advertisement

A Geometric Perspective on Random Walks with Topological Constraints Clayton Shonkwiler Colorado State University Wake Forest University September 9, 2015 Random Walks (and Polymer Physics) Statistical Physics Point of View A polymer in solution takes on an ensemble of random shapes, with topology as the unique conserved quantity. Protonated P2VP Roiter/Minko Clarkson University Plasmid DNA Alonso-Sarduy, Dietler Lab EPF Lausanne Random Walks (and Polymer Physics) Statistical Physics Point of View A polymer in solution takes on an ensemble of random shapes, with topology as the unique conserved quantity. Schematic Image of Polymer Melt Szamel Lab CSU Random Walks (and Polymer Physics) Statistical Physics Point of View A polymer in solution takes on an ensemble of random shapes, with topology as the unique conserved quantity. Physics Setup Modern polymer physics is based on the analogy between a polymer chain and a random walk. —Alexander Grosberg, NYU. A Random Walk with 3,500 Steps Topologically Constrained Random Walks A topologically constrained random walk (TCRW) is a collection of random walks in R3 whose components are required to realize the edges of some fixed multigraph. Abstract graph TCRW Topologically Constrained Random Walks A topologically constrained random walk (TCRW) is a collection of random walks in R3 whose components are required to realize the edges of some fixed multigraph. Barbell graph Branched DNA Benham–Mielke Ann. Rev. Biomed. Eng. 7, 21–53 Topologically Constrained Random Walks A topologically constrained random walk (TCRW) is a collection of random walks in R3 whose components are required to realize the edges of some fixed multigraph. Tezuka Lab, Tokyo Institute of Technology Topologically Constrained Random Walks A topologically constrained random walk (TCRW) is a collection of random walks in R3 whose components are required to realize the edges of some fixed multigraph. Tezuka Lab, Tokyo Institute of Technology A synthetic K3,3 ! Classical Problems • What is the joint distribution of steps in a TCRW? Classical Problems • What is the joint distribution of steps in a TCRW? • What can we prove about TCRWs? • What is the joint distribution of vertex–vertex distances? • What is the expectation of radius of gyration? • What is the expectation of total turning? Classical Problems • What is the joint distribution of steps in a TCRW? • What can we prove about TCRWs? • What is the joint distribution of vertex–vertex distances? • What is the expectation of radius of gyration? • What is the expectation of total turning? • How do we sample TCRWs? Classical Problems • What is the joint distribution of steps in a TCRW? • What can we prove about TCRWs? • What is the joint distribution of vertex–vertex distances? • What is the expectation of radius of gyration? • What is the expectation of total turning? • How do we sample TCRWs? Point of Talk We can use geometric understanding of the moduli space of TCRWs based on a fixed graph to answer these questions. Closed Random Walks (a.k.a. Random Polygons) The simplest multigraph with at least one edge is , which correponds to a classical random walk, modeling a linear polymer. Closed Random Walks (a.k.a. Random Polygons) The simplest multigraph with at least one edge is , which correponds to a classical random walk, modeling a linear polymer. The next simplest multigraph is , which yields a closed random walk (or random polygon), modeling a ring polymer. Closed Random Walks (a.k.a. Random Polygons) The simplest multigraph with at least one edge is , which correponds to a classical random walk, modeling a linear polymer. The next simplest multigraph is , which yields a closed random walk (or random polygon), modeling a ring polymer. Knotted DNA Wassermann et al. Science 229, 171–174 DNA Minicircle simulation Harris Lab University of Leeds, UK Closed Random Walks (a.k.a. Random Polygons) The simplest multigraph with at least one edge is , which correponds to a classical random walk, modeling a linear polymer. The next simplest multigraph is , which yields a closed random walk (or random polygon), modeling a ring polymer. Knotted DNA Wassermann et al. Science 229, 171–174 DNA Minicircle simulation Harris Lab University of Leeds, UK We will focus on closed random walks in this talk. A Closed Random Walk with 3,500 Steps (Incomplete?) History of Sampling Algorithms • Markov Chain Algorithms • crankshaft (Vologoskii 1979, Klenin 1988) • polygonal fold (Millett 1994) • Direct Sampling Algorithms • triangle method (Moore 2004) • generalized hedgehog method (Varela 2009) • sinc integral method (Moore 2005, Diao 2011) (Incomplete?) History of Sampling Algorithms • Markov Chain Algorithms • crankshaft (Vologoskii et al. 1979, Klenin et al. 1988) • convergence to correct distribution unproved • polygonal fold (Millett 1994) • convergence to correct distribution unproved • Direct Sampling Algorithms • triangle method (Moore et al. 2004) • samples a subset of closed polygons • generalized hedgehog method (Varela et al. 2009) • unproved whether this is correct distribution • sinc integral method (Moore et al. 2005, Diao et al. 2011) • requires sampling complicated 1-d polynomial densities oped piece of the subject is humbly known as “Shape Theory.” It was the las A pillow problem matical statistics at Cambridge University, David Kendall [21, 26]. We redi eorists knew, that triangles are naturally mapped onto points of the hemisphe esult and the history of shape space. A side benefit: if we can random polygons, we can urely geometrical derivation of understand the picture of triangle space, delve into the lin answer Lewis Carroll’s Pillow Problem #58. triangles to random matrix theory. uvenate the study of shape theory ! rroll’s Pillow Problem 58 (January 20, 1884). 25 and 83 are page numbers fo . He specifies the longest side AB and assumes that C falls uniformly in t What does it mean to take a random triangle? Question What does it mean to choose a random triangle? What does it mean to take a random triangle? Question What does it mean to choose a random triangle? Statistician’s Answer The issue of choosing a “random triangle” is indeed problematic. I believe the difficulty is explained in large measure by the fact that there seems to be no natural group of transitive transformations acting on the set of triangles. –Stephen Portnoy, 1994 (Editor, J. American Statistical Association) What does it mean to take a random triangle? Question What does it mean to choose a random triangle? What does it mean to take a random triangle? Question What does it mean to choose a random triangle? Applied Mathematician’s Answer We will add a purely geometrical derivation of the picture of triangle space, delve into the linear algebra point of view, and connect triangles to random matrix theory. –Alan Edelman and Gil Strang, 2012 What does it mean to take a random triangle? Question What does it mean to choose a random triangle? What does it mean to take a random triangle? Question What does it mean to choose a random triangle? Differential Geometer’s Answer Pick by the measure defined by the volume form of the natural Riemannian metric on the manifold of 3-gons, of course. That ought to be a special case of the manifold of n-gons. But what’s the manifold of n-gons? And what makes one metric natural? Don’t algebraic geometers understand this? –Jason Cantarella to me, a few years ago Lead-Up to the Algebraic Geometer’s Answer (Seemingly) Trivial Observation 1 Given z1 = a1 + ib1 , . . . , zn = an + ibn X zi2 = (a12 − b12 ) + i(2a1 b1 ) + · · · + (an2 − bn2 ) + i(2an bn ) = (a12 + · · · + an2 ) − (b12 + · · · + bn2 ) + i 2(a1 b1 + · · · + an bn ) D E = (|~a|2 − |~b|2 ) + i 2 ~a, ~b Lead-Up to the Algebraic Geometer’s Answer (Seemingly) Trivial Observation 1 Given z1 = a1 + ib1 , . . . , zn = an + ibn X zi2 = (a12 − b12 ) + i(2a1 b1 ) + · · · + (an2 − bn2 ) + i(2an bn ) = (a12 + · · · + an2 ) − (b12 + · · · + bn2 ) + i 2(a1 b1 + · · · + an bn ) D E = (|~a|2 − |~b|2 ) + i 2 ~a, ~b (Seemingly) Trivial Observation 2 Given z1 = a1 + ib1 , . . . , zn = an + ibn |z12 | + · · · + |zn2 | = |z1 |2 + · · · + |zn |2 = (a12 + b12 ) + · · · + (an2 + bn2 ) = (a12 + · · · + an2 ) + (b12 + · · · + bn2 ) = |~a|2 + |~b|2 The Algebraic Geometer’s Answer Theorem (Hausmann and Knutson, 1997) The space of closed planar n-gons with length 2, up to translation and rotation, is identified with the Grassmann manifold G2 (Rn ) of 2-planes in Rn . The Algebraic Geometer’s Answer Theorem (Hausmann and Knutson, 1997) The space of closed planar n-gons with length 2, up to translation and rotation, is identified with the Grassmann manifold G2 (Rn ) of 2-planes in Rn . Proof. Take an orthonormal frame ~a, ~b for the plane, let z1 a1 + ib1 X̀ . .. ~z = , v = zj2 .. = ` . j=1 an + ibn P By the observations, v0 = vn = 0, |v`+1 − v` | = 2. Rotating the frame a, b in their plane rotates the polygon in the complex plane. zn Our answer Theorem (with Cantarella and Deguchi) The volume form of the standard Riemannian metric on G2 (Rn ) – which is to say, Haar measure – defines the natural probability measure on closed, planar n-gons of length 2 up to translation and rotation. It has a (transitive) action by isometries given by the action of SO(n) on G2 (Rn ). So random triangles are points selected uniformly on RP2 since random triangle → random point in G2 (R3 ) ∼ = G1 (R3 ) = RP2 . Putting the pillow problem to bed Acute triangles (gold) turn out to be defined by natural algebraic conditions on RP2 (or the sphere). Proposition (with Cantarella, Chapman, and Needham, 2015) The fraction of obtuse triangles is 3 log 8 − ' 83.8% 2 π Back to Three Dimensions Theorem (with Cantarella and Deguchi) The volume form of the standard Riemannian metric on G2 (Cn ) defines the natural probability measure on closed space n-gons of length 2 up to translation and rotation. It has a (transitive) action by isometries given by the action of U(n) on G2 (Cn ). Proof. Again, we use an identification due to Hausmann and Knutson where • instead of combining two real vectors to make one complex vector, we combine two complex vectors to get one quaternionic vector • instead of squaring complex numbers, we apply the Hopf map to quaternions Random Polygons and Ring Polymers Statistical Physics Point of View A ring polymer in solution takes on an ensemble of random shapes, with topology (knot type!) as the unique conserved quantity. Knotted DNA Wassermann et al. Science 229, 171–174 Plasmid DNA Alonso-Sarduy, Dietler Lab EPF Lausanne A theorem about random knots Definition The total curvature of a space polygon is the sum of its turning angles. A theorem about random knots Definition The total curvature of a space polygon is the sum of its turning angles. Theorem (with Cantarella, Grosberg, and Kusner) The expected total curvature of a random n-gon of length 2 sampled according to the measure on G2 (Cn ) is π π 2n n+ . 2 4 2n − 3 A theorem about random knots Definition The total curvature of a space polygon is the sum of its turning angles. Theorem (with Cantarella, Grosberg, and Kusner) The expected total curvature of a random n-gon of length 2 sampled according to the measure on G2 (Cn ) is π π 2n n+ . 2 4 2n − 3 Corollary (with Cantarella, Grosberg, and Kusner) At least 1/3 of hexagons and 1/11 of heptagons are unknots. Responsible sampling algorithms How can we sample and determine distributions of knot types? Proposition (classical?) The natural measure on G2 (Cn ) is obtained by generating two random complex n-vectors with independent Gaussian coordinates and their span. In[9]:= RandomComplexVector@n_D := Apply@Complex, Partition@ð, 2D & RandomVariate@NormalDistribution@D, 81, 2 n<D, 82<D@@1DD; ComplexDot@A_, B_D := Dot@A, Conjugate@BDD; ComplexNormalize@A_D := H1 Sqrt@Re@ComplexDot@A, ADDDL A; RandomComplexFrame@n_D := Module@8a, b, A, B<, 8a, b< = 8RandomComplexVector@nD, RandomComplexVector@nD<; A = ComplexNormalize@aD; B = ComplexNormalize@b - Conjugate@ComplexDot@A, bDD AD; 8A, B< D; Using this, we can generate ensembles of random polygons . . . Random 2,000-gons Random 2,000-gons Random 2,000-gons Random 2,000-gons Random 2,000-gons Random 2,000-gons Random 2,000-gons Random 2,000-gons Random 2,000-gons Random 2,000-gons Equilateral Random Walks Physicists tend to model polymers with equilateral random walks; i.e., walks consisting of unit-length steps. The moduli space of such walks up to translation is S 2 (1) × . . . × S 2 (1). {z } | n Equilateral Random Walks Physicists tend to model polymers with equilateral random walks; i.e., walks consisting of unit-length steps. The moduli space of such walks up to translation is S 2 (1) × . . . × S 2 (1). {z } | n Let ePol(n) be the submanifold of closed equilateral random walks (or random equilateral polygons): those walks which satisfy both k~ei k = 1 for all i and n X i=1 ~ei = ~0. The Triangulation Polytope Definition An abstract triangulation T of the n-gon picks out n − 3 nonintersecting chords. The lengths of these chords obey triangle inequalities, so they lie in a convex polytope in Rn−3 called the triangulation polytope Pn . 2 d1 1 d2 0 0 1 2 The Triangulation Polytope Definition An abstract triangulation T of the n-gon picks out n − 3 nonintersecting chords. The lengths of these chords obey triangle inequalities, so they lie in a convex polytope in Rn−3 called the triangulation polytope Pn . d2 ≤ 2 2 d1 d2 ≤ d1 + 1 d1 ≤ 2 1 d2 d1 + d2 ≥ 1 0 0 d1 ≤ d2 + 1 1 2 The Triangulation Polytope Definition An abstract triangulation T of the n-gon picks out n − 3 nonintersecting chords. The lengths of these chords obey triangle inequalities, so they lie in a convex polytope in Rn−3 called the triangulation polytope Pn . (0, 2, 2) (2, 2, 2) d1 d2 (2, 0, 2) d3 (0, 0, 0) (2, 2, 0) Action-Angle Coordinates Definition If Pn is the triangulation polytope and T n−3 = (S 1 )n−3 is the torus of n − 3 dihedral angles, then there are action-angle coordinates: α : Pn × T n−3 → ePol(n)/ SO(3) 14 ✓2 d1 d2 ✓1 Polygons and Polytopes, Together Theorem (with Cantarella) α pushes the standard probability measure on Pn × T n−3 forward to the correct probability measure on ePol(n)/ SO(3). Polygons and Polytopes, Together Theorem (with Cantarella) α pushes the standard probability measure on Pn × T n−3 forward to the correct probability measure on ePol(n)/ SO(3). Corollary (with Cantarella) At least 1/2 of the space of equilateral 6-edge polygons consists of unknots. Polygons and Polytopes, Together Theorem (with Cantarella) α pushes the standard probability measure on Pn × T n−3 forward to the correct probability measure on ePol(n)/ SO(3). Ingredients of the Proof. Kapovich–Millson toric symplectic structure on polygon space + Duistermaat–Heckman theorem + Hitchin’s theorem on compatibility of Riemannian and symplectic volume on symplectic reductions of Kähler manifolds + Howard–Manon–Millson analysis of polygon space. Corollary (with Cantarella) At least 1/2 of the space of equilateral 6-edge polygons consists of unknots. Numerical Experiments Despite the theorem, we observe experimentally that (with 95% confidence) between 1.1 and 1.5 in 10,000 hexagons are knotted. How can we be so sure? Numerical Experiments Despite the theorem, we observe experimentally that (with 95% confidence) between 1.1 and 1.5 in 10,000 hexagons are knotted. How can we be so sure? Algorithm (with Cantarella) A Markov chain which converges to the correct measure on ePol(n)/ SO(3). Steps in the chain are generated in O(n2 ) time. This generalizes to other fixed edgelength polygon spaces as well as to polygons in various confinement regimes. Numerical Experiments Despite the theorem, we observe experimentally that (with 95% confidence) between 1.1 and 1.5 in 10,000 hexagons are knotted. How can we be so sure? Algorithm (with Cantarella) A Markov chain which converges to the correct measure on ePol(n)/ SO(3). Steps in the chain are generated in O(n2 ) time. This generalizes to other fixed edgelength polygon spaces as well as to polygons in various confinement regimes. Algorithm (with Cantarella and Uehara) An unbiased sampling algorithm which generates a uniform point on ePol(n)/ SO(3) in O(n5/2 ) time. Numerical Experiments Despite the theorem, we observe experimentally that (with 95% confidence) between 1.1 and 1.5 in 10,000 hexagons are knotted. How can we be so sure? Algorithm (with Cantarella) A Markov chain which converges to the correct measure on ePol(n)/ SO(3). Steps in the chain are generated in O(n2 ) time. This generalizes to other fixed edgelength polygon spaces as well as to polygons in various confinement regimes. Algorithm (with Cantarella and Uehara) An unbiased sampling algorithm which generates a uniform point on ePol(n)/ SO(3) in O(n5/2 ) time. The hard part is sampling the convex polytope Pn . The Fan Triangulation Polytope (2, 3, 2) d1 d2 d3 (0, 0, 0) (2, 1, 0) The polytope Fn corresponding to the “fan triangulation” is defined by the triangle inequalities: 0 ≤ d1 ≤ 2 1 ≤ di + di+1 |di − di+1 | ≤ 1 0 ≤ dn−3 ≤ 2 A change of coordinates If we introduce a fake chordlength d0 = 1, and make the linear transformation si = di − di+1 , for 0 ≤ i ≤ n − 4, sn−3 = dn−3 − d0 then our inequalities 0 ≤ d1 ≤ 2 1 ≤ di + di+1 |di − di+1 | ≤ 1 0 ≤ dn−3 ≤ 2 become −1 ≤ si ≤ 1, | {z X |di −di+1 |≤1 si = 0, } 2 | i−1 X j=0 sj + si ≤ 1 {z di +di+1 ≥1 } A change of coordinates If we introduce a fake chordlength d0 = 1, and make the linear transformation si = di − di+1 , for 0 ≤ i ≤ n − 4, sn−3 = dn−3 − d0 then our inequalities 0 ≤ d1 ≤ 2 1 ≤ di + di+1 |di − di+1 | ≤ 1 0 ≤ dn−3 ≤ 2 become X −1 ≤ si ≤ 1, si = 0, | {z } easy conditions 2 i−1 X j=0 sj + si ≤ 1 | {z } hard conditions Basic Idea Definition The m-dimensional polytope Cm is the slice of the hypercube [−1, 1]m+1 by the plane x1 + · · · + xm+1 = 0. 0 → 1 2 2 2 1 1 0 0 0 1 2 Idea Sample points in Cn−3 , which all obey the “easy conditions”, and reject any samples which fail to obey the “hard conditions”. Relative volumes Theorem (Marichal-Mossinghoff) The volume of the projection of Cn−3 is Pb n−2 2 c j=0 n−2 j (−1)j (n − 2j − 2)n−3 (n − 3)! Theorem (Khoi, Takakura, Mandini) The volume of the (n − 3)-dimensional fan triangulation polytope for n-edge equilateral polygons Fn is − Pb n2 c j n−3 j=0 (−1) (n − 2j) 2(n − 3)! n j Runtime of algorithm depends on acceptance ratio Acceptance ratio = Vol(Fn ) Vol(Cn−3 ) bounded below by n1 . is conjectured ' n6 . It is certainly 0.14 0.12 0.10 Vol(Fn ) Vol(Cn−3 ) 0.08 graph of 0.06 6 n (in red) 0.04 0.02 100 200 300 400 number of edges in polygon 500 Sampling Cn−3 Recall that we’re interested in the polytope Cn−3 determined by s0 + s1 + . . . + sn−3 = 0 in the cube [−1, 1]n−2 . Sampling Cn−3 Recall that we’re interested in the polytope Cn−3 determined by s0 + s1 + . . . + sn−3 = 0 in the cube [−1, 1]n−2 . After dropping the last coordinate, this corresponds to the slab Qn−3 = {−1 ≤ s0 + s1 + . . . + sn−4 ≤ 1} in the hypercube [−1, 1]n−3 . Sampling Cn−3 Recall that we’re interested in the polytope Cn−3 determined by s0 + s1 + . . . + sn−3 = 0 [−1, 1]n−2 . in the cube After dropping the last coordinate, this corresponds to the slab Qn−3 = {−1 ≤ s0 + s1 + . . . + sn−4 ≤ 1} in the hypercube [−1, 1]n−3 . C2 Q2 Sampling Cn−3 Recall that we’re interested in the polytope Cn−3 determined by s0 + s1 + . . . + sn−3 = 0 [−1, 1]n−2 . in the cube After dropping the last coordinate, this corresponds to the slab Qn−3 = {−1 ≤ s0 + s1 + . . . + sn−4 ≤ 1} in the hypercube [−1, 1]n−3 . Q3 Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. 0.5 0.4 n=1 P(−1 0.3 P si ≤ 1) = 1 0.2 0.1 -4 -2 0 2 4 Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. 0.5 0.4 n=2 0.3 P(−1 P si ≤ 1) = 3 4 0.2 0.1 -4 -2 0 2 4 Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. 0.5 0.4 n=3 0.3 P(−1 P si ≤ 1) = 2 3 0.2 0.1 -4 -2 0 2 4 Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. 0.5 0.4 n=4 0.3 P(−1 P si ≤ 1) = 115 192 0.2 0.1 -4 -2 0 2 4 Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. 0.5 0.4 n=5 0.3 P(−1 P si ≤ 1) = 11 20 0.2 0.1 -4 -2 0 2 4 Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. By Shepp’s local limit theorem, ! n−4 X P −1 ≤ si ≤ 1 ' P −1 ≤ N i=0 0, r n−3 3 ! ≤1 ! Sampling Qn−3 We can sample Qn−3 (and hence Cn−3 ) by rejection sampling [−1, 1]n−3 . The acceptance probability is Vol Qn−3 . Vol[−1, 1]n−3 But this is just the probability that a sum of Uniform([−1, 1]) variates is between −1 and 1. By Shepp’s local limit theorem, ! n−4 X P −1 ≤ si ≤ 1 ' P −1 ≤ N i=0 = erf s 0, r 3 2(n − 3) n−3 3 ! ' ! r ≤1 6 . πn ! The Algorithm Moment Polytope Sampling Algorithm (with Cantarella and Uehara, 2015) 1 2 3 Generate (s0 , . . . , sn−4 ) uniformly on [−1, 1]n−3 O(n) time √ P Test whether −1 ≤ si ≤ 1 acceptance ratio ' 1/ n P Let sn−3 = − si and test (s0 , . . . , sn−3 ) against the “hard” conditions acceptance ratio > 1/n 4 Change coordinates to get diagonal lengths 5 Generate dihedral angles from T n−3 6 Build sample polygon in action-angle coordinates Future Challenges • Topologically-constrained random walks based on more complicated graphs. • Incorporate geometric constraints (restricted turning angles, excluded volume, etc.), which correspond to physical restrictions on polymer geometries. • Stronger theoretical bounds on knot probabilities, average knot invariants, etc. • A general theory of random piecewise-linear submanifolds? Thank you! Thank you for listening! References • Probability Theory of Random Polygons from the Quaternionic Viewpoint Jason Cantarella, Tetsuo Deguchi, and Clayton Shonkwiler Communications on Pure and Applied Mathematics 67 (2014), no. 10, 658–1699. • The Expected Total Curvature of Random Polygons Jason Cantarella, Alexander Y Grosberg, Robert Kusner, and Clayton Shonkwiler American Journal of Mathematics 137 (2015), no. 2, 411–438 • The Symplectic Geometry of Closed Equilateral Random Walks in 3-Space Jason Cantarella and Clayton Shonkwiler Annals of Applied Probability, to appear. http://arxiv.org/a/shonkwiler_c_1 A Combinatorial Mystery Recall the volumes of the cross polytope and moment polytope: Vol(Cn−3 ) = Pb n−2 2 c Vol(Fn ) = − j=0 Pb n2 c j=0 (−1)j (n − 2j − 2)n−3 (n − 3)! (−1)j (n − 2j)n−3 2(n − 3)! n j n−2 j A Combinatorial Mystery Recall the volumes of the cross polytope and moment polytope: Vol(Fn ) = − Pb n2 c j=0 (−1)j (n − 2j)n−3 2(n − 3)! √ 3 3 ' Cn/2 conj. 8 n j where Cm is the mth Catalan number 2m Γ(2m + 1) 1 Cm = = . m+1 m Γ(m + 2)Γ(m + 1) Catalan Numbers and Moment Polytope Volumes The ratio of Vol(Fn ) to Cn/2 : 1. 0.8 Vol(Fn ) Cn/2 0.6 √ 3 3 8 0.4 (in red) 0.2 0 20 40 60 80 number of edges in polygon 100 A Recurrence Relation for Vol(Fn ) The normalized volume (n − 3)! Vol(Fn ) of the moment polytope is the k = 1 case of a two-parameter family V (n, k ) given by the recurrence relation V (n, k ) = (n − k − 1)V (n − 1, k − 1) + (n + k − 1)V (n − 1, k + 1) subject to the boundary conditions V (n, 0) = 0, V (3, 1) = 1, V (3, 2) = 1 . 2 A Recurrence Relation for Vol(Fn ) The normalized volume (n − 3)! Vol(Fn ) of the moment polytope is the k = 1 case of a two-parameter family V (n, k ) given by the recurrence relation V (n, k ) = (n − k − 1)V (n − 1, k − 1) + (n + k − 1)V (n − 1, k + 1) 0 1 0 0 0 0 0 0 0 1 2 A Recurrence Relation for Vol(Fn ) The normalized volume (n − 3)! Vol(Fn ) of the moment polytope is the k = 1 case of a two-parameter family V (n, k ) given by the recurrence relation V (n, k ) = (n − k − 1)V (n − 1, k − 1) + (n + k − 1)V (n − 1, k + 1) 0 0 0 0 0 0 0 0 1 2 5 24 154 1280 13005 156800 1 2 1 4 22 160 1445 15680 199066 1 8 75 800 9821 137088 1 16 236 3584 58478 1 32 1 721 64 1 15232 2178 128 1 cf. OEIS A012249 “Volume of a certain rational polytope. . . ” Catalan Numbers and Eulerian Numbers Conjecture √ 3 3 Cn/2 . Vol(Fn ) ' 8 Catalan Numbers and Eulerian Numbers Conjecture √ 3 3 Cn/2 . Vol(Fn ) ' 8 Combining the conjecture with Stirling’s approximation and r 6 n−3 Vol(Cn−3 ) ' 2 πn would suffice to prove Vol(Fn ) 6 ' . Vol(Cn−3 ) n