_ t xxx xxx x xx x x x
(1)

_u  u  6vu  6v u  30u u²  0, x 
 t xxx x x x

t 0
The functions v₀(x), u₀(x) satisfy the following conditions:

(i)
^{u0(x) is absolutely continuous on each finite segment} ^{ , }  ^ ^{, }
and the

inequalities hold
 
_ ^|u₀ ^{(x) | dx  ,} _ ^{(1 | x |)[| v}₀ ^{(x) |  | u}₀^{ (x) |]dx  }, (3)
 
(ii) the operator generated by the differential expression

d ₂
2
T (0, k) :  _dx2  v₀ (x)  2ku₀ (x)  k

has exactly 2N simple eigenvalues
k₁(0),k₂ (0),...,k_{2 N} (0) .

The main aim of this work is to derive representations for the solutions ^v(x,t)
and ^u(x,t) of the Cauchy problem (1)–(3) within the inverse scattering method for the

quadratic pencil of Sturm-Liouville operators:
T (t, k) y :  y^''  v(x,t) y  2ku(x,t) y  k ² y  0,


^{х } . (4)

The inverse scattering problem for the quadratic pencil of Sturm-Liouville operators in the class of “rapidly decreasing” functions was solved in the works [6,7], with periodical potential in [8,9].

The basic facts from scattering problem

In this section we give basic information about the scattering theory for the Sturm–Liouville equation with an energy-dependent potential.
Consider the following quadratic pencil of Sturm-Liouville equatins
^{T (0, k) y :  y''  v(x) y  2ku(x) y  k 2 y  0, х } (5)

where
u(x)
and
v(x)
are real functions, moreover,
u(x)
is absolutely continuous on

^{each finite segment} ^{ , }  ^ ^{, }
and the inequalities hold

 
_ |u _ x_ | dx  , _ (1 | x |)[v(x) | u^(x) |]dx  . (6)

 
Under condition (6), Eq. (5) has solutions
Imk  0 and the asymptotic formulas hold


f_ (x, k ),


f_ (x, k )
regular in the half-plane

f_ (x, k)  e^ikx[1 o(1)],
f_ (x, k)  e^ikx[1 o(1)],
x   , (7)
x  . (8)

For real
k  0 , the pairs
f_ (x, k ),
f_ (x, k )
and
f_ (x, k),
f_ (x, k) (the bar over the function

here and below denotes complex conjugation) form two fundamental systems of solutions to equation (5). The following relations hold
f_ (x, k)  b(k) f_ (x, k)  a(k) f_ (x, k) , (9)
f_ (x, k)  b (k) f_ (x, k)  a(k) f_ (x, k). (10)

The functions
a(k )
and
b(k )
are defined for all
k  R^*  (, ) \{0}
and the following

equality is fulfilled

Moreover, the function

a(k )
a(k) 2  b(k) 2  1, k  R^* .
admits an analytic continuation to the half-plane Imk  0

and can have at most a finite number of zeros
k₁,k₂ ,...,k_N , besides, at

k  k_n , n 1,2,..., N
the following equality holds:

n n
f (x, k )  B^ f_

(x, k_n ) , (11)

where the quantities
B^{ are independent of x . The corresponding functions}
f_ (x, k_n )

n
are the only
L² (R)
solutions of (5) for Imk  0 and are the 'bound states'.

The set of the quantities
^r (k)  ^b(k) , k  R, k , k ,..., k

, ^ , ^ ,..., ^{ }

(12)

^{ } a(k)
1 2 N 1 2 N ^

 
and

^r (k)   ^{b (k)} , k  R, k , k ,..., k

,  ^ , ^ ,..., ^{ }

(13)

^{ } a(k)
1 2 N 1 2 N ^

 
are called the left and right scattering data of Eq. (5), respectively, here

n
 ^ 
_B
n _{, n}


k k_n
 1, 2,..., N . (14)

Functions
r_ (k )
and
r_ (k )
are called the left and right reflection coefficients,

respectively.
We now turn to the question of constructing ^u(x)

and ^v(x)

from scattering data.

Note that scattering data (12), (13) and
F_ (x)
are bijectively related via transforms

_N  ₁ 
F (x)  i_ ^e ^iknx  r (k)e^ikxdk . (15)

 n _ 

2
n1 _

To restore the coefficient functions
u(x)
and
v(x)
in equation (5) from the right

reflection coefficient
r_ (k )
we proceed as follows:

It is necessary to find the function
F_ (x)
by formula (15) and solve with respect

to K ⁽⁰⁾ (x, y)  L (x,), ^{K(1) (x, y)  L (x, )} integral equations
 1  1

 



F_ (x  y)  K ⁽⁰⁾ (x, y) 
_ K ⁽⁰⁾ (x,t)F (t  y)dt  0,
x
x  y   ,

 



iF_ (x  y)  K ⁽¹⁾ (x, y) 
_ K ⁽¹⁾ (x, t)F (t  y)dt  0,
x
x  y   .

Next, we have to define the function _ (x)
equation of the Volterra type
as a solution to a nonlinear integral

in which

_ (x)  _(t,_ (t))dt,
x
^{   x  } ,

^Φ^{t, z} ^{ Re K0} ^t,t  ^{m K 1} ^t,t ^{sin2z  2 Re K 1} ^t,t ^{sin2z  2 Im K 0} ^t,t ^cos2z
 ^{ }   ^   ^ 

    

After that, the coefficients equalities
u(x)
and
v(x)
of the equation (5) are determined by the

^{u(x)  }_^{ (x)} ,

v(x)  u² (x)  2 ^d _Re K (x, x)_cos (x)  _Im K (x, x)_sin
(x)_ .

_dx    

It is worthy to remark that the functions
_{ }1
h_n (x)  _{ }


^d [ f
dk ^

(x, k)  B^ f_

n
(x, k)]
(16)

_ k k_{n }
k k_n

are solutions of the equations
T (k
^{) y  k 2 y, n  1, 2,..., N} . For Imk  0 , using (7) and

n n
(8), we obtain the following asymptotics

n
h (x)  e^iknx ,


x   , (17)

n n
h (x)  B^e^iknx ,
From asymptotics (7), (8), (17) and (18) we get
x   . (18)

W{h (x), f (x,k )}  2ik , ^{W{h (x), f (x, k )}  2ik B}
n  n n ^{n  n n n}