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I'm inclined to say yes, as it doesn't involve exponentiation, roots, logarithmic or trigonometric functions, but I watched a video where the teacher said that the absolute value function is "clearly non-linear". Why would he say that? Is he wrong?

Wikipedia's graph for abs:

enter image description here

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    Well what's your definition of linear function?2011-12-05
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    I'd say a function that draws a straight line when graphed on the two/three dimensional plane.2011-12-05
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    Well abs(x) doesn't satisfy that!2011-12-05
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    Why? Look at this: http://en.wikipedia.org/wiki/Absolute_value I'm confused.2011-12-05
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    [Related question](http://math.stackexchange.com/questions/67537/can-you-use-a-logarithm-coefficient-in-a-linear-equation)2011-12-05
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    Two things:that article doesn't show (just) one straight line! Also, a graphical definition usually isn't best. How about defining a linear function as a first degree polynomial? In that case, we can see that no first degree polynomial satisfies the properties of abs(x). One such property is that abs(x) is an even function, whereas f(x) = ax + b is neither even nor odd (with $a \neq 0 \neq b$)2011-12-05
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    Thanks, I ignored what you explained.2011-12-05
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    "... as it doesn't involve exponentiation, roots, logarithmic or trigonometric functions." We have to be very careful when defining things in terms of what they are *not*. For example, $y=\frac{1}{1+x^2}$ doesn't involve anything in your list, but that's not linear (graph it!). However, $y = \ln (e^{3x})$ turns out to be linear (simplify it to see what linear function it's equivalent to).2011-12-06

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Linear functions in analytic geometry are functions of the form $f(x)=a\cdot x+b$ for $a,b \in \mathbb{R}$.

Now try to write $\text{abs}(x)$ in such a form.

Another way to see it: linear functions are "straight lines" in the coordinate system (excluding vertical lines), this clearly excludes having a "sharp edge" in the graph of the function like $\text{abs}(x)$ has it for $x=0$.

In linear algebra (and this is the more common definition) linear functions denote ones of the form $f(x)=a\cdot x$ which is equivalent to require $b=0$ in the above definition. As $\text{abs}(x)$ is not linear with the first, weaker definition it cannot be linear either with this definition.

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    This is usually called an affine function; it is linear only if $b = 0$.2011-12-05
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    @Leandro Yea that is also in the article. But if $\text{abs}$ is not even affine it can neither be linear (using your definition) so it is good to use the weaker one for the question he asked.2011-12-05
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    @omgzor I did not mean to be insulting, if you read that link why don't you include your efforts into your question and tell us which part you don't understand?2011-12-05
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    @Listing I disagree. If the OP is confused about what is a linear function, bending the definitions won't do any good.2011-12-05
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    @Listing I don't think it is right to say that linear functions in geometry are those of the form $f(x) = ax + b$.2011-12-05
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    I just quote wikipedia there ( http://en.wikipedia.org/wiki/Linear_function )2011-12-05
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    It depends a great deal what level you are working at. The equation of a general straight line in the plane has the form $ax+by=c$ (deals with the vertical case) or some equivalent. In three dimensions you need to intersect two planes etc. Given that this is for enquiries at every level, I would note that my daughter is learning to distinguish between linear and quadratic equations (or forms to generalise at a higher level). OP does not deal with definition or level, so it is easy both to patronise and also to be over-sophisticated.2011-12-05
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A function $f(x)$ is linear if it satisfies the property $$f(ax+y) = af(x) + f(y).$$ Let's try $a=-1$, $x=1$, $y=0$: $$\begin{align*} |ax+y| = |-1| &= 1\\ -1\ |1|+|0| &= -1\end{align*},$$ so $f(x) = |x|$ is not linear.

Sometimes (especially in geometry) "linear" is understood to mean affine. A function $f(x)$ is affine if it satisfies the property $$f[ax + (1-a)y] = af(x) + (1-a)f(y).$$ Once again let's try $a=-1$, $x=1$, $y=0$: $$\begin{align*} |ax+(1-a)y| = |-1| &= 1\\ af(x)+(1-a)f(y) = -1\ |1| + 2\cdot 0 &= -1,\end{align*}$$ so $|x|$ isn't affine either.

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    It is worse than failing $f(ax+y) = af(x) + f(y)$. It fails BOTH $f(x+y) = f(x) + f(y)$ and $f(ax) = af(x)$.2011-12-05
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    If a function is linear then it is affine(convex).2011-12-06
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I would simply define a linear function as always having the same slope (and, more technically, it must be continuous).

Clearly, the absolute value function has a negative slope for values < 0 and positive slope for values > 0. So it's not linear.

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    In order for a function to have a well-defined sense of "slope", it must be differentiable, which implies continuity. However, the absolute value function, in addition to not having the same slope everywhere, does not even have a slope at 0, so your idea still works.2011-12-06
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Think of the definition of absolute value. It is a piecewise defined function. |x| = x, if x>=0 and -x if x<0. In other words, the graph of y=|x| is formed by two pieces of two lines. For the part of the domain where x-values are less than zero, the graph corresponds to the graph of y=-x. For parts of the domain where x-values are greater than or equal to zero, the graph corresponds to the graph of y=x. While the absolute value function does not satisfy the above definitions for linear functions, it is actually "parts" of two linear functions.