High Bandwidth Memory Market: Segmented: By Product (GPU, CPU, APU, FPGA, ASIC); By Application (Graphics, High-Performance Computing, Networking, And Data Centers); , And Region – Global Analysis of Market Size, Share & Trends For 2019–2020 And Forecasts

High Bandwidth Memory Market: Segmented: By Product (GPU, CPU, APU, FPGA, ASIC); By Application (Graphics, High-Performance Computing, Networking, And Data Centers); , And Region – Global Analysis of Market Size, Share & Trends For 2019–2020 And Forecasts To 2031

High Bandwidth Memory Market to surpass USD 4.9 billion by 2031 from USD 1.8 billion in 2021 at a CAGR of 32.9% in the coming years, i.e., 2021-31. 

Product Overview
High bandwidth memory is a high-performance random access memory interface for 3D stacked dynamic random access memory, as well as high-performance graphics accelerators and network devices. TSV-based stacked dynamic random access memory uses a hybrid memory cube as a high-performance random access memory interface. Due to their tiny form size, high bandwidth, and low cost, hybrid memory cubes, and high bandwidth are a viable solution for standard DRAM (dynamic random-access memory).

Market Highlights
High Bandwidth Memory market is expected to project a notable CAGR of 32.9% in 2031.

The growing demand for memories with high bandwidth, low power consumption, and great scalability is driving the development of various 3D-stacked memories. With the rise of Big Data, the Internet of Things (IoT), and other data-intensive applications, there is an increased demand for technology that can process and store more data efficiently.

Global High Bandwidth Memory: Segments
APU segment to grow with the highest CAGR during 2021-31

Global High Bandwidth Memory market is segmented by product into GPU, CPU, APU, FPGA, ASIC During the forecast period; the market for APUs is predicted to develop at the fastest rate. HBM-based APUs are a new AMD (US) innovation designed to fulfill the demands of high-performance computing. On a single SoC, APUs combines GPU and CPU capabilities. By removing connections between chips, APUs' overall energy efficiency improves even more. Graphics programmes can also be run on APUs. Additionally, AMD (US), the world's largest APU manufacturer, presented an APU with integrated HBM and stacked non-volatile memory cells. This will help to accelerate the use of APUs in computing applications.

Graphics segment to grow with the highest CAGR during 2021-31

Global High Bandwidth Memory market is segmented by application into Graphics, High-performance Computing, Networking, and Data Centers. During the projection period, the HMC and HBM market for graphics applications is predicted to develop at the fastest CAGR. The vast majority of HBM-enabled products on the market are GPUs. HBM was first used in graphics cards for graphics applications. For example, AMD (US) and SK Hynix (South Korea) created HBM technology for usage in GPUs. APUs, in addition to GPUs, have been brought to the market and are increasingly used for gaming applications. The growing use of HMC and HBM in gaming is partly due to the need to process large numbers of pixels for larger screens and to enable greater compute rates for better stability in high-end gaming.

Market Dynamics
Drivers
Great scalability

The growing demand for memories with high bandwidth, low power consumption, and great scalability is driving the development of various 3D-stacked memories. In the network system, there is also a large demand for high-efficiency and high-performance memory for data packet buffering, data packet processing, and storage applications above 100 Gbps. HMC and HBM, which have a bandwidth of more than 100 Gbps, could be a viable DRAM replacement as they reach comparable speeds while consuming far less power. Furthermore, these technologies are constantly improving on the market.

Increasing big data

The Internet of Things has resulted in a significant amount of data being generated. Furthermore, Big Data applications such as business analytics, scientific computing, financial transactions, social networking, and search engines are fast growing in popularity. To attain high processing throughput, all of these applications handle enormous datasets and require high-performance IT infrastructures. According to information presented at the National Association of Software and Services Companies.

Restraint
Hindrance caused by thermal effect

HMC and HBM are DRAM stacks with micro bumps and TSVs connecting them internally to TSVs and externally to one or more chips. Even though these technologies have various advantages, manufacturers face a significant difficulty due to thermal concerns produced by the high level of integration and their impact on the overall module. These technologies provide extremely dense multi-level integration per unit footprint, posing thermal management problems.

Global High Bandwidth Memory: Key Players       
Micron
Company Overview, Business Strategy, Key Product Offerings, Financial Performance, Key Performance Indicators, Risk Analysis, Recent Development, Regional Presence, SWOT Analysis

Samsung
SK Hynix
Advanced Micro Devices
Intel
Xilinx
Fujitsu
Nvidia
IBM
Open-Silicon
Cadence
Marvell
Other Prominent Players
Global High Bandwidth Memory: Regions
Global High Bandwidth Memory market is segmented based on regional analysis into five major regions: North America, Latin America, Europe, Asia Pacific and the Middle East and Africa. North America accounted for XX percent of the market in 2021, and the region is expected to grow at a CAGR of XX percent over the next decade. High-performance computing (HPC) applications that require high-bandwidth memory solutions for quick data processing are driving the adoption of HMC and HBM memories in North America. The expanding market for AI, machine learning, and cloud computing is driving up demand for HPC in North America. Furthermore, key HPC-based CPU and processor manufacturers, such as Intel, are headquartered in North American countries. Other major tech firms with US headquarters, such as Google, Amazon, and Microsoft, have fueled demand for high-performance CPUs in servers and supercomputers.

Global High Bandwidth Memory is further segmented by region into:

North America Market Size, Share, Trends, Opportunities, Y-o-Y Growth, CAGR – United States and Canada
Latin America Market Size, Share, Trends, Opportunities, Y-o-Y Growth, CAGR – Mexico, Argentina, Brazil and Rest of Latin America
Europe Market Size, Share, Trends, Opportunities, Y-o-Y Growth, CAGR – United Kingdom, France, Germany, Italy, Spain, Belgium, Hungary, Luxembourg, Netherlands, Poland, NORDIC, Russia, Turkey and ,Rest of Europe
Asia Pacific Market Size, Share, Trends, Opportunities, Y-o-Y Growth, CAGR – India, China, South Korea, Japan, Malaysia, Indonesia, New Zealand, Australia and Rest of APAC
Middle East and Africa Market Size, Share, Trends, Opportunities, Y-o-Y Growth, CAGR – North Africa, Israel, GCC, South Africa and Rest of MENA
Global High Bandwidth Memory report also contains analysis on:
High Bandwidth Memory Segments:   

By application 
Graphics
High-performance Computing
Networking
Data Centers
By product
GPU
CPU
APU
FPGA
ASIC 
High Bandwidth Memory Dynamics
High Bandwidth Memory Size
Supply & Demand
Current Trends/Issues/Challenges
Competition & Companies Involved in the Market
Value Chain of the Market
Market Drivers and Restraints
High Bandwidth Memory Market Report Scope and Segmentation
Report Attribute
Details

Market size value in 2021 USD 1.8 billion
Revenue forecast in 2031 USD 4.9  billion
Growth Rate
CAGR of 32.9% from 2021 to 2031

Base year for estimation 2020
Quantitative units Revenue in USD million and CAGR from 2021 to 2031
Report coverage
Revenue forecast, company ranking, competitive landscape, growth factors, and trends

Segments covered Product, Application and Region
Regional scope North America, Europe, Asia Pacific, Latin America, Middle East & Africa (MEA)
Key companies profiled Samsung (South Korea), Micron (US), SK Hynix (South Korea), Intel (US), Advanced Micro Devices (AMD) (US), Xilinx (US), Fujitsu (Japan), NVIDIA (US), IBM (US), and Open-Silicon, Inc.(US), and Other Prominent Players .


1. Executive Summary
2. Global High Bandwidth Memory Market
2.1. Product Overview
2.2. Market Definition
2.3. Segmentation
2.4. Assumptions and Acronyms
3. Research Methodology
3.1. Research Objectives
3.2. Primary Research
3.3. Secondary Research
3.4. Forecast Model
3.5. Market Size Estimation
4. Average Pricing Analysis
5. Macro-Economic Indicators
6. Market Dynamics
6.1. Growth Drivers
6.2. Restraints
6.3. Opportunity
6.4. Trends
7. Correlation & Regression Analysis
7.1. Correlation Matrix
7.2. Regression Matrix
8. Recent Development, Policies & Regulatory Landscape
9. Risk Analysis
9.1. Demand Risk Analysis
9.2. Supply Risk Analysis
10. Global High Bandwidth Memory Market Analysis
10.1. Porters Five Forces
10.1.1. Threat of New Entrants
10.1.2. Bargaining Power of Suppliers
10.1.3. Threat of Substitutes
10.1.4. Rivalry
10.2. PEST Analysis
10.2.1. Political
10.2.2. Economic
10.2.3. Social
10.2.4. Technological
11. Global High Bandwidth Memory Market
11.1. Market Size & forecast, 2020A-2031F
11.1.1. By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
11.1.2. By Volume (Million Units) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12. Global High Bandwidth Memory Market: Market Segmentation
12.1. By Regions
12.1.1. North America:(U.S. and Canada), By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.1.2. Latin America: (Brazil, Mexico, Argentina, Rest of Latin America), By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.1.3. Europe: (Germany, UK, France, Italy, Spain, BENELUX, NORDIC, Hungary, Poland, Turkey, Russia, Rest of Europe), By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.1.4. Asia-Pacific: (China, India, Japan, South Korea, Indonesia, Malaysia, Australia, New Zealand, Rest of Asia Pacific), By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.1.5. Middle East and Africa: (Israel, GCC, North Africa, South Africa, Rest of Middle East and Africa), By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.2. By Application: Market Share (2020-2031F)
12.2.1. Graphics, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.2.2. High-performance Computing, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.2.3. Networking, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.2.4. Data Centers, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.3. By Product: Market Share (2020-2031F)
12.3.1. GPU, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.3.2. CPU, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.3.3. APU, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.3.4. FPGA, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
12.3.5. ASIC, By Value (USD Million) 2020-2031F; Y-o-Y Growth (%) 2021-2031F
13 Company Profile
13.1. Micron
13.1.1. Company Overview
13.1.2. Company Total Revenue (Financials)
13.1.3. Market Potential
13.1.4. Global Presence
13.1.5. Key Performance Indicators
13.1.6. SWOT Analysis
13.1.7. Product Launch
13.2. Samsung
13.3. SK Hynix
13.4. Advanced Micro Devices
13.5. Intel
13.6. Xilinx
13.7. Fujitsu
13.8. Nvidia
13.9. IBM
13.10. Open-Silicon
13.11. Cadence
13.12. Marvell
13.13. Other Prominent Players
14 Consultant Recommendation
**The above given segmentations and companies could be subjected to further modification based on in-depth feasibility studies conducted for the final deliverable.

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