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Line 33: \|} The '''dual-complex numbers''' make up a four-dimensional [[Algebra over a field\|algebra]] over the [[real number]]s.<ref>{{Citation\|last=Matsuda\|first=Genki\|title=Anti-commutative Dual Complex Numbers and 2D Rigid Transformation\|date=2014~~\|url=https://doi.org/10.1007/978-4-431-55007-5_17~~\|work=Mathematical Progress in Expressive Image Synthesis I: Extended and Selected Results from the Symposium MEIS2013\|pages=131–138\|editor-last=Anjyo\|editor-first=Ken\|series=Mathematics for Industry\|publisher=Springer Japan\|language=en\|doi=10.1007/978-4-431-55007-5_17\|isbn=9784431550075~~\|access-date=2019-09-14~~\|last2=Kaji\|first2=Shizuo\|last3=Ochiai\|first3=Hiroyuki\|arxiv=1601.01754}}</ref><ref>Gunn C. (2011) On the Homogeneous Model of Euclidean Geometry. In: Dorst L., Lasenby J. (eds) Guide to Geometric Algebra in Practice. Springer, London</ref> Their primary application is in representing [[rigid body motion\|rigid body motions]] in 2D space. Unlike multiplication of [[dual number]]s or of [[complex number]]s, that of dual-complex numbers is [[non-commutative]].

Applications of dual quaternions to 2D geometry: Difference between revisions