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Chapter VI Inverse Scattering Problem for Time-Dependent Potentials
225
CHAPTER VI INVERS E SCATTER1N G PROBLEM FOR TI M E- DEP EN DENT POTE NTlALS
This chapter is devoted t o the inverse scattering problem for time-dependent potentials q ( t , x) which are not periodic in time. Moreover, q ( t , z) might increase polynomially as t -+ 00. In this situation the local energy can increase too, and, in general, the scattering operator S does not exist. For this reason we introduce t h e generalized scattering kernel K # in Section 6.1. If S exists, then K # coincides with the kernel o f the operator S - Id in t h e translation representation o f Uo(t). We obtain a representation of
I<# involving a solution w ( t , x ; s , w ) of for large negative time equal t o
(0
+ q)w
= 0 with initial d a t a
~5(”-~)/’(t + s- < x , w >).
In Section 6.2
w modulo smooth terms. The uniqueness of t h e inverse scattering problem is established in Section 6.3. Here we expose we construct a parametrix for
a procedure for recovering a stationary potential from the scattering data. Finally, we discuss a link between the inverse scattering problem and t h e asymptotic o f the scattering amplitude .(A,
0 , w ) as
1x1
+ m.
6.1. Generalized scattering kernel Throughout this section we assume n
2 3, n odd,
and we use the notati-
ons o f Chapter V. Let q ( t , x) be a potential satisfying the conditions (a) and
(b) of assumption (H,) in Section 5.1. For such potentials the scattering operator S does noet exist in general, and we cannot define the scattering kernel.
Nevertheless, we introduce a natural generalization o f this kernel
called generalized scattering kernel. For this purpose we first obtain a link between t h e asymptotic wave profiles of the outgoing solutions o f (5.1.1) and those o f the solutions of t h e Cauchy problem for 0 . Introduce the function
Inverse scat t ering problem for time-dependent pot entials
226
and for s 6 R,w
E S"-* consider t h e solution P ( t ,x ; s , w ) of t h e problem
+ q)r+= o ,
{ r+
(6.1.l)
(0
= hl(t
+
3-
< x , w >) .
For the initial data in (6.1.1) we find
+
(hl,Y)(t
5-
< x , w >) E C ( R t x R,x
s : l ;
HAW),
Y ( t ) being the Heaviside function. As we have mentioned in Section 5.1, this guarantees t h e existence o f a solution I?+ with
Define
u + ( t , x ; s,w) = r + ( t , x ; s , w ) - hl(t
+ s-
us+c(t,z;s , w ) = dp+l)/*u+(t,x;s , w )
< x , w >) ,
.
Below we show that utc is closely related t o the kernel of the scattering operator S.
E Ho have translation representation ( R , q ) ( s , w ) E C,"(B x Sn-')with k = 0 for Is1 > a . Then Uo(-t)cp E 0: for t > a + p. We fix t o > a p and set g = U ( 0 , -to)Uo(-to)'p. Then we find Let
'p
+
lim IIU(-t,O)g - Uo(-t)'pII =
t-w
t , it easily follows t h a t g = W-'p. In the general case, we preserve this notation and set g = W-cp. Clearly, W-'p does not depend on t h e choice of to. Introduce In t h e case that q ( t , x ) is periodic with respect t o
(vo(t,x), atvo(t,4) = Uo(t)'p , (v+(t,21, &v+(t,4) = U ( t ,o w - ' p
-
Generalized scattering kernel
227
With the notation vo#(s,w) for the asymptotic wave profile of v o ( t , z ) , we have t h e following. Lemma 6.1.1.
Let cp E (6.1.3)
Ho be such that R,cp E Cr(R x
9-l).
Then
v + ( t , z ) = vo(t,z) - ( 2 ~ ) - ( " - ' ) / ~ .
. J J u+(t,2 ; s, w)a;"+')/2v,#(s, w)dsdw , where the integral must be interpreted in the sense of distributions.
Proof. Denote by V+(t,z)the right-hand side of (6.1.3).
Since u+ = 0 for
< -t - p and v,# = 0 for Is( > a and some a > 0, we obtain V+ = vo for t < -a - p. By Proposition 2.3.2 we have s
/
vo(t,z) = -(27r)-("-')/2
dp-3)/2"0#(< 2 , w
> -t,w)dw
sn-1
Then
V+(t,z) = vo(t, z) + (2r)-("-')/2
-
Consequently, V+(t,z)is a solution t < -a - p. On the other hand,
to > a
+ p.
Thus
s-
< 2 , w >) -
r+(t,z ; s , w ) ] ap+1)/2v,#(s,w)dsdw =
= -(2n)-("-')/2
for
// [ h l ( t +
JJ
r+(t, ; 9, w)ajn+1)/2v,#(s, w)dsdw.
of (5.1.1) with initial data
V+ = vo for
V+ and v+ are solutions of (5.1.1) with equal initial
data, hence V+= v+. The proof is complete. 0
The function u+ is a solution of the equation
Inverse scattering problem for time-dependent potentials
228
~ ~ + (s ,tw ,) ~ = -; q ( t , q + ( t , x ; s , w ) E
E Since u+ = 0 for
t <
c(w,x s;-1
; L;o,(& ; L y R : ) )
.
-s - p,
u+ is obviously outgoing. So by Theorem 2.6.6, we conclude that ut has an asymptotic wave profile u f ( s ’ , 0 ; s , w ) E C(R,x Sz-’; L,”,,(Rnz,, x Sg-l)). Taking the asymptotic wave profiles in (6.1.3), we deduce (6.1.4)
w+#(s‘, 0 ) = v,f(s’, 0 ) -
- (2
JJ u f ( s ’ , 0 ; s,w)d~+’)/’v,#(s,w)dsdw .
-(n-1)/2
Now assume t h a t t h e scattering operator S exists. As in Section 4.1 set
s = R, SR,’
.
Then S is a bounded operator from
L2(Rx Sn-l) into L 2 ( Rx Sn-l).The
relation
shows t h a t t h e asymptotic wave profile v+#(s‘,0) coincides with t h e asymptotic wave profile o f presentation
R,Sq
(Uo(t)Sp)l. The latter differs from the translation re-
only by the factor -2-’/2(-i)(n-’)/2.
So we can rewrite
(6.1.4) in t h e form (6.1.5)
(.?1vo#)(s’, 0 ) = vo#(s’, 0) t
where
and the integral in (6.1.5) is taken in t h e sense of distributions. This observation shows that the Schwartz kernel of t h e operator
3 - I d coincides with
the distribution K # ( s ‘ , O ; s , w ) . On the other hand, we may introduce I<# even if S does not exist. Moreover, we have the equality
Generalized scattering kernel
01
o+#(s/,
= w,j+(s1,0>
229
+ JJ
o ; s,w)vf(s,w)dsdw.
~#(s',
For this reason we introduce t h e following.
Deflnltlon. Assume q ( t , x ) satisfies the conditions (a) and (b) of Section 5.1. Then t h e distribution
K # , given by (6.1.6), is called the generalized scattering kernel
of problem (5.1.1).
Roughly speaking, I@ is t h e asymptotic wave profile of u : = d!ntl)/z~t.
But we cannot directly apply Theorem 2.6.6 to u;,. Next we obtain a representation for I<#. Given cp(s',s) E
C,"(R2),we
have (6.1.7)
// K # ( s ' , O ;
s , w ) ( P ( s ' , s ) ~ s '= ~s
1)/2
.
s , w ) . All integrals are taken in the sense of distributions. In the second equality of (6.1.7) we have used Proposition 2.6.8 and the fact t h a t Out = -qI'+. Thus we have proved the following. Theorem 6.1.5
The generalized scattering kernel
I<#
K#(s',0 ; s , w ) = - d i
JJ
(6.1.8)
admits the representation
d p - 3 ) / 2 q ( tx)w(t, , x ; s,w) .
. d::-')/%(t
+
SI-
< x,0 > ) d x d t ,
Inverse scattering problem for time-dependent potentials
230
where the integral is interpreted as in (6.1.7).
Moreover,
K#
i s a C"
function of 0, w with values in the space of distributions in s', s. Notice that for
1x1 5
p t h e function
has compact support with respect t o t ,
d$'-1)/2d~"t')/2~(< z,0 > - t , s ) 2
and s. So integration with re-
t , z and s in (6.1.7) can be taken in the ordinary sense since q(t, z)r+(t2 , ; s , w ) E C ( R t x Esx SZ-l; L?oc(IR;)).On the other hand, if q ( t , z) E C"(R"+*), a similar argument implies that K# is a C" function
spect t o
of s , 0 , w with values in the space of distributions in s'. a
To study the support of I{#, we need some preparation. First we obtain representation for U ( t , s ) when t and s are bounded.
Lemma 6.1.4.
t
For fixed
E
IR, s E IR and f
.Hpthe series
E
+C 00
(6.1.9) U ( t , s ) = Uo(t - S)
K(t,s)
k=l
with
1 1 t
Vk(t,S)
=
a1
do1
8
a
d
~
...2
8
7'
dUk
8
Uo(t - a i ) & ( ~ i ) ~ o( 00 2i ) ... U O ( 0 k - 1 - 0 k ) Q ( n k ) U o ( 0 k
k 2 1, is convergent
in
- s)f
Hp. Moreover, the convergence is uniform when t
and s run over bounded intervals.
where t
R ~ ( t , s ) f= (-l)N
J
dal
I
Let
CA
,
> 0 and 7 > 0 be constants
...
7-l
daNUo(t
8
for which
- 0 1 ) Q ( o 1 ) ...
Generalized scattering kernel
231
Then
IIRN(t,s)ll 5 CA It - s l N y N / N !5 CA(2Ay)N/1 and the convergence of (6.1.9) follows immediately. 0
Lemma 6.1.5.
We have
Proof. Clearly, the initial data f of I?+
a t the time tl
in the half space l-I's,w = { ( t , x ) : < x , w
< -s - p are supported
> 5 t + s } . We
claim that the
same is true for
W ~ ( t , t ~= ) fUo(t - .~)Q(.~)...&(.N)~O(.N
- t1)f
Indeed, assume ( t o , x O )E s u p p U o ( a ~- tl)f and consider the backward cone
c, = { ( t , Z )
:
Ix - 501 5 t o - t , t < t o }
.
By a finite propagation speed argument the cone Co must intersect the space
l-I's,w. Thus there exists
(i,i) E nS,,n Co which implies
< z0,u > 5 < i , w > Repeating this argument for
+ li - 201 5 c + s + t o - t^ = t o + s .
Q(ak)Uo(ak
- Ok-l)g, k = 2, ..., N
claim is proved. Application of (6.1.9) finishes the proof. 0
Obviously, Lemma 6.1.5 yields
- 1, the
Inverse scattering problem for time-dependent potentials
232
(6.1.11)
c ( ( t , z ) : < z,w > 5 t + s} .
supp w t,x
After this preparation we turn t o the analysis of s u p p K # . Theorem
6.1.6.
For fixed
0,w
we have
Proof. Assume (d,0 ; s , w )
E suppK#.
In view of (6.1.8) there exists
(i,2 )
such that
lil I p ,
(i,2 ) E supp w(t, z ; 5,w ) , i + sf - < i,0 > = 0 .
By (6.1.11) we find
and the proof is complete. 0
In the next section we shall construct a parametrix for possible t o examine t h e behaviour o f
K # as 0
-t
w which makes it
w.
6.2. Construction of a parametrix for w ( t , z ; s , w ) Throughout this section we use freely t h e notations of the previous section and we assume that q ( t , z )
E Cm(Rnt') is a potential satisfying t h e
conditions (a) and (b) of Section 5.1. Introduce the functions
Notice t h a t hk(E) E
Hkc(R).
We shall construct a parametrix u, for w of the form
Construction of a parametrix for w ( t , x ; s , w )
(6.2.1) u , ( t , x ; s , w )
Applying ( 0
233
)+
=S(t+s-
+ q ) to urn we find j=O m
+2 C j=O
where
((at
+
< w,
02
>)Aj)hj-l
7
h-l = 6. Determining A j inductively from the equations
we find
-W
/
0
(6.2.2)
1 Aj+l(t,x,w) = - 2 --oo j=o,l,
Clearly,
((0+ q ) A j ) ( t + n , x
+ a w , w ) d ~,
...,m - 1 ,
A j = 0 for
< x,w > <
urn= 6 ( t + s -
- p , j = 0,1, ..., rn,hence
< x,w >) f o r t < - s - p
Thus we get
It is straightforward t o see that
hj(t
+s -
< x,w >) E C ( R t x ZR, x s y ; H:,,(a:)) ,
j
21
Inverse scattering problem for time-dependent potentials
234
Moreover, the support of ((0 {(t,X)
Since 0
: -p
+ q)A,)h,
is contained in the set
5 < z,w > 5 t +s} .
+ q is a strictly hyperbolic operator,
t h e energy estimates for t h e
solutions of the Cauchy problem (6.2.3) yield the following. ProDosition 6.2.1 We have
w ( ~ , xS;, W )
(6.2.6)
m
=
C
- 6(t + s - < X , W
>) =
A j ( t , ~ , w ) h j (+tS - c X , W >)
j=O
where
R,
E
+ R,(~,x;
S,W)
,
C ( R t x R,x SG-’; Hmt’(Rz)).
In the same way we can show that
R,
has N derivatives with respect t o
t , E , s, w , provided rn is sufficiently large. 6.3. Uniqueness of t h e inverse scattering problem for time- dependent potentials Throughout this section we assume n = 3 and consider potentials q(t, x) satisfying
(i) (ii)
4(t,Z) E
C Y R 4 )9
there exists p > 0 such that q ( t , X) = 0
for 1x1 2 p, t E
(Q)
(iii) there exist C
R,
> 0, N > 0 such that
Iq(t,z)l 5 C ( l +
for all ( t , x ) E R4.
Our aim in this section is t o prove that if the generalized scattering ker-
(Q) coincide, then the potentials coincide, too. W e start with a useful formula for I<#(s’,O; s , w ) . nels of two potentials satisfying
Proposition 6.3.1.
For 0 # w we have
Uniqueness of the inverse scattering problem
K#(s', 0 ; s , w ) =
(6.3.1)
+J
2,O >
q(<
- s',X)u;(<
Proof. Let cp(s',s)
=
+
+
=
I2
Clearly, t h e integrals
R3 as
s' - s.
yields
K#(s', 0 ; S,W)cp(S',S)dS'ds
I1
< 2, 0 - w > =
E C,"(IR2). Since w ( t , z ; s , w ) = usfc(t,x; s , w ) + S ( t
< x , w >), application o f (6.1.8)
JJ
1,
2,0 > - s f , 2 ; s,w)da:
where dS, denotes the measure in the hyperplane
s-
235
Il
and
I2 are taken over
compact sets. In
I* we
regard
a union of planes
IJ
{z : < x , O - w > =
s'-s}
S'ER
and thus write
Il
in the form
On the other hand, according t o Proposition 6.2.1, for fixed w E S2 we have
L ~ o , ( I R t x I R , x I R ~Changingthevariable< ). z,O > 12,we obtain (6.3.1). The proof is complete.
uL(t,z;s,w) E = s' in 0
-
t
=
Inverse scattering problem for time-dependent potentials
236
Now we pass t o the main result o f this chapter. Theorem 6.3.2.
Let qi(t, z), i = 1,2, be two potentials satisfying t h e assumption (Q) and let
.I 0 so t h a t
(6.3.2) Kf(s‘, O ; S , W ) = Kf(s‘, 0 ; S, w )
( w - w o ( < 6 , Is’-s1<6.
for 1 0 - w 0 ( < 6 ,
Then q l ( t , z )= q 2 ( t , 2 ) for all
Proof.
For fixed
( t , z ) E R4.
O # w the distribution
is a smooth function of s with values in t h e space of distributions in s‘. Since u:, = 0 for < z,w > > t s, it is straightforward t o check t h a t
+
M(s’,O; s , w ) = O
for s ’ - s
>plO-w(.
Mi(s’,O; s , w ) , i = 1,2, the functions related t o q ; ( t , x ) , i = 1,2. Since I
d (6.3.3) - ( M i - Mz) = 0 dS’
# w , (0- wo( < 6,(w - u g ( < 6,1s’ - s( < 6. Fix 0 # w so that 10 - woI < E , I w - wo( < E , where 0 < E 5 rnin(:,
for 0 Then
MI = M2 = 0 for
s’
> s + 5/2.
Combining this with
6).
(6.3.3),we arrive
at
10 - w o J < E , Ju-wol < 6 , 1s’ - sI < E . Now fix E > 0. We want t o examine the behaviour of 10, - wI h.I, as 0, -t w , s h -+ s for m -t 00. The functions Mi are not conitnuous in
for
Uniqueness of the inverse scattering problem s’,
0 , s, w. So limm+m 10,
{Om}, {&I.
Take a E S2, < a , w
--wI
237
Mi depends on the choice of the sequences
> = 0 and set
O ( p ) = w cos p
+ a sin p ,
s’(p) = s
+ a! sin p .
Obviously,
-s‘(p)+s
P = [
2
-cr]sinp
and hence,
(6.3.5)
lim lO(p) - wI M,(s’(p),O ( p ) ; s , w ) = )r-0 P#O
=a
Indeed, taking into account representation (6.2.6) for u:~, we conclude t h a t
ut remains bounded for fixed w E S2 as t , z and s run over a compact set. This observation enables us t o deduce the boundedness of the integrals
- s ‘ ( p ) , p ; s,w)dz as p
00.
---f
U L ,denotes ~ the solution related t o q,, i = 1,2. Conse-
Here
quently, from (6.3.4) and (6.3.5) we derive
1
(6.3.6)
(41 - q2)(< z , w
> - s,z)dSx = 0
=Cl
for all s E
R,
(Y
E
R
and all w , a E S2 satisfying
IW-WIJI<&,
By q we denote q1 q ( t , z ) = 0 for
- q2.
=
0.
Our next purpose is t o show that (6.3.6) implies
( t , z ) E R4. Fix s and w so that I w - woI < E . Given a E S2, < a , w > = 0, choose b E S2 so that the triple (w, a , a) forms an orthonormal basis in E3.Setting z = (YU + Pb + yw,from (6.3.6) we find the equality
23 8
Inverse scattering problem for time-dependent potentials
11
(6.3.7)
q(y - s , a u
+ p b + yw)dpdy = 0
for all a E R
.
Define
Qdz) =
J
q(r - 8
+ p b E {x
,
+ 7w)dy , ~
< z , w > = 0). Choosing arbitrary orthogonal unit vectors a , b in t h e plane < x , w > = 0, we conclude that t h e integral of Q s , w ( z )over each straight line in t h e hyperplane < x , w > = 0 vanishes.
where z = a a
:
Now using t h e inverse Radon transform, it is easy t o see that Q S , J z ) = 0 for all z , i.e.
1
(6.3.8)
q(y - s , a a
R,CY
for all s E
E
+ p b + yw)dy = 0 IR, Iw - woI < E and basis in < x , w > = 0.
R,p
forming an orthonormal
E
for all unit vectors a , 2,
The condition (iii) guarantees t h a t q ( t , z ) E J’(R4). Hence t h e Fourier transform
@(T,<)E
Given cp(r,<)E
Cr(R4),we
have
< i(T,E),cp(?-,E)> =
(6.3.9)
= where
J‘(R4)exists.
J q ( t , x) [J e-i*T-i(p(T, < ) d ~ d < dtdx ] ,
< , > denotes t h e action
of
G(T,<)
butions. L e t a , b , w form an orthonormal variables
we obtain
v(T,<)in t h e sense of distribasis in R3.Introducing the new on
Uniqueness of the inverse scattering problem
239
then by (6.3.8) we can conclude that (6.3.10) < ~ ( T , ( ) , V ( T , ( )> = 0
.
To make this argument precise, we must show that the set c3,,,s has a non-empty interior. Consider an orthonormal basis a , b,wo in R3. Introduce a ( p ) = a cos p - w,-, sin p
,
w ( p ) = wo cos p
+ a sin p .
Clearly, for Ipl < ~ / we 2 have Iw(p) - woI < E . The vectors a ( p ) , b, w ( p ) form an orthonormal basis in R3 and by (6.3.8) we find (6.3.11)
J
Q(Y - % 4 P )
+ Pb + V J ( P ) ) d Y= 0
R,/3 E R and Ipl < ~ / 2 . Given a fixed T~ E R,choose toso that
for all s E
R,cr
E
Consider the equation (6.3.12)
= aa(p)
+pb - .~(p)
A simple calculation yields
By the implicit function theorem we determine the functions p ( ~t ,) as solution of (6.3.12) for
0 < E~ being sufficiently small. Clearly, we can choose
€0
t ) ,P(T, t),
CY(T,
so that
Now choose V ( T ,<) E C,"(R4)with suppcp c Co. Consider the integral with respect to (T,<)in (6.3.9) and pass to the new variables
+,
(7,
0, P ( T , E l , P ( 7 , t ) ),
Then in view of (6.3.13) we find
(TrO
E
co
'
Inverse scattering problem for time-dependent potentials
240
with ( ( ~ , a , , b , p= ) aa(p)
+ ,bb - ~
( p ) The . integration in
T,
a,p, p is
over some small neighbourhood of (TO,ao,@O,O).
We wish t o change the order of integration in (6.3.14). For this purpose consider
Next for fixed p , Ipl 2,
< ~ / 2 ,in the
above integral with respect t o
t and
we apply the change of variables
tIf(t,s,p)l = y - 3 ,5 CN(1 z = a'a(p) + Itl’)-’+ p'b* + y f d ( p ). This justifies thefunction change of the order o f integration: Then t h e phase
tr
+
< x , ( ( ~ , a , / ? , p ) >= a ' a + P ' P - s r
does not depend on y. Thus we are in position t o apply (6.3.11) which yields
Uniqueness of the inverse scattering problem
$(T)
=0
for
241
IT - rol > E O ,
(J e-""vt>@(t)d<) dtdx
=
J
=
J ~ " - + c (J q ( t , x M ( t ) d t ) @(<)dt.
q(t,x)&t)
=
$ ( t ) is the Fourier transform of $ with respect t o T and 3"-+( denotes the Fourier transform with respect t o x . Since Q ( < ) is an arbitrary test function with support in {[ : I< - to[< E ~ } we , derive Here
(6.3.15) FX+t
(/ q ( t, x) &t) d t) = 0
On t h e other hand, according t o (ii),
for
I< - (01 < EO .
Inverse scattering problem for time-dependent potentials
242
F(O = ~ L - E
(J q ( t ,z ~ t ) d t )
is an analytic function of
J
I . By (6.3.15)we deduce
q(t,z)q(t)dt = o
for 1x15 p
.
We rewrite this in the form
J Ft,,
q(t, z)d(t)dt =
< 3 t + , q ( t , 5),$(4 > = 0
being the Fourier transform with respect t o
Since 7.0
7
t . This yields
E B is arbitrary, we obtain q ( t , z ) = 0 for all ( t , z ) E R4and t h e
proof is complete. 0
Finally, we discuss briefly the stationary case in which q ( z ) does not depend on
t . First, it is easy t o see t h a t K # ( s ’ , O ; s , w ) depends on - s. In fact, let wO(t, z ; w) be the solution of the problem
the
difference s’
(6.3.16)
(0
+ q(z))wo = 0
WO lt<-,
7
< z,w >)
=qt -
Then we obtain 2U(t,z; s , u ) = w r J ( t + s , z ; w)
and changing the variables in
(6.1.8),we find
‘J ‘J
(6.3.17)K # ( s ’ , O ; s , w ) = 8n2
Thus
q(z)&wO(< z,0
>
+ s - s’,z;
w)dx
K#(s’, 0 ; s , w ) = S#(s‘ - s, 0 , w ) , where
(6.3.18) S#(s,O,w) = 7
q(z)dtwo(< z , 0
is a smooth function of 0 , w E
S2with
8n
-
S,Z;
w)ds
values in t h e space of distributions
6.3.2says that if the scattering to the potentials q ; ( x ) , i = 1,2,satisfy
in s. In this situation Theorem
i = 1,2,related
>
kernels S?,
.
Uniqueness of the inverse scattering problem S,#(S,
243
0 , w ) = S,#(S,0 , w )
for Is1 < 6, 10 - woI
< 6,Iw - uoI < 6,
then q I ( z ) = q2(z).
For stationary potentials q ( z ) there exists a simple procedure for recovering q ( z ) from S#(s,O,w).
Assume that we know the distribution
S # ( s , O , w ) related t o q ( z ) for Is1 < S and all 0 E S2, w E S 2 . Since S#(s,O,w) = d , M ( s , O , u ) , we can determine M ( s , O , w )for Is1 < S
&
from the expression S
< ~ ( s , ~ , w ) , p (>s = )
-ST~
< ~ # ( s , ~ , w-) ,J
p(cr)da
>,
--oo
where 'p E
C,"(lsl < 6). For a E S2, < a,w >= 0 we set
~ ( p=) Q sin p
,
O ( p ) = w cos p
+ a sin p
and define
In physics literature, t h e inverse scattering problem is connected with t h e scattering amplitude. T o discuss this connection, consider t h e case t h a t t h e operator
L = -A
+ q(z), introduced in Section 5.5, has no point spectrum.
Then t h e global energy of the solutions with initial data and for fixed z , w E to
t.
f E Ho
is bounded
S 2 , w o ( t , x ; w ) is a tempered distribution with respect
This implies that for fixed 0 , w E S2, S # ( s , O , w ) is a tempered
distribution with respect t o s. We define the scattering amplitude by
2T .(X,O,w) = - Fs+xS#(s,O,w) ,
zx
.Fs.+x being the Fourier transform with respect t o s. It is easy t o see t h a t
3 , , ~ ( d ~ w ~z( <, >~ - s , z ; w ) ) = -ixewhere v0(X, z ; w ) = Fs',,xwo(s, z ; u)and
iX
Vo(-X,
z ; 0)
,
Inverse scattering problem for time-dependent potentials
244 (A
+ X2 - q(z))vo(X,
Thus
1 (6.3.19) a(X, 0 , w ) = - -
4n
2
1
;W ) = 0
.
e-ix<"o>q(z)vo(-X,
z ; w )dz
.
Setting
U ~ c ( t , z ; w ) = w o ( t , z ; w ) - S (t),
we obtain
(6.3.20) a(X,O,w) = -
-
!- eixX<"9W-o' q(x)dx 4x 4n
J
e-iX
-
q ( x ) v s c ( - X , z ; w)dz
'
Consider the function u + ( t , z ; w ) = rt(t,x ; 0 , w ) - hl(t - < x , w >) with and hl as in Section 6.1. Omitting the dependence of rt on s and w , we
conclude that u+ is an outgoing solution of the equation
nu+ = -q(z)r+(t,a:j . Conseq uent I y, t
u+ = -
J
( ~ o (t
(0, q ( x ) r + ( T ,x)))
d~ =
-M M
= -
J
( U 0 ( 4 ( 0 ,n(.)r+(t
-
.,4)), do
*
0
Choose p ( X ) E J ( R )and denote by v+(X,x; w ) the Fourier transform of u + ( t , z ; w ) with respect to t . Then (6.3.21)
< v+(X,x; w),p(X) > = < u + ( t , x ;w ) , J e-ixtcp(X)dX > = M o o
=-
J J -03
0
(uo(0)(0, q ( x ) r + ( t- 0,~ 1 ) ) ~.
245
Uniqueness of the inverse scattering problem When z runs over a compact set in
R3,t h e integration with
respect t o c in
(6.3.21) is over a bounded interval. For such z we can change the order of integration and get
v,,(--X,x; w ) =
w) =
-X%+(-X,X;
03
=
J
( ~ o ( o )(0, q(x)eixovo(o, ; w ) ) ) d c
.
0
Repeating t h e argument of t h e proof o f Theorem 2.6.9 with p = -iX, we can transform the latter integral and we obtain a representation o f vSc(-X, z ; w ) by the outgoing Green function
rZixgiven
Thus we see that
in (2.6.12).
vsc( -A, x ; w ) is t h e unique (-iX)-outgoing solution of the equation
(A
+ X2 - q ( x ) ) v s c =
Furthermore,
q(X)e
iX
v,, satisfies t h e outgoing Somrnerfeld condition (2.6.17) and
we can find a link between u(X,O,w) and the asymptotic behaviour of
v,,(X,x; w ) as z = r 0 , r = 1x1 --+
00.
In physics literature t h e term
is called Born approximation. Letting
X(O - w )
-+
1x1
-+
00,
10 - wI
-+
0, so t h a t
- p , we can find from the Born approximation the Fourier
transform i ( p ) . On the other hand, it is possible t o show that the second term in the right-hand side of (6.3.20) goes t o 0 as
1x1
respect t o 0 , w E S2. The reader should consult Saito
-+
00
uniformly with
111 for results in this
direction. Thus the Born approximation determines uniquely t h e potential Q(X).
Inverse scattering problem for time-dependent potentials
246 Notes
The idea t o consider a generalized scattering kernel I<# for scattering by moving obstacles is due t o Cooper and Strauss 121, 141. Lemma 6.1.1
[4]. The representation 6.1.3,and Lemma 6.1.4have been obtained by Stefanov [8]. In Sections 6.2 and 6.3 we closely follow the above work of Stefanov, where Theorem 6.3.2 is proved. This theorem generalizes t h e previous results o f Ferreira and Perla Menzala [l] and Stefanov [5], [6],
is an analogue o f a result of Cooper and Strauss
of
I<#, given
in Theorem
where t h e uniqueness of t h e inverse scattering problem for two potentials
qi(t,z), i = 1 , 2 , has been treated under the assumption q l ( t , z )2 q l ( t , z ) . For stationary potential t h e representation
(6.2.6)has
been obtained and
111, Newton [l], Rose, Cheney and De Facio [l],[2]. A procedure for recovering q ( t , x) from t h e solution of t h e Newton-Marchenko
studied by Morawetz
equation for time-dependent potentials has been proposed by Stefanov 171. Thus he generalizes the previous results for stationary potentials.
The inverse scattering problem for stationary potentials has been examined by many authors. We refer t o t h e books o f Marchenko and Chadan and Sabatier
[3],Levitan [l]
111 for the results and history concerning this pro-
blem. The recent results for t h e multidimensional inverse scattering problem are exposed in t h e important work o f Henkin and Novikov
[l].
CHAPTER VI INVERS E SCATTER1N G PROBLEM FOR TI M E- DEP EN DENT POTE NTlALS
This chapter is devoted t o the inverse scattering problem for time-dependent potentials q ( t , x) which are not periodic in time. Moreover, q ( t , z) might increase polynomially as t -+ 00. In this situation the local energy can increase too, and, in general, the scattering operator S does not exist. For this reason we introduce t h e generalized scattering kernel K # in Section 6.1. If S exists, then K # coincides with the kernel o f the operator S - Id in t h e translation representation o f Uo(t). We obtain a representation of
I<# involving a solution w ( t , x ; s , w ) of for large negative time equal t o
(0
+ q)w
= 0 with initial d a t a
~5(”-~)/’(t + s- < x , w >).
In Section 6.2
w modulo smooth terms. The uniqueness of t h e inverse scattering problem is established in Section 6.3. Here we expose we construct a parametrix for
a procedure for recovering a stationary potential from the scattering data. Finally, we discuss a link between the inverse scattering problem and t h e asymptotic o f the scattering amplitude .(A,
0 , w ) as
1x1
+ m.
6.1. Generalized scattering kernel Throughout this section we assume n
2 3, n odd,
and we use the notati-
ons o f Chapter V. Let q ( t , x) be a potential satisfying the conditions (a) and
(b) of assumption (H,) in Section 5.1. For such potentials the scattering operator S does noet exist in general, and we cannot define the scattering kernel.
Nevertheless, we introduce a natural generalization o f this kernel
called generalized scattering kernel. For this purpose we first obtain a link between t h e asymptotic wave profiles of the outgoing solutions o f (5.1.1) and those o f the solutions of t h e Cauchy problem for 0 . Introduce the function
Inverse scat t ering problem for time-dependent pot entials
226
and for s 6 R,w
E S"-* consider t h e solution P ( t ,x ; s , w ) of t h e problem
+ q)r+= o ,
{ r+
(6.1.l)
(0
= hl(t
+
3-
< x , w >) .
For the initial data in (6.1.1) we find
+
(hl,Y)(t
5-
< x , w >) E C ( R t x R,x
s : l ;
HAW),
Y ( t ) being the Heaviside function. As we have mentioned in Section 5.1, this guarantees t h e existence o f a solution I?+ with
Define
u + ( t , x ; s,w) = r + ( t , x ; s , w ) - hl(t
+ s-
us+c(t,z;s , w ) = dp+l)/*u+(t,x;s , w )
< x , w >) ,
.
Below we show that utc is closely related t o the kernel of the scattering operator S.
E Ho have translation representation ( R , q ) ( s , w ) E C,"(B x Sn-')with k = 0 for Is1 > a . Then Uo(-t)cp E 0: for t > a + p. We fix t o > a p and set g = U ( 0 , -to)Uo(-to)'p. Then we find Let
'p
+
lim IIU(-t,O)g - Uo(-t)'pII =
t-w
t , it easily follows t h a t g = W-'p. In the general case, we preserve this notation and set g = W-cp. Clearly, W-'p does not depend on t h e choice of to. Introduce In t h e case that q ( t , x ) is periodic with respect t o
(vo(t,x), atvo(t,4) = Uo(t)'p , (v+(t,21, &v+(t,4) = U ( t ,o w - ' p
-
Generalized scattering kernel
227
With the notation vo#(s,w) for the asymptotic wave profile of v o ( t , z ) , we have t h e following. Lemma 6.1.1.
Let cp E (6.1.3)
Ho be such that R,cp E Cr(R x
9-l).
Then
v + ( t , z ) = vo(t,z) - ( 2 ~ ) - ( " - ' ) / ~ .
. J J u+(t,2 ; s, w)a;"+')/2v,#(s, w)dsdw , where the integral must be interpreted in the sense of distributions.
Proof. Denote by V+(t,z)the right-hand side of (6.1.3).
Since u+ = 0 for
< -t - p and v,# = 0 for Is( > a and some a > 0, we obtain V+ = vo for t < -a - p. By Proposition 2.3.2 we have s
/
vo(t,z) = -(27r)-("-')/2
dp-3)/2"0#(< 2 , w
> -t,w)dw
sn-1
Then
V+(t,z) = vo(t, z) + (2r)-("-')/2
-
Consequently, V+(t,z)is a solution t < -a - p. On the other hand,
to > a
+ p.
Thus
s-
< 2 , w >) -
r+(t,z ; s , w ) ] ap+1)/2v,#(s,w)dsdw =
= -(2n)-("-')/2
for
// [ h l ( t +
JJ
r+(t, ; 9, w)ajn+1)/2v,#(s, w)dsdw.
of (5.1.1) with initial data
V+ = vo for
V+ and v+ are solutions of (5.1.1) with equal initial
data, hence V+= v+. The proof is complete. 0
The function u+ is a solution of the equation
Inverse scattering problem for time-dependent potentials
228
~ ~ + (s ,tw ,) ~ = -; q ( t , q + ( t , x ; s , w ) E
E Since u+ = 0 for
t <
c(w,x s;-1
; L;o,(& ; L y R : ) )
.
-s - p,
u+ is obviously outgoing. So by Theorem 2.6.6, we conclude that ut has an asymptotic wave profile u f ( s ’ , 0 ; s , w ) E C(R,x Sz-’; L,”,,(Rnz,, x Sg-l)). Taking the asymptotic wave profiles in (6.1.3), we deduce (6.1.4)
w+#(s‘, 0 ) = v,f(s’, 0 ) -
- (2
JJ u f ( s ’ , 0 ; s,w)d~+’)/’v,#(s,w)dsdw .
-(n-1)/2
Now assume t h a t t h e scattering operator S exists. As in Section 4.1 set
s = R, SR,’
.
Then S is a bounded operator from
L2(Rx Sn-l) into L 2 ( Rx Sn-l).The
relation
shows t h a t t h e asymptotic wave profile v+#(s‘,0) coincides with t h e asymptotic wave profile o f presentation
R,Sq
(Uo(t)Sp)l. The latter differs from the translation re-
only by the factor -2-’/2(-i)(n-’)/2.
So we can rewrite
(6.1.4) in t h e form (6.1.5)
(.?1vo#)(s’, 0 ) = vo#(s’, 0) t
where
and the integral in (6.1.5) is taken in t h e sense of distributions. This observation shows that the Schwartz kernel of t h e operator
3 - I d coincides with
the distribution K # ( s ‘ , O ; s , w ) . On the other hand, we may introduce I<# even if S does not exist. Moreover, we have the equality
Generalized scattering kernel
01
o+#(s/,
= w,j+(s1,0>
229
+ JJ
o ; s,w)vf(s,w)dsdw.
~#(s',
For this reason we introduce t h e following.
Deflnltlon. Assume q ( t , x ) satisfies the conditions (a) and (b) of Section 5.1. Then t h e distribution
K # , given by (6.1.6), is called the generalized scattering kernel
of problem (5.1.1).
Roughly speaking, I@ is t h e asymptotic wave profile of u : = d!ntl)/z~t.
But we cannot directly apply Theorem 2.6.6 to u;,. Next we obtain a representation for I<#. Given cp(s',s) E
C,"(R2),we
have (6.1.7)
// K # ( s ' , O ;
s , w ) ( P ( s ' , s ) ~ s '= ~s
1)/2
.
s , w ) . All integrals are taken in the sense of distributions. In the second equality of (6.1.7) we have used Proposition 2.6.8 and the fact t h a t Out = -qI'+. Thus we have proved the following. Theorem 6.1.5
The generalized scattering kernel
I<#
K#(s',0 ; s , w ) = - d i
JJ
(6.1.8)
admits the representation
d p - 3 ) / 2 q ( tx)w(t, , x ; s,w) .
. d::-')/%(t
+
SI-
< x,0 > ) d x d t ,
Inverse scattering problem for time-dependent potentials
230
where the integral is interpreted as in (6.1.7).
Moreover,
K#
i s a C"
function of 0, w with values in the space of distributions in s', s. Notice that for
1x1 5
p t h e function
has compact support with respect t o t ,
d$'-1)/2d~"t')/2~(< z,0 > - t , s ) 2
and s. So integration with re-
t , z and s in (6.1.7) can be taken in the ordinary sense since q(t, z)r+(t2 , ; s , w ) E C ( R t x Esx SZ-l; L?oc(IR;)).On the other hand, if q ( t , z) E C"(R"+*), a similar argument implies that K# is a C" function
spect t o
of s , 0 , w with values in the space of distributions in s'. a
To study the support of I{#, we need some preparation. First we obtain representation for U ( t , s ) when t and s are bounded.
Lemma 6.1.4.
t
For fixed
E
IR, s E IR and f
.Hpthe series
E
+C 00
(6.1.9) U ( t , s ) = Uo(t - S)
K(t,s)
k=l
with
1 1 t
Vk(t,S)
=
a1
do1
8
a
d
~
...2
8
7'
dUk
8
Uo(t - a i ) & ( ~ i ) ~ o( 00 2i ) ... U O ( 0 k - 1 - 0 k ) Q ( n k ) U o ( 0 k
k 2 1, is convergent
in
- s)f
Hp. Moreover, the convergence is uniform when t
and s run over bounded intervals.
where t
R ~ ( t , s ) f= (-l)N
J
dal
I
Let
CA
,
> 0 and 7 > 0 be constants
...
7-l
daNUo(t
8
for which
- 0 1 ) Q ( o 1 ) ...
Generalized scattering kernel
231
Then
IIRN(t,s)ll 5 CA It - s l N y N / N !5 CA(2Ay)N/1 and the convergence of (6.1.9) follows immediately. 0
Lemma 6.1.5.
We have
Proof. Clearly, the initial data f of I?+
a t the time tl
in the half space l-I's,w = { ( t , x ) : < x , w
< -s - p are supported
> 5 t + s } . We
claim that the
same is true for
W ~ ( t , t ~= ) fUo(t - .~)Q(.~)...&(.N)~O(.N
- t1)f
Indeed, assume ( t o , x O )E s u p p U o ( a ~- tl)f and consider the backward cone
c, = { ( t , Z )
:
Ix - 501 5 t o - t , t < t o }
.
By a finite propagation speed argument the cone Co must intersect the space
l-I's,w. Thus there exists
(i,i) E nS,,n Co which implies
< z0,u > 5 < i , w > Repeating this argument for
+ li - 201 5 c + s + t o - t^ = t o + s .
Q(ak)Uo(ak
- Ok-l)g, k = 2, ..., N
claim is proved. Application of (6.1.9) finishes the proof. 0
Obviously, Lemma 6.1.5 yields
- 1, the
Inverse scattering problem for time-dependent potentials
232
(6.1.11)
c ( ( t , z ) : < z,w > 5 t + s} .
supp w t,x
After this preparation we turn t o the analysis of s u p p K # . Theorem
6.1.6.
For fixed
0,w
we have
Proof. Assume (d,0 ; s , w )
E suppK#.
In view of (6.1.8) there exists
(i,2 )
such that
lil I p ,
(i,2 ) E supp w(t, z ; 5,w ) , i + sf - < i,0 > = 0 .
By (6.1.11) we find
and the proof is complete. 0
In the next section we shall construct a parametrix for possible t o examine t h e behaviour o f
K # as 0
-t
w which makes it
w.
6.2. Construction of a parametrix for w ( t , z ; s , w ) Throughout this section we use freely t h e notations of the previous section and we assume that q ( t , z )
E Cm(Rnt') is a potential satisfying t h e
conditions (a) and (b) of Section 5.1. Introduce the functions
Notice t h a t hk(E) E
Hkc(R).
We shall construct a parametrix u, for w of the form
Construction of a parametrix for w ( t , x ; s , w )
(6.2.1) u , ( t , x ; s , w )
Applying ( 0
233
=S(t+s-
+ q ) to urn we find j=O m
+2 C j=O
where
((at
+
< w,
02
>)Aj)hj-l
7
h-l = 6. Determining A j inductively from the equations
we find
-W
/
0
(6.2.2)
1 Aj+l(t,x,w) = - 2 --oo j=o,l,
Clearly,
((0+ q ) A j ) ( t + n , x
+ a w , w ) d ~,
...,m - 1 ,
A j = 0 for
< x,w > <
urn= 6 ( t + s -
- p , j = 0,1, ..., rn,hence
< x,w >) f o r t < - s - p
Thus we get
It is straightforward t o see that
hj(t
+s -
< x,w >) E C ( R t x ZR, x s y ; H:,,(a:)) ,
j
21
Inverse scattering problem for time-dependent potentials
234
Moreover, the support of ((0 {(t,X)
Since 0
: -p
+ q)A,)h,
is contained in the set
5 < z,w > 5 t +s} .
+ q is a strictly hyperbolic operator,
t h e energy estimates for t h e
solutions of the Cauchy problem (6.2.3) yield the following. ProDosition 6.2.1 We have
w ( ~ , xS;, W )
(6.2.6)
m
=
C
- 6(t + s - < X , W
>) =
A j ( t , ~ , w ) h j (+tS - c X , W >)
j=O
where
R,
E
+ R,(~,x;
S,W)
,
C ( R t x R,x SG-’; Hmt’(Rz)).
In the same way we can show that
R,
has N derivatives with respect t o
t , E , s, w , provided rn is sufficiently large. 6.3. Uniqueness of t h e inverse scattering problem for time- dependent potentials Throughout this section we assume n = 3 and consider potentials q(t, x) satisfying
(i) (ii)
4(t,Z) E
C Y R 4 )9
there exists p > 0 such that q ( t , X) = 0
for 1x1 2 p, t E
(Q)
(iii) there exist C
R,
> 0, N > 0 such that
Iq(t,z)l 5 C ( l +
for all ( t , x ) E R4.
Our aim in this section is t o prove that if the generalized scattering ker-
(Q) coincide, then the potentials coincide, too. W e start with a useful formula for I<#(s’,O; s , w ) . nels of two potentials satisfying
Proposition 6.3.1.
For 0 # w we have
Uniqueness of the inverse scattering problem
K#(s', 0 ; s , w ) =
(6.3.1)
+J
2,O >
q(<
- s',X)u;(<
Proof. Let cp(s',s)
=
+
+
=
I2
Clearly, t h e integrals
R3 as
s' - s.
yields
K#(s', 0 ; S,W)cp(S',S)dS'ds
I1
< 2, 0 - w > =
E C,"(IR2). Since w ( t , z ; s , w ) = usfc(t,x; s , w ) + S ( t
< x , w >), application o f (6.1.8)
JJ
1,
2,0 > - s f , 2 ; s,w)da:
where dS, denotes the measure in the hyperplane
s-
235
Il
and
I2 are taken over
compact sets. In
I* we
regard
a union of planes
IJ
{z : < x , O - w > =
s'-s}
S'ER
and thus write
Il
in the form
On the other hand, according t o Proposition 6.2.1, for fixed w E S2 we have
L ~ o , ( I R t x I R , x I R ~Changingthevariable< ). z,O > 12,we obtain (6.3.1). The proof is complete.
uL(t,z;s,w) E = s' in 0
-
t
=
Inverse scattering problem for time-dependent potentials
236
Now we pass t o the main result o f this chapter. Theorem 6.3.2.
Let qi(t, z), i = 1,2, be two potentials satisfying t h e assumption (Q) and let
.I
(6.3.2) Kf(s‘, O ; S , W ) = Kf(s‘, 0 ; S, w )
( w - w o ( < 6 , Is’-s1<6.
for 1 0 - w 0 ( < 6 ,
Then q l ( t , z )= q 2 ( t , 2 ) for all
Proof.
For fixed
( t , z ) E R4.
O # w the distribution
is a smooth function of s with values in t h e space of distributions in s‘. Since u:, = 0 for < z,w > > t s, it is straightforward t o check t h a t
+
M(s’,O; s , w ) = O
for s ’ - s
>plO-w(.
Mi(s’,O; s , w ) , i = 1,2, the functions related t o q ; ( t , x ) , i = 1,2. Since I
d (6.3.3) - ( M i - Mz) = 0 dS’
# w , (0- wo( < 6,(w - u g ( < 6,1s’ - s( < 6. Fix 0 # w so that 10 - woI < E , I w - wo( < E , where 0 < E 5 rnin(:,
for 0 Then
MI = M2 = 0 for
s’
> s + 5/2.
Combining this with
6).
(6.3.3),we arrive
at
10 - w o J < E , Ju-wol < 6 , 1s’ - sI < E . Now fix E > 0. We want t o examine the behaviour of 10, - wI h.I, as 0, -t w , s h -+ s for m -t 00. The functions Mi are not conitnuous in
for
Uniqueness of the inverse scattering problem s’,
0 , s, w. So limm+m 10,
{Om}, {&I.
Take a E S2, < a , w
--wI
237
Mi depends on the choice of the sequences
> = 0 and set
O ( p ) = w cos p
+ a sin p ,
s’(p) = s
+ a! sin p .
Obviously,
P = [
2
-cr]sinp
and hence,
(6.3.5)
lim lO(p) - wI M,(s’(p),O ( p ) ; s , w ) = )r-0 P#O
Indeed, taking into account representation (6.2.6) for u:~, we conclude t h a t
ut remains bounded for fixed w E S2 as t , z and s run over a compact set. This observation enables us t o deduce the boundedness of the integrals
- s ‘ ( p ) , p ; s,w)dz as p
00.
---f
U L ,denotes ~ the solution related t o q,, i = 1,2. Conse-
Here
quently, from (6.3.4) and (6.3.5) we derive
1
(6.3.6)
(41 - q2)(< z , w
> - s,z)dSx = 0
for all s E
R,
(Y
E
R
and all w , a E S2 satisfying
IW-WIJI<&,
By q we denote q1 q ( t , z ) = 0 for
- q2.
0.
Our next purpose is t o show that (6.3.6) implies
( t , z ) E R4. Fix s and w so that I w - woI < E . Given a E S2, < a , w > = 0, choose b E S2 so that the triple (w, a , a) forms an orthonormal basis in E3.Setting z = (YU + Pb + yw,from (6.3.6) we find the equality
23 8
Inverse scattering problem for time-dependent potentials
11
(6.3.7)
q(y - s , a u
+ p b + yw)dpdy = 0
for all a E R
.
Define
Qdz) =
J
q(r - 8
+ p b E {x
,
+ 7w)dy , ~
< z , w > = 0). Choosing arbitrary orthogonal unit vectors a , b in t h e plane < x , w > = 0, we conclude that t h e integral of Q s , w ( z )over each straight line in t h e hyperplane < x , w > = 0 vanishes.
where z = a a
:
Now using t h e inverse Radon transform, it is easy t o see that Q S , J z ) = 0 for all z , i.e.
1
(6.3.8)
q(y - s , a a
R,CY
for all s E
E
+ p b + yw)dy = 0 IR, Iw - woI < E and basis in < x , w > = 0.
R,p
forming an orthonormal
E
for all unit vectors a , 2,
The condition (iii) guarantees t h a t q ( t , z ) E J’(R4). Hence t h e Fourier transform
@(T,<)E
Given cp(r,<)E
Cr(R4),we
have
< i(T,E),cp(?-,E)> =
(6.3.9)
= where
J‘(R4)exists.
J q ( t , x) [J e-i*T-i
< , > denotes t h e action
of
G(T,<)
butions. L e t a , b , w form an orthonormal variables
we obtain
v(T,<)in t h e sense of distribasis in R3.Introducing the new on
Uniqueness of the inverse scattering problem
239
then by (6.3.8) we can conclude that (6.3.10) < ~ ( T , ( ) , V ( T , ( )> = 0
.
To make this argument precise, we must show that the set c3,,,s has a non-empty interior. Consider an orthonormal basis a , b,wo in R3. Introduce a ( p ) = a cos p - w,-, sin p
,
w ( p ) = wo cos p
+ a sin p .
Clearly, for Ipl < ~ / we 2 have Iw(p) - woI < E . The vectors a ( p ) , b, w ( p ) form an orthonormal basis in R3 and by (6.3.8) we find (6.3.11)
J
Q(Y - % 4 P )
+ Pb + V J ( P ) ) d Y= 0
R,/3 E R and Ipl < ~ / 2 . Given a fixed T~ E R,choose toso that
for all s E
R,cr
E
Consider the equation (6.3.12)
= aa(p)
+pb - .~(p)
A simple calculation yields
By the implicit function theorem we determine the functions p ( ~t ,) as solution of (6.3.12) for
0 < E~ being sufficiently small. Clearly, we can choose
€0
t ) ,P(T, t),
CY(T,
so that
Now choose V ( T ,<) E C,"(R4)with suppcp c Co. Consider the integral with respect to (T,<)in (6.3.9) and pass to the new variables
+,
(7,
0, P ( T , E l , P ( 7 , t ) ),
Then in view of (6.3.13) we find
(TrO
E
co
'
Inverse scattering problem for time-dependent potentials
240
with ( ( ~ , a , , b , p= ) aa(p)
+ ,bb - ~
( p ) The . integration in
T,
a,p, p is
over some small neighbourhood of (TO,ao,@O,O).
We wish t o change the order of integration in (6.3.14). For this purpose consider
Next for fixed p , Ipl 2,
< ~ / 2 ,in the
above integral with respect t o
t and
we apply the change of variables
tIf(t,s,p)l = y - 3 ,5 CN(1 z = a'a(p) + Itl’)-’+ p'b* + y f d ( p ). This justifies thefunction change of the order o f integration: Then t h e phase
tr
+
< x , ( ( ~ , a , / ? , p ) >= a ' a + P ' P - s r
does not depend on y. Thus we are in position t o apply (6.3.11) which yields
Uniqueness of the inverse scattering problem
$(T)
=0
for
241
IT - rol > E O ,
(J e-""vt>@(t)d<) dtdx
=
J
=
J ~ " - + c (J q ( t , x M ( t ) d t ) @(<)dt.
q(t,x)&t)
=
$ ( t ) is the Fourier transform of $ with respect t o T and 3"-+( denotes the Fourier transform with respect t o x . Since Q ( < ) is an arbitrary test function with support in {[ : I< - to[< E ~ } we , derive Here
(6.3.15) FX+t
(/ q ( t, x) &t) d t) = 0
On t h e other hand, according t o (ii),
for
I< - (01 < EO .
Inverse scattering problem for time-dependent potentials
242
F(O = ~ L - E
(J q ( t ,z ~ t ) d t )
is an analytic function of
J
I . By (6.3.15)we deduce
q(t,z)q(t)dt = o
for 1x15 p
.
We rewrite this in the form
J Ft,,
q(t, z)d(t)dt =
< 3 t + , q ( t , 5),$(4 > = 0
being the Fourier transform with respect t o
Since 7.0
7
t . This yields
E B is arbitrary, we obtain q ( t , z ) = 0 for all ( t , z ) E R4and t h e
proof is complete. 0
Finally, we discuss briefly the stationary case in which q ( z ) does not depend on
t . First, it is easy t o see t h a t K # ( s ’ , O ; s , w ) depends on - s. In fact, let wO(t, z ; w) be the solution of the problem
the
difference s’
(6.3.16)
(0
+ q(z))wo = 0
WO lt<-,
7
< z,w >)
=qt -
Then we obtain 2U(t,z; s , u ) = w r J ( t + s , z ; w)
and changing the variables in
(6.1.8),we find
‘J ‘J
(6.3.17)K # ( s ’ , O ; s , w ) = 8n2
Thus
q(z)&wO(< z,0
>
+ s - s’,z;
w)dx
K#(s’, 0 ; s , w ) = S#(s‘ - s, 0 , w ) , where
(6.3.18) S#(s,O,w) = 7
q(z)dtwo(< z , 0
is a smooth function of 0 , w E
S2with
8n
-
S,Z;
w)ds
values in t h e space of distributions
6.3.2says that if the scattering to the potentials q ; ( x ) , i = 1,2,satisfy
in s. In this situation Theorem
i = 1,2,related
>
kernels S?,
.
Uniqueness of the inverse scattering problem S,#(S,
243
0 , w ) = S,#(S,0 , w )
for Is1 < 6, 10 - woI
< 6,Iw - uoI < 6,
then q I ( z ) = q2(z).
For stationary potentials q ( z ) there exists a simple procedure for recovering q ( z ) from S#(s,O,w).
Assume that we know the distribution
S # ( s , O , w ) related t o q ( z ) for Is1 < S and all 0 E S2, w E S 2 . Since S#(s,O,w) = d , M ( s , O , u ) , we can determine M ( s , O , w )for Is1 < S
&
from the expression S
< ~ ( s , ~ , w ) , p (>s = )
-ST~
< ~ # ( s , ~ , w-) ,J
p(cr)da
>,
--oo
where 'p E
C,"(lsl < 6). For a E S2, < a,w >= 0 we set
~ ( p=) Q sin p
,
O ( p ) = w cos p
+ a sin p
and define
In physics literature, t h e inverse scattering problem is connected with t h e scattering amplitude. T o discuss this connection, consider t h e case t h a t t h e operator
L = -A
+ q(z), introduced in Section 5.5, has no point spectrum.
Then t h e global energy of the solutions with initial data and for fixed z , w E to
t.
f E Ho
is bounded
S 2 , w o ( t , x ; w ) is a tempered distribution with respect
This implies that for fixed 0 , w E S2, S # ( s , O , w ) is a tempered
distribution with respect t o s. We define the scattering amplitude by
2T .(X,O,w) = - Fs+xS#(s,O,w) ,
zx
.Fs.+x being the Fourier transform with respect t o s. It is easy t o see t h a t
3 , , ~ ( d ~ w ~z( <, >~ - s , z ; w ) ) = -ixewhere v0(X, z ; w ) = Fs',,xwo(s, z ; u)and
iX
Vo(-X,
z ; 0)
,
Inverse scattering problem for time-dependent potentials
244 (A
+ X2 - q(z))vo(X,
Thus
1 (6.3.19) a(X, 0 , w ) = - -
4n
2
1
;W ) = 0
.
e-ix<"o>q(z)vo(-X,
z ; w )dz
.
Setting
U ~ c ( t , z ; w ) = w o ( t , z ; w ) - S (t
we obtain
(6.3.20) a(X,O,w) = -
-
!- eixX<"9W-o' q(x)dx 4x 4n
J
e-iX
-
q ( x ) v s c ( - X , z ; w)dz
'
Consider the function u + ( t , z ; w ) = rt(t,x ; 0 , w ) - hl(t - < x , w >) with and hl as in Section 6.1. Omitting the dependence of rt on s and w , we
conclude that u+ is an outgoing solution of the equation
nu+ = -q(z)r+(t,a:j . Conseq uent I y, t
u+ = -
J
( ~ o (t
(0, q ( x ) r + ( T ,x)))
d~ =
-M M
= -
J
( U 0 ( 4 ( 0 ,n(.)r+(t
-
.,4)), do
*
0
Choose p ( X ) E J ( R )and denote by v+(X,x; w ) the Fourier transform of u + ( t , z ; w ) with respect to t . Then (6.3.21)
< v+(X,x; w),p(X) > = < u + ( t , x ;w ) , J e-ixtcp(X)dX > = M o o
=-
J J -03
0
(uo(0)(0, q ( x ) r + ( t- 0,~ 1 ) ) ~.
245
Uniqueness of the inverse scattering problem When z runs over a compact set in
R3,t h e integration with
respect t o c in
(6.3.21) is over a bounded interval. For such z we can change the order of integration and get
v,,(--X,x; w ) =
w) =
-X%+(-X,X;
03
=
J
( ~ o ( o )(0, q(x)eixovo(o, ; w ) ) ) d c
.
0
Repeating t h e argument of t h e proof o f Theorem 2.6.9 with p = -iX, we can transform the latter integral and we obtain a representation o f vSc(-X, z ; w ) by the outgoing Green function
rZixgiven
Thus we see that
in (2.6.12).
vsc( -A, x ; w ) is t h e unique (-iX)-outgoing solution of the equation
(A
+ X2 - q ( x ) ) v s c =
Furthermore,
q(X)e
iX
v,, satisfies t h e outgoing Somrnerfeld condition (2.6.17) and
we can find a link between u(X,O,w) and the asymptotic behaviour of
v,,(X,x; w ) as z = r 0 , r = 1x1 --+
00.
In physics literature t h e term
is called Born approximation. Letting
X(O - w )
-+
1x1
-+
00,
10 - wI
-+
0, so t h a t
- p , we can find from the Born approximation the Fourier
transform i ( p ) . On the other hand, it is possible t o show that the second term in the right-hand side of (6.3.20) goes t o 0 as
1x1
respect t o 0 , w E S2. The reader should consult Saito
-+
00
uniformly with
111 for results in this
direction. Thus the Born approximation determines uniquely t h e potential Q(X).
Inverse scattering problem for time-dependent potentials
246 Notes
The idea t o consider a generalized scattering kernel I<# for scattering by moving obstacles is due t o Cooper and Strauss 121, 141. Lemma 6.1.1
[4]. The representation 6.1.3,and Lemma 6.1.4have been obtained by Stefanov [8]. In Sections 6.2 and 6.3 we closely follow the above work of Stefanov, where Theorem 6.3.2 is proved. This theorem generalizes t h e previous results o f Ferreira and Perla Menzala [l] and Stefanov [5], [6],
is an analogue o f a result of Cooper and Strauss
of
I<#, given
in Theorem
where t h e uniqueness of t h e inverse scattering problem for two potentials
qi(t,z), i = 1 , 2 , has been treated under the assumption q l ( t , z )2 q l ( t , z ) . For stationary potential t h e representation
(6.2.6)has
been obtained and
111, Newton [l], Rose, Cheney and De Facio [l],[2]. A procedure for recovering q ( t , x) from t h e solution of t h e Newton-Marchenko
studied by Morawetz
equation for time-dependent potentials has been proposed by Stefanov 171. Thus he generalizes the previous results for stationary potentials.
The inverse scattering problem for stationary potentials has been examined by many authors. We refer t o t h e books o f Marchenko and Chadan and Sabatier
[3],Levitan [l]
111 for the results and history concerning this pro-
blem. The recent results for t h e multidimensional inverse scattering problem are exposed in t h e important work o f Henkin and Novikov
[l].