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Computational fluid dynamics (CFD) is a branch of fluid mechanics that uses numerical analysis and data structures to solve and analyze problems that involve fluid flows are used to perform the calculations required to simulate the interaction of liquids and gases with surfaces defined by boundary conditions.
Scope of the Report:
CFD facilitates the researchers to quantify and predict effects of simultaneous flow of heat, mass transfer, phase change, chemical reaction, mechanical movements, and stresses in displacement of solids.
The global Computational Fluid Dynamics market is valued at xx million USD in 2017 and is expected to reach xx million USD by the end of 2023, growing at a CAGR of xx% between 2017 and 2023.
The Asia-Pacific will occupy for more market share in following years, especially in China, also fast growing India and Southeast Asia regions.
North America, especially The United States, will still play an important role which cannot be ignored. Any changes from United States might affect the development trend of Computational Fluid Dynamics.
Europe also play important roles in global market, with market size of xx million USD in 2017 and will be xx million USD in 2023, with a CAGR of xx%.
This report studies the Computational Fluid Dynamics market status and outlook of Global and major regions, from angles of players, countries, product types and end industries; this report analyzes the top players in global market, and splits the Computational Fluid Dynamics market by product type and applications/end industries.
Market Segment by Companies, this report covers
ANSYS
CD-adapco
Dassault Systemes
Mentor Graphics
Exa
Altair
Autodesk
COMSOL
CEI
ESI Group
MSC Software
Market Segment by Regions, regional analysis covers
North America (United States, Canada and Mexico)
Europe (Germany, France, UK, Russia and Italy)
Asia-Pacific (China, Japan, Korea, India and Southeast Asia)
South America (Brazil, Argentina, Colombia)
Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa)
Market Segment by Type, covers
Numerical Analysis
Data Structures
Market Segment by Applications, can be divided into
Aerospace & Defense
Automotive
Electrical & Electronics
Industrial Machinery
Material and Chemical Processing
Energy Industry
The base year for the study has been considered 2019, historic year 2014 and 2018, the forecast period considered is from 2020 to 2027. The regions analyzed for the market include North America, Europe, South America, Asia Pacific, and Middle East and Africa. These regions are further analyzed at the country-level. The study also includes attractiveness analysis of type, application and regions which are benchmarked based on their market size, growth rate and attractiveness in terms of present and future opportunity for understanding the future growth of the market.
Market is segmented on the basis:
The report offers in-depth analysis of driving factors, opportunities, restraints, and challenges for gaining the key insight of the market. The report emphasizes on all the key trends that play a vital role in the enlargement of the market from 2019 to 2026.
The report provides company profile of the key players operating in the market and a comparative analysis based on their business overviews industry offering, segment market share, regional presence, business strategies, innovations, mergers & acquisitions, recent developments, joint venture, collaborations, partnerships, SWOT analysis, and key financial information.
Table of Contents
1 Computational Fluid Dynamics Market Overview
1.1 Product Overview and Scope of Computational Fluid Dynamics
1.2 Classification of Computational Fluid Dynamics by Types
1.2.1 Global Computational Fluid Dynamics Revenue Comparison by Types (2017-2023)
1.2.2 Global Computational Fluid Dynamics Revenue Market Share by Types in 2017
1.2.3 Numerical Analysis
1.2.4 Data Structures
1.3 Global Computational Fluid Dynamics Market by Application
1.3.1 Global Computational Fluid Dynamics Market Size and Market Share Comparison by Applications (2013-2023)
1.3.2 Aerospace & Defense
1.3.3 Automotive
1.3.4 Electrical & Electronics
1.3.5 Industrial Machinery
1.3.6 Material and Chemical Processing
1.3.7 Energy Industry
1.4 Global Computational Fluid Dynamics Market by Regions
1.4.1 Global Computational Fluid Dynamics Market Size (Million USD) Comparison by Regions (2013-2023)
1.4.1 North America (USA, Canada and Mexico) Computational Fluid Dynamics Status and Prospect (2013-2023)
1.4.2 Europe (Germany, France, UK, Russia and Italy) Computational Fluid Dynamics Status and Prospect (2013-2023)
1.4.3 Asia-Pacific (China, Japan, Korea, India and Southeast Asia) Computational Fluid Dynamics Status and Prospect (2013-2023)
1.4.4 South America (Brazil, Argentina, Colombia) Computational Fluid Dynamics Status and Prospect (2013-2023)
1.4.5 Middle East and Africa (Saudi Arabia, UAE, Egypt, Nigeria and South Africa) Computational Fluid Dynamics Status and Prospect (2013-2023)
1.5 Global Market Size of Computational Fluid Dynamics (2013-2023)
2 Manufacturers Profiles
2.1 ANSYS
2.1.1 Business Overview
2.1.2 Computational Fluid Dynamics Type and Applications
2.1.2.1 Product A
2.1.2.2 Product B
2.1.3 ANSYS Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.2 CD-adapco
2.2.1 Business Overview
2.2.2 Computational Fluid Dynamics Type and Applications
2.2.2.1 Product A
2.2.2.2 Product B
2.2.3 CD-adapco Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.3 Dassault Systemes
2.3.1 Business Overview
2.3.2 Computational Fluid Dynamics Type and Applications
2.3.2.1 Product A
2.3.2.2 Product B
2.3.3 Dassault Systemes Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.4 Mentor Graphics
2.4.1 Business Overview
2.4.2 Computational Fluid Dynamics Type and Applications
2.4.2.1 Product A
2.4.2.2 Product B
2.4.3 Mentor Graphics Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.5 Exa
2.5.1 Business Overview
2.5.2 Computational Fluid Dynamics Type and Applications
2.5.2.1 Product A
2.5.2.2 Product B
2.5.3 Exa Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.6 Altair
2.6.1 Business Overview
2.6.2 Computational Fluid Dynamics Type and Applications
2.6.2.1 Product A
2.6.2.2 Product B
2.6.3 Altair Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.7 Autodesk
2.7.1 Business Overview
2.7.2 Computational Fluid Dynamics Type and Applications
2.7.2.1 Product A
2.7.2.2 Product B
2.7.3 Autodesk Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.8 COMSOL
2.8.1 Business Overview
2.8.2 Computational Fluid Dynamics Type and Applications
2.8.2.1 Product A
2.8.2.2 Product B
2.8.3 COMSOL Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.9 CEI
2.9.1 Business Overview
2.9.2 Computational Fluid Dynamics Type and Applications
2.9.2.1 Product A
2.9.2.2 Product B
2.9.3 CEI Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.10 ESI Group
2.10.1 Business Overview
2.10.2 Computational Fluid Dynamics Type and Applications
2.10.2.1 Product A
2.10.2.2 Product B
2.10.3 ESI Group Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
2.11 MSC Software
2.11.1 Business Overview
2.11.2 Computational Fluid Dynamics Type and Applications
2.11.2.1 Product A
2.11.2.2 Product B
2.11.3 MSC Software Computational Fluid Dynamics Revenue, Gross Margin and Market Share (2016-2017)
3 Global Computational Fluid Dynamics Market Competition, by Players
3.1 Global Computational Fluid Dynamics Revenue and Share by Players (2013-2018)
3.2 Market Concentration Rate
3.2.1 Top 5 Computational Fluid Dynamics Players Market Share
3.2.2 Top 10 Computational Fluid Dynamics Players Market Share
3.3 Market Competition Trend
4 Global Computational Fluid Dynamics Market Size by Regions
4.1 Global Computational Fluid Dynamics Revenue and Market Share by Regions
4.2 North America Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
4.3 Europe Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
4.4 Asia-Pacific Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
4.5 South America Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
4.6 Middle East and Africa Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
5 North America Computational Fluid Dynamics Revenue by Countries
5.1 North America Computational Fluid Dynamics Revenue by Countries (2013-2018)
5.2 USA Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
5.3 Canada Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
5.4 Mexico Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
6 Europe Computational Fluid Dynamics Revenue by Countries
6.1 Europe Computational Fluid Dynamics Revenue by Countries (2013-2018)
6.2 Germany Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
6.3 UK Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
6.4 France Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
6.5 Russia Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
6.6 Italy Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
7 Asia-Pacific Computational Fluid Dynamics Revenue by Countries
7.1 Asia-Pacific Computational Fluid Dynamics Revenue by Countries (2013-2018)
7.2 China Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
7.3 Japan Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
7.4 Korea Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
7.5 India Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
7.6 Southeast Asia Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
8 South America Computational Fluid Dynamics Revenue by Countries
8.1 South America Computational Fluid Dynamics Revenue by Countries (2013-2018)
8.2 Brazil Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
8.3 Argentina Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
8.4 Colombia Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
9 Middle East and Africa Revenue Computational Fluid Dynamics by Countries
9.1 Middle East and Africa Computational Fluid Dynamics Revenue by Countries (2013-2018)
9.2 Saudi Arabia Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
9.3 UAE Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
9.4 Egypt Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
9.5 Nigeria Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
9.6 South Africa Computational Fluid Dynamics Revenue and Growth Rate (2013-2018)
10 Global Computational Fluid Dynamics Market Segment by Type
10.1 Global Computational Fluid Dynamics Revenue and Market Share by Type (2013-2018)
10.2 Global Computational Fluid Dynamics Market Forecast by Type (2018-2023)
10.3 Numerical Analysis Revenue Growth Rate (2013-2023)
10.4 Data Structures Revenue Growth Rate (2013-2023)
11 Global Computational Fluid Dynamics Market Segment by Application
11.1 Global Computational Fluid Dynamics Revenue Market Share by Application (2013-2018)
11.2 Computational Fluid Dynamics Market Forecast by Application (2018-2023)
11.3 Aerospace & Defense Revenue Growth (2013-2018)
11.4 Automotive Revenue Growth (2013-2018)
11.5 Electrical & Electronics Revenue Growth (2013-2018)
11.6 Industrial Machinery Revenue Growth (2013-2018)
11.7 Material and Chemical Processing Revenue Growth (2013-2018)
11.8 Energy Industry Revenue Growth (2013-2018)
12 Global Computational Fluid Dynamics Market Size Forecast (2018-2023)
12.1 Global Computational Fluid Dynamics Market Size Forecast (2018-2023)
12.2 Global Computational Fluid Dynamics Market Forecast by Regions (2018-2023)
12.3 North America Computational Fluid Dynamics Revenue Market Forecast (2018-2023)
12.4 Europe Computational Fluid Dynamics Revenue Market Forecast (2018-2023)
12.5 Asia-Pacific Computational Fluid Dynamics Revenue Market Forecast (2018-2023)
12.6 South America Computational Fluid Dynamics Revenue Market Forecast (2018-2023)
12.7 Middle East and Africa Computational Fluid Dynamics Revenue Market Forecast (2018-2023)
13 Research Findings and Conclusion
14 Appendix
14.1 Methodology
14.2 Data Source
List of Tables and Figures
Figure Computational Fluid Dynamics Picture
Table Product Specifications of Computational Fluid Dynamics
Table Global Computational Fluid Dynamics and Revenue (Million USD)
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