Bäcklund transforms have their origins in differential geometry: the first nontrivial example is the transformation of pseudospherical surfaces introduced by L. Bianchi and A.V. Bäcklund in the 1880s. This is a geometrical construction of a new pseudospherical surface from an initial such surface using a solution of a linear differential equation. Pseudospherical surfaces can be described as solutions of the sine-Gordon equation, and hence the Bäcklund transformation of surfaces can be viewed as a transformation of solutions of the sine-Gordon equation.

The prototypical example of a Bäcklund transform is the Cauchy–Riemann system

${\displaystyle u_{x}=v_{y},\quad u_{y}=-v_{x},\,}$ 

which relates the real and imaginary parts ${\displaystyle u}$  and ${\displaystyle v}$  of a holomorphic function. This first order system of partial differential equations has the following properties.

1. If ${\displaystyle u}$  and ${\displaystyle v}$  are solutions of the Cauchy–Riemann equations, then ${\displaystyle u}$  is a solution of the Laplace equation
   ${\displaystyle u_{xx}+u_{yy}=0}$ 
   (i.e., a harmonic function), and so is ${\displaystyle v}$ . This follows straightforwardly by differentiating the equations with respect to ${\displaystyle x}$  and ${\displaystyle y}$  and using the fact that
   ${\displaystyle u_{xy}=u_{yx},\quad v_{xy}=v_{yx}.\,}$ 
2. Conversely if ${\displaystyle u}$  is a solution of Laplace's equation, then there exist functions ${\displaystyle v}$  which solve the Cauchy–Riemann equations together with ${\displaystyle u}$ .

Thus, in this case, a Bäcklund transformation of a harmonic function is just a conjugate harmonic function. The above properties mean, more precisely, that Laplace's equation for ${\displaystyle u}$  and Laplace's equation for ${\displaystyle v}$  are the integrability conditions for solving the Cauchy–Riemann equations.

These are the characteristic features of a Bäcklund transform. If we have a partial differential equation in ${\displaystyle u}$ , and a Bäcklund transform from ${\displaystyle u}$  to ${\displaystyle v}$ , we can deduce a partial differential equation satisfied by ${\displaystyle v}$ .

This example is rather trivial, because all three equations (the equation for ${\displaystyle u}$ , the equation for ${\displaystyle v}$  and the Bäcklund transform relating them) are linear. Bäcklund transforms are most interesting when just one of the three equations is linear.

Suppose that u is a solution of the sine-Gordon equation

${\displaystyle u_{xy}=\sin u.\,}$ 

Then the system

${\displaystyle {\begin{aligned}v_{x}&=u_{x}+2a\sin {\Bigl (}{\frac {v+u}{2}}{\Bigr )}\\v_{y}&=-u_{y}+{\frac {2}{a}}\sin {\Bigl (}{\frac {v-u}{2}}{\Bigr )}\end{aligned}}\,\!}$ 

where a is an arbitrary parameter, is solvable for a function v which will also satisfy the sine-Gordon equation. This is an example of an auto-Bäcklund transform.

By using a matrix system, it is also possible to find a linear Bäcklund transform for solutions of sine-Gordon equation.

A Bäcklund transform can turn a non-linear partial differential equation into a simpler, linear, partial differential equation.

For example, if u and v are related via the Bäcklund transform

${\displaystyle {\begin{aligned}v_{x}&=u_{x}+2a\exp {\Bigl (}{\frac {u+v}{2}}{\Bigr )}\\v_{y}&=-u_{y}-{\frac {1}{a}}\exp {\Bigl (}{\frac {u-v}{2}}{\Bigr )}\end{aligned}}\,\!}$ 

where a is an arbitrary parameter, and if u is a solution of the Liouville equation

${\displaystyle u_{xy}=\exp u\,\!}$ 

then v is a solution of the much simpler equation, ${\displaystyle v_{xy}=0}$ , and vice versa.

We can then solve the (non-linear) Liouville equation by working with a much simpler linear equation.

• Integrable system
• Korteweg–de Vries equation
• Darboux transformation

• "Bäcklund transformation", Encyclopedia of Mathematics, EMS Press, 2001 [1994]
• Weisstein, Eric W. "Bäcklund Transformation". MathWorld.