9 (a) Three consecutive terms in an arithmetic sequence are $3e^{p}$, $5$, $3e^{r}$. Find the possible values of $p$. Give your answers in an exact form. 9 (b) Prove that there is no possible value of $q$ for which $3e^{q}$, $5$, $3e^{r}$ are consecutive terms of a geometric sequence.

A-Level AQA Maths Pure Geometric Sequences & Series: 9 (a) Three consecutive terms in

9 (a) Three consecutive terms in an arithmetic sequence are $3e^{p}$, $5$, $3e^{r}$ - AQA - A-Level Maths Pure - Question 9 - 2017 - Paper 2

Question 9

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9 (a) Three consecutive terms in an arithmetic sequence are $3e^{p}$, $5$, $3e^{r}$. Find the possible values of $p$. Give your answers in an exact form. 9 (b) Pro... show full transcript

Worked Solution & Example Answer:9 (a) Three consecutive terms in an arithmetic sequence are $3e^{p}$, $5$, $3e^{r}$ - AQA - A-Level Maths Pure - Question 9 - 2017 - Paper 2

Step 1

Find the possible values of $p$

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Answer

To find the possible values of $p$ , we start by setting up the condition for the terms to be in an arithmetic sequence. The difference between the first and second term should equal the difference between the second and third term:

$3e^{p} - 5 = 3e^{r} - 5$

This simplifies to:

$3e^{p} = 3e^{r}$

Dividing both sides by 3 gives:

$e^{p} = e^{r}$

Taking the natural logarithm of both sides results in:

$p = r$

Next, we also set the difference condition as:

$5 - 3e^{p} = 3e^{r} - 5$

Rearranging gives:

$10 = 3e^{r} + 3e^{p}$

Substituting $r$ with $p$ , we have:

$10 = 3e^{p} + 3e^{p}$

or:

$10 = 6e^{p}$

Dividing both sides by 6 yields:

$e^{p} = rac{10}{6} = rac{5}{3}$

Taking the natural logarithm of both sides gives:

$p = ext{ln} rac{5}{3}$

Thus, the possible values of $p$ in exact form is:

$p = ext{ln} rac{5}{3}$ .

Step 2

Prove that there is no possible value of $q$ for which $3e^{q}$, $5$, $3e^{r}$ are consecutive terms of a geometric sequence.

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Answer

To prove this, we assume that $3e^{q}$ , $5$ , and $3e^{r}$ are consecutive terms of a geometric sequence, which means that the ratio between consecutive terms must be equal:

$rac{5}{3e^{q}} = rac{3e^{r}}{5}$

Cross-multiplying gives:

$5^2 = 3e^{q} imes 3e^{r}$

or:

$25 = 9 e^{q + r}$

Thus:

$e^{q + r} = rac{25}{9}$

Now, since $q$ and $r$ can take any real values, let's express $e^{q}$ in terms of $e^{r}$ :

If we solve for $e^{q}$ , we have:

$e^{q} = rac{25}{9 e^{r}}$

This leads us to:

$3e^{q} = rac{75}{9 e^{r}}$

However, observe that for both expressions $3e^{q}$ and $3e^{r}$ to be positive, $e^{r}$ must be positive. Consequently, there cannot be a scenario wherein $3e^{q}$ , $5$ , and $3e^{r}$ can hold as consecutive terms of a geometric sequence due to the inherent contradictions from equating the ratios.

Thus, we conclude that there is no possible value of $q$ for which $3e^{q}$ , $5$ , and $3e^{r}$ can be consecutive terms of a geometric sequence.

9 (a) Three consecutive terms in an arithmetic sequence are $3e^{p}$, $5$, $3e^{r}$ - AQA - A-Level Maths Pure - Question 9 - 2017 - Paper 2

Worked Solution & Example Answer:9 (a) Three consecutive terms in an arithmetic sequence are $3e^{p}$, $5$, $3e^{r}$ - AQA - A-Level Maths Pure - Question 9 - 2017 - Paper 2

Find the possible values of $p$

Prove that there is no possible value of $q$ for which $3e^{q}$, $5$, $3e^{r}$ are consecutive terms of a geometric sequence.

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