cdot \vec{v}) + [(-1)(-1)](\vec{w}\cdot\vec{w}) \\ [3pt] & = & \vec{v} \cdot \vec{v} + (-1)(\vec{v} \cdot \vec{w}) + (-1)(\vec{v} \cdot \vec{w}) + \vec{w}\cdot\vec{w} \\ [3pt] & = & \vec{v} \cdot \vec{v} -2(\vec{v} \cdot \vec{w}) + \vec{w}\cdot\vec{w} \\ [3pt] & = & \|\vec{v}\|^2-2(\vec{v} \cdot \vec{w}) + \|\vec{w}\|^2 \\ \end{array} \]

Hence, \| \vec{v} - \vec{w} \|^2 = \|\vec{v}\|^2 -2 (\vec{v}\cdot\vec{w}) + \|\vec{w}\|^2 as required.

If we take a step back from the pedantry in Example 9.2.1, we see that the bulk of the work is needed to show that (\vec{v} - \vec{w}) \cdot (\vec{v} - \vec{w}) = \vec{v} \cdot \vec{v} -2(\vec{v} \cdot \vec{w}) + \vec{w}\cdot\vec{w}. If this looks familiar, it should.

As the dot product enjoys many of the same properties enjoyed by real numbers, the machinations required to expand (\vec{v} - \vec{w}) \cdot (\vec{v} - \vec{w}) for vectors \vec{v} and \vec{w} match those required to expand (v-w)(v-w) for real numbers v and w, and hence we get similar looking results.

The identity verified in Example 9.2.1 plays a large role in the development of the geometric properties of the dot product, which we now explore.

Suppose \vec{v} and \vec{w} are two nonzero vectors. If we draw \vec{v} and \vec{w} with the same initial point, we define the angle between  \vec{v} and \vec{w} to be the angle \theta determined by the rays containing the vectors \vec{v} and \vec{w}, as illustrated below. We require 0 \leq \theta \leq \pi. (Think about why this is needed in the definition.)

Three pairs of vectors, v and w, side by side. The first pair v and w are in the same direction with the same initial point, but w is shorter than v. In the second pair the vectors share the same initial point, but are in different directions. The angle between the vectors is theta and theta is between 0 and pi. The third pair v and w have the same initial point and are in opposite directions. The angle, theta, between the two vectors is exactly pi.
Representations of Angles between Vectors

The following theorem gives us some insight into the geometric role the dot product plays.

Theorem 9.6  Geometric Interpretation of Dot Product

If \vec{v} and \vec{w} are nonzero vectors then

    \[ \vec{v} \cdot \vec{w} = \|\vec{v}\| \|\vec{w}\| \cos(\theta),\]

where \theta is the angle between \vec{v} and \vec{w}.

We prove Theorem 9.6 in cases. If \theta = 0, then \vec{v} and \vec{w} have the same direction. It follows[1] that there is a real number k > 0 such that \vec{w} = k \vec{v}. Hence,

    \[\vec{v} \cdot \vec{w} = \vec{v} \cdot (k \vec{v}) = k (\vec{v} \cdot \vec{v}) = k \| \vec{v} \|^2\]

Working from the other end of the equation,

    \[ \begin{array}{rcl} \| \vec{v} \| \| \vec{w} \| \cos(\theta) &=& \| \vec{v} \| \|k \vec{v} \| \cos(0) \\ &=& \| \vec{v} \| (|k| \| \vec{v} \|) (1) \\ &=& k \| \vec{v} \|^2 \end{array}\]

where \|k \vec{v} \| = |k| \| \vec{v} \| courtesy of Theorem 9.3, and |k| = k because k > 0.

Hence, in the case \theta = 0, we have shown \vec{v} \cdot \vec{w} = k \| \vec{v} \|^2 and \| \vec{v} \| \| \vec{w} \| \cos(\theta)= k \| \vec{v} \|^2. Putting these two equations together shows that

    \[\vec{v} \cdot \vec{w} = \|\vec{v}\| \|\vec{w}\| \cos(\theta) \]

holds in this case.

If \theta = \pi, \vec{v} and \vec{w} have the exact opposite directions, so there is a real number k< 0 with \vec{w} = k \vec{v}.

As before, we compute \vec{v} \cdot \vec{w} = \vec{v} \cdot (k \vec{v}) = k (\vec{v} \cdot \vec{v}) = k \| \vec{v} \|^2. Because k< 0 here, we have |k| = -k. Hence, we find

    \[ \begin{array}{rcl} \| \vec{v} \| \| \vec{w} \| \cos(\theta) &=& \| \vec{v} \| \| k \vec{v} \| \cos(\pi) \\ &=& \| \vec{v} \| (|k| \| \vec{v} \|) (-1) \\ &=& \| \vec{v} \| (-k) \| \vec{v} \| (-1)\\ &=& k \| \vec{v} \|^2 \end{array} \]

Once again, both \vec{v} \cdot \vec{w} = k \| \vec{v} \|^2 and \| \vec{v} \| \| \vec{w} \| \cos(\theta)= k \| \vec{v} \|^2, so \vec{v} \cdot \vec{w} = \|\vec{v}\| \|\vec{w}\| \cos(\theta) in this case.

Next, if 0 < \theta < \pi, the vectors \vec{v}, \vec{w} and \vec{v} - \vec{w} determine a triangle with side lengths \| \vec{v} \|, \| \vec{w} \| and \| \vec{v} - \vec{w} \|, respectively, as seen in the diagram below.

Two triangles side by side. The first triangle is created by vectors v, w, and v-w. The vectors v and w share an initial point and the angle between the two vectors is theta. The second triangle has the magnitudes of v, w, and v-w, as the sides. The angle theta is between vectors v and w, which share an initial point.
Geometric Proof of the Dot Product

The Law of Cosines yields \| \vec{v} - \vec{w} \|^2 = \|\vec{v}\|^2 + \|\vec{w}\|^2 - 2\|\vec{v}\| \|\vec{w}\| \cos(\theta).

From Example 9.2.1, we also have that \|\vec{v} - \vec{w}\|^2 = \|\vec{v}\|^2 -2 (\vec{v} \cdot \vec{w}) + \|\vec{w}\|^2 .

Equating these two expressions for \| \vec{v} - \vec{w} \|^2 gives

    \[ \begin{array}{rcl} \|\vec{v}\|^2 + \|\vec{w}\|^2 - 2\|\vec{v}\| \|\vec{w}\| \cos(\theta) &=& \|\vec{v}\|^2 -2 (\vec{v} \cdot \vec{w}) + \|\vec{w}\|^2 \\[4pt] - 2\|\vec{v}\| \|\vec{w}\| \cos(\theta) \\[4pt] &=& -2 (\vec{v} \cdot \vec{w}) \end{array} \]

Hence, \vec{v} \cdot \vec{w} = \|\vec{v}\| \|\vec{w}\| \cos(\theta), as required.

An immediate consequence of Theorem 9.6 is the following.

Theorem 9.7

Let \vec{v} and \vec{w} be nonzero vectors and let \theta be the angle between \vec{v} and \vec{w}. Then

    \[ \theta = \arccos\left( \dfrac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|}\right) = \arccos(\bm\hat{v} \cdot \bm\hat{w}) \]

We obtain the formula in Theorem 9.7 by solving the equation given in Theorem 9.6 for \theta .

As \vec{v} and \vec{w} are nonzero, so are \| \vec{v} \| and \|\vec{w}\|. Hence, we may divide both sides of \vec{v} \cdot \vec{w} = \| \vec{v} \| \|\vec{w} \| \cos(\theta) by \| \vec{v} \| \|\vec{w} \|. Given 0 \leq \theta \leq \pi by definition, the values of \theta exactly match the range of the arccosine function. Hence,

    \[ \cos(\theta) = \frac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|} \, \Rightarrow \, \theta = \arccos\left( \frac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|}\right).\]

Using Theorem 9.5, we can rewrite

    \[ \begin{array}{rcl} \frac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|} &=& \left(\frac{1}{\|\vec{v}\|} \vec{v}\right) \cdot \left(\frac{1}{\|\vec{w}\|} \vec{w}\right) \\[10pt] &=& \bm\hat{v} \cdot \bm\hat{w} \end{array} \]

giving us the alternative formula listed in Theorem 9.7: \theta = \arccos(\bm\hat{v} \cdot \bm\hat{w}).

We are overdue for an example.

Example 9.2.2

Example 9.2.2.1

Compute the angle between the following pairs of vectors. Graph each pair of vectors in standard position to check the reasonableness of your answer.

\vec{v} = \left< 3, -3\sqrt{3} \right>, and \vec{w} = \left<-\sqrt{3}, 1 \right>

Solution:

We use the formula \theta = \arccos\left( \frac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|}\right) from Theorem 9.7 in each case below.

Compute the angle between \vec{v} = \left< 3, -3\sqrt{3} \right>, and \vec{w} = \left<-\sqrt{3}, 1 \right>.

We have

    \[ \begin{array}{rcl} \vec{v} \cdot \vec{w} &=& \left< 3, -3\sqrt{3} \right> \cdot \left<-\sqrt{3}, 1 \right> \\ & =& -3\sqrt{3} - 3\sqrt{3} \\ &=& -6\sqrt{3} \end{array} \]

Computing the length of each vector, we find

    \[ \begin{array}{rcl} \| \vec{v} \| &=& \sqrt{3^2+(-3\sqrt{3})^2}\\[4pt] &=& \sqrt{36} \\[4pt] &=& 6 \end{array} \]

and

    \[ \begin{array}{rcl} \| \vec{w}\| &=& \sqrt{(-\sqrt{3})^2+1^2} \\[4pt] &=& \sqrt{4} \\[4pt] &=& 2 \end{array} \]

Hence, we find

    \[ \begin{array}{rcl} \theta &=& \arccos\left(\frac{-6\sqrt{3}}{12}\right) \\[4pt] &=& \arccos\left(-\frac{\sqrt{3}}{2}\right) \\[4pt] &=& \frac{5\pi}{6} \end{array} \]

We check our answer geometrically by graphing this pair of vectors.

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Example 9.2.2.2

Compute the angle between the following pairs of vectors. Graph each pair of vectors in standard position to check the reasonableness of your answer.

\vec{v} = \left< 2, 2 \right>, and \vec{w} = \left<5, -5\right>

Solution:

We use the formula \theta = \arccos\left( \frac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|}\right) from Theorem 9.7 in each case below.

Compute the angle between \vec{v} = \left< 2, 2 \right>, and \vec{w} = \left<5, -5\right>.

For \vec{v} = \left< 2, 2 \right> and \vec{w} = \left<5, -5\right>, we find

    \[ \begin{array}{rcl} \vec{v} \cdot \vec{w} &=& \left< 2, 2 \right> \cdot \left<5, -5\right>\\ &=& 10-10 \\ &=& 0 \end{array} \]

Hence, it doesn’t matter what \| \vec{v} \| and \| \vec{w} \| are,

    \[ \begin{array}{rcl} \theta &=& \arccos\left( \frac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|}\right) \\[10pt] &=& \arccos(0) \\[4pt] &=& \frac{\pi}{2} \end{array} \]

We check our answer geometrically by graphing this pair of vectors.

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Example 9.2.2.3

Compute the angle between the following pairs of vectors. Graph each pair of vectors in standard position to check the reasonableness of your answer.

\vec{v} = \left< 3, -4 \right>, and \vec{w} = \left<2, 1\right>

Solution:

We use the formula \theta = \arccos\left( \frac{\vec{v} \cdot \vec{w}}{\| \vec{v} \| \|\vec{w} \|}\right) from Theorem 9.7 in each case below.

Compute the angle between \vec{v} = \left< 3, -4 \right>, and \vec{w} = \left<2, 1\right>.

We find

    \[ \begin{array}{rcl} \vec{v} \cdot \vec{w} &=& \left< 3, -4 \right> \cdot \left<2, 1\right>\\ &=& 6 - 4 \\ &=& 2 \end{array} \]

Computing lengths, we find

    \[ \begin{array}{rcl} \| \vec{v} \| &=& \sqrt{3^2+(-4)^2}\\[4pt] &=& \sqrt{25} \\ &=& 5 \end{array} \]

and

    \[ \begin{array}{rcl} \vec{w} &=& \sqrt{2^2+1^2}\\[4pt] &=& \sqrt{5} \end{array} \]

and as a result

    \[ \begin{array}{rcl} \theta &=& \arccos\left(\frac{2}{5\sqrt{5}}\right)\\[10pt] &=& \arccos\left(\frac{2\sqrt{5}}{25} \right) \end{array} \]

As \frac{2\sqrt{5}}{25} isn’t the cosine of one of the `common angles,’ we leave our exact answer in terms of the arccosine function. For the purposes of checking our answer, however, we approximate \theta \approx 79.7^{\circ}.

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A few remarks about Example 9.2.2 are in order. Note that for nonzero vectors \vec{v} and \vec{w}, the lengths \| \vec{v} \| and \| \vec{w} \| are always positive. Theorem 9.6 tells us that \vec{v} \cdot \vec{w} = \| \vec{v} \| \| \vec{w} \| \cos(\theta), thus we know the sign of \vec{v} \cdot \vec{w} is the same as the sign of \cos(\theta).

Geometrically, if \vec{v} \cdot \vec{w} < 0, then \cos(\theta) < 0 so \theta is an obtuse angle, demonstrated in number 1 above.

If \vec{v} \cdot \vec{w} = 0, then \cos(\theta) = 0 so \theta = \frac{\pi}{2} as in number 2. In this case, the vectors \vec{v} and \vec{w} are called orthogonal. Geometrically, when orthogonal vectors are sketched with the same initial point, the lines containing the vectors are perpendicular. Hence, if \vec{v} and \vec{w} are orthogonal, we write \vec{v} \perp \vec{w}.

Note there is no `zero product property’ for the dot product. As with the vectors in number 2 above, it is quite possible to have \vec{v} \cdot \vec{w} = 0 but neither \vec{v} nor \vec{w} be \vec{0}.

Finally, if \vec{v} \cdot \vec{w} > 0, then \cos(\theta) > 0 so \theta is an acute angle, as in the case of number 3 above.

We summarize all of our observations in the schematic below.

Three vector pairs, v and w, and the angle, theta, between the vectors. In each pair, the initial points of v and w are the same point. In the first picture, theta is an obtuse angle and the dot product is negative. In the second picture theta is a right angle and the dot product equals zero. In the last picture, theta is an acute angle, and the dot product is positive.
Relationship between the Dot Product and the Angle

Of the three cases diagrammed above, the one which has the most mathematical significance moving forward is the orthogonal case. Hence, we state the corresponding theorem below.

Theorem 9.8

For nonzero vectors \vec{v} and \vec{w}, \vec{v} \perp \vec{w} if and only if \vec{v} \cdot \vec{w} = 0.

Basically, Theorem 9.8 tells us that `the dot product detects orthogonality.’ This is a helpful interpretation to keep in mind as you continue your study of vectors in later courses.

We have already argued one direction of Theorem 9.8, namely if \vec{v} \cdot \vec{w} = 0 then \vec{v} \perp \vec{w} in the comments following Example 9.2.2.

To show the converse, we note if \vec{v} \perp \vec{w}, then the angle between \vec{v} and \vec{w}, \theta = \frac{\pi}{2}. From Theorem 9.6, we have that \vec{v} \cdot \vec{w} = \| \vec{v} \| \| \vec{w} \| \cos \left( \frac{\pi}{2} \right) = \| \vec{v} \| \| \vec{w} \| \cdot (0) = 0, as required.

We can use Theorem 9.8 in the following example to provide a different proof about the relationship between the slopes of perpendicular lines.[2]

Example 9.2.3

Example 9.2.3

Let L_{1} be the line y = m_{1}x + b_{1} and let L_{2} be the line y = m_{2}x + b_{2}. Prove that L_{1} is perpendicular to L_{2} if and only if m_{1} \cdot m_{2} = -1.

Solution:

Our strategy is to find two vectors: \vec{v_{1}}, which has the same direction as L_{1}, and \vec{v_{2}}, which has the same direction as L_{2} and show \vec{v_{1}} \perp \vec{v_{2}} if and only if m_{1} m_{2} = -1.

To that end, we substitute x=0 and x=1 into y = m_{1}x + b_{1} to find two points which lie on L_{1}, namely P(0, b_{1}) and Q(1, m_{1} + b_{1}).

We let \vec{v_{1}} = \overrightarrow{PQ} = \left<1-0,(m_{1}+b_{1}) - b_{1}\right>=\left<1,m_{1}\right>. Because \vec{v_{1}} is determined by two points on L_{1}, it may be viewed as lying on L_{1}, so \vec{v_{1}} has the same direction as L_{1} .

Similarly, we get the vector \vec{v_{2}} = \left<1,m_{2}\right> which has the same direction as the line L_{2}. Hence, L_{1} and L_{2} are perpendicular if and only if \vec{v_{1}} \perp \vec{v_{2}}. According to Theorem 9.8, \vec{v_{1}} \perp \vec{v_{2}} if and only if \vec{v_{1}} \cdot \vec{v_{2}} = 0.

Notice that \vec{v_{1}} \cdot \vec{v_{2}} = \left<1,m_{1}\right> \cdot \left<1,m_{2}\right> = 1 + m_{1}m_{2}. Hence, \vec{v_{1}} \cdot \vec{v_{2}} = 0 if and only if 1 + m_{1}m_{2} =0, which is true if and only if m_{1} m_{2} = -1, as required.

 

9.2.1 Vector Projections

 

While Theorem 9.8 certainly gives us some insight into what the dot product means geometrically, there is more to the story of the dot product. Consider the two nonzero vectors \vec{v} and \vec{w} drawn with a common initial point O below. For the moment, assume that the angle between \vec{v} and \vec{w}, \theta, is acute.

Three diagrams including the vector pair, v and w, with the same initial point O and the angle theta between them. The first picture is the original vectors and angle. The second picture includes a point T at the terminal point of vector v and a dashed line from T perpendicular to vector w. The point on vector w where the dashed line touches w is labeled R. The vector created with initial point O and terminal point R is called vector p. The last picture is the triangle created by points O, T, and R.
Geometric Representation of an Orthogonal Projection

We wish to develop a formula for the vector \vec{p}, indicated below, which is called the orthogonal projection of <strong>\vec{v} onto \vec{w}</strong>.  The vector \vec{p} is obtained geometrically as follows: drop a perpendicular from the terminal point T of \vec{v} to the vector \vec{w} and call the point of intersection R. The vector \vec{p} is then defined as \vec{p} = \overrightarrow{OR}.

Like any vector, \vec{p} is determined by its magnitude \| \vec{p} \| and its direction \bm\hat{p} according to the formula \vec{p} = \| \vec{p} \| \bm\hat{p}. Because we want \bm\hat{p} to have the same direction as \vec{w}, we have \bm\hat{p} = \bm\hat{w}.

To determine \| \vec{p} \|, we apply Definition 7.2 to the right triangle \triangle ORT. We find \cos(\theta) = \frac{\| \vec{p} \|}{\| \vec{v} \|}, or, equivalently, \| \vec{p} \| = \| \vec{v} \| \cos(\theta). Using Theorems 9.6 and 9.5, we get:

    \[ \begin{array}{rcl} \| \vec{p} \| &=& \| \vec{v} \| \cos(\theta)\\[4pt] &=& \frac{ \| \vec{v} \| \| \vec{w} \| \cos(\theta)}{\| \vec{w} \|}\\[8pt] &=& \frac{\vec{v} \cdot \vec{w}}{\|\vec{w}\|}\\[8pt] &=& \vec{v} \cdot \left(\frac{1}{\|\vec{w}\|} \vec{w}\right)\\[10pt] &=& \vec{v} \cdot \bm\hat{w} \end{array}\]

Hence, \| \vec{p} \| = \vec{v} \cdot \bm\hat{w}, and as \bm\hat{p} = \bm\hat{w}, we have

    \[ \begin{array}{rcl} \vec{p} &=& \| \vec{p} \| \bm\hat{p} \\ &=& (\vec{v} \cdot \bm\hat{w}) \bm\hat{w} \end{array} \]

Now suppose that the angle \theta between \vec{v} and \vec{w} is obtuse, and consider the diagram below.

Two vectors w and v with angle theta between them. Theta is obtuse. Vector w in the negative direction is also drawn. There is a dashed line from the terminal point of vector v to the vector w in the negative direction. R is on -w and is at the dashed line. The supplement to theta, theta prime.
Geometric Representation of an Orthogonal Projection, Obtuse Angle

In this case, we see that \bm\hat{p} = - \bm\hat{w} and using the triangle \triangle ORT, we find \| \vec{p} \| = \| \vec{v} \| \cos(\theta'). Because \theta + \theta' = \pi, it follows that \cos(\theta') = -\cos(\theta), which means

    \[ \| \vec{p} \| = \| \vec{v} \| \cos(\theta') = - \| \vec{v} \| \cos(\theta). \]

Rewriting this last equation in terms of \vec{v} and \vec{w} as before, we get \|\vec{p} \| = -(\vec{v} \cdot \bm\hat{w}). Putting this together with \bm\hat{p} = - \bm\hat{w}, we get

    \[ \begin{array}{rcl} \vec{p} &=& \| \vec{p} \| \bm\hat{p}\\ &=& -(\vec{v} \cdot \bm\hat{w}) (-\bm\hat{w}) \\ &=& (\vec{v} \cdot \bm\hat{w}) \bm\hat{w} \end{array} \]

 in this case as well.

If the angle between \vec{v} and \vec{w} is \frac{\pi}{2} then it is easy to show[3] that \vec{p} = \vec{0}. Because \vec{v} \perp \vec{w} in this case, \vec{v} \cdot \vec{w} = 0. It follows that \vec{v} \cdot \bm\hat{w} = 0 and \vec{p} = \vec{0} = 0 \bm\hat{w} = (\vec{v} \cdot \bm\hat{w}) \bm\hat{w} in this case, too. We have motivated the following.

Definition 9.8

Let \vec{v} and \vec{w} be nonzero vectors.

The orthogonal projection of \vec{v} onto \vec{w}, denoted \text{proj}_{\vec{w}}(\vec{v}) is given by \text{proj}_{\vec{w}}(\vec{v}) = (\vec{v} \cdot \bm\hat{w}) \bm\hat{w}.

Definition 9.8 gives us a good idea what the dot product does. The scalar \vec{v} \cdot \bm\hat{w} is a measure of how much of the vector \vec{v} is in the direction of the vector \vec{w} and is thus called the scalar projection of \vec{v} onto \vec{w}.

While the formula given in Definition 9.8 is theoretically appealing, because of the presence of the normalized unit vector \bm\hat{w}, computing the projection using the formula \text{proj}_{\vec{w}}(\vec{v}) = (\vec{v} \cdot \bm\hat{w}) \bm\hat{w} can be messy. We present two other formulas that are often used in practice.

Theorem 9.9  Alternate Formulas for Vector Projections

If \vec{v} and \vec{w} are nonzero vectors then

    \[\text{proj}_{\vec{w}}(\vec{v}) = (\vec{v} \cdot \bm\hat{w}) \bm\hat{w} = \left(\dfrac{\vec{v} \cdot \vec{w}}{\| \vec{w}\|^2}\right) \vec{w} = \left(\dfrac{\vec{v} \cdot \vec{w}}{\vec{w} \cdot \vec{w}}\right) \vec{w} \]

The proof of Theorem 9.9, which we leave to the reader as an exercise, amounts to using the formula \bm\hat{w} = \left(\frac{1}{\| \vec{w} \|}\right) \vec{w} and properties of the dot product. It is time for an example.

Example 9.2.4

Example 9.2.4

Let \vec{v} = \left<1,8\right> and \vec{w} = \left<-1,2\right>. Determine \vec{p} = \text{proj}_{\vec{w}}(\vec{v}). Check your answer geometrically.

Solution:

We find

    \[\vec{v} \cdot \vec{w} = \left<1,8\right> \cdot \left<-1,2\right> = (-1) + 16 = 15 \]

and

    \[ \vec{w} \cdot \vec{w} = \left<-1,2\right> \cdot \left<-1,2\right> = 1 + 4 = 5\]

Hence,

    \[ \begin{array}{rcl} \vec{p} &=& \frac{\vec{v} \cdot \vec{w}}{\vec{w} \cdot \vec{w}} \vec{w} \\[10pt] &=& \frac{15}{5} \left<-1,2\right>\\[10pt] &=& \left<-3,6\right> \end{array}\]

We plot \vec{v}, \vec{w} and \vec{p} in standard position below on the left. We see \vec{p} has the same direction as \vec{w}, but we need to do more to show \vec{p} in is indeed the orthogonal projection of \vec{v} onto \vec{w}.

Consider the vector \vec{q} whose initial point is the terminal point of \vec{p} and whose terminal point is the terminal point of \vec{v}. From the definition of vector arithmetic, \vec{p} + \vec{q} = \vec{v}, so that \vec{q} = \vec{v} - \vec{p}.

For \vec{v} = \left<1,8\right> and \vec{p} = \left<-3,6\right>, then \vec{q} = \left<1,8\right> - \left<-3,6\right> = \left<4,2\right>.

To prove \vec{q} \perp \vec{w}, we compute the dot product:

    \[ \begin{array}{rcl} \vec{q} \cdot \vec{w} &=& \left<4,2\right> \cdot \left<-1,2\right> \\ &=& (-4)+4 \\ &=& 0 \end{array} \]

Hence, per Theorem 9.8, we know \vec{q} \perp \vec{w} which completes our check.[4]

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In Example 9.2.4 above, writing \vec{v} = \vec{p} + \vec{q} is an example of what is called a vector decomposition of \vec{v}. We generalize this result in the following theorem.

Theorem 9.10  Generalized Decomposition Theorem

Let \vec{v} and \vec{w} be nonzero vectors. There are unique vectors \vec{p} and \vec{q} such that \vec{v} = \vec{p} + \vec{q} where \vec{p} = k \vec{w} for some scalar k, and \vec{q} \cdot \vec{w} = 0.

If the vectors \vec{p} and \vec{q} in Theorem 9.10 are nonzero, then we can say \vec{p} is `parallel’[5] to \vec{w} and \vec{q} is `orthogonal’ to \vec{w}. In this case, the vector \vec{p} is sometimes called the `vector component of \vec{v} parallel to \vec{w}‘ and \vec{q} is called the `vector component of \vec{v} orthogonal to \vec{w}.’

To prove Theorem 9.10, we take \vec{p} = \text{proj}_{\vec{w}}(\vec{v}) and \vec{q} = \vec{v} - \vec{p}. Then \vec{p} is, by definition, a scalar multiple of \vec{w}. Next, we compute \vec{q} \cdot \vec{w}.

    \[ \begin{array}{rcll} \vec{q} \cdot \vec{w} & = & (\vec{v} - \vec{p}) \cdot \vec{w}& \text{Definition of } \vec{q} \\ [3pt] & = & \vec{v} \cdot \vec{w} - \vec{p} \cdot \vec{w} & \text{Properties of Dot Product} \\ [8pt] & = & \vec{v} \cdot \vec{w} - \left(\dfrac{\vec{v} \cdot \vec{w}}{\vec{w} \cdot \vec{w}} \vec{w}\right) \cdot \vec{w} & \vec{p} = \text{proj}_{\vec{w}}(\vec{v}) \\ [8pt] & = & \vec{v} \cdot \vec{w} - \left(\dfrac{\vec{v} \cdot \vec{w}}{\vec{w} \cdot \vec{w}}\right) (\vec{w} \cdot \vec{w}) & \text{Properties of Dot Product} \\ [8pt] & = & \vec{v} \cdot \vec{w} - \vec{v}\cdot \vec{w} & \\ [3pt] & = & 0 & \end{array} \]

Hence, \vec{q} \cdot \vec{w} = 0, as required. At this point, we have shown that the vectors \vec{p} and \vec{q} guaranteed by Theorem 9.10 exist. Now we need to show that they are unique – that is, there is only one such way to decompose \vec{v} in the manner described in Theorem 9.10.

Suppose \vec{v} = \vec{p} + \vec{q} = \vec{p} \,' + \vec{q} \,' where the vectors \vec{p} \,' and \vec{q} \,' satisfy the same properties described in Theorem 9.10 as \vec{p} and \vec{q}. Then \vec{p} - \vec{p} \,' = \vec{q} \,' - \vec{q}, so

    \[ \begin{array}{rcl} \vec{w} \cdot (\vec{p} - \vec{p} \,') & =& \vec{w} \cdot (\vec{q} \,' - \vec{q}) \\ &=& \vec{w} \cdot \vec{q} \,' - \vec{w} \cdot \vec{q} \\ &=& 0 - 0 \\ &=& 0 \end{array} \]

The long and short of this computation is that \vec{w} \cdot (\vec{p} - \vec{p} \,') = 0.

Now there are scalars k and k \,' so that \vec{p} = k \vec{w} and \vec{p} \,' = k\,'\vec{w}. This means

    \[ \begin{array}{rcl} \vec{w} \cdot (\vec{p} - \vec{p} \,') &=& \vec{w} \cdot ( k \vec{w} - k \,' \vec{w}) \\ &=& \vec{w} \cdot ([k - k \,'] \vec{w}) \\ &=& (k - k \,') (\vec{w} \cdot \vec{w}) \\ &=& (k - k \,') \| \vec{w} \|^2 \end{array} \]

Because \vec{w} \neq \vec{0}, \| \vec{w} \|^2 \neq 0, which means the only way \vec{w} \cdot (\vec{p} - \vec{p} \,') = (k - k \,') \| \vec{w} \|^2 = 0 is for k - k \,' = 0, or k = k \,'. \vskip 0.5em

This means \vec{p} = k \vec{w} = k \,' \vec{w} = \vec{p} \,'. As \vec{q} \,' - \vec{q} = \vec{p} - \vec{p} \,' = \vec{p} - \vec{p} = \vec{0}, it must be that \vec{q} \,' = \vec{q} as well.

Hence, we have shown there is only one way to write \vec{v} as a sum of vectors as described in Theorem 9.10, so the decomposition listed there is unique.

We close this section with an application of the dot product. In Physics, if a constant force F is exerted over a distance d, the work W done by the force is given by W = Fd. Here, the assumption is that the force is being applied in the direction of the motion. If the force applied is not in the direction of the motion, we can use the dot product to find the work done.

Consider the scenario sketched below in which the constant force \vec{F} is applied to move an object from the point P to the point Q. Here the force is being applied at an angle \theta as opposed to being applied directly in the direction of the motion.

A diagram with a horizontal ray with initial point P and terminal point Q. There are two vectors, one with initial point P and the other with initial point Q, both vectors are in the same direction and same length. The angle between each vector F and the horizontal is theta.
Diagram for Work

To find the work W done in this scenario, we need to find how much of the force \vec{F} is in the direction of the motion \overrightarrow{PQ}. This is precisely what the dot product \vec{F} \cdot \widehat{PQ} represents.

The distance the object travels is \| \overrightarrow{PQ} \|, so we get W = (\vec{F} \cdot \widehat{PQ}) \| \overrightarrow{PQ} \|. As \overrightarrow{PQ} = \|\overrightarrow{PQ}\| \widehat{PQ}, we can simplify this formula as follows: W = (\vec{F} \cdot \widehat{PQ}) \| \overrightarrow{PQ} \| = \vec{F} \cdot ( \| \overrightarrow{PQ} \|\widehat{PQ} ) = \vec{F} \cdot \overrightarrow{PQ}.

Using Theorem 9.6, we can rewrite W = \vec{F} \cdot \overrightarrow{PQ} = \| \vec{F} \| \| \overrightarrow{PQ} \| \cos(\theta), where \theta is the angle between the applied force \vec{F} and the trajectory of the motion \overrightarrow{PQ}. We have proved the following.

Theorem 9.11  Work as a Dot Product

Suppose a constant force \vec{F} is applied along the vector \overrightarrow{PQ}. The work W done by \vec{F} is given by

    \[ W = \vec{F} \cdot \overrightarrow{PQ} = \| \vec{F} \| \| \overrightarrow{PQ} \| \cos(\theta),\]

where \theta is the angle between \vec{F} and \overrightarrow{PQ}.

We test out our formula for work in the following example.

Example 9.2.5

Example 9.2.5

Taylor exerts a force of 10 pounds to pull her wagon a distance of 50 feet over level ground. If the handle of the wagon makes a 30^{\circ} angle with the horizontal, how much work did Taylor do pulling the wagon? Assume the force of 10 pounds is exerted at a 30^{\circ} angle for the duration of the 50 feet.

 

A diagram of a wagon. The horizontal extension of the bottom of the wagon and the handle of the wagon form a 30 degree angle.
Wagon for Example 9.2.5

Solution:

There are (at least) two ways to attack this problem. One way is to find the vectors \vec{F} and \overrightarrow{PQ} mentioned in Theorem 9.11 and compute W = \vec{F} \cdot \overrightarrow{PQ}.

To do this, we assume the origin is at the point where the handle of the wagon meets the wagon and the positive x-axis lies along the dashed line in the figure above.

To find the force vector \vec{F}, we note the force in this situation is a constant 10 pounds, so \|\vec{F}\| = 10. Moreover, the force is being applied at a constant angle of \theta = 30^{\circ} with respect to the positive x-axis. Definition 9.4 gives us

    \[ \begin{array}{rcl} \vec{F} &=& \| \vec{F} \| \left< \cos(\theta), \sin(\theta) \right>\\ &=& 10 \left<\cos(30^{\circ}), \sin(30^{\circ})\right>\\ &=& \left<5\sqrt{3}, 5\right> \end{array} \]

The wagon is being pulled along 50 feet in the positive x-direction, so we find the displacement vector is

    \[ \overrightarrow{PQ} = 50 \bm\hat{\text{i}} = 50\left<1,0\right> = \left<50,0\right> \]

Per Theorem 9.11, W = \vec{F} \cdot \overrightarrow{PQ} = \left<5\sqrt{3}, 5\right> \cdot \left<50,0\right> = 250\sqrt{3}.

Force is measured in pounds and distance is measured in feet, giving us W = 250\sqrt{3} foot-pounds.

Alternatively, we can use the formula W = \| \vec{F} \| \| \overrightarrow{PQ} \| \cos(\theta). With \| \vec{F} \| = 10 pounds, \| \overrightarrow{PQ} \| = 50 feet and \theta = 30^{\circ}, we get W = (10 \, \text{pounds})(50 \, \text{feet}) \cos\left(30^{\circ}\right) = 250 \sqrt{3} foot-pounds of work.

9.2.2 Section Exercises

In Exercises 1 – 20, use the pair of vectors \vec{v} and \vec{w} to find the following quantities.

  • \vec{v} \cdot \vec{w}
  • The angle \theta (in degrees) between \vec{v} and \vec{w}
  • \text{proj}_{\vec{w}}(\vec{v})
  • \vec{q} = \vec{v} - \text{proj}_{\vec{w}}(\vec{v})  (Show that \vec{q} \cdot \vec{w} = 0.)
  1. \vec{v} = \left\langle -2, -7 \right\rangle and \vec{w} = \left\langle 5, -9 \right\rangle
  2. \vec{v} = \left\langle -6, -5 \right\rangle and \vec{w} = \left\langle 10, -12 \right\rangle
  3. \vec{v} = \left\langle 1, \sqrt{3} \right\rangle and \vec{w} = \left\langle 1, -\sqrt{3} \right\rangle
  4. \vec{v} = \left\langle 3, 4 \right\rangle and \vec{w} = \left\langle -6, -8 \right\rangle
  5. \vec{v} = \left\langle -2,1 \right\rangle and \vec{w} = \left\langle 3,6 \right\rangle
  6. \vec{v} = \left\langle -3\sqrt{3}, 3\right\rangle and \vec{w} = \left\langle -\sqrt{3}, -1 \right\rangle
  7. \vec{v} = \left\langle 1, 17 \right\rangle and \vec{w} = \left\langle -1, 0 \right\rangle
  8. \vec{v} = \left\langle 3, 4 \right\rangle and \vec{w} = \left\langle 5, 12 \right\rangle
  9. \vec{v} = \left\langle -4, -2 \right\rangle and \vec{w} = \left\langle 1, -5 \right\rangle
  10. \vec{v} = \left\langle -5, 6 \right\rangle and \vec{w} = \left\langle 4, -7 \right\rangle
  11. \vec{v} = \left\langle -8, 3 \right\rangle and \vec{w} = \left\langle 2, 6 \right\rangle
  12. \vec{v} = \left\langle 34, -91 \right\rangle and \vec{w} = \left\langle 0, 1 \right\rangle
  13. \vec{v} =3 \bm\hat{\text{i}}- \bm\hat{\text{j}} and \vec{w} = 4 \bm\hat{\text{j}}
  14. \vec{v} = -24 \bm\hat{\text{i}}+ 7 \bm\hat{\text{j}} and \vec{w} = 2 \bm\hat{\text{i}}
  15. \vec{v} =\frac{3}{2} \bm\hat{\text{i}}+ \frac{3}{2} \bm\hat{\text{j}} and \vec{w} = \bm\hat{\text{i}}- \bm\hat{\text{j}}
  16. \vec{v} = 5 \bm\hat{\text{i}}+12 \bm\hat{\text{j}} and \vec{w} = -3 \bm\hat{\text{i}}+ 4 \bm\hat{\text{j}}
  17. \vec{v} = \left\langle \frac{1}{2}, \frac{\sqrt{3}}{2} \right\rangle and \vec{w} = \left\langle -\frac{\sqrt{2}}{2}, \frac{\sqrt{2}}{2} \right\rangle
  18. \vec{v} = \left\langle \frac{\sqrt{2}}{2}, \frac{\sqrt{2}}{2} \right\rangle and \vec{w} = \left\langle \frac{1}{2}, -\frac{\sqrt{3}}{2} \right\rangle
  19. \vec{v} = \left\langle \frac{\sqrt{3}}{2}, \frac{1}{2} \right\rangle and \vec{w} = \left\langle -\frac{\sqrt{2}}{2}, -\frac{\sqrt{2}}{2} \right\rangle
  20. \vec{v} = \left\langle \frac{1}{2}, -\frac{\sqrt{3}}{2} \right\rangle and \vec{w} = \left\langle \frac{\sqrt{2}}{2}, -\frac{\sqrt{2}}{2} \right\rangle
  21. A force of 1500 pounds is required to tow a trailer. Find the work done towing the trailer along a flat stretch of road 300 feet. Assume the force is applied in the direction of the motion.
  22. Find the work done lifting a 10 pound book 3 feet straight up into the air. Assume the force of gravity is acting straight downwards.
  23. Suppose Taylor fills her wagon with rocks and must exert a force of 13 pounds to pull her wagon across the yard. If she maintains a 15^{\circ} angle between the handle of the wagon and the horizontal, compute how much work Taylor does pulling her wagon 25 feet. Round your answer to two decimal places.
  24. In Exercise 61 in Section 9.1, two drunken college students have filled an empty beer keg with rocks which they drag down the street by pulling on two attached ropes. The stronger of the two students pulls with a force of 100 pounds on a rope which makes a 13^{\circ} angle with the direction of motion. (In this case, the keg was being pulled due east and the student’s heading was N77^{\circ}E.) Find the work done by this student if the keg is dragged 42 feet.
  25. Find the work done pushing a 200 pound barrel 10 feet up a 12.5^{\circ} incline. Ignore all forces acting on the barrel except gravity, which acts downwards. Round your answer to two decimal places.
    HINT: Because you are working to overcome gravity only, the force being applied acts directly upwards. This means that the angle between the applied force in this case and the motion of the object is not the 12.5^{\circ} of the incline!
  26. Prove the distributive property of the dot product in Theorem 9.5.
  27. Finish the proof of the scalar property of the dot product in Theorem 9.5.
  28. Show Theorem 9.10 reduces to Theorem 9.4 in the case \vec{w} = \bm\hat{\text{i}}.
  29. Use the identity in Example 9.2.1 to prove the Parallelogram Law

        \[ \|\vec{v}\|^2 + \|\vec{w}\|^2 = \dfrac{1}{2}\left[ \| \vec{v} + \vec{w}\|^2 + \|\vec{v} - \vec{w}\|^2\right] \]

  30. We know that |x + y| \leq |x| + |y| for all real numbers x and y by the Triangle Inequality established in Exercise 55 in Section 1.4. We can now establish a Triangle Inequality for vectors. In this exercise, we prove that \| \vec{u} + \vec{v} \| \leq \| \vec{u} \| + \| \vec{v} \| for all pairs of vectors \vec{u} and \vec{v}.
    1. (Step 1) Show that \| \vec{u} + \vec{v} \|^{2} = \| \vec{u} \|^{2} + 2\vec{u} \cdot \vec{v} + \| \vec{v} \|^{2}.
    2. (Step 2) Show that |\vec{u} \cdot \vec{v}| \leq \| \vec{u} \| \| \vec{v} \|. This is the celebrated Cauchy-Schwarz Inequality.[6]
      HINT: Start with |\vec{u} \cdot \vec{v}| = |\; \| \vec{u} \| \| \vec{v} \|\cos(\theta) \;| and use the fact that |\cos(\theta)| \leq 1 for all \theta.
    3. (Step 3) Show:

          \[\| \vec{u} + \vec{v} \|^{2} = \| \vec{u} \|^{2} + 2\vec{u} \cdot \vec{v} + \| \vec{v} \|^{2} \leq \| \vec{u} \|^{2} + 2|\vec{u} \cdot \vec{v}| + \| \vec{v} \|^{2} \leq \| \vec{u} \|^{2} + 2\| \vec{u} \| \| \vec{v} \| + \| \vec{v} \|^{2} = (\| \vec{u} \| + \| \vec{v} \|)^{2}.\]

    4. (Step 4) Use Step 3 to show that \| \vec{u} + \vec{v} \| \leq \| \vec{u} \| + \| \vec{v} \| for all pairs of vectors \vec{u} and \vec{v}.

 

Section 9.2 Exercise Answers can be found in the Appendix … Coming soon


  1. Because \vec{v} = \| \vec{v} \| \bm\hat{v} and \vec{w} = \| \vec{w} \| \bm\hat{w}, if \bm\hat{v} = \bm\hat{w} then \vec{w} = \|\vec{w}\| \bm\hat{v} = \frac{\| \vec{w} \|}{\| \vec{v} \|} (\| \vec{v} \| \bm\hat{v}) = \frac{\| \vec{w} \|}{\| \vec{v} \|} \vec{v}. In this case, k = \frac{\| \vec{w} \|}{\| \vec{v} \|} > 0.
  2. See Exercise 41 in Section 1.3.1.
  3. In this case, the point R coincides with the point O, so \vec{p} = \overrightarrow{OR} = \overrightarrow{OO} = \vec{0}.
  4. Note that, necessarily, \vec{q} \perp \vec{p} as well!
  5. See Exercise 64 in Section 9.1.
  6. It is also known by other names. Check out this site for details.
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