Poste de travail laser pour réseaux de Bragg en fibre optique, Prévisions de la Taille du Marché Mondial, Classement et Part de Marché des 5 Premières Entreprises

Selon le nouveau rapport d'étude de marché “Rapport sur le marché mondial de Poste de travail laser pour réseaux de Bragg en fibre optique 2024-2030”, publié par QYResearch, la taille du marché mondial de Poste de travail laser pour réseaux de Bragg en fibre optique devrait atteindre 1180 millions de dollars d'ici 2030, à un TCAC de 13.9% au cours de la période de prévision.

Figure 1. Taille du marché mondial de Poste de travail laser pour réseaux de Bragg en fibre optique (en millions de dollars américains), 2019-2030

Selon QYResearch, les principaux fabricants mondiaux de Poste de travail laser pour réseaux de Bragg en fibre optique comprennent WOP, Innofocus, etc. En 2023, les trois premiers acteurs mondiaux détenaient une part d'environ 82.0% en termes de chiffre d'affaires.

Figure 2. Classement et part de marché des 5 premiers acteurs mondiaux de Poste de travail laser pour réseaux de Bragg en fibre optique (Le classement est basé sur le chiffre d'affaires de 2023, continuellement mis à jour)

The market for laser workstations used for the production and analysis of Fiber Bragg Gratings (FBGs) is influenced by several key drivers, which contribute to its growth and development. Here are some important market drivers:

1. Rising Demand for Fiber Bragg Gratings: FBGs are widely used in various applications, including telecommunications, structural health monitoring, temperature sensing, and pressure measurements. The increasing demand for these applications drives the need for advanced laser workstations capable of producing high-quality FBGs.

2. Advancements in Laser Technology: Continuous improvements in laser technologies, including sources that are more efficient, reliable, and capable of producing precise and high-resolution gratings, are driving the adoption of laser workstations. New types of lasers and improved fabrication techniques enhance the performance of FBGs.

3. Growth in Telecommunications Sector: The telecommunications industry is one of the largest consumers of Fiber Bragg Gratings, especially for applications in fiber-optic communications and signal processing. As demand for high-speed data transmission and 5G technology continues to grow, the need for FBGs and the corresponding laser workstations will increase.

4. Development of Smart Infrastructure: The expansion of smart building technologies and infrastructure monitoring systems that utilize FBG sensors for real-time condition monitoring and data collection is driving market growth. Laser workstations are essential for developing customized FBGs tailored to specific monitoring needs.

5. Innovations in Sensing Technologies: FBGs are increasingly being adopted in various sensing applications due to their advantages, such as high sensitivity and immunity to electromagnetic interference. The growth in industries such as aerospace, automotive, and energy sector—for structural and environmental monitoring—requires robust laser workstations for the production of specialized FBGs.

6. Focus on Research and Development: Research institutions and labs are actively engaged in developing new applications for FBGs, which drives the demand for laser workstations that can facilitate advanced experimental setups. This R&D focus contributes to the advancement of FBG-related technologies and products.

7. Miniaturization Trends: The growing trend toward miniaturization in various applications, especially in telecommunications and medical devices, requires precise and compact FBG solutions. Laser workstations equipped to produce smaller and more intricate FBGs are increasingly important.

8. Energy Efficiency and Cost Reduction: Advances in laser technology have enabled the development of more energy-efficient laser workstations, which can reduce operating costs. This is particularly attractive for businesses and research institutions looking to optimize their operations.

9. Customization and Flexibility: The ability to design and fabricate customized FBGs for specific applications is driving demand for adaptable laser workstations. Systems that allow for easy programming and adjustment for different grating patterns can enhance production efficiency and innovation.

10. Growing Adoption in Medical Applications: The healthcare sector is increasingly exploring the use of FBGs for applications such as biomedical sensing and imaging. As this trend grows, the need for specialized laser workstations for producing medical-grade FBGs will also increase.

11. Collaborative Industry Growth: Collaborations between universities, research institutions, and industries focused on fiber optics and sensor technologies promote innovation and lead to the development of new applications for FBGs. This collaborative growth stimulates demand for laser workstations.

In summary, the market for laser workstations for Fiber Bragg Gratings is driven by rising demand for FBGs in various sectors, advancements in laser technology, the growth of telecommunications and smart infrastructure applications, research initiatives, and the increasing adoption of FBGs in sensing and medical applications. These factors create a conducive environment for the expansion of this market.

À propos de QYResearch

QYResearch a été fondée en 2007 en Californie aux États-Unis. C'est une société de conseil et d'étude de marché de premier plan à l'échelle mondiale. Avec plus de 17 ans d'expérience et une équipe de recherche professionnelle dans différentes villes du monde, QYResearch se concentre sur le conseil en gestion, les services de base de données et de séminaires, le conseil en IPO, la recherche de la chaîne industrielle et la recherche personnalisée. Nous société a pour objectif d’aider nos clients à réussir en leur fournissant un modèle de revenus non linéaire. Nous sommes mondialement reconnus pour notre vaste portefeuille de services, notre bonne citoyenneté d'entreprise et notre fort engagement envers la durabilité. Jusqu'à présent, nous avons coopéré avec plus de 60 000 clients sur les cinq continents. Coopérons et bâtissons ensemble un avenir prometteur et meilleur.

QYResearch est une société de conseil de grande envergure de renommée mondiale. Elle couvre divers segments de marché de la chaîne industrielle de haute technologie, notamment la chaîne industrielle des semi-conducteurs (équipements et pièces de semi-conducteurs, matériaux semi-conducteurs, circuits intégrés, fonderie, emballage et test, dispositifs discrets, capteurs, dispositifs optoélectroniques), la chaîne industrielle photovoltaïque (équipements, cellules, modules, supports de matériaux auxiliaires, onduleurs, terminaux de centrales électriques), la chaîne industrielle des véhicules électriques à énergie nouvelle (batteries et matériaux, pièces automobiles, batteries, moteurs, commande électronique, semi-conducteurs automobiles, etc.), la chaîne industrielle des communications (équipements de système de communication, équipements terminaux, composants électroniques, frontaux RF, modules optiques, 4G/5G/6G, large bande, IoT, économie numérique, IA), la chaîne industrielle des matériaux avancés (matériaux métalliques, polymères, céramiques, nano matériaux, etc.), la chaîne industrielle de fabrication de machines (machines-outils CNC, machines de construction, machines électriques, automatisation 3C, robots industriels, lasers, contrôle industriel, drones), l'alimentation, les boissons et les produits pharmaceutiques, l'équipement médical, l'agriculture, etc.

Get Information About Optic Circulators

Fiber Circulator is used to minimize the dispersion of light within a fiber optic system. Fiber optic circulators, when used with a dispersion compensating module (DCM), may send light across the system while using half the fiber to produce the necessary compensatory effect.

Applications

Optical circulators enable bidirectional ports, allowing an optical signal to be transmitted and received using a single fiber. Fiber optic circulators are utilized in a variety of applications, including dense wavelength division multiplexing (DWDM) networks, polarization mode dispersion, chromatic dispersion correction, optical add-drop modules, optical amplifiers, and fiber optic sensors.

Division Multiplexing (DWDM) Networks

Fibre Circulators in DWDM networks provide 50 dB isolation between forward and backward propagating signals.  Fiber optic circulators also have a cross-talk level of greater than 60 decibels.

Optical Add-drop Multiplexing (OADM)

Optical add-drop modules function as main filters. Optical couplers can produce this behavior by utilizing a Fiber Bragg Grating (FBG). The full bandwidth signal enters the coupler and is routed to the next port, where the FBG is inserted. The FBG reflects the required signal to the coupler, while the dropped channels depart via the port. PMD may be corrected using optical couplers, which rotate the optical signal's electric and magnetic fields.

Polarization mode dispersion (PMD)

Some fiber optic systems exhibit polarization mode dispersion (PMD), which is a natural feature of all optical media.  PMD is created by a discrepancy in light propagation velocities between the transmission medium's orthogonal main polarization states.  If the optical pulse contains both polarisation components, the individual polarisation components in fibre optic circulators will travel at different speeds and arrive at various times, causing the received optical signal to be distorted.

PMD may be corrected using optical couplers, which rotate the optical signal's electric and magnetic fields.

Chromatographic Dispersion Compensation

Optical Circulator uses a chipped Fiber Bragg Grating to adjust for chromatic dispersion. FBGs are wavelength-dependent reflectors. A portion of optical fiber is treated or doped with a substance that affects the fiber's refractive index, resulting in wavelength-dependent reflections. Chipped Fiber Bragg Gratings have numerous gratings displaced across fiber and can compensate for chromatic dispersion.

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Discussion of Fiber Bragg Grating Technology Applicability on Diagnostic Field Testing of Steel Girder Bridges

Abstract

The application of Fiber Bragg Grating (FBG) technology for purposes of diagnostic field testing on steel girder bridges is discussed in this paper based on the authors experience in field tests of highway bridges. The primary benefit of the FBG technology is the ability to have many sensors (strain gages) multiplexed in a single fiber optic line. In practice, the FBG system is problematic for field conditions of a typical highway bridge. In field tests, measured FBG data showed that the strain histories obtained for a load immediately above the girder of interest were accurate, but the accuracy of the strain histories decreases for adjacent girders as the transverse distance from the load increased. Moreover, protective measures are necessary for FBG systems to be utilized in highway bridge field testing.

Read More about this article: https://irispublishers.com/ctcse/fulltext/discussion-of-fiber-bragg-grating-technology-applicability-on-diagnostic-field-testing-of-steel-girder-bridges.ID.000681.php

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diode laser module

Diode laser module are versatile components used in a variety of applications, such as semiconductor wafer defect detection, hair removal, and plastics welding. They offer high power and homogeneity with a range of wavelengths from 808 nm to 1550 nm and can achieve up to 95% beam homogeneity with the help of specialized optics .

These modules can be configured with single emitters for high power applications, like MOPA (Master Oscillator Power Amplifier) systems, or as single bars for direct diode applications with wavelengths extending from 640 nm to 2.1 µm and continuous wave (CW) powers up to 80 W . They also come with options for locking and narrow linewidth using Volume Bragg Gratings (VBG) to improve spectral performance .

Diode laser module typically include not only the diode itself but also optics, cooling devices, and electrical elements. They facilitate ease of use by shaping the output beam, often into a collimated beam for efficient transmission and coupling with optical fibers . Fiber-coupled modules, also known as "pig-tailed" laser diodes, can launch light directly into an optical fiber, with options for single-mode or multimode fibers depending on the power level .

Diode laser module also feature power and wavelength stabilization to ensure consistent performance. This can be achieved through internal feedback loops with monitor photodiodes, and some modules are designed for very careful stabilization to minimize relative intensity noise . Furthermore, they can support power modulation and pulse generation, with some modules capable of producing nanosecond or picosecond light pulses .

For applications requiring specific beam shapes, such as lines, crosses, or squares, laser diode modules can be equipped with the necessary optics to achieve the desired output . Additionally, some modules include internal frequency doublers for wavelength conversion, such as creating green light from a laser diode emitting at a different wavelength .

Cooling and temperature stabilization are crucial for maintaining the performance of high-power laser diode modules. Modules may include metallic surfaces for easy mounting on coolers or thermoelectric coolers with feedback systems to stabilize the diode temperature, leading to a more stable output wavelength and power .

Diode laser module find use in a wide range of applications including optical alignment, printing, imaging, displays, bar code scanning, data storage, sensors, solid-state laser pumping, free-space optical communications, and medical applications like photodynamic therapy and ophthalmology . They are also commonly used as OEM components in larger devices .

Newport offers CW laser diode modules with various wavelengths from UV to 1550 nm, featuring high optical power levels and models with ultrafine PID temperature control . Diode laser module are designed for easy mounting and are available in different series to cater to various budget and performance requirements, although they are not CE marked .

Know About The Fiber Cable Cutting and FBT Fiber Taper Machine

The foundation of connectivity in the quickly developing field of telecommunications, where dependability is crucial and data transmission speeds are constantly rising, is found in the complex field of fiber optics. The intricately designed FBT Fiber Taper Machine and Fiber Cable Cutting Machine are essential tools for molding and optimizing fiber optic cable performance.

The Fiber Optics Revolution

Fiber optics has completely changed communication networks all over the world by enabling data to be sent over great distances at the speed of light. The optical fibers, which are pliable, thin strands of plastic or glass that transmit data as light pulses, are the central component of this technology. The need for dependable and effective fiber optic components is growing as demands for higher internet speeds, high-definition video streaming, and strong communication networks rise.

Accurate Engineering Precision: The Machine for FBT Fiber Taping

The FBT Fiber Taper Machine, a high-precision tool that can tape optical fibers with unmatched accuracy, is the center of fiber optic production. For optimum performance, fiber Bragg gratings, couplers, and other crucial parts need to be precisely tapered. This is accomplished by the FBT Fiber Taper Machine by precisely regulating the fiber's stretching and heating, which results in consistent taper profiles and little insertion loss.

The adaptability of the FBT Fiber Taper Machine is one of its key features. It is essential for many different applications since it can handle several types of fibers, such as polarization-maintaining, multimode, and single-mode fibers. The FBT Fiber Taper Machine meets the industry's strict requirements by producing consistent and dependable results for laser, sensor, and telecommunications applications.

Increasing Productivity: The Fiber Cable Cutting Device

To manufacture high-quality components, fiber optic cables must be precisely cut in addition to being tapered. The Fiber Cable Cutting Machine is useful in this situation. These machines minimize fiber end-face imperfections and reduce signal attenuation by ensuring clean and accurate cuts through the use of modern cutting mechanisms like laser or diamond blades.

The Fiber Cable Cutting Machine is incredibly efficient and can handle many fibers at once with a high throughput. These devices cut ribbon cables and individual fibers with remarkable speed and accuracy, producing reliable results every time.

Market Expansion: Predictions for the Structural Health Monitoring Sector

The global structural health monitoring market is poised for significant growth, with revenues expected to reach a staggering US$13,155.4 million by the year 2032, according to recent market analysis. This surge is driven by the escalating demand for evaluating and monitoring the structural health of critical assets such as bridges, dams, buildings, wind turbines, and machinery.

In 2022, the market for structural health monitoring recorded revenues of US$3,409.4 million, marking a substantial milestone in the sector’s growth trajectory. The market is projected to expand at an impressive Compound Annual Growth Rate (CAGR) of 14.5% from 2022 to 2032, underscoring the increasing emphasis on ensuring the safety and durability of infrastructural elements.

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Key Takeaways: Structural Health Monitoring Market

By component, the software segment is anticipated to account for the leading share of around 40% in 2022 while the hardware segment is estimated to grow at the highest CAGR of 17.6% through 2032.

By type, the wireless SHM system segment is expected to grow at a highest CAGR of 14.8% between 2022 & 2032

By application, the vessels and platforms segment is anticipated to grow at a CAGR of 19.0% during the forecast period.

South Asia and Pacific structural health monitoring market is expected to progress at the highest CAGR of around 17.8% through 2032.

The structural health monitoring market in Japan is expected to grow at a CAGR of around 18.6% through 2032.

In India, sales of structural health monitoring systems are expected to grow at a CAGR of close to 19.9% over the next ten years.

“Demand for structural health monitoring is increasing in monitoring of bridges and dams because dam monitoring instrumentation plays an important role in security monitoring for people and dams, offering important details on the performance of the dam and detecting issues at an early and preventable step. says FMI analyst.

Competition Analysis and Regional Trends

The competition in the structural health monitoring market is intensifying, with various players vying to offer innovative solutions and advanced technologies. As demands for precision, reliability, and real-time data analysis continue to rise, market participants are focusing on delivering cutting-edge solutions to gain a competitive edge.

Additionally, regional trends indicate a significant market traction in various parts of the world. As infrastructure projects gain momentum across different regions, the need for efficient structural health monitoring solutions is becoming increasingly evident, driving market growth on a global scale.

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Key Components and Sensors

The realm of structural health monitoring encompasses a range of components such as data acquisition systems, data diagnostics, and digital processing. Diverse sensors are instrumental in this domain, including microwave sensors, imaging ultrasonic sensors, smart sensors or sensor coatings, acoustic emission sensors, inclinometers slope indicators, and fiber Bragg diffraction grating sensors. These technologies collectively contribute to ensuring the integrity and safety of structures.

With the global structural health monitoring market poised for exponential growth, it is evident that the sector is evolving to meet the demands of an expanding infrastructure landscape. As the world’s critical assets undergo increasing scrutiny, the market is set to play a pivotal role in enhancing the longevity and reliability of vital structures.

Key Segments Profiled in the Global Structural Health Monitoring Market

Structural Health Monitoring Market by Component:

Structural Health Monitoring in Hardware

Structural Health Monitoring in Sensors

Structural Health Monitoring in Data Acquisition Systems

Structural Health Monitoring in Others

Structural Health Monitoring in Software

Structural Health Monitoring in Design and Analysis

Structural Health Monitoring in Parameter Identification and Tracking

Structural Health Monitoring in Others

Structural Health Monitoring in Service

Structural Health Monitoring in Installation Service

Structural Health Monitoring in Design and Consulting Service

Structural Health Monitoring in Operation and Maintenance Service

Structural Health Monitoring Market by Type:

Wired Structural Health Monitoring Systems

Wireless Structural Health Monitoring Systems

Structural Health Monitoring Market by Application:

Structural Health Monitoring for Bridges and Dams

Structural Health Monitoring for Building and Stadiums

Structural Health Monitoring for Vessels and Platforms

Structural Health Monitoring for Airframes and Wind Turbines

Structural Health Monitoring for Large Machines and Equipment

Structural Health Monitoring Market by Region:

North America Structural Health Monitoring Market

Latin America Structural Health Monitoring Market

Europe Structural Health Monitoring Market

East Asia Structural Health Monitoring Market

South Asia & Pacific Structural Health Monitoring Market

Middle East and Africa (MEA) Structural Health Monitoring Market

North America is has dominated the Fiber Bragg Grating Amplifier market due to the availability of advanced technological products in the region...

Sysargus excels in Data Acquisition Systems (DAS), providing state-of-the-art solutions for efficient data collection and analysis. Leveraging cutting-edge technology, Sysargus designs and implements robust DAS tailored to diverse industry needs. Their systems ensure accurate real-time data capture from various sensors and sources, fostering informed decision-making. With a focus on reliability and scalability, Sysargus empowers businesses with seamless integration of data acquisition into their operations. Whether in industrial automation, research, or monitoring applications, Sysargus' expertise in Data Acquisition Systems enhances productivity and facilitates a deeper understanding of processes, contributing to overall efficiency and competitiveness for their clients.

"Innovations in Optical Connectivity: The Role of Fiber Optic Circulators in Next-Generation Networks"

Fiber optic circulators are essential components in optical communication systems that enable the routing and control of light signals. They are based on the principle of non-reciprocity, meaning that the light propagation is directional and can flow in one direction while being blocked or attenuated in the opposite direction. Fiber optic circulators are commonly used in various applications, including telecommunications, fiber optic sensing, and optical testing.

The key features and functions of fiber optic circulators include:

Light Routing: Fiber optic circulators allow the routing of light signals from one optical fiber to another in a specific direction. They typically have three or more ports that facilitate the bidirectional transmission of light. The circulator can route light from port 1 to port 2 while blocking or minimizing the signal loss in the reverse direction.

Signal Isolation: Fiber optic circulators provide high isolation between ports, ensuring that light signals transmitted in one direction do not interfere with or affect signals traveling in the opposite direction. This isolation property is crucial in preventing signal degradation and maintaining the integrity of optical communication systems.

Wavelength Division Multiplexing (WDM): Fiber optic circulators can be designed to operate at specific wavelengths, enabling the implementation of wavelength division multiplexing techniques. In WDM systems, multiple wavelengths of light are simultaneously transmitted through a single optical fiber, effectively increasing the data transmission capacity. Fiber optic circulators play a key role in directing the different wavelengths to their respective destinations.

Optical Signal Processing: Fiber optic circulators can be integrated into optical signal processing systems to perform various functions such as signal amplification, filtering, and dispersion compensation. By combining fiber optic circulators with other optical components, complex optical signal processing tasks can be achieved, enhancing the performance and efficiency of optical communication systems.

Fiber Optic Sensing: Fiber optic circulators are also used in fiber optic sensing applications where the detection of changes in light signals is critical. By directing light signals through different sensing elements, such as fiber Bragg gratings or interferometric sensors, fiber optic circulators enable precise and accurate measurement of physical parameters like strain, temperature, pressure, and vibration.

In summary, fiber optic circulators play a vital role in controlling and directing light signals in optical communication systems. They enable the efficient routing of light, provide isolation between different ports, support wavelength division multiplexing, and can be integrated into optical signal processing and sensing applications. With their unique non-reciprocal properties, fiber optic circulators contribute to the advancement of high-speed telecommunications, fiber optic sensing technology, and various other optical applications.

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