Artificial Intelligence
Global Indoor Air Quality Monitors Market to Reach US$6.4 Billion by the Year 2027
New York, May 12, 2022 (GLOBE NEWSWIRE) — Reportlinker.com announces the release of the report “Global Indoor Air Quality Monitors Industry” – https://www.reportlinker.com/p05957040/?utm_source=GNW
– Online interactive peer-to-peer collaborative bespoke updates
– Access to our digital archives and MarketGlass Research Platform
– Complimentary updates for one yearGlobal Indoor Air Quality Monitors Market to Reach US$6.4 Billion by the Year 2027
– Amid the COVID-19 crisis, the global market for Indoor Air Quality Monitors estimated at US$3.7 Billion in the year 2020, is projected to reach a revised size of US$6.4 Billion by 2027, growing at a CAGR of 8.2% over the period 2020-2027.Fixed Indoor Monitors, one of the segments analyzed in the report, is projected to grow at a 7.9% CAGR to reach US$4.2 Billion by the end of the analysis period. After an early analysis of the business implications of the pandemic and its induced economic crisis, growth in the Portable Indoor Monitors segment is readjusted to a revised 8.9% CAGR for the next 7-year period. This segment currently accounts for a 33.6% share of the global Indoor Air Quality Monitors market.
– The U.S. Accounts for Over 39.4% of Global Market Size in 2020, While China is Forecast to Grow at a 10.1% CAGR for the Period of 2020-2027
– The Indoor Air Quality Monitors market in the U.S. is estimated at US$1.5 Billion in the year 2020. The country currently accounts for a 39.39% share in the global market. China, the world second largest economy, is forecast to reach an estimated market size of US$445.5 Million in the year 2027 trailing a CAGR of 10.1% through 2027. Among the other noteworthy geographic markets are Japan and Canada, each forecast to grow at 7.4% and 7.8% respectively over the 2020-2027 period. Within Europe, Germany is forecast to grow at approximately 7.9% CAGR while Rest of European market (as defined in the study) will reach US$445.5 Million by the year 2027.
– Select Competitors (Total 101 Featured) 3M Company Aeroqual Limited Awair Inc. Camfil AB Daikin North America LLC. Emerson Electric Co. Horiba, Ltd. Lennox International Inc. Panasonic Corporation Siemens AG Teledyne Technologies Incorporated Testo SE & Co. KGaA Thermo Fisher Scientific Inc. Trane Technologies plc Trion, Inc. TSI Incorporated
Read the full report: https://www.reportlinker.com/p05957040/?utm_source=GNW
I. METHODOLOGY
II. EXECUTIVE SUMMARY
1. MARKET OVERVIEW
Rising Air Pollution Exposing More than ½ of the World
Population to Health Risks Provides the Foundation for the
Growth of Indoor Air Quality Monitors
Why Indoor Air Quality Matters?
EXHIBIT 1: Global Indoor Air Pollution Related Fatalities by
Health Condition: Percentage Breakdown of Deaths for ALRI,
COPD, Ischemic Heart Disease, Lung Cancer, and Stroke for the
Year 2021
How Air Quality Monitoring Can Help?
What?s the Prognosis on the Pandemic? Here?s What Everyone
Should Know About the Dynamics of the Ongoing Multiwave
Pandemic & Its Impact on the Economy
After Omicron, Comes Stealth Omicron & Deltacron Fueling Fresh
Waves of Infections Across the Globe
With New Strains Emerging at an Alarming Rate, Focus Shifts to
Booster Doses & Vaccine Tweaking Amid Waning Vaccine Immunity.
But How Practical Is It to Implement Them?
EXHIBIT 2: With Vaccinated Population Showing Signs of
Declining Clinical Protection, Booster Doses Are Emerging Into
a Necessity to Restore Vaccine Effectiveness, but this
Strategy is Not Within Reach for Most Countries: Number of
Booster Doses Administered Per 100 People by Country as of
March 2022
At the Dawn of 2022 After Numerous New Strains & Millions of
Deaths, Challenges in Vaccine Production, Supply, Access &
Technology Sharing Continue to Remain
EXHIBIT 3: How & When Will the World Be Vaccinated? Global
Number of Annual COVID-19 Vaccine Doses (In Million) for Years
2020 through 2025 by Geographic Region/Country
Split Scenarios Unfold: The Great Vaccine Divide Emerges
EXHIBIT 4: With Low Vaccination Rates in Africa Emerging Into a
Global Security Issue, Vaccine Imbalances Will Stretch the
Pandemic Further into 2022: Global Percentage (%) of
Population Administered With Vaccines by Region as of March
2022
The Great Vaccine Controversy & Growing Anti-Vaccination
Movement Aggravates the Divide Between the Vaccinated & the
Unvaccinated
EXHIBIT 5: Top Reasons for Unwillingness & Uncertainty Towards
COVID-19 Vaccines Among the By-Choice Unvaccinated People: %
Share of Various Reasons as of the Year 2022
The Verdict?s Out – The Pandemic Cannot Be Ended But Can be
Maneuvered to Become Endemic and More Manageable
Amid this Prolonged Pandemic, Why Should Businesses Care About
Progress on Vaccinations?
Dragging Pandemic, New Virus Strains, Fresh Societal Risks,
Renewed Economic Disruptions Bring Weaker Growth in 2022 as
Compared to 2021
EXHIBIT 6: Uncertain, Uneven & Bumpy Recovery Shaped by New
Variants Comes Into Play, Lowering Growth Expectations for
2022 & 2023: World Economic Growth Projections (Real GDP,
Annual % Change) for the Years 2020, 2021, 2022 and 2023
EXHIBIT 7: Persistently High Unemployment Indicates Long-Term
Scarring from the COVID-19 Pandemic, Wage Inequality & Uneven
Economic Recovery. Tough Times to Continue for Industries
Reliant on Consumer Discretionary Incomes Until 2023: Global
Number of Unemployed People (In Million) for Years 2019
Through 2023
New Bursts of Food & Energy Inflation Triggered by Russia-
Ukraine War to Threaten Economic Recovery
Competition
EXHIBIT 8: Indoor Air Quality Monitors – Global Key Competitors
Percentage Market Share in 2022 (E)
Competitive Market Presence – Strong/Active/Niche/Trivial for
101 Players Worldwide in 2022 (E)
Indoor Air Quality Monitors (IAQM): Definition, Overview &
Importance
World Brands
Recent Market Activity
2. FOCUS ON SELECT PLAYERS
3. MARKET TRENDS & DRIVERS
After a Sharp Decline in 2020, Growing Understanding of the
Importance of Improving Indoor Air Quality (IAQ) to Reduce
Risk of COVID-19 Spread Leads to Demand Spike in 2021
Tracing Market Dynamics Now & Beyond
Rise in Allergies Sets the Tone for Product Adoption & Market
Growth
Indoor Spaces in Residential, Commercial, Industrial &
Healthcare Settings Witness Strong Demand for Indoor Air
Quality Monitors
Rise in Smart Homes Strengthens the Business Case for Smart
Indoor Air Quality Monitors
EXHIBIT 9: Smart Homes Emerge as a Disruptive Trend Enhancing
Lives of Homeowners & Also Creating New Market Opportunities
for Smart Indoor Air Quality Monitors: Smart Home Penetration
Rate (%) by Region/Country for the Year 2022
Continuous Technology Innovations Remains Crucial to Future Growth
Stringent Regulations & Establishment of Standards to Benefit
Growth in the Market
Role of Artificial Intelligence in Indoor Air Quality Monitors
Gets Bigger
In Focus: IoT Based Indoor Air Quality Monitoring
Green Building Strategies and Focus on Ventilation Management
Bodes Well
Role of Indoor Air Quality Monitoring in Optimizing Building
Automation
Navigating Through Myriad Challenges is Vital for Players in
the Market
4. GLOBAL MARKET PERSPECTIVE
Table 1: World Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Geographic Region – USA, Canada,
Japan, China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 2: World Historic Review for Indoor Air Quality Monitors
by Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 3: World 15-Year Perspective for Indoor Air Quality
Monitors by Geographic Region – Percentage Breakdown of Value
Sales for USA, Canada, Japan, China, Europe, Asia-Pacific and
Rest of World Markets for Years 2012, 2021 & 2027
Table 4: World Recent Past, Current & Future Analysis for Fixed
Indoor Monitors by Geographic Region – USA, Canada, Japan,
China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 5: World Historic Review for Fixed Indoor Monitors by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 6: World 15-Year Perspective for Fixed Indoor Monitors by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 7: World Recent Past, Current & Future Analysis for
Portable Indoor Monitors by Geographic Region – USA, Canada,
Japan, China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 8: World Historic Review for Portable Indoor Monitors by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 9: World 15-Year Perspective for Portable Indoor Monitors
by Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 10: World Recent Past, Current & Future Analysis for
Chemical Pollutants by Geographic Region – USA, Canada, Japan,
China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 11: World Historic Review for Chemical Pollutants by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 12: World 15-Year Perspective for Chemical Pollutants by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 13: World Recent Past, Current & Future Analysis for
Physical Pollutants by Geographic Region – USA, Canada, Japan,
China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 14: World Historic Review for Physical Pollutants by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 15: World 15-Year Perspective for Physical Pollutants by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 16: World Recent Past, Current & Future Analysis for
Biological Pollutants by Geographic Region – USA, Canada,
Japan, China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 17: World Historic Review for Biological Pollutants by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 18: World 15-Year Perspective for Biological Pollutants
by Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 19: World Recent Past, Current & Future Analysis for
Government Buildings by Geographic Region – USA, Canada, Japan,
China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 20: World Historic Review for Government Buildings by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 21: World 15-Year Perspective for Government Buildings by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 22: World Recent Past, Current & Future Analysis for
Commercial by Geographic Region – USA, Canada, Japan, China,
Europe, Asia-Pacific and Rest of World Markets – Independent
Analysis of Annual Sales in US$ Thousand for Years 2020 through
2027 and % CAGR
Table 23: World Historic Review for Commercial by Geographic
Region – USA, Canada, Japan, China, Europe, Asia-Pacific and
Rest of World Markets – Independent Analysis of Annual Sales in
US$ Thousand for Years 2012 through 2019 and % CAGR
Table 24: World 15-Year Perspective for Commercial by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 25: World Recent Past, Current & Future Analysis for
Industrial by Geographic Region – USA, Canada, Japan, China,
Europe, Asia-Pacific and Rest of World Markets – Independent
Analysis of Annual Sales in US$ Thousand for Years 2020 through
2027 and % CAGR
Table 26: World Historic Review for Industrial by Geographic
Region – USA, Canada, Japan, China, Europe, Asia-Pacific and
Rest of World Markets – Independent Analysis of Annual Sales in
US$ Thousand for Years 2012 through 2019 and % CAGR
Table 27: World 15-Year Perspective for Industrial by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 28: World Recent Past, Current & Future Analysis for
Residential by Geographic Region – USA, Canada, Japan, China,
Europe, Asia-Pacific and Rest of World Markets – Independent
Analysis of Annual Sales in US$ Thousand for Years 2020 through
2027 and % CAGR
Table 29: World Historic Review for Residential by Geographic
Region – USA, Canada, Japan, China, Europe, Asia-Pacific and
Rest of World Markets – Independent Analysis of Annual Sales in
US$ Thousand for Years 2012 through 2019 and % CAGR
Table 30: World 15-Year Perspective for Residential by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
Table 31: World Recent Past, Current & Future Analysis for
Other End-Uses by Geographic Region – USA, Canada, Japan,
China, Europe, Asia-Pacific and Rest of World Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2020 through 2027 and % CAGR
Table 32: World Historic Review for Other End-Uses by
Geographic Region – USA, Canada, Japan, China, Europe,
Asia-Pacific and Rest of World Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 33: World 15-Year Perspective for Other End-Uses by
Geographic Region – Percentage Breakdown of Value Sales for
USA, Canada, Japan, China, Europe, Asia-Pacific and Rest of
World for Years 2012, 2021 & 2027
III. MARKET ANALYSIS
UNITED STATES
Indoor Air Quality Monitors – Strong/Active/Niche/Trivial – Key
Competitors in the United States for 2022 (E)
Market Analytics
Table 34: USA Recent Past, Current & Future Analysis for Indoor
Air Quality Monitors by Product – Fixed Indoor Monitors and
Portable Indoor Monitors – Independent Analysis of Annual Sales
in US$ Thousand for the Years 2020 through 2027 and % CAGR
Table 35: USA Historic Review for Indoor Air Quality Monitors
by Product – Fixed Indoor Monitors and Portable Indoor Monitors
Markets – Independent Analysis of Annual Sales in US$ Thousand
for Years 2012 through 2019 and % CAGR
Table 36: USA 15-Year Perspective for Indoor Air Quality
Monitors by Product – Percentage Breakdown of Value Sales for
Fixed Indoor Monitors and Portable Indoor Monitors for the
Years 2012, 2021 & 2027
Table 37: USA Recent Past, Current & Future Analysis for Indoor
Air Quality Monitors by Pollutant Type – Chemical Pollutants,
Physical Pollutants and Biological Pollutants – Independent
Analysis of Annual Sales in US$ Thousand for the Years 2020
through 2027 and % CAGR
Table 38: USA Historic Review for Indoor Air Quality Monitors
by Pollutant Type – Chemical Pollutants, Physical Pollutants
and Biological Pollutants Markets – Independent Analysis of
Annual Sales in US$ Thousand for Years 2012 through 2019 and %
CAGR
Table 39: USA 15-Year Perspective for Indoor Air Quality
Monitors by Pollutant Type – Percentage Breakdown of Value
Sales for Chemical Pollutants, Physical Pollutants and
Biological Pollutants for the Years 2012, 2021 & 2027
Table 40: USA Recent Past, Current & Future Analysis for Indoor
Air Quality Monitors by End-Use – Government Buildings,
Commercial, Industrial, Residential and Other End-Uses –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 41: USA Historic Review for Indoor Air Quality Monitors
by End-Use – Government Buildings, Commercial, Industrial,
Residential and Other End-Uses Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 42: USA 15-Year Perspective for Indoor Air Quality
Monitors by End-Use – Percentage Breakdown of Value Sales for
Government Buildings, Commercial, Industrial, Residential and
Other End-Uses for the Years 2012, 2021 & 2027
CANADA
Table 43: Canada Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Product – Fixed Indoor Monitors
and Portable Indoor Monitors – Independent Analysis of Annual
Sales in US$ Thousand for the Years 2020 through 2027 and %
CAGR
Table 44: Canada Historic Review for Indoor Air Quality
Monitors by Product – Fixed Indoor Monitors and Portable Indoor
Monitors Markets – Independent Analysis of Annual Sales in US$
Thousand for Years 2012 through 2019 and % CAGR
Table 45: Canada 15-Year Perspective for Indoor Air Quality
Monitors by Product – Percentage Breakdown of Value Sales for
Fixed Indoor Monitors and Portable Indoor Monitors for the
Years 2012, 2021 & 2027
Table 46: Canada Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Pollutant Type – Chemical
Pollutants, Physical Pollutants and Biological Pollutants –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 47: Canada Historic Review for Indoor Air Quality
Monitors by Pollutant Type – Chemical Pollutants, Physical
Pollutants and Biological Pollutants Markets – Independent
Analysis of Annual Sales in US$ Thousand for Years 2012 through
2019 and % CAGR
Table 48: Canada 15-Year Perspective for Indoor Air Quality
Monitors by Pollutant Type – Percentage Breakdown of Value
Sales for Chemical Pollutants, Physical Pollutants and
Biological Pollutants for the Years 2012, 2021 & 2027
Table 49: Canada Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by End-Use – Government Buildings,
Commercial, Industrial, Residential and Other End-Uses –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 50: Canada Historic Review for Indoor Air Quality
Monitors by End-Use – Government Buildings, Commercial,
Industrial, Residential and Other End-Uses Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2012 through 2019 and % CAGR
Table 51: Canada 15-Year Perspective for Indoor Air Quality
Monitors by End-Use – Percentage Breakdown of Value Sales for
Government Buildings, Commercial, Industrial, Residential and
Other End-Uses for the Years 2012, 2021 & 2027
JAPAN
Table 52: Japan Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Product – Fixed Indoor Monitors
and Portable Indoor Monitors – Independent Analysis of Annual
Sales in US$ Thousand for the Years 2020 through 2027 and %
CAGR
Table 53: Japan Historic Review for Indoor Air Quality Monitors
by Product – Fixed Indoor Monitors and Portable Indoor Monitors
Markets – Independent Analysis of Annual Sales in US$ Thousand
for Years 2012 through 2019 and % CAGR
Table 54: Japan 15-Year Perspective for Indoor Air Quality
Monitors by Product – Percentage Breakdown of Value Sales for
Fixed Indoor Monitors and Portable Indoor Monitors for the
Years 2012, 2021 & 2027
Table 55: Japan Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Pollutant Type – Chemical
Pollutants, Physical Pollutants and Biological Pollutants –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 56: Japan Historic Review for Indoor Air Quality Monitors
by Pollutant Type – Chemical Pollutants, Physical Pollutants
and Biological Pollutants Markets – Independent Analysis of
Annual Sales in US$ Thousand for Years 2012 through 2019 and %
CAGR
Table 57: Japan 15-Year Perspective for Indoor Air Quality
Monitors by Pollutant Type – Percentage Breakdown of Value
Sales for Chemical Pollutants, Physical Pollutants and
Biological Pollutants for the Years 2012, 2021 & 2027
Table 58: Japan Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by End-Use – Government Buildings,
Commercial, Industrial, Residential and Other End-Uses –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 59: Japan Historic Review for Indoor Air Quality Monitors
by End-Use – Government Buildings, Commercial, Industrial,
Residential and Other End-Uses Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 60: Japan 15-Year Perspective for Indoor Air Quality
Monitors by End-Use – Percentage Breakdown of Value Sales for
Government Buildings, Commercial, Industrial, Residential and
Other End-Uses for the Years 2012, 2021 & 2027
CHINA
Table 61: China Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Product – Fixed Indoor Monitors
and Portable Indoor Monitors – Independent Analysis of Annual
Sales in US$ Thousand for the Years 2020 through 2027 and %
CAGR
Table 62: China Historic Review for Indoor Air Quality Monitors
by Product – Fixed Indoor Monitors and Portable Indoor Monitors
Markets – Independent Analysis of Annual Sales in US$ Thousand
for Years 2012 through 2019 and % CAGR
Table 63: China 15-Year Perspective for Indoor Air Quality
Monitors by Product – Percentage Breakdown of Value Sales for
Fixed Indoor Monitors and Portable Indoor Monitors for the
Years 2012, 2021 & 2027
Table 64: China Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Pollutant Type – Chemical
Pollutants, Physical Pollutants and Biological Pollutants –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 65: China Historic Review for Indoor Air Quality Monitors
by Pollutant Type – Chemical Pollutants, Physical Pollutants
and Biological Pollutants Markets – Independent Analysis of
Annual Sales in US$ Thousand for Years 2012 through 2019 and %
CAGR
Table 66: China 15-Year Perspective for Indoor Air Quality
Monitors by Pollutant Type – Percentage Breakdown of Value
Sales for Chemical Pollutants, Physical Pollutants and
Biological Pollutants for the Years 2012, 2021 & 2027
Table 67: China Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by End-Use – Government Buildings,
Commercial, Industrial, Residential and Other End-Uses –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 68: China Historic Review for Indoor Air Quality Monitors
by End-Use – Government Buildings, Commercial, Industrial,
Residential and Other End-Uses Markets – Independent Analysis
of Annual Sales in US$ Thousand for Years 2012 through 2019 and
% CAGR
Table 69: China 15-Year Perspective for Indoor Air Quality
Monitors by End-Use – Percentage Breakdown of Value Sales for
Government Buildings, Commercial, Industrial, Residential and
Other End-Uses for the Years 2012, 2021 & 2027
EUROPE
Indoor Air Quality Monitors – Strong/Active/Niche/Trivial – Key
Competitors in Europe for 2022 (E)
Market Analytics
Table 70: Europe Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Geographic Region – France,
Germany, Italy, UK and Rest of Europe Markets – Independent
Analysis of Annual Sales in US$ Thousand for Years 2020 through
2027 and % CAGR
Table 71: Europe Historic Review for Indoor Air Quality
Monitors by Geographic Region – France, Germany, Italy, UK and
Rest of Europe Markets – Independent Analysis of Annual Sales
in US$ Thousand for Years 2012 through 2019 and % CAGR
Table 72: Europe 15-Year Perspective for Indoor Air Quality
Monitors by Geographic Region – Percentage Breakdown of Value
Sales for France, Germany, Italy, UK and Rest of Europe Markets
for Years 2012, 2021 & 2027
Table 73: Europe Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Product – Fixed Indoor Monitors
and Portable Indoor Monitors – Independent Analysis of Annual
Sales in US$ Thousand for the Years 2020 through 2027 and %
CAGR
Table 74: Europe Historic Review for Indoor Air Quality
Monitors by Product – Fixed Indoor Monitors and Portable Indoor
Monitors Markets – Independent Analysis of Annual Sales in US$
Thousand for Years 2012 through 2019 and % CAGR
Table 75: Europe 15-Year Perspective for Indoor Air Quality
Monitors by Product – Percentage Breakdown of Value Sales for
Fixed Indoor Monitors and Portable Indoor Monitors for the
Years 2012, 2021 & 2027
Table 76: Europe Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Pollutant Type – Chemical
Pollutants, Physical Pollutants and Biological Pollutants –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 77: Europe Historic Review for Indoor Air Quality
Monitors by Pollutant Type – Chemical Pollutants, Physical
Pollutants and Biological Pollutants Markets – Independent
Analysis of Annual Sales in US$ Thousand for Years 2012 through
2019 and % CAGR
Table 78: Europe 15-Year Perspective for Indoor Air Quality
Monitors by Pollutant Type – Percentage Breakdown of Value
Sales for Chemical Pollutants, Physical Pollutants and
Biological Pollutants for the Years 2012, 2021 & 2027
Table 79: Europe Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by End-Use – Government Buildings,
Commercial, Industrial, Residential and Other End-Uses –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 80: Europe Historic Review for Indoor Air Quality
Monitors by End-Use – Government Buildings, Commercial,
Industrial, Residential and Other End-Uses Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2012 through 2019 and % CAGR
Table 81: Europe 15-Year Perspective for Indoor Air Quality
Monitors by End-Use – Percentage Breakdown of Value Sales for
Government Buildings, Commercial, Industrial, Residential and
Other End-Uses for the Years 2012, 2021 & 2027
FRANCE
Table 82: France Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Product – Fixed Indoor Monitors
and Portable Indoor Monitors – Independent Analysis of Annual
Sales in US$ Thousand for the Years 2020 through 2027 and %
CAGR
Table 83: France Historic Review for Indoor Air Quality
Monitors by Product – Fixed Indoor Monitors and Portable Indoor
Monitors Markets – Independent Analysis of Annual Sales in US$
Thousand for Years 2012 through 2019 and % CAGR
Table 84: France 15-Year Perspective for Indoor Air Quality
Monitors by Product – Percentage Breakdown of Value Sales for
Fixed Indoor Monitors and Portable Indoor Monitors for the
Years 2012, 2021 & 2027
Table 85: France Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Pollutant Type – Chemical
Pollutants, Physical Pollutants and Biological Pollutants –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 86: France Historic Review for Indoor Air Quality
Monitors by Pollutant Type – Chemical Pollutants, Physical
Pollutants and Biological Pollutants Markets – Independent
Analysis of Annual Sales in US$ Thousand for Years 2012 through
2019 and % CAGR
Table 87: France 15-Year Perspective for Indoor Air Quality
Monitors by Pollutant Type – Percentage Breakdown of Value
Sales for Chemical Pollutants, Physical Pollutants and
Biological Pollutants for the Years 2012, 2021 & 2027
Table 88: France Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by End-Use – Government Buildings,
Commercial, Industrial, Residential and Other End-Uses –
Independent Analysis of Annual Sales in US$ Thousand for the
Years 2020 through 2027 and % CAGR
Table 89: France Historic Review for Indoor Air Quality
Monitors by End-Use – Government Buildings, Commercial,
Industrial, Residential and Other End-Uses Markets –
Independent Analysis of Annual Sales in US$ Thousand for Years
2012 through 2019 and % CAGR
Table 90: France 15-Year Perspective for Indoor Air Quality
Monitors by End-Use – Percentage Breakdown of Value Sales for
Government Buildings, Commercial, Industrial, Residential and
Other End-Uses for the Years 2012, 2021 & 2027
GERMANY
Table 91: Germany Recent Past, Current & Future Analysis for
Indoor Air Quality Monitors by Product – Fixed Indoor Monitors
and Portable Indoor Monitors – Independent Analysis of Annual
Sales in US$ Thousand for the Years 2020 through 2027 and %
CAGR
Table 92: Germany Historic Review for Indoor Air Quality
Monitors by Product – Fixed Indoor Monitors and Portable Indoor
Monitors Markets – Independent Analysis of Annual Sales in US$
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Artificial Intelligence
IBM, Government of Canada, Government of Quebec Sign Agreements to Strengthen Canada’s Semiconductor Industry
Up to $187M CAD to be invested to progress expansion of chip packaging capacity and capabilities and to strengthen R&D at IBM Canada’s Bromont plant
BROMONT, QC, April 26, 2024 /PRNewswire/ — IBM (NYSE: IBM), the Government of Canada, and the Government of Quebec today announced agreements that will strengthen Canada’s semiconductor industry, and further develop the assembly, testing and packaging (ATP) capabilities for semiconductor modules to be used across a wide range of applications including telecommunications, high performance computing, automotive, aerospace & defence, computer networks, and generative AI, at IBM Canada’s plant in Bromont, Quebec. The agreements reflect a combined investment valued at approximately $187M CAD.
“Today’s announcement is a massive win for Canada and our dynamic tech sector. It will create high-paying jobs, invest in innovation, strengthen supply chains, and help make sure the most advanced technologies are Canadian-made. Semiconductors power the world, and we’re putting Canada at the forefront of that opportunity,” said the Right Honourable Justin Trudeau, Prime Minister of Canada
In addition to the advancement of packaging capabilities, IBM will be conducting R&D to develop methods for scalable manufacturing and other advanced assembly processes to support the packaging of different chip technologies, to further Canada’s role in the North American semiconductor supply chain and expand and anchor Canada’s capabilities in advanced packaging.
The agreements also allow for collaborations with small and medium-sized Canadian-based enterprises with the intent of fostering the development of a semiconductor ecosystem, now and into the future.
“IBM has long been a leader in semiconductor research and development, pioneering breakthroughs to meet tomorrow’s challenges. With the demand for compute surging in the age of AI, advanced packaging and chiplet technology is becoming critical for the acceleration of AI workloads,” said Darío Gil, IBM Senior Vice President and Director of Research. “As one of the largest chip assembly and testing facilities in North America, IBM’s Bromont facility will play a central role in this future. We are proud to be working with the governments of Canada and Quebec toward those goals and to build a stronger and more balanced semiconductor ecosystem in North America and beyond.”
IBM Canada’s Bromont plant is one of North America’s largest chip assembly and testing facilities, having operated in the region for 52 years. Today, the facility transforms advanced semiconductor components into state-of-the-art microelectronic solutions, playing a key role in IBM’s semiconductor R&D leadership alongside IBM’s facilities at the Albany NanoTech Complex and throughout New York’s Hudson Valley. These agreements will help to further establish a corridor of semiconductor innovation from New York to Bromont.
“Advanced packaging is a crucial component of the semiconductor industry, and IBM Canada’s Bromont plant has led the world in this process for decades,” said Deb Pimentel, president of IBM Canada. “Building upon IBM’s 107-year legacy of technology innovation and R&D in Canada, the Canadian semiconductor industry will now become even stronger, allowing for robust supply chains and giving Canadians steady access to even more innovative technologies and products. This announcement represents just one more example of IBM’s leadership and commitment to the country’s technology and business landscape.”
Chip packaging, the process of connecting integrated circuits on a chip or circuit board, has become more complex as electronic devices have shrunk and the components of chips themselves get smaller and smaller. IBM announced the world’s first 2 nanometer chip technology in 2021 and, as the semiconductor industry moves towards new methods of chip construction, advances in packaging will grow in importance.
“Semiconductors are part of our everyday life. They are in our phones, our cars, and our appliances. Through this investment, we are supporting Canadian innovators, creating good jobs, and solidifying Canada’s semiconductor industry to build a stronger economy. Canada is set to play a larger role in the global semiconductor industry thanks to projects like the one we are announcing today. Because, when we invest in semiconductor and quantum technologies, we invest in economic security.” — The Honourable François-Philippe Champagne, Minister of Innovation, Science and Industry
“This investment by IBM in Bromont will ensure that Quebec continues to stand out in the field of microelectronics. An increase in production capacity will solidify Quebec’s position in the strategic microelectronics sector in North America.” — The Honourable Pierre Fitzgibbon, Minister of Economy, Innovation and Energy, Minister responsible for Regional Economic Development and Minister responsible for the Metropolis and the Montreal region
About IBMIBM is a leading provider of global hybrid cloud and AI, and consulting expertise. We help clients in more than 175 countries capitalize on insights from their data, streamline business processes, reduce costs and gain the competitive edge in their industries. More than 4,000 government and corporate entities in critical infrastructure areas such as financial services, telecommunications and healthcare rely on IBM’s hybrid cloud platform and Red Hat OpenShift to affect their digital transformations quickly, efficiently and securely. IBM’s breakthrough innovations in semiconductors, AI, quantum computing, industry-specific cloud solutions and consulting deliver open and flexible options to our clients. All of this is backed by IBM’s legendary commitment to trust, transparency, responsibility, inclusivity and service. Visit www.ibm.com for more information.
Media ContactLorraine BaldwinIBM [email protected]
Willa HahnIBM [email protected]
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Artificial Intelligence
HITACHI ACQUIRES MA MICRO AUTOMATION OF GERMANY IN EFFORT TO ACCELERATE GLOBAL EXPANSION OF ROBOTIC SI BUSINESS IN THE MEDICAL AND OTHER FIELDS
HOLLAND, Mich., April 26, 2024 /PRNewswire/ — Hitachi Ltd. (TSE: 6501, “Hitachi”) has signed a stock purchase agreement on April 26 to acquire all shares of MA micro automation GmbH (“MA micro automation”, headquartered in St. Leon-Rot, Germany) from MAX Management GmbH (a subsidiary of MAX Automation SE). MA micro automation is a leading provider of robotic and automation technology (robotic SI) including high-speed linear handling systems, high-precision assembly lines, and high-speed vision inspection technology for Europe, North America, and Southeast Asia, for EUR 71.5M million. The transaction is expected to close in the second half of 2024, pending completion of the customary regulatory filings. After the acquisition is completed, MA micro automation will join JR Automation Technologies, LLC (“JR Automation”), a market leader in providing advanced automation solutions and digital technologies in the robotic system integration business for North America, Europe, and Southeast Asia as a continued effort to expand the company’s global presence.
MA micro automation is a technology leader for automation solutions within micro-assembly. Through its state-of-the-art proprietary high-speed and high-precision automation know-how, combined with unique optical image inspection capabilities, MA micro automation serves high-growth med-tech automation end-markets, covering the production, assembly, and testing medical and optical components including contact lenses, IVD and diabetes diagnostics consumables, and injection molding for medical use. The company was established in 2003 through a carve-out from Siemens*1 and since 2013 has been part of the MAX Automation group.
JR Automation is a leading provider of intelligent automated manufacturing technology solutions, serving customers across the globe in a variety of industries including automotive, life sciences, e-mobility, consumer and industrial products. With over 20 locations between North America, Europe, and Southeast Asia, the leading integrator offers nearly 2 million square feet (185,806 sq. m) of available build and engineering floorspace. This acquisition allows JR Automation to further grow and strengthen both the company’s geographical footprint and their continued commitment on expanding support capabilities within the European region and medical market vertical.
“MA micro automation provides engineering, build and support expertise with established capabilities in complex vision applications, high-speed and high-precision automation technologies. When integrated with JR Automation’s uniform global process and digital technologies, this partnership will further enhance our ability to deliver added value and support to all of our customers worldwide and continue to grow our capabilities in the medical market,” says Dave DeGraaf, CEO of JR Automation. “As we integrate this new dimension, impressive talents and abilities of the MA micro automation team we further enhance our ability to serve our customers, creating a more robust and globally balanced offering.”
With this acquisition, Hitachi aims to further enhance its ability to provide a “Total Seamless Solution*2” to connect manufacturer’s factory floors seamlessly and digitally with their front office data, allowing them to achieve total optimization and bringing Industry 4.0 to life. This “Total Seamless Solution” strategy links organizations’ operational activities such as engineering, supply chain, and purchasing to the plant floor and allows for real time, data-driven decision-making that improves the overall business value for customers.
Kazunobu Morita, Vice President and Executive Officer, CEO of Industrial Digital Business Unit, Hitachi, Ltd. says, “We are very pleased to welcome MA micro automation to the Hitachi Group. The team is based in Europe, providing robotic SI to global medical device manufacturing customers with its high technological capabilities and will join forces with JR Automation and Hitachi Automation to strengthen our global competitiveness. Hitachi aims to enhance its ability to provide value to customers and grow alongside them by leveraging its strengths in both OT, IT, including robotic SI, and “Total Seamless Solution” through Lumada*3’s customer co-creation framework.”
Joachim Hardt, CEO MA micro automation GmbH says, “Following the successful establishment and growth of MA micro automation within the attractive automation market for medical technology products, we are now opening a new chapter. Our partnership with Hitachi will not only strengthen our global competitive position, but we will also benefit from joint technological synergies and a global market presence. We look forward to a synergistic partnership with Hitachi and JR Automation.”
Outline of MA micro automation
Name
MA micro automation GmbH
Head Office
St. Leon-Rot, Germany
Representative
Joachim Hardt (CEO)
Outline of Business
Automation solutions within micro-assembly
Total no. of Employees:
Approx. 200 (As of April 2024)
Founded
2003
Revenues (2023)
€ 46.5 million
Website
*1
“Siemens” is a registered trademark or trademark of Siemens Trademark GmbH & Co. KG in the U.S. and other countries.
*2
“Total Seamless Solution” is a registered trademark of Hitachi, Ltd. in the U.S. and Japan.
*3
Lumada: A collective term for solutions, services and technologies based on Hitachi’s advanced digital technologies for creating value from customers’ data accelerating digital innovation. https://www.hitachi.com/products/it/lumada/global/en/index.html
About JR AutomationEstablished in 1980, JR Automation is a leading provider of intelligent automated manufacturing technology solutions that solve customers’ key operational and productivity challenges. JR Automation serves customers across the globe in a variety of industries, including automotive, life sciences, aerospace, and more.
In 2019, JR Automation was acquired by Hitachi, Ltd. In a strategic effort towards offering a seamless connection between the physical and cyber space for industrial manufacturers and distributers worldwide. With this partnership, JR Automation provides customers a unique, single-source solution for complete integration of their physical assets and data information, offering greater speed, flexibility, and efficiencies towards achieving their Industry 4.0 visions. JR Automation employs over 2,000 people at 21 manufacturing facilities in North America, Europe, and Asia. For more information, please visit www.jrautomation.com.
About Hitachi, Ltd.Hitachi drives Social Innovation Business, creating a sustainable society through the use of data and technology. We solve customers’ and society’s challenges with Lumada solutions leveraging IT, OT (Operational Technology) and products. Hitachi operates under the 3 business sectors of “Digital Systems & Services” – supporting our customers’ digital transformation; “Green Energy & Mobility” – contributing to a decarbonized society through energy and railway systems, and “Connective Industries” – connecting products through digital technology to provide solutions in various industries. Driven by Digital, Green, and Innovation, we aim for growth through co-creation with our customers. The company’s revenues as 3 sectors for fiscal year 2023 (ended March 31, 2024) totaled 8,564.3 billion yen, with 573 consolidated subsidiaries and approximately 270,000 employees worldwide. For more information on Hitachi, please visit the company’s website at https://www.hitachi.com.
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Artificial Intelligence
$10 million Artificial Intelligence Mathematical Olympiad Prize appoints further advisory committee members
D. Sculley, Kevin Buzzard, Leo de Moura, Lester Mackey and Peter J. Liu appointed to the advisory committee for the Artificial Intelligence Mathematical Olympiad Prize.
LONDON, April 26, 2024 /PRNewswire/ — XTX Markets’ newly created Artificial Intelligence Mathematical Olympiad Prize (‘AIMO Prize’) is a $10mn challenge fund designed to spur the creation of a publicly shared AI model capable of winning a gold medal in the International Mathematical Olympiad (IMO).
XTX Markets is delighted to announce the appointment of five further advisory committee members. This group brings great expertise in machine learning, including D. Sculley, the CEO of Kaggle; Lester Mackey, a Principal Researcher at Microsoft Research and a Macarthur Fellow; and Peter J. Liu, a research scientist at Google DeepMind.
Prolific mathematicians Kevin Buzzard, who achieved a perfect score in the International Mathematical Olympiad, and Leo De Moura who is the Chief Architect for Lean, the automated reasoning tool, also join the advisory group.
They join the existing advisory committee members Terence Tao and Timothy Gowers, both winners of the Fields Medal, as well as Dan Roberts, Geoff Smith and Po-Shen Loh.
The AIMO Advisory Committee will support the development of the AIMO Prize, including advising on appropriate protocols and technical aspects, and designing the various competitions and prizes.
Simon Coyle, Head of Philanthropy at XTX Markets, commented:
“We are thrilled to complete the AIMO Advisory Committee with the appointments of D., Kevin, Leo, Lester and Peter. Together, they have enormous experience in machine learning and automated reasoning and are already bringing expertise and wisdom to the AIMO Prize. We look forward to announcing the winners of the AIMO’s first Progress Prize soon, and then publicly sharing the AI models to support the open and collaborative development of AI.”
Further information on the AIMO Prize
There will be a grand prize of $5mn for the first publicly shared AI model to enter an AIMO approved competition and perform at a standard equivalent to a gold medal in the IMO. There will also be a series of progress prizes, totalling up to $5mn, for publicly shared AI models that achieve key milestones towards the grand prize.
The first AIMO approved competition opened to participants in April 2024 on the Kaggle competition platform. The first progress prize focuses on problems pitched at junior and high-school level maths competitions. There is a total prize pot of $1.048m for the first progress prize, of which at least $254k will be awarded in July 2024, There will be a presentation of progress held in Bath, England in July 2024, as part of the 65th IMO.
For more information on the AIMO Prize visit: https://aimoprize.com/ or the competition page on Kaggle: https://www.kaggle.com/competitions/ai-mathematical-olympiad-prize/
Advisory Committee member profiles:
D. Sculley
D. is the CEO at Kaggle. Prior to joining Kaggle, he was a director at Google Brain, leading research teams working on robust, responsible, reliable and efficient ML and AI. In his career in ML, he has worked on nearly every aspect of machine learning, and has led both product and research teams including those on some of the most challenging business problems. Some of his well-known work involves ML technical debt, ML education, ML robustness, production-critical ML, and ML for scientific applications such as protein design.
Kevin Buzzard
Kevin a professor of pure mathematics at Imperial College London, specialising in algebraic number theory. As well as his research and teaching, he has a wide range of interests, including being Deputy Head of Pure Mathematics, Co-Director of a CDT and the department’s outreach champion. He is currently focusing on formal proof verification, including being an active participant in the Lean community. From October 2024, he will be leading a project to formalise a 21st century proof of Fermat’s Last Theorem. Before joining Imperial, some 20 years ago, he was a Junior Research Fellow at the University of Cambridge, where he had previously been named ‘Senior Wrangler’ (the highest scoring undergraduate mathematician). He was also a participant in the International Mathematical Olympiad, winning gold with a perfect score in 1987. He has been a visitor at the IAS in Princeton, a visiting lecturer at Harvard, has won several prizes both for research and teaching, and has given lectures all over the world.
Leo de Moura
Leo is a Senior Principal Applied Scientist in the Automated Reasoning Group at AWS. In his spare time, he dedicates himself to serving as the Chief Architect of the Lean FRO, a non-profit organization that he proudly co-founded alongside Sebastian Ullrich. He is also honoured to hold a position on the Board of Directors at the Lean FRO, where he actively contributes to its growth and development. Before joining AWS in 2023, he was a Senior Principal Researcher in the RiSE group at Microsoft Research, where he worked for 17 years starting in 2006. Prior to that, he worked as a Computer Scientist at SRI International. His research areas are automated reasoning, theorem proving, decision procedures, SAT and SMT. He is the main architect of several automated reasoning tools: Lean, Z3, Yices 1.0 and SAL. Leo’s work in automated reasoning has been acknowledged with a series of prestigious awards, including the CAV, Haifa, and Herbrand awards, as well as the Programming Languages Software Award by the ACM. Leo’s work has also been reported in the New York Times and many popular science magazines such as Wired, Quanta, and Nature News.
Lester Mackey
Lester Mackey is a Principal Researcher at Microsoft Research, where he develops machine learning methods, models, and theory for large-scale learning tasks driven by applications from climate forecasting, healthcare, and the social good. Lester moved to Microsoft from Stanford University, where he was an assistant professor of Statistics and, by courtesy, of Computer Science. He earned his PhD in Computer Science and MA in Statistics from UC Berkeley and his BSE in Computer Science from Princeton University. He co-organized the second place team in the Netflix Prize competition for collaborative filtering; won the Prize4Life ALS disease progression prediction challenge; won prizes for temperature and precipitation forecasting in the yearlong real-time Subseasonal Climate Forecast Rodeo; and received best paper, outstanding paper, and best student paper awards from the ACM Conference on Programming Language Design and Implementation, the Conference on Neural Information Processing Systems, and the International Conference on Machine Learning. He is a 2023 MacArthur Fellow, a Fellow of the Institute of Mathematical Statistics, an elected member of the COPSS Leadership Academy, and the recipient of the 2023 Ethel Newbold Prize.
Peter J. Liu
Peter J. Liu is a Research Scientist at Google DeepMind in the San Francisco Bay area, doing machine learning research with a specialisation in language models since 2015 starting in the Google Brain team. He has published and served as area chair in top machine learning and NLP conferences such as ICLR, ICML, NEURIPS, ACL and EMNLP. He also has extensive production experience, including launching the first deep learning model for Gmail Anti-Spam, and using neural network models to detect financial fraud for top banks. He has degrees in Mathematics and Computer Science from the University of Toronto.
About XTX Markets:
XTX Markets is a leading financial technology firm which partners with counterparties, exchanges and e-trading venues globally to provide liquidity in the Equity, FX, Fixed Income and Commodity markets. XTX has over 200 employees based in London, Paris, New York, Mumbai, Yerevan and Singapore. XTX is consistently a top 5 liquidity provider globally in FX (Euromoney 2018-present) and is also the largest European equities (systematic internaliser) liquidity provider (Rosenblatt FY: 2020-2023).
The company’s corporate philanthropy focuses on STEM education and maximum impact giving (alongside an employee matching programme). Since 2017, XTX has donated over £100mn to charities and good causes, establishing it as a major donor in the UK and globally.
In a changing world XTX Markets is at the forefront of making financial markets fairer and more efficient for all.
View original content:https://www.prnewswire.co.uk/news-releases/10-million-artificial-intelligence-mathematical-olympiad-prize-appoints-further-advisory-committee-members-302128542.html
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