university of california, berkeley / university of michigan, ann

Real and Convex Algebraic Geometry Cynthia Vinzant University of California, Berkeley / University of Michigan, Ann Arbor Advisor: Prof. Bernd Sturmfels I am interested real algebraic geometry and connections to convexity and optimization. Central objects in this study are affine linear slices of the cone of symmetric, positive semidefinite matrices {x ∈ R n : A 0 + X i x i A i 0}, called spectrahedra, and their linear projections. Their boundaries are hyperbolic hypersurfaces with definite determinantal representations det(A 0 + ∑ i x i A i ). One of the big challenges in this field is to understand (and construct) such determinantal representations of these hypersurfaces. Contact Curves and Determinantal Representations One can construct symmetric determinantal representations of curves in P 2 via their contact curves. If f = det(A(x)) where A(x)= ∑ i x i A i , for matrices A i ∈ C d×d sym , then the degree d - 1 curve g = det A(x) v v T 0 meets f in d(d-1) 2 points of multiplicity 2 for any v ∈ C d \0. Conversely, from such a curve, one can reconstruct the determinantal representation A(x) [1]. Tangency and Convex Hulls Q: What is the algebraic boundary of the convex hull of a curve? its degree? its irreducible components? Here’s my favorite example: C = {(t, 4t 3 - 3t, 16t 5 - 20t 3 +5t): t ∈ [-1, 1]}⊂ R 3 . The Zariski closure of the boundary of its convex hull, conv(C ), is cut out by a union of irreducible hypersurfaces of degrees 1, 1, 4, 4, and 7. One can also ask for set of vertices {a 1 ,a 2 }∈ Sym 2 ([-1, 1]) of edges on conv(C ): C conv(C ) Sym 2 ([-1, 1]) conv(C ) ∨ The algebraic boundary of the dual convex body, conv(C ) ∨ , is the union of two hyperplanes and a degree-7 component given by the discriminant of R{1, t, t 3 ,t 5 }. Central Curves in Optimization Another interesting way algebraic geometry arises in optimization is in the study of central curves of linear pro- grams. Given a linear space L, we can define L -1 = 1 x 1 ,..., 1 x n : x ∈L∩ (C * ) n . The central curve associated to L and two additional vectors c, v ∈ R n is given by (L + span(c)) -1 ∩ (L ⊥ + v). One can write the degree and genus of these curves in terms of matroid invariants and obtain bounds on their curvature [2]. References [1] DIXON: Note on the reduction of a ternary quantic to a symmetrical determinant, Cambr. Proc. 11 (1902) 350–351. [2] DE L OERA ,S TURMFELS, AND V INZANT, The central curve in linear programming, arXiv:1012.3978. GAeL XIX, Berlin, 2011

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Page 1: University of California, Berkeley / University of Michigan, Ann

Real and Convex Algebraic GeometryCynthia Vinzant

University of California, Berkeley / University of Michigan, Ann Arbor

Advisor: Prof. Bernd Sturmfels

I am interested real algebraic geometry and connectionsto convexity and optimization. Central objects in thisstudy are affine linear slices of the cone of symmetric,positive semidefinite matrices

{x ∈ Rn : A0 +∑i

xiAi � 0},

called spectrahedra, and their linear projections.

Their boundaries are hyperbolic hypersurfaces withdefinite determinantal representations det(A0+

∑i xiAi).

One of the big challenges in this field is to understand(and construct) such determinantal representations ofthese hypersurfaces.

Contact Curves and DeterminantalRepresentations

One can construct symmetric determinantal represen-tations of curves in P2 via their contact curves. If f =det(A(x)) where A(x) =

∑i xiAi, for matrices Ai ∈ Cd×d

sym,then the degree d− 1 curve

g = det

(A(x) vvT 0

)meets f in d(d−1)

2 points of multiplicity 2 for any v ∈ Cd\0.Conversely, from such a curve, one can reconstruct thedeterminantal representation A(x) [1].

Tangency and Convex Hulls

Q: What is the algebraic boundary of the convex hull ofa curve? its degree? its irreducible components?

Here’s my favorite example:

C = {(t, 4t3 − 3t, 16t5 − 20t3 + 5t) : t ∈ [−1, 1]} ⊂ R3.

The Zariski closure of the boundary of its convex hull,conv(C), is cut out by a union of irreducible hypersurfacesof degrees 1, 1, 4, 4, and 7. One can also ask for set ofvertices {a1, a2} ∈ Sym2([−1, 1]) of edges on conv(C):

C conv(C) Sym2([−1, 1]) conv(C)∨

The algebraic boundary of the dual convex body,conv(C)∨, is the union of two hyperplanes and a degree-7component given by the discriminant of R{1, t, t3, t5}.

Central Curves in Optimization

Another interesting way algebraic geometry arises in op-timization is in the study of central curves of linear pro-grams. Given a linear space L, we can define

L−1 ={(

x1, . . . ,

): x ∈ L ∩ (C∗)n

The central curve associated to L and two additionalvectors c,v ∈ Rn is given by (L+ span(c))−1 ∩ (L⊥ + v).

One can write the degree and genus of these curves interms of matroid invariants and obtain bounds on theircurvature [2].

References

[1] DIXON: Note on the reduction of a ternary quantic to a symmetrical determinant, Cambr. Proc. 11 (1902) 350–351.

[2] DE LOERA, STURMFELS, AND VINZANT, The central curve in linear programming, arXiv:1012.3978.

GAeL XIX, Berlin, 2011

U.S. v. Oracle Corp. - Berkeley Law - University of California, Berkeley

Eric Linder University of California, Berkeley Lawrence Berkeley National Lab

Gvl Berkeley Cambridge University Minshall