Tampere University of Technology

TUTCRIS Research Portal

A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions

Research output: Chapter in Book/Report/Conference proceedingConference contributionScientificpeer-review

Standard

A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions. / Eriksson, Sirkka-Liisa; Orelma, Heikki.

Modern Trends in Hypercomplex Analysis. ed. / Swanhild Bernstein; Uwe Kähler; Irene Sabadini; Franciscus Sommen. Springer International Publishing, 2016. p. 175-189 (Trends in Mathematics).

Research output: Chapter in Book/Report/Conference proceedingConference contributionScientificpeer-review

Harvard

Eriksson, S-L & Orelma, H 2016, A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions. in S Bernstein, U Kähler, I Sabadini & F Sommen (eds), Modern Trends in Hypercomplex Analysis. Trends in Mathematics, Springer International Publishing, pp. 175-189, ISAAC Congress, 1/01/00. https://doi.org/10.1007/978-3-319-42529-0_9

APA

Eriksson, S-L., & Orelma, H. (2016). A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions. In S. Bernstein, U. Kähler, I. Sabadini, & F. Sommen (Eds.), Modern Trends in Hypercomplex Analysis (pp. 175-189). (Trends in Mathematics). Springer International Publishing. https://doi.org/10.1007/978-3-319-42529-0_9

Vancouver

Eriksson S-L, Orelma H. A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions. In Bernstein S, Kähler U, Sabadini I, Sommen F, editors, Modern Trends in Hypercomplex Analysis. Springer International Publishing. 2016. p. 175-189. (Trends in Mathematics). https://doi.org/10.1007/978-3-319-42529-0_9

Author

Eriksson, Sirkka-Liisa ; Orelma, Heikki. / A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions. Modern Trends in Hypercomplex Analysis. editor / Swanhild Bernstein ; Uwe Kähler ; Irene Sabadini ; Franciscus Sommen. Springer International Publishing, 2016. pp. 175-189 (Trends in Mathematics).

Bibtex - Download

@inproceedings{891cba9f031d4d13b6ae2537d16db726,
title = "A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions",
abstract = "In complex function theory holomorphic functions are conjugate gradient of real harmonic functions. We may build function theories in higher dimensions based on this idea if we generalize harmonic functions and define the conjugate gradient operator. We study this type of function theory in R3 connected to harmonic functions with respect to the Laplace–Beltrami operator of the Riemannian metric ds2=x−2k2(∑2i=0dx2i). The domain of the definition of our functions is in R3 and the image space is the associative algebra of quaternions H generated by 1, e1, e2 and e12 = e1e2 satisfying the relation e i e j + e j e i = –2δ ij , i, j = 1, 2. The complex field C is identified by the set {x0+x1e1|x0,x1εB}. The conjugate gradient is defined in terms of modified Dirac operator, introduced by Mkf=Df+kx−12Qf¯¯¯¯¯¯¯, where Qf is given by the decomposition f (x) = Pf (x) + Qf (x) e2 with Pf (x) and Qf (x) in C and Qf¯¯¯¯¯¯¯ is the usual complex conjugation.Leutwiler noticed around 1990 that if the usual Euclidean metric is changed to the hyperbolic metric of the Poincar{\'e} upper half-space model (k = 1), then the power function (x0 + x1e1 + x2e2) n , calculated using quaternions, is the conjugate gradient of the a hyperbolic harmonic function. We study functions, called k-hypermonogenic, satisfying M k f = 0. Monogenic functions are 0-hypermonogenic. Moreover, 1-hypermonogenic functions are hypermonogenic defined by H. Leutwiler and the first author.We prove a new Cauchy type integral formulas for k-hypermonogenic functions where the kernels are calculated using the hyperbolic distance and are k-hypermonogenic functions. This formula gives the known formulas in case of monogenic and hypermonogenic functions. It also produces new Cauchy and Teodorescu type integral operators investigated in the future research.",
author = "Sirkka-Liisa Eriksson and Heikki Orelma",
note = "EXT={"}Eriksson, Sirkka-Liisa{"}",
year = "2016",
month = "11",
day = "23",
doi = "10.1007/978-3-319-42529-0_9",
language = "English",
isbn = "978-3-319-42528-3",
series = "Trends in Mathematics",
publisher = "Springer International Publishing",
pages = "175--189",
editor = "Swanhild Bernstein and Uwe K{\"a}hler and Irene Sabadini and Franciscus Sommen",
booktitle = "Modern Trends in Hypercomplex Analysis",

}

RIS (suitable for import to EndNote) - Download

TY - GEN

T1 - A New Cauchy Type Integral Formula for Quaternionic k-hypermonogenic Functions

AU - Eriksson, Sirkka-Liisa

AU - Orelma, Heikki

N1 - EXT="Eriksson, Sirkka-Liisa"

PY - 2016/11/23

Y1 - 2016/11/23

N2 - In complex function theory holomorphic functions are conjugate gradient of real harmonic functions. We may build function theories in higher dimensions based on this idea if we generalize harmonic functions and define the conjugate gradient operator. We study this type of function theory in R3 connected to harmonic functions with respect to the Laplace–Beltrami operator of the Riemannian metric ds2=x−2k2(∑2i=0dx2i). The domain of the definition of our functions is in R3 and the image space is the associative algebra of quaternions H generated by 1, e1, e2 and e12 = e1e2 satisfying the relation e i e j + e j e i = –2δ ij , i, j = 1, 2. The complex field C is identified by the set {x0+x1e1|x0,x1εB}. The conjugate gradient is defined in terms of modified Dirac operator, introduced by Mkf=Df+kx−12Qf¯¯¯¯¯¯¯, where Qf is given by the decomposition f (x) = Pf (x) + Qf (x) e2 with Pf (x) and Qf (x) in C and Qf¯¯¯¯¯¯¯ is the usual complex conjugation.Leutwiler noticed around 1990 that if the usual Euclidean metric is changed to the hyperbolic metric of the Poincaré upper half-space model (k = 1), then the power function (x0 + x1e1 + x2e2) n , calculated using quaternions, is the conjugate gradient of the a hyperbolic harmonic function. We study functions, called k-hypermonogenic, satisfying M k f = 0. Monogenic functions are 0-hypermonogenic. Moreover, 1-hypermonogenic functions are hypermonogenic defined by H. Leutwiler and the first author.We prove a new Cauchy type integral formulas for k-hypermonogenic functions where the kernels are calculated using the hyperbolic distance and are k-hypermonogenic functions. This formula gives the known formulas in case of monogenic and hypermonogenic functions. It also produces new Cauchy and Teodorescu type integral operators investigated in the future research.

AB - In complex function theory holomorphic functions are conjugate gradient of real harmonic functions. We may build function theories in higher dimensions based on this idea if we generalize harmonic functions and define the conjugate gradient operator. We study this type of function theory in R3 connected to harmonic functions with respect to the Laplace–Beltrami operator of the Riemannian metric ds2=x−2k2(∑2i=0dx2i). The domain of the definition of our functions is in R3 and the image space is the associative algebra of quaternions H generated by 1, e1, e2 and e12 = e1e2 satisfying the relation e i e j + e j e i = –2δ ij , i, j = 1, 2. The complex field C is identified by the set {x0+x1e1|x0,x1εB}. The conjugate gradient is defined in terms of modified Dirac operator, introduced by Mkf=Df+kx−12Qf¯¯¯¯¯¯¯, where Qf is given by the decomposition f (x) = Pf (x) + Qf (x) e2 with Pf (x) and Qf (x) in C and Qf¯¯¯¯¯¯¯ is the usual complex conjugation.Leutwiler noticed around 1990 that if the usual Euclidean metric is changed to the hyperbolic metric of the Poincaré upper half-space model (k = 1), then the power function (x0 + x1e1 + x2e2) n , calculated using quaternions, is the conjugate gradient of the a hyperbolic harmonic function. We study functions, called k-hypermonogenic, satisfying M k f = 0. Monogenic functions are 0-hypermonogenic. Moreover, 1-hypermonogenic functions are hypermonogenic defined by H. Leutwiler and the first author.We prove a new Cauchy type integral formulas for k-hypermonogenic functions where the kernels are calculated using the hyperbolic distance and are k-hypermonogenic functions. This formula gives the known formulas in case of monogenic and hypermonogenic functions. It also produces new Cauchy and Teodorescu type integral operators investigated in the future research.

U2 - 10.1007/978-3-319-42529-0_9

DO - 10.1007/978-3-319-42529-0_9

M3 - Conference contribution

SN - 978-3-319-42528-3

T3 - Trends in Mathematics

SP - 175

EP - 189

BT - Modern Trends in Hypercomplex Analysis

A2 - Bernstein, Swanhild

A2 - Kähler, Uwe

A2 - Sabadini, Irene

A2 - Sommen, Franciscus

PB - Springer International Publishing

ER -