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Scalar Projections

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As an engineer, or a pilot, or racecar driver, or even a chef, it can often be useful to determine the result of different amounts and directions of force applied to a particular action to decide on the best use of added strength, altitude, speed, or heat in order to achieve the optimum result.

This lesson is about scalar projections , which allow you to do the things above and a whole host of others.

Watch This

Embedded Video:

- Khan Academy: Introduction to Projections

Guidance

A scalar projection allows you to investigate the result of different "lengths" of one vector on an overall study. The projection of a vector onto a particular direction is, in effect, the result of applying a specific value in that direction. Recall that the dot product of a vector is a scalar quantity describing only the magnitude of a particular vector. A scalar projection is given by the dot product of a vector with a unit vector for that direction.

For example, the component notations for the vectors shown below are AB =\left \langle {4,3} \right \rangle and D =\left \langle {3,-1.25} \right \rangle .

The scalar projection of vector AB onto \hat{x} is given by

\overrightarrow{AB} \times \hat{x}=(4 \cdot 1)+(3 \cdot 0)+(0 \cdot 0)=4

The scalar projection of vector AB onto \hat{y} is given by

\overrightarrow{AB} \times \hat{y}=(4 \cdot 0)+(3 \cdot 1)+(0 \cdot 0)=3

And the scalar projection of vector AB onto \hat{z} is given by

\overrightarrow{AB} \times \hat{z}=(4 \cdot 0)+(3 \cdot 0)+(0 \cdot 1)=0

The scalar projections of AB onto the x and y directions are non-zero numbers because the vector is located in the x-y plane. The scalar projection of AB onto the z direction is equal to zero, because the z direction is perpendicular to AB .

Vector Projections

The vector projection of a vector onto a given direction has a magnitude equal to the scalar projection. The direction of the vector projection is the same as the unit vector of that given direction. Recall that when a vector \overrightarrow{v} is multiplied by a scalar s , its components are given by

\overrightarrow{sv}=\left \langle sv_x,sv_y,sv_z \right \rangle

To calculate the vector projection of AB onto the direction of vector D , use the scalar projection calculated in the previous example and the unit vector \overrightarrow{D} .

(\overrightarrow{AB}\ \times \overrightarrow{D}) \overrightarrow{D}=\left \langle (1.23 \cdot 0.923),(1.23 \cdot -0.385)\right \rangle=\left \langle 1.135,-0.474 \right \rangle

This process is clearly explained in the video above.

Example A

The diagram below shows both vectors AB and D together on the same grid. Determine the scalar projection of vector AB onto the direction of vector D .

Solution: To find the scalar projection onto the direction of another vector we need to know the unit vector in the direction of vector D .

First, the components of \overrightarrow{D} are

\overrightarrow{D}=\left \langle 3,-1.25 \right \rangle

Now the magnitude of \overrightarrow{D} is

|D|=\sqrt{(D_x)^2+(D_y)^2}=\sqrt{3^2+(-1.25)^2}=\sqrt{9+1.5625}=\sqrt{10.5625} =3.25 .

Finally, the direction vector of \overrightarrow{D} is

\overrightarrow{D}=\frac{\overrightarrow{D}}{|D|}=\frac{3\hat{x}+(-1.25)\hat{y}}{3.25}=\frac{3}{3.25}\ \hat{x}+\frac{-1.25}{3.25}\ \hat{y} .

\overrightarrow{D}=\left \langle 0.923,-0.385 \right \rangle

Now we can use the dot-product to calculate the scalar projection of AB onto the direction of vector D .

\overrightarrow{AB}\ \times \overrightarrow{D}=(3 \cdot 0.923)+(4 \cdot -0.385)+(0 \cdot 0)=2.769+(-1.54)=1.23

Example B

Determine the scalar projection of the vector \overrightarrow{R}=\left \langle 27,39,52 \right \rangle onto the direction of \overrightarrow{T}=\left \langle 44,26,17 \right \rangle .

Solution

The scalar projection of one vector onto the direction of the other is the dot product of the first vector with the unit vector representing the direction of the second vector. To calculate the scalar projection, we need to determine the unit vector in the direction of vector \overrightarrow{T}=\left \langle 44,26,17\right \rangle . Remember that a unit vector is equal to the ratio of the vector and its magnitude, therefore we first need to calculate the length of vector \overrightarrow{T}

|\overrightarrow{T}|=\sqrt{T_x^2+T_y^2+T_z^2}=\sqrt{(44)^2+(26)^2 +(17)^2}=\sqrt{1936+676+289} =\sqrt{2901}=53.86

\overrightarrow{T}=\frac{\overrightarrow{T}}{|\overrightarrow{T}|}=\frac{\left \langle 44,26,17 \right \rangle}{53.86}=\left \langle \frac{44}{53.86},\frac{26}{53.86},\frac{17}{53.86} \right \rangle=\left \langle 0.8169,0.4827,0.3156 \right \rangle

Now we can calculate the scalar projection of \overrightarrow{R} onto \overrightarrow{T} by calculating the dot product

\overrightarrow{R} \times \overrightarrow{T}=(27 \cdot 0.8169)+(39 \cdot 0.4827)+(52 \cdot 0.3156)=22.0563+18.6253 + 16.4112=57.0928

Example C

Determine the vector projection of \overrightarrow{A} onto the direction of \overrightarrow{B} and the vector projection of \overrightarrow{B} onto the direction of \overrightarrow{A} . \overrightarrow{A}=7cm @ 0^\circ and \overrightarrow{B}=4cm @ -22^\circ .

Solution

The vector projection of one vector onto the direction of another vector is given by (\overrightarrow{A} \times \overrightarrow{B})\overrightarrow{B} , where \overrightarrow{B} is the unit vector in the direction of \overrightarrow{B} . Since it is a unit vector \overrightarrow{B} has a magnitude of 1 and has the same direction as \overrightarrow{B} ,\overrightarrow{B}=1 @ -22^\circ . Therefore, (\overrightarrow{A} \times \overrightarrow{B})  \overrightarrow{B}=(|\overrightarrow{A}||\overrightarrow{B}|\ \mbox{cos}\ \theta) \overrightarrow{B}=\left ((7)(1)\ \mbox{cos}\ 22\right ) @ -22^\circ = 6.49 @ -22^\circ

The vector projection of one vector onto the direction of another vector is given by (\overrightarrow{B} \times \overrightarrow{A})\overrightarrow{A} , where \overrightarrow{A} is the unit vector in the direction of \overrightarrow{A} . Since it is a unit vector \overrightarrow{A} has a magnitude of 1 and has the same direction as \overrightarrow{A} , \overrightarrow{A}=1 @ 0^\circ . Therefore, (\overrightarrow{B} \times \overrightarrow{A})\overrightarrow{A}=(|\overrightarrow{B}||\overrightarrow{A}|\ \mbox{cos}\ \theta)\overrightarrow{A}=((4)(1)\mbox{cos}\ 22) @ 0^\circ = 3.71 @ 0^\circ

Vocabulary

A projection describes the effect of a quantity, either vector or scalar, on a given direction.

A dot product is the calculated magnitude of a given vector or vectors in a given direction.

Guided Practice

Questions

1) Determine the vector projection of vector \overrightarrow{MN} onto the vector \overrightarrow{KL}

Solution

1) The vector progression of one vector onto a second vector is the multiplication of the dot products of the two vectors and the unit vector defining the direction of the second vector. In this case, (\overrightarrow{MN} \times \overrightarrow{KL})\overrightarrow{KL} . First we need to identify the components of the two vectors by using the information given on the graph. In this case, \overrightarrow{MN}=\left \langle -2.25,0.0\right \rangle and \overrightarrow{KL}=\left \langle 1.5,2,0 \right \rangle . Then we need to determine the dot product of the two vectors.

\overrightarrow{MN} \times \overrightarrow{KL}=(MN)_x \ (KL)_x  \ +  \ (MN)_y \ (KL)_y  \ +  \ (MN)_z \ (KL)_z = (2.25)(1.5) + (2)(0) + (0)(0) = 3.375

We also need to determine the unit vector in the direction of \overrightarrow{KL} .Remember that a unit vector is equal to the ratio of the vector and its magnitude, therefore we first need to calculate the length of vector \overrightarrow{KL} .

|\overrightarrow{KL}|=\sqrt{(KL)_x^2+(KL)_y^2+(KL)_z^2}=\sqrt{(1.5)^2+(2)^2+(0)^2}=\sqrt{2.25+4+0} = \sqrt{6.25}=2.5

\overrightarrow{KL}=\frac{\overrightarrow{KL}}{|\overrightarrow{KL}|}=\frac{\left \langle 1.5,2.0, 0 \right \rangle}{2.5}=\left \langle \frac{1.5}{2.5},\frac{2}{2.5},\frac{0}{2.5} \right \rangle=\left \langle 0.6,0.8,0 \right \rangle

Lastly, we multiply the dot product of the two vectors by this unit vector,

(\overrightarrow{MN} \times \overrightarrow{KL}) \overrightarrow{KL}=(3.375)\left \langle 0.6,0.8,0 \right \rangle=\left \langle 2.025,2.7,0 \right \rangle

Practice

Scalar Multiples 51 - 55

  1. Calculate the result of a scalar multiple of 6 on the vector \left \langle 1, 19\right \rangle
  2. Calculate the result of a scalar multiple of (-8) on the vector \left \langle 7, 8 \right \rangle
  3. Calculate the result of a scalar multiple of 15 on the vector \left \langle -7, 3\right \rangle
  4. Calculate the result of a scalar multiple of (-11) on the vector \left \langle -9, 20\right \rangle
  5. Calculate the result of a scalar multiple of 16 on the vector \left \langle 9, 10\right \rangle

Scalar Projections 71-80

  1. Given Vector A = \left \langle -4, 6  \right \rangle and Vector B = \left \langle  9, 15 \right \rangle What is the projection of A onto B?
  2. What is the projection of \left \langle 2, 10  \right \rangle onto \left \langle 1, 3  \right \rangle ?
  3. Given Vector C = \left \langle 1, 2 \right \rangle and Vector D = \left \langle 1, 11 \right \rangle What is the projection of C onto D?
  4. Given Vector E = \left \langle -5, 3 \right \rangle and Vector F = \left \langle -1, 18 \right \rangle What is the projection of E onto F?
  5. What is the projection of \left \langle -2, 1 \right \rangle onto \left \langle  -5, 6 \right \rangle ?
  6. Given Vector H = \left \langle 8i + 11j  \right \rangle and Vector I = \left \langle -2i + 15j \right \rangle What is the projection of H onto I?
  7. What is the projection of \left \langle -1, 6 \right \rangle onto \left \langle  8, 16 \right \rangle ?
  8. What is the projection of \left \langle -1, 8 \right \rangle onto \left \langle  7, 8  \right \rangle ?
  9. Given Vector J = \left \langle -4i + 8j  \right \rangle and Vector K = \left \langle -8i + 10j \right \rangle What is the projection of J onto K?
  10. Given Vector L = \left \langle -4,3 \right \rangle and Vector M = \left \langle 7, 17 \right \rangle What is the projection of L onto M?

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