Question

1. determine the point(s), if any, at which the function is discontinuous. classify any discontinuity as jump, removable, infinite, or other. (i) (\frac{x + 1}{x^2 + 1}) (ii) (\frac{x^2 - 9}{x^2 - 5x + 6}) (iii) (\frac{|x - 3|}{x - 3}) (iv) (\tan(2x))

Explanation:

(i) For the function \( f(x) = \frac{x + 1}{x^2 + 1} \)

Step 1: Analyze the denominator

The denominator is \( x^2 + 1 \). For real numbers \( x \), \( x^2\geq0 \), so \( x^2 + 1\geq1 \). The denominator is never zero for any real \( x \).

Step 2: Conclusion about continuity

Since the denominator is non - zero for all real \( x \), the function \( f(x)=\frac{x + 1}{x^2+1} \) is continuous for all real numbers \( x\in\mathbb{R} \). There are no points of discontinuity.

(ii) For the function \( f(x)=\frac{x^2 - 9}{x^2-5x + 6} \)

Step 1: Factor numerator and denominator

Factor the numerator: \( x^2-9=(x - 3)(x + 3) \) (using the difference of squares formula \( a^2-b^2=(a - b)(a + b) \))
Factor the denominator: \( x^2-5x + 6=(x - 2)(x - 3) \) (by finding two numbers that multiply to 6 and add up to - 5, which are - 2 and - 3)
So the function can be written as \( f(x)=\frac{(x - 3)(x + 3)}{(x - 2)(x - 3)} \), \( x
eq3 \)

Step 2: Simplify the function (excluding \( x = 3 \))

Cancel out the common factor \( (x - 3) \) (for \( x
eq3 \)), we get \( f(x)=\frac{x + 3}{x - 2} \), \( x
eq3 \)

Step 3: Analyze the denominator of the simplified function and the original function

• For the original function, the denominator is zero when \( x = 2 \) and \( x=3 \).
• For \( x = 2 \): The simplified function \( \frac{x + 3}{x - 2} \) has a denominator zero at \( x = 2 \), and \( \lim_{x

ightarrow2^+}f(x)=\lim_{x
ightarrow2^+}\frac{x + 3}{x - 2}=\infty \) and \( \lim_{x
ightarrow2^-}f(x)=\lim_{x
ightarrow2^-}\frac{x + 3}{x - 2}=-\infty \), so \( x = 2 \) is a point of infinite discontinuity.

• For \( x = 3 \): The limit \( \lim_{x

ightarrow3}f(x)=\lim_{x
ightarrow3}\frac{x + 3}{x - 2}=\frac{3 + 3}{3 - 2}=6 \). But the function is not defined at \( x = 3 \) in the original function. So \( x = 3 \) is a removable discontinuity.

(iii) For the function \( f(x)=\frac{|x - 3|}{x - 3} \)

Step 1: Analyze the absolute value function

Recall that \( |x-3|=

$$\begin{cases}x - 3, & x\geq3\\-(x - 3), & x<3\end{cases}$$

\)

Step 2: Find the left - hand limit and right - hand limit at \( x = 3 \)

• Right - hand limit (\( x

ightarrow3^+ \)): When \( x
ightarrow3^+ \), \( |x - 3|=x - 3 \), so \( \lim_{x
ightarrow3^+}\frac{|x - 3|}{x - 3}=\lim_{x
ightarrow3^+}\frac{x - 3}{x - 3}=1 \)

• Left - hand limit (\( x

ightarrow3^- \)): When \( x
ightarrow3^- \), \( |x - 3|=-(x - 3) \), so \( \lim_{x
ightarrow3^-}\frac{|x - 3|}{x - 3}=\lim_{x
ightarrow3^-}\frac{-(x - 3)}{x - 3}=-1 \)

Step 3: Conclusion about discontinuity

Since \( \lim_{x
ightarrow3^+}f(x)
eq\lim_{x
ightarrow3^-}f(x) \), the function has a jump discontinuity at \( x = 3 \). Also, the function is not defined at \( x = 3 \).

(iv) For the function \( y = \tan(2x) \)

Answer:

The function \( \frac{x + 1}{x^2+1} \) is continuous for all real \( x \), no points of discontinuity.

(ii)