alternative method? (1 Viewer)

rickypontingdagoat · Jan 3, 2024

hey I was wondering if you could do part ii) using triangle inequalities instead of graphically? I know the first part is doable.

Thanks.

WeiWeiMan · Jan 3, 2024

|z-3i+(-2+2i)|=1
1|≤|z-3i|+|-2+2i|
i could be completely wrong but that should give a rough idea
how are you 2028

rickypontingdagoat · Jan 3, 2024

I'm not, how are you 2026?

WeiWeiMan · Jan 3, 2024

rickypontingdagoat said:
I'm not, how are you 2026?

cuz i'm literally 2026

Average Boreduser · Jan 3, 2024

Just realised u meant p2

mb

Average Boreduser · Jan 3, 2024

still don't thing triangle law will be that helpful. if u found the min max for |z|, you can look at z-3i, makes a triangle, my guess it might be isosceles then the max might be a similar triangle? using ratio find min max? I'm blurting out crap rn bc im scared im gonna get it wrong.

Drongoski · Jan 3, 2024

Luukas.2 · Jan 3, 2024

rickypontingdagoat said:
View attachment 41999
hey I was wondering if you could do part ii) using triangle inequalities instead of graphically? I know the first part is doable.

Thanks.

Yes, you can.

For part (ii), take $\alpha = 2 + i$ and $\beta = 3i$ .

We are given that $|z - \alpha| = 1$ and can calculate that $|\alpha - \beta| = |(2 + i) - 3i| = |2 - 2i| = \sqrt{2^2 + (-2)^2} = 2\sqrt{2}$ .

We seek $|z - \beta|$ .

Applying the triangle inequality gives us that:

$\begin{align*} |z - \alpha| + |\alpha - \beta| &\ge |(z - \alpha) + (\alpha - \beta)| \\ 1 + 2\sqrt{2} &\ge |z - \beta| \\ |z - \beta| &\le 1 + 2\sqrt{2} \end{align*}$

And similarly, that:

$\begin{align*} |z - \beta| + |\alpha - z| &\ge |(z - \beta) + (\alpha - z)| \\ |z - \beta| + 1 &\ge |\alpha - \beta| \qquad \text{as $|\alpha - z| = |-1(z - \alpha)| = |-1||z - \alpha| = 1 \times 1 = 1$} \\ |z - \beta| &\ge 2\sqrt{2} - 1 \end{align*}$

Combining these:

$2\sqrt{2} - 1 \le |z - 3i| \le 1 + 2\sqrt{2}$

Luukas.2 · Jan 3, 2024

Luukas.2 said:
Yes, you can.

For part (ii), take $\alpha = 2 + i$ and $\beta = 3i$ .

We are given that $|z - \alpha| = 1$ and can calculate that $|\alpha - \beta| = |(2 + i) - 3i| = |2 - 2i| = \sqrt{2^2 + (-2)^2} = 2\sqrt{2}$ .

We seek $|z - \beta|$ .

Applying the triangle inequality gives us that:

$\begin{align*} |z - \alpha| + |\alpha - \beta| &\ge |(z - \alpha) + (\alpha - \beta)| \\ 1 + 2\sqrt{2} &\ge |z - \beta| \\ |z - \beta| &\le 1 + 2\sqrt{2} \end{align*}$

And similarly, that:

$\begin{align*} |z - \beta| + |\alpha - z| &\ge |(z - \beta) + (\alpha - z)| \\ |z - \beta| + 1 &\ge |\alpha - \beta| \qquad \text{as $|\alpha - z| = |-1(z - \alpha)| = |-1||z - \alpha| = 1 \times 1 = 1$} \\ |z - \beta| &\ge 2\sqrt{2} - 1 \end{align*}$

Combining these:

$2\sqrt{2} - 1 \le |z - 3i| \le 1 + 2\sqrt{2}$

Note, also, that the method generalises, to:

$|\alpha - \beta| - |z - \alpha| \le |z - \beta| \le |\alpha - \beta| + |z - \alpha|$

is the result without any substitutions.

Applying it to part (i), we use:

$\alpha = 2 + i \ \ \text{and} \ \ \beta = 0 \quad \implies \quad |\alpha - \beta| = |2 + i - 0| = \sqrt{2^2 + 1^2} = \sqrt{5}$

and so, by substitution, we can confirm @Drongoski's answer, that

$\sqrt{5} - 1 \le |z| \le \sqrt{5} + 1$

We can also expand the method to a circle with any centre $\alpha$ and any other point on the Argand Diagram, $\beta$ . This can provide a quick check for analogous MX1 vector problems.

It can even be applied to cases like $\beta = 1 +i$ , which actually lies on the locus $|z - \alpha| = 1$ , as:

$\alpha = 2 + i \ \ \text{and} \ \ \beta = 1 + i \quad \implies \quad |\alpha - \beta| = |2 + i - (1 + i)| = |1| = 1$

and so yields the (expected) result, that the distance must be between zero and the length of the diameter:

$1 - 1 \le |z - \beta| \le 1 + 1 \qquad \implies \qquad 0 \le |z - 1 - i| \le 2$

rickypontingdagoat · Jan 3, 2024

Thank you so much!

alternative method? (1 Viewer)

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