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<math>f'(z_0)=\lim_{z\to z_0}\frac{f(z)-f(z_0)}{z-z_0}</math>
 
<math>f'(z_0)=\lim_{z\to z_0}\frac{f(z)-f(z_0)}{z-z_0}</math>
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 +
Here's a hint on I.8.3 --[[User:Bell|Bell]]
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 +
It is straightforward to show that
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 +
<math>(z,w)\mapsto z+w</math>
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 +
is a continuous mapping
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<math>(\mathbb C\times \mathbb C)\to\mathbb C</math>
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 +
because
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<math>|(z+w)-(z_0+w_0)|\le|z-z_0|+|w-w_0|</math>
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and to make this last quantity less than epsilon, it suffices to take
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<math>|z-z_0|<\epsilon/2</math>
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 +
and
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<math>|w-w_0|<\epsilon/2.</math>
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To handle complex multiplication, you will need to use the standard trick:
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<math>zw-z_0w_0 = zw-zw_0+zw_0-z_0w_0=z(w-w_0)+w_0(z-z_0)</math>.

Revision as of 07:57, 3 September 2009

Homework 1

HWK 1 problems

This is where members of the class could exchange ideas about the homework. Here is an example of a math formula that is easy to input:

$ f'(z_0)=\lim_{z\to z_0}\frac{f(z)-f(z_0)}{z-z_0} $

Here's a hint on I.8.3 --Bell

It is straightforward to show that

$ (z,w)\mapsto z+w $

is a continuous mapping

$ (\mathbb C\times \mathbb C)\to\mathbb C $

because

$ |(z+w)-(z_0+w_0)|\le|z-z_0|+|w-w_0| $

and to make this last quantity less than epsilon, it suffices to take

$ |z-z_0|<\epsilon/2 $

and

$ |w-w_0|<\epsilon/2. $

To handle complex multiplication, you will need to use the standard trick:

$ zw-z_0w_0 = zw-zw_0+zw_0-z_0w_0=z(w-w_0)+w_0(z-z_0) $.

Alumni Liaison

ECE462 Survivor

Seraj Dosenbach