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Evolution Equations and FEM
Chapter 3 Evolution Equations and FEM
In the case of temporally inhomogeneous parabolic equations, the complex m e t h o d does not work so well by itself for the analysis of the finite element approximation. Here, we adopt the m e t h o d of Helfrich and then that of energy, and extend the error estimates of the preceding chapter to this case.
3.1
Generation
Theories
The present chapter is devoted to the temporally inhomogeneous parabolic equation; t2 C R 2 denotes a polygon, and /2 = /2(x,t, D) a second order elliptic operator with time-dependent real smooth coefficients:
c(~, t, D) = - ~
~-~ a~j0 (~, t)
0
2
+ Z~=~ bj(x , t) ~+~(~,t). o
i,j=l
Uniform ellipticity 2
i,j=l
is assumed, 51 > 0 being a constant. We study the parabolic equation
ut +/2(x, t, D)u = 0
in t2 x (0, T)
(3.1)
with the initial condition
glt=o = uo(x)
in ft
(3.2)
and with the boundary condition either u = 0
on at2 x (0, T)
(3.3)
or
0u -t- a u = 0 cO~,c
on 0t2 x (0, T ) .
--
(3.4)
In (3.4), cr = a(x, t) is a smooth function on 0t2 x [0, T], and 0/0r, L denotes the differentiation along the outer co-normal vector ~L: 0
_ ~-'2
n i a i j ( x , t)
i,j=l
95
0
3. Evolution Equations and FEM
96
where n = (nl, n~) is the outer unit normal vector on 0f~. Assuming u0 E X = L2(~), we can reduce equation (3.1) with (3.2) and (3.3) (or (3.4)) to the evolution equation
du
dt
+ A(t)u = 0
(0 < t < T)
(3.5)
with u(0) = u0
(3.6)
in X = L2(gt). Taking V = H~(f~) or Hl(f~) according as the b o u n d a r y condition (3.3) or (3.4), we put
.At(u, v) = i,j:,
aij(x, t)-~xj -~xi dx + J:'
bj(x, t)--VOzy dx
+ ffl c(x, t)uv dx + fon a(x, t)uv dS for u, v E V. An m-sectorial operator A(t) in X can be defined through the relation
At(u, v) = (A(t)u, v) ,
(3.7)
where u E D (A(t)) C V and v E V. As in the temporally homogeneous case of w relation
D (A(t)) = H2(fl) N H~(fi)
the
(3.8)
follows for V = H~(f~) and
D (A(t)) = {v C H2(f~)
+av=O
on0f~
(3.9)
for V = Hl(f~), if 0fi is smooth for instance. Generation theories of a family of evolution operators {U(t,S)}o
du dt
- - + A(t)u : 0
(s < t < T)
(3.10)
with 'u(s) = 'Uo C X
(3.11)
3.1. Generation Theories
97
is given by u(t) = U(t, s)u0. Consequently, the semigroup properties
U(t,r)U(r, s) = U(t, s)
(0 < s < r <_ t <_ T)
and
U(t,t) = I
(0 <_ t <_ T)
follow. Furthermore, we have
U(t, s) = - A ( t ) U ( t , s)
and
-~sU(t, s) = U(t, s)A(s)
(3.12)
in the strong sense in X for 0 _< s < t < T. It is worthwhile to give a short summary of those theories here. In fact, studying the finite element approximation of (3.5), we show some kind of stability of approximate solutions and smoothness of original ones. Both of them are established by re-examining the theories, and then error estimates will follow. Crucial assumptions are the following: (i) Each - A ( t ) generates a holomorphic semigroup with certain estimates uniform in t E [0, T]. (ii) A(t) is smooth in t E [0, T] in some sense. The family {U(t, S)}o
IA,(~, ~)1 s c~ II~llv II~llv
(u, v ~ V)
A~(~ , ~) > a l~ I~V - ~1~1 X=
(~ ~ v)
and -
-
,
(3 13) "
with constants C1 > 0, 6 > 0 and A E ][{ independent of t E [0, T]. We may suppose A = 0 in (3.13), taking v - e-~tu(t)instead of u - u ( t ) i n (3.5)"
x,(~, ~)>__ ~11~11~
(~ ~ v ) .
(3.14)
Then, A(t) becomes of type (0, M) with 0 E (0, 7r/2) uniformly in t e [0, T]; we have
C \ Eo C p(A(t)) for
ro = {~ c e l
o < arg I~l < o},
(3.15)
3. Evolution Equations and FEM
98 and M~ II(zI- m(t)l _ XlIx, X <_-~
(0 + e _< [arg z I < _ 7r)
(3.16)
for e > 0. Each -A(t) generates a holomorphic semigroup {e -~a(t) }s>0 uniformly bounded in t C [0, T]. We have
II~-~A(,)llx,x <_1 for 0 < s < + o c and 0 < t < T. Concrete expressions of the second condition, on the other hand, are slightly different according to the theories. In each of them, construction of the family gives some estimates on their members at the same time. For the moment, the operator norm on X = L2(12) is simply written as II" IIGeneration
T h e o r y of T a n a b e - S o b o l e v s k i i
Because of (3.8), D(A(t)) is independent of t in the case of V = H~(f~). Furthermore, the inequality I[A(t)A(s)
-~ -
111_
cIt-
sl ~
(t,~ E
[0, Z])
(3.17)
follows with c~ C (0, 1] from an integration by parts and the elliptic estimate. In such a situation, the family of evolution operators {U(t,s)}o
U(t,s) = e-(t-s)A(~) +
e-(t-r)A(~)R(r,s) dr,
(3.18)
where R = R(t, s) is the solution of the integral equation of Volterra type, I~,(t, S) --
I~ 1 (t, r ) R ( r ,
s)dr
= /~1 (t, S)
(3.19)
for /~,1 (t, S) -- --
(A(t)
- A ( s ) ) e -(t-s)A(s)
Those relations are obtained formally by substituting tile right-hand side of (3.18) into the first relation of (3.12). Eventually the unique solvability of (3.19) follows and {U(t,s)} defined by (3.18) becomes the desired family of evolution operators. Meanwhile the following estimates are proven, where 0 _< s < r < t _< T and 0 E (0, a):
(3.20) IIU(t, s)ll + [IA(t)u(t, s)A(s)-' I[ <- c,
[IA(t) [ u ( t ,
~) - u(,-,
~)] A(.~)-' II -< C o ( t
- ~)o(~ _ ~ ) - o
(3.21) (3.22)
3.1. Gel~el"ation Theories
99
G e n e r a t i o n T h e o r y of F u j i e - T a n a b e If V = Hl(f~), D(A(t)) varies as t changes, and the preceding theory does not work directly. However, the m-sectorial operator A(t) in X defined through (3.7) can be regarded as that in V', which is denoted by A(t). Its domain is independent of t: D(A(t)) = V, and furthermore, conditions (3.15) and (3.16) hold with A(t) and X replaced by A(t) and f( = V', respectively:
V',V' --
]Z q- 1
The coefficients aij, bj, c and cr are smooth so that the inequality IAt(u, v) - A~(u, v)l _< O It - sl ~
I1~11~I1~11~
(u, v E
V)
(3.24)
holds with c~ E (0, 1]. This implies (3.17) for A(t) in 2 . Therefore, from the preceding theory, {A(t)} generates a family of evolution operators in 2 denoted by {U(t, s)}0 1/2, it can be shown that
U(t,s)=O(t,s)x becomes a bounded operator in X and {U(t,s)} forms a family of evolution operators generated by - A ( t ) . This {U(t, s)} satisfies (3.20) and U(t, s)[ _< C in X. G e n e r a t i o n T h e o r y of K a t o - S o b o l e v s k i i We can show that D (A(t) p) is invariant in t for p C [0, 1/2). symmetric part A ~ of At as in w
To see this, take the
Ato= 1 (.,4, + At).
At(~, ~) = A,(~, ~),
If Ao(t) denotes the self-adjoint operator associated with At~ it holds that
c - ' Ivllv _< IlAo(t)l/% Ix < C vllv.
(3.25)
As is described in the commentary to w the domain of A(t) p is equal to that of Ao(t) p if p C [0, 1/2). (The idea of proof will be obtained from the argument described below.) Here, the latter is independent of t if p = 1/2 as is indicated in (3.25), and p = 0 obviously:
D(Ao(t) '/2) = V,
D(Ao(t) ~ = X.
Then, Heinz' inequality implies the invariance of D (A(t) p) in t for p E [0, 1/2). We show that the inequality
IlA(t)PA(s)-p-/11
c t - sl
(t, s E [0, T])
(3.26)
3. Evolution Equations and F E M
100 follows from (3.24). In fact, given # > 0, we have (#I + A(t)) - 1 -
(pI + A ( s ) ) - ' = - (pI + A(t)) -1 Ao(t) 1/2. Bo(t, s ) . Ao(s) 1/2 (#I + A(s)) -1
with Bo(t, s) = Ao(t) -1/2 [A(t) - A(s)] Ao(s) -~/2
Inequality (3.24) reads; IA(t) - A(s)l v,v, <- C I t - sl ~ , or
liB(t, ~)11 ~ c It - ~1~ We make use of the following. L e m m a 3.1. If H is a non-negative self-adjoint operator on a Hilbert space X with norm
II. II, ~ e h~ve
~
~ #2~ IH~/2 (~I + H) -~ v[I 2 d # -
Cp IIH~
2
(3.27)
for p c [0, 1/2) and v E D(H~ Proof: Introducing tile spectral decomposition
ad E ( a) ,
H :
we have
#~o ]IH~/~ (#I + H)-'
= d#
-
~,=o @
a(~, + a ) - ~ d IIE(a)~ll ~
9
-
ad IIE(:~)vll =
=
ad IIE(:~)vll ~. a ~o-'
=
Co
#~o(# + a)-~da ~o(#
+ 1)-2d#
A2PdlE(A)vl 2-- CplIHPv 2.
This means (3.27).
[]
We are able to give the following. Proof of (3.26): We show
II[A(t) p - A(s) p] vii < c It - sl ~ IIAo(s)~
(3.28)
3.1. Generation Theories
I01
for p E (0, 1/2) and v e D (Ao(s)a). Then, inequality (3.26) follows from (2.43). For this purpose, we may take v r D(A). Applying (2.18), we have ([A(t) ~ - A(s) ~ v, X) = sin 7rp
7r
/0
pP dp. (B(t,s)Ao(s) 1/2 (pI + A0(s)) -1 v, Ao(t) 1/2 (pI + Ao(t))-i X)
for X E X. In use of (3.25), inequality (3.28) follows as [([A(t)P - A(s)P] v, X)[
(/0 9
I[Ao(t)'/2 (#I + Ao(t)) -x Xll2x d•
It - s[ ~
= c~ IIAo(s)Ovllx. I l x l l x - I t - sl ~ . The proof is complete. Above properties of the fractional powers of generators, summarized as the invaria.nce of D (A(t) o) and inequality (3.26), guarantees the existence of the family of evolution operators in the following way if c~ + p > 1 is satisfied. Therefore, evolution operators exist if c~ > 1/2 again, in the parabolic initial b o u n d a r y value problem in consideration. For simplicity, we describe the case p = 1/m with m an integer. By taking an appropriate approximation of A(t), say, the modified Yosida approximation: Aa(t) = A(t)(1 + AA(t)o) -m with ,~ I 0, we can reduce the theory to the case where each A(t) is bounded in X. In fact, we can show that (3.26) implies
IlA~(OPA~(s) - p - Ill <_ C l t - sl ~
(t, s e [0, T])
with a constant C > 0 independent of )~ > 0. Existence of a family of evolution operators {Ua(t,s)}o
U(t, s) = s-lim Ua (t, s). M0
Then, {U(t,s)}o
llA(t)ZU(t,s)ll < C z ( t - s)-z
(O<_s
follows from ]lA~(t)Zu~(t, s)[I < C z ( t -
s) -z
(0 < s < t < T ) ,
(3.29)
where 0 _< p < a + p. We shall give an outline of its proof, dropping the suffix A for simplicity of writing.
3. Evolution Equations and FEM
102 Letting
D(t, s ) = A(t)PA(s) - p - I, we have
liD(t, s)
~
Clt
-
s ~
and m
A(t) - A(s) = Z
A(t)I-PPD(t' s)A(s)PP"
(3.30)
p=l
We get t
-
= ~=
e-(t-r)A(t)A(t)l-p"D(t,r)A(r)~~
dr.
(3.31)
We introduce the following notation: Given the operator-valued functions I(e = IQ(t, s) (g = 1, 2) on D = {(t, s ) [ 0 _< s _< t <_ r } , we define another I( = K1 * I(2 by (//(1 * 1(2)(t,s)=
K~(t,r)K2(r,s) dr.
For a > 0 and M > 0, we say t h a t K E Q(a, M) if the inequality
[ K( t,s)ll - M ( t -
s) a-1
holds. Then, if Kl C Q(ae, Me) for g = 1, 2 we have /s
* /(2 E Q ( a l +a2, B ( a l , a 2 ) M 1 M 2 ) ,
where B(a, b) denotes the beta function: B(a,b)
jfo 1(1
=
-
x )a- l x b-1 d ~ .
Let
W(t, s) = U(t, s) - e -(t-~)A(t)
and
Yq(t, s) = A(t)oow(t, s).
Equality (3.31) reads; m
(3.32) p=l
3.1. Generation Theories
103
where
Hq,p(t, s) = A(t)'-PP+qPe-(t-s)A(t)D(t,
s)
(3.33)
and m
p=l
for
Yp,_, (t, 8) = A(t)PPe-(t-s)A(t) To avoid a technical difficulty, we take (3.34) and transform (3.32) into a system of integral equations for
{Zql q = 1,.-. ,m}. That is, m
Z~ = ~
Hq,, , Z, + &,o
(3.35)
p=l
with m
(3.36) p=l
Consequently, Zq (q = 1 , . . . , m) is subject to the iteration scheme oo
Zq -- ~
(3.37)
Zq,i
i=0
with m
Zq,,+, = ~
H~,, 9&,,
(~ = o, 1 , . . . ) .
p=l
From definition (3.33) follows H~,, ~ Q (~ - qp + pp, M , )
with a constant M1 > 0, because (2.16) holds by (3.16)"
<
> 0),
(3.38)
3. Evolution Equations and F E M
104 where ~c >_ 0. F u r t h e r m o r e , we have
Zq,o E Q(1 + a - qp, Mo) for some M0 > 0. We can derive
Zq,i E Q (1 + (i + 1)a - qp, Mi) with A/Ii+l/~Ii = r n M o M i B (c~ + p - 1, (i + 1)c~) by an induction, and then Zq E Q ( 1 + a - q p ,
(3.39)
C)
follows from (3.37) with a constant C > 0. Inequality (3.39) now gives an estimate on Yq even in the case t h a t q is not an integer. Namely, (3.34) makes sense for any q >_ 0, and Zq,o is again given by (3.36). T h e n Zq is defined by (3.35) with p taking integers as before. Since Zq in (3.35) admits (3.39), inequality (3.34) gives an estimate of Yq for a - qp + p > 0, because Yq,O E Q(1 - qp, C) can be shown. Consequently, Yq E Q(1 - qp, C) follows. Writing qp = / 3 , we then obtain (3.29) from (3.38).
Generation Theory of Kato-Tanabe Let us define another bilinear form .At(, ) on V x V by
,=
j=l
s
/o ~
Then, we have
IA,(u,~)l _< C llullvllvllv, I.A,(.,,, v) - A,(.,,, ~)1 _< c It - ~1~ II~llv Ilvll~, for u , v E V with some c~ E (0, 1] and lira
sup
(At-
1
As)('u, v) - As(u, v) = 0 .
II~llv,llvllv
dA(t)-' dt
d A -
ds
(S)-1 ~
holds with K > 0 and a E (0, 1].
K
It-
s
(t, ~ E [0, T])
(3.40)
3.1. Generation Theories
105
2) The inequality
c9 ( z I - A(t)) -~
M~
holds for c > 0 sufficiently small.
Proof of (3.41): Take z
(z e c \ r0+~)
---[;i
9 C \ E0+E and v
(3.41)
9X, and put
w(t)=(zI-A(t))-lv. We show that it is continuously differentiable in X with the estimate
Ow x
-5i-
M~
(3.42)
-
satisfied. Recall
(8.48)
(z - A ~ ) ( ~ ( t ) , ~) = (~, ~) and (2.31)"
Jzl lJxJl~ + II~II~V - -<
~o I~ II~IIX~
- A ( ~ , ~)J ,
where X C V and z C C \ Eel. This implies also (2.33) as
I1~1 ~ < 6o Iv ~ /I~1
~nd
I1~11~ < ~o vlt~ /t~ ~/~
Differentiating formally in t, we get (Z -- , A t ) ( ~ b ( t ) , )(~) = A t ( w ( t ) , ) ~ )
(3.44)
from (3.43). Here, the right-hand side is a bounded linear functional of X C V. In use of (2.31), we can define ~b(t) E V through (3.44) conversely, by Lax-Milgram's theorem. Now we shall show lim w(t) - w(s) _ ~b(s)ll t--~s
t -- 8
: 0.
(3.45)
V
In fact, letting ~ ( t ) - ~(~) t--8
we have
(~ -
A~)(~(t), ~(t))
=
t-8
t--8
(Z -- r
-- W(8), x ( t ) ) -- (Z -- ,At) (~b(8), x ( t ) )
(z - A~) ( ~ ( t ) - ~(~), ~(t)) - As (~(~), ~(t)) + (A~ - A~)(w(~), ~(t))
t--8
{1
((z - As) - (z - A~)) (~(~), ~(t)) - A~ (w(~), ~(t)) + (At - A s ) ( ~ ( ~ ) , ~(t))
}
3. Evolution Equations and FEM
106 Again by (2.31), we get 1
IIx(t)ll* V - -< ~0
(.4, - .4~) (~(~), z(t)) - A~ (~(~), ~(t)) + &c It- ~1. Iw(~) ,,. IIx(t) v,
or
IIx(t)llv < C I t - s
9~,(~)1 v +C
sup xEV
1
---zU t (.4, - .4~) (~(~), ~) - A~ (~(~), ~)
Ilxllv_
lim IIx(t)llv = 0 . t---* 8 We turn to the proof of (3.42). In fact, again by (2.31) we have
z IIw(t)ll x2 + I~(t) ~. _< ~o I(z - .A,.)(~(t), ~(t))l 5o 12., (w(t), w(t)) I _< C IIw(t) ,, IIw(t)ll,,. This implies
~i,(t) Iv < c IIw(t)Iv -
CIl~ll~ Izll/~
and
~/2 II~i~(t)lv/~ ......
IIw(t) Ix < Cllw(t)llv
Izl '/~
-
C lvllx
Izl
by (2.33). The proof is complete.
Proof of (3.~0): We take v C X, and set .f(t) = A ( t ) - l v E V. The existence of df(t)/dt follows similarly. Noting At (.f (t), X) = (v, X) , we define j~(t) by
where ~ E V. Then it follows that lim
t--~8
.f(t) - . f ( s ) - r t-s
=0. V
3.1. Generation Theories
107
Inequality (3.40) is a consequence of the stronger one:
Ilvll~,.
(3.46)
In fact we have
IIx ~ < A<(r - r x) = -Jlt(f(t), x ) - ( A t - A,)(j'(s), x ) + Jl,(f(s), x) = ( f % - Jlt)(f(t), x ) + J l ~ ( f ( s ) - f(t), x) - ( A t - As)(r <
x)
C Ilxllv (it - sl ~ IIf(t)llv + Ilf(s) - f(t)llv + It - sl IIr
or
iii(t)- ./(~)llv _< c (it- ~l ~ lif(,)il~ + ilf(~)- f(t)ll~ + it- ~l
Its( )ll ).
(3.47)
Remember that
IIf(t)llv <_ C IIv v, follows from
llf(t)ll~
_ .At(f(t), f(t)) -- (v, f(t)) < c
IlVllw, IIf(t)llw
.
Similarly,
~llJ(s)ll~ ~ A,(r
r
- -J~(f(s), r
< c }lf(s)llv IIf(s)llv
gives
Finally, we have
(5lif(s)- f(t)ll~
< .At(f(s)- f(t), f ( s ) - f(t)) = ( A t - As)(f(s), f ( s ) - f(t)) <
C It - ~1 IIf(~)ll. IIf(~) - f(t)ll.
and hence
] i f ( s ) - f(t)iiv <_ C I t - s I tlf(s)llv <_ C i t - s I livllv, follows. Plugging those inequalities into (3.47), we obtain (3.46). Subject to the above conditions on the differentiability of resolvents, the family of evolution operators {g(t,S)}o
u(t, ~) = ~-(~-~)~(~) + w ( t , ~)
3. Evolution Equations and FEM
108 with
w(t, ~) =
~-(*-~(*)R(~, ~) d~,
(8.48)
where R = R(t, s) is the solution of
R(t, ~) = R~(t, ~) +
R~(t, T)~(,-, ~) d~
(3.49)
for
0 + N0 R l ( t , s ) = -(~-t
)r
1 O~F e -(t- s)z -07(zI0 -- 27r,. A(t))-ldz,
(3.50)
F being positively oriented boundary of E0+~ for e > 0. Inequality (3.20) and IIg(t, s)ll < c are also derived from this scheme. More precisely, we have
IR(t, s)][ _< C
(0 _< s _< t _< T)
(3.51)
and
(0 _< s < ~ < t <_ T),
(3.52)
for 7 C (0, 1) and 5 C (0, a). They are consequences of those with R replaced by R1,
IIR~(t, s)ll <_ c
(3.5a)
and
II/~l(t, 8 ) - /l~l(r, 8)11 ~ C7,5((t- T)7(T- 8) -7 -[- ( t - r ) a ( r - s)~-a-1), respectively. This theory of generation is particularly remarkable as any assumptions on the domains of A(t) are not made. Consequently, it is no wonder that a little stronger assumption on the smoothness in t of A(t) is imposed.
3.2
A Priori
Estimates
In this section, we show a uniform estimate concerning the evolution operator associated with the discretized problem, which plays a key role in the error analysis. In the following lemma, V C H C V' denotes a triple of Hilbert spaces, A(t) an m-sectorial operator in X associated with the bilinear form At(, ) on V x V, smooth in t E [0, T] in the sense of the preceding section, and {U(t, S)}o<8
3.2. A Priori Estimates
109
L e m m a 3.2. Each/3 e (0, 1/2) admits the equality
d(t)U(t, s) - A(r)U(r, s) = A(t) [e -(t-~)A(t) - e -(~-s)A(t)] + A(t)ZZ~(t, r, s)
(3.54)
with Zz(t, r, s) subject to the estimate IIZ,(t, r, s)ll <
C,(t
-
r)(r
-
(3.55)
s) ~-',
where O < s < r < t < T. Proof: We shall take the reduction process first. In fact, from the construction we have A(t)U(t, s) - A(r)U(r, s) = A(t) [e - ( t - s ) A ( t ) --
e -(r-s)A(t)]
+A(t)" [A(t)l-'~ -(~-s)~(') - A(~)'-'~ -(~-s)~(~)] +A(t)" [ I - A(t)-ZA(r)'] A ( r ) l - ' e -(~-s)A(~) +A(t) a [ A ( t ) l - ' w ( t , s) - A ( r ) l - ' W ( r , s)] +A(t) ~ [ I - A(t)-~A(r) ~] A(r)'-~W(r, s), so that 4
/=1
holds with
Z~(t, r, s) = A(t)l-Ze -(r-s)A(t) - A(r)l-Ze -(r-s)A(~), Z~(t, r, s) =
[I - A(t)-ZA(r) ~] A(r)X-'e -(~-s)A(r),
z~(t, ~., s)
A(O'-~w(t,
:
Z~(t, r, s) :
s) - A(~.)~-~WO ., ~),
[I - A(t)-ZA(r) ~] A(r)'-~W(r, s).
The Dunford integral gives the expression
d(t)Ze_Tm(t ) _ A(s)e_~d(~ ) = 12m ofr z'-Ze-rz
[ ( z I - d ( t ) ) - ' - (zI - m(s))-'] dz,
while
]l(z~-
A ( t ) ) -1 - ( z I -
A(s))-'ll < c~ It- sI -
Izl
follows from (3.41). We have
IlA(t)~e -~A(t) - A(s)~-~(s)ll <_ c~ It - sl r - ~ < c
d--~-~lt-s l -
~ - ~ e -~"~~176 At
G I t - sl r ~-~
(3.56)
3. Evolution Equations and FEM
110
for/3 > -1. This implies IIz~(t, ~, s)ll < c~(t - ~)(~ - ~)~-~
Inequality
III-
A(t)-ZA(s);311 <- C ~ l t - sl
follows from (3.26). We have
~
C / 3 ( t - r ) ( l " - 8) ~-1
Inequality (3.51) gives IIA(t)l-ZW(t,s)lt
: <_ c~
A(t)l-ze-(t-r)A(t)R(r,s)dr ( t - ~)~-'d~ = C ~ ( t -
~)~
and hence llz~( t, ~, ~)11 - c , ( t - ~)(~ - ~),
follows. The proof of Lemma 3.2 has been reduced to
Ilz~(t, ~, s)l t = IlA(t)l-~w(t, s) - A ( r ) ' - ~ W ( r , s)l I <_ C,(t - r ) ( r - s ) ' - ' Equality (3.48) now gives 7
Z~(t,r,s) = A ( t ) l - Z w ( t , s ) - A ( r ) l - Z W ( r , s ) = ~
Z[3(t,r,s )
l=5
with Z~(t, r, s)
=
f
t
A(t)l-~e -(t-~)A(t) [/~(z, s) -/~(t, s)] dz,
z~(t, ~, ~) =
[ A ( t ) ' - ~ -('-z~('~ - A ( ~ ) l - ~ - ( ~ - ~ ( ~ ]
Z~(t, ~, s)
A(t)~-~-(~-z~(~)dz
=
+
[P(~, 9 .~) - ~(~, ~)1 d~,
. ~(t, s),
[ A ( t ) l - ~ - ( ~-z~(~ - A ( ~ ) I - ~ -(~-z~(~]
d z - ~ ( ~ , s).
3.2. A Priori Estimates
111
In use of (3.52) we have
[IZ~(t,r,s)l[
<
IlA(t)'-Ze-(t-z)A(t)ll .
<_ c~.,
IIR(z,s)- R(t,s)ll dz
( t - ~)~-~(t- ~)~(~- ~)-~d~
+G,~
( t - z)~-~+~(z- s) -~+~-~ (9z - s)~-'dz,
<- G .
( t - z)~-l+~(z- ~)-~+l-~dz. ( ~ - s) ~-~
=
~)(~- ~)~-1
G(t-
taking "7 e ( 1 - f l , 1) and 5 e (c~ - fl, c~). From (3.96) and (3.56)we have
_ G(t-
~)(~- z) ~-~.
Combining this with
}lA(t),-z~-I,-zl~r
A(~,)'-Z~-Ir-z/Ar II
-< G(~"- ~)~-', we get [IA(t)~-ze
-r
-
A(r)l-Ze-(r-z)m(r)[I < C ~ ( t - r)'~(r- z) - ~ + z - '
for r~ E [0, 1]. This implies
IIG( t, ~, ~)ll _<
I[A(t) ~-~-(~-~(~ - A(~)'-~-(~-z)~(~)l[- I1~(~, ~ ) - ~(z, ~)11 d~-
+c~,~
= G(t-
( t - ~)~(~ - ~)-~+~-1. (~ - ~)~(~- ~)~
,~)~(,~- s)~-',
3. Evolution Equations and FEM
112 by taking -7 e ( a - / 3 , 1) and (5 E ( a - / 3 , a) similarly. We have Z~(t, r, $)
=
[A(t)-fle-(t-z)A(t)]~:t r R(t, 9 8) -Jr-[A(t)-fle -(t-z)A(t) - A ( r ) - f l e - ( r - z ) A ( r ) ] : : :
I~(t, 9 8)
11
/=8
with
Z~(t, r, s) = [I - e -(t-~)m(t)] [A(t)-zR(t, s) - A(r)-ZR(r, s)], Z~(t, r, s) = - e -(t-r)A(t) [A(r) -z - A(t) -z] R(r, s), zl~~ r, s) = - [A(t)-Ze -(t-~)A(t) - A(t)-f~e -(~-s)a(t)] R(r, s), z ~ l ( t , 1", S)
:
-- [A(t)-~e -(r-s)A(t) - A(r)-~e -(T-s)A(r)] R(r, s).
The inequality
IIA(t) - ~ - A(~)-~II <- G It- ~1 follows from (3.26) so that we have IIz~(t,
~, ~)11 <-
c~(t -
~)(~ - s)/2i'- 1 .
On the other hand the inequalities
Ilzy(t, r, ~)ll _< Cz(t- ,~)(,~- ~)~-' and
IIz~'(t, r, s)ll _< G ( t - r)(~- s)~-' follow from (3.96) and (3.56), respectively. In this way, Lemma 3.2 has been reduced to
[[A(t)-zR(t, s ) - A(r)-ZR(r, s)[ I _< Cf3(t- r ) ( r - s) z-I
(3.57)
Integral equation (3.49) reduces this inequality furthermore to IIA(t)-ZR,(t, s ) - A(r)-ZR,(,', s)l [ <_ C ~ ( t - r ) ( r - s) z-l,
(3.58)
R~ - Rl(t, s) being the right-trend side of (3.50). We show this fact first. In fact, in use of (3.49) we have m(t)-~R(t,
s) - d ( r ) - r R ( r ,
s)
= [ A ( t ) - O R l ( t , s ) - A(r)-aR~(r,s)] + +
/'
A(t)-;3R,(t,z)R(z,s)
dz
[ A ( t ) - O R l ( t , z ) - A(r)-aR~(r,z)] R(z,s) dz.
3.2. A Priori Estimates
113
The second term of the right-hand side is estimated by (3.51) and (3.53):
/*
liA(t)-Zll
9IIRl(t,
z) l-IIR(z,
~)11 dz <
c(t
-
~).
Similarly, the third term is estimated as
fs r IlA(t)-ZRl(t,z) - A(r)-~t~l (r, z) C
dz
9IR(z,s)
( t - r ) a ( r - z)~-lds = C~3(t- r ) a ( r - s) l~.
Thus, (3.58) implies (3.57). We now turn to the proof of (3.58). Recall the symmetric part Ao(t) of A(t) associated with Ao. We have the following. L e m m a 3.3. The equality
[ 0_~( z l _ A(t))_ 1 - -~sO(zl - A(s))-l] = A(t)lo/2 ( z I - A0(t)) -1Bz(t, s)Ao(s) 1/2 ( z I - Ao(s)) -1 holds with
Bz(t, s)II ~
c I~ -
(3.59)
sl ~ ,
where z E EOl. Proof: Define A'(t)" V --, V ' b y J~t(u, v) = (A' (t)u, v) for u, v E V. It holds that
0 (zI - A(t)) -1 = - ( z I - A(t)) 0-7
-1 d'
(t) (zI - A(t)) - 1
We have
0 =
(zI(zI q-(zI
A(t)) -1
0
A(s))-I 1
(zI-
A(~)) -1A'(t)(zI -
+ (zI - A(t)) -1
A(t)) -1 [A(/~) - A(s)]
-
d(f)) -1 [m'(t)
-
(zI
[A(t) - A(s)]
d9' ( s )
The equality
m'(s)]
-
(zI -
A(s)) -1
d(s)) -1
(zI -
A(s)) -1
(zI - A(s)) -1 d'(s)(zI
-
d(s)) -1
114
3. Evolution Equations and F E M
arises with the following terms" Bl(t, 8)
=
Ao(t) -1/2 ( z I - Ao(t)) ( z I - A(t)) -1Ao(t) 1/2 A9o ( t ) - l / 2 A ' ( t ) d o ( t ) -1/2. do(t) 1/2 ( z I - A ( t ) ) -~ do(t) 1/2 Ao(t) 9 -1/2 [A(t) - A(s)] Ao(t) -~/9
Ao(8) 9 1/2 ( z I - A(8)) -1 ( z I - A o ( s ) ) d o ( s ) -~/2, B2(t, s)
=
mo(t) -1/2 ( z I - Ao(t)) ( z I - A ( t ) ) -1 do(t) ~/2 Ao($) 9 -1/2 [A'(t) - A'(s)] do(s) -'/2
A(8)) -1 ( z I -
Ao(s) 9 ~/2 ( z I Ba(t, s)
=
A o ( s ) ) A o ( s ) -1/2,
Ao(t) -1/2 ( z I - Ao(t)) ( z I - A(t)) -1Ao(t) 1/2 Ao(t) 9 -1/2 [A(t) - A(s)] Ao(s) -1/2. Ao(s) 1/2 ( z I - A(s)) -1Ao(s) 1/2 d9o ( s ) - ~ / e A ' ( s ) d o ( s ) - l / 2 ,
m o ( s ) ( z I - A ( s ) ) -~ ( z I - do(s))Ao(s) -Vg
Thus the lemma has been reduced to the following inequalities:
IlAo(t)-'/~ (zI
- Ao(t)) ( z I - A ( t ) ) -~ Ao(t)l/2ll <_ C,
IlAo(t)-l/2A'(t)Ao(t)-l/21l
<_ C,
< C It - ~1,
IlAo(t) -1/~ [n(e) - A(~)] no(~)-'/=ll
IIAo(t)-'/2 (zI - n ( t ) ) - ' (~I - Ao(e)) no(e)-'/=ll < C,
IlAo(t)
A'(~)] nol/=ll _< C l t - ~ l
~
They are direct consequences of (3.23), (3.25), and the following inequalities:
IA(t)l v,v, ~ C,
C -1 ~
C -1 ~ IIA0(t)Iv, v, < C,
I A'(t)llv, v, <_ C, A(t) - A(s)llv, v, < C I t - sl,
IIA'(t) - A'(.s)l v,v, < C I t - ,s ~. Details are left to tile reader. Now we show the following inequalities as consequences of Lemmas 3.3 and 3.1, where
9 ~ (0,1/2). A ( t ) -O~ A ( t ) -~ (9
(zI - A(t))
-1
0
- ~
(3.60)
<_ C o ,
( z I - A(s)) -1
A ( t ) o f f - - T A ( t ) - ' - A ( s ) o "ff-~A(s)- ~
< C It - s] ~ , < CI~ It -,sl "
(3.61) (3.62)
3.2. A Priori Estimates Proof of (3.60):
115
Inequality (3.26) (with a = 1) gives
l]A(t) ~ [A(t + e) -~ - A(t) -z]
tl -<
and hence (3.60) follows because
ate3A(t)_ ~ ---- 27rzl/r z-~-~c3 (zI -
A(t)) -1
dz
exists. P~oof of (J.61): If H is a positive definite self-adjoint operator in X, its spectral decomposition assures
IIH1/~ (zI - H)-~I _< c for z E E01. Inequality (3.61)follows from (3.59).
Proof of (3.62):
Noting
cOA(t)Z . A(t)_Z ' A(t)Z at~---A(t)-~ = cot we have
A(t)~ ff---iA(t)-~- A(s)~ ff---~A(s)-~ = - ata a(t)~. A(t)_ ~ + ff__~A(s)~.A(s)_ ~
[-~A(t)Z- osOA(s)Z] A(t)-z + CgA(s)3" A(s)-Z [IInequality (3.62) is reduced to
[ff---~A(t)~- ~sA(S)~J A(s)-~[[ < C~ t-s[ ~.
(3.63)
We have assumed the boundedness of A(t) so that (2.18) holds for any v E X. It follows that
8 A(t)Zv =
sin 7r/3 ]i~176Zc3
7r
1
tt -~ (#I + A(t))- v dl~.
If we apply Lemma 3.3, we get
sin7cflTr/o~176
(B-u(t's)A~
(pI + Ao(s))-lv, Ao(t) 1/2 (pI + Ao(t))-lx).
3. Evolution Equations and FEM
116 Inequality (3.63) follows from
( OA(t)~-~
--~sOA(s)~l C
(fOOO#Z3 [Ao(8)1/2
( # I --t-
A0(8))-1 '/)112)1/2
IlAo(t) ~/~ ( . I + Ao(t)) -~ ~[l~ d.
:
It -
sl ~
c~ IIA0(~)~llx. I~llx" t - ~1~
and (3.25). We are able to complete the proof of Lemma 3.2.
Proof of (3.58): We have Oq e_(t_s)A(t) A(t)-ZR~ (t, s) = - A ( t ) - z - ~0qe -(t-~)A(t) - A(t)-Z-~s
=
O -~
_
(A(t)_ze_(t_s)a(t) ) + A ( t ) l - . e_(t_~)a( t)
0__ A + ot ( t ) - "
=
e
-(t-s)A(t)
1 Ot 0 f_ 2m r z-Ze1
27r~
(t-s)z
(zI - A(t)) -1 dz
Jfr Z 1-~e-(t-~)z (zI
--
A(t)) -1 dz + -~ 0 A(t)_ ~ e_(t_s)A(t) 9
1 f~ z-Ze -(t-~)zO (zI - A(t)) - l dz + o__ Ot A (t)-z . e-(t-~)A(t) 2m Ot Therefore, the equality =
16
A(t)-~Rl(t's) - A(r)-~Rl(r's) = E Ze(t'r's)
g=12
holds with
Z12(t, r, 8) =
1 ofr z-~e -(~-~)z [e -
zla(t, r, z) -
1 Jfr 27rz
~e-(~-~)z [0-o-i (z: - A(t)) -1 - ~0 (ZI-- A(t))-lJ d~,
Z14(t,r,z)
=
Z15(t, r, Z)
:
Z'6(t, r, s)
=
0-t0A(t)_ ~ " A(t);~ -~r0 A(r)_ ~ . A(r)f3] A(t)_~e_(t_s)A(t) ~O
A(r)_ ~ A(r);' [A(t)-Ze -(t-s)A(t)- A(t)-Zc-("-s)A(t)],
O A ( r ) - " . A(r) ~ [A(t)-/~e -(r-s)A(t) - A(r)-~ -(r-s)A(r)] Or
3.2. A Priori Estimates
117
Here, we have
,•'0 ~
<
C
# - z e -(r-s)'c~176 (9t - r)# d# #
--
C/3(t-
1")(/--
<
C
p - Z e -(r-s)ac~176 . (t - r ) a d #
8)/5-1
and
IJZ'a(t,
r, s)
:
j~0~176 c~(t- ,-)~(r- s)~-'
Taking the adjoint operators in (3.62), we have
cot (t)-Z " A ( t ) z
A ( s ) - Z " A(s)Z
< Cz
It
- sl
This implies
]lz'4(t, ~, s)JI ~
A ( t ) - ~ . A ( t ) ~ - -~rA(r) -~
IIA(t)-~ll. 9 II~-('-~)A(~)ll s) ~.
_< G(tSimilarly, we have
}I~ at
A9( r ) ~
(t)-~ " A ( t ) z
-
and hence
9
[[A(t)-l~e-(t-s)A< t) _ A(t)-Ze-(r-s)Att)[[
C/~(t- r)(? ~ -- 8) ~-1 hdds by (2.19). Finally, inequality (3.56) is valid for/3 > - 1 and therefore
[IA(t)-Ze-(r-s)A(t) _ A(r)-~e-(~-sla(r)ll <
c~(t-
~)(,~-
~)~-'
follows. The proof is complete. Modifying the proof of Lemma 3.2 slightly, we have (3.54) with/3 = 0 and Zo(t, r, s) satisfying IIZ0(t, ~,
s)ll
<_
c ~ ( t - r)~(r - s) -~
for 0 < ~ < a. Combining this with (2.20), we get IIA(t)U(t, s) - A ( r ) U ( r , s)ll < G ( t
- r)~(r - s) - ~ - 1 + C~(t - r)~(r - s) -~
(3.64)
for 0 _< s < r < t _< T, where/3 E [0, 1] and ~c E [0, a). The proof is simpler and left to the reader.
3. Evolution Equations and F E M
118 3.3
Semi-discretization
As is described in w parabolic equation (3.1) with (3.3) (or (3.4)) and (3.2) is reduced to evolution equation (3.5) with (3.6). In the same way as in the preceding chapter, this equation is discretized with respect to the space variables x = (xl,x2). We triangulate f~ into small elements with the size parameter h > 0 and denote by Vh C V the space of piecewise linear trial functions. As before, Xh denotes Vh equipped with the L 2 topology. The operator norm II " Ilxh,x, is written as I1" II for simplicity. The m-sectorial operator in Xh associated with r h is denoted by Ah(t). Finally, Ph : X ~ Xh is the orthogonal projection. Then, the semidiscrete finite element approximation of (3.5) with (3.6) is given by duh --+ dt
Ah(t)Uh = 0
(0 < t < T)
(3.65)
with Uh(0) =
Phu0
in Xh. Because dim Xh < +oo and Ah(t)'s are smooth in t, they generate a family of evolution operators {Uh(t,S)}o
] Ah(t)Uh(t, S)ll + IlUh(t, S)Ah(S)ll <_ C ( t - s) -1 and
(3.66)
IIuh(t,~) l < c
hold uniformly in h for 0 < s < t < T. Here, the theories Fujie-Tanabe and KatoSobolevskii are applicable. The theory of Kato-Tanabe works also from the argument in w We turn to the error estimate for scheme (3.65). Employing the method of Helfrich, we show
Ileh(t)l x < Ch'2t-' '~011x
(0 < t < T)
for eh(t) = u ( t ) - uh(t), and extend the similar result of w introduced the error operator Eh = Eh(t, s) by
(3.67) For this purpose we
G ( t , ~) = u(t, s) - Uh(t, s)P,~. Obviously,
~h(t) = E,.(t. 0)..0 holds and inequality (3.67) is reduced to
IIG(t, s)ll < c h 2 ( t - s)-'
(o < s < t <_ T ) .
(3.68)
3.3. Semi-discretization Calculations of w equality
119 are valid even for temporally inhomogeneous generators. From the
O [Uh(t, r)PhEh(r, s)] = Uh(t r)[Ah(r)Ph - PhA(r)] U(r, s) Or follows
PhEh(t, s) =
~st Uh(t, r)[Ah(r)Ph
- PhA(r)] U(r, s) dr.
Introduce the Ritz operator Rh(t)" V ~ Vh through the relation (~r
x;, ~ v.).
(3.69)
The equality
Ah(t)Rh(t)v = PhA(t)v
(v E D (A(t)) C Vh)
holds similarly to (1.24). We have
Eh(t, s)
= =
[I - Ph] Eh(t, s) + PhEh(t, s) E~(t, ~) + EX(t, ~) + e~(t, ~)
with
E~(t, s)
=
E~(t, s)
=
E3(t, s)
=
/t
[I - Uh(t, S)Ph] [I -- Rh(t)] U(t, s), Uh(t, r)A~(r) [Rh(t) -- Rh(r)] U(t, s) dr, Uh(t, r)Ah(r)Ph [I - Rh(r)] [U(r, s) - U(t, s)] dr.
It sumces to show that
IIE~( t, ~)ll -< c h ~ ( E s t i m a t e of
t -
8)-1
( ( = 1,2,3).
E~(t, s)
We have shown inequalities (1.38) and (1.42) for v E V N H2(~):
II[Rh(t) - I] ~llv
<
II[Rh(t) - I] ~llx
<
Ch Ilvl ~.(~),
Ch~ll'~ll_,-,~(~).
Therefore, from the elliptic estimate follows that
[IE~(t,s)ll
~_ (I + l Uh(t,s)l I . IIPhll) . l[[I- Rh(t)]A(t)-lll . llA(t)U(t,s)l I ~_ C h 2 ( t - s) -1
(3.70) (3.71)
3. Evolution Equations and FEM
120
Estimate of E~(t, s) We shall show the inequality
ll[Rh(t)-/~h(S)]Vllx <--Ch 2 It- sl ~ IvllH~(a)
(3.72)
for v E V N H2(f~). Then it follows that IIE~(t,s)ll
_
IIUh(t,r)Ah(r)ll
tl[Rh(t) - R~(~)] A(t)-' l[" IIA(t)U(t, s)ll d~ <
c
( t - s)-l+~h~d~. ( t -
= Ch2(t-
~)-~
Ch2(t- s) -1. To show (3.72), we recall the adjoint form .A~('u, v) = .At(v, u), and denote by/~h(t) the 8)-1+ c~ ~
Ritz operator associated with it:
.,4; (,Oh(t)~, ~:h) : A;(v, ~:h)
(,, ~ v, ~,, c v,,).
The inequalities
ll[/~h(t)--/]vlIv~ ChlvllH~(~) and
I][~h(t) -/]vllx ~ Ch21v IH~(nl hold similarly to (3.70) and (3.71), respectively, where v C V N H2(~2). Setting z = [Rh(t)- Rh(s)] v E Vh, we have
llzll
= A, (z,
A, (z,
=
(At - As) ([1 - Rh(s)] v, [~h(t)A(t)*-lz)
=
( A t - Ms)([1-- Rh(S)] V, [/~h(t)- I] A(t)*-lz) + ( A ~ - A s ) ( [ I - R/~(s)] v, A(t)*-lz)
= ( A t - A s ) ( [ I - Rh(s)]v, [/~h(s)- I] A(t)*-lz) + As ( [ I - Rh(s)] v, [A(s) * - 1 - A(t) *-1] z)
:
(,At- ,As)([I- Rh(8)] "u, [il~h(8) - I]
A(t)'-lz)
+ .As ([I - Rh(s)] v, [I - Rh(s)] [A(8) *-1 - A(t) *-1] z)
_<
+ c I I [ / - Rh(s)] vllv I[[1 - ~h(S)] [A(s) * - ] - A(t) *-]] 6' It - sl ~ h 2 Ilvl g=(~) IA(t) *-'zl ,,=(.) + Ch 2 Ilvlln=(~) l] [A(S)*-I -- A(t)*-l] ~11.~(~)-
zll~
3.3. Semi-discretization
121
The elliptic estimate implies
IIA(t)*-x~llH~(~) ~ c Ilzll~ and
II [A(s) *-1 -
A(t) *-1] ZlIH2(a) -< C It - sl ~ Ilzllx.
Inequality (3.72) has been proven.
E s t i m a t e of E3(t, s)
First Case
If V = H~(f~), the duality argument of Helfrich is applicable and inequality (3.22) follows. For Uo E D ( A ( s ) ) =_ D we have
jfst IIUh(t, r)Ah(r)ll.
SO ollx
I11I -/~h(r)] A(t)-l[[
IlA(t)[u(t, 9 s) - U(r, s)] A(s)-lll <_ Co
=
(t - s)-lhg(t - r)~
- s)-~
IlA(s)uollx 9 ds
IIA(s)u01 x
Ch 2 IIA(s)uollx
with 0 E (0, c~). We can show
for g = 1, 2 similarly, from the second estimate of (3.21). (Details are left to the reader.) We have
IIEh(t, s)A(s)-~ll < Ch 2.
(3.73)
Now, the semigroup property of evolution operators implies
Uh(t, r)Uh(r, s) = Uh(t, s)
and
U(t, r)U(r, s) = U(t, s)
for 0 _< s _< r < t _< T. The identity
Eh(t, s) = Uh(t, so)PhEh(So, s) + Eh(t, so)U(so, s)
(3.74)
follows with so = (t + s)/2. The second term of the right-hand side of (3.74) is estimated as
IIE~(t,~o)U(so, s)ll
<_ IJE~(t, so)A(~o)-~ll'llA(so)U(so, <
C h 2 ( t - s) -1
s)ll
3. Evolution Equations and F E M
122 by (3.73). On the other hand, (3.69) gives [[Uh(t,S)PhEh(So, S)II =
[IU~(t, so)Ah(So)Rh(So)A(so)-XEh(So, s)ll
< [Iuh(t, so)Ah(So)Ph [Rh(S0) - I]A(so)-lEh(So, S)] + ]lUh(t, so)Ah(so)PhA(So)-IEh(So, s)ll C(t- s) -1 {] [/~h(SO)- I] A(8o)-1 I 9 IIE,~(~o,s)ll +llA(so)-lEh(so, s)[I}. Because IIEh(So, s)ll ~ c follows from (3.66), inequality (3.68) is a consequence of
]A(t)-lEh(t,s)l
<_ Ch 2.
(3.75)
To prove this inequality, let
U(t, s) = U ( T -
s, T -
t)*
(Ih(t, s) = Uh(T - s, T - t)*.
and
Then,
{U(t,S)}o
{U~(t,S)}o
and
are nothing but the families of evolution operators generated by A(t) - A ( T t)* in X and Xh respectively. The relation
Ah(t) = A h ( T -
l~h(t, s) = l~l(t, s) - [Ih(t, S)Ph = E h ( T - s, T - t)* follows. Because
I1E,,/,sIAl,/ 11 is proven similarly to (3.73), we get (3.75) as
I[A(t)-lEh(t,s)[I E s t i m a t e of
Eta(t, s)
= ]lEh(t,s)*A(s)*-l][
<_ Ch 2.
Second Case
If V = H I ( ~ ) , D ( A ( t ) ) varies as t changes. We cannot expect the estimate
IIA(t)U( t, s)A(s) -1]1 <- C or IIA(t)[U(t, s) - U(r, s)]A(s) -1 II -< Co(t - r)~ In this case, we apply the method of telescoping as
5
(t- ~)E,~(t, ~) : ~ F~(t, s) g=l
- s) -~
t)* and
123
3.3. Semi-discretization
with the following terms:
fs t (r - s)Uh(t, r ) A h ( r ) . Ph [I - Rh(r)] [U(r, s) - U(t, s)] dr,
F~(t, s)
=
F~(t, s)
=
(t - r)Uh(t, r ) A h ( r ) " [Rh(s) -- R~(r)] [U(r, s) - U(t, s)] dr,
F~(t, s)
=
(t - r)[Uh(t, s ) A h ( s ) -- Uh(t, r)Ah(r)]
f'
Ph 9 [I - Rh(s)] [U(r, s) - U(t, s)] dr, (r -- s)[U(r, s) - U(t, s)] dr,
F2(t, s)
=
--Uh(t, s ) A h ( S ) " Ph [I -- Rh(S)]
F2(t, s)
=
Uh(t, s ) A h ( s ) . Ph [I -- Rh(S)] (t -- s)
[U(r, s) - U(t, s)] dr.
We have to show that [IFeh(t, s)l I _< C h 2
(g = 1, 2 , . . . , 5).
(3.76)
Recall that Kato-Tanabe's generation theory is applicable to (3.5). Combined this with the elliptic estimate we can show the following for 0 _< s < r < t _< T, where 0 _
IlU(t, 8) - U(r, 8)IlL2(FI),H2(~2) ~_ C k { ( t - T)~(T -- 8) -~-1 -1- ( t - T)~(T -- 8)-1} , IlUh(t,r)Ah(r) -- U , ( t , s ) A ~ ( s ) l l
<_ Ck { ( t - r ) - ~ - Z ( r - s) ~ + ( t -
/s'
[U(t, s) - U(r, s)] dr
I[
L2(f~),H2(f~)
(3.77)
r ) - l ( r - 8)a},
(3.78) (3.79)
< C.
Those inequalities are proven in the following way. Proof of (3. 77):
Take u0 E L2(f~) and set u(-, t) = U(t, S)Uo. We have B(x,t,D)u(x,t)
=0
on 0f~ where 13 = O/Ovc + ~. This implies B ( x , t, D) (u(x, t) - u(x, r)) : [B(x, t, D) - B ( x , r, D)] u(x, r)
there. Similarly, we have
[A(t)U(t, s) - A(r)U(r,
s)] uo(x)
+ [s
r, D) - s
t,
D)] u(x,
r)
3. Evolution Equations and F E M
124
in f~. The elliptic estimate gives
II[U(t, ~) - u(~, ~)1 ~olIH~(~) -- I1~(', t) -- ~(., ~)11,~(~) <_ C I~(', t, D) (u(., t) - u(-, ~))11~(~) +C ILL(', t, D) (u(., t) - u(., ~))11,,,~(o~) <_ C I I [ A ( t ) U ( t , ~) - A(,~)U(r, ~)] ~o11~(~) +C I [L(', ~, D) - s t, D)] u(., ~)11~(~) +C lilt3(', ~, D) - B(-, t, D)] u(., ~) I1,,,,~(o~) <_ C I I A ( t ) U ( t , ~) - A ( r ) U ( , ' , ~)11" luoll~(~) + C ( t - ,~) I1~(', ~)11~(~) <_ C IIA(t)U(t, ~) - A(,~)U(, , ~)11 I1'~o11~(~) + C ( t - ,~)(~- ~)-' I1~o11~(~) Inequality (3.64)implies (3.77).
[]
Proof of (3. 78)" This is nothing but the adjoint form of (3.64) applied to A(t) = Ah(t) and U(t, s) = Uh(t, s). [] Proof of (3. 79): Letting u(., t) = U(t, S)Uo, we have s
s, D) (u(x, t) - u(r, x)) = [s
+ [s
x, D) - E(s, x,
s, D) - s
t, D)] u(z, t)
D)] u(z, r) + [A(t)U(t, s) - A(r)U(r, s)] to(Z)
in t2 and B(x, s, D) (u(x, t) - u(x, r)) : [B(x, s, D) - B(x, t, D)] u(x, t) + [B(r r, D) - B(x, s, D)] u(r r)
on cgf~. The elliptic estimate now gives [U(t, s) - U(r, s)] no dr
f'
H2(U)
<_ C(t - s)II[E(., s, D) - s
+C
I[s
r, D) - s
=
('u(-, t) - u(., r ) ) d r
t, D)] u(.,
t)JlL~(~)
H2(~)
s, D)] u(-, r)llL2(U ) dr
+C(t - s)I [~(., s, D) - B(., t, D)] u(-, t)ll,,/~(on) +C <
C ( t - s) 2
[A(t)U(t, s) - A(r)U(r, s)] uo dr
Ji'u(-, t)llu~(n) + C
(r -s)tl'u(,
II
r)liu~(~)
L'~(n) dr
~)11 ~o11~(~) + C IIU(t, ,~) - I I. I1~,o11~(~) <_ C ( t - ~) I uoll~,(~) + C I uoll~(~) ___C I1,,,o I~(,) 9 +c(t
- ~)IIA(t)U(t,
3.3. Semi-discretization
125
The proof is complete. Now the proof of (3.76) is given as follows. First, with/3 E (0, 1) we have
IIF ( t, )ll -< <
/s
- s)Ilgh(t,
IIU(~. ~) - u ( t . ~)l ~ ( ~ ) , ~ ( ~ ) dr
I9I I - R~(~)ll.~(~).~(~)"
C~h 2
8 ) ( t - T) -1
(r9{( t -
<
r)&(r)l
T)~(T -- 8) -~-1 + ( t -
T)~(r -- s) -1 } dr
Ch 2
and
jfs t (t - r)IIUh(t, r)Ah(r)ll
~
IIFZ(t, s)ll
U(t, ~)llL=(~),H~(~)dr
IIRh(~) 9 - Rh(~)l H=(~),L=(~)" IIU0", ~0 -
_< c ~ h ~ fS t (~ - ~) {(t - ~)~(~ - ~)-~-~ + (t - ~)~(~ - ~)-1} a~ <
C h 2.
Next, with 0 < "i' < ~ _
_<
r) l U h ( t , r ) A h ( r ) -- Uh(t,s)Ah(s)l]
(t-
III 9 -
R"(S) IIH=(~),L=(~)"IIU(t,
~) - U(~', ~) IIL=(~),H=(~) d,"
( t - T) { ( t - r ) - l - ~ ( r - 8) ~ Jr- ( t - r ) - l ( r -
C~h 2
8) ~}
{ (t - T)7(r - 8) -1-3' -Jr (t - T)m(r -- S) -1 } dr <
C h 2.
W i t h / 3 c (0, 1), we have
I[F2(t, )ll
s)&(s)ll.
Ilun(t,
III-
Rh(S)IIH=(~),L~(~)
9 IIg(t, s) - U(r, S)[IL2(a),H:(a)" (r -- s) dr
<_
C~(t- s)-~h 2 9
<
{( t -
~)~(~ - ~ ) - ~ - 1 + ( t -
~)~(~-
~ ) - 1 } (~ _ ~) d~
C h 2.
Finally, we have [IF2( t, s)ll
_<
IUh(t,s)&(s)
9 <
C h 2.
liRa(s) 9 - IllH~(~),L~(~)
[u(~, ~) -
u(t,
~)] d~
L2(~"/),H2(n)
3. Evolution Equations and F E M
126 Summing up those estimates, we obtain
IlE2(t,~)ll <_ ch~(t_ ~)-, All the proof for inequality (3.68) is complete.
3.4
Full-discretization
Fully discrete approximations are obtained by discretizing the semidiscrete equation
duh dt
+ Ah(t)Uh = 0
(0 < t <_ T)
with
Uh(O) = Phuo
(3.80)
in the time variable t. In the present section, we adopt the backward difference method with the mesh length r > 0 satisfying T = N r . T h a t is,
U~h(t + r) -- U~h(t)
+ Ah(t + r)u,~(t + r) = 0
(t = n r )
(3.81)
in Xh with
~,~(o) = P~,o, where n = 0, 1,-.- , N. Thanks to (3.14), tile scheme is uniquely solvable and
e~h(t) = u h ( t ) - U,;(t) denotes the error, where t = nr. we shall derive
Id,(t)llx _< c~-t-' luol x and extend a result in w
(3.82)
Combining (3.82) with (3.67), we obtain
u(t) - u;(t)l x < C (h? + r) t-~ I 'uo Ix
(t = n r ) .
(3.83)
Let t,~ = nT and set
U[~ (tn, tj) =
{ ( / h + TAh(tn)) -1 (Ih + TAh(tn-1)) -1"'" (Ih + TAh(tj+l)) -1 Ih.
We have ~,;(t) = ui:(t, o)&~o
(t = t,,)
and
,,,,, ( t ) = u,, ( t, 0)P,,,~,o.
(~ > j) ( ~ = j).
3.4. Full-discretization
127
Drop the suffix h for simplicity of writing. Because of (3.80) and (3.81), we have for t = tn that
e ~(t + r) - e r(t)
tnt-r
f f
=
[A(t + r)u r(t + r) - A(r)u(r)] dr
at
=
t+r
[A(t + r)u(t + r ) -
A(r)u(r)] d r - r A ( t + r)e" (t + r).
,It
Hence
er(t -+- 7) = (1 + r A ( t + "r) )-l er (t) + (1 + r A ( t
+
T)) -1
f
t+r
[A(t + r)u(t + r ) -
A(r)u(r)] dr.
Jt
Because of e ~ (0) = 0 we obtain
e ~(tn)
-- E ~(tn)Puo =
(I q- 7A(tn)) -1 (I + "rA(tn_l)) - 1 . . . (I + TA(tk)) -1 k--1
-1
[A(tk)U(tk, 9 O) - A(r)U(r, 0)] drPuo,
(a.s4)
Er(t) being the error operator: E ,(t) = u(t, o)P - u ~(t, o ) Inequality (3.82) is reduced to those on the stability of the approximate operator U r (tn, tj+l) and the smoothness of the original one A(t)U(t, s) - A(r)U(r, s). We have proven Lemma 3.2 for the latter. As for the former, we have the following lemma, proven similarly to the continuous case: L e m m a 3.4. For each/3 E [0, 4/3), the inequality
II
tj)A(tj+l)Zll <__Cz(tn - tj) -~
(a.85)
holds true. Proof." Taking adjoint form reduces inequality (3.85) to I A(tn)ZU~(tn, tj)l] <__Cz(tn
-
tj) -~,
of which continuous version is proven in w
IIA(t)ZU(t, s)ll<_ Cz(t- s) -z All we have to do is to trace computations
in the context of discreteness.
(3.86)
3. Evolution Equations and F E M
128
In fact, inequality (3.26) holds for A(t) = Ah(t) uniformly in h as is described there. Identity (3.30) holds for A(t) = Ah(t) so that we obtain
U'(tn, tj) - (1 + rA(tj)) -(n-j) =
~
[(1 + ~-A(t~))-(~-k)U'(tk, t j ) - (1 + 7A(t~))-(n-k+l)U'(tk_x,tj)]
k=j+l
=
~
(1 +7-A(tn))-(~-k+l) [(1 +~-A(tn))- (1 +~-A(tk))]U'(tk, ty)
k:j+l
= T ~ (1 + rA(tn)) -('~-k+~) [A(tn) - A(tk)] U~(tk,tj) k=j+l = ~p=l
(1 + 7A(tn))-(n-k+UA(tn)l-PPD(tn, tk)A(tk)PPVr(tk,tj).
~
(3.87)
k=j+l
Given operator-valued functions fit = Ke(tn, tj) with t~ = 1, 2 on
D r={(t~,tj) I N>_n>_j>_O}, we define K = K1 .r /42 by n--1
(K1 *~ K2) (tn, tj) = ~- Z
Kl(tn, tk)K2(tk, tj).
k=j+l
Furthermore, we set
WT(t~,tj) Y~(rn, tj)
= Ur - (1 + TA(t~)) -(~-j) = A(t~)qPWT(t~,tj).
(3.88) (3.89)
Then, equality (3.87) reads: m
Yq = E p=l
H q~p , ~- U + Yq,~O,
(3.90)
where
Hq~p(t~, tj)
= A(tn)I-pP+qP(1 + ~-A(t~))-(~-J+l)D(t~, tj),
(3.91)
m ,0
=
,p
,- 1
(3.92)
p=l
with
Yp~_l(t,,,tj) = A(tn)PP(1 + TA(tn)) -(''-j)
(3.93)
Note the elementary inequality (3.94). The desired inequality (3.86) can be derived in a similar way to that in w
3.4. Full-discretization
129
Details are left to the reader, but the following inequality is worth mentioning, where
O < a
B N(a, b) - -~1 k=l
1
- -~
< S(a, b) =-
/o (1
-
-
x)a-lxb-ldx.
(3.94)
In fact, f(x) = (1 - x)a-lx b-1 is monotonically increasing in [0, 1) when b _> 1 _> a, while f(x) is convex in (0, 1) when a, b _< 1. Those facts imply (3.94). [] We are able to give the following.
Proof of (3.82):
E~(tn) =
The operator E ~ in the right-hand side of (3.84) splits as
n~k
(1 + ~-A(tn)) -1... (1 + TA(tk))-lA(tk)[e -tkA(tk)- e -rA(tk)] dr
E k=l
-1
(1 + rA(tn)) -1... (1 + rA(tk))-lA(tk)~Z~(tk, r, O) dr
+ k=l
=
-1
(1 + TA(tn))-lA(tn)
[e-tnA(t~) - e -rA(t~)] dr --1
+
Ur(tn, tk_l)A(tk)[e -tkA(tk)- e -ra(tk)] dr k=l
-1
~
+~
k=l
U'(tn, tk_l)A(tk)ZZz(tk, r, O) dr.
(3.95)
-1
Inequality (2.19) is applied to A = Ah(r) uniformly in h. We have for n > - 1 that
[IA(r)~[e -tA(~) -~-~A<~>]II C (t- s)s -n-l,
(3.96)
where 0 < s _< t < oc. Supposing n > 2, we can estimate the first term of the right-hand side of (3.95) as
[1(1 + TA(t~))-lA(tn)ll
~
n
lie -t~A(t~) - e-~A(t~)ll dr
--1
CT
( t n - r)r-~dr <_ CT-1T2(tn-1
-1 --1
~ Crt-
3. Evolution Equations and F E M
130
Next, by Lemma 3.2, the third term of the right-hand side of (3.95) is estimated as
k~l
Ilg~(t~,t~-l)A(t~)z[I
--1
< C a k1= ~
IIZz(tk, 9 r,O)ll dr
-, (tn - tk-l)-Z(tk -- r ) r - l + Z d r
n
___ c~ ~ ( ~ -
k + 1 ) - ~ - ~ ( k ~ ) ~-'
k=l n = c~
Z(~
- k + 1)-~k ~-1
k=l Inequality (3.94) now gives that
~~ IIg'(t~,
tk_l)A(tk)Zll ]lZz(tk, 9 r, O)l I dr <_ CT. k=l The desired inequality (3.82) has been reduced to
fi'
,11
To see this, take/3 C (0, 1/3). We get
n En-1 o~tl k U~(tn, tk_l)A(tk) k=l
[e - t k a ( t k )
- e -~A(tk)] dr
-' n-1( n = E k + 1)UT(t~, tk_l)A(tk) 1+'. ~tlk A ( t k ) - ' [e -tkA(tk) --e -rA(tk)] dr k=l -1 n-1
+ E(k
- 1)UT(tn, tk_l)A(tk) '-~
k=2 9
A(tk) ~ [e -tkA(tk) - e -rA(tk)] dr.
(3.98)
-1
The first term of the right-hand side of (3.98) is estimated by Lemma 3.4 and (3.96) as
n-1 ~-~.(n-k+ 1) llUT(t,~,tk_~)A(t~)'+Zll. ~t.lk IlA(tk) -~ [et~A(t~)--e-~A(t~)]l I dr k=l
-1
_< Cr Z ( r t - k + 1)-'T - 1 - ' ~t.lk (tk -- r)r'-idr k=l -1 n-1
rt-1
< C/3 Z ( ~ 9 , k=l
]~:-J-- I)-~qT -1-/~ T2(~T)/9-1 9
rt
:
Ca E ( n k=l
If + 1 ) - ' k '-1 _< C.
131
3.5. A l t e r n a t i v e A p p r o a c h
Similarly, the second term of the right-hand side of (3.98) is estimated as
n-1 E(kk=2
1)IIU~(t~,tk_l)A(tk)l-~ll. _< C 0
n-1
( k - 1)(tn - t k - ,
k=2 rz-1 _< c , ~ ( k k=2 n-1 < Cr E ( k k=2
/i k -1
)-1+/~
IIA(t,)~
9
[~-~(~)- ~-~(t~)] II d~
(tk - r ) r
-/~-1
dr
-1
- 1 ) ( ~ - k + 1) -1+~ ~-1+~. 9 ~ . ((k - 1)~) -~-~
- 1)-r
k -+- 1) r
< C.
The proof is complete.
3.5
Alternative
Approach
Inequality (3.83) is proven in a different way by the energy method. In this section, we describe the arguments of M. Luskin and R. Rannacher for the semidiscrete approximation and M.Y. Huang and V. Thom~e for the fulldiscrete approximation, respectively. A Priori Estimates
First, we show some estimates concerning the solution of the equation du d--7 + A ( t ) u = f (t)
with
(0 < t < T )
u(0) = ,to
(3.99)
in a Hilbert space X over R. Here, A ( t ) is an m-sectorial operator associated with a bilinear form At( , ) on V x V through a triple of Hilbert spaces V C X C V*. We suppose
I.,4t(,< ~)1
<
C1 Ilu Iv IIv Iv
and
.a~(~, ~) > 5 II~ll~-
(3.100)
for u, v E V, where C 1 > 0 and 5 > 0 are constants. It is also supposed to be smooth so that oq A (u, v)
and
02
exist and satisfy
IAt(,
and
A~(,~, ~)1 ~
c
I1~11~Ilvllv
132
3. Evolution Equations and F E M
for u, v C V. Problem (3.99) admits the weak form (Ut, ?J) + .At(u , v) ~- (f(t), v)
(3.101)
for v C V, where ( , ) denotes tile inner product in X. This implies (Utt , 72) nt- .At(ttt, v) -- - A t ( u ,
v) -nt- (It(t), v).
(3.102)
/0
(3.103)
We have the following. P r o p o s i t i o n 3.5. The inequality
Ilu(t)ll 2x +
/0
Ilu(s)llv~ ds _< C I1~oll ~x + c
IIf(s)ll~.ds
hold, fo~ th~ ,ol~t~o~ ~ = ~(t) of (S.99).
Proof: Putting v = u(t) in (3.101), we h~ve ld
2 dt Ilu(t)ll~ + 5 Ilu(t)ll~ _< Ilf(t)llv. Ilu(t)llv by (3.100). Then, Schwarz's inequality gives
-
and
d dt Ilu(t)ll2x + l u(t)llv2 < C Ilf(t)l 2v. -
_
inequality (3.103) follows.
[]
Letting .A;(u, v) = .At(v, u) and A ~ = (.At + .At)/2, we suppose that
v) + (B(t)u, v)
.At(u, v) = A~
(3.104)
holds with a bounded linear operator B(t) : V ~ X. This assumption is satisfied if .At(, ) is associated with a second-order elliptic operator with real coefficients. We have the following. Proposition
3.6. The inequality
ilu(t)ll 2v +
/0
Ilu~(s)llx2 ds _< C Iluoll 2v + C
/0
f(s)l
x
ds
holds for the solution u = u(t) of (3.99). Proof: Putting v = ut in (3.101), we have
Ilu~ I~ + A~(u, u~)
= (f,
Ut)
< --
1 2 1 ~ II/11X + 2 Ilu~ I~
"
On the other hand, equality (3.104) gives
1d
1
.At(U, Ut) = -~--~.At(U, U) -- = A t ( U , U) nrZ
1.B.t.u,( ( )
Ut)
Q
(3.105)
133
3.5. Alternative Approach
Those relations imply lutll x~ + ~dA , (u, u ) <_ C I/ll x~ + c I1~ Iv. Then, inequality (3.1o5) follows from (3.100) and (3.103). P r o p o s i t i o n 3.7. The inequality Ilu,(t)l x~ +
/o
I~,(s)llv~ ds _< C Ilu~(0)ll x2 + C l'~o I.~
(If(s)I~,. + II/~(~)11~v*) ds
+ C
(3.106)
holds for the solution u = u(t) of (3.99). Proof." Putting v = ut in (3.102), we have
ld 2 dt I1~'11~ + 61~,11~, < -<
c II~llv I1~ Iv + f~llv. I~1 v 1
-~11~ ~v + C' I1~ Iv~ + C IIf~llv* 9 2
This implies
Ilu~(t)ll ~x +
/o
Ilu~(sDllv~ds_< II~,(o)ll~ + c'
/o
II~(~)ll ~vds +
c
/o
II/t(s)ll~.
ds.
Then, inequality (3.106) follows from (3.103). P r o p o s i t i o n 3.8. The inequality
/0
s ~ Ilu,(s)ll~, ds _< C Iluoll.~ + c
ji
(ll/(s)[Iv. + II/~(s)ll 2v.) ds
holds for the solution u = u(t) of (3.99). Proof: Putting v = t2ut in (3.102), we have
ld 2 dt (t2 I]utl]~.) + 5t 2 Ilu, ll ~v < - ? A , ( ~ , u,) + t I1~11x~ + t2(ft, ut) -
-
v + c II~llv + t II~ll~ + ~t ~ II~,ll~, + c II/~ll 2V. 9
This implies d~ (t2 I[ut[ ~) +
I[ut][y _
g + t II~,llx + c IIf~ll~.
(3.107)
3. Evolution Equations and FEM
134 and the inequality
/o
s ~ Ilut(s)ll*v ds _< C
/o t (ll~(s)ll~
+ s lut(s)12x + lift(s)Iv*) ds
(3.108)
follows. Next, putting v = tut in (3.101), we have
t i1~,11~x+_did (tAt(u, for c > 0. The inequality
jot
II~t(~)ll ~ d ~ <_~
u))
--
At(u, u) -t- .At(u, u) -t- At(tut, u) -t- (f, tut)
-<
~t ~ll~t ~v + c~ II~llv + c~ IIf I~.
/~t
~ II~t(~)llv~ d ~ + C ~
jot (11~(~)11'v +
If(~)ll~.)d~
follows. Taking e > 0 small enough and combining this with (3.108), we have
/o s21lut(s)ll~ds c /o { Ilu(s)ll~ + II/(s)I~. + IIf,(s)I~. } ds. _<
Then, inequality (3.107) follows from (3.103). Proposition t llu,(t)ll~ +
3.9. The inequality
i
X
t
II~.(s)ll ~ ds <
c ilu,(o)ll x~ + c II~ollx~ + c
/o'
(llf~(~)llx~ + IIf(~)llv.) d~ (3.109)
holds for the solution u = u(t) of (3.99). Proof." Putting v
~-- Utt
in (3.102), we have
IlUttll 2X -Jr-,At (ut, utt) : -At (u, utt) + (ft, tttt).
(3.110)
Here, note that
12ddt.At(ut, ut) = < - At (.tz, tttt)
.At (ut, uu) + ~1 At (ut, ut) + 1 (But,
r
?ztt) + C I1..,11~
1
Utt)
2
d 9 ~-- - d--iAt (11., ?zt) -~- At (.~z,"~l.t) + At (ut, ut) <
-
d dt
A,(,~, .,~,) + c I1,,, } + c
ul ~v ,
135
3.5. Alternative Approach and 1 We obtain
d d &(~, ~,,) -< C I~,1 ~ + CII~I ~ + CIIf, ll~ u.ll~: + aTA,(~,, u,)+ ~7 Multiplying t now gives that
'(
)
t lluttll2x + -~t A~(u~, u~)+ At(u, ut) -< c(t +
1)(llut]l
2v + I~1 ~ +
Ift I~)-
This implies
tA~(~,~) +
/o
~ll~,(411~ <_ c
/o
(ll~,(~)llt + 11,,(~)115 + IIf~(~)ll~) d~.
Inequality (3.109)follows from (3.103)and (3.106). Semidiscrete Approximation Let fZ C R 2 be a convex polygon, and A t ( , ) a bilinear form on V x V with V = H~(f~) (for simplicity) induced from a second order elliptic differential operator. The associated m-sectorial operator in X -- L2(f2) is denoted by A(t). We take the evolution equation
du + A ( t ) u = O (O < t < T) dt
with
u(0)=u0
with
uh(0) = PhUo,
and its semidiscrete finite element approximation
duh d--T- + Ah(t)Uh = 0
(0 < t < T)
described in w and w respectively. Now we develop the error analysis by the energy method. Recall t h a t Rh = Rh(t)" V ---+Vh denotes the Ritz operator associated with At( , ):
At(Rh(t)v, Xh) = At(v, Xh)
(v e V, Xh r Vh)
(3.111)
We have the following. L e m m a 3.10. Any v = v(t) c C 1 ([0, T] --+ V) satisfies the inequality
Ila~(v- nhV)llH,(~) <_ Ch ~-j (llv g~(~)+ IIV~IIH~-,(~>) fork
1,2 and j = 0 , 1 .
(3.112)
3. Evolution Equations and F E M
136
Proof." Equality (3.111) implies
.A~(a,(v - R,,v), x~) = -A,(,, - R,,~. x~)
(3.113)
for Xh E Vh, and hence
a l a~(v - R~v)ll~
~
.At (oqt(y - R h V ) , Ot(v -- f~h'U))
--
.At (Ot(V -- R h V ) , Otv -- Xh) -- A t ( v -- R h V , Xh)
___ c (lla,(v follows. T h e results in w
Rhv)liv Ila~v
-
- xhll,,,. + IIv - Rhvllv
Ilxhllv)
are summarized as
II(Rh(t)-
1)v g,(n) <--
Chk-Jll~llH~(n)
(3.114)
for k = 1,2 and j = 0, 1. Taking Xh = Rh(t)Otv(t), we get (3.112) for j = 1 and k = 1,2. The remaining case j = 0 is obtained by the duality a r g u m e n t similarly, in use of (3.113) and the elliptic estimate of A(t). It is left to the reader. [] Suppose u0 E V, and take the solution Uh = gh(t) E Xh of duh
dt
+ Ah(t)gh = O (O <_ t <_ T)
~(0) = R~(0)~0.
with
We have the following. Lemma
3.11.
The inequality
Z
~ II~h(~)ll~-d~ ~
Ch~l ~o11~"
(3.115)
holds for -eh = u -- Uh. Pro@
We have
(9~,,, x,,) + A~(~,,, xh) = 0 for Xh E Vh. Taking Xh = Rh(t)-eh(t), we get ld
2dtll~hll~c+ A,(~h,~h)
=
(0,~h, (1 - Rh)-~h)+ At (eh, (1 -- Rh)~h)
=
(ateh, (1 - Rh)'U) + .At (-eh, (1 -- Rh)'U)
(
<_ c~ h~ I1,~11~(~) + Ila,~,~llx
) +cllehllv
for c > O. This implies
d -dt
1~,,112 x + -~hl ~ _<
Ch ~
( I1~11~,-,~(~)
+ Ila~,,llx
)
137
3.5. A l t e r n a t i v e Approach
by (3.100), and hence
/0
II~h(~)ll ~V dx
<
Ch ~
<_ c h ~
I1~(~) .:(~) + IIO~h(~)ll
ds + II~h(o)llx
II~(s)
+ ch ~ ~ol follows. The elliptic estimate gives
Ilu(s)ll/_z~(r~) < c IIA(~)~(s)Ix : c Ilu,(~)l x, while inequality (3.105) of Proposition 3.6 is valid for u = Uh uniformly in h. The righthand side is further estimated from above by ch ~
(11~ol ~ + IIRh(0)~oll~) <
Ch ~
I1~o
and the proof is complete.
[]
If one assumes the inverse assumption, L 2 orthogonal projection Ph " X ~ X h satisfies
llPhllv_v <_ c
(3.116)
by Proposition 1.5. Then, the inequality
fo ~ II~h(~)tl ~V d~ < is proven in a similar manner, where eh = u assumed in the following lemma.
Ch ~
I1~o11~,
Uh. However, inequality (3.116) is not
L e m m a 3.12. I f uo E V A H k - J ( ~ ) we have
~0 t II~h(~)ll x~ d~ <-
c t l - J h 2k
Iluo
2
,
(3.117)
9V)
(3.118)
where k = l , 2 and j = 0 , 1 . Proof:
Given t > 0, we take the backward problems (v, O~w) - A~(v, w) = (v, e~(s))
(v
with w(t) = 0 in X and
(x~. 0 ~ , )
- As(X,. ~ , ) = (x~. ~,.(~))
(x~ e v~)
with wh(t) = 0 in Xn, respectively. Those problems have unique solutions w = w(t)
9 C O([0, t), D (A(t)*)) A C O([0, t ] , X ) n C ~ ([0, t ) , X )
3. Evolution Equations and F E M
138 and
~
= ~(t)
~ c ' ([o.t]. x h ) .
respectively. In spite of the inhomogeneous terms in the right-hand side, the argument in the proof of Lemma 3.11 is applicable with the time variable t reversed. A quick overview reveals that
/o'
w(~) - w~(~)l ~. d~ _< C h ~
Combining this with inequality (3.105) implies that
L
' (llo~(~)-
<-
(21a, w,,(~) ~x + 2 IIO, w(~)llx~ + h -~ IIw,.(~) - w(~)ll~) d~
< c
--
I~,(~)1 ~ d~.
h-2 II~(~) - ~ , ( ~ ) l l ~ ) ds
o.~,.(~)+
/o' 1'
/o'
Ile,(s)ll ~ ds.
(3.119)
X
Taking v = eh(s) in (3.118), we have
II~,,(s)ll%
=
(e~(s),O~w(~)) - A~(~,,(s),w(s)) {(~,,. o ~ ( ~ - ~ , , ) ) - .4s(~. ~ - w,,)} + ( ~ , , . O s ~ , , ) -
..4~(~,,.w,,).
Here, eh = ( u - RhU)+ (Rhu- uh) and
(~,,. o~(w,,- ~)) - .4~(x,,. ~ , , - ~) = o holds for Xh E Vh. It follows that
I~,(~)11~
=
{(~-
~,,~. o ~ ( ~ - ~ , ) ) - A s ( ~ - R.,,~. ~ d + ~ (~,,. ~ ) - ( o ~ . w~) - .4~(~,,. ~ ) .
~,,)}
Furthermore, the equality
(O~eh, Xh) + A~(Ch, Xh) = 0 holds for Xh E Vh. W e have
I1~(~)11 ~x = ( ~ - R,,,~, o ~ ( w - w , , ) ) - A ~ ( ~ - R ~ , ~ -
d
w,,)+ y~ (~,,, ~,,).
In use of e,,(0) = wh(t) = 0, we h a v e
/0'
II~,,(~)ll ~X ds = _
/o' ]o'
( ( ~ - ~,,~,, a~(w - w , , ) ) -
~
A ~ ( u - R,,~, w - w,,))d~
(llOs~ - a~,,,,,, ~ + t,, -~ w - w , ,
+ c~
/0'
I~)d.~
(I ~ - ~,,,~11~ + h ~ I1,~- ~,,,~11~)d~
(3.120)
139
3.5. Alternative Approach
for c > 0. We obtain
/o
I I ~ ( ~ ) l l ~ d ~ -< C
/o
(ll**-Rh~ll ~~ + h ~ I1~- R ~ I I ~ ) d ~
by (3.119)and (3.120). Inequality (3.117)follows from (3.114). As is described in w
the following theorem implies Ileh(t) x <-- Ch2t-1 Iluollx
by Helfrich's duality method. T h e o r e m 3.13. If Uo E V r~ H 2 (f~), the estimate le.(t)llx < CA ~
luo H~(~)
(3.121)
holds true. Proof." Putting = [(t)= Rh(t)eh(t)= Rh(t)u(t)-
Uh(t) E Vh,
we have ({t, ~) 2t r
~)
--
(Ot(t~hU), ~) -- (OtUh, ~) Jr- r
=
(at(Rhu), ~) - (atu, ~) -(a~(~ - R~), ~).
:
~) -- At(Uh, ~)
Multiplying t implies
1 d (t I1{11~)
2 dt
1 t~t,(~, {) = ~ I1{11~ -
+
t(at(u
-
Rhu)
~)
and hence
t ll{(t)ll~: < c --
J/o'
I1{(~)11~ d ~ + C
f'
~ Ila~(u- R~u)(~)lt ~ d~ X
follows. We obtain
t Ileh(t)ll 2X -< t l l ( u - Rhu)(t)ll~: + C + c
/o
Ile~(s)ll~ d~
I I ( u - R~u)(~)ll~ d~ + C
jo
~ Ila~(u- R ~ ) I I ~ d~.
Here, Lemma 3.10 applies. We get
t lleh(t)ll 2X <- C foot Ileh(s)llx2 ds + Cth 4
{
max [[U(S)IIH2(~) + O
)}
8 [[U(S)IIH2(~) + [[Ut(8)[[ 2u~(n) ds
140
3. Evolution Equations and F E M
For the right-hand side we have
fo' I1~(~)11~ d~ X
< --
C t h 4 I1~o11~(~)
by (3.117), and also
I~(~) IH~(~) _< c II~oll.~(a) and
Jo"(
u(~)ll ~
)
~
d~ < C I ~oll ~
by Propositions 3.7 and 3.9, respectively. Inequality (3.121) now follows. Full-discrete
Approximation
The energy method is also applicable to the error analysis for fully discretized problems. Here we study the backward difference finite element method,
~;(t + r - ~ ( t ) T
+ Aj~(t + T)U "(t h + ~) = 0
with
~;~(o)
=
Phi0,
w h e r e t = t n f o r 0 _ < n < N. We drop the suffix h, and the error is denoted by e(t) = u ' ( t ) - u ( t ) .
The inequality
L e m m a 3.14.
n--1
t 2 Ile(t)ll x2 < - c~ -2 I~011x~ + Cr ~
IIe" (tj)llv.2
(3.122)
j=l
holds for t = tn. Proof:
Given v = v(t), we put
Otv(t) = v(tj) - v ( t j _ l ) T
for t = tj with j _> 1. We have (ut, v) + At(u, v) = 0
and
(O~u~,v) + A~(u ~, v) = 0
for v E V and t - tj. It follows that
(Ote(tj), v) + At3 (e(tj), v) = (Tj, v) ,
(3.123)
3.5. Alternative Approach
141
where
1 f~~, 1 (~_ "~j = Otu(tj) - ut(tj) = -~
tj_,)~.(~) d~
(3.124)
Putting ~(ty) = tje(tj) and ~j = ty3'j, we get
(Ote(tj), v) 4- At3 (e(tj), v) = (~j 4- e(tj-1), v) . Letting v = ~(tj) now gives that
1 (~(tj) - e(tj-1), ~(tj)) 4- Atj (~(tj), ~(tj)) = (~j 4- e(tj_l), ~(tj)). T In other words, the inequality 1
:2 (ll~-(tj)ll~-II~(tj
-
12) 4- TAt, (~(tj), ~(tj)) = T (X/j 4-
- 1)112 x + r 2 IIO~(tj)
e ( t j _ l ) , e(tj))
holds and we obtain ila(tj)ll ~x - I I ~ ( t j - 1 ) l l
~ + 2 w ~ l ~ ( t j ) l l ~V X
<_ 27 (Sj 4- e(tj_l), ~(tj)) < 2~- { c (llgjll ~v . + I l e ( t j - 1 ) l l v ~. )
+ ~
-
Ila(tj)llv}
9
We have II~(tj)ll X ~ - I l e ( t j - 1 ) l l x<- 2Cw ([l@jl[~. + Ile(tj-1)[2v.)
and hence
t 2 Ile(t,)llx = II~(t,)lI2x <__2 c T
tj 1l'TjIlv. + j=l
Ile(tj)lIv 9
{3.125)
j=l
follows. Equality (3.124) implies ii,),jll2 _~ 1 T
/t;
' (8 - t j _ l ) 2 Ilutt(8)ll 2. d8 1
and hence tj II~jll..
follows because t y ( s with f = 0 implies
_
ftj 'j--1
..
tj-1) <_ Ts for s E [tj-1, tj]. On the other hand, equality (3.110) IIuttllv. < Cllutllv + CIlullv.
(3.126)
3. Evolution Equations and F E M
142
Therefore, we get
n
2
2
< ~-~
j=l
j~0tn
-< c wi
~ I1~.(~)111 V* d~
/o ' (ll~(~)ll~+s ~ll~r
_ cw 2 Ilu011~
by Propositions 3.5 and 3.8. Inequality (3.122) is now a consequence of (3.125). For the operator T(t) =_ A(t) -1, the relation Ilfllv.
~
IIZ(t)fllv
(f ~ Vh)
holds uniformly in h. In use of T'(t) = - A ( t ) - l A ' ( t ) A ( t ) - l ,
I Z'(t)fllv <_ C
Ilfllv.
we have
9
In terms of T(t), equality (3.123) is written as
T(tj)Ote(tj) + e(tj) = T(tj)3,j. Setting Fj = T(tj)~,j, we get
Ot [T(tj)e(tj)] + e(tj) = Fj + [OtT(tj)] e(tj_l). Here we take L 2 inner product with T(tj)e(tj).
We have
(T(tj)e(tj), e(tj)) ~ I e(tj)l
~.
and
(Ot [T(tj)e(ty)] , T(tj)e(ty)) 1 = 2T (llT(tJ)e(tJ) 12X - I l T ( t j - l e ( t j - 1 ) I x
+ 7-IIOt [T(tj)e(tj)]llx),
as in the proof of L e m m a 3.14. It follows that
_1 2
(llZ(ty)e(tj)ll 2x --[IT(tj -1 )e(tj_ 1 )1 2x + ~ II0, (T(tj)e(tj))ll 2 ~) 2 x / + ~ I~(tj)llv. 7<_ Ilrjllv. IIT(tj)e(tj)llv + II[O~T(tj)] e(t~_l) x IIT(tj)e(tj)l x
with a constant # > 0. The right-hand side is estimated from above with some t, 6_ (tj_l, tj)"
I FjlIv. IIT(tj)e(tj)llv § IIT'(t,)e(tj-1)llv T ( t j ) e ( t j ) I x _< c (IIFjlIv. e(tj)llv. + Ile(tj-,)l v. IIZ(tj)e(tj)l x) 1
2
2
_< -~. (lle(tj)llv. + I e(tj_~)llv.) + C (llT(tj)e(tj)ll 2X + IIFj I~*).
(3.127)
Commentary to Chapter 3
143
We obtain 1
9
3
1
2
2
2
+ ~ - , (If~(tj)lf v. -II~(t~- ~)11~.) _< c~- (llT(tj)~(t~)fl~ + Ilrjlt~.) and hence
]]T(tn)e(tn)]] x2 + ~ s
II~(tj)ll~. -< c ~ s
j=l
Ilrjll ~v.
n + c~- ~lf(tj)e(tj)ll2x
j=l
j=l
follows. Then the discrete Gronwall's inequality implies that n
IIT(t~)e(t~)llx + f
Ile(tj)ll V* 2 <- - CT ~ j=l
Ilrjll 2V*
"
(3.128)
j=l
Here, Schwarz's inequality gives JIFjll2v.
IIZ(tj)'~jll~. < 1__
-
T
~ (s - tj_~) 2 ]lZ(tj)u~(s)l[~. ds 1
similarly to the proof of Lemma 3.14. On the other hand, T(t)ut + u = 0 implies
T(t)utt = - u t - T'(t)ut. Therefore, given s E [tj-1, tj] there exists s. E (tj-1, tj) satisfying
<_ Ily(s)utt(s)llv. + f IlY'(s,)u,(s)lIv. _< Ilu~(s)llg. + IIT'(s)~,(s)ltv. + w IlT'(s,)utt(s)llv.
IIT(tj)u,(s)llv.
<__ c (ll~(~)llv. + II~,(~)llv + ~ II~,(~)llv.). In use of [lutllv. = I A(t)ullv.
< C I1~11~, w~ h~v~
IIT(t~)~.(~)llv. <
c
(ll~(*)llv
+ ~
II~,(*)llv)
by (3.126). Consequently, the inequality
~ - ~ Ilrjll ~. _< C j-1
j=l
-1
(~- tj_~ (11~(~)11~+
-<
c~ ~
<
c w 2 IIPu0112
--
(ll~(s)ll =v +
I1~(~)11~)d~
~ Ilu,(~)ll~)ds (3.129)
X
follows from Propositions 3.5 and 3.8. Combining (3.122) with (3.128) and (3.129) gives inequality (3.82):
II~(t)lt~
< CTt-1
II~ollx.
3. Evolution Equations and FEM
144 Commentary
to C h a p t e r 3
3.1. The generation theory of Tanabe-Sobolevskii was given by Tanabe [377] and Sobolevskii [353], independently. Inequality (3.17) is a consequence of the elliptic estimate of Agmon, Douglis, and Nirenberg [3]. The generation theory of Fujie-Tanabe was given by Fujie and Tanabe [132]. Inequality (3.23) follows from the coerciveness of At. The righthand side may be replaced by C~ Izl, but this form simplifies the treatment of fractional powers of A(t). The proof of (3.23) is also given in Tanabe [378]. Generation theory of Kato-Sobolevskii was given by Kato [201] when p-1 is an integer and Sobolevskii [354] for the general case. Inequality (3.27) was made use of by Heinz [169] and Kato [202], [200]. For the theories of fractional powers of m-sectorial operators, see Kato [199]. Inequality (3.26) was also proven there. Equality (3.3o) is due to P.E. Sobolevskii. The theory of Kato-Tanabe was given by Kato and Tanabe [209]. See also Suzuki [368] and ~3.3 for the fact that smoothness of bilinear forms confirm the assumptions of the last theory. Most of those generation theories are described in Tanabe [378] in details. 3.2. Inequality (3.55) was proven by Suzuki [368]. Proof of (3.64) was also given there. Note that necessary assumptions for A(t) are those on the theory of Kato-Tanabe and inequalities (3.60)-(3.62). Once they are provided, the Banach space structure induces the conclusion. 3.3. Inequality (3.67) was proven by Fujita and Suzuki [147] for boundary condition (3.a) and Suzuki [3661, [36s] for the general case. Related works were done by Helfrich [171], Fujita [140], Suzuki [365], and Sammon [335]. 3.4. For the detailed proof of (3.86), see Suzuki [368]. Inequality (3.82) was proven by Suzuki [366], [3681 Related works were done by Sammon [335]. 3.5. Error analysis on the fully discrete approximation of temporally inhomogeneous parabolic equations has been done independently by Baiocchi and Brezzi [23], Huang and Thom~e [184], [185], Luskin and Rannacher [256], [257], and Sammon [336], [337] Contrarily to Suzuki [366], [368], the Hilbert space structure of the problem were used systematically there. The works described in this section were done by Luskin and Rannacher [256] and Huang and ThomSe [185]. The error analysis for schemes with higher accuracy were done by Baiocchi and Brezzi [23], Luskin and Rannacher [257], and Sammon [336], [337].
In the case of temporally inhomogeneous parabolic equations, the complex m e t h o d does not work so well by itself for the analysis of the finite element approximation. Here, we adopt the m e t h o d of Helfrich and then that of energy, and extend the error estimates of the preceding chapter to this case.
3.1
Generation
Theories
The present chapter is devoted to the temporally inhomogeneous parabolic equation; t2 C R 2 denotes a polygon, and /2 = /2(x,t, D) a second order elliptic operator with time-dependent real smooth coefficients:
c(~, t, D) = - ~
~-~ a~j0 (~, t)
0
2
+ Z~=~ bj(x , t) ~+~(~,t). o
i,j=l
Uniform ellipticity 2
i,j=l
is assumed, 51 > 0 being a constant. We study the parabolic equation
ut +/2(x, t, D)u = 0
in t2 x (0, T)
(3.1)
with the initial condition
glt=o = uo(x)
in ft
(3.2)
and with the boundary condition either u = 0
on at2 x (0, T)
(3.3)
or
0u -t- a u = 0 cO~,c
on 0t2 x (0, T ) .
--
(3.4)
In (3.4), cr = a(x, t) is a smooth function on 0t2 x [0, T], and 0/0r, L denotes the differentiation along the outer co-normal vector ~L: 0
_ ~-'2
n i a i j ( x , t)
i,j=l
95
0
3. Evolution Equations and FEM
96
where n = (nl, n~) is the outer unit normal vector on 0f~. Assuming u0 E X = L2(~), we can reduce equation (3.1) with (3.2) and (3.3) (or (3.4)) to the evolution equation
du
dt
+ A(t)u = 0
(0 < t < T)
(3.5)
with u(0) = u0
(3.6)
in X = L2(gt). Taking V = H~(f~) or Hl(f~) according as the b o u n d a r y condition (3.3) or (3.4), we put
.At(u, v) = i,j:,
aij(x, t)-~xj -~xi dx + J:'
bj(x, t)--VOzy dx
+ ffl c(x, t)uv dx + fon a(x, t)uv dS for u, v E V. An m-sectorial operator A(t) in X can be defined through the relation
At(u, v) = (A(t)u, v) ,
(3.7)
where u E D (A(t)) C V and v E V. As in the temporally homogeneous case of w relation
D (A(t)) = H2(fl) N H~(fi)
the
(3.8)
follows for V = H~(f~) and
D (A(t)) = {v C H2(f~)
+av=O
on0f~
(3.9)
for V = Hl(f~), if 0fi is smooth for instance. Generation theories of a family of evolution operators {U(t,S)}o
du dt
- - + A(t)u : 0
(s < t < T)
(3.10)
with 'u(s) = 'Uo C X
(3.11)
3.1. Generation Theories
97
is given by u(t) = U(t, s)u0. Consequently, the semigroup properties
U(t,r)U(r, s) = U(t, s)
(0 < s < r <_ t <_ T)
and
U(t,t) = I
(0 <_ t <_ T)
follow. Furthermore, we have
U(t, s) = - A ( t ) U ( t , s)
and
-~sU(t, s) = U(t, s)A(s)
(3.12)
in the strong sense in X for 0 _< s < t < T. It is worthwhile to give a short summary of those theories here. In fact, studying the finite element approximation of (3.5), we show some kind of stability of approximate solutions and smoothness of original ones. Both of them are established by re-examining the theories, and then error estimates will follow. Crucial assumptions are the following: (i) Each - A ( t ) generates a holomorphic semigroup with certain estimates uniform in t E [0, T]. (ii) A(t) is smooth in t E [0, T] in some sense. The family {U(t, S)}o
IA,(~, ~)1 s c~ II~llv II~llv
(u, v ~ V)
A~(~ , ~) > a l~ I~V - ~1~1 X=
(~ ~ v)
and -
-
,
(3 13) "
with constants C1 > 0, 6 > 0 and A E ][{ independent of t E [0, T]. We may suppose A = 0 in (3.13), taking v - e-~tu(t)instead of u - u ( t ) i n (3.5)"
x,(~, ~)>__ ~11~11~
(~ ~ v ) .
(3.14)
Then, A(t) becomes of type (0, M) with 0 E (0, 7r/2) uniformly in t e [0, T]; we have
C \ Eo C p(A(t)) for
ro = {~ c e l
o < arg I~l < o},
(3.15)
3. Evolution Equations and FEM
98 and M~ II(zI- m(t)l _ XlIx, X <_-~
(0 + e _< [arg z I < _ 7r)
(3.16)
for e > 0. Each -A(t) generates a holomorphic semigroup {e -~a(t) }s>0 uniformly bounded in t C [0, T]. We have
II~-~A(,)llx,x <_1 for 0 < s < + o c and 0 < t < T. Concrete expressions of the second condition, on the other hand, are slightly different according to the theories. In each of them, construction of the family gives some estimates on their members at the same time. For the moment, the operator norm on X = L2(12) is simply written as II" IIGeneration
T h e o r y of T a n a b e - S o b o l e v s k i i
Because of (3.8), D(A(t)) is independent of t in the case of V = H~(f~). Furthermore, the inequality I[A(t)A(s)
-~ -
111_
cIt-
sl ~
(t,~ E
[0, Z])
(3.17)
follows with c~ C (0, 1] from an integration by parts and the elliptic estimate. In such a situation, the family of evolution operators {U(t,s)}o
U(t,s) = e-(t-s)A(~) +
e-(t-r)A(~)R(r,s) dr,
(3.18)
where R = R(t, s) is the solution of the integral equation of Volterra type, I~,(t, S) --
I~ 1 (t, r ) R ( r ,
s)dr
= /~1 (t, S)
(3.19)
for /~,1 (t, S) -- --
(A(t)
- A ( s ) ) e -(t-s)A(s)
Those relations are obtained formally by substituting tile right-hand side of (3.18) into the first relation of (3.12). Eventually the unique solvability of (3.19) follows and {U(t,s)} defined by (3.18) becomes the desired family of evolution operators. Meanwhile the following estimates are proven, where 0 _< s < r < t _< T and 0 E (0, a):
(3.20) IIU(t, s)ll + [IA(t)u(t, s)A(s)-' I[ <- c,
[IA(t) [ u ( t ,
~) - u(,-,
~)] A(.~)-' II -< C o ( t
- ~)o(~ _ ~ ) - o
(3.21) (3.22)
3.1. Gel~el"ation Theories
99
G e n e r a t i o n T h e o r y of F u j i e - T a n a b e If V = Hl(f~), D(A(t)) varies as t changes, and the preceding theory does not work directly. However, the m-sectorial operator A(t) in X defined through (3.7) can be regarded as that in V', which is denoted by A(t). Its domain is independent of t: D(A(t)) = V, and furthermore, conditions (3.15) and (3.16) hold with A(t) and X replaced by A(t) and f( = V', respectively:
V',V' --
]Z q- 1
The coefficients aij, bj, c and cr are smooth so that the inequality IAt(u, v) - A~(u, v)l _< O It - sl ~
I1~11~I1~11~
(u, v E
V)
(3.24)
holds with c~ E (0, 1]. This implies (3.17) for A(t) in 2 . Therefore, from the preceding theory, {A(t)} generates a family of evolution operators in 2 denoted by {U(t, s)}0
U(t,s)=O(t,s)x becomes a bounded operator in X and {U(t,s)} forms a family of evolution operators generated by - A ( t ) . This {U(t, s)} satisfies (3.20) and U(t, s)[ _< C in X. G e n e r a t i o n T h e o r y of K a t o - S o b o l e v s k i i We can show that D (A(t) p) is invariant in t for p C [0, 1/2). symmetric part A ~ of At as in w
To see this, take the
Ato= 1 (.,4, + At).
At(~, ~) = A,(~, ~),
If Ao(t) denotes the self-adjoint operator associated with At~ it holds that
c - ' Ivllv _< IlAo(t)l/% Ix < C vllv.
(3.25)
As is described in the commentary to w the domain of A(t) p is equal to that of Ao(t) p if p C [0, 1/2). (The idea of proof will be obtained from the argument described below.) Here, the latter is independent of t if p = 1/2 as is indicated in (3.25), and p = 0 obviously:
D(Ao(t) '/2) = V,
D(Ao(t) ~ = X.
Then, Heinz' inequality implies the invariance of D (A(t) p) in t for p E [0, 1/2). We show that the inequality
IlA(t)PA(s)-p-/11
c t - sl
(t, s E [0, T])
(3.26)
3. Evolution Equations and F E M
100 follows from (3.24). In fact, given # > 0, we have (#I + A(t)) - 1 -
(pI + A ( s ) ) - ' = - (pI + A(t)) -1 Ao(t) 1/2. Bo(t, s ) . Ao(s) 1/2 (#I + A(s)) -1
with Bo(t, s) = Ao(t) -1/2 [A(t) - A(s)] Ao(s) -~/2
Inequality (3.24) reads; IA(t) - A(s)l v,v, <- C I t - sl ~ , or
liB(t, ~)11 ~ c It - ~1~ We make use of the following. L e m m a 3.1. If H is a non-negative self-adjoint operator on a Hilbert space X with norm
II. II, ~ e h~ve
~
~ #2~ IH~/2 (~I + H) -~ v[I 2 d # -
Cp IIH~
2
(3.27)
for p c [0, 1/2) and v E D(H~ Proof: Introducing tile spectral decomposition
ad E ( a) ,
H :
we have
#~o ]IH~/~ (#I + H)-'
= d#
-
~,=o @
a(~, + a ) - ~ d IIE(a)~ll ~
9
-
ad IIE(:~)vll =
=
ad IIE(:~)vll ~. a ~o-'
=
Co
#~o(# + a)-~da ~o(#
+ 1)-2d#
A2PdlE(A)vl 2-- CplIHPv 2.
This means (3.27).
[]
We are able to give the following. Proof of (3.26): We show
II[A(t) p - A(s) p] vii < c It - sl ~ IIAo(s)~
(3.28)
3.1. Generation Theories
I01
for p E (0, 1/2) and v e D (Ao(s)a). Then, inequality (3.26) follows from (2.43). For this purpose, we may take v r D(A). Applying (2.18), we have ([A(t) ~ - A(s) ~ v, X) = sin 7rp
7r
/0
pP dp. (B(t,s)Ao(s) 1/2 (pI + A0(s)) -1 v, Ao(t) 1/2 (pI + Ao(t))-i X)
for X E X. In use of (3.25), inequality (3.28) follows as [([A(t)P - A(s)P] v, X)[
(/0 9
I[Ao(t)'/2 (#I + Ao(t)) -x Xll2x d•
It - s[ ~
= c~ IIAo(s)Ovllx. I l x l l x - I t - sl ~ . The proof is complete. Above properties of the fractional powers of generators, summarized as the invaria.nce of D (A(t) o) and inequality (3.26), guarantees the existence of the family of evolution operators in the following way if c~ + p > 1 is satisfied. Therefore, evolution operators exist if c~ > 1/2 again, in the parabolic initial b o u n d a r y value problem in consideration. For simplicity, we describe the case p = 1/m with m an integer. By taking an appropriate approximation of A(t), say, the modified Yosida approximation: Aa(t) = A(t)(1 + AA(t)o) -m with ,~ I 0, we can reduce the theory to the case where each A(t) is bounded in X. In fact, we can show that (3.26) implies
IlA~(OPA~(s) - p - Ill <_ C l t - sl ~
(t, s e [0, T])
with a constant C > 0 independent of )~ > 0. Existence of a family of evolution operators {Ua(t,s)}o
U(t, s) = s-lim Ua (t, s). M0
Then, {U(t,s)}o
llA(t)ZU(t,s)ll < C z ( t - s)-z
(O<_s
follows from ]lA~(t)Zu~(t, s)[I < C z ( t -
s) -z
(0 < s < t < T ) ,
(3.29)
where 0 _< p < a + p. We shall give an outline of its proof, dropping the suffix A for simplicity of writing.
3. Evolution Equations and FEM
102 Letting
D(t, s ) = A(t)PA(s) - p - I, we have
liD(t, s)
~
Clt
-
s ~
and m
A(t) - A(s) = Z
A(t)I-PPD(t' s)A(s)PP"
(3.30)
p=l
We get t
-
= ~=
e-(t-r)A(t)A(t)l-p"D(t,r)A(r)~~
dr.
(3.31)
We introduce the following notation: Given the operator-valued functions I(e = IQ(t, s) (g = 1, 2) on D = {(t, s ) [ 0 _< s _< t <_ r } , we define another I( = K1 * I(2 by (//(1 * 1(2)(t,s)=
K~(t,r)K2(r,s) dr.
For a > 0 and M > 0, we say t h a t K E Q(a, M) if the inequality
[ K( t,s)ll - M ( t -
s) a-1
holds. Then, if Kl C Q(ae, Me) for g = 1, 2 we have /s
* /(2 E Q ( a l +a2, B ( a l , a 2 ) M 1 M 2 ) ,
where B(a, b) denotes the beta function: B(a,b)
jfo 1(1
=
-
x )a- l x b-1 d ~ .
Let
W(t, s) = U(t, s) - e -(t-~)A(t)
and
Yq(t, s) = A(t)oow(t, s).
Equality (3.31) reads; m
(3.32) p=l
3.1. Generation Theories
103
where
Hq,p(t, s) = A(t)'-PP+qPe-(t-s)A(t)D(t,
s)
(3.33)
and m
p=l
for
Yp,_, (t, 8) = A(t)PPe-(t-s)A(t) To avoid a technical difficulty, we take (3.34) and transform (3.32) into a system of integral equations for
{Zql q = 1,.-. ,m}. That is, m
Z~ = ~
Hq,, , Z, + &,o
(3.35)
p=l
with m
(3.36) p=l
Consequently, Zq (q = 1 , . . . , m) is subject to the iteration scheme oo
Zq -- ~
(3.37)
Zq,i
i=0
with m
Zq,,+, = ~
H~,, 9&,,
(~ = o, 1 , . . . ) .
p=l
From definition (3.33) follows H~,, ~ Q (~ - qp + pp, M , )
with a constant M1 > 0, because (2.16) holds by (3.16)"
<
> 0),
(3.38)
3. Evolution Equations and F E M
104 where ~c >_ 0. F u r t h e r m o r e , we have
Zq,o E Q(1 + a - qp, Mo) for some M0 > 0. We can derive
Zq,i E Q (1 + (i + 1)a - qp, Mi) with A/Ii+l/~Ii = r n M o M i B (c~ + p - 1, (i + 1)c~) by an induction, and then Zq E Q ( 1 + a - q p ,
(3.39)
C)
follows from (3.37) with a constant C > 0. Inequality (3.39) now gives an estimate on Yq even in the case t h a t q is not an integer. Namely, (3.34) makes sense for any q >_ 0, and Zq,o is again given by (3.36). T h e n Zq is defined by (3.35) with p taking integers as before. Since Zq in (3.35) admits (3.39), inequality (3.34) gives an estimate of Yq for a - qp + p > 0, because Yq,O E Q(1 - qp, C) can be shown. Consequently, Yq E Q(1 - qp, C) follows. Writing qp = / 3 , we then obtain (3.29) from (3.38).
Generation Theory of Kato-Tanabe Let us define another bilinear form .At(, ) on V x V by
,=
j=l
s
/o ~
Then, we have
IA,(u,~)l _< C llullvllvllv, I.A,(.,,, v) - A,(.,,, ~)1 _< c It - ~1~ II~llv Ilvll~, for u , v E V with some c~ E (0, 1] and lira
sup
(At-
1
As)('u, v) - As(u, v) = 0 .
II~llv,llvllv
dA(t)-' dt
d A -
ds
(S)-1 ~
holds with K > 0 and a E (0, 1].
K
It-
s
(t, ~ E [0, T])
(3.40)
3.1. Generation Theories
105
2) The inequality
c9 ( z I - A(t)) -~
M~
holds for c > 0 sufficiently small.
Proof of (3.41): Take z
(z e c \ r0+~)
---[;i
9 C \ E0+E and v
(3.41)
9X, and put
w(t)=(zI-A(t))-lv. We show that it is continuously differentiable in X with the estimate
Ow x
-5i-
M~
(3.42)
-
satisfied. Recall
(8.48)
(z - A ~ ) ( ~ ( t ) , ~) = (~, ~) and (2.31)"
Jzl lJxJl~ + II~II~V - -<
~o I~ II~IIX~
- A ( ~ , ~)J ,
where X C V and z C C \ Eel. This implies also (2.33) as
I1~1 ~ < 6o Iv ~ /I~1
~nd
I1~11~ < ~o vlt~ /t~ ~/~
Differentiating formally in t, we get (Z -- , A t ) ( ~ b ( t ) , )(~) = A t ( w ( t ) , ) ~ )
(3.44)
from (3.43). Here, the right-hand side is a bounded linear functional of X C V. In use of (2.31), we can define ~b(t) E V through (3.44) conversely, by Lax-Milgram's theorem. Now we shall show lim w(t) - w(s) _ ~b(s)ll t--~s
t -- 8
: 0.
(3.45)
V
In fact, letting ~ ( t ) - ~(~) t--8
we have
(~ -
A~)(~(t), ~(t))
=
t-8
t--8
(Z -- r
-- W(8), x ( t ) ) -- (Z -- ,At) (~b(8), x ( t ) )
(z - A~) ( ~ ( t ) - ~(~), ~(t)) - As (~(~), ~(t)) + (A~ - A~)(w(~), ~(t))
t--8
{1
((z - As) - (z - A~)) (~(~), ~(t)) - A~ (w(~), ~(t)) + (At - A s ) ( ~ ( ~ ) , ~(t))
}
3. Evolution Equations and FEM
106 Again by (2.31), we get 1
IIx(t)ll* V - -< ~0
(.4, - .4~) (~(~), z(t)) - A~ (~(~), ~(t)) + &c It- ~1. Iw(~) ,,. IIx(t) v,
or
IIx(t)llv < C I t - s
9~,(~)1 v +C
sup xEV
1
---zU t (.4, - .4~) (~(~), ~) - A~ (~(~), ~)
Ilxllv_
lim IIx(t)llv = 0 . t---* 8 We turn to the proof of (3.42). In fact, again by (2.31) we have
z IIw(t)ll x2 + I~(t) ~. _< ~o I(z - .A,.)(~(t), ~(t))l 5o 12., (w(t), w(t)) I _< C IIw(t) ,, IIw(t)ll,,. This implies
~i,(t) Iv < c IIw(t)Iv -
CIl~ll~ Izll/~
and
~/2 II~i~(t)lv/~ ......
IIw(t) Ix < Cllw(t)llv
Izl '/~
-
C lvllx
Izl
by (2.33). The proof is complete.
Proof of (3.~0): We take v C X, and set .f(t) = A ( t ) - l v E V. The existence of df(t)/dt follows similarly. Noting At (.f (t), X) = (v, X) , we define j~(t) by
where ~ E V. Then it follows that lim
t--~8
.f(t) - . f ( s ) - r t-s
=0. V
3.1. Generation Theories
107
Inequality (3.40) is a consequence of the stronger one:
Ilvll~,.
(3.46)
In fact we have
IIx ~ < A<(r - r x) = -Jlt(f(t), x ) - ( A t - A,)(j'(s), x ) + Jl,(f(s), x) = ( f % - Jlt)(f(t), x ) + J l ~ ( f ( s ) - f(t), x) - ( A t - As)(r <
x)
C Ilxllv (it - sl ~ IIf(t)llv + Ilf(s) - f(t)llv + It - sl IIr
or
iii(t)- ./(~)llv _< c (it- ~l ~ lif(,)il~ + ilf(~)- f(t)ll~ + it- ~l
Its( )ll ).
(3.47)
Remember that
IIf(t)llv <_ C IIv v, follows from
llf(t)ll~
_ .At(f(t), f(t)) -- (v, f(t)) < c
IlVllw, IIf(t)llw
.
Similarly,
~llJ(s)ll~ ~ A,(r
r
- -J~(f(s), r
< c }lf(s)llv IIf(s)llv
gives
Finally, we have
(5lif(s)- f(t)ll~
< .At(f(s)- f(t), f ( s ) - f(t)) = ( A t - As)(f(s), f ( s ) - f(t)) <
C It - ~1 IIf(~)ll. IIf(~) - f(t)ll.
and hence
] i f ( s ) - f(t)iiv <_ C I t - s I tlf(s)llv <_ C i t - s I livllv, follows. Plugging those inequalities into (3.47), we obtain (3.46). Subject to the above conditions on the differentiability of resolvents, the family of evolution operators {g(t,S)}o
u(t, ~) = ~-(~-~)~(~) + w ( t , ~)
3. Evolution Equations and FEM
108 with
w(t, ~) =
~-(*-~(*)R(~, ~) d~,
(8.48)
where R = R(t, s) is the solution of
R(t, ~) = R~(t, ~) +
R~(t, T)~(,-, ~) d~
(3.49)
for
0 + N0 R l ( t , s ) = -(~-t
)r
1 O~F e -(t- s)z -07(zI0 -- 27r,. A(t))-ldz,
(3.50)
F being positively oriented boundary of E0+~ for e > 0. Inequality (3.20) and IIg(t, s)ll < c are also derived from this scheme. More precisely, we have
IR(t, s)][ _< C
(0 _< s _< t _< T)
(3.51)
and
(0 _< s < ~ < t <_ T),
(3.52)
for 7 C (0, 1) and 5 C (0, a). They are consequences of those with R replaced by R1,
IIR~(t, s)ll <_ c
(3.5a)
and
II/~l(t, 8 ) - /l~l(r, 8)11 ~ C7,5((t- T)7(T- 8) -7 -[- ( t - r ) a ( r - s)~-a-1), respectively. This theory of generation is particularly remarkable as any assumptions on the domains of A(t) are not made. Consequently, it is no wonder that a little stronger assumption on the smoothness in t of A(t) is imposed.
3.2
A Priori
Estimates
In this section, we show a uniform estimate concerning the evolution operator associated with the discretized problem, which plays a key role in the error analysis. In the following lemma, V C H C V' denotes a triple of Hilbert spaces, A(t) an m-sectorial operator in X associated with the bilinear form At(, ) on V x V, smooth in t E [0, T] in the sense of the preceding section, and {U(t, S)}o<8
3.2. A Priori Estimates
109
L e m m a 3.2. Each/3 e (0, 1/2) admits the equality
d(t)U(t, s) - A(r)U(r, s) = A(t) [e -(t-~)A(t) - e -(~-s)A(t)] + A(t)ZZ~(t, r, s)
(3.54)
with Zz(t, r, s) subject to the estimate IIZ,(t, r, s)ll <
C,(t
-
r)(r
-
(3.55)
s) ~-',
where O < s < r < t < T. Proof: We shall take the reduction process first. In fact, from the construction we have A(t)U(t, s) - A(r)U(r, s) = A(t) [e - ( t - s ) A ( t ) --
e -(r-s)A(t)]
+A(t)" [A(t)l-'~ -(~-s)~(') - A(~)'-'~ -(~-s)~(~)] +A(t)" [ I - A(t)-ZA(r)'] A ( r ) l - ' e -(~-s)A(~) +A(t) a [ A ( t ) l - ' w ( t , s) - A ( r ) l - ' W ( r , s)] +A(t) ~ [ I - A(t)-~A(r) ~] A(r)'-~W(r, s), so that 4
/=1
holds with
Z~(t, r, s) = A(t)l-Ze -(r-s)A(t) - A(r)l-Ze -(r-s)A(~), Z~(t, r, s) =
[I - A(t)-ZA(r) ~] A(r)X-'e -(~-s)A(r),
z~(t, ~., s)
A(O'-~w(t,
:
Z~(t, r, s) :
s) - A(~.)~-~WO ., ~),
[I - A(t)-ZA(r) ~] A(r)'-~W(r, s).
The Dunford integral gives the expression
d(t)Ze_Tm(t ) _ A(s)e_~d(~ ) = 12m ofr z'-Ze-rz
[ ( z I - d ( t ) ) - ' - (zI - m(s))-'] dz,
while
]l(z~-
A ( t ) ) -1 - ( z I -
A(s))-'ll < c~ It- sI -
Izl
follows from (3.41). We have
IlA(t)~e -~A(t) - A(s)~-~(s)ll <_ c~ It - sl r - ~ < c
d--~-~lt-s l -
~ - ~ e -~"~~176 At
G I t - sl r ~-~
(3.56)
3. Evolution Equations and FEM
110
for/3 > -1. This implies IIz~(t, ~, s)ll < c~(t - ~)(~ - ~)~-~
Inequality
III-
A(t)-ZA(s);311 <- C ~ l t - sl
follows from (3.26). We have
~
C / 3 ( t - r ) ( l " - 8) ~-1
Inequality (3.51) gives IIA(t)l-ZW(t,s)lt
: <_ c~
A(t)l-ze-(t-r)A(t)R(r,s)dr ( t - ~)~-'d~ = C ~ ( t -
~)~
and hence llz~( t, ~, ~)11 - c , ( t - ~)(~ - ~),
follows. The proof of Lemma 3.2 has been reduced to
Ilz~(t, ~, s)l t = IlA(t)l-~w(t, s) - A ( r ) ' - ~ W ( r , s)l I <_ C,(t - r ) ( r - s ) ' - ' Equality (3.48) now gives 7
Z~(t,r,s) = A ( t ) l - Z w ( t , s ) - A ( r ) l - Z W ( r , s ) = ~
Z[3(t,r,s )
l=5
with Z~(t, r, s)
=
f
t
A(t)l-~e -(t-~)A(t) [/~(z, s) -/~(t, s)] dz,
z~(t, ~, ~) =
[ A ( t ) ' - ~ -('-z~('~ - A ( ~ ) l - ~ - ( ~ - ~ ( ~ ]
Z~(t, ~, s)
A(t)~-~-(~-z~(~)dz
=
+
[P(~, 9 .~) - ~(~, ~)1 d~,
. ~(t, s),
[ A ( t ) l - ~ - ( ~-z~(~ - A ( ~ ) I - ~ -(~-z~(~]
d z - ~ ( ~ , s).
3.2. A Priori Estimates
111
In use of (3.52) we have
[IZ~(t,r,s)l[
<
IlA(t)'-Ze-(t-z)A(t)ll .
<_ c~.,
IIR(z,s)- R(t,s)ll dz
( t - ~)~-~(t- ~)~(~- ~)-~d~
+G,~
( t - z)~-~+~(z- s) -~+~-~ (9z - s)~-'dz,
<- G .
( t - z)~-l+~(z- ~)-~+l-~dz. ( ~ - s) ~-~
=
~)(~- ~)~-1
G(t-
taking "7 e ( 1 - f l , 1) and 5 e (c~ - fl, c~). From (3.96) and (3.56)we have
_ G(t-
~)(~- z) ~-~.
Combining this with
}lA(t),-z~-I,-zl~r
A(~,)'-Z~-Ir-z/Ar II
-< G(~"- ~)~-', we get [IA(t)~-ze
-r
-
A(r)l-Ze-(r-z)m(r)[I < C ~ ( t - r)'~(r- z) - ~ + z - '
for r~ E [0, 1]. This implies
IIG( t, ~, ~)ll _<
I[A(t) ~-~-(~-~(~ - A(~)'-~-(~-z)~(~)l[- I1~(~, ~ ) - ~(z, ~)11 d~-
+c~,~
= G(t-
( t - ~)~(~ - ~)-~+~-1. (~ - ~)~(~- ~)~
,~)~(,~- s)~-',
3. Evolution Equations and FEM
112 by taking -7 e ( a - / 3 , 1) and (5 E ( a - / 3 , a) similarly. We have Z~(t, r, $)
=
[A(t)-fle-(t-z)A(t)]~:t r R(t, 9 8) -Jr-[A(t)-fle -(t-z)A(t) - A ( r ) - f l e - ( r - z ) A ( r ) ] : : :
I~(t, 9 8)
11
/=8
with
Z~(t, r, s) = [I - e -(t-~)m(t)] [A(t)-zR(t, s) - A(r)-ZR(r, s)], Z~(t, r, s) = - e -(t-r)A(t) [A(r) -z - A(t) -z] R(r, s), zl~~ r, s) = - [A(t)-Ze -(t-~)A(t) - A(t)-f~e -(~-s)a(t)] R(r, s), z ~ l ( t , 1", S)
:
-- [A(t)-~e -(r-s)A(t) - A(r)-~e -(T-s)A(r)] R(r, s).
The inequality
IIA(t) - ~ - A(~)-~II <- G It- ~1 follows from (3.26) so that we have IIz~(t,
~, ~)11 <-
c~(t -
~)(~ - s)/2i'- 1 .
On the other hand the inequalities
Ilzy(t, r, ~)ll _< Cz(t- ,~)(,~- ~)~-' and
IIz~'(t, r, s)ll _< G ( t - r)(~- s)~-' follow from (3.96) and (3.56), respectively. In this way, Lemma 3.2 has been reduced to
[[A(t)-zR(t, s ) - A(r)-ZR(r, s)[ I _< Cf3(t- r ) ( r - s) z-I
(3.57)
Integral equation (3.49) reduces this inequality furthermore to IIA(t)-ZR,(t, s ) - A(r)-ZR,(,', s)l [ <_ C ~ ( t - r ) ( r - s) z-l,
(3.58)
R~ - Rl(t, s) being the right-trend side of (3.50). We show this fact first. In fact, in use of (3.49) we have m(t)-~R(t,
s) - d ( r ) - r R ( r ,
s)
= [ A ( t ) - O R l ( t , s ) - A(r)-aR~(r,s)] + +
/'
A(t)-;3R,(t,z)R(z,s)
dz
[ A ( t ) - O R l ( t , z ) - A(r)-aR~(r,z)] R(z,s) dz.
3.2. A Priori Estimates
113
The second term of the right-hand side is estimated by (3.51) and (3.53):
/*
liA(t)-Zll
9IIRl(t,
z) l-IIR(z,
~)11 dz <
c(t
-
~).
Similarly, the third term is estimated as
fs r IlA(t)-ZRl(t,z) - A(r)-~t~l (r, z) C
dz
9IR(z,s)
( t - r ) a ( r - z)~-lds = C~3(t- r ) a ( r - s) l~.
Thus, (3.58) implies (3.57). We now turn to the proof of (3.58). Recall the symmetric part Ao(t) of A(t) associated with Ao. We have the following. L e m m a 3.3. The equality
[ 0_~( z l _ A(t))_ 1 - -~sO(zl - A(s))-l] = A(t)lo/2 ( z I - A0(t)) -1Bz(t, s)Ao(s) 1/2 ( z I - Ao(s)) -1 holds with
Bz(t, s)II ~
c I~ -
(3.59)
sl ~ ,
where z E EOl. Proof: Define A'(t)" V --, V ' b y J~t(u, v) = (A' (t)u, v) for u, v E V. It holds that
0 (zI - A(t)) -1 = - ( z I - A(t)) 0-7
-1 d'
(t) (zI - A(t)) - 1
We have
0 =
(zI(zI q-(zI
A(t)) -1
0
A(s))-I 1
(zI-
A(~)) -1A'(t)(zI -
+ (zI - A(t)) -1
A(t)) -1 [A(/~) - A(s)]
-
d(f)) -1 [m'(t)
-
(zI
[A(t) - A(s)]
d9' ( s )
The equality
m'(s)]
-
(zI -
A(s)) -1
d(s)) -1
(zI -
A(s)) -1
(zI - A(s)) -1 d'(s)(zI
-
d(s)) -1
114
3. Evolution Equations and F E M
arises with the following terms" Bl(t, 8)
=
Ao(t) -1/2 ( z I - Ao(t)) ( z I - A(t)) -1Ao(t) 1/2 A9o ( t ) - l / 2 A ' ( t ) d o ( t ) -1/2. do(t) 1/2 ( z I - A ( t ) ) -~ do(t) 1/2 Ao(t) 9 -1/2 [A(t) - A(s)] Ao(t) -~/9
Ao(8) 9 1/2 ( z I - A(8)) -1 ( z I - A o ( s ) ) d o ( s ) -~/2, B2(t, s)
=
mo(t) -1/2 ( z I - Ao(t)) ( z I - A ( t ) ) -1 do(t) ~/2 Ao($) 9 -1/2 [A'(t) - A'(s)] do(s) -'/2
A(8)) -1 ( z I -
Ao(s) 9 ~/2 ( z I Ba(t, s)
=
A o ( s ) ) A o ( s ) -1/2,
Ao(t) -1/2 ( z I - Ao(t)) ( z I - A(t)) -1Ao(t) 1/2 Ao(t) 9 -1/2 [A(t) - A(s)] Ao(s) -1/2. Ao(s) 1/2 ( z I - A(s)) -1Ao(s) 1/2 d9o ( s ) - ~ / e A ' ( s ) d o ( s ) - l / 2 ,
m o ( s ) ( z I - A ( s ) ) -~ ( z I - do(s))Ao(s) -Vg
Thus the lemma has been reduced to the following inequalities:
IlAo(t)-'/~ (zI
- Ao(t)) ( z I - A ( t ) ) -~ Ao(t)l/2ll <_ C,
IlAo(t)-l/2A'(t)Ao(t)-l/21l
<_ C,
< C It - ~1,
IlAo(t) -1/~ [n(e) - A(~)] no(~)-'/=ll
IIAo(t)-'/2 (zI - n ( t ) ) - ' (~I - Ao(e)) no(e)-'/=ll < C,
IlAo(t)
A'(~)] nol/=ll _< C l t - ~ l
~
They are direct consequences of (3.23), (3.25), and the following inequalities:
IA(t)l v,v, ~ C,
C -1 ~
C -1 ~ IIA0(t)Iv, v, < C,
I A'(t)llv, v, <_ C, A(t) - A(s)llv, v, < C I t - sl,
IIA'(t) - A'(.s)l v,v, < C I t - ,s ~. Details are left to tile reader. Now we show the following inequalities as consequences of Lemmas 3.3 and 3.1, where
9 ~ (0,1/2). A ( t ) -O~ A ( t ) -~ (9
(zI - A(t))
-1
0
- ~
(3.60)
<_ C o ,
( z I - A(s)) -1
A ( t ) o f f - - T A ( t ) - ' - A ( s ) o "ff-~A(s)- ~
< C It - s] ~ , < CI~ It -,sl "
(3.61) (3.62)
3.2. A Priori Estimates Proof of (3.60):
115
Inequality (3.26) (with a = 1) gives
l]A(t) ~ [A(t + e) -~ - A(t) -z]
tl -<
and hence (3.60) follows because
ate3A(t)_ ~ ---- 27rzl/r z-~-~c3 (zI -
A(t)) -1
dz
exists. P~oof of (J.61): If H is a positive definite self-adjoint operator in X, its spectral decomposition assures
IIH1/~ (zI - H)-~I _< c for z E E01. Inequality (3.61)follows from (3.59).
Proof of (3.62):
Noting
cOA(t)Z . A(t)_Z ' A(t)Z at~---A(t)-~ = cot we have
A(t)~ ff---iA(t)-~- A(s)~ ff---~A(s)-~ = - ata a(t)~. A(t)_ ~ + ff__~A(s)~.A(s)_ ~
[-~A(t)Z- osOA(s)Z] A(t)-z + CgA(s)3" A(s)-Z [IInequality (3.62) is reduced to
[ff---~A(t)~- ~sA(S)~J A(s)-~[[ < C~ t-s[ ~.
(3.63)
We have assumed the boundedness of A(t) so that (2.18) holds for any v E X. It follows that
8 A(t)Zv =
sin 7r/3 ]i~176Zc3
7r
1
tt -~ (#I + A(t))- v dl~.
If we apply Lemma 3.3, we get
sin7cflTr/o~176
(B-u(t's)A~
(pI + Ao(s))-lv, Ao(t) 1/2 (pI + Ao(t))-lx).
3. Evolution Equations and FEM
116 Inequality (3.63) follows from
( OA(t)~-~
--~sOA(s)~l C
(fOOO#Z3 [Ao(8)1/2
( # I --t-
A0(8))-1 '/)112)1/2
IlAo(t) ~/~ ( . I + Ao(t)) -~ ~[l~ d.
:
It -
sl ~
c~ IIA0(~)~llx. I~llx" t - ~1~
and (3.25). We are able to complete the proof of Lemma 3.2.
Proof of (3.58): We have Oq e_(t_s)A(t) A(t)-ZR~ (t, s) = - A ( t ) - z - ~0qe -(t-~)A(t) - A(t)-Z-~s
=
O -~
_
(A(t)_ze_(t_s)a(t) ) + A ( t ) l - . e_(t_~)a( t)
0__ A + ot ( t ) - "
=
e
-(t-s)A(t)
1 Ot 0 f_ 2m r z-Ze1
27r~
(t-s)z
(zI - A(t)) -1 dz
Jfr Z 1-~e-(t-~)z (zI
--
A(t)) -1 dz + -~ 0 A(t)_ ~ e_(t_s)A(t) 9
1 f~ z-Ze -(t-~)zO (zI - A(t)) - l dz + o__ Ot A (t)-z . e-(t-~)A(t) 2m Ot Therefore, the equality =
16
A(t)-~Rl(t's) - A(r)-~Rl(r's) = E Ze(t'r's)
g=12
holds with
Z12(t, r, 8) =
1 ofr z-~e -(~-~)z [e -
zla(t, r, z) -
1 Jfr 27rz
~e-(~-~)z [0-o-i (z: - A(t)) -1 - ~0 (ZI-- A(t))-lJ d~,
Z14(t,r,z)
=
Z15(t, r, Z)
:
Z'6(t, r, s)
=
0-t0A(t)_ ~ " A(t);~ -~r0 A(r)_ ~ . A(r)f3] A(t)_~e_(t_s)A(t) ~O
A(r)_ ~ A(r);' [A(t)-Ze -(t-s)A(t)- A(t)-Zc-("-s)A(t)],
O A ( r ) - " . A(r) ~ [A(t)-/~e -(r-s)A(t) - A(r)-~ -(r-s)A(r)] Or
3.2. A Priori Estimates
117
Here, we have
,•'0 ~
<
C
# - z e -(r-s)'c~176 (9t - r)# d# #
--
C/3(t-
1")(/--
<
C
p - Z e -(r-s)ac~176 . (t - r ) a d #
8)/5-1
and
IJZ'a(t,
r, s)
:
j~0~176 c~(t- ,-)~(r- s)~-'
Taking the adjoint operators in (3.62), we have
cot (t)-Z " A ( t ) z
A ( s ) - Z " A(s)Z
< Cz
It
- sl
This implies
]lz'4(t, ~, s)JI ~
A ( t ) - ~ . A ( t ) ~ - -~rA(r) -~
IIA(t)-~ll. 9 II~-('-~)A(~)ll s) ~.
_< G(tSimilarly, we have
}I~ at
A9( r ) ~
(t)-~ " A ( t ) z
-
and hence
9
[[A(t)-l~e-(t-s)A< t) _ A(t)-Ze-(r-s)Att)[[
C/~(t- r)(? ~ -- 8) ~-1 hdds by (2.19). Finally, inequality (3.56) is valid for/3 > - 1 and therefore
[IA(t)-Ze-(r-s)A(t) _ A(r)-~e-(~-sla(r)ll <
c~(t-
~)(,~-
~)~-'
follows. The proof is complete. Modifying the proof of Lemma 3.2 slightly, we have (3.54) with/3 = 0 and Zo(t, r, s) satisfying IIZ0(t, ~,
s)ll
<_
c ~ ( t - r)~(r - s) -~
for 0 < ~ < a. Combining this with (2.20), we get IIA(t)U(t, s) - A ( r ) U ( r , s)ll < G ( t
- r)~(r - s) - ~ - 1 + C~(t - r)~(r - s) -~
(3.64)
for 0 _< s < r < t _< T, where/3 E [0, 1] and ~c E [0, a). The proof is simpler and left to the reader.
3. Evolution Equations and F E M
118 3.3
Semi-discretization
As is described in w parabolic equation (3.1) with (3.3) (or (3.4)) and (3.2) is reduced to evolution equation (3.5) with (3.6). In the same way as in the preceding chapter, this equation is discretized with respect to the space variables x = (xl,x2). We triangulate f~ into small elements with the size parameter h > 0 and denote by Vh C V the space of piecewise linear trial functions. As before, Xh denotes Vh equipped with the L 2 topology. The operator norm II " Ilxh,x, is written as I1" II for simplicity. The m-sectorial operator in Xh associated with r h is denoted by Ah(t). Finally, Ph : X ~ Xh is the orthogonal projection. Then, the semidiscrete finite element approximation of (3.5) with (3.6) is given by duh --+ dt
Ah(t)Uh = 0
(0 < t < T)
(3.65)
with Uh(0) =
Phu0
in Xh. Because dim Xh < +oo and Ah(t)'s are smooth in t, they generate a family of evolution operators {Uh(t,S)}o
] Ah(t)Uh(t, S)ll + IlUh(t, S)Ah(S)ll <_ C ( t - s) -1 and
(3.66)
IIuh(t,~) l < c
hold uniformly in h for 0 < s < t < T. Here, the theories Fujie-Tanabe and KatoSobolevskii are applicable. The theory of Kato-Tanabe works also from the argument in w We turn to the error estimate for scheme (3.65). Employing the method of Helfrich, we show
Ileh(t)l x < Ch'2t-' '~011x
(0 < t < T)
for eh(t) = u ( t ) - uh(t), and extend the similar result of w introduced the error operator Eh = Eh(t, s) by
(3.67) For this purpose we
G ( t , ~) = u(t, s) - Uh(t, s)P,~. Obviously,
~h(t) = E,.(t. 0)..0 holds and inequality (3.67) is reduced to
IIG(t, s)ll < c h 2 ( t - s)-'
(o < s < t <_ T ) .
(3.68)
3.3. Semi-discretization Calculations of w equality
119 are valid even for temporally inhomogeneous generators. From the
O [Uh(t, r)PhEh(r, s)] = Uh(t r)[Ah(r)Ph - PhA(r)] U(r, s) Or follows
PhEh(t, s) =
~st Uh(t, r)[Ah(r)Ph
- PhA(r)] U(r, s) dr.
Introduce the Ritz operator Rh(t)" V ~ Vh through the relation (~r
x;, ~ v.).
(3.69)
The equality
Ah(t)Rh(t)v = PhA(t)v
(v E D (A(t)) C Vh)
holds similarly to (1.24). We have
Eh(t, s)
= =
[I - Ph] Eh(t, s) + PhEh(t, s) E~(t, ~) + EX(t, ~) + e~(t, ~)
with
E~(t, s)
=
E~(t, s)
=
E3(t, s)
=
/t
[I - Uh(t, S)Ph] [I -- Rh(t)] U(t, s), Uh(t, r)A~(r) [Rh(t) -- Rh(r)] U(t, s) dr, Uh(t, r)Ah(r)Ph [I - Rh(r)] [U(r, s) - U(t, s)] dr.
It sumces to show that
IIE~( t, ~)ll -< c h ~ ( E s t i m a t e of
t -
8)-1
( ( = 1,2,3).
E~(t, s)
We have shown inequalities (1.38) and (1.42) for v E V N H2(~):
II[Rh(t) - I] ~llv
<
II[Rh(t) - I] ~llx
<
Ch Ilvl ~.(~),
Ch~ll'~ll_,-,~(~).
Therefore, from the elliptic estimate follows that
[IE~(t,s)ll
~_ (I + l Uh(t,s)l I . IIPhll) . l[[I- Rh(t)]A(t)-lll . llA(t)U(t,s)l I ~_ C h 2 ( t - s) -1
(3.70) (3.71)
3. Evolution Equations and FEM
120
Estimate of E~(t, s) We shall show the inequality
ll[Rh(t)-/~h(S)]Vllx <--Ch 2 It- sl ~ IvllH~(a)
(3.72)
for v E V N H2(f~). Then it follows that IIE~(t,s)ll
_
IIUh(t,r)Ah(r)ll
tl[Rh(t) - R~(~)] A(t)-' l[" IIA(t)U(t, s)ll d~ <
c
( t - s)-l+~h~d~. ( t -
= Ch2(t-
~)-~
Ch2(t- s) -1. To show (3.72), we recall the adjoint form .A~('u, v) = .At(v, u), and denote by/~h(t) the 8)-1+ c~ ~
Ritz operator associated with it:
.,4; (,Oh(t)~, ~:h) : A;(v, ~:h)
(,, ~ v, ~,, c v,,).
The inequalities
ll[/~h(t)--/]vlIv~ ChlvllH~(~) and
I][~h(t) -/]vllx ~ Ch21v IH~(nl hold similarly to (3.70) and (3.71), respectively, where v C V N H2(~2). Setting z = [Rh(t)- Rh(s)] v E Vh, we have
llzll
= A, (z,
A, (z,
=
(At - As) ([1 - Rh(s)] v, [~h(t)A(t)*-lz)
=
( A t - Ms)([1-- Rh(S)] V, [/~h(t)- I] A(t)*-lz) + ( A ~ - A s ) ( [ I - R/~(s)] v, A(t)*-lz)
= ( A t - A s ) ( [ I - Rh(s)]v, [/~h(s)- I] A(t)*-lz) + As ( [ I - Rh(s)] v, [A(s) * - 1 - A(t) *-1] z)
:
(,At- ,As)([I- Rh(8)] "u, [il~h(8) - I]
A(t)'-lz)
+ .As ([I - Rh(s)] v, [I - Rh(s)] [A(8) *-1 - A(t) *-1] z)
_<
+ c I I [ / - Rh(s)] vllv I[[1 - ~h(S)] [A(s) * - ] - A(t) *-]] 6' It - sl ~ h 2 Ilvl g=(~) IA(t) *-'zl ,,=(.) + Ch 2 Ilvlln=(~) l] [A(S)*-I -- A(t)*-l] ~11.~(~)-
zll~
3.3. Semi-discretization
121
The elliptic estimate implies
IIA(t)*-x~llH~(~) ~ c Ilzll~ and
II [A(s) *-1 -
A(t) *-1] ZlIH2(a) -< C It - sl ~ Ilzllx.
Inequality (3.72) has been proven.
E s t i m a t e of E3(t, s)
First Case
If V = H~(f~), the duality argument of Helfrich is applicable and inequality (3.22) follows. For Uo E D ( A ( s ) ) =_ D we have
jfst IIUh(t, r)Ah(r)ll.
SO ollx
I11I -/~h(r)] A(t)-l[[
IlA(t)[u(t, 9 s) - U(r, s)] A(s)-lll <_ Co
=
(t - s)-lhg(t - r)~
- s)-~
IlA(s)uollx 9 ds
IIA(s)u01 x
Ch 2 IIA(s)uollx
with 0 E (0, c~). We can show
for g = 1, 2 similarly, from the second estimate of (3.21). (Details are left to the reader.) We have
IIEh(t, s)A(s)-~ll < Ch 2.
(3.73)
Now, the semigroup property of evolution operators implies
Uh(t, r)Uh(r, s) = Uh(t, s)
and
U(t, r)U(r, s) = U(t, s)
for 0 _< s _< r < t _< T. The identity
Eh(t, s) = Uh(t, so)PhEh(So, s) + Eh(t, so)U(so, s)
(3.74)
follows with so = (t + s)/2. The second term of the right-hand side of (3.74) is estimated as
IIE~(t,~o)U(so, s)ll
<_ IJE~(t, so)A(~o)-~ll'llA(so)U(so, <
C h 2 ( t - s) -1
s)ll
3. Evolution Equations and F E M
122 by (3.73). On the other hand, (3.69) gives [[Uh(t,S)PhEh(So, S)II =
[IU~(t, so)Ah(So)Rh(So)A(so)-XEh(So, s)ll
< [Iuh(t, so)Ah(So)Ph [Rh(S0) - I]A(so)-lEh(So, S)] + ]lUh(t, so)Ah(so)PhA(So)-IEh(So, s)ll C(t- s) -1 {] [/~h(SO)- I] A(8o)-1 I 9 IIE,~(~o,s)ll +llA(so)-lEh(so, s)[I}. Because IIEh(So, s)ll ~ c follows from (3.66), inequality (3.68) is a consequence of
]A(t)-lEh(t,s)l
<_ Ch 2.
(3.75)
To prove this inequality, let
U(t, s) = U ( T -
s, T -
t)*
(Ih(t, s) = Uh(T - s, T - t)*.
and
Then,
{U(t,S)}o
{U~(t,S)}o
and
are nothing but the families of evolution operators generated by A(t) - A ( T t)* in X and Xh respectively. The relation
Ah(t) = A h ( T -
l~h(t, s) = l~l(t, s) - [Ih(t, S)Ph = E h ( T - s, T - t)* follows. Because
I1E,,/,sIAl,/ 11 is proven similarly to (3.73), we get (3.75) as
I[A(t)-lEh(t,s)[I E s t i m a t e of
Eta(t, s)
= ]lEh(t,s)*A(s)*-l][
<_ Ch 2.
Second Case
If V = H I ( ~ ) , D ( A ( t ) ) varies as t changes. We cannot expect the estimate
IIA(t)U( t, s)A(s) -1]1 <- C or IIA(t)[U(t, s) - U(r, s)]A(s) -1 II -< Co(t - r)~ In this case, we apply the method of telescoping as
5
(t- ~)E,~(t, ~) : ~ F~(t, s) g=l
- s) -~
t)* and
123
3.3. Semi-discretization
with the following terms:
fs t (r - s)Uh(t, r ) A h ( r ) . Ph [I - Rh(r)] [U(r, s) - U(t, s)] dr,
F~(t, s)
=
F~(t, s)
=
(t - r)Uh(t, r ) A h ( r ) " [Rh(s) -- R~(r)] [U(r, s) - U(t, s)] dr,
F~(t, s)
=
(t - r)[Uh(t, s ) A h ( s ) -- Uh(t, r)Ah(r)]
f'
Ph 9 [I - Rh(s)] [U(r, s) - U(t, s)] dr, (r -- s)[U(r, s) - U(t, s)] dr,
F2(t, s)
=
--Uh(t, s ) A h ( S ) " Ph [I -- Rh(S)]
F2(t, s)
=
Uh(t, s ) A h ( s ) . Ph [I -- Rh(S)] (t -- s)
[U(r, s) - U(t, s)] dr.
We have to show that [IFeh(t, s)l I _< C h 2
(g = 1, 2 , . . . , 5).
(3.76)
Recall that Kato-Tanabe's generation theory is applicable to (3.5). Combined this with the elliptic estimate we can show the following for 0 _< s < r < t _< T, where 0 _
IlU(t, 8) - U(r, 8)IlL2(FI),H2(~2) ~_ C k { ( t - T)~(T -- 8) -~-1 -1- ( t - T)~(T -- 8)-1} , IlUh(t,r)Ah(r) -- U , ( t , s ) A ~ ( s ) l l
<_ Ck { ( t - r ) - ~ - Z ( r - s) ~ + ( t -
/s'
[U(t, s) - U(r, s)] dr
I[
L2(f~),H2(f~)
(3.77)
r ) - l ( r - 8)a},
(3.78) (3.79)
< C.
Those inequalities are proven in the following way. Proof of (3. 77):
Take u0 E L2(f~) and set u(-, t) = U(t, S)Uo. We have B(x,t,D)u(x,t)
=0
on 0f~ where 13 = O/Ovc + ~. This implies B ( x , t, D) (u(x, t) - u(x, r)) : [B(x, t, D) - B ( x , r, D)] u(x, r)
there. Similarly, we have
[A(t)U(t, s) - A(r)U(r,
s)] uo(x)
+ [s
r, D) - s
t,
D)] u(x,
r)
3. Evolution Equations and F E M
124
in f~. The elliptic estimate gives
II[U(t, ~) - u(~, ~)1 ~olIH~(~) -- I1~(', t) -- ~(., ~)11,~(~) <_ C I~(', t, D) (u(., t) - u(-, ~))11~(~) +C ILL(', t, D) (u(., t) - u(., ~))11,,,~(o~) <_ C I I [ A ( t ) U ( t , ~) - A(,~)U(r, ~)] ~o11~(~) +C I [L(', ~, D) - s t, D)] u(., ~)11~(~) +C lilt3(', ~, D) - B(-, t, D)] u(., ~) I1,,,,~(o~) <_ C I I A ( t ) U ( t , ~) - A ( r ) U ( , ' , ~)11" luoll~(~) + C ( t - ,~) I1~(', ~)11~(~) <_ C IIA(t)U(t, ~) - A(,~)U(, , ~)11 I1'~o11~(~) + C ( t - ,~)(~- ~)-' I1~o11~(~) Inequality (3.64)implies (3.77).
[]
Proof of (3. 78)" This is nothing but the adjoint form of (3.64) applied to A(t) = Ah(t) and U(t, s) = Uh(t, s). [] Proof of (3. 79): Letting u(., t) = U(t, S)Uo, we have s
s, D) (u(x, t) - u(r, x)) = [s
+ [s
x, D) - E(s, x,
s, D) - s
t, D)] u(z, t)
D)] u(z, r) + [A(t)U(t, s) - A(r)U(r, s)] to(Z)
in t2 and B(x, s, D) (u(x, t) - u(x, r)) : [B(x, s, D) - B(x, t, D)] u(x, t) + [B(r r, D) - B(x, s, D)] u(r r)
on cgf~. The elliptic estimate now gives [U(t, s) - U(r, s)] no dr
f'
H2(U)
<_ C(t - s)II[E(., s, D) - s
+C
I[s
r, D) - s
=
('u(-, t) - u(., r ) ) d r
t, D)] u(.,
t)JlL~(~)
H2(~)
s, D)] u(-, r)llL2(U ) dr
+C(t - s)I [~(., s, D) - B(., t, D)] u(-, t)ll,,/~(on) +C <
C ( t - s) 2
[A(t)U(t, s) - A(r)U(r, s)] uo dr
Ji'u(-, t)llu~(n) + C
(r -s)tl'u(,
II
r)liu~(~)
L'~(n) dr
~)11 ~o11~(~) + C IIU(t, ,~) - I I. I1~,o11~(~) <_ C ( t - ~) I uoll~,(~) + C I uoll~(~) ___C I1,,,o I~(,) 9 +c(t
- ~)IIA(t)U(t,
3.3. Semi-discretization
125
The proof is complete. Now the proof of (3.76) is given as follows. First, with/3 E (0, 1) we have
IIF ( t, )ll -< <
/s
- s)Ilgh(t,
IIU(~. ~) - u ( t . ~)l ~ ( ~ ) , ~ ( ~ ) dr
I9I I - R~(~)ll.~(~).~(~)"
C~h 2
8 ) ( t - T) -1
(r9{( t -
<
r)&(r)l
T)~(T -- 8) -~-1 + ( t -
T)~(r -- s) -1 } dr
Ch 2
and
jfs t (t - r)IIUh(t, r)Ah(r)ll
~
IIFZ(t, s)ll
U(t, ~)llL=(~),H~(~)dr
IIRh(~) 9 - Rh(~)l H=(~),L=(~)" IIU0", ~0 -
_< c ~ h ~ fS t (~ - ~) {(t - ~)~(~ - ~)-~-~ + (t - ~)~(~ - ~)-1} a~ <
C h 2.
Next, with 0 < "i' < ~ _
_<
r) l U h ( t , r ) A h ( r ) -- Uh(t,s)Ah(s)l]
(t-
III 9 -
R"(S) IIH=(~),L=(~)"IIU(t,
~) - U(~', ~) IIL=(~),H=(~) d,"
( t - T) { ( t - r ) - l - ~ ( r - 8) ~ Jr- ( t - r ) - l ( r -
C~h 2
8) ~}
{ (t - T)7(r - 8) -1-3' -Jr (t - T)m(r -- S) -1 } dr <
C h 2.
W i t h / 3 c (0, 1), we have
I[F2(t, )ll
s)&(s)ll.
Ilun(t,
III-
Rh(S)IIH=(~),L~(~)
9 IIg(t, s) - U(r, S)[IL2(a),H:(a)" (r -- s) dr
<_
C~(t- s)-~h 2 9
<
{( t -
~)~(~ - ~ ) - ~ - 1 + ( t -
~)~(~-
~ ) - 1 } (~ _ ~) d~
C h 2.
Finally, we have [IF2( t, s)ll
_<
IUh(t,s)&(s)
9 <
C h 2.
liRa(s) 9 - IllH~(~),L~(~)
[u(~, ~) -
u(t,
~)] d~
L2(~"/),H2(n)
3. Evolution Equations and F E M
126 Summing up those estimates, we obtain
IlE2(t,~)ll <_ ch~(t_ ~)-, All the proof for inequality (3.68) is complete.
3.4
Full-discretization
Fully discrete approximations are obtained by discretizing the semidiscrete equation
duh dt
+ Ah(t)Uh = 0
(0 < t <_ T)
with
Uh(O) = Phuo
(3.80)
in the time variable t. In the present section, we adopt the backward difference method with the mesh length r > 0 satisfying T = N r . T h a t is,
U~h(t + r) -- U~h(t)
+ Ah(t + r)u,~(t + r) = 0
(t = n r )
(3.81)
in Xh with
~,~(o) = P~,o, where n = 0, 1,-.- , N. Thanks to (3.14), tile scheme is uniquely solvable and
e~h(t) = u h ( t ) - U,;(t) denotes the error, where t = nr. we shall derive
Id,(t)llx _< c~-t-' luol x and extend a result in w
(3.82)
Combining (3.82) with (3.67), we obtain
u(t) - u;(t)l x < C (h? + r) t-~ I 'uo Ix
(t = n r ) .
(3.83)
Let t,~ = nT and set
U[~ (tn, tj) =
{ ( / h + TAh(tn)) -1 (Ih + TAh(tn-1)) -1"'" (Ih + TAh(tj+l)) -1 Ih.
We have ~,;(t) = ui:(t, o)&~o
(t = t,,)
and
,,,,, ( t ) = u,, ( t, 0)P,,,~,o.
(~ > j) ( ~ = j).
3.4. Full-discretization
127
Drop the suffix h for simplicity of writing. Because of (3.80) and (3.81), we have for t = tn that
e ~(t + r) - e r(t)
tnt-r
f f
=
[A(t + r)u r(t + r) - A(r)u(r)] dr
at
=
t+r
[A(t + r)u(t + r ) -
A(r)u(r)] d r - r A ( t + r)e" (t + r).
,It
Hence
er(t -+- 7) = (1 + r A ( t + "r) )-l er (t) + (1 + r A ( t
+
T)) -1
f
t+r
[A(t + r)u(t + r ) -
A(r)u(r)] dr.
Jt
Because of e ~ (0) = 0 we obtain
e ~(tn)
-- E ~(tn)Puo =
(I q- 7A(tn)) -1 (I + "rA(tn_l)) - 1 . . . (I + TA(tk)) -1 k--1
-1
[A(tk)U(tk, 9 O) - A(r)U(r, 0)] drPuo,
(a.s4)
Er(t) being the error operator: E ,(t) = u(t, o)P - u ~(t, o ) Inequality (3.82) is reduced to those on the stability of the approximate operator U r (tn, tj+l) and the smoothness of the original one A(t)U(t, s) - A(r)U(r, s). We have proven Lemma 3.2 for the latter. As for the former, we have the following lemma, proven similarly to the continuous case: L e m m a 3.4. For each/3 E [0, 4/3), the inequality
II
tj)A(tj+l)Zll <__Cz(tn - tj) -~
(a.85)
holds true. Proof." Taking adjoint form reduces inequality (3.85) to I A(tn)ZU~(tn, tj)l] <__Cz(tn
-
tj) -~,
of which continuous version is proven in w
IIA(t)ZU(t, s)ll<_ Cz(t- s) -z All we have to do is to trace computations
in the context of discreteness.
(3.86)
3. Evolution Equations and F E M
128
In fact, inequality (3.26) holds for A(t) = Ah(t) uniformly in h as is described there. Identity (3.30) holds for A(t) = Ah(t) so that we obtain
U'(tn, tj) - (1 + rA(tj)) -(n-j) =
~
[(1 + ~-A(t~))-(~-k)U'(tk, t j ) - (1 + 7A(t~))-(n-k+l)U'(tk_x,tj)]
k=j+l
=
~
(1 +7-A(tn))-(~-k+l) [(1 +~-A(tn))- (1 +~-A(tk))]U'(tk, ty)
k:j+l
= T ~ (1 + rA(tn)) -('~-k+~) [A(tn) - A(tk)] U~(tk,tj) k=j+l = ~p=l
(1 + 7A(tn))-(n-k+UA(tn)l-PPD(tn, tk)A(tk)PPVr(tk,tj).
~
(3.87)
k=j+l
Given operator-valued functions fit = Ke(tn, tj) with t~ = 1, 2 on
D r={(t~,tj) I N>_n>_j>_O}, we define K = K1 .r /42 by n--1
(K1 *~ K2) (tn, tj) = ~- Z
Kl(tn, tk)K2(tk, tj).
k=j+l
Furthermore, we set
WT(t~,tj) Y~(rn, tj)
= Ur - (1 + TA(t~)) -(~-j) = A(t~)qPWT(t~,tj).
(3.88) (3.89)
Then, equality (3.87) reads: m
Yq = E p=l
H q~p , ~- U + Yq,~O,
(3.90)
where
Hq~p(t~, tj)
= A(tn)I-pP+qP(1 + ~-A(t~))-(~-J+l)D(t~, tj),
(3.91)
m ,0
=
,p
,- 1
(3.92)
p=l
with
Yp~_l(t,,,tj) = A(tn)PP(1 + TA(tn)) -(''-j)
(3.93)
Note the elementary inequality (3.94). The desired inequality (3.86) can be derived in a similar way to that in w
3.4. Full-discretization
129
Details are left to the reader, but the following inequality is worth mentioning, where
O < a
B N(a, b) - -~1 k=l
1
- -~
< S(a, b) =-
/o (1
-
-
x)a-lxb-ldx.
(3.94)
In fact, f(x) = (1 - x)a-lx b-1 is monotonically increasing in [0, 1) when b _> 1 _> a, while f(x) is convex in (0, 1) when a, b _< 1. Those facts imply (3.94). [] We are able to give the following.
Proof of (3.82):
E~(tn) =
The operator E ~ in the right-hand side of (3.84) splits as
n~k
(1 + ~-A(tn)) -1... (1 + TA(tk))-lA(tk)[e -tkA(tk)- e -rA(tk)] dr
E k=l
-1
(1 + rA(tn)) -1... (1 + rA(tk))-lA(tk)~Z~(tk, r, O) dr
+ k=l
=
-1
(1 + TA(tn))-lA(tn)
[e-tnA(t~) - e -rA(t~)] dr --1
+
Ur(tn, tk_l)A(tk)[e -tkA(tk)- e -ra(tk)] dr k=l
-1
~
+~
k=l
U'(tn, tk_l)A(tk)ZZz(tk, r, O) dr.
(3.95)
-1
Inequality (2.19) is applied to A = Ah(r) uniformly in h. We have for n > - 1 that
[IA(r)~[e -tA(~) -~-~A<~>]II C (t- s)s -n-l,
(3.96)
where 0 < s _< t < oc. Supposing n > 2, we can estimate the first term of the right-hand side of (3.95) as
[1(1 + TA(t~))-lA(tn)ll
~
n
lie -t~A(t~) - e-~A(t~)ll dr
--1
CT
( t n - r)r-~dr <_ CT-1T2(tn-1
-1 --1
~ Crt-
3. Evolution Equations and F E M
130
Next, by Lemma 3.2, the third term of the right-hand side of (3.95) is estimated as
k~l
Ilg~(t~,t~-l)A(t~)z[I
--1
< C a k1= ~
IIZz(tk, 9 r,O)ll dr
-, (tn - tk-l)-Z(tk -- r ) r - l + Z d r
n
___ c~ ~ ( ~ -
k + 1 ) - ~ - ~ ( k ~ ) ~-'
k=l n = c~
Z(~
- k + 1)-~k ~-1
k=l Inequality (3.94) now gives that
~~ IIg'(t~,
tk_l)A(tk)Zll ]lZz(tk, 9 r, O)l I dr <_ CT. k=l The desired inequality (3.82) has been reduced to
fi'
,11
To see this, take/3 C (0, 1/3). We get
n En-1 o~tl k U~(tn, tk_l)A(tk) k=l
[e - t k a ( t k )
- e -~A(tk)] dr
-' n-1( n = E k + 1)UT(t~, tk_l)A(tk) 1+'. ~tlk A ( t k ) - ' [e -tkA(tk) --e -rA(tk)] dr k=l -1 n-1
+ E(k
- 1)UT(tn, tk_l)A(tk) '-~
k=2 9
A(tk) ~ [e -tkA(tk) - e -rA(tk)] dr.
(3.98)
-1
The first term of the right-hand side of (3.98) is estimated by Lemma 3.4 and (3.96) as
n-1 ~-~.(n-k+ 1) llUT(t,~,tk_~)A(t~)'+Zll. ~t.lk IlA(tk) -~ [et~A(t~)--e-~A(t~)]l I dr k=l
-1
_< Cr Z ( r t - k + 1)-'T - 1 - ' ~t.lk (tk -- r)r'-idr k=l -1 n-1
rt-1
< C/3 Z ( ~ 9 , k=l
]~:-J-- I)-~qT -1-/~ T2(~T)/9-1 9
rt
:
Ca E ( n k=l
If + 1 ) - ' k '-1 _< C.
131
3.5. A l t e r n a t i v e A p p r o a c h
Similarly, the second term of the right-hand side of (3.98) is estimated as
n-1 E(kk=2
1)IIU~(t~,tk_l)A(tk)l-~ll. _< C 0
n-1
( k - 1)(tn - t k - ,
k=2 rz-1 _< c , ~ ( k k=2 n-1 < Cr E ( k k=2
/i k -1
)-1+/~
IIA(t,)~
9
[~-~(~)- ~-~(t~)] II d~
(tk - r ) r
-/~-1
dr
-1
- 1 ) ( ~ - k + 1) -1+~ ~-1+~. 9 ~ . ((k - 1)~) -~-~
- 1)-r
k -+- 1) r
< C.
The proof is complete.
3.5
Alternative
Approach
Inequality (3.83) is proven in a different way by the energy method. In this section, we describe the arguments of M. Luskin and R. Rannacher for the semidiscrete approximation and M.Y. Huang and V. Thom~e for the fulldiscrete approximation, respectively. A Priori Estimates
First, we show some estimates concerning the solution of the equation du d--7 + A ( t ) u = f (t)
with
(0 < t < T )
u(0) = ,to
(3.99)
in a Hilbert space X over R. Here, A ( t ) is an m-sectorial operator associated with a bilinear form At( , ) on V x V through a triple of Hilbert spaces V C X C V*. We suppose
I.,4t(,< ~)1
<
C1 Ilu Iv IIv Iv
and
.a~(~, ~) > 5 II~ll~-
(3.100)
for u, v E V, where C 1 > 0 and 5 > 0 are constants. It is also supposed to be smooth so that oq A (u, v)
and
02
exist and satisfy
IAt(,
and
A~(,~, ~)1 ~
c
I1~11~Ilvllv
132
3. Evolution Equations and F E M
for u, v C V. Problem (3.99) admits the weak form (Ut, ?J) + .At(u , v) ~- (f(t), v)
(3.101)
for v C V, where ( , ) denotes tile inner product in X. This implies (Utt , 72) nt- .At(ttt, v) -- - A t ( u ,
v) -nt- (It(t), v).
(3.102)
/0
(3.103)
We have the following. P r o p o s i t i o n 3.5. The inequality
Ilu(t)ll 2x +
/0
Ilu(s)llv~ ds _< C I1~oll ~x + c
IIf(s)ll~.ds
hold, fo~ th~ ,ol~t~o~ ~ = ~(t) of (S.99).
Proof: Putting v = u(t) in (3.101), we h~ve ld
2 dt Ilu(t)ll~ + 5 Ilu(t)ll~ _< Ilf(t)llv. Ilu(t)llv by (3.100). Then, Schwarz's inequality gives
-
and
d dt Ilu(t)ll2x + l u(t)llv2 < C Ilf(t)l 2v. -
_
inequality (3.103) follows.
[]
Letting .A;(u, v) = .At(v, u) and A ~ = (.At + .At)/2, we suppose that
v) + (B(t)u, v)
.At(u, v) = A~
(3.104)
holds with a bounded linear operator B(t) : V ~ X. This assumption is satisfied if .At(, ) is associated with a second-order elliptic operator with real coefficients. We have the following. Proposition
3.6. The inequality
ilu(t)ll 2v +
/0
Ilu~(s)llx2 ds _< C Iluoll 2v + C
/0
f(s)l
x
ds
holds for the solution u = u(t) of (3.99). Proof: Putting v = ut in (3.101), we have
Ilu~ I~ + A~(u, u~)
= (f,
Ut)
< --
1 2 1 ~ II/11X + 2 Ilu~ I~
"
On the other hand, equality (3.104) gives
1d
1
.At(U, Ut) = -~--~.At(U, U) -- = A t ( U , U) nrZ
1.B.t.u,( ( )
Ut)
Q
(3.105)
133
3.5. Alternative Approach
Those relations imply lutll x~ + ~dA , (u, u ) <_ C I/ll x~ + c I1~ Iv. Then, inequality (3.1o5) follows from (3.100) and (3.103). P r o p o s i t i o n 3.7. The inequality Ilu,(t)l x~ +
/o
I~,(s)llv~ ds _< C Ilu~(0)ll x2 + C l'~o I.~
(If(s)I~,. + II/~(~)11~v*) ds
+ C
(3.106)
holds for the solution u = u(t) of (3.99). Proof." Putting v = ut in (3.102), we have
ld 2 dt I1~'11~ + 61~,11~, < -<
c II~llv I1~ Iv + f~llv. I~1 v 1
-~11~ ~v + C' I1~ Iv~ + C IIf~llv* 9 2
This implies
Ilu~(t)ll ~x +
/o
Ilu~(sDllv~ds_< II~,(o)ll~ + c'
/o
II~(~)ll ~vds +
c
/o
II/t(s)ll~.
ds.
Then, inequality (3.106) follows from (3.103). P r o p o s i t i o n 3.8. The inequality
/0
s ~ Ilu,(s)ll~, ds _< C Iluoll.~ + c
ji
(ll/(s)[Iv. + II/~(s)ll 2v.) ds
holds for the solution u = u(t) of (3.99). Proof: Putting v = t2ut in (3.102), we have
ld 2 dt (t2 I]utl]~.) + 5t 2 Ilu, ll ~v < - ? A , ( ~ , u,) + t I1~11x~ + t2(ft, ut) -
-
v + c II~llv + t II~ll~ + ~t ~ II~,ll~, + c II/~ll 2V. 9
This implies d~ (t2 I[ut[ ~) +
I[ut][y _
g + t II~,llx + c IIf~ll~.
(3.107)
3. Evolution Equations and FEM
134 and the inequality
/o
s ~ Ilut(s)ll*v ds _< C
/o t (ll~(s)ll~
+ s lut(s)12x + lift(s)Iv*) ds
(3.108)
follows. Next, putting v = tut in (3.101), we have
t i1~,11~x+_did (tAt(u, for c > 0. The inequality
jot
II~t(~)ll ~ d ~ <_~
u))
--
At(u, u) -t- .At(u, u) -t- At(tut, u) -t- (f, tut)
-<
~t ~ll~t ~v + c~ II~llv + c~ IIf I~.
/~t
~ II~t(~)llv~ d ~ + C ~
jot (11~(~)11'v +
If(~)ll~.)d~
follows. Taking e > 0 small enough and combining this with (3.108), we have
/o s21lut(s)ll~ds c /o { Ilu(s)ll~ + II/(s)I~. + IIf,(s)I~. } ds. _<
Then, inequality (3.107) follows from (3.103). Proposition t llu,(t)ll~ +
3.9. The inequality
i
X
t
II~.(s)ll ~ ds <
c ilu,(o)ll x~ + c II~ollx~ + c
/o'
(llf~(~)llx~ + IIf(~)llv.) d~ (3.109)
holds for the solution u = u(t) of (3.99). Proof." Putting v
~-- Utt
in (3.102), we have
IlUttll 2X -Jr-,At (ut, utt) : -At (u, utt) + (ft, tttt).
(3.110)
Here, note that
12ddt.At(ut, ut) = < - At (.tz, tttt)
.At (ut, uu) + ~1 At (ut, ut) + 1 (But,
r
?ztt) + C I1..,11~
1
Utt)
2
d 9 ~-- - d--iAt (11., ?zt) -~- At (.~z,"~l.t) + At (ut, ut) <
-
d dt
A,(,~, .,~,) + c I1,,, } + c
ul ~v ,
135
3.5. Alternative Approach and 1 We obtain
d d &(~, ~,,) -< C I~,1 ~ + CII~I ~ + CIIf, ll~ u.ll~: + aTA,(~,, u,)+ ~7 Multiplying t now gives that
'(
)
t lluttll2x + -~t A~(u~, u~)+ At(u, ut) -< c(t +
1)(llut]l
2v + I~1 ~ +
Ift I~)-
This implies
tA~(~,~) +
/o
~ll~,(411~ <_ c
/o
(ll~,(~)llt + 11,,(~)115 + IIf~(~)ll~) d~.
Inequality (3.109)follows from (3.103)and (3.106). Semidiscrete Approximation Let fZ C R 2 be a convex polygon, and A t ( , ) a bilinear form on V x V with V = H~(f~) (for simplicity) induced from a second order elliptic differential operator. The associated m-sectorial operator in X -- L2(f2) is denoted by A(t). We take the evolution equation
du + A ( t ) u = O (O < t < T) dt
with
u(0)=u0
with
uh(0) = PhUo,
and its semidiscrete finite element approximation
duh d--T- + Ah(t)Uh = 0
(0 < t < T)
described in w and w respectively. Now we develop the error analysis by the energy method. Recall t h a t Rh = Rh(t)" V ---+Vh denotes the Ritz operator associated with At( , ):
At(Rh(t)v, Xh) = At(v, Xh)
(v e V, Xh r Vh)
(3.111)
We have the following. L e m m a 3.10. Any v = v(t) c C 1 ([0, T] --+ V) satisfies the inequality
Ila~(v- nhV)llH,(~) <_ Ch ~-j (llv g~(~)+ IIV~IIH~-,(~>) fork
1,2 and j = 0 , 1 .
(3.112)
3. Evolution Equations and F E M
136
Proof." Equality (3.111) implies
.A~(a,(v - R,,v), x~) = -A,(,, - R,,~. x~)
(3.113)
for Xh E Vh, and hence
a l a~(v - R~v)ll~
~
.At (oqt(y - R h V ) , Ot(v -- f~h'U))
--
.At (Ot(V -- R h V ) , Otv -- Xh) -- A t ( v -- R h V , Xh)
___ c (lla,(v follows. T h e results in w
Rhv)liv Ila~v
-
- xhll,,,. + IIv - Rhvllv
Ilxhllv)
are summarized as
II(Rh(t)-
1)v g,(n) <--
Chk-Jll~llH~(n)
(3.114)
for k = 1,2 and j = 0, 1. Taking Xh = Rh(t)Otv(t), we get (3.112) for j = 1 and k = 1,2. The remaining case j = 0 is obtained by the duality a r g u m e n t similarly, in use of (3.113) and the elliptic estimate of A(t). It is left to the reader. [] Suppose u0 E V, and take the solution Uh = gh(t) E Xh of duh
dt
+ Ah(t)gh = O (O <_ t <_ T)
~(0) = R~(0)~0.
with
We have the following. Lemma
3.11.
The inequality
Z
~ II~h(~)ll~-d~ ~
Ch~l ~o11~"
(3.115)
holds for -eh = u -- Uh. Pro@
We have
(9~,,, x,,) + A~(~,,, xh) = 0 for Xh E Vh. Taking Xh = Rh(t)-eh(t), we get ld
2dtll~hll~c+ A,(~h,~h)
=
(0,~h, (1 - Rh)-~h)+ At (eh, (1 -- Rh)~h)
=
(ateh, (1 - Rh)'U) + .At (-eh, (1 -- Rh)'U)
(
<_ c~ h~ I1,~11~(~) + Ila,~,~llx
) +cllehllv
for c > O. This implies
d -dt
1~,,112 x + -~hl ~ _<
Ch ~
( I1~11~,-,~(~)
+ Ila~,,llx
)
137
3.5. A l t e r n a t i v e Approach
by (3.100), and hence
/0
II~h(~)ll ~V dx
<
Ch ~
<_ c h ~
I1~(~) .:(~) + IIO~h(~)ll
ds + II~h(o)llx
II~(s)
+ ch ~ ~ol follows. The elliptic estimate gives
Ilu(s)ll/_z~(r~) < c IIA(~)~(s)Ix : c Ilu,(~)l x, while inequality (3.105) of Proposition 3.6 is valid for u = Uh uniformly in h. The righthand side is further estimated from above by ch ~
(11~ol ~ + IIRh(0)~oll~) <
Ch ~
I1~o
and the proof is complete.
[]
If one assumes the inverse assumption, L 2 orthogonal projection Ph " X ~ X h satisfies
llPhllv_v <_ c
(3.116)
by Proposition 1.5. Then, the inequality
fo ~ II~h(~)tl ~V d~ < is proven in a similar manner, where eh = u assumed in the following lemma.
Ch ~
I1~o11~,
Uh. However, inequality (3.116) is not
L e m m a 3.12. I f uo E V A H k - J ( ~ ) we have
~0 t II~h(~)ll x~ d~ <-
c t l - J h 2k
Iluo
2
,
(3.117)
9V)
(3.118)
where k = l , 2 and j = 0 , 1 . Proof:
Given t > 0, we take the backward problems (v, O~w) - A~(v, w) = (v, e~(s))
(v
with w(t) = 0 in X and
(x~. 0 ~ , )
- As(X,. ~ , ) = (x~. ~,.(~))
(x~ e v~)
with wh(t) = 0 in Xn, respectively. Those problems have unique solutions w = w(t)
9 C O([0, t), D (A(t)*)) A C O([0, t ] , X ) n C ~ ([0, t ) , X )
3. Evolution Equations and F E M
138 and
~
= ~(t)
~ c ' ([o.t]. x h ) .
respectively. In spite of the inhomogeneous terms in the right-hand side, the argument in the proof of Lemma 3.11 is applicable with the time variable t reversed. A quick overview reveals that
/o'
w(~) - w~(~)l ~. d~ _< C h ~
Combining this with inequality (3.105) implies that
L
' (llo~(~)-
<-
(21a, w,,(~) ~x + 2 IIO, w(~)llx~ + h -~ IIw,.(~) - w(~)ll~) d~
< c
--
I~,(~)1 ~ d~.
h-2 II~(~) - ~ , ( ~ ) l l ~ ) ds
o.~,.(~)+
/o' 1'
/o'
Ile,(s)ll ~ ds.
(3.119)
X
Taking v = eh(s) in (3.118), we have
II~,,(s)ll%
=
(e~(s),O~w(~)) - A~(~,,(s),w(s)) {(~,,. o ~ ( ~ - ~ , , ) ) - .4s(~. ~ - w,,)} + ( ~ , , . O s ~ , , ) -
..4~(~,,.w,,).
Here, eh = ( u - RhU)+ (Rhu- uh) and
(~,,. o~(w,,- ~)) - .4~(x,,. ~ , , - ~) = o holds for Xh E Vh. It follows that
I~,(~)11~
=
{(~-
~,,~. o ~ ( ~ - ~ , ) ) - A s ( ~ - R.,,~. ~ d + ~ (~,,. ~ ) - ( o ~ . w~) - .4~(~,,. ~ ) .
~,,)}
Furthermore, the equality
(O~eh, Xh) + A~(Ch, Xh) = 0 holds for Xh E Vh. W e have
I1~(~)11 ~x = ( ~ - R,,,~, o ~ ( w - w , , ) ) - A ~ ( ~ - R ~ , ~ -
d
w,,)+ y~ (~,,, ~,,).
In use of e,,(0) = wh(t) = 0, we h a v e
/0'
II~,,(~)ll ~X ds = _
/o' ]o'
( ( ~ - ~,,~,, a~(w - w , , ) ) -
~
A ~ ( u - R,,~, w - w,,))d~
(llOs~ - a~,,,,,, ~ + t,, -~ w - w , ,
+ c~
/0'
I~)d.~
(I ~ - ~,,,~11~ + h ~ I1,~- ~,,,~11~)d~
(3.120)
139
3.5. Alternative Approach
for c > 0. We obtain
/o
I I ~ ( ~ ) l l ~ d ~ -< C
/o
(ll**-Rh~ll ~~ + h ~ I1~- R ~ I I ~ ) d ~
by (3.119)and (3.120). Inequality (3.117)follows from (3.114). As is described in w
the following theorem implies Ileh(t) x <-- Ch2t-1 Iluollx
by Helfrich's duality method. T h e o r e m 3.13. If Uo E V r~ H 2 (f~), the estimate le.(t)llx < CA ~
luo H~(~)
(3.121)
holds true. Proof." Putting = [(t)= Rh(t)eh(t)= Rh(t)u(t)-
Uh(t) E Vh,
we have ({t, ~) 2t r
~)
--
(Ot(t~hU), ~) -- (OtUh, ~) Jr- r
=
(at(Rhu), ~) - (atu, ~) -(a~(~ - R~), ~).
:
~) -- At(Uh, ~)
Multiplying t implies
1 d (t I1{11~)
2 dt
1 t~t,(~, {) = ~ I1{11~ -
+
t(at(u
-
Rhu)
~)
and hence
t ll{(t)ll~: < c --
J/o'
I1{(~)11~ d ~ + C
f'
~ Ila~(u- R~u)(~)lt ~ d~ X
follows. We obtain
t Ileh(t)ll 2X -< t l l ( u - Rhu)(t)ll~: + C + c
/o
Ile~(s)ll~ d~
I I ( u - R~u)(~)ll~ d~ + C
jo
~ Ila~(u- R ~ ) I I ~ d~.
Here, Lemma 3.10 applies. We get
t lleh(t)ll 2X <- C foot Ileh(s)llx2 ds + Cth 4
{
max [[U(S)IIH2(~) + O
)}
8 [[U(S)IIH2(~) + [[Ut(8)[[ 2u~(n) ds
140
3. Evolution Equations and F E M
For the right-hand side we have
fo' I1~(~)11~ d~ X
< --
C t h 4 I1~o11~(~)
by (3.117), and also
I~(~) IH~(~) _< c II~oll.~(a) and
Jo"(
u(~)ll ~
)
~
d~ < C I ~oll ~
by Propositions 3.7 and 3.9, respectively. Inequality (3.121) now follows. Full-discrete
Approximation
The energy method is also applicable to the error analysis for fully discretized problems. Here we study the backward difference finite element method,
~;(t + r - ~ ( t ) T
+ Aj~(t + T)U "(t h + ~) = 0
with
~;~(o)
=
Phi0,
w h e r e t = t n f o r 0 _ < n < N. We drop the suffix h, and the error is denoted by e(t) = u ' ( t ) - u ( t ) .
The inequality
L e m m a 3.14.
n--1
t 2 Ile(t)ll x2 < - c~ -2 I~011x~ + Cr ~
IIe" (tj)llv.2
(3.122)
j=l
holds for t = tn. Proof:
Given v = v(t), we put
Otv(t) = v(tj) - v ( t j _ l ) T
for t = tj with j _> 1. We have (ut, v) + At(u, v) = 0
and
(O~u~,v) + A~(u ~, v) = 0
for v E V and t - tj. It follows that
(Ote(tj), v) + At3 (e(tj), v) = (Tj, v) ,
(3.123)
3.5. Alternative Approach
141
where
1 f~~, 1 (~_ "~j = Otu(tj) - ut(tj) = -~
tj_,)~.(~) d~
(3.124)
Putting ~(ty) = tje(tj) and ~j = ty3'j, we get
(Ote(tj), v) 4- At3 (e(tj), v) = (~j 4- e(tj-1), v) . Letting v = ~(tj) now gives that
1 (~(tj) - e(tj-1), ~(tj)) 4- Atj (~(tj), ~(tj)) = (~j 4- e(tj_l), ~(tj)). T In other words, the inequality 1
:2 (ll~-(tj)ll~-II~(tj
-
12) 4- TAt, (~(tj), ~(tj)) = T (X/j 4-
- 1)112 x + r 2 IIO~(tj)
e ( t j _ l ) , e(tj))
holds and we obtain ila(tj)ll ~x - I I ~ ( t j - 1 ) l l
~ + 2 w ~ l ~ ( t j ) l l ~V X
<_ 27 (Sj 4- e(tj_l), ~(tj)) < 2~- { c (llgjll ~v . + I l e ( t j - 1 ) l l v ~. )
+ ~
-
Ila(tj)llv}
9
We have II~(tj)ll X ~ - I l e ( t j - 1 ) l l x<- 2Cw ([l@jl[~. + Ile(tj-1)[2v.)
and hence
t 2 Ile(t,)llx = II~(t,)lI2x <__2 c T
tj 1l'TjIlv. + j=l
Ile(tj)lIv 9
{3.125)
j=l
follows. Equality (3.124) implies ii,),jll2 _~ 1 T
/t;
' (8 - t j _ l ) 2 Ilutt(8)ll 2. d8 1
and hence tj II~jll..
follows because t y ( s with f = 0 implies
_
ftj 'j--1
..
tj-1) <_ Ts for s E [tj-1, tj]. On the other hand, equality (3.110) IIuttllv. < Cllutllv + CIlullv.
(3.126)
3. Evolution Equations and F E M
142
Therefore, we get
n
2
2
< ~-~
j=l
j~0tn
-< c wi
~ I1~.(~)111 V* d~
/o ' (ll~(~)ll~+s ~ll~r
_ cw 2 Ilu011~
by Propositions 3.5 and 3.8. Inequality (3.122) is now a consequence of (3.125). For the operator T(t) =_ A(t) -1, the relation Ilfllv.
~
IIZ(t)fllv
(f ~ Vh)
holds uniformly in h. In use of T'(t) = - A ( t ) - l A ' ( t ) A ( t ) - l ,
I Z'(t)fllv <_ C
Ilfllv.
we have
9
In terms of T(t), equality (3.123) is written as
T(tj)Ote(tj) + e(tj) = T(tj)3,j. Setting Fj = T(tj)~,j, we get
Ot [T(tj)e(tj)] + e(tj) = Fj + [OtT(tj)] e(tj_l). Here we take L 2 inner product with T(tj)e(tj).
We have
(T(tj)e(tj), e(tj)) ~ I e(tj)l
~.
and
(Ot [T(tj)e(ty)] , T(tj)e(ty)) 1 = 2T (llT(tJ)e(tJ) 12X - I l T ( t j - l e ( t j - 1 ) I x
+ 7-IIOt [T(tj)e(tj)]llx),
as in the proof of L e m m a 3.14. It follows that
_1 2
(llZ(ty)e(tj)ll 2x --[IT(tj -1 )e(tj_ 1 )1 2x + ~ II0, (T(tj)e(tj))ll 2 ~) 2 x / + ~ I~(tj)llv. 7<_ Ilrjllv. IIT(tj)e(tj)llv + II[O~T(tj)] e(t~_l) x IIT(tj)e(tj)l x
with a constant # > 0. The right-hand side is estimated from above with some t, 6_ (tj_l, tj)"
I FjlIv. IIT(tj)e(tj)llv § IIT'(t,)e(tj-1)llv T ( t j ) e ( t j ) I x _< c (IIFjlIv. e(tj)llv. + Ile(tj-,)l v. IIZ(tj)e(tj)l x) 1
2
2
_< -~. (lle(tj)llv. + I e(tj_~)llv.) + C (llT(tj)e(tj)ll 2X + IIFj I~*).
(3.127)
Commentary to Chapter 3
143
We obtain 1
9
3
1
2
2
2
+ ~ - , (If~(tj)lf v. -II~(t~- ~)11~.) _< c~- (llT(tj)~(t~)fl~ + Ilrjlt~.) and hence
]]T(tn)e(tn)]] x2 + ~ s
II~(tj)ll~. -< c ~ s
j=l
Ilrjll ~v.
n + c~- ~lf(tj)e(tj)ll2x
j=l
j=l
follows. Then the discrete Gronwall's inequality implies that n
IIT(t~)e(t~)llx + f
Ile(tj)ll V* 2 <- - CT ~ j=l
Ilrjll 2V*
"
(3.128)
j=l
Here, Schwarz's inequality gives JIFjll2v.
IIZ(tj)'~jll~. < 1__
-
T
~ (s - tj_~) 2 ]lZ(tj)u~(s)l[~. ds 1
similarly to the proof of Lemma 3.14. On the other hand, T(t)ut + u = 0 implies
T(t)utt = - u t - T'(t)ut. Therefore, given s E [tj-1, tj] there exists s. E (tj-1, tj) satisfying
<_ Ily(s)utt(s)llv. + f IlY'(s,)u,(s)lIv. _< Ilu~(s)llg. + IIT'(s)~,(s)ltv. + w IlT'(s,)utt(s)llv.
IIT(tj)u,(s)llv.
<__ c (ll~(~)llv. + II~,(~)llv + ~ II~,(~)llv.). In use of [lutllv. = I A(t)ullv.
< C I1~11~, w~ h~v~
IIT(t~)~.(~)llv. <
c
(ll~(*)llv
+ ~
II~,(*)llv)
by (3.126). Consequently, the inequality
~ - ~ Ilrjll ~. _< C j-1
j=l
-1
(~- tj_~ (11~(~)11~+
-<
c~ ~
<
c w 2 IIPu0112
--
(ll~(s)ll =v +
I1~(~)11~)d~
~ Ilu,(~)ll~)ds (3.129)
X
follows from Propositions 3.5 and 3.8. Combining (3.122) with (3.128) and (3.129) gives inequality (3.82):
II~(t)lt~
< CTt-1
II~ollx.
3. Evolution Equations and FEM
144 Commentary
to C h a p t e r 3
3.1. The generation theory of Tanabe-Sobolevskii was given by Tanabe [377] and Sobolevskii [353], independently. Inequality (3.17) is a consequence of the elliptic estimate of Agmon, Douglis, and Nirenberg [3]. The generation theory of Fujie-Tanabe was given by Fujie and Tanabe [132]. Inequality (3.23) follows from the coerciveness of At. The righthand side may be replaced by C~ Izl, but this form simplifies the treatment of fractional powers of A(t). The proof of (3.23) is also given in Tanabe [378]. Generation theory of Kato-Sobolevskii was given by Kato [201] when p-1 is an integer and Sobolevskii [354] for the general case. Inequality (3.27) was made use of by Heinz [169] and Kato [202], [200]. For the theories of fractional powers of m-sectorial operators, see Kato [199]. Inequality (3.26) was also proven there. Equality (3.3o) is due to P.E. Sobolevskii. The theory of Kato-Tanabe was given by Kato and Tanabe [209]. See also Suzuki [368] and ~3.3 for the fact that smoothness of bilinear forms confirm the assumptions of the last theory. Most of those generation theories are described in Tanabe [378] in details. 3.2. Inequality (3.55) was proven by Suzuki [368]. Proof of (3.64) was also given there. Note that necessary assumptions for A(t) are those on the theory of Kato-Tanabe and inequalities (3.60)-(3.62). Once they are provided, the Banach space structure induces the conclusion. 3.3. Inequality (3.67) was proven by Fujita and Suzuki [147] for boundary condition (3.a) and Suzuki [3661, [36s] for the general case. Related works were done by Helfrich [171], Fujita [140], Suzuki [365], and Sammon [335]. 3.4. For the detailed proof of (3.86), see Suzuki [368]. Inequality (3.82) was proven by Suzuki [366], [3681 Related works were done by Sammon [335]. 3.5. Error analysis on the fully discrete approximation of temporally inhomogeneous parabolic equations has been done independently by Baiocchi and Brezzi [23], Huang and Thom~e [184], [185], Luskin and Rannacher [256], [257], and Sammon [336], [337] Contrarily to Suzuki [366], [368], the Hilbert space structure of the problem were used systematically there. The works described in this section were done by Luskin and Rannacher [256] and Huang and ThomSe [185]. The error analysis for schemes with higher accuracy were done by Baiocchi and Brezzi [23], Luskin and Rannacher [257], and Sammon [336], [337].