Difference between revisions of "Equation of a Line"

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===Equation of a line===
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== Equation of a line ==
 
There are various ways of defining a line. In the following subsections, a linear equation of the line is given in each case.
 
There are various ways of defining a line. In the following subsections, a linear equation of the line is given in each case.
 
   
 
   
 
====Slope–intercept form or Gradient-intercept form====
 
====Slope–intercept form or Gradient-intercept form====
A non-vertical line can be defined by its slope {{mvar|m}}, and its {{mvar|y}}-intercept {{math|''y''{{sub|0}}}} (the {{mvar|y}} coordinate of its intersection with the {{mvar|y}}-axis). In this case its ''linear equation'' can be written  
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A non-vertical line can be defined by its slope {{mvar|m}}, and its {{mvar|y}}-intercept ''y''<sub>0</sub> (the {{mvar|y}} coordinate of its intersection with the {{mvar|y}}-axis). In this case its ''linear equation'' can be written  
 
:<math>y=mx+y_0.</math>
 
:<math>y=mx+y_0.</math>
  
If, moreover, the line is not horizontal, it can be defined by its slope and its {{mvar|x}}-intercept {{math|''x''{{sub|0}}}}. In this case, its equation can be written
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If, moreover, the line is not horizontal, it can be defined by its slope and its {{mvar|x}}-intercept ''x''<sub>0</sub>. In this case, its equation can be written
 
:<math>y=m(x-x_0),</math>
 
:<math>y=m(x-x_0),</math>
 
or, equivalently,
 
or, equivalently,
 
:<math>y=mx-mx_0.</math>
 
:<math>y=mx-mx_0.</math>
  
These forms rely on the habit of considering a non vertical line as the [[graph of a function]].<ref>{{harvnb|Larson|Hostetler|2007|loc=p. 25}}</ref> For a line given by an equation  
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These forms rely on the habit of considering a non vertical line as the graph of a function. For a line given by an equation  
 
:<math>ax+by+c = 0,</math>
 
:<math>ax+by+c = 0,</math>
 
these forms can be easily deduced from the relations  
 
these forms can be easily deduced from the relations  
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\end{align}</math>
 
\end{align}</math>
  
====Point–slope form or Point-gradient form====
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===Point–slope form or Point-gradient form===
  
 
A non-vertical line can be defined by its slope {{mvar|m}}, and the coordinates <math>x_1, y_1</math> of any point of the line. In this case, a linear equation of the line is
 
A non-vertical line can be defined by its slope {{mvar|m}}, and the coordinates <math>x_1, y_1</math> of any point of the line. In this case, a linear equation of the line is
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for emphasizing that the slope of a line can be computed from the coordinates of any two points.
 
for emphasizing that the slope of a line can be computed from the coordinates of any two points.
  
====Intercept form====
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===Intercept form===
A line that is not parallel to an axis and does not pass through the origin cuts the axes in two different points. The intercept values {{math|''x''{{sub|0}}}} and {{math|''y''{{sub|0}}}} of these two points are nonzero, and an equation of the line is<ref name=WilsonTracey>{{harvnb|Wilson|Tracey|1925|loc=pp. 52-53}}</ref>
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A line that is not parallel to an axis and does not pass through the origin cuts the axes in two different points. The intercept values ''x''<sub>0</sub> and ''y''<sub>0</sub> of these two points are nonzero, and an equation of the line is
 
:<math>\frac{x}{x_0} + \frac{y}{y_0} = 1.</math>
 
:<math>\frac{x}{x_0} + \frac{y}{y_0} = 1.</math>
(It is easy to verify that the line defined by this equation has {{math|''x''{{sub|0}}}} and {{math|''y''{{sub|0}}}} as intercept values).
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(It is easy to verify that the line defined by this equation has ''x''<sub>0</sub> and ''y''<sub>0</sub> as intercept values).
  
====Two-point form====
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===Two-point form===
 
Given two different points {{math|(''x''{{sub|1}}, ''y''{{sub|1}})}} and {{math|(''x''{{sub|2}}, ''y''{{sub|2}})}}, there is exactly one line that passes through them. There are several ways to write a linear equation of this line.
 
Given two different points {{math|(''x''{{sub|1}}, ''y''{{sub|1}})}} and {{math|(''x''{{sub|2}}, ''y''{{sub|2}})}}, there is exactly one line that passes through them. There are several ways to write a linear equation of this line.
  
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:<math>y - y_1 = \frac{y_2 - y_1}{x_2 - x_1} (x - x_1).</math>
 
:<math>y - y_1 = \frac{y_2 - y_1}{x_2 - x_1} (x - x_1).</math>
  
By [[clearing denominators]], one gets the equation  
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By clearing denominators, one gets the equation  
 
:<math> (x_2 - x_1)(y - y_1) - (y_2 - y_1)(x - x_1)=0,</math>
 
:<math> (x_2 - x_1)(y - y_1) - (y_2 - y_1)(x - x_1)=0,</math>
 
which is valid also when {{math|1=''x''{{sub|1}} = ''x''{{sub|2}}}} (for verifying this, it suffices to verify that the two given points satisfy the equation).
 
which is valid also when {{math|1=''x''{{sub|1}} = ''x''{{sub|2}}}} (for verifying this, it suffices to verify that the two given points satisfy the equation).
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(exchanging the two points changes the sign of the left-hand side of the equation).
 
(exchanging the two points changes the sign of the left-hand side of the equation).
  
====Determinant form====
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===Determinant form===
The two-point form of the equation of a line can be expressed simply in terms of a [[determinant]]. There are two common ways for that.
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The two-point form of the equation of a line can be expressed simply in terms of a determinant. There are two common ways for that.
  
 
The equation <math> (x_2 - x_1)(y - y_1) - (y_2 - y_1)(x - x_1)=0</math> is the result of expanding the determinant in the equation
 
The equation <math> (x_2 - x_1)(y - y_1) - (y_2 - y_1)(x - x_1)=0</math> is the result of expanding the determinant in the equation
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\end{vmatrix}=0.</math>
 
\end{vmatrix}=0.</math>
  
Beside being very simple and mnemonic, this form has the advantage of being a special case of the more general equation of a [[hyperplane]] passing through {{mvar|n}} points in a space of dimension {{math|''n'' – 1}}. These equations rely on the condition of [[linear dependence]] of points in a [[projective space]].
+
Beside being very simple and mnemonic, this form has the advantage of being a special case of the more general equation of a hyperplane passing through {{mvar|n}} points in a space of dimension {{math|''n'' – 1}}. These equations rely on the condition of linear dependence of points in a projective space.
  
 
== Licensing ==  
 
== Licensing ==  

Revision as of 15:21, 11 January 2022

Equation of a line

There are various ways of defining a line. In the following subsections, a linear equation of the line is given in each case.

Slope–intercept form or Gradient-intercept form

A non-vertical line can be defined by its slope m, and its y-intercept y0 (the y coordinate of its intersection with the y-axis). In this case its linear equation can be written

If, moreover, the line is not horizontal, it can be defined by its slope and its x-intercept x0. In this case, its equation can be written

or, equivalently,

These forms rely on the habit of considering a non vertical line as the graph of a function. For a line given by an equation

these forms can be easily deduced from the relations

Point–slope form or Point-gradient form

A non-vertical line can be defined by its slope m, and the coordinates of any point of the line. In this case, a linear equation of the line is

or

This equation can also be written

for emphasizing that the slope of a line can be computed from the coordinates of any two points.

Intercept form

A line that is not parallel to an axis and does not pass through the origin cuts the axes in two different points. The intercept values x0 and y0 of these two points are nonzero, and an equation of the line is

(It is easy to verify that the line defined by this equation has x0 and y0 as intercept values).

Two-point form

Given two different points (xTemplate:Sub, yTemplate:Sub) and (xTemplate:Sub, yTemplate:Sub), there is exactly one line that passes through them. There are several ways to write a linear equation of this line.

If xTemplate:SubxTemplate:Sub, the slope of the line is Thus, a point-slope form is[1]

By clearing denominators, one gets the equation

which is valid also when xTemplate:Sub = xTemplate:Sub (for verifying this, it suffices to verify that the two given points satisfy the equation).

This form is not symmetric in the two given points, but a symmetric form can be obtained by regrouping the constant terms:

(exchanging the two points changes the sign of the left-hand side of the equation).

Determinant form

The two-point form of the equation of a line can be expressed simply in terms of a determinant. There are two common ways for that.

The equation is the result of expanding the determinant in the equation

The equation can be obtained be expanding with respect to its first row the determinant in the equation

Beside being very simple and mnemonic, this form has the advantage of being a special case of the more general equation of a hyperplane passing through n points in a space of dimension n – 1. These equations rely on the condition of linear dependence of points in a projective space.

Licensing

Content obtained and/or adapted from:

Resources

  • Cite error: Invalid <ref> tag; no text was provided for refs named WilsonTracey