On quaternion applications in obtaining surfaces

In this paper, we survey the historical development of quaternions and give some recently studies and applications of quaternions of obtaining surfaces.

Quaternions were advertised by Irish mathematician Sir William Rowan Hamilton in 1843. While he was searching for methods of extensioning complex numbers to higher dimensional spaces, he accidentally invented quaternions. He fell down to find a handy method in three-dimensional space. That is, he could not reach a real in three dimensional skew field. But, he composed quaternions by working in four dimensional space. As to Hamilton, while he was walking with wife over the Royal Canal in Dublin on 16 October 1843, he was experience an epiphany the solution of the equation, Then, without wasting any time, Hamilton carved this equation with the help of his pocketknife the around the corner Broom Bridge (where Hamilton called Brougham Bridge). The phenomenon is called exploration of the quaternion group. Also, in one sense, Hamilton fathered the cross products and dot products of vector algebra. Moreover, Hamilton characterized a quaternion as a serried four item multiple of real numbers, and identified the first item as the "scalar" part, and the remaining three as the "vector" part [1][2][3].
Nowadays, the quaternions which are chiefly utilized in computer graphics, control theory and signal processing for representing rotations and orientations are widespread utilized for spacecraft attitude control systems to be commanded. Also, they are utilized to telemeter their current attitude. The logic is that joining quaternion transitions is much more computationally determined then joining a lot of matrix transitions. Quaternions do not possess a computational singularity (unspecified partition by zero) in control and modelling applications that can take place for quarter spin turns (90°) that are accomplishable by several Air, Sea and Space transports. In pure mathematics, quaternions which are one of the four finite dimensional normed division algebras over the real numbers come to light considerably applications from beginning to end algebra and geometry. Also, quaternions are used not only in rotation but also in reflection [4][5][6][7][8].
Let us now examine the works on applications of quaternions in obtaining surfaces. Primarily, the sum, product, point product, division of two quaternions, inverse of a quaternion and its modulus have been defined. In addition, quaternions are represented by the matrix. Also, quaternions are used in rotation. For example, a counterclockwise rotation through an angle a about an axisx can be represented (Fig. 1), wherex is a unit vector [8].
If we consider the linear map: *Corresponding author: yayli@science.ankara.edu.tr w ! W w ð Þ ¼qwq; whereq ¼ bi þ cj þ dk, b; c; d 2 R is a unit vector quaternion. That is to say, this expression is called reflection (Fig. 2). On the other hand, give the following reference [9] to Definition 1 and Definition 2: Definition 1. A dual number A has the form A = a + ea* where a and a* are real numbers and e is the dual symbol subjected to the rules A dual quaternion Q is written as Hamiltonian conjugate of Q, norm of Q, reciprocal of Q and unit dual quaternion are obtained. Also, screw operators are defined using this dual quaternion.
Definition 2. LetÃ andB be unit dual vectors in ID 3 (i.e. set of unit vector dual quaternions) the quaternion product of these two dual vectors is given byÃB  The expression (1) can rewrite as:ÃB This expression is called screw operator (Fig. 3).
Let's approach today. In computer graphics, spherical linear interpolation (slerp) is shorth and for spherical linear interpolation, in the context of quaternion interpolation for the purpose of animating 3D rotation [10]. Linear interpolation have been done on Euclidean sphere using quaternions. Also, split-quaternions are elements of a four-dimensional associative algebra introduced by James Cockle in 1849.

Definition 3. A split quaternion q is an expression of the form
where q 1 , q 2 , q 3 and q 4 are real numbers and i, j, k are split quaternion units which satisfy the non-commutative multiplication rules [11] The linear interpolation on Loretzian sphere Minkowski space have been done using split quaternions. That also yields the shortest possible interpolation path between the two split quaternion on the unit Lorentzian sphere [12].
Spherical spline quaternion interpolation has been done on sphere in Euclidean space using quaternions (Fig. 4). The spline split quaternion interpolation on hyperbolic sphere in Minkowski space has been done using split quaternions and metric Lorentz. This interpolation curve is called spherical spline split quaternion interpolation in Minkowski space (MSquad) (Fig. 5) [13].
Quaternions are more usable than three Euler angles in the three dimensional Euclidean space. Thus, many laws in different fields can be given by the quaternions. Canal surfaces and tube surfaces can be obtained by the quaternion product and by the matrix representation. Also, the equation of canal surface given by the different frames of its spine curve can be obtained by the same unit quaternion. In addition, these surfaces are obtained by the homothetic motion [1]. For example, for unit speed curve: ; cos ffiffi ffi 3 p t 2 ;  the Frenet frame vectors can be given as, ; The tube surface X(t, h) can be obtained by the homothetic motion as X(t, h) = a(t) + rMN(t), where M is the matrix representation for the unit quaternion q(t, h) = cosh + sinhT(t). Moreover, the graphic is as follows (Fig. 6).
All constant slope surfaces are found in the Euclidean 3-space. Namely, those surfaces for which the position vector of a point of the surface makes constant angle with the normal at the surface in that point. These surfaces could be thought as then bi-dimensional analogue of the generalized helices (Fig. 7) [15]. Circular surfaces are smooth one-parameter families of circles. Three main purposes about circular surfaces and roller coaster surfaces are defined as circular surfaces whose generating circles are lines of curvature. The first one is to reconstruct equations of spacelike circular surfaces and spacelike roller coaster surfaces by using unit split quaternions and homothetic motions.
The second one is to parametrize timelike circular surfaces and give some geometric properties such as striction curves, singularities, Gaussian and mean curvatures. Furthermore, the conditions for timelike roller coaster surfaces to be flat or minimal surfaces are obtained. The last one is to express split quaternionic and matrix representations of timelike circular surfaces and timelike roller coaster surfaces [16]. where s is the arc-length parameter of a 1 (s) = e. Using the timelike unit split quaternion q e = cosh + esinh, we have C ðn;n;b;rÞ ðs; hÞ ¼ nðsÞ þ rðsÞq e ðs; hÞ Â nðsÞ: For r = 1 and r ¼ s 2 , the spacelike circular surfaces are illustrated (Fig. 8).  Canal surfaces determined by spherical indicatrices of any spatial curve in Minkowski 3-space by means of timelike split quaternions. Moreover, using orthogonal matrices corresponding to these quaternions, the canal surfaces are obtained as homothetic motions. Then, we investigate a relationship between the canal surfaces and unit split quaternions [17]. Then, taking r = 1 and r = h, respectively, the equations of the tubular and generalized tubular surfaces KT ðs; hÞ and T (s, h) generated by the tangent indicatrix T are given by (Fig. 10 þ sin 3s cos h þ 5 3 cos 3s sin h :

Conclusion
In this paper, the historical development of quaternions is surveyed. Also, some recently studies and applications of quaternions of obtaining surfaces are considered. Within the framework of the knowledge acquired, it is observed that applies to many areas of quaternions. The number of these studies is increasing day by day. We were only able to give a small summary. We are very happy to try to contribute to these studies. Our work in this direction continues.