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.
ArrayNav represents a significant leap forward in navigation technology through the implementation of multiple antennas which greatly enhances GNSS performance. With its capability to recognize and eliminate multipath signals or those intended for jamming or spoofing, ArrayNav ensures a high degree of accuracy and reliability in diverse environments. Utilizing four antennas along with specialized firmware, ArrayNav can place null signals in the direction of unwanted interference, thus preserving the integrity of GNSS operations. This setup not only delivers a commendable 6-18dB gain in sensitivity but also ensures sub-meter accuracy and faster acquisition times when acquiring satellite data. ArrayNav is ideal for urban canyons and complex terrains where signal integrity is often compromised by reflections and multipath. As a patented solution from EtherWhere, it efficiently remedies poor GNSS performance issues associated with interference, making it an invaluable asset in high-reliability navigation systems. Moreover, the system provides substantial improvements in sensitivity, allowing for robust navigation not just in clear open skies but also in challenging urban landscapes. Through this additive capability, ArrayNav promotes enhanced vehicular ADAS applications, boosting overall system performance and achieving higher safety standards.
The Polar ID Biometric Security System represents a major innovation in smartphone security, offering a simplified yet highly secure face unlock solution. Unlike traditional systems, Polar ID uses breakthrough meta-optic technology to capture the unique 'polarization signature' of a face, enabling it to detect and prevent spoofing attempts with exceptional accuracy. This system provides more than 10 times the resolution of existing facial authentication solutions, functioning reliably under various light conditions, from bright daylight to complete darkness. It achieves this with a single low-profile near-infrared polarization camera and a 940nm illumination source, eliminating the need for bulky and expensive optical modules. Furthermore, the Polar ID not only reduces the required footprint of the technology, allowing it to fit into more compact form factors, but it also lowers costs, making secure face recognition accessible to a broader range of devices. This advancement in biometric technology is particularly valuable for mobile and consumer electronics, offering enhanced security without sacrificing convenience. The Polar ID sets a new benchmark for mobile security solutions with its unique combination of size, security, and cost-efficiency.
Vantablack S-VIS is a revolutionary space-qualified coating renowned for its unparalleled ability to suppress stray light. This is crucial for enhancing the performance and precision of optical instruments used in space applications. With its spectrally flat absorption capabilities extending from the UV range to the near-millimeter (THz) range, Vantablack S-VIS significantly improves light absorption, reducing interference and enhancing image quality. The coating has demonstrated exceptional performance in harsh environments, thriving under the intensity of solar, lunar, and terrestrial light in a zero-gravity context. Its deployment has resulted in lighter and smaller calibration systems and baffles, which is critical for space-bound equipment where size and weight are significant constraints. These coatings enhance emissivity across the IR spectrum, making them ideal for blackbody calibration in IR cameras and other sensitive optical systems. Since its initial deployment in low Earth orbit, the Vantablack S-VIS has amassed a significant track record of success in space missions. It possesses excellent thermal stability and is resistant to radiation and extreme vibrational forces, ensuring reliability and longevity in challenging space conditions. These attributes, coupled with its lightweight nature, make Vantablack S-VIS an optimal choice for advanced space imaging technologies.
The Multi-Channel Silicon Photonic Chipset by Rockley Photonics represents a milestone in high-speed data transmission technology. It combines silicon photonics with the hybrid integration of III-V Distributed Feedback (DFB) lasers and electro-absorption modulators to deliver a high-performance chipset capable of supporting data rates of up to 400 GBASE-DR4. Each channel in the transmitter achieves substantial optical modulation amplitude (OMA) and a high extinction ratio with minimal TDECQ penalty, ensuring compliance with IEEE standards. This chipset is tailored for high-bandwidth and high-data rate applications, providing the essential infrastructure for advanced data communication networks. By merging III-V DFB lasers with electro-absorption modulators, the system can operate efficiently across multiple channels, enhancing data transfer speeds while maintaining signal integrity. The innovation of this chipset lies in its multi-channel design, which facilitates increased data throughput and reliability. It is particularly useful in data centers and network systems where rapid data exchange is critical. Rockley's chipset also emphasizes energy efficiency and signal precision, which are crucial for meeting the growing demands of modern telecommunications architectures and network environments.
The EW6181 is a cutting-edge multi-GNSS silicon solution offering the lowest power consumption and high sensitivity for exemplary accuracy across a myriad of navigation applications. This GNSS chip is adept at processing signals from numerous satellite systems including GPS L1, Glonass, BeiDou, Galileo, and several augmentation systems like SBAS. The integrated chip comprises an RF frontend, a digital baseband processor, and an ARM microcontroller dedicated to operating the firmware, allowing for flexible integration across devices needing efficient power usage. Designed with a built-in DC-DC converter and LDOs, the EW6181 silicon streamlines its bill of materials, making it perfect for battery-powered devices, providing extended operational life without compromising on performance. By incorporating patent-protected algorithms, the EW6181 achieves a remarkably compact footprint while delivering superior performance characteristics. Especially suited for dynamic applications such as action cameras and wearables, its antenna diversity capabilities ensure exceptional connectivity and positioning fidelity. Moreover, by enabling cloud functionality, the EW6181 pushes boundaries in power efficiency and accuracy, catering to connected environments where greater precision is paramount.
The MVUM1000 features a 256-element linear ultrasound array tailored for medical imaging applications. Capitalizing on capacitive micromachined ultrasound transducers (CMUT), it offers superior sensitivity and low power consumption. The array can be integrated with front-end electronics and supports multiple imaging modes, including time-of-flight and Doppler. This versatility, combined with minimal energy requirements, makes it well-suited for advanced medical imaging, including portable and traditional ultrasound devices.
The aLFA-C product is an advanced interfacing ASIC designed for space applications, specifically for infrared readout ICs (ROICs) and other image sensors. It integrates much of the typical front-end electronics infrastructure in a single solution, offering versatility through features such as operation on a single unregulated supply using onboard LDOs and regulators, and compatibility with external clocks or crystal oscillators. Communication with external devices is achieved via a SpaceWire interface, and a programmable sequencer with 8 levels of nesting enhances the control towards the ROIC. Capable of handling 32 programmable digital outputs, the aLFA-C also allows the customization of input thresholds and output formats, supporting CMOS, LVDS, and CML. Its analog acquisition system includes 32 signal channels plus 4 reference channels, each with differential or single-ended input capability and 16-bit ADC resolution. The ADCs are equipped with features like calibration and post-correction, supporting various configurations for enhanced speed and performance. Additionally, the aLFA-C provides several programmable voltage sources and current outputs, accompanied by measurement capabilities for resistance, voltage, and current, making it extremely flexible for a wide range of applications. Its design is robust against radiation, exhibiting tolerance against TID, SEU, and SEL, and operates efficiently in temperatures from 35K to 330K, making it ideal for the harsh environments of space.
The FaintStar star sensor-on-a-chip device is a crucial component for precise space navigation and tracking. It features a resolution of 1020 x 1020 pixels, equipped with a 10μm pitch, facilitating high-precision detection of star patterns. The sensor incorporates a 12-bit A-to-D converter, which enhances the dynamic range and accuracy of the imaging process. Designed with advanced 'light-to-centroids' image processing capabilities, the FaintStar offers rapid and precise calculation of star positions, critical for navigation systems requiring real-time data handling. The space-proven status (TRL9) underscores its reliability and effectiveness in operational space conditions. Additionally, the sensor supports a SpaceWire LVDS command/data interface, allowing for efficient data communication. Engineered for durability, the FaintStar is radiation-tolerant, handling the harsh conditions encountered in space environments. It is compliant with ESCC 2269000 evaluation and ESCC 9020 flight model procurement, indicating its adherence to space hardware standards and ensuring its readiness for mission-critical applications.
The Bioptx Biosensing Band and Platform is groundbreaking in continuous health monitoring, leveraging spectroscopy to expand biomarker detection for hydration and body temperature. This platform integrates Rockley's advanced Bioptx Band with their Developer API, offering cloud connectivity and enhanced software integration. Notably, it merges SWIR laser-based spectroscopy with traditional LED-based photoplethysmography (PPG), creating a novel category of non-invasive biosensing in a wearable format. This facilitates continuous physiological data collection, delivering real-time insights into tissue composition. Key features of the Bioptx Platform include the ability to measure body temperature, hydration, heart rate, heart rate variability, respiratory rate, and blood oxygen saturation. Through its miniature SWIR spectrophotometer, the platform collects spectral data over several days, presenting users with detailed insights into tissue dynamics. Compatible with Rockley's Developer API, this platform provides a comprehensive solution for monitoring vital signs through continuous data flow and cloud-based analysis. The Bioptx Platform stands out due to its integration of advanced biomarker sensing capabilities in a wearable device, empowering users with real-time monitoring and analysis of vital health metrics. This novel use of spectroscopy for hydration assessment exemplifies its potential to impact health and wellness monitoring significantly, providing unprecedented insights into key physiological parameters.
Moonstone, an offering from Lightelligence, is a highly versatile laser source available in both single and multi-wavelength configurations. Unlike conventional laser packages, Moonstone features a compact design and enhanced temperature management, making it a cost-effective and modular solution for diverse applications including telecommunications, LiDAR, and sensor technologies. The product leverages an automated optical packaging process that integrates off-the-shelf laser chips with the Moonstone carrier through advanced techniques like eutectic soldering and die-bonding. The ensuing laser assembly enables a free-space coupling method for single wavelength use, and a multiplexing approach for multi-wavelength scenarios, optimizing optical signal combination and transmission efficiencies. Moonstone's precision engineering and thermal regulation provide low coupling losses and high output power, suitable for demanding environments where high-speed and high-bandwidth data transmission are crucial. It serves a vital role in optical computing, offering substantial power delivery while maintaining a low phase noise footprint, thus bolstering AI computational capacities significantly.
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.
ASIC North specializes in creating sensor interface derivatives, custom-designed to enhance existing system functionalities. These interfaces are strategically developed to seamlessly integrate with a myriad of industry applications, offering precision and adaptability. Through cutting-edge design practices, ASIC North ensures that these sensor interface circuits can handle a diverse array of inputs, providing reliable data conversion and processing across different environments.<br><br>Each sensor interface derivative is crafted to meet the specific needs of advanced technological systems, supporting applications such as IoT devices, smart home technologies, and industrial automation. Utilizing a comprehensive design and testing methodology, ASIC North guarantees high performance and compatibility with current industry standards. This meticulous attention to detail helps improve system reliability and operational efficiency.<br><br>By choosing ASIC North's sensor interface derivatives, companies benefit from unparalleled technical support and innovative solutions tailored to their unique challenges. These interfaces not only enhance the capabilities of existing systems but also ensure scalability and future-proofing, aligning with dynamic technological advancements and evolving market trends.
The Yuzhen 600 is a highly efficient RFID chip designed for robust IoT applications. This chip provides swift and accurate transmission of data, making it an ideal choice for inventory management and tracking systems. Its architecture emphasizes energy efficiency, ensuring prolonged operational life in the field. Yuzhen 600's advanced communication protocols support seamless integration into various IoT networks, enhancing system performance and reliability.
DigiLens offers high-performance waveguide optics designed specifically for XR and AR applications. These optics are known for their outstanding transparency and minimal eye glow, making them socially acceptable and user-friendly. They provide an efficient solution for both indoor and outdoor use, with high transmissivity and excellent brightness levels that cater to a variety of applications.\n\nThe waveguide optic design is focused on delivering an exceptional user experience by combining lightweight and durable materials with high performance. DigiLens employs its proprietary inkjet printing and holographic techniques to ensure the unwavering quality and consistency of its optic offerings. This allows for rapid development cycles and cost-effective production, providing a competitive edge in the market.\n\nWith these optics, DigiLens aims to set new standards for AR and XR technologies by facilitating seamless integration and enhanced functionality. The integration of these high-efficiency waveguides into smartglasses enables users to work smarter by blending digital information with the physical world, which is crucial for various industry applications.
Tower Semiconductor offers a sophisticated SiGe BiCMOS technology specifically designed for radio frequency (RF) applications. Known for achieving exceptional high-speed and low-noise performance, this technology is pivotal in the development of RF circuits. It supports scalable production for a variety of communications technologies, ensuring high linearity and low power consumption. The platform enables a comprehensive range of frequencies, making it ideal for consumer, infrastructure, and automotive applications demanding rapid data processing capabilities. The SiGe BiCMOS technology integrates both bipolar and CMOS processes, allowing for superior device performance and greater design flexibility. This integration supports applications like wireless communications, providing designers with a versatile toolkit to meet difficult design challenges. The technology is supported by extensive Tower Semiconductor fabrication facilities, ensuring high yield and superior quality manufacturing. Key applications include integration in power management systems, RF amplifiers, and high-speed analog signal processing units. Designed to be robust and efficient, The SiGe BiCMOS platform is well-cross-qualified across multiple geographic locations, ensuring uninterrupted global supply and adaptable manufacturing capabilities. Tower Semiconductor continues to enhance this technology to enable advanced RF design solutions, boosting development opportunities for cutting-edge technology systems in modern automotive and communication infrastructures.
The ARINC 818-3 IP Core builds upon previous standards to offer more robust features for high-speed video transmission in avionics systems. It complies with ARINC 818-3 specifications, which include improvements in data management and transmission efficiency over its predecessors. Ideal for the demanding environments of aerospace applications, this IP core provides heightened bandwidth and enhanced performance capabilities. It facilitates the transmission of various high-definition video protocols, catering to the increasing complexity of avionic systems. The ARINC 818-3 IP Core supports complex video processing tasks with minimal latency, making it suitable for integration in modern avionics platforms. With its superior performance metrics, the core is pivotal in refining data transmission and operational efficiency in avionic networks. Like its ARINC 818-2 counterpart, the ARINC 818-3 is provided with extensive documentation, offering a ready-to-integrate package that includes VHDL or Verilog synthesizable files. iWave’s technical support ensures seamless implementation, thus enhancing development processes within aerospace systems.
The Orion Family of Pattern Projectors from Metalenz is a series of high-performance, compact projector systems designed to enhance 3D depth sensing. These projectors leverage advanced meta-optic technology to convert laser emissions into highly detailed dot, line, or flood patterns, making them ideal for various applications including smartphones, AR/VR systems, and industrial robotics. A key element of their design is the integration of multifunctional elements into a single, flat optic, which streamlines the production process and reduces the size and cost of the system. The Orion 18K, a prominent model in this family, generates approximately 18,000 dots in a pseudorandom pattern using a VCSEL array, offering high contrast even under challenging lighting conditions. Additionally, these projectors are renowned for their robust optical performance, stable operation across a wide temperature range, and ease of integration into existing systems. Their capability to replace multiple traditional optical elements with a single meta-optic not only simplifies assembly but also enhances the precision and efficiency of 3D sensing applications. With their compact design and powerful performance, Orion Pattern Projectors are setting a new standard in the field of optics for depth sensing and recognition technologies.
The ARINC 818-2 IP Core is engineered to facilitate high-speed serial digital video transmission within avionics systems. This core adheres to the ARINC 818-2 standard, ensuring data reliability and integrity. It's ideally suited for advanced avionics applications, providing features for video conversion and transmission over fiber optic channels. With its scalable architecture, the ARINC 818-2 IP Core can easily adapt to different system requirements, offering flexibility in designing novel avionic solutions. Furthermore, this IP core supports versatile configurations, addressing a wide range of video applications in the aerospace industry. By integrating the ARINC 818-2 IP Core, users can achieve seamless connectivity between high-resolution compliant video equipment, enhancing the overall effectiveness of their avionic systems. It also supports various video resolutions and data throughputs, aligning with contemporary aerospace demands. Delivered with thorough documentation and VHDL or Verilog synthesizable RTL, the ARINC 818-2 IP Core enables rapid prototyping, system integration, and design refinement. iWave Systems offers full technical support to ensure efficient deployment and troubleshooting, making this IP core a valuable asset for avionics manufacturers.
The High-Performance Photonic Interconnect by Pacific MicroCHIP is a sophisticated solution tailored for advanced telecommunications applications. It seamlessly integrates with other optical components and delivers exceptional data throughput, enhancing speed and efficiency in communication systems. This product is critical for modern networks needing robust connectivity at lower latency levels.
The ARINC 818 Switch is designed to manage multiple ARINC 818 protocol video streams, providing efficient routing and switching solutions for high-speed video data within avionics systems. This switch is a vital component for avionics manufacturers seeking robust solutions for video management across multiple channels or nodes. It supports high-density data environments, allowing for seamless integration with existing avionic systems that utilize the ARINC 818 protocol. By consolidating multiple video streams, the ARINC 818 Switch enhances data flow control without compromising on data integrity or throughput. Its architecture ensures reduced latency and increased transfer rates, which are crucial for applications requiring synchronized video feeds, such as navigational or operational guidance in aircraft. Designed to be both versatile and reliable, the ARINC 818 Switch comes with comprehensive documentation and is fully supported by iWave's technical team, facilitating smooth integration into complex avionic systems. This makes it an excellent choice for advanced video processing and management tasks in aerospace environments.
The Time-to-Digital Converter (TDC) Core is a high-precision component designed for applications requiring exceptional timing accuracy. With an impressive time resolution of just 5 picoseconds, this core sets new benchmarks in precision measurement. Its capability to deliver accurate digital outputs from time intervals makes it indispensable in a variety of high-speed data applications. Utilizing the breakthrough CP-Line (Carry and Propagation) technology, this TDC core ensures that every digital delay is managed seamlessly to optimize performance. It's particularly advantageous in areas like test and measurement, high-frequency trading systems, and advanced communication systems where microsecond latency can be critical. The core’s compact design minimizes integration challenges, allowing it to fit into diverse systems requiring exact timing mechanisms. Its digital nature ensures that it is immune to many of the issues affecting traditional analog solutions, such as offset and drift, ensuring reliable and repeatable results.