Björling problem

Problem in differential geometry
Catalan's minimal surface. It can be defined as the minimal surface symmetrically passing through a cycloid.

In differential geometry, the Björling problem is the problem of finding a minimal surface passing through a given curve with prescribed normal (or tangent planes). The problem was posed and solved by Swedish mathematician Emanuel Gabriel Björling,[1] with further refinement by Hermann Schwarz.[2]

The problem can be solved by extending the surface from the curve using complex analytic continuation. If c ( s ) {\displaystyle c(s)} is a real analytic curve in R 3 {\displaystyle \mathbb {R} ^{3}} defined over an interval I, with c ( s ) 0 {\displaystyle c'(s)\neq 0} and a vector field n ( s ) {\displaystyle n(s)} along c such that | | n ( t ) | | = 1 {\displaystyle ||n(t)||=1} and c ( t ) n ( t ) = 0 {\displaystyle c'(t)\cdot n(t)=0} , then the following surface is minimal:

X ( u , v ) = ( c ( w ) i w 0 w n ( w ) × c ( w ) d w ) {\displaystyle X(u,v)=\Re \left(c(w)-i\int _{w_{0}}^{w}n(w)\times c'(w)\,dw\right)}

where w = u + i v Ω {\displaystyle w=u+iv\in \Omega } , u 0 I {\displaystyle u_{0}\in I} , and I Ω {\displaystyle I\subset \Omega } is a simply connected domain where the interval is included and the power series expansions of c ( s ) {\displaystyle c(s)} and n ( s ) {\displaystyle n(s)} are convergent.[3]

A classic example is Catalan's minimal surface, which passes through a cycloid curve. Applying the method to a semicubical parabola produces the Henneberg surface, and to a circle (with a suitably twisted normal field) a minimal Möbius strip.[4]

A unique solution always exists. It can be viewed as a Cauchy problem for minimal surfaces, allowing one to find a surface if a geodesic, asymptote or lines of curvature is known. In particular, if the curve is planar and geodesic, then the plane of the curve will be a symmetry plane of the surface.[5]

References

  1. ^ E.G. Björling, Arch. Grunert, IV (1844) pp. 290
  2. ^ H.A. Schwarz, J. reine angew. Math. 80 280-300 1875
  3. ^ Kai-Wing Fung, Minimal Surfaces as Isotropic Curves in C3: Associated minimal surfaces and the Björling's problem. MIT BA Thesis. 2004 http://ocw.mit.edu/courses/mathematics/18-994-seminar-in-geometry-fall-2004/projects/main1.pdf
  4. ^ W.H. Meeks III (1981). "The classification of complete minimal surfaces in R3 with total curvature greater than 8 π {\displaystyle -8\pi } ". Duke Math. J. 48 (3): 523–535. doi:10.1215/S0012-7094-81-04829-8. MR 0630583. Zbl 0472.53010.
  5. ^ Björling problem. Encyclopedia of Mathematics. URL: http://www.encyclopediaofmath.org/index.php?title=Bj%C3%B6rling_problem&oldid=23196

External image galleries

  • Björling Surfaces, at the Indiana Minimal Surface Archive: http://www.indiana.edu/~minimal/archive/Bjoerling/index.html