(1)
Cauchy- Riemann equations
Let
| (1) |
where
| (2) |
so
| (3) |
The total derivative of 
with respect to 
is then
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| (4) |
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| (5) |
In terms of and 
, (5) becomes
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| (6) |
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| (7) |
Along the real, or x-axis, 
, so
| (8) |
Along the imaginary, or y-axis, 
, so
| (9) |
If 
is complex differentiable, then the value of the derivative must be the same for a given 
, regardless of its orientation. Therefore, (8) must equal (9), which requires that
| (10) |
and
| (11) |
These are known as the Cauchy-Riemann equations.
They lead to the conditions
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| (12) |
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| (13) |
The Cauchy-Riemann equations may be concisely written as
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| (14) |
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| (15) |
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| (16) |
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| (17) |
where 
is the complex conjugate.
If 
, then the Cauchy-Riemann equations become
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| (18) |
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| (19) |
(Abramowitz and Stegun 1972, p. 17).
If 
and 
satisfy the Cauchy-Riemann equations, they also satisfy Laplace's equation in two dimensions, since
| (20) |
| (21) |
By picking an arbitrary 
, solutions can be found which automatically satisfy the Cauchy-Riemann equations and Laplace's equation. This fact is used to use conformal mappings to find solutions to physical problems involving scalar potentials such as fluid flow and electrostatics.
