Strong Markov property of determinatal processes

Strong Markov property of determinatal processes Hideki Tanemura Chiba university (Chiba, Japan) (August 2, 2013) Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 1 / 27

Introduction The configuration space of unlabelled particles: { M = ξ( ) = } δ xj ( ) : {j I : x j K} <, for any K compact j I M is a Polish space with the vague topology. The configuration space of noncolliding systems: { } M 0 = ξ M : ξ({x}) = 1, for any x supp ξ { } = {x j } : {j : x j K} <, for any K compact. A configuration space X is relative compact, if sup ξ(k) <, ξ X for any K R compact Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 2 / 27

Introduction The moment generating function of multitime distribution of the M-valued process Ξ(t) is defined as { M Ψ (t 1,...,t M ) (f 1,..., f M ) = Ψ t (f) = E exp m=1 for 0 t 1 < t 2 < < t M, f = (f 1, f 2,..., f M ) C 0 (R) M. Ψ t (f) = N m 0, 1 m M { M Q M m=1 RN m m=1 R 1 N m! dx(m) N m ρ ξ ( t 1, x (1) N 1 ;... ; t M, x (M) N M ), f m (x)ξ(t m, dx)} ] (1) N m ( χ m i=1 x (m) i ) } with χ m ( ) = e f m( ) 1 and the multitime correlation functions ρ ξ (... ). Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 3 / 27

Introduction A processs Ξ(t) is said to be determinantal if the moment generating function (1) is given by the Fredholm determinant ] Ψ t f] = δ st δ x (y) + K(s, x; t, y)χ t (y), (2) Det (s,t) {t 1,t 2,...,t M } 2, (x,y) R 2 In other words, the multitime correlation functions are represented as ] ( ) ρ t 1, x (1) N 1 ;... ; t M, x (M) N M = det K(t m, x (m) 1 j N j ; t n, x (n) k ). m,1 k N n 1 m,n M The function K is called the correlation kernel of the process Ξ(t). Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 4 / 27

Examples of determinatal processes (1) Non-colliding Brownian motion (The Dyson model): X j (t) = x j + B j (t) + k:1 k N k j t 0 ds X j (s) X k (s), 1 j N where B j (t), j = 1, 2,..., N are independent one dimensional BMs. (2) Non-colliding Bessel process: X j (t) = x j + B j (t) + 2ν + 1 2 + t { k:1 k N k j 0 t 0 ds X j (s) 1 X j (s) X k (s) + 1 X j (s) + X k (s) } ds, 1 j N Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 5 / 27

Related results (O) Spohn: 1987, Prḧofer-Spohn: JSP02, Johanson: CMP02] Infinite many particle systems Ξ t obtaine by the Bulk or the Soft-edge scaling limits of the processes. equilibrium systems (1) Katori-T: JSP09, CMP10, JSP11, ECP13]: Infinite many particle systems in non-equilibrium (2) Katori-T: MPRF11] Markov property of the reversible Markov processes. (3) Oasda: PTRF12, SPA13, AOP13, Osada-T: in preparation, Osada-Honda: preprint] Constructing diffusion processes Ξ DF t by Dirichlet form technique and deriving ISDEs related to them. (4) Osada-T: in preparation] The uniqueness of solutions of the ISDE. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 6 / 27

Infinite dimensional SDEs for Ξ DF t = j N δ X j (t) Bulk scaling limit : Osada:PTRF12] β = 1, 2 and 4 dx j (t) = db j (t) + β 2 k N k j dt, j N. (3) X j (t) X k (t) Hard edge scaling limit : Honda-Osada: preprint] ν > 1 dx j (t) = db j (t) + 2ν + 1 1 2 X j (t) dt + β { 2 k N k j 1 X j (t) X k (t) + 1 X j (t) + X k (t) } dt, j N. (4) Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 7 / 27

Infinite dimensional SDEs for Ξ DF t = j N δ X j (t) Soft edge scaling limit : Osada-T: in preparation] β = 1, 2 and 4 where ρ(x) = dx j (t) = db j (t) + β 2 lim L k N,k j X k (t) L x1(x<0) π. 1 X j (t) X k (t) ρ(y) y L y dy dt, j N, (5) Questions 1. The Dyson model constructed by Spohn(1987) solves ISDE (1)? 2. The infinite particle system constructed by Prähofer-Spohn(2002), Johannson(2002) solves ISDE (2)? Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 8 / 27

Main Theorem In this talk we consider the case that β = 2, and ν = 1 2, 1 2. Theorem Let Ξ t be the determinantal process obtained by (i) or (ii) or (iii): (i) the bulk scaling limit of noncolliding BM (ii) the soft-edge scaling limit of noncolliding BM (iii) the hard-edge scalig limit of one or three dimensional Bessel process. There exists the state spaces S associated with the process Ξ t such that the process (P ξ, Ξ t ), ξ S has the strong Markov property. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 9 / 27

Answer the questions Strong Markov property of Ξ t the quasi-regularity of the Dirichlet form associated with Ξ t Ξ t solve the same ISDE as the coincidence of the processes Ξ t and Ξ DF t (by the technique in (3)) Ξ DF t Ξ DF t (by (4)) Remark. The state space of is uniquely determined up to quasi everwhere. That is S is a version of the state space. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 10 / 27

State Space M κ 1 L 0 (ζ), ζ M, κ 1 > 0, L 0 N, is the set of configurations ξ M 0 satisfying N κ 2 ζ(0, L] ξ(0, L]) L κ 1, ζ( L, 0] ξ( L, 0]) L κ 1, L L 0. (6) L 0, κ 2 > 0, L 0 N, is the set of configurations ξ M 0 satisfying ( ) ξ x e x κ2, x + e x κ2 ] \ {x} = 0, x supp ξ, x > L 0. (7) Put M κ 1 (ζ) = L 0 N S(ζ) = M κ 1 L 0 (ζ), κ (0,1) N κ 2 = L 0 N (M κ (ζ) N κ ). N κ 2 L 0. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 11 / 27

State space We introduce the following configurations: ζ ρ = δ x, ζ Ai = δ x, ζ (ν) = x:sin(ρx)=0 x:ai(x)=0 x:j ν(x)=0 Let µ sin : The determinatal point process with the sine kernel. µ Ai : The determinatal point process with the Airy kernel. µ Jν : The determinatal point process with the Bessel kernel. Let κ 2 > κ 1 > 0, It is readily checked that µ Jν ({ξ 2 = j N µ sin (M κ 1 (ζ ρ ) N κ 2 ) = 1, κ 1 > 0, µ Ai (M κ 1 (ζ Ai ) N κ 2 ) = 1 κ 1 > 1/2, δ x 2 j : ξ = j N δ x. δ xj M κ 1 (ζ (ν ) N κ 2 }) = 1 κ 1 > 0. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 12 / 27

Harmonic transformation (Brownian motions with a drift) B(t) = (B 1 (t),..., B N (t)) : N-dim BM Let g be a F t -adapted symmetric measurable function on C(0, T ], R N ). (1) Noncolliding Brownian motions with constant drift E x g(y( ))] = E x g(b( )) h N(B(T )) h N (x) N j=1 ] e D(B j x j )(T ) D2 T 2, where h N (x) = 1 i<j N (x j x i ) = det 1 i,j N x j 1 i ]. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 13 / 27

Harmonic transformation (Bessel processes ν = ± 1 2 ) Suppose that g(x 1, x 2,..., x N ) = g( x 1, x 2,..., x N ). (2) Noncolliding 3-dimensional Bessel process (Type C) where E x g(y( ))] = E x h (0) N (x) = 1 i<j N g(b( ))) h(0) N (B(T )) h (0) N (x) N j=1 (xj 2 xi 2 ) = det 1 i,j N ] B j (T ), x j x 2(j 1) i (3) Noncolliding 1-dimensional Bessel process (Type D) E x g 1 (Y( ))] = E x g(b( )) h(0) N (B(T ))] h (0) N (x). ]. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 14 / 27

Entire functions Suppose that ξ = ξ(r) i=1 δ u i M 0 with ξ(r) N. ( Φ 0 (ξ, u, z) = 1 z u ), z C, u R r u r supp ξ {u} (1)(Noncolliding Brownian motions with constant drift) Φ D (ξ, u, z) = e D(z u) Φ 0 (ξ, u, z), u R. (2)(Noncolliding 3-dimensional Bessel process (Type C)) Φ (1/2) (ξ, u, z) = z u Φ 0(ξ 2, u 2, z 2 ), u > 0. (3)( Noncolliding 1-dimensional Bessel process (Type D)) Φ ( 1/2) (ξ, u, z) = Φ 0 (ξ 2, u 2, z 2 ), u 0. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 15 / 27

Complex Brownian motion Put V j (t), 1 j N : indep. BMs with V j (0) = u j R W j (t), 1 j N : indep. BMs with W j (0) = 0, Z j (t) = V j (t) + 1W j (t), 1 j N : Complex BMs Z(t) = (Z 1 (t), Z 2 (t),..., Z N (t)), V(t) = (V 1 (t), V 2 (t),..., V N (t)), Noting that and for ξ = N j=1 δ x j, x C N, E W h N (Z(T ))] = h N (V(N)), h N (z) h N (x) = det Φ 0(ξ, x j, z k ). 1 j,k N Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 16 / 27

Theorem (Complex Brownian motion representations) Let 0 < t < T <. For any F(t)-measurable function F : (1)(Noncolliding Brownian motions with constant drift) ξ(r) ( )] ))] E ξ F Ξ( ) = Eu F det Φ D (ξ, u i, Z j (T. i=1 δ Vi ( ) 1 i,j ξ(r) (2)(Noncolliding 3-dimensional Bessel process (Type C)) ξ(r) ( )] ))] E ξ F Ξ( ) = Eu F det Φ (1/2) (ξ, u i, Z j (T. i=1 δ Vi ( ) 1 i,j ξ(r) (3)( Noncolliding 1-dimensional Bessel process (Type D)) ξ(r) ( )] ))] E ξ F Ξ( ) = Eu F det Φ ( 1/2) (ξ, u i, Z j (T. i=1 δ Vi ( ) 1 i,j ξ(r) Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 17 / 27

Entire functions for configurations of infinitely many points Lemma 1 If ξ M κ 1 (ζ ρ ) N κ 2 with 0 < κ 1 < κ 2 < 1, Φ 0 (ξ, a, z) = lim L Φ 0(ξ L, L], a, z), exists, and Φ 0 (ξ, a, z) C exp{c( a δ + z θ )}, a supp ξ, z C, for some C = C(κ 1, κ 2, L 0 ) > 0,c = c(κ 1, κ 2, L 0 ) > 0, δ (0, 1) and θ (1, 2). THEOREM 1 (Katori-T. CMP10, ECP13) Suppose that ξ S(ζ ρ ). Then (Ξ(t), P ξ L,L] ) (Ξ(t), P ξ ), L weakly on C(0, ) M 0 ). In particular, the process (Ξ(t), P ξ ) has a modification which is almost-surely continuous on 0, ) with Ξ(0) = ξ. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 18 / 27

CBM representation for infinte particle systems In case F is a polynomial, CBMR holds for ξ S(ζ ρ ). For example (1) For any measurable function f on R with compact support ] E ξ f (u)ξ t (du) = ξ(du)e u f (V 1 (t))φ 0 (ξ, u, Z 1 (T )] R R (2) For any measurable symmetric function f on R 2 with compact support ] E ξ φ(u 1, u 2 )Ξ t Ξ t (du 1 du 2 ) u 1 <u 2 ] = ξ(du)e (u1,u 2 ) f (V 1 (t), V 2 (t)) det Φ 0(ξ, u i, Z j (T )) u 1 <u 2 1 i,j 2 Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 19 / 27

State space Lemma 2 Let ζ = ζ ρ, ζ Ai or ζ (ν), ν = ± 1 2, 1/2 < κ 1 < κ 2 < 1. Then for any κ 1 > κ 1 and κ 2 > κ 2 ( ) P ξ Ξ t M κ 1 (ζ) N κ 2, t > 0 = 1. To prove this lemma we apply CBMR to functions F 1 and F 2 : ( ) F 1 δ Xj ( ) = sup f (X j (t)) f (X j (0)), j j t 0,T ] ( ) F 2 δ Xj ( ) = sup f ( X j (t) X k (t) ), j j,k t 0,T ] and the following identity: Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 20 / 27

Another key identity For a symmetric function F (v 1, v 2 ) ] E (u1,u 2 ) f (V 1, V 2 ) det Φ 0(ξ, u i, Z j ) 1 i,j 2 = E (u1,u 2 ) f (V 1, V 2 ) h 2(V 1 (T ), V 2 (T )) h 2 (u 1, u 2 ) ] Φ 0 (ξ {u 1, u 2 } c, u j, Z j (T )). (8) j=1,2 Then, (Y 1 (t), Y 2 (t)) can be treated as the non-colliding Brownian motion of 2-particles. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 21 / 27

Soft-edge case We introduce the entire function defined by { z } Φ 1 (ξ, 0, z) = exp {0} c x ξ(dx) Φ 0 (ξ, 0, z). Then Ai(z) = exp{d 1 z}φ 1 (ζ Ai, 0, z). The soft-edge scaling limit case is associated with the entire function for ξ with ξ(r) = N defined by { z } Φ Ai (ξ, 0, z) = exp d 1 z + {0} c x (ξ ζn Ai)(dx) Φ 1 (ζ Ai, 0, z), Φ Ai (ξ, u, z) = Φ Ai (τ u ξ, 0, z u). where ζ N Ai = N j=1 δ a j, with the decreasing sequence {a j } of zeros of Ai. Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 22 / 27

Hard-edge case J ν (z) = (z/2)ν Γ(ν + 1) Φ 0(ζ 2 J ν, z 2 ) The hard-edge scaling limit case is associated with the entire functions defined by Φ (1/2) (ξ, u, z) = z u Φ 0(ξ 2, u 2, z 2 ), Φ ( 1/2) (ξ, u, z) = Φ 0 (ξ 2, u 2, z 2 ). Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 23 / 27

Markov property Lemma 3 Let (ζ, Φ) = (ζ ρ, Φ 0 ), (ζ Ai, Φ Ai ) or (ζ (ν), Φ (ν) ), ν = ± 1 2, and let 1/2 < κ 1 < κ 2 < 1. (1) Suppose that ξ M κ 1 L 0 (ζ) N κ 2 L 0, with L 0 N. Then Φ(ξ L, L], u, z) Φ(ξ, u, z), L. (2) Suppose ξ n, ξ M κ 1 L 0 (ζ) N κ 2 L 0 (ζ), and u n supp ξ n, u supp ξ. If ξ n ξ, vaguely and u n u, n, then Φ(ξ n, u n, z) Φ(ξ, u, z), n Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 24 / 27

(P ξ L,L], Ξ t ) is a Markov process, that is, ] ] E ξ L,L] f 1 (Ξ s )f 2 (Ξ t ) = E ξ L,L] f 1 (Ξ s )E Ξs f 2 (Ξ t s )] for 0 < s < t and polynomials f 1, f 2 : ( f j (ξ) = Q j ϕ 1 (x)ξ(dx),..., R R ) ϕ k (x)ξ(dx) By taking L from Lemmas 1 and 3 ] ] E ξ f 1 (Ξ s )f 2 (Ξ t ) = E ξ f 1 (Ξ s )E Ξs f 2 (Ξ t s )] Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 25 / 27

Strong Markov property For a polynomial function f we put T t f (ξ) = E ξ f (Ξ t )], the semigroup associated with the Markov process (P ξ, Ξ t ). Suppose that ξ n, ξ M ε L 0 (ξ Z/ρ ) N κ L 0 for some L 0 N. From Lemmas 1 and 2, ξ n ξ, vaguely T t f (ξ n ) T t f (ξ). We equip S δ with the topology by the inductive limit. Then, for ξ n, ξ S δ We have the Feller property. ξ n ξ, T t f (ξ n ) T t f (ξ). Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 26 / 27

Thanks Thank you for your attention! Hideki Tanemura (Chiba univ.) () Markov process (August 2, 2013) 27 / 27