Artificial Intelligence
Global Defense Robotics Market to Reach $22.4 Billion by 2026
New York, Oct. 27, 2021 (GLOBE NEWSWIRE) — Reportlinker.com announces the release of the report “Global Defense Robotics Industry” – https://www.reportlinker.com/p05442633/?utm_source=GNW
While the interest towards defense robotics remained strong among governments of leading countries since early 20th century, wider rollout of such systems materialized only during the past two decades. Thanks to full-fledged efforts from the governments of the US, Israel, the UK, France and Russia, defense robotics have achieved significant progression from experimental, remote-operated surveillance machines to autonomous technologies capable of executing combat operations. A primary factor steering momentum in the defense robotics domain is the reduced need for human involvement during military operations and subsequently reduced casualties in combat operations. Being mechanical systems powered by digital technologies, defense robotics can penetrate into enemy territories in stealth mode and independently execute given task, thus potentially minimizing casualties that usually occur in conventional manned missions. Further, these advanced systems come with unique attributes such as fatigueless functioning, high precision, support for any type of terrain, continued functioning despite damaging bomb/weapon attacks, and ability to fit into spaces not possible with mechanical systems or humans, which fully recommend their deployment in military applications. Robotics, when inducted into defense forces, seamlessly improve operational performance, efficiency and efficacy of troops in ground, aerial and maritime operations.
Defense robotics are utilized in various forms including unmanned aerial vehicles (UAVs), unmanned marine vehicles (UMVs) and unmanned ground vehicles (UGVs). UAVs, the pilot-less aircraft, constitute the most widely used form of defense robotics. The US has been a pioneer in development of military UAVs, and currently holds a large fleet of UAVs supplementing its military operations in Afghanistan, Iraq & Syria, and other parts of the world. Similarly, UMVs are mostly made available in the form of USVs (or Unmanned Surface Vessels) and UUVs (or Unmanned Underwater Vehicles) and extend superior capabilities to naval forces in maritime operations. On the other hand, UGVs are ground robots designed with wheels or tracks mainly to supplement the on-foot troops in harsh conditions. Whichever robot deployed the purpose remains the same, i.e., supplementing or replacing the personnel in reconnaissance, combat, logistics and other military tasks, while bestowing the warfighter with greater capabilities in battlefield operations.
Amid the COVID-19 crisis, the global market for Defense Robotics estimated at US$13.2 Billion in the year 2020, is projected to reach a revised size of US$22.4 Billion by 2026, growing at a CAGR of 9.5% over the analysis period. Human Operated , one of the segments analyzed in the report, is projected to grow at a 9.3% CAGR to reach US$15.1 Billion by the end of the analysis period. After a thorough analysis of the business implications of the pandemic and its induced economic crisis, growth in the Autonomous segment is readjusted to a revised 9.9% CAGR for the next 7-year period. This segment currently accounts for a 38.6% share of the global Defense Robotics market.
World market for defense robotics, despite its visible exposure to ongoing COVID-19 crisis, exhibited a moderate level of resilience, as governments continued to maintain or increase their defense and homeland security budgets. Militaries hold a pivotal role in protecting national interests and stay firm for their operations irrespective of consequences. The role of militaries goes beyond safeguarding borders and thwarting invasion attempts to other emergency scenarios like floods, natural disasters and terrorist activity. The COVID-19 health emergency highlighted the significant of militaries and enabled them to assume a central role in the fight against the COVID-19 virus that has left scores of people infected globally. However, the pandemic has also thrown serious challenges for the defense & military sector by disrupting routine operations. Defense robotics markets continued to display relative stability in 2020. Robots have gained importance amid the pandemic for current and future combat, and military actions. In countries such as Russia, while the pandemic led to imposition of certain limitations on the concepts of operations (CONOPS), and tactics, techniques and procedures (TTPs), it had a moderated impact on armed forces training and fighting. The military is moving towards advanced unmanned weapons development.
The U.S. Market is Estimated at $5.3 Billion in 2021, While China is Forecast to Reach $4.5 Billion by 2026
The Defense Robotics market in the U.S. is estimated at US$5.3 Billion in the year 2021. The country currently accounts for a 38.69% share in the global market. China, the world second largest economy, is forecast to reach an estimated market size of US$4.5 Billion in the year 2026 trailing a CAGR of 12.1% through the analysis period. Among the other noteworthy geographic markets are Japan and Canada, each forecast to grow at 7.2% and 7.8% respectively over the analysis period. Within Europe, Germany is forecast to grow at approximately 7.5% CAGR while Rest of European market (as defined in the study) will reach US$5.1 Billion by the close of the analysis period.
In the coming years, demand for defense robotics will continue to expand at a faster pace with a number of factors contributing to increased adoption of these advanced technologies by militaries around the world. Rising emphasis on robotic solutions in command, control, communications and computers (C4); intelligence, surveillance & reconnaissance (ISR); and battlefield combat operations are consistently fuelling momentum in the defense robotics space. At the same time, growing concerns over rising human casualties in military operations and sustained focus on reducing warfield deaths through advanced strategies are creating strong business case for military robotics. Defense robotics market is sensing large-scale opportunities through ongoing expansion in global defense spending and drive towards military modernization programs among governments, worldwide. On the other hand, progressive improvements in underlying technologies and functional scope of robotic systems are paving way for wider proliferation of defense robotics.
Increasing number of nations are making investments on robotic solutions on the back of growing terrorist and border encroachment activities. About 90 countries have already deployed defense robots in military operations in one form or the other. Future success of defense robotics market would be directed by progressive advancements in sensing technology, computer programming, communication capabilities, and material science, which would help defense robotics to refine their functionality, performance, efficiency and effectiveness to attract wider audience. Advancements in key parameters such as integration, interoperability, commonality and affordability, and full-scale warfield readiness would also play important role in global adoption of defense robotics. With such robots projected to be the ultimate weapons in the future battleground, military bodies around the world are making heavy investments in research and development of weapon systems that are increasingly automated. However, automated weapons require human intervention in the form of inputs at certain points to avoid targets within areas of restricted fire as per the laws of the Geneva Conventions. This limitation prevents automated weapons from being fully autonomous.
By Type, Airborne Segment to Reach $15.2 Billion by 2026
Global market for Airborne (Type) segment is estimated at US$8.9 Billion in 2020, and is projected to reach US$15.2 Billion by 2026 reflecting a compounded annual growth rate of 9.6% over the analysis period. The United States constitutes the largest regional market for Airborne segment, accounting for 40.2% of the global sales in 2020. China is poised to register the fastest compounded annual growth rate of 12.3% over the analysis period, to reach US$3.3 Billion by the end of the analysis period.
Select Competitors (Total 110 Featured)
- AeroVironment Inc.
- BAE Systems plc
- Boeing Company
- Boston Dynamics
- Clearpath Robotics Inc.
- Elbit Systems Ltd.
- Endeavor Robotics
- General Atomics
- General Dynamics Corporation
- Israel Aerospace Industries (IAI)
- Lockheed Martin Corporation
- Northrop Grumman Corporation
- Oceaneering International Inc.
- QinetiQ Group plc
- Saab AB
- Textron Inc.
- Thales Group
Read the full report: https://www.reportlinker.com/p05442633/?utm_source=GNW
I. METHODOLOGY
II. EXECUTIVE SUMMARY
1. MARKET OVERVIEW
Impact of Covid-19 and a Looming Global Recession
2020: A Year of Disruption & Transformation
As the Race between the Virus & Vaccines Intensifies, Where is
the World Economy Headed in 2021?
EXHIBIT 1: World Economic Growth Projections (Real GDP, Annual
% Change) for 2020 through 2022
Defense Robotics Exhibits Moderate Level of Resilience
COVID-19-Led Profound Changes in Relation with Technology
Pivots Incorporation of Unmanned Military Systems
Defense Spending Levels Influence Market Growth
Global Defense Spending in 2020
EXHIBIT 2: Defense Spending Trends Set Demand Dynamics for
Defense Robotics: Military Expenditure Worldwide in US$
Billion for the Years 2010 through 2020
EXHIBIT 3: Leading Countries Ranked by Defense Budgets in US$
Billion for 2020
EXHIBIT 4: Leading Countries Ranked by Defense Budgets in US$
Billion for 2020
Armed Forces Stay on Course to Hone Military Robots for Combats
despite COVID-19
Robots: An Introductory Prelude
EXHIBIT 5: Global Robots Market by End-Use Sector (in %): 2020
Defense Robotics: The Unmanned Systems for Military Applications
Classification of Defense Robots
Major Applications
Developing Regions: Hot Spots for Future Growth
Market Outlook
Myriad Benefits Offered Enhance Market Prospects
Regional Overview
The US: Key Revenue Contributor
New Robotic Equipment Developments for the US Military
US Funding Requests for UAV Programs for Financial Year 2022
The U.S. Navy Emphasizes Distributed Fleet Architecture
DoD Funding in FY2021 Defense Budget for Unmanned Systems
Europe
UK
Germany
Russia: Increasing Focus on AI-Equipped Military Robots
Developing Regions: Hot Spots for Future Growth
China: A High Potential Market for Defense Robotics
New R&D Projects to Drive Future Growth
List of Military UACVs & UAVs in China
India
India to Procure US-made Predator Drones
Competitive Scenario
Recent Market Activity
2. FOCUS ON SELECT PLAYERS
3. MARKET TRENDS & DRIVERS
Ever-Hostile Geopolitical Scenario & Relentless Quest for
Military Supremacy to Sustain Spending on Military UAVs
EXHIBIT 6: Military Expenditure as a % of GDP in Select
Countries: 2020
Rapidly Evolving Role of UAVs in Border Security Programs Bodes
Well
Increase in Global Terrorism & the Ensuing Growing Security
Concerns to Drive UAV Deployments
EXHIBIT 7: Number of Terrorist Attacks Worldwide for the Period
2011-2019
EXHIBIT 8: Continued Threat of Terrorism Drives the Focus on
Surveillance as Counterterrorism Response: Global Number of
Fatalities Due to Terrorist Attacks: 2012-2019
Unmanned Aerial Vehicles (UAVs) Drive Momentum in Defense
Robotics Market
EXHIBIT 9: Global Aerial Drone Market by Application (2020):
Percentage Breakdown of Dollar Spending for Civilian and
Defense Sector
MALE & HALE UAVs Suffice Military Needs in Long-Range Tactical
Missions
Unmanned Combat Aerial Vehicles (UCAV): Strong Potential Ahead
US Army Prepares to Conduct Soldier Assessment of RCV
Prototypes in 2022
Autonomous, Smart Military Robots Set to Operate along Real
Warfighters
Killer Robots: The Risks
Unmanned Ground Vehicles (UGVs) Enable Seamless Efficiency in
Ground Operations
Robotic Arms Enhance the Functionality of UGVs
New Line of Ground Robots to Widen Market Prospects of UGVs
Unmanned Marine Vehicles (UMVs) Gain Critical Interest in
Maritime Operations
USVs Seek Bigger Role in Maritime Operations
New Capabilities for Diverse Missions Drive USV Adoption
UUVs Make Steady Progress
EXHIBIT 10: Global ROVs Market by Application (2021):
Percentage Breakdown of Dollar Spending for Military, Oil &
Gas and Other Offshore Applications, and Research
Solar Powered UAV Elicit Increasing Interest Worldwide
Artificial Intelligence (AI) Steps In to Add Next Generation
Capabilities
EXHIBIT 11: AI?s Growing Prominence in Military Applications
Boosts Opportunities: Global AI in Military Market (In US$
Billion) for the Years 2019, 2021, 2023, 202 5 & 2027
ML and AI Facilitate Autonomy of Unmanned Vehicles
Use of Robots for Reconnaissance Operations Gains Momentum as
Age of Connected Battlefield & Network Centric Warfare
Strategies Make C4ISR the Backbone of Modern Military
Operations
Rise in Integration of Weapons Systems into Robots
AI Application in Weapon Systems Raises Ethical Questions
AUV Drive Growth in UUV Segment
EXHIBIT 12: Global AUVs Market by Application (2021):
Percentage Breakdown of Dollar Spending for Commercial,
Military and Research
Drone Swarm Technology Gains Pace
Recent Developments in Defense Robotics Research
US Army Pushes for Stronger Divisions, Smaller Brigades, and
More Robots
4. GLOBAL MARKET PERSPECTIVE
Table 1: World Current & Future Analysis for Defense Robotics
by Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2020 through 2027 and
% CAGR
Table 2: World Historic Review for Defense Robotics by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2016 through 2019 and
% CAGR
Table 3: World 11-Year Perspective for Defense Robotics by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World Markets for Years 2016, 2021 & 2027
Table 4: World Current & Future Analysis for Human Operated by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2020 through 2027 and
% CAGR
Table 5: World Historic Review for Human Operated by Geographic
Region – USA, Canada, Japan, China, Europe, Asia-Pacific and
Rest of World Markets – Independent Analysis of Annual Sales in
US$ Million for Years 2016 through 2019 and % CAGR
Table 6: World 11-Year Perspective for Human Operated by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2016, 2021 & 2027
Table 7: World Current & Future Analysis for Autonomous by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2020 through 2027 and
% CAGR
Table 8: World Historic Review for Autonomous by Geographic
Region – USA, Canada, Japan, China, Europe, Asia-Pacific and
Rest of World Markets – Independent Analysis of Annual Sales in
US$ Million for Years 2016 through 2019 and % CAGR
Table 9: World 11-Year Perspective for Autonomous by Geographic
Region – Percentage Breakdown of Value Sales for USA, Canada,
Japan, China, Europe, Asia-Pacific and Rest of World for Years
2016, 2021 & 2027
Table 10: World Current & Future Analysis for Airborne by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2020 through 2027 and
% CAGR
Table 11: World Historic Review for Airborne by Geographic
Region – USA, Canada, Japan, China, Europe, Asia-Pacific and
Rest of World Markets – Independent Analysis of Annual Sales in
US$ Million for Years 2016 through 2019 and % CAGR
Table 12: World 11-Year Perspective for Airborne by Geographic
Region – Percentage Breakdown of Value Sales for USA, Canada,
Japan, China, Europe, Asia-Pacific and Rest of World for Years
2016, 2021 & 2027
Table 13: World Current & Future Analysis for Marine by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2020 through 2027 and
% CAGR
Table 14: World Historic Review for Marine by Geographic Region –
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World Markets – Independent Analysis of Annual Sales in US$
Million for Years 2016 through 2019 and % CAGR
Table 15: World 11-Year Perspective for Marine by Geographic
Region – Percentage Breakdown of Value Sales for USA, Canada,
Japan, China, Europe, Asia-Pacific and Rest of World for Years
2016, 2021 & 2027
Table 16: World Current & Future Analysis for Land by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2020 through 2027 and
% CAGR
Table 17: World Historic Review for Land by Geographic Region –
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World Markets – Independent Analysis of Annual Sales in US$
Million for Years 2016 through 2019 and % CAGR
Table 18: World 11-Year Perspective for Land by Geographic
Region – Percentage Breakdown of Value Sales for USA, Canada,
Japan, China, Europe, Asia-Pacific and Rest of World for Years
2016, 2021 & 2027
III. MARKET ANALYSIS
UNITED STATES
Table 19: USA Current & Future Analysis for Defense Robotics by
Mode Of Operation – Human Operated and Autonomous – Independent
Analysis of Annual Sales in US$ Million for the Years 2020
through 2027 and % CAGR
Table 20: USA Historic Review for Defense Robotics by Mode Of
Operation – Human Operated and Autonomous Markets – Independent
Analysis of Annual Sales in US$ Million for Years 2016 through
2019 and % CAGR
Table 21: USA 11-Year Perspective for Defense Robotics by Mode
Of Operation – Percentage Breakdown of Value Sales for Human
Operated and Autonomous for the Years 2016, 2021 & 2027
Table 22: USA Current & Future Analysis for Defense Robotics by
Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 23: USA Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 24: USA 11-Year Perspective for Defense Robotics by Type –
Percentage Breakdown of Value Sales for Airborne, Marine and
Land for the Years 2016, 2021 & 2027
CANADA
Table 25: Canada Current & Future Analysis for Defense Robotics
by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 26: Canada Historic Review for Defense Robotics by Mode
Of Operation – Human Operated and Autonomous Markets –
Independent Analysis of Annual Sales in US$ Million for Years
2016 through 2019 and % CAGR
Table 27: Canada 11-Year Perspective for Defense Robotics by
Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 28: Canada Current & Future Analysis for Defense Robotics
by Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 29: Canada Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 30: Canada 11-Year Perspective for Defense Robotics by
Type – Percentage Breakdown of Value Sales for Airborne, Marine
and Land for the Years 2016, 2021 & 2027
JAPAN
Table 31: Japan Current & Future Analysis for Defense Robotics
by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 32: Japan Historic Review for Defense Robotics by Mode Of
Operation – Human Operated and Autonomous Markets – Independent
Analysis of Annual Sales in US$ Million for Years 2016 through
2019 and % CAGR
Table 33: Japan 11-Year Perspective for Defense Robotics by
Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 34: Japan Current & Future Analysis for Defense Robotics
by Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 35: Japan Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 36: Japan 11-Year Perspective for Defense Robotics by
Type – Percentage Breakdown of Value Sales for Airborne, Marine
and Land for the Years 2016, 2021 & 2027
CHINA
Table 37: China Current & Future Analysis for Defense Robotics
by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 38: China Historic Review for Defense Robotics by Mode Of
Operation – Human Operated and Autonomous Markets – Independent
Analysis of Annual Sales in US$ Million for Years 2016 through
2019 and % CAGR
Table 39: China 11-Year Perspective for Defense Robotics by
Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 40: China Current & Future Analysis for Defense Robotics
by Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 41: China Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 42: China 11-Year Perspective for Defense Robotics by
Type – Percentage Breakdown of Value Sales for Airborne, Marine
and Land for the Years 2016, 2021 & 2027
EUROPE
Table 43: Europe Current & Future Analysis for Defense Robotics
by Geographic Region – France, Germany, Italy, UK and Rest of
Europe Markets – Independent Analysis of Annual Sales in US$
Million for Years 2020 through 2027 and % CAGR
Table 44: Europe Historic Review for Defense Robotics by
Geographic Region – France, Germany, Italy, UK and Rest of
Europe Markets – Independent Analysis of Annual Sales in US$
Million for Years 2016 through 2019 and % CAGR
Table 45: Europe 11-Year Perspective for Defense Robotics by
Geographic Region – Percentage Breakdown of Value Sales for
France, Germany, Italy, UK and Rest of Europe Markets for Years
2016, 2021 & 2027
Table 46: Europe Current & Future Analysis for Defense Robotics
by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 47: Europe Historic Review for Defense Robotics by Mode
Of Operation – Human Operated and Autonomous Markets –
Independent Analysis of Annual Sales in US$ Million for Years
2016 through 2019 and % CAGR
Table 48: Europe 11-Year Perspective for Defense Robotics by
Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 49: Europe Current & Future Analysis for Defense Robotics
by Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 50: Europe Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 51: Europe 11-Year Perspective for Defense Robotics by
Type – Percentage Breakdown of Value Sales for Airborne, Marine
and Land for the Years 2016, 2021 & 2027
FRANCE
Table 52: France Current & Future Analysis for Defense Robotics
by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 53: France Historic Review for Defense Robotics by Mode
Of Operation – Human Operated and Autonomous Markets –
Independent Analysis of Annual Sales in US$ Million for Years
2016 through 2019 and % CAGR
Table 54: France 11-Year Perspective for Defense Robotics by
Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 55: France Current & Future Analysis for Defense Robotics
by Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 56: France Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 57: France 11-Year Perspective for Defense Robotics by
Type – Percentage Breakdown of Value Sales for Airborne, Marine
and Land for the Years 2016, 2021 & 2027
GERMANY
Table 58: Germany Current & Future Analysis for Defense
Robotics by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 59: Germany Historic Review for Defense Robotics by Mode
Of Operation – Human Operated and Autonomous Markets –
Independent Analysis of Annual Sales in US$ Million for Years
2016 through 2019 and % CAGR
Table 60: Germany 11-Year Perspective for Defense Robotics by
Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 61: Germany Current & Future Analysis for Defense
Robotics by Type – Airborne, Marine and Land – Independent
Analysis of Annual Sales in US$ Million for the Years 2020
through 2027 and % CAGR
Table 62: Germany Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 63: Germany 11-Year Perspective for Defense Robotics by
Type – Percentage Breakdown of Value Sales for Airborne, Marine
and Land for the Years 2016, 2021 & 2027
ITALY
Table 64: Italy Current & Future Analysis for Defense Robotics
by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 65: Italy Historic Review for Defense Robotics by Mode Of
Operation – Human Operated and Autonomous Markets – Independent
Analysis of Annual Sales in US$ Million for Years 2016 through
2019 and % CAGR
Table 66: Italy 11-Year Perspective for Defense Robotics by
Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 67: Italy Current & Future Analysis for Defense Robotics
by Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 68: Italy Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 69: Italy 11-Year Perspective for Defense Robotics by
Type – Percentage Breakdown of Value Sales for Airborne, Marine
and Land for the Years 2016, 2021 & 2027
UNITED KINGDOM
Table 70: UK Current & Future Analysis for Defense Robotics by
Mode Of Operation – Human Operated and Autonomous – Independent
Analysis of Annual Sales in US$ Million for the Years 2020
through 2027 and % CAGR
Table 71: UK Historic Review for Defense Robotics by Mode Of
Operation – Human Operated and Autonomous Markets – Independent
Analysis of Annual Sales in US$ Million for Years 2016 through
2019 and % CAGR
Table 72: UK 11-Year Perspective for Defense Robotics by Mode
Of Operation – Percentage Breakdown of Value Sales for Human
Operated and Autonomous for the Years 2016, 2021 & 2027
Table 73: UK Current & Future Analysis for Defense Robotics by
Type – Airborne, Marine and Land – Independent Analysis of
Annual Sales in US$ Million for the Years 2020 through 2027 and
% CAGR
Table 74: UK Historic Review for Defense Robotics by Type –
Airborne, Marine and Land Markets – Independent Analysis of
Annual Sales in US$ Million for Years 2016 through 2019 and %
CAGR
Table 75: UK 11-Year Perspective for Defense Robotics by Type –
Percentage Breakdown of Value Sales for Airborne, Marine and
Land for the Years 2016, 2021 & 2027
REST OF EUROPE
Table 76: Rest of Europe Current & Future Analysis for Defense
Robotics by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 77: Rest of Europe Historic Review for Defense Robotics
by Mode Of Operation – Human Operated and Autonomous Markets –
Independent Analysis of Annual Sales in US$ Million for Years
2016 through 2019 and % CAGR
Table 78: Rest of Europe 11-Year Perspective for Defense
Robotics by Mode Of Operation – Percentage Breakdown of Value
Sales for Human Operated and Autonomous for the Years 2016,
2021 & 2027
Table 79: Rest of Europe Current & Future Analysis for Defense
Robotics by Type – Airborne, Marine and Land – Independent
Analysis of Annual Sales in US$ Million for the Years 2020
through 2027 and % CAGR
Table 80: Rest of Europe Historic Review for Defense Robotics
by Type – Airborne, Marine and Land Markets – Independent
Analysis of Annual Sales in US$ Million for Years 2016 through
2019 and % CAGR
Table 81: Rest of Europe 11-Year Perspective for Defense
Robotics by Type – Percentage Breakdown of Value Sales for
Airborne, Marine and Land for the Years 2016, 2021 & 2027
ASIA-PACIFIC
Table 82: Asia-Pacific Current & Future Analysis for Defense
Robotics by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 83: Asia-Pacific Historic Review for Defense Robotics by
Mode Of Operation – Human Operated and Autonomous Markets –
Independent Analysis of Annual Sales in US$ Million for Years
2016 through 2019 and % CAGR
Table 84: Asia-Pacific 11-Year Perspective for Defense Robotics
by Mode Of Operation – Percentage Breakdown of Value Sales for
Human Operated and Autonomous for the Years 2016, 2021 & 2027
Table 85: Asia-Pacific Current & Future Analysis for Defense
Robotics by Type – Airborne, Marine and Land – Independent
Analysis of Annual Sales in US$ Million for the Years 2020
through 2027 and % CAGR
Table 86: Asia-Pacific Historic Review for Defense Robotics by
Type – Airborne, Marine and Land Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2016 through 2019 and
% CAGR
Table 87: Asia-Pacific 11-Year Perspective for Defense Robotics
by Type – Percentage Breakdown of Value Sales for Airborne,
Marine and Land for the Years 2016, 2021 & 2027
REST OF WORLD
Table 88: Rest of World Current & Future Analysis for Defense
Robotics by Mode Of Operation – Human Operated and Autonomous –
Independent Analysis of Annual Sales in US$ Million for the
Years 2020 through 2027 and % CAGR
Table 89: Rest of World Historic Review for Defense Robotics by
Mode Of Operation – Human Operated and Autonomous Markets –
Independent Analysis of Annual Sales in US$ Million for Years
2016 through 2019 and % CAGR
Table 90: Rest of World 11-Year Perspective for Defense
Robotics by Mode Of Operation – Percentage Breakdown of Value
Sales for Human Operated and Autonomous for the Years 2016,
2021 & 2027
Table 91: Rest of World Current & Future Analysis for Defense
Robotics by Type – Airborne, Marine and Land – Independent
Analysis of Annual Sales in US$ Million for the Years 2020
through 2027 and % CAGR
Table 92: Rest of World Historic Review for Defense Robotics by
Type – Airborne, Marine and Land Markets – Independent Analysis
of Annual Sales in US$ Million for Years 2016 through 2019 and
% CAGR
Table 93: Rest of World 11-Year Perspective for Defense
Robotics by Type – Percentage Breakdown of Value Sales for
Airborne, Marine and Land for the Years 2016, 2021 & 2027
IV. COMPETITION
Total Companies Profiled: 110
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Artificial Intelligence
More than $9 Million Awarded to High School Scientists and Engineers at the Regeneron International Science and Engineering Fair 2024
Grace Sun, 16, receives $75,000 Top Award for a new kind of organic electrochemical transistor at the world’s largest pre-college science, technology, engineering and math (STEM) competition.
TARRYTOWN, N.Y. and WASHINGTON, May 17, 2024 /PRNewswire/ — Regeneron Pharmaceuticals, Inc. (NASDAQ: REGN) and Society for Science (the Society) announced that Grace Sun, 16, of Lexington, Kentucky, won the $75,000 top award, the George D. Yancopoulos Innovator Award, named in honor of the pioneering drug researcher and Regeneron co-Founder, Board co-Chair, President and Chief Scientific Officer, in the 2024 Regeneron International Science and Engineering Fair (Regeneron ISEF), the world’s largest pre-college science and engineering competition. Other top prizes went to projects in second-order cone programming, microplastics filtration and multi-sensory therapy for dementia.
The top winners were honored during two award ceremonies: the Special Awards on May 16 and the Grand Awards Ceremony on the morning of May 17. In total, over $9 million USD was awarded to the finalists based on their projects’ creativity, innovation and depth of scientific inquiry. The competition featured nearly 2,000 young scientists representing 49 U.S. states and nearly 70 countries, regions and territories across the world.
Grace Sun, 16, of Lexington, Kentucky, won first place and received the $75,000 George D. Yancopoulos Innovator Award for her research on building a better organic electrochemical transistor that she hopes will be used to develop new electronic devices that could help detect and treat serious illnesses like diabetes, epilepsy and organ failure. To overcome the problems that have previously prevented such devices from working effectively inside the body, Grace developed a new way of chemically treating their organic components, which greatly improved their laboratory performance.
Michelle Wei, 17, of San Jose, California, received one of two Regeneron Young Scientist Awards of $50,000 for her research to improve the speed and efficiency of a type of software that is useful in many fields such as machine learning, transportation and financial systems. Michelle’s new approach involved determining a quick approximate solution to the second-order cone programming problem, then splitting the initial cone into smaller cones, which enabled her new algorithm to greatly outperform previous approaches.
Krish Pai, 17, of Del Mar, California, received the second Regeneron Young Scientist Award of $50,000 for his machine-learning research to identify microbial genetic sequences that can be modified to biodegrade plastic. His new software, called Microby, scans databases of microorganisms and determines which ones can be changed genetically to biodegrade plastics. In tests, he identified two microorganisms that can be genetically modified to degrade plastic at a cost he believes would be ten times less than traditional recycling.
“Congratulations to the Regeneron International Science and Engineering Fair 2024 winners,” said Maya Ajmera, President and CEO, Society for Science and Executive Publisher, Science News. “I’m truly inspired by the ingenuity and determination shown by these remarkable students. Coming from around the world with diverse backgrounds and academic disciplines, these students have shown that it is possible to come together in unity to tackle some of the toughest challenges facing our world today, and I could not be prouder.”
Regeneron ISEF provides a global stage for the world’s best and brightest young scientists and engineers. Through this competition, Regeneron and the Society are fostering the next generation of STEM leaders who are pioneering solutions to improve our world. Since 2020, Regeneron has provided STEM experiences to approximately 2.4 million students, on track to meet its goal of 2.5 million by 2025.
“The talent, intelligence and potential of this year’s Regeneron ISEF finalists is truly inspiring, and I congratulate each on their remarkable achievements,” said George D. Yancopoulos, M.D., Ph.D., co-Founder, Board co-Chair, President and Chief Scientific Officer of Regeneron. “Science competitions like ISEF were pivotal in shaping my own career and fueling my passion to fight back against disease. I look forward to seeing these students continue to push the boundaries of science and technology to create positive and sustainable change for all humanity.”
Other top honors from the competition include:
Justin Huang and Victoria Ou, both 17, of Woodlands, Texas, received the Gordon E. Moore Award for Positive Outcomes for Future Generations of $50,000 for their new prototype filtration system that uses ultrasonic waves to remove microscopic plastic particles from water. In lab tests, the acoustic force from the high-frequency sound waves removed between 84% and 94% of the suspended microplastic particles in a single pass. The students are now working to scale up and fine-tune their experimental system.
Ingrid Wai Hin Chan, 17, of Hong Kong, China received the Craig R. Barrett Award for Innovation of $10,000 for her research on using a multi-sensory therapy for dementia patients. Her mixed therapy app would allow patients to practice physical and cognitive skills through a personalized, immersive environment using virtual reality headsets. Ingrid conducted an eight-week study with six people living with dementia and found that the cognitive function of patients who used her prototype improved in several areas. She believes her app could serve as a viable option for dementia patients with limited access to in-person professional therapy.
Tanishka Balaji Aglave, 15, of Valrico, Florida, received the H. Robert Horvitz Prize for Fundamental Research of $10,000 for her investigation into a natural alternative treatment against citrus greening, a disease that threatens citrus farming in many parts of the world and is currently only treated with antibiotics. Tanishka injected the trunks of infected trees with an extract from the curry leaf tree, and found through tests that this potential method could effectively and sustainably manage citrus greening disease.
Maddux Alexander Springer, 18, of Honolulu, Hawaii, received the Peggy Scripps Award for Science Communication of $10,000 for his research into fibropapillomatosis (FP), a disease that is the primary cause of death in green sea turtles. Some turtles he studied in Kaneohe Bay, Hawaii, were stricken with a disease that causes internal and external tumors that inhibit their everyday lives. After analyzing the turtles’ diet of green algae, Maddux concluded that this disease, wastewater, invasive algae and the amino acid arginine all pose a grave risk to these endangered sea creatures.
Ria Kamat, 17, of Hackensack, New Jersey; Anna Oliva, 17, of Houston, TX; and Shuhan Luo, 18, of Worcester, MA, received the Dudley R. Herschbach SIYSS Award, which provides finalists an all-expense paid trip to attend the Stockholm International Youth Science Seminar during Nobel Week in Stockholm, Sweden.
Jack Shannon, 18, of Clane, Kildare, Ireland, and Nikhil Vemuri, 17, of Cary, North Carolina, received the EU Contest for Young Scientists Award. Their projects will represent Regeneron ISEF at the EU Contest for Young Scientists to be held this September in Katowice, Poland.
For more information about the top winners and access to visual assets visit: https://www.societyforscience.org/isef-2024-media-kit.
The full list of Special Award ISEF 2024 Finalists can be found at https://www.societyforscience.org/press-release/regeneron-isef-2024-special-awards-winners.
In addition to the Top Award winners, more than 450 finalists received awards and prizes for their innovative research, including “First Award” winners, who each received a $5,000 prize.
The following lists the First Award winners for each of the 22 categories, from which the Top Awards were chosen:
Animal Sciences, sponsored by Society for ScienceMaddux Alexander Springer, Honolulu, Hawaii
Behavioral and Social Sciences, sponsored by Society for ScienceAndrew Y. Liang, San Jose, California
Biochemistry, sponsored by RegeneronAmy Hong Xiao, Garden City, New York
Biomedical and Health Sciences, sponsored by RegeneronRia Kamat, Hackensack, New Jersey; Kevin Xuan Lei, Shanghai, China
Biomedical Engineering, sponsored by Alfred E. Mann CharitiesAyush Garg, Dublin, California; Divij Motwani, Palo Alto, California; Akash Ashish Pai, Portland, Oregon
Cellular and Molecular Biology, sponsored by RegeneronLara and Maya Sarah Hammoud, Beverly Hills, Michigan
Chemistry, sponsored by Society for ScienceAkilan Sankaran, Albuquerque, New Mexico; Arjun Suresh Malpani and Siddharth Daniel D’costa, Portland, Oregon
Computational Biology and Bioinformatics, sponsored by RegeneronKun-Hyung Roh, Bronx, New York
Earth and Environmental Sciences, sponsored by Google.orgNikhil Vemuri, Durham, North Carolina; Justin Yizhou Huang and Victoria Ou, The Woodlands, Texas
Embedded Systems, sponsored by HPChloe Rae and Sophie Rose Filion, Welland, Ontario, Canada
Energy: Sustainable Materials and Design, sponsored by Siemens EnergyAlia Wahban, Hamilton, Ontario, Canada
Engineering Technology: Statics and Dynamics, sponsored by Howmet Aerospace FoundationChiyo Nakatsuji, Bunkyoku, Tokyo, Japan; Kevin Shen, Olympia, Washington
Environmental Engineering, sponsored by JacobsKrish Pai, San Diego, California; Jack Shannon, Clane, Kildare, Ireland
Materials Science, sponsored by Howmet Aerospace FoundationGrace Sun, Lexington, Kentucky
Mathematics, sponsored by Akamai FoundationAnna Oliva, Houston, Texas
Microbiology, sponsored by Schattner FoundationMatthew Chang, Irvine, California
Physics and Astronomy, sponsored by Richard F. Caris Charitable Trust IIHarini Thiagarajan and Vishal Ranganath Yalla, Bothell, Washington; Shuhan Luo, Worcester, Massachusetts
Plant Sciences, sponsored by Society for SciencePauline Estrada, Fresno, California; Tanishka Balaji Aglave, Dover, Florida
Robotics and Intelligent Machines, sponsored by RegeneronMichal Lajciak, Dubnica nad Vahom, Trenciansky kraj, Slovakia; Anthony Efthimiadis, Oakville, Ontario, Canada
Systems Software, sponsored by MicrosoftMichelle Wei, San Jose, California
Technology Enhances the Arts, sponsored by Society for ScienceAnant Khandelwal, Sritan Motati and Siddhant Sood, Alexandria, Virginia
Translational Medical Science, sponsored by RegeneronZheng-Chi Lee, West Lafayette, Indiana; Ingrid Wai Hin Chan, Hong Kong, China
The full list of all award-winning ISEF 2024 finalists is available here: https://www.societyforscience.org/press-release/regeneron-isef-2024-full-awards.
View all the finalists’ research here: https://projectboard.world/isef.
About the Regeneron International Science and Engineering FairThe Regeneron International Science and Engineering Fair (Regeneron ISEF), a program of Society for Science for over 70 years, is the world’s largest global science competition for high school students. Through a global network of local, regional and national science fairs, millions of students are encouraged to explore their passion for scientific inquiry. Each spring, a group of these students is selected as finalists and offered the opportunity to compete for approximately U.S. $9 million in awards and scholarships.
In 2019, Regeneron became the title sponsor of ISEF to help reward and celebrate the best and brightest young minds globally and encourage them to pursue careers in STEM to positively impact the world. Regeneron ISEF is supported by a community of additional sponsors, including Akamai Foundation, Alfred E. Mann Charities, Aramco, Caltech, Google.org, Gordon and Betty Moore Foundation, Howmet Aerospace Foundation, HP, , Jacobs, King Abdulaziz & his Companions Foundation for Giftedness and Creativity, Microsoft, National Geographic Society, Richard F. Caris Charitable Trust II, Rise, an initiative of Schmidt Futures and the Rhodes Trust, Schattner Foundation, Siemens Energy, Annenburg Foundation, Ballmer Group, Broadcom Foundation, Cesco Linguistic Services, Conrad N. Hilton Foundation, Edison International, Insaco, Oracle Academy, The Eli and Edythe Broad Foundation, The Ralph M. Parsons Foundation and US Army ROTC. Many are entrepreneurs across a wide range of industries. Learn more at https://www.societyforscience.org/isef/.
About Society for ScienceSociety for Science is a champion for science, dedicated to promoting the understanding and appreciation of science and the vital role it plays in human advancement. Established in 1921, Society for Science is best known for its award-winning journalism through Science News and Science News Explores, its world-class science research competitions for students, including the Regeneron Science Talent Search, the Regeneron International Science and Engineering Fair and the Thermo Fisher Scientific Junior Innovators Challenge, and its outreach and equity programming that seeks to ensure that all students have an opportunity to pursue a career in STEM. A 501(c)(3) membership organization, Society for Science is committed to inform, educate and inspire. Learn more at www.societyforscience.org and follow us on Facebook, Twitter, Instagram and Snapchat (Society4Science).
About RegeneronRegeneron (NASDAQ: REGN) is a leading biotechnology company that invents, develops and commercializes life-transforming medicines for people with serious diseases. Founded and led by physician-scientists, our unique ability to repeatedly and consistently translate science into medicine has led to numerous approved treatments and product candidates in development, most of which were homegrown in our laboratories. Our medicines and pipeline are designed to help patients with eye diseases, allergic and inflammatory diseases, cancer, cardiovascular and metabolic diseases, neurological diseases, hematologic conditions, infectious diseases and rare diseases.
Regeneron believes that operating as a good corporate citizen is crucial to delivering on our mission. We approach corporate responsibility with three goals in mind: to improve the lives of people with serious diseases, to foster a culture of integrity and excellence and to build sustainable communities. Regeneron is proud to be included on the Dow Jones Sustainability World Index and the Civic 50 list of the most “community-minded” companies in the U.S. Throughout the year, Regeneron empowers and supports employees to give back through our volunteering, pro bono and matching gift programs. Our most significant philanthropic commitments are in the area of early science education, including the Regeneron Science Talent Search and the Regeneron International Science and Engineering Fair (ISEF).
For more information, please visit www.Regeneron.com or follow Regeneron on LinkedIn, Instagram, Facebook or X.
More information about the top winners and access to visual assets visit: https://www.societyforscience.org/isef-2024-media-kit.
Media ContactsJoseph Brown, [email protected]
Gayle Kansagor, Society for [email protected]
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View original content:https://www.prnewswire.co.uk/news-releases/more-than-9-million-awarded-to-high-school-scientists-and-engineers-at-the-regeneron-international-science-and-engineering-fair-2024-302149316.html
Artificial Intelligence
J.P. Morgan Life Sciences Private Capital, Blue Horizon Advisors and United Al Saqer Announce Winner of Inaugural 2024 Life Sciences Innovation Summit
In conjunction with Abu Dhabi Global Healthcare Week 2024
ABU DHABI, UAE, May 17, 2024 /PRNewswire/ — J.P. Morgan Life Sciences Private Capital, Blue Horizon Advisors and United Al Saqer Group announced today Rayees Rahman of Harmonic Discovery as the winner of the inaugural J.P. Morgan Asset Management: Life Sciences Innovation Summit. Harmonic Discovery is a precision pharmacology company applying its generative chemistry platform to advance next-generation kinase inhibitors.
In partnership with the Department of Health – Abu Dhabi (DoH), the Summit took place on May 14-15, 2024 at Cleveland Clinic Abu Dhabi and showcased the 11 innovative finalists, as well as highlighted existing innovators and opportunities in the Emirate of Abu Dhabi. The event also featured keynote speeches from Dr. Laurie Glimcher of Dana-Farber Cancer Institute, Dr. Shahrukh Hashmi of the Department of Health – Abu Dhabi, and Dr. David Ho of Columbia University Medical Center and provided attendees networking opportunities to gain valuable insights into the future of life sciences innovation.
In addition, the jury designated Chun-Hao Huang of Algen Biotechnologies as honourable mention. Algen Biotechnologies is a platform therapeutics and drug discovery company using world-leading CRISPR and AI to find treatments for cancer, inflammation and metabolic diseases.
The winners were selected by an esteemed, international panel of judges, which included:Laurie Glimcher, MD, President and CEO at Dana-Farber Cancer InstituteJorge Guzman, MD, CEO at Cleveland Clinic Abu DhabiProf. Shahrukh Khurshid Hashmi, MD, Director of Research, Department of Health, Abu DhabiYasmine Hayek Kobeissi, PhD, CQF, BSc., Executive Director at Blue Horizon AdvisorsAnya Schiess, Managing Partner at J.P. Morgan Life Sciences Private CapitalWalid Zaher, PhD, Co-Founder and CEO, Carexso
Dr. Asma Al Mannaei, Executive Director of the Research and Innovation Centre at the Department of Health – Abu Dhabi said: “Under the directives of the UAE’s wise leadership, and renowned for its world-leading medical infrastructure, Abu Dhabi stands at the forefront of healthcare excellence, offering an unparalleled opportunity for advancement in healthcare for global partners. It was our utmost pleasure hosting the J.P. Morgan Asset Management Life Sciences Innovation Summit 2024 on the sidelines of Abu Dhabi Global Healthcare Week and we commend the winners for their pioneering efforts in driving impactful advancements in healthcare; their dedication to innovation not only transforms the landscape of medicine, but also holds the promise of improving lives worldwide.”
Stephen Squinto, PhD, Chief Investment Officer, J.P. Morgan Life Sciences Private Capital said: “We are thrilled with the level of biotech passion and innovation that we observed at this year’s Summit in Abu Dhabi. The energy was truly palpable we are thrilled to announce Rayees Rahman as the winner of our first Life Sciences Innovation Summit. Harmonic Discovery’s approach embodies the next generation of drug discovery and development. We appreciate the time and effort of all participants and cannot wait for our next event in the region.”
Nabil Kobeissi, Chief Executive Officer of Blue Horizon Advisors, said: “As the main sponsor, we are committed to nurturing and fostering the growth of all 11 finalists in this vibrant biotech ecosystem. This Summit marks the beginning of a transformative journey, and we are confident that it will pave the way for a flourishing hub in the region. We are also pleased to announce that we will commit to invest in and partner with the winner, Harmonic Discovery, to support its future growth in the region.”
Sponsors for the event included J.P. Morgan Life Sciences Private Capital, J.P. Morgan Commercial Bank, Blue Horizon Advisors, United Al Saqer Group, Thermo Fisher Scientific, and Salam Capital. The Summit organisation, logistics and finalist recruitment were facilitated by Lyfebulb.
Of importance, at the Summit, Mr. Mohamed Al Breiki, Executive Director of Sustainable Development at Masdar City, announced that Masdar City Free Zone would award all 11 Finalists complimentary business licenses to further support their establishment in the region. Masdar City is one of the world’s most sustainable urban developments and innovation hubs with a growing focus on life science entrepreneurship in Abu Dhabi.
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Artificial Intelligence
Congregating in the Lion City for a Win-Win Future of Intelligent Computing at the Global Data Center Facility Summit 2024
SINGAPORE, May 17, 2024 /PRNewswire/ — On May 17, 2024, the Global Data Center Facility Summit 2024 was held in Singapore with the theme of “Power the Digital Era Forward.” At the summit, over 600 data center industry leaders, technical experts, and ecosystem partners gathered to discuss new trends and opportunities of the global data center industry in the intelligent computing era. The attendees also got to experience all-scenario, all-ecosystem, and all-service end-to-end (E2E) solutions, share innovative practices of green data centers in the Asia Pacific and Europe, and experience the exhibition vehicle to unveil the mystery of Outdoor PowerPOD that features one power system per container. By fully embracing the intelligent computing era, Huawei strives to power the digital era forward.
Seizing Opportunities Brought by AI and Jointly Building Green & Reliable Computing Infrastructure
At the opening speech, Charles Yang, Senior Vice President of Huawei and President of Marketing, Sales and Services, Huawei Digital Power, noted that since ChatGPT ushered in the AI era, large models keep pushing the limits of computing power and the intelligent computing industry is witnessing an unprecedented construction boom. As predicted, 100 GW will be added to the global data center installed capacity and the market value will exceed US$600 billion in the next five years.
According to Charles, with opportunities come challenges. The primary challenge concerning the data center industry is reliability and electricity. Data centers are scaling up from the MW-level to the GW-level. E2E reliability of data centers is becoming even more important than ever. In response to the opportunities, Huawei will work with customers and partners to expand the industry space.
Steering Data Centers to the AI Era with Product + Service + Ecosystem
During the summit, Sun Xiaofeng, President of Huawei Data Center Facility & Critical Power Business, delivered a speech titled “Power the Digital Era Forward. ” He stated that as AI large models are penetrating, the surging compute demands drive the expansive growth in data center.
To address the challenges, Huawei strives to build product + service + ecosystem E2E data center solutions that feature fast deployment, flexible cooling, green energy, and ultimate reliability.
Fast deployment: Data centers are fully modularized and prefabricated to ensure high quality and efficient construction.Flexible cooling: Air-liquid fusion and integrated cooling source emerges as the optimal cooling architecture for intelligent computing.Green energy: New generation-grid-load-storage integrated solution is built to ensure the sound operations of intelligent computing centers.Ultimate reliability: Data centers are safeguarded through reliable products and preventive protection.Currently, Huawei’s global service network covers more than 170 countries with over 1800 professional engineers, providing 24/7 technical support. With N+ flagship service centers, Huawei has built a one-hour service radius for its customers.
The ecosystem is a key part for a win-win future of intelligent computing. Huawei works with partners to develop comprehensive E2E solutions and provide customers with one-stop data center services.
During the summit, Huawei and the ASEAN Centre for Energy released a white paper on “Building Next Generation Data Center Facility in ASEAN.” The document provides insights into the status quo, challenges, and trends of data centers in the ASEAN region, and emphasizes that efficient and energy-saving products and solutions should be applied. It also proposes future-oriented policy recommendations for data center markets.
In the ecosystem exhibition area, Huawei showcased scenario-based solutions for large-, medium-, and small-sized data centers, and demonstrated data center consulting, design, integrated development, and delivery capabilities with dozens of ecosystem partners including CIMC, Weichai, CSCEC, and Huashi.
On a special note, the Huawei Outdoor PowerPOD exhibition vehicle made its global debut. The Huawei Outdoor PowerPOD features one power system per container, outdoor deployment, plug-and-play, and high protection rating and reliability. It has become the preferred choice for decoupling the power supply architecture.
A single tree cannot make a forest.
AI is presenting great opportunities. By delving into the industry, aggregating partner ecosystems, and making innovations applicable to transformations, Huawei will continue to help customers build reliable computing infrastructure, accelerating the industry to embrace AI and powering the digital era forward.
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View original content:https://www.prnewswire.co.uk/news-releases/congregating-in-the-lion-city-for-a-win-win-future-of-intelligent-computing-at-the-global-data-center-facility-summit-2024-302148973.html
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