SuanShu numerical library

SuanShu
Stable release	20120606 / 2012-06-06
Written in	Java
Type	Math
License	Apache License 2.0
Website	github.com/haksunlinm/SuanShu

SuanShu is a Java math library.^[1] It is open-source under Apache License 2.0 available in GitHub. SuanShu is a large collection of Java classes for basic numerical analysis, statistics, and optimization.^[2] It implements a parallel version of the adaptive strassen’s algorithm for fast matrix multiplication^[3]. SuanShu has been quoted and used in a number of academic works.^[4]^[5]^[6]^[7]

Features

linear algebra
unconstrained and constrained optimization
statistical analysis
ordinary and partial differential equation solvers

License terms

SuanShu is released under the terms of the Apache License 2.0

Examples of usage

The following code shows the object-oriented design of the library (in contrast to the traditional procedural design of many other FORTRAN and C numerical libraries) by a simple example of minimization.

LogGamma logGamma = new LogGamma(); // the log-gamma function
BracketSearchMinimizer solver = new BrentMinimizer(1e-8, 10); // precision, max number of iterations
UnivariateMinimizer.Solution soln = solver.solve(logGamma); // optimization
double x_min = soln.search(0, 5); // bracket = [0, 5]
System.out.println(String.format("f(%f) = %f", x_min, logGamma.evaluate(x_min)));

References

^ Li, Haksun (11 February 2022). Numerical Methods Using Java: For Data Science, Analysis, and Engineering.
^ "Java Numerics: Main". math.nist.gov. Retrieved 2021-03-23.
^ "Fastest Java Matrix Multiplication | NM DEV". NM DEV | Mathematics at Your Fingertips. 2015-08-07. Retrieved 2021-08-02.
^ Möhlmann, Eike (2018). Automatic stability verification via Lyapunov functions: representations, transformations, and practical issues (phd thesis). Universität Oldenburg.
^ Christou, Ioannis T.; Vassilaras, Spyridon (2013-10-01). "A parallel hybrid greedy branch and bound scheme for the maximum distance-2 matching problem". Computers & Operations Research. 40 (10): 2387–2397. doi:10.1016/j.cor.2013.04.009. ISSN 0305-0548.
^ Łukawska, Barbara; Łukawski, Grzegorz; Sapiecha, Krzysztof (2016-10-04). "An implementation of articial advisor for dynamic classication of objects". Annales Universitatis Mariae Curie-Sklodowska, sectio AI – Informatica. 16 (1): 40. doi:10.17951/ai.2016.16.1.40. ISSN 2083-3628.
^ Ansari, Mohd Samar (2013-09-03). Non-Linear Feedback Neural Networks: VLSI Implementations and Applications. Springer. ISBN 978-81-322-1563-9.

[1] Li, Haksun (11 February 2022). Numerical Methods Using Java: For Data Science, Analysis, and Engineering.

[2] "Java Numerics: Main". math.nist.gov. Retrieved 2021-03-23.

[3] "Fastest Java Matrix Multiplication | NM DEV". NM DEV | Mathematics at Your Fingertips. 2015-08-07. Retrieved 2021-08-02.

[4] Möhlmann, Eike (2018). Automatic stability verification via Lyapunov functions: representations, transformations, and practical issues (phd thesis). Universität Oldenburg.

[5] Christou, Ioannis T.; Vassilaras, Spyridon (2013-10-01). "A parallel hybrid greedy branch and bound scheme for the maximum distance-2 matching problem". Computers & Operations Research. 40 (10): 2387–2397. doi:10.1016/j.cor.2013.04.009. ISSN 0305-0548.

[6] Łukawska, Barbara; Łukawski, Grzegorz; Sapiecha, Krzysztof (2016-10-04). "An implementation of articial advisor for dynamic classication of objects". Annales Universitatis Mariae Curie-Sklodowska, sectio AI – Informatica. 16 (1): 40. doi:10.17951/ai.2016.16.1.40. ISSN 2083-3628.

[7] Ansari, Mohd Samar (2013-09-03). Non-Linear Feedback Neural Networks: VLSI Implementations and Applications. Springer. ISBN 978-81-322-1563-9.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

Features

License terms

Examples of usage

See also

References