Maths Ext 1 - Got Some Questions (1 Viewer)

Life'sHard · Sep 13, 2021

Q

Vector Q I've been staring at for ages.

tickboom · Sep 13, 2021

Does this help? It's a similar question and I reckon if you use the same approach, you should be able to work it out ...

Life'sHard · Sep 13, 2021

tickboom said:
Does this help? It's a similar question and I reckon if you use the same approach, you should be able to work it out ...

Idk I'm still failing to see the link.

Life'sHard · Sep 13, 2021

ExtremelyBoredUser said:
https://www.youtube.com /watch?v=iqd9XbUHAwY&feature=emb_title

i put a space so it doesnt automatically made it media file

No I mean the link between the questions lmao. Not the video.

cassicowfan · Sep 13, 2021

idk if its how ur supposed to but u can prove DEC and AEF are similar

so EF/DE=AF/DC

AC=AD+DC
=-DA+DC
=v-u

bcus DE = DA + AE
DE = u + 2/5(AC)
= u + 2/5(v-u)

and EF = EA + AF
= -2/5(AC) + AF
= -2/5(v-u) + AF

so bcus of the similar

(2/5(u-v) + AF)/(u + 2/5(v-u)) = AF/DC

and then u can solve algebraically for AF/DC and u get AF/DC = 2/3

Life'sHard · Sep 13, 2021

cassicowfan said:
idk if its how ur supposed to but u can prove DEC and AEF are similar

so EF/DE=AF/DC

AC=AD+DC
=-DA+DC
=v-u

bcus DE = DA + AE
DE = u + 2/5(AC)
= u + 2/5(v-u)

and EF = EA + AF
= -2/5(AC) + AF
= -2/5(v-u) + AF

so bcus of the similar

(2/5(u-v) + AF)/(u + 2/5(v-u)) = AF/DC

and then u can solve algebraically for AF/DC and u get AF/DC = 2/3

That's actually insane wth. I still want to figure out a vector way but this makes sense tyvm.

CM_Tutor · Sep 14, 2021

To start with, we have $\overrightarrow{DA} = \overrightarrow{u}$ and $\overrightarrow{DC} = \overrightarrow{v}$ and we seek $\overrightarrow{AF} = \cfrac{2}{3}\overrightarrow{DC}$ given that $\overrightarrow{AE} = \cfrac{2}{5}\overrightarrow{AC}$ .

Start by expressing $\overrightarrow{AE}$ and $\overrightarrow{AC}$ in terms of $\overrightarrow{u}$ and $\overrightarrow{v}$ , so that we can make use of the given information:

$\overrightarrow{AC} = \overrightarrow{AD} + \overrightarrow{DC} = -\overrightarrow{DA} + \overrightarrow{DC} = -\overrightarrow{u} + \overrightarrow{v}$

$\text{So,}\ \overrightarrow{AE} = \cfrac{2}{5}\overrightarrow{AC} = \cfrac{2}{5}\left(\overrightarrow{v} - \overrightarrow{u}\right)$

Now, we know that $\overrightarrow{DC} = \overrightarrow{v}$ and so our goal if to show that $\overrightarrow{AF} = \cfrac{2}{3}\overrightarrow{v}$ , so we need to find a way to get to $\overrightarrow{AF}$ from what we know about $\overrightarrow{AE}$ ... and we might note that we haven't yet used the fact that $ABCD$ is a parallelogram.

I notice that I want $\overrightarrow{AF}$ and I have $\overrightarrow{AE}$ , so we might seek $\overrightarrow{EF}$ , which we can see is a part of $\overrightarrow{DF}$ , as is $\overrightarrow{DE}$ :

$\overrightarrow{DE} = \overrightarrow{DA} + \overrightarrow{AE} = \overrightarrow{u} + \cfrac{2}{5}\left(\overrightarrow{v} - \overrightarrow{u}\right) = \cfrac{1}{5}\left(3\overrightarrow{u} + 2\overrightarrow{v}\right)$

And, since $E$ lies between $D$ and $F$ , it follows that

$\overrightarrow{DF} = k\overrightarrow{DE} = \cfrac{k}{5}\left(3\overrightarrow{u} + 2\overrightarrow{v}\right) \qquad \text{for some constant $k>1$.}$

$\text{Thus,}\ \overrightarrow{AF} = \overrightarrow{AD} + \overrightarrow{DF} = -\overrightarrow{u} + \cfrac{k}{5}\left(3\overrightarrow{u} + 2\overrightarrow{v}\right) = \left(\cfrac{3k}{5} - 1\right)\overrightarrow{u} + \cfrac{2k}{5}\overrightarrow{v}$

But, we also know that $F$ lies between $A$ and $B$ , and that $AB || CD$ (since we have a parallelogram) and so

$\overrightarrow{AF} = \lambda\overrightarrow{AB} = \lambda\overrightarrow{v} \qquad \text{for some $0 < \lambda < 1$.}$

We thus have two forms for $\overrightarrow{AF}$ :

$\overrightarrow{AF} = \left(\cfrac{3k}{5} - 1\right)\overrightarrow{u} + \cfrac{2k}{5}\overrightarrow{v} = \lambda\overrightarrow{v}$

and noting that the vectors $\overrightarrow{u}$ and $\overrightarrow{v}$ have non-zero magnitude and are not parallel (as they represent sides of a parallelogram), we can conclude that

$\cfrac{3k}{5} - 1 = 0 \qquad \qquad \text{and} \qquad \qquad \cfrac{2k}{5} = \lambda$

Rearranging the first equation allows us to find $k$ :

$k = \cfrac{5}{3}$

from which we can find $\lambda$ :

$\lambda = \cfrac{2k}{5} = \cfrac{2}{5} \times \cfrac{5}{3} = \cfrac{2}{3}$

And hence, we have shown that

$\overrightarrow{AF} = \lambda\overrightarrow{v} = \cfrac{2}{3}\overrightarrow{v} = \cfrac{2}{3}\overrightarrow{DC}$

as required.

Life'sHard · Sep 14, 2021

CM_Tutor said:
To start with, we have $\overrightarrow{DA} = \overrightarrow{u}$ and $\overrightarrow{DC} = \overrightarrow{v}$ and we seek $\overrightarrow{AF} = \cfrac{2}{3}\overrightarrow{DC}$ given that $\overrightarrow{AE} = \cfrac{2}{5}\overrightarrow{AC}$ .

Start by expressing $\overrightarrow{AE}$ and $\overrightarrow{AC}$ in terms of $\overrightarrow{u}$ and $\overrightarrow{v}$ , so that we can make use of the given information:

$\overrightarrow{AC} = \overrightarrow{AD} + \overrightarrow{DC} = -\overrightarrow{DA} + \overrightarrow{DC} = -\overrightarrow{u} + \overrightarrow{v}$

$\text{So,}\ \overrightarrow{AE} = \cfrac{2}{5}\overrightarrow{AC} = \cfrac{2}{5}\left(\overrightarrow{v} - \overrightarrow{u}\right)$

Now, we know that $\overrightarrow{DC} = \overrightarrow{v}$ and so our goal if to show that $\overrightarrow{AF} = \cfrac{2}{3}\overrightarrow{v}$ , so we need to find a way to get to $\overrightarrow{AF}$ from what we know about $\overrightarrow{AE}$ ... and we might note that we haven't yet used the fact that $ABCD$ is a parallelogram.

I notice that I want $\overrightarrow{AF}$ and I have $\overrightarrow{AE}$ , so we might seek $\overrightarrow{EF}$ , which we can see is a part of $\overrightarrow{DF}$ , as is $\overrightarrow{DE}$ :

$\overrightarrow{DE} = \overrightarrow{DA} + \overrightarrow{AE} = \overrightarrow{u} + \cfrac{2}{5}\left(\overrightarrow{v} - \overrightarrow{u}\right) = \cfrac{1}{5}\left(3\overrightarrow{u} + 2\overrightarrow{v}\right)$

And, since $E$ lies between $D$ and $F$ , it follows that

$\overrightarrow{DF} = k\overrightarrow{DE} = \cfrac{k}{5}\left(3\overrightarrow{u} + 2\overrightarrow{v}\right) \qquad \text{for some constant $k>1$.}$

$\text{Thus,}\ \overrightarrow{AF} = \overrightarrow{AD} + \overrightarrow{DF} = -\overrightarrow{u} + \cfrac{k}{5}\left(3\overrightarrow{u} + 2\overrightarrow{v}\right) = \left(\cfrac{3k}{5} - 1\right)\overrightarrow{u} + \cfrac{2k}{5}\overrightarrow{v}$

But, we also know that $F$ lies between $A$ and $B$ , and that $AB || CD$ (since we have a parallelogram) and so

$\overrightarrow{AF} = \lambda\overrightarrow{AB} = \lambda\overrightarrow{v} \qquad \text{for some $0 < \lambda < 1$.}$

We thus have two forms for $\overrightarrow{AF}$ :

$\overrightarrow{AF} = \left(\cfrac{3k}{5} - 1\right)\overrightarrow{u} + \cfrac{2k}{5}\overrightarrow{v} = \lambda\overrightarrow{v}$

and noting that the vectors $\overrightarrow{u}$ and $\overrightarrow{v}$ have non-zero magnitude and are not parallel (as they represent sides of a parallelogram), we can conclude that

$\cfrac{3k}{5} - 1 = 0 \qquad \qquad \text{and} \qquad \qquad \cfrac{2k}{5} = \lambda$

Rearranging the first equation allows us to find $k$ :

$k = \cfrac{5}{3}$

from which we can find $\lambda$ :

$\lambda = \cfrac{2k}{5} = \cfrac{2}{5} \times \cfrac{5}{3} = \cfrac{2}{3}$

And hence, we have shown that

$\overrightarrow{AF} = \lambda\overrightarrow{v} = \cfrac{2}{3}\overrightarrow{v} = \cfrac{2}{3}\overrightarrow{DC}$

as required.

Thanks! I’ve also worked it out this morning using vector method like this. This however has nice explanations for future people who want to learn how to solve it.

Maths Ext 1 - Got Some Questions (1 Viewer)

Life'sHard

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tickboom

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Life'sHard

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Life'sHard

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cassicowfan

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Life'sHard

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CM_Tutor

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Life'sHard

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