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Grenoble, France
1-10 Employees
2018
SCINTIL Photonics is a fabless company that develops and markets silicon photonics with integrated lasers and optical amplifiers, for high speed optical interconnects in Data Centers, HPC and 5/6G infrastructure. Based in Grenoble, France and Toronto, Canada, SCINTIL is currently taking its innovative technology to an industrial level as it gears up for mass production. Delivers 8 or 16 lasers frequencies spaced by 100 GHz/200 GHz and multiplexed on 2 to 4 ports.
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Featured
AUGMENTED SILICON PHOTONICS WITH INTEGRATED LASERS
... SCINTIL Photonics, a supplier of silicon photonic integrated circuits augmented with hybrid silicon lasers and optical amplifiers, mass-produced in semi-conductor foundry, for optical connectivity in Data Centers, High Performance Computing (HPC/AI/ML) and ...
Lausanne, Switzerland
11-50 Employees
2016
LIGENTEC is your partner for low loss Photonic Integrated Circuits (PIC). Based on our all-nitride-core technology, we provide customer specific, integrated photonic circuits. LIGENTEC is a spin-off from the Federal Institute of Technology in Lausanne (EPFL) and started based on the ground-taking work of the laboratory of Professor Kippenberg on low loss silicon nitride for non-linear applications. Today, LIGENTEC offers a technology portfolio for silicon-nitride based Photonic Integrated Circuits from the visible to the infrared for linear and non-linear optical processing in applications such as communication, autonomous driving, quantum computing, metrology, biomedical and more. LIGENTEC headquarters are located at Lausanne, Switzerland with a subsidiary in France close to Paris.
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LOW-LOSS INTEGRATED PHOTONICS
... LIGENTEC is a B2B Manufacturer of Photonic Integrated Circuits for High-Tech areas such as AI, Quantum Technologies, LIDAR and Biosensors. ...
Almelo, Netherlands
51-100 Employees
1999
We are a forward-thinking partner in the high-end precision-production industry, providing innovative production solutions—from low to high volumes, from prototyping to mass production. Whether you are a supplier of components, subsystems, or even complete assemblies, we get involved early in your product life cycle to create the right production system for you—flexible to meet your current needs and scalable to help you grow, from lab to fab. We are proud to offer you a portfolio of production equipment for Precision Assembly, Glass Molding, and Integrated Photonics. And our Customized Solutions provide tailored products to meet your exacting needs—allowing you to take steps ahead. We are pioneers in advanced technology and love to create solutions for complex precision alignments for the world’s leading brands—including automotive sensor manufacturers, mobile phone component suppliers, medical device manufacturers, and component suppliers in photonics and optics.
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Integrated Photonics
... IMS offers two types of integrated photonics. Equipment that is key in the production and integration of Photonic Integrated Circuits. ...
Eindhoven, Netherlands
1-10 Employees
2021
PITC turns the inventions and innovations in Integrated Photonics into industrial successes. We provide technology solutions, knowledge and technical support to companies that target specific market applications. PITC is an independent institute that builds partnerships, strengthens the photonics ecosystem, and links it to a global customer base. PITC supports companies that want to make the step towards high-quality production or want to enter the photonics supply chain. PITC is also there for OEMs, end users, and application owners that want to integrate photonics in their solutions. PITC supports training programs and workforce education in photonic technologies, design, and applications. PITC provides its partners with access to knowledge, shared tools and facilities. Together with program members PITC will establish a funnel of innovations that provide steppingstones towards large-scale application of Integrated Photonics.
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PITC – Integrated Photonics
... Accelerating Integrated Photonics by bridging the gap between research and ...
Goleta, United States
11-50 Employees
2022
OpenLight is the world leader in custom, PASIC design and manufacture. This single chip concept vastly reduces manufacturing and assembly costs, by removing less reliable manufacturing processes altogether, such as aligning external lasers to waveguides. Application Specific Integrated Circuits are central to the operation of most of the electronic products and computers used today, optimising performance, cost and efficiency.PASIC’s are the photonic equivalent!Photonic Application Specific Integrated Circuits are central to photonics-based design, both now and in the future, for the same reason as ASICs. OpenLight is bringing PASIC design to the mass market, with its PDK, production services, and a wealth of PASIC support tools, such as Evaluations kits and PDK Samplers. Carter is a semiconductor communications industry veteran, with an impressive, 25-year track record. Kevin is a seasoned and results proven semiconductor and fiberoptics professional with 25 years of experience in global sales and marketing. Kaman was Chief Systems Architect and Director of Product Management at Calient Networks. OpenLight’s inhouse engineers provide custom PASIC design and layout services to help with….
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Driving the new era of open silicon photonics with integrated lasers
... Driving the new era of open silicon photonics with integrated ...
Cambridge, United States
1-10 Employees
2018
Being a part of the HyperLight team provides you the flexibility to grow and learn, while succeeding in a fast-paced, revolutionary environment. HyperLight’s scalable photonic integrated circuits (PICs) provide disruptive advantages for customers needing high bandwidth and low power electro-optic solutions, including data center, telecommunications, radio communication, sensing, and LiDAR applications. Using a streamlined rapid prototyping to volume manufacturing process, the PICs are customized and are produced in volume based on their specific use. These powerful devices offer high bandwidth, low insertion loss, high extinction ratio, low-drive voltages, and the ability to handle high optical powers, which are desired for high-speed modulation systems.
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Empower your system with High-performance integrated photonics devices
... HyperLight unleashes the potential of integrated photonics by developing a proprietary platform based on thin-film lithium niobate (TFLN) ...
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Artemis - Aegiq | Quantum computing and networking delivering value using quantum & integrated photonics
... Artemis - Aegiq | Quantum computing and networking delivering value using quantum & integrated photonics ...
Enschede, Netherlands
11-50 Employees
2017
PHIX offers assembly services and contract manufacturing for photonic integrated circuits (PICs) and MEMS. We build optoelectronic modules based on all major PIC technology platforms, such as Indium Phosphide, Silicon Photonics, Silicon Nitride, and Planar Lightwave Circuit. We specialize in chip-to-chip hybrid integration, coupling to fiber arrays, and interfacing of DC and RF electrical signals. By offering our knowledge already at the chip design stage, we ensure ease of scale-up for volume manufacturing. PHIX provides a one-stop-shop for PIC and MEMS assembly, from design to volume production.
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About Us - PHIX Photonics Assembly
... What is integrated photonics packaging? ...
Netherlands
11-50 Employees
2016
From our beginnings in ultra-low loss photonic integrated circuits (PICs), LioniX International has grown into a leading global provider of customized microsystem solutions specializing in integrated photonics and customized MEMS devices. Watch the LioniX International story: how we solve our customers’ challenges. The strength of our approach is in how we apply our technology building blocks and expertise to co-develop a solution with you. We work with you from design to finished device to reach your product development goals. Then we support you as you grow, with production facilities to cover all volume requirements – from custom R&D to high volume production.
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LioniX International welcomes Dr Peter Maat as Group Leader for Integrated Microwave Photonics Group
... We’re delighted to welcome Dr Peter Maat to LioniX International as Head of our Integrated Microwave Photonics Group. ...
Edmonton, Canada
1-10 Employees
2002
We are an integrated photonics foundry specializing in rapid turnaround prototyping and low-to-mid volume production. Devices are manufactured using a state-of-the-art 100 keV electron beam lithography system. Custom transmission gratings for EUV and higher energy X-ray systems. Turnaround time from design submission to delivery as short as three weeks. By using state-of-the-art electron beam lithography, we achieve features sizes of 60 nm. Our online design submission system is user-friendly and we offer a process design kit for our fabrication service. We specialize in fast turnaround times of less than four weeks for a single layer of metal. We offer fabrication of custom interposer designs with rapid turnaround times.
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Applied Nanotools Inc.
... Integrated Photonics ...
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Some interesting numbers and facts about the results you have just received for Integrated Photonics
| Country with most fitting companies | United States |
| Amount of fitting manufacturers | 65 |
| Amount of suitable service providers | 36 |
| Average amount of employees | 11-50 |
| Oldest suiting company | 1999 |
| Youngest suiting company | 2022 |
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Integrated photonics refers to the technology that allows for the manipulation and control of light (photons) on a very small scale, typically within a chip-scale platform. This innovative field combines multiple optical components such as waveguides, modulators, and lasers into a single integrated circuit, akin to how electronic components are integrated in silicon chips. The primary objective of integrated photonics is to improve performance, reduce size, and lower the costs of optical systems. By leveraging the principles of photonics, integrated photonics enables the transmission of data at significantly higher speeds and over longer distances with less energy consumption compared to traditional electronic devices. Its impact is profound across various sectors, including telecommunications, where it revolutionizes data transmission methods; healthcare, through advanced diagnostic equipment; and computing, by enhancing the capabilities of processors and data storage devices. Furthermore, integrated photonics plays a crucial role in the development of sensors and LiDAR systems for autonomous vehicles, offering improved detection and ranging capabilities. The ability to process information using light rather than electricity not only paves the way for more efficient and compact devices but also opens up new avenues for innovation in fields such as quantum computing and optical computing, marking a significant leap forward in technology and its application across industries.
1. Increased Efficiency
Integrated photonics technology is renowned for its ability to transmit data at significantly higher speeds compared to traditional electronic devices. This increase in efficiency is due to photons' ability to move faster than electrons, making data transfer both quicker and more reliable.
2. Lower Energy Consumption
One of the most compelling advantages of integrated photonics lies in its lower energy consumption. Photonic devices require less power to operate than their electronic counterparts, leading to more energy-efficient systems. This not only reduces operational costs but also contributes to a lower carbon footprint.
3. Enhanced Data Capacity
Integrated photonics can handle vast amounts of data with minimal loss in signal integrity. This is crucial in today's data-driven world, where the demand for high-speed, high-capacity communications systems is continuously growing. Photonics technology allows for the management of larger data volumes, meeting the increasing needs of modern telecommunications and computing.
4. Reduced Size and Weight
The compact nature of integrated photonics technology allows for devices to be smaller and lighter. This reduction in size and weight is particularly beneficial in applications where space is at a premium, such as in aerospace and mobile technologies. Miniaturized photonic components contribute to the development of more portable and space-efficient systems.
While evaluating the different suppliers make sure to check the following criteria:
1. Technology and Innovation
Ensure the supplier is at the forefront of integrated photonics technology, offering innovative solutions that can keep pace with industry advancements.
2. Manufacturing Capabilities
Assess the supplier's ability to produce high-quality, reliable photonic components at scale. Consider their manufacturing processes and quality control measures.
3. Customization and Flexibility
Determine if the supplier can provide customized solutions tailored to your specific needs and if they are flexible enough to adapt to changing requirements.
4. Supply Chain Reliability
Evaluate the robustness of the supplier's supply chain, including their ability to deliver products on time and manage logistics efficiently.
5. Technical Support and Service
Confirm the availability of comprehensive technical support and customer service, ensuring that the supplier can assist with both pre-sales questions and post-sales support.
6. Cost-Effectiveness
Consider the overall cost-effectiveness of the supplier's offerings, balancing quality, performance, and price to ensure you receive the best value for your investment.
Integrated photonics, a technology that merges photonic devices into a single platform, is revolutionizing multiple industries with its versatility and efficiency. In the telecommunications sector, it enhances data transmission speeds and bandwidth, enabling faster, more reliable internet and communication services. This innovation is critical for companies requiring high-speed data transfer, such as streaming services and cloud computing providers. Another significant application is in the healthcare industry, where integrated photonics is used in advanced diagnostic equipment. Its ability to manipulate light at small scales improves the resolution and precision of medical imaging tools, facilitating early detection of diseases and conditions. This technology is pivotal for medical device manufacturers and healthcare facilities aiming to offer cutting-edge diagnostic services. Furthermore, integrated photonics plays a crucial role in the manufacturing sector, particularly in precision machining and quality control processes. The technology's high-resolution sensing capabilities allow for accurate measurement and inspection of components, ensuring product quality and consistency. This application is invaluable for manufacturers seeking to maintain high standards and efficiency in production lines. Lastly, in the aerospace and defense industries, integrated photonics contributes to the development of sophisticated navigation and communication systems. Its lightweight, high-performance characteristics are ideal for applications where space and weight are at a premium, offering enhanced functionality without compromising on system size or power consumption. This use case is essential for companies involved in the design and manufacture of advanced aerospace and defense technologies.
Integrated photonics, a cutting-edge field focusing on the development and application of photonic devices to process and transmit information, currently sits at various Technology Readiness Levels (TRLs) ranging from 4 to 6, depending on the specific application and development stage. This range signifies that the technology has evolved from small-scale, experimental validations in a laboratory setting (TRL 4) to integrations in relevant environments where its performance can be tested (TRL 6). The reason for this specific positioning in the TRL spectrum stems from several technical challenges and breakthroughs. On the one hand, the fabrication of photonic integrated circuits (PICs) involves complex processes that require nanoscale precision, including lithography and etching, which have seen considerable advancements yet still face reproducibility and scalability challenges. On the other hand, the integration of electronic and photonic components on a single platform poses both design and material compatibility hurdles that researchers are actively overcoming. Despite these challenges, significant progress in materials science, particularly in silicon photonics and the development of new laser sources, modulators, and detectors, has propelled the field forward. The current TRL reflects a technology that has proven its fundamental operational principles and is swiftly moving towards more advanced prototypes and pilot applications, underscoring a transition phase towards full commercialization.
In the short term, advancements in integrated photonics are expected to focus on enhancing data transmission rates and reducing energy consumption in telecommunications. The development of more efficient, compact photonic chips will enable faster, more reliable internet services. Innovations like hybrid silicon lasers are poised to revolutionize data centers, offering improved speed and efficiency. Looking to the mid-term, integrated photonics will play a crucial role in advancing healthcare diagnostics. The integration of photonic sensors into lab-on-a-chip devices is anticipated, enabling rapid, precise disease detection at lower costs. This period will also witness the expansion of integrated photonics into more consumer electronics, improving the performance and functionality of devices such as smartphones and wearable technology through better data processing and sensing capabilities. In the long term, the focus will shift towards quantum computing and deep-space communication. Integrated photonics is expected to provide the backbone for quantum computers, dramatically increasing processing power and enabling complex simulations. For space exploration, the technology is set to enhance communication systems, allowing for faster, more reliable data transmission across vast distances. These advancements will not only push the boundaries of computing and communication but also pave the way for new scientific discoveries and technological innovations.
Some interesting questions that has been asked about the results you have just received for Integrated Photonics
What are related technologies to Integrated Photonics?
Based on our calculations related technologies to Integrated Photonics are Magnets, Printed Electronics, Industrial Amplifiers, Electronic Transducers, Electronic Oscillators
Who are Start-Ups in the field of Integrated Photonics?
Start-Ups who are working in Integrated Photonics are PITC - Photonic Integration Technology Center
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OpenLightWhich industries are mostly working on Integrated Photonics?
The most represented industries which are working in Integrated Photonics are Manufacturing, Hardware, Science and Engineering, Professional Services, Information Technology
How does ensun find these Integrated Photonics Companies?
ensun uses an advanced search and ranking system capable of sifting through millions of companies and hundreds of millions of products and services to identify suitable matches. This is achieved by leveraging cutting-edge technologies, including Artificial Intelligence.
