V. V. Koryshev in relation to cylindrical surfaces suggested constructing of Green tensors based on the iterative procedure of solving the boundary problem of electrodynamics for flat SIS. It is suggested that this method is applicable for convex surfaces of arbitrary radius of curvature 
and 
. In this article are generalized for double curvature SIS.
Points, located above the S surface can be unambiguously described by the radius vector 
[2]:
 |
(1) |
where 
, 
— coordinates of points on the S surfaces, specified by the radius vector 
, and the direction of the 
axis is specified by the direction of the normal vector to S 
. The covariant basis above the S surface taking into account the derivative Weingarten formula [3] can be written as follows:
 |
(2) |
where 
and 
– covariant basis on the surface S, 
, 
– components of the secondary quadratic form of the surface S, 
– contravariant components of metric tensor.
We will use the following notation: 
— covariant components of tensor of the used coordinate system ,, , g — determinant of metric tensor,
 |
(3) |
where 
,
— metric tensor on the S surface.
Heterogeneous Maxwell equations written for covariant coordinates of vector field (dependency on time is specified as 
), have as it is known the following form:
 |
(4а) |
where n, k — "dead" indices, 
— contravariant Levy−Civita pseudotensor, 
— covariant components of metric tesnor, g — module of determinant of metric tensor, 
, 
— covariant components of vectors of secondary field, 
, 
— covariant components of vector of magnetic and electric currents on radiators which are sources of secondary waves, 
— symbol of covariant derivative. Using simple transformations, the equations (4a) can be represented as follows:
 |
(4б) |
where Rot means rotor operation in the Cartesian coordinate system and 
, 
are vectors of electric and magnetic steady volume external “currents” caused by the curvature of the surface of the AA:
 |
(5) |
In the notation (5) 
— identity tensor, 
— tensor, covariant components of which are 
. If the carrier of exterior currents 
, 
is finite, then 
, 
when 
according to the uniqueness theorem [4]. As it follows from (4), the original diffraction problem in the convex body can be substituted by the equivalent diffraction problem on a flat surface with existence of currents bulk–distributed over this surface , . The properties of the space above S remain the same. Taking into account (3), we will write 
in detailed form:
 |
(6) |
To simplify the recording, we will use the following notation: 
, 
, 
, 
, m=1,2,3 — orts of the Cartesian coordinate system. According to (4) it can be written as follows:
 |
(7) |
where V — volume of the entire space involved (0≤z≤∞, -∞≤x,y≤∞), and tensors 
, 
are determined by the equations:
 |
(8) |
 |
(9) |
where
Here
, 
— “reflection” coefficients for flat surface [5]. The remaining tensors are determined from the equations:
In expressions (8) and (9) the top line in curly brackets corresponds to the case 
, and the bottom one — to the case 
; index p=1 corresponds to the H−wave, and index p=2 — to the E−wave, and
We will introduce the notation:
— field six−vector, 
— current six−vector, 
, 
— linear matrix integral operations, cores of which are equal to:
Then, using (5), the expressions (7) can be represented in the operation form:
 |
(10) |
The equation (10) will be solved by the iterative method, and in correspondence with (4) and (5)
Let’s examine the first approximation, taking as the zeroth approximation the field of flat array 
, 
:
 |
(11) |
where 
— volume, taken by currents , . After substituting (11) into (7) and reducing the similar terms, we obtain:
where Green tensors 
of the conformal surface in the first approximation have the following form:
 |
(12) |
In the expression (12) 
, when 
and 
, when 
,
and index "r" denotes regular parts of the tensor Green functions [6]. Usage of tensors (12) means that we passed from electrodynamic examining of the conformal surface to examining of the flat surface when only exterior currents exist: , . Effect of bulk , is taken into account when deriving the expressions (12).
Let’s write the volume integral in (12) in more detail by substituting into it (8) and (9). By considering two characteristic cases and writing the expressions in general form we receive:
— when
 |
(13) |
— when
 |
(14) |
The following notation is used:
 |
(15) |
When calculating using the formulas (13) and (14) the following integrals appear:
 |
(16) |
where the following notation is used:
 |
(17) |
When calculating using the formulas (17) it is inconvenient to use the general expressions (6). To simplify the notation, we will assume that , , in non-umbilical points represent an orthogonal coordinate system in the lines of curvature of the surface S [3]. The main directions and can be determined from the equations:
 |
(18) |
where the following notation is used:
— surface equation of S, 
, 
, 
, and functions 
and 
are determined from the conditions of equality of secondary mixed derivatives (consistency condition). Using the notation 
, these conditions can be written as follows:
they, taking into account (18) reduce to the two independent linear differential equations in partial derivatives:
 |
(19) |
with initial conditions 
. The following notation is used here:
By solving the equations (19), we receive [7]:
where 
and 
— are corresponding solutions of the normal differential equations 
and 
, which determine the equations of projections of curvature lines of the surface S to the plane 
: 
and 
. Functions 
and 
— are arbitrary differentiable functions, satisfying the conditions 
when 
.
In umbilical points of the surface S we choose as the main directions two mutually orthogonal directions [3].
Thus, in the curvature lines we receive (
, 
, 
— main curvatures of the surface S):
— when 
 |
(20а) |
— when 
 |
(20б) |
When deriving the expressions (20a) the formula (2.325.1) from [8] is taken into account, and 
— is the analytical continuation into the complex area, sliced along the negative part of the real axis, integral exponential function [9]. The remaining integrals in (17) are equal to zero.
Also of interest are the values of some integrals from (20a) when b=∞ [9]:
 |
(21) |
When S is a cylindrical surface (
, 
, 
), the expressions (20a) are simplified:
The expressions (12)…(14) taking into account (15)…(21) completely solve the problem of determining the tensor Green functions of conformal surface in first approximation and, therefore, the first approximation of the electromagnetic field scattered by this surface.
