All IPs > Analog & Mixed Signal > Temperature Sensor
The category of Analog & Mixed Signal > Temperature Sensor in the Silicon Hub encompasses a wide range of semiconductor IPs designed to enable precise temperature monitoring within various electronic systems. These IPs are pivotal in ensuring reliable performance of electronic products by providing accurate temperature data, which is essential for maintaining optimal operating conditions and preventing thermal-related failures.
Temperature sensors within this category come in diverse forms, including analog and digital outputs, leveraging innovative mixed signal design techniques to achieve high precision despite varying environmental conditions. Key applications of these semiconductor IPs can be found in sectors such as consumer electronics, automotive, industrial automation, and healthcare devices, where temperature monitoring is critical for operational efficiency and safety.
Integrating temperature sensor IPs into semiconductor designs simplifies system architecture by reducing the need for additional discrete components, thereby saving space and power while enhancing overall functionality. In automotive applications, for example, these sensors are crucial for monitoring engine temperature, battery thermal management, and cabin climate control systems. In consumer electronics, they ensure safe battery operation and efficient thermal management for gadgets like smartphones and laptops.
Overall, temperature sensor semiconductor IPs play a vital role in the development of modern electronic systems by providing the precise temperature measurement capabilities required for various thermal management applications. Silicon Hub offers a comprehensive selection of these IPs, tailored to meet the stringent demands of today’s advanced technology ecosystems, ensuring your products are equipped with the latest in thermal sensing innovation.
The Chipchain C100 is a pioneering solution in IoT applications, providing a highly integrated single-chip design that focuses on low power consumption without compromising performance. Its design incorporates a powerful 32-bit RISC-V CPU which can reach speeds up to 1.5GHz. This processing power ensures efficient and capable computing for diverse IoT applications. This chip stands out with its comprehensive integrated features including embedded RAM and ROM, making it efficient in both processing and computing tasks. Additionally, the C100 comes with integrated Wi-Fi and multiple interfaces for transmission, broadening its application potential significantly. Other notable features of the C100 include an ADC, LDO, and a temperature sensor, enabling it to handle a wide array of IoT tasks more seamlessly. With considerations for security and stability, the Chipchain C100 facilitates easier and faster development in IoT applications, proving itself as a versatile component in smart devices like security systems, home automation products, and wearable technology.
The Time-Triggered Protocol (TTP) designed by TTTech is an advanced communication protocol meant to enhance the reliability of data transmission in critical systems. Developed in compliance with the SAE AS6003 standard, this protocol is ideally suited for environments requiring synchronized operations, such as aeronautics and high-stakes energy sectors. TTP allows for precise scheduling of communication tasks, creating a deterministic communication environment where the timing of data exchanges is predictable and stable. This predictability is crucial in eliminating delays and minimizing data loss in safety-critical applications. The protocol lays the groundwork for robust telecom infrastructures in airplanes and offers a high level of system redundancy and fault tolerance. TTTech’s TTP IP core is integral to their TTP-Controller ASICs and is designed to comply with stringent integrity and safety requirements, including those outlined in RTCA DO-254 / EUROCAE ED-80. The versatility of TTP allows it to be implemented across varying FPGA platforms, broadening its applicability to a wide range of safety-critical industrial systems.
BCD technology uniquely combines the traits of Bipolar, CMOS, and DMOS transistors to deliver efficient power management solutions. This technology is engineered to handle a range of power requirements, making it a versatile choice for applications spanning from consumer electronics to industrial equipment. The blend of these transistor types offers both high voltage handling capabilities and precise digital control. Bipolar transistors contribute excellent analog performance, while CMOS transistors provide intricate digital logic benefits. DMOS transistors add high current and voltage tolerance, resulting in a robust technology that excels in power-driving applications. This combination allows devices to efficiently manage power dissipation, significantly reducing energy waste and enabling longer battery life for portable devices. The BCD process supports the implementation of complex circuits with enhanced reliability. It is well-suited for automotive industries and consumer products requiring solid state power control. With the integration of multiple transistor types, the technology advances superior power management solutions, offering improved efficiency, thermal performance, and scalability. Tower Semiconductor ensures this process is backed by comprehensive design resources, allowing customers to harness the full potential of BCD technology for diverse applications.
The ELFIS2 Image Sensor is a sophisticated development from Caeleste tailored for advanced imaging applications. It is designed to offer unparalleled image fidelity across a plethora of environments, making it an indispensable tool for both scientific and space missions. This image sensor excels in capturing high contrast and high detail images, even under challenging conditions such as low light or rapidly changing brightness.\n\nELFIS2 features state-of-the-art image processing capabilities, combined with robust construction to withstand the rigors of space missions. The sensor is optimized to operate efficiently with minimal power consumption while delivering high-resolution images, ensuring that mission data is both accurate and reliable. The sensor's design also facilitates ease of integration into complex systems, providing a seamless fit for advanced imaging needs.\n\nCaeleste's expertise ensures that the ELFIS2 sensor is equipped with the latest in sensor technology, making it suitable for a variety of applications ranging from astronomy to industrial monitoring. Whether deployed in outer space or earthbound observation platforms, the ELFIS2 Image Sensor proves to be a remarkable blend of technology and craftsmanship.
The MVDP2000 series is engineered for precise differential pressure measurement using advanced capacitive sensing technology. These sensors, known for their robust performance, are calibrated impeccably over both pressure and temperature ranges, providing reliable results with minimized power usage. Highly suitable for OEM applications, these sensors are ideal for environments requiring fast response and accuracy.\n\nBuilt to the exacting needs of portable applications, these sensors offer digital and analog outputs for easy integration. Featuring a compact 7 x 7 mm DFN package, they operate efficiently over a wide temperature spread and are rated for demanding industrial and medical applications.\n\nTheir optimization for low power consumption and quick response time significantly increases their utility in fast-paced environments like HVAC systems, respiratory devices, and other critical monitoring applications. With customizable options, these sensors support specific application adaptations, making them adaptable and efficient.
The ultra-low-power human body detector from Microdul is engineered to provide efficient, static detection capabilities essential for wearable technology. This detector helps significantly reduce energy consumption in devices when not actively in use. Its advanced design allows it to recognize the presence or absence of a human, making it ideal for applications requiring power-saving features, such as smart devices and IoT equipment. The precise nature of its operation ensures long battery life, thereby enhancing the user experience in battery-dependent gadgets. Moreover, its application in static detection means it can operate seamlessly without requiring constant recalibration or complex interfacing. Its implementation is particularly valuable in the wearables market where minimizing power draw while maintaining functionality is a critical competitive factor. With its ability to integrate smoothly into existing systems, this detector forms an indispensable part of power-efficient device design strategies focused on long-term effectiveness in changing environments. Its versatility extends to various industries, ensuring compatibility with diverse technological ecosystems while emphasizing seamless operation and reliability. As a result, it paves the way for new possibilities in the design of cutting-edge consumer electronics.
Analog Bits' sensor solutions are designed to ensure high precision in monitoring and adjusting system parameters. These include temperature sensors, voltage monitors, and power integrity sensors which are critical for maintaining optimal operational conditions within semiconductor devices. With a focus on high accuracy and reliability, these sensors are integrated seamlessly into larger mixed-signal environments. They serve various applications from ensuring power supply stability to monitoring thermal conditions, which in turn, safeguard against potential overheating and electrical failures. These sensor IPs are particularly valuable in next-generation process nodes such as TSMC's N5 and below, providing intelligent systems with the insights necessary for adapting to changing conditions. By enhancing system durability and performance, these sensors play a central role in advancing energy-efficient technologies in industries ranging from automotive to consumer electronics.
ISELED Technology is an innovative solution for automotive lighting, integrating smart RGB LED control and communication capabilities into compact, efficient modules. These modules support precise color calibration and temperature compensation, leveraging a digital communication protocol to ensure consistent lighting quality. The system is engineered to facilitate seamless integration into automotive lighting applications, enhancing aesthetic appeal and operational efficiency.
Microdul’s ultra-low-power temperature sensor is designed for applications demanding exceptional energy efficiency combined with precise temperature monitoring. This sensor is especially relevant for IoT applications, where extended battery life and reliable performance are critical. By utilizing advanced design principles, the sensor operates with minimal power draw while providing accurate readings, making it ideal for integration into a vast array of devices that require temperature regulation. These sensors are poised to redefine energy management in devices by contributing to longer operational lifespan and better energy resource utilization, which is crucial in modern IoT frameworks and energy harvesting scenarios. They employ cutting-edge technology to maintain high accuracy despite changes in environmental conditions, ensuring consistent performance in critical applications. The sensor’s design ensures compatibility with numerous architectures, providing flexibility and ease of integration into both new and existing systems. As technology shifts towards increasingly interconnected systems, this sensor stands out by fulfilling the dual needs of efficiency and performance, making it a strategic choice for forward-thinking device manufacturers.
In smartphone applications, ActLight’s Dynamic PhotoDetector (DPD) offers a step-change in photodetection technology, enhancing features such as proximity sensing and ambient light detection. This high sensitivity sensor, with its ability to detect subtle changes in light, supports functions like automatic screen brightness adjustments and energy-efficient proximity sensing. Designed for low voltage operation, the DPD effectively reduces power consumption, making it suitable for high-performance phones without increasing thermal load. The technology also facilitates innovative applications like 3D imaging and eye-tracking, adding richness to user experiences in gaming and augmented reality.
The MVT4000D series represents state-of-the-art digital temperature sensors, known for their high accuracy and stability. Leveraging the capabilities of Silicon Carbide MEMS technology, these sensors perform with remarkable reliability and effectiveness. They've been meticulously crafted to offer fast response times and low power consumption, catering to a wide array of applications where precision is key.\n\nThese sensors come with a small form factor of 2.5 x 2.5 x 0.9 mm, making them suitable for highly integrated systems. With digital I2C interface options and an operating range between -40 to 125°C, the MVT4000D sensors are versatile. The series features on-chip calibration, allowing for plug-and-play use, which significantly facilitates the deployment process.\n\nSuch features lend themselves well to industrial, consumer, medical, and automotive applications, where accurate temperature monitoring is critical. Available in different accuracy specifications, they satisfy various user needs while ensuring cost-effective operation and maintenance.
The MVH4000 Series is a line of precise and fully calibrated humidity and temperature sensors. These sensors, utilizing advanced Silicon Carbide MEMS technology, are notable for their extremely fast response and minimal power consumption, making them ideal for challenging environments. The sensors ensure excellent long-term stability, ensuring reliability over extended periods.\n\nThe sensors provide a broad temperature operating range from -40 to 125°C and come in a compact design of 2.5 x 2.5 x 0.9 mm. On-chip calibration allows for immediate deployment, easing integration into existing systems. Additionally, the sensors come with digital I2C or analog interfacing options, depending on the specific model.\n\nEngineered for precision, the MVH4000 sensors offer various accuracy options and include on-chip features that support ease of use in critical applications. Their versatility makes them apt for uses ranging from industrial to automotive sectors.
Thermal oxide, often referred to as SiO2, is an essential film used in creating various semiconductor devices, ranging from simple to complex structures. This dielectric film is created by oxidizing silicon wafers under controlled conditions using high-purity, low-defect silicon substrates. This process produces a high-quality oxide layer that serves two main purposes: it acts as a field oxide to electrically insulate different layers, such as polysilicon or metal, from the silicon substrate, and as a gate oxide essential for device function. The thermal oxidation process occurs in furnaces set between 800°C to 1050°C. Utilizing high-purity steam and oxygen, the growth of thermal oxide is meticulously controlled, offering batch thickness uniformity of ±5% and within-wafer uniformity of ±3%. With different techniques used for growth, dry oxidation results in slower growth, higher density, and increased breakdown voltage, whereas wet oxidation allows faster growth, even at lower temperatures, facilitating the formation of thicker oxides. NanoSILICON, Inc. is equipped with state-of-the-art horizontal furnaces that manage such high-precision oxidation processes. These furnaces, due to their durable quartz construction, ensure stability and defect-free production. Additionally, the processing equipment, like the Nanometrics 210, inspects film thickness and uniformity using advanced optical reflection techniques, guaranteeing a high standard of production. With these capabilities, NanoSILICON Inc. supports a diverse range of wafer sizes and materials, ensuring superior quality oxide films that meet specific needs for your semiconductor designs.
The MVWS4000 series integrates three crucial environmental sensing modalities—humidity, pressure, and temperature—into a single, compact package. These digital sensors are built on a proprietary Silicon Carbide platform, offering enhanced reliability and energy efficiency. Ideal for OEM and battery-operated devices, they bridge the gap between performance and power conservation.\n\nThese sensors exhibit remarkable accuracy, with 1.5% for humidity, 1.0 hPa for pressure, and 0.3°C for temperature. Crafted for long-term stability, the sensors are suitable for demanding, resource-constrained applications. Their compact dimensions, along with a desirable operating range, make them versatile for various implementations.\n\nGiven their design for reduced energy use, these sensors are excellent for portable and embedded systems. With digital interfaces, including I2C and SPI, they offer flexible integration paths for manufacturers aiming to meet varied application requirements in industrial, consumer, medical, and automotive sectors.
EnSilica's eSi-Analog offerings encompass a wide range of silicon-proven analog IP solutions designed to meet the demands of competitive markets where analog capabilities are essential for system performance. These solutions stand out for their high performance and easy integration, which help reduce time-to-market and costs while supporting successful custom ASIC and SoC devices.\n\nThe eSi-Analog IP portfolio includes critical components such as oscillators, SMPSs, LDOs, temperature sensors, PLLs, and ultra-low-power radio elements like sub-GHz BLE, NFC Tag Front-end, and sensor interfaces. These blocks are optimized for low power consumption and high resolution, making them suitable for a wide array of applications.\n\nBy offering flexible configuration options, eSi-Analog IP allows customization according to specific project needs, leveraging EnSilica's expertise in full SoC integration. This facilitates the development of complex designs across multiple process nodes, ensuring customers achieve their design goals efficiently and effectively.
ActLight's Dynamic PhotoDetector (DPD) enhances the capabilities of smart rings with state-of-the-art photodetection technology. Designed for compact form factors, this sensor excels in environments where space is limited, such as inside a ring. Its operation at low voltages significantly extends battery life, crucial for the discreet and continual monitoring required by smart rings. The DPD's high sensitivity ensures accurate biometric readings, crucial for tracking vital signs like heart rate and activity levels without relying on additional amplification. This technology supports users in their wellness journeys by delivering reliable health data in a sleek, user-friendly device.
The 5G NR LDPC Decoder resource by Mobiveil supports advanced LDPC decoding capabilities optimized for modern telecommunication needs. Employing the Min-Sum LDPC decoding algorithm, it allows for programmable bit widths and features early exit iteration capabilities. Support for Hybrid Automatic Repeat Request (HARQ) ensures robustness by accumulating computed LLR values, increasing its efficacy in error correction scenarios.
ActLight's Dynamic PhotoDetector (DPD) for wearables is specifically engineered to revolutionize light sensing in compact devices. This innovative sensor operates on low voltage, significantly extending the battery life of wearable devices such as fitness trackers and smartwatches. The DPD's high sensitivity allows it to detect even minimal light changes without the need for bulky amplifiers, enabling a sleek design and energy-efficient operation. This sensor supports advanced health monitoring features, providing precise heart rate and activity measurements, thereby empowering users with real-time wellness insights. Its compact size makes it ideal for integration into space-constrained wearable devices without compromising performance.
The Dynamic PhotoDetector (DPD) tailored for hearables by ActLight offers an unparalleled advancement in light sensing technology for compact audio devices. Designed for energy efficiency, the DPD operates at low voltages which not only conserves battery life but also maintains peak performance, crucial for modern, on-the-go audio wearables. With its high sensitivity, the sensor excels in detecting minute changes in light conditions, thus ensuring consistent and reliable biometric data acquisition. This makes it particularly advantageous for heart rate and activity monitoring in hearables, enhancing the overall user experience with precise health tracking capabilities.
The agileTSENSE_D temperature sensor provides a digital output, extending the capabilities of traditional temperature sensing by incorporating digital signal processing. It retains the core analog sensing mechanism but wraps the output in a digital format for easier integration into modern digital systems, including IoT devices and data centers. This product is designed for environments where digital interfacing is critical. With its adaptable architecture, the agileTSENSE_D delivers precision temperature measurements over a broad operational range, ensuring that systems maintain optimal performance and safety. This functionality is crucial for thermal monitoring and management. 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 CANsec Controller Core is engineered to provide enhanced security features for automotive CAN networks. Traditional CAN networks are not inherently secure, posing challenges in protecting against unauthorized access and data tampering. This controller core integrates security protocols directly into the CAN framework, offering an encryption-enabled solution tailored for modern automotive needs. This controller core implements standardized security measures, ensuring confidentiality, integrity, and authenticity of CAN messages. By incorporating advanced cryptographic algorithms, the CANsec Controller Core meets stringent security requirements without compromising the performance that automotive applications demand. Its design focuses on minimizing resource consumption while providing robust security enhancements. Ideal for vehicles requiring secure communication between various electronic control units (ECUs), the core upholds the automotive industry’s increasing emphasis on cybersecurity. The CANsec Controller Core is versatile in its implementation, suitable for both new vehicle architectures and as an upgrade to existing systems, making it a vital component of future-proof automotive design.
The agileTSENSE_A is a general-purpose temperature sensor that utilizes a ΔVBE sensing mechanism to amplify and transform temperature-related voltages into a single-ended signal. This sensor is designed to work seamlessly with the agileADC to provide digital outputs with impressive accuracy of +/-0.25°C. It's especially significant for modern SoCs, where thermal management is crucial for power optimization and security threat detection. This sensor covers a wide operating range from -20°C to +100°C. It features a rapid startup time and minimal current consumption, making it apt for SoC integrations where efficiency is key. Further customization options allow for ease of incorporation into diverse systems. 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.
Engineered for energy-sensitive applications, Microdul’s capacitive proximity switch combines precision with ultra-low-power consumption, making it ideal for modern technological needs. This switch is designed to detect touch reliably without direct physical contact, thereby facilitating advanced user interfaces, particularly in devices where minimizing energy usage is critical. The switch’s lightweight design and responsive detection capability allow it to support numerous applications such as touchpads and sliders commonly used in consumer electronics. Its capacitive nature ensures swift response times, making it suitable for dynamic environments where instant feedback is necessary, such as in user interface control panels. Applications extend to smart technology fields, where energy savings can be maximized. The capacitive proximity switch continues to function effectively across various climates and conditions, promising versatility and adaptability. By enhancing system efficiency through minimal power demands, it impressively complements design strategies that focus on sustainability and long-term operational economy.
X-REL is EASii IC’s line of semiconductor products explicitly tailored for extreme environments, featuring extraordinary reliability at temperatures ranging from -60°C to +230°C. These high-reliability components address the rigorous demands across sectors like oil and gas, geothermal energy, aerospace, and automotive. Available in various packages, including ceramic, metal, and, for less constrained environments, plastic, X-REL products offer extended life with minimum system cost. These components are engineered to fulfill the need for continuous operation under severe conditions, delivering five years of guaranteed reliability. X-REL’s diverse lineup encompasses power management solutions, clock and timing circuits, discrete transistors and diodes, and interfaces. The robust performance of these components, coupled with certifications like ISO9001 and EN9100, underscores their suitability for mission-critical applications, where traditional designs may falter due to adverse heat and stress.
This technology focuses on the design and integration of sensors beyond traditional imaging applications, providing essential data inputs for smart devices and systems. Tailored for applications demanding high precision and reliability, these non-imaging sensors are employed across industries such as industrial automation, automotive, and wearable technology. The versatility of non-imaging sensor technology lies in its ability to perform accurate environmental monitoring, movement tracking, and biometric data capture, among other functions. These sensors are built with advanced materials and techniques to ensure resilience under various operational conditions, making them suitable for both high-stress industrial environments and delicate medical instruments. Tower Semiconductor enhances its sensor technology with strong design support and versatile integration options, assisting clients in developing customized applications to meet unique specifications. This forward-thinking approach ensures the technology remains a vital component in the development of future-forward sensing solutions, catering to diverse market needs.
The Linear Temperature Sensor by TES Electronic Solutions offers reliable temperature monitoring capabilities crucial for maintaining optimal conditions in electronic circuitry. It provides accurate linear temperature readings, essential for applications that require precise temperature control. This sensor is suitable for integration into a variety of systems ranging from consumer electronics to industrial machinery. Its compact design allows for easy incorporation into existing circuitries without necessitating extensive modifications. Ideally deployed where temperature precision can impact performance, this sensor delivers consistent outputs with high sensitivity and accuracy. The durability and reliability of the Linear Temperature Sensor ensure long-term stability and resistance to environmental temperature fluctuations, making it essential for applications focused on precision.
The SAR ADC with an integrated temperature sensor is designed for applications requiring precise voltage and temperature monitoring. It is a successive approximation register (SAR) type ADC that offers a 12-bit resolution and a sampling rate of 20 kSPS, making it ideal for low-frequency, DC measurements like temperature and voltage diagnostics. This mixed-signal ADC incorporates an integrated temperature sensor calibrated at room temperature, providing accurate readings across a wide range of temperatures from -40°C to +125°C. The unit's differential input range of 1.0 V is suitable for diverse sensing tasks, ensuring adaptability in various thermal and voltage environments. Integrated with an optional bandgap reference, the ADC supports a streamlined implementation by minimizing external component requirements. Developed in a high-voltage process node, it is available for customization to suit different process technologies, ensuring flexibility and compatibility with various platforms. Its ability to provide integrated solutions for monitoring makes it ideal for applications in sensor systems and environmental monitoring.
The TS5111 and TS5110 device incorporate thermal sensing capability which is controlled and read over two wire bus. These device operate on I2C and I3C two wire serial bus interface. The TS5 designed for Memory Module Applications. The TS5 device intended to operate up to 12.5 MHz on a I3C Basic Bus or up to 1 MHz on a I2C Bus. All TS5 devices respond to specific pre-defined device select code on the I2C/I3C Bus.
The OT0120t180 is crafted for TSMC's 180nm node and delivers consistent voltage references for micro-power applications. Its design focuses on precision and low power consumption, making it well-suited for portable electronic devices. This bandgap provides stability across various environmental conditions, ensuring reliable performance in power-sensitive components.
The VS1001REF Low-Drift Voltage Reference IC is designed to ensure stable voltage output crucial in high-precision applications. It integrates a precision voltage generator combined with an output buffer to deliver both programmable and adjustable voltage settings, maintaining stability across various operational environments. Foundational in supporting systems where long-term voltage consistency is essential, it is instrumental in optimizing performance for precision electronics, extending utility in diverse areas from industrial control applications to precision measurement systems.
Designed for the 180nm node, the OT0121v180 bandgap reference by TSMC provides a regulated 5V output, ensuring stability across various environmental conditions. Its robustness makes it suitable for applications that require consistent voltage supply, particularly in analog circuits within industrial and consumer electronics. The precision in this bandgap’s design ensures reliability in performance-sensitive applications.
The OT0118u55 is a universal bandgap reference designed for UMC's 55nm Ultra Low Power process. This product provides a stable voltage reference, crucial for the performance and reliability of analog and mixed-signal circuits. It ensures minimal power fluctuations and offers consistent output under diverse environmental conditions, making it suitable for low-power applications.
The OT0102 is a bandgap reference suiting 500nm technology, prioritizing low power consumption while delivering stable voltage references. It’s ideal for use in older generation process nodes where power efficiency and consistent power delivery are necessary. This bandgap offers reliability and precision, catering to embedded systems and analog-to-digital converters needing consistent power supply.
This five-volt bandgap reference is designed for VIS’s 150nm process node. The OT0118v150 ensures a stable voltage output, even in fluctuating temperatures, making it perfect for applications in power management and analog systems. Its precise voltage regulation aids in maintaining consistent operations critical to the success of sophisticated electronic devices.
The OT0118 bandgap reference is tailored for UMC’s 130nm process and offers precise voltage stability. Its design ensures minimal deviation across various operational conditions, making it ideal for systems that demand high precision under low power. This bandgap reference is key in ensuring circuit stability and reliability in critical applications.
Join the world's most advanced semiconductor IP marketplace!
It's free, and you'll get all the tools you need to discover IP, meet vendors and manage your IP workflow!
No credit card or payment details required.
Join the world's most advanced AI-powered semiconductor IP marketplace!
It's free, and you'll get all the tools you need to advertise and discover semiconductor IP, keep up-to-date with the latest semiconductor news and more!
Plus we'll send you our free weekly report on the semiconductor industry and the latest IP launches!