Difference between revisions of "Absolute value"
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− | + | '''Absolute value''' is a [[function]] measuring a number's distance from zero. The absolute value of <math>x</math> is written <math>|x|</math>. | |
− | + | *If <math>x</math> is a positive number, then <math>|x| = x</math>. | |
+ | *If <math>x</math> is a negative number, then <math>|x| = -x</math>. | ||
+ | *If <math>x=0</math> then <math>|x| = 0</math>. | ||
− | + | For example, <math>|-3| = 3</math>, and <math>|5| = 5</math>. Notice that <math>|x|</math> is never negative. | |
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Absolute value has several useful properties. One is the ''multiplicative'' property. If <math>x</math> and <math>y</math> are two numbers, then <math>|xy| = |x| \times |y|</math>. Another is the ''triangle inequality'', which is the fact that <math>|x+y| \leq |x| + |y|</math>. For example, if <math>x = 3</math> and <math>y = -5</math>, then <math>|x+y| = |3 + (-5)| = |3 - 5| = |-2| = 2</math>, while <math>|x| + |y| = |-5| + |3| = 5 + 3 = 8</math>. In this case, the triangle inequality is the fact that 2 is not more than 8. | Absolute value has several useful properties. One is the ''multiplicative'' property. If <math>x</math> and <math>y</math> are two numbers, then <math>|xy| = |x| \times |y|</math>. Another is the ''triangle inequality'', which is the fact that <math>|x+y| \leq |x| + |y|</math>. For example, if <math>x = 3</math> and <math>y = -5</math>, then <math>|x+y| = |3 + (-5)| = |3 - 5| = |-2| = 2</math>, while <math>|x| + |y| = |-5| + |3| = 5 + 3 = 8</math>. In this case, the triangle inequality is the fact that 2 is not more than 8. | ||
− | [[Complex number]]s also have an absolute value. If <math>z = x+iy</math> is a complex number with real part <math>x</math> and imaginary part <math>y</math>, then <math>|z| = \sqrt{x^2 + y^2}</math>. If we represent <math>z</math> as a point in the complex plane with coordinates <math>(x,y)</math>, then <math>|z|</math> is the distance from this point to the origin. The absolute value of complex numbers also has the multiplicative property and satisfies the triangle inequality. | + | If <math>x</math> is a [[real number]], then <math>\sqrt{x^2} = |x|</math>. The absolute value is necessary because the principal [[square root]] is, by definition, nonnegative. |
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+ | [[Complex number]]s also have an absolute value (sometimes called the modulus). If <math>z = x+iy</math> is a complex number with real part <math>x</math> and imaginary part <math>y</math>, then <math>|z| = \sqrt{x^2 + y^2}</math>. If we represent <math>z</math> as a point in the complex plane with coordinates <math>(x,y)</math>, then <math>|z|</math> is the distance from this point to the origin. The absolute value of complex numbers also has the multiplicative property and satisfies the triangle inequality. | ||
− | [[Category:Algebra]] | + | [[Category:Algebra Terms]] |
Latest revision as of 23:05, March 1, 2021
Absolute value is a function measuring a number's distance from zero. The absolute value of is written .
- If is a positive number, then .
- If is a negative number, then .
- If then .
For example, , and . Notice that is never negative.
Absolute value has several useful properties. One is the multiplicative property. If and are two numbers, then . Another is the triangle inequality, which is the fact that . For example, if and , then , while . In this case, the triangle inequality is the fact that 2 is not more than 8.
If is a real number, then . The absolute value is necessary because the principal square root is, by definition, nonnegative.
Complex numbers also have an absolute value (sometimes called the modulus). If is a complex number with real part and imaginary part , then . If we represent as a point in the complex plane with coordinates , then is the distance from this point to the origin. The absolute value of complex numbers also has the multiplicative property and satisfies the triangle inequality.