All IPs > Analog & Mixed Signal > Switched Cap Filter
Switched cap filter semiconductor IPs are integral components in the realm of analog and mixed signal technology. These IPs are specifically designed to optimize signal processing and to efficiently manage the conversion between analog and digital signals. The versatility and precision of switched cap filters make them ideal for a variety of applications, including communication systems, audio processing, and data conversion.
In essence, switched cap filters function by substituting resistors with capacitors and switches, thereby enabling precise control over filter parameters such as frequency and bandwidth. This approach not only enhances the performance of the filtering process but also allows for easy integration into complex signal management architectures present in modern electronic devices. Overall, these semiconductor IPs provide engineers with a flexible and cost-effective solution to meet the demands of high-performance signal processing.
The products found in this category often include complete filter designs that can be readily implemented into chip designs, as well as customizable modules that allow for the adjustment of key parameters to suit specific application requirements. Designers and engineers will appreciate the high degree of control and precision offered by these IPs, ensuring that the end products function accurately and efficiently under varying conditions.
As modern devices continue to demand higher levels of efficiency and performance, incorporating robust switched cap filter semiconductor IPs becomes increasingly vital. Whether implementing these filters for noise reduction in consumer electronics or ensuring clear audio transmission in communication systems, these IPs play a crucial role in the advancement of cutting-edge technology.
The MVPM100 series brings forth cutting-edge microsystem technology to measure particulate matter precisely in a compact module. Distinguished from traditional bulky sensors, it directly measures particle mass instead of relying on optical estimates, providing enhanced accuracy. This makes it optimal for diverse applications demanding precise air quality assessments.\n\nIts compact form factor, alongside its low power consumption, ensures suitability for a wide range of industrial and consumer products. Its capability to monitor particulate matter with high accuracy and over extensive temperature ranges makes it highly desirable for health and environmental applications.\n\nProviding interfaces through I2C and UART, the sensors facilitate easy integration into complex systems, maintaining a balance between performance and power efficiency. Designed for robustness, they are adaptable across varied consumer, medical, and industrial environments, verifying air quality with a high degree of precision.
The Polar ID Biometric Security System offers an advanced, secure face unlock capability for smartphones, utilizing groundbreaking meta-optics technology to capture the full polarization state of light. Unlike traditional biometric systems, Polar ID distinguishes the unique polarization signature of human facial features, which adds an additional security layer by detecting the presence of non-human elements like sophisticated 3D masks. This system eliminates the need for multiple complex optical modules, thus simplifying smartphone design while enhancing security. Designed to fit the most compact form factors, Polar ID uses a near-infrared polarization camera at 940nm paired with active illumination. This configuration ensures functionality across various lighting conditions, from bright outdoor environments to complete darkness, and operates effectively even when users wear sunglasses or face masks. Smartphone OEMs can integrate this secure and cost-effective solution onto a wide range of devices, surpassing traditional fingerprint sensors in reliability. Polar ID not only offers a higher resolution than existing solutions but does so at a reduced cost compared to structured light setups, democratizing access to secure biometric authentication across consumer devices. The system's efficiency and compactness are achieved through Metalenz's meta-optic innovations, offering consistent performance regardless of external impediments such as lighting changes.
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 High-Voltage ICs by Advanced Silicon are key components for driving various thin film technologies. Designed with a high pin count for multi-channel output, these drivers are adept at turning on and off thin film switching devices across technologies such as amorphous silicon, poly-silicon, and IGZO. They also provide precise analog driving of MEMs devices and ITO capacitive loads, essential for applications requiring high precision and resilience, like digital flat-panel X-ray detectors. With resolutions from 64 to 1024 output voltage levels, these ICs maintain performance across demanding environments and applications.
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.
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) 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 5th Generation Power Metering solution by Dolphin Semiconductor is a cutting-edge IP offering, designed for single or three-phase detection with a strong focus on energy efficiency and accuracy in power metering applications. This advanced platform leverages a 24-bit ADC for high-precision energy measurements, ensuring low noise at low frequencies, minimal offset, and high total harmonic distortion (THD) performance. Developed to simplify and accelerate design processes while supporting scalability across multiple power metering solutions, this IP optimizes cost and complexity. It includes integrated power computation algorithms that streamline operations, supported with optional power and energy computation engines requiring minimal computational resources from a supporting MCU SoC. The IP offers significant benefits such as error measurement well below 0.1% over a 1/7000 range, making it ideal for smart energy applications. Additionally, it features synchronized channels with phase shifting calibration, eliminating the need for input DC blocking capacitors. Compatible with process nodes from 180nm down to 40nm, this power metering solution offers a flexible, cost-effective IP robust for contemporary semiconductor applications.
The MVUM1000 stands out as a compact, advanced linear ultrasound array designed for medical imaging. Featuring 256 elements, it integrates capacitive micromachined ultrasound transducers (CMUT), enhancing both power efficiency and sensitivity. This integration aids in high-quality medical diagnostics and imaging applications.\n\nOffered with a range of adaptive imaging modes, such as Doppler, these arrays facilitate multifaceted ultrasound applications, from portable devices to comprehensive cart-based systems. They provide exceptional lateral and axial imaging capabilities, meeting rigorous clinical needs.\n\nThe sensor array is also characterized by a high degree of integration with electronics, enabling seamless embedding into various platforms. Its flexibility in operation and customizable features allow for expansive usability in point-of-care situations, ensuring healthcare professionals can deliver precise diagnostics efficiently.
The Heimdall platform is engineered for applications requiring low-resolution image processing and quick interpretation. It integrates image signal processing capabilities into a compact design, perfect for IoT applications where space and power consumption are constraints. The platform supports various image-related tasks including object detection and movement tracking. With a core image sensor of 64x64 pixels, Heimdall is optimized for environments where minor details are less critical. This makes it ideal for motion sensing, smart lighting, and automation systems where the understanding of space occupancy or movement is essential. The platform's energy-efficient design, capable of integrating energy-harvesting technology, ensures sustainable operation in remote and hard-to-reach locations. By providing rapid image interpretation, Heimdall supports quick decision-making processes crucial for smart infrastructure and security applications.
The AFX010x Product Family by SCALINX consists of advanced Analog Front Ends (AFEs) ideal for data-acquisition systems, particularly for benchtop and portable applications. This product family is designed to cater to needs for low power consumption, high signal fidelity, broad bandwidth, and impressive sampling rates. Each Integrated Circuit (IC) features four independent channels, each equipped with a programmable input capacitance, a single-ended to differential-output programmable gain amplifier (PGA), an offset DAC, an ADC, and a digital processor. Housed in a standard 12 mm × 12 mm, 196-ball BGA, these products benefit from the proprietary SCCORE™ technology, which facilitates a compact PCB footprint and energy savings of up to 50%. The AFEs offer a maximum sampling rate of 5 GS/s and maintain consistency with applications requiring high resolution data acquisition, such as USB and PC-based oscilloscopes and non-destructive testing systems. By featuring on-chip clock synthesizers and voltage references, they ensure superior performance with power consumption rates as low as 425 mW per channel. Moreover, these AFEs boast a range of programmable gains and bandwidths, adaptable over wide bipolar voltage ranges, making them extremely flexible to suit various signal processing needs. Their pin-to-pin compatibility across different models simplifies upgrades and customization, maximizing flexibility and adaptability in diverse technological contexts.
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.
Akronic excels in the design of Analog and Mixed-Signal (AMS) integrated circuits, employing both CMOS and BiCMOS technologies. Their extensive experience enables them to create essential building blocks for modern telecom and radar transceivers. Their design range covers a broad spectrum of IC fabrication technologies, from conventional to the latest node dedicated processes. They specialize in providing comprehensive chip design solutions that adapt to diverse requirements. Critical components designed by Akronic include advanced low-pass filters, gain-control operations, signal converters, and frequency synthesis elements, far exceeding industry standards. These elements, characterized by flexibility and precision, contribute significantly to the performance and reliability of electronic systems across various applications.
Functioning as a tunable high-pass filter, the ATEK890P4 is optimized for operations in the 1 GHz to 1.95 GHz range. It showcases a tight insertion loss of 2 dB and a rejection of 55 dBc, ensuring clear and selective high-frequency signal passage. This filter is particularly advantageous for systems that demand rigorous high-pass filtering and performance stability in a 4x4 mm QFN format.
The ATEK884P5 is a sophisticated tunable band-pass filter designed for frequencies between 1 GHz and 7.5 GHz. It features finely adjustable properties that allow it to achieve up to 11 dB of insertion loss with a rejection ratio of 40 dBc. This makes it ideal for communication systems requiring precise filtering across a broad frequency range. Packaged in a 4x4 mm QFN, it offers both high performance and compact integration capabilities.
Trimension SR250 is designed to optimize application performance in ultra-wideband (UWB) technology. This solution allows for precise location tracking across a range of scenarios, including automotive and industrial applications. Its robust architecture is tailored for seamless integration with existing systems, enhancing overall functionality and user experience. Trimension SR250's UWB capabilities make it a versatile choice for developers looking to implement real-time tracking and proximity-based solutions. The SR250 module stands out for its high accuracy and reliability, which are crucial for applications requiring consistent performance in dynamic environments. This technology supports various use cases, such as enhancing vehicular safety through reliable in-car communications and expanding the capabilities of smart infrastructure. With its cutting-edge design, the Trimension SR250 ensures minimal interference, thus guaranteeing stable operations even in densely populated wireless environments. Furthermore, Trimension SR250 is engineered for energy efficiency, aligning with the industry's move towards sustainable technology use. Its power optimization features make it suitable for battery-powered devices, extending operational time without frequent charging. This innovative UWB solution exemplifies NXP's dedication to providing cutting-edge technologies that meet modern demands for precision and efficiency.
Trimension SR040 is engineered for ultra-precision tracking and communication in fast-evolving technological landscapes, particularly focusing on proximity-based applications. This module is crucial for systems where detailed spatial awareness and communication are required, like in industrial automation and automotive safety applications. It effectively bridges the gap between advanced technology and practical, everyday usage through its precise UWB capabilities. Among its innovative features, the SR040 supports seamless integration into broader systems, enhancing network capabilities and improving device-to-device communication. This is particularly beneficial in crowded signal environments where reliable communication is necessary. The SR040 allows for tight spatial resolutions and high accuracy, making it a trusted choice for developers who need consistent and reliable performance. NXP developers focused on energy optimization to ensure the SR040 meets the industry's call for environmentally friendly solutions. Its ability to operate efficiently on minimal power supports the longevity of battery-driven devices. As smart technology becomes more prevalent, the Trimension SR040 stands out by offering efficient, scalable, and sustainable solutions for future connectivity challenges.
Designed for high-precision, short-range location services, the Trimension SR150 offers unrivaled performance in UWB technology for spatial awareness applications. This product serves industries such as automotive and industrial automation, where short-range communication and location tracking are critical. Fully compatible with modern technologies, the SR150 module enables seamless interactions within smart ecosystems. The versatility and adaptability of the Trimension SR150 make it perfect for various applications, including real-time asset tracking and enhanced vehicular communication systems. It significantly improves situational awareness, providing insights that are essential for safety and efficiency in automotive and industrial settings. The robust capabilities of the SR150 module ensure that it retains superior functioning amidst challenging environments. Combining state-of-the-art technology with energy-efficient design, the Trimension SR150 highlights NXP’s commitment to sustainability and innovation. Its low power consumption extends device lifespan, making it an ideal component for devices requiring long operation times. By focusing on providing stable and accurate UWB performance, this product supports the growing demand for precise and reliable location services.
CSEM’s MEMS Technology Solutions provide a comprehensive foundation for creating highly sensitive and precise microelectromechanical systems. These advanced solutions capitalize on the unique mechanical and electrical properties inherent in MEMS technology, making them indispensable in sectors ranging from consumer electronics to aerospace. By utilizing state-of-the-art manufacturing techniques, CSEM delivers tailored solutions that integrate seamless functionality with miniaturized design, enabling next-generation innovations across myriad industries. Within this domain, CSEM offers silicon and polymer-based MEMS solutions that support high-volume production without sacrificing precision or reliability. Their facilities are equipped to handle the full development cycle of MEMS, from design and simulation to prototype fabrication and testing, ensuring high quality and performance across applications. CSEM's expertise extends to the development of enabling components such as rubidium vapor cells for use in atomic clocks and next-gen sensors. By spearheading advancements in MEMS technology, CSEM equips industries with critical tools that advance operational efficiency and open new horizons in precision engineering.
The Mali-C78AE is designed to achieve high-level image processing, catering primarily to industrial and automotive settings where precision in visual data capture is critical. It represents a significant leap in enabling advanced driver assistance systems (ADAS) and autonomous vehicle technology. Its structure is optimized for real-time processing, with high-speed data throughput and sophisticated image processing algorithms that support clear, high-quality image outputs under varying lighting conditions. This processor ensures reliable, fast image recognition and processing, which is vital for safety and navigation in automated systems. Incorporating error detection and correction mechanisms, the Mali-C78AE is highly resilient, reducing the risk of failure and ensuring consistent performance. With its robust security and processing capabilities, it is well-suited for use in smart vehicles and other precision-requiring environments.
The XH035 platform merges sensor and high-voltage technology into a robust 350 nm process. It features a 3.3 V core module that prioritizes ultra-low noise and is complemented by an optional 5 V dual gate module. Designed for durability, the platform supports high operating temperatures and integrates a mix of digital, analog, high-voltage, and non-volatile memory technologies. This adaptability makes it ideal for sensor and sensor interface applications, especially in challenging environments. Its comprehensive PDK support across major EDA vendors ensures seamless implementation in diverse design environments.
The XO035 platform is tailored for high-speed optoelectronics applications, ideal for optical data storage, communication, and high dynamic range sensors. It features a modular 350 nm manufacturing technology, equipped with specialized opto-process modules such as optimized PIN cathode implantation, optical window etching, and an anti-reflecting coating layer. The platform supports up to four metal layers, allowing for various thick metal options, which significantly enhances device performance. Photodiodes are highly sensitive, and multiple wavelength optimizations are possible. Extensive support is provided for popular EDA vendors.
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!