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Module 3 · L14 of 15 ~35 min ⚡ +95 XP available

Graphs of Inverse Trig Functions

You already know the values — now see the shapes. The graphs of $\sin^{-1}x$, $\cos^{-1}x$, and $\tan^{-1}x$ each tell a visual story about domains, ranges, and asymptotes. Mastering these graphs is essential for differentiation in HSC Extension 1 and for identifying where inverse trig functions are valid.

Today's hook — The graph of $y = \sin^{-1}x$ is the reflection of $y = \sin x$ in which line? And over what domain is this reflection valid? Your intuition about "flipping" a graph in $y = x$ is correct — but there's a crucial domain restriction that most students miss. By the end of this lesson you'll sketch all three inverse trig graphs confidently and prove their intersection point exactly.

0/5QUESTS

Recall — your gut answer first

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The graph of $y = \sin^{-1}x$ is the reflection of $y = \sin x$ in which line? Over what domain is this reflection valid? Write your gut answer before reading on.

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The two moves

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Every graph of an inverse trig function question reduces to two operations: identify the key features (domain, range, intercepts, concavity, asymptotes), and use the reflection property in $y = x$ to see how it relates to the original function.

The graph of $y = f^{-1}(x)$ is always the reflection of $y = f(x)$ in the line $y = x$. For inverse trig functions, this reflection is only of the restricted piece of the original function. $y = \sin^{-1}x$ reflects only $y = \sin x$ for $x \in [-\frac{\pi}{2}, \frac{\pi}{2}]$.

$\tan^{-1}x \to \pm\dfrac{\pi}{2}$ as $x \to \pm\infty$

$\sin^{-1}$ is increasing

Passes through $(-1, -\frac{\pi}{2})$, $(0, 0)$, $(1, \frac{\pi}{2})$. Always increasing. Concave down for $x>0$, concave up for $x < 0$.

$\cos^{-1}$ is decreasing

Passes through $(1, 0)$, $(0, \frac{\pi}{2})$, $(-1, \pi)$. Always decreasing. No negative outputs.

$\tan^{-1}$ has asymptotes

Horizontal asymptotes at $y = \pm\frac{\pi}{2}$. Passes through $(0, 0)$. Increasing. Odd function: $\tan^{-1}(-x) = -\tan^{-1}x$.

What you'll master

Know

Key facts

Key points on each inverse trig graph: intercepts and endpoints
Monotonicity: $\sin^{-1}$ and $\tan^{-1}$ increase; $\cos^{-1}$ decreases
Horizontal asymptotes of $\tan^{-1}x$ at $y = \pm\frac{\pi}{2}$

Understand

Concepts

The reflection property: inverse function graphs reflect in $y = x$
Why $\tan^{-1}$ has asymptotes but $\sin^{-1}$ and $\cos^{-1}$ do not
Why the graphs of $\sin^{-1}x$ and $\cos^{-1}x$ intersect at $x = \frac{1}{\sqrt{2}}$

Can do

Skills

Sketch all three inverse trig graphs with correct features labelled
Identify and explain key features: domain, range, intercepts, concavity
Prove the intersection of $\sin^{-1}x$ and $\cos^{-1}x$

Key terms

Reflection in $y = x$The graph of an inverse function is the mirror image of the original (restricted) function in the line $y = x$. Points $(a,b)$ and $(b,a)$ are reflections of each other.

MonotonicA function that is always increasing or always decreasing. All three inverse trig functions are monotonic.

Horizontal asymptoteA horizontal line $y = k$ that the graph approaches as $x \to \pm\infty$. $\tan^{-1}x$ has asymptotes $y = \pm\frac{\pi}{2}$.

ConcavityWhether the graph curves upward (concave up) or downward (concave down). Changes in concavity occur at inflection points.

Odd functionA function with $f(-x) = -f(x)$, symmetric about the origin. Both $\sin^{-1}x$ and $\tan^{-1}x$ are odd functions.

Complement sum$\sin^{-1}x + \cos^{-1}x = \frac{\pi}{2}$ — the graphs of $\sin^{-1}x$ and $\cos^{-1}x$ sum to $\frac{\pi}{2}$ at every $x$ in their domain.

Graph of $y = \sin^{-1}x$

core concept

The graph of $y = \sin^{-1}x$ is the reflection of $y = \sin x$ restricted to $x \in [-\frac{\pi}{2}, \frac{\pi}{2}]$, reflected in the line $y = x$.

$y = \sin^{-1}x$ is increasing, passes through the origin, and is an odd function symmetric about $(0,0)$.

Domain: $[-1, 1]$
Range: $[-\frac{\pi}{2}, \frac{\pi}{2}]$
Passes through: $(0, 0)$, $(1, \frac{\pi}{2})$, $(-1, -\frac{\pi}{2})$
Always increasing
Odd function: $\sin^{-1}(-x) = -\sin^{-1}(x)$ — symmetric about the origin
Concavity: concave down for $x > 0$; concave up for $x < 0$
No asymptotes (it is a bounded, finite curve)

Reflection check. Take any point on the restricted $y = \sin x$, e.g.\ $(\frac{\pi}{6}, \frac{1}{2})$. Reflecting in $y = x$ gives $(\frac{1}{2}, \frac{\pi}{6})$. Verify: $\sin^{-1}(\frac{1}{2}) = \frac{\pi}{6}$. ✓ This is the definition of an inverse function.

The graph of $y = \sin^{-1}x$ is the reflection of $y = \sin x$ restricted to $x \in [-\frac{\pi}{2}, \frac{\pi}{2}]$, reflected in the line $y = x$.

Pause — copy the key features of $y=\sin^{-1}x$: domain $[-1,1]$, range $[-\pi/2,\pi/2]$, passes through $(-1,-\pi/2),(0,0),(1,\pi/2)$, and sketch the shape into your book.

Quick check: Which point does $y = \sin^{-1}x$ pass through?

Graph of $y = \cos^{-1}x$

core concept

We just saw that the graph of $y=\sin^{-1}x$ is the reflection of $y=\sin x$ (restricted to $[-\pi/2,\pi/2]$) in the line $y=x$; it has domain $[-1,1]$, range $[-\pi/2,\pi/2]$, and passes through $(-1,-\pi/2),(0,0),(1,\pi/2)$. That raises a question: how do the graphs of $y=\cos^{-1}x$ and $y=\tan^{-1}x$ differ — specifically, which ones have horizontal asymptotes, and where do they intersect the axes? This card answers it → $\cos^{-1}$ has no asymptote (domain $[-1,1]$); $\tan^{-1}$ has two asymptotes $y=\pm\pi/2$ and passes through the origin.

The graph of $y = \cos^{-1}x$ is the reflection of $y = \cos x$ restricted to $x \in [0, \pi]$, reflected in the line $y = x$.

$y = \cos^{-1}x$ is always decreasing. Unlike $\sin^{-1}x$, it is not an odd function — it has no negative outputs.

Domain: $[-1, 1]$
Range: $[0, \pi]$
Passes through: $(1, 0)$, $(0, \frac{\pi}{2})$, $(-1, \pi)$
Always decreasing (cosine is decreasing on $[0, \pi]$, so its inverse is also decreasing)
NOT an odd function — all outputs are non-negative
Concavity: concave down throughout
No asymptotes

Key contrast with $\sin^{-1}$. Note that $\sin^{-1}x + \cos^{-1}x = \frac{\pi}{2}$, which means the graphs of $\sin^{-1}x$ and $\cos^{-1}x$ always sum to $\frac{\pi}{2}$. Geometrically, $\cos^{-1}x$ is the "complement" of $\sin^{-1}x$ at every point of their shared domain.

The graph of $y = \cos^{-1}x$ is the reflection of $y = \cos x$ restricted to $x \in [0, \pi]$, reflected in the line $y = x$.

Pause — copy the key features of $y=\cos^{-1}x$: domain $[-1,1]$, range $[0,\pi]$, passes through $(-1,\pi),(0,\pi/2),(1,0)$, and sketch the shape into your book.

Did you get this? True or false: the graph of $y = \cos^{-1}x$ is decreasing throughout its domain.

Graph of $y = \tan^{-1}x$

core concept

We just saw that $y=\cos^{-1}x$ has domain $[-1,1]$, range $[0,\pi]$, is always decreasing, and has no asymptotes. That raises a question: $\tan^{-1}$ has an unbounded domain unlike $\cos^{-1}$ — how does this produce horizontal asymptotes, and what are the exact values they approach? This card answers it → $y=\tan^{-1}x\to\pi/2$ as $x\to+\infty$ and $\to-\pi/2$ as $x\to-\infty$.

The graph of $y = \tan^{-1}x$ is the reflection of $y = \tan x$ restricted to $x \in (-\frac{\pi}{2}, \frac{\pi}{2})$, reflected in the line $y = x$. The vertical asymptotes of $\tan x$ become horizontal asymptotes of $\tan^{-1}x$.

$y = \tan^{-1}x$ never reaches $\pm\frac{\pi}{2}$ — these are horizontal asymptotes. The curve has an S-shape (inflection at the origin).

Domain: $(-\infty, \infty)$ — all real $x$
Range: $(-\frac{\pi}{2}, \frac{\pi}{2})$ — open interval, asymptotes not reached
Passes through: $(0, 0)$
Horizontal asymptotes: $y = \frac{\pi}{2}$ (as $x \to +\infty$) and $y = -\frac{\pi}{2}$ (as $x \to -\infty$)
Always increasing
Odd function: $\tan^{-1}(-x) = -\tan^{-1}(x)$
Inflection point at the origin (concave down for $x > 0$, concave up for $x < 0$)

Pause — copy the key features of $y=\tan^{-1}x$: domain $\mathbb{R}$, range $(-\pi/2,\pi/2)$, horizontal asymptotes $y=\pm\pi/2$, passes through the origin into your book.

Fill the gap: The horizontal asymptotes of $y = \tan^{-1}x$ are at $y = $ .

Worked examples · 3 in a row, reveal as you go

PROBLEM 1 · SKETCHING FEATURES

For the graph of $y = \cos^{-1}x$, state the domain, range, all axis intercepts, and describe the monotonicity.

Domain: $[-1,1]$. Range: $[0,\pi]$.

These come from the restricted domain of $\cos x$ on $[0,\pi]$, where it is strictly decreasing.

PROBLEM 2 · INTERSECTION POINT

Show that the graphs of $y = \cos^{-1}x$ and $y = \sin^{-1}x$ intersect at $x = \dfrac{1}{\sqrt{2}}$.

At the intersection point: $\cos^{-1}x = \sin^{-1}x$. Let this common value be $\theta$, so $\cos^{-1}x = \sin^{-1}x = \theta$.

Set the two expressions equal and introduce a common variable.

PROBLEM 3 · COMPARING ALL THREE

Compare the graphs of $y = \sin^{-1}x$, $y = \cos^{-1}x$, and $y = \tan^{-1}x$: which are odd functions? Which have horizontal asymptotes? Which pass through the origin?

Odd functions: $\sin^{-1}x$ and $\tan^{-1}x$ are odd ($f(-x) = -f(x)$, symmetric about origin). $\cos^{-1}x$ is not odd — it has no negative outputs.

Test: $\sin^{-1}(-x) = -\sin^{-1}(x)$ ✓; $\cos^{-1}(-x) = \pi - \cos^{-1}(x) \neq -\cos^{-1}(x)$ ✗.

Did you get this? True or false: $y = \cos^{-1}x$ is an odd function.

Odd one out: Which of these is NOT a feature of $y = \tan^{-1}x$?

Activities · practice with the ideas

State the domain and range of $y = \tan^{-1}x$.

Sketch $y = \sin^{-1}x$, showing all key points clearly: endpoints and the origin.

Show that $\sin^{-1}x + \cos^{-1}x = \dfrac{\pi}{2}$. (Hint: let $\sin^{-1}x = \theta$ and use co-function identities.)

What is the $y$-intercept of $y = \cos^{-1}x$? Why is this different from $y = \sin^{-1}x$?

Explain why $\tan^{-1}x$ has horizontal asymptotes at $y = \pm\frac{\pi}{2}$, but $\sin^{-1}x$ has no asymptotes at all.

Revisit your thinking

Earlier you were asked: The graph of $y = \sin^{-1}x$ is the reflection of $y = \sin x$ in which line? Over what domain is this reflection valid?

The reflection is in the line $y = x$. However, it is not the entire sine curve that reflects — only the portion restricted to $x \in [-\frac{\pi}{2}, \frac{\pi}{2}]$. This is the domain where $\sin x$ is strictly increasing and one-to-one. Reflecting this restricted piece in $y = x$ gives the curve $y = \sin^{-1}x$ with domain $[-1, 1]$ and range $[-\frac{\pi}{2}, \frac{\pi}{2}]$.

Why do $\sin^{-1}x$ and $\cos^{-1}x$ have limited domains while $\tan^{-1}x$ has domain $\mathbb{R}$? Because the outputs of $\sin x$ and $\cos x$ are bounded in $[-1,1]$, so their inverses can only accept $x \in [-1,1]$. Tangent, however, takes all real values as outputs on its restricted domain $(-\frac{\pi}{2}, \frac{\pi}{2})$ — so $\tan^{-1}x$ can accept any real input.

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Work mode · how are you completing this lesson?

Multiple choice

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Pick your answer, then rate your confidence — that tells the system what to drill next. Each retry pulls a fresh mix from the bank.

Short answer

ApplyBand 42 marks

Q1. State the domain and range of $y = \tan^{-1}x$. (2 marks)

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ApplyBand 4–53 marks

Q2. Sketch $y = \sin^{-1}x$, showing all key points: domain endpoints, $y$-intercept, and any relevant values. (3 marks)

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AnalyseBand 52 marks

Q3. Prove that $\sin^{-1}x + \cos^{-1}x = \dfrac{\pi}{2}$ for $x \in [-1,1]$. (2 marks)

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Comprehensive answers (click to reveal)

Activity answers: 1. Domain $\mathbb{R}$, range $(-\frac{\pi}{2}, \frac{\pi}{2})$ 2. Mark $(-1,-\frac{\pi}{2})$, $(0,0)$, $(1,\frac{\pi}{2})$; curve increasing, odd 3. Proof below 4. $\cos^{-1}(0) = \frac{\pi}{2}$ because $\cos\frac{\pi}{2} = 0$; differs from $\sin^{-1}(0)=0$ since $\sin^{-1}$ uses range $[-\frac{\pi}{2},\frac{\pi}{2}]$ 5. $\tan x$ had vertical asymptotes at $x = \pm\frac{\pi}{2}$ (boundaries of the open restricted domain); reflecting in $y=x$ turns these into horizontal asymptotes of $\tan^{-1}x$. $\sin x$ had endpoints (closed interval), not asymptotes.

Q1 (2 marks): Domain: $(-\infty,\infty)$ or $\mathbb{R}$ [1]. Range: $(-\frac{\pi}{2}, \frac{\pi}{2})$ — open interval [1].

Q2 (3 marks): Correct domain $[-1,1]$ and range $[-\frac{\pi}{2},\frac{\pi}{2}]$ labelled [1]. Three key points $(-1,-\frac{\pi}{2})$, $(0,0)$, $(1,\frac{\pi}{2})$ marked [1]. Curve drawn increasing, with correct concavity (concave down for $x>0$, concave up for $x<0$) [1].

Q3 (2 marks): Let $\sin^{-1}x = \theta$, so $\sin\theta = x$ with $\theta \in [-\frac{\pi}{2}, \frac{\pi}{2}]$ [0.5]. Then $\cos(\frac{\pi}{2}-\theta) = \sin\theta = x$, and since $\frac{\pi}{2}-\theta \in [0,\pi]$ (which is the range of $\cos^{-1}$), we have $\cos^{-1}(x) = \frac{\pi}{2}-\theta$ [1]. Therefore $\sin^{-1}x + \cos^{-1}x = \theta + \frac{\pi}{2} - \theta = \frac{\pi}{2}$ [0.5].

Boss battle · The Graph Gauntlet

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Key takeaways before you fight:

Inverse trig graphs are reflections of restricted trig graphs in $y = x$.
$\sin^{-1}x$: increasing, domain $[-1,1]$, range $[-\frac{\pi}{2}, \frac{\pi}{2}]$, odd, through $(0,0)$
$\cos^{-1}x$: decreasing, domain $[-1,1]$, range $[0, \pi]$, NOT odd, $y$-int at $\frac{\pi}{2}$
$\tan^{-1}x$: increasing, domain $\mathbb{R}$, range $(-\frac{\pi}{2}, \frac{\pi}{2})$, odd, asymptotes $y = \pm\frac{\pi}{2}$
$\sin^{-1}x + \cos^{-1}x = \frac{\pi}{2}$ — intersection at $\left(\frac{1}{\sqrt{2}}, \frac{\pi}{4}\right)$

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