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 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.
Altek's 3D Imaging Chip is a breakthrough in the field of vision technology. Designed with an emphasis on depth perception, it enhances the accuracy of 3D scene capturing, making it ideal for applications requiring precise distance gauging such as autonomous vehicles and drones. The chip integrates seamlessly within complex systems, boasting superior recognition accuracy that ensures reliable and robust performance. Building upon years of expertise in 3D imaging, this chip supports multiple 3D modes, offering flexible solutions for devices from surveillance robots to delivery mechanisms. It facilitates medium-to-long-range detection needs thanks to its refined depth sensing capabilities. Altek's approach ensures a comprehensive package from modular design to chip production, creating a cohesive system that marries both hardware and software effectively. Deployed within various market segments, it delivers adaptable image solutions with dynamic design agility. Its imaging prowess is further enhanced by state-of-the-art algorithms that refine image quality and facilitate facial detection and recognition, thereby expanding its utility across diverse domains.
The EW6181 GPS and GNSS Silicon is an advanced semiconductor solution specifically engineered for high-efficiency, low-power applications. This digital GNSS silicon offers a compact design with a footprint of approximately 0.05mm2, particularly when applied in 5nm semiconductor technology. Designed for seamless integration, the EW6181 combines innovative DSP algorithms and multi-node licensing flexibility, enhancing the overall device performance in terms of power conservation and reliability. Featuring a robust architecture, the EW6181 integrates meticulously calibrated components all aimed at reducing the bill of materials (BoM) while ensuring extended battery life for devices such as tracking tags and modules. This strategic component minimization directly translates to more efficient power usage, addressing the needs of power-sensitive applications across various sectors. Capable of supporting high-reliability location tracking, the EW6181 comes supplemented with stable firmware, ensuring dependable performance and future upgrade paths. Its adaptable IP core can be licensed in RTL, gate-level netlist, or GDS forms, adaptable to a wide range of technology nodes, assuming the availability of the RF frontend capabilities.
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.
ELFIS2 is a sophisticated visible light imaging ASIC designed to deliver superior performance under the extreme conditions typical in space. Known for its radiation hard design, it withstands both total ionizing dose (TID) and single event effects (SEU/SEL), ensuring dependable operation even when exposed to high radiation levels in outer space. This image sensor features HDR (High Dynamic Range) capabilities, which allow it to capture clear, contrast-rich images in environments with varying light intensities, without motion artifacts thanks to its Motion Artifact Free (MAF) technology. Additionally, its global shutter ensures that every pixel is exposed simultaneously, preventing distortion in high-speed imaging applications. Utilizing back-side illumination (BSI), the ELFIS2 achieves superior sensitivity and quantum efficiency, making it an ideal choice for challenging lighting conditions. This combination of advanced features makes the ELFIS2 particularly well-suited for scientific and space-based imaging applications requiring exacting standards.
The Polar ID Biometric Security System offers an advanced, secure face unlock capability for smartphones, utilizing groundbreaking meta-optics technology to capture the full polarization state of light. Unlike traditional biometric systems, Polar ID distinguishes the unique polarization signature of human facial features, which adds an additional security layer by detecting the presence of non-human elements like sophisticated 3D masks. This system eliminates the need for multiple complex optical modules, thus simplifying smartphone design while enhancing security. Designed to fit the most compact form factors, Polar ID uses a near-infrared polarization camera at 940nm paired with active illumination. This configuration ensures functionality across various lighting conditions, from bright outdoor environments to complete darkness, and operates effectively even when users wear sunglasses or face masks. Smartphone OEMs can integrate this secure and cost-effective solution onto a wide range of devices, surpassing traditional fingerprint sensors in reliability. Polar ID not only offers a higher resolution than existing solutions but does so at a reduced cost compared to structured light setups, democratizing access to secure biometric authentication across consumer devices. The system's efficiency and compactness are achieved through Metalenz's meta-optic innovations, offering consistent performance regardless of external impediments such as lighting changes.
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.
ZIA Image Signal Processing technology provides state-of-the-art solutions for optimizing image quality and enhancing vision-based systems. This technology is integral to applications requiring precise image analysis, such as surveillance cameras and automotive safety systems. It supports various image processing tasks, including de-noising, color correction, and sharpness enhancement, delivering superior visual output even under challenging conditions. ZIA's adaptable architecture supports integration into a range of devices, ensuring broad applicability across multiple sectors.
This technology leverages the strengths of both Silicon-Germanium (SiGe) and BiCMOS processes to produce highly efficient RF solutions. SiGe BiCMOS technology is particularly advantageous for its performance in high-frequency applications, making it ideal for RF and wireless communication technologies. The integration of BiCMOS allows for the combination of bipolar and CMOS transistors on a single chip, enhancing the capacity for analog signal processing alongside digital logic. The SiGe component offers a significant advantage in terms of speed and frequency, ensuring high-performance operation suitable for cutting-edge communication standards. By merging these technologies, the process achieves low-noise amplification and superior linearity, which are crucial for advanced telecommunication systems and data transfer technologies. This makes it a go-to choice for various industries, including aerospace and defense, where precision signal processing is paramount. Additionally, the technology comes with a comprehensive suite of design kits that facilitate seamless integration with existing systems. These kits provide everything from standard libraries to bespoke IP configurations, helping customers tailor their solutions efficiently and effectively. The flexibility and performance it offers make this technology a standout in the realm of RF engineering, addressing the needs of high-speed communication infrastructure.
The Hyperspectral Imaging System by Imec offers enhanced imaging capabilities, chiefly used in space exploration and Earth observation for on-chip spectral imaging. This technology allows for efficient data capture across numerous spectral bands, giving a comprehensive view that is critical for scientific and commercial applications. With its compact and robust design, the system delivers high-resolution imaging while maintaining the portability needed for field applications. This advanced imaging system leverages on-chip technology that combines innovative hardware and software solutions, contributing to its high efficiency and accuracy in capturing detailed spectral information. The hyperspectral imaging achieved allows for assembling vast datasets rapidly, which is valuable in various applications ranging from environmental monitoring to agricultural assessments. Incorporating lead-free quantum dot photodiodes, the system ensures environmentally friendly operation and precise spectral capture. The modular design of the system facilitates easy integration into existing platforms, expanding its usability across different sectors requiring advanced imaging capabilities.
The ArrayNav Adaptive GNSS Solution ushers in an era of enhanced automotive navigation, leveraging advanced adaptive antenna technology. This solution expertly applies multiple antennas to increase antenna gain and diversity, offering substantial advancements in navigation precision and operational consistency within complex environments. By integrating array-based technology, ArrayNav is tailored to improve the sensitivity and coverage necessary for sophisticated automotive systems. ArrayNav's use of adaptive antennas translates to significant reductions in issues such as multipath fading, which often affects navigation accuracy in urban canyons. With these enhancements, the solution ensures more reliable performance, boosting accuracy even in challenging terrains or when faced with potential signal interference. This solution has been specifically engineered for applications that demand robustness and precision, such as automotive advanced driver-assistance systems (ADAS). By employing the ArrayNav technology, users can benefit from higher degrees of jamming resistance, leading to safer and more accurate navigation results across a broad range of environments.
Photowave optical communications hardware is expertly crafted for the emerging needs of AI memory applications requiring disaggregated resources. Specifically engineered to be compatible with PCIe 5.0/6.0 and CXL 2.0/3.0, Photowave capitalizes on photonics to provide superior latency and energy efficiency. This technology is a game-changer for data centers, offering managers the ability to scale resources flexibly either within individual racks or across multiple server racks, paving the way for more adaptive and powerful data management solutions. By embracing the fundamental strengths of photonics, Photowave empowers large-scale computing systems to achieve previously unattainable levels of efficiency and responsiveness. This optical communication solution ensures seamless integration with state-of-the-art computing infrastructure, thus facilitating the shift towards more intelligent and modular computing environments which underpin the growth of AI-driven applications. The Photowave hardware is meticulously designed to uphold the highest standards in optical communication, ensuring fast data transfer capabilities that drastically reduce latency and improve the overall performance of computing tasks. In environments where swift and reliable data processing is paramount, Photowave stands out as a crucial component, helping optimize technological investments and boost the performance of AI and machine learning workloads.
The MVUM1000 stands out as a compact, advanced linear ultrasound array designed for medical imaging. Featuring 256 elements, it integrates capacitive micromachined ultrasound transducers (CMUT), enhancing both power efficiency and sensitivity. This integration aids in high-quality medical diagnostics and imaging applications.\n\nOffered with a range of adaptive imaging modes, such as Doppler, these arrays facilitate multifaceted ultrasound applications, from portable devices to comprehensive cart-based systems. They provide exceptional lateral and axial imaging capabilities, meeting rigorous clinical needs.\n\nThe sensor array is also characterized by a high degree of integration with electronics, enabling seamless embedding into various platforms. Its flexibility in operation and customizable features allow for expansive usability in point-of-care situations, ensuring healthcare professionals can deliver precise diagnostics efficiently.
The ZIA Stereo Vision technology is crafted for applications that require depth perception and accurate distance measuring. Utilizing stereo vision algorithms, it excels in generating 3D data from dual-camera setups, which is crucial for robots, drones, and autonomous vehicles. By employing advanced disparity mapping techniques, this technology ensures high fidelity in spatial analysis, making it particularly effective in dynamic environments. Its integration optimizes tasks that need real-time 3D depth information, aiding navigation and object placement.
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.
Akronic offers cutting-edge RF and mm-Wave IC design services, showcasing their expertise across various high-frequency subsystems of wireless radio transceivers. Their proficiency encompasses frequencies from a few MHZ to 100 GHz, embodying their capability in device modeling and chip layout at these wavelengths. By optimizing active biasing for peak performance against noise and power metrics, Akronic leverages sophisticated circuit topologies to guarantee low power consumption and minimal silicon footprint. Their design implements state-of-the-art techniques for simulation and packaging, ensuring that outcomes precisely match theoretical projections. Akronic's RF and mm-Wave IC designs support diverse applications, reinforcing their standing as leaders in the field.
GUC’s Mixed-Signal Front-End is designed to address the complex requirements of modern analog signal processing applications. This product blends both analog and digital circuits to efficiently manage and convert real-world signals into data that digital systems can process. Targeted at sectors where precise signal interpretation and processing are critical, this mixed-signal solution enhances the capability of system designs. The solution integrates various components necessary for complete signal chain management, ensuring minimal signal distortion and high-accuracy outcomes. It supports a wide range of applications from communications to industrial automation where data integrity is paramount. By compacting multiple functionalities into a single, optimized front-end, the solution reduces overall system complexity and cost. This Mixed-Signal Front-End is pivotal in systems where sensor data must be accurately translated into actionable digital information. Its versatile design supports developments in fields with stringent requirements for latency and performance, showcasing GUC’s commitment to engineering excellence in semiconductor solutions. By simplifying signal processing tasks, it extends the capabilities of integrated systems, setting new standards in analog processing technologies.
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.
Functioning as a tunable high-pass filter, the ATEK890P4 is optimized for operations in the 1 GHz to 1.95 GHz range. It showcases a tight insertion loss of 2 dB and a rejection of 55 dBc, ensuring clear and selective high-frequency signal passage. This filter is particularly advantageous for systems that demand rigorous high-pass filtering and performance stability in a 4x4 mm QFN format.
The ATEK884P5 is a sophisticated tunable band-pass filter designed for frequencies between 1 GHz and 7.5 GHz. It features finely adjustable properties that allow it to achieve up to 11 dB of insertion loss with a rejection ratio of 40 dBc. This makes it ideal for communication systems requiring precise filtering across a broad frequency range. Packaged in a 4x4 mm QFN, it offers both high performance and compact integration capabilities.
The AFBR-POC205A2 Optical Power Converter is engineered to convert optical power into electrical power efficiently. Designed to excel in networking hardware, this device ensures that optical signals are harnessed to fuel communications systems effectively. The product's architecture supports robust data integrity and efficient transmission, making it ideal for high-speed data applications. The optical to electrical power conversion capability introduces an innovative solution for power-efficient operations, especially in bandwidth-demanding environments. This converter showcases a sophisticated design, emphasizing reliability and efficiency. The AFBR-POC205A2 is particularly suited for environments requiring seamless data handling and resilience to power fluctuations. Integrated into network infrastructures, it can enhance system performance while minimizing energy consumption, aligning with sustainability goals. Featuring superior functionality, this optical power converter supports heightened electrical response sensitivity. Its design reduces power losses during conversion, leading to greater energy savings and increased operational lifespans of associated network components. Such efficiency is particularly beneficial in extensive data centers where high-performance and energy efficiency are paramount.
The AFBR-POC205A8 Optical Power Converter is a state-of-the-art solution designed to transform optical signals into electrical energy with exceptional efficiency. Key to modern data transmission systems, this converter facilitates the conversion process with minimal energy loss and maximal signal fidelity. Built for advanced network applications, the AFBR-POC205A8 integrates seamlessly with existing infrastructure, providing robust support for high-speed data requirements. Its innovative technology supports seamless data flow and integrity, crucial for maintaining operational efficiency in high-performance environments. The engineering precision of this device ensures reduced conversion bottlenecks, enhancing overall system throughput. Its capacity for maintaining signal strength post-conversion makes it invaluable in both large-scale and high-demand data communication settings. Additionally, its energy efficiency contributes to reduced operational costs, making it an economically favorable choice for enterprises aiming for sustainable practices.
FaintStar is an innovative sensor-on-a-chip designed for applications requiring medium to high accuracy, such as star trackers and navigation cameras. It boasts a 1020 x 1020 pixel configuration with a 10um pitch and features 12-bit A-to-D conversion. The device is flight-proven with Technology Readiness Level 9, incorporating 'light-to-centroids' image processing. FaintStar is equipped with a SpaceWire LVDS command/data interface, supporting speeds of 40Mb/s and 80Mb/s, ensuring swift data transmission critical for space missions. Its radiation tolerance includes TiD, proton, and SEE data mitigations, making it suitable for demanding space environments. Importantly, it is ITAR-free and complies with ESCC 2269000 and ESCC 9020 standards for flight model procurement. This sensor is an exceptional choice for space missions needing reliable and accurate imaging capabilities, leveraging Caeleste's advancements in sensor technology to push the boundaries of what these systems can achieve.
The PolarEyes Polarization Imaging System expands the horizons of imaging technology by utilizing metasurface optics to capture extremely detailed polarization data from visual scenes. Metalenz's PolarEyes system is engineered to reveal layers of information that traditional cameras miss, such as the texture and material properties of an object, by harnessing the full potential of light polarization. This system is especially transformative for applications in smart devices and automation, providing critical depth and texture information for enhanced decision-making processes in systems such as robotic vision and automotive sensors. By amplifying the richness of visual data with minimal additional hardware requirements, it supports the integration of more intelligent object recognition and environmental perception across a wide range of devices. PolarEyes not only increases the sensitivity and precision of optical sensors, but it does so within the form factor constraints typical of consumer electronics. This makes it a versatile solution for industries looking to elevate the performance capabilities of existing and new technologies without incurring significant changes to device architecture or budget.
The Crystal Waveguides by DigiLens are engineered to integrate seamlessly into various augmented reality devices, including smartglasses and smart helmets. These waveguides are pivotal in enhancing digital overlays on real-world environments, providing superior performance across consumer, enterprise, and industrial applications. Designed for high brightness and efficiency, the waveguides deliver exceptional image quality with ultra-low eye glow, making them ideal for both personal and professional use. DigiLens' proprietary CrystalClear® material is a highlight of the 30th generation waveguides, offering unmatched versatility and integration ease. This technology is supported by a scalable manufacturing process that enables rapid design iterations and product optimizations. The waveguides are not just about high-performing optics; they also focus on maintaining natural eye appearance and enhancing user comfort through reduced eye glow. By leveraging a unique combination of inkjet printing technology and holographic processes, these waveguides promise next-level user experiences by melding digital content seamlessly with the physical world. The latest iterations are not only lightweight and ready for consumer markets but also cater efficiently to enterprise needs, reinforcing DigiLens’ leadership in the field of augmented reality.
The XPH90 platform is cutting-edge technology designed to harness silicon-on-insulator (SOI) for photonics, integrating III-V materials for superior data transmission. It supports high-efficiency electro-optic modulators and state-of-the-art grating couplers. This platform is designed to meet the burgeoning requirements of high-speed data center communication, telecom, and LiDAR applications, thanks to its integration of various photonics devices. It offers multiple etch levels for enhanced optical performance and supports materials with high and low refractive indices for optimized coupling with III-V components.
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