D Tangent Surfaces of Timelike Biharmonic D Helices according to Darboux Frame on Non-degenerate Timelike Surfaces in the Lorentzian Heisenberg GroupH

Similar documents
TIMELIKE BIHARMONIC CURVES ACCORDING TO FLAT METRIC IN LORENTZIAN HEISENBERG GROUP HEIS 3. Talat Korpinar, Essin Turhan, Iqbal H.

Position vector of spacelike biharmonic curves in the Lorentzian Heisenberg group Heis 3

Characterizing Of Dual Focal Curves In D 3. Key Words: Frenet frame, Dual 3-space, Focal curve. Contents. 1 Introduction Preliminaries 77

Null Bertrand curves in Minkowski 3-space and their characterizations

A Note On Bertrand Curves Of Constant Precession. Key Words: Curves of constant precession, Frenet formula, Bertrand curve.

A STUDY ON A RULED SURFACE WITH LIGHTLIKE RULING FOR A NULL CURVE WITH CARTAN FRAME

CMC A-net surfaces in three dimensional Heisenberg group

1-TYPE AND BIHARMONIC FRENET CURVES IN LORENTZIAN 3-SPACE *

ON HELICES AND BERTRAND CURVES IN EUCLIDEAN 3-SPACE. Murat Babaarslan 1 and Yusuf Yayli 2

C-parallel Mean Curvature Vector Fields along Slant Curves in Sasakian 3-manifolds

Smarandache Curves In Terms of Sabban Frame of Fixed Pole Curve. Key Words: Smarandache Curves, Sabban Frame, Geodesic Curvature, Fixed Pole Curve

THE NATURAL LIFT CURVES AND GEODESIC CURVATURES OF THE SPHERICAL INDICATRICES OF THE TIMELIKE BERTRAND CURVE COUPLE

k type partially null and pseudo null slant helices in Minkowski 4-space

SPLIT QUATERNIONS and CANAL SURFACES. in MINKOWSKI 3-SPACE

THE BERTRAND OFFSETS OF RULED SURFACES IN R Preliminaries. X,Y = x 1 y 1 + x 2 y 2 x 3 y 3.

CHARACTERIZATIONS OF SPACE CURVES WITH 1-TYPE DARBOUX INSTANTANEOUS ROTATION VECTOR

On the Dual Darboux Rotation Axis of the Timelike Dual Space Curve

Inextensible Flows of Curves in Lie Groups

is constant [3]. In a recent work, T. IKAWA proved the following theorem for helices on a Lorentzian submanifold [1].

ON OSCULATING, NORMAL AND RECTIFYING BI-NULL CURVES IN R 5 2

Differential-Geometrical Conditions Between Geodesic Curves and Ruled Surfaces in the Lorentz Space

On Natural Lift of a Curve

Determination of the Position Vectors of Curves from Intrinsic Equations in G 3

On constant isotropic submanifold by generalized null cubic

A METHOD OF THE DETERMINATION OF A GEODESIC CURVE ON RULED SURFACE WITH TIME-LIKE RULINGS

An Optimal Control Problem for Rigid Body Motions in Minkowski Space

Eikonal slant helices and eikonal Darboux helices in 3-dimensional pseudo-riemannian manifolds

arxiv: v1 [math.dg] 26 Nov 2012

SOME RELATIONS BETWEEN NORMAL AND RECTIFYING CURVES IN MINKOWSKI SPACE-TIME

N C Smarandache Curve of Bertrand Curves Pair According to Frenet Frame

Constant mean curvature biharmonic surfaces

Classifications of Special Curves in the Three-Dimensional Lie Group

A Note on Inextensible Flows of Partially & Pseudo Null Curves in E 4 1

Existence Theorems for Timelike Ruled Surfaces in Minkowski 3-Space

SLANT AND LEGENDRE CURVES IN BIANCHI-CARTAN-VRANCEANU GEOMETRY

ON THE RULED SURFACES WHOSE FRAME IS THE BISHOP FRAME IN THE EUCLIDEAN 3 SPACE. 1. Introduction

Parallel Transport Frame in 4 dimensional Euclidean Space E 4

On T-slant, N-slant and B-slant Helices in Pseudo-Galilean Space G 1 3

The equiform differential geometry of curves in 4-dimensional galilean space G 4

Spherical Images and Characterizations of Time-like Curve According to New Version of the Bishop Frame in Minkowski 3-Space

BERTRAND CURVES IN THREE DIMENSIONAL LIE GROUPS

The Ruled Surfaces According to Type-2 Bishop Frame in E 3

Mannheim partner curves in 3-space

Inelastic Admissible Curves in the Pseudo Galilean Space G 3

A local characterization for constant curvature metrics in 2-dimensional Lorentz manifolds

arxiv: v1 [math.dg] 12 Jun 2015

Biharmonic pmc surfaces in complex space forms

On a family of surfaces with common asymptotic curve in the Galilean space G 3

INEXTENSIBLE FLOWS OF CURVES IN THE EQUIFORM GEOMETRY OF THE PSEUDO-GALILEAN SPACE G 1 3

THE CHARACTERIZATIONS OF GENERAL HELICES IN THE 3-DIMEMSIONAL PSEUDO-GALILEAN SPACE

On the Fundamental Forms of the B-scroll with Null Directrix and Cartan Frame in Minkowskian 3-Space

The Natural Lift of the Fixed Centrode of a Non-null Curve in Minkowski 3-Space

BIHARMONIC SUBMANIFOLDS OF GENERALIZED COMPLEX SPACE FORMS 1. INTRODUCTION

Smarandache curves according to Sabban frame of fixed pole curve belonging to the Bertrand curves pair

arxiv: v1 [math.dg] 1 Oct 2018

Some Characterizations of Partially Null Curves in Semi-Euclidean Space

Minkowski spacetime. Pham A. Quang. Abstract: In this talk we review the Minkowski spacetime which is the spacetime of Special Relativity.

Available online at J. Math. Comput. Sci. 6 (2016), No. 5, ISSN:

Relatively normal-slant helices lying on a surface and their characterizations

Some Research Themes of Aristide Sanini. 27 giugno 2008 Politecnico di Torino

A Note About the Torsion of Null Curves in the 3-Dimensional Minkowski Spacetime and the Schwarzian Derivative

Arc Length and Riemannian Metric Geometry

Timelike Rotational Surfaces of Elliptic, Hyperbolic and Parabolic Types in Minkowski Space E 4 with Pointwise 1-Type Gauss Map

Constant ratio timelike curves in pseudo-galilean 3-space G 1 3

Minimal timelike surfaces in a certain homogeneous Lorentzian 3-manifold II

ON THE CURVATURE THEORY OF NON-NULL CYLINDRICAL SURFACES IN MINKOWSKI 3-SPACE

GENERALIZED NULL SCROLLS IN THE n-dimensional LORENTZIAN SPACE. 1. Introduction

arxiv: v1 [math.dg] 22 Aug 2015

Transversal Surfaces of Timelike Ruled Surfaces in Minkowski 3-Space

Fathi M. Hamdoon and A. K. Omran

DIFFERENTIAL GEOMETRY OF CURVES AND SURFACES IN LORENTZ-MINKOWSKI SPACE

The equiform differential geometry of curves in the pseudo-galilean space

Characterizations of the Spacelike Curves in the 3-Dimentional Lightlike Cone

SPLIT QUATERNIONS AND SPACELIKE CONSTANT SLOPE SURFACES IN MINKOWSKI 3-SPACE

The Frenet Serret formulas

Killing Magnetic Curves in Three Dimensional Isotropic Space

CURVATURE VIA THE DE SITTER S SPACE-TIME

BERTRAND CURVES IN GALILEAN SPACE AND THEIR CHARACTERIZATIONS. and Mahmut ERGÜT

ON THE PARALLEL SURFACES IN GALILEAN SPACE

Investigation of non-lightlike tubular surfaces with Darboux frame in Minkowski 3-space

Geometric approximation of curves and singularities of secant maps Ghosh, Sunayana

CERTAIN CLASSES OF RULED SURFACES IN 3-DIMENSIONAL ISOTROPIC SPACE

Classification results and new examples of proper biharmonic submanifolds in spheres

BÄCKLUND TRANSFORMATIONS ACCORDING TO BISHOP FRAME IN EUCLIDEAN 3-SPACE

Surfaces with Parallel Normalized Mean Curvature Vector Field in 4-Spaces

Qing-Ming Cheng and Young Jin Suh

An introduction to General Relativity and the positive mass theorem

f-biharmonic AND BI-f-HARMONIC SUBMANIFOLDS OF PRODUCT SPACES

Week 3: Differential Geometry of Curves

Biconservative surfaces in Riemannian manifolds

SLANT HELICES IN MINKOWSKI SPACE E 3 1

On the Invariants of Mannheim Offsets of Timelike Ruled Surfaces with Timelike Rulings

C-partner curves and their applications

Dual Smarandache Curves of a Timelike Curve lying on Unit dual Lorentzian Sphere

Surfaces Family with Common Smarandache Geodesic Curve According to Bishop Frame in Euclidean Space

The Left Invariant Metrics which is Defined on Heisenberg Group

Type II hidden symmetries of the Laplace equation

CHARACTERIZATION OF SLANT HELIX İN GALILEAN AND PSEUDO-GALILEAN SPACES

THE DARBOUX TRIHEDRONS OF REGULAR CURVES ON A REGULAR SURFACE

Non-null weakened Mannheim curves in Minkowski 3-space

Transcription:

Bol. Soc. Paran. Mat. (3s.) v. 32 1 (2014): 35 42. c SPM ISSN-2175-1188 on line ISSN-00378712 in press SPM: www.spm.uem.br/bspm doi:10.5269/bspm.v32i1.19035 D Tangent Surfaces of Timelike Biharmonic D Helices according to Darboux Frame on Non-degenerate Timelike Surfaces in the Lorentzian Heisenberg GroupH Talat Körpinar and Essin Turhan abstract: In this paper, we study D tangent surfaces of timelike biharmonic D-helices according to Darboux frame on non-degenerate timelike surfaces in the Lorentzian Heisenberg group H. We obtain parametric equation D tangent surfaces of timelike biharmonic D-helices in the Lorentzian Heisenberg group H. Moreover, we illustrate the figure of our main theorem. Key Words: D Biharmonic curve, D tangent surfaces, Darboux frame, Heisenberg group. Contents 1 Introduction 35 2 Preliminaries 36 3 Timelike Biharmonic D-Helices According to Darboux Frame on a Non-Degenerate Timelike Surface in the Lorentzian Heisenberg Group H 37 4 D Tangent Surfaces According to Darboux Frame on a Non-Degenerate Timelike Surface in the Lorentzian Heisenberg Group H 39 1. Introduction A smooth map φ : N M is said to be biharmonic if it is a critical point of the bienergy functional: E 2 (φ) = where T(φ) := tr φ dφ is the tension field of φ N 1 2 T(φ) 2 dv h, 2000 Mathematics Subject Classification: 31B30, 58E20 35 Typeset by B S P M style. c Soc. Paran. de Mat.

36 Talat Körpinar and Essin Turhan The Euler Lagrange equation of the bienergy is given by T 2 (φ) = 0. Here the section T 2 (φ) is defined by T 2 (φ) = φ T(φ)+trR(T(φ),dφ)dφ, and called the bitension field of φ. Non-harmonic biharmonic maps are called proper biharmonic maps. In this paper, we study D tangent surfaces of timelike biharmonic D-helices according to Darboux frame on non-degenerate timelike surfaces in the Lorentzian Heisenberg group H. We obtain parametric equation D tangent surfaces of timelike biharmonic D-helices in the Lorentzian Heisenberg group H. Moreover, we illustrate the figure of our main theorem. 2. Preliminaries Heisenberg group plays an important role in many branches of mathematics such as representation theory, harmonic analysis, PDEs or even quantum mechanics, where it was initially defined as a group of 3 3 matrices 1 x z 0 1 y : x,y,z R 0 0 1 with the usual multiplication rule. The left-invariant Lorentz metric on H is ρ = dx 2 +dy 2 +(xdy +dz) 2. The following set of left-invariant vector fields forms an orthonormal basis for the corresponding Lie algebra: { e 1 = z, e 2 = y x z, e 3 = }. (2.1) x The characterising properties of this algebra are the following commutation relations: ρ(e 1,e 1 ) = ρ(e 2,e 2 ) = 1, ρ(e 3,e 3 ) = 1. (2.2)

D Tangent Surfaces of Timelike Biharmonic D Helices 37 3. Timelike Biharmonic D-Helices According to Darboux Frame on a Non-Degenerate Timelike Surface in the Lorentzian Heisenberg Group H LetΠ H be a timelike surface with the unit normal vectornin the Lorentzian Heisenberg group H. If γ is a timelike curve on Π H, then we have the Frenet frame {T,N,B} and Darboux frame {T,n,g} with spacelike vector g = T n along the curve γ. Let {T,N,B} be the Frenet frame fields tangent to the Lorentzian Heisenberg group H along γ defined as follows: T is the unit vector field γ tangent to γ, N is the unit vector field in the direction of T T (normal to γ) and B is chosen so that {T,N,B} is a positively oriented orthonormal basis. Then, we have the following Frenet formulas: T T = κn, T N = κt+τb, (3.1) T B = τn, where κ is the curvature of γ and τ is its torsion and ρ(t,t) = 1, ρ(n,n) = 1, ρ(b,b) = 1, (3.2) ρ(t,n) = ρ(t,b) = ρ(n,b) = 0. Let θ be the angle between N and n. The relationships between {T,N,B} and {T, n, g} are as follows: and T = T, N = cosθn+sinθg, (3.3) B = sinθn cosθg, T = T, g = sinθn cosθb, (3.4) n = cosθn+sinθb. By differentiating (3.4), using (3.1), (3.3) and Frenet formulas we obtain T T = (κcosθ)n+(κsinθ)g, ( T g = ( κsinθ)t+ τ + dθ ) n, (3.5) ds ( T n = ( κcosθ)t τ + dθ ) g. ds

38 Talat Körpinar and Essin Turhan If we represent κcosθ, κsinθ and τ + dθ ds with the symbols κ n, κ g, and τ g respectively, then the equations in (3.5) can be written as T T = κ g g+κ n n, T g = κ g T+τ g n, (3.6) T n = κ n T τ g g. With respect to the orthonormal basis {e 1,e 2,e 3 }, we can write T = T 1 e 1 +T 2 e 2 +T 3 e 3, g = g 1 e 1 +g 2 e 2 +g 3 e 3. (3.7) n = n 1 e 1 +n 2 e 2 +n 3 e 3, To separate a curve according to Darboux frame from that of Frenet- Serret frame, in the rest of the paper, we shall use notation for the curve as D-curve. First of all we recall the following well known result (cf. [8]). Theorem 3.1. Let γ : I Π H be a non-geodesic unit speed timelike curve on timelike surface Π in the Lorentzian Heisenberg group H. γ is a unit speed timelike biharmonic curve on Π if and only if κ 2 n +κ2 g = constant 0, (3.8) κ n κ3 n +κ gτ g κ 2 g κ n +κ g τ g +κ g τ g τ2 g κ n = κ n (1 4g 2 1 ) 4κ gn 1 g 1, κ g κ 3 g 2κ nτ g κ 2 nκ g κ n τ g κ g τ 2 g = 4κ n n 1 g 1 +κ g (1 4n 2 1). Theorem 3.2. Let γ : I Π H be a non-geodesic unit speed timelike biharmonic D- helix on timelike surface Π in the Lorentzian Heisenberg group H. Then parametric equations of timelike biharmonic D- helix are x(s) = coshℵ R (cosh[rs]sinh[ ]+cosh[ ]sinh[rs])+ 1, y(s) = coshℵ R (cosh[ ]cosh[rs]+sinh[ ]sinh[rs])+ 2, (3.9) z(s) = sinhℵs+ ( +Rs) 2R 2 cosh 2 ℵ 1 R cosh2 ℵcosh[ ]cosh[rs] 1 R cosh2 ℵsinh[ ]sinh[rs] 1 4R 2 cosh2 ℵsinh2[Rs+ ]+ 3, where, 1, 2, 3, are constants of integration and R =sechℵ κ 2 n +κ2 g 2sinhℵ. Using Mathematica in above system we have Fig.1:

D Tangent Surfaces of Timelike Biharmonic D Helices 39 Fig. 1 4. D Tangent Surfaces According to Darboux Frame on a Non-Degenerate Timelike Surface in the Lorentzian Heisenberg Group H A ruled surface is formed by a continuous family of straight line segments. The D tangent surface of γ is a ruled surface O(s,u) = γ(s)+ut(s). (4.1) Theorem 4.1. Let γ : I O H be a non-geodesic unit speed timelike biharmonic D- helix on timelike surface O in the Lorentzian Heisenberg group H. Then,

40 Talat Körpinar and Essin Turhan equation of D tangent surface of timelike biharmonic D- helix is O(s,u) = [sinhℵs+ ( +Rs) 2R 2 cosh 2 ℵ 1 R cosh2 ℵcosh[ ]cosh[rs] 1 R cosh2 ℵsinh[ ]sinh[rs] 1 4R 2 cosh2 ℵsinh2[Rs+ ] + 3 +[ coshℵ R (cosh[rs]sinh[ ]+cosh[ ]sinh[rs])+ 1] (4.2) [ coshℵ R (cosh[ ]cosh[rs]+sinh[ ]sinh[rs])+ 2]+usinhP]e 1 +[ coshℵ R (cosh[ ]cosh[rs]+sinh[ ]sinh[rs]) +ucoshpsinh[ms+n]+ 2 ]e 2 +[ coshℵ R (cosh[rs]sinh[ ]+cosh[ ]sinh[rs]) +ucoshpcosh[ms+n]+ 1 ]e 3, where, 1, 2, 3, are constants of integration and R =sechℵ κ 2 n +κ 2 g 2sinhℵ. Proof: From the assumption we get T = sinhpe 1 +coshpsinh[ms+n]e 2 +coshpcosh[ms+n]e 3. (4.3) Substituting Eq.(3.9) and Eq.(4.3) into Eq.(4.1), we obtain Eq.(4.2). This completes the proof. Theorem 4.2. Let γ : I O H be a non-geodesic unit speed timelike biharmonic D- helix on timelike surface O in the Lorentzian Heisenberg group H. Then, equation of D tangent surface of timelike biharmonic D- helix are x O = [ coshℵ R (cosh[rs]sinh[ ]+cosh[ ]sinh[rs])+ucoshpcosh[ms+n]+ 1] y O = [ coshℵ R (cosh[ ]cosh[rs]+sinh[ ]sinh[rs])+ucoshpsinh[ms+n]+ 2] z O = [sinhℵs+ ( +Rs) 2R 2 cosh 2 ℵ 1 R cosh2 ℵcosh[ ]cosh[rs] 1 R cosh2 ℵsinh[ ]sinh[rs] 1 4R 2 cosh2 ℵsinh2[Rs+ ] + 3 +[ coshℵ R (cosh[rs]sinh[ ]+cosh[ ]sinh[rs])+ 1] [ coshℵ R (cosh[ ]cosh[rs]+sinh[ ]sinh[rs])+ 2]+usinhP] [ coshℵ R (cosh[ ]cosh[rs]+sinh[ ]sinh[rs])+ucoshpsinh[ms+n]+ 2] [ coshℵ R (cosh[rs]sinh[ ]+cosh[ ]sinh[rs])+ucoshpcosh[ms+n]+ 1],

D Tangent Surfaces of Timelike Biharmonic D Helices 41 where, 1, 2, 3, are constants of integration and R =sechℵ κ 2 n +κ 2 g 2sinhℵ. Proof: From Theorem 4.1, we easily have above system, which completes the proof. In the light of Theorem 4.2, we give the following figures for the D tangent surface of timelike biharmonic D- helix. Fig. 2 Fig. 3

42 Talat Körpinar and Essin Turhan References 1. J. F. Burke: Bertrand Curves Associated with a Pair of Curves, Mathematics Magazine, 34 (1) (1960), 60-62. 2. R. Caddeo, S. Montaldo, P. Piu: Biharmonic curves on a surface, Rend. Mat. Appl. 21 (2001), 143 157. 3. J. Eells, J.H. Sampson: Harmonic mappings of Riemannian manifolds, Amer. J. Math. 86 (1964), 109 160. 4. A.A. Ergin: Timelike Darboux curves on a timelike surface M M1 3, Hadronic Journal 24 (6) (2001), 701-712. 5. N. Ekmekçi and K. Ilarslan: On Bertrand curves and their characterization, Diff.Geom. Dyn. Syst., 3 (2) (2001), 17-24. 6. S. Flöry, H. Pottmann, Ruled surfaces for rationalization and design in architecture. In: Proceedings of the conference of the association for computer aided design in architecture (ACADIA); 2010. 7. S.Izumiya, D.Pei, T.Sano: The lightcone Gauss map and the lightcone developable of a spacelike curve in Minkowski 3-space, Glasgow Math. J. 42 (2000), 75-89. 8. T. Körpınar and E. Turhan, On Characterization Timelike Biharmonic D-Helices According to Darboux Frame On Non-Degenerate Timelike Surfaces In The Lorentzian Heisenberg Group, Annals of Fuzzy Mathematics and Informatics, 4 (2) (2012), 393-400. 9. T. Körpınar and E. Turhan: On Spacelike Biharmonic Slant Helices According to Bishop Frame in the Lorentzian Group of Rigid Motions E(1,1), Bol. Soc. Paran. Mat. 30 (2) (2012), 1 10. 10. J. Milnor, Curvatures of Left-Invariant Metrics on Lie Groups, Advances in Mathematics 21 (1976), 293-329. 11. A.W. Nutbourne, R.R. Martin, Differential Geometry Applied to the Design of Curves and Surfaces, Ellis Horwood, Chichester, UK, 1988. 12. B. O Neill, Semi-Riemannian Geometry, Academic Press, New York (1983). Talat Körpinar and Essin Turhan Fırat University, Department of Mathematics, 23119, Elazığ, Turkey E-mail address: talatkorpinar@gmail.com E-mail address: essin.turhan@gmail.com

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback