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 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 MVH4000 series is a line of highly precise and fully calibrated humidity and temperature sensors. Utilizing a unique Silicon Carbide MEMS technology, these sensors boast outstanding long-term stability, quick response times, and low power usage. Their compact size makes them ideal for applications where space is at a premium, offering significant advantages in battery-powered and time-sensitive environments. Long-term reliability, minimal power draw, and robustness are key features of the MVH4000 sensors, making them a top choice for demanding applications with critical process controls.
The MVT4000D series comprises highly accurate digital temperature sensors, renowned for their robust performance based on the proprietary Silicon Carbide MEMS technology. These sensors feature rapid response times and exceptional long-term stability, with very low power consumption. They are designed to optimize space usage on PCBs with their small form factor, catering to a broad spectrum of industries including medical and automotive. Their precision and reliability make them the sensors of choice for processes requiring tight control.
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.
The MVWS4000 series provides a comprehensive solution with its three-in-one digital sensors that measure humidity, pressure, and temperature. Designed for high performance, these sensors offer rapid readings and are optimized for battery efficiency. The use of Silicon Carbide technology ensures durability and energy efficiency, making the sensors suitable for battery-powered applications across various markets. Their compact design and multiple accuracy grades make them adaptable to specific client requirements.
Thermal Oxide Processing is a critical service offered by NanoSILICON, Inc., utilizing silicon dioxide (SiO2) as a key insulation material in semiconductor devices. This material serves as a field oxide, separating conductive layers like polysilicon and metal from the silicon base. Additionally, it functions as a gate oxide, playing a crucial role in the device's operation. Silicon wafers are subjected to oxidation within a high-temperature range of 800°C to 1050°C in quartz tube furnaces, ensuring a slow and controlled heating process to prevent deformation. The characteristics of dry oxidation, which include slow oxide growth and high density, make it suitable for high breakdown voltage applications. On the other hand, wet oxidation offers faster growth, even at lower temperatures, allowing for the creation of thicker oxide layers. These processes are conducted using ultra-pure steam and oxygen sources, ensuring batch thickness uniformity within ±5% and intra-wafer uniformity within ±3%. Technical proficiency is emphasized with the employment of advanced measurement tools like the Nanometrics 210 for optical parameter adjustment and precise film thickness verification. This technique allows for accurate measurement at various stages of the semiconductor fabrication, from as small as 10µm, guaranteeing the high quality of the thermal oxide films.
The Chipchain C100 is a sophisticated single-chip solution tailored for Internet of Things (IoT) applications. It incorporates a 32-bit RISC-V CPU, capable of running at speeds up to 1.5GHz, making it ideal for high-performance computing tasks. With built-in RAM and ROM, it provides efficient processing and memory capabilities. The C100 features integrated wireless communication through Wi-Fi, alongside various transmission interfaces. This makes the chip versatile for a wide range of applications while maintaining low power consumption. It also includes essential components like an analog-to-digital converter (ADC), low dropout regulators (LDO), and a temperature sensor. Designed for ease of use in diverse IoT environments, the C100 facilitates simpler, faster development, making it suitable for security systems, smart homes, toys, games, and healthcare applications. Its integration of multiple functionalities in a compact design ensures reliable performance across industries.
Analog Bits' sensors are engineered for PVT (Process, Voltage, Temperature) monitoring, specifically designed to oversee both on-chip and system-level power. Noteworthy for their small footprint, these sensors are silicon proven at advanced nodes like 5nm and 3nm. Beyond traditional applications, they are essential in scenarios where security is a concern, being capable of detecting voltage spikes during potential hacks. The sensors' integration onto the die contributes to energy-efficient software load balancing.
The Time-Triggered Protocol (TTP) is an advanced communication protocol specifically designed for managing the growing complexity and requirements of distributed fault-tolerant systems. TTP provides a framework for creating modular, scalable control systems that are essential in modern automotive, aerospace, and industrial applications. Its structured time-triggered communication is tailored to support reliable, synchronized distributed computing, which is crucial for safety-critical systems demanding high-precision operations at lower lifecycle costs.\n\nEstablished as a standard (SAE AS6003), TTP boasts a significant improvement in communication bandwidth over legacy interfaces like ARINC 429 and MIL-1553, enabling efficient integration within sophisticated system architectures. Beyond just enhancing deterministic communication, TTP delivers distributed platform services that simplify designing advanced systems, effectively reducing both software and system lifecycle costs. This attribute makes TTP especially valuable for managing applications where timing and safety are paramount.\n\nComprehensive toolsets and components, including chip IPs and development systems, support and streamline TTP application development. These resources are pivotal in facilitating rapid prototyping and testing, allowing engineers to implement robust and reliable network solutions efficiently. TTP's capability to reduce system complexity positions it as a vital technology in progressing vehicle electronics, aerospace systems, and other automation-driven industries.
Microdul’s ultra-low-power temperature sensor is tailored for IoT applications, focusing on energy efficiency and reliability. Designed to function efficiently with minimal power consumption, this sensor is essential for extending the life of battery-operated devices. Its operational efficiency allows for precise temperature readings, making it suited to various applications including remote environmental monitoring and wearable technology. This component is particularly beneficial in energy harvesting applications, where maintaining low power usage is critical to maximize operational duration. It provides consistent and accurate temperature measurements, ensuring devices can monitor environmental conditions reliably without energy waste. The temperature sensor's architecture supports integration into smart device ecosystems, contributing to enhanced device intelligence and operational sustainability. With its precise sensing capabilities and low power requirements, it fits perfectly into advanced IoT frameworks focused on sustainability and energy management.
Designed for minimal energy usage, this detector is perfect for applications where power efficiency is critical. It's ideal for devices that remain idle for extended periods and need to reduce consumption during those times. This technology is used in wearables to lower power usage significantly when not in use, effectively extending the battery life of the device. The sensor detects static presence effectively but is also competent in recognizing touch, making it versatile for various applications. This component is adept at identifying dynamic touch events, allowing it to operate as a single button, a keyboard, slider, or proximity switch. Such versatility makes it useful in applications ranging from activating devices upon contact to function selection in various electronics. The detector’s reliability and low energy demand make it an optimal choice for energy-conscious systems. Furthermore, the Human Body Detector integrates seamlessly into IoT systems, particularly in devices requiring sustained battery life. It ensures that electronics operate effectively with minimal power, providing a significant advantage in terms of energy efficiency and operational longevity.
The eSi-Analog IP by EnSilica features an extensive portfolio of analog IP blocks optimized for integration into custom ASIC and SoC solutions. These IPs cover a diverse range of functionalities essential for high-performance analog circuit design, contributing significantly to a system's overall capability.\n\nFocusing on high-resolution performance and low power usage, these analog IP blocks enable efficient integration across multiple process nodes. Notably, EnSilica's selection includes oscillators, power management modules such as SMPS and LDOs, and various sensor interfaces, which are silicon proven in leading foundry processes to meet specific application requirements.\n\nThe adaptability of these IPs ensures that they can be customized to meet precise specifications, facilitating seamless SoC integration. This flexibility not only reduces time-to-market but also enhances design efficiency, making them suitable for a wide array of applications including wireless communication, medical devices, and consumer electronics.
Tower Semiconductor’s Non-Imaging Sensor Technology focuses on developing advanced sensor solutions that capture and interpret data beyond traditional imaging applications. This technology aims to equip various devices and systems with the ability to sense environmental changes and other parameters crucial for enhancing interactive functionality. Non-imaging sensors are instrumental in smart devices, industrial automation, automotive safety features, and medical diagnostics, providing essential data that aids decision-making and system responsiveness. The focus is on ensuring sensors have high sensitivity and accuracy while maintaining minimal power consumption, vital for portable and battery-operated devices. With ongoing advances in sensor technology, Tower Semiconductor designs and manufactures sensors capable of functioning in diverse environments, adapting to broad usage scenarios across different industries. This capability ensures that sensors can provide reliable outputs whether in controlled indoor setups or challenging outdoor conditions. These sensor technologies contribute essentially to the growing Internet of Things (IoT) market, where everyday objects are expected to gain sensory capabilities, integrating seamlessly into smart grids and homes to create enhanced living and working environments.
The ADC/Temp. Sensor from M31 Technology is a state-of-the-art mixed-signal IP block tailored for precise data conversion and temperature monitoring. With resolutions spanning from 10 to 12-bit and conversion speeds up to 2.5MSPS, it offers high flexibility for a variety of applications. The architecture supports both differential and single-ended input types, granting it versatility whether deployed in battery-powered devices or IoT applications demanding low power consumption.
The CM6216ea temperature sensor offers ultra-low power operation combined with high precision, making it an excellent choice for monitoring temperature in various applications. With an extended temperature range and a high measurement accuracy of 0.1°C, this sensor is designed to provide reliable data for thermal management systems. Currently under development, it promises advancements in ensuring the efficient design of systems requiring precise thermal regulation. Its design is aimed at minimizing energy consumption, supporting extended battery life in portable and energy-sensitive devices.