All IPs > Analog & Mixed Signal > Coder/Decoder
In the rapidly evolving landscape of modern electronics, analog and mixed-signal coder/decoder semiconductor IPs play a critical role by facilitating the conversion and processing of signals between analog and digital forms. This category showcases intellectual property cores that are essential for the development of a wide array of communication and processing technologies. By enabling the encoding and decoding of signals, these IPs ensure that data is transmitted accurately and efficiently across diverse systems.
Coder/Decoder IPs are pivotal in applications that require precise signal transformation, especially in sectors like telecommunications, audio processing, and data communication. For instance, in telecommunications, these IPs help convert voice signals into digital data that can be easily transmitted over networks and then re-converted into an understandable format at the receiving end. Similarly, in audio applications, they are integral to transforming analog audio inputs into high-quality digital sound output and vice-versa, ensuring clear and robust audio experiences.
Products within this category often include narrowband coders/decoders for voice and data communication, audio codecs for high-fidelity sound systems, and video coders/decoders that enable seamless streaming and broadcasting. They are designed to cater to both high-performance and low-power applications, reflecting the diverse needs of modern electronic devices from consumer gadgets to industrial machines.
Silicon Hub's collection of coder/decoder semiconductor IPs is crafted to be both versatile and scalable, offering solutions that can be tailored to specific application requirements. Engineers and designers can find reliable and efficient IP solutions that optimize system performance by reducing complexity and enhancing signal integrity, paving the way for innovative electronic applications across various industries.
iWave Global introduces the ARINC 818 Switch, a pivotal component in the management and routing of video data within avionics systems. Designed for applications that require efficient video data distribution and management, the switch is optimized for performance in environments with stringent data handling requirements. The switch's architecture supports a high level of bandwidth, allowing for the smooth routing of multiple video streams in real-time. Its design includes advanced features that ensure low-latency, error-free data transfer, integral to maintaining the integrity and reliability of video data in critical applications. Featuring robust interoperability characteristics, the ARINC 818 Switch easily integrates into existing systems, facilitating modular expansion and adaptability to new technological standards. It is indispensable for any aerospace project that involves complex video data management, providing a stable platform for video data routing and switching.
The PDM-to-PCM Converter from Archband Labs leads in transforming pulse density modulation signals into pulse code modulation signals. This converter is essential in applications where high fidelity of audio signal processing is vital, including digital audio systems and communication devices. Archband’s solution ensures accurate conversion, preserving the integrity and clarity of the original audio. This converter is crafted to seamlessly integrate with a wide array of systems, offering flexibility and ease-of-use in various configurations. Its robust design supports a wide range of input frequencies, making it adaptable to different signal environments. The PDM-to-PCM Converter also excels in minimizing latency and reducing overhead processing times. It’s engineered for environments where precision and sound quality are paramount, ensuring that audio signals remain crisp and undistorted during conversion processes.
Digital Predistortion (DPD) is a sophisticated technology crafted to optimize the power efficiency of RF power amplifiers. The flagship product, FlexDPD, presents a complete, adaptable sub-system that can be customized to any ASIC or FPGA/SoC platform. Thanks to its scalability, it is compatible with various device vendors. Designed for high performance, this DPD solution significantly boosts RF efficiencies by counteracting signal distortion, ensuring clear and effective transmission. The core of the DPD solution lies in its adaptability to a broad range of systems including 5G, multi-carrier platforms, and O-RAN frameworks. It's built to handle transmission bandwidths exceeding 1 GHz, making it a versatile and future-proof technology. This capability not only enhances system robustness but also offers a seamless integration pathway for next-generation communication standards. Additionally, Systems4Silicon’s DPD solution is field-tested, ensuring reliability in real-world applications. The solution is particularly beneficial for projects that demand high signal integrity and efficiency, providing a tangible advantage in competitive markets. Its compatibility with both ASIC and FPGA implementations offers flexibility and choice to partners, significantly reducing development time and cost.
The ARINC 818-3 IP Core from iWave Global represents an advancement in avionics video interface technology, designed for high-speed and high-fidelity video data transmission. This IP core addresses the needs of modern aerospace systems that require robust video communication links both for military and commercial use. It supports a wide array of enhancements over previous generations, including increased bandwidth and improved signal integrity. This ensures that the ARINC 818-3 IP Core can handle the demands of next-generation avionic systems seamlessly, supporting advanced video processing and display systems. The core's design prioritizes modularity and scalability, allowing for easy integration and expansion to meet evolving system requirements. It is positioned as an essential tool for aviation applications demanding high reliability and accuracy in video data handling and display solutions, making it indispensable for new and retrofitted aerospace projects.
The Digital Radio (GDR) from GIRD Systems is an advanced software-defined radio (SDR) platform that offers extensive flexibility and adaptability. It is characterized by its multi-channel capabilities and high-speed signal processing resources, allowing it to meet a diverse range of system requirements. Built on a core single board module, this radio can be configured for both embedded and standalone operations, supporting a wide frequency range. The GDR can operate with either one or two independent transceivers, with options for full or half duplex configurations. It supports single channel setups as well as multiple-input multiple-output (MIMO) configurations, providing significant adaptability in communication scenarios. This flexibility makes it an ideal choice for systems that require rapid reconfiguration or scalability. Known for its robust construction, the GDR is designed to address challenging signal processing needs in congested environments, making it suitable for a variety of applications. Whether used in defense, communications, or electronic warfare, the GDR's ability to seamlessly switch configurations ensures it meets the evolving demands of modern communications technology.
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.
HFFx Auto is a high-frequency restoration technology designed to address audio quality degradation resulting from the use of lossy codecs. This technology is incredibly versatile, functioning effectively with both streamed audio-visual content and digital broadcast services. Its adaptability enables seamless adjustment across varying channel bandwidths and is capable of enhancing audio originally constrained by low sampling rates or sources like analogue tapes. Beyond restoration, HFFx Auto aids in up-conversion to higher sampling rates, offering a more open and natural sound experience. This capability makes it an indispensable tool for digital TV and other audio applications where enhancing the clarity and quality of sound is crucial. By automatically restoring bandwidth and compensating for frequency loss, HFFx Auto ensures that audio outputs remain vibrant and true to the original source material.
Laser Triangulation Sensors offered by Riftek Europe are designed for precise non-contact measurement and position checking. These sensors utilize blue and infrared lasers to measure dimensions and displacements ranging from 2 mm to 2.5 meters. The high frequency of 160 kHz sampling assures quick and accurate data capture with a measurement error as low as +/- 1 um. These sensors are versatile, suitable for a myriad of applications in various industries, from automotive to manufacturing, where precision measurements are critical. They provide robust performance even in demanding conditions due to their high-speed scanning capabilities. With their advanced laser technology, these sensors not only measure but also check run-outs, surface profiles, and deformations of components, providing comprehensive analysis for quality control and process optimization. Their integration into industrial setups enhances productivity and supports effective automation strategies.
D2D® Technology, developed by ParkerVision, is a revolutionary approach to RF conversion that transforms how wireless communication operates. This technology eliminates traditional intermediary stages, directly converting RF signals to digital data. The result is a more streamlined and efficient communication process that reduces complexity and power consumption. By bypassing conventional analog-to-digital conversion steps, D2D® achieves higher data accuracy and reliability. Its direct conversion approach not only enhances data processing speeds but also minimizes energy usage, making it an ideal solution for modern wireless devices that demand both performance and efficiency. ParkerVision's D2D® technology continues to influence a broad spectrum of wireless applications. From improving the connectivity in smartphones and wearable devices to optimizing signal processing in telecommunication networks, D2D® is a cornerstone of ParkerVision's technological offerings, illustrating their commitment to advancing communication technology through innovative RF solutions.
The Mixed-Signal CODEC offered by Archband Labs integrates advanced analog and digital audio processing to deliver superior sound quality. Designed for a variety of applications such as portable audio devices, automotive systems, and entertainment systems, this CODEC provides efficiency and high performance. With cutting-edge technologies, it handles complex signal conversions with minimal power consumption. This CODEC supports numerous interface standards, making it a versatile component in numerous audio architectures. It's engineered to offer precise sound reproduction and maintains audio fidelity across all use cases. The integrated components within the CODEC streamline design processes and reduce the complexity of audio system implementations. Furthermore, the Mixed-Signal CODEC incorporates features that support high-resolution audio, ensuring compatibility with high-definition sound systems. It's an ideal choice for engineers looking for a reliable and comprehensive audio processing solution.
The BAT Audio Platform represents a leading-edge audio IP solution developed for battery-powered System-on-Chip (SoC) applications. Intelligently designed to offer unparalleled audio fidelity, this platform significantly enhances auditory features in SoCs, accommodating uses from active noise cancellation and beamforming to voice user interfaces. With a focus on low energy consumption, BAT ensures extended battery life, optimizing devices for efficient operations. Offering an expansive array of off-the-shelf solutions combined with numerous customization options, BAT enables rapid market readiness and risk reduction by building upon top-tier, silicon-proven IPs. This platform not only accelerates project timelines but also decreases development costs, freeing clients to focus on their core competencies while leveraging Dolphin's audio expertise. Incorporating features like WhisperTrigger for ultra-low-power voice activity detection and WhisperExtractor for energy-saving analog feature extraction, BAT represents a holistic approach to advancing audio technology. The platform’s digital and mixed-signal solutions provide seamless integration and configuration, ensuring high fidelity and low power consumption across a spectrum of applications from consumer electronics to IoT devices.
The FCM1401 Dual-Drive™ Power Amplifier is tailored for Ku-band applications, utilizing CMOS technology to deliver solutions between 12.4 to 16 GHz. This product is designed to optimize power output while maintaining a compact silicon footprint. Notable for its excellent efficiency, the FCM1401 addresses the specific demands of telecom and satellite communications applications. The amplifier provides reliable performance characterized by a gain of 22 dB and a Psat of 19.2 dBm, achieving a power-added efficiency of 47% while operating at a supply voltage of 1.8V. Through these specifications, it positions itself as an ideal solution for applications requiring high power output and minimal heat generation. This product benefits from world-class CMOS integration, ensuring compatibility with modern telecom systems, enhancing their range and reducing their energy costs. The FCM1401 is equipped with a QFN/EVB package, allowing for straightforward implementation in various industrial contexts. It sets itself apart by offering an increased frequency range while delivering robust power handling capabilities, facilitating the high RF power needs of contemporary communication systems. The dual-drive capability of the FCM1401 means that it can effectively double the input signal power into the output without losing efficiency, making it highly suited for use in mission-critical operations where reliability and performance are paramount. Its high power-added efficiency also translates to cooler operation, reducing the need for extensive thermal management solutions, thus lowering associated costs.
ZIA Image Signal Processing technology provides state-of-the-art solutions for optimizing image quality and enhancing vision-based systems. This technology is integral to applications requiring precise image analysis, such as surveillance cameras and automotive safety systems. It supports various image processing tasks, including de-noising, color correction, and sharpness enhancement, delivering superior visual output even under challenging conditions. ZIA's adaptable architecture supports integration into a range of devices, ensuring broad applicability across multiple sectors.
The 8b/10 Decoder by Roa Logic is a comprehensive implementation of the 8b/10b encoding scheme developed by Widmer and Franaszek. This decoder offers a full solution that automates special comma detection and identifies K28.5 characters, which is essential for maintaining data integrity during transmission. It is designed for environments where precise data decoding is crucial, supporting seamless data transfer across various communication interfaces. This decoder ensures high accuracy in data interpretation by meticulously translating encoded bitstreams back to their original data form. Crafted with precision, it facilitates reliable data communication while reducing error rates during transmission. It is ideally suited for applications requiring error-free data exchange, where decoding accuracy is paramount. Supporting a range of protocols that utilize the 8b/10b scheme, the decoder’s robust design ensures compatibility and reliable performance. Its straightforward integration supports developers in creating efficient platforms for data handling, reinforcing the reliability of communication systems at large.
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 Camera PHY Interface for Advanced Processes by CURIOUS Corporation is designed to meet the demanding needs of modern imaging technology. This interface enables high-speed data transmission, catering to advanced process nodes required to support contemporary camera sensors. The interface efficiently handles various protocols, ensuring seamless integration with cutting-edge camera technologies. This makes it an ideal choice for applications where rapid data transfer and high-resolution image processing are necessary. The interface is engineered with sophisticated technology that provides reliable performance across multiple camera systems. Known for its adaptability, the Camera PHY Interface caters to diverse application needs by supporting various camera types and integration scenarios. This versatility plays a crucial role in fulfilling the requirements of high-performance imaging devices, ensuring superior camera functionality. Aside from its robust design, the interface also includes advanced features to support high-speed operations, making it capable of handling complex imaging tasks with ease. This positions the Camera PHY Interface as a pivotal component in the assembly of sophisticated and dynamic imaging systems, ensuring optimal functionality and performance.
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.
This technology represents a significant innovation in the field of wireless energy transfer, allowing for the efficient transmission of power without physical connections or radiation. By leveraging magnetic resonance, this non-radiative energy transfer system can power devices over distances with high efficiency. It's designed to be safe and environmentally friendly, avoiding the pitfalls of electromagnetic radiation while maintaining a high level of power transfer efficiency. The technology finds its applications in various sectors, including consumer electronics, automotive, and industrial applications where it provides a seamless and reliable solution to power transfer needs. The system's capability to transfer power efficiently without contact makes it ideal for scenarios where traditional power connections might be impractical or inconvenient, enabling new levels of convenience and flexibility for users. Designed to integrate smoothly with existing infrastructure, this energy transfer system can significantly reduce reliance on traditional charging methods, paving the way for more innovative and sustainable energy solutions. Furthermore, the system's architecture is geared towards scalability and adaptability, making it suitable for a wide range of devices and use cases.
The JPEG Encoder for Image Compression is a sophisticated IP core designed to support machine vision applications, offered by Section5. It is developed for integration in standard FPGAs, facilitating a cost-effective and efficient image processing solution. Capable of handling pixel bit depths up to 12 bits, this encoder provides high-quality image compression suitable for various multimedia applications. This IP core supports a diverse range of configurations, including the L1 pipeline for monochrome images and the L2 dual-pipe for high-quality YUV422 encoding. The JPEG Encoder also includes a higher pixel clock variant, L2H, that can accommodate up to 200 MHz for specific platforms. Its deployment capabilities include UDP/Ethernet streaming solutions compliant with RFC 2435 standards, enhancing its applicability in networked systems. Supported by extensive simulation models, Section5’s JPEG Encoder ensures high performance and reliability in deployment. Available reference designs and receiver software streamline the integration process across Linux and Windows platforms, facilitating seamless implementation in varying environments.
ParkerVision's Energy Sampling Technology is a state-of-the-art solution in RF receiver design. It focuses on achieving high sensitivity and dynamic range by implementing energy sampling techniques. This technology is critical for modern wireless communication systems, allowing devices to maintain optimal signal reception while consuming less power. Its advanced sampling methods enable superior performance in diverse applications, making it a preferred choice for enabling efficient wireless connectivity. The energy sampling technology is rooted in ParkerVision's expertise in matched filter concepts. By applying these concepts, the technology enhances the modulation flexibility of RF systems, thereby expanding its utility across a wide range of wireless devices. This capability not only supports devices in maintaining consistent connectivity but also extends their battery life due to its low energy requirements. Overall, ParkerVision's energy sampling technology is a testament to their innovative approach in RF solutions. It stands as an integral part of their portfolio, addressing the industry's demand for high-performance and energy-efficient wireless technology solutions.
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.
The CCSDS AR4JA LDPC Encoder and Decoder FEC IP Core is a configurable design that allows runtime configuration for decoding different code rates (i.e., 1/2, 2/3, and 3/4). To obtain high throughput, two different levels of parallelism are carried out; 128 check nodes and 6 variable nodes which are processed at the same time. Pipeline architecture is followed which significantly speeds up the whole decoding process. Also, layered architecture is implemented which helps to enhance the speed of the decoding process. AR4JA LDPC decoder supports soft decision decoding and hard decision output. Additional features include: CCSDS AR4JA LDPC Code family is quasi-cyclic, irregular parity check matrix, run time configuration for more than one code rate (i.e., 1/2, 2/3, 3/4), configurable codeword size that supports 2K, 3K, and 4K information words, minimum sum algorithm, and layered decoding architecture.
Crest Factor Reduction (CFR) is a critical technology in managing the efficiency of power amplifiers in communication systems. FlexCFR offers a standards-independent solution that can be compiled across any ASIC or FPGA/SoC platform, thanks to its flexible architecture. This feature makes it an ideal choice for projects that require versatility in deployment. The primary objective of CFR technology is to restrict the signal envelope, thereby allowing amplifiers to operate closer to saturation. This leads to improved power efficiency, minimizing energy loss during signal transmission. By reducing the peak-to-average power ratio (PAPR), FlexCFR ensures that systems achieve greater stability and performance. FlexCFR is particularly adept at supporting complex communication systems because of its agnostic approach to communication standards. It integrates seamlessly into existing systems, offering an immediate uplift in efficiency and performance without significant alterations to existing infrastructure. The configurable nature of the technology means it can cater to diverse project requirements across various sectors, enhancing its appeal in the market.
Mobix Labs' EMI Flex Filters are designed to address electromagnetic interference challenges in advanced technologies, ensuring smooth data transmission without disruptions. These filters are characterized by their ultra-thin and flexible form factor, which allows them to fit complex surfaces and enclosures, maintaining signal clarity and high-speed data transmission even in demanding environments. With the capability to filter up to 50 GHz, these filters are ideal for 5G and radar applications, ensuring long-term reliability across various industries. The EMI Flex Filters offer exceptional attenuation, catering to stringent military and aerospace standards. They provide customizable form factors to suit specific device requirements, ensuring versatility and adaptability in integration. Their durable design makes them suitable for applications that involve harsh conditions, enhancing their broad use-case potential in military, aerospace, telecommunication, IoT, medical, and automotive sectors. These filters emphasize performance by achieving minimal signal loss, which is critical for high-speed data applications. Military-grade performance and custom engineering support enable tailored solutions to meet precise specifications, reinforcing Mobix Labs' leadership in advanced EMI filtering technology.
Cologne Chip’s C3-CODEC-G712-4 is an advanced audio codec IP core that forms part of the renowned DIGICC-based ASIC IP lineup. This codec is tailored for efficient audio signal processing and supports a variety of telecommunication applications. What distinguishes the C3-CODEC-G712-4 is its ability to deliver high-fidelity audio through a fully digital approach, which streamlines the integration into various digital platforms, eliminating the complexity associated with analog audio signal management. Designed for robust performance, this codec ensures minimal latency and high efficiency in audio compression and decompression, making it an ideal choice for real-time communication systems. Its compact design and digital architecture allow for seamless compatibility with modern telecommunication infrastructure, providing users with excellent signal clarity without a significant resource footprint. Furthermore, Cologne Chip supports the C3-CODEC-G712-4 with extensive documentation and integration tools, easing its adoption into new and existing systems. This codec plays a critical role in enhancing the audio quality of communication systems while maintaining cost-effectiveness, thanks to the reduced need for external analog components and converters traditionally required in audio processing.
The Reed Solomon Encoder is fed with an input message of K information symbols, the Encoder appends 2T parity symbols to the input message in order to form the encoded codeword. The Reed Solomon Decoder receives an (N=K+2T) codeword, and it can locate and correct up to 8 possible symbol errors or up to 14 erasures. Both of the Encoder and the Decoder support any input timing pattern, in case of the Encoder; the output timing pattern will be the same as the input. In case of the Decoder; the output timing pattern is fully controlled in order to support any desired pattern by the user. The Reed Solomon Decoder keeps track of corrected errors. Input codewords with more than 8 errors are regarded as uncorrectable, and are flagged. The Implementation of Reed Solomon IP Core targets very low latency, high speed, and low gate count with a simple interface for easy integration on SoC applications.
The DVB-C Demodulator is engineered to meet the specific needs of cable video and broadband data transmission systems with an integrated Forward Error Correction (FEC) capability. This core is structured to enhance demodulation processes, streamlining communications and ensuring data reliability across transmission channels. Suitable for a variety of digital broadcasting requirements, it serves as a critical component in maintaining signal integrity and performance.
Designed for advanced 5G mmWave implementations, the FCM3801-BD Dual-Drive™ Power Amplifier cover frequency ranges of 32 to 44 GHz. Utilizing sophisticated CMOS technology, this amplifier is positioned for excellence with a gain of 19 dB and Psat of 18.3 dBm, attaining a power-added efficiency of 45% at a supply voltage of 1.8V. Its development caters to high-performance applications within the realm of 5G infrastructure. The FCM3801-BD stands out with its bare die format, offering versatility in design incorporation and enabling engineers to customize their system layouts to optimize performance. It's tailored for contexts that demand significant RF power and minimal total thermal output, minimizing cooling requirements. This power amplifier leverages the dual-drive architecture to multiply the input signal with maximum efficiency, appealing to high-demand telecom operations. The combination of high efficiency and elevated power levels make the FCM3801-BD integral for forward-looking communication technologies, providing solutions that meet the intense data demands of modern networks.
Aragio's LVDS solutions are tailored for high-speed data transmission up to 1 GHz for drivers and 1.2 GHz for receivers. Designed to meet the LVDS standard, the offering includes a CML interface to the core and power-up sequence independence. The solution provides flexibility with both 50Ω and 100Ω termination options, tailored to provide low power consumption while maintaining high performance. These features make it suitable for diverse high-speed data applications, ensuring reliability and energy efficiency.
The ARINC 664 P7 IP Core by iWave Global is at the forefront of aviation network solutions, offering an advanced platform for Ethernet-based communication in aerospace systems. Known for adhering to stringent industry standards, this IP core provides reliable and efficient communication protocols essential for avionics Ethernet networks. It effectively manages high-speed data across network infrastructures, paving the way for streamlined operations within aircraft systems. The core supports features essential for critical networked systems, such as bandwidth allocation, prioritization of data flows, and quality of service mechanisms. Ideal for enhanced networking capabilities in aircraft, the ARINC 664 P7 IP Core ensures data communication integrity, which is essential for the safety-critical operations found in modern aviation environments. This core is crucial for developers aiming to create sophisticated onboard systems that require precise and dependable data exchange mechanisms.
Mixed-Signal IP Solutions address the need for integrated circuits that handle both analog and digital signals. This category of IP is critical in applications where digital signal processing is required alongside analog signal inputs or outputs. These solutions provide effective bridging between the analog and digital circuitry components, ensuring that data is processed accurately and efficiently across different signal types. MosChip's Mixed-Signal IP Solutions are crafted to maximize performance without compromising compatibility with a wide range of electronic applications, including communication devices, sensors, and audio equipment. The design of these solutions focuses on achieving high fidelity in signal conversion and processing, which is crucial for maintaining the integrity of the overall system functionality. The inherent flexibility of these solutions makes them well-suited for deployment across multiple industries that demand both reliability and precision in signal processing. By accommodating both digital and analog requirements, they facilitate the design of cutting-edge products that meet the growing technological demands of today and tomorrow.
NeoBit is an innovative silicon-based One-Time Programmable (OTP) memory technology from eMemory Technology Inc. It is a leading-edge solution designed to offer non-volatile storage capabilities within integrated circuits. NeoBit is essential for applications where permanent data storage is critical, providing a secure, reliable platform for storing configuration data, security keys, and other vital information. The technology behind NeoBit ensures that once data is programmed in the memory, it cannot be altered or erased, thus safeguarding information against unauthorized changes. This feature makes it especially valuable in security-sensitive areas such as digital rights management, encryption keys, and secure identity applications. NeoBit's reliability and robustness are what set it apart from conventional storage methods as it continues to perform optimally in varying operating conditions. Adopted widely across multiple industries, NeoBit caters to the growing need for data integrity and resilience in hostile environments. It offers a compact footprint and is highly customizable to suit specific application requirements, making it a preferred option for semiconductors needing embedded security and configuration options.
NeoFuse represents a state-of-the-art anti-fuse One-Time Programmable (OTP) silicon IP solution. This technology is a key offering of eMemory Technology Inc., focusing on providing an unparalleled level of permanence and security for data storage within electronic devices. Once data is written into the NeoFuse, it becomes impervious to any modification, providing an ideal solution for applications requiring unalterable data recording. NeoFuse's anti-fuse approach is particularly advantageous in environments demanding high-security measures. This includes sectors like aerospace, defense, and high-stakes commercial applications where the integrity of data is paramount. By leveraging advanced physical and electronic characteristics, NeoFuse offers robust performance, resisting tampering and environmental influences. Moreover, NeoFuse has been successfully utilized in various cutting-edge technologies such as AI and HPC, demonstrating reliability and resilience. Its compatibility with modern semiconductor processes ensures that NeoFuse-based applications can meet the rigorous requirements of today's data-critical operations while offering a scalable and future-proof solution for storing sensitive information securely.
The ARINC 818-2 IP Core by iWave Global is engineered to support the high-speed video interface standard used in aerospace applications. This IP core signifies a leap in the integration of advanced video transmission protocols with existing avionics architectures. It is tailored for applications that demand highly reliable and efficient video data communications. Focusing on seamless compatibility, the ARINC 818-2 IP Core integrates easily into various platforms, ensuring minimal modifications and reduced time-to-market for development. This core supports high-speed data transfer rates, providing robust solutions for real-time video streaming and data transfer. Ideal for systems requiring precise video data handling, the ARINC 818-2 IP Core guarantees data integrity and synchronization across all transmission stages. Its versatile design allows for broad implementation across military and commercial aviation sectors, where data reliability and transfer efficiency are paramount.
The SMS Fully Integrated Gigabit Ethernet & Fibre Channel Transceiver Core is an advanced solution designed for high-speed data transmission applications. This core incorporates all necessary high-speed serial link blocks, such as high-speed drivers and PLL architectures, which enable precise clock recovery and signal synchronization.\n\nThe transceiver core is compliant with IEEE 802.3z for Gigabit Ethernet and is also compatible with Fibre Channel standards, ensuring robust performance across a variety of network settings. It features an inherently full-duplex operation, providing simultaneous bidirectional data paths through its 10-bit controller interface. This enhances communication efficiency and overall data throughput.\n\nParticularly suited for networks requiring low jitter and high-speed operation, this transceiver includes proprietary technology for superior jitter performance and noise immunity. Its implementation in low-cost, low-power CMOS further provides a cost-effective and energy-efficient solution for high-speed networking requirements.
The 802.11 LDPC solution offers a high-throughput design intended to meet demanding specifications for wireless communication standards. It features the flexibility to adjust LDPC decoding iterations, balancing throughput with error correction performance based on specific requirements. The system is designed to accommodate on-the-fly configuration from one frame to another, ensuring adaptability in various operating conditions. This feature-rich IP aims to maintain optimal bit-error-rate and packet-error-rate performance to ensure data integrity and reliability in dynamic digital communication environments.
GUC’s Mixed-Signal Front-End is designed to address the complex requirements of modern analog signal processing applications. This product blends both analog and digital circuits to efficiently manage and convert real-world signals into data that digital systems can process. Targeted at sectors where precise signal interpretation and processing are critical, this mixed-signal solution enhances the capability of system designs. The solution integrates various components necessary for complete signal chain management, ensuring minimal signal distortion and high-accuracy outcomes. It supports a wide range of applications from communications to industrial automation where data integrity is paramount. By compacting multiple functionalities into a single, optimized front-end, the solution reduces overall system complexity and cost. This Mixed-Signal Front-End is pivotal in systems where sensor data must be accurately translated into actionable digital information. Its versatile design supports developments in fields with stringent requirements for latency and performance, showcasing GUC’s commitment to engineering excellence in semiconductor solutions. By simplifying signal processing tasks, it extends the capabilities of integrated systems, setting new standards in analog processing technologies.
The FCM2801-BD Dual-Drive™ Power Amplifier is crafted to excel in 5G mmWave applications, focusing on frequencies from 23 to 36 GHz. It integrates CMOS technology to maximize power delivery while minimizing heat output, offering a gain of 22 dB and Psat of 19.5 dBm with power-added efficiency standing at 53%. The supply voltage for this amplifier is 1.8V, highlighting its compatibility with modern power supply requirements. Designed for 5G infrastructure, the FCM2801-BD supports critical applications necessitating superior RF power and reliability. This amplifier makes use of a bare die package, opening options for flexible design integration in advanced communication systems. Its efficiency and high power output contribute to better coverage with reduced energy utilization, aligning perfectly with modern 5G deployment goals. Incorporating the dual-drive architecture, the FCM2801-BD enhances operational stability and output capabilities, making it highly suitable for deployment in stringent network environments. With the capability to lower energy costs while maintaining high throughput and high-bandwidth performance, this amplifier becomes a valuable asset for telecommunications and related industries.
Akronic offers cutting-edge RF and mm-Wave IC design services, showcasing their expertise across various high-frequency subsystems of wireless radio transceivers. Their proficiency encompasses frequencies from a few MHZ to 100 GHz, embodying their capability in device modeling and chip layout at these wavelengths. By optimizing active biasing for peak performance against noise and power metrics, Akronic leverages sophisticated circuit topologies to guarantee low power consumption and minimal silicon footprint. Their design implements state-of-the-art techniques for simulation and packaging, ensuring that outcomes precisely match theoretical projections. Akronic's RF and mm-Wave IC designs support diverse applications, reinforcing their standing as leaders in the field.
The Analog IP offered by Key ASIC encompasses a broad range of components meant to satisfy the intricate needs of mixed-signal designs. Their audio codec IPs support 16, 18, and 24-bit sigma-delta architectures primarily for applications requiring high-fidelity audio processing. The voice codec supports both 14-bit ADC and 16-bit DAC at 48 KHz, ensuring crystal-clear audio for communication devices. For data conversion needs, their offerings include ADCs ranging from 6-bit to 12-bit, with various sampling rates that cater to different performance levels, from slow ADC tasks to high-speed functionality at 200 MHz. Their DACs, similarly spanning 8-bit to 12-bit, are engineered to handle a range of frequencies, making them ideal for applications in digital communications and signal processing. Other significant components include a programmable gain amplifier (PGA) with a 46 MHz bandwidth, bandgap references, DC-DC converters, voltage regulators, and power-on-reset elements. These IPs can be leveraged across consumer electronics and advanced data acquisition systems to enhance system efficiency and minimize power consumption.
The SiC Schottky Diode by Nexperia is a specialized semiconductor component designed to facilitate efficient rectification in high-frequency applications. Unlike conventional diodes, this SiC variant offers significantly lower reverse recovery charges and power losses, boasting improved energy efficiency. It finds its applications in high-power systems such as photovoltaic inverters, power supplies, and electric vehicle chargers, where it contributes to improved system performance and reliability. With its ability to operate at higher temperatures without significant loss of efficiency or performance, this Schottky diode is a favorite in applications demanding compact size yet robust performance. Implementing SiC technology enhances the diode's thermal stability, which ensures consistent functionality in power management systems exposed to extreme conditions. Consequently, designers can achieve higher current ratings without increasing the component size or cost. The innovative design of the SiC Schottky Diode ensures minimal leakage current, which conserves energy and contributes to the overall cut down of electromagnetic interference. Its high switching speeds complement its energy-saving capabilities, making it a preferable choice for modern power electronics where efficiency and performance are pivotal. Designed with sustainability and performance in mind, this diode is an ideal fit for forward-thinking applications that value long-term efficiency improvements.
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.
This 24-bit, 128Ksps Analog Front End (AFE) is engineered to meet the stringent demands of energy metering applications. Featuring a sigma-delta analog-to-digital converter (ADC), it ensures ultra-high precision in measuring electrical parameters. The design is implemented on the SMIC180nm technology node, providing robust performance and reliability across various conditions, making it a reliable choice for both residential and commercial energy metering solutions.
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.
MEMTECH's H-Series PHY IP is a top-tier solution tailored for high-bandwidth memory (HBM) systems. This IP is engineered to deliver superior performance for high graphics processing, high-performance computing, and advanced networking applications. The H-Series PHY IP is compliant with HBM2 and HBM2E standards, providing a cutting-edge balance of bandwidth, latency, and power efficiency, making it an ideal choice for demanding computational environments. With its sophisticated design, the H-Series PHY IP offers seamless integration into a variety of system architectures. It supports a robust ecosystem for HBM applications, combining low-power operation with high data rates necessary for modern computing workloads. This ensures that MEMTECH's IP can cater to the exhaustive processing needs of sectors relying heavily on high-performance data throughput, such as AI and ML applications. The H-Series PHY IP is equipped with a range of design optimization tools and reference architectures that enable rapid deployment and customization. These attributes make it a flexible choice for engineers aiming to push the limits of their chip designs, ensuring that high-speed data transactions occur efficiently and reliably.
The EPC Gen2/ISO 18000-6 Analog Front End developed by RADLogic serves as an integral part of RFID systems. It is engineered to work in perfect harmony with digital protocol engines, enhancing the efficiency of RFID communication. This analog front end plays a crucial role in converting the received analog signals into digital ones that can be processed further by the digital protocols. One of its key tasks is to manage the signal integrity and ensure that noise levels are kept to a minimum, a critical factor for successful RFID operations. The front end is built with precision to accommodate various signal conditions, allowing for stable performance even in challenging environments. Its design emphasizes high sensitivity, which improves the overall read range and accuracy of RFID readers. With a focus on reliability, the analog front end is capable of operating under diverse conditions without degradation. It supports seamless integration into existing systems, ensuring that the users can upgrade their RFID capabilities without any significant overhauls. This component, much like RADLogic’s broader portfolio, is designed to meet demanding industry standards, reflecting their robust experience in developing RFID technologies.
iWave Global's ARINC 818-2 Multi-Channel Conversion Card is designed for high-efficiency conversion of video data across multiple channels. This card is ideal for aerospace environments where managing numerous data streams is crucial for operations. It integrates seamlessly into existing systems, offering compatibility with a variety of video standards. Built to operate under stringent conditions, the multi-channel variant supports multiple video streams concurrently, enhancing operational efficiency in data-intensive applications. It is a critical component for systems requiring simultaneous handling of various video data sources without compromising on speed or accuracy. The card's architecture is focused on reducing latency while maximizing throughput, ensuring a consistent and reliable performance across applications like avionics, where data precision and system integration are essential. With its advanced capabilities, the ARINC 818-2 Multi-Channel Conversion Card is an indispensable tool for complex video data management in dynamic aviation environments.
This highly accurate 24-bit Sigma Delta ADC is designed for applications involving weighing scales and sensors. Utilizing the TSMC180nm process, it provides the reliability and precision required for commercial weighing systems and industrial sensor applications. With its ability to handle differential and pseudo-differential inputs, it serves as a robust solution for ensuring measurement accuracy and stability in challenging environments.
The 32-bit, 8Ksps Sigma Delta ADC is tailored for seismic precision applications, providing a high degree of accuracy needed for energy exploration and geophysical measurements. This AFE, implemented using TSMC's 180nm technology, incorporates advanced features to minimize noise and distortion, crucial for detecting and interpreting seismic signals. It supports applications in oil and gas exploration where precise data acquisition is essential, offering outstanding performance even in the harshest field conditions.
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