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Application of a new variational technique for the study of seepage as a free boundary problem
0895-7177/90 $3.00+0.00 Pergamon Pressplc
Math1Comput.Modelling, Vol.14,pp.781-784,1990 Printed in Great Britain
APPLICATION OF A NEW VARIATIONAL TECHNIQUE SEEPAGE AS A FREE BOUNDARY PROBLEM
S. M.
Makky
and
A.
FOR
THE
STUDY
OF
Ibrahim
Mathematics Department, College of Science, P.O.Box 41005, Al-Jadria, Bagdad, IRAQ
University
of Bagdad
Abstractl Seepage in soil is formulated as a free boundary problem. An equivalent variational problem is formulated, then an approximate solution for the variational problem is sought. By representing the velocity potential and the unknown boundary as linear combinations of certain classes of functions (generalized Ritz method) the variational problem is recast to the realm of mathematical programming. A computer programme is developed and used successfully to solve the seepage problem from a triangular channel to underground water beneath the channel. The same procedure is utilized to solve the seepage problem in earth dams. The results seem to be very realistic. Keywords
Seepage; free Ritz method
boundary
problems;
variational
methods;
INTRODUCTION The above method is used successfully to solve problem of seepage from a the through homogeneous, triangular ditch isotorpic soil to underground water below The ditch is assumed so long the ditch. that the seepage can be considered two dimensional and in the vertical plane. A computer programme is developed and writtten in BASIC for an HP9845 minicomputer and implemented for the study of The results are the seepage problem. given in graphical form.
Seepage problems play a vital role in many aspects of life; in agriculture, irrigation, design of dams & foundations, in water & soil polution, to name but a In few. most seepage problems the surface separating the saturated soil its from surroundings is unknown beforehand. As a matter of fact determining the seperating surface constitutes a major part of the solution. Thus, most seepage probleas can be formulated as free boundary problems. Many investigators have tackled free boundary problems, and a variety of methods are developed for this purpose l~l,[zl. In this article a recently developed variational approach for free boundary problems is adapted to solve a particular seepage problem. The method can be summarized as follows. An equivalent extremum variational problem is sought whose critical point is a solution for the free boundary problem. Then the function representing the unknown boundary as well as the other variables of the problem are expressed AS linear combinations of the elements of preassigned complete sequences of functions (generalized Rits method). -fhis means that the problem is recasL to the realm of mathematical programming.
STATEMENT
OF THE
PROBLEM
The problem is to study the seepage from a ditch to an underground water beneath it. It is assumed that: lThe cross section of the the level isoscele triangle; uid in the ditch is constant. 2due and
ditch is an of the liq-
The ditch is so long that the flow to seepage can be considered steady two dimensional.
The soil between the ditch and the 3underneath underground water is permeable, homogeneous and isotropic. 781
Proc. 7th IN. Conj on Mathematical and Computer Modellin~
782
The region below the ditch which is eaturated by water is called the flow region. saturated boundary between and The unsaturated regions (neglecting capillary forces) constitutes one of the unknowns of the problem.
h(0) h'(O)= h(E)
0
(9c)
-m
(9d)
h'(E)=
V
Mathematical
Vn(h(y),y)
of
the
Problem
Relative to the coordinate system depicmodel corted in Pig.1, the mathematical problem described in responding to the the previous section reads as follows [s] VXX + vyy = 0 in the region
(1) R bounded
by OABD.
=o,
for
otxtm
(2)
Vx(0.r)
=o,
for
O
(3)
V(x,c(x))
= E
for
o
(4)
V
(x,0)
V(x,g(x))
,
(9b)
= xo
The reason for studying such a problem is to determine the rate of flow of liquid from the ditch to the underground water for pollution prevention purposes and for agricultural irrigation. Model
(9a)
= xi
Consequently, conditions take the forms: for
0 < y < E
(6;
= 0 ,
for
0 < y < E
(6')
Equivalent
Variational
It can be shown that the variational problem equivalent to the free boundary problem given by differential equation conditions (2-6) reads (1) and boundary as follows: Find the functions xi that render the be minimum.
x < xi
(6)
I(V,h,w)
=
f"" 0
,
0
for
XQ<
x < xl
V and h and the point following integral to
It can be easily must satisfy the
curve
seen that following
dx
dy
+
0
('/x2+ vy')
cCcY
dx dy
(10)
meets here V satisfies conditions satisfies conditions (9).
y = c(x) = mx + L ( straight line is the equation of the representing the edge of the ditch. Y = g(x) , is the equation of the ting the free surface.
(Vx2+Vy2)
f
(6)
bove relations: In the V i.s the velocity potential. the point where the free surface X the underground water.
represen-
the function g conditions: (7a)
SOLUTION
OF
THE
(2-6)
and
A Functio_n__ SatisfxtiKJ&_Non-homoxeneoue _-&u&d&.ry Ce_ndition_s R to the region of flow Devide subregions as follows (see figure 2)
I
four
(Ilab
O
; O
(7b)
KZ = r(x,Y):
o
; L
= 0
(7c)
&I = I(x,y):
x+
; O
I
(llc)
(Xi ) = --‘t.
(7d)
HA = [(x,y):
xq
; L
1
(lid)
g'(x0) g(w)
= L + mxc = -1
the Due to more seems free surface
= E
/m
singularity benoficiaJ
= IZ-I(y)
Thus
conditions
by:
R at. xl jt the represent
Define WI =
by:
x = h(y) the
of t0
(8) (7)
will
be
replaced
h
PROBLEM
RI = I(x,y):
g(xg)
g'
Problem
C(X) x0<
= g(x),for
Vn(x,g(x))=
(6) will
= Y ,
(h(y),y)
The
(5) and
the
following
( 2E y/L
1
functions
1 - ( E yz/Lz )
(12a) (12b)
W2 = E w3 = Wl(X,Y)
(lib)
+ lu[ h(y)
Wl(X,Y)J - xo
I2
(x-xoJ2/ (12c)
Proc. 7th Int. Conf. on Mathematical w4
Wz(x,y)
=
+
[y-
WZ(X,Y)l
Furthermore W = Wi
h(y)
- xc
(12d)
1
let for
on Ri,
i = 1,2,3
6 4
(13)
Note that the above definitions for W renders the functions W, Wx, and Wy to be Moreover the function W continuous on R. Define a function P as satisfies (2-6). follows :
P(x,y)=
x2y
Ly-C(x)lIx-h(y)1
N
c
c Amn
m-0
x"y"
n--O
(14) This function satisfies the homogenous boundary conditions associated with (2-6) for any choice of parameters Amn. Define V by V(x,y)
= P(x,y)+Wi
,for
(x,y)
in
Ri
(15)
It follows that V will satisfy conditions (2-S) for any choice of parameters Amn. The
Form
of
the
Free
Surfac.e
When the free surface is expressed by relations (8) it must satisfy conditions (8a-8d). It can be checked that the function defined by ,y) = By'+
h(xl,B,B
xi + y21BE2+
(m/E)
+
LJ 3(x3-x1)/
E2) - y3[2BE
+
BLJ y"
In
m/E')
OF THE
PROBLEM
To simplify the computational efforts so that a minicomputer (HP 9845) can handle such a big problem. only B, AQO, MO, Aoi are retained. Thus, the number of variables is five, namely xi, B, and A,C, D for k,o, ho, AM. Differentiation is carried by hand, before integration. Gaussian quadrature is used for numerical integration [41. The measurements are taken to be L=l;
M
783
Modelling
SOLUTION
(x-xo)2/
2 [
and Computer
E = 1.5
;
m = 0.5
;
x*3 = 1
Figure 3 shows successive approximations for the free surface, and the curve to which they converge to. REMARKS The convergence of the above described procedure is ensured by the convergence of the Ritz method for variational problems, and by the convergence of the algorithm used to solve the resulting nonlinear programming problem. The convergence of the method of steepest descent is discussed in [51. The convergence of the Ritz method is proved in 16) when the problem has fixed boundaries. The proof is generalized in [?I to cover free boundary problems. The same procedure is used successfully to study seepage through earth dams [a), and water coning in oil wells lo].
+ (2/E3)1 REFERENCES
LZZ
(
Y-E
(16)
5’2
111 satisfies
the
above
ment i oned
conditions. 121
When the form (15) for V and (16) for h are used in connection with the expression (10) for I and when integration is carried out it follows that I becomes a function of variables Ixl,A~<~-,H.B~I. In is words the variational problem other now equivalent to t.he following unconstreined non-linear programming problem: Find the minimum of the function I(Xl,A:r.-,B,BIJI.
There are some efficicnl algorithims to tical solve the above mathemaproblem. l'he mrLhod of programming this steepest descent. is chosc~n t’O1 purpose.
Crank, J. (19841, "Free and Moving Boundary Problems".ClayeDdon P&X.%.%, Ockendon, J.H. and W.R. Hedgkins (Edsl (1975)," Moving Boundary Problems in Heat Flow and Diffusion II, Clere_ndon_press,
Voroglu,
E. and W.D.L. Finn, (1982), "A Variable Domajn Finite Element Analysis of Seepage From a Ditch", in Ghallghar,H.H. and J.T. Oden, fEdsI, "Finite Elements in Fluids", Wiley Interscience Pub. Krylov, V.I., 141 (1962), "Approximate Calculation of Integrals", Tbe~_ __Macmillan Co. Lucnbcrger, D.G. 51 ( 1965 ) ( "Introductlon to Linear and Non-linear PrOgramming", Addj son Wes_l_ey. Kantwvich, 61 L.V. and V.l. Krylov, f 195x I )” Approximate Methods of High131
PI- Anaiysis",
Noordhot'f
Proc.
784 [7]
[8J
7th Int. Conf. on Mathematical
Ibrahim, A. (1988), w On Seepage Problem", H.Sc. Theses, Math. Dept., Science, University of College of Baghdad, (in Arabic) Houssain I. (1987) "Extremum Variational Principles for Boundary value Problems", H.Sc. Theses, Math. Dept.
FIG.(l)
FIG.(2)
SUB31V:S!3\5
3F
Ti(E
FLOW
*SHAPE
REB’ON
AND
[Sl
DIMENSIONS
and Computer
MoaWing
College of Science, University of Baghdad, (in Arabic) Hakky, S.M. and A. Hamad, (19891, "Water Coning in Oil Wells", Proc. of Int. Conf. on Approximation,Optmizetion Computation, Dalian, and China.
OF
THE
DITCH.
Math1Comput.Modelling, Vol.14,pp.781-784,1990 Printed in Great Britain
APPLICATION OF A NEW VARIATIONAL TECHNIQUE SEEPAGE AS A FREE BOUNDARY PROBLEM
S. M.
Makky
and
A.
FOR
THE
STUDY
OF
Ibrahim
Mathematics Department, College of Science, P.O.Box 41005, Al-Jadria, Bagdad, IRAQ
University
of Bagdad
Abstractl Seepage in soil is formulated as a free boundary problem. An equivalent variational problem is formulated, then an approximate solution for the variational problem is sought. By representing the velocity potential and the unknown boundary as linear combinations of certain classes of functions (generalized Ritz method) the variational problem is recast to the realm of mathematical programming. A computer programme is developed and used successfully to solve the seepage problem from a triangular channel to underground water beneath the channel. The same procedure is utilized to solve the seepage problem in earth dams. The results seem to be very realistic. Keywords
Seepage; free Ritz method
boundary
problems;
variational
methods;
INTRODUCTION The above method is used successfully to solve problem of seepage from a the through homogeneous, triangular ditch isotorpic soil to underground water below The ditch is assumed so long the ditch. that the seepage can be considered two dimensional and in the vertical plane. A computer programme is developed and writtten in BASIC for an HP9845 minicomputer and implemented for the study of The results are the seepage problem. given in graphical form.
Seepage problems play a vital role in many aspects of life; in agriculture, irrigation, design of dams & foundations, in water & soil polution, to name but a In few. most seepage problems the surface separating the saturated soil its from surroundings is unknown beforehand. As a matter of fact determining the seperating surface constitutes a major part of the solution. Thus, most seepage probleas can be formulated as free boundary problems. Many investigators have tackled free boundary problems, and a variety of methods are developed for this purpose l~l,[zl. In this article a recently developed variational approach for free boundary problems is adapted to solve a particular seepage problem. The method can be summarized as follows. An equivalent extremum variational problem is sought whose critical point is a solution for the free boundary problem. Then the function representing the unknown boundary as well as the other variables of the problem are expressed AS linear combinations of the elements of preassigned complete sequences of functions (generalized Rits method). -fhis means that the problem is recasL to the realm of mathematical programming.
STATEMENT
OF THE
PROBLEM
The problem is to study the seepage from a ditch to an underground water beneath it. It is assumed that: lThe cross section of the the level isoscele triangle; uid in the ditch is constant. 2due and
ditch is an of the liq-
The ditch is so long that the flow to seepage can be considered steady two dimensional.
The soil between the ditch and the 3underneath underground water is permeable, homogeneous and isotropic. 781
Proc. 7th IN. Conj on Mathematical and Computer Modellin~
782
The region below the ditch which is eaturated by water is called the flow region. saturated boundary between and The unsaturated regions (neglecting capillary forces) constitutes one of the unknowns of the problem.
h(0) h'(O)= h(E)
0
(9c)
-m
(9d)
h'(E)=
V
Mathematical
Vn(h(y),y)
of
the
Problem
Relative to the coordinate system depicmodel corted in Pig.1, the mathematical problem described in responding to the the previous section reads as follows [s] VXX + vyy = 0 in the region
(1) R bounded
by OABD.
=o,
for
otxtm
(2)
Vx(0.r)
=o,
for
O
(3)
V(x,c(x))
= E
for
o
(4)
V
(x,0)
V(x,g(x))
,
(9b)
= xo
The reason for studying such a problem is to determine the rate of flow of liquid from the ditch to the underground water for pollution prevention purposes and for agricultural irrigation. Model
(9a)
= xi
Consequently, conditions take the forms: for
0 < y < E
(6;
= 0 ,
for
0 < y < E
(6')
Equivalent
Variational
It can be shown that the variational problem equivalent to the free boundary problem given by differential equation conditions (2-6) reads (1) and boundary as follows: Find the functions xi that render the be minimum.
x < xi
(6)
I(V,h,w)
=
f"" 0
,
0
for
XQ<
x < xl
V and h and the point following integral to
It can be easily must satisfy the
curve
seen that following
dx
dy
+
0
('/x2+ vy')
cCcY
dx dy
(10)
meets here V satisfies conditions satisfies conditions (9).
y = c(x) = mx + L ( straight line is the equation of the representing the edge of the ditch. Y = g(x) , is the equation of the ting the free surface.
(Vx2+Vy2)
f
(6)
bove relations: In the V i.s the velocity potential. the point where the free surface X the underground water.
represen-
the function g conditions: (7a)
SOLUTION
OF
THE
(2-6)
and
A Functio_n__ SatisfxtiKJ&_Non-homoxeneoue _-&u&d&.ry Ce_ndition_s R to the region of flow Devide subregions as follows (see figure 2)
I
four
(Ilab
O
; O
(7b)
KZ = r(x,Y):
o
; L
= 0
(7c)
&I = I(x,y):
x+
; O
I
(llc)
(Xi ) = --‘t.
(7d)
HA = [(x,y):
xq
; L
1
(lid)
g'(x0) g(w)
= L + mxc = -1
the Due to more seems free surface
= E
/m
singularity benoficiaJ
= IZ-I(y)
Thus
conditions
by:
R at. xl jt the represent
Define WI =
by:
x = h(y) the
of t0
(8) (7)
will
be
replaced
h
PROBLEM
RI = I(x,y):
g(xg)
g'
Problem
C(X) x0<
= g(x),for
Vn(x,g(x))=
(6) will
= Y ,
(h(y),y)
The
(5) and
the
following
( 2E y/L
1
functions
1 - ( E yz/Lz )
(12a) (12b)
W2 = E w3 = Wl(X,Y)
(lib)
+ lu[ h(y)
Wl(X,Y)J - xo
I2
(x-xoJ2/ (12c)
Proc. 7th Int. Conf. on Mathematical w4
Wz(x,y)
=
+
[y-
WZ(X,Y)l
Furthermore W = Wi
h(y)
- xc
(12d)
1
let for
on Ri,
i = 1,2,3
6 4
(13)
Note that the above definitions for W renders the functions W, Wx, and Wy to be Moreover the function W continuous on R. Define a function P as satisfies (2-6). follows :
P(x,y)=
x2y
Ly-C(x)lIx-h(y)1
N
c
c Amn
m-0
x"y"
n--O
(14) This function satisfies the homogenous boundary conditions associated with (2-6) for any choice of parameters Amn. Define V by V(x,y)
= P(x,y)+Wi
,for
(x,y)
in
Ri
(15)
It follows that V will satisfy conditions (2-S) for any choice of parameters Amn. The
Form
of
the
Free
Surfac.e
When the free surface is expressed by relations (8) it must satisfy conditions (8a-8d). It can be checked that the function defined by ,y) = By'+
h(xl,B,B
xi + y21BE2+
(m/E)
+
LJ 3(x3-x1)/
E2) - y3[2BE
+
BLJ y"
In
m/E')
OF THE
PROBLEM
To simplify the computational efforts so that a minicomputer (HP 9845) can handle such a big problem. only B, AQO, MO, Aoi are retained. Thus, the number of variables is five, namely xi, B, and A,C, D for k,o, ho, AM. Differentiation is carried by hand, before integration. Gaussian quadrature is used for numerical integration [41. The measurements are taken to be L=l;
M
783
Modelling
SOLUTION
(x-xo)2/
2 [
and Computer
E = 1.5
;
m = 0.5
;
x*3 = 1
Figure 3 shows successive approximations for the free surface, and the curve to which they converge to. REMARKS The convergence of the above described procedure is ensured by the convergence of the Ritz method for variational problems, and by the convergence of the algorithm used to solve the resulting nonlinear programming problem. The convergence of the method of steepest descent is discussed in [51. The convergence of the Ritz method is proved in 16) when the problem has fixed boundaries. The proof is generalized in [?I to cover free boundary problems. The same procedure is used successfully to study seepage through earth dams [a), and water coning in oil wells lo].
+ (2/E3)1 REFERENCES
LZZ
(
Y-E
(16)
5’2
111 satisfies
the
above
ment i oned
conditions. 121
When the form (15) for V and (16) for h are used in connection with the expression (10) for I and when integration is carried out it follows that I becomes a function of variables Ixl,A~<~-,H.B~I. In is words the variational problem other now equivalent to t.he following unconstreined non-linear programming problem: Find the minimum of the function I(Xl,A:r.-,B,BIJI.
There are some efficicnl algorithims to tical solve the above mathemaproblem. l'he mrLhod of programming this steepest descent. is chosc~n t’O1 purpose.
Crank, J. (19841, "Free and Moving Boundary Problems".ClayeDdon P&X.%.%, Ockendon, J.H. and W.R. Hedgkins (Edsl (1975)," Moving Boundary Problems in Heat Flow and Diffusion II, Clere_ndon_press,
Voroglu,
E. and W.D.L. Finn, (1982), "A Variable Domajn Finite Element Analysis of Seepage From a Ditch", in Ghallghar,H.H. and J.T. Oden, fEdsI, "Finite Elements in Fluids", Wiley Interscience Pub. Krylov, V.I., 141 (1962), "Approximate Calculation of Integrals", Tbe~_ __Macmillan Co. Lucnbcrger, D.G. 51 ( 1965 ) ( "Introductlon to Linear and Non-linear PrOgramming", Addj son Wes_l_ey. Kantwvich, 61 L.V. and V.l. Krylov, f 195x I )” Approximate Methods of High131
PI- Anaiysis",
Noordhot'f
Proc.
784 [7]
[8J
7th Int. Conf. on Mathematical
Ibrahim, A. (1988), w On Seepage Problem", H.Sc. Theses, Math. Dept., Science, University of College of Baghdad, (in Arabic) Houssain I. (1987) "Extremum Variational Principles for Boundary value Problems", H.Sc. Theses, Math. Dept.
FIG.(l)
FIG.(2)
SUB31V:S!3\5
3F
Ti(E
FLOW
*SHAPE
REB’ON
AND
[Sl
DIMENSIONS
and Computer
MoaWing
College of Science, University of Baghdad, (in Arabic) Hakky, S.M. and A. Hamad, (19891, "Water Coning in Oil Wells", Proc. of Int. Conf. on Approximation,Optmizetion Computation, Dalian, and China.
OF
THE
DITCH.