Scientists have found a relationship between the temperature and the height above a distant planet's surface. $T(h)$, given below, is the temperature in Celsius at a height of $h$ kilometers above the planet's surface. The relationship is as follows.
\[
T(h)=48.5-2.5 h
\]
Complete the following statements.
Let $T^{-1}$ be the inverse function of $T$.
Take $x$ to be an output of the function $T$.
That is, $x=I(h)$ and $h=T^{-1}(x)$.
(a) Which statement best describes $T^{-1}(x)$ ?
The ratio of the temperature (in degrees Celsius) to the number of kilometers, $x$.
The reciprocal of the temperature (in degrees Celsius) at a height of $x$ kilometers.
The height above the surface (in kilometers) when the temperature is $x$ degrees Celsius.
The temperature (in degrees Celsius) at a height of $x$ kilometers.
(b) $T^{-1}(x)=\square$
(c) $T^{-1}(33)=\square$
Answer
Final Answer: \(\boxed{(a)\ The\ statement\ that\ best\ describes\ T^{-1}(x)\ is\ "The\ height\ above\ the\ surface\ (in\ kilometers)\ when\ the\ temperature\ is\ x\ degrees\ Celsius."\ (b)\ T^{-1}(x)=19.4 - 0.4x\ (c)\ T^{-1}(33)=6.2}\)
Step 1 :The problem is asking for the inverse function of \(T(h)\) and its value at a certain point. The inverse function, \(T^{-1}(x)\), will give us the height above the surface when the temperature is \(x\) degrees Celsius.
Step 2 :To find the inverse function, we need to switch the roles of \(h\) and \(x\) in the original function and solve for \(h\).
Step 3 :By doing this, we find that the inverse function is \(T^{-1}(x)=19.4 - 0.4x\).
Step 4 :Then, we can substitute \(x=33\) into the inverse function to find the corresponding height.
Step 5 :By substituting, we find that \(T^{-1}(33)=6.2\).
Step 6 :Final Answer: \(\boxed{(a)\ The\ statement\ that\ best\ describes\ T^{-1}(x)\ is\ "The\ height\ above\ the\ surface\ (in\ kilometers)\ when\ the\ temperature\ is\ x\ degrees\ Celsius."\ (b)\ T^{-1}(x)=19.4 - 0.4x\ (c)\ T^{-1}(33)=6.2}\)
