1. Introduction and Preliminaries
Differentiable manifolds
with a non-symmetric metric tensor,
with a non-symmetric affine connection and their mappings were, and still are, the subject of interest of many scientists [
1,
2,
3,
4,
5,
6,
7,
8,
9,
10,
11,
12,
13,
14]. The use of a non-symmetric basic tensor and non-symmetric connection became especially relevant after the appearance of the works of A. Einstein related to creating the unified field theory, where the symmetric part of the basic tensor is related to gravitation, and the antisymmetric one to electromagnetism. We can say that, after A. Einstein [
15,
16], the main steps were made by L. P. Eisenhart [
17,
18].
Geometric mappings are interesting, both theoretically and practically. Geodesic and almost geodesic lines play an important role in geometry and physics [
1,
2,
6,
19]. The movement of many types of mechanical systems, as well as bodies or particles in gravitational or electromagnetic fields, in continual constant surroundings, is often conducted in paths, which can be looked upon as geodesic lines of Riemannian or affine connected spaces, which are defined by the energetic regime along which the process takes place. So, for example, two Riemannian spaces, which admit reciprocal geodesic mapping, describe processes which are unfolded by an equivalent exterior load and equal orbit, but different energetic regimes. In this case, one of these processes can be modeled by another. During recent years, many papers have been devoted to the theory of holomorphically projective mappings; let us mention J. Mikeš, S.M. Minčić, M.S. Stanković, Lj. S. Velimirović, M. Lj. Zlatanović, etc. [
7,
12,
13,
14,
19]. This paper is a natural continuation of the research published in paper [
20] in which biholomorphically projective mappings were studied, and they can be observed as a kind of generalization of holomorphically projective mappings.
A generalized Riemannian space
in the sense of Eisenhart’s definition [
18] is a differentiable
N-dimensional manifold, equipped with a non-symmetric metric tensor
. The connection coefficients of the space
are the generalized Cristoffel’s symbols of the second kind [
19]:
where
,
and
where, for example,
. We suppose that
,
. In the general case, the connection coefficients are not symmetric, i.e.,
, and they can be represented as the sum of the symmetric and antisymmetric parts
where the symmetric and antisymmetric part of
are given by the formulas
The magnitude
is the torsion tensor of the space
.
In a generalized Riemannian space, one can define four kinds of covariant derivatives [
9]. For example, for a tensor
in
we have
where
(
) denotes a covariant derivative of the kind
and
.
In the case of the space
, we have twelve curvature tensors, and S. M. Minčić proved that there are five independent ones. In this paper, we will consider the following five independent curvature tensors [
9]:
Let
and
be two generalized Riemannian spaces. We will observe these spaces in the common system of coordinates defined by the mapping
If
and
are connection coefficients of the spaces
and
, respectively, then
is the deformation tensor of the connection for a mapping
f.
The relations between the corresponding curvature tensors of the spaces
and
are obtained in [
19] as follows:
where
is a deformation tensor for a mapping
f,
is its antisymmetric part and
is a torsion tensor.
2. Quasi-Canonical Biholomorphically Projective Mappings
In paper [
20], we define biholomorphically projective mappings between two generalized Riemannian spaces
and
with almost complex structures that are equal in a common system of coordinates defined by the mapping
. We have considered a generalized Riemannian space
with a non-symmetric metric tensor
and almost complex structure
such that
where
a is scalar invariant, and we have defined the biholomorphically projective curve of the kind
and the biholomorphically projective mapping of the kind
.
Definition 1 ([
20])
. In the space , a curve l given in parametric formis said to be biholomorphically projective of the kind θ if it satisfies the following equation:where a, b and c are functions of parameter t, and Definition 2 ([
20])
. A diffeomorphism is a biholomorphically projective mapping of the kind if biholomorphically projective curves of the kind of the space are mapped to the biholomorphically projective curves of the kind θ of the space . Since it holds [
20]
we conclude that the biholomorphically projective curves of the first kind and the biholomorphically projective curves of the second kind match, so we will simply call them the biholomorphically projective curves. Therefore, the biholomorphically projective curves of the spaces
and
, respectively, satisfy relations [
20]
where
and
are functions of parameter
t,
and
and
are connection coeficients of the spaces
and
, respectively,
.
From Equations (
8) and (
9) we obtain [
20]
where we denote
,
. We can set
,
,
Now, we have [
20]
From this we conclude that the following relation is satisfied [
20]:
and the deformation tensor has the form
where
is a symmetrization without division by indices
;
,
and
are vectors;
and
is an antisymmetric tensor.
Inspired by the form of the deformation tensor (
11), we will define a new type of mapping. Let
and
be two generalized Riemannian spaces with almost complex structures
and
, respectively, where
in the common system of coordinates defined by the mapping
, and assume that it holds that
where
a is scalar invariant.
The mapping
is a quasi-canonical biholomorphically projective mapping if in the common coordinate system the connection coefficients
and
satisfy the relation
where
is a symmetrization without division by indices
;
and
are vectors;
and
is an antisymmetric tensor.
Let
be a deformation tensor with respect to the quasi-canonical biholomorphically projective mapping
. Then, from
and
, we have
3. Some Relations between Curvature Tensors
In this section, we will find the relations between the corresponding curvature tensors of the spaces and .
According to relations (5), (7) and (13), for the curvature tensor of the first kind we have
where
is a symmetrization without division,
is an antisymmetrization without division by indices
and
Based on the facts given above, we have obtained the following statement.
Theorem 1. A quasi-canonical biholomorphically projective relation between the curvature tensors of the first kind of the generalized Riemannian spaces and is given by Formula (14), where is the torsion tensor and the notation is the same as in (15).
From relations (5), (7) and (13), for the curvature tensor of the second kind, we obtain the following:
where
are determined by Formula (15) and
Therefore, the following theorem is valid.
Theorem 2. A quasi-canonical biholomorphically projective relation between the curvature tensors of the second kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in and .
Considering relations (5), (7) and (13), for the curvature tensor of the third kind we have the following:
where the notation is the same as in
and
.
In this way, the following theorem is proven.
Theorem 3. A quasi-canonical biholomorphically projective relation between the curvature tensors of the third kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in and .
Using relations
,
and
, for a curvature tensor of the fourth kind we obtain the following:
where the notation is the same as in
and
. This proves the next statement.
Theorem 4. A quasi-canonical biholomorphically projective relation between the curvature tensors of the fourth kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in and .
Considering relations
,
and
, for the curvature tensor of the fifth kind we have the following:
where the notation is the same as in
and
Based on the facts given above, we have proved the next theorem related to curvature tensors of the fifth kind.
Theorem 5. A quasi-canonical biholomorphically projective relation between the curvature tensors of the fifth kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in and .
4. Equitorsion Quasi-Canonical Biholomorphically Projective Mapping
The mapping
is an equitorsion quasi-canonical biholomorphically projective mapping, if the torsion tensors of the spaces
and
are equal in a common coordinate system after the mapping
f. In this case, based on
and
, we conclude that
Then, relation (13) becomes
Considering
, from
, we obtain the following:
Hence, the next theorem holds.
Theorem 6. An equitorsion quasi-canonical biholomorphically projective relation between the curvature tensors of the first kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in .
The relation between the curvature tensors of the second kind
, after applying relation
, becomes the following:
In this way, the following theorem is proven.
Theorem 7. An equitorsion quasi-canonical biholomorphically projective relation between the curvature tensors of the second kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor.
The relation between the curvature tensors of the third kind
, with respect to
, becomes the following:
and we may formulate the following theorem.
Theorem 8. An equitorsion quasi-canonical biholomorphically projective relation between the curvature tensors of the third kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in and .
In particular, from relations
and
, we have
Therefore, the next theorem holds.
Theorem 9. An equitorsion quasi-canonical biholomorphically projective relation between the curvature tensors of the fourth kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in and .
Analogously, from
, with respect to
, we obtain the following:
i.e., the following theorem is valid:
Theorem 10. An equitorsion quasi-canonical biholomorphically projective relation between the curvature tensors of the fifth kind of the generalized Riemannian spaces and is given by Formula , where is the torsion tensor and the notation is the same as in and .
5. Invariant Geometric Objects of Quasi-Canonical Biholomorphically Projective Mappings
In this section, we will obtain an invariant geometric object of an equitorsion quasi-canonical biholomorphically projective mapping. In relation to that, in relation
, let us set
Then, we have
Contractingby indices
h and
i in
, assuming that it is valid that
and
we obtain
Substituting (32) in (29) we have
If we denote
relation (33) can be presented in the form
where
is an object of the space
. The magnitude
is called a
Thomas equitorsion quasi-canonical biholomorphically projective parameter and it is not a tensor.
Accordingly, we conclude that the following assertion is valid.
Theorem 11. The geometric object given by Equation (34) is an invariant of the equitorsion quasi-canonical biholomorphically projective mapping , provided that relations (30) and (31) are valid.