Consider function g. g(x) = { (1/2)^x +3, x< 0. -x^2 +2, x>_ 0

Consider function g. g(x) = { (1/2)^x +3, x< 0. -x^2 +2, x>_ 0

asked Nov 2, 2023 151k views

1 Answer

$\square$ The function is continuous. [False]

Both pieces of the function are continuous, so the overall continuity of
g(x) depends on continuity at
x=0 .

We have

$\displaystyle \lim_(x\to0^-) g(x) = \lim_(x\to0) \left(\frac1{2^x} + 3\right) = 1 + 3 = 4$

and

$\displaystyle \lim_(x\to0^+) g(x) = \lim_(x\to0) (-x^2+2) = 2$

The one-sided limits do not match, so
is not continuous at
x=0 .

$\square$ As
approaches positive infinity,
g(x) approaches positive infinity. [False]

g(x) is a large negative number when
is very large, so
g(x) is approaching negative infinity.

$\boxed{\checkmark}$ The function is decreasing over its entire domain. [True]

This requires
$g'(x) \le 0$ on the entire real line. Compute the derivative of
.

$g'(x) = \begin{cases}-\ln(2)\left(\frac12\right)^x & x<0 \\\\ ? & x=0 \\\\ -2x & x>0 \end{cases}$

•
$\left(\frac12\right)^x > 0$ for all real
, so
g'(x)<0 whenever
x<0 .

•
$x^2\ge0$ for all real
, so
$-x^2\le0$ and
$-x^2+2\le2$ . Equality occurs only for
x=0 , which does not belong to
x>0 .

Whether the derivative at
x=0 exists or not is actually irrelevant. The point is that
g(b) < g(a) if
b>a for all real
a,b .

$\boxed{\checkmark}$ The domain is all real numbers. [True]

There are no infinite/nonremovable discontinuities, so all good here.

$\boxed{\checkmark}$ The
-intercept is 2. [True]

When
x=0 ,

g(0) = -0^2 + 2 = 2

Alexandr Viniychuk answered Nov 7, 2023

by Alexandr Viniychuk

7.7k points

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