cs-optimization-binary-solutions 1.0.1

.NET Framework 4.5.2 This package targets .NET Framework 4.5.2. The package is compatible with this framework or higher. 
dotnet add package cs-optimization-binary-solutions --version 1.0.1                

                    
                

            
NuGet\Install-Package cs-optimization-binary-solutions -Version 1.0.1
This command is intended to be used within the Package Manager Console in Visual Studio, as it uses the NuGet module's version of Install-Package. 
<PackageReference Include="cs-optimization-binary-solutions" Version="1.0.1" />
For projects that support PackageReference, copy this XML node into the project file to reference the package. 
paket add cs-optimization-binary-solutions --version 1.0.1                

                    
                

            
#r "nuget: cs-optimization-binary-solutions, 1.0.1"
#r directive can be used in F# Interactive and Polyglot Notebooks. Copy this into the interactive tool or source code of the script to reference the package. 
// Install cs-optimization-binary-solutions as a Cake Addin
#addin nuget:?package=cs-optimization-binary-solutions&version=1.0.1

// Install cs-optimization-binary-solutions as a Cake Tool
#tool nuget:?package=cs-optimization-binary-solutions&version=1.0.1

cs-optimization-binary-solutions

Local search optimization for binary-coded solutions implemented in C#

Features

The following meta-heuristic algorithms are provided for binary optimization (Optimization in which the solutions are binary-coded):

  • Genetic Algorithm
  • Memetic Algorithm
  • GRASP
  • Multi-start Hill Climbing
  • Tabu Search
  • Variable Neighbhorhood Search
  • Iterated Local Search
  • Random Search

Usage

The code below shows how to use Genetic Algorithm to solve an optimization problem that looks for the binary-coded solution with minimum number of 1 bits:

int popSize = 100;
int dimension = 1000; // solution has 1000 bits
GeneticAlgorithm method = new GeneticAlgorithm(popSize, dimension);
method.MaxIterations = 500;

method.SolutionUpdated += (best_solution, step) =>
{
	Console.WriteLine("Step {0}: Fitness = {1}", step, best_solution.Cost);
};

BinarySolution finalSolution = method.Minimize((solution, constraints) =>
{
	int num1Bits = 0;
	for(int i=0; i < solution.Length; ++i)
	{
		num1Bits += solution[i];
	}
	return num1Bits; // try to minimize the number of 1 bits in the solution
});
Console.WriteLine("final solution: {0}", finalSolution);

The code below shows how to use Memetic Algorithm to solve an optimization problem that looks for the binary-coded solution with minimum number of 1 bits:

int popSize = 100;
int dimension = 1000; // solution has 1000 bits
MemeticAlgorithm method = new MemeticAlgorithm(popSize, dimension);
method.MaxIterations = 10;
method.MaxLocalSearchIterations = 1000;

method.SolutionUpdated += (best_solution, step) =>
{
	Console.WriteLine("Step {0}: Fitness = {1}", step, best_solution.Cost);
};

BinarySolution finalSolution = method.Minimize((solution, constraints) =>
{
	int num1Bits = 0;
	for(int i=0; i < solution.Length; ++i)
	{
		num1Bits += solution[i];
	}
	return num1Bits; // try to minimize the number of 1 bits in the solution
});
Console.WriteLine("final solution: {0}", finalSolution);

The code below shows how to use Stochastic Hill Climber to solve an optimization problem that looks for the binary-coded solution with minimum number of 1 bits:

int dimension = 1000; // solution has 1000 bits
StochasticHillClimber method = new StochasticHillClimber(dimension);
method.MaxIterations = 100;

method.SolutionUpdated += (best_solution, step) =>
{
	Console.WriteLine("Step {0}: Fitness = {1}", step, best_solution.Cost);
};

BinarySolution finalSolution = method.Minimize((solution, constraints) =>
{
	int num1Bits = 0;
	for(int i=0; i < solution.Length; ++i)
	{
		num1Bits += solution[i];
	}
	return num1Bits; // try to minimize the number of 1 bits in the solution
});
Console.WriteLine("final solution: {0}", finalSolution);

The code below shows how to use Iterated Local Search to solve an optimization problem that looks for the binary-coded solution with minimum number of 1 bits:

int dimension = 1000; // solution has 1000 bits
IteratedLocalSearch method = new IteratedLocalSearch(dimension);
method.MaxIterations = 1000;

method.SolutionUpdated += (best_solution, step) =>
{
	Console.WriteLine("Step {0}: Fitness = {1}", step, best_solution.Cost);
};

BinarySolution finalSolution = method.Minimize((solution, constraints) =>
{
	int num1Bits = 0;
	for(int i=0; i < solution.Length; ++i)
	{
		num1Bits += solution[i];
	}
	return num1Bits; // try to minimize the number of 1 bits in the solution
});
Console.WriteLine("final solution: {0}", finalSolution);
Product Compatible and additional computed target framework versions.
.NET Framework net452 is compatible.  net46 was computed.  net461 was computed.  net462 was computed.  net463 was computed.  net47 was computed.  net471 was computed.  net472 was computed.  net48 was computed.  net481 was computed. 
Compatible target framework(s)
Included target framework(s) (in package)
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This package has no dependencies.

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Version Downloads Last updated
1.0.1 1,201 11/4/2017

Numerical Optimization Package in which solutions are binary-coded. Based on .NET 4.5.2