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Mathematical Expression Editor
We see that if a function is differentiable at a point, then it must be continuous at
that point.
There are connections between continuity and differentiability.
Differentiability Implies Continuity If is a differentiable function at , then is
continuous at .
To explain why this is true, we are going to use the following
definition of the derivative
Assuming that exists, we want to show that is continuous at , hence
we must show that Starting with we multiply and divide by to get
Since we see that , and so is continuous at .
This theorem is often written as its contrapositive:
If is not continuous at , then is not differentiable at .
Thus from the theorem above, we see that all differentiable functions on are
continuous on . Nevertheless there are continuous functions on that are not
differentiable on .
Which of the following functions are continuous but not differentiable on ? (Select
all correct answers)
From our informal definition of derivative of a function, we can see that the
piece-wise function
is not differentible at :
Notice that however much we ’zoom in’ on the function at , there is always a
kink.
Using the ’zoomed in’ graph of the piecewise function above, what is ?
because to
the left of the ’kink,’ the line is horizontal, which has slope . because to the right of the ’kink,’ the line has slope . because is the average of the slopes of the lines to the left and right of the kink.
does not exist because there is no one best tangent line approximation of the function at .
Using that limit vocabulary, explain why the piecewise function is not differentiable
at . It may be helpful to note that the slope of when is and the slope of when is
.
Consider What values of and make differentiable at ?
To start, we
know that we must make both continuous and differentiable. Hence, we
must ensure that the value of both pieces of agree at . Write with me
Now we must ensure that the derivatives of each piece of agree at . Write with me
Moreover, by the definition of a tangent line. Hence we must have
Ah! So now
so . Thus setting and will give us a continuous and differentiable piecewise
function.