Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators

Karthikeyan, Kulandhaivel; Karthikeyan, Panjaiyan; Patanarapeelert, Nichaphat; Sitthiwirattham, Thanin

doi:10.3390/axioms10040313

Open AccessArticle

Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators

by

Kulandhaivel Karthikeyan

¹

,

Panjaiyan Karthikeyan

²,

Nichaphat Patanarapeelert

^3,* and

Thanin Sitthiwirattham

^4,*

¹

Department of Mathematics & Centre for Research and Development, KPR Institute of Engineering and Technology, Coimbatore 641 407, India

²

PG and Research Department of Mathematics, Sri Vasavi College, Erode 638 136, India

³

Department of Mathematics, Faculty of Applied Science, King Mongkut’s University of Technology North Bangkok, Bangkok 10800, Thailand

⁴

Mathematics Department, Faculty of Science and Technology, Suan Dusit University, Bangkok 10300, Thailand

^*

Authors to whom correspondence should be addressed.

Axioms 2021, 10(4), 313; https://doi.org/10.3390/axioms10040313

Submission received: 24 September 2021 / Revised: 17 November 2021 / Accepted: 18 November 2021 / Published: 22 November 2021

(This article belongs to the Special Issue Advances in Nonlinear Boundary Value Problems: Theory and Applications)

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Abstract

:

In this manuscript, we establish the mild solutions for Hilfer fractional derivative integro-differential equations involving jump conditions and almost sectorial operator. For this purpose, we identify the suitable definition of a mild solution for this evolution equations and obtain the existence results. In addition, an application is also considered.

Keywords:

Hilfer fractional derivative; mild solutions; impulsive conditions; almost sectorial operators; measure of non-compactness

1. Introduction

Fractional differential equations are a type of mathematical equation that are used to describe the behaviour of a number of complicated and nonlocal systems with memory. Because of the fractional derivative’s effective memory function, it has been widely used to describe many physical phenomena, such as flow in porous media and fluid dynamic traffic models; more precisely, fractional differential equations have been widely used in engineering, physics, chemistry, biology, and other fields. One can refer to the references in [1,2,3,4,5,6].

The theory of impulsive differential equations describes the processes which experience a suddenly change of their state at certain moments. There has been notable developments in the field of impulsive theory, especially in the area of impulsive differential equations with fixed moments. In recent years, the mathematical models of phenomena in physical, engineering, and biomedical sciences focus on the impulsive differential equations. The condition (2) includes such a kind of dynamics.

In [7], Anjali et al. discussed the analysis of Hilfer fractional differential equations with almost sectorial operators, and Abdo et al. [8] proved the existence of soutions for Hilfer fractional differential equations with boundary conditions. Boundary value problems for Hilfer fractional differential inclusions with nonlocal integral boundary conditions is investigated by Wongcharoen et al. [9]. In [10], the authors Yong et al. discussed the multi point boundary value problem for Hilfer fractional differential equation at Resonance. For some recent works of the mild solution, see [11,12,13].

Motivated by the above-cited works, we consider the impulsive initial Hilfer fractional derivative integro-differential equations involving jump conditions with almost sectorial operator in Banach space

Y

of the following form:

\begin{matrix} D^{α, ν} ℘ (t) + A ℘ (t) = & E (t, ℘ (t), \int_{0}^{t} ς (t, s) ϑ (s, ℘ (s)) d s), t \in (0, T] = J \end{matrix}

(1)

\begin{matrix} {Δ ℘ |}_{t = t_{k}} = & I_{k} (℘ (t_{k}^{-})), k = 1, 2, 3, . . . m \end{matrix}

(2)

\begin{matrix} I_{0 +}^{(1 - α) (1 - ν)} ℘ (0) = & \sum_{k = 1}^{m} c_{k} ℘ (t_{k}), \end{matrix}

(3)

where

D_{0 +}^{α, ν}

is the Hilfer fractional derivative of order

α \in (0, 1)

and type

ν \in [0, 1]

.

A

is an almost sectorial operator in

Y

having norm

∥ \cdot ∥, E : J \times Y \times Y \to Y

is a function which is defined later, and

0 < t_{1} < t_{2} < \dots < t_{m} < b, m \in N,

and

c_{k}

are real numbers such that

c_{k} \neq 0

. For brevity, we will take the following:

\begin{matrix} B ℘ (t) = \int_{0}^{t} ς (t, s) ϑ (s, u (s)) d s . \end{matrix}

In [7], Anjali Jaiswal and Bahuguna studied the equations of the Hilfer fractional deritaive with almost sectorial operator in the abstract sense as follows:

\begin{matrix} D^{α, ν} (t) + A u (t) = & E (t, u (t)), t \in (o, T] \\ I_{0 +}^{(1 - α) (1 - ν)} u (0) = & u_{0} . \end{matrix}

We also refer to the work in [3], where Hamdy M. Ahmed et al. studied the existence for nonlinear Hilfer fractional derivative differential equations with control. Sufficient conditions were established where the time fractional derivative is the Hilfer derivative. In [14], Yong Zhoy et al. studied the factional Cauchy problems with almost sectorial operators of the following form:

\begin{matrix} D^{α} u (t) = & A x (t) + F (t, x (t)), t \in (0, T] \\ I_{0 +}^{(1 - α)} x (0) = & x_{0} \end{matrix}

where

D^{α}

is the Riemann–Liouville derivative of order

α

,

I^{(1 - α)}

is the Riemann–Liouville integral of order

1 - α

,

0 < α < 1

, A is an almost sectorial operator on a complex Banach space, and

F

is a given function.

The following sections describes the supporting results of the given problem and also generalize the results in [14].

2. Preliminaries

Definition 1

([15]). For

α > 0

, the fractional integral of order α of a function

f (t)

is defined by:

\begin{matrix} I_{0 +}^{α} f (t) = \frac{1}{Γ (α)} \int_{0}^{t} f (r) {(t - r)}^{α - 1} d r . \end{matrix}

Definition 2

([15]). For

0 < α < 1

, the Riemann–Liouville (R–L) fractional derivative with order α of a function

f (t)

is defined by the following:

\begin{matrix} D^{α} f (t) = \frac{1}{Γ (1 - α)} \frac{d}{d t} \int_{0}^{t} \frac{f (r)}{{(t - r)}^{α}} d r . \end{matrix}

Definition 3

([15]). For

0 < α < 1

, the Caputo fractional derivative with order α of a function

f (t)

is defined by the following:

\begin{matrix} ^{c} D^{α} f (t) = \frac{1}{Γ (1 - α)} \int_{0}^{t} \frac{f^{'} (r)}{{(t - r)}^{α}} d r . \end{matrix}

Definition 4

([16]). Let

0 < α < 1

and

0 \leq v \leq 1

. The Hilfer fractional derivative of order α and type v is defined by the following:

\begin{matrix} D_{0 +}^{α, v} u (t) = I_{0 +}^{v (1 - α)} \frac{d}{d t} I_{0 +}^{(1 - v) (1 - α)} u (t) . \end{matrix}

Measure of Non-compactness:

Let

L

⊂

Y

and be bounded. The Hausdorff measure of non-compactness

Φ

is defined by the following:

\begin{matrix} Ψ (L) = \inf \{ζ > 0 such that L \subset ⋃_{j = 1}^{m} B_{ζ} (x_{j}) where x_{j} \in Y, m \in N\} . \end{matrix}

(4)

The Kurtawoski measure of non-compactness

Φ

on a bounded set

B \subset Y

is defined by the following:

\begin{matrix} Φ (L) = \inf \{ϵ > 0 such that L \subset ⋃_{j = 1}^{m} M_{j} and diam (M_{j}) \leq ϵ\} \end{matrix}

(5)

with the following properties:

$L_{1} \subset L_{2}$ gives $Ψ (L_{1}) \leq Ψ (L_{2})$ where $L_{1}, L_{2}$ are bounded subsets of $Y$ ;
$Ψ (L) = 0$ iff $L$ is relatively compact in $Y$ ;
$Ψ ({z} ⋃ L) = Ψ (L)$ for all $z \in Y$ $L \subseteq Y$ ;
$Ψ (L_{1} ⋃ L_{2}) \leq \max {Ψ (L_{1}), Ψ (L_{2})}$ ;
$Ψ (L_{1} + L_{2}) \leq Ψ (L_{1}) + Ψ (L_{2})$ ;
$Ψ (r L) \leq | r | Ψ (L)$ for every $r \in R$ .

Let

W \subset C (I, Y)

and

W (r) = {υ (r) \in Y | υ \in W}

. We define

\begin{matrix} \int_{0}^{t} W (r) d r = \{\int_{0}^{t} υ (r) d r | υ \in W\}, for t \in J . \end{matrix}

Proposition 1

([17]). If

W \subset C (J, Y)

is equicontinuous and bounded, then

t \to Ψ (W (t))

is continuous on I and

\begin{matrix} Ψ (W) = \max Ψ (W (t)), Ψ (\int_{0}^{t} υ (r) d r) \leq \int_{0}^{t} Ψ (υ (r)) d r, for t \in I . \end{matrix}

Proposition 2

([18]). Let

{υ_{n} : I \to Y, n \in N}

be the Bochner integrable functions such that, for

n \in N, ∥ υ_{n} ∥ \leq m (t)

a.e

m \in L^{1} (I, R^{+})

. Then,

ξ (t) = Ψ ({υ_{n} (t)}_{n = 1}^{\infty}) \in L^{1} (I, R^{+})

and satisfies the following:

\begin{matrix} Ψ ({\int_{0}^{t} υ_{n} (r) d r : n \in N}) \leq 2 \int_{0}^{t} ξ (r) d r . \end{matrix}

Proposition 3

([19]). Let

W

be a bounded set. Then, for any

ζ > 0

, there exists a sequence

{υ_{n}}_{n = 1}^{\infty} \subset W

, such that:

\begin{matrix} Ψ (W) \leq 2 Ψ {υ_{n}}_{n = 1}^{\infty} + ζ . \end{matrix}

Almost Sectorial Operators:

Let

0 < μ < π

and

- 1 < β < 0

. We define

S_{μ}^{0} = {υ \in C \ {0} that is | a r g υ | < μ}

and its closure by

S_{μ}

, that is

S_{μ} = {υ \in C \ {0} | \arg υ | < μ} ⋃ {0}

.

Definition 5

([20]). For

- 1 < β < 0, 0 < ω < \frac{π}{2}

, we define

{⊙_{ω}^{β}}

as a family of all closed and linear operators

A : D (A) \subset X \to Y

this implies the following:

1.: $σ (A)$ is contained in the $S_{ω}$ ;
2.: For all $μ \in (ω, π),$ there exists $M_{μ}$ such that

$\begin{matrix} {∥ R (z, A) ∥}_{L (X)} \leq M_{μ} {| z |}^{β} \end{matrix}$

where $R (z, A) = {(z I - A)}^{- 1}$ is the resolvent operator of $A$ for $z \in ρ (A)$ and $A \in ⊙_{ω}^{β}$ is called an almost sectorial operator on X.

Proposition 4

([20]). Let

A \in ⊙_{ω}^{β}

for

- 1 < β < 0

and

0 < ω < \frac{π}{2}

. Then, the below properties are completed:

1.: $ℑ (t)$ is analytic and $\frac{d^{n}}{d t^{n}} ℑ (t) = (- A^{n} ℑ (t) (t \in S_{\frac{π}{2}}^{0})$ ;
2.: $ℑ (t + s) = ℑ (t) ℑ (s) \forall t, s \in S_{\frac{π}{2}}^{0}$ ;
3.: ${∥ ℑ (t) ∥}_{L (Y)} \leq C_{0} t^{- β - 1} (t > 0)$ ; where $C_{0} = C_{0} (β) > 0$ is a constant;
4.: Let $\sum_{ℑ} = {x \in Y : l i m_{t \to 0_{+}} ℑ (t) x = x}$ . Then $D (A^{θ}) \subset \sum_{ℑ}$ if $θ > 1 + β$ ;
5.: $R (r, - A) = \int_{0}^{\infty} e^{- r s} ℑ (s) d s$ for $r \in C$ with $R e (r) > 0$ .

We consider the following Wright-type function [15]:

\begin{matrix} M_{α} (θ) = \sum_{n \in N} \frac{{(- θ)}^{n - 1}}{Γ (1 - α n) (n - 1)!}, θ \in C . \end{matrix}

For

- 1 < σ < \infty, r > 0

, the following are satisfied:

(A1): $M_{α} (θ) \geq 0, t > 0$ ;
(A2): $\int_{0}^{\infty} θ^{σ} M_{α} d θ = \frac{Γ (1 + σ)}{Γ (1 + α σ)}$ ;
(A3): $\int_{0}^{\infty} \frac{α}{θ^{α + 1}} e^{- r θ} M_{α} (\frac{1}{θ^{α}}) d θ = e^{- r^{α}}$ .

Define the operator families

{S_{α} (t)} |_{t \in S_{\frac{π}{2} - w}^{0}}

and

{Q_{α} (t)} |_{t \in S_{\frac{π}{2} - w}^{0}}

as follows:

\begin{matrix} S_{α} (t) = \int_{0}^{\infty} M_{α} (ζ) ϱ (t^{α} ζ) d ζ \end{matrix}

\begin{matrix} Q_{α} (t) = \int_{0}^{\infty} α ζ M_{α} (ζ) ϱ (t^{α} ζ) d ζ . \end{matrix}

Theorem 1

(Theorem 4.6.1 [15]). For each fixed

t \in S_{\frac{π}{2} - ω}^{0}, S_{α} (t)

and

Q_{α} (t)

are bounded and linear operators on

Y

. In addition:

\begin{matrix} ∥ S_{α} (t) ∥ \leq C_{s} t^{- α (1 + β)}, ∥ Q_{α} (t) ∥ \leq C_{p} t^{- α (1 + β)}, t > 0 \end{matrix}

where

C_{s}

and

C_{p}

are constants.

Theorem 2

(Theorem 4.6.2 [15]).

S_{α} (t)

and

Q_{α} (t)

are continuous in the uniform operator topology for

t > 0

. Moreover, for every

s > 0

, the continuity is uniform on

[s, \infty]

.

For

T > 0

, we set

J = [0, T]

and

J^{'} = (0, T]

. We introduce

C (J, Y)

as the space of continuous functions from

J

to

Y

. Define

Y = {℘ \in C (J^{'}, Y) : {lim}_{t \to 0} t^{1 + α β (1 - v)} ℘ (t)

exists and is finite}

, and

{∥ ℘ ∥}_{Y} = \sup_{t \in J}^{'} {t^{1 + α β (1 - v)} ∥ ℘ (t) ∥}

.

Then,

Y

is a Banach space. Then:

(a): For $v = 1, Y = C (J, Y)$ and ${∥ ℘ ∥}_{Y} = \sup_{t \in J} ∥ ℘ (t) ∥$ ;
(b): For $v = {0, ∥ u ∥}_{Y} = \sup_{t \in J^{'}} ∥ t^{(1 + α β)} u (t) ∥$ ;
(c): Let $℘ (t) = t^{1 + α β (1 - ν)} y (t), t \in J^{'}$ . Then $℘ \in Y$ if and only if $y \in C (J, Y)$ and ${∥ ℘ ∥}_{Y} = ∥ y ∥$ .

We define

B_{r} (J) = {y \in C (J, Y) such that ∥ y ∥ \leq r}

and

B_{r}^{Y} (J^{'}) = {u \in Y such that ∥ ℘ ∥ \leq r}

.

We assume the following hypotheses to prove our results.

Hypothesis 1 (H1).

For each fixed

t \in J^{'}, E (t, ., .) : X \times Y \to Y

is a continuous function and for each

℘ \in C (J^{'}, Y), E (., ℘, B ℘) : J^{'} \to Y

is strongly measurable.

Hypothesis 2 (H2).

∃ a function

k \in L^{1} (J^{'}, R^{+})

satisfying the following:

\begin{matrix} I_{0 +}^{- α β} k \in C (J^{'}, R), \lim t^{(1 + α β) (1 - ν)} I_{0 +}^{- α β} k (t) = 0 . \end{matrix}

Hypothesis 3 (H3).

\begin{matrix} \sup_{[0, T]} (t^{(1 + α β) (1 - n u)} ∥ S_{α, ν (t) u_{0}} ∥ + t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{- α β - 1} k (r) d r) \leq r \end{matrix}

for a constant

r > 0

and

u_{0} \in D (A^{θ}), θ > 1 + β,

where

S_{α, ν (t)} = I_{0 +}^{ν (1 - α)} t^{- 1} Q_{α} (t)

.

Hypothesis 4 (H4).

∃ constants

γ_{k}

such that

∥ I_{k} (℘) ∥ \leq γ_{k}, k = 1, 2, \dots, m

for each

℘ \in Y

.

Definition 6.

By a mild solution of the Cauchy problem (1.1)–(1.3), we mean a function

℘ \in C (J^{'}, X)

that satisfies the following:

\begin{matrix} ℘ (t) = S_{α, ν} (t) \hat{v} + \int_{0}^{t} K_{α} (t - r) E (r, ℘ (r), (B ℘) r) d r + \sum_{0 < t_{k} < t} S_{α, ν} (t - t_{k}) I_{k} (℘ (t_{k}^{-})), t \in J^{'} \end{matrix}

(6)

where

\begin{matrix} \hat{v} = \sum_{k = 1}^{m} c_{k} ℘ (t_{k}), S_{α, ν} (t) = I_{0 +}^{ν (1 - α)} K_{α} (t), K_{α} = t^{α - 1} Q_{α} (t) . \end{matrix}

Now, we define an operator

P : B_{r} (J^{'}) \to B_{r} (J^{'})

as follows:

\begin{matrix} (P ℘) (t) = & S_{α, ν} (t) \hat{v} + \int_{0}^{t} {(t - r)}^{α - 1} Q_{α} (t - r) E (r, ℘ (r), (B ℘) r) d r \\ + \sum_{0 < t_{k} < t} S_{α, ν} (t - t_{k}) I_{k} (℘ (t_{k}^{-})) . \end{matrix}

(7)

Lemma 1 ([7]).

K_{α} (t)

and

S_{α, ν} (t)

are bounded linear operators on

Y

, for every fixed

t \in S_{\frac{π}{2} - ω}^{0}

. Furthermore for

t > 0

:

\begin{matrix} ∥ K_{α} (t) x ∥ \leq C_{p} t^{- 1 - α β} ∥ x ∥, ∥ S_{α, ν (t) x} ∥ \leq \frac{Γ (- α β)}{Γ (ν (1 - α) - α β)} C_{p} t^{ν (1 - α) - α β - 1} ∥ x ∥ . \end{matrix}

Proposition 5 ([7]).

K_{α} (t)

and

S_{α, ν (t)}

are strongly continuous, for

t > 0

.

Let

M_{s} = {sup}_{t \in J} ∥S_{α, ν (t)}∥

. Assume that

\sum_{c_{k}}^{m} \leq \frac{1}{M_{s}}

.

We have:

\begin{matrix} ∥\sum_{c_{k}}^{m} S_{α, ν} (t_{k})∥ \leq M_{s} . \frac{1}{M_{s}} < 1 . \end{matrix}

3. Main Results

Theorem 3.

Let

A \in ⊙_{ω}^{β}

for

- 1 < β < 0

and

0 < ω < \frac{π}{2}

. Assuming (H1)–(H4) are satisfied, the operators

{F y : y \in B_{r} (J)}

are equicontinuous provided

℘_{0} \in D (A^{θ})

with

θ > 1 + β

.

Proof.

For

y \in B_{r} (J)

and

t_{1} = 0 < t_{2} \leq T

, we gave the following:

\begin{matrix} ∥ F y (t_{2}) - F y (0) ∥ = & ∥ t_{2}^{(1 + α μ) (1 - ν)} (S_{α, ν (t_{2})} \hat{v} + \int_{0}^{t_{2}} {(t_{2} - r)}^{α - 1} Q_{α} (t_{2} - r) E (r, ℘ (r), (B ℘) r) d r \\ + \sum_{0 < t_{k} < t_{2}} S_{α, ν} (t_{2} - t_{k}) I_{k} (℘ (t_{k}^{-}))) ∥ \\ \leq ∥ t_{2}^{(1 + α μ) (1 - ν)} S_{α, ν (t_{2})} \hat{v} ∥ \\ + ∥ t_{2}^{(1 + α μ) (1 - ν)} \int_{0}^{t_{2}} {(t_{2} - r)}^{α - 1} Q_{α} (t_{2} - r) E (r, ℘ (r), (B ℘) r) d r ∥ \\ + ∥ t_{2}^{(1 + α μ) (1 - ν)} \sum_{0 < t_{k} < t_{2}} S_{α, ν} (t_{2} - t_{k}) I_{k} (℘ (t_{k}^{-})) ∥ \end{matrix}

\to 0,

as

t_{2} \to 0

.

Now, let

0 < t_{1} < t_{2} \leq T

:

\begin{matrix} ∥ F y (t_{2}) - F y (t_{1}) ∥ \leq & ∥ t_{2}^{(1 + α μ) (1 - ν)} S_{α, ν (t_{2})} \hat{v} - t_{1}^{(1 + α μ) (1 - v)} S_{α, ν (t_{1})} \hat{v} ∥ \\ + ∥ t_{2}^{(1 + α μ) (1 - v)} \int_{0}^{t_{2}} {(t_{2} - r)}^{α - 1} Q_{α} (t_{2} - r) E (r, ℘ (r), (B ℘) r) d r \\ - t_{1}^{(1 + α μ) (1 - ν)} \int_{0}^{t_{1}} {(t_{1} - r)}^{α - 1} Q_{α} (t_{1} - r) E (r, ℘ (r), (B ℘) r) d r ∥ \\ + ∥ t_{2}^{(1 + α μ) (1 - ν)} \sum_{0 < t_{k} < t_{2}} S_{α, ν} (t_{2} - t_{k}) I_{k} (℘ (t_{k}^{-})) \\ - t_{1}^{(1 + α μ) (1 - ν)} \sum_{0 < t_{k} < t_{1}} S_{α, ν} (t_{1} - t_{k}) I_{k} (℘ (t_{k}^{-})) ∥ . \end{matrix}

Here, using the triangle inequality, we have the following:

\begin{matrix} ∥ F y (t_{2}) - F y (t_{1}) ∥ \leq & ∥ t_{2}^{(1 + α μ) (1 - ν)} S_{α, ν (t_{2})} \hat{v} - t_{1}^{(1 + α μ) (1 - ν)} S_{α, ν (t_{1})} \hat{v} ∥ \\ + ∥ t_{2}^{(1 + α μ) (1 - ν)} \int_{t_{1}}^{t_{2}} {(t_{2} - r)}^{α - 1} Q_{α} (t_{2} - r) E (r, ℘ (r), (B ℘) r) d r ∥ \\ + ∥ t_{2}^{(1 + α μ) (1 - ν)} \int_{0}^{t_{1}} {(t_{2} - r)}^{α - 1} Q_{α} (t_{2} - r) E (r, ℘ (r), (B u) r) d r \\ - t_{1}^{(1 + α μ) (1 - ν)} \int_{0}^{t_{1}} {(t_{1} - r)}^{α - 1} Q_{α} (t_{2} - r) E (r, ℘ (r), (B ℘) r) d r ∥ \\ + ∥ t_{1}^{(1 + α μ) (1 - ν)} \int_{0}^{t_{1}} {(t_{1} - r)}^{α - 1} Q_{α} (t_{2} - r) E (r, ℘ (r), (B ℘) r) d r \\ - t_{1}^{(1 + α μ) (1 - ν)} \int_{0}^{t_{1}} {(t_{1} - r)}^{α - 1} Q_{α} (t_{1} - r) E (r, ℘ (r), (B ℘) r) d r ∥ \\ + ∥ t_{2}^{(1 + α μ) (1 - v)} \sum_{0 < t_{k} < t_{2}} S_{α, ν} (t_{2} - t_{k}) I_{k} (℘ (t_{k}^{-})) \\ - t_{1}^{(1 + α μ) (1 - ν)} \sum_{0 < t_{k} < t_{1}} S_{α, ν} (t_{1} - t_{k}) I_{k} (℘ (t_{k}^{-})) ∥ \\ = & I_{1} + I_{2} + I_{3} + I_{4} + I_{5} . \end{matrix}

By the strong continuity of

S_{α, ν} (t)

, we obtain

I_{1} \to 0

as

t_{2} \to t_{1}

. In addition:

\begin{matrix} I_{2} \leq & C_{p} t_{2}^{(1 + α β) (1 - ν)} \int_{t_{1}}^{t_{2}} {(t_{2} - r)}^{- α β - 1} κ (r) d r \\ \leq & C_{p} | t_{2}^{(1 + α β) (1 - ν)} \int_{0}^{t_{2}} {(t_{2} - r)}^{- α β - 1} κ (r) d r - t_{2}^{(1 + α β) (1 - ν)} \int_{0}^{t_{1}} {(t_{1} - r)}^{- α β - 1} κ (r) d r | \\ \leq & C_{p} \int_{0}^{t_{1}} | t_{1}^{(1 + α β) (1 - ν)} {(t_{1} - r)}^{- α β - 1} - t_{2}^{(1 + α β) (1 - ν)} {(t_{2} - r)}^{- α β - 1} | κ (r) d r . \end{matrix}

Then,

I_{2} \to 0

as

t_{2} \to t_{1}

, by using (H2) and the dominated convergence theorem. Since

\begin{matrix} I_{3} \leq C_{p} \int_{0}^{t_{1}} {(t_{2} - r)}^{- α - α β} | t_{2}^{(1 + α β) (1 - ν)} {(t_{2} - r)}^{α - 1} - t_{1}^{(1 + α β) (1 - ν)} {(t_{1} - r)}^{α - 1} | κ (r) d r \end{matrix}

and

\begin{matrix} {(t_{2} - r)}^{- α - α β} | t_{2}^{(1 + α β) (1 - ν)} {(t_{2} - r)}^{α - 1} - t_{1}^{(1 + α β) (1 - ν)} {(t_{1} - r)}^{α - 1} | κ (r) \end{matrix}

\begin{matrix} \leq & t_{2}^{(1 + α β) (1 - ν)} {(t_{2} - r)}^{α - 1} κ (r) + t_{1}^{(1 + α β) (1 - ν)} {(t_{1} - r)}^{α - 1} κ (r) \\ \leq & 2 t_{1}^{(1 + α β) (1 - ν)} {(t_{1} - r)}^{α - 1} κ (r) \end{matrix}

and

\int_{0}^{t_{1}} 2 t_{1}^{(1 + α β) (1 - ν)} {(t_{1} - r)}^{α - 1} κ (r)

exists, i.e.,

I_{3} \to 0

as

t_{2} \to t_{1}

.

For

ϵ > 0

, we have the following:

\begin{matrix} I_{4} = & ∥ \int_{0}^{t_{1}} t_{1}^{(1 + α β) (1 - ν)} [Q_{α} (t_{2} - r) - Q_{α} (t_{1} - r)] {(t_{1} - r)}^{α - 1} E (r, ℘ (r), (B ℘) r) d r ∥ \\ \leq & \int_{0}^{t_{1} - ϵ} t_{1}^{(1 + α β) (1 - ν)} ∥ Q_{α} (t_{2} - r) - Q_{α} (t_{1} - r) ∥_{L (X)} {(t_{1} - r)}^{α - 1} κ (r) \\ + \int_{t_{1}}^{t_{1}} t_{1}^{(1 + α β) (1 - ν)} ∥ Q_{α} (t_{2} - r) - Q_{α} (t_{1} - r) ∥_{L (X)} {(t_{1} - r)}^{α - 1} κ (r) \\ \leq & t_{1}^{(1 + α β) (1 - ν)} \int_{0}^{t_{1}} {(t_{1} - r)}^{α - 1} κ (r) d r \sup_{s \in [0, t_{1} - ϵ]} ∥ Q_{α} (t_{2} - r) - Q_{α} (t_{1} - r) ∥_{L (X)} \\ + C_{p} \int_{t_{1}}^{t_{1}} t_{1}^{(1 + α β) (1 - ν)} ({(t_{2} - r)}^{- α - α β} + {(t_{1} - r)}^{- α - α β}) {(t_{1} - r)}^{α - 1} κ (r) d r \\ \leq & t_{1}^{(1 + α β) (1 - ν) + α (1 + β)} \int_{0}^{t_{1}} {(t_{1} - r)}^{- α β - 1} κ (r) d r \sup_{s \in [0, t_{1} - ϵ]} ∥ Q_{α} (t_{2} - r) - Q_{α} (t_{1} - r) ∥_{L (X)} \\ + 2 C_{p} \int_{t_{1} - ϵ}^{t_{1}} t_{1}^{(1 + α β) (1 - ν)} {(t_{1} - r)}^{- α β - 1} κ (r) d r . \end{matrix}

Since

Q_{α} (t)

is uniformly continuous and

{lim}_{t_{2} \to t_{1}} I_{2} = 0

, then

I_{4} \to 0

as

t_{2} \to t_{1}

, i.e., independent of

y \in B_{r} (J)

.

Clearly, by the strong continuity of

S_{α, ν} (t)

, we obtain the following:

\begin{matrix} I_{5} = ∥ t_{2}^{(1 + α μ) (1 - v)} \sum_{0 < t_{k} < t_{2}} S_{α, ν} (t_{2} - t_{k}) I_{k} (℘ (t_{k}^{-})) \\ - t_{1}^{(1 + α μ) (1 - ν)} \sum_{0 < t_{k} < t_{1}} S_{α, ν} (t_{1} - t_{k}) I_{k} (℘ (t_{k}^{-})) ∥ \to 0 as t_{2} \to t_{1} . \end{matrix}

Hence,

∥ F y (t_{2}) - F y (t_{1}) ∥ \to 0

independently of

y \in B_{r} (J)

as

t_{2} \to t_{1}

; therefore,

{F y : y \in B_{r} (J)}

is equicontinuous. □

Theorem 4.

Let

- 1 < β < 0

and

0 < ω < \frac{π}{2}

and

A \in ⊙_{ω}^{β}

. Then, under Assumptions (H1)–(H3) the operator

{F y : y \in B_{r} (J)}

is continuous and bounded provided

℘_{0} \in D (A^{θ})

with

θ > 1 + β

.

Proof.

Firstly, we prove that

F

maps

B_{r} (J)

. Taking

y \in B_{r} (J)

and define

℘ (t) = t^{- (1 + α β) (1 - ν)} y (t)

, we have

℘ \in B_{r}^{Y} (J^{'})

. Let

t \in [0, T]

:

\begin{matrix} ∥ F ∥ \leq ∥ t^{(1 + α β) (1 - ν)} S_{α, ν} (t) \hat{v} ∥ + t^{(1 + α β) (1 - ν)} ∥ \int_{0}^{t} {(t - r)}^{α - 1} Q_{α} (t - r) E (r, ℘ (r), (B ℘) r) d r ∥ \end{matrix}

From (H2) and (H3), we obtain the following:

\begin{matrix} ∥ F y (t) ∥ \leq & t^{(1 + α β) (1 - ν)} ∥ S_{α, ν} (t) \hat{v} ∥ + t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{- α β - 1} κ (r) d r \\ \leq & \sup_{[0, T]} t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{- α β - 1} κ (r) d r \\ \leq & r . \end{matrix}

Hence,

∥ F y ∥ \leq r

, for any

y \in B_{r} (I)

.

Now, to verify

F

is continuous in

B_{r} (I)

, let

y_{n}

,

y \in B (I), n = 1, 2, \dots,

with

\lim_{n \to \infty} y_{n} = y

. Hence,

\lim_{n \to \infty} y_{n} (t) = y (t)

and

\lim_{n \to \infty} t^{- (1 + α β) (1 - v)} y_{n} (t) = t^{- (1 + α β) (1 - v)} y (t)

and

\lim_{n \to \infty} t^{- (1 + α β) (1 - ν)} y_{n} (t) = t^{- (1 + α β) (1 - ν)} y (t),

on

J^{'}

(H1) implies the following:

\begin{matrix} E (t, ℘_{n} (t), B (℘_{n} (t))) = & E (t, t^{- (1 + α β) (1 - ν)} y_{n} (t), t^{- (1 + α β) (1 - ν)} B (y_{n} (t))) \\ \to E (t, t^{- (1 + α β) (1 - ν)} y (t), t^{- (1 + α β) (1 - ν)} B (y (t))), \end{matrix}

as

n \to \infty

.

We use (H2) to obtain the inequality

{(t - r)}^{- α β - 1} | E (r, ℘_{n} (r), B (℘_{n} (r))) | \leq 2 {(t - r)}^{- (α β) (1 - ν)} κ (r)

, i.e.,

\begin{matrix} \int_{0}^{t} {(t - r)}^{- α β - 1} ∥ E (r, ℘_{n} (r), B (℘_{n} (r))) - E (r, ℘ (r), B (℘ (r)) ∥ d r \to 0, as n \to \infty . \end{matrix}

Let

t \in [0, T]

. Now:

\begin{matrix} ∥ F y_{n} (t) - F y (t) ∥ \leq t^{(1 + α β) (1 - ν)} ∥ \int_{0}^{t} {(t - r)}^{α - 1} Q_{α} (t - r) (E (r, ℘_{n} (r), B (℘_{n} (r)) - E (r, ℘ (r), B (℘ (r))) d r ∥ . \end{matrix}

Applying Theorem (1), we have the following:

\begin{matrix} ∥ F y_{n} (t) - F y (t) ∥ \leq C_{p} t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{- α β - 1} ∥ E (r, ℘_{n} (r), B (℘_{n} (r)) - E (r, ℘ (r), B (℘ (r)) ∥ d r \end{matrix}

\to 0

as

n \to \infty

.

that is,

F y_{n} \to F y

pointwise on

J

. In addition, Theorem (3) implies that

F y_{n} \to F y

uniformly on

J

as

n \to \infty

. Hence,

F

is continuous. □

4. $ℑ (t)$ Is Compact

We can assume that, for

t > 0

, the semigroup

T (t)

is compact on

Y

. Hence, the compactness of

Q_{α} (t)

is as follows:

Theorem 5.

Let

- 1 < β < 0, 0 < ω < \frac{π}{2}

and

A \in Θ_{ω}^{β}

. If

T (t) (t > 0)

is compact and (H1)–(H4) hold, then ∃ a mild solution of (1.1)–(1.3) in

B_{r}^{Y} (I^{'})

for every

℘_{0} \in D (A^{θ})

with

θ > 1 + β

.

Proof.

Since we have assumed

ℑ (t)

is compact, it gives the equicontinuity of

ℑ (t) (t > 0)

. Moreover, from Theorems (3) and (4), we know that

F : B_{r}^{Y} (J^{'}) \to B_{r}^{Y} (J^{'})

is continuous and bounded and

ε : B_{r} (J) \to B_{r} (J)

is bounded, continuous, and

{ε y : y \in B_{r} (J)}

equicontinuous. We can write

ϵ : B_{r} (J) \to B_{r} (J)

as follows:

\begin{matrix} (ϵ y) (t) = (ϵ^{1} y) (t) + (ϵ^{2} y) (t) \end{matrix}

where:

\begin{matrix} (ϵ^{1} y) (t) & = t^{(1 + α β) (1 - ν)} S_{α, ν} (t) ℘_{0} = t^{1 + α β) (1 - ν)} I_{0 +}^{ν (1 - α)} t^{α - 1} Q_{α} (t) \bar{v} \\ = \frac{t^{(1 + α β) (1 - ν)}}{Γ (ν (1 - α))} \int_{0}^{t} {(t - r)}^{ν (1 - α) - 1} r^{α - 1} \int_{0}^{\infty} α θ M_{α} (θ) ℑ (r^{α} θ) \bar{v} d θ d r \\ = \frac{α t^{(1 + α β) (1 - ν)}}{Γ (ν (1 - α))} \int_{0}^{t} \int_{0}^{\infty} {(t - r)}^{ν (1 - α) - 1} r^{α - 1} θ M_{α} (θ) ℑ (r^{α} θ) \bar{v} d θ d r \end{matrix}

and

\begin{matrix} (ε^{2} y) (t) = & t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{α - 1} Q_{α} (t - r) E (r, ℘ (r) (B ℘) r) d r \\ + \sum_{0 < t_{k} < t} S_{α, ν} (t - t_{k}) I_{k} (℘ (t_{k}^{-})) . \end{matrix}

For

σ > 0

and

ζ \in (0, t)

, we define an operator

ε_{ζ, σ}^{1}

on

B_{r} (J)

by

\begin{matrix} (ε_{ζ, σ}^{1} y) (t) & = \frac{t^{(1 + α β) (1 - ν)}}{Γ (ν (1 - α))} \int_{ζ}^{t} \int_{σ}^{\infty} {(t - r)}^{(1 - α) ν - 1} r^{α - 1} θ M_{α} (θ) ℑ (r^{α} θ) \bar{v} d θ d r \\ = \frac{α t^{(1 + α β) (1 - ν)}}{Γ (ν (1 - α))} T (ζ^{α} σ) \int_{ζ}^{t} \int_{σ}^{\infty} {(t - r)}^{(1 - α) ν - 1} r^{α - 1} θ M_{α} (θ) ℑ (r^{α} θ - ζ^{α} σ) \bar{v} d θ d r . \end{matrix}

Since

T (ϵ^{α} δ)

is compact

V_{ζ, σ}^{1} (t) = {ε_{ζ, σ}^{1} y) (t), y \in B_{r} (J)}

is precompact in

X \forall ζ \in (0, t)

and

δ > 0

. Moreover, for any

y \in B_{r} (J)

\begin{matrix} ∥ (ε^{1} y) (t) - (ε_{ζ, σ}^{1} y) (t) ∥ & \leq K (α, ν) ∥ t^{(1 + α β) (1 - ν)} \int_{0}^{t} \int_{0}^{σ} {(t - r)}^{ν (1 - α) - 1} r^{α - 1} θ M_{α} (θ) ℑ (r^{α} θ) \bar{v} d θ d r ∥ \\ + K (α, ν) ∥ t^{(1 + α β) (1 - ν)} \int_{0}^{ζ} \int_{σ}^{\infty} {(t - r)}^{ν (1 - α) - 1} r^{α - 1} θ M_{α} (θ) ℑ (r^{α} θ) \bar{v} d θ d r ∥ \\ \leq K (α, ν) t^{(1 + α β) (1 - ν)} \int_{0}^{t} \int_{0}^{σ} {(t - r)}^{ν (1 - α) - 1} r^{α - 1} θ M_{α} (θ) r^{- α γ - α} ∥ \bar{v} ∥ θ^{- β - 1} d θ d r \\ + K (α, ν) t^{(1 + α β) (1 - ν)} \int_{0}^{ζ} \int_{σ}^{\infty} {(t - r)}^{ν (1 - α) - 1} r^{α - 1} θ M_{α} (θ) r^{- α β - α} θ^{- β - 1} ∥ \bar{v} ∥ d θ d r \\ = K (α, ν) t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{ν (1 - α) - 1} r^{- α β - 1} ∥ \bar{v} ∥ d r \int_{0}^{σ} θ^{- β} M_{α} (θ) d θ \\ + K (α, ν) t^{(1 + α β) (1 - ν)} \int_{0}^{ζ} {(t - r)}^{ν (1 - α) - 1} r^{- α β - 1} ∥ \bar{v} ∥ d r \int_{η}^{\infty} θ^{- β} M_{α} (θ) d θ \\ \leq K t^{- α ν (1 + β)} ∥ \bar{v} ∥ \int_{0}^{η} θ^{- β} M_{α} (θ) d θ \\ + K t^{- α ν (1 + β)} ∥ \bar{v} ∥ \int_{0}^{ζ} {(1 - s)}^{ν (1 - α) - 1} r^{- α β - 1} d r \int_{η}^{\infty} θ^{- β} M_{α} (θ) d θ, \\ \to 0, as ζ \to 0, σ \to 0, \end{matrix}

where,

K (α, ν) = \frac{α}{Γ (ν (1 - α))}

.

Therefore,

V_{ζ, σ}^{1} (t) = {ε_{ζ, σ}^{1} y) (t), y \in B_{r} (J)}

are arbitrarily close to

V^{1} (t) = {ε^{1} y) (t), y \in B_{r} (I)}

, for

t > 0

. Hence,

V^{1} (t)

, for

t > 0

, is precompact in

Y

.

For

ζ \in (0, t)

and

σ > 0

, we can present an operator

ε_{ζ, σ}^{2}

on

B_{r} (I)

by

\begin{matrix} (ε_{ζ, σ}^{2} y) (t) = & α t^{(1 + α β) (1 - ν)} \int_{0}^{t - ζ} \int_{σ}^{\infty} θ M_{α} (θ) {(t - r)}^{α - 1} ℑ ({(t - r)}^{α} θ) E (r, ℘ (r), (B ℘) r) d θ d r \\ + \sum_{0 < t_{k} < t} S_{α, v} (t - t_{k}) I_{k} (℘ (t_{k}^{-})) \\ = & α t^{(1 + α β) (1 - ν)} T (ζ^{α} σ) \int_{0}^{t - ζ} \int_{σ}^{\infty} θ M_{α} (θ) {(t - r)}^{α - 1} ℑ ({(t - r)}^{α} θ - ζ^{α} σ) E (r, ℘ (r), (B ℘) r) d θ d r \\ + \sum_{0 < t_{k} < t} S_{α, ν} (t - t_{k}) I_{k} (℘ (t_{k}^{-})) . \end{matrix}

Hence,

V_{ζ, σ}^{2} (t) = {ε_{ζ, σ}^{2} y) (t), y \in B_{r} (J)}

is precompact in

X \forall ζ \in (0, t)

and

σ > 0

due to the compactness of

ℑ (ζ^{α} σ)

. For every

y \in B_{r} (J)

, we obtain the following:

\begin{matrix} ∥ (ε^{2} y) (t) - (ε_{ζ, σ}^{2} y) (t) ∥ \leq & ∥ α t^{(1 + α β) (1 - ν)} (\int_{0}^{t} \int_{0}^{σ} θ M α (θ) {(t - r)}^{α - 1} ℑ ({(t - r)}^{α} θ) E (r, ℘ (r), (B ℘) r) d θ d r \\ + \sum_{0 < t_{k} < t} S_{α, ν} (t + σ - t_{k}) I_{k} (℘ (t_{k}^{-}))) ∥ \\ + ∥ α t^{(1 + α β) (1 - ν)} (\int_{t - ζ}^{t} \int_{σ}^{\infty} {(t - r)}^{α - 1} θ M_{α} (θ) ℑ ({(t - r)}^{α} θ) E (r, ℘ (r), (B ℘) r) d θ d r \\ + \sum_{0 < t_{k} < t} S_{α, ν} (t + ζ - t_{k}) I_{k} (℘ (t_{k}^{-}))) ∥ \\ \leq & α C_{0} t^{(1 + α β) (1 - ν)} (\int_{0}^{t} {(t - r)}^{- α β - 1} k (r) d r \int_{0}^{σ} θ^{- β} M_{α} (θ) d θ + \sum_{0 < t_{k} < σ} γ_{k}) \\ + α C_{0} t^{(1 + α β) (1 - ν)} (\int_{t - ζ}^{t} {(t - r)}^{- α β - 1} k (r) d r \int_{0}^{\infty} θ^{- β} M_{α} (θ) d θ + \sum_{0 < t_{k} < ζ} γ_{k}) \\ \leq & α C_{0} t^{(1 + α β) (1 - ν)} (\int_{0}^{t} {(t - r)}^{- α β - 1} k (r) d r \int_{0}^{σ} θ^{- β} M_{α} (θ) d θ + \sum_{0 < t_{k} < η} γ_{k}) \\ + \frac{α C_{0} Γ (1 - β)}{Γ (1 - α β)} t^{(1 + α β) (1 - ν)} (\int_{t - ζ}^{t} {(t - r)}^{- α β - 1} k (r) d r + \sum_{0 < t_{k} < ζ} γ_{k}) \\ \to 0 as σ \to 0 . \end{matrix}

Therefore,

V_{ζ, σ}^{2} (t) = {ε_{ζ, σ}^{2} y) (t), y \in B_{r} (J)}

are arbitrarily close to

V^{2} (t) = {ε^{2} y) (t), y \in B_{r} (J)}, t > 0

. This gives the relative compactness of

V^{2} (t), t > 0

in

Y

. Moreover,

V (t) = {ε y) (t), y \in B_{r} (J)}

is relatively compact in

Y \forall t \in [0, T]

. Hence,

{ε y, y \in B_{r} (J)}

is relatively compact by using the Arzela–Ascoli Theorem.

Now

ε

is continuous and

{ε y, y \in B_{r} (J)}

is relatively compact. Hence, by the Schauder fixed point theorem, ∃ a fixed point

y^{*} \in B_{r} (J)

of

ε

. Let

℘^{*} (t) = t^{(1 + α β) (ν - 1)} y^{*} (t)

. Then,

℘^{*}

is a mild solution of (1.1)–(1.3). □

5. $ℑ (t)$ Is Noncompact

We consider as follows,

Hypothesis 5 (H5).

∃ a constant

k > 0

satisfying the following

\begin{matrix} ψ (E (t, E_{1}, E_{2})) \leq k ψ (E_{1}, E_{2}) for a . e t \in [0, T] \end{matrix}

for every bounded subset

E_{1}, E_{2} \subset Y

.

Theorem 6.

Let

- 1 < β < 0, 0 < ω < \frac{π}{2}

and

A \in Θ_{ω}^{β}

. Assume that (H1)–(H5) hold. Then the Cauchy problem (1.1)–(1.3) has a mild solution in

B_{r}^{Y} (I^{'})

for every

u_{0} \in D (E^{θ})

with

θ > 1 + β

.

Proof.

By Theorems (3) and (4), we obtain

ε : B_{r} (I) \to B_{r} (I)

as continuous, boundedm and

{ε y : y \in B_{r} (I)}

is equicontinuous. Now, we verify that there is a subset of

B_{r} (I)

such that

ε

is compact in it.

For any bounded set

P_{0} \subset B_{r} (I)

, set the following:

\begin{matrix} ε^{(1)} (P_{0}) = ε (P_{0}), ε^{(n)} (P_{0}) = ε (\bar{c o} (ε^{(n - 1)} (P_{0}))), n = 2, 3, \dots \end{matrix}

For any

ϵ > 0

, we can obtain from Propositions (1)–(3), a subsequence

{y_{n}^{(1)}}_{n = 1}^{\infty} \subset P_{0}

satisfying:

\begin{matrix} ψ (ε^{(1)} (P_{0} (t))) \leq & 2 ψ (t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{α - 1} Q_{α} (t - r) E (r, {r^{- (1 + α β) (1 - ν)} (y_{n}^{(1)} (r), B y_{n}^{(1)} (r))}_{n = 1}^{\infty}) d r \\ + \sum_{0 < t_{k} < t} γ_{k}) \\ \leq & 4 C_{p} t^{(1 + α β) (1 - ν)} (\int_{0}^{t} {(t - r)}^{- α β - 1} ψ (E (r, {r^{- (1 + α β) (1 - ν)} (y_{n}^{(1)} (r), B y_{n}^{(1)} (r))}_{n = 1}^{\infty})) d r \\ + \sum_{0 < t_{k} < t} γ_{k}) \\ \leq & 4 C_{p} k t^{(1 + α β) (1 - ν)} ψ (P_{0}) (\int_{0}^{t} {(t - r)}^{- α β - 1} r^{- (1 + α β) (1 - ν)} d r \\ + \sum_{0 < t_{k} < t} γ_{k}) \\ = 4 C_{p} k t^{- α β} ψ (P_{0}) (\frac{Γ (- α β) Γ ((- α β + ν (1 + α β))}{Γ (- 2 α β + ν (1 + α β))} + \sum_{0 < t_{k} < t} γ_{k}) . \end{matrix}

From

ϵ

is arbitrary, we obtain the following:

\begin{matrix} ψ (ε^{(1)} (P_{0} (t))) \leq 4 C_{p} k t^{- α β} ψ (P_{0}) (\frac{Γ (- α β) Γ ((- α β + ν (1 + α β))}{Γ (- 2 α β + ν (1 + α β))} + \sum_{0 < t_{k} < t} γ_{k}) . \end{matrix}

Again, for any

ϵ > 0

, we can obtain from Propositions (1)–(3) a subsequence

{y_{n}^{(2)}, B y_{n}^{(2)}}_{n = 1}^{\infty} \subset \bar{c o} (ε^{(1)} (P_{0}))

that implies the following:

\begin{matrix} ψ (ε^{(2)} (P_{0} (t))) & = ψ (ε (\bar{c o} (ε^{(1)} (P_{0} (t))))) \\ \leq 2 ψ (t^{(1 + α β) (1 - ν)} \int_{0}^{t} {(t - r)}^{α - 1} Q_{α} (t - r) E (r, {r^{- (1 + α β) (1 - ν)} (y_{n}^{(2)} (r), B y_{n}^{(2)} (r))}_{n = 1}^{\infty}) d r \\ + \sum_{0 < t_{k} < t} γ_{k}) \\ \leq 4 C_{p} t^{(1 + α β) (1 - ν)} (\int_{0}^{t} {(t - r)}^{- α β - 1} ψ (E (r, {r^{- (1 + α β) (1 - ν)} (y_{n}^{(2)} (r), B y_{n}^{(2)} (r))}_{n = 1}^{\infty}) d r \\ + \sum_{0 < t_{k} < t} γ_{k}) \\ \leq 4 C_{p} k t^{(1 + α β) (1 - ν)} (\int_{0}^{t} {(t - r)}^{- α β - 1} ψ (r^{- (1 + α β) (1 - ν)} ({y_{n}^{(2)} (r), B y_{n}^{(2)} (r)}_{n = 1}^{\infty})) d r \\ + \sum_{0 < t_{k} < t} γ_{k}) \\ \leq 4 C_{p} k t^{(1 + α β) (1 - ν)} (\int_{0}^{t} {(t - r)}^{- α β - 1} r^{- (1 + α β) (1 - ν)} ψ ({y_{n}^{(2)} (r), B y_{n}^{(2)}}_{n = 1}^{\infty}) d r + \sum_{0 < t_{k} < t} γ_{k}) \\ \leq \frac{{(4 C_{p} k)}^{2} t^{(1 + α β) (1 - ν)} Γ (- α β) Γ (- α β + ν (1 + α β))}{Γ (- 2 α β + ν (1 + α β))} ψ (P_{0}) \\ \times (\int_{0}^{t} {(t - r)}^{- α β - 1} r^{- (1 + α β) (1 - ν) - α β} d r + \sum_{0 < t_{k} < t} γ_{k}) \\ = (\frac{{(4 C_{p} k)}^{2} t^{- 2 α β} Γ^{2} (- α β) Γ (- α β + ν (1 + α β))}{Γ (- 3 α β + ν (1 + α β))} + \sum_{0 < t_{k} < t} γ_{k}) ψ (P_{0}) . \end{matrix}

We can verify the following by the mathematical induction:

\begin{matrix} ψ (ε^{(n)} (P_{0} (t))) \leq \frac{{(4 C_{p} k)}^{n} t^{- n α β} Γ^{n} (- α β) Γ (- α β + ν (1 + α β))}{Γ (- (n + 1) α β + ν (1 + α β))} ψ (P_{0}), n \in N . \end{matrix}

Let

M = 4 C_{p} k T^{- α β} Γ (- α β)

. We can find

m, k \in N

big enough such that

\frac{1}{k} < α β < \frac{1}{k - 1}

and

\frac{n + 1}{k} > 2

for

n > m . Γ (- (n + 1) α β + ν (1 + α β)) > Γ (\frac{n + 1}{k})

. That is:

\begin{matrix} \frac{{(4 C_{p} k)}^{n} T^{- n α β} Γ^{n} (- α β) Γ (- α β + ν (1 + α β))}{Γ (- (n + 1) α β + ν (1 + α β))} < \frac{{(4 C_{p} k)}^{n} T^{- n α β} Γ^{n} (- α β) Γ (- α β + ν (1 + α β))}{Γ (\frac{n + 1}{k})} . \end{matrix}

Replace

(n + 1)

by

(j + 1) k

. Then, the R.H.S of the inequality given above becomes the following:

\begin{matrix} \frac{M^{(j + 1) k - 1} Γ (- α β + ν (1 + α β))}{Γ (j + 1)} = \frac{{(M^{k})}^{j} M^{k - 1} Γ (- α β + ν (1 + α β))}{j!} \to 0 as j \to \infty . \end{matrix}

Therefore, there exists a constant

n_{0} \in N

such that

\begin{matrix} \frac{(4 C_{p} k^{n} t^{- n α β} Γ^{n} (- α β) Γ (- α β + ν (1 + α β)}{Γ (- (n + 1) α β + ν (1 + α β))} \leq & \frac{{(4 C_{p} k)}^{n_{0}} T^{- n_{0} α β} Γ^{n_{0}} (- α β) Γ (- α β + ν (1 + α β))}{Γ (- (n_{0} + 1) α β + ν (1 + α β))} \\ = & p < 1 . \end{matrix}

Now:

\begin{matrix} ψ (ε^{(n_{0})} (P_{0} (t))) \leq p ψ (P_{0}) . \end{matrix}

From

ε^{(n_{0})} (P_{0} (t))

is bounded and equicontinuous, applying Proposition (1), we obtain the following:

\begin{matrix} ψ (ε^{(n_{0})} (P_{0})) = max_{t \in [0, T]} ψ (ε^{n_{0}} (P_{0} (t))) . \end{matrix}

Hence:

\begin{matrix} ψ (ε^{n_{0}} (P_{0})) \leq p ψ (P_{0}), \end{matrix}

where

p < 1

. Now applying a similar technique as applied in Theorem 4.2 [14], we obtain a nonempty, convex, and compact subset

C

in

B_{r} (J)

with

ε (C) \subset C

and

ε (C)

is compact. By applying the Schauder fixed point theorem, we obtain a fixed point

y^{*}

in

B_{r} (J)

of

ε

. Let

℘^{*} (t) = t^{(1 + α β) (ν - 1)} y^{*} (t)

. Then,

℘^{*} (t)

is a mild solution of (1.1)–(1.3). □

6. Example

We consider the following impulsive system:

\begin{matrix} D_{0 +}^{α, ν} ℘ (t, x) - \partial_{x}^{2} ℘ (t, x) = & E (t, ℘ (t, x), B ℘ (t, x)) t \in [0, T], x \in [0, a] \\ ℘ (t, 0) = ℘ (t, a) = & 0 on t \in [0, T] \\ I_{0 +}^{(1 - α) (1 - ν)} ℘ (0, x) = & \sum_{k = 1}^{m} c_{k} ℘ (t_{k}, x), x \in [0, a] \\ {Δ ℘ |}_{t = 1 / 2} = & I_{1} (℘ ({\frac{1}{2}}^{-})), \end{matrix}

(8)

in Banach space

Y = C^{α} ([0, a]) (0 < α < 1)

of all Holder continuous functions, where

α = \frac{1}{4}, ν = \frac{1}{2}, E (t, ℘, B ℘) = t^{- \frac{1}{5}} \cos^{2} ℘

,

c_{k} \in R, k = 1, 2, . . ., m

, such that

\sum_{k = 1}^{m} |c_{k}| < \frac{1}{M_{s}}

. Here, we can convert the above problem (1.1–1.3) in abstract form as follows:

\begin{matrix} D^{α, ν} ℘ (t) + A ℘ (t) = & E (t, ℘ (t), \int_{0}^{t} ς (t, s) ϑ (s, ℘ (s)) d s) t \in (0, T] = J \\ {Δ ℘ |}_{t = t_{k}} = & I_{k} (℘ (t_{k}^{-})), k = 1, 2, 3, . . . m \\ I_{0 +}^{(1 - α) (1 - ν)} ℘ (0) = & \sum_{k = 1}^{m} c_{k} ℘ (t_{k}, x) . \end{matrix}

(9)

Here,

A = - \partial_{x}^{2}

with

D (A) = {℘ \in C^{2 + α} ([0, a]) such that ℘ (t, 0) = 0 = ℘ (t, a)}

. It follows from the work in [20]∃ constants

δ, ϵ > 0

, such that

A + δ \in ⊙_{\frac{π}{2} - ϵ}^{\frac{π}{2} - 1} (Y)

. To verify the compactness of semigroup

ℑ (t)

, it is enough to prove that

R (α, - (A + δ)

is compact for every

α > 0

(see Lemma 4.66 [15]). Since

D (A \subset C^{2 + α} ([0, a]))

and

C^{2 + α} ([0, a])

are compactly embedded in

C^{α} ([0, a])

, the compactness of the resolvent operator follows for every

α > 0

. We choose

l (t) = t^{- \frac{1}{5}}

:

\begin{matrix} r = \sup_{[0, T]} (t^{(1 + α β) (1 - ν)} ∥ S_{α, ν} (t) u_{0} ∥) + \frac{T^{\frac{17}{20} Γ (- \frac{β}{4}) Γ (\frac{4}{5})}}{Γ (\frac{4}{5} - \frac{β}{4})} . \end{matrix}

Then, the Hypotheses (H1)–(H5) are satisfied. According to Theorem 5, the Problem (6.1) has a mild solution in

B_{r}^{Y} ((0, T])

.

7. Conclusions

In this paper, we proved the mild solutions of Hilfer fractional integro-differential equation with impulsive almost sectorial operator, by applying the fixed point theory. We will find to investigate stability of similar problem in our future research work.

Author Contributions

Conceptualization, K.K., P.K., N.P. and T.S.; methodology, K.K., P.K., N.P. and T.S.; formal analysis, K.K., P.K., N.P. and T.S.; funding acquisition, N.P. and T.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by King Mongkut’s University of Technology North Bangkok. Contract no.KMUTNB-63-KNOW-20.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors would like to express their gratitude to anonymous referees for very helpful suggestions and comments which led to improvements of our original manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

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Karthikeyan, K.; Karthikeyan, P.; Patanarapeelert, N.; Sitthiwirattham, T. Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators. Axioms 2021, 10, 313. https://doi.org/10.3390/axioms10040313

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Karthikeyan K, Karthikeyan P, Patanarapeelert N, Sitthiwirattham T. Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators. Axioms. 2021; 10(4):313. https://doi.org/10.3390/axioms10040313

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Karthikeyan, Kulandhaivel, Panjaiyan Karthikeyan, Nichaphat Patanarapeelert, and Thanin Sitthiwirattham. 2021. "Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators" Axioms 10, no. 4: 313. https://doi.org/10.3390/axioms10040313

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Karthikeyan, K., Karthikeyan, P., Patanarapeelert, N., & Sitthiwirattham, T. (2021). Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators. Axioms, 10(4), 313. https://doi.org/10.3390/axioms10040313

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Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators

Abstract

1. Introduction

2. Preliminaries

3. Main Results

4. $ℑ (t)$ Is Compact

5. $ℑ (t)$ Is Noncompact

6. Example

7. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

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Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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Mild Solutions for Impulsive Integro-Differential Equations Involving Hilfer Fractional Derivative with almost Sectorial Operators

Abstract

1. Introduction

2. Preliminaries

3. Main Results

4. ℑ ( t ) Is Compact

5. ℑ ( t ) Is Noncompact

6. Example

7. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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4. $ℑ (t)$ Is Compact

5. $ℑ (t)$ Is Noncompact