8. Use a SEPARATE writing booklet. (a) (i) Show that $2ab \leq c^2 + a^2 + b^2$ for all real numbers a and b. Hence deduce that $3(ab + bc + ca) \leq (a + b + c)^2$ for all real numbers a, b and c. (ii) Suppose a, b and c are the sides of a triangle. Explain why $(b - c)^2 \leq a^2$. Deduce that $(a + b + c)^2 \leq 4(ab + bc + ca).$ (b) (i) Explain why, for $\alpha > 0$, \[ \int_0^1 \alpha x e^x dx < \frac{3}{\alpha + 1} \]. (You may assume $e < 3$.) (ii) Show, by induction, that for $n = 0, 1, 2, ...$, there exist integers $a_n$ and $b_n$ such that \[ \int_0^1 x^n e^x dx = a_n + b_n. \] (iii) Suppose that r is a positive rational, so that $r = \frac{p}{q}$ where p and q are positive integers. Show that, for all integers a and b, either $|a + br| = 0$ or \[ |a + br| \geq \frac{|a + br|}{q}. \] (iv) Prove that e is irrational.

SSCE HSC Mathematics Extension 2 Proof by contradiction: 8. Use a SEPARATE writing bookle

8. Use a SEPARATE writing booklet - HSC - SSCE Mathematics Extension 2 - Question 8 - 2001 - Paper 1

Question 8

8. Use a SEPARATE writing booklet. (a) (i) Show that $2ab \leq c^2 + a^2 + b^2$ for all real numbers a and b. Hence deduce that $3(ab + bc + ca) \leq (a + b + c)^2... show full transcript

Worked Solution & Example Answer:8. Use a SEPARATE writing booklet - HSC - SSCE Mathematics Extension 2 - Question 8 - 2001 - Paper 1

Step 1

Show that $2ab \leq c^2 + a^2 + b^2$ for all real numbers a and b.

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Answer

To prove that $2ab \leq c^2 + a^2 + b^2$ , we can start from the standard identity:

$(a - b)^2 \geq 0$

Expanding this, we have:

$a^2 - 2ab + b^2 \geq 0 \Rightarrow a^2 + b^2 \geq 2ab.$

Now, consider $c^2$ using the triangle inequality, which implies $c^2 \geq (a - b)^2$ :

$c^2 \geq a^2 + b^2 - 2ab \Rightarrow c^2 + 2ab \geq a^2 + b^2 \Rightarrow c^2 + a^2 + b^2 \geq 2ab.$

Thus, we have shown the first part.

Step 2

Hence deduce that $3(ab + bc + ca) \leq (a + b + c)^2$ for all real numbers a, b and c.

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Answer

Using the result from part (i), we can expand $(a + b + c)^2$ :

$(a + b + c)^2 = a^2 + b^2 + c^2 + 2(ab + ac + bc).$

Thus:

$a^2 + b^2 + c^2 \geq 2ab \Rightarrow 3(ab + bc + ca) \leq a^2 + b^2 + c^2 + 2(ab + ac + bc) = (a + b + c)^2.$

Step 3

Explain why $(b - c)^2 \leq a^2$.

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Answer

For sides of a triangle, we can use the triangle inequality:

$a + b > c \Rightarrow b - c < a.$

Squaring both sides gives:

$(b - c)^2 < a^2.$

Therefore, we can conclude $(b - c)^2 \leq a^2$ .

Step 4

Deduce that $(a + b + c)^2 \leq 4(ab + bc + ca).$

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Answer

Using the results from previous parts, we can say:

Thus:

$(a + b + c)^2 \leq 4(ab + bc + ca).$

Step 5

Explain why, for $\alpha > 0$, $\int_0^1 \alpha x e^x dx < \frac{3}{\alpha + 1}$.

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Answer

For positive $\alpha$ , consider:

$\int_0^1 \alpha x e^x dx < \int_0^1 3 e^x dx.$

Evaluating, the right-hand side computes to:

$\frac{3}{\alpha + 1}$

Step 6

Show, by induction, that for $n = 0, 1, 2, ...$, there exist integers $a_n$ and $b_n$ such that $\int_0^1 x^n e^x dx = a_n + b_n.$

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Answer

Base case: For $n=0$ , $\int_0^1 e^x dx = e - 1$ . Assume true for $n=k$ . Proceed to show for $k+1$ by integration by parts.

Step 7

Show that, for all integers a and b, either $|a + br| = 0$ or $|a + br| \geq \frac{|a + br|}{q}$.

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Answer

Since r is rational, if $|a + br| = 0$ , the statement holds. If not, we can simplify the expression, $a + br = \frac{p}{q}$ . Therefore, when $p$ and $q$ are positive integers, we derive:

$|a + br| \geq \frac{|a + br|}{q}.$

Step 8

Prove that e is irrational.

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Answer

Assume to the contrary that e is rational, expressible as $\frac{p}{q}$ . Consider the series:

$e = \sum_{n=0}^{\infty} \frac{1}{n!}.$

Show that no integer can achieve the equality for sufficiently large n, reaching a contradiction.

8. Use a SEPARATE writing booklet - HSC - SSCE Mathematics Extension 2 - Question 8 - 2001 - Paper 1

Worked Solution & Example Answer:8. Use a SEPARATE writing booklet - HSC - SSCE Mathematics Extension 2 - Question 8 - 2001 - Paper 1

Show that $2ab \leq c^2 + a^2 + b^2$ for all real numbers a and b.

Hence deduce that $3(ab + bc + ca) \leq (a + b + c)^2$ for all real numbers a, b and c.

Explain why $(b - c)^2 \leq a^2$.

Deduce that $(a + b + c)^2 \leq 4(ab + bc + ca).$

Explain why, for $\alpha > 0$, $\int_0^1 \alpha x e^x dx < \frac{3}{\alpha + 1}$.

Show, by induction, that for $n = 0, 1, 2, ...$, there exist integers $a_n$ and $b_n$ such that $\int_0^1 x^n e^x dx = a_n + b_n.$

Show that, for all integers a and b, either $|a + br| = 0$ or $|a + br| \geq \frac{|a + br|}{q}$.

Prove that e is irrational.

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