Author:
Rao Sabbavarapu Nageswara,Khuddush Mahammad,Msmali Ahmed Hussein,Ahmadini Abdullah Ali H.
Abstract
AbstractThis paper deals with the existence results of the infinite system of tempered fractional BVPs $$\begin{aligned}& {}^{\mathtt{R}}_{0}\mathrm{D}_{\mathrm{r}}^{\varrho , \uplambda} \mathtt{z}_{\mathtt{j}}(\mathrm{r})+\psi _{\mathtt{j}}\bigl(\mathrm{r}, \mathtt{z}(\mathrm{r})\bigr)=0,\quad 0< \mathrm{r}< 1, \\& \mathtt{z}_{\mathtt{j}}(0)=0,\qquad {}^{\mathtt{R}}_{0} \mathrm{D}_{ \mathrm{r}}^{\mathtt{m}, \uplambda} \mathtt{z}_{\mathtt{j}}(0)=0, \\& \mathtt{b}_{1} \mathtt{z}_{\mathtt{j}}(1)+\mathtt{b}_{2} {}^{ \mathtt{R}}_{0}\mathrm{D}_{\mathrm{r}}^{\mathtt{m}, \uplambda} \mathtt{z}_{\mathtt{j}}(1)=0, \end{aligned}$$
D
r
ϱ
,
λ
0
R
z
j
(
r
)
+
ψ
j
(
r
,
z
(
r
)
)
=
0
,
0
<
r
<
1
,
z
j
(
0
)
=
0
,
0
R
D
r
m
,
λ
z
j
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=
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b
1
z
j
(
1
)
+
b
2
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D
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m
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λ
z
j
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,
where $\mathtt{j}\in \mathbb{N}$
j
∈
N
, $2<\varrho \le 3$
2
<
ϱ
≤
3
, $1<\mathtt{m}\le 2$
1
<
m
≤
2
, by utilizing the Hausdorff measure of noncompactness and Meir–Keeler fixed point theorem in a tempered sequence space.
Publisher
Springer Science and Business Media LLC
Subject
Algebra and Number Theory,Analysis
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