Complex Anal. Oper. Theory https://doi.org/10.1007/s11785-018-0795-4

Complex Analysis and Operator Theory

The Harmonic Dirichlet–Besov Space and the Optimal Norm for the Bergman Projection Djordjije Vujadinovi´c1

Received: 20 September 2017 / Accepted: 27 April 2018 © Springer International Publishing AG, part of Springer Nature 2018

Abstract We found the optimal operator-norm constant for the harmonic Bergman projection in the context of harmonic Dirichlet–Besov space regarding the natural semi-norm defined on it. Also, we give the two-side norm estimation when it comes to the complete norm. Keywords Harmonic Besov space · Harmonic Bergman projection · Zonal harmonics · Bochner spaces Mathematics Subject Classification Primary 46E20 · 46E22

1 Introduction and Notation Throughout this paper, B will be the open unit ball in Rn for a fixed positive integer n ≥ 2. The weighted measure dvα on B is defined by dvα (x) = cα (1 − |x|2 )α−1 dv(x) for any α > 0, where dv is the Lebesgue volume measure on B. Here, the constant cα is 2( n +α) chosen such that vα is normalized, i.e. vα (B) = 1 and it is given by cα = n|B|(2n )(α) . 2

By |B| we denote the volume of B and we let dτ (x) = (1 − |x|2 )−n dv(x). The class of all harmonic functions f on the unit ball B is denoted by H (B) and by h 2 (B) the space of all square-integrable harmonic functions f (with respect to dv) in B, i.e.,

Communicated by Daniel Aron Alpay.

B 1

Djordjije Vujadinovi´c [email protected] Faculty of Mathematics, University of Montenegro, Dzordza Vašingtona bb, 81000 Podgorica, Montenegro

D. Vujadinovi´c

  f 2L 2 (B,dv) =

| f (x)|2 dv(x) < ∞, f ∈ h 2 (B). B p

p

More generally, the weighted harmonic Bergman space bα = bα (B), 1 ≤ p ≤ ∞, is the space of all complex-valued harmonic functions f, such that the norm 1/ p

  f  L p (B,dvα ) =

B

| f | p dvα

is finite. We will use the following notation for the partial derivatives |∂ m f (x)| =



|∂ k f (x)|, ∂ k f (x) =

|k|=m

∂ |k| f (x) . ∂xk

n Here k = (k1 , . . . , kn ) is multi-index and |k| = i=1 ki = m. The Dirichlet–Besov spaces of harmonic functions in the unit ball represents the special case of the harmonic Besov spaces B p when p = 2. The harmonic Besov spaces have been studied by many authors in various settings of conditions and function domains. One may see the extensive study on them in [5]. Following the work of Jevti´c and Pavlovi´c (see [6]) on the harmonic Besov space B p , 1 ≤ p ≤ ∞, which is defined as a space consisting of all harmonic functions f ∈ H (B) such that the function (1 − |x|2 )k |∂ k f (x)| belongs to L p (B, dτ ) for some positive integer k, k > n−1 p . In fact, if 1 ≤ p ≤ ∞ and f ∈ H (B), then the following statements are equivalent: 2 m 0 m 0 f (x)| ∈ (a) There is a positive integer m 0 > n−1 p such that (1 − |x| ) |∂ L p (B, dτ ). 2 m m p (b) For all positive integers m > n−1 p , (1 − |x| ) |∂ f (x)| ∈ L (B, dτ ), (see Theorem 3.2 in [6]).

The definition is independent from the choice of integer m. The Besov space-norm, in this paper, is defined in the following manner:  f B p =



|∂ α f (0)| +



1/ p (1 − |x|2 )mp |∂ m f (x)| p dτ (x)

, 1 ≤ p < ∞,

B

|α|
(1.1) and  f B∞ =



|∂ α f (0)| + sup(1 − |x|2 )m |∂ m f (x)|, p = ∞.

(1.2)

B

|α|
The derived semi-norm (1.1) is given by   f  B˜ p =

1/ p (1 − |x|2 )mp |∂ m f (x)| p dτ (x) B

.

(1.3)

The Harmonic Dirichlet–Besov Space and the Optimal Norm…

In the rest of the paper, the integer m is fixed in (1.1) and (1.3), and satisfies the inequality m > n−1 p . We shall underline the definition of the harmonic Dirichlet–Besov space B 2 . Definition 1.1 The harmonic Dirichlet–Besov space B 2 is the set of functions f harmonic in B such that   f  B˜ 2 = where m >

1/2 (1 − |x| )

2 2m

|∂ f (x)| dτ (x) m

2

< ∞,

(1.4)

B

n−1 2 .

Weighted harmonic Bergman kernel Since the Hilbert space bα2 is closed in the weighted Lebesgue space L 2 (B, dvα ) there is a unique reproducing kernel Rα (x, y) defined on B × B which is real and symmetric, such that Rα (x, ·) ∈ bα2 stands for any fixed x ∈ B and  f (x) = f (y)Rα (x, y)dvα (y), f ∈ bα2 . B

Following [1] (see Theorem 8.9, page 177) the unweighted harmonic Bergman kernel is given by the sequent formula ∞

R0 (x, y) =

1  (n + 2k)Z k (x, y), x, y ∈ B, n|B|

(1.5)

k=0

where Z k are extended zonal harmonic. For more information about zonal harmonics we refer to [1] (Chapter 5). The series (1.5) converges absolutely and uniformly on K × B for every compact set K ⊂ B. The formula for the weighted harmonic Bergman kernel for α > 0 is given by Rα (x, y) = ωα

∞  (k + n/2 + α) k=0

where ωα =

(n/2) (n/2+α) .

(k + n/2)

Z k (x, y), x, y ∈ B,

(1.6)

We will denote the above coefficients with An,α k =

(k + n/2 + α) . (k + n/2)

The weighted harmonic Bergman projection Pα is presented as an integral operator  f (y)Rα (x, y)dvα (y), f ∈ L 2 (B, dvα ), x ∈ B . Pα f (x) = B

It is known that Pα is bounded on L p (B, dvα ) for 1 < p < ∞.

D. Vujadinovi´c

The estimation of the norm for the harmonic Bergman projection in case we conp p sider the harmonic Bergman space bα , Pα : L p (B, dvα ) → bα was observed in [3]. The authors obtained the optimal two-side norm estimation. Namely, they proved the existence of the constant Cα > 0 for a given α > −1, such that Cα−1

p2 p2 ≤ Pα  L p (B,dvα )→bαp ≤ Cα , p−1 p−1

when 1 < p < ∞. Of course, Pα  L 2 (B,dvα )→bα2 = 1. The following theorem describes the connection between the harmonic Besov space and the harmonic Bergman projection (see [6]). Theorem 1.2 For the 1 ≤ p ≤ ∞, the Bergman projection Pα , α > 0, is bounded and maps L p (B, dτ ) onto the harmonic Besov space B p . The main inducement for this paper is natural continuation of the previous research in the context of the harmonic Besov spaces. Some estimations of the norm for Pα : L p (B, dτ ) → B p , when 1 < p < ∞ have already been done in [9]. The fact that the harmonic Bergman projection Pα : L 2 (B, dτ ) → B 2 is not an orthogonal projection motivates us to observe this particular case. The analogous problem in the one-dimensional analytic case for the Besov space was considered in [8].

2 Preliminaries Gamma function’s inequalities The following inequalities for the Gamma function (see Theorem 2 in [4], page 7) will be of interest. Proposition 2.1 Let m, p and k be real numbers with m, p > 0 and p > k > − m: If k( p − m − k)  0( 0)

(2.1)

( p)(m)  ()( p − k)(m + k).

(2.2)

then we have Proposition 2.2 Let p > 0 and q ∈ R such that |q| < p. Then  2 ( p) < ( p − q)( p + q). According to the introduced semi-norm (1.3) the inner product associate with the harmonic Dirichlet–Besov space B 2 is f, g =

  |k|=m B

and  f 2B˜ 2 = f, f .

(1 − |x|2 )2m

∂m f ∂m g (x) (x)dτ (x), ∂xk ∂xk

f, g ∈ B 2 , (2.3)

The Harmonic Dirichlet–Besov Space and the Optimal Norm…

In this section we are going to find the “exact” norm for the weighted Bergman projection Pα restricted on the subspace L 2 (B, dτ ) regarding the semi-norm generated with (2.3) in B 2 . Specifically, we find the operator norm Pα g B˜ 2 . g L 2 (B,dτ ) =0 g L 2 (B,dτ )

Pα  L 2 (B,dτ )→ B˜ 2 =

sup

Moreover, the completion of the semi-norm  ·  B˜ 2 in B 2 is defined as  f B2 =



|∂ k f (0)| +  f  B˜ 2 ,

(2.4)

k
and we will also consider the operator norm Pα  L 2 (B,dτ )→B 2 =

Pα g B 2 g L 2 (B,dτ ) =0 g L 2 (B,dτ ) sup

or briefly Pα . At this point, we recall the basic definition of the Bochner space which will be significant in order to prove the main result. Namely, for the given measure space (X, , μ), and the Banach space (Y,  · Y ), the Bochner space L p (X, Y ) 1 ≤ p ≤ ∞, is defined to be the space of all Bochner measurable functions f : X → Y in a way that the corresponding norm is finite   f  L p (X,Y ) =

p

X

1/ p

 f (x)Y dμ(x)

< ∞,

(2.5)

with a usual modification for p = ∞,  f  L ∞ (X,Y ) = ess sup  f (x)Y .

(2.6)

x∈X

We return to the initial problem. The next lemma deals with the problem of finding the image of a polynomial by harmonic Bergman projection. More precisely, we are going to observe the function ϕ(x) p(x), where p is a polynomial in Rn and n ϕ(x) = (1 − |x|2 ) 2 . The homogenous polynomial p ∈ Pm (Rn ) can be represented as a unique sum of harmonic homogenous polynomials (see Theorem 5.7 in [1], page 77), i.e., p = pm + |x|2 pm−2 + · · · + |x|2k pm−2k ,

(2.7)

where k = [ m2 ] and each p j ∈ H j (Rn ). The above decomposition reduces on p = pm + pm−2 + · · · + pm−2k , on S.

(2.8)

D. Vujadinovi´c

Here, Pm (Rn ) is a notation for the set of all homogenous polynomials of degree m ∈ N, while H j (Rn ) is a set of all harmonic homogenous polynomial of degree j. By P(Rn ) we denote the set of all polynomials in Rn . In the sequel lemma, for any p ∈ Pm (Rn ) by pi , i ≤ m, we mean the harmonic homogenous polynomial of degree i which appears in decomposition (2.7). Lemma 2.3 Let p ∈ P(Rn ). Then, Pα (ϕp)(x) = D(n, α) 

p(x) =

∞ 

Ain,α

i=0

 j≥i

( i+ 2j+n ) (n +

i+ j 2

+ α)

ψ ij (x), where

ψ j (x), ψ j ∈ P j (Rn ),

(2.9)

j≥0 ( n2

+ α) . |B|(α)

D(n, α) =

Proof Using the homogenous expansion of the polynomial p ∈ P(Rn ), we write  ψ j (x), (2.10) p(x) = j≥0

where the sum in (2.10) is finite, and as we have stated above, ψ j is the homogenous polynomial of degree j. Thus, Pα (ϕp)(x)  = Rα (x, y)ϕ(y) p(y)dvα (y) B

= ωα



∞ 

Ain,α

i=0 ∞ 

= ωα cα

Ain,α

i=0 ∞ 

= ωα cα n = ωα cα n = ωα cα n =

i=0 ∞  i=0 ∞ 

ωα cα n 2

i=0 ∞  i=0

Z i (x, y)ϕ(y) p(y)dvα (y)

B



(1 − |y|2 )n/2+α−1 ψ j (y)Z i (x, y)dv(y)

j≥0 B

Ain,α Ain,α

  

ψ ij (x)  B

S

Z i (x, ξ )ψ j (ξ )dσ (ξ )

 (1 − r 2 )n/2+α−1r j+i+n−1 dr 

 j≥i

1

0

j≥i

Ain,α

 (1 − r 2 )n/2+α−1r j+n+i−1 dr

j≥0 0

j≥i

Ain,α

1

1

S

Z i (x, ξ )ψ ij (ξ )dσ (ξ )

(1 − r 2 )n/2+α−1r j+i+n−1 dr

0

j +n+i n + α, 2 2

 ψ ij (x).

(2.11)



The Harmonic Dirichlet–Besov Space and the Optimal Norm…

The important single-sum formula for the inner-product on the unit sphere ( ·, · S ) of two harmonic polynomials (see Theorem 5.14 in [1], page 84) is given by the following expression,   Theorem 2.4 If p = α bα x α and q = α cα x α are harmonic polynomials on Rn , then  p, q S = bα cα wα , α

where wα =

α! . n(n + 2) · · · (n + 2|α| − 2)

We conclude this section by presenting the main result of this paper and its corollaries. Theorem 2.5 For the defined semi-norm (2.3) on the harmonic Dirichlet–Besov space, the operator norm of the harmonic Bergman projection is expressed by  Pα  L 2 (B,dτ )→ B˜ 2 =

n2m−1 ( n2 )(2m − n + 1)(n + 2α − 1) π n/2 |B| 2 (α)

1/2 .

(2.12)

Now, we observe the problem of finding the operator norm for the Pα , where we consider the Banach norm defined by (2.4). For this purpose we define first the functional

m : L 2 (B, dτ ) → C,  ∂ k Pα g(0).

m (g) =

(2.13)

k
Lemma 2.6   m  L 2 (B,dτ )→C = 2



2 n (n (An,α k k!) dim Hk (R )

k
+ 2α − 1)(k + n2 )

n|B|(k +

3n 2

+ 2α − 1)

1/2 .

Proof According to the Theorem 1.2 for f ∈ B 2 there is g ∈ L 2 (B, dτ ) in a way that f = Pα g. For x ∈ B, we may assume that the vector x is of the form xe1 , x ∈ R. So,   ∂ k f (0) = lim ∂ k f (x) k
x→0

= lim

x→0

k


k
∂ k Rα (x, y)g(y)dvα (y)

D. Vujadinovi´c

= lim ωα x→0

= lim ωα x→0

= lim ωα x→0

= ωα



= ωα

An,α d

∂ k Z d (x, y)g(y)dvα (y)

B

∂ k Z d (x, ξ )|y|d g(y)dvα (y)

  ∂k Zd (x, ξ )|y|d g(y)dvα (y) β B ∂x

|β|=k

k


An,α k k!

B

 An,α d

k
B

Z k (e1 , ξ )|y|k g(y)dvα (y)

 An,α k k!

k
where ξ =

An,α d

k
k




∞ 

B

Z k (e1 , y)g(y)dvα (y),

(2.14)

y |y| .

Now, simple duality argument and identity (2.14) implies 2  sup ∂ k Pα g(0) g L 2 (B,dτ ) ≤1 k
= (ωα cα ) =

2

k


k1 ,k2


×

k1 ,k2
n,α An,α k1 Ak2 k1 !k2 !



× =

S



n,α An,α k1 Ak2 k1 !k2 !



1

B

Z k1 (e1 , y)Z k2 (e1 , y)(1 − |y|2 )n+2α−2 dv(x)

(1 − r 2 )n+2α−2 r k1 +k2 +n−1 dr

0

Z k1 (e1 , ξ )Z k2 (e1 , ξ )dσ (ξ )

 n,α n n |B|(ωα cα )2 . (Ak k!)2 dim Hk (Rn )B n + 2α − 1, k + 2 2 k
(2.15)

Theorem 2.7 max{ m , Pα  L 2 (B,dτ )→ B˜ 2 } ≤ Pα  ≤  m  + Pα  L 2 (B,dτ )→ B˜ 2 .

(2.16)

Proof Out of the definition of the norm in (2.4) and Lemma 2.6 we derive the following easy inequality (2.17) Pα  ≤  m  + Pα  L 2 (B,dτ )→ B˜ 2 .

The Harmonic Dirichlet–Besov Space and the Optimal Norm…

On the other hand, for a positive number  > 0, let g ∈ L 2 (B, dτ ) be a function such that g L 2 (B,dτ ) ≤ 1 and Pα g B˜ 2 > Pα  L 2 (B,dτ )→ B˜ 2 − . Furthermore, we may choose h ∈ L 2 (B, dτ ) in a way that h L 2 (B,dτ ) ≤ 1 and Pα h B˜ 2 >  m  − .

Notice that under the previous notation, we have Pα (g − g1 + h) B˜ 2 > m  + Pα  L 2 (B,dτ )→ B˜ 2 − ,  where Pα g1 (x) = k


2 n (n (An,α k k!) dim Hk (R )

+ 2α − 1)(k + n2 )

n|B|(k +

+ 2α − 1) 1/2 n2m−1 ( n2 )(2m − n + 1)(n + 2α − 1) + . π n/2 |B| 2 (α) k


1/2

3n 2

(2.18)

3 The Proof of the Theorem 2.5 Proof Since the space of all the harmonic polynomials is dense in h 2 (B), we will consider the acting of the weighted Bergman projection on a set {ϕ(x)ψ(x)|ψ ∈ P(Rn )}.  From the homogeneous expansion of ψ(x) = j≥0 ψ j (x) and the Lemma 2.3 we get

Pα (ϕψ)(x) =

( n2

∞ + α) 

|B|(α)

 n,α

Ai

i=0

If we denote by ψ ij (x) =

j≥i

 |s|=i



 i+ 2j+n

 ψ ij (x).  n + i+2 j + α

j

as x s ,

(3.1)

(3.2)

D. Vujadinovi´c

then, the Theorem 2.4 implies ϕψ2L 2 (B,dτ )

=



=



ψi (x)ψ j (x)dv(x)

B

i, j

 n|B|

r

=

i, j

=

 i, j

=

 i, j

= =

i+ j+n−1

0

i, j





1

n|B| i + j +n n|B| i + j +n

 S

dr

S

ψi (ξ )ψ j (ξ )dσ (ξ )

⎛ ⎞⎛ ⎞   ⎝ ψil (ξ )⎠ ⎝ ψ sj (ξ )⎠ dσ (ξ ) l≤i



s≥0 S

s≤ j

ψis (ξ )ψ sj (ξ )dσ (ξ )

j  d!adi ad 2π n/2 ( n2 )(i + j + n) n(n + 2) · · · (n + 2s − 2) s≥0 |d|=s





π n/2

i, j

i + j +n

 s≥0 |d|=s

s≥0 |d|=s

j

d!adi ad 2s−1 ( n2 + s)

 d!a i a j π n/2 d d . 2s−1 ( n2 + s) i + j +n i, j≥s

Moreover, ∂ m Pα (ϕψ)(x) 

  ∞  i+ 2j+n    n2 + α 

 = Ain,α ∂ k ψ ij (x) i+ j |B|(α) i=0 j≥i  n + 2 + α |k|=m 

  ∞  i+ 2j+n    j,k  n2 + α 

 = Ain,α as x s−k i+ j |B|(α) i=0 j≥i  n + 2 + α |s|=i |k|=m =

∞ 

A˜ in,α

i=0

j,k

where as

j

= as

 j≥i

n

Ci,n,α j

  |s|=i |k|=m

(sd +1) d=1 (sd −kd +1)

A˜ in,α =

j,k

as x s−k ,

and s − k = (s1 − k1 , . . . , sn − kn ),

1 An,α , Ci,n,α j = |B|(α) i



 i+ j+n  + α  2 2

 . i+ j  n+ 2 +α

n

(3.3)

The Harmonic Dirichlet–Besov Space and the Optimal Norm…

Therefore, taking into account the definition of wα from the Theorem 2.4 and using the polar coordinates x = r ξ, ξ ∈ S, we obtain Pα (ϕψ)2B˜ 2 =

∞ 

( A˜ in,α )2

i=0

 B

⎛ ⎞2  n,α   j,k (1 − |x|2 )2m−n ⎝ Ci, j as x s−k ⎠ dv(x) |s|=i |k|=m

j≥i

 1 ∞  n,α 2 ˜ = n |B| ( Ai ) (1 − r 2 )2m−n r 2(i−m)+n−1 dr 0

i=0

⎛

 ×

⎝

S

 

⎛ ⎝



|s|=i |k|=m

⎞

⎞2

j,k ⎠ s−k ⎠ Ci,n,α ξ j as

dσ (ξ )

j≥i

 n,α n n |B| ( A˜ i )2 B 2m − n + 1, i − m + 2 2 i=0 ⎛ ⎞2    n,α j,k ⎝ × Ci, j as ⎠ ws−k ∞

=

|s|=i |k|=m

j≥i

n ( A˜ in,α )2 B 2m − n + 1, i − m + 2 i=0 ⎛ ⎞2    n,α j ws−k ((s)!)2 ⎝ × Ci, j as ⎠ . ((s − k)!)2

=

n |B| 2

∞ 

|s|=i |k|=m

(3.4)

j≥i

Now, let us consider the set Nn0 of all non-negative n−tulpes and discrete measure μ defined on Nn0 as 1  μ(s1 , s2 , . . . , sn ) = |s|−1  n 2  2 + |s| and the Hilbert space L 2 ([0, 1], dvn ), dvn (x) = x n−1 d x. Our intention is to transfer the obtained identities in the certain norm relations to the context of the Bochner space L 2 (Nn0 , L 2 ([0, 1], dvn )). Let us first introduce the mapping  : L 2 (S) ∩ P(Rn ) → L 2 (Nn0 , L 2 ([0, 1], dvn (x))) given by (ψ) = f, ψ(ξ ) = f (s, x) = where ψ j (ξ ) =





ψ j (ξ ), ψ j ∈ H j (S)

j≥0

π n/2 s!

 i≥0 |s|=i



ast x t , s ∈ Nn0 , x ∈ [0, 1],

t≥|s| j

as ξ s .

(3.5)

D. Vujadinovi´c

  Furthermore, let us denote by  L 2 (S) ∩ P(Rn ) = M and the unit ball B = { f ∈ L 2 (Nn0 , L 2 ([0, 1], dvn ))|  f  L 2 (Nn ,L 2 ([0,1],dvn )) ≤ 1}. 0

Taking into account the definition of the Bochner norm (2.5) let us note that the obtained expression for the (3.3) can be rewritten as ϕψ2L 2 (B,dτ ) =  f 2L 2 (Nn ,L 2 ([0,1],dv )) , f = ψ. 0

(3.6)

n

On the other hand, we define the new function g ∈ L 2 (Nn0 , L 2 ([0, 1], dvn )) as g(s, x)

⎛

= Q n,s,α (1 − x 2 )

n 2 +α−1

x |s| ⎝ ⎛

= Q n,s,α (1 − x 2 )

n 2 +α−1

x |s| ⎝

 |k|=m

 |k|=m

where Q n,s,α

⎞1/2 ws−k s! ⎠ ((s − k)!)2 ⎞1/2 ( n2 )s! ⎠ 2|s|−m ( n2 + |s| − m)(s − k)! ,

n 1/2 ˜ n,α 1

n

= n/4 n2|s| |B|(|s| + )B 2m − n + 1, |s| − m + A|s| . π 2 2 

Then, Pα (ϕψ)2B˜ 2

=

Nn0

f (s), g(s) 2L 2 ([0,1],dv ) dμ(s).

(3.7)

n

Thus, we need to find the minimal constant C in a way that Pα (ϕψ)2B˜ 2 ≤ C 2 ϕψ2L 2 (B,dτ ) , i.e.,

(3.8)

 Nn0

f (s), g(s) 2L 2 ([0,1],dv ) dμ(s) ≤ C 2  f 2L 2 (Nn ,L 2 ([0,1],dv )) . n

n

0

(3.9)

Using the Cauchy-Schwarz inequality, we have  Nn0

f (s), g(s) 2L 2 ([0,1],dv ) dμ(s) 

≤

Nn0

n

(3.10)  f (s)2L 2 ([0,1],dv ) g(s)2L 2 ([0,1],dv ) dμ(s). n

n

The Harmonic Dirichlet–Besov Space and the Optimal Norm…

On the other hand, the duality argument and inequality  Nn0

 f (s)2L 2 ([0,1],dv ) g(s)2L 2 ([0,1],dv ) dμ(s) n



≤C implies

n

(3.11)

2 Nn0

 f (s)2L 2 ([0,1],dv ) dμ(s) n

 sup

f ∈M∩B Nn0

f (s), g(s) 2L 2 ([0,1],dv ) dμ(s) ≤ C 2 ,

(3.12)

n

where C = sup g(s) L 2 ([0,1],dvn ) . s∈Nn0

We aim to prove that the obtained constant C is indeed the desired constant from the (3.8). For this purpose, let us first notice that for the fixed multi-index s0 ∈ Nn0 the given function g(s0 , x) can be uniformly approximated by polynomials p N ,s0 (x) =  N  n +α−1 2 C(s0 ) d=0 (−1)d x 2d+|s0 | , N ∈ N, where d ⎛ ⎞1/2  ( n2 )s! ⎠ . C(s) = Q n,α,s ⎝ 2|s|−m ( n2 + |s| − m)(s − k)! |k|=m

On the other hand, it can easily be checked that we can find the χ ∈ L 2 (S) ∩ P(Rn ) in a way that (χ )(s0 , ·) = 2|s0 |−1 (|s0 | + n2 ) p N ,s0 . Denoting by (χ )(s0 , ·) = f, for some  > 0 and N big enough, we have  f (s, ·), g(s, ·) 2 dμ(s) Nn0

  f (s, ·), g(s, ·) 2 2 L ([0,1],dvn ) . (3.13) > g(s0 )2L 2 ([0,1],dv ) −  + n 2|s|−1 (|s| + n2 ) s=s0

Finally,  C = A(n, m, α) sup s∈N0n

= A(n, m, α)  × sup

 2 (|s| +

+ α)

n 2

( 3n 2 + |s| + 2α  2 (|s| +

n 2

1/2



s! |k|=m (s−k)! − 1)(m + |s| − n2

+ α)(|s| + 1)

+ 1) 

,1/2 n ( 3n + |s|+2α−1)(m +|s|− + 1)(|s| − m + 1) 2 2  1/2 n m−1 n2 ( 2 )(2m − n + 1)(n + 2α − 1) A(n, m, α) = . (3.14) π n/2 |B| 2 (α) |s|≥0

D. Vujadinovi´c

Furthermore, we consider the function (x), x ≥ m, which is defined as (x) =



 3n 2

   2 x + n2 + α (x + 1) .    + x + 2α − 1  m + x − n2 + 1 (x − m + 1)

The Gamma function’s inequalities (1.3) and (1.4) for m ≥

n 2

gives



 n n  m + x − + 1 (x − m + 1) ≥  x − + 1 (x + 1) 2 2  

 

3n n n 2 + x + 2α − 1  x − + 1 ,  x + +α ≤  2 2 2 (3.15) i.e., (x) ≤ 1. On the other hand, Stirling’s asymptotic formula implies that lim (x) = 1.

x→∞

So, C = A(n, m, α).

(3.16)



Remark 3.1 Although in the inequalities (3.15) we supposed that m ≥ n2 , the fact that m is a nonnegative integer, produces no effect on the range of the initial condition m > n−1 2 .

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