Prove \(f(x)=\dfrac{x-2}{x-3}\) is a Bijection

📺 Video Explanation

📝 Question

Show that:

\[ f:\mathbb{R}\setminus\{3\}\to\mathbb{R}\setminus\{1\} \]

defined by:

\[ f(x)=\frac{x-2}{x-3} \]

is a bijection.

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✅ Solution

🔹 Step 1: Prove One-One (Injective)

Assume:

\[ f(x_1)=f(x_2) \]

Then:

\[ \frac{x_1-2}{x_1-3}=\frac{x_2-2}{x_2-3} \]

Cross multiply:

\[ (x_1-2)(x_2-3)=(x_2-2)(x_1-3) \]

Expand:

\[ x_1x_2-3x_1-2x_2+6=x_1x_2-3x_2-2x_1+6 \]

Simplify:

\[ -x_1+x_2=0 \]

\[ x_1=x_2 \]

✔ Hence, \(f\) is one-one.

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🔹 Step 2: Prove Onto (Surjective)

Let:

\[ y\in\mathbb{R}\setminus\{1\} \]

Need to find:

\[ x\in\mathbb{R}\setminus\{3\} \]

such that:

\[ \frac{x-2}{x-3}=y \]

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Solve:

\[ x-2=y(x-3) \]

\[ x-2=yx-3y \]

\[ x-yx=2-3y \]

\[ x(1-y)=2-3y \]

\[ x=\frac{2-3y}{1-y} \]

Since:

\[ y\neq1 \]

denominator is non-zero.

So such \(x\) exists.

Also:

\[ x\neq3 \]

(otherwise denominator of original function undefined).

✔ Hence, onto.

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🎯 Final Answer

\[ \boxed{f(x)=\frac{x-2}{x-3}\text{ is bijective}} \]

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🚀 Exam Shortcut

• Rational functions: use cross multiplication for injection
• For onto, solve \(f(x)=y\)
• If inverse exists, function is bijection