All IPs > Analog & Mixed Signal > Oversampling Modulator
The Oversampling Modulator category within Silicon Hub's Analog & Mixed Signal section houses a comprehensive range of semiconductor IPs specially designed to improve signal resolution and processing in high-performance integrated circuits. These IP solutions are integral in the conversion of analog signals into digital formats, utilizing advanced techniques to achieve superior resolution and reduce quantization noise. An oversampling modulator essentially increases the signal-to-noise ratio (SNR) by sampling the signal at a higher rate than the Nyquist frequency, which is paramount for applications requiring high fidelity data conversion.
Oversampling modulators are a critical component in the design and development of devices that demand precise digital representation of analog inputs, such as in high-end audio equipment, instrumentation, and communications systems. These systems often require robust performance characteristics to handle complex signals with minimal distortion and loss. By utilizing semiconductor IPs in this category, developers can streamline their design process, reduce time-to-market, and optimize the performance of their signal processing applications.
In products ranging from digital audio converters to advanced communication transceivers, oversampling modulator semiconductor IPs provide the necessary tools for achieving precise analog-to-digital and digital-to-analog conversion, while maintaining data integrity. They are particularly useful in applications that necessitate the suppression of noise and the enhancement of dynamic range, where audio and data quality are paramount. In addition, these modulators can also play a role in reducing system power consumption, thus contributing to the development of energy-efficient solutions.
Our selection of oversampling modulator semiconductor IPs at Silicon Hub caters to a broad spectrum of needs within various industries. Whether you are developing consumer electronics, automotive systems, or medical devices, our library of IPs offers versatile solutions capable of adapting to the unique requirements of specialized applications. Empower your development projects with our state-of-the-art modulator IP offerings to ensure exceptional signal processing and conversion capabilities in your innovative designs.
Altek's 3D Imaging Chip is a breakthrough in the field of vision technology. Designed with an emphasis on depth perception, it enhances the accuracy of 3D scene capturing, making it ideal for applications requiring precise distance gauging such as autonomous vehicles and drones. The chip integrates seamlessly within complex systems, boasting superior recognition accuracy that ensures reliable and robust performance. Building upon years of expertise in 3D imaging, this chip supports multiple 3D modes, offering flexible solutions for devices from surveillance robots to delivery mechanisms. It facilitates medium-to-long-range detection needs thanks to its refined depth sensing capabilities. Altek's approach ensures a comprehensive package from modular design to chip production, creating a cohesive system that marries both hardware and software effectively. Deployed within various market segments, it delivers adaptable image solutions with dynamic design agility. Its imaging prowess is further enhanced by state-of-the-art algorithms that refine image quality and facilitate facial detection and recognition, thereby expanding its utility across diverse domains.
aLFA-C is another notable product from Caeleste, intended for diverse applications requiring refined imaging capabilities. This sensor is exemplary in balancing speed and precision, catering to both scientific and industrial imaging requirements. Its design includes advanced features that ensure reliable image quality, even in suboptimal lighting conditions, making it a versatile tool for industries that demand rigorous accuracy.\n\nBuilt by leveraging Caeleste's extensive knowledge in CMOS image sensor technology, the aLFA-C provides users with flexibility in utilization across varying scenarios. From capturing high-speed industrial processes to detailed life sciences imaging, this sensor adapts to deliver optimal results. Its robustness and precision imaging are supported by sophisticated sensor architecture that minimizes noise while maintaining the integrity of the readout signal.\n\nCaeleste’s focus on offering customizable solutions is evident in the aLFA-C sensor's adaptability to different usage parameters, allowing users to achieve their specific imaging goals. The sensor represents a blend of performance and adaptability, ensuring that whatever the need, from industrial inspections to detailed scientific analysis, aLFA-C consistently delivers.
Advanced Silicon's Sensing Integrated Circuits are engineered for exceptional performance in diverse sensor systems, ranging from photo-diode based detectors to low-noise pixel arrays for photon detection. These ICs leverage multi-channel configurations with integrated per channel analog-to-digital conversion, providing superb noise specs, ADC linearity, and resolution. This makes them ideal for use in digital X-ray systems, CT and PET scanners, particle detectors, and even fingerprint detection solutions. By enhancing integration and performance while minimizing size and power consumption, these products empower highly efficient and advanced sensor applications.
ASIC North's Pipeline ADCs are designed to offer high-resolution, fast sampling, making them ideal for applications requiring precision and speed. These converters feature a pipeline architecture that enhances throughput and reduces latency, ensuring data integrity in high-performance applications. They are particularly suited for use in communications, imaging, and audio processing where maintaining signal fidelity is critical. ASIC North's expertise in mixed-signal processes ensures these ADCs deliver exemplary performance across a range of settings.
The TW330 distortion correction IP is tailored for use in applications requiring dynamic image transformations, such as VR headsets and automotive HUDs. Utilizing GPU-powered technologies, it offers real-time coordinate transformations, distortion corrections, and other modifications up to a resolution of 16K x 16K in both RGB and YUV formats. This IP is crucial for enhancing visual accuracy and display adaptability across varied markets.
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.
Building upon advanced CMOS processes, this image sensor technology is tailored to meet the demands of high-resolution image capture with exceptional clarity and speed. It showcases the integration of sophisticated pixel architectures alongside cutting-edge analog-to-digital conversion techniques. These elements work in tandem to ensure outstanding image quality, making the technology ideal for applications like digital cameras, smartphones, and security cameras. The technology's core strength lies in its ability to deliver high dynamic range and low-light sensitivity, expanding its usability across different lighting conditions. It supports a wide array of pixel sizes and formats, allowing for customization based on specific application needs. Alongside these features, the technology provides efficient noise reduction and energy management, contributing to prolonged battery life and enhanced sensor performance. Moreover, the CMOS Image Sensor Technology benefits from sustained innovation and development, ensuring it remains at the forefront of imaging advancements. It is equipped with various supportive resources such as reference designs and application notes, which help integrate the sensors seamlessly into new products. This positions Tower Semiconductor's technology as a vital enabler for modern imaging devices where precision and detail are critical.
ISPido offers a comprehensive set of IP cores focused on high-resolution image signal processing and tuning across multiple devices and platforms, including CPU, GPU, VPU, FPGA, and ASIC technologies. Its flexibility is a standout feature, accommodating ultra-low power devices as well as systems exceeding 8K resolution. Designed for devices where power efficiency and high-quality image processing are paramount, ISPido adapts to a range of hardware architectures to deliver optimal image quality and processing capabilities. The IP has been widely adopted in various applications, making it a cornerstone for industries requiring advanced image calibration and processing capabilities.
The Hyperspectral Imaging System offers advanced solutions for capturing detailed spectral information beyond the visible range. This system provides unmatched access to spectral imaging, making it ideal for applications requiring precise detail, such as environmental monitoring and industrial inspection. Hyperspectral imaging divides the spectrum into many bands, delivering a richer data set that enhances material identification, classification, and analysis. This technology is pivotal where high precision in spectral analysis is necessary, aiding sectors such as agriculture and defense. Capable of capturing spectral data in high resolution across multiple wavelengths, the system's applications extend to medical fields, offering improved diagnostics and insights into biological samples. Integrating state-of-the-art CMOS technology, it ensures fast, accurate data acquisition with lower power consumption.
Designed for smaller scale transformations, the TW220/240 IP handles tasks such as distortion correction, scaling, and rotation for images up to 4K x 4K resolution. It supports RGB and YUV formats, offering vital capabilities for applications needing precision in image processing at lower resolutions. Its applications span from consumer digital products to professional imaging equipment.
The JPEG XS Encoder/Decoder is designed to provide visually lossless compression with ultra-low latency. This makes it an ideal fit for next-generation applications in 5G environments, large screens, and high-quality video processing. The encoder/decoder couples high efficiency with minimal data delay, maintaining superior image quality while enabling real-time data transfer essential for live broadcasting and professional media dealings.
The Terefilm photopolymer is an innovative material utilized by Terecircuits to facilitate the mass transfer of microLED components. This material is crucial in achieving sub-micron accuracy for the placement of microLEDs, a necessary feature given their minute size. MicroLEDs can be as small as 5-50 microns, which makes traditional methods incapable of efficiently processing them. One of the significant challenges in assembling microLEDs is their requirement for precise sub-micron placement, as any misalignment could drastically affect performance. Terefilm Photo-polymer allows for rapid transfer and placement of microLED components with ease, overcoming the limitation of current manufacturing processes that could take days to assemble large numbers of components. This material works through a photo-activated process. A donor plate is used to pick up thousands of microLEDs directly from wafers, holding them at the fabrication pitch. Using an opaque mask and light activation, only select microLEDs are released onto the display substrate at a desired pixel pitch. This cycle is repeated until the entire substrate is populated efficiently and accurately, facilitating faster and more cost-effective manufacturing of microLED displays.
The Mixed-Signal Front-End designed by Global Unichip Corp. stands at the forefront of processing analog signals into digital forms. It's a crucial element for systems where high precision, low noise, and robust performance are required. The IP is adept at managing various signal inputs and enhancing the overall system performance in diverse applications ranging from consumer electronics to automotive systems. Engineered with cutting-edge technologies, this Mixed-Signal Front-End integrates seamlessly within existing architectures, promoting reduced signal degradation and enhanced fidelity. Its design ensures minimal interference and excellent signal integrity, which are pivotal in high-demand environments where accurate signal processing is critical, like in radar and lidar technologies. Flexibility is another hallmark of this IP, with scalable solutions that can be tailored to meet specific project requirements. Its robust architecture supports extensive interoperability, allowing it to be readily incorporated into broader system designs, facilitating faster development cycles and improved cost efficiencies.
The Orion Family of Pattern Projectors from Metalenz harnesses the power of meta-optics to offer precise pattern projection capabilities. These projectors are pivotal for applications requiring high-resolution pattern delivery, such as in structured light systems used for depth sensing and imaging. The use of metasurfaces allows these projectors to output highly accurate and customizable light patterns, making them optimal for integration into smart devices and industrial systems. Metalenz's Orion projectors are characterized by their ability to efficiently replace complex, traditional projector modules with a single, multifunctional component. This not only reduces system size but also simplifies manufacturing and assembly processes. The compact nature of the Orion projectors makes them ideally suited for mobile devices, enhancing their functionality for applications like biometric security and 3D mapping. By utilizing meta-optics, these projectors achieve superior light distribution control, providing improved depth accuracy and imaging quality. The projectors are designed to be adaptable to various system requirements and conditions, ensuring reliable performance across different environmental settings. The Orion projectors represent Metalenz's commitment to bringing advanced optical solutions into mainstream applications, supporting both consumer and industrial innovations.
The SiC Schottky Diodes are engineered for efficiency in low-loss systems. These silicon carbide devices provide high speed switching and minimal reverse recovery time, significantly reducing conduction losses. As a result, they are an excellent choice for applications such as power factor correction and power inverter circuits. Their unique structure also ensures high voltage operation capability, making them well-suited for both industrial and renewable energy sectors. The diodes’ robustness and efficiency contribute to the development of compact and efficient power management solutions.
Akronic excels in the design of Analog and Mixed-Signal ICs, leveraging their extensive experience to craft various integral components for modern telecom and radar transceiver radios. They offer solutions in both CMOS and BiCMOS processes, accommodating a wide range of IC fabrication technologies from conventional to cutting-edge nodes. Their expertise spans low-pass filters and base-band functions, showcasing an ability to design sophisticated analog blocks like 5th order or higher leapfrog filters and high-speed analog-to-digital converters. Their designs accommodate various gain-control operations with linear-in-dB or stepped mechanisms, and they are adept in implementing signal converters like high-speed ADCs and DACs, switched-capacitor DACs, and time-interleaved ADCs. Additionally, Akronic's skillset includes frequency synthesis and the design of fractional/Integer-N PLLs, loop filters, and multi-modulus prescalers, ensuring efficient and reliable operation across various specifications. Akronic's methodology incorporates advanced techniques to mitigate potential discrepancies between simulations and real-world performance, incorporating maturity in their design choices and processes. This includes LO leakage compensation and enhanced signal processing capabilities, ensuring optimal IC performance. Their deep understanding of analog mixed-signal design principles contributes significantly to various demanding applications across telecommunications and radar sensing sectors.
The ADQ7DC model is a highly sophisticated digitizer designed for both single and dual-channel applications. It stands out with its impressive sampling rate of up to 10 GSPS, complemented by 14-bit resolution, enabling exquisite detail and clarity in the captured signals. Its input bandwidth reaches up to 3 GHz, catering to demanding applications that require high-speed and high-fidelity data processing. This digitizer is suitable for high-performance data acquisition, making it a preferred choice for industries that rely on critical signal detection and analysis.
This fractional-N synthesizer operates over an expansive frequency range from 1 GHz to 16 GHz, delivering low phase noise performance crucial for high-demand applications. Engineered to suit a variety of advanced needs, it supports stable operation in high-frequency environments, making it ideal for modern wireless communication systems. The synthesizer's design focuses on maximizing spectral efficiency while minimizing noise, a critical factor for improving the signal integrity in telecommunications networks. This is achieved through sophisticated architecture that allows for effective frequency synthesis with reduced spurious emissions, enhancing both the clarity and reliability of transmitted signals. Employing this synthesizer, engineers can achieve precise frequency generation which is essential for applications like RF communication systems, where maintaining signal fidelity is paramount. With its wide bandwidth and low noise characteristics, it is well-suited for integration into systems that require robust performance under varying conditions. This synthesizer is a vital component in modern transceiver and radio communication designs, contributing to expanded operational metrics and system efficiencies.
Silhouse is a cutting-edge machine vision solution designed to accelerate the implementation of image processing applications across various industries. Its state-of-the-art technology provides rapid image analysis and processing capabilities, enabling users to harness machine learning algorithms for enhanced visual data interpretation. From improving quality control processes in manufacturing to enabling automation in logistics, Silhouse is versatile and scalable, making it ideal for diverse industrial applications. The platform's ability to integrate with existing systems allows for seamless adoption and instant benefits, thereby reducing deployment times and costs normally associated with traditional vision systems. The adaptability and precision of Silhouse empower users to conduct complex image-based analysis tasks effectively, fostering innovation in sectors where visual data is critical. Its robust design ensures reliability and accuracy, establishing it as a valuable resource in industrial settings demanding high-speed, quality image processing.
intoPIX's JPEG 2000 codec delivers premium image quality for digital video over IP networks with advanced compression capabilities. Widely recognized for its ability to handle high bit depths and resolutions, the JPEG 2000 codec is a staple in media productions that require high visual fidelity. It offers extensive feature support for different chroma subsampling schemes and bit rates, facilitating excellence in broadcast and cinema applications. As a cornerstone technology in intoPIX's offerings, the JPEG 2000 codec emphasizes minimal latency alongside high throughput levels, making it suitable for live production and post-production environments. It is equipped to handle visually lossless compression, ensuring that the subtle nuances of high-quality video are maintained for the end viewer. This codec supports various profiles, making it highly adaptable for different video settings, and provides robust error resilience ensuring seamless streaming even in network variability situations. Its powerful processing capabilities make it ideal for sectors where image integrity is paramount, such as digital cinema and HD broadcasting.
The Bayer to RGB Converter by Zipcores converts Bayer filter image data to RGB format, which is essential in image processing applications particularly in digital cameras and scanners. This core is critical for devices that capture images using a sensor with a Bayer filter, facilitating the conversion of raw data into a form suitable for image viewing and analysis. It efficiently processes the pixel data to generate high-quality RGB images, maintaining fine details and color accuracy, which is crucial for professional photography and video production environments. Optimized for performance, this converter minimises processing delays, enabling continuous high-speed image pipelines. The core's design emphasizes ease of integration, providing flexibility for developers seeking to enhance their imaging systems with real-time processing capabilities. Its compact footprint makes it suitable for resource-limited environments, while still providing the high processing standards required by modern image applications.
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.
This advanced Sigma-Delta Modulator, TRV107TSM180BCD, leverages cutting-edge mixed-signal processing techniques to deliver superior signal conversion efficiency. Crafted specifically for applications demanding high-resolution data capture, it operates on the trusted principles of Delta-Sigma Modulation to provide exceptional noise shaping and low distortion levels. Integrated within an 180nm CMOS process, and utilizing a power-efficient 1.8V supply, the TRV107TSM180BCD excels in minimizing quantization noise—boosting performance in precision-demanding contexts such as high-fidelity audio and advanced telecommunications systems. The modulator's adaptable architecture is key for seamless adaptation into complex signal processing environments. It supports effective modulation across varied frequencies, asserting its utility in broad applications from consumer electronics to intricate industrial systems, all while maintaining the rigorous standards of modern integrated circuit designs.
The TRV106TSM180BCD is a sophisticated Nyquist-Rate ADC, architectured for high accuracy in analog-to-digital conversion. This device is particularly valuable in systems requiring precision data capture over a wide bandwidth. With a notable integration of switch capacitor technology, this ADC emphasizes minimal power usage while delivering robust performance outputs. Operating on a single-bit, Delta-Sigma Modulation process, the TRV106TSM180BCD offers a programmable decimation rate, allowing it to adapt to various signal processing requirements. It supports applications where latency and accuracy are paramount, making it suitable for communications and industrial electronics. Rated for operation in 180nm CMOS technology, with a supply voltage of 1.8V, this ADC integrates seamlessly into power-sensitive environments. Its design ensures efficient functioning across a range of frequencies, promoting effective integration into diverse electronic systems without sacrificing computational accuracy or speed.
The CT22403 ADC from Canova Tech is a precise 14-bit, 10MS/s successive approximation register (SAR) converter. It is designed to deliver high-performance data acquisition with excellent linearity and resolution. The calibration functionality ensures minimized errors and optimizes accuracy across various applications, ensuring it meets the demands of discerning industrial and consumer needs. This ADC is suitable for diverse sensing and measurement tasks, where precision and speed are not just desired but required.
The PolarEyes system by Metalenz introduces a pioneering approach to imaging that leverages polarization to deliver detailed depth and material composition insights. Unlike conventional systems which rely on bulky filters and splitters, PolarEyes condenses this functionality into a scalable form suitable for mass-market applications. Its compact design allows it to be integrated into mobile devices, offering capabilities previously restricted to larger laboratory setups. PolarEyes specializes in enhanced 3D sensing, allowing for precise shape and contour detection which supports advanced machine vision applications. The system's ability to capture full polarization data means it can assess material properties and detect transparent objects, providing groundbreaking applications in both consumer electronics and smart industrial systems. This unique feature set enables more efficient and accurate recognition in robotic and automotive applications, as well as consumer devices like smartphones and wearables. Through the use of Metalenz's meta-optics, PolarEyes eliminates the inefficiencies and cost barriers of traditional polarization imaging. It supports environments where light interference is a challenge, such as outdoor settings, by removing glare and improving visibility. The versatility of PolarEyes lies not only in its hardware capability but also in the software that supports diverse applications from facial recognition to material classification and autonomous navigation.
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!