All IPs > Analog & Mixed Signal > Sensor
The Sensor Semiconductor IP category under the Analog & Mixed Signal section at Silicon Hub offers a diverse range of solutions tailored for integrating advanced sensing functionalities into various electronic applications. Sensors play a crucial role in bridging the physical world with digital systems, making them indispensable in today's technology-driven environments. These IPs enable the seamless integration of sensors with analog and mixed signal components, significantly enhancing the performance and efficiency of the resulting devices.
Within this category, you'll find semiconductor IPs that cater to a broad spectrum of sensor types, including but not limited to, temperature sensors, pressure sensors, accelerometers, gyroscopes, and biosensors. These IPs are designed to ensure accurate data conversion and interpretation, translating real-world phenomena into readable electronic signals. By incorporating these IPs, developers can significantly reduce time-to-market and development costs, all while ensuring high-performance standards and reliability.
Sensor semiconductor IPs are crucial for applications across numerous industries, ranging from consumer electronics, automotive, and healthcare to industrial automation and IoT. For example, in the automotive industry, sensor IPs are integral to systems such as stability control, airbag deployment, and engine management, contributing to safety and efficiency. In healthcare, they enable precise wearable health monitoring devices that track vital signs and physical activity, offering unprecedented improvements in patient care.
Choosing the right sensor IP can make a considerable difference in the functionality and market success of a product. At Silicon Hub, we aim to provide comprehensive solutions, combining flexibility, accuracy, and resilience to meet the diverse needs of modern electronic designs. Explore our collection to find the perfect sensor semiconductor IPs for your next groundbreaking project.
Designed for high-speed transmission, the 16x112G Tx Chiplet showcases superior integration with 16 channels, each operating at 112Gbps. It includes a modulator and driver within a single silicon unit, optimized for optical communication systems requiring high-speed, high-bandwidth data transfer. This sophisticated chiplet ensures seamless modulation of optical signals, supporting efficient driver control and optimized data transmission. The integrated design simplifies system architecture, reducing the overall footprint while maintaining exceptional reliability and performance. Its built-in digital control aids in managing complex signal processing requirements, suitable for diverse applications within optical networking infrastructures. Verifying its design through silicon-proven processes assures users of its capability to meet rigorous industry standards. The application of this chiplet spans high-speed data centers, telecommunications networks, and beyond, where its efficiency and performance are indispensable. The innovation behind its creation reflects Enosemi's dedication to advancing optical technology, offering clients robust and reliable tools to meet current and future communication needs.
Silicon Creations' Analog Glue solutions provide essential analog functionalities to complete custom SoC designs seamlessly. These functional blocks, which constitute buffer and bandgap reference circuits, are vital for seamless on-chip clock distribution and ensure low-jitter operations. Analog Glue includes crucial components such as power-on reset (POR) generators and bridging circuits to support various protocols and interfaces within SoCs. These supplementary macros are crafted to complement existing PLLs and facilities like SerDes, securing reliable signal transmission under varied operating circumstances. Serving as the unsung heroes of chip integration, these Analog Glue functions mitigate the inevitable risks of complex SoC designs, supporting efficient design flows and effective population of chip real estate. Thus, by emphasizing critical system coherency, they enhance overall component functionality, providing a stable infrastructure upon which additional system insights can be leveraged.
The RIOT100 sensor by NOVELIC is a sophisticated device focused on accurate human presence detection through advanced radar technology. Engineered to be highly sensitive, this sensor excels in detecting micromovements, whether occupants are in motion or stationary. This capability makes it particularly useful for energy-saving applications in smart lighting and IoT systems. Operating efficiently across diverse environments, the RIOT100 can be integrated invisibly behind materials like glass or wood, making it adaptable for both residential and commercial applications. Its customizable detection range, up to 25 meters, allows it to ignore irrelevant movements, focusing on designated areas to maintain privacy and confidentiality in sensitive locations. With built-in signal processing, the RIOT100 provides immediate feedback and requires no external data processing units, streamlining installation and functionality. Such features enable the sensor to serve in high-precision applications like security systems, hospitality, and public spaces, ensuring both reliability and efficiency across a broad spectrum of uses.
Polar ID is revolutionizing biometric security by using meta-optic technology to read the unique polarization signature of human faces. This innovative approach significantly improves security, effectively differentiating between real and fake faces primarily through its precise polarization detection capabilities. The system operates efficiently in all lighting conditions thanks to its near-infrared illumination at 940nm, making it versatile enough for both indoor and outdoor settings. It's designed to be compact, suitable even for smartphones with limited space, and significantly more cost-effective compared to conventional structured light solutions. Polar ID not only enhances security by preventing unauthorized access through spoofing with masks or photos, but it also elevates user convenience through its seamless integration into mobile devices. The absence of bulky notch requirements further underscores its design excellence. Its technological makeup stems from Metalenz's proprietary meta-optics, which allows it to fuse advanced functionality into a single compact system. Additionally, Polar ID eliminates the need for additional optical modules, integrating itself as a single image-based recognition and authentication solution. By adopting a complete system approach, Polar ID is set to redefine digital security across a vast array of consumer electronics, including smartphones and IoT devices. This meta-optic advancement is also projected to enhance future applications, likely extending into secure digital transactions and possibly medical diagnostics, broadening the horizons for secure biometric technology in personal and professional spheres.
Altek's 3D Imaging Chip offers cutting-edge depth sensing technology, suitable for applications requiring medium to long-range recognition. This technology enhances precision in surveillance systems and transport robots. With years of experience in 3D sensing technology, the chip provides comprehensive and integrated from module to chip solutions, ensuring high accuracy. Its advanced capabilities allow for robust identification performance across diverse environments, reinforcing Altek's reputation in the imaging sector.
The REFS, a robust band-gap and PTAT current reference, is designed to bolster RF, analog, and mixed-signal integrated circuits with significant stability even across varied operational conditions. This component outputs currents and voltages that remain consistent against temperature fluctuations, making it indispensable in high-precision electronic environments. It features multiple outputs referenced to both internal and external resistors, all of which are programmable within a flexibility range of ±30% to support custom calibration needs.
The aLFA-C sensor is recognized for its innovative design, tailored for precise imaging applications spanning various fields, including life sciences and industrial use. This sensor harnesses cutting-edge technology to deliver exceptional image quality, boasting a high-speed operation, low noise, and enhanced dynamic range to accommodate diverse imaging requirements. Its versatile architecture supports both scientific research and industrial imaging applications, making it a valuable tool for professionals seeking accuracy and reliability.\n\nEngineered to perform optimally in challenging conditions, the aLFA-C sensor is suitable for capturing detailed images in environments demanding high sensitivity and accuracy. Whether it's employed in medical diagnostics or industrial inspections, the sensor consistently provides high-resolution outputs. Its design facilitates seamless integration into complex imaging systems, thereby enhancing overall performance and reliability.\n\nThe aLFA-C is particularly suited for applications where speed and precision are critical. Its advanced features allow for effective operation across a breadth of environments, ensuring that users gain clear, precise insights from their imaging data. This flexibility extends its applicability in areas such as medical imaging, where accurate visualization is crucial, and industrial settings, where durability and performance cannot be compromised.
The agileVGLITCH voltage monitor provides security and protection against voltage side-channel attacks (SCAs) and tampering such as supply voltage changes/glitches and power supply manipulation. The sensor provides digital outputs to warn (secure) processors of intrusion attempts, thus enabling a holistic approach to hardware security. As a key part of the agileSCA TVC (Temperature, Voltage, Clock) security sensor this can be tuned to your specifications. It is ideally suited for monitoring in application areas such as IoT, AI, security and automotive. Agile Analog designs are based on tried and tested architectures to ensure reliability and functionality. Our automated design methodology is programmatic, systematic and repeatable leading to analog IP that is more verifiable, more robust and more reliable. Our methodology also allows us to quickly re-target our IP to different process options. Our highly configurable and multi-node analog IP products are developed to meet the customer’s exact requirements. These digitally-wrapped and verified solutions can be seamlessly integrated into any SoC, significantly reducing complexity, time and costs.
ISELED technology integrates the functionality of an LED driver with RGB LEDs into a singular, smart component, drastically enhancing automotive lighting systems. This innovative approach simplifies the design and control of lighting effects, allowing for direct color calibration at the LED manufacturer level. ISELED significantly reduces the system complexity by automating color mixing and temperature compensation directly within the LED module. This technology supports seamless communication through a bidirectional protocol, enabling the precise control of individual and clustered LEDs. This level of control allows ISELED to cater to a wide range of automotive lighting applications, from ambient to functional and dynamic effects, delivering superior illumination and aesthetic appeal. ISELED also excels in energy efficiency by using a simple 5V supply and integrating a DC/DC conversion for power management. It supports various lighting configurations, enhancing the vehicle's interior ambiance and user experience, while promoting scalability and robustness against power outages.
The C100 is a highly integrated SoC designed for IoT applications, boasting efficient control and connectivity features. It is powered by an enhanced 32-bit RISC-V CPU running at up to 1.5GHz, making it capable of tackling demanding processing tasks while maintaining low power consumption. The inclusion of embedded RAM and ROM further enriches its computational prowess and operational efficiency. Equipped with integrated Wi-Fi, the C100 facilitates seamless wireless communication, making it ideal for varied IoT applications. It supports multiple types of transmission interfaces and features key components such as an ADC and LDO, enhancing its versatility. The C100 also offers built-in temperature sensors, providing higher integration levels for simplified product designs across security systems, smart homes, toys, healthcare, and more. Aiming to offer a compact form factor without compromising on performance, the C100 is engineered to help developers rapidly prototype and bring to market devices that are safe, stable, and efficient. Whether for audio, video, or edge computing tasks, this single-chip solution embodies the essence of Chipchain's commitment to pioneering in the IoT domain.
The MVPM100 Series offers cutting-edge particulate matter sensors that excel in compactness and accuracy, designed specifically for detecting PM2.5 particles. Leveraging advanced microsystem technology, these sensors measure the mass of particles directly, a method that provides superior precision compared to conventional optical sensors. Their versatile interface options and minimal power requirements make these sensors an ideal choice for a wide array of applications, with particular utility in environments that demand reliable air quality monitoring. These sensors cater to industrial, consumer, medical, and automotive sectors, ensuring broad applicability. The MVPM100’s compact form factor and robust design mean they are suitable for integration within various systems, offering consumer and industry professionals a trusted technology for high-quality particulate detection.
The THOR platform is a versatile tool for developing application-specific NFC sensor and data logging solutions. It incorporates silicon-proven IP blocks, creating a comprehensive ASIC platform suitable for rigorous monitoring and continuous data logging applications across various industries. THOR is designed for accelerated development timelines, leveraging low power and high-security features. Equipped with multi-protocol NFC capabilities and integrated temperature sensors, the THOR platform supports a wide range of external sensors, enhancing its adaptability to diverse monitoring needs. Its energy-efficient design allows operations via energy harvesting or battery power, ensuring sustainability in its applications. This platform finds particular utility in sectors demanding precise environmental monitoring and data management, such as logistics, pharmaceuticals, and industrial automation. The platform's capacity for AES/DES encrypted data logging ensures secure data handling, making it a reliable choice for sectors with stringent data protection needs.
The ASPER short-range radar sensor by NOVELIC is a groundbreaking solution that provides superior environmental awareness around vehicles through its 79 GHz frequency band. Designed for automotive applications, ASPER replaces conventional ultrasonic park assist systems, offering a superior 180-degree field of view with a single module. This allows for comprehensive 360-degree coverage with the use of multiple sensors, enhancing detection reliability and reducing blind spots. ASPER's high frequency aids in achieving outstanding accuracy and resolution, crucial for parking assistance and collision warning systems. The radar can detect obstacles as close as 5 cm and as far as 100 meters, making it an ideal choice for urban environments where precision is paramount. With its robust design, ASPER functions effectively even in adverse conditions like fog or dirt, maintaining high performance without interference from environmental factors. The versatility of ASPER extends to various applications, such as blind spot detection, rear cross-traffic alerts, and automated door opening. Its edge processing capabilities allow for domain-specific processing, integrating easily into existing vehicle systems via CAN interfaces. This innovative radar solution is not only cost-effective but also simplifies system complexity, offering a modern alternative to traditional sensors.
Imec's Hyperspectral Imaging System is designed for advanced optical sensing applications. This system integrates state-of-the-art sensors that can capture high-resolution spectral data across a wide range of wavelengths. Utilizing Imec's expertise in compact chip design, the system is engineered to be both portable and efficient, making it suitable for industries such as agriculture, food safety, and environmental monitoring. Its sophisticated image processing algorithms and user-friendly interface allow for seamless integration into existing workflows, providing comprehensive data analysis and reporting capabilities.
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.
The MVH4000 Series are highly precise sensors for measuring relative humidity and temperature. These sensors are engineered using advanced Silicon Carbide MEMS technology, providing excellent long-term stability and reliability. With a swift response time and minimal power consumption, they are perfect for applications requiring fast and accurate environmental monitoring. These compact sensors, ideal for critical PCB real estate, include on-chip calibration, enabling straightforward integration into existing systems. Each sensor in the series offers different accuracy grades and outputs, allowing users to select the model that best fits their needs. The sensors' digital (I2C) or analog outputs ensure compatibility with a wide range of systems. Notably, their long-term stability and accuracy contribute to lowering the total cost of ownership, making them a cost-effective choice for industrial, consumer, medical, and automotive applications. The MVH4000 Series also come in a compact form factor of 2.5 x 2.5 x 0.9 mm, making them easy to fit into space-constrained devices. Additionally, the sensors’ robust design supports a broad operating temperature range from -40 to 125°C, making them suitable for diverse environments and demanding applications.
Our range of sensing integrated circuits caters to both photonic and capacitive detection needs. These ICs are designed to simplify the complexity of system design and minimize risks associated with their implementation. Whether dealing with basic photo-diode array detection or sophisticated low-noise photon detection solutions, our analog front ends are engineered to support a wide range of applications. Charge sensors in this series are equipped with multi-channel A-to-D conversion, setting a high bar in noise performance, ADC linearity, and resolution. These innovations are particularly beneficial in medical imaging, like digital X-ray panels, and other scanning technologies such as CT and PET scanners. Fingerprint detection and particle detection also benefit from the robust capabilities of these sensing ICs. Additionally, our capacitive sensing ICs cater to touch screen interfaces, providing high sensitivity along with excellent signal interference rejection. These features are vital for robust performance across varying screen formats and are critical in applications such as interactive digital displays and rugged touch-based systems.
The FaintStar Sensor-on-a-Chip exemplifies cutting-edge sensor technology. Developed to support the European Space Agency's HERA mission, this sensor demonstrates outstanding performance during planetary missions, like the Mars flyby, by capturing faint light signals under challenging conditions. Its design emphasizes high sensitivity and low noise, ensuring clear image capture even in low-light environments. Built with advanced ADCs directly on the wafer, the FaintStar system enhances readout efficiency and reliability.\n\nThis sensor is designed for applications requiring exceptional detection capabilities in the realm of space exploration. Its ability to operate efficiently in high-radiation environments further extends its usage to scientific research and space missions. By maintaining a balance between speed and operational efficiency, it supports a wide range of imaging applications, contributing to space discovery and the advancement of astrophysics.\n\nThe FaintStar Sensor-on-a-Chip also features a robust architecture tailored for high-yield volume production, which caters to the needs of imaging systems demanding outstanding throughput and precision. The sensor's architectural innovation allows it to excel in its role within space missions, where reducing size and optimizing power consumption are paramount. Additionally, its seamless integration into high-precision imaging systems makes it indispensable for scientific and exploratory endeavors.
Trion FPGAs by Efinix cater specifically to the edge computing and Internet of Things (IoT) market. These versatile FPGAs are designed with a flexible architecture that serves a wide range of logic applications, making them an excellent choice for general-purpose computing needs. With support for applications demanding both high performance and low power, Trion FPGAs provide an ideal environment for innovative designs that push the boundaries of IoT technology. Designed to integrate seamlessly within existing systems, they're ideal for applications needing agile solutions capable of processing at the network's edge, bringing new capabilities to IoT deployments and smart technology installations. From 4K to 120K logic elements, Trion offers scalable solutions to cater to varied project needs, empowering designers to tailor solutions specifically for their unique requirements.
The Stereax line by Ilika represents a leap in micro solid-state battery technology, particularly suited for the healthcare industry and industrial IoT applications. With a focus on miniaturization, these batteries are ultra-thin, rechargeable, and entirely free from liquid or polymer components, making them safe and reliable for sensitive environments like active medical implants and smart sensors. Stereax batteries boast long life with thousands of recharge cycles, ensuring durability and sustainable use over time. The innovative design of Stereax allows them to be seamlessly integrated into devices with limited space, offering a miniature power solution that does not compromise on energy efficiency or safety. Their rectangular form factor is similar to integrated circuits, expanding their compatibility with various applications. In partnership with Cirtec Medical, Ilika is ensuring the global commercial availability of Stereax, which targets markets requiring secure, compact, and efficient energy solutions. Potential applications range from neurostimulation and cardiac sensing to various smart medical and industrial IoT sensors, underlining Stereax's versatility and the significant advantages it brings to miniaturized technology.
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.
EnSilica’s eSi-Analog suite offers a broad array of Analog IP solutions essential for integrating analog functions into custom ASIC and SoC devices. Proven across various process nodes, these solutions are renowned for their performance, power efficiency, and adaptability to customer specifications, thereby expediting time-to-market and lowering costs. With an extensive range of easy-to-integrate IPs, eSi-Analog encompasses high-performance blocks like oscillators, SMPSs, PLLs, LDOs, and more, each optimized for low power consumption and high resolution. The flexibility of this IP suite allows for adaptation to various application needs, supporting industries as diverse as automotive and healthcare with critical analog capabilities. Specialized in enabling SoC platforms with robust analog interfaces, this IP package features components like temperature sensors and ultra-low power radios. The solutions in eSi-Analog are designed to integrate seamlessly across major foundry technologies, offering a competitive edge for customers seeking to enhance system performance with reliable analog solutions.
Ubi.cloud is an innovative geolocation solution by Ubiscale designed for device and chipset makers. It fundamentally shifts power-draining GPS and Wi-Fi processes from devices to the cloud. This transition helps in significantly reducing the size and cost of the devices, while dramatically improving their power efficiency. The utilization of cloud-based processing allows for reduced hardware requirements, thereby enabling smaller device footprints and lower energy consumption rates. By focusing on minimizing the physical and energy demands on IoT devices, Ubi.cloud addresses major engineering challenges associated with Global Navigation Satellite System (GNSS). These challenges include managing the life-time of devices, miniaturization constraints due to limited battery capacity, and the integration of various hardware features. Additionally, the cost efficiencies gained from this cloud-centric processing alleviate budgetary pressures, making IoT deployment more economically viable. Ubi.cloud's innovative approach not only supports the creation of more sustainable and efficient IoT devices but also enhances the user's experience by enabling more reliable and robust tracking features. It sets a new benchmark in making IoT solutions more accessible and effective for a wide range of applications.
Archband Labs' Cap-less LDO Regulator is crafted to offer excellent power regulation without the need for external capacitors. It is suited for a variety of compact electronic devices that require efficient voltage stabilization. This regulator stands out due to its minimal footprint and power consumption, making it an ideal solution for portable and space-constrained applications. It ensures stable voltage output and reduces noise, offering a high level of interference immunity which is critical in maintaining the performance of sensitive electronic components. With its focus on energy efficiency, the Cap-less LDO Regulator is engineered to provide consistent output even under variable load conditions. The simplicity of not requiring external components also reduces the overall system cost and design complexity, aiding in quicker development cycles and more robust device longevity.
The MVDP2000 Series showcases a line of highly sensitive differential pressure sensors designed for precision and robustness in demanding environments. These sensors apply a proprietary capacitive sensing technology that ensures digital calibration across temperature and pressure variables, thus enhancing accuracy and reliability. With a compact size and power efficiency, the MVDP2000 sensors are ideal for applications requiring fast response and low power usage, such as portable and OEM devices. Their range of use includes respiratory equipment, gas flow instruments, and pressure monitoring systems in various industries. These sensors provide quick analog and digital outputs with resolutions between 15 to 21 bit, maintaining an error band of less than 1% FS. Their broad operating range and low power draw further bolster the sensors’ applicability, catering especially to consumer and medical industries.
The MVT4000D Series digital temperature sensors utilize proprietary Silicon Carbide MEMS technology to offer exceptional accuracy and stability. Rated for industrial-grade applications, these sensors are highly responsive, with a typical response time of only 2 seconds, making them ideal for environments where rapid temperature shifts occur. The design focuses on delivering precise temperature readings with a high accuracy of ±0.2°C over an extensive operating temperature range from -40°C to 125°C. The sensors are digitally calibrated, enhancing their reliability and making them ready to deploy without the need for further calibration. Their small size and low power draw, paired with their digital I2C output, allow seamless integration into various systems while conserving energy, thereby extending battery life for portable applications. These sensors find applications across different industries including industrial, consumer electronics, medical, and automotive sectors.
The VoSPI Rx for FLIR Lepton IR Sensor is designed to cater to infrared sensor needs for various applications. Specially configured to support the FLIR Lepton sensor, this receiver facilitates effective and precise data handling of infrared signals, crucial in environments demanding high thermal accuracy. It provides real-time processing capabilities, aligning with the rigorous demands of security and monitoring applications. This receiver excels in maintaining data integrity, ensuring that the thermal data transmitted across platforms is of the highest accuracy. Its sophisticated engineering allows it to work seamlessly with other system components, enhancing system performance and reliability. The receiver is integrated with features that boost signal processing while minimizing latency, providing a seamless operational environment. This ensures that users can rely on it for consistent performance across various industry applications, boosting both efficiency and reliability.
The 802.15.4 Transceiver Core is a specialized solution for ultra-low power and reliable wireless communication networks. It is designed to support the IEEE 802.15.4 standard, which is the backbone of protocols such as Zigbee. This core provides robust and secure networking capabilities, making it an ideal choice for applications in Smart Metering, Home Automation, and Industrial Automation sectors. Its operation in the 2.4GHz band ensures a balance between range and data rate, which is optimal for maintaining low power consumption while ensuring reliable data transmission. Optimized for small form factor devices, the 802.15.4 Transceiver Core features advanced power management techniques, extending the battery life of portable and wireless sensor devices. It integrates comprehensive security features to protect data integrity and prevent unauthorized access, catering to the growing demand for cybersecurity in IoT networks. The core’s architecture supports rapid deployment of mesh networking, allowing devices to communicate over extended distances by routing through intermediate devices. Compatibility with other communication standards is another asset of the 802.15.4 Transceiver Core, enabling integration with wider network infrastructures. This ensures flexibility in deployment, allowing seamless expansion and adaptation in dynamic environments. Its robust design and efficient operation make it a cornerstone in modern wireless sensor networks, facilitating the realization of smart, interconnected ecosystems.
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.
The Dynamic PhotoDetector (DPD) by ActLight specifically designed for smartphone applications marks a considerable advancement in mobile light sensing technology. This sensor is crafted with enhanced sensitivity and efficiency, capable of adjusting its operational parameters dynamically based on ambient light conditions. It ensures the optimum performance of smartphone features reliant on light sensing, such as automatic screen brightness adjustment and camera functionalities. Notably, the DPD achieves this while maintaining a lower power consumption profile than conventional alternatives, which is a significant advantage for today's power-hungry smartphones that demand long battery life. Its state-of-the-art design encapsulates high-performance metrics in a small, cost-effective package, allowing manufacturers to integrate it into devices without substantial adjustments in design and costs. This technology not only improves user experience by providing smoother, more responsive control over light-related smartphone features but also supports the burgeoning trend towards more eco-friendly, energy-efficient consumer electronics, reducing the overall energy footprint of modern mobile devices.
The MVWS4000 Series integrates three crucial environmental sensors—humidity, pressure, and temperature—into one compact device. This all-in-one sensor solution leverages advanced Silicon Carbide technology to offer enhanced reliability and optimal performance. Designed with fast response times, these sensors are tailored for applications that demand precision and efficiency, such as battery-powered and OEM applications. They provide various accuracy grades to cater to diverse budget requirements, ensuring they are both versatile and cost-effective. Robust in construction and small in form, the MVWS4000 maintains long-term stability, boasting excellent precision with minimal power consumption. Their digital I2C and SPI output interfaces simplify incorporation into modern systems, making them an excellent choice for industrial, consumer, medical, and automotive markets.
Analog Bits delivers a comprehensive suite of sensor solutions that facilitate precise monitoring of process, voltage, and temperature (PVT), as well as power supply monitoring both on-chip and at system level. Their sensors boast a minimal footprint and are fully integrated into the die, ensuring enhanced power delivery integrity and protection against anomalies like voltage spikes. These sensors, proven at nodes as small as 5nm, are a reliable choice for ensuring energy efficiency and operational integrity in a wide range of applications. They empower software load balancing, thereby optimizing energy efficiency, while covering extensive PVT monitoring capabilities essential in modern semiconductor environments.
ActLight's Dynamic PhotoDetector (DPD) for Smart Rings introduces a new dimension of light sensitivity tailored to the intricacies of ring-sized wearable technology. This innovation focuses on maximal efficiency and minimal size, offering wearers enhanced interaction and monitoring capabilities through improved light detection. Perfectly suited for devices requiring continuous power management, the DPD allows smart rings to maintain functionality over extended periods without draining their compact power sources. The sensor’s ability to adjust dynamically to ambient lighting conditions also enhances its utility in diverse environments, providing accurate readings no matter the surrounding light conditions. This feature is particularly beneficial for applications in fitness and health tracking, where accurate data collection is paramount. Additionally, integrating seamlessly into a ring form factor, the DPD supports the creation of elegant, minimalist designs that consumers in the smart jewelry market seek. The DPD technology presents an ideal solution for smart rings that need to deliver robust functionality, efficient power usage, and exquisite design all in one, ultimately enabling makers to craft next-generation smart jewelry that pushes the boundaries of what's possible in wearables.
Archband Labs' SAR ADC is optimized for precision and speed, engineered for applications in high-performance computing and complex instrumentation. Known for its low latency and high resolution, this ADC is perfect for systems needing reliable and meticulous data conversion. Designed with innovative successive approximation techniques, Archband's SAR ADC excels in environments that require fast data acquisition and processing. Its low power consumption trait ensures it can be integrated into power-sensitive devices without sacrificing performance. This ADC is highly versatile, featuring adaptable resolution settings and noise reduction capabilities, tailored to suit a wide range of application needs, from consumer electronics to industrial measurement systems. Its compact design also makes it suitable for systems constrained by space without compromising the quality and speed of data handling.
The ELFIS2 Image Sensor stands at the forefront of modern imaging technology, designed to deliver superior performance across a variety of demanding applications. This sensor excels in environments where precision and low noise are paramount, making it an invaluable asset in fields such as space exploration and scientific imaging. Its advanced architecture ensures that the ELFIS2 can accurately capture detailed images even under challenging conditions, demonstrating outstanding sensitivity and resilience.\n\nIncorporating state-of-the-art technology, the ELFIS2 Image Sensor offers remarkable noise reduction and enhanced image clarity, which are essential for capturing critical data in low-light scenarios. Its robust design supports high-speed imaging processes, providing users with the ability to conduct thorough analysis and deliver critical insights in real-time. This sensor is particularly suitable for applications within scientific research, offering a reliable solution for projects that require precision and accuracy in data acquisition.\n\nThe ELFIS2's architecture is built to support a wide range of imaging needs, facilitating use in both terrestrial and space-based applications. Whether utilized in laboratory environments or onboard spacecraft, this sensor provides consistent, high-quality imaging, establishing it as a go-to solution for researchers and engineers alike. Its versatility and reliability make it an essential component in the toolkit of those engaged in cutting-edge scientific and technological exploration.
1D Optical Micrometers are essential tools designed for high-precision measurement of diameters, gaps, and displacements of cylindrical objects and other geometrical features. These devices are particularly suited for industries where accurate, non-contact measurement is necessary for maintaining quality and precision, such as in wire, rod, and tubing inspections. Series such as the RF651 provide efficient measurement capabilities over various ranges from 5 mm to 100 mm, with astonishing low error margins and high sampling rates of up to 10,000 Hz. This ensures reliable data collection at high speeds, making them indispensable for dynamic measurement tasks where fast feedback is required to monitor and control manufacturing processes. The optical design of these micrometers allows for robustness and versatility in handling complex measurement tasks under varying environmental conditions. They prioritize precision through their sophisticated optical systems, yielding high-resolution output critical in sectors like electronics and precision engineering. Furthermore, these instruments excel in providing end-to-end measurement solutions that can be integrated into automation systems, allowing for seamless data flow and enhanced process control. By minimizing setup complexity, they contribute significantly to reduced downtime and increased efficiency in production environments.
Aeonic Insight provides advanced on-die telemetry capabilities, facilitating unprecedented insight into power grids, clock health, and SoC security. This IP is designed to deliver actionable intel through sensor modules specifically built for a range of applications including datacenter CPUs, AI accelerators, and automotive systems. Featuring process-portable architecture, these sensors efficiently scale across advanced process nodes while maintaining power and area efficiency. The provision of industry-standard interfaces also enhances their compatibility with third-party platforms, making them versatile in diverse design environments.
Certus Semiconductor's Analog I/O offerings bring ultra-low capacitance and robust ESD protection to the forefront. These solutions are crafted to handle extreme voltage conditions while securing signal integrity by minimizing impedance mismatches. Key features include integrated ESD and power clamps, support for broad RF frequencies, and the ability to handle signal swings below ground. Ideal for high-speed RF applications, these Analog I/Os provide superior protection and performance, aligning with the most demanding circuit requirements.
Tower Semiconductor's CMOS Image Sensor Technology is at the forefront of imaging solutions, delivering superior image quality and performance. This technology incorporates cutting-edge pixel design and integration techniques to meet the demanding needs of high-resolution imaging applications. It's widely used in various fields, from consumer electronics to automotive safety systems. This advanced CMOS technology is characterized by its low power consumption and high-speed processing capabilities, making it ideal for portable and battery-operated devices. It also offers high sensitivity and noise reduction, which enhances image clarity in low-light conditions, a crucial feature for surveillance and security applications. The versatility of Tower Semiconductor's image sensor technology supports a spectrum of resolutions and configurations, allowing for customized solutions tailored to specific application needs. This adaptability to a wide range of environments makes it a preferred choice for industries requiring precise and dependable imaging solutions.
The Neuropixels Probe developed by Imec is a cutting-edge tool for neuroscience research, providing unprecedented neural recording capabilities. This high-density probe, equipped with numerous electrodes, allows researchers to simultaneously capture electrical activity from hundreds of neurons with high temporal and spatial resolution. Ideal for brain-computer interface studies and complex neural network analysis, the probe offers real-time data acquisition and is instrumental in advancing our understanding of brain functions. Its compact and minimally invasive design is specifically tailored to facilitate long-term implantation, ensuring minimal tissue damage during and after experiments.
ZIA ISP is a compact image signal processing core designed for AI camera systems, delivering enhanced visual data processing. Featuring compatibility with Sony's high-sensitivity sensors, it excels in harsh environments like rain or fog, providing noise-free imaging. Leveraging high dynamic range (HDR) technology, it supports a dynamic range of up to 120dB, ensuring detailed image capture.
The Human Body Detector from Microdul AG is an ultra-low-power sensor designed to significantly enhance energy efficiency in wearable devices. It operates by detecting the presence of a human body, thus enabling devices to switch to low-power modes when not in use. This functionality is particularly beneficial for devices like fitness trackers and smartwatches, where conserving battery life is crucial. The sensor's static operation capability further aids in reducing unnecessary power consumption, ensuring that devices remain operational for extended periods. Utilizing advanced sensing technology, this detector provides reliable performance even in dynamic environments. Its compact design makes it suitable for integration into various wearable formats without compromising on comfort or functionality. The sensor's versatility ensures adaptability across a wide range of applications, enhancing device functionality through intelligent power management. Ideal for IoT and wearable applications, the Human Body Detector stands out due to its efficiency and precision. With Microdul's expertise in ultra-low-power design, this sensor is crafted to meet the demands of modern device users who require durable and energy-efficient solutions.
NOVELIC's ACAM in-cabin monitoring solution is a revolutionary 60 GHz radar sensor designed for comprehensive vehicle interior surveillance. It combines high precision sensing with privacy protection, providing an unobtrusive way to monitor the presence of passengers, including detecting whether a child has been left unattended. The technology is finely tuned to differentiate between living beings and objects, ensuring accurate readings without requiring a direct line of sight, therefore preserving passenger privacy. ACAM is equipped with versatile applications that enhance vehicle safety and comfort. Its features include the ability to detect seat occupancy, offer intrusion alerts, and monitor vital signs like respiration rates, even through obstacles like heavy clothing. The solution is designed to work seamlessly across various lighting and weather conditions, ensuring reliability and minimal false alarms. The innovative design of ACAM also includes gesture control capabilities, allowing for contactless operation of car features, thus improving driver focus and vehicle operation convenience. Consequently, this technology not only improves safety standards in vehicles but also aligns with future Euro NCAP requirements for modern passenger cars, providing an upgrade path for existing vehicles to achieve top safety ratings.
Optical Component Building Blocks by Enosemi comprise a suite of essential components engineered to streamline the creation of sophisticated optical systems. These building blocks include a variety of optical devices such as waveguides, modulators, and detectors, each designed to ensure seamless optical signal routing and processing. With a focus on reliability and integration, these components are developed through extensive testing and validation processes. They ensure high performance and compatibility, enabling the construction of efficient and scalable optical networks. By adopting these building blocks, developers can reduce design complexity and enhance system robustness. The versatility of these components allows them to be used across various sectors, including telecommunications, data centers, and imaging systems. Their innovative design supports rapid prototyping and deployment, offering clients a significant advantage in the fast-paced world of optical technology.
Enosemi's photonic subsystems are integral to the development of advanced optical circuits, providing comprehensive solutions that integrate multiple optical components into cohesive systems. These subsystems facilitate efficient light signal modulation, amplification, and conversion necessary for complex optical networking tasks. By utilizing validated designs and comprehensive testing methodologies, these subsystems offer high reliability and performance. They support a wide array of applications, from high-capacity data transmission networks to intricate photonic processing systems, enabling groundbreaking advancements in optical circuit technology. The subsystems are crafted to meet diverse client needs, offering customization options to suit specific application requirements. This flexibility ensures that clients can leverage the latest photonic technologies to optimize their systems and achieve superior operational efficiency and effectiveness.
The agileIRDROP IR Drop Sensor is a circuit to detect supply IR drops within the system. It is useful to detect loss of power or attacks to the power supply. The agileIRDROP consists of a voltage reference and comparator(s) set at different threshold levels for multi-level detection. The number of trigger outputs can be customized, and each threshold can be adjusted during operation to support DVFS operation. A four-output configuration is shown in the block diagram as reference. Agile Analog designs are based on tried and tested architectures to ensure reliability and functionality. Our automated design methodology is programmatic, systematic and repeatable leading to analog IP that is more verifiable, more robust and more reliable. Our methodology also allows us to quickly re-target our IP to different process options. Our highly configurable and multi-node analog IP products are developed to meet the customer’s exact requirements. These digitally-wrapped and verified solutions can be seamlessly integrated into any SoC, significantly reducing complexity, time and costs.
The Ultra-Low-Power Temperature Sensor by Microdul AG is engineered to provide precise thermal readings while maintaining minimal power consumption, making it ideal for IoT devices and energy-harvesting applications. This sensor is optimized for environments where long battery life is a critical requirement, providing accurate temperature monitoring without the high energy cost associated with traditional sensors. By offering a low-power solution, this sensor contributes to the overall efficiency of systems such as environmental monitors and portable gadgets. Its application is particularly beneficial in smart home systems and wearable technology, where keeping track of temperature with minimal power usage is essential to maintaining prolonged operation. Microdul’s design emphasizes both accuracy and energy efficiency, ensuring that each deployment yields reliable results. The sensor's integration into IoT frameworks allows for broader data-driven insights, supporting advancements in automated control systems and responsive applications that rely on temperature data.
Tailored for hearables, the Dynamic PhotoDetector (DPD) from ActLight offers significant improvements in ambient light detection crucial for enhancing user experiences in audio devices. The DPD is designed with a focus on low power consumption, ensuring extended use without frequent battery charges, which is a critical feature for earbuds and other in-ear devices. This technology facilitates the creation of adaptive audio environments by accurately responding to light variations, ultimately leveling up the performance of any audio-centric wearable technology. Its miniaturized profile combined with high sensitivity paves the way for more compact and efficient hearable designs, allowing manufacturers to build devices that are as aesthetically pleasing as they are functional.
The Orion line of pattern projectors by Metalenz is a game-changer in the field of 3D depth sensing for various platforms, including smartphones, robotics, and the Internet of Things (IoT). These projectors stand out for their revolutionary meta-optic design, which allows for the generation of complex patterns such as dots and lines with high contrast and wide field illumination. This is achieved by transforming emissions from a VCSEL (Vertical-Cavity Surface-Emitting Laser) into defined projection patterns using a singular, flat optical element. The Orion projectors are versatile, finding applications across many technological domains, such as face authentication, gesture recognition, and obstacle detection. With their ability to maintain performance under diverse lighting conditions, both indoors and out, these projectors overcome common limitations faced by traditional pattern projectors. Moreover, Orion's compactness and simplified integration process make them ideal for devices where space is at a premium. One of the standout models, the Orion 18K, brings remarkable efficiency by replacing multiple complex lens barrels with a single meta-optic, enhancing system performance while also reducing production costs. Its design reduces z-height, making it compatible with thin-profile devices, revolutionizing the deployment of high-performing optical systems in consumer devices and automotive applications alike.
ZORM is an industrial zone monitoring solution by NOVELIC designed to ensure safety and operational efficiency in challenging environments. Utilizing a 60 GHz mmWave radar sensor, ZORM effectively creates defined safety zones around industrial machinery, providing precise detection of human presence and movement. This sensor ensures machinery halts operations if a human presence is detected within a danger zone, resuming only when it is deemed safe. ZORM’s robust architecture allows it to perform reliably in harsh conditions, including areas with significant dust, fog, or extreme temperatures. ZORM supports multiple targets, tracking stationary and moving objects by assessing speed, direction, and distance. This capability makes it an invaluable tool for environments requiring stringent safety standards, offering compliance with leading international safety regulations. The radar’s capability to seamlessly integrate with existing safety systems further enhances its appeal as a comprehensive solution for industrial safety requirements.
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