VCE Methods Question Thread!

[Cranium002]

Hi Guys,

What is the best way you guys have approached Methods? Any Suggestions?

[ang.ie36]

How do we understand or get what application questions are asking us??!!
pls help
and is it too late to understand concepts?

[ang.ie36]

Is it possible to get above 40 ss if we r behind now?

[Lear]

Can Methods students be expected to find the derivatives of exponential functions with a base other than e and logarithmic functions with base other than e?

[Stargirl123]

Hey everyone! Stuck on these two, can anyone help?

A = (-4,6) B = (6,-7)

1. Find the coordinates of the point P on the line segment AB such that AP:PB = 3:1

2. Find the coordinates of the point P on the line AB such that AP:AB = 3:1 and P is closer to point B than to point A

[jazzycab]

Can Methods students be expected to find the derivatives of exponential functions with a base other than e and logarithmic functions with base other than e?

Yes, this is assessable, but uncommon on VCAA exams.

Hey everyone! Stuck on these two, can anyone help?

A = (-4,6) B = (6,-7)

1. Find the coordinates of the point P on the line segment AB such that AP:PB = 3:1

2. Find the coordinates of the point P on the line AB such that AP:AB = 3:1 and P is closer to point B than to point A

Both questions can be done quite similarly (using basically the same idea as for finding a midpoint).
For both questions, the line segment is split into 4 sections.
For question 1, the horizontal and vertical displacements of \(P\) from \(A\) are \(\frac{3}{4}\) of the displacements of each respective component of \(B\) from \(A\) (note that this is literally just an application of similar triangles).
That is:

Hopefully you can do question 2 from here.

[Andrewt468]

Hi,

Can anyone please tell me what the 4 transformation of this equation is -.-

-3\sqrt{2x}/25-2

Thanks!

[jazzycab]

Hi,

Can anyone please tell me what the 4 transformation of this equation is -.-

-3\sqrt{2x}/25-2

Thanks!

Please specify the actual question (i.e. you haven't actually given an equation, nor what we are transforming from, or to).
I imagine the question is a transformation involving the basic square root function, but what is the image and what is the pre-image?
Is the question,
State a sequence of four transformations that, when applied to the function \(y=\sqrt{x}\) gives the function \(y=-\frac{3\sqrt{2x}}{25}-2\), or something similar?

[Andrewt468]

woops..
yh  from y = √x

[jazzycab]

woops..
yh  from y = √x

Note: This is not the only solution, simply the one that I feel is the most efficient:

So we have:
- A dilation of factor \(\frac{3}{25}\) from the \(x\)-axis
- A dilation of factor \(\frac{1}{2}\) from the \(y\)-axis
- A reflection in the \(x\)-axis
- A translation of 2 units down

[Andrewt468]

thank you

[pokemonmaster123]

How would we sketch a graph like y = x^4+2x^2+1 on exam 1?

[Qwerty1234qwerty]

That’s just (x^2+1)^2

[pokemonmaster123]

That’s just (x^2+1)^2

But how would it be sketched without the CAS?

[jazzycab]

But how would it be sketched without the CAS?

Find the turning points firstly:

This is a quartic polynomial with one stationary point.

Now let's find any axes-intercepts:

So we have a \(y\)-intercept at \(\left(0,1\right)\), which also happens to be the stationary point. Note that there are no \(x\)-intercepts.

Theoretically, there are a few possible shapes of quartics with one stationary point - namely, a curve similar to the standard quartic/quadratic with a stationary point and no points of inflection, or a curve with a stationary point and one non-stationary point of inflection. If we consider the underlying quadratic, \(y=x^2+1\), we could potentially sketch this as the product of two functions (where both are \(y=x^2+1\)).
However, a much simpler way of identifying the shape is by considering that \(y=x^2+1\) is symmetrical about the \(y\)-axis. This means that when we square the whole thing, it will still be symmetrical about the \(y\)-axis, thus, the shape is similar to that of \(y=x^4\) (i.e. it can't be a quartic with a stationary point and a non-stationary point of inflection, otherwise it would lose this symmetry property).
To get the curvature/gradient relatively accurate, you could then plot a few points and draw a smooth basic quartic/quadratic-shaped curve through them.
Note that the shape is different to that of \(y=x^4\) in that \(y=x^4+2x^2+1\ne x^4+1\), but the main difference is how steep the curve is.
_________________________________________________________________________________________

Can't believe I didn't think to mention this initially. This can be sketched reasonably easily using addition of ordinates (i.e. sketch \(y=x^4+1\) and \(y=2x^2\) then add the curves together using the addition of ordinates technique.