Lamarle Formula in 3-Dimensional Lorentz Space Soley ERSOY, Murat TOSUN Department of Mathematics, Faculty of Arts and Sciences Sakarya University, 54187 Sakarya/TURKEY 0 1 January 5, 2010 0 2 n Abstract a J TheLamarleFormula,givenbyKruppain[8],isknownasarelation- shipbetweentheGaussiancurvatureandthedistributionparameterofa 5 ruled surface in the surface theory. The ruled surfaces were investigated ] in3differentclasseswithrespecttothecharacterofbasecurvesandrul- G ings,[14],[15]. Inthispaperonaccountofthesestudies,therelationships D between the Gaussian curvatures and distribution parameters of space- like ruled surface, timelike ruled surface with spacelike ruling and time- . h like ruled surface with timelike ruling are obtained, respectively. These at relationshipsarecalledasLorentzianLamarleformulas. Finallysomeex- m amples concerning with these relations are given. Subject Classification: 53B30, 53C50, 14J26 [ Key Words: Ruledsurface,distributionparameter,Gaussiancurvature, 1 Lamarle formula. v 9 9 6 1 Introduction 0 1. The study of ruled surface in R3 is classical subject in differential geometry. It 0 hasagainbeenstudiedinsomeareas(i.e. Projectivegeometry, [13], Computer- 0 aideddesign,[11],etc.) Also,itiswellknownthatthegeometryofruledsurface 1 is very important of kinematics or spatial mechanisms in R3, [4], [7]. A ruled : v surface is one which can be generated by sweeping a line through space. Devel- i X opable surfaces are special cases of ruled surfaces, [10]. Cylindrical surfaces are examples of developable surfaces. On a developable surface at least one of the r a two principal curvatures is zero at all points.Consequently the Gaussian curva- ture is zero everywhere too. So it is meaningful for us to study non-cylindrical ruled surfaces. Lorentz metrics in 3 dimensional Lorentz space R3 is indefinite. In the theory − 1 of relativity, geometry of indefinite metric is very crucial. Hence, the theory of ruled surface in Lorentz space R3, which has the metric ds2 =dx2+dx2 dx2, 1 1 2− 3 attracted much attention. The situation is much more complicated than the Euclidean case, since the ruled surfaces may have a definite metric (spacelike surfaces), Lorentz metric (timelike surfaces) or mixed metric. Some character- izations for ruled surfaces are obtained by [9]. Timelike and spacelike ruled surfaces are defined and the characterizations of timelike and spacelike ruled surfaces are found in [2], [5], [6], [14] and [15]. 1 2 Preliminaries Let R3 denote the 3 dimensional Lorentz space, i.e. the Euclidean space E3 1 − with standard flat metric given by g =dx2+dx2 dx2 (2.1) 1 2− 3 where (x ,x ,x ) is rectangular coordinate system of R3. Since g is indefinite 1 2 3 1 metric, recall that a vector ~v in R3 can have one of three casual characters: 1 it can be space-like if g(~v,~v) > 0 or ~v = 0, time-like if g(~v,~v) < 0 and null g(~v,~v)=0 and~v =0. Similarly, an arbitrary curve α~ =α~(s) R3 can locally 6 ⊂ 1 be space-like, time-like or null (light-like), if all of its velocity vectors α~′(s) are respectively space-like, time-like or null (light-like). The norm of a vector ~v is given by ~v = g(~v,~v). Therefore, ~v is a unit vector if g(~v,~v) = 1. k k | | ∓ Furthermore, vectorps~v and w~ are said to be orthogonal if g(~v,w~)=0, [10]. Let the set of all timelike vectors in R3 be Γ. For ~u Γ, we call 1 ∈ C(~u)= ~v Γ ~v,~u <0 { ∈ | h i } as time-conic of Lorentz space R3 including vector ~u, [10]. 1 Let ~v and w~ be two time-like vectors in Lorentz space R3. In this case there 1 exists the following inequality g(~v,w~) ~v . w~ . | |≥k k k k In this inequality if one wishes the equality condition, then it is necessary for~v and w~ be linear dependent. If time-like vectors ~v and w~ stay inside the same time-conic then there is a unique non-negative real number of θ 0 such that ≥ g(~v,w~)= ~v . w~ .coshθ (2.2) −k k k k where the number θ is called an angle between the timelike vectors, [10]. Let~v andw~ bespacelikevectorsinR3 thatspanaspacelikesubspace. Wehave 1 that g(~v,w~) ~v . w~ | |≤k k k k with equality if and only if ~v and w~ are linearly dependent. Hence, there is a unique angle 0 θ π such that ≤ ≤ g(~v,w~)= ~v . w~ .cosθ (2.3) k k k k where the number θ is called the Lorentzian spacelike angle between spacelike vectors~v and w~, [12]. Let~v and w~ be spacelike vectors in R3 that span a timelike subspace. We have 1 that g(~v,w~) > ~v . w~ . | | k k k k Hence, there is a unique real number θ >0 such that g(~v,w~)= ~v . w~ .coshθ. (2.4) k k k k The Lorentzian timelike angle between spacelike vectors ~v and w~ is defined to be θ, [12]. 2 Let ~v be a spacelike vector and w~ be a timelike vector in R3. Then there is a 1 unique real number θ 0 such that ≥ g(~v,w~)= ~v . w~ .sinhθ. (2.5) k k k k The Lorentzian timelike angle between~v and w~ is defined to be θ, [12]. For any vectors~v =(v ,v ,v ), w~ =(w ,w ,w ) R3 , the Lorentzian product 1 2 3 1 2 3 ∈ 1 ~v w~ of~v and w~ is defined as [1] ∧ ~v w~ =(v w v w ,v w v w ,v w v w ). (2.6) 3 2 2 3 1 3 3 1 1 2 2 1 ∧ − − − 3 Ruled Surface in R3 1 A ruled surface M R3 is a regular surface that has a parametrization ϕ : (I R) R3 of the∈form1 × → 1 ϕ(u,v)=α~(u)+v~γ(u) (3.1) whereα~ and~γ arecurvesinR3 withα~′ nevervanishes. Thecurveαiscalledthe 1 basecurve. Therulingsofruledsurfacearethestraightlinesv α~(u)+v~γ(u). IfconsecutiverulingsofaruledsurfaceinR3intersect,thenthe→surfaceissaidto 1 bedevelopable. Allotherruledsurfacesarecalledskewsurfaces. Ifthereexistsa commonperpendiculartotwoconstructiverulingsintheskewsurface, thenthe foot ofthecommon perpendicularonthemain rulingiscalled astriction point. The set of striction points on a ruled surface defines the striction curve,[15]. The striction curve, β(u) can be written in terms of the base curve α(u) as g(α~′(u),~γ′(u)) β~(u)=α~(u) ~γ(u). (3.2) − ~γ′,~γ′ h i A ruled surface given by (3.1) is called non-cylindrical if ~γ ~γ′ is nowhere ∧ zero. Thus, the rulings are always changing directions on a non-cylindrical ruled surface. A non-cylindrical ruled surface always has a parameterization of the form ϕ˜(u,v)=β~(u)+v~e(u) (3.3) where ~e(u) = ~γ(u) = 1, β~′(u),~e′(u) = 0 and β~(u) is striction curve of k k k~γ(u)k D E ϕ˜, [3]. Thedistributionparameter(ordrall)ofanon-cylindricalruledsurfacegivenby equation (3.3), is a function P defined by det β~′,~e,~e′ P = (cid:16) (cid:17). (3.4) ~e′,~e′ h i where β~ is the striction curve and ~e is the director curve. Moreover, Gaussian curvature of non-cylindrical ruled surface ϕ˜(u,v) is LM N2 K = − (3.5) EG F2 − 3 whereE, F andGarethecoefficientsofthefirstfundamentalform, whereasL, N andM arethecoefficientsofthesecondfundamentalform,ofnon-cylindrical ruled surface, [3]. The unit normal vector of non-cylindrical ruled surface ϕ˜ is given by ϕ˜ ϕ˜ η(u,v)= u∧ v . (3.6) ϕ˜ ϕ˜ u v k ∧ k A surface in the 3 dimensional Minkowski space-time R3 is called a time-like − 1 surface if induced metric on the surface is a Lorentzian metric i.e. the normal on the surface is a space-like vector, [15]. In R3, according to the character of the non-null base curve and the non-null 1 ruling, ruled surfaces are classified into three different groups. As a spacelike ruling moves along a spacelike curve it generates a spacelike ruled surface, that will be denoted by M . Furthermore, the movement of a timelike ruling along 1 a spacelike curve and the movement of a spacelike ruling along a timelike curve generate timelike ruled surfaces. Let us denote these timelike ruled surfaces by M and M , respectively. Now, we will establish Lamarle formula for these 2 3 ruled surfaces M , M , M separately. 1 2 3 4 Lamarle Formula for the Spacelike Ruled Sur- face Let M be a spacelike ruled surface parametrized by 1 ϕ :I R R3 1 × → 1 (u,v) ϕ (u,v)=α~ (u)+v~e (u). 1 1 1 → Ifwechoose ~e =1,~n = ~e′1 andξ~ = ~e1∧~e′1 , weobtain the orthonormal k 1k 1 ~e′1 1 ~e1∧~e′1 k k k k framefield ~e ,~n ,ξ~ . Supposethattheseorthonormalframefieldformsright 1 1 1 n o handed system and is space,time,space type. In this case we may write { } ~e ,~e =1, ~n ,~n = 1, ξ~ ,ξ~ =1, 1 1 1 1 1 1 h i h i − D E (4.1) ~e ,~n = ~n ,ξ~ = ξ~ ,~e =0 1 1 1 1 1 1 h i D E D E and ~e ~n = ξ~ , ~n ξ~ = ~e , ξ~ ~e =~n . (4.2) 1 1 1 1 1 1 1 1 1 ∧ − ∧ − ∧ The Frenet formulae of this orthonormal frame along e become 1 ~e′ =κ ~n , ~n′ =κ ~e +τ ξ~ , ξ~′ =τ ~n . (4.3) 1 1 1 1 1 1 1 1 1 1 1 Let β~ (u) be a striction curve of spacelike ruled surface M given by equation 1 1 (3.2) in R3. In this case the tangent vector β~′ of this curve stays in spacelike 1 1 plane. Taking the angle σ to be the angle between β~′ and~e since the tangent 1 1 1 vector of striction curve of M is 1 β~′ =~e cosσ +ξ~ sinσ 1 1 1 1 1 4 we find the striction curve of M to be 1 β~ = cosσ ~e + sinσ ξ~ du. 1 Z (cid:16) 1 1 1 1(cid:17) The spacelike non-cylindrical ruled surface M is parametrized by 1 ϕ˜ (u,v)= cosσ ~e +sinσ ξ~ du+v~e . 1 Z (cid:16) 1 1 1 1(cid:17) 1 From the equation (3.4) the distribution parameter of M is found to be 1 det cosσ ~e +sinσ ξ~ ,~e ,κ ~n 1 1 1 1 1 1 1 sinσ P = (cid:16) (cid:17) = 1. κ ~n ,κ ~n κ 1 1 1 1 1 h i Adopting κ = 1 we get the distribution parameter as follows 1 ρ1 P =ρ sinσ . (4.4) 1 1 Consideringequation(4.2)fromequation(3.6)wewritetheunitnormaltangent vector of spacelike non-cylindrical ruled surface M 1 sinσ ~n +vκ ξ~ ~η = 1 1 1 1 . (4.5) 1 sin2σ +v2κ2 q − 1 1 (cid:12) (cid:12) Taking into consideration that κ (cid:12)= 1 and equatio(cid:12)n (4.4) we obtain 1 ρ1 P~n + vξ~ ~η = 1 1 . (4.6) 1 P2+v2 |− | p Furthermore, since the unit normal tangent vector η of a spacelike surface M 1 1 is timelike we find that P2+v2 <0, that is v < P . − | | | | The partial differentiation of M with respect to u and v from equation (4.3) 1 are as follows ϕ˜ =cosσ ~e +sinσ ξ~ + vκ ~n , 1u 1 1 1 1 1 1 (4.7) ϕ˜ =~e . 1v 1 Therefore, we find the first fundamental form’s coefficients of M to be 1 E = ϕ˜ ,ϕ˜ =cos2σ +sin2σ v2κ2 =1 v2κ2, h 1u 1ui 1 1− 1 − 1 F = ϕ˜ ,ϕ˜ =cosσ , (4.8) 1u 1v 1 h i G= ϕ˜ ,ϕ˜ =1. 1v 1v h i Inadditiontothese, thesecondorderpartialdifferentialsofM arefoundtobe 1 ϕ˜ = σ′ sinσ +vκ2 ~e +(κ cosσ +τ sinσ +vκ′)~n +(σ′ cosσ +vκ τ )ξ~ , 1uu − 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 ϕ˜ =κ(cid:0) ~n , (cid:1) 1uv 1 1 ϕ˜ =0. 1vv From equation (4.5) and the last equations we get the coefficients of second fundamental of M as 1 5 L= ϕ˜ ,~η = −κ1cosσ1sinσ1−τ1sin2σ1−vκ′1sinσ1+σ1′cosσ1vκ1+v2κ21τ1, 1uu h i q−sin2σ1+v2κ21 | | N = ϕ˜ ,~η = −κ1sinσ1 , (4.9) 1uv h i q−sin2σ1+v2κ21 | | M = ϕ˜ ,~η =0. 1vv h i Consideringequation(4.8)and(4.9)together,wegivethefollowingtheoremfor the Gaussian curvature of spacelike ruled surface M . 1 Theorem 4.1 Let M be spacelike non-cylindrical ruled surface in R3. The 1 1 Gaussian curvature of spacelike non-cylindrical ruled surface M is given in 1 terms of its distribution parameter P by P2 K = (4.10) −(P2 v2)2 − where v < P . | | | | Proof. Substituting equations (4.8) and (4.9) into equation (3.5) and making appropriate simplifications we find the Gaussian curvature of M to be 1 κ2sin2σ K = 1 1 . − sin2σ v2κ2 2 1− 1 (cid:0) (cid:1) Considering κ = 1 and equation (4.4) completes the proof. 1 ρ1 The relation between Gaussian curvature and the distribution parameter of M given by equation (4.10) is called Lorentzian Lamarle formula for the 1 spacelike non-cylindrical ruled surface M . 1 The Lorentzian Lamarle formula for the spacelike ruled surface in R3 is non- 1 positive. Therefore we give the following corollary. Corollary 4.1 Let M be a spacelike non-cylindrical ruled surface with distri- 1 bution parameter P and Gaussian curvature K in R3. 1 1. Along a ruling the Gaussian curvature K(u,v) 0 as v . → →∓∞ 2. K(u,v)=0 if and only if P =0. 3. If the distribution parameter is P never vanishes then K(u,v) is contin- uous and when v = 0 i.e. at the central point on each ruling, K(u,v) assumes its maximum value. Example 4.1 In3 dimensionalLorentzspaceR3 letusdefineanon-cylindrical − 1 ruled surface as ϕ(u,v)=( vcoshu, u, vsinhu) − − that is a 2nd type helicoid and a spacelike surface where 1<v <1, see Figure − 4.1. 6 The Gaussian curvature of this 2nd type helicoid is K = 1 , v < 1, −(1−v2)2 | | see Figure 4.2. 5 Lamarle Formula for the Timelike Ruled Sur- face with Spacelike Base Curve and Timelike Ruling Let M be timelike ruled surface with spacelike base curve and timelike ruling 2 in 3 dimensional Lorentz space, R3. Thus, this ruled surface is parametrized − 1 as follows ϕ :I R R3 2 × → 1 (u,v) ϕ (u,v)=α~ (u)+v~e (u). 2 2 2 → Here, taking ~e = 1 , ~n = ~e′2 and ξ~ = ~e2∧~e′2 , we reach the or- k 2k 2 ~e′2 2 ~e2∧~e′2 k k k k thonormal frame field ~e ,~n ,ξ~ .This forms a right handed system and in 2 2 2 n o time,space,space type. Therefore, { } ~e ,~e = ~n ,~n = ξ~ ,ξ~ =1 2 2 2 2 2 2 −h i h i D E (5.1) ~e ,~n = ~n ,ξ~ = ξ~ ,~e =0 2 2 2 2 2 2 h i D E D E and ~e ~n = ξ~ , ~n ξ~ =~e , ξ~ ~e = ~n . (5.2) 2 2 2 2 2 2 2 2 2 ∧ − ∧ ∧ − The differential formulae of this orthonormal system are ~e′ =κ ~n , ~n′ =κ ~e τ ξ~ , ξ~′ =τ ~n . (5.3) 2 2 2 2 2 2− 2 2 2 2 2 Now,letthestrictioncurvegivenbyequation(3.2)oftimelikeruledsurfaceM 2 be β~ (u). β~ (u) is a spacelike curve and the tangent vector of this curve β~′ 2 2 2 stays in the timelike plane ~e ,ξ~ . Adopting the hyperbolic angle σ between 2 2 2 (cid:16) (cid:17) β~′ and~e we write 2 2 β~′ = sinhσ ~e +coshσ ξ~ . 2 2 2 2 2 7 From the last equation we write for the striction curve of M 2 β~ = (sinhσ ~e +coshσ ξ )du. 2 Z 2 2 2 2 Let M be timelike non-cylindrical ruled surface with spacelike base curve and 2 timelike ruling in R3. In this case we reparametrize M such as 1 2 ϕ˜ (u,v)= sinhσ ~e + coshσ ξ~ du+v~e . 2 Z (cid:16) 2 2 2 2(cid:17) 2 Considering equation (3.4) we find the distribution parameter of timelike non- cylindrical ruled surface M to be 2 det sinhσ ~e +coshσ ξ~ ,~e ,κ ~n 2 2 2 2 2 2 2 coshσ P = (cid:16) (cid:17) = 2. κ ~n ,κ ~n κ 2 2 2 2 2 h i Taking κ = 1 we rewrite the distribution parameter of M as 2 ρ2 2 P =ρ coshσ . (5.4) 2 2 If we consider equation (5.2), from equation (3.6) we see that the timelike non- cylindrical ruled surface’s unit normal vector becomes coshσ ~n +vκ ξ~ ~η = − 2 2 2 2. (5.5) 2 cosh2σ +v2κ2 2 2 q (cid:12) (cid:12) (cid:12) (cid:12) Since κ = 1 , from equation (5.4) we find 2 ρ2 P~n +vξ~ ~η = − 2 2. (5.6) 2 √P2+v2 From equation (5.3), partial differential of M with respect to u and v are 2 ϕ˜ = sinhσ ~e + coshσ ξ~ + vκ ~n , 2u 2 2 2 2 2 2 (5.7) ϕ˜ =~e . 2v 2 Considering the last equations with equation (5.1) we find the coefficients of first fundamental form of M to be 2 E = ϕ˜ ,ϕ˜ = sinh2σ +cosh2σ +v2κ2 =1+v2κ2, h 2u 2ui − 2 2 2 2 F = ϕ˜ ,ϕ˜ = sinhσ , (5.8) 2u 2v 2 h i − G= ϕ˜ ,ϕ˜ = 1. 2v 2v h i − Furthermore, if we consider equation, (5.7) we reach that the second order partial differentials of M 2 ϕ˜ = σ′ coshσ +vκ2 ~e +(κ sinhσ +τ coshσ +vκ′)~n +(σ′ sinhσ vκ τ )ξ~ , 2uu 2 2 2 2 2 2 2 2 2 2 2 2− 2 2 2 ϕ˜ =κ(cid:0) ~n , (cid:1) 2uv 2 2 ϕ =0. 2vv 8 From equation (5.5) and the last equations we find the second fundamentals form’s coefficients as follows L= ϕ˜ ,~η = −κ2sinhσ2coshσ2−τ2cosh2σ2−vκ′2coshσ2−vκ2σ2′ sinhσ2+v2κ22τ2, h 2uu 2i √cosh2σ2+v2κ22 N = ϕ˜ ,~η = κ2coshσ2 , h 2uv 2i √cosh2σ2+vκ22 M = ϕ˜ ,~η =0. 2vv 2 h i (5.9) Therefore, for the Gaussian curvature of timelike ruled surface M , we give the 2 following theorem. Theorem 5.1 Let M be a timelike non-cylindrical ruled surface with spacelike 2 base curve and timelike ruling in R3. Taking P to be the distribution parameter 1 of M we see that the Gaussian curvature of M is 2 2 P2 K = . (5.10) (P2+v2)2 Proof. Substituting equations (5.8) and (5.9) into equation (3.5) we find the Gaussian curvature of M to be 2 κ2 cosh2σ K = 2 2 . cosh2σ +κ2v2 2 2 2 (cid:0) (cid:1) Here considering κ = 1 and equation (5.4) completes the proof. 2 ρ2 The relation between Gaussian curvature and the distribution parameter of M given by equation (5.10) is called Lorentzian Lamarle formula for the 2 timelike non-cylindrical ruled surface with spacelike base curve and timelike ruling. The Lamarle formula for the timelike ruled surface in R3 is non–negative. So, 1 we give the following corollary. Corollary 5.1 Let P be a distribution parameter and K be a Gaussian curva- ture of a timelike non-cylindrical ruled surface M with spacelike base curve and 2 timelike ruling in R3. In this case 1 1. Along ruling as v , K(u,v) 0. →∓∞ → 2. K(u,v)=0 if and only if P =0. 3. If the distribution parameter of M never vanishes, then K(u,v) is con- 2 tinuous and as v = 0 i.e. at the central point on each ruling, K(u,v) takes its minimum value. Example 5.1 In 3 dimensional Lorentz space R3. − 1 ϕ(u,v)=( vsinhu, u, vcoshu) − − is a 3rd type helicoid and a timelike non-cylindrical ruled surface with spacelike base curve and timelike ruling, see: Figure 5.1. 9 The Gaussian curvature of this 3rd type helicoid is K = 1 , see Figure −(1+v2)2 5.2. 6 Lamarle Formula for Timelike Ruled Surface with Timelike Base Curve and Spacelike Rul- ing Suppose that the timelike ruled surface M with timelike base curve and space- 3 like ruling in three dimensional Lorentz space R3 is parametrized as follows 1 ϕ :I R R3 3 × → 1 (u,v) ϕ (u,v)=α~ (u)+v~e (u). 3 3 3 → Consideringthat ~e =1,~n = ~e′3 andξ~ = ~e3∧~e′3 ,wereachtheorthonor- k 3k 3 ~e′3 3 ~e3∧~e′3 k k k k mal frame field ~e ,~n ,ξ~ .This forms a right handed system which is in type 3 3 3 n o space,space,time . Thus we write { } ~e ,~e = ~n ,~n = ξ~ ,ξ~ =1 3 3 3 3 3 3 h i h i −D E (6.1) ~e ,~n = ~n ,ξ~ = ξ~ ,~e =0 3 3 3 3 3 3 h i D E D E and cross product is defined to be ~e ~n =ξ~ , ~n ξ~ = ~e , ξ~ ~e = ~n . (6.2) 3 3 3 3 3 3 3 3 3 ∧ ∧ − ∧ − Differential formulae for this orthonormal system is expressed by ~e′ =κ ~n , ~n′ = κ ~e +τ ξ~ , ξ~′ =τ ~n . (6.3) 3 3 3 3 − 3 3 3 3 3 3 3 Letthestrictioncurveoftimelikeruledsurfacegivenbyequation(3.2)beβ~ (u). 3 This curve is a timelike curve and the tangent vector of this curve stays within the timelike plane ~e ,ξ~ . Adopting the hyperbolic angle σ to be the angle 3 3 3 (cid:16) (cid:17) between β~′ and~e we may write 3 3 β~′ = sinhσ ~e + coshσ ξ~ 3 3 3 3 3 10