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Linear equation
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<h2 id="one-variable">One variable</h2> <p>A linear equation in one variable x can be written as a x + b = 0 , {\displaystyle ax+b=0,} with a ≠ 0 {\displaystyle a\neq 0} . </p><p>The solution is x = − b a {\displaystyle x=-{\frac {b}{a}}} . </p> <h2 id="two-variables">Two variables</h2> <p>A linear equation in two variables x and y can be written as a x + b y + c = 0 , {\displaystyle ax+by+c=0,} where a and b are not both 0.<a class="footnote-ref" id="fnref:1" href="#fn:1"><sup>1</sup></a> </p><p>If a and b are real numbers, it has infinitely many solutions. </p> <h3>Linear function</h3> <p class="note">Main article: <a href="/facts/Linear_function_(calculus)/sbyEbb6x">Linear function (calculus)</a></p> <p>If <i>b</i> ≠ 0, the equation </p> a x + b y + c = 0 {\displaystyle ax+by+c=0} <p>is a linear equation in the single variable y for every value of x. It therefore has a unique solution for y, which is given by </p> y = − a b x − c b . {\displaystyle y=-{\frac {a}{b}}x-{\frac {c}{b}}.} <p>This defines a <a href="/facts/Function_(mathematics)/CdReEKCh">function</a>. The <a href="/facts/Graph_of_a_function/htYX0BGX">graph</a> of this function is a <a href="/facts/Line_(geometry)/gJqsr4Gj">line</a> with <a href="/facts/Slope_(mathematics)/a2L3k0j5">slope</a> − a b {\displaystyle -{\frac {a}{b}}} and <a href="/facts/Y-intercept/oJvV25PI">y-intercept</a> − c b . {\displaystyle -{\frac {c}{b}}.} The functions whose graph is a line are generally called <i>linear functions</i> in the context of <a href="/facts/Calculus/MEmUTYoz">calculus</a>. However, in <a href="/facts/Linear_algebra/8VaB4VWk">linear algebra</a>, a <a href="/facts/Linear_function/Ejvy8CKy">linear function</a> is a function that maps a sum to the sum of the images of the summands. So, for this definition, the above function is linear only when <i>c</i> = 0, that is when the line passes through the origin. To avoid confusion, the functions whose graph is an arbitrary line are often called <i><a href="/facts/Affine_function/BD7yDr10">affine functions</a></i>, and the linear functions such that <i>c</i> = 0 are often called <i><a href="/facts/Linear_map/Q1PBKNVV">linear maps</a></i>. </p> <h3>Geometric interpretation</h3> <p>Each solution (<i>x</i>, <i>y</i>) of a linear equation </p> a x + b y + c = 0 {\displaystyle ax+by+c=0} <p>may be viewed as the <a href="/facts/Cartesian_coordinates/lkTqvMmB">Cartesian coordinates</a> of a point in the <a href="/facts/Euclidean_plane/tAUtRFcn">Euclidean plane</a>. With this interpretation, all solutions of the equation form a <a href="/facts/Line_(geometry)/gJqsr4Gj">line</a>, provided that a and b are not both zero. Conversely, every line is the set of all solutions of a linear equation. </p><p>The phrase "linear equation" takes its origin in this correspondence between lines and equations: a <i>linear equation</i> in two variables is an equation whose solutions form a line. </p><p>If <i>b</i> ≠ 0, the line is the <a href="/facts/Graph_of_a_function/htYX0BGX">graph of the function</a> of x that has been defined in the preceding section. If <i>b</i> = 0, the line is a <i>vertical line</i> (that is a line parallel to the y-axis) of equation x = − c a , {\displaystyle x=-{\frac {c}{a}},} which is not the graph of a function of x. </p><p>Similarly, if <i>a</i> ≠ 0, the line is the graph of a function of y, and, if <i>a</i> = 0, one has a horizontal line of equation y = − c b . {\displaystyle y=-{\frac {c}{b}}.} </p> <h3>Equation of a line</h3> <p>There are various ways of defining a line. In the following subsections, a linear equation of the line is given in each case. </p> <h4>Slope–intercept form or Gradient-intercept form </h4> <p>A non-vertical line can be defined by its slope m, and its y-intercept <i>y</i>0 (the y coordinate of its intersection with the y-axis). In this case, its <i>linear equation</i> can be written </p> y = m x + y 0 . {\displaystyle y=mx+y_{0}.} <p>If, moreover, the line is not horizontal, it can be defined by its slope and its x-intercept <i>x</i>0. In this case, its equation can be written </p> y = m ( x − x 0 ) , {\displaystyle y=m(x-x_{0}),} <p>or, equivalently, </p> y = m x − m x 0 . {\displaystyle y=mx-mx_{0}.} <p>These forms rely on the habit of considering a nonvertical line as the <a href="/facts/Graph_of_a_function/htYX0BGX">graph of a function</a>.<a class="footnote-ref" id="fnref:2" href="#fn:2"><sup>2</sup></a> For a line given by an equation </p> a x + b y + c = 0 , {\displaystyle ax+by+c=0,} <p>these forms can be easily deduced from the relations </p> m = − a b , x 0 = − c a , y 0 = − c b . {\displaystyle {\begin{aligned}m&=-{\frac {a}{b}},\\x_{0}&=-{\frac {c}{a}},\\y_{0}&=-{\frac {c}{b}}.\end{aligned}}} <h4>Point–slope form or Point-gradient form</h4> <p>A non-vertical line can be defined by its slope m, and the coordinates x 1 , y 1 {\displaystyle x_{1},y_{1}} of any point of the line. In this case, a linear equation of the line is </p> y = y 1 + m ( x − x 1 ) , {\displaystyle y=y_{1}+m(x-x_{1}),} <p>or </p> y = m x + y 1 − m x 1 . {\displaystyle y=mx+y_{1}-mx_{1}.} <p>This equation can also be written </p> y − y 1 = m ( x − x 1 ) {\displaystyle y-y_{1}=m(x-x_{1})} <p>to emphasize that the slope of a line can be computed from the coordinates of any two points. </p> <h4>Intercept form</h4> <p>A line that is not parallel to an axis and does not pass through the origin cuts the axes into two different points. The intercept values <i>x</i>0 and <i>y</i>0 of these two points are nonzero, and an equation of the line is<a class="footnote-ref" id="fnref:3" href="#fn:3"><sup>3</sup></a> </p> x x 0 + y y 0 = 1. {\displaystyle {\frac {x}{x_{0}}}+{\frac {y}{y_{0}}}=1.} <p>(It is easy to verify that the line defined by this equation has <i>x</i>0 and <i>y</i>0 as intercept values). </p> <h4>Two-point form</h4> <p>Given two different points (<i>x</i>1, <i>y</i>1) and (<i>x</i>2, <i>y</i>2), there is exactly one line that passes through them. There are several ways to write a linear equation of this line. </p><p>If <i>x</i>1 ≠ <i>x</i>2, the slope of the line is y 2 − y 1 x 2 − x 1 . {\displaystyle {\frac {y_{2}-y_{1}}{x_{2}-x_{1}}}.} Thus, a point-slope form is<a class="footnote-ref" id="fnref:4" href="#fn:4"><sup>4</sup></a> </p> y − y 1 = y 2 − y 1 x 2 − x 1 ( x − x 1 ) . {\displaystyle y-y_{1}={\frac {y_{2}-y_{1}}{x_{2}-x_{1}}}(x-x_{1}).} <p>By <a href="/facts/Clearing_denominators/zbfX6zV4">clearing denominators</a>, one gets the equation </p> ( x 2 − x 1 ) ( y − y 1 ) − ( y 2 − y 1 ) ( x − x 1 ) = 0 , {\displaystyle (x_{2}-x_{1})(y-y_{1})-(y_{2}-y_{1})(x-x_{1})=0,} <p>which is valid also when <i>x</i>1 = <i>x</i>2 (to verify this, it suffices to verify that the two given points satisfy the equation). </p><p>This form is not symmetric in the two given points, but a symmetric form can be obtained by regrouping the constant terms: </p> ( y 1 − y 2 ) x + ( x 2 − x 1 ) y + ( x 1 y 2 − x 2 y 1 ) = 0 {\displaystyle (y_{1}-y_{2})x+(x_{2}-x_{1})y+(x_{1}y_{2}-x_{2}y_{1})=0} <p>(exchanging the two points changes the sign of the left-hand side of the equation). </p> <h4>Determinant form</h4> <p>The two-point form of the equation of a line can be expressed simply in terms of a <a href="/facts/Determinant/eGYqJ2TF">determinant</a>. There are two common ways for that. </p><p>The equation ( x 2 − x 1 ) ( y − y 1 ) − ( y 2 − y 1 ) ( x − x 1 ) = 0 {\displaystyle (x_{2}-x_{1})(y-y_{1})-(y_{2}-y_{1})(x-x_{1})=0} is the result of expanding the determinant in the equation </p> | x − x 1 y − y 1 x 2 − x 1 y 2 − y 1 | = 0. {\displaystyle {\begin{vmatrix}x-x_{1}&y-y_{1}\\x_{2}-x_{1}&y_{2}-y_{1}\end{vmatrix}}=0.} <p>The equation ( y 1 − y 2 ) x + ( x 2 − x 1 ) y + ( x 1 y 2 − x 2 y 1 ) = 0 {\displaystyle (y_{1}-y_{2})x+(x_{2}-x_{1})y+(x_{1}y_{2}-x_{2}y_{1})=0} can be obtained by expanding with respect to its first row the determinant in the equation </p> | x y 1 x 1 y 1 1 x 2 y 2 1 | = 0. {\displaystyle {\begin{vmatrix}x&y&1\\x_{1}&y_{1}&1\\x_{2}&y_{2}&1\end{vmatrix}}=0.} <p>Besides being very simple and mnemonic, this form has the advantage of being a special case of the more general equation of a <a href="/facts/Hyperplane/2s2ycYYd">hyperplane</a> passing through n points in a space of dimension <i>n</i> − 1. These equations rely on the condition of <a href="/facts/Linear_dependence/8JrHfIIa">linear dependence</a> of points in a <a href="/facts/Projective_space/7MSpA9cM">projective space</a>. </p> <h2 id="more-than-two-variables">More than two variables</h2> <p>A linear equation with more than two variables may always be assumed to have the form </p> a 1 x 1 + a 2 x 2 + ⋯ + a n x n + b = 0. {\displaystyle a_{1}x_{1}+a_{2}x_{2}+\cdots +a_{n}x_{n}+b=0.} <p>The coefficient b, often denoted <i>a</i>0 is called the <i>constant term</i> (sometimes the <i>absolute term</i> in old books<a class="footnote-ref" id="fnref:5" href="#fn:5"><sup>5</sup></a><a class="footnote-ref" id="fnref:6" href="#fn:6"><sup>6</sup></a>). Depending on the context, the term <i>coefficient</i> can be reserved for the <i>a</i><i>i</i> with <i>i</i> > 0. </p><p>When dealing with n = 3 {\displaystyle n=3} variables, it is common to use x , y {\displaystyle x,\;y} and z {\displaystyle z} instead of indexed variables. </p><p>A solution of such an equation is a n-tuple such that substituting each element of the tuple for the corresponding variable transforms the equation into a true equality. </p><p>For an equation to be meaningful, the coefficient of at least one variable must be non-zero. If every variable has a zero coefficient, then, as mentioned for one variable, the equation is either <i>inconsistent</i> (for <i>b</i> ≠ 0) as having no solution, or all n-tuples are solutions. </p><p>The n-tuples that are solutions of a linear equation in n variables are the <a href="/facts/Cartesian_coordinates/lkTqvMmB">Cartesian coordinates</a> of the points of an (<i>n</i> − 1)-dimensional <a href="/facts/Hyperplane/2s2ycYYd">hyperplane</a> in an n-dimensional <a href="/facts/Euclidean_space/R2UbzmzM">Euclidean space</a> (or <a href="/facts/Affine_space/tlvI3oX1">affine space</a> if the coefficients are complex numbers or belong to any field). In the case of three variables, this hyperplane is a <a href="/facts/Plane_(geometry)/tAUtRFcn">plane</a>. </p><p>If a linear equation is given with <i>a</i><i>j</i> ≠ 0, then the equation can be solved for <i>x</i><i>j</i>, yielding </p> x j = − b a j − ∑ i ∈ { 1 , … , n } , i ≠ j a i a j x i . {\displaystyle x_{j}=-{\frac {b}{a_{j}}}-\sum _{i\in \{1,\ldots ,n\},i\neq j}{\frac {a_{i}}{a_{j}}}x_{i}.} <p>If the coefficients are <a href="/facts/Real_number/R02gw5Pb">real numbers</a>, this defines a <a href="/facts/Real-valued_function/jetqlJpK">real-valued</a> <a href="/facts/Function_of_several_real_variables/cyujR2q2">function of n real variables</a>. </p> <h2 id="see-also">See also</h2> <ul><li><a href="/facts/Linear_equation_over_a_ring/2rGTE3GK">Linear equation over a ring</a></li> <li><a href="/facts/Algebraic_equation/1QauIGxs">Algebraic equation</a></li> <li><a href="/facts/Line_coordinates/Hk9UeN0t">Line coordinates</a></li> <li><a href="/facts/Linear_inequality/YGHD3tW5">Linear inequality</a></li> <li><a href="/facts/Nonlinear_system/4aYItALC">Nonlinear equation</a></li></ul> <h2 id="notes">Notes</h2> <ul><li>Barnett, R.A.; Ziegler, M.R.; Byleen, K.E. (2008), <i>College Mathematics for Business, Economics, Life Sciences and the Social Sciences</i> (11th ed.), Upper Saddle River, N.J.: Pearson, <a href="/facts/ISBN_(identifier)/15AdSPa9">ISBN</a> 978-0-13-157225-6</li> <li>Larson, Ron; Hostetler, Robert (2007), <a href="https://archive.org/details/precalculusconci00lars"><i>Precalculus:A Concise Course</i></a>, Houghton Mifflin, <a href="/facts/ISBN_(identifier)/15AdSPa9">ISBN</a> 978-0-618-62719-6</li> <li>Wilson, W.A.; Tracey, J.I. (1925), <i>Analytic Geometry</i> (revised ed.), D.C. Heath</li></ul> <h2 id="external-links">External links</h2> <ul><li><a href="https://www.encyclopediaofmath.org/index.php?title=Linear_equation">"Linear equation"</a>, <i><a href="/facts/Encyclopedia_of_Mathematics/WC6mGtPm">Encyclopedia of Mathematics</a></i>, <a href="/facts/European_Mathematical_Society/B3h7b672">EMS Press</a>, 2001 [1994]</li></ul> <h2 id="references">References</h2> <ol> <li id="fn:1"><p>Barnett, Ziegler & Byleen 2008, pg. 15 - Barnett, R.A.; Ziegler, M.R.; Byleen, K.E. (2008), College Mathematics for Business, Economics, Life Sciences and the Social Sciences (11th ed.), Upper Saddle River, N.J.: Pearson, ISBN 978-0-13-157225-6 <a href="#fnref:1" class="footnote-back-ref">↩</a></p></li> <li id="fn:2"><p>Larson & Hostetler 2007, p. 25 - Larson, Ron; Hostetler, Robert (2007), Precalculus:A Concise Course, Houghton Mifflin, ISBN 978-0-618-62719-6 <a href="https://archive.org/details/precalculusconci00lars" target="_blank">https://archive.org/details/precalculusconci00lars</a> <a href="#fnref:2" class="footnote-back-ref">↩</a></p></li> <li id="fn:3"><p>Wilson & Tracey 1925, pp. 52-53 - Wilson, W.A.; Tracey, J.I. (1925), Analytic Geometry (revised ed.), D.C. Heath <a href="#fnref:3" class="footnote-back-ref">↩</a></p></li> <li id="fn:4"><p>Wilson & Tracey 1925, pp. 52-53 - Wilson, W.A.; Tracey, J.I. (1925), Analytic Geometry (revised ed.), D.C. Heath <a href="#fnref:4" class="footnote-back-ref">↩</a></p></li> <li id="fn:5"><p>Charles Hiram Chapman (1892). An Elementary Course in Theory of Equations. J. Wiley & sons. p. 17. Extract of page 17 <a href="https://books.google.com/books?id=2PQGAAAAYAAJ" target="_blank">https://books.google.com/books?id=2PQGAAAAYAAJ</a> <a href="#fnref:5" class="footnote-back-ref">↩</a></p></li> <li id="fn:6"><p>David Martin Sensenig (1890). Numbers Universalized: An Advanced Algebra. American Book Company. p. 113. Extract of page 113 <a href="https://books.google.com/books?id=TvMGAAAAYAAJ" target="_blank">https://books.google.com/books?id=TvMGAAAAYAAJ</a> <a href="#fnref:6" class="footnote-back-ref">↩</a></p></li> </ol>