tag:joss.theoj.org,2005:/papers/tagged/algebra?page=2Journal of Open Source Software2021-10-15T11:39:58ZJournal of Open Source Softwarehttps://joss.theoj.orgtag:joss.theoj.org,2005:Paper/23812021-10-15T11:39:58Z2021-10-16T00:03:36ZPyArmadillo: a streamlined linear algebra library for Pythonacceptedv0.500.02021-02-10 06:48:26 UTC662021-10-15 11:39:58 UTC620213051JasonRumenganData61/CSIRO, Australia, Queensland University of Technology, Australia0000-0003-1839-5138TerryYueZhuoUniversity of New South Wales, Australia0000-0002-5760-5188ConradSandersonData61/CSIRO, Australia, Griffith University, Australia0000-0002-0049-450110.21105/joss.03051https://doi.org/10.5281/zenodo.5564389Python, C++, Matlabhttps://joss.theoj.org/papers/10.21105/joss.03051.pdflinear algebra, scientific computing, mathematicstag:joss.theoj.org,2005:Paper/28872021-08-24T12:40:33Z2021-08-25T00:02:04ZSymfem: a symbolic finite element definition libraryacceptedv2021.7.62021-07-17 16:42:26 UTC642021-08-24 12:40:33 UTC620213556MatthewW.ScroggsDepartment of Engineering, University of Cambridge0000-0002-4658-244310.21105/joss.03556https://doi.org/10.5281/zenodo.5242891Pythonhttps://joss.theoj.org/papers/10.21105/joss.03556.pdffinite element method, basis functions, symbolic algebra, numerical analysistag:joss.theoj.org,2005:Paper/28082021-07-19T12:55:02Z2021-07-20T00:00:54Zcaracas: Computer algebra in Racceptedv1.1.12021-06-22 09:19:25 UTC632021-07-19 12:55:02 UTC620213438MikkelMeyerAndersenDepartment of Mathematical Sciences, Aalborg University, Denmark0000-0002-0234-0266SørenHøjsgaardDepartment of Mathematical Sciences, Aalborg University, Denmark0000-0002-3269-955210.21105/joss.03438https://doi.org/10.5281/zenodo.5070324R, Pythonhttps://joss.theoj.org/papers/10.21105/joss.03438.pdfcas, mathematics, symbolic mathematics, statistics, tex, latextag:joss.theoj.org,2005:Paper/22932021-07-09T17:42:32Z2021-07-10T00:02:42ZlibCEED: Fast algebra for high-order element-based discretizationsacceptedv0.8.02021-01-04 07:15:15 UTC632021-07-09 17:42:32 UTC620212945JedBrownUniversity of Colorado at Boulder0000-0002-9945-0639AhmadAbdelfattahUniversity of Tennessee0000-0001-5054-4784ValeriaBarraUniversity of Colorado at Boulder0000-0003-1129-2056NatalieBeamsUniversity of Tennessee0000-0001-6060-4082Jean-SylvainCamierLawrence Livermore National Laboratory0000-0003-2421-1999VeselinDobrevLawrence Livermore National Laboratory0000-0003-1793-5622YohannDudouitLawrence Livermore National Laboratory0000-0001-5831-561XLeilaGhaffariUniversity of Colorado at Boulder0000-0002-0965-214XTzanioKolevLawrence Livermore National Laboratory0000-0002-2810-3090DavidMedinaOccalytics LLCWillPaznerLawrence Livermore National Laboratory0000-0003-4885-2934ThilinaRatnayakaUniversity of Illinois at Urbana-Champaign0000-0001-6102-6560JeremyThompsonUniversity of Colorado at Boulder0000-0003-2980-0899StanTomovUniversity of Tennessee0000-0002-5937-795910.21105/joss.02945https://doi.org/10.5281/zenodo.5080235C, C++, Cudahttps://joss.theoj.org/papers/10.21105/joss.02945.pdfhigh-performance computing, high-order methods, finite elements, spectral elements, matrix-freetag:joss.theoj.org,2005:Paper/24392021-04-05T12:48:27Z2021-04-06T00:01:43Zepipack: An infectious disease modeling package for Pythonacceptedv0.1.12021-03-04 15:23:47 UTC602021-04-05 12:48:27 UTC620213097BenjaminF.MaierInstitute for Theoretical Biology, Humboldt-University of Berlin, Philippstr. 13, D-10115 Berlin, Robert Koch Institute, Nordufer 20, D-13353 Berlin0000-0001-7414-882310.21105/joss.03097https://doi.org/10.5281/zenodo.4655616Pythonhttps://joss.theoj.org/papers/10.21105/joss.03097.pdfinfectious disease modeling, stochastic simulations, computer algebra systems, networks, visualizationtag:joss.theoj.org,2005:Paper/23872021-03-31T15:42:57Z2021-04-02T12:27:09ZMetatheory.jl: Fast and Elegant Algebraic Computation in Julia with Extensible Equality Saturationacceptedv0.1.02021-02-12 14:39:29 UTC592021-03-31 15:42:57 UTC620213078AlessandroCheliUniversity of Pisa, Pisa, Italy0000-0002-8122-946910.21105/joss.03078https://doi.org/10.5281/zenodo.4646136Juliahttps://joss.theoj.org/papers/10.21105/joss.03078.pdfcompiler, symbolic, algebra, rewriting, optimizationtag:joss.theoj.org,2005:Paper/20542021-03-31T15:40:57Z2021-04-01T09:15:29Zropenblas: Download, Compile and Link OpenBLAS Library with Racceptedv0.2.82020-10-01 19:42:35 UTC592021-03-31 15:40:57 UTC620212769Pedro RafaelDiniz MarinhoDepartment of Statistics, Federal University of Paraíba, João Pessoa, Paraíba - PB, Brazil0000-0003-1591-830010.21105/joss.02769https://doi.org/10.5281/zenodo.4618251Rhttps://joss.theoj.org/papers/10.21105/joss.02769.pdfCompiling R and OpenBLAS, Link OpenBLAS, Switch between versions of R, Fast algebraic computingtag:joss.theoj.org,2005:Paper/16162020-08-31T06:29:30Z2021-02-15T11:30:46ZGinkgo: A high performance numerical linear algebra libraryacceptedv1.1.12020-05-20 16:10:14 UTC522020-08-31 06:29:30 UTC520202260HartwigAnztKarlsruhe Institute of Technology, Innovative Computing Laboratory, University of Tennessee, Knoxville0000-0003-2177-952XTerryCojeanKarlsruhe Institute of Technology0000-0002-1560-921XYen-ChenChenThe University of TokyoGoranFlegarUniversity of Jaume I0000-0002-4154-0420FritzGöbelKarlsruhe Institute of TechnologyThomasGrützmacherKarlsruhe Institute of Technology0000-0001-9346-2981PratikNayakKarlsruhe Institute of Technology0000-0002-7961-1159TobiasRibizelKarlsruhe Institute of Technology0000-0003-3023-1849Yu-HsiangTsaiKarlsruhe Institute of Technology0000-0001-5229-373910.21105/joss.02260https://doi.org/10.5281/zenodo.4003613C++, SourcePawn, Cudahttps://joss.theoj.org/papers/10.21105/joss.02260.pdflinear-algebra, hpc, cuda, modern-c++, hip, spmvtag:joss.theoj.org,2005:Paper/13242020-07-04T16:51:52Z2021-02-15T11:31:23ZFLAM: Fast Linear Algebra in MATLAB - Algorithms for Hierarchical Matricesacceptedv1.1.0 (will update on completion)2019-11-07 18:37:26 UTC512020-07-04 16:51:52 UTC520201906KennethL.HoCenter for Computational Mathematics, Flatiron Institute0000-0001-5450-496610.21105/joss.01906https://doi.org/10.5281/zenodo.3930385Matlabhttps://joss.theoj.org/papers/10.21105/joss.01906.pdfhierarchical matrices, fast multipole method, low rank, interpolative decomposition, recursive skeletonization, hierarchical interpolative factorization, integral equations, partial differential equationstag:joss.theoj.org,2005:Paper/9292020-02-18T19:07:16Z2021-02-15T11:32:24ZManif: A micro Lie theory library for state estimation in robotics applicationsacceptedbranch: joss2019-03-15 16:11:36 UTC462020-02-18 19:07:16 UTC520201371JérémieDerayInstitut de Robòtica i Informàtica Industrial, CSIC-UPC, Llorens Artigas 4-6, 08028, Barcelona, Spain.0000-0001-5279-8251JoanSolàInstitut de Robòtica i Informàtica Industrial, CSIC-UPC, Llorens Artigas 4-6, 08028, Barcelona, Spain.0000-0002-2933-338110.21105/joss.01371https://doi.org/10.5281/zenodo.3626651C, C++https://joss.theoj.org/papers/10.21105/joss.01371.pdfLie group, Lie algebra, State Estimation, Robotics