Mathematica Solution for Environmental Sciences

INDUSTRY SOLUTIONS FOR SCIENCE ENVIRONMENTAL SCIENCES Other Mathematica Solutions » Geosciences » Biological Sciences » Data Analysis and Mining » Other Mathematica Solutions » Whether it's for climate change prediction, alternative energy development, or pollution modeling, the Mathematica environmental sciences solution lets you work easily with any data (including data we build in), apply the most sophisticated computational techniques, and generate fully interactive models that are ideal for publishing or results verification. Powerful computational abilities for large-scale environmental modeling Diffusion of atmospheric pollution—accounting for wind, solar radiation, and chemical reactions between pollutants—using grid computation capabilities Making and deploying tools for analyzing monitored data Examples of fitting forest-growth data and determining parameters for emissions-reduction policies Importing your environmental data and combining it with our built-in data Mapping the yearly average temperature trend in several cities, using built-in weather and geographic data Acquire data, analyze, and share results in one document for easy verification An interactive notebook showing volcano elevations: one source for calculations, slideshows, applications, and websites KEY CAPABILITIES WHY CHOOSE MATHEMATICA WAYS TO USE Mathematica includes thousands of built-in functions for computation, modeling, visualization, development, and deployment » Environmental sciences specific capabilities: Descriptive statistics for univariate and multivariate data, and exploratory analysis techniques for studying air quality or other data » Calculate and present results in one fully interactive file and deploy to the Player family or the web to document and share results, allowing others to verify your parameters » Import data in hundreds of formats, including formats used for environmental monitoring results, such as HDF5 and NetCDF » Combine your data with built-in, curated data including geographic, scientific, economic, and demographic information for environmental planning or monitoring » Quickly compute models involving thousands of equations or large matrices for chemical kinetics and use built-in nonlinear optimization routines to find the best parameters » Powerful symbolic and numeric differential equation solvers for chemical or climate modeling » Use Mathematica's built-in scientific and geographic data for your work Country Data » Includes environmental data for all countries: energy consumption, natural resources, public health statistics, percentage of arable or irrigated land, and more Weather Data » Use current and historical weather data from all standard weather stations worldwide Chemical Data » Assess physical, structural, safety, and other properties of more than 34,000 compounds Easy programmability lets you extend built-in graphing capabilities to create any sort of plot you need » Create interactive tools for data analysis or to easily change parameters for prototyping climate models » Create highly customized, presentation-quality interactive visualizations or graphics for publication, with a large variety of powerful visualization functions » Use Java and .NET linking to communicate with lab equipment connected to a serial or USB port, or with equipment that uses GPIB, VISA, IVI, and more » KEY CAPABILITIES WHY CHOOSE MATHEMATICA WAYS TO USE Compare Mathematica to your current tools. Do they have these advantages? Import experimental data, perform computations, and deliver results in one interactive document rather than working with several applications, making it easy to share data » Competitor note: Excel, R, Stata, and other programs do not offer an integrated document environment Integrated automatic report generation to document tasks you perform in Mathematica and instantly generate reports with graphics, text, and code, making it easy for others to verify your results » Competitor note: Sage, Octave and other freeware do not support automatic report generation Symbolic calculations improve the accuracy and reliability of environmental science models over solely numeric computations Competitor note: R, Stata, Matlab, and other numerical systems do not have integrated symbolic functionality Instantly create interactive modeling or data analysis tools without programming expertise » Powerful symbolic statistical computation and built-in functions for all standard statistical distributions Competitor note: Advanced symbolic computational capabilities are unique to Mathematica Create highly customized, presentation-quality visualizations, including charts, bar charts, scatter plots, and many more » Competitor note: SPSS requires explicit programming for customized charts Sophisticated typesetting for chemical and mathematical equations, standard word processing, and interactive applications in a single document » Competitor note: Unique to Mathematica KEY CAPABILITIES WHY CHOOSE MATHEMATICA WAYS TO USE Model the dispersion of pollutants in the atmosphere with the finite element method Use built-in historical weather data to study environmental changes » Solve complicated chemical kinetic modeling problems to develop fuels from new sources » Create engineering models to optimize production methods of solar panels and use built-in weather data to backtest their reliability Study the chemistry of air pollution to design cleaner cars » Examine satellite data to study deforestation Analyze soil test or atmospheric data to track the spread of contaminants or monitor cleanup efforts ENVIRONMENTAL SCIENCES CASE STUDIES Case Study Breaking Down Biofuels: Eco-friendly Solutions with Mathematica » Finding the Missing Link: Building an Integrated System in Mathematica » Take a Deep Breath... » South Africa's National Disaster Atlas Uses webMathematica Technology to Fight Catastrophic Events » Some Major Organizations Using Mathematica Brookhaven National Laboratory CEA/DAM CNRS Corning Desert Research Institute ENVIRON U.S. Environmental Protection Agency National Renewable Energy Laboratory Oak Ridge National Laboratory RELATED DOCUMENTATION Guides to Mathematica's Environmental Sciences Capabilities Matrix Operations » Equation Solving » Differential Equations » Optimization » Chemical and Biomolecular Data Formats » Scientific and Medical Data Formats » Core Language Overview » MathLink API » Java Interface (J/Link) » Tutorials on Using Mathematica for Environmental Sciences Tasks Density and Contour Plots » Running Mathematica from within an External Program » Differential Equation Solving with `DSolve` » Numerical Calculations » Introduction to Systems of ODEs » Advanced Matrix Operations » Constrained Optimization » In-Depth Information on Mathematica's Environmental Sciences Functions `CountryData` » `ChemicalData` » `NSolve` » `ContourPlot` » `DSolve` » `NDSolve` » `LeastSquares` » More Documentation » OTHER RESOURCES Books Lake Victoria: Ecology, Resources, Environment » Computational Geosciences with Mathematica » Illustrating Evolutionary Computation with Mathematica » More Books » Articles and Presentations An Interactive Algorithm for the Calculation of the Radiological Consequences of a Nuclear Accident in Europe » A Unit Hydrograph Rainfall-Runoff Model using Mathematica » Vulnerability of Northern Prairie Wetlands to Climate Change » An Exploratory Model of the Integrated Energy System and Markets using Mathematica » The Use of a Code-Generating System for the Derivation of the Equations for Wind Turbine Dynamics » More Articles and Presentations » Additional Products Time Series » More Products » GET STARTED WITH MATHEMATICA Watch a Tutorial Screencast Making Interactive Models in Mathematica » New Features in Mathematica 7 » Introduction to Mathematica Graphics » Utilizing Mathematica's Integrated Data » More Screencasts » Attend a Free Online Seminar S10: A Brief Overview of Mathematica » S13: Introduction to Visualization with Mathematica » S21: Working with Data Collections » S24: Working with Imported Data in Mathematica » S25: Image Processing with Mathematica » More Seminars » Enroll in a Course M101: A First Course in Mathematica » M205: Visualization and Dynamic Interactivity » M215: Applied Statistical Analysis » M221: Introduction to Programming in Mathematica » More Courses » USER STORIES Breaking Down Biofuels: Eco-friendly Solutions with Mathematica "I've literally tried to do everything with Mathematica." —Andrew Hull Finding the Missing Link: Building an Integrated System in Mathematica "This is a big advantage to have something in one place where everything works together and where everything is consistent.... You can concentrate on what you want to learn...." —Frank Scherbaum INTERACTIVE ENVIRONMENTAL SCIENCES EXAMPLES Sample Demonstrations Contributed by Users Best Effort Global Warming Trajectories » Fuel Break » Changing Sea Levels » A Forest Growth Curve » Richards Growth Curve » Cellular Automaton Model of Pine Savanna Dynamics in Response to Fire and Hurricanes » View All » Download Free Player Here »

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