1. Introduction
As an important kind of submanifolds, curves in different spaces have attracted wide attention from mathematicians. Studies have focused on investigating not only regular curves, but also singular curves, and have made great achievements (see [
1,
2,
3,
4,
5,
6,
7,
8,
9,
10,
11]). Because Lorentz space is strongly connected to the theory of general relativity, the investigation of submanifolds in Lorentz space and its subspaces has great significance. Scholars have shown interest in curves in Lorentz space and its subspace and have studied evolutes, involutes, parallels and some other associated curves in these spaces. There have been several relevant investigations in this area (see [
3,
4,
5,
6,
7,
12,
13,
14,
15]). Having the appearance of a negative index, there are three types of vectors in Lorentz space. For a curve, the type of tangent vector at each point determines the type of point. As for non-lightlike curves in Lorentz space, we always select their arc-length parameters and adopt the Frenet–Serret frame to investigate them (see [
8,
16]).
In fact, curves in Lorentz space do not always consist of a single type of points, but rather can involve all three types of points. This is what we mean by mixed-type curves. As a more familiar condition, the investigation of mixed-type curves has important significance. Because the curvature at lightlike points cannot be defined, the classical Frenet–Serret frame does not work. Due to the lack of necessary tools for its research, almost no research has been conducted on this subject. In 2018, S. Izumiya, M. C. Romero Fuster, and M. Takahashi presented the lightcone frame and established the fundamental theory of mixed-type curves in
in [
17]. As an application of the theory, they studied the evolutes of regular mixed-type curves. In [
18], T. Liu and the second author of this paper gave the lightcone frame in Lorentz 3-space and considered mixed-type curves in this space. Currently, the investigation of mixed-type curves in
has not been completed. As the depth of their work, the
-cusp mixed-type curves in
were investigated, as well as the evolutes of the
-cusp mixed-type curves, as presented by us in [
19]. Later, we also considered the evolutoids of mixed-type curves in
.
The pedal curves is a kind of significant curves due to their geometric properties. In the Euclidean space
, the pedal curve is always defined by the locus of the foot of the perpendicular from the given point to the tangent to the base curve. M. Bo
ek and G. Folt
n considered the relationship of singular points of regular curves’ pedal curves and the inflections of the base curves in
in [
20]. Later, in [
21], Y. Li and the second author of this paper studied the pedal curve of the given curves with singular points in
. O. O
ulcan Tuncer et al. described the relationship of the pedal curves and contrapedal curves in
in [
22]. However, on the topic of pedal curves of mixed-type curves in
, which is an interesting and worthy subject, there have not been relevant investigations.
Our purpose in this paper was to solve the problems related to the pedal curves of mixed-type curves in
. In
Section 2, we review some essential knowledge about
and introduce the lightcone frame. Then, we define the pedal curves of mixed-type curves and investigate their properties in
Section 3. We consider when the pedal curves of mixed-type curves have singular points and investigate the relationship of the types of points of the pedal curves and the base curves. Finally, in
Section 4, for the purpose of showing the characteristics of the pedal curves of mixed-type curves, we present two examples.
If not specifically mentioned, all maps and manifolds in this paper are infinitely differentiable.
2. Preliminaries
Here, we introduce some essential knowledge about the Lorentz–Minkowski plane for the sake of convenience.
Let
be a vector space of dimension 2. If
is endowed with the metric which is induced by the
pseudo-scalar product
where
,
, and
, then we call
the Lorentz–Minkowski plane and denote it by
.
For a non-zero vector , there are three types of vectors in . When is positive, negative and vanishing, it is called spacelike, timelike or lightlike, respectively. A non-lightlike vector refers to a vector that is spacelike or timelike.
For a vector , if there exists a vector , which satisfies , we say is pseudo-perpendicular to .
We define the
norm of
by
and the pseudo-orthogonal complement of
is given by
. By definition,
and
are pseudo-orthogonal to each other, and
It is obvious that if and only if is lightlike, and is timelike (resp. spacelike) if and only if is spacelike (resp. timelike).
Let
be a regular curve. Denote
. Then we say
is a
spacelike (resp.
timelike,
lightlike) curve if
is positive (resp. negative, vanishing) for any
. Furthermore, the type of a point
(or,
t) is determined by the type of
. For more details, see [
17].
Moreover, we say a curve is non-lightlike if it is a spacelike or timelike curve and a point is non-lightlike if it is a spacelike or timelike point. If contains three types of points simultaneously, then it is exactly a mixed-type curve, which is the main research object in this paper.
Set
and
. These are linearly independent lightlike vectors. The pair {
,
} is called a
lightcone frame along
in
, which was introduced by S. Izumiya, M. C. Romero Fuster, and M. Takahashi in [
17].
Let
be a regular mixed-type curve. There exists a corresponding smooth map
, which satisfies
If Equation (
1) is established,
is called
the lightlike tangential data of
. The pseudo-orthogonal complement of
can be expressed by
Since
the type of
can be determined by
. For more details about the lightcone frame and the lightlike tangential data, see [
17].
Definition 1. Let be a regular mixed-type curve. We call a point an inflection if .
Remark 1. When is a non-lightlike curve, the curvature at is . If , then is called an inflection of . This satisfies Definition 1.
Let
be a regular mixed-type curve with the lightlike tangential date
. Then,
is an inflection of
if and only if
Remark 2. Let be a regular mixed-type curve with the lightlike tangential date . When , but , i.e., , but , is called an ordinary inflection. In this paper, we only consider ordinary inflections of the mixed-type curves, and we call them inflections for short.
3. Pedal Curves of the Mixed-Type Curves in
The pedal curves of the regular curves in are widely studied. As for the regular curves in , the pedal curves of them are defined similarly. They are always given by the pseudo-orthogonal projection of a fixed point on the tangent lines of the base curves. Therefore, the definitions of pedal curves of the regular non-lightlike curves are given as follows.
Definition 2. Let be a regular non-lightlike curve and be a point in . Then, the pedal curve of the base curve is given by It is obvious that the pedal curve of a non-lightlike curve with the lightcone frame
and the lightlike tangential data
is
Let
be a regular mixed-type curve. Since
when
is a lightlike point, it is probably not always possible to define a pedal curve of a mixed type curve. In fact, if
coincides with the lightlike point or
is on the tangent line of the lightlike point, we can define the pedal curve
of
with the lightcone frame
and the lightlike tangential data
by Formula (
3).
When
is a non-lightlike point,
satisfies Formula (
3), obviously.
When
is a lightlike point,
, and we suppose that
coincides with the lightlike point or
is on the tangent line of the lightlike point. In these cases, Formula (
3) also holds, and in the following, we discuss the specific forms of
.
If
is non-lightlike, by direct calculation,
If
is a lightlike point. Firstly, suppose that
and
, then
coincides with the lightlike point or
is on the tangent line of the lightlike point is exactly
. In this case, we define
as
. Then, we can find that
If
is not an inflection,
, then
If
is an inflection, we have
and
Since
, we can find that
. Continue to calculate and we can get
Therefore, when , is always equal to 0.
By the above calculation, we can define
as
. To sum up, if
coincides with
, then
,
is given by
If
is on the tangent line of
, then
,
is given by
As for the condition of and , in this case coincides with the lightlike point or is on the tangent line of the lightlike point refers to , similarly we can find that:
If
coincides with
, then
is given by
If
is on the tangent line of
, then
is given by
Remark 3. Let be a regular mixed-type curve and be a point in . is the pedal curve of . Suppose that is a lightlike point, if is neither coincident with nor on the tangent line of , then when t approaches to , goes to infinity. Since one of and is equal to 0, asymptotic with lightlike line of or . Specifically, when , since asymptotic with lightlike line along the positive or negative direction of Similarly, when , asymptotic with lightlike line along the positive or negative direction of We can see the relevant examples in Section 4. Considering when the pedal curves of the regular mixed-type curves have singular points, we have following conclusions.
Theorem 1. Let be a regular mixed-type curve and be a point in . is the pedal curve of ρ. Then
- (1)
if is a non-lightlike point, then is a singular point if and only if one of the following conditions occur:
- (i)
is an inflection but is not coincides with ;
- (ii)
is not an inflection, but coincides with ;
- (iii)
is an inflection and coincides with .
- (2)
if is a lightlike point, and coincides with or is on the tangent line of , then is regular.
Proof. As the pedal curve of the mixed-type curve
is given by the Formula (
3), by direct calculation, we can get -4.6cm0cm
When
is a non-lightlike point,
if and only if
and
Specifically,
but if and only if is an inflection, but is not coincides with ;
but if and only if is not an inflection, but coincides with ;
and if and only if is an inflection and coincides with .
Following that, we consider the condition when is a lightlike point. First, we suppose that , . Since , we cannot calculate . When , we have known that is asymptotic with lightlike line along the positive or negative direction of So we consider the condition that .
First we suppose that is not an inflection of , then .
Since
, we can find that
As , and , we can obtain . Therefore, is a regular point.
Afterwards, we suppose that is an inflection of , then , but .
Since
, we can obtain
As
,
and
, we can get
. Therefore,
is a regular point.
When , and , we can get is a regular point similarly. □
Let be a regular mixed-type curve and be a point in . is the pedal curve of . If we denote , , ⋯, . Then, we have the following proposition about types of the singular points of .
Proposition 1. Let be a regular mixed-type curve and be a point in . is the pedal curve of ρ. Suppose that exists. Then, is an -cusp if and only if
- (1)
,
- (2)
.
We have given the definition of
-cusp in [
19]. According to the conclusion in [
19], we can obtain Proposition 1 directly.
Proposition 2. Let be a regular mixed-type curve and be a point in . is the pedal curve of ρ. Suppose that is on the tangent line of .
- (1)
If is a non-lightlike point, then coincides with ;
- (2)
If is a lightlike point, then is not coincident with .
Proof. Since the pedal curve of the mixed-type curve
is given by Formula (
3).
Suppose that is on the tangent line of , then we have and are linearly dependent.
If
is a non-lightlike point, then there exists
, such that
Therefore, coincides with .
If
is a lightlike point, we have know that when
and
,
when
and
,
Thus, is not coincident with . □
Then, we investigate the type of points of the pedal curve of the mixed-type curve in and the following proposition can be obtained.
Proposition 3. Let be a regular mixed-type curve and be a point in . is the pedal curve of ρ. If is regular, then
- (1)
When is non-lightlike, is a spacelike point if and only if .
- (2)
When is non-lightlike, is a timelike point if and only if .
- (3)
When is non-lightlike, is a lightlike point if and only if .
- (4)
When is lightlike, , and ,
- (i)
suppose that is not the inflection of ρ,
- (a)
is a lightlike point if and only if coincides with ;
- (b)
is a non-lightlike point if and only if is on the tangent line of . Moreover, is spacelike (or, timelike) if and only if (or, ).
- (ii)
suppose that is an inflection of ρ, is always lightlike.
- (5)
When is lightlike, , and ,
- (i)
suppose that is not the inflection of ρ,
- (a)
is a lightlike point if and only if coincides with ;
- (b)
is a non-lightlike point if and only if is on the tangent line of . Moreover, is spacelike (or, timelike) if and only if (or, ).
- (ii)
suppose that is an inflection of ρ, is always lightlike.
Proof. Since
is given by Formula (
4), we can calculate that
When is a non-lighlike point, the type of can be easily obtained.
When is a lighlike point, by the proof of Theorem 1, we can get the conclusion. □