Lithium Niobate Modulator Market , by Type (10 GHz, 20 GHz, 40 GHz, Others), Wavelength Window (800 NM, 1060 NM, 1300 NM, 1550 NM, Others), Application (Phase Keyed Optical Communication, Coherent Communication Links, Spectrum Broadening, Interferometric Sensing, Quantum Key Distribution, Others), End-Use (IT and Telecom, Aerospace and Defense, Industrial, Research, Others), Regional Analysis (North America, Europe, Asia-Pacific, LAMEA): Global Opportunity Analysis and Industry Forecast, 2019–2026
- RES4072030
- 240 Pages
- January 2020
- Semiconductor and Electronics
Market Definition:
Lithium niobate is a complex of lithium, niobate and oxygen. lithium niobate single crystals are significant material for piezoelectric sensors, mobile phones, optical modulators and optical wave guides. The lithium niobate modulators are considered the strength of the modern telecommunication. These modulators are advanced for digital & analog signal process, optical computing and communication.
Market Drivers:
Lithium niobate modulator market drivers: The global lithium niobate modulator was valued at $6,538.0 million in 2018, is projected to reach $36,711.3 million and at a CAGR of 24.0% during forecast period. This is due to rise in the utilization of lithium niobate modulators in aerospace & defense and IT & Telecom sectors. Majority of the IT & Telecom sector uses these modulators as key device for mobile networks and LAN services to deliver higher data rate. Furthermore, the lithium niobate modulator is major commination device for television broadcasting and digital communication services. Lithium niobate modulator is considered most mature and reliable technology in aerospace and defense sector. Lithium niobate modulator transfer the data with high secure and it is used for longer distance transmissions and optical fiber communication. These aspects are projected to drive the lithium niobate modulator market growth in the aerospace and defense sector.
Market Restraints:
The major restraint for the growth of the lithium niobate modulator market is price of the modulator. The cost of these modulators is high compared to other modulators, this leads to majority of the buyers are transferring to other modulators.
Market Opportunities:
Lithium niobate modulators have been used in telecommunications, but due to swift industrialization and developments in communication are increasing the use in the different sectors, including industrial, IT & Telecom, aerospace and defense and others. Moreover, increasing the preference of lithium niobate based optical fiber for the use in 5G technology is expected to provide major investment opportunities in the lithium niobate modulator market.
Lithium Niobate Modulator Market, by Type
10 GHz segment is predicted to be most lucrative till the end of 2026
Source: Research Analysis
Global lithium niobate modulator market is classified into wavelength window, type, application and end use. on the basis of type, the market is categorized into 10 GHz, 20 GHz, 40 GHz and others. among these, 10 GHz segment is projected to experience substantial growth over the forecast period and account for $11,215.2 million. The market for 20 GHz segment held the global lithium niobate modulator market in 2018, is anticipated to register $12,605.1 million, at a 25.4% CAGR over forecast period. This is due to their extensive usage in satellite radio communication, microwave communication devices and TV & cable broadcasting services.
Lithium Niobate Modulator Market, by Wavelength Window
1060 NM segment is predicted to be most lucrative till the end of 2026
Source: Research Analysis
On the basis of wavelength window, the market is classified into 800 NM, 1060 NM, 1300 NM, 1550 NM and others. 1550 NM modulator market registered key market share in 2018, accounted for $2,721.6 million, owing to demands from the digital communication sector. additionally, the market for 1060 NM modulator will experience significant growth in the coming years, this is owing to these modulators deliver analog transmissions and pulse generation in the optical fiber communication.
Lithium Niobate Modulator Market, by End-Use
IT & Telecom segment is will grow at a CAGR of 25.1% during the projected period
Source: Research Analysis
On the basis of end use, aerospace & defense segment will experience notable growth rate, is expected to register for $9,100.4 million by the end of 2026. The lithium niobate modulator market for IT & Telecom sector is accounted for the highest market value in 2018 and valued at $2,341.6 million, and is anticipated to account for $14,070.8 million by the end of 2026, owing to the rise in demands from optical fiber industry for high-frequency modulators and higher data speeds.
Lithium Niobate Modulator Market, by Application
Interferometric sensing segment will grow at a CAGR of 26.0% during the projected period
Source: Research Analysis
On the basis on application, the interferometric sensing led the market and is project to register for $8,391.4 million by 2026 and is increasing from $1,318.9 million in 2018, owing to rise in usage of lithium niobate modulator in field sensor devices. The keyed optical communication sector accounted for the major lithium niobate modulator market share in 2018, is anticipated to reach $9710.5 million, at a CAGR of 24.3% during forecast period. The lithium niobate modulators are place a major role in the communication from airplane to ground level.
Lithium Niobate Modulator Market, by Region:
Asia Pacific region will have enormous opportunities for the market investors to grow over the coming years
The global lithium niobate modulator market is dominated by North America and is expected to reach $14,394.7 million by 2026, and is rising from $2,364.5 million in 2018, owing to the existence of developed countries and mobile network services was increased by 10.7% as compared to the 2018. Therefore, there is increase demands from optic-electric fiber modulator market to provide high speed data networks.
The market for Asia-Pacific is projected to experience rapid development in the lithium niobate modulator market and is expected to account for $7,856.3 million in the coming years. This is owing to the surge in the demands from communication sector for VoLTE & 5G network and wireless LAN services. Japan, China and India are major developing economies and generate highest revenue in the Asia-Pacific.
Key participants in Global Lithium Niobate Modulator Market:
Product development and joint ventures are the most common strategies followed by the market players
Source: Research Dive Analysis
The top key players in the global market are Lumentum Operations LLC, Gooch & House plc, Fabrinet Inc., Fujitsu Optical Components Ltd, EOSPACE, Inc. THORLABS, iXblue Group, and Beijing Panwoo Integrated Optoelectronic Inc. These key players are majorly concentrating some of the approaches such as geographical expansion, new advancements in technology and mergers & acquisitions in order to gain highest lithium niobate modulator market size in the global market. For example, iXblue group is launched new product for navigation for U.S. navy “Integrated Bridge and Navigation System (IBNS)”, which provides the positioning of war ships and underwater images of submarines.
Aspect Particulars
Historical Market Estimations 2016-2018
Base Year for Market Estimation 2018
Forecast timeline for Market Projection 2019-2026
Geographical Scope North America, Europe, Asia-Pacific, LAMEA
Segmentation by Type • 10 GHz
• 20 GHz
• 40 GHz
• Others
By Wavelength Window
• 800 NM
• 1060 NM
• 1300 NM
• 1550 NM
• Others
By Application
• Phase Keyed Optical Communications
• Coherent Communication Links
• Spectrum Broadening
• Interferometric Sensing
• Quantum Key Distribution
• Others
By End-use
• IT and Telecom
• Aerospace and Defense
• Industrial
• Research
• Others
Key Countries covered U.S., Canada, Mexico, Germany, UK, Italy, Spain, Russia, Japan, China, India, South Korea, Australia, Brazil, South Africa and Saudi Arabia
Key Companies Profiled • iXblue Group
• Gooch & Housego plc
• Fujitsu Optical Components Ltd
• THORLABS
• Beijing Panwoo Integrated ptoelectronic Inc.
• Fabrinet Inc.
• Lumentum Operations LLC
• EOSPACE, Inc.
1.1. Desk Research
1.2. Real time insights and validation
1.3. Forecast model
1.4. Assumptions and forecast parameters
1.4.1. Assumptions
1.4.2. Forecast parameters
1.5. Data sources
1.5.1. Primary
1.5.2. Secondary
2. Executive Summary
2.1. 360° summary
2.2. Type trends
2.3. Wavelength window trends
2.4. End-use trends
2.5. Application trends
3. Market overview
3.1. Market segmentation & definitions
3.2. Key takeaways
3.2.1. Top investment pockets
3.2.2. Top winning strategies
3.3. Porter’s five forces analysis
3.3.1. Bargaining power of consumers
3.3.2. Bargaining power of suppliers
3.3.3. Threat of new entrants
3.3.4. Threat of substitutes
3.3.5. Competitive rivalry in the market
3.4. Market dynamics
3.4.1. Drivers
3.4.2. Restraints
3.4.3. Opportunities
3.5. Technology landscape
3.6. Regulatory landscape
3.7. Patent landscape
3.8. Pricing overview
3.8.1. By type
3.8.2. By wavelength window
3.8.3. By end-use
3.8.4. By application
3.8.5. By region
3.9. Market value chain analysis
3.9.1. Stress point analysis
3.9.2. Raw material analysis
3.9.3. Manufacturing process
3.9.4. Distribution channel analysis
3.9.5. Operating vendors
3.9.5.1. Raw material suppliers
3.9.5.2. Product manufacturers
3.9.5.3. Product distributors
3.10. Strategic overview
4. Lithium Niobate Modulator Market, by Type
4.1. 10 GHz
4.1.1. Market size and forecast, by region, 2018-2026
4.1.2. Comparative market share analysis, 2018 & 2026
4.2. 20 GHz
4.2.1. Market size and forecast, by region, 2018-2026
4.2.2. Comparative market share analysis, 2018 & 2026
4.3. 40 GHz
4.3.1. Market size and forecast, by region, 2018-2026
4.3.2. Comparative market share analysis, 2018 & 2026
4.4. Others
4.4.1. Market size and forecast, by region, 2018-2026
4.4.2. Comparative market share analysis, 2018 & 2026
5. Lithium Niobate Modulator Market, by Wavelength window
5.1. 800 NM
5.1.1. Market size and forecast, by region, 2018-2026
5.1.2. Comparative market share analysis, 2018 & 2026
5.2. 1060 NM
5.2.1. Market size and forecast, by region, 2018-2026
5.2.2. Comparative market share analysis, 2018 & 2026
5.3. 1300 NM
5.3.1. Market size and forecast, by region, 2018-2026
5.3.2. Comparative market share analysis, 2018 & 2026
5.4. 1550 NM
5.4.1. Market size and forecast, by region, 2018-2026
5.4.2. Comparative market share analysis, 2018 & 2026
5.5. Others
5.5.1. Market size and forecast, by region, 2018-2026
5.5.2. Comparative market share analysis, 2018 & 2026
6. Lithium Niobate Modulator Market, by End-use
6.1. IT and Telecom
6.1.1. Market size and forecast, by region, 2018-2026
6.1.2. Comparative market share analysis, 2018 & 2026
6.2. Aerospace and Defense
6.2.1. Market size and forecast, by region, 2018-2026
6.2.2. Comparative market share analysis, 2018 & 2026
6.3. Industrial
6.3.1. Market size and forecast, by region, 2018-2026
6.3.2. Comparative market share analysis, 2018 & 2026
6.4. Research
6.4.1. Market size and forecast, by region, 2018-2026
6.4.2. Comparative market share analysis, 2018 & 2026
6.5. Others
6.5.1. Market size and forecast, by region, 2018-2026
6.5.2. Comparative market share analysis, 2018 & 2026
7. Lithium Niobate Modulator Market, by Application
7.1. Phased keyed optical communication
7.1.1. Market size and forecast, by region, 2018-2026
7.1.2. Comparative market share analysis, 2018 & 2026
7.2. Spectrum broadening
7.2.1. Market size and forecast, by region, 2018-2026
7.2.2. Comparative market share analysis, 2018 & 2026
7.3. Interferometric sensing
7.3.1. Market size and forecast, by region, 2018-2026
7.3.2. Comparative market share analysis, 2018 & 2026
7.4. Quantum key distribution
7.4.1. Market size and forecast, by region, 2018-2026
7.4.2. Comparative market share analysis, 2018 & 2026
7.5. Others
7.5.1. Market size and forecast, by region, 2018-2026
7.5.2. Comparative market share analysis, 2018 & 2026
8. Lithium Niobate Modulator Market, by Region
8.1. North America
8.1.1. Market size and forecast, by type, 2018-2026
8.1.2. Market size and forecast, by wavelength window, 2018-2026
8.1.3. Market size and forecast, by end-use, 2018-2026
8.1.4. Market size and forecast, by application, 2018-2026
8.1.5. Market size and forecast, by country, 2018-2026
8.1.6. Comparative market share analysis, 2018 & 2026
8.1.7. U.S.
8.1.7.1. Market size and forecast, by type, 2018-2026
8.1.7.2. Market size and forecast, by wavelength window, 2018-2026
8.1.7.3. Market size and forecast, by end-use, 2018-2026
8.1.7.4. Market size and forecast, by application, 2018-2026
8.1.7.5. Comparative market share analysis, 2018 & 2026
8.1.8. Canada
8.1.8.1. Market size and forecast, by type, 2018-2026
8.1.8.2. Market size and forecast, by wavelength window, 2018-2026
8.1.8.3. Market size and forecast, by end-use, 2018-2026
8.1.8.4. Market size and forecast, by application, 2018-2026
8.1.8.5. Comparative market share analysis, 2018 & 2026
8.1.9. Mexico
8.1.9.1. Market size and forecast, by type, 2018-2026
8.1.9.2. Market size and forecast, by wavelength window, 2018-2026
8.1.9.3. Market size and forecast, by end-use, 2018-2026
8.1.9.4. Market size and forecast, by application, 2018-2026
8.1.9.5. Comparative market share analysis, 2018 & 2026
8.2. Europe
8.2.1. Market size and forecast, by type, 2018-2026
8.2.2. Market size and forecast, by wavelength window, 2018-2026
8.2.3. Market size and forecast, by end-use, 2018-2026
8.2.4. Market size and forecast, by application, 2018-2026
8.2.5. Market size and forecast, by country, 2018-2026
8.2.6. Comparative market share analysis, 2018 & 2026
8.2.7. UK
8.2.7.1. Market size and forecast, by type, 2018-2026
8.2.7.2. Market size and forecast, by wavelength window, 2018-2026
8.2.7.3. Market size and forecast, by end-use, 2018-2026
8.2.7.4. Market size and forecast, by application, 2018-2026
8.2.7.5. Comparative market share analysis, 2018 & 2026
8.2.8. Germany
8.2.8.1. Market size and forecast, by type, 2018-2026
8.2.8.2. Market size and forecast, by wavelength window, 2018-2026
8.2.8.3. Market size and forecast, by end-use, 2018-2026
8.2.8.4. Market size and forecast, by application, 2018-2026
8.2.8.5. Comparative market share analysis, 2018 & 2026
8.2.9. France
8.2.9.1. Market size and forecast, by type, 2018-2026
8.2.9.2. Market size and forecast, by wavelength window, 2018-2026
8.2.9.3. Market size and forecast, by end-use, 2018-2026
8.2.9.4. Market size and forecast, by application, 2018-2026
8.2.9.5. Comparative market share analysis, 2018 & 2026
8.2.10. Russia
8.2.10.1. Market size and forecast, by type, 2018-2026
8.2.10.2. Market size and forecast, by wavelength window, 2018-2026
8.2.10.3. Market size and forecast, by end-use, 2018-2026
8.2.10.4. Market size and forecast, by application, 2018-2026
8.2.10.5. Comparative market share analysis, 2018 & 2026
8.2.11. Rest of Europe
8.2.11.1. Market size and forecast, by type, 2018-2026
8.2.11.2. Market size and forecast, by wavelength window, 2018-2026
8.2.11.3. Market size and forecast, by end-use, 2018-2026
8.2.11.4. Market size and forecast, by application, 2018-2026
8.2.11.5. Comparative market share analysis, 2018 & 2026
8.3. Asia Pacific
8.3.1. Market size and forecast, by type, 2018-2026
8.3.2. Market size and forecast, by wavelength window, 2018-2026
8.3.3. Market size and forecast, by end-use, 2018-2026
8.3.4. Market size and forecast, by application, 2018-2026
8.3.5. Market size and forecast, by country, 2018-2026
8.3.6. Comparative market share analysis, 2018 & 2026
8.3.7. China
8.3.7.1. Market size and forecast, by type, 2018-2026
8.3.7.2. Market size and forecast, by wavelength window, 2018-2026
8.3.7.3. Market size and forecast, by end-use, 2018-2026
8.3.7.4. Market size and forecast, by application, 2018-2026
8.3.7.5. Comparative market share analysis, 2018 & 2026
8.3.8. India
8.3.8.1. Market size and forecast, by type, 2018-2026
8.3.8.2. Market size and forecast, by wavelength window, 2018-2026
8.3.8.3. Market size and forecast, by end-use, 2018-2026
8.3.8.4. Market size and forecast, by application, 2018-2026
8.3.8.5. Comparative market share analysis, 2018 & 2026
8.3.9. Japan
8.3.9.1. Market size and forecast, by type, 2018-2026
8.3.9.2. Market size and forecast, by wavelength window, 2018-2026
8.3.9.3. Market size and forecast, by end-use, 2018-2026
8.3.9.4. Market size and forecast, by application, 2018-2026
8.3.9.5. Comparative market share analysis, 2018 & 2026
8.3.10. Australia
8.3.10.1. Market size and forecast, by type, 2018-2026
8.3.10.2. Market size and forecast, by wavelength window, 2018-2026
8.3.10.3. Market size and forecast, by end-use, 2018-2026
8.3.10.4. Market size and forecast, by application, 2018-2026
8.3.10.5. Comparative market share analysis, 2018 & 2026
8.3.11. Rest of Asia Pacific
8.3.11.1. Market size and forecast, by type, 2018-2026
8.3.11.2. Market size and forecast, by wavelength window, 2018-2026
8.3.11.3. Market size and forecast, by end-use, 2018-2026
8.3.11.4. Market size and forecast, by application, 2018-2026
8.3.11.5. Comparative market share analysis, 2018 & 2026
8.4. LAMEA
8.4.1. Market size and forecast, by type, 2018-2026
8.4.2. Market size and forecast, by wavelength window, 2018-2026
8.4.3. Market size and forecast, by end-use, 2018-2026
8.4.4. Market size and forecast, by application, 2018-2026
8.4.5. Market size and forecast, by country, 2018-2026
8.4.6. Comparative market share analysis, 2018 & 2026
8.4.7. Latin America
8.4.7.1. Market size and forecast, by type, 2018-2026
8.4.7.2. Market size and forecast, by wavelength window, 2018-2026
8.4.7.3. Market size and forecast, by end-use, 2018-2026
8.4.7.4. Market size and forecast, by application, 2018-2026
8.4.7.5. Comparative market share analysis, 2018 & 2026
8.4.8. Middle East
8.4.8.1. Market size and forecast, by type, 2018-2026
8.4.8.2. Market size and forecast, by wavelength window, 2018-2026
8.4.8.3. Market size and forecast, by end-use, 2018-2026
8.4.8.4. Market size and forecast, by application, 2018-2026
8.4.8.5. Comparative market share analysis, 2018 & 2026
8.4.9. Africa
8.4.9.1. Market size and forecast, by type, 2018-2026
8.4.9.2. Market size and forecast, by wavelength window, 2018-2026
8.4.9.3. Market size and forecast, by end-use, 2018-2026
8.4.9.4. Market size and forecast, by application, 2018-2026
8.4.9.5. Comparative market share analysis, 2018 & 2026
9. Company profiles
9.1. FUJITSU OPTICAL COMPONENTS LIMITED
9.1.1. Business overview
9.1.2. Financial performance
9.1.3. Product portfolio
9.1.4. Recent strategic moves & developments
9.1.5. SWOT analysis
9.2. THORLABS, INC.
9.2.1. Business overview
9.2.2. Financial performance
9.2.3. Product portfolio
9.2.4. Recent strategic moves & developments
9.2.5. SWOT analysis
9.3. LUMENTUM OPERATIONS LLC
9.3.1. Business overview
9.3.2. Financial performance
9.3.3. Product portfolio
9.3.4. Recent strategic moves & developments
9.3.5. SWOT analysis
9.4. BEIJING PANWOO INTEGRATED OPTOELECTRONIC INC.
9.4.1. Business overview
9.4.2. Financial performance
9.4.3. Product portfolio
9.4.4. Recent strategic moves & developments
9.4.5. SWOT analysis
9.5. EOSPACE INC.
9.5.1. Business overview
9.5.2. Financial performance
9.5.3. Product portfolio
9.5.4. Recent strategic moves & developments
9.5.5. SWOT analysis
9.6. GOOCH & HOUSEGO PLC
9.6.1. Business overview
9.6.2. Financial performance
9.6.3. Product portfolio
9.6.4. Recent strategic moves & developments
9.6.5. SWOT analysis
9.7. FABRINET INC.
9.7.1. Business overview
9.7.2. Financial performance
9.7.3. Product portfolio
9.7.4. Recent strategic moves & developments
9.7.5. SWOT analysis
9.8. IXBLUE GROUP
9.8.1. Business overview
9.8.2. Financial performance
9.8.3. Product portfolio
9.8.4. Recent strategic moves & developments
9.8.5. SWOT analysis
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