Effects of EEG examination and ABA-therapy on resting-state EEG in children with low-functioning autism

Galina V. Portnova; Oxana Ivanova; Elena V. Proskurnina; Galina V. Portnova; Oxana Ivanova; Elena V. Proskurnina

doi:10.3934/Neuroscience.2020011

AIMS Neuroscience

2020, Volume 7, Issue 2: 153-167. doi: 10.3934/Neuroscience.2020011

Previous Article Next Article

Review Topical Sections

Effects of EEG examination and ABA-therapy on resting-state EEG in children with low-functioning autism

1.
Institute of Higher Nervous Activity and Neurophysiology of RAS, 5A Butlerova St., Moscow 117485, Russia
2.
FSBI Federal medical center Rosimushchestvo, 31 Kalanchevskaya str., 107078, Moscow, Russia
3.
Research Centre for Medical Genetics, 1 Moskvorechye St., Moscow 115522, Russia

Received: 05 March 2020 Accepted: 01 June 2020 Published: 05 June 2020

Objective We aimed to study the effects of EEG examination and ABA-therapy on resting-state EEG in children with low-functioning autism and tactile defensiveness.

Methods We have performed this study with three cohorts of preschoolers: children with autistic spectrum disorder (ASD) who needed applied behavior analysis (ABA) therapy due to their tactile defensiveness; children with ASD who didn't need ABA therapy; and the control group of healthy children. Number of microstates was determined in the initial and final parts of the resting-state EEGs.

Results and conclusions Children with higher tactile defensiveness for the most part had specific EEG microstates associated with unpleasant emotions and senses. The EEG microstates of children with ASD who did not need ABA therapy, had more similarities with the EEG microstates of typically developing children except for temporary changes. Meanwhile, the children with tactile defensiveness demonstrated typical patterns of EEG microstates from start to finish of the procedure.

Keywords:

Citation: Galina V. Portnova, Oxana Ivanova, Elena V. Proskurnina. Effects of EEG examination and ABA-therapy on resting-state EEG in children with low-functioning autism[J]. AIMS Neuroscience, 2020, 7(2): 153-167. doi: 10.3934/Neuroscience.2020011

Related Papers:

[1]	Haytham M. Rezk, Mohammed Zakarya, Amirah Ayidh I Al-Thaqfan, Maha Ali, Belal A. Glalah . Unveiling new reverse Hilbert-type dynamic inequalities within the framework of Delta calculus on time scales. AIMS Mathematics, 2025, 10(2): 2254-2276. doi: 10.3934/math.2025104
[2]	Ahmed A. El-Deeb, Dumitru Baleanu, Nehad Ali Shah, Ahmed Abdeldaim . On some dynamic inequalities of Hilbert's-type on time scales. AIMS Mathematics, 2023, 8(2): 3378-3402. doi: 10.3934/math.2023174
[3]	Ahmed A. El-Deeb, Samer D. Makharesh, Sameh S. Askar, Dumitru Baleanu . Bennett-Leindler nabla type inequalities via conformable fractional derivatives on time scales. AIMS Mathematics, 2022, 7(8): 14099-14116. doi: 10.3934/math.2022777
[4]	Marwa M. Ahmed, Wael S. Hassanein, Marwa Sh. Elsayed, Dumitru Baleanu, Ahmed A. El-Deeb . On Hardy-Hilbert-type inequalities with $\alpha$ -fractional derivatives. AIMS Mathematics, 2023, 8(9): 22097-22111. doi: 10.3934/math.20231126
[5]	Saad Ihsan Butt, Erhan Set, Saba Yousaf, Thabet Abdeljawad, Wasfi Shatanawi . Generalized integral inequalities for ABK-fractional integral operators. AIMS Mathematics, 2021, 6(9): 10164-10191. doi: 10.3934/math.2021589
[6]	Soubhagya Kumar Sahoo, Fahd Jarad, Bibhakar Kodamasingh, Artion Kashuri . Hermite-Hadamard type inclusions via generalized Atangana-Baleanu fractional operator with application. AIMS Mathematics, 2022, 7(7): 12303-12321. doi: 10.3934/math.2022683
[7]	Jian-Mei Shen, Saima Rashid, Muhammad Aslam Noor, Rehana Ashraf, Yu-Ming Chu . Certain novel estimates within fractional calculus theory on time scales. AIMS Mathematics, 2020, 5(6): 6073-6086. doi: 10.3934/math.2020390
[8]	Elkhateeb S. Aly, Y. A. Madani, F. Gassem, A. I. Saied, H. M. Rezk, Wael W. Mohammed . Some dynamic Hardy-type inequalities with negative parameters on time scales nabla calculus. AIMS Mathematics, 2024, 9(2): 5147-5170. doi: 10.3934/math.2024250
[9]	Ahmed A. El-Deeb, Osama Moaaz, Dumitru Baleanu, Sameh S. Askar . A variety of dynamic $\alpha$ -conformable Steffensen-type inequality on a time scale measure space. AIMS Mathematics, 2022, 7(6): 11382-11398. doi: 10.3934/math.2022635
[10]	Elkhateeb S. Aly, Ali M. Mahnashi, Abdullah A. Zaagan, I. Ibedou, A. I. Saied, Wael W. Mohammed . N-dimension for dynamic generalized inequalities of Hölder and Minkowski type on diamond alpha time scales. AIMS Mathematics, 2024, 9(4): 9329-9347. doi: 10.3934/math.2024454

Abstract

Objective We aimed to study the effects of EEG examination and ABA-therapy on resting-state EEG in children with low-functioning autism and tactile defensiveness.

1. Introduction

Quantum calculus or briefly $q$ -calculus is a study of calculus without limits. Post-quantum or $(p, q)$ -calculus is a generalization of $q$ -calculus and it is the next step ahead of the $q$ -calculus. Quantum Calculus is considered an incorporative subject between mathematics and physics, and many researchers have a particular interest in this subject. Quantum calculus has many applications in various mathematical fields such as orthogonal polynomials, combinatorics, hypergeometric functions, number theory and theory of differential equations etc. Many scholars researching in the field of inequalities have started to take interest in quantum calculus during the recent years and the active readers are referred to the articles ^{[2,3,7,8,9,11,12,16,17,21,24,25,27,28,29]} and the references cited in them for more information on this topic. The authors explore various integral inequalities in all of the papers mentioned above by using $q$ -calculus and $(p, q)$ -calculus for certain classes of convex functions.

In this paper, the main motivation is to study trapezoid type $(p, q)$ -integral inequalities for convex and quasi-convex functions. In fact, we prove that the assumption of the differentiability of the mapping in the $(p, q)$ -Hermite-Hadamard type integral inequalities given in ^[12] can be eliminated. The relaxation of the differentiability of the mapping in the $(p, q)$ -Hermite-Hadamard type integral inequalities proved in ^[12] also indicates the originality of results established in our research and these findings have some relationships with those results proved in earlier works.

2. Preliminaries

The basic concepts and findings which will be used in order to prove our results are addressed in this section.

Let $I\subset\mathbb{R}$ be an interval of the set of real numbers. A function $f:I\rightarrow\mathbb{R}$ is called as a convex on $I$ , if the inequality

$f\left( tx+\left( 1-t\right) y\right) \leq tf\left( x\right) +\left( 1-t\right) f\left( y\right)$

holds for every $x, y\in I$ and $t\in\left[ 0, 1\right]$ .

A $f:I\rightarrow\mathbb{R}$ known to be a quasi-convex function, if the inequality

$f\left( tx+\left( 1-t\right) y\right) \leq\sup\left\{ f\left( x\right) ,f\left( y\right) \right\}$

holds for every $x, y\in I$ and $t\in\left[ 0, 1\right]$ .

The following properties of convex functions are very useful to obtain our results.

Definition 2.1. ^[19] A function $f$ defined on $I$ has a support at $x_{0}\in I$ if there exists an affine function $A\left(x\right) = f\left(x_{0}\right) +m\left(x-x_{0}\right)$ such that $A\left(x\right) \leq f\left(x\right)$ for all $x\in I$ . The graph of the support function $A$ is called a line of support for $f$ at $x_{0}$ .

Theorem 2.1. ^[19] A function $f:\left(a, b\right) \rightarrow \mathbb{R}$ is a convex function if and only if there is at least one line of support for $f$ at each $x_{0}\in\left(a, b\right)$ .

Theorem 2.2. ^[4] If $f:\left[ a, b\right] \rightarrow \mathbb{R}$ is a convex function, then $f$ is continuous on $\left(a, b\right)$ .

Perhaps the most famous integral inequalities for convex functions are known as Hermite-Hadamard inequalities and are expressed as follows:

$\begin{equation} f\left( \frac{a+b}{2}\right) \leq\frac{1}{b-a}\int\limits_{a}^{b}f\left( t\right) dt\leq\frac{f\left( a\right) +f\left( b\right) }{2}, \end{equation}$

(2.1)

where the function $f:I\rightarrow \mathbb{R}$ is convex and $a, b\in I$ with $a < b$ .

By using the following identity, Pearce and Pečarić proved trapezoid type inequalities related to the convex functions in ^[18] and ^[6]. Some trapezoid type inequalities related to quasi-convex functions are proved in ^[1] and ^[9].

Lemma 2.3. ^[6] Let $f:I^{\circ}\subset \mathbb{R} \rightarrow \mathbb{R}$ be a differentiable mapping on $I^{\circ}$ ( $I^{\circ}$ is the interior of $I$ ), $a, b\in I^{\circ}$ with $a < b$ . If $f^{\prime}\in L\left[ a, b\right]$ , then the following equality holds:

$\begin{equation} \frac{f\left( a\right) +f\left( b\right) }{2}-\frac{1}{b-a}\int \limits_{a}^{b}f\left( t\right) dt = \frac{b-a}{2}\int\limits_{0}^{1}\left( 1-2t\right) f^{\prime}\left( ta+\left( 1-t\right) b\right) dt. \end{equation}$

(2.2)

Some definitions and results for $\left(p, q\right)$ -differentiation and $\left(p, q\right)$ -integration of the function $f:\left[ a, b\right] \rightarrow \mathbb{R}$ in the papers ^[12,22,23].

Definition 2.2. Let $f:\left[ a, b\right] \rightarrow \mathbb{R}$ be a continuous function and $0 < q < p\leq1$ , then $\left(p, q\right)$ -derivative of $f$ at $t\in\left[ a, b\right]$ is characterized by the expression

$\begin{equation} \begin{array} [c]{c} _{a}D_{p,q}f\left( t\right) \end{array} = \frac{f\left( pt+\left( 1-p\right) a\right) -f\left( qt+\left( 1-q\right) a\right) }{\left( p-q\right) \left( t-a\right) },\text{ }t\neq a. \end{equation}$

(2.3)

The function $f$ is said to be $\left(p, q\right)$ -differentiable on $\left[ a, b\right]$ , if $\begin{array} [c]{c} _{a}D_{p, q}f\left(t\right) \end{array}$ exists for all $t\in\left[ a, b\right]$ . It should be noted that

$\begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} = \underset{t\rightarrow a}{\lim} \begin{array} [c]{c} _{a}D_{p,q}f\left( t\right) \end{array} .$

It is clear that if $p = 1$ in $\left(2.3\right)$ , then

$\begin{align} \begin{array} [c]{c} _{a}D_{q}f\left( t\right) \end{array} & = \frac{f\left( t\right) -f\left( qt+\left( 1-q\right) a\right) }{\left( 1-q\right) \left( t-a\right) },\text{ }t\neq a. \\ \begin{array} [c]{c} _{a}D_{q}f\left( a\right) \end{array} & = \underset{t\rightarrow a}{\lim} \begin{array} [c]{c} _{a}D_{q}f\left( t\right) \end{array} \end{align}$

(2.4)

the $q$ -derivative of the function $f$ defined on $\left[ a, b\right]$ (see ^{[16,21,25,26]}).

Remark 2.1. If one takes $a = 0$ in $\left(2.3\right)$ , then $\begin{array} [c]{c} _{0}D_{p, q}f\left(t\right) = D_{p, q}f\left(t\right) \end{array}$ , where $\begin{array} [c]{c} D_{p, q}f\left(t\right) \end{array}$ is the $\left(p, q\right)$ -derivative of $f$ at $t\in\left[ 0, b\right]$ (see ^[5,10,20]) defined by the expression

$\begin{equation} \begin{array} [c]{c} D_{p,q}f\left( t\right) \end{array} = \frac{f\left( pt\right) -f\left( qt\right) }{\left( p-q\right) t},\text{ }t\neq0. \end{equation}$

(2.5)

Remark 2.2. If for $a = 0$ and $p = 1$ in $\left(2.3\right)$ , then $\begin{array} [c]{c} _{0}D_{q}f\left(x\right) \end{array} = \begin{array} [c]{c} D_{q}f\left(t\right) \end{array}$ , where $\begin{array} [c]{c} D_{q}f\left(t\right) \end{array}$ is the $q$ -derivative of $f$ at $t\in\left[ 0, b\right]$ (see ^[15]) given by the expression

$\begin{equation} \begin{array} [c]{c} D_{q}f\left( t\right) \end{array} = \frac{f\left( t\right) -f\left( qt\right) }{\left( 1-q\right) t},\text{ }t\neq0. \end{equation}$

(2.6)

Definition 2.3. Let $f:\left[ a, b\right] \rightarrow \mathbb{R}$ be a continuous function and $0 < q < p\leq1$ . The definite $\left(p, q\right)$ -integral of the function $f$ on $\left[ a, b\right]$ is defined as

$\begin{equation} \int\limits_{a}^{b}f\left( t\right) \begin{array} [c]{c} _{a}d_{p,q}t \end{array} = \left( p-q\right) \left( b-a\right) \sum\limits_{n = 0}^{\infty}\frac {q^{n}}{p^{n+1}}f\left( \frac{q^{n}}{p^{n+1}}b+\left( 1-\frac{q^{n}} {p^{n+1}}\right) a\right) \end{equation}$

(2.7)

If $c\in\left(a, b\right)$ , then the definite $\left(p, q\right)$ -integral of the function $f$ on $\left[ c, b\right]$ is defined as

$\begin{equation} \int\limits_{c}^{b}f\left( t\right) \begin{array} [c]{c} _{a}d_{p,q}t \end{array} = \int\limits_{a}^{b}f\left( t\right) \begin{array} [c]{c} _{a}d_{p,q}t \end{array} -\int\limits_{a}^{c}f\left( t\right) \begin{array} [c]{c} _{a}d_{p,q}t \end{array} . \end{equation}$

(2.8)

Remark 2.3. Let $p = 1$ be in $\left(2.7\right)$ , then

$\begin{equation} \int\limits_{a}^{b}f\left( t\right) \begin{array} [c]{c} _{a}d_{q}t \end{array} = \left( 1-q\right) \left( b-a\right) \sum\limits_{n = 0}^{\infty} q^{n}f\left( q^{n}b+\left( 1-q^{n}\right) a\right) \end{equation}$

(2.9)

the definite $q$ -integral of the function $f$ defined on $\left[ a, b\right]$ (see ^{[16,21,25,26]}).

Remark 2.4. Suppose that $a = 0$ in $\left(2.7\right)$ , then

$\begin{equation} \int\limits_{0}^{b}f\left( t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} = \int\limits_{0}^{b}f\left( t\right) \begin{array} [c]{c} d_{p,q}t \end{array} = \left( p-q\right) b\sum\limits_{n = 0}^{\infty}\frac{q^{n}}{p^{n+1}}f\left( \frac{q^{n}}{p^{n+1}}b\right) \end{equation}$

(2.10)

the definite $\left(p, q\right)$ -integral of $f$ on $\left[ 0, b\right]$ (see ^[20,22,23]). We notice that for $a = 0$ and $p = 1$ in $\left(2.7\right)$ , then

$\begin{equation} \int\limits_{0}^{b}f\left( t\right) \begin{array} [c]{c} _{0}d_{q}t \end{array} = \int\limits_{0}^{b}f\left( t\right) \begin{array} [c]{c} d_{q}t \end{array} = \left( 1-q\right) b\sum\limits_{n = 0}^{\infty}q^{n}f\left( q^{n}b\right) \end{equation}$

(2.11)

is the definite $q$ -integral of $f$ over the interval $\left[ 0, b\right]$ (see ^[15]).

Remark 2.5. When we take $a = 0$ and $p = 1$ , then the existing definitions in the literature are obtained, hence the Definition 2.2 and Definition 2.3 are well defined.

Quantum trapezoid type inequalities are obtained by Noor et al.^[16] and Sudsutad ^[21] by applying the definition convex and quasi-convex functions on the absolute values of the $q$ -derivative over the finite interval of the set of real numbers.

Lemma 2.4. Let $f:\left[ a, b\right] \subset \mathbb{R} \rightarrow \mathbb{R}$ be a continuous function and $0 < q < 1$ . If $\begin{array} [c]{c} _{a}D_{q}f \end{array}$ is a $q$ -integrable function on $\left(a, b\right)$ , then the equality holds:

$\begin{align} & \frac{1}{b-a}\int\limits_{a}^{b}f\left( t\right) \begin{array} [c]{c} _{a}d_{q}t \end{array} -\frac{qf\left( a\right) +f\left( b\right) }{1+q} \\ & = \frac{q\left( b-a\right) }{1+q}\int\limits_{0}^{1}\left( 1-\left( 1+q\right) t\right) \begin{array} [c]{c} _{a}D_{q}f\left( tb+\left( 1-t\right) b\right) \end{array} \begin{array} [c]{c} _{0}d_{q}t \end{array} . \end{align}$

(2.12)

The $\left(p, q\right)$ -Hermite-Hadamard type inequalities were proved in ^[12].

Theorem 2.5. Let $f:\left[ a, b\right] \rightarrow \mathbb{R}$ be a convex differentiable function on $\left[ a, b\right]$ and $0 < q < p\leq1$ . Then we have

$\begin{equation} f\left( \frac{qa+pb}{p+q}\right) \leq\frac{1}{p\left( b-a\right) } \int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} _{a}d_{p,q}x \end{array} \leq\frac{qf\left( a\right) +pf\left( b\right) }{p+q}. \end{equation}$

(2.13)

In this paper, we remove the $(p, q)$ -differentiability assumption of the function $f$ in Theorem 2.5 and establish $(p, q)$ -analog of the Lemma 2.4 and Lemma 2.3. We obtain $(p, q)$ -analog of the trapezoid type integral inequalities by applying the established identity, which generalize the inequalities given in ^{[1,6,9,16,18,21]}.

3. Main results

Throughout this section let $I\subset \mathbb{R}$ be an interval, $a, b\in I^{\circ}$ ( $I^{\circ}$ is the interior of $I$ ) with $a < b$ (in other words $\left[ a, b\right] \subset I^{\circ}$ ) and $0 < q < p\leq1$ are constants. Let us start proving the inequalities $\left(2.13\right)$ , with the lighter conditions for the function $f$ .

Theorem 3.1. Let $f:I\rightarrow \mathbb{R}$ be a convex function on $I$ and $a, b\in I^{\circ}$ with $a < b$ , then the following inequalities hold:

(3.1)

Proof. Since $f$ is convex function on the interval $I$ , by Theorem 2.2 $f$ is continuous on $I^{\circ}$ and $\left[ a, b\right] \subset I^{\circ}$ , the function $\ f$ is continuous on $\left[ a, b\right]$ . By using Theorem 2.1, there is at least one line of support for $f$ at each $x_{0} \in\left(a, b\right)$ . Since $x_{0} = \frac{qa+pb}{p+q}\in\left(a, b\right)$ , using Definition 2.1

$\begin{equation} A\left( x\right) = f\left( \frac{qa+pb}{p+q}\right) +m\left( x-\frac{qa+pb}{p+q}\right) \leq f\left( x\right) \end{equation}$

(3.2)

For all $x\in\left[ a, b\right]$ and some $m\in\left[ f_{-}^{\prime}\left(\frac{qa+pb}{p+q}\right), f_{+}^{\prime}\left(\frac{qa+pb}{p+q}\right) \right]$ . In the proof of the Theorem 2.5 the authors used the tangent line at the point of $x_{0} = \frac{qa+pb}{p+q}$ . Similarly, using the inequality $\left(3.2\right)$ and a similar method with the proof of the Theorem 2.5 we have $\left(3.1\right)$ but we omit the details. Thus the proof is accomplished.

We will use the following identity to prove trapezoid type $\left(p, q\right)$ -integral inequalities for convex and quasi-convex functions.

Lemma 3.2. Let $f:I^{\circ}\subset \mathbb{R} \rightarrow \mathbb{R}$ be a continuous function on $I^{\circ}$ and $a, b\in I^{\circ}$ with $a < b$ . If $\begin{array} [c]{c} _{a}D_{p, q}f \end{array}$ is continuous on $\left[ a, b\right]$ , then the equality:

$\begin{align} & \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} _{a}d_{p,q}x \end{array} -\frac{pf\left( b\right) +qf\left( a\right) }{p+q} \\ & = \frac{q\left( b-a\right) }{p+q}\int\limits_{0}^{1}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \end{align}$

(3.3)

holds.

Proof. Since $f$ is continuous on $I^{\circ}$ and $a, b\in I^{\circ}$ , the function $f$ is continuous on $\left[ a, b\right]$ . Hence, clearly $a < pb+\left(1-p\right) a\leq b$ for $0 < p\leq1$ and $\left[ a, pb+\left(1-p\right) a\right] \subset\left[ a, b\right]$ . Hence $f$ is continuous on $\left[ a, pb+\left(1-p\right) a\right]$ and hence according to the condition of the Definition 2.3, the function $f$ is $\left(p, q\right)$ -integrable on $\left[ a, pb+\left(1-p\right) a\right]$ . This means that the $\left(p, q\right)$ -integral

$\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} _{a}d_{p,q}x \end{array}$

is well defined and exists.

Since $f$ is continuous on $\left[ a, b\right]$ . Hence from Definition 2.2, $f$ is $\left(p, q\right)$ -differentiable on $\left[ a, b\right]$ . Thus the $\left(p, q\right)$ -derivative of $f$ given by the expression

$\begin{align} \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} & = \frac{\left[ f\left( p\left[ tb+\left( 1-t\right) a\right] +\left( 1-p\right) a\right) -f\left( q\left[ tb+\left( 1-t\right) a\right] +\left( 1-q\right) a\right) \right] }{\left( p-q\right) \left[ tb+\left( 1-t\right) a-a\right] } \\ & = \frac{f\left( ptb+\left( 1-pt\right) a\right) -f\left( qtb+\left( 1-qt\right) a\right) }{t\left( p-q\right) \left( b-a\right) }\text{, }t\neq0 \end{align}$

(3.4)

is well defined and exists.

Since $\left(1-\left(p+q\right) t\right)$ is continuous on $\left[ 0, 1\right]$ and $\begin{array} [c]{c} _{a}D_{p, q}f \end{array}$ is continuous on $\left[ a, b\right]$ , then

$\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array}$

is continuous on $\left[ 0, 1\right]$ and from Definition 2.3. Thus $\left(1-\left(p+q\right) t\right) \begin{array} [c]{c} _{a}D_{p, q}f\left(tb+\left(1-t\right) a\right) \end{array}$ is $\left(p, q\right)$ -integrable on $\left[ 0, 1\right]$ and the $\left(p, q\right)$ -integral

$\int\limits_{0}^{1}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \begin{array} [c]{c} _{0}d_{p,q}t \end{array}$

is well defined and exists.

By using $\left(2.7\right)$ and $\left(3.4\right)$ , we get

$\frac{q\left( b-a\right) }{p+q}\int\limits_{0}^{1}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \begin{array} [c]{c} _{0}d_{p,q}t \end{array}$

$= \frac{q\left( b-a\right) }{p+q}\int\limits_{0}^{1}\left( 1-\left( p+q\right) t\right) \frac{f\left( ptb+\left( 1-pt\right) a\right) -f\left( qtb+\left( 1-qt\right) a\right) }{t\left( p-q\right) \left( b-a\right) } \begin{array} [c]{c} _{0}d_{p,q}t \end{array}$

$= \frac{q}{p+q}\left[ \frac{1}{\left( p-q\right) }\int\limits_{0}^{1} \frac{f\left( ptb+\left( 1-pt\right) a\right) -f\left( qtb+\left( 1-qt\right) a\right) }{t} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right.$

$\left. -\frac{\left( p+q\right) }{\left( p-q\right) }\int\limits_{0} ^{1}f\left( ptb+\left( 1-pt\right) a\right) -f\left( qtb+\left( 1-qt\right) a\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right]$

$= \frac{q}{\left( p+q\right) \left( p-q\right) }\left[ \begin{array} [c]{c} \int\limits_{0}^{1}\frac{f\left( ptb+\left( 1-pt\right) a\right) }{t} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} -\int\limits_{0}^{1}\frac{f\left( qtb+\left( 1-qt\right) a\right) }{t} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \\ -\left( p+q\right) \int\limits_{0}^{1}f\left( ptb+\left( 1-pt\right) a\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} +\left( p+q\right) \int\limits_{0}^{1}f\left( qtb+\left( 1-qt\right) a\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \end{array} \right]$

$= \frac{q}{\left( p+q\right) }\left[ \begin{array} [c]{c} \sum_{n = 0}^{\infty}f\left( \frac{q^{n}}{p^{n}}b+\left( 1-\frac{q^{n}}{p^{n} }\right) a\right) -\sum_{n = 0}^{\infty}f\left( \frac{q^{n+1}}{p^{n+1} }b+\left( 1-\frac{q^{n+1}}{p^{n+1}}\right) a\right) \\ -\left( p+q\right) \sum_{n = 0}^{\infty}\frac{q^{n}}{p^{n+1}}f\left( \frac{q^{n}}{p^{n}}b+\left( 1-\frac{q^{n}}{p^{n}}\right) a\right) \\ +\left( p+q\right) \sum_{n = 0}^{\infty}\frac{q^{n}}{p^{n+1}}f\left( \frac{q^{n+1}}{p^{n+1}}b+\left( 1-\frac{q^{n+1}}{p^{n+1}}\right) a\right) \end{array} \right]$

$= \frac{q}{\left( p+q\right) }\left[ \begin{array} [c]{c} f\left( b\right) -f\left( a\right) -\frac{\left( p+q\right) }{p} \sum_{n = 0}^{\infty}\frac{q^{n}}{p^{n}}f\left( \frac{q^{n}}{p^{n}}b+\left( 1-\frac{q^{n}}{p^{n}}\right) a\right) \\ +\frac{\left( p+q\right) }{q}\sum_{n = 0}^{\infty}\frac{q^{n+1}}{p^{n+1} }f\left( \frac{q^{n+1}}{p^{n+1}}b+\left( 1-\frac{q^{n+1}}{p^{n+1}}\right) a\right) \end{array} \right]$

$= \frac{q}{\left( p+q\right) }\left[ f\left( b\right) -f\left( a\right) -\frac{\left( p+q\right) }{q}f\left( b\right) -\frac{\left( p+q\right) }{p}\sum\limits_{n = 0}^{\infty}\frac{q^{n}}{p^{n}}f\left( \frac{q^{n}}{p^{n} }b+\left( 1-\frac{q^{n}}{p^{n}}\right) a\right) \right.$

$\left. +\frac{\left( p+q\right) }{q}\sum\limits_{n = -1}^{\infty}\frac{q^{n+1} }{p^{n+1}}f\left( \frac{q^{n+1}}{p^{n+1}}b+\left( 1-\frac{q^{n+1}}{p^{n+1} }\right) a\right) \right]$

$= \frac{q}{\left( p+q\right) }\left[ \begin{array} [c]{c} -f\left( a\right) -\frac{p}{q}f\left( b\right) -\frac{\left( p+q\right) }{p}\sum_{n = 0}^{\infty}\frac{q^{n}}{p^{n}}f\left( \frac{q^{n}}{p^{n} }b+\left( 1-\frac{q^{n}}{p^{n}}\right) a\right) \\ +\frac{\left( p+q\right) }{q}\sum_{n = 0}^{\infty}\frac{q^{n}}{p^{n}}f\left( \frac{q^{n}}{p^{n}}b+\left( 1-\frac{q^{n}}{p^{n}}\right) a\right) \end{array} \right]$

$= \frac{q}{\left( p+q\right) }\left[ -f\left( a\right) -\frac{p} {q}f\left( b\right) -\left( \frac{\left( p+q\right) }{p}-\frac{\left( p+q\right) }{q}\right) \sum\limits_{n = 0}^{\infty}\frac{q^{n}}{p^{n}}f\left( \frac{q^{n}}{p^{n}}b+\left( 1-\frac{q^{n}}{p^{n}}\right) a\right) \right]$

$= \frac{q}{\left( p+q\right) }\left[ -f\left( a\right) -\frac{p} {q}f\left( b\right) -\left( \frac{\left( p+q\right) }{p}-\frac{\left( p+q\right) }{q}\right) \frac{1}{\left( p-q\right) \left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} _{a}d_{p,q}x \end{array} \right]$

$= \frac{1}{p\left( b-q\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} _{a}d_{p,q}x \end{array} -\frac{pf\left( b\right) +qf\left( a\right) }{p+q}.$

This completes the proof.

Remark 3.1. The subsequent observations are important to note from the result of Lemma 3.2:

1. If $p = 1$ , we recapture Lemma 2.4,

2. If $p = 1$ and $q\rightarrow1^{-}$ , we recapture Lemma 2.3.

We can now prove some quantum estimates of $\left(p, q\right)$ -trapezoidal integral inequalities by using convexity and quasi-convexity of the absolute values of the $\left(p, q\right)$ -derivatives.

Theorem 3.3. Let $f:I^{\circ}\subset \mathbb{R} \rightarrow \mathbb{R}$ be a continuous function on $I^{\circ}$ and $a, b\in I^{\circ}$ with $a < b$ such that $\begin{array} [c]{c} _{a}D_{p, q}f \end{array}$ is continuous on $\left[ a, b\right]$ and $0 < q < p\leq1$ . If $\left\vert \begin{array} [c]{c} _{a}D_{p, q}f \end{array} \right\vert ^{r}$ is a convex function on $\left[ a, b\right]$ for $r\geq1$ , then

$\begin{equation} \left\vert \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \mathit{\text{}} \begin{array} [c]{c} _{a}d_{p,q}x \end{array} -\frac{pf\left( b\right) +qf\left( a\right) }{p+q}\right\vert \end{equation}$

(3.5)

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \frac{2\left( p+q-1\right) }{\left( p+q\right) ^{2}}\right] ^{1-\frac{1}{r}}\left[ \gamma_{1}\left( p,q\right) \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert ^{r}+\gamma_{2}\left( p,q\right) \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ^{r}\right] ^{\frac{1}{r}}$

holds, where

$\gamma_{1}\left( p,q\right) = \frac{q\left[ \left( p^{3}-2+2p\right) +\left( 2p^{2}+2\right) q+pq^{2}\right] +2p^{2}-2p}{\left( p+q\right) ^{3}\left( p^{2}+pq+q^{2}\right) }$

and

$\gamma_{2}\left( p,q\right) = \frac{q\left[ \left( 5p^{3}-4p^{2} -2p+2\right) +\left( 6p^{2}-4p-2\right) q+\left( 5p-2\right) q^{2} +2q^{3}\right] +\left( 2p^{4}-2p^{3}-2p^{2}+2p\right) }{\left( p+q\right) ^{3}\left( p^{2}+pq+q^{2}\right) }.$

Proof. Taking absolute value on both sides of $\left(3.3\right)$ , applying the power-mean inequality and by using the convexity of $\left\vert _{a}D_{p, q}f\right\vert ^{r}$ for $r\geq1$ , we obtain

$\begin{equation} \left\vert \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \text{ } \begin{array} [c]{c} _{a}d_{p,q}x \end{array} -\frac{pf\left( b\right) +qf\left( a\right) }{p+q}\right\vert \end{equation}$

(3.6)

$\leq\frac{q\left( b-a\right) }{p+q}\int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array}$

$\leq\frac{q\left( b-a\right) }{p+q}\left( \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right) ^{1-\frac{1}{r}}\left( \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \right\vert ^{r} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right) ^{\frac{1}{r}}$

$\leq\frac{q\left( b-a\right) }{p+q}\left( \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right) ^{1-\frac{1}{r}}$

$\times\left[ \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert ^{r}\int\limits_{0}^{1}t\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} +\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ^{r}\int\limits_{0}^{1}\left( 1-t\right) \left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{r}}.$

We evaluate the definite ( $p, q$ )-integrals as follows

$\begin{equation} \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} = \int\limits_{0}^{\frac{1}{p+q}}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} -\int\limits_{\frac{1}{p+q}}^{1}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \end{equation}$

(3.7)

$= 2\int\limits_{0}^{\frac{1}{p+q}}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} -\int\limits_{0}^{1}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} = \frac{2\left( p+q-1\right) }{\left( p+q\right) ^{2}},$

$\begin{equation} \int\limits_{0}^{1}t\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} = 2\int_{0}^{\frac{1}{p+q}}t\left( 1-\left( p+q\right) t\right) \text{ } \begin{array} [c]{c} _{0}d_{p,q}t \end{array} -\int\limits_{0}^{1}t\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \end{equation}$

(3.8)

$= \frac{2p^{2}+2pq+2q^{2}-2p-2q}{\left( p+q\right) ^{3}\left( p^{2} +pq+q^{2}\right) }-\frac{-pq}{\left( p+q\right) \left( p^{2} +pq+q^{2}\right) }$

$= \frac{p^{3}q+2p^{2}q^{2}+pq^{3}+2p^{2}+2pq+2q^{2}-2p-2q}{\left( p+q\right) ^{3}\left( p^{2}+pq+q^{2}\right) }$

$= \frac{q\left[ \left( p^{3}-2+2p\right) +\left( 2p^{2}+2\right) q+pq^{2}\right] +2p^{2}-2p}{\left( p+q\right) ^{3}\left( p^{2} +pq+q^{2}\right) } = \gamma_{1}\left( p,q\right)$

and

$\begin{equation} \int\limits_{0}^{1}\left( 1-t\right) \left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} = \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} -\int\limits_{0}^{1}t\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \end{equation}$

(3.9)

$= \frac{2\left( p+q-1\right) }{\left( p+q\right) ^{2}}-\frac{\left[ p^{3}q+2p^{2}q^{2}+pq^{3}+2p^{2}+2pq+2q^{2}-2p-2q\right] }{\left( p+q\right) ^{3}\left( p^{2}+pq+q^{2}\right) }$

$= \frac{q\left[ \left( 5p^{3}-4p^{2}-2p+2\right) +\left( 6p^{2} -4p-2\right) q+\left( 5p-2\right) q^{2}+2q^{3}\right] +\left( 2p^{4}-2p^{3}-2p^{2}+2p\right) }{\left( p+q\right) ^{3}\left( p^{2}+pq+q^{2}\right) }$

$= \gamma_{2}\left( p,q\right) .$

Making use of $\left(3.7\right)$ , $\left(3.8\right)$ and $\left(3.9\right)$ in $\left(3.6\right)$ , gives us the desired result $\left(3.5\right)$ . The proof is thus accomplished.

Corollary 3.1. We can get the following subsequent results from $\left(3.5\right)$ proved in Theorem 3.3:

$(1).$ Suppose $p = 1$ and $r = 1$ , then we acquire the inequality proved in [,Theorem 4.1] (see also [,inequality $(5)$ ]):

(3.10)

$\leq\frac{q^{2}\left( b-a\right) }{\left( 1+q\right) ^{4}\left( 1+q+q^{2}\right) }\left[ \left[ 1+4q+q^{2}\right] \left\vert \begin{array} [c]{c} _{a}D_{q}f\left( b\right) \end{array} \right\vert +\left[ 1+3q^{2}+2q^{3}\right] \left\vert \begin{array} [c]{c} _{a}D_{q}f\left( a\right) \end{array} \right\vert \right] .$

$(2).$ Letting $p = 1$ , provides the inequality established in [16,Theorem 3.2] (see also ^[14], [21,Theorem 4.2] and ^[13]):

$\begin{equation} \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) \begin{array} [c]{c} _{a}d_{q}x \end{array} -\frac{qf\left( a\right) +f\left( b\right) }{1+q}\right\vert \leq \frac{q\left( b-a\right) }{1+q}\left[ \frac{2q}{\left( 1+q\right) ^{2} }\right] ^{1-\frac{1}{r}} \end{equation}$

(3.11)

$\times\left[ \frac{q\left[ 1+4q+q^{2}\right] }{\left( 1+q\right) ^{3}\left( 1+q+q^{2}\right) }\left\vert \begin{array} [c]{c} _{a}D_{q}f\left( b\right) \end{array} \right\vert ^{r}+\frac{q\left[ 1+3q^{2}+2q^{3}\right] }{\left( 1+q\right) ^{3}\left( 1+q+q^{2}\right) }\left\vert \begin{array} [c]{c} _{a}D_{q}f\left( a\right) \end{array} \right\vert ^{r}\right] ^{\frac{1}{r}}.$

$(3).$ Taking $p = 1$ and letting $q\rightarrow1^{-}$ , gives the inequality proved in [18,Theorem 1]:

$\begin{equation} \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) dx-\frac{f\left( a\right) +f\left( b\right) }{2}\right\vert \leq \frac{\left( b-a\right) }{4}\left[ \frac{\left\vert f^{\prime}\left( a\right) \right\vert ^{r}+\left\vert f^{\prime}\left( b\right) \right\vert ^{r}}{2}\right] ^{\frac{1}{r}}. \end{equation}$

(3.12)

$(4).$ Suppose $r = 1$ , $p = 1$ and letting $q\rightarrow1^{-}$ , we obtain the inequality proved in [6,Theorem 2.2]:

$\begin{equation} \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) dx-\frac{f\left( a\right) +f\left( b\right) }{2}\right\vert \leq \frac{\left( b-a\right) \left[ \left\vert f^{\prime}\left( a\right) \right\vert +\left\vert f^{\prime}\left( b\right) \right\vert \right] }{8}. \end{equation}$

(3.13)

Theorem 3.4. Let $f:I^{\circ}\subset \mathbb{R} \rightarrow \mathbb{R}$ be a continuous function on $I^{\circ}$ and $a, b\in I^{\circ}$ with $a < b$ . If $\begin{array} [c]{c} _{a}D_{p, q}f \end{array}$ is continuous on $\left[ a, b\right]$ , $0 < q < p\leq1$ and $\left\vert \begin{array} [c]{c} _{a}D_{p, q}f \end{array} \right\vert ^{r}$ is a convex function on $\left[ a, b\right]$ for $r > 1$ , then

(3.14)

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \gamma_{3}\left( p,q;s\right) \right] ^{\frac{1}{s}}\left( \frac{\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert ^{r}+\left( p+q-1\right) \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ^{r}}{p+q}\right) ^{\frac{1}{r}},$

where

$\gamma_{3}\left( p,q;s\right) = \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert ^{s} \begin{array} [c]{c} _{0}d_{p,q}t \end{array}$

and $\frac{1}{r}+\frac{1}{s} = 1$ .

Proof. Taking absolute value on both sides of $\left(3.3\right)$ , applying the Hölder inequality and using the convexity of $\left\vert \begin{array} [c]{c} _{a}D_{p, q}f \end{array} \right\vert ^{r}$ for $r > 1$ , we get

$\begin{equation} \left\vert \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} _{a}d_{p,q}x \end{array} -\frac{pf\left( b\right) +qf\left( a\right) }{p+q}\right\vert \end{equation}$

(3.15)

$\leq\frac{q\left( b-a\right) }{p+q}\left( \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert ^{s} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right) ^{\frac{1}{s}}$

$\times\left[ \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert ^{r}\int\limits_{0}^{1}t \begin{array} [c]{c} _{0}d_{p,q}t \end{array} +\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ^{r}\int\limits_{0}^{1}\left( 1-t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{r}}$

$= \frac{q\left( b-a\right) }{p+q}\left( \gamma_{3}\left( p,q;s\right) \right) ^{\frac{1}{s}}\left[ \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert ^{r}\int\limits_{0}^{1}t \begin{array} [c]{c} _{0}d_{p,q}t \end{array} +\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ^{r}\int\limits_{0}^{1}\left( 1-t\right) \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{r}}.$

We evaluate the definite $\left(p, q\right)$ -integrals as follows

$\int\limits_{0}^{1}t\text{ } \begin{array} [c]{c} _{0}d_{p,q}t \end{array} = \frac{1}{p+q}$

and

$\int\limits_{0}^{1}\left( 1-t\right) \text{ } \begin{array} [c]{c} _{0}d_{p,q}t \end{array} = \frac{p+q-1}{p+q}.$

By using the values of the above definite $\left(p, q\right)$ -integrals in $\left(3.15\right)$ , we get what is required.

Corollary 3.2. In Theorem 3.4;

$(1).$ If we take $p = 1$ , then

(3.16)

$\leq\frac{q\left( b-a\right) }{1+q}\left[ \gamma_{3}\left( 1,q;s\right) \right] ^{\frac{1}{s}}\left( \frac{\left\vert \begin{array} [c]{c} _{a}D_{q}f\left( b\right) \end{array} \right\vert ^{r}+q\left\vert \begin{array} [c]{c} _{a}D_{q}f\left( a\right) \end{array} \right\vert ^{r}}{1+q}\right) ^{\frac{1}{r}}.$

$(2).$ If we take $p = 1$ and letting $q\rightarrow1^{-}$ , then

$\begin{equation} \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) dx-\frac{f\left( a\right) +f\left( b\right) }{2}\right\vert \leq \frac{\left( b-a\right) }{2\left( s+1\right) ^{\frac{1}{s}}}\left[ \frac{\left\vert f^{\prime}\left( a\right) \right\vert ^{r}+\left\vert f^{\prime}\left( b\right) \right\vert ^{r}}{2}\right] ^{\frac{1}{r}}. \end{equation}$

(3.17)

Remark 3.5. The inequality $\left(3.17\right)$ has been established in [6,Theorem 2.3].

Theorem 3.5. Let $f:I^{\circ}\subset \mathbb{R} \rightarrow \mathbb{R}$ be a continuous function on $I^{\circ}$ and $a, b\in I^{\circ}$ with $a < b$ . Suppose that $\begin{array} [c]{c} _{a}D_{p, q}f \end{array}$ is continuous on $\left[ a, b\right]$ , $0 < q < p\leq1$ and $\left\vert \begin{array} [c]{c} _{a}D_{p, q}f \end{array} \right\vert ^{r}$ is a convex function on $\left[ a, b\right]$ for $r > 1$ , then

(3.18)

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \frac{2\left( p+q-1\right) }{\left( p+q\right) ^{2}}\right] ^{\frac{1}{s}}\left[ \gamma_{1}\left( p,q\right) \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert ^{r}+\gamma_{2}\left( p,q\right) \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ^{r}\right] ^{\frac{1}{r}},$

where $\gamma_{1}\left(p, q\right)$ , $\gamma_{2}\left(p, q\right)$ are defined as in Theorem 3.3 and $\frac{1}{r}+\frac{1}{s} = 1$ .

(3.19)

$= \frac{q\left( b-a\right) }{p+q}\left\vert \int\limits_{0}^{1}\left( 1-\left( p+q\right) t\right) \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right\vert$

$= \frac{q\left( b-a\right) }{p+q}\left\vert \int\limits_{0}^{1}\left( 1-\left( p+q\right) t\right) ^{\frac{1}{s}}\left( 1-\left( p+q\right) t\right) ^{\frac{1}{r}} \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right\vert$

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{s}}\left[ \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \right\vert ^{r} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{r}}$

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{s}}$

Making use of $\left(3.7\right)$ , $\left(3.8\right)$ and $\left(3.9\right)$ in $\left(3.19\right)$ , gives us the desired result $\left(3.18\right)$ . The proof is thus accomplished.

Corollary 3.3. The following results are the consequences of Theorem 3.5:

$(1).$ Taking $p = 1$ , we obtain the inequality proved in [16,Theorem 3.3] (see also [14,inequality (8)]):

(3.20)

$(2).$ Taking $p = 1$ and letting $q\rightarrow1^{-}$ , we obtain the inequality proved in [18,Theorem 1]:

$\begin{equation} \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) dx-\frac{f\left( a\right) +f\left( b\right) }{2}\right\vert \leq \frac{\left( b-a\right) }{2^{s+1}}\left[ \frac{\left\vert f^{\prime}\left( b\right) \right\vert ^{r}+\left\vert f^{\prime}\left( a\right) \right\vert ^{r}}{4}\right] ^{\frac{1}{r}}. \end{equation}$

(3.21)

Some results related for quasi-convexity are presented in the following theorems.

Theorem 3.6. Let $f:I^{\circ}\subset \mathbb{R} \rightarrow \mathbb{R}$ be a continuous function on $I^{\circ}$ and $a, b\in I^{\circ}$ with $a < b$ . If $\begin{array} [c]{c} _{a}D_{p, q}f \end{array}$ is continuous on $\left[ a, b\right]$ , where $0 < q < p\leq1$ and $\left\vert \begin{array} [c]{c} _{a}D_{p, q}f \end{array} \right\vert ^{r}$ is a quasi-convex function on $\left[ a, b\right]$ $r\geq1$ , then

$\begin{equation} \left\vert \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} \mathit{\text{}}_{a}d_{p,q}x \end{array} -\frac{pf\left( b\right) +qf\left( a\right) }{p+q}\right\vert \end{equation}$

(3.22)

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \frac{2\left( p+q-1\right) }{\left( p+q\right) ^{2}}\right] \sup\left\{ \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ,\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert \right\} .$

Proof. Taking absolute value on both sides of $\left(3.3\right)$ , applying the power mean inequality and using the quasi-convexity of $\left\vert _{a}D_{p, q}f\right\vert ^{r}$ on $\left[ a, b\right]$ for $r\geq1$ , we have that

$\left\vert \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \begin{array} [c]{c} _{a}d_{p,q}x \end{array} -\frac{pf\left( b\right) +qf\left( a\right) }{p+q}\right\vert$

$\leq\frac{q\left( b-a\right) }{p+q}\left( \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right) ^{1-\frac{1}{r}}$

$\times\left( \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \text{ } \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \sup\left\{ \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ^{r},\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert ^{r}\right\} \right) ^{\frac{1}{r}}$

$= \frac{q\left( b-a\right) }{p+q}\left( \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right) \sup\left\{ \left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( a\right) \end{array} \right\vert ,\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( b\right) \end{array} \right\vert \right\} .$

From $\left(3.7\right)$ , we have

$\int_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert _{0}d_{p,q} t = \frac{2\left( p+q-1\right) }{\left( p+q\right) ^{2}}.$

Hence the inequality $\left(3.22\right)$ is established.

Corollary 3.4. In Theorem 3.6

$(1).$ If we let $p = 1$ , then:

(3.23)

$\leq\frac{q\left( b-a\right) }{1+q}\left[ \frac{2q}{\left( 1+q\right) ^{2}}\right] \sup\left\{ \left\vert \begin{array} [c]{c} _{a}D_{q}f\left( a\right) \end{array} \right\vert ,\left\vert \begin{array} [c]{c} _{a}D_{q}f\left( b\right) \end{array} \right\vert \right\} .$

$(2).$ If we take $p = 1$ and letting $q\rightarrow1^{-}$ , then:

$\begin{equation} \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) dx-\frac{f\left( a\right) +f\left( b\right) }{2}\right\vert \leq \frac{\left( b-a\right) }{4}\sup\left\{ \left\vert f^{\prime}\left( a\right) \right\vert ,\left\vert f^{\prime}\left( b\right) \right\vert \right\} . \end{equation}$

(3.24)

Remark 3.3. From the results of Corollary 4, we can observe the following consequences

$(1).$ The result of the inequality $\left(3.23\right)$ has also been obtained in [16,Theorem 3.4] (see also [14,inequality (9)]),

$(2).$ The result of the inequality $\left(3.24\right)$ was established in [1,Theorem 6] and [9,Theorem 1].

Theorem 3.7. Let $f:I^{\circ}\subset \mathbb{R} \rightarrow \mathbb{R}$ be a continuous function on $I^{\circ}$ and $a, b\in I^{\circ}$ with $a < b$ . If $\begin{array} [c]{c} _{a}D_{p, q}f \end{array}$ is continuous on $\left[ a, b\right]$ , where $0 < q < p\leq1$ and $\left\vert \begin{array} [c]{c} _{a}D_{p, q}f \end{array} \right\vert ^{r}$ is a quasi-convex function on $\left[ a, b\right]$ for $r > 1$ , then:

$\begin{equation} \left\vert \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \mathit{\text{}}_{a}d_{p,q}x-\frac{pf\left( b\right) +qf\left( a\right) }{p+q}\right\vert \end{equation}$

(3.25)

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \gamma_{3}\left( p,q;s\right) \right] ^{\frac{1}{s}}\left( \sup\left\{ \left\vert _{a}D_{p,q}f\left( a\right) \right\vert ,\left\vert _{a}D_{p,q}f\left( b\right) \right\vert \right\} \right) ,$

where $\gamma_{3}\left(p, q;s\right)$ is as defined in Theorem 3.4 and $\frac{1}{r}+\frac{1}{s} = 1$ .

Proof. Taking absolute value on both sides of $\left(3.3\right)$ , applying the Hölder inequality and using the quasi-convexity of $\left\vert _{a}D_{p, q}f\right\vert ^{r}$ on $\left[ a, b\right]$ for $r > 1$ , we have that

$\left\vert \frac{1}{p\left( b-a\right) }\int\limits_{a}^{pb+\left( 1-p\right) a}f\left( x\right) \text{ }_{a}d_{p,q}x-\frac{pf\left( b\right) +qf\left( a\right) }{p+q}\right\vert$

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert ^{s} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{s}}$

$\times\left[ \int\limits_{0}^{1}\left\vert \begin{array} [c]{c} _{a}D_{p,q}f\left( tb+\left( 1-t\right) a\right) \end{array} \right\vert ^{r} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{r}}$

$\leq\frac{q\left( b-a\right) }{p+q}\left[ \int\limits_{0}^{1}\left\vert 1-\left( p+q\right) t\right\vert ^{s} \begin{array} [c]{c} _{0}d_{p,q}t \end{array} \right] ^{\frac{1}{s}}\sup\left\{ \left\vert _{a}D_{p,q}f\left( b\right) \right\vert ,\left\vert _{a}D_{p,q}f\left( a\right) \right\vert \right\} .$

$= \frac{q\left( b-a\right) }{p+q}\left[ \gamma_{3}\left( p,q;s\right) \right] ^{\frac{1}{s}}\left( \sup\left\{ \left\vert _{a}D_{p,q}f\left( a\right) \right\vert ,\left\vert _{a}D_{p,q}f\left( b\right) \right\vert \right\} \right)$

The inequality $\left(3.25\right)$ is proved.

Corollary 3.5. In Theorem 3.7;

$(1).$ If $p = 1$ , then we obtain the inequality proved in [9,Theorem 2]:

$\begin{align} & \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) \begin{array} [c]{c} _{a}d_{q}x \end{array} -\frac{qf\left( a\right) +f\left( b\right) }{1+q}\right\vert \\ & \leq\frac{q\left( b-a\right) }{1+q}\left[ \gamma_{3}\left( 1,q;s\right) \right] ^{\frac{1}{s}}\left( \sup\left\{ \left\vert _{a} D_{q}f\left( a\right) \right\vert ,\left\vert _{a}D_{q}f\left( b\right) \right\vert \right\} \right) , \end{align}$

(3.26)

$(2).$ If $p = 1$ and letting $q\rightarrow1^{-}$ , then:

$\begin{equation} \left\vert \frac{1}{\left( b-a\right) }\int\limits_{a}^{b}f\left( x\right) dx-\frac{f\left( a\right) +f\left( b\right) }{2}\right\vert \leq \frac{\left( b-a\right) }{2\left( s+1\right) ^{\frac{1}{s}}}\sup\left\{ \left\vert f^{\prime}\left( a\right) \right\vert ,\left\vert f^{\prime }\left( b\right) \right\vert \right\} . \end{equation}$

(3.27)

acknowledgement

The authors would like to thank the referee for his/her careful reading of the manuscript and for making valuable suggestions.

Conflict of interest

The authors declare to have no conflict of interest.

Limitations

Unfortunately, we had the only one attempt to divide children with low-functioning ASD in two groups. If child refused to participate in EEG study, he received ABA therapy or was excluded from the study. The tactile hypersensitivity was not the only reason which didn't allow conducting a study on the first attempt, the four children with ASD excluded from the study because of the unmotivated aggression, disruptive behavior and even fever. Because of the difficulties to recruit participants in advance, we had to divide groups after the attempt to perform an EEG examination.

Funding

The reported study was funded by RFBR according to the research project № 18-00-01670 (18-00-01511) and the state assignment of Ministry of Education and Science of the Russian Federation for 2019-2021 (No. АААА-А17-117092040004-0).

Conflict of interests

The authors have no conflicts of interest to disclose.

References

[1]	Mayes SD, Calhoun SL, Murray MJ, et al. (2009) Comparison of scores on the Checklist for Autism spectrum disorder, childhood Autism rating scale, and Gilliam Asperger's disorder scale for children with low functioning autism, high functioning autism, Asperger's disorder, ADHD, and typical development. J Autism Dev Disord 39: 1682-1693. doi: 10.1007/s10803-009-0812-6
[2]	Binnie CD, Prior PF (1994) Electroencephalography. J Neurol Neurosurg Psychiatry 57: 1308-1319. doi: 10.1136/jnnp.57.11.1308
[3]	Rutherford MD, Baron-Cohen S, Wheelwright S (2002) Reading the mind in the voice: a study with normal adults and adults with Asperger syndrome and high functioning autism. J Autism Dev Disord 32: 189-194. doi: 10.1023/A:1015497629971
[4]	Paul R, Shriberg LD, McSweeny J, et al. (2005) Brief report: relations between prosodic performance and communication and socialization ratings in high functioning speakers with autism spectrum disorders. J Autism Dev Disord 35: 861-869. doi: 10.1007/s10803-005-0031-8
[5]	Brambilla P, Hardan A, di Nemi SU, et al. (2003) Brain anatomy and development in autism: review of structural MRI studies. Brain Res Bull 61: 557-569. doi: 10.1016/j.brainresbull.2003.06.001
[6]	Ray E, Schlottmann A (2007) The perception of social and mechanical causality in young children with ASD. Res Autism Spect Dis 1: 266-280. doi: 10.1016/j.rasd.2006.11.002
[7]	Schuler AL, Fay WH (1980) Emerging language in autistic children Baltimore: University Park Press, 216.
[8]	Smith EG, Bennetto L (2007) Audiovisual speech integration and lipreading in autism. J Child Psychol Psychiatry 48: 813-821. doi: 10.1111/j.1469-7610.2007.01766.x
[9]	von Hofsten C, Rosander K (2012) Perception-action in children with ASD. Front Integr Neurosci 6: 115. doi: 10.3389/fnint.2012.00115
[10]	Gillberg C, Billstedt E (2000) Autism and Asperger syndrome: coexistence with other clinical disorders. Acta Psychiatr Scand 102: 321-330. doi: 10.1034/j.1600-0447.2000.102005321.x
[11]	Yasuhara A (2010) Correlation between EEG abnormalities and symptoms of autism spectrum disorder (ASD). Brain Dev 32: 791-798. doi: 10.1016/j.braindev.2010.08.010
[12]	Marco EJ, Hinkley LB, Hill SS, et al. (2011) Sensory processing in autism: A review of neurophysiologic findings. Pediatr Res 69: 48R-54R. doi: 10.1203/PDR.0b013e3182130c54
[13]	Moore DJ (2015) Acute pain experience in individuals with autism spectrum disorders: A review. Autism 19: 387-399. doi: 10.1177/1362361314527839
[14]	Tomchek SD, Dunn W (2007) Sensory processing in children with and without Autism: A comparative study using the short sensory profile. Am J Occup Ther 61: 190-200. doi: 10.5014/ajot.61.2.190
[15]	Olausson HW, Cole J, Vallbo A, et al. (2008) Unmyelinated tactile afferents have opposite effects on insular and somatosensory cortical processing. Neurosci Lett 436: 128-132. doi: 10.1016/j.neulet.2008.03.015
[16]	McPhilemy C, Dillenburger K (2013) Parents' experiences of applied behaviour analysis (ABA)-based interventions for children diagnosed with autistic spectrum disorder. Brit J Spec Educ 40: 154-161. doi: 10.1111/1467-8578.12038
[17]	Cooper JO, Heron TE, Heward WL (2007) Applied behavior analysis. London: Pearson 770.
[18]	AlHumaid J, Tesini D, Finkelman M, et al. (2016) Effectiveness of the D-TERMINED program of repetitive tasking for children with autism spectrum disorder. J Dent Child 83: 16-21.
[19]	Wang J, Barstein J, Ethridge LE, et al. (2013) Resting state EEG abnormalities in autism spectrum disorders. J Neurodev Disord 5: 24. doi: 10.1186/1866-1955-5-24
[20]	Heunis TM, Aldrich C, de Vries PJ (2016) Recent advances in resting-state electroencephalography biomarkers for autism spectrum disorder—A review of methodological and clinical challenges. Pediatr Neurol 61: 28-37. doi: 10.1016/j.pediatrneurol.2016.03.010
[21]	Khanna A, Pascual-Leone A, Michel CM, et al. (2015) Microstates in resting-state EEG: current status and future directions. Neurosci Biobehav Rev 49: 105-113. doi: 10.1016/j.neubiorev.2014.12.010
[22]	Gasser T, Verleger R, Bacher P, et al. (1988) Development of the EEG of school-age children and adolescents. I. Analysis of band power. Electroencephalogr Clin Neurophysiol 69: 91-99. doi: 10.1016/0013-4694(88)90204-0
[23]	Fraga Gonzalez G, Van der Molen MJW, Zaric G, et al. (2016) Graph analysis of EEG resting state functional networks in dyslexic readers. Clin Neurophysiol 127: 3165-3175. doi: 10.1016/j.clinph.2016.06.023
[24]	Conyers C, Miltenberger RG, Peterson B, et al. (2004) An evaluation of in vivo desensitization and video modeling to increase compliance with dental procedures in persons with mental retardation. J Appl Behav Anal 37: 233-238. doi: 10.1901/jaba.2004.37-233
[25]	Shabani DB, Fisher WW (2006) Stimulus fading and differential reinforcement for the treatment of needle phobia in a youth with autism. J Appl Behav Anal 39: 449-452. doi: 10.1901/jaba.2006.30-05
[26]	Royeen CB (1985) Domain specifications of the construct tactile defensiveness. Am J Occup Ther 39: 596-599. doi: 10.5014/ajot.39.9.596
[27]	Larson KA (1982) The sensory history of developmentally delayed children with and without tactile defensiveness. Am J Occup Ther 36: 590-596. doi: 10.5014/ajot.36.9.590
[28]	Poulsen AT, Pedroni A, Langer N, et al. (2018) Microstate EEGlab toolbox: An introductory guide. bioRxiv 289850.
[29]	Coben R, Clarke AR, Hudspeth W, et al. (2008) EEG power and coherence in autistic spectrum disorder. Clin Neurophysiol 119: 1002-1009. doi: 10.1016/j.clinph.2008.01.013
[30]	Murias M, Webb SJ, Greenson J, et al. (2007) Resting state cortical connectivity reflected in EEG coherence in individuals with autism. Biol Psychiatry 62: 270-273. doi: 10.1016/j.biopsych.2006.11.012
[31]	Clarke AR, Barry RJ, McCarthy R, et al. (2001) Age and sex effects in the EEG: development of the normal child. Clin Neurophysiol 112: 806-814. doi: 10.1016/S1388-2457(01)00488-6
[32]	Tierney AL, Gabard-Durnam L, Vogel-Farley V, et al. (2012) Developmental trajectories of resting EEG power: An endophenotype of autism spectrum disorder. PloS One 7: e39127. doi: 10.1371/journal.pone.0039127
[33]	Lehmann D (1971) Multichannel topography of human alpha EEG fields. Electroencephalogr Clin Neurophysiol 31: 439-449. doi: 10.1016/0013-4694(71)90165-9
[34]	Lehmann D, Strik WK, Henggeler B, et al. (1998) Brain electric microstates and momentary conscious mind states as building blocks of spontaneous thinking: I. Visual imagery and abstract thoughts. Int J Psychophysiol 29: 1-11. doi: 10.1016/S0167-8760(97)00098-6
[35]	D'Croz-Baron DF, Baker M, Michel CM, et al. (2019) EEG microstates analysis in young adults with autism spectrum disorder during resting-state. Front Hum Neurosci 13: 173. doi: 10.3389/fnhum.2019.00173
[36]	Jia H, Yu D (2019) Aberrant intrinsic brain activity in patients with autism spectrum disorder: Insights from EEG microstates. Brain Topogr 32: 295-303. doi: 10.1007/s10548-018-0685-0
[37]	Stam CJ, Tavy DL, Keunen RW (1993) Quantification of Alpha rhythm desynchronization using the acceleration spectrum entropy of the EEG. Clin Electroencephalogr 24: 104-109. doi: 10.1177/155005949302400306
[38]	Klimesch W (1999) Event-related band power changes and memory performance. Event-related desynchronization: handbook of electroencephalography and clinical neurophysiology Amsterdam: Elsevier, 161-178.
[39]	Babiloni C, Carducci F, Cincotti F, et al. (1999) Human movement-related potentials vs desynchronization of EEG alpha rhythm: a high-resolution EEG study. Neuroimage 10: 658-665. doi: 10.1006/nimg.1999.0504
[40]	Williamson SJ, Kaufman L, Lu ZL, et al. (1997) Study of human occipital Alpha rhythm: the Alphon hypothesis and Alpha suppression. Int J Psychophysiol 26: 63-76. doi: 10.1016/S0167-8760(97)00756-3
[41]	Yakovenko IA, Cheremushkin EA, Kozlov MK (2014) Changes in the Beta rhythm on acquisition of a set to an emotional facial expression with lengthening of the time interval between the Warning and Trigger stimuli. Neurosci Behav Physiol 44: 1031-1038. doi: 10.1007/s11055-014-0020-5
[42]	Sato W, Aoki S (2006) Right hemispheric dominance in processing of unconscious negative emotion. Brain Cogn 62: 261-266. doi: 10.1016/j.bandc.2006.06.006
[43]	Quandt LC, Marshall PJ, Bouquet CA, et al. (2013) Somatosensory experiences with action modulate alpha and beta power during subsequent action observation. Brain Res 1534: 55-65. doi: 10.1016/j.brainres.2013.08.043
[44]	Babiloni C, Brancucci A, Del Percio C, et al. (2006) Anticipatory electroencephalography Alpha rhythm predicts subjective perception of pain intensity. J Pain 7: 709-717. doi: 10.1016/j.jpain.2006.03.005
[45]	Gruzelier JH, Foks M, Steffert T, et al. (2014) Beneficial outcome from EEG-neurofeedback on creative music performance, attention and well-being in school children. Biol Psychol 95: 86-95. doi: 10.1016/j.biopsycho.2013.04.005

neurosci-07-02-011-s01.pdf

Reader Comments

Your name:*

Email:*
© 2020 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

AIMS Neuroscience

3.1 4.2

Metrics

Article views(7611) PDF downloads(513) Cited by(15)

Preview PDF

Download XML

Export Citation

Article outline

Show full outline

AIMS Neuroscience

Effects of EEG examination and ABA-therapy on resting-state EEG in children with low-functioning autism

Related Papers:

Abstract

1. Introduction

2. Preliminaries

3. Main results

acknowledgement

Conflict of interest

References

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Figures and Tables

Other Articles By Authors

Catalog

Abstract

1. Introduction

2. Preliminaries

3. Main results

acknowledgement

Conflict of interest

References

AIMS Neuroscience

Effects of EEG examination and ABA-therapy on resting-state EEG in children with low-functioning autism

Related Papers:

Abstract

1. Introduction

2. Preliminaries

3. Main results

acknowledgement

Conflict of interest

References

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Figures and Tables

Other Articles By Authors

Related pages

Tools

Export File

Citation

Format

Content

Catalog

Abstract

1. Introduction

2. Preliminaries

3. Main results

acknowledgement

Conflict of interest

References