On the Frame Set for the 3-Spline

Abdou Ganiou Débayo Atindehou

doi:10.4236/am.2022.135026

Applied Mathematics > Vol.13 No.5, May 2022

On the Frame Set for the 3-Spline

Abdou Ganiou Débayo Atindehou
Département de Mathématiques, Faculté des Sciences et Techniques (FAST), Université d’Abomey-Calavi (UAC), Cotonou, Benin.
DOI: 10.4236/am.2022.135026 PDF HTML XML 107 Downloads 624 Views

Abstract

This paper investigates the fine structure of the Gabor frame generated by the B-spline B₃. In other words, one extends the known part of the Gabor frame set for the 3-spline with the construction of the compactly supported dual windows. The frame set of the function B₃ is the subset of all parameters (a,b) ∈ R²₊for which the time-frequency shifts of B₃ along aZ × bZ form a Gabor frame for L²(R).

Keywords

Gabor Frames, Frame Set, 3-Splines, Compactly Dual Frame

Share and Cite:

Atindehou, A. (2022) On the Frame Set for the 3-Spline. Applied Mathematics, 13, 377-400. doi: 10.4236/am.2022.135026.

1. A New Set of Points in the Frame Set of the 3-Spline

The Gabor frame generated by $g \in L^{2} (ℝ)$ and $a, b > 0$ is the set of functions

$G (g, a, b) = {M_{l b} T_{k a} g = e^{2 π i l b \cdot} g (\cdot - k a) : (l, k) \in ℤ^{2}}$

for which there exist $A, B > 0$ such that

$A {‖ f ‖}_{2}^{2} \leq \sum_{l, k \in ℤ} {| 〈 f, M_{l b} T_{k a} g 〉 |}^{2} \leq B {‖ f ‖}_{2}^{2},$

for all $f \in L^{2} (ℝ)$ , see, [1] [2] for details. The mystery of the fine structure of Gabor frames [3] and application requirements have obliged many researchers to investigate the characterization of Gabor frame set for some functions having good time-frequency concentration. For example, in the hyperbolic secant functions or different splines windows [4] [5] [6], the functions satisfy the partitions of unity [7] [8] and the sign-changing functions with compact support [9] [10] [11] are already been studied. More generally, the frame set $F (g)$ of $g \in L^{2} (ℝ)$ is known only for a few classes of functions, see [3] [12] - [22]. For instance, the determination of the frame set of B-splines for $N \geq 2$ is listed as one of the six problems in frame theory [12]. Recently, we have investigated the frame set of a class of compactly supported functions that include the B-splines. In particular, we have extended and put in a more general framework some of the known results on the frame set for this class of functions [23].

In this paper, we investigate the set of parameters $(a, b) \in ℝ_{+}^{2}$ such that $G (B_{3}, a, b)$ is a Gabor frame where

$B_{3} (x) = χ_{[- 1 / 2, 1 / 2]} * χ_{[- 1 / 2, 1 / 2]} * χ_{[- 1 / 2, 1 / 2]} (x) = {\begin{array}{l} \frac{1}{2} x^{2} + \frac{3}{2} x + \frac{9}{8} & x \in [- \frac{3}{2}, - \frac{1}{2}] \\ - x^{2} + \frac{3}{4} & x \in [- \frac{1}{2}, \frac{1}{2}] \\ \frac{1}{2} x^{2} - \frac{3}{2} x + \frac{9}{8} & x \in [\frac{1}{2}, \frac{3}{2}] \end{array}$

is the 3-spline. This set is called the frame set of $B_{3}$ and is given by

$F (B_{3}) = {(a, b) \in ℝ_{+}^{2} : G (B_{3}, a, b) is a frame} .$

It is not difficult to see that $F (B_{3}) \neq \emptyset$ . Indeed, for any $a \in (0,3)$ there exists $b_{0} > 0$ such that for all $0 < b \leq b_{0}$ , $(a, b) \in F (B_{3})$ [ [24], Theorem 4.18]. Furthermore, $F (B_{3})$ is an open set in $ℝ_{+}^{2}$ [25] [26]. This is a consequence of the fact that $B_{3}$ belongs to the modulation space $M^{1} (ℝ)$ [2]. However, the complete characterization of $F (B_{3})$ is still unknown.

To the best of our knowledge [1] [5] [8] [11] [23] [27] [28], the biggest subset known in $F (B_{3})$ is the connected set

${(a, b) \in ℝ_{+}^{2} : a b < 1, 0 < a < 3, 0 < b \leq \max_{a} (\frac{2}{3}, \frac{4}{3 + 3 a})} .$

In this note, we complete this last subset by showing that $Γ$ belongs to $F (B_{3})$ where $Γ = \cup_{m = 3}^{\infty} Γ_{m}$ with for $m \geq 4$ ,

$\begin{array}{l} Γ_{m} : = {(a, b) \in ℝ_{+}^{2} : a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 1)}{2 m - 1}], \\ b \in (\frac{2 (m - 1)}{3 + (2 m - 3) a}, \min_{a} (\frac{2 m}{3 + (2 m - 1) a}, \frac{4}{3 + 2 a})], b > \frac{2}{3}} \end{array}$ (1)

and

$Γ_{3} : = {(a, b) \in ℝ_{+}^{2} : a \in [\frac{3}{4}, \frac{6}{5}], b \in (\frac{4}{3 + 3 a}, \frac{6}{3 + 5 a}], b > \frac{2}{3}} .$ (2)

More specifically, our main result gives the frame properties on $Γ$ .

Theorem 1. For $m \geq 3$ , let $(a, b) \in Γ_{m}$ . Then, the Gabor system $G (B_{3}, a, b)$ is a frame for $L^{2} (ℝ)$ , and there is a unique dual window $H_{3} \in L^{2} (ℝ)$ such

that $s u p p H_{3} \subseteq [- \frac{2 m - 1}{2} a, \frac{2 m - 1}{2} a]$ . Furthermore, for each $(a, b) \in Γ$ , the Gabor system $G (B_{3}, a, b)$ is a frame for $L^{2} (ℝ)$ .

Theorem 1 is proved by using the following well-known necessary and sufficient condition, which is well developed in [ [23], Proposition 2], for two Bessel Gabor systems to be dual of each other.

For $m \geq 1$ , let $0 < a < 3$ and $\frac{2 (m - 1)}{3 + (2 m - 3) a} < b \leq \frac{2 m}{3 + (2 m - 1) a}$ . Assume that $H_{3}$ is a bounded real-function with support on $[- \frac{2 m - 1}{2} a, \frac{2 m - 1}{2} a]$ . Then, the Gabor systems $G (B_{3}, a, b)$ and $G (H_{3}, a, b)$ are dual frames for $L^{2} (ℝ)$ if and only if

$\sum_{k =1 - m}^{m - 1} B_{3} (x - l / b + k a) H_{3} (x + k a) = b δ_{l,0}, | l | \leq m - 1, for a .e . x \in [- \frac{a}{2}, \frac{a}{2}] .$ (3)

We can rewrite (3) as a matrix-vector equation:

${\hat{E}}_{m} (x) {\hat{F}}_{m}^{t} (x) = B^{t} for a .e . x \in [- \frac{a}{2}, \frac{a}{2}],$ (4)

where ${\hat{F}}_{m} (x)$ and $B$ are the row vectors given respectively by ${\hat{F}}_{m} (x) = {[H_{3} (x + k a)]}_{| k | \leq m - 1}$ and $B = {[b δ_{l,0}]}_{| l | \leq m - 1}$ ; ${\hat{E}}_{m} (x)$ is the $(2 m - 1) \times (2 m - 1)$ matrix-valued function defined by ${\hat{E}}_{m} (x) = {[B_{3} (x - \frac{l}{b} + k a)]}_{1 - m \leq l, k \leq m - 1}$ . Using the fact that the 3-spline $B_{3}$ is supported by $[- \frac{3}{2}, \frac{3}{2}]$ and $(a, b) \in Γ_{m}$ ; one observes easily that for all $x \in [- \frac{a}{2},0]$ , not only the all ${\hat{E}}_{m} (x)$ ’s on-diagonal entries are positive but also the matrix-valued function ${\hat{E}}_{m} (x)$ can be rewritten as the following block matrix:

${\hat{E}}_{m} (x) = (\begin{matrix} {\hat{G}}_{m - 1} (x) & {\hat{I}}_{m - 1} (x) \\ O & {\hat{J}}_{m - 1} (x) \end{matrix}),$ (5)

where $O$ is a $(m - 2) \times (m + 1)$ matrix of 0’s, ${\hat{I}}_{m - 1} (x)$ is a $(m + 1) \times (m - 2)$ matrix, ${\hat{J}}_{m - 1} (x)$ is a $(m - 2) \times (m - 2)$ upper triangular matrix and ${\hat{G}}_{m - 1} (x)$ is the $(m + 1) \times (m + 1)$ tridiagonal matrix given by

${\hat{G}}_{m - 1} (x) = {[B_{3} (x - \frac{l}{b} + k a)]}_{1 - m \leq l, k \leq 1} .$ (6)

Figure 1 shows the connected set known in $F (B_{3})$ .

The rest of the paper is organized as follows. In Section 2 we prove our main results by studying the invertibility of the matrix ${\hat{G}}_{m - 1} (x)$ .

2. Invertibility of ${\hat{G}}_{m - 1} (x)$ for $(a, b) \in Γ_{m}$

To prove Theorem 1, we only need to show that (3) has a unique solution ${\hat{F}}_{m} (x)$ . This is equivalent to proving respectively that the $(2 m - 1) \times (2 m - 1)$ matrix-valued function ${\hat{E}}_{m} (x)$ is invertible for a.e. $x \in [- \frac{a}{2}, \frac{a}{2}]$ . In other

Figure 1. A sketch of $F (B_{3})$ . No frame property in the red region, the green region is from [29] and the yellow region is the result from [11]. The blue and the magenta regions are respectively from [28] and [27]. The cyan region is the result from [23] completed by theorem 1.

words, from the block form for the matrix ${\hat{E}}_{m} (x)$ , we need to prove that the matrix ${\hat{G}}_{m - 1} (x)$ is invertible.

Throughout the paper, we use the fact that

$\min_{a} (\frac{2 m}{3 + (2 m - 1) a}, \frac{4}{3 + 2 a}) = {\begin{array}{l} \frac{4}{3 + 2 a} & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ \frac{2 m}{3 + (2 m - 1) a} & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array}$

The following lemma gives the behavior of the entries of ${\hat{G}}_{m - 1} (x)$ .

Lemma 1. For $m \geq 3$ , let $(a, b) \in Γ_{m}$ , $x \in [- \frac{a}{2};0]$ and consider $B_{3}$ . Then the following hold:

1) $B_{3} (x + \frac{k}{b} - k a) > 0$ , for all $k \in {1 - m, \dots, m - 1}$ .

2) $B_{3} (x + \frac{k}{b} - (k - 1) a) > 0$ for $k \in {0;1}$ and

$\begin{array}{l} B_{3} (x + \frac{k}{b} - (k - 1) a) \\ = {\begin{array}{l} B_{3} (x + \frac{k}{b} - (k - 1) a) > 0 & if x \in [- \frac{a}{2}; \frac{3}{2} - \frac{k}{b} + (k - 1) a) \\ 0 & if x \in [\frac{3}{2} - \frac{k}{b} + (k - 1) a;0] \end{array} \end{array}$

for all $k \in {2, \dots, m - 1}$ .

3) $B_{3} (x + \frac{m - 2}{b} - (m - 1) a) > 0$ and

$\begin{array}{l} B_{3} (x + \frac{k}{b} - (k + 1) a) \\ = {\begin{array}{l} 0 & if x \in [- \frac{a}{2}; - \frac{3}{2} - \frac{k}{b} + (k + 1) a] \\ B_{3} (x + \frac{k}{b} - (k + 1) a) > 0 & if x \in (- \frac{3}{2} - \frac{k}{b} + (k + 1) a; 0] \end{array} \end{array}$

for all ${k = - 1, \dots, m - 3}$ .

Proof. 1) Firstly, let $k \in {1 - m, \dots, - 1}$ . We have

$\begin{array}{l} x + \frac{k}{b} - k a \leq \frac{k}{b} - k a \\ \leq {\begin{array}{l} k (\frac{3 + 2 a}{4}) - k a = k (\frac{3 - 2 a}{4}) & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ k (\frac{3 + (2 m - 1) a}{2 m}) - k a = \frac{3 k}{2 m} - \frac{k}{2 m} a & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} \\ \leq {\begin{array}{l} \frac{3 k}{4} - \frac{k}{2} \times \frac{3 (m - 2)}{2 (m - 1)} = \frac{3 k}{4 (m - 1)} & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ \frac{3 k}{2 m} - \frac{k}{2 m} \times \frac{3 (m - 1)}{2 m - 1} = \frac{3 k}{2 (2 m - 1)} & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} \\ < 0 \end{array}$

and

$\begin{matrix} x + \frac{k}{b} - k a \geq \frac{k}{b} - \frac{2 k + 1}{2} a \\ > k (\frac{3 + (2 m - 3) a}{2 (m - 1)}) - \frac{2 k + 1}{2} a = \frac{3 k}{2 (m - 1)} - \frac{m - 1 + k}{2 (m - 1)} a \\ \geq \frac{3 k}{2 (m - 1)} - \frac{m - 1 + k}{2 (m - 1)} \times \frac{3 (m - 1)}{2 m - 1} = \frac{3}{2} (\frac{k}{m - 1} - \frac{m - 1 + k}{2 m - 1}) \\ \geq - \frac{3}{2} (because \frac{k}{m - 1} - \frac{m - 1 + k}{2 m - 1} \geq - 1) . \end{matrix}$

Therefore for all $k \in {1 - m, \dots, - 1}$ , $- \frac{3}{2} < x + \frac{k}{b} - k a < 0$ . Thus $B_{3} (x + \frac{k}{b} - k a) > 0$ . Secondly, let $k \in {0, \dots, m - 1}$ . We have

$\begin{matrix} x + \frac{k}{b} - k a \leq \frac{k}{b} - k a < k (\frac{3 + (2 m - 3) a}{2 (m - 1)}) - k a = \frac{3 k}{2 (m - 1)} - \frac{k a}{2 (m - 1)} \\ \leq \frac{3 k}{2 (m - 1)} - \frac{k}{2 (m - 1)} \times \frac{3 (m - 3)}{2 (m - 2)} = \frac{k}{4 (m - 2)} \leq \frac{3}{2} \end{matrix}$

and

$\begin{array}{l} x + \frac{k}{b} - k a \geq - \frac{a}{2} + \frac{k}{b} - k a = \frac{k}{b} - \frac{2 k + 1}{2} a \\ \geq {\begin{array}{l} k (\frac{3 + 2 a}{4}) - \frac{2 k + 1}{2} a = \frac{3 k}{4} - \frac{k + 1}{2} a & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ k (\frac{3 + (2 m - 1) a}{2 m}) - \frac{2 k + 1}{2} a = \frac{3 k}{2 m} - \frac{m + k}{2 m} a & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} \\ \geq {\begin{cases} \frac{3 k}{4} - \frac{k + 1}{2} \times \frac{3 (m - 2)}{2 (m - 1)} = - \frac{3}{2} (\frac{(m - 2) - k}{2 (m - 1)}) \\ \frac{3 k}{2 m} - \frac{m + k}{2 m} \times \frac{3 (m - 1)}{2 m - 1} = - \frac{3}{2} (\frac{(m - 1) - k}{2 m - 1}) \end{cases} \\ > - \frac{3}{2} \end{array}$

Then for all $k \in {0, \dots, m - 1}$ , $- \frac{3}{2} < x + \frac{k}{b} - k a < \frac{3}{2}$ . Thus $B_{3} (x + \frac{k}{b} - k a) > 0$ .

2) Let $k \in {0, \dots, m - 1}$ . We have

$\begin{matrix} x + \frac{k}{b} - (k - 1) a \leq \frac{k}{b} - (k - 1) a < k (\frac{3 + (2 m - 3) a}{2 (m - 1)}) - (k - 1) a \\ = \frac{3 k}{2 (m - 1)} + \frac{2 (m - 1) - k}{2 (m - 1)} a \\ \leq \frac{3 k}{2 (m - 1)} + \frac{2 (m - 1) - k}{2 (m - 1)} \times \frac{3 (m - 1)}{2 m - 1} \\ = \frac{3}{2} (\frac{k}{m - 1} + \frac{2 (m - 1) - k}{2 m - 1}) \end{matrix}$

and

$\begin{array}{l} x + \frac{k}{b} - (k - 1) a \geq - \frac{a}{2} + \frac{k}{b} - (k - 1) a = \frac{k}{b} - \frac{2 k - 1}{2} a \\ \geq {\begin{array}{l} k (\frac{3 + 2 a}{4}) - \frac{2 k - 1}{2} a = \frac{3 k}{4} - \frac{k - 1}{2} a & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ k (\frac{3 + (2 m - 1) a}{2 m}) - \frac{2 k - 1}{2} a = \frac{3 k}{2 m} + \frac{m - k}{2 m} a & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} \\ \geq {\begin{array}{l} \frac{3 k}{4} - \frac{k - 1}{2} \times \frac{3 (m - 2)}{2 (m - 1)} = \frac{3}{2} (\frac{m + k - 2}{2 (m - 1)}) & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ \frac{3 k}{2 m} + \frac{m - k}{2 m} \times \frac{3 (m - 2)}{2 (m - 1)} = \frac{3}{2} (\frac{m + k - 2}{2 (m - 1)}) & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} \end{array}$

Then for all $k \in {1, \dots, m - 1}$ ;

$0 < \frac{3}{2} (\frac{m + k - 2}{2 (m - 1)}) \leq x + \frac{k}{b} - (k - 1) a < \frac{3}{2} (\frac{k}{m - 1} + \frac{2 (m - 1) - k}{2 m - 1}) .$

Therefore for all $k \in {2, \dots, m - 1}$ ,

and using the fact that $b > \frac{2}{3}$ , we have easily $B_{3} (x + \frac{k}{b} - (k - 1) a) > 0$ for $k \in {0;1}$ .

3) Let $k \in {0, \dots, m - 2}$ . We have

$\begin{matrix} x + \frac{k}{b} - (k + 1) a \leq \frac{k}{b} - (k + 1) a < k (\frac{3 + (2 m - 3) a}{2 (m - 1)}) - (k + 1) a \\ = \frac{3 k}{2 (m - 1)} - \frac{2 (m - 1) + k}{2 (m - 1)} a \\ \leq \frac{3 k}{2 (m - 1)} - \frac{2 (m - 1) + k}{2 (m - 1)} \times \frac{3 (m - 3)}{2 (m - 2)} \\ = \frac{3}{2} (\frac{k - 2 m + 6}{2 (m - 2)}) = \frac{3}{2} (\frac{(k - m + 2) + (4 - m)}{2 (m - 2)}) \leq 0 \end{matrix}$

as far as $m \geq 4$ and

$\begin{array}{l} x + \frac{k}{b} - (k + 1) a \geq - \frac{a}{2} + \frac{k}{b} - (k + 1) a = \frac{k}{b} - \frac{2 k + 3}{2} a \\ \geq {\begin{array}{l} k (\frac{3 + 2 a}{4}) - \frac{2 k + 3}{2} a = \frac{3 k}{4} - \frac{k + 3}{2} a & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ k (\frac{3 + (2 m - 1) a}{2 m}) - \frac{2 k + 3}{2} a = \frac{3 k}{2 m} - \frac{3 (m - 1) + k + 3}{2 m} a & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} \\ \geq {\begin{array}{l} \frac{3 k}{4} - \frac{k + 3}{2} \times \frac{3 (m - 2)}{2 (m - 1)} = \frac{3}{2} (\frac{k - 3 (m - 2)}{2 (m - 1)}) & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ \frac{3 k}{2 m} - \frac{3 (m - 1) + k + 3}{2 m} \times \frac{3 (m - 1)}{2 m - 1} = \frac{3}{2} (\frac{k - 3 (m - 1)}{2 m - 1}) & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} \end{array}$

Then for all $k \in {0, \dots, m - 2}$ ;

${\begin{cases} \frac{3}{2} (\frac{k - 3 (m - 2)}{2 (m - 1)}) \\ \frac{3}{2} (\frac{k - 3 (m - 1)}{2 m - 1}) \end{cases} \leq x + \frac{k}{b} - (k + 1) a < \frac{3}{2} (\frac{(k - m + 2) + (4 - m)}{2 (m - 2)}) \leq 0$

as far as $m \geq 4$ and

$- \frac{3}{2} - \frac{3 ({(m - 1)}^{2} + 1)}{2 (m - 1) (2 m - 1)} < x - \frac{1}{b} \leq {\begin{array}{l} - \frac{3 (2 m - 5)}{4 (m - 2)} & if a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{3 (m - 2)}{2 (m - 1)}] \\ - \frac{3 (2 m - 3)}{4 (m - 1)} & if a \in [\frac{3 (m - 2)}{2 (m - 1)}, \frac{3 (m - 1)}{2 m - 1}] \end{array} < 0.$

Thus $B_{3} (x + \frac{m - 2}{b} - (m - 1) a) > 0$ and

$\begin{array}{l} B_{3} (x + \frac{k}{b} - (k + 1) a) \\ = {\begin{array}{l} 0 & if x \in [- \frac{a}{2}; - \frac{3}{2} - \frac{k}{b} + (k + 1) a] \\ B_{3} (x + \frac{k}{b} - (k + 1) a) > 0 & if x \in [- \frac{3}{2} - \frac{k}{b} + (k + 1) a; 0] \end{array} \end{array}$

for $k = - 1, \dots, m - 3$ .

The following remark gives the trivial two different partitions of $[- \frac{a}{2};0]$ which can be derived from the definition of $Γ_{m} (m \geq 3)$ and will be used to compute the determinant of the matrix ${\hat{G}}_{m - 1} (x)$ .

Remark 1. a) If $3 - \frac{3}{b} + a \leq 0$ and

· $a \in [\frac{3 (m - 3)}{2 (m - 2)}, \frac{6 m - 9}{4 m - 3}]$ , then $- \frac{3}{2} - \frac{m - 3}{b} + (m - 2) a \leq - \frac{a}{2}$ . Hence

$[- \frac{a}{2}, 0] = \cup_{k = 1}^{m - 2} (Q_{k} \cup T_{k}) \cup T_{m - 1}$

where $Q_{k} = [\frac{3}{2} - \frac{k + 1}{b} + k a, - \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a]$ and $T_{k} = (- \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a, \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ with the convention that $T_{m - 1} = [- \frac{a}{2}, \frac{3}{2} - \frac{m - 1}{b} + (m - 2) a)$ and $T_{1} = (- \frac{3}{2} + \frac{1}{b}, 0]$ .

· $a \in [\frac{3 (m - 2)}{2 m - 3}, \frac{3 (m - 1)}{2 m - 1}]$ , then $- \frac{a}{2} \leq - \frac{3}{2} - \frac{m - 3}{b} + (m - 2) a$ . Thus

$[- \frac{a}{2}, 0] = \cup_{k = 1}^{m - 1} (Q_{k} \cup T_{k})$

where $Q_{k} = [\frac{3}{2} - \frac{k + 1}{b} + k a, - \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a]$ and $T_{k} = (- \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a, \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ with the convention that $Q_{m - 1} = [- \frac{a}{2}, - \frac{3}{2} - \frac{m - 3}{b} + (m - 2) a]$ and $T_{1} = (- \frac{3}{2} + \frac{1}{b},0]$ .

· $a \in (\frac{6 m - 9}{4 m - 3}; \frac{3 (m - 2)}{2 m - 3})$ for $m \neq 3$ , then $- \frac{3}{2} - \frac{m - 3}{b} + (m - 2) a + \frac{a}{2}$ is sign-changing. So, we use both different previous partitions.

b) If $3 - \frac{3}{b} + a > 0$ , then a is only in $[\frac{3 (m - 3)}{2 (m - 2)}, \frac{6 m - 9}{4 m - 3}]$ . Hence

$[- \frac{a}{2}, 0] = (\cup_{k = 1}^{m - 1} {\tilde{Q}}_{k}) \cup (\cup_{k = 2}^{m - 1} {\tilde{T}}_{k})$

where ${\tilde{Q}}_{k} = [\frac{3}{2} - \frac{k + 1}{b} + k a, - \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a]$ and ${\tilde{T}}_{k} = (- \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a, \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ with the convention that ${\tilde{Q}}_{m - 1} = [- \frac{a}{2}, - \frac{3}{2} - \frac{m - 4}{b} + (m - 3) a]$ and ${\tilde{Q}}_{1} = [\frac{3}{2} - \frac{2}{b} + a, 0]$ .

NB: Specially for $m = 3$ , one substitutes $\frac{3 (m - 3)}{2 (m - 2)}$ by $\frac{3}{4}$ . The different cases considered in proving this result are illustrated for the cases $m = 3$ and $m = 4$ in Figure 2.

Let $k \in {1, \dots, m - 1}$ , $l = 2, 3, 4$ and denote $A_{l l}^{k} (x)$ the $l \times l$ sub-matrix of ${\hat{G}}_{m - 1} (x)$ , defined respectively by

$A_{22}^{k} (x) = (\begin{matrix} B_{3} (x + \frac{k}{b} - k a) & B_{3} (x + \frac{k}{b} - (k - 1) a) \\ B_{3} (x + \frac{k - 1}{b} - k a) & B_{3} (x + \frac{k - 1}{b} - (k - 1) a) \end{matrix}),$

$A_{33}^{k} (x) = (\begin{matrix} B_{3} (x + \frac{k}{b} - k a) & B_{3} (x + \frac{k}{b} - (k - 1) a) & 0 \\ B_{3} (x + \frac{k - 1}{b} - k a) & B_{3} (x + \frac{k - 1}{b} - (k - 1) a) & B_{3} (x + \frac{k - 1}{b} - (k - 2) a) \\ 0 & B_{3} (x + \frac{k - 2}{b} - (k - 1) a) & B_{3} (x + \frac{k - 2}{b} - (k - 2) a) \end{matrix})$

Figure 2. The off-diagonal of ${\hat{G}}_{m - 1} (x)$ for $m = 3$ and $m = 4$ when $x \in [- \frac{a}{2},0]$ .

and

$A_{44}^{k} (x) = (\begin{matrix} B_{3} (x + \frac{k}{b} - k a) & B_{3} (x + \frac{k}{b} - (k - 1) a) & 0 & 0 \\ B_{3} (x + \frac{k - 1}{b} - k a) & B_{3} (x + \frac{k - 1}{b} - (k - 1) a) & B_{3} (x + \frac{k - 1}{b} - (k - 2) a) & 0 \\ 0 & B_{3} (x + \frac{k - 2}{b} - (k - 1) a) & B_{3} (x + \frac{k - 2}{b} - (k - 2) a) & B_{3} (x + \frac{k - 2}{b} - (k - 3) a) \\ 0 & 0 & B_{3} (x + \frac{k - 3}{b} - (k - 2) a) & B_{3} (x + \frac{k - 3}{b} - (k - 3) a) \end{matrix}) .$

The following Lemma indicates that the matrices $A_{l l}^{k} (x)$ are invertible.

Lemma 2. Given $m \geq 3$ , let $(a, b) \in Γ_{m}$ and $x \in [- \frac{a}{2};0]$ . The following hold:

a) if $k \in {1, \dots, m - 1}$ , then $| A_{l l}^{k} (x) | > 0$ for all $l = 2, 3$ .

b) $| A_{44}^{k} (x) | > 0$ , for all $k \in {2, \dots, m - 1}$ .

This result is proved in Appendix 4.

The following Proposition gives an explicit expression for the determinant of the sub-matrix ${\hat{G}}_{m - 1} (x)$ when $m \geq 3$ , $x \in [- \frac{a}{2};0]$ and under the hypotheses of Theorem 1.

Proposition 1. For $m \geq 3$ , let $(a, b) \in Γ_{m}$ and $x \in [- \frac{a}{2},0]$ . The following statements hold:

$\forall x \in D, | {\hat{G}}_{m - 1} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) |$

where $D, I, i$ and j are given in the following cases:

1) If $3 - \frac{3}{b} + a \leq 0$ and

a) $\frac{3 (m - 3)}{2 (m - 2)} \leq a \leq \frac{6 m - 9}{4 m - 3}$ , then

i) for all $k \in {1, \dots, m - 2}$ , $D = Q_{k}$ , $I = {- 1, \dots, m - 1} \ {k, k - 1}$ , $i = k$ , and $j = 2$ .

ii) for all $k \in {1, \dots, m - 1}$ , $D = T_{k}$ , $I = {- 1, \dots, m - 1} \ {k, k - 1, k - 2}$ , $i = k$ and $j = 3$ .

b) $\frac{3 (m - 2)}{2 m - 3} \leq a \leq \frac{3 (m - 1)}{2 m - 1}$ , then for all $k \in {1, \dots, m - 1}$ , one has:

i) for $D = Q_{k}$ , $I = {- 1, \dots, m - 1} \ {k, k - 1}$ , $i = k$ , and $j = 2$ .

ii) for $D = T_{k}$ , $I = {- 1, \dots, m - 1} \ {k, k - 1, k - 2}$ , $i = k$ and $j = 3$ .

c) $\frac{6 m - 9}{4 m - 3} < a < \frac{3 (m - 2)}{2 m - 3}$ when $m \neq 3$ , then one uses i) and ii) obtained in a) or b).

2) If $3 - \frac{3}{b} + a > 0$ , then

a) For all $k \in {1, \dots, m - 1}$ , $D = {\tilde{Q}}_{k}$ , $I = {- 1, \dots, m - 1} \ {k, k - 1, k - 2}$ , $i = k$ and $j = 3$ .

b) For all $k \in {2, \dots, m - 1}$ , $D = {\tilde{T}}_{k}$ , $I = {- 1, \dots, m - 1} \ {k, k - 1, k - 2, k - 3}$ , $i = k$ and $j = 4$ .

Moreover the matrix ${\hat{E}}_{m} (x)$ is invertible.

Proof. We prove the result by induction on m by using the different partitions of $[- \frac{a}{2};0]$ obtained in Remark 1. For $m = 3$ , the matrix ${\hat{G}}_{2} (x)$ given by

${\hat{G}}_{2} (x) = (\begin{matrix} B_{3} (x + \frac{2}{b} - 2 a) & B_{3} (x + \frac{2}{b} - a) & 0 & 0 \\ B_{3} (x + \frac{1}{b} - 2 a) & B_{3} (x + \frac{1}{b} - a) & B_{3} (x + \frac{1}{b}) & 0 \\ 0 & B_{3} (x - a) & B_{3} (x) & B_{3} (x + a) \\ 0 & 0 & B_{3} (x - \frac{1}{b}) & B_{3} (x - \frac{1}{b} + a) \end{matrix}) .$

Suppose that $3 - \frac{3}{b} + a \leq 0$ and $\frac{3}{4} \leq a \leq 1$ , then $[- \frac{a}{2}; 0] = Q_{1} \cup T_{1} \cup T_{2}$ with $T_{2} = [- \frac{a}{2}; \frac{3}{2} - \frac{2}{b} + a)$ , $Q_{1} = [\frac{3}{2} - \frac{2}{b} + a; - \frac{3}{2} + \frac{1}{b}]$ and $T_{1} = (- \frac{3}{2} + \frac{1}{b}; 0]$ .

So, it is easy to see that for all $x \in Q_{1}$ , $| {\hat{G}}_{2} (x) | = B_{3} (x + \frac{2}{b} - 2 a) B_{3} (x - \frac{1}{b} + a) \cdot | A_{22}^{1} (x) |$ ; $x \in T_{1}$ , $| {\hat{G}}_{2} (x) | = B_{3} (x + \frac{2}{b} - 2 a) \cdot | A_{33}^{1} (x) |$ and $x \in T_{2}$ , $| {\hat{G}}_{2} (x) | = B_{3} (x - \frac{1}{b} + a) \cdot | A_{33}^{2} (x) |$ . This establishes the part (a) for the base case $m = 3$ .

Suppose that $3 - \frac{3}{b} + a \leq 0$ and $1 < a \leq \frac{6}{5}$ , then $[- \frac{a}{2}; 0] = Q_{2} \cup T_{2} \cup Q_{1} \cup T_{1}$ with $Q_{2} = [- \frac{a}{2}; - \frac{3}{2} + a]$ , $T_{2} = (- \frac{3}{2} + a; \frac{3}{2} - \frac{2}{b} + a)$ , $Q_{1} = [\frac{3}{2} - \frac{2}{b} + a; - \frac{3}{2} + \frac{1}{b}]$ and $T_{1} = (- \frac{3}{2} + \frac{1}{b}; 0]$ . So, it is easy to see that

$\forall x \in D = Q_{k} (k = 1, 2), | {\hat{G}}_{2} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) |$

where $I = {- 1,0,1,2} \ {k, k - 1}$ , $i = k$ , and $j = 2$ ; and

$\forall x \in D = T_{k} (k = 1, 2), | {\hat{G}}_{2} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) |$

where $I = {- 1,0,1,2} \ {k, k - 1, k - 2}$ , $i = k$ and $j = 3$ . Hence (b) holds. Similarly, (2) holds.

Suppose that (1) and (2) hold for $m - 1 \geq 3$ and let us prove that they hold for m. So, one compute the determinant of the matrix ${\hat{G}}_{m} (x)$ given by

${\hat{G}}_{m} (x) = {[B_{3} (x - \frac{l}{b} + k a)]}_{- m \leq l, k \leq 1} .$

Suppose $3 - \frac{3}{b} + a > 0$ . From Remark 1, we have $[- \frac{a}{2};0] = (\cup_{k = 1}^{m} {\tilde{Q}}_{k}) \cup (\cup_{k = 2}^{m} {\tilde{T}}_{k})$ with ${\tilde{Q}}_{m} = [- \frac{a}{2}; - \frac{3}{2} - \frac{m - 3}{b} + (m - 2) a]$ ; ${\tilde{Q}}_{k} = [\frac{3}{2} - \frac{k + 1}{b} + k a; - \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a]$ , for all $k \in {2, \dots, m - 1}$ ; ${\tilde{Q}}_{1} = [\frac{3}{2} - \frac{2}{b} + a; 0]$ and ${\tilde{T}}_{k} = (- \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a; \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ , for all $k \in {2, \dots, m}$ .

Let $x \in D = {\tilde{Q}}_{m}$ . Thus $B_{3} (x + \frac{k}{b} - (k + 1) a) = 0$ for all $k \in {- 1, \dots, m - 3}$ . Hence,

$| {\hat{G}}_{m} (x) | = (\prod_{l = - 1}^{m - 3} B_{3} (x + \frac{l}{b} - l a)) \cdot | A_{33}^{m} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) |$

where $I = {- 1, \dots, m - 3}$ , $i = m$ and $j = 3$ .

Let $x \in D = {\tilde{Q}}_{m - 1}$ . Therefore $B_{3} (x + \frac{m}{b} - (m - 1) a) = 0$ and $B_{3} (x + \frac{k}{b} - (k + 1) a) = 0$ for all $k \in {- 1, \dots, m - 4}$ . Consequently,

$| {\hat{G}}_{m} (x) | = (\prod_{\begin{matrix} l = - 1 \\ l \neq m - 3, m - 2, m - 1 \end{matrix}}^{m} B_{3} (x + \frac{l}{b} - l a)) \cdot | A_{33}^{m - 1} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) |$

where $I = {- 1, \dots, m} \ {m - 3, m - 2, m - 1}$ , $i = m - 1$ and $j = 3$ .

Let $k \in {1, \dots, m - 2}$ and $x \in D = {\tilde{Q}}_{k}$ . Thus $B_{2} (x + \frac{m}{b} - (m - 1) a) = 0$ . Hence, $| {\hat{G}}_{m} (x) | = B_{3} (x + \frac{m}{b} - m a) \cdot | {\hat{G}}_{m - 1} (x) |$ and by the induction assumption, we have

$| {\hat{G}}_{m} (x) | = (\prod_{\begin{matrix} l = - 1 \\ l \neq k, k - 1, k - 2 \end{matrix}}^{m} B_{3} (x + \frac{l}{b} - l a)) \cdot | A_{33}^{k} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) |$

where $I = {- 1, \dots, m} \ {k, k - 1, k - 2}$ , $i = k$ and $j = 3$ .

Let $x \in D = {\tilde{T}}_{m}$ . Thus $B_{3} (x + \frac{k}{b} - (k + 1) a) = 0$ for all $k \in {- 1, \dots, m - 4}$ . Hence,

$| {\hat{G}}_{m} (x) | = (\prod_{\begin{matrix} l = - 1 \\ l \neq m - 3, m - 2, m - 1, m \end{matrix}}^{m} B_{3} (x + \frac{l}{b} - l a)) \cdot | A_{44}^{m} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) |$

where $I = {- 1, \dots, m} \ {m - 3; m - 2, m - 1, m}$ , $i = m$ and $j = 4$ .

Let $k \in {2, \dots, m - 1}$ and $x \in D = {\tilde{T}}_{k}$ . Then $B_{3} (x + \frac{m}{b} - (m - 1) a) = 0$ . Thus $| {\hat{G}}_{m} (x) | = B_{3} (x + \frac{m}{b} - m a) \cdot | {\hat{G}}_{m - 1} (x) |$ and by the induction assumption, we have

$| {\hat{G}}_{m} (x) | = (\prod_{\begin{matrix} l = - 1 \\ l \neq k, k - 1, k - 2, k - 3 \end{matrix}}^{m} B_{3} (x + \frac{l}{b} - l a)) \cdot | A_{44}^{k} (x) | = \prod_{l \in I} B_{3} (x + \frac{l}{b} - l a) \cdot | A_{j j}^{i} (x) | .$

where $I = {- 1, \dots, m} \ {k, k - 1, k - 2, k - 3}$ , $i = k$ and $j = 4$ .

Together, (2) holds for the case m. Similarly, one proves that (1) holds for the case m.

To end the proof, we observe that by using the block decomposition of ${\hat{E}}_{m} (x)$ , we have for all $x \in [- \frac{a}{2};0]$ ,

$| {\hat{E}}_{m} (x) | = (\prod_{1 - m}^{- 2} B_{3} (x + \frac{k}{b} - k a)) \cdot | {\hat{G}}_{m - 1} (x) | .$

We know that $B_{3} (x + \frac{k}{b} - k a) > 0$ , $\forall k \in {1 - m, \dots, m - 1}$ and $| {\hat{G}}_{m - 1} (x) | > 0$ because $| A_{l l}^{k} (x) | > 0$ from Lemma 2. Thus we conclude that $| {\hat{E}}_{m} (x) | > 0$ for all $x \in [- \frac{a}{2};0]$ , and by symmetry $(| {\hat{E}}_{m} (- x) | = | {\hat{E}}_{m} (x) |)$ this holds for all $x \in [- \frac{a}{2}; \frac{a}{2}]$ .

We are now ready to prove Theorem 1.

Proof of Theorem 1. By Proposition 1 we know that ${\hat{E}}_{m} (x)$ is invertible. Let ${\hat{F}}_{m} (x)$ be defined on $ℝ$ as follows. For $x \in ℝ \ [- \frac{2 m - 1}{2} a, \frac{2 m - 1}{2} a]$ , let ${\hat{F}}_{m} (x) = 0$ and for $x \in [- \frac{2 m - 1}{2} a, \frac{2 m - 1}{2} a]$ let ${\hat{F}}_{m} (x)$ be defined by ${\hat{F}}_{m}^{t} (x) = b {({\hat{E}}_{m}^{- 1} (x))}_{m}$ , where ${\hat{F}}_{m} (x) = {[H_{3} (x + k a)]}_{| k | \leq m - 1}$ and ${({\hat{E}}_{m}^{- 1} (x))}_{m}$ is the m^th column vector of the matrix ${\hat{E}}_{m}^{- 1} (x)$ . Consequently, $H_{3}$ is a compactly supported and bounded function for which $G (H_{3}, a, b)$ is a Bessel sequence. By construction, it also follows that $B_{3}$ and $H_{3}$ are dual windows.

3. Conclusion

We studied the fine structure of the Gabor frame generated by the B-spline $B_{3}$ . It should be remembered that this structure determines all pairs $(a, b) \in ℝ_{+}^{2}$ for which the Gabor system $G (B_{3}, a, b)$ forms a frame. We presented the known results of the Gabor frame set $F (B_{3})$ and we added a new set of points in the frame set of the 3-spline while building the compactly supported dual windows of $B_{3}$ . All our results are obtained thanks to the partitioning of the domain in which the frame set is sought. This partitioning allowed us to establish a global approach, based on the study of the invertibility of a square matrix specific to each sub-domain, and which will be used to find other points belonging to the frame set of the B-spline $B_{3}$ .

Appendix

Consider the first-order difference $Δ_{a} B_{3}$ and the second-order difference $Δ_{a}^{2} B_{3}$ given respectively by

$Δ_{a} B_{3} (x) = B_{3} (x) - B_{3} (x - a) and Δ_{a}^{2} B_{3} (x) = B_{3} (x) - 2 B_{3} (x - a) + B_{3} (x - 2 a)$

The following Lemma completes the Lemma 2.2 of [27] in the case of $B_{3}$ .

Lemma 3. Let $0 < a < 3$ . Then $Δ_{a}^{2} B_{3} (x) > 0$ , for all $x \in (- \frac{3}{2} + a, \frac{3}{2} - \frac{2}{b} + a)$ .

Proof. By definition of the functional space $V_{a} g$ and the Lemma 2.2 in [27], it is known that $Δ_{a}^{2} B_{3} (x) > 0$ for all $x \in [- \frac{3}{2}, - \frac{3}{4} + \frac{3 a}{4}]$ .

In particular, for $a \geq 1$ or $b \leq \frac{8}{9 + a}$ , $(- \frac{3}{2} + a, \frac{3}{2} - \frac{2}{b} + a) \subset [- \frac{3}{2}, - \frac{3}{4} + \frac{3 a}{4}]$ while for $a < 1$ and $b > \frac{8}{9 + a}$ , $- \frac{3}{4} + \frac{3 a}{4} < \frac{3}{2} - \frac{2}{b} + a$ . In other words, to have that $Δ_{a}^{2} B_{3} (x) > 0$ on $(- \frac{3}{2} + \frac{3 a}{4}, \frac{3}{2} - \frac{2}{b} + a)$ , it suffices to show that, for $a < 1$ and $b > \frac{8}{9 + a}$ ,

$Δ_{a}^{2} B_{3} (x) > 0, \forall x \in (- \frac{3}{4} + \frac{3 a}{4}, \frac{3}{2} - \frac{2}{b} + a) .$

Otherwise, we only show that for $\frac{3}{4} \leq a < 1$ and $\frac{8}{9 + a} < b \leq \frac{4}{3 + 2 a}$ ;

$Δ_{a}^{2} B_{3} (x) > 0, \forall x \in (- \frac{3}{4} + \frac{3 a}{4}, \frac{3}{2} - \frac{2}{b} + a) \subset (- \frac{3}{16}, 0] .$

Let $f (x) : = Δ_{a}^{2} B_{3} (x)$ . It is easy to see that for all $x \in (- \frac{3}{4} + \frac{3 a}{4}, \frac{3}{2} - \frac{2}{b} + a)$ ,

$\begin{matrix} f (x) = B_{3} (x) - 2 B_{3} (x - a) \\ = - x^{2} + \frac{3}{4} - {(x - a)}^{2} - 3 (x - a) - \frac{9}{4} \\ = - 2 x^{2} + (2 a - 3) x - a^{2} + 3 a - \frac{3}{2} . \end{matrix}$

One has $f^{'} (- \frac{3}{16}) = 2 a - \frac{9}{4} < 0$ et $f (0) = - a^{2} + 3 a - \frac{3}{2} > 0$ . Thus $f (x) > 0$ , $\forall x \in (- \frac{3}{16}, 0]$ . Consequently,

$\forall x \in (- \frac{3}{4} + \frac{3 a}{4}, \frac{3}{2} - \frac{2}{b} + a), Δ_{a}^{2} B_{3} (x) > 0$

as wanted.

The following Lemma shows the invertibility of the matrix $A_{44}^{2} (x)$ .

Lemma 4. Let $a \in [\frac{3}{4}, \frac{3}{2}]$ , $b \in [\frac{3}{3 + a}, \frac{4}{3 + 2 a}]$ and $x \in (- \frac{3}{2} + \frac{1}{b}; \frac{3}{2} - \frac{2}{b} + a)$ . Then $| A_{44}^{2} (x) | > 0$ .

Proof. Let $L_{2} (x) : = | A_{44}^{2} (x) |$ and $L_{2}^{i, j} (x)$ denote the ij^th minor of $L_{2} (x)$ , the determinant of the matrix obtained by removing the i^th row and the j^th column from $L_{2} (x)$ . We have respectively

(1) $B_{3} (x) > B_{3} (x - a)$ and $B_{3} (x) > B_{3} (x + a)$ ;

(2) $L_{2}^{3, 2} (x) > 0$ and $L_{2}^{3, 4} (x) > 0$ ;

(3) $L_{2}^{33} (x) > L_{2}^{3, 2} (x) + L_{2}^{3, 4} (x)$ .

Combining (1), (2) and (3), we have for all $x \in (- \frac{3}{2} + \frac{1}{b}; \frac{3}{2} - \frac{2}{b} + a)$ ,

$\begin{matrix} L_{2} (x) = - B_{3} (x - a) \cdot L_{2}^{3, 2} (x) + B_{3} (x) \cdot L_{2}^{33} (x) - B_{3} (x + a) \cdot L_{2}^{3, 4} (x) \\ > [B_{3} (x) - B_{3} (x - a)] \cdot L_{2}^{3, 2} (x) + [B_{3} (x) - B_{3} (x + a)] \cdot L_{2}^{3, 4} (x) > 0. \end{matrix}$

This implies that for all $x \in (- \frac{3}{2} + \frac{1}{b}; \frac{3}{2} - \frac{2}{b} + a)$ , $| A_{44}^{2} (x) | > 0$ .

We have for all $x \in (- \frac{3}{2} + \frac{1}{b}; \frac{3}{2} - \frac{2}{b} + a)$ , $x - a < x < 0 < x + a$ and $- x - a < x$ . Thus $B_{3} (x - a) < B_{3} (x)$ and $B_{3} (x) > B_{3} (x + a)$ . On the other hand,

$\begin{array}{l} L_{2}^{3, 2} (x) = B_{3} (x + \frac{2}{b} - 2 a) B_{3} (x + \frac{1}{b}) B_{3} (x - \frac{1}{b} + a) > 0 \\ and L_{2}^{3, 4} (x) = B_{3} (x - \frac{1}{b}) | A_{22}^{2} (x) | > 0. \end{array}$

Then (1) and (2) hold.

One has $\begin{matrix} L_{2}^{33} (x) - L_{2}^{3, 2} (x) - L_{2}^{3, 4} (x) = [B_{3} (x - \frac{1}{b} + a) - B_{3} (x - \frac{1}{b})] | A_{22}^{2} (x) | \\ - B_{3} (x + \frac{2}{b} - 2 a) B_{3} (x + \frac{1}{b}) B_{3} (x - \frac{1}{b} + a) \end{matrix}$ where $B_{3} (x - \frac{1}{b}) = \frac{1}{2} {(x - \frac{1}{b})}^{2} + \frac{3}{2} (x - \frac{1}{b}) + \frac{9}{8}$ , $B_{3} (x + \frac{1}{b}) = \frac{1}{2} {(x - \frac{1}{b})}^{2} - \frac{3}{2} (x + \frac{1}{b}) + \frac{9}{8}$ and

$B_{3} (x - \frac{1}{b} + a) = {\begin{array}{l} \frac{1}{2} {(x - \frac{1}{b} + a)}^{2} + \frac{3}{2} (x - \frac{1}{b} + a) + \frac{9}{8} & if a \in [\frac{3}{4},1] \\ - {(x - \frac{1}{b} + a)}^{2} + \frac{3}{4} & if a \in [1; \frac{3}{2}] . \end{array}$

Let $g (x) : = [B_{3} (x - \frac{1}{b} + a) - B_{3} (x - \frac{1}{b})] - B_{3} (x + \frac{1}{b})$ . It is easy to remark that the function g is strictly increasing on $(- \frac{3}{2} + \frac{1}{b}; \frac{3}{2} - \frac{2}{b} + a)$ and $g (- \frac{3}{2} + \frac{1}{b}) > 0$ where

$g (- \frac{3}{2} + \frac{1}{b}) = {\begin{array}{l} \frac{1}{2} (- 3 + a + \frac{2}{b}) (3 + a - \frac{2}{b}) & if a \in [\frac{3}{4},1] \\ - a^{2} + 3 a - \frac{2}{b^{2}} + \frac{6}{b} - 6 & if a \in [1; \frac{3}{2}] . \end{array}$

Consequently $B_{3} (x - \frac{1}{b} + a) - B_{3} (x - \frac{1}{b}) > B_{3} (x + \frac{1}{b})$ .

Let $h (x) : = | A_{22}^{2} (x) | - B_{3} (x + \frac{2}{b} - 2 a) B_{3} (x - \frac{1}{b} + a)$ where

$A_{22}^{2} (x) = (\begin{matrix} B_{3} (x + \frac{2}{b} - 2 a) & B_{3} (x + \frac{2}{b} - a) \\ B_{3} (x + \frac{1}{b} - 2 a) & B_{3} (x + \frac{1}{b} - a) \end{matrix}) .$

We obtain

$\min_{x} h (x) = h (\frac{3}{2} - \frac{2}{b} + a) = B_{3} (\frac{3}{2} - a) [B_{3} (\frac{3}{2} - \frac{1}{b}) - B_{3} (\frac{3}{2} - \frac{3}{b} + 2 a)] > 0$

because $\frac{3}{2} - \frac{3}{b} + 2 a < - \frac{3}{2} + \frac{1}{b} \Rightarrow B_{3} (\frac{3}{2} - \frac{3}{b} + 2 a) < B_{3} (\frac{3}{2} - \frac{1}{b})$ . Consequently (3) holds.

Therefore $| A_{22}^{2} (x) | > B_{3} (x + \frac{2}{b} - 2 a) B_{3} (x - \frac{1}{b} + a)$ . Hence $L_{2}^{33} (x) > L_{2}^{3, 2} (x) + L_{2}^{3, 4} (x)$ .

Proof of Lemma 2. Throughout this proof, we use the Lemma 1 and Remark 1 without notify it.

(a) Let $k \in {1, \dots, m - 1}$ . In the first time, we consider the matrix $A_{22}^{k} (x)$ given by

$A_{22}^{k} (x) = (\begin{matrix} B_{3} (x + \frac{k}{b} - k a) & B_{3} (x + \frac{k}{b} - (k - 1) a) \\ B_{3} (x + \frac{k - 1}{b} - k a) & B_{3} (x + \frac{k - 1}{b} - (k - 1) a) \end{matrix}) .$

We prove that for all $k \in {1, \dots, m - 1}$ , $B_{3} (x + \frac{k}{b} - k a) > B_{3} (x + \frac{k}{b} - (k - 1) a)$ . For this, we know that $- \frac{3}{2} < x + \frac{k}{b} - k a < \frac{3}{2}$ and $x + \frac{k}{b} - (k - 1) a > 0$ , therefore we have two different cases.

* If $x + \frac{k}{b} - k a > 0$ , we have $x + \frac{k}{b} - k a < x + \frac{k}{b} - (k - 1) a$ and using the strict decreasing of $B_{3}$ on $[0, \frac{3}{2}]$ , one has $B_{3} (x + \frac{k}{b} - k a) > B_{3} (x + \frac{k}{b} - (k - 1) a)$ .

* If $x + \frac{k}{b} - k a \leq 0$ , then $- x - \frac{k}{b} + k a \geq 0$ and

$- x - \frac{k}{b} + k a - (x + \frac{k}{b} - (k - 1) a) = - 2 x - \frac{2 k}{b} + (2 k - 1) a \leq 2 k (a - \frac{1}{b}) < 0.$

Thus $- x - \frac{k}{b} + k a < x + \frac{k}{b} - (k - 1) a$ and using the fact that $B_{3}$ is symmetric around the origin and strict decreasing on $[0, \frac{3}{2}]$ , one has $B_{3} (x + \frac{k}{b} - k a) > B_{3} (x + \frac{k}{b} - (k - 1) a)$ .

Next, we prove that for all $k \in {1, \dots, m - 2}$ , $B_{3} (x + \frac{k - 1}{b} - k a) < B_{3} (x + \frac{k - 1}{b} - (k - 1) a)$ . We also know that $- \frac{3}{2} < x + \frac{k - 1}{b} - (k - 1) a < \frac{3}{2}$ and $x + \frac{k - 1}{b} - k a < 0$ , therefore we can consider the following two cases.

* If $x + \frac{k - 1}{b} - (k - 1) a \leq 0$ , on has $x + \frac{k - 1}{b} - k a < x + \frac{k - 1}{b} - (k - 1) a$ . Therefore by the strict increasing of $B_{3}$ on $[- \frac{3}{2};0]$ , we obtain $B_{3} (x + \frac{k - 1}{b} - k a) < B_{3} (x + \frac{k - 1}{b} - (k - 1) a)$ .

* If $x + \frac{k - 1}{b} - (k - 1) a > 0$ , then $- x - \frac{k - 1}{b} + (k - 1) a \leq 0$ and $- x - \frac{k - 1}{b} + (k - 1) a - (x + \frac{k - 1}{b} - k a) = - 2 x - \frac{2 (k - 1)}{b} + (2 k - 1) a \geq 0$ . Indeed,

$\begin{array}{l} - 2 x - \frac{2 (k - 1)}{b} + (2 k - 1) a \geq - \frac{2 (k - 1)}{b} + (2 k - 1) a \\ \geq - (k - 1) \frac{3 + (2 m - 3) a}{m - 1} + (2 k - 1) a = - \frac{3 (k - 1)}{m - 1} + \frac{k + m - 2}{m - 1} a \\ \geq - \frac{3 (k - 1)}{m - 1} + \frac{k + m - 2}{m - 1} \times \frac{3 (m - 3)}{2 (m - 2)} = \frac{3 (m - 2 - k)}{2 (m - 2)} \geq 0. \end{array}$

Thus $x + \frac{k - 1}{b} - k a \leq - x - \frac{k - 1}{b} + (k - 1) a$ and using the fact that $B_{3}$ is symmetric around the origin and strict increasing on $[- \frac{3}{2};0]$ , one has $B_{3} (x + \frac{k - 1}{b} - k a) \leq B_{3} (x + \frac{k - 1}{b} - (k - 1) a)$ .

All in all, we conclude that $| A_{22}^{k} (x) | > 0$ for all $k \in {1, \dots, m - 2}$ .

For $k = m - 1$ , we consider the matrix $A_{22}^{m - 1} (x)$ given by

$A_{22}^{m - 1} (x) = (\begin{matrix} B_{3} (x + \frac{m - 1}{b} - (m - 1) a) & B_{3} (x + \frac{m - 1}{b} - (m - 2) a) \\ B_{3} (x + \frac{m - 2}{b} - (m - 1) a) & B_{3} (x + \frac{m - 2}{b} - (m - 2) a) \end{matrix}) .$

We know respectively that $B_{3} (x + \frac{m - 1}{b} - (m - 1) a) > 0$ , $B_{3} (x + \frac{m - 2}{b} - (m - 1) a) > 0$ , $B_{3} (x + \frac{m - 2}{b} - (m - 2) a) > 0$ , $B_{3} (x + \frac{m - 1}{b} - (m - 1) a) > B_{3} (x + \frac{m - 1}{b} - (m - 2) a)$ and

$\begin{array}{l} B_{3} (x + \frac{m - 1}{b} - (m - 2) a) \\ = {\begin{array}{l} B_{3} (x + \frac{m - 1}{b} - (m - 2) a) > 0 & if x \in [- \frac{a}{2}; \frac{3}{2} - \frac{m - 1}{b} + (m - 2) a) \\ 0 & if x \in [\frac{3}{2} - \frac{m - 1}{b} + (m - 2) a; 0] \end{array} \end{array}$

It is easy to see that if $x \in [\frac{3}{2} - \frac{m - 1}{b} + (m - 2) a;0]$ , then $| A_{22}^{m - 1} (x) | > 0$ . To end, we prove that for all $x \in [- \frac{a}{2}; \frac{3}{2} - \frac{m - 1}{b} + (m - 2) a)$ , $| A_{22}^{m - 1} (x) | > 0$ .

We also know that $- \frac{3}{2} < x + \frac{m - 2}{b} - (m - 2) a < \frac{3}{2}$ and $x + \frac{m - 2}{b} - (m - 1) a < 0$ , therefore we can consider the following two cases.

*If $x + \frac{m - 2}{b} - (m - 2) a \leq 0$ , one has $x + \frac{m - 2}{b} - (m - 1) a < x + \frac{m - 2}{b} - (m - 2) a$ . Therefore by the strict increasing of $B_{3}$ , we obtain $B_{3} (x + \frac{m - 2}{b} - (m - 1) a) < B_{3} (x + \frac{m - 2}{b} - (m - 2) a)$ .

*If $x + \frac{m - 2}{b} - (m - 2) a > 0$ , then $- x - \frac{m - 2}{b} + (m - 2) a \leq 0$ and $- x - \frac{m - 2}{b} + (m - 2) a - (x + \frac{m - 2}{b} - (m - 1) a)$

$= - 2 x - \frac{2 (m - 2)}{b} + (2 m - 3) a > - 3 + \frac{2}{b} + a \geq 0$ . Thus $x + \frac{m - 2}{b} - (m - 1) a < - x - \frac{m - 2}{b} + (m - 2) a$ and using the fact that $B_{3}$ is symmetric around the origin and strict increasing, one has

$B_{3} (x + \frac{m - 2}{b} - (m - 1) a) \leq B_{3} (x + \frac{m - 2}{b} - (m - 2) a) .$

In the second time, we consider, for all $k \in {1, \dots, m - 1}$ , the matrix $A_{33}^{k} (x)$ given by

For $x \in [- \frac{a}{2}; - \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a] \cup [\frac{3}{2} - \frac{k}{b} + (k - 1) a;0]$ , we have $B_{3} (x + \frac{k - 2}{b} - (k - 1) a) = 0$ or $B_{3} (x + \frac{k}{b} - (k - 1) a) = 0$ and hence

$\begin{array}{l} | A_{33}^{k} (x) | = B_{3} (x + \frac{k - 2}{b} - (k - 2) a) | A_{22}^{k} (x) | > 0 \\ or | A_{33}^{k} (x) | = B_{3} (x + \frac{k}{b} - k a) | A_{22}^{k - 1} (x) | > 0. \end{array}$

Let $x \in (- \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a; \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ .

We proved previously that $B_{3} (x + \frac{k}{b} - k a) > B_{3} (x + \frac{k}{b} - (k - 1) a)$ for all $k \in {1, \dots, m - 1}$ .

Nest, we prove that $B_{3} (x + \frac{k - 1}{b} - k a) < B_{3} (x + \frac{k - 1}{b} - (k - 1) a)$ and $B_{3} (x + \frac{k - 1}{b} - (k - 1) a) > B_{3} (x + \frac{k - 1}{b} - (k - 2) a)$ .

We know for all $k \in {1, \dots, m - 1}$ , $- \frac{3}{2} < x + \frac{k - 1}{b} - (k - 1) a < \frac{3}{2}$ , $x + \frac{k - 1}{b} - k a < 0$ and $x + \frac{k - 1}{b} - (k - 2) a > 0$ , therefore we have different following cases.

*If $x + \frac{k - 1}{b} - (k - 1) a \leq 0$ , on has $x + \frac{k - 1}{b} - k a < x + \frac{k - 1}{b} - (k - 1) a$ . Therefore by the strict increasing of $B_{3}$ on $[- \frac{3}{2};0]$ , we obtain $B_{3} (x + \frac{k - 1}{b} - k a) < B_{3} (x + \frac{k - 1}{b} - (k - 1) a)$ .

*If $x + \frac{k - 1}{b} - (k - 1) a > 0$ , then $- x - \frac{k - 1}{b} + (k - 1) a < 0$ and $- x - \frac{k - 1}{b} + (k - 1) a - (x + \frac{k - 1}{b} - k a) = - 2 x - \frac{2 (k - 1)}{b} + (2 k - 1) a > 0$ . Indeed,

$\begin{array}{l} x \in (- \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a; \frac{3}{2} - \frac{k}{b} + (k - 1) a) \\ \Rightarrow - 2 x - \frac{2 (k - 1)}{b} + (2 k - 1) a > - 3 + \frac{2}{b} + a > 0. \end{array}$

Therefore $x + \frac{k - 1}{b} - k a < - x - \frac{k - 1}{b} + (k - 1) a$ and consequently we have

$B_{3} (x + \frac{k - 1}{b} - k a) < B_{3} (x + \frac{k - 1}{b} - (k - 1) a) .$

*If $x + \frac{k - 1}{b} - (k - 1) a > 0$ , we have $x + \frac{k - 1}{b} - (k - 1) a < x + \frac{k - 1}{b} - (k - 2) a$ and then $B_{3} (x + \frac{k - 1}{b} - (k - 1) a) > B_{3} (x + \frac{k - 1}{b} - (k - 2) a)$ .

*If $x + \frac{k - 1}{b} - (k - 1) a \leq 0$ , then $- x - \frac{k - 1}{b} + (k - 1) a \geq 0$ and $- x - \frac{k - 1}{b} + (k - 1) a - (x + \frac{k - 1}{b} - (k - 2) a) = - 2 x - \frac{2 (k - 1)}{b} + (2 k - 3) a < 0$ because

$x \in (- \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a; \frac{3}{2} - \frac{k}{b} + (k - 1) a) \Rightarrow - 2 x - \frac{2 (k - 1)}{b} + (2 k - 3) a < 3 - \frac{2}{b} - a < 0.$

Thus $- x - \frac{k - 1}{b} + (k - 1) a < x + \frac{k - 1}{b} - (k - 2) a$ and using the fact that $B_{3}$ is symmetric around the origin and strict decreasing on $[0, \frac{3}{2}]$ , one has

$B_{3} (x + \frac{k - 1}{b} - (k - 1) a) > B_{3} (x + \frac{k - 1}{b} - (k - 2) a) .$

Let us prove that $B_{3} (x + \frac{k - 2}{b} - (k - 1) a) < B_{3} (x + \frac{k - 2}{b} - (k - 2) a)$ for all $k \in {1, \dots, m - 1}$ .

One has $B_{3} (x - \frac{1}{b}) < B_{3} (x - \frac{1}{b} + a)$ because $- \frac{3}{2} < x - \frac{1}{b} < x - \frac{1}{b} + a < 0$ .

Let $k \in {2, \dots, m - 1}$ . We known that $- \frac{3}{2} < x + \frac{k - 2}{b} - (k - 2) a < \frac{3}{2}$ and $x + \frac{k - 2}{b} - (k - 1) a < 0$ , therefore we have two cases.

*If $x + \frac{k - 2}{b} - (k - 2) a \leq 0$ , then $x + \frac{k - 2}{b} - (k - 1) a < x + \frac{k - 2}{b} - (k - 2) a$ and therefore $B_{3} (x + \frac{k - 2}{b} - (k - 1) a) < B_{3} (x + \frac{k - 2}{b} - (k - 2) a)$ .

*If $x + \frac{k - 2}{b} - (k - 2) a > 0$ , then $- x - \frac{k - 2}{b} + (k - 2) a < 0$ and $- x - \frac{k - 2}{b} + (k - 2) a - (x + \frac{k - 2}{b} - k a)$

$= - 2 x - \frac{2 (k - 2)}{b} - (2 k - 3) a > - 3 + \frac{4}{b} - a > 0$ . Therefore $x + \frac{k - 2}{b} - k a < - x - \frac{k - 2}{b} + (k - 2) a$ and then

$B_{3} (x + \frac{k - 2}{b} - (k - 1) a) < B_{3} (x + \frac{k - 2}{b} - (k - 2) a) .$

Let

$\begin{matrix} p (x) = | \begin{matrix} B_{3} (x + \frac{k}{b} - k a) & 0 \\ 0 & B_{3} (x + \frac{k - 2}{b} - (k - 2) a) \end{matrix} | \\ - | \begin{matrix} B_{3} (x + \frac{k}{b} - (k - 1) a) & 0 \\ B_{3} (x + \frac{k - 2}{b} - (k - 1) a) & B_{3} (x + \frac{k - 2}{b} - (k - 2) a) \end{matrix} | \end{matrix}$

$- | \begin{matrix} B_{3} (x + \frac{k}{b} - k a) & B_{3} (x + \frac{k}{b} - (k - 1) a) \\ 0 & B_{3} (x + \frac{k - 2}{b} - (k - 1) a) \end{matrix} | .$

A direct computation shows that

$\begin{array}{l} p (x) = B_{3} (x + \frac{k}{b} - k a) B_{3} (x + \frac{k - 2}{b} - (k - 2) a) - B_{3} (x + \frac{k}{b} - (k - 1) a) \\ \times B_{3} (x + \frac{k - 2}{b} - (k - 2) a) - B_{3} (x + \frac{k}{b} - k a) B_{3} (x + \frac{k - 2}{b} - (k - 1) a) \\ = - Δ_{a} B_{3} (x + \frac{k}{b} - (k - 1) a) Δ_{a} B_{3} (x + \frac{k - 2}{b} - (k - 2) a) \\ + Δ_{a} B_{3} (x + \frac{k}{b} - (k - 2) a) Δ_{a} B_{3} (x + \frac{k - 2}{b} - (k - 1) a) \\ = Δ_{a} B_{3} (- x - \frac{k}{b} + k a) Δ_{a} B_{3} (x + \frac{k - 2}{b} - (k - 2) a) - Δ_{a} B_{3} (- x - \frac{k}{b} + (k - 1) a) \\ \times Δ_{a} B_{3} (x + \frac{k - 2}{b} - (k - 1) a) (one uses Δ_{a} B_{3} (x) = - Δ_{a} B_{3} (- x + a)) \end{array}$

Hence to have $p (x) > 0$ , it suffices to show that for all $x \in (- \frac{3}{2} - \frac{k - 2}{b} + (k - 1) a; \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ ,

$\begin{array}{l} {\begin{cases} Δ_{a} B_{3} (x + \frac{k - 2}{b} - (k - 2) a) > Δ_{a} B_{3} (x + \frac{k - 2}{b} - (k - 1) a) \\ Δ_{a} B_{3} (- x - \frac{k}{b} + k a) > Δ_{a} B_{3} (- x - \frac{k}{b} + (k - 1) a) \end{cases} \\ \Leftrightarrow {\begin{cases} Δ_{a}^{2} B_{3} (x + \frac{k - 2}{b} - (k - 2) a) > 0 \\ Δ_{a}^{2} B_{3} (- x - \frac{k}{b} + k a) > 0 \end{cases} \end{array}$

This means precisely that $Δ_{a}^{2} B_{3} (x) > 0$ , $x \in (- \frac{3}{2} + a, \frac{3}{2} - \frac{2}{b} + a)$ which is obtained in Lemma 3.

b) Let $k \in {2, \dots, m - 1}$ and consider the matrix

*If $3 - \frac{3}{b} + a \leq 0$ , then $\frac{3}{2} - \frac{k}{b} + (k - 1) a \leq - \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a$ and therefore $\forall x \in [- \frac{a}{2};0]$ , $B_{3} (x + \frac{k - 3}{b} - (k - 2) a) = 0$ or $B_{3} (x + \frac{k}{b} - (k - 1) a) = 0$ . Thus

$\begin{array}{l} | A_{44}^{k} (x) | = B_{3} (x + \frac{k - 3}{b} - (k - 3) a) \cdot | A_{33}^{k} (x) | > 0 \\ or | A_{44}^{k} (x) | = B_{3} (x + \frac{k}{b} - k a) \cdot | A_{33}^{k - 1} (x) | > 0. \end{array}$

*If $3 - \frac{3}{b} + a > 0$ , then $- \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a < \frac{3}{2} - \frac{k}{b} + (k - 1) a$ .

When $x \in [- \frac{a}{2}; - \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a] \cup [\frac{3}{2} - \frac{k}{b} + (k - 1) a;0]$ , then $B_{3} (x + \frac{k - 3}{b} - (k - 2) a) = 0$ or $B_{3} (x + \frac{k}{b} - (k - 1) a) = 0$ and therefore

We finish by proving that for all $x \in (- \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a; \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ , $| A_{44}^{k} (x) | > 0$ . We observe that for $k = 3$ and $x \in (- 1 + a;1 - \frac{3}{b} + 2 a)$ , then $| A_{44}^{3} (x) | = | A_{44}^{2} (x + \frac{1}{b} - a) |$ and for $k \in {4, \dots, m - 1}$ and $x \in (- \frac{3}{2} - \frac{k - 3}{b} + (k - 2) a; \frac{3}{2} - \frac{k}{b} + (k - 1) a)$ , then $| A_{44}^{k} (x) | = | A_{44}^{3} (x + \frac{k - 3}{b} - (k - 3) a) | > 0$ . So we only prove that for all $x \in (- \frac{3}{2} + \frac{1}{b}; \frac{3}{2} - \frac{2}{b} + a)$ , $| A_{44}^{2} (x) | > 0$ . Using the condition $3 - \frac{3}{b} + a > 0$ , we consider $a \in [\frac{3}{4}, \frac{3}{2}]$ and $b \in [\frac{3}{3 + a}, \frac{4}{3 + 2 a}]$ . In other words, by the Lemma 4, we have this result.

Conflicts of Interest

The author declares no conflicts of interest regarding the publication of this paper.

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