All IPs > Analog & Mixed Signal > Photonics
Photonics semiconductor IPs play a vital role in the ever-growing field of optical technologies and integrated communications. As the demand for faster and more reliable communication networks increases, these IPs provide essential functionalities that help optimize the performance of optical systems. At Silicon Hub, we offer a comprehensive collection of photonics IPs that cater to a variety of applications including data transmission, sensor technology, and integrated photonic circuits. These IPs are designed to meet the rigorous demands of modern communication systems and facilitate the development of advanced technological solutions.
Photonics IPs are crucial for enabling photon management and manipulation, allowing designers to capitalize on the benefits of light as a carrier of information. This category includes a variety of IP cores such as modulators, detectors, and laser drivers, all tailored to improve the efficiency and performance of optical communication links. By leveraging these technologies, developers can create innovative products that deliver higher bandwidth, lower power consumption, and enhanced signal integrity, essential for applications such as data centers, telecommunications, and fiber-optic networks.
Integrated photonic circuits (IPCs) are another key application area for photonics semiconductor IPs. These IPCs combine multiple photonic functionalities into a single chip, offering significant advantages in terms of miniaturization, performance, and cost-effectiveness. Photonics IPs provide the building blocks necessary for the integration of components like waveguides, modulators, and amplifiers, ensuring seamless interconnection and interaction of optical signals on a compact platform. As a result, IPCs are driving innovations in fields such as quantum computing, biosensing, and lidar technologies.
In addition to communications and sensors, photonics semiconductor IPs are used in a diverse range of technologies, from healthcare to automotive industries. They are integral to developing systems that require precise light manipulation and measurement capabilities. Our category at Silicon Hub ensures that you have access to state-of-the-art photonics IPs that help transform your ideas into reality, enhancing productivity and enabling you to keep pace with the rapid technological advancements in the digital age. Explore our offerings today and discover how photonics semiconductor IPs can redefine your next project.
Silicon Creations delivers precision LC-PLLs designed for ultra-low jitter applications requiring high-end performance. These LC-tank PLLs are equipped with advanced digital architectures supporting wide frequency tuning capabilities, primarily suited for converter and PHY applications. They ensure exceptional jitter performance, maintaining values well below 300fs RMS. The LC-PLLs from Silicon Creations are characterized by their capacity to handle fractional-N operations, with active noise cancellation features allowing for clean signal synthesis free of unwanted spurs. This architecture leads to significant power efficiencies, with some IPs consuming less than 10mW. Their low footprint and high frequency integrative capabilities enable seamless deployments across various chip designs, creating a perfect balance between performance and size. Particular strength lies in these PLLs' ability to meet stringent PCIe6 reference clocking requirements. With programmable loop bandwidth and an impressive tuning range, they offer designers a powerful toolset for achieving precise signal control within cramped system on chip environments. These products highlight Silicon Creations’ commitment to providing industry-leading performance and reliability in semiconductor design.
The Vantablack S-VIS Space Coating is engineered for space applications, where it serves as an advanced stray light suppression and blackbody coating. Suitable for use on satellite instruments, this coating helps to minimize the light reflection that can occur in space environments, thereby ensuring higher accuracy in optical measurements and instrument calibration. Vantablack S-VIS offers exceptional spectral absorption from ultraviolet through to the terahertz range, crucial for a variety of optical systems. Its lightweight and highly absorbent properties allow for more compact baffle and calibration systems without compromising performance. The coating has demonstrated reliability in space missions, offering consistent absorption over extended periods. This coating is particularly critical for optical systems that operate under the challenging conditions of space, including variations in temperature and pressure, as well as the intense radiation environment. It has been applied successfully in low earth orbit operations, enhancing the operability of instruments by reducing system complexity and improving the accuracy of optical sensors.
The Ring PLLs offered by Silicon Creations illustrate a versatile clocking solution, well-suited for numerous frequency generation tasks within integrated circuit designs. Known for their general-purpose and specialized applications, these PLLs are crafted to serve a massive array of industries. Their high configurability makes them applicable for diverse synthesis needs, acting as the backbone for multiple clocking strategies across different environments. Silicon Creations' Ring PLLs epitomize high integration with functions tailored for low jitter and precision clock generation, suitable for battery-operated devices and systems demanding high accuracy. Applications span from general clocking to precise Audio Codecs and SerDes configurations requiring dedicated performance metrics. The Ring PLL architecture achieves best-in-class long-term and period jitter performance with both integer and fractional modes available. Designed to support high volumes of frequencies with minimal footprint, these PLLs aid in efficient space allocation within system designs. Their use of silicon-proven architectures and modern validation methodologies assure customers of high reliability and quick integration into existing SoC designs, emphasizing low risk and high reward configurations.
The Polar ID Biometric Security System by Metalenz revolutionizes smartphone biometric security with its advanced imaging capabilities that capture the full polarization state of light. This system detects unique facial polarization signatures, enabling high-precision face authentication that even sophisticated 3D masks cannot deceive. Unlike traditional systems requiring multiple optical modules, Polar ID achieves secure recognition with a single image, ideal for secure digital payments and more. Operating efficiently across various lighting conditions, from bright daylight to complete darkness, Polar ID ensures robust security without compromising user convenience. By leveraging meta-optic technology, it offers a compact, cost-effective alternative to structured light solutions, suitable for widespread deployment across millions of mobile devices.
EW6181 is an IP solution crafted for applications demanding extensive integration levels, offering flexibility by being licensable in various forms such as RTL, gate-level netlist, or GDS. Its design methodology focuses on delivering the lowest possible power consumption within the smallest footprint. The EW6181 effectively extends battery life for tags and modules due to its efficient component count and optimized Bill of Materials (BoM). Additionally, it is backed by robust firmware ensuring highly accurate and reliable location tracking while offering support and upgrades. The IP is particularly suitable for challenging application environments where precision and power efficiency are paramount, making it adaptable across different technology nodes given the availability of its RF frontend.
Altek Corporation's 3D Imaging Chip is designed to enhance three-dimensional sensing capabilities across various applications. By incorporating advanced image processing algorithms, it delivers superior depth perception and spatial awareness, making it well-suited for industries that require high precision and accuracy. This chip is particularly beneficial in robotics, automation, and surveillance, where accurate distance measurement and object tracking are critical.<br/><br/>The chip's innovative design allows for seamless integration with existing systems, optimizing performance without compromising on speed or quality. Its ability to deliver real-time processing enables dynamic interactions, providing improved user experiences in augmented and virtual reality environments. Moreover, the chip's energy-efficient construction ensures prolonged operation without excessive power consumption, making it an ideal choice for portable devices.<br/><br/>Altek's commitment to pushing the boundaries of imaging technology is evident in this 3D Imaging Chip. It combines hardware resilience with software intricacy, creating a robust solution that supports a multitude of applications, from industrial automation to healthcare equipment, enhancing operational efficiency through sophisticated visual data analysis.
The Hyperspectral Imaging System developed by Imec represents a significant advancement in the realm of imaging technology. This sophisticated system is capable of capturing and processing a wide spectrum of wavelengths simultaneously, making it ideal for detailed spectral analysis in both industrial and research applications. This imaging system is instrumental in providing accurate and high-resolution data that can be crucial in fields like agriculture, environmental monitoring, and medical diagnostics. Imec's Hyperspectral Imaging System is notable for its integration into small and efficient devices, enabling portable and flexible use in various scenarios. The system's design leverages cutting-edge nanoelectronics to ensure that it is both lightweight and highly functional, offering unparalleled performance on the go. Its ability to capture detailed spectral information expands its utility across multiple disciplines, making it a versatile tool for addressing complex analytical challenges. The unique technology behind this system is grounded in Imec's expertise in photonics and CMOS sensors, ensuring superior sensitivity and precision. This hyperspectral imaging technology is designed to provide real-time, reliable information with a high degree of accuracy, supporting applications that require detailed spectroscopic data, thus empowering industries to make more informed decisions.
Rockley Photonics has introduced the Bioptx Biosensing Band and Platform for sampling to strategic customers and partners. This complete biosensing solution is designed for wearables, capitalizing on the company's advanced silicon photonics platform, which facilitates comprehensive and non-invasive biomarker monitoring. Tailored for consumer and healthcare markets, the platform enables detailed physiological monitoring through short-wave infrared spectroscopy. Its miniaturized form factor is perfect for integration in wearable devices, offering a new dimension in health tracking and fitness diagnostics.
ArrayNav is a groundbreaking GNSS solution utilizing patented adaptive antenna technology, crafted to provide automotive Advanced Driver-Assistance Systems (ADAS) with unprecedented precision and capacity. By employing multiple antennas, ArrayNav substantially enhances sensitivity and coverage through increased antenna gain, mitigates multipath fading with antenna diversity, and offers superior interference and jamming rejection capabilities. This advancement leads to greater accuracy in open environments and markedly better functionality within urban settings, often challenging due to signal interference. It is designed to serve both standalone and cloud-dependent use cases, thereby granting broad application flexibility.
Silicon Creations offers a diverse suite of PLLs designed for a wide range of clocking solutions in modern SoCs. The Robust PLLs cover an extensive range of applications with their multi-functional capability, adaptable for various frequency synthesis needs. With ultra-wide input and output capabilities, and best-in-class jitter performances, these PLLs are ideal for complex SoC environments. Their construction ensures modest area consumption and application-appropriate power levels, making them a versatile choice for numerous clocking applications. The Robust PLLs integrate advanced designs like Low-Area Integer PLLs that minimize component usage while maximizing performance metrics, crucial for achieving high figures of merit concerning period jitter. High operational frequencies and superior jitter characteristics further position these PLLs as highly competitive solutions in applications requiring precision and reliability. By incorporating innovative architectures, they support precision data conversion and adaptable clock synthesis for systems requiring both integer and fractional-N modes without the significant die area demands found in traditional designs.
The FaintStar sensor is designed to excel in detecting low-light astronomical phenomena. This advanced sensor combines large pixel architecture with high sensitivity to capture faint signals with exceptional clarity. It is engineered to provide stellar image quality despite challenging lighting conditions in space, thanks to its integrated noise-reduction technologies. With applications primarily in astronomy, the FaintStar sensor supports missions that require precise and reliable low-light imaging solutions to unlock mysteries of the cosmos.
The MVUM1000 is a state-of-the-art ultrasound sensor array tailored for medical imaging applications. This linear array comprises up to 256 elements and is based on capacitive micromachined ultrasound transducers (CMUT), providing exceptional sensitivity and integrability with electronic interfaces. Boasting multiple imaging modes, such as time-of-flight and Doppler, these sensors can address a variety of medical diagnostic needs including point-of-care and handheld devices. The low power consumption combined with high sensitivity makes these sensors highly efficient for portable medical equipment. Functional across a wide range of frequencies, the MVUM1000 supports medical imaging with precision, offering device manufacturers flexibility in design with the possibility of integrating front-end electronics. It opens up new avenues for innovation in ultrasound technology while catering to ever-growing portable healthcare needs.
DigiLens has developed advanced waveguide optics specifically designed for XR and AR applications. These optics are distinguished by their capability to deliver high efficiency, brightness, and resolution, while maintaining a socially acceptable low eye glow, making them ideally suited for both indoor and outdoor usage. By integrating proprietary materials with an innovative inkjet printing and holographic contact copy process, DigiLens efficiently creates waveguides that are thin and lightweight, supporting enhanced user experiences across a variety of AR applications. The waveguides are designed to provide a high transmission rate of over 90% and can operate effectively in daylight, boasting a luminance exceeding 500 nits/lumen. This feature makes them adaptable for diverse environments, whether they be entertainment spaces or industrial settings. The design prioritizes user comfort and seamless integration into daily activities, offering a truly immersive experience. Further enhancing their functionality, these waveguides feature exceptional transparency that maintains the user's view of the real world while displaying augmented overlays. This duality enables interactive experiences without losing the natural visual connections essential for augmented reality. DigiLens' waveguides are thus a vital element for next-generation wearable tech, driving forward the practical integration of AR into various industries.
ELFIS2 represents a leap forward in high-speed imaging, particularly valuable for scientific research that demands rapid capture rates without sacrificing detail or clarity. This sensor enhances image quality under fast-paced conditions, perfect for understanding dynamic processes in both natural and laboratory settings. Its low-noise design further supports clarity in fast imaging scenarios, making it an ideal choice for scientific experiments that necessitate temporal precision along with visual accuracy.
Moonstone Laser Sources by Lightelligence provide cutting-edge photonic solutions aimed at facilitating advanced optical computing applications. These laser sources are tailored for high precision and efficiency, essential for tasks demanding robust photonic performance. The unique attributes of Moonstone make it suitable for integration into diverse technological frameworks where precision and reliability are paramount. As the backbone of optical computing, laser sources like Moonstone ensure that photonic applications achieve desired speed and accuracy, fostering greater innovation in photonics-driven technologies. With their focus on precision and application flexibility, Moonstone Laser Sources empower industries to explore new frontiers in photonics, supporting the evolution of next-generation computing technologies.
ASIC North's Sensor Interface Derivatives are specialized circuits designed to enhance sensor systems by improving their performance and integration into broader network architectures. These derivatives offer reliable operation across a wide range of applications, ensuring robust performance even in challenging environments. With a focus on customizability, the designs are adaptable to meet specific client needs, facilitating the development of efficient sensor networks.
SiGe BiCMOS Technology for RF from Tower Semiconductor is engineered for the RF communication domain, providing a high-performance solution suitable for various applications. By leveraging silicon-germanium technology, this technology offers enhanced speed and efficiency that is vital for wireless and broadband communication systems. Its precision and low noise capabilities make it an ideal choice for high-frequency, high-speed data transmission requirements. The technology facilitates seamless signal processing, which is crucial for maintaining the quality and integrity of communications. This makes it distinctly important in applications requiring reliable performance under challenging conditions. This technology also emphasizes its adaptability to a broad range of operating environments, ensuring consistent performance across diverse applications. With proven reliability, it bridges traditional RF limitations with the innovative prowess of BiCMOS technology, offering robust solutions for modern communication challenges.
The Orion Family of Pattern Projectors by Metalenz stands at the forefront of 3D depth sensing technology. Designed to enhance applications ranging from smartphones to AR/VR devices, Orion projectors create complex dot and line patterns using a single, flat meta-optic. These projectors support multiple illumination patterns, benefiting from a wide field of view and high power per dot to suit indoor and outdoor environments. Orion projectors feature Metalenz's unique meta-surface technology, which simplifies the assembly process by integrating all optical functions within one element. This drastically reduces component count and overall system height, enabling seamless incorporation into various platforms including mobile and robotics applications. The projectors are optimized for precise and efficient photon conversion emanating from VCSEL arrays. Notably, the Orion 18K pattern projector employs a pseudorandom arrangement of emitters, maximizing the contrast and power efficacy under diverse lighting scenarios. Its durability across temperature fluctuations further reinforces its suitability for a range of advanced sensing tasks.
Designed to revolutionize AI-driven data centers, the Photowave Optical Communications Hardware capitalizes on the inherent advantages of photonics. With capabilities that support PCIe 5.0/6.0 and CXL 2.0/3.0, this hardware facilitates enhanced scalability of AI memory applications within data centers. The technology provides significant latency reduction and energy efficiency, allowing for more effective resource allocation across server racks, which is a crucial feature for modern data infrastructure. The Photowave hardware serves the evolving needs of data-driven applications, ensuring seamless integration and performance boosts in environments demanding high-speed data transfer and processing. By addressing the latency and power efficiency concerns prevalent in traditional electronics, it is integral in the transition towards faster, more sustainable data center operations. Incorporating these photonic advantages, Photowave stands as a testament to Lightelligence’s goal of transforming data operations and enhancing the utility of AI technologies. Its role in this ecosystem is vital, making it a cornerstone product for entities looking to modernize their computational frameworks.
The Heimdall platform is engineered for applications requiring low-resolution image processing and quick interpretation. It integrates image signal processing capabilities into a compact design, perfect for IoT applications where space and power consumption are constraints. The platform supports various image-related tasks including object detection and movement tracking. With a core image sensor of 64x64 pixels, Heimdall is optimized for environments where minor details are less critical. This makes it ideal for motion sensing, smart lighting, and automation systems where the understanding of space occupancy or movement is essential. The platform's energy-efficient design, capable of integrating energy-harvesting technology, ensures sustainable operation in remote and hard-to-reach locations. By providing rapid image interpretation, Heimdall supports quick decision-making processes crucial for smart infrastructure and security applications.
A comprehensive photonic interconnect that delivers exceptionally high data throughput across various communication channels. It integrates seamlessly with existing systems to enhance performance in broadband applications. Designed for scalability, it supports significant data loads without compromising speed or reliability. Featuring low power consumption, its operation is both cost-effective and environmentally sustainable. The integration helps eliminate bottlenecks typically associated with high-volume data transfer, ensuring smooth and efficient data management across platforms.
The Mixed-Signal Front-End offered by Global Unichip Corp. is engineered to enhance analog signal processing capabilities, critical in various electronics industries. This technology provides a bridge between analog and digital domains, enabling precise signal processing and data conversion. The front-end is designed to work in tandem with complex silicon systems, leveraging cutting-edge mixed-signal IP to ensure optimal signal fidelity and resolution. This IP is particularly valuable in fields like telecommunications, automotive electronics, and consumer electronics, where analog signals must be accurately converted and processed within digital systems. The seamless integration into SoC structures offers flexibility and scalability for designers looking to enhance their chip capabilities without compromising on performance or efficiency. Moreover, Global Unichip's Mixed-Signal Front-End stands out with its robust customization capabilities, allowing for adaptations to specific needs and applications. This adaptability makes it a preferred choice for companies aiming to innovate within the confines of precise analog-digital interaction, ensuring that their systems can handle the rapid shifts in data inherent in modern electronics applications.
The AFBR-POC205A2 Optical Power Converter is a cutting-edge device designed to efficiently convert optical power into electrical energy, primarily used in high-speed data transmission applications. This modular device is equipped with robust features to support seamless integration into various optical networks, ensuring that it meets the performance demands of modern digital infrastructures. The design focus on minimizing power loss while maximizing conversion efficiency makes this product essential for optimizing energy use in optical systems. By leveraging advanced technology, the AFBR-POC205A2 enhances the ability to maintain stable power levels in communication networks. Its compatibility with a range of optical communication protocols broadens its applicability, ensuring that it can easily adapt to different system requirements. The compact and durable design ensures reliability and extended operational life, making it a cost-effective solution for businesses looking to enhance their network's efficiency and resilience. Incorporating the AFBR-POC205A2 into a digital infrastructure offers significant benefits including improved energy efficiency, reduced operational costs, and enhanced system robustness. It stands out in the optical power conversion segment by balancing superior performance with economic energy consumption, solidifying its role as a key component in advanced network architectures.
The AFBR-POC205A8 Optical Power Converter offers state-of-the-art technology designed to efficiently transform optical power into electrical power, crucial for meeting the increasing demands of high-capacity optical networks. This converter is engineered to deliver outstanding performance in a compact form, making it ideal for high-density network environments where space saving is critical. Its advanced functionality ensures minimal energy loss during conversion, thus optimizing the overall energy usage of the system. The device's compatibility with various optical protocols ensures its versatility across multiple networking platforms, allowing integration into both existing systems and new, cutting-edge setups. It ensures consistent delivery of high-quality power conversion under various operational conditions. With the AFBR-POC205A8, users benefit from enhanced reliability and efficiency, supporting more sustainable power management in digital communications. Its robust build ensures long-term operational stability, while its advanced technology assures adherence to the high-performance standards required within modern network infrastructures.
Expanding on its expertise with space applications, Surrey NanoSystems offers a specialized coating for satellite constellations. This coating, designed for easy application and handling, enhances the capabilities of modern satellite systems by reducing optical cross-talk and stray light in multi-satellite configurations. Specifically tailored for use in space, the coating ensures enduring performance even in the vacuum and radiation-rich environment of space. It serves critical roles in thermal management and optical optimization, aiding satellite payloads in achieving precise observational functions. By significantly improving light absorption, these coatings help maintain the functionality and longevity of space instruments, allowing for clearer imaging and accurate data collection over the satellite's operational life. This innovation contributes to more efficient and effective satellite operations, critical for telecommunications, Earth observation, and scientific exploration missions.
The Laser Driver from 1-VIA is devised to support high-speed optical connectivity in AI applications, guaranteeing efficient laser modulation and power control. As an integral part of the optical communication chain, this driver ensures optimized performance for systems requiring rapid data transmission and precise optical signal handling, making it crucial for current and emerging digital infrastructures. Featuring robust modulation methods, the Laser Driver provides stable operations under varying loads, enhancing the reliability and effectiveness of laser-based communications. Its design is tailored to address the issues of power efficiency and modulation complexity in the ever-growing domains of AI and telecommunications. 1-VIA’s Laser Driver exemplifies a dedication to advanced optical system solutions, where speed and precision are paramount. This product is instrumental in implementing AI-driven technologies that require dynamic and reliable laser sources, aiding in the development of next-generation optical and data systems with its outstanding modulation capabilities and energy-efficient design.
Rockley Photonics' Multi-Channel Silicon Photonic Chipset is engineered for high-speed data transmission applications. The chipset integrates hybrid III-V DFB lasers and electro-absorption modulators into a silicon photonics framework, allowing it to support 4×106Gb/s 400 GBASE-DR4 data rates over multiple channels. This highly efficient setup delivers significant optical modulation amplitude (OMA) and maintains a low TDECQ penalty, fully complying with IEEE standards. This chipset is particularly suited for optical communications, providing the robustness and speed necessary for demanding data centers and telecommunication infrastructures.
The Orca-C2X represents RADX’s commitment to extending high-performance solutions into PXIe systems through the integration of extreme performance NVIDIA GPUs and PCIe-to-PXIe subsystems. The Orca-C2X enables seamless operability between PXIe and PCIe environments, offering unrestricted bandwidth of up to 16 GB/Sec, outperforming traditional remote-control systems. Engineered for flexibility and futureproofing, Orca-C2X supports PCIe G3/G4 lanes, facilitating a wide range of PCIe devices across different system configurations. Its low-latency design ensures minimal delay, enhancing the performance of host and target adapters during seamless subsystem integration. The Orca-C2X also foregoes the need for Thunderbolt connections, boosting PCIe compatibility and system versatility with features like Re-Driver technology to further augment its low-latency operations, making it highly suitable for advanced computing environments that demand speed and precision.
The ATEK890P4 is a tunable high-pass filter designed for frequency ranges between 1 and 1.95 GHz. This innovative filter provides significant signal processing flexibility within the RF domain. With an impressive insertion loss of just 2 dB, the filter maintains excellent signal passage while managing interference rejection at 55 dBc effectively. Such tunability is instrumental in radio frequency applications where the operational environment may demand varying filtering characteristics. The capability to modify the filter's parameters enables tailored performance, essential for dynamic communication systems and stringent testing protocols. It is encased in a practical 4x4 mm QFN package conducive to efficient design incorporation. This filter caters to RF environments requiring adaptable filtering solutions, efficiently balancing between maintaining quality signal throughput and precise frequency discrimination, vital in advanced telecommunications and meticulous instrumentation.
The ATEK884P5 is a versatile tunable band-pass filter that spans a broad frequency range from 1 to 7.5 GHz, making it ideal for numerous RF applications. Designed to offer flexibility and precision, this filter features a low insertion loss of 11 dB and a rejection rate of 40 dBc, ensuring only desired frequencies are let through while unwanted ones are significantly attenuated. The device's tunability allows for frequent adjustments to accommodate different operational needs, making it particularly useful in applications that require adaptable RF environments such as in laboratory testing or dynamic communication systems. It is housed in a compact 4x4 mm QFN package, ensuring both ease of integration and high performance. Suitable for applications demanding dynamic frequency selection and enhanced signal clarity, the ATEK884P5 meets the needs of advanced communication systems and precision testing equipment, where performance and reliability are paramount.
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