A-Level Edexcel Maths Pure Functions: 8. (a) By writing sec θ = \frac{

8. (a) By writing sec θ = \frac{1}{cos θ}, show that \frac{d}{dθ}(sec θ) = sec θtan θ (b) Given that x = e^{sec y}, x > e, \, 0 < y < \frac{π}{2} show that \frac{dy}{dx} = \frac{1}{x \, g(x)} \, \, x > e where g(x) is a function of ln x. - Edexcel - A-Level Maths Pure - Question 8 - 2018 - Paper 5

Question 8

$8.-(a)-By-writing-sec-θ-=-\frac{1}{cos-θ},-show-that-\frac{d}{dθ}(sec-θ)-=-sec-θtan-θ--(b)-Given-that--x-=-e^{sec-y},--x->-e,-\,-0-<-y-<-\frac{π}{2}--show-that-\frac{dy}{dx}-=-\frac{1}{x-\,-g(x)}-\,--\,-x->-e--where-g(x)-is-a-function-of-ln-x.-Edexcel-A-Level Maths Pure-Question 8-2018-Paper 5.png$

8. (a) By writing sec θ = \frac{1}{cos θ}, show that \frac{d}{dθ}(sec θ) = sec θtan θ (b) Given that x = e^{sec y}, x > e, \, 0 < y < \frac{π}{2} show that \frac... show full transcript

Worked Solution & Example Answer:8. (a) By writing sec θ = \frac{1}{cos θ}, show that \frac{d}{dθ}(sec θ) = sec θtan θ (b) Given that x = e^{sec y}, x > e, \, 0 < y < \frac{π}{2} show that \frac{dy}{dx} = \frac{1}{x \, g(x)} \, \, x > e where g(x) is a function of ln x. - Edexcel - A-Level Maths Pure - Question 8 - 2018 - Paper 5

Step 1

By writing sec θ = \frac{1}{cos θ}, show that \frac{d}{dθ}(sec θ) = sec θtan θ

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Answer

To differentiate sec θ, we use the fact that sec θ can be expressed as (\frac{1}{cos θ}).

Using the quotient rule:

$\frac{d}{dθ}(sec θ) = \frac{d}{dθ}\left(\frac{1}{cos θ}\right) = \frac{0\cdot cos θ - 1\cdot\frac{d}{dθ}(cos θ)}{(cos θ)^2}$

The derivative of cos θ is -sin θ:

$= \frac{-(-sin θ)\cdot cos θ}{(cos θ)^2} = \frac{sin θ}{(cos θ)^2} = sec θ \cdot tan θ$

Thus, we have shown that (\frac{d}{dθ}(sec θ) = sec θtan θ).

Step 2

Given that x = e^{sec y}, x > e, 0 < y < \frac{π}{2} show that \frac{dy}{dx} = \frac{1}{x \, g(x)} where g(x) is a function of ln x.

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Answer

Starting with the relationship (x = e^{sec y}), we differentiate both sides with respect to x.

Since the left hand side is simply 1 (as it derives itself):

dx/dx = 1

On the right hand side:

dy/dx \cdot e^{sec y} \cdot sec y , tan y\ \text{(chain rule)}

Equating these gives us:

$1 = \frac{dy}{dx} \cdot e^{sec y} \cdot sec y \cdot tan y$

Now, we can rewrite this to isolate \frac{dy}{dx}:

$\frac{dy}{dx} = \frac{1}{e^{sec y} \cdot sec y \cdot tan y}$

Since (x = e^{sec y}) then we can write:

$= \frac{1}{x \cdot sec y \cdot tan y}$

Next, noticing that sec y can be expressed in terms of ln x:

let (g(x) = sec y \cdot tan y), therefore:

$\frac{dy}{dx} = \frac{1}{x \cdot g(x)}$ where g(x) is indeed a function of ln x, completing the solution.

By writing sec θ = \frac{1}{cos θ}, show that \frac{d}{dθ}(sec θ) = sec θtan θ

Given that x = e^{sec y}, x > e, 0 < y < \frac{π}{2} show that \frac{dy}{dx} = \frac{1}{x \, g(x)} where g(x) is a function of ln x.

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