Restricting Domains
As we have seen, \(f(x)=x^2\) does not have an inverse function because it is not one-to-one. However, we can choose a subset of the domain of f such that the function is one-to-one. This subset is called a restricted domain. By restricting the domain of \(f\), we can define a new function g such that the domain of \(g\) is the restricted domain of f and \(g(x)=f(x)\) for all \(x\) in the domain of \(g\). Then we can define an inverse function for g on that domain. For example, since \(f(x)=x^2\) is one-to-one on the interval \([0,∞)\), we can define a new function g such that the domain of \(g\) is \([0,∞)\) and \(g(x)=x^2\) for all \(x\) in its domain. Since \(g\) is a one-to-one function, it has an inverse function, given by the formula \(g^{−1}(x)=\sqrt{x}\). On the other hand, the function \(f(x)=x^2\) is also one-to-one on the domain \((−∞,0]\). Therefore, we could also define a new function \(h\) such that the domain of \(h\) is \((−∞,0]\) and \(h(x)=x^2\) for all \(x\) in the domain of \(h\). Then \(h\) is a one-to-one function and must also have an inverse. Its inverse is given by the formula \(h^{−1}(x)=−\sqrt{x}\) (Figure).
Figure \(\PageIndex{4}\): (a) For \(g(x)=x^2\) restricted to \([0,∞)\),\(g^{−1}(x)=\sqrt{x}\). (b) For \(h(x)=x^2\) restricted to \((−∞,0]\),\(h^{−1}(x)=−\sqrt{x}\).
Example \(\PageIndex{4}\): Restricting the Domain
Consider the function \(f(x)=(x+1)^2\).
- Sketch the graph of \(f\) and use the horizontal line test to show that \(f\) is not one-to-one.
- Show that \(f\) is one-to-one on the restricted domain \([−1,∞)\). Determine the domain and range for the inverse of \(f\) on this restricted domain and find a formula for \(f^{−1}\).
Solution
a) The graph of \(f\) is the graph of \(y=x^2\) shifted left \(1\) unit. Since there exists a horizontal line intersecting the graph more than once, \(f\) is not one-to-one.
b) On the interval [−1,∞),f is one-to-one.
The domain and range of \(f^{−1}\) are given by the range and domain of \(f\), respectively. Therefore, the domain of \(f^{−1}\) is \([0,∞)\) and the range of \(f^{−1}\) is \([−1,∞)\). To find a formula for \(f^{−1}\), solve the equation \(y=(x+1)^2\) for x. If \(y=(x+1)^2\), then \(x=−1±\sqrt{y}\). Since we are restricting the domain to the interval where \(x≥−1\), we need \(±\sqrt{y}≥0\). Therefore, \(x=−1+\sqrt{y}\). Interchanging \(x\) and \(y\), we write \(y=−1+\sqrt{x}\) and conclude that \(f^{−1}(x)=−1+\sqrt{x}\).
Exercise \(\PageIndex{4}\)
Consider \(f(x)=1/x^2\) restricted to the domain \((−∞,0)\). Verify that \(f\) is one-to-one on this domain. Determine the domain and range of the inverse of \(f\) and find a formula for \(f^{−1}\).
- Hint
-
The domain and range of \(f^{−1}\) is given by the range and domain of \(f\), respectively. To find \(f^{−1}\), solve \(y=1/x^2\) for \(x\).
- Answer
-
The domain of \(f^{−1}\) is \((0,∞)\). The range of \(f^{−1}\) is \((−∞,0)\). The inverse function is given by the formula \(f^{−1}(x)=−1/\sqrt{x}\).
Inverse Trigonometric Functions
The six basic trigonometric functions are periodic, and therefore they are not one-to-one. However, if we restrict the domain of a trigonometric function to an interval where it is one-to-one, we can define its inverse. Consider the sine function ([link]). The sine function is one-to-one on an infinite number of intervals, but the standard convention is to restrict the domain to the interval \([−\frac{π}{2},\frac{π}{2}]\).By doing so, we define the inverse sine function on the domain \([−1,1]\) such that for any \(x\) in the interval \([−1,1]\), the inverse sine function tells us which angle \(θ\) in the interval \([−\frac{π}{2},\frac{π}{2}]\) satisfies \(sinθ=x\). Similarly, we can restrict the domains of the other trigonometric functions to define inverse trigonometric functions, which are functions that tell us which angle in a certain interval has a specified trigonometric value.
Definition
The inverse sine function, denoted \(\sin^{−1}\) or arcsin, and the inverse cosine function, denoted \(\cos^{−1}\) or arccos, are defined on the domain \(D={x|−1≤x≤1}\) as follows:
\(\sin^{−1}(x)=y\) if and only if \(\sin(y)=x\) and \(−\frac{π}{2}≤y≤\frac{π}{2}\);
\(cos^{−1}(x)=y\) if and only if \(\cos(y)=x\) and \(0≤y≤π\).
The inverse tangent function, denoted \(tan^{−1}\)or arctan, and inverse cotangent function, denoted \(cot^{−1}\) or arccot, are defined on the domain \(D={x|−∞<x<∞}\) as follows:
\(tan^{−1}(x)=y\) if and only if \(tan(y)=x\) and \(−\frac{π}{2}<y<\frac{π}{2}\);
\(cot^{−1}(x)=y\) if and only if \(cot(y)=x\) and \(0<y<π\).
The inverse cosecant function, denoted \(csc^{−1}\) or arccsc, and inverse secant function, denoted \(sec^{−1}\) or arcsec, are defined on the domain \(D={x||x|≥1}\) as follows:
\(csc^{−1}(x)=y\) if and only if \(csc(y)=x\) and \(−\frac{π}{2}≤y≤\frac{π}{2}, y≠0\);
\(sec^{−1}(x)=y\) if and only if \(sec(y)=x\) and\(0≤y≤π, y≠π/2\).
To graph the inverse trigonometric functions, we use the graphs of the trigonometric functions restricted to the domains defined earlier and reflect the graphs about the line \(y=x\) (Figure).
Figure \(\PageIndex{5}\): The graph of each of the inverse trigonometric functions is a reflection about the line \(y=x\) of the corresponding restricted trigonometric function.
When evaluating an inverse trigonometric function, the output is an angle. For example, to evaluate \(cos^{−1}(12)\), we need to find an angle \(θ\) such that \(cosθ=\frac{1}{2}\). Clearly, many angles have this property. However, given the definition of \(cos^{−1}\), we need the angle \(θ\) that not only solves this equation, but also lies in the interval \([0,π]\). We conclude that \(cos^{−1}(\frac{1}{2})=\frac{π}{3}\).
We now consider a composition of a trigonometric function and its inverse. For example, consider the two expressions \(\sin(\sin^{−1}(\frac{\sqrt{2}}{2}))\) and \(\sin^{−1}(\sin(π)).\)
For the first one, we simplify as follows:
\[\sin(\sin^{−1}(\frac{\sqrt{2}}{2}))=\sin(\frac{π}{4})=\frac{\sqrt{2}}{2}.\]
For the second one, we have
\[\sin^{−1}(\sin(π))=\sin^{−1}(0)=0.\]
The inverse function is supposed to “undo” the original function, so why isn’t \(\sin^{−1}(\sin(π))=π?\) Recalling our definition of inverse functions, a function \(f\) and its inverse \(f^{−1}\) satisfy the conditions \(f(f^{−1}(y))=y\) for all \(y\) in the domain of \(f^{−1}\) and \(f^{−1}(f(x))=x\) for all \(x\) in the domain of \(f\), so what happened here? The issue is that the inverse sine function, \(\sin^{−1}\), is the inverse of the restricted sine function defined on the domain \([−\frac{π}{2},\frac{π}{2}]\). Therefore, for \(x\) in the interval \([−\frac{π}{2},\frac{π}{2}]\), it is true that \(\sin^{−1}(\sin x)=x\). However, for values of \(x\) outside this interval, the equation does not hold, even though \(\sin^{−1}(\sin x)\) is defined for all real numbers \(x\).
What about \(\sin(\sin^{−1}y)?\) Does that have a similar issue? The answer is no. Since the domain of sin−1 is the interval \([−1,1]\), we conclude that \(\sin(\sin^{−1}y)=y\) if \(−1≤y≤1\) and the expression is not defined for other values of \(y\). To summarize,
\(\sin(\sin^{−1}y)=y\) if \(−1≤y≤1\)
and
\((\sin^{−1}(\sin x)=x\) if \(−\frac{π}{2}≤x≤\frac{π}{2}.\)
Similarly, for the cosine function,
\(\cos(cos^{−1}y)=y\) if \(−1≤y≤1\)
and
\(cos^{−1}(\cos x)=x\) if \(0≤x≤π.\)
Similar properties hold for the other trigonometric functions and their inverses.
Example \(\PageIndex{5}\): Evaluating Expressions Involving Inverse Trigonometric Functions
Evaluate each of the following expressions.
- \(\sin^{−1}(−\frac{\sqrt{3}}{2})\)
- \(tan(tan^{−1}(−\frac{1}{\sqrt{3}}))\)
- \(cos^{−1}(\cos(\frac{5π}{4}))\)
- \(\sin^{−1}(\cos(\frac{2π}{3}))\)
Solution
- Evaluating \(\sin^{−1}(−\sqrt{3}/2)\) is equivalent to finding the angle \(θ\) such that \(sinθ=−\sqrt{3}/2\) and \(−π/2≤θ≤π/2\). The angle \(θ=−π/3\) satisfies these two conditions. Therefore, \(\sin^{−1}(−\sqrt{3}/2)=−π/3\).
- First we use the fact that \(tan^{−1}(−1/3√)=−π/6.\) Then \(tan(π/6)=−1/\sqrt{3}\). Therefore, \(tan(tan^{−1}(−1/\sqrt{3}))=−1/\sqrt{3}\).
- To evaluate \(cos^{−}1(\cos(5π/4))\),first use the fact that \(\cos(5π/4)=−\sqrt{2}/2\). Then we need to find the angle \(θ\) such that \(\cos(θ)=−\sqrt{2}/2\) and \(0≤θ≤π\). Since \(3π/4\) satisfies both these conditions, we have \(\cos(cos^{−1}(5π/4))=\cos(cos^{−1}(−\sqrt{2}√2))=3π/4\).
- Since \(\cos(2π/3)=−1/2\), we need to evaluate \(\sin^{−1}(−1/2)\). That is, we need to find the angle \(θ\) such that \(\sin(θ)=−1/2\) and \(−π/2≤θ≤π/2\). Since \(−π/6\) satisfies both these conditions, we can conclude that \(\sin^{−1}(\cos(2π/3))=\sin^{−1}(−1/2)=−π/6.\)
The Maximum Value of a Function
In many areas of science, engineering, and mathematics, it is useful to know the maximum value a function can obtain, even if we don’t know its exact value at a given instant. For instance, if we have a function describing the strength of a roof beam, we would want to know the maximum weight the beam can support without breaking. If we have a function that describes the speed of a train, we would want to know its maximum speed before it jumps off the rails. Safe design often depends on knowing maximum values.
This project describes a simple example of a function with a maximum value that depends on two equation coefficients. We will see that maximum values can depend on several factors other than the independent variable x.
1. Consider the graph in Figure of the function \(y=\sin x+\cos x.\) Describe its overall shape. Is it periodic? How do you know?
Figure \(\PageIndex{6}\): The graph of y=\sin x+\cos x.
Using a graphing calculator or other graphing device, estimate the \(x\)- and \(y\)-values of the maximum point for the graph (the first such point where x > 0). It may be helpful to express the \(x\)-value as a multiple of π.
2. Now consider other graphs of the form \(y=A\sin x+B\cos x\) for various values of A and B. Sketch the graph when A = 2 and B = 1, and find the x- and y-values for the maximum point. (Remember to express the x-value as a multiple of π, if possible.) Has it moved?
3. Repeat for A = 1, B = 2. Is there any relationship to what you found in part (2)?
4. Complete the following table, adding a few choices of your own for A and B:
\(A\) |
\(B\) |
\(x\) |
\(y\) |
\(A\) |
\(B\) |
\(x\) |
\(y\) |
0 |
1 |
|
|
3 |
4 |
|
|
1 |
0 |
|
|
4 |
3 |
|
|
1 |
1 |
|
|
\(\sqrt{3}\) |
1 |
|
|
1 |
2 |
|
|
1 |
\(\sqrt{3}\) |
|
|
2 |
1 |
|
|
12 |
5 |
|
|
2 |
2 |
|
|
5 |
12 |
|
|
5. Try to figure out the formula for the \(y\)-values.
6. The formula for the \(x\)-values is a little harder. The most helpful points from the table are \((1,1),(1,\sqrt{3}),(\sqrt{3},1).\) (Hint: Consider inverse trigonometric functions.)
7. If you found formulas for parts (5) and (6), show that they work together. That is, substitute the \(x\) -value formula you found into \(y=A\sin x+B\cos x\) and simplify it to arrive at the \(y\)-value formula you found.