Skip to main content

Section 1.1 Linear Systems, Vector Equations, and Augmented Matrices (E1)

Definition 1.1.1.

A linear equation is an equation of the variables \(x_i\) of the form

\begin{equation*} a_1x_1+a_2x_2+\dots+a_nx_n=b\text{.} \end{equation*}

A solution for a linear equation is a Euclidean vector

\begin{equation*} \left[\begin{array}{c} s_1 \\ s_2 \\ \vdots \\ s_n \end{array}\right] \end{equation*}

that satisfies

\begin{equation*} a_1s_1+a_2s_2+\dots+a_ns_n=b \end{equation*}

(that is, a Euclidean vector that can be plugged into the equation).

Remark 1.1.2.

In previous classes you likely used the variables \(x,y,z\) in equations. However, since this course often deals with equations of four or more variables, we will often write our variables as \(x_i\text{,}\) and assume \(x=x_1,y=x_2,z=x_3,w=x_4\) when convenient.

Definition 1.1.3.

A system of linear equations (or a linear system for short) is a collection of one or more linear equations.

\begin{alignat*}{5} a_{11}x_1 &\,+\,& a_{12}x_2 &\,+\,& \dots &\,+\,& a_{1n}x_n &\,=\,& b_1 \\ a_{21}x_1 &\,+\,& a_{22}x_2 &\,+\,& \dots &\,+\,& a_{2n}x_n &\,=\,& b_2\\ \vdots& &\vdots& && &\vdots&&\vdots \\ a_{m1}x_1 &\,+\,& a_{m2}x_2 &\,+\,& \dots &\,+\,& a_{mn}x_n &\,=\,& b_m \end{alignat*}

Its solution set is given by

\begin{equation*} \setBuilder { \left[\begin{array}{c} s_1 \\ s_2 \\ \vdots \\ s_n \end{array}\right] }{ \left[\begin{array}{c} s_1 \\ s_2 \\ \vdots \\ s_n \end{array}\right] \text{is a solution to all equations in the system} }\text{.} \end{equation*}

Remark 1.1.4.

When variables in a large linear system are missing, we prefer to write the system in one of the following standard forms:

Original linear system:

\begin{alignat*}{2} x_1 + 3x_3 &\,=\,& 3\\ 3x_1 - 2x_2 + 4x_3 &\,=\,& 0\\ -x_2 + x_3 &\,=\,& -2 \end{alignat*}

Verbose standard form:

\begin{alignat*}{4} 1x_1 &\,+\,& 0x_2 &\,+\,& 3x_3 &\,=\,& 3\\ 3x_1 &\,-\,& 2x_2 &\,+\,& 4x_3 &\,=\,& 0\\ 0x_1 &\,-\,& 1x_2 &\,+\,& 1x_3 &\,=\,& -2 \end{alignat*}

Concise standard form:

\begin{alignat*}{4} x_1 & & &\,+\,& 3x_3 &\,=\,& 3\\ 3x_1 &\,-\,& 2x_2 &\,+\,& 4x_3 &\,=\,& 0\\ &\,-\,& x_2 &\,+\,& x_3 &\,=\,& -2 \end{alignat*}

Remark 1.1.5.

It will often be convenient to think of a system of equations as a vector equation.

By applying vector operations and equating components, it is straightforward to see that the vector equation

\begin{equation*} x_1 \left[\begin{array}{c} 1 \\ 3 \\ 0 \end{array}\right]+ x_2 \left[\begin{array}{c} 0 \\ -2 \\ -1 \end{array}\right] + x_3 \left[\begin{array}{c} 3 \\ 4 \\1 \end{array}\right] = \left[\begin{array}{c} 3 \\ 0 \\ -2 \end{array}\right] \end{equation*}

is equivalent to the system of equations

\begin{alignat*}{4} x_1 & & &\,+\,& 3x_3 &\,=\,& 3\\ 3x_1 &\,-\,& 2x_2 &\,+\,& 4x_3 &\,=\,& 0\\ &\,-\,& x_2 &\,+\,& x_3 &\,=\,& -2 \end{alignat*}

Definition 1.1.6.

A linear system is consistent if its solution set is non-empty (that is, there exists a solution for the system). Otherwise it is inconsistent.

Activity 1.1.8.

All inconsistent linear systems contain a logical contradiction. Find a contradiction in this system to show that its solution set is the empty set.

\begin{align*} -x_1+2x_2 &= 5\\ 2x_1-4x_2 &= 6 \end{align*}

Activity 1.1.9.

Consider the following consistent linear system.

\begin{align*} -x_1+2x_2 &= -3\\ 2x_1-4x_2 &= 6 \end{align*}

(a)

Find three different solutions for this system.

(b)

Let \(x_2=a\) where \(a\) is an arbitrary real number, then find an expression for \(x_1\) in terms of \(a\text{.}\) Use this to write the solution set \(\setBuilder { \left[\begin{array}{c} \unknown \\ a \end{array}\right] }{ a \in \IR }\) for the linear system.

Activity 1.1.10.

Consider the following linear system.

\begin{alignat*}{5} x_1 &\,+\,& 2x_2 &\, \,& &\,-\,& x_4 &\,=\,& 3\\ &\, \,& &\, \,& x_3 &\,+\,& 4x_4 &\,=\,& -2 \end{alignat*}

Describe the solution set

\begin{equation*} \setBuilder { \left[\begin{array}{c} \unknown \\ a \\ \unknown \\ b \end{array}\right] }{ a,b \in \IR } \end{equation*}

to the linear system by setting \(x_2=a\) and \(x_4=b\text{,}\) and then solving for \(x_1\) and \(x_3\text{.}\)

Observation 1.1.11.

Solving linear systems of two variables by graphing or substitution is reasonable for two-variable systems, but these simple techniques won't usually cut it for equations with more than two variables or more than two equations. For example,

\begin{alignat*}{5} -2x_1 &\,-\,& 4x_2 &\,+\,& x_3 &\,-\,& 4x_4 &\,=\,& -8\\ x_1 &\,+\,& 2x_2 &\,+\,& 2x_3 &\,+\,& 12x_4 &\,=\,& -1\\ x_1 &\,+\,& 2x_2 &\,+\,& x_3 &\,+\,& 8x_4 &\,=\,& 1 \end{alignat*}

has the exact same solution set as the system in the previous activity, but we'll want to learn new techniques to compute these solutions efficiently.

Remark 1.1.12.

The only important information in a linear system are its coefficients and constants.

Original linear system:

\begin{alignat*}{2} x_1 + 3x_3 &\,=\,& 3\\ 3x_1 - 2x_2 + 4x_3 &\,=\,& 0\\ -x_2 + x_3 &\,=\,& -2 \end{alignat*}

Verbose standard form:

\begin{alignat*}{4} 1x_1 &\,+\,& 0x_2 &\,+\,& 3x_3 &\,=\,& 3\\ 3x_1 &\,-\,& 2x_2 &\,+\,& 4x_3 &\,=\,& 0\\ 0x_1 &\,-\,& 1x_2 &\,+\,& 1x_3 &\,=\,& -2 \end{alignat*}

Coefficients/constants:

\begin{alignat*}{4} 1 & & 0 &\,\,& 3 &\,|\,& 3\\ 3 &\, \,& -2 &\,\,& 4 &\,|\,& 0\\ 0 &\, \,& -1 &\,\,& 1 &\,|\,& -2 \end{alignat*}

Definition 1.1.13.

A system of \(m\) linear equations with \(n\) variables is often represented by writing its coefficients and constants in an augmented matrix.

\begin{alignat*}{5} a_{11}x_1 &\,+\,& a_{12}x_2 &\,+\,& \dots &\,+\,& a_{1n}x_n &\,=\,& b_1\\ a_{21}x_1 &\,+\,& a_{22}x_2 &\,+\,& \dots &\,+\,& a_{2n}x_n &\,=\,& b_2\\ \vdots& &\vdots& && &\vdots&&\vdots\\ a_{m1}x_1 &\,+\,& a_{m2}x_2 &\,+\,& \dots &\,+\,& a_{mn}x_n &\,=\,& b_m \end{alignat*}
\begin{equation*} \left[\begin{array}{cccc|c} a_{11} & a_{12} & \cdots & a_{1n} & b_1\\ a_{21} & a_{22} & \cdots & a_{2n} & b_2\\ \vdots & \vdots & \ddots & \vdots & \vdots\\ a_{m1} & a_{m2} & \cdots & a_{mn} & b_m \end{array}\right] \end{equation*}

Example 1.1.14.

The corresponding augmented matrix for this system is obtained by simply writing the coefficients and constants in matrix form.

Linear system:

\begin{alignat*}{2} x_1 + 3x_3 &\,=\,& 3\\ 3x_1 - 2x_2 + 4x_3 &\,=\,& 0\\ -x_2 + x_3 &\,=\,& -2 \end{alignat*}

Augmented matrix:

\begin{equation*} \left[\begin{array}{ccc|c} 1 & 0 & 3 & 3 \\ 3 & -2 & 4 & 0 \\ 0 & -1 & 1 & -2 \end{array}\right] \end{equation*}

Vector equation:

\begin{equation*} x_1 \left[\begin{array}{c} 1 \\ 3 \\ 0 \end{array}\right]+ x_2 \left[\begin{array}{c} 0 \\ -2 \\ -1 \end{array}\right] + x_3 \left[\begin{array}{c} 3 \\ 4 \\1 \end{array}\right] = \left[\begin{array}{c} 3 \\ 0 \\ -2 \end{array}\right] \end{equation*}

Subsection 1.1.1 Videos

Figure 1.1.15. Video: Converting between systems, vector equations, and augmented matrices

Exercises 1.1.2 Exercises

Exercises available at checkit.clontz.org 1 .

https://checkit.clontz.org/#/banks/tbil-la/E1/