Toll Free : + 1-888-961-4454 | Int'l : + 91 (788) 802-9103 | support@researchdive.com
SE200242 |
Pages: 225 |
May 2022 |
The lithium niobate market is heavily influenced by telecommunication applications; it makes a significant contribution to the value of optical networks through component interconnection. Because network security is so important in modern communications, lithium niobate is used to integrate diverse routing via spatial switches. As a result, the lithium niobate modulator is primarily considered because of its high modulation rate and robustness. Lithium niobate-based electro-optical modulates signal to facilitate deep interconnection in sectors distributed deep beneath. As a result, an electro-optical modulation technique has recognized as a crucial component of the communication network. These optical fibers are ideal for use in the army, industrial, cable tv, and utility sectors because they provide electrical isolation, data security, and electromagnetic interference.
Lithium niobate sensors are used in industrial automation to increase productivity and efficiency because of their short wavelengths loss and large electrical coefficients properties, which make them responsive even in tiny areas. The tremendous growth of remote monitoring and proactive maintenance in industry sectors is expected to open new growth opportunities for sensing devices, catapulting the global lithium niobate modulator market during the forecast period.
The cost of the modulator is a major restraint on the global lithium niobate modulator market. The price of the lithium niobate modulator is very high when compared to other modulators; as a result, most consumers are unable to use these products in their communication.
According to regional analysis, the Asia-Pacific lithium niobate modulator market accounted for $750.3 million in 2021 and is predicted to grow with a CAGR of 7.76%, in the projected timeframe owing to rising lithium niobate modulator demand across the region.
Lithium niobate has nonlinear optical, photorefractive, piezoresistive, and electrical properties that are not found in other materials. It is defined as electrical substances and is used for crystal increasing techniques that aid in the production of large crystalline of high perfection on a consistent basis. Its unique combination of acousto-optics, nonlinear optical, and electro-optical properties makes it an appealing application for integrated optic fiber. It is a supporting system for the advanced electronics and telecommunications industries, and it plays an important role in converting electronic data to optical information on fiber optic systems. Sensors, optical waveguides, optical modulators, and mobile phones all use lithium niobate.
A lithium niobate modulator is an electrical gadget that modifies an optical light source using a sound wave element with just an electro-optic impact. Modulators made of lithium niobate are used to change the battery powered properties of a material including such magnitude, phase, placement, and intensity. They find wide applications in optical computer science, digital & analogue data processing, and communications.
The COVID-19 pandemic has had an impact on all aspects of society, including individuals and businesses. The internet ecosystem has played a critical role all over the world. The reliance on online businesses has grown significantly as a result of the COVID-19 pandemic. In the midst of the Covid-19 pandemic, the nation's biggest investors started focusing just on internet infrastructure market, citing a strong market for wealth to boost the data economic system. The emergence of massively scalable computer science had also increased global knowledge in data centers. High-speed serial transmitters and modulators, which form the backbone of networks such as the internet, are used in communication systems, servers, and other electronic systems.
Furthermore, widespread shift to work-from-home policies as a result of the COVID-19 pandemic has resulted in a massive increase in global lithium niobate modulators as they are electro optic devices that use a signal controlled element which exhibits an electro-optic effect to modulate optical beam. The basic knowledge behind these modulators is to modify the electric-optical properties of a material such as amplitude, phase, position and frequency. Lithium modulators are developed for the use in optical computing, digital & analog signal processing, and communications. All such factors may increase the market's long-term survival in the coming years.
Lithium modulators have significant growth in the communication sector for use in wireless LAN services, 3G, and VoLTE networks to provide high speed internet services. In addition, there has been an increased demand for lithium niobate integrated modulators from the developed and developing economies as modulator is strong communication tool for the digital communication, broadcasting, and analog data transition services. In aerospace & defense, the lithium niobate modulator technology is most reliable and mature technology and these modulators are used for fiber optic communication and longer distances transmissions. These factors are anticipated to drive the lithium niobate modulator market growth in the aerospace & defense sector.
Furthermore, in defense and aerospace industries, lithium niobate modulators have been used in wireless network equipment, satellite connectivity, and advanced radar systems. These modulators are being used to track unnamed aircraft as well as ships that use the radar detection system. Lithium niobate modulators are used in telecommunication and digital communications systems, and their integration in the IT and telecom sectors is growing. To provide continuous internet access, lithium niobate modulation schemes are used in interconnection breakthroughs such as 5G internet and mobile networking. As a result, technological advancements and the deployment of 5G data network in the telecommunications field are expected to offer lucrative opportunities for the lithium niobate modulator market.
To know more about global lithium niobate modulator market trends, get in touch with our analysts here.
The cost of the modulator is a major restraint on the global lithium niobate modulator market. The price of the lithium niobate modulator is very high when compared to other modulators; as a result, most consumers are unable to use these products in their communication. Due to the high price, the customers turn towards alternative modulators, the costs of the lithium niobate modulatory might hamper the lithium niobate modulator market growth during the forecast period.
Lithium niobate modulators were previously used in telecommunication however, technological advancements and rapid industrialization in the lithium niobate modulator market have increased the modulators' use in a variety of sectors including communication sector developments such as 5G technology and digital communication to provide continuous internet services. The global increase in data consumption and improvement in network coverage have fueled the demand for lithium niobate modulator. The 5th generation wireless network is expected to be the next technological leap because it can transmit more data while maintaining a more stable and reliable connection. This, in turn, is expected to drive growth in the market for lithium niobate modulator.
Furthermore, rapidly increasing expenditure on 5G infrastructure and applications due to a shift in customer choice toward upcoming technologies and smart phones is one of the major factors determining this industry. Both these potential factors driving future growth include an increase in mobile subscribers, a huge influx in market for high data connectivity, and an increase in demand for valuation managed services. Over the last few centuries, the worldwide communications system has undoubtedly been one of the most important locations for continued technological advancements. All such aspects may further lead to lucrative market opportunities for key players in the upcoming years.
To know more about global lithium niobate modulator market trends, get in touch with our analysts here.
Based on type, the market is classified into 10 GHz, 20 GHz, 40 GHz, and others. In these, the 20 GHz modulator market registered the dominating market share in 2021.
Source: Research Dive Analysis
In 2021, the global 20 GHz modulator market had a dominant market share and is expected to generate a revenue of $2,235.1 million by 2030, growing from $1,290.5 million in 2021. The wide usage of 20 GHz modulator in television broadcasting, microwave devices, and satellite radio services is expected to drive the market growth. 20 GHz modulator is an integrated component that overlays a low-frequency (data) signal onto an elevated (carrier) signal in order to transfer wireless data. It is because high frequencies signals can be received with shorter aerial attacks, which are much more practical than slightly longer. Analog or digital information signals can be used. 20 GHz modulator overlaid the digital signals on top of the carrier signal by changing one of the carrier's properties, such as magnitude, frequency, or process. All these factors are estimated to drive the adoption of 20 GHz during the forecast period.
By wavelength window, the lithium niobate modulator market is categorized into 800 NM, 1060 NM, 1300 NM, 1550 NM, and others. Among these, the 1550 NM sub-segment was the highest contributor to the lithium niobate modulator market in 2021.
Source: Research Dive Analysis
The 1550 NM sub-segment is anticipated to dominate the market during the forecast period and generate a revenue of $2,591.8 million by 2030, growing from $1,512.3 million in 2021, with a CAGR of 6.42%. This is due to rise in the usage of 1550 NM modulator in digital communication and Rayleigh scattering & infrared absorption are in the range of 1550 NM wavelength band. The 1550 NM modulator has a low insertion loss, a high bandwidth, a low half-wave voltage, and good optical power damage characteristics. Its high-speed optical communication system is primarily used for lighting systems, phase difference of cohesive communication systems, sideband ROF systems, and to decrease the simulation of optical fiber communication systems. These types of factors are predicted to drive the growth of the market.
Based on application, the market has been divided into phase keyed optical communications, spectrum broadening, interferometric sensing, quantum key distribution, and others. Among these, phase keyed optical communication sub-segment held the majority of the lithium niobate modulator market share in 2021.
Source: Research Dive Analysis
The phase keyed optical communications sub-segment is anticipated to have a dominant market share and generate a revenue of $1,622.0 million by 2030, growing from $958.0 million in 2021. Phase keyed optical communication is a digitally modulated procedure that sends information by modifying (modulating) this same phase of a fixed frequency reference signal (the carrier wave). Modulation is obtained by modifying the sum and trigonometric functions inputs at particular times. It is common in wireless LANs, and Wifi communication. To depict digital data, any digital modulation technique utilizes a finite number of different signals. Phase keyed optical communication employs a limited number of phases, each with its own distinctive form of binary code. Each phase typically encodes an equal number of bits. Each bit pattern forms the symbol represented by the particular phase. The phase of the received signal is determined by the demodulator, which is specially designed for the emblem used by the modulator. All such elements may increase the demand for sub-segment and lithium niobate modulator market demand.
Based on end-use, the market has been divided into IT & telecom, aerospace & defense, industrial, research, and others. Among these, IT & telecom sub-segment held the majority of the lithium niobate modulator market share in 2021.
Source: Research Dive Analysis
The IT & telecom sub-segment is anticipated to have a dominant market share and generate a revenue of $2,394.9 million by 2030, growing from $1,326.0 million in 2021. This growth in the market can be attributed to the adoption of lithium niobate based optical fiber modulators for use in wireless LAN and mobile network services. As business owners keep expanding their wireless infrastructure that supports venture mobility, the lithium niobate modulator market is exhibiting rapid growth in the adoption of sophisticated enterprise WLAN systems. Enterprise WLAN infrastructure is heavily used to support the constantly changing and unpredictable business requirements, such as high bandwidth and low latency, as well as business-critical applications. According to the Ericsson Mobility Report, November 2020, over 200 service providers have launched Fixed Wireless Access (FWA) services, opening up new market opportunities for lithium niobate modulator. All such elements may increase the demand for sub-segment and lithium niobate modulator market demand.
The lithium niobate modulator market was inspected across North America, Europe, Asia-Pacific, and LAMEA.
Source: Research Dive Analysis
North America lithium niobate modulator market is the dominant region market, and it is expected to generate $2,492.7 million in 2030, growing from $1,478.3 million in 2021. This is due to the upsurge in lithium niobate modulator market majorly in developed economies such as the U.S. and Canada. The growth is majorly due to the increase in the use of lithium niobate modulator in optical fiber market for higher data rates and good compatibility. Increased research & development efforts, the introduction of technologies, as well as expense methods for lithium niobate modulators are expected to dominate the growth lithium niobate modulator market. Furthermore, excess supply for lithium niobate modulators in developing and underdeveloped nations for digital communication, transmitting, and analogue information set of processes & practices is primarily driving North America lithium niobate modulator market. The lithium niobate modulator is a highly reliable and efficient innovation used in fiber optic communication and lengthy transmission in the aerospace and defense sectors. These factors boost the North American lithium niobate modulator market.
Source: Research Dive Analysis
Some of the leading lithium niobate modulator market players are iXblue Group, Gooch & House plc, Fujitsu Optical Components Ltd, THORLABS, Beijing Panwoo Integrated Optoelectronic Inc., Fabrinet Inc., Lumentum Operations LLC, and EOSPACE, Inc.
| Aspect | Particulars |
| Historical Market Estimations | 2020-2021 |
| Base Year for Market Estimation | 2021 |
| Forecast Timeline for Market Projection | 2022-2030 |
| Geographical Scope | North America, Europe, Asia-Pacific, LAMEA |
| Segmentation by Type |
|
| Segmentation by Wavelength Window |
|
| Segmentation by Application |
|
| Segmentation by End-use |
|
| Key Companies Profiled |
|
1.Research Methodology
1.1.Desk Research
1.2.Real time insights and validation
1.3.Forecast model
1.4.Assumptions and forecast parameters
1.5.Market size estimation
1.5.1.Top-down approach
1.5.2.Bottom-up approach
2.Report Scope
2.1.Market definition
2.2.Key objectives of the study
2.3.Report overview
2.4.Market segmentation
2.5.Overview of the impact of COVID-19 on Global Lithium Niobate Modulator market
3.Executive Summary
4.Market Overview
4.1.Introduction
4.2.Growth impact forces
4.2.1.Drivers
4.2.2.Restraints
4.2.3.Opportunities
4.3.Market value chain analysis
4.3.1.List of raw material suppliers
4.3.2.List of manufacturers
4.3.3.List of distributors
4.4.Innovation & sustainability matrices
4.4.1.Technology matrix
4.4.2.Regulatory matrix
4.5.Porter’s five forces analysis
4.5.1.Bargaining power of suppliers
4.5.2.Bargaining power of consumers
4.5.3.Threat of substitutes
4.5.4.Threat of new entrants
4.5.5.Competitive rivalry intensity
4.6.PESTLE analysis
4.6.1.Political
4.6.2.Economical
4.6.3.Social
4.6.4.Technological
4.6.5.Environmental
4.7.Impact of COVID-19 on Lithium Niobate Modulator market
4.7.1.Pre-covid market scenario
4.7.2.Post-covid market scenario
5.Lithium Niobate Modulator Market Analysis, by Type
5.1.Overview
5.2.10 GHz
5.2.1.Definition, key trends, growth factors, and opportunities
5.2.2.Market size analysis, by region
5.2.3.Market share analysis, by country
5.3.20 GHz
5.3.1.Definition, key trends, growth factors, and opportunities
5.3.2.Market size analysis, by region
5.3.3.Market share analysis, by country
5.4.40 GHz
5.4.1.Definition, key trends, growth factors, and opportunities
5.4.2.Market size analysis, by region
5.4.3.Market share analysis, by country
5.5.Others
5.5.1.Definition, key trends, growth factors, and opportunities
5.5.2.Market size analysis, by region
5.5.3.Market share analysis, by country
5.6.Research Dive Exclusive Insights
5.6.1.Market attractiveness
5.6.2.Competition heatmap
6.Lithium Niobate Modulator Market Analysis, by Wavelength Window
6.1.800 NM
6.1.1.Definition, key trends, growth factors, and opportunities
6.1.2.Market size analysis, by region
6.1.3.Market share analysis, by country
6.2.1060 NM
6.2.1.Definition, key trends, growth factors, and opportunities
6.2.2.Market size analysis, by region
6.2.3.Market share analysis, by country
6.3.1300 NM
6.3.1.Definition, key trends, growth factors, and opportunities
6.3.2.Market size analysis, by region
6.3.3.Market share analysis, by country
6.4.1550 NM
6.4.1.Definition, key trends, growth factors, and opportunities
6.4.2.Market size analysis, by region
6.4.3.Market share analysis, by country
6.5.Others
6.5.1.Definition, key trends, growth factors, and opportunities
6.5.2.Market size analysis, by region
6.5.3.Market share analysis, by country
6.6.Research Dive Exclusive Insights
6.6.1.Market attractiveness
6.6.2.Competition heatmap
7.Lithium Niobate Modulator Market Analysis, by Application
7.1.Phase Keyed Optical Communications
7.1.1.Definition, key trends, growth factors, and opportunities
7.1.2.Market size analysis, by region
7.1.3.Market share analysis, by country
7.2.Spectrum Broadening
7.2.1.Definition, key trends, growth factors, and opportunities
7.2.2.Market size analysis, by region
7.2.3.Market share analysis, by country
7.3.Interferometric Sensing
7.3.1.Definition, key trends, growth factors, and opportunities
7.3.2.Market size analysis, by region
7.3.3.Market share analysis, by country
7.3.4.Market share analysis, by country
7.4.Quantum Key Distribution
7.4.1.Definition, key trends, growth factors, and opportunities
7.4.2.Market size analysis, by region
7.4.3.Market share analysis, by country
7.4.4.Market share analysis, by country
7.5.Others
7.5.1.Definition, key trends, growth factors, and opportunities
7.5.2.Market size analysis, by region
7.5.3.Market share analysis, by country
7.5.4.Market share analysis, by country
7.6.Research Dive Exclusive Insights
7.6.1.Market attractiveness
7.6.2.Competition heatmap
8.Lithium Niobate Modulator Market, by Region
8.1.North America
8.1.1.U.S.
8.1.1.1.Market size analysis, by Type
8.1.1.2.Market size analysis, by Wavelength Window
8.1.1.3.Market size analysis, by Application
8.1.1.4.Market size analysis, by End-use
8.1.2.Canada
8.1.2.1.Market size analysis, by Type
8.1.2.2.Market size analysis, by Wavelength Window
8.1.2.3.Market size analysis, by Application
8.1.2.4.Market size analysis, by End-use
8.1.3.Mexico
8.1.3.1.Market size analysis, by Type
8.1.3.2.Market size analysis, by Wavelength Window
8.1.3.3.Market size analysis, by Application
8.1.3.4.Market size analysis, by End-use
8.1.4.Research Dive Exclusive Insights
8.1.4.1.Market attractiveness
8.1.4.2.Competition heatmap
8.2.Europe
8.2.1.Germany
8.2.1.1.Market size analysis, by Type
8.2.1.2.Market size analysis, by Wavelength Window
8.2.1.3.Market size analysis, by Application
8.2.1.4.Market size analysis, by End-use
8.2.2.UK
8.2.2.1.Market size analysis, by Type
8.2.2.2.Market size analysis, by Wavelength Window
8.2.2.3.Market size analysis, by Application
8.2.2.4.Market size analysis, by End-use
8.2.3.France
8.2.3.1.Market size analysis, by Type
8.2.3.2.Market size analysis, by Wavelength Window
8.2.3.3.Market size analysis, by Application
8.2.3.4.Market size analysis, by End-use
8.2.4.Spain
8.2.4.1.Market size analysis, by Type
8.2.4.2.Market size analysis, by Wavelength Window
8.2.4.3.Market size analysis, by Application
8.2.4.4.Market size analysis, by End-use
8.2.5.Italy
8.2.5.1.Market size analysis, by Type
8.2.5.2.Market size analysis, by Wavelength Window
8.2.5.3.Market size analysis, by Application
8.2.5.4.Market size analysis, by End-use
8.2.6.Rest of Europe
8.2.6.1.Market size analysis, by Type
8.2.6.2.Market size analysis, by Wavelength Window
8.2.6.3.Market size analysis, by Application
8.2.6.4.Market size analysis, by End-use
8.2.7.Research Dive Exclusive Insights
8.2.7.1.Market attractiveness
8.2.7.2.Competition heatmap
8.3.Asia Pacific
8.3.1.China
8.3.1.1.Market size analysis, by Type
8.3.1.2.Market size analysis, by Wavelength Window
8.3.1.3.Market size analysis, by Application
8.3.1.4.Market size analysis, by End-use
8.3.2.Japan
8.3.2.1.Market size analysis, by Type
8.3.2.2.Market size analysis, by Wavelength Window
8.3.2.3.Market size analysis, by Application
8.3.2.4.Market size analysis, by End-use
8.3.3.India
8.3.3.1.Market size analysis, by Type
8.3.3.2.Market size analysis, by Wavelength Window
8.3.3.3.Market size analysis, by Application
8.3.3.4.Market size analysis, by End-use
8.3.4.Australia
8.3.4.1.Market size analysis, by Type
8.3.4.2.Market size analysis, by Wavelength Window
8.3.4.3.Market size analysis, by Application
8.3.4.4.Market size analysis, by End-use
8.3.5.South Korea
8.3.5.1.Market size analysis, by Type
8.3.5.2.Market size analysis, by Wavelength Window
8.3.5.3.Market size analysis, by Application
8.3.5.4.Market size analysis, by End-use
8.3.6.Rest of Asia Pacific
8.3.6.1.Market size analysis, by Type
8.3.6.2.Market size analysis, by Wavelength Window
8.3.6.3.Market size analysis, by Application
8.3.6.4.Market size analysis, by End-use
8.3.7.Research Dive Exclusive Insights
8.3.7.1.Market attractiveness
8.3.7.2.Competition heatmap
8.4.LAMEA
8.4.1.Brazil
8.4.1.1.Market size analysis, by Type
8.4.1.2.Market size analysis, by Wavelength Window
8.4.1.3.Market size analysis, by Application
8.4.1.4.Market size analysis, by End-use
8.4.2.Saudi Arabia
8.4.2.1.Market size analysis, by Type
8.4.2.2.Market size analysis, by Wavelength Window
8.4.2.3.Market size analysis, by Application
8.4.2.4.Market size analysis, by End-use
8.4.3.UAE
8.4.3.1.Market size analysis, by Type
8.4.3.2.Market size analysis, by Wavelength Window
8.4.3.3.Market size analysis, by Application
8.4.3.4.Market size analysis, by End-use
8.4.4.South Africa
8.4.4.1.Market size analysis, by Type
8.4.4.2.Market size analysis, by Wavelength Window
8.4.4.3.Market size analysis, by Application
8.4.4.4.Market size analysis, by End-use
8.4.5.Rest of LAMEA
8.4.5.1.Market size analysis, by Type
8.4.5.2.Market size analysis, by Wavelength Window
8.4.5.3.Market size analysis, by Application
8.4.5.4.Market size analysis, by End-use
8.4.6.Research Dive Exclusive Insights
8.4.6.1.Market attractiveness
8.4.6.2.Competition heatmap
9.Competitive Landscape
9.1.Top winning strategies, 2021
9.1.1.By strategy
9.1.2.By year
9.2.Strategic overview
9.3.Market share analysis, 2021
9.4.Top Five Players Market Overview
9.5.Lithium Niobate Modulator Market, By Company
10.Company Profiles
10.1.iXblue Group
10.1.1.Overview
10.1.2.Business segments
10.1.3.Product portfolio
10.1.4.Financial performance
10.1.5.Recent developments
10.1.6.SWOT analysis
10.2.Gooch & Housego plc
10.2.1.Overview
10.2.2.Business segments
10.2.3.Product portfolio
10.2.4.Financial performance
10.2.5.Recent developments
10.2.6.SWOT analysis
10.3.Fujitsu Optical Components Ltd
10.3.1.Overview
10.3.2.Business segments
10.3.3.Product portfolio
10.3.4.Financial performance
10.3.5.Recent developments
10.3.6.SWOT analysis
10.4.THORLABS
10.4.1.Overview
10.4.2.Business segments
10.4.3.Product portfolio
10.4.4.Financial performance
10.4.5.Recent developments
10.4.6.SWOT analysis
10.5.Beijing Panwoo Integrated ptoelectronic Inc.
10.5.1.Overview
10.5.2.Business segments
10.5.3.Product portfolio
10.5.4.Financial performance
10.5.5.Recent developments
10.5.6.SWOT analysis
10.6.Fabrinet Inc.
10.6.1.Overview
10.6.2.Business segments
10.6.3.Product portfolio
10.6.4.Financial performance
10.6.5.Recent developments
10.6.6.SWOT analysis
10.7.Lumentum Operations LLC
10.7.1.Overview
10.7.2.Business segments
10.7.3.Product portfolio
10.7.4.Financial performance
10.7.5.Recent developments
10.7.6.SWOT analysis
10.8.EOSPACE, Inc.
10.8.1.Overview
10.8.2.Business segments
10.8.3.Product portfolio
10.8.4.Financial performance
10.8.5.Recent developments
10.8.6.SWOT analysis
11.Appendix
11.1.Parent & peer market analysis
11.2.Premium insights from industry experts
11.3.Related reports
* Taxes/Fees, If applicable will be added during checkout. All prices in USD.
Have a question ?
Enquire To BuyNeed to add more ?
Request Customization
