Space-time fractional foam drainage equation

,
)
1
(
)
1
(
),
(
)
,
(













ct
kx
V
t
x
V
(42) 
where
 k
and 
c
are constants in eq. (41), Eq. (41) can be transformed as 
,
0
2
2
1
2
2
2
2









V
k
V
kV
V
V
k
V
c
(43) 
According to the balancing principle, the solution of (43) can be written as
)
(
1
0
)
(






e
A
A
V
(44) 
where 
1
0
,
A
A
are constants to be determined later and
)
(


satisfies the nonlinear ODE (7). 
By substituting eq. (44) into eq. (43) and using (7) commonly, the left-hand side of eq. (43) 
becomes a polynomial in
)
(



e
. Collecting the coefficients of this polynomial to zero yields a 
system of algebraic equations in terms of 
c
r
q
p
k
A
A
,
,
,
,
,
,
1
0
. The algebraic equations are 
overlooked for convenience. Solving the resulting algebraic equations with aid of symbolic 
computation, such as Maple, one get 












2
3
3
1
0
4
1
,
,
,
2
r
k
pq
k
c
k
k
kp
A
r
k
A
(45) 
where 
k, 
q
p
,
and 
r
are arbitrary constants. 
By combining the equations (9), (42), (44) and (45), the space-time fractional foam drainage 
equation (41) has the following traveling wave solutions: 
For Type 1: 
,
0
4
,
0
,
))
(
4
5
.
0
tanh(
4
2
2
)
,
(
2
0
2
2
1

















q
r
q
r
q
r
q
r
q
k
r
k
t
x
V


(46) 
,
0
4
,
0
,
))
(
4
5
.
0
tan(
4
2
2
)
,
(
2
0
2
2
2

















q
r
q
r
r
q
r
q
q
k
r
k
t
x
V


(47) 
,
0
4
,
0
,
1
))
(
exp(
2
)
,
(
2
0
3













q
r
q
r
r
k
r
k
t
x
V


(48) 
,
0
4
,
0
,
0
,
4
))
(
2
)
(
2
)
,
(
2
0
0
2
4















q
r
r
q
r
r
k
r
k
t
x
V




(49) 

where, 





t
r
k
q
k
kx
)
1
(
4
4
)
1
(
2
3
3








.
For Type 2: 
,
0
,
0
,
)
1
(
)
1
(
tan
)
,
(
0
3
5

























q
p
t
pq
k
kx
pq
pq
k
t
x
V





(50) 
,
0
,
0
,
)
1
(
)
1
(
cot
)
,
(
0
3
6
























q
p
t
pq
k
kx
pq
pq
k
t
x
V





(51) 
0
,
0
,
)
1
(
)
1
(
tanh
)
,
(
0
3
7



























q
p
t
pq
k
kx
pq
pq
k
t
x
V





,
(52) 
,
0
,
0
,
)
1
(
)
1
(
coth
)
,
(
0
3
8



























q
p
t
pq
k
kx
pq
pq
k
t
x
V





(53) 
For Type 3: 
,
0
,
0
,
)
1
(
4
4
)
1
(
)
,
(
1
0
2
3
3
9


















r
q
t
r
k
q
k
kx
k
t
x
V





(54) 
3.4 Time fractional fifth order Sawada-Kotera (SK) equation 
Finally, to illustrate more applicability of this proposed method, the following time fractional SK 
equation is considered:
.
1
0
,
0
5
5
5
5
5
3
3
2
2
2






















x
U
x
U
U
x
U
x
U
x
U
U
t
U
(55) 
The time fractional equation (55) appeared as a model equation in many physical instances that 
propagates in opposite directions. To obtain the analytical solutions of Eq. (55), one can 
introduce the following fractional complex transformation: 
],
)
1
(
[
),
(
)
,
(









t
c
x
k
w
t
x
U
(56) 
where
k
and 
c
are constants to be evaluated later. According to the transformation (55), one can 
be obtained to the following nonlinear ODE: 

.
0
)
(
5
)
(
3
5
5
5
5
2
2
3
3










d
w
d
k
d
w
d
w
d
d
k
w
d
d
k
d
dw
kc
(57) 
Integrating the Eq. (57) once and setting the constant of integration to zero for simplicity, one get 
.
0
5
3
5
4
4
4
2
2
2
3







d
w
d
k
d
w
d
w
k
w
cw
(58) 
According to the balancing principle between 
4
4

d
w
d
and
3
w
that are involved in eq. (58), one 
obtain 
.
2

N
Therefore the solution of (58) according to the proposed method can be written as
)
(
2
2
)
(
1
0
)
(










e
A
e
A
A
w
(59) 
where 
1
0
,
A
A
and 
2
A
are constants to be determined later. Substituting Eq. (59) into Eq. (58) and 
collecting the degree of the polynomial in
)
(



e
yields a system of algebraic nonlinear equations 
which are omitted for simplicity. Solving the resulting algebraic equations, one obtains 
Set 1:
2
2
2
2
1
2
0
2
2
4
2
4
6
,
6
,
6
),
16
8
(
p
k
A
pr
k
A
pq
k
A
q
p
r
pqr
k
c










(60) 
Set2:
,
6
,
6
,
,
52
2
11
)
10
2
5
(
2
2
2
2
1
2
0
2
2
4
4
4
2
4
4
2
4
p
k
A
pr
k
A
k
A
q
p
k
r
k
qp
r
k
pq
k
r
k
c













(61) 
where 
20
840
1680
105
)
15
60
(
2
2
2
4
2
pqr
q
p
r
r
pq







,
q
p
,
and 
r
are arbitrary constants. 
Therefore, the time fractional SK equation according to the 
Set 1
has the following traveling 
wave solutions:
For Type 1: 
,
0
,
0
4
,
))
(
4
5
.
0
tanh(
4
6
))
(
4
5
.
0
tanh(
4
6
6
)
,
(
2
2
0
2
2
2
0
2
2
2
2
1
1































q
q
r
r
q
r
q
r
q
k
r
q
r
q
r
q
r
k
q
k
t
x
U




(62) 

,
0
,
0
4
,
))
(
)
4
(
5
.
0
tan(
)
4
(
2
6
))
(
)
4
(
5
.
0
tan(
)
4
(
6
6
)
,
(
2
2
0
2
2
2
0
2
2
2
2
1
2








































q
r
r
q
r
q
r
q
k
r
q
r
q
r
q
r
k
q
k
t
x
U
(63) 
0
)
4
(
,
0
,
0
,
1
6
1
6
)
,
(
2
2
))
(
(
2
))
(
(
2
2
1
0
0
3























q
r
r
q
e
r
k
e
r
k
t
x
U
r
r




(64) 
,
0
4
,
0
,
0
,
4
))
(
2
)
(
6
4
))
(
2
)
(
6
6
)
,
(
2
2
0
0
2
2
0
0
3
2
2
1
4


























q
r
r
q
r
r
k
r
r
k
q
k
t
x
U








(65) 
where, 
.
)
1
(
)
16
8
(
2
4
2
4
















t
q
r
qr
k
x
k
For Type 2: 
,
0
,
0
)),
(
(
tan
6
6
)
,
(
0
2
2
2
1
5






q
p
pq
pq
k
pq
k
t
x
U


(66) 
,
0
,
0
)),
(
(
cot
6
6
)
,
(
0
2
2
2
1
6






q
p
pq
pq
k
pq
k
t
x
U


(67) 
,
0
,
0
)),
(
(
tanh
6
6
)
,
(
0
2
2
2
1
7







q
p
pq
pq
k
pq
k
t
x
U


(68) 
,
0
,
0
)),
(
(
coth
6
6
)
,
(
0
2
2
2
1
8







q
p
pq
pq
k
pq
k
t
x
U


(69) 
where, 
.
)
1
(
)
16
(
2
2
4













t
q
p
k
x
k
The other obtained solutions of Eq. (55) according to 

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