All IPs > Analog & Mixed Signal > PLL
The Analog & Mixed Signal PLL (Phase-Locked Loop) category of semiconductor IP at Silicon Hub encompasses a collection of sophisticated circuit designs used primarily for frequency synthesis, clock management, and timing in integrated circuits. PLLs are indispensable in a variety of electronic applications where synchronized frequency and phase-locked signals are crucial. This class of semiconductor IPs is pivotal for ensuring stable and reliable operations in digital and analog systems alike.
PLLs are widely utilized in communication systems, consumer electronics, and computing devices. In communication systems, they play a critical role in modulating and demodulating signals, ensuring accurate data transmission. Consumer electronics, such as smartphones, tablets, and gaming devices, leverage PLL technology to maintain accurate system clocks, which is essential for digital signal processing and multimedia performance. In computing, PLLs help in maintaining synchronous operations between processors and memory, allowing seamless multitasking and high-speed data processing.
Within this category, you will find a variety of PLL designs and architectures, each tailored to specific application needs, including fractional-N PLLs, integer-N PLLs, and Delay-Locked Loops (DLLs). These variants offer different advantages, such as reduced phase noise, higher frequency stability, and improved design flexibility. Additionally, some advanced PLL IPs incorporate features like spread spectrum clocking to minimize electromagnetic interference, making them suitable for use in sensitive electronic environments.
Overall, the Analog & Mixed Signal PLL semiconductor IPs available at Silicon Hub are integral components that help optimize the performance, efficiency, and reliability of modern electronic systems. They enable designers and engineers to tackle complex clocking requirements and achieve precise control over signal timing, which is a cornerstone of innovation in technology sectors ranging from telecom to computing and beyond.
Silicon Creations delivers precision LC-PLLs designed for ultra-low jitter applications requiring high-end performance. These LC-tank PLLs are equipped with advanced digital architectures supporting wide frequency tuning capabilities, primarily suited for converter and PHY applications. They ensure exceptional jitter performance, maintaining values well below 300fs RMS. The LC-PLLs from Silicon Creations are characterized by their capacity to handle fractional-N operations, with active noise cancellation features allowing for clean signal synthesis free of unwanted spurs. This architecture leads to significant power efficiencies, with some IPs consuming less than 10mW. Their low footprint and high frequency integrative capabilities enable seamless deployments across various chip designs, creating a perfect balance between performance and size. Particular strength lies in these PLLs' ability to meet stringent PCIe6 reference clocking requirements. With programmable loop bandwidth and an impressive tuning range, they offer designers a powerful toolset for achieving precise signal control within cramped system on chip environments. These products highlight Silicon Creations’ commitment to providing industry-leading performance and reliability in semiconductor design.
The Ring PLLs offered by Silicon Creations illustrate a versatile clocking solution, well-suited for numerous frequency generation tasks within integrated circuit designs. Known for their general-purpose and specialized applications, these PLLs are crafted to serve a massive array of industries. Their high configurability makes them applicable for diverse synthesis needs, acting as the backbone for multiple clocking strategies across different environments. Silicon Creations' Ring PLLs epitomize high integration with functions tailored for low jitter and precision clock generation, suitable for battery-operated devices and systems demanding high accuracy. Applications span from general clocking to precise Audio Codecs and SerDes configurations requiring dedicated performance metrics. The Ring PLL architecture achieves best-in-class long-term and period jitter performance with both integer and fractional modes available. Designed to support high volumes of frequencies with minimal footprint, these PLLs aid in efficient space allocation within system designs. Their use of silicon-proven architectures and modern validation methodologies assure customers of high reliability and quick integration into existing SoC designs, emphasizing low risk and high reward configurations.
The VCO24G is engineered as a 24GHz Colpitts Voltage-Controlled Oscillator, offering low noise performance and a differential architecture ideal for integrating within PLL systems and broadband testing environments. This VCO capitalizes on the low-cost, high-output capabilities of the 0.18um SiGe process, ensuring it meets rigorous demands for precision and long-term reliability in various telecommunication applications. Its design lends itself to high-frequency operations with exceptional signal stability.
The pPLL03F-GF22FDX is a state-of-the-art, all-digital Fractional-N PLL crafted specifically for performance computing environments, offering low jitter and compact design. This advanced PLL is optimized for clocking applications that demand precise timing, functioning at frequencies of up to 4GHz. Its architecture makes it an excellent choice for driving performance computers and ADC/DAC systems where moderate SNR is essential. Constructed utilizing Perceptia's robust second-gen all-digital PLL technology, it delivers consistent results across a broad spectrum of process variations and conditions. Noteworthy for its tiny area, the pPLL03F enables system designers to efficiently manage complex multi-domain clock systems utilizing shared power supplies. Each instance includes a built-in power regulator, facilitating seamless sharing of power across various blocks relying on its clock outputs. Featuring dual PLL outputs through distinct postscalers, it's designed for easy integration into SOC systems while being highly testable, supporting industry-standard flows. It is usable in both integer-N and fractional-N modes, offering substantial flexibility in synchronizing input-output clock frequencies at the system level. The design encompasses compactness and effectiveness, ensuring low consumption while maintaining superior performance.
The Ultra-Low Latency 10G Ethernet MAC IP core is engineered to optimize network performance by reducing latency and increasing data throughput. It provides an essential solution for applications requiring high-speed, reliable network connectivity through the use of FPGA technologies. Designed to fit efficiently within FPGA architectures, this MAC core consumes fewer resources while maintaining performance. It achieves this by offering a streamlined all-RTL solution that minimizes complexity, reliance on CPUs, and power consumption. Available in both cut-through and store-and-forward modes, this MAC allows for adaptable network configurations to suit project-specific requirements. The Ultra-Low Latency Ethernet MAC IP features advanced capabilities such as Deficit Idle Control, which optimizes throughput by controlling the inter-frame gap, ensuring smooth data streaming. The integration of a robust error-checking and correction mechanism further supports reliable, high-performance data transfer, making it ideal for demanding applications.
The 10G Ethernet MAC and PCS from Chevin Technology is designed to offer high-speed Ethernet connectivity for FPGAs. This IP core maximizes throughput with low latency and fits within a compact architecture that utilizes minimal FPGA resources. It adheres to IEEE 802.3by standards, making it ideal for seamless integration in various FPGA designs, including those with a focus on ultra-fast duplex Ethernet. Chevin Technology’s 10G MAC simplifies synthesis by offering a user-friendly guide and expert support, ensuring minimal disruption to your existing design. It is compatible with both Intel and Xilinx FPGA families, and features an all-logic architecture which lowers energy consumption and reduces latency by not requiring additional CPU or software overheads. The design offers both cut-through and store-and-forward operational modes, along with a powerful CRC32 engine for error detection and correction during data transmission. Reference designs for boards such as Bittware IA-840F and Alpha Data ADM-PCIE-8V3 are available to aid in rapid deployment and integration.
The High-Speed PLL provided by SkyeChip offers a versatile frequency synthesizer solution with a wide output range from 300MHz to 3.2GHz. It is equipped with features like FBDIV and POSTDIV configurations to suit various divisions, and operates efficiently within a temperature range of -40°C to 125°C. This makes it an essential component for precision clock generation in a variety of IC applications.
The AFX010x Product Family serves benchtop and portable data-acquisition systems, offering up to four channels with a resolution reaching up to 16 bits. It boasts a sampling rate capability of up to 5 GSPS, supported by a digitally-selectable 3dB bandwidth extending to 300 MHz. Integrated features such as a single-to-differential amplifier and offset DAC make it a comprehensive solution for high-resolution systems. The family includes products suitable for a variety of applications, ensuring high signal integrity and power efficiency. This product line is engineered for minimal power consumption while maintaining high sampling rates and wide bandwidth. Each AFE IC encompasses four independent, highly integrated channels. These channels feature programmable input capacitance, a programmable gain amplifier (PGA), offset DAC, ADC, and a digital processor. The AFX010x products are pin-to-pin compatible in a standard package, designed for high integration and reduced PCB footprint. The product's versatility is highlighted by features such as the capability to choose different power modes, allowing adaptability to specific needs. With low power consumption and advanced on-chip technology like clock synthesizers, these products offer exceptional configurability and SWaP-C optimization. Applications extend to areas like handheld and benchtop oscilloscopes, non-destructive testing, and noise diagnostics.
The DIV60G is a high frequency, fully differential frequency divider reaching up to 60GHz, ideal for sophisticated PLL applications and broadband measurement equipment. It includes an active balun with differential I/Q outputs, offering unparalleled frequency dividing capabilities. Its ultra-high frequency operating parameters are supported by a 0.18um SiGe process, making it particularly effective for use in environments requiring precision and low phase noise. Tailored for advanced industrial use, this divider provides substantial flexibility with differential inputs and outputs.
The Vantablack S-VIS coating is specifically tailored for space applications, where it serves a crucial role in suppressing stray light in optical systems and blackbody calibration of infrared camera systems. Its exceptionally high performance and spectrally flat absorption from the UV to the near-millimeter spectral range make it indispensable for ensuring accurate readings and operations in the challenging environment of space. One of the prominent applications of the S-VIS coating is in the reduction of launch weight for instruments, thanks to its ability to absorb light efficiently from all angles. This not only enhances the operation of devices like star trackers and optical calibration systems but also minimizes the overall size and complexity of these systems, offering significant cost savings. This coating has proven its reliability in harsh space conditions since its first deployment in low Earth orbit in 2015. Its capabilities in outgassing management and thermal stability are well-documented, making it a trusted solution for enhancing the operational longevity and performance of space missions.
The PLL12G, serving as a Clock Multiplication Unit, is engineered to generate clock outputs in the 8.5GHz to 11.3GHz range, complementing a host of transceiver standards like 10GbE and OC-192. It operates with low power consumption, courtesy of IBM's 65nm process, making it suitable for various clocking modes crucial in phase-locked loop systems. Its diverse functionality ensures it's integral to telecommunications infrastructures where multiple clocking modes, including FEC support, are required.
eSi-Analog delivers integrated analog solutions that enhance the performance of custom ASICs and SoCs. The IP range includes oscillators, PLLs, and sensor interfaces, critical to developing high-fidelity analog functionalities. Designed for low power consumption, these solutions are adaptable to customers' requirements, ensuring expedited time-to-market. Silicon-proven across multiple process nodes, eSi-Analog enables innovative designs in competitive, dynamic industries. With a focus on reducing integration complexity and costs while maintaining high performance, eSi-Analog serves crucial roles in various applications, such as IoT devices, wearables, and medical systems, benefiting from the reliable analog performance.
The TimeServoPTP expands on the capabilities of the TimeServo by offering a fully compliant IEEE 1588v2 Precision Time Protocol (PTP) ordinary clock implementation. Specifically designed as an FPGA component, it supports both 1-step and 2-step synchronization processes, ensuring cohesive operation in synchronization tasks involving network time grandmasters. With capabilities that include up to 32 'time now' outputs with clock domain crossing logic, TimeServoPTP is engineered for applications where maintaining coherent time is crucial. This is especially beneficial in scenarios requiring precise timekeeping over Ethernet using PTP/1588 EtherType frames. The internal Gardner Type-2 DPLL further adds to its high precision in synchronization tasks. The solution is straightforward to implement, functioning independently from host processors post-initialization. Compatible with Intel and Xilinx FPGA devices, TimeServoPTP is an ideal choice for applications in autonomous synchronization where minimal host interaction is preferred, and is well-suited for both complex and standard timekeeping challenges in network infrastructure.
802.11 LDPC offers a highly efficient solution for wireless communication systems, ensuring high throughput and dynamic configuration. The design allows frame-to-frame configuration, optimizing the trade-off between throughput and error correction performance. Meeting stringent bit-error-rate and packet-error-rate specifications, this technology is ideal for robust communication systems requiring reliable data transmission.
The VCO25G is a Colpitts Voltage-Controlled Oscillator, featuring a low noise differential architecture suitable for applications up to 25.5GHz. Built using a cost-effective 0.18um SiGe process, this VCO is integral to high-performance PLLs, offering valuable benefits in broadband measurement and testing environments. It is designed for seamless integration within complex telecommunication systems, ensuring reliability and precision in frequency control with minimal environmental interference.
This innovative system combines voltage droop mitigation with fine-grained DVFS capabilities in a single integrated solution. Its exceptional observability stems from advanced telemetry features that provide critical insights into voltage behavior for optimized silicon management. Utilizing standard-cell design, it effectively responds to droop events with unprecedented speed, reducing voltage margins and enhancing power savings for system-on-chips (SoCs). This solution is robust across different process technologies, ensuring consistency in performance and feature reliability.
Analog Bits delivers high-quality clocking solutions that are renowned for their flexibility and low power consumption. Their clocking IPs include a wide range of low jitter PLLs that are adaptable to various applications, offering high precision and stability essential for maintaining the performance of integrated circuits. These clocking solutions are designed for advanced process nodes, proving their capability in meeting the needs of modern semiconductor design. Compatible with leading process technologies, these clocking solutions accommodate customizations that enhance ease of integration within client systems. The clocking IP ensures optimal performance across a broad spectrum of applications such as consumer electronics, automotive, and server solutions, making it a versatile choice for developers striving for excellence in their chip design projects. Further proving its robustness, the Clocking solutions are supported by Analog Bits’ expertise in silicon-proven technologies. This guarantees that clients receive reliable and high-performance IP that efficiently powers the clock mechanisms within their semiconductor devices.
RIFTEK's Laser Triangulation Sensors are designed to perform non-contact measurements, crucial for determining positions with extreme accuracy. These sensors are capable of measuring dimensions and displacements over ranges extending from 2 mm to 2.5 meters. With a precision margin of approximately ±1 µm and a sampling frequency reaching up to 160 kHz, these sensors are available in configurations utilizing both blue and infrared lasers, catering to diverse measurement needs. This technology is applied in various domains where exact measurement is pivotal, ensuring measurements are not only accurate but also fast, catering to the demands of high-speed industrial applications.
The Titanium Ti375 FPGA is crafted to deliver high density and low power consumption, fitting well into modern computing systems where efficiency is paramount. Utilizing a 16 nm process node, the Ti375 offers optimal performance in a small form factor, making it ideal for applications that require significant computational power within limited physical space. With support for hardened controllers including MIPI D-PHY and LPDDR4, it's equipped to handle a range of IoT and industrial device needs. Efinix's Titanium series integrates SEU protection mechanisms to ensure device integrity and prevent data corruption from random events, which is crucial for consistent device operation. The bitstream security features in the Titanium series protect designs from unauthorized tampering or infringement, thereby extending the lifecycle of the products in which they are embedded. Moreover, the Titanium FPGAs, including the Ti375, focus on ease of integration into customer applications with a commitment to product longevity until at least 2045, evidenced by its use in diverse markets from industrial control systems to automotive and consumer electronics. This long-term support is critical for applications that demand sustained reliability and support over time. The Ti375 hosts numerous logic elements, RAM blocks, DSP capabilities, and PLLs, providing a comprehensive solution for tasks ranging from complex data processing to real-time image and signal handling, making it a go-to choice for many developers in high-end performance sectors.
The DIV50G1 is a programmable prescaler operating up to 50GHz with various dividing coefficients. Its design caters to high-precision applications requiring careful frequency management and offers single-ended or differential inputs with differential outputs. This flexibility supports integration into complex PLL circuits and broadband measurement gear. The technological foundation is a robust 0.18um SiGe process, ensuring reliability and superior performance for advanced technological applications demanding frequency adjustability and precision.
The Digital PreDistortion (DPD) Solution by Systems4Silicon is a cutting-edge technology developed to maximize the power efficiency of RF power amplifiers. Known as FlexDPD, this solution is vendor-independent, allowing it to be compiled across various FPGA or ASIC platforms. It's designed to be scalable, optimizing resources according to bandwidth, performance, and multiple antennae requirements. One of the key benefits of FlexDPD is its substantial efficiency improvements, reaching over 50% when used with modern GaN devices in Doherty configurations, surpassing distortion improvements of 45 dB. FlexDPD is versatile, operating with communication standards including multi-carrier, multi-standard, and various generations from 2G to 5G. It supports both time division and frequency division duplexing, and can accommodate wide Tx bandwidths, limited only by equipment capabilities. The technology is also agnostic to amplifier topology and transistor technology, providing broad applicability across different setups, whether class A/B or Doherty, and different transistor types like LDMOS, GaAs, or GaN. This technology integrates seamlessly with Crest Factor Reduction (CFR) and envelope tracking techniques, ensuring a low footprint on resources while maximizing efficiency. With complementary integration and performance analysis tools, Systems4Silicon provides comprehensive support and documentation, ensuring that clients can maximize the benefits of their DPD solution.
The mmWave PLL is a sophisticated Phase Locked Loop designed for ultra-precision wireless communications and radar applications. This fractional-N PLL synthesizer provides low phase noise performance suitable for demanding carrier and fast chirp FMCW waveforms, critical in modern communication networks. Its operational range corresponds to fundamental frequencies of 19.00-20.15 GHz, scalable to radar bands of 38-40.5 GHz and 76-81 GHz through frequency multipliers, highlighting its versatility across applications. The mmWave PLL supports a customizable frequency range from 19 GHz to 81 GHz, ensuring tailored application requirements can be achieved. Integrated design features include a built-in sequencer, calibration, and self-test capabilities, all of which contribute to the PLL's robustness. The unit is compliant with automotive standards like AEC-Q100 Grade 1, making it suitable for rigorous environments, such as automotive radar systems. Technical specifications reveal its operational proficiency with power consumption at under 120 mA and operating temperatures from -40 to +125 °C (ambient) and -40 to +150 °C (junction). This is supported by SPI control interfaces for precise manageability, ensuring integration efforts align seamlessly within varied system architectures.
The FCM3801-BD Power Amplifier enhances Falcomm's powerful offerings in the realm of high-performance digital power amplification. Functioning at an impressive 38 GHz center frequency, this device is engineered for ultra-efficient energy solutions in the field of advanced telecommunications. With a design that underscores energy efficiency and reliability, the FCM3801-BD is a key player for telecom operators aiming to optimize power resources. This amplifier's intelligent construction ensures unwavering performance even in challenging conditions, reflecting Falcomm's commitment to sustainability and operational excellence. Ideal for applications such as high-speed data transmission and enhanced signal processing, the FCM3801-BD promises to reduce power demands while delivering high output. This enables telecom providers to pursue eco-friendlier paths in their operations without compromising on service quality or connectivity capabilities.
The EAMD12G serves as a modulator driver for EA/MZ applications, tailored specifically to drive up to 11.3Gb/s in fiber optic communications. It features programmable output voltage swing and DC offset adjustment, with built-in monitoring capabilities to ensure precision in modulation tasks. Integrated within the robust TowerJazz 0.18um SiGe process, it is adept for high-frequency operation necessary for effective data transmission in modern broadband setups.
The VCOMB12G is an advanced low noise multi-band LC voltage-controlled oscillator designed for sophisticated phase-locked loop applications, particularly in fiber optic systems. This oscillator offers a wide frequency range and supports multiple clocking modes, providing essential flexibility in cutting-edge communication systems. It is capable of integrating seamlessly into complex digital frameworks where accurate frequency tuning is crucial. Its design ensures minimal power consumption, promoting energy efficiency without sacrificing performance.
The pPLL08 Family represents a cutting-edge class of all-digital Fractional-N RF Frequency Synthesizer PLLs tailored for RF applications like 5G and WiFi. These PLLs are characterized by exceptionally low jitter and minimal phase noise, with operational frequencies reaching up to 8GHz, making them ideal for Local Oscillator and ADC/DAC clocking in highly demanding environments requiring superior SNR. Built with Perceptia's state-of-the-art second-gen digital PLL technology, the pPLL08 Family ensures unparalleled performance consistency across a wide range of processes, delivering results that are independent of PVT condition variants. Their architecture employs a compact LC tank DCO, maintaining the balance between size, power usage, and interference immunity, crucial for advanced RF systems. The family supports both integer-N and fractional-N configurations, offering superior flexibility for system-level clock frequency management. With robust integration capabilities, they seamlessly fit into complex SoC designs and come alongside extensive support for design implementation. Their ability to effectively support various wireless standards, including 5G and WiFi, underscores their versatility in modern RF design.
The Dual-Drive™ Power Amplifier FCM1401 stands out for its exceptional energy efficiency and advanced two-stage architecture. Operating at a center frequency of 14 GHz, it embodies industry-leading innovation in power amplifiers by offering a significant leap in power efficiency. This product is ideal for mobile connected devices and telecommunication applications that demand lower energy consumption without sacrificing performance. With its robust design, the FCM1401 ensures that operators can enhance operational efficiency while reducing the environmental footprint of power consumption. The design caters to high-frequency applications by maximizing performance and maintaining the reliability expected in modern telecom infrastructures. It therefore offers a practical solution for enhancing device longevity with reduced operational expenses. This amplifier is tailored to support both space communications and mobile technology applications, offering unparalleled power handling capabilities. Whether enriching the battery life or scaling up the signal strength, it aligns with green energy initiatives by providing significant output without increased energy use.
The 2D FFT from Dillon Engineering efficiently handles two-dimensional data transformation applications. It is particularly beneficial in scenarios where large-scale data analysis and image processing tasks require swift execution. The core exemplifies Dillon's expertise in enhancing processing speeds while maintaining high-quality output, making it indispensable for projects involving complex two-dimensional signal processing. Dillon's 2D FFT is designed to operate with internal or external memory configurations, supporting high throughput and flexibility in memory management. By utilizing dual FFT engines, it ensures efficient handling of horizontal and vertical data streams, making it suitable for tasks involving multidimensional data like images or video streams. This FFT Core is highly adaptable due to its flexible architecture enabled by the ParaCore Architect™ tool, which ensures that it can be easily customized to meet specific design and performance criteria. Thus, Dillon's 2D FFT stands as a crucial component for developers seeking to incorporate effective, reliable, and fast two-dimensional FFT processing into their systems.
Certus Semiconductor's Analog I/O solutions deliver state-of-the-art protection through ultra-low capacitance and extreme ESD protection. Designed for high-speed SerDes and RF applications, these products ensure that signal integrity and impedance matching are not compromised. The Analog I/O offerings from Certus are driven by innovation, featuring less than 50 fF capacitance solutions apt for today's advanced technological demands. These analog solutions are equipped to tolerate signal swings below ground, capable of providing robust ESD protection withstanding over 16kV HBM. In addition to these capabilities, they possess high temperature tolerance and can endure aggressive operational environments, making them an ideal fit for sectors demanding high reliability and rugged performance. The comprehensive design integrates IO, ESD, and power clamps into significant macro cells for optimal performance. Certus Semiconductor ensures that their analog solutions are adaptable, scalable, and ready to meet future demands in high-speed and high-frequency applications.
Optimized for precision voltage reference, the Band-Gap Reference delivers stable voltage outputs ranging from 0.6V to 1.2V, supporting a current operation of 25μA within a voltage range of 2.2V to 5.5V. It ensures high precision with an accuracy between 1% to 3%, depending on operational conditions, making it highly effective for calibration and biasing circuits in diverse electronic applications. The band-gap reference is critical in systems that demand a stable, low-temperature-coefficient voltage reference such as analog-to-digital converters and power management circuits. Its resilience across different temperatures and voltage supplies ensures reliable performance in varying environmental conditions. Implemented across Magna and Samsung foundries via 65nm, 130nm, and 180nm process technologies, the reference circuit is silicon-proven, demonstrating consistent and reliable operation in delivering precise voltage references for demanding electronic systems.
The FCM2801-BD Power Amplifier from Falcomm represents a pinnacle in amplification technology, engineered to excel in ultra-efficient energy use. This power amplifier operates at a center frequency of 28 GHz, making it well-suited for high-speed wireless communications and next-generation telecom services. Its design not only prioritizes power efficiency but also durability and performance in demanding environments. The FCM2801-BD offers considerable improvements in power usage efficiency, aligning with modern demands for low-energy-consumption solutions. Thus, it caters to both commercial and industrial applications that require robust yet efficient power amplification. This product is fundamental in reducing operational costs for telecommunication providers and in advancing the performance of consumer electronics. Its precision engineering ensures it can withstand and operate efficiently in a wide range of conditions, cementing its place as a core component in innovative telecom solutions.
The HUMMINGBIRD is an advanced Optical Network-on-Chip (NoC), designed to optimize data flow within complex computing environments. By integrating photonic networking capabilities, HUMMINGBIRD allows for streamlined data communication across chip components, reducing latency and power use significantly. Its architecture is geared towards accommodating rapid, efficient data processing, proving essential for data centers aiming to enhance internal communication without the bottleneck of traditional electronic interconnections. As an embodiment of optical advancements, HUMMINGBIRD sets the stage for enhanced computational harmony and performance.
The Moonstone series introduces high-efficiency laser sources tailored for advanced photonic applications. These laser sources are engineered to cater to sophisticated computational and communication needs, offering excellent precision and reliability. Their integration into photonic systems ensures not only high performance but also greater energy efficiency, crucial for demanding environments that prioritize both speed and sustainability. With Moonstone, users are equipped with the tools necessary to push the boundaries of what's achievable in photonic-based technologies, acting as a cornerstone for innovative developments across optical computing sectors.
The pPLL02F Family comprises a series of comprehensive all-digital Fractional-N PLLs, designed to deliver exceptional performance in a compact footprint. These PLLs are engineered for applications requiring clock sources in moderate-speed digital systems and microprocessors, with operational frequencies reaching up to 2GHz. The pPLL02F is acclaimed for its minimal jitter, ensuring stable performance across various clocking tasks. The family is built on advanced second-generation digital PLL technology, capable of both integer and fractional multiplications for flexible design adaptation. This technology ensures consistent performance across multiple manufacturing processes, immune to fluctuations in PVT conditions. Besides its compact size, each PLL in this family operates with reduced power consumption, making it optimal for systems with multiple PLL requirements sharing power supplies. equipped with features such as an integrated power supply regulator and support for multi-clock domain systems, pPLL02F integrates seamlessly within SOC designs. It offers straightforward integration support and is compatible with industry-standard backend flows, facilitating its use in mainstream SoC development.
This technology platform is devoted to radio frequency and includes features such as a high-performance silicon-germanium process. It is designed to enhance both RF circuits and mixed-signal designs, making it suitable for applications in wireless communication and infrastructure. This technology leverages the improved speed and reduced power consumption benefits of SiGe BiCMOS, making it a cornerstone for modern communication solutions. The SiGe BiCMOS Technology offers exceptional performance in terms of frequency response and signal integrity. It allows designers to create smaller, more efficient chips that are capable of forming the backbone of diverse RF applications. Its versatility is evident in the wide array of devices it supports, enabling compact yet powerful units suitable for today's demanding technological environments. With its strong emphasis on cost-effectiveness, SiGe BiCMOS Technology is adept at reducing material usage and power consumption. The process's integration capability allows for the accommodation of diverse components on a single chip, enabling significant advancements in system simplification while enhancing component reliability and longevity.
hellaPHY Positioning Solution is an advanced edge-based software that significantly enhances cellular positioning capabilities by leveraging 5G and existing LTE networks. This revolutionary solution provides accurate indoor and outdoor location services with remarkable efficiency, outperforming GNSS in scenarios such as indoor environments or dense urban areas. By using the sparsest PRS standards from 3GPP, it achieves high precision while maintaining extremely low power and data utilization, making it ideal for massive IoT deployments. The hellaPHY technology allows devices to calculate their location autonomously without relying on external servers, which safeguards the privacy of the users. The software's lightweight design ensures it can be integrated into the baseband MCU or application processors, offering seamless compatibility with existing hardware ecosystems. It supports rapid deployment through an API that facilitates easy integration, as well as Over-The-Air updates, which enable continuous performance improvements. With its capability to operate efficiently on the cutting edge of cellular standards, hellaPHY provides a compelling cost-effective alternative to traditional GPS and similar technologies. Additionally, its design ensures high spectral efficiency, reducing strain on network resources by utilizing minimal data transmission, thus supporting a wide range of emerging applications from industrial to consumer IoT solutions.
StreamDSP's JPEG2000 Video Compression Solution provides advanced video and image compression capabilities necessary for a host of professional applications where image quality is paramount. With support for both lossy and lossless compression in a single codestream, this solution balances between achieving the highest image quality and maximizing compression efficiency. It is ideal for applications ranging from digital cinema and medical imaging to remote sensing and scientific research, where maintaining image integrity is crucial. The solution is implemented within FPGA environments, leveraging the high-performance processing capabilities without the need for external processors. This flexibility allows for substantial customization, meeting the varied demands of industries that rely on high-quality image processing. With a range of adaptable features and configurable options, the JPEG2000 Video Compression Solution offers both flexibility and robustness in meeting the needs of complex image processing tasks.
Dillon Engineering's Pipelined FFT Core is designed to streamline continuous data transformations with minimal memory usage. This architecture is optimal for low-latency applications where consistent data flow and smooth signal processing are required, making it an essential solution for environments where real-time performance is critical. The core features a single butterfly per rank pipeline structure, allowing for continuous data processing without significant delays. The incorporation of both fixed and floating point operations enhances its versatility, catering to a broad spectrum of industry needs. Its design supports innovative synchronization methods that ensure data consistency and accuracy throughout the operational cycle. Employing Dillon's advanced ParaCore Architect™, the Pipelined FFT delivers enhanced customizability, adapting swiftly to different architectures and design requirements. This makes it particularly suitable for applications involving real-time data analytics and signal processing where efficiency and precision are priorities. Its streamlined approach and minimal resource reliance mark it as a choice component for sophisticated digital systems.
The pPLL05 Family serves as a collection of low power, all-digital Fractional-N PLLs that are optimal for IoT and embedded system applications. These PLLs are designed to operate efficiently in environments with low voltage supply, achieving performance at frequencies up to 1GHz. The low power consumption of the pPLL05 makes it especially suitable for battery-operated and space-constrained devices. This family stands out with its minimal power requirement and small footprint, ensuring a seamless fit within compact designs that utilize a shared supply with associated blocks. When provided with an analog power supply, it offers superior jitter performance, enhancing the accuracy of the output clock. The pPLL05 Family includes integrated features such as support for multi-PLL systems and flexible integer and fractional multiplication, allowing for numerous input and output frequency combinations at the system level. Integrated using advanced second-gen digital PLL technology, the pPLL05 excels in consistency and performance across various manufacturing processes. It's ideal for applications that require low power yet reliable clock sources, offering robust integration capabilities with comprehensive support for design flow and customization services.
Silicon Creations offers a diverse suite of PLLs designed for a wide range of clocking solutions in modern SoCs. The Robust PLLs cover an extensive range of applications with their multi-functional capability, adaptable for various frequency synthesis needs. With ultra-wide input and output capabilities, and best-in-class jitter performances, these PLLs are ideal for complex SoC environments. Their construction ensures modest area consumption and application-appropriate power levels, making them a versatile choice for numerous clocking applications. The Robust PLLs integrate advanced designs like Low-Area Integer PLLs that minimize component usage while maximizing performance metrics, crucial for achieving high figures of merit concerning period jitter. High operational frequencies and superior jitter characteristics further position these PLLs as highly competitive solutions in applications requiring precision and reliability. By incorporating innovative architectures, they support precision data conversion and adaptable clock synthesis for systems requiring both integer and fractional-N modes without the significant die area demands found in traditional designs.
The OT3122t130 PLL is purpose-built for integration with TSMC's 130nm process node, providing a reliable solution for precise frequency synthesis in electronic circuits. This PLL is ideally suited for applications demanding rigorous timing accuracy and stability, offering a fundamental building block in advanced digital systems. Engineered to optimize performance under various electrical environments, this PLL excels in minimizing phase noise and jitter, crucial for maintaining data integrity across high-speed interfaces. With its focus on dependability, the OT3122t130 supports seamless synchronization between complex digital components, ensuring system coherence and enhancing overall operational efficiency. This PLL's compatibility with TSMC's 130nm processes highlights its adaptability and versatility in meeting diverse industry standards. Its deployment in applications like telecommunications, computing, and consumer electronics underlines its significant role in facilitating high-performance hardware solutions. Developers can leverage its robust design for both prototype and mass-production circuits. In summary, the OT3122t130 stands as a testament to precision engineering, blending advanced PLL design with competitive performance properties, necessary for contemporary digital designs.
Aeonic Generate is a family of digital phase-locked loop (PLL) solutions designed for SoCs demanding high reliability. It provides area-efficient clock generation with unique features like fine-grained droop response and distributed clocking. Offering unparalleled observability, these solutions operate effectively from standard power supplies and are almost eight times smaller than traditional fractional PLLs. The process-portable design ensures easy adaptation across advanced technologies.
Sentire Radar is a sophisticated radar system offering intelligent solutions across different frequency bands for diverse applications. Known for its precision in range and speed measurement through advanced modules, the Sentire Radar system is essential for applications in perimeter surveillance, industrial measurements, and automotive systems. It features multi-channel antenna systems and high-frequency circuits for thorough radar signal processing, proving to be a comprehensive solution from design to implementation.
This high-speed interface product is designed to accommodate data rates up to 12.5Gbps, providing exceptional performance for connecting digital-to-analog converters, among other uses. It supports the JESD204B standard for serial data interconnect, ensuring reliable data transfer with features including deterministic latency support and comprehensive SYSREF functionality. The design incorporates independent transmitting and receiving blocks capable of handling complex data flows, such as 8b/10b encoding and scrambling. Engineered for versatility, the IP core allows for flexible data packet and lane width configurations. This adaptability makes it suitable for a wide range of applications in radio frequency (RF) communications and high-speed data acquisition systems. Furthermore, the product's support for various foundry process nodes, including 65nm, 55nm, 40nm, and 28nm, enhances its usability across different manufacturing environments. These technical specifications make it an essential component for developers seeking efficient interconnect solutions in advanced electronics and communications systems.
Cobalt is a cutting-edge ultra-low power GNSS receiver that broadens the capability of IoT System-on-Chip (SoC) by integrating GNSS functionality efficiently. Cobalt is designed to address the needs of mass-market applications that are primarily constrained by size and cost, targeting sectors such as logistics, agriculture, and mobility services. This receiver incorporates sophisticated embedded processing with cloud assistance to enhance power efficiency while maintaining sensitivity. It supports multiple constellations like Galileo, GPS, and Beidou, ensuring reliable and precise positioning. Developed in collaboration with CEVA DSP and backed by the European Space Agency, Cobalt is optimized for use with modern SoCs, facilitating the integration of GNSS without excessive resource consumption. Cobalt offers shared resources between GNSS and modem functions, reducing the footprint and cost of implementation. Its innovative software-defined receiver can operate as both a standalone and cloud-assisted solution, making it versatile and adaptable to a variety of market needs. This positions Cobalt as an ideal solution for IoT devices requiring dependable localization features without compromising on battery life.
The UltraLong FFT is a cutting-edge solution offered by Dillon Engineering, ideal for applications necessitating extensive data processing capabilities. The IP Core is optimized to cater to FPGA and ASIC platforms, achieving exceptional throughput by leveraging external memory resources. With a focus on overcoming limitations posed by memory bandwidth, this core seamlessly handles high-volume data processing tasks, ensuring smooth performance across varying environments. Dillon Engineering's UltraLong FFT Core integrates perfectly into systems demanding high-speed data transformations. It employs a combination of dual FFT engines, working in tandem to deliver frequencies at renowned speed levels. Particularly potent for handling intricate computations, this FFT implementation holds potential for a diverse range of applications, spanning from scientific analysis to real-time signal processing. Designed with flexibility in mind, the UltraLong FFT Core can be adapted to different architectural requirements. Its parameterization ability, using Dillon's ParaCore Architect™ tool, empowers designers with the customization options needed for specialized implementations. Combined with its practical approach to leveraging hardware resources, it forms a robust component in the cutting-edge digital processing toolkit.
Himax offers a comprehensive range of display driver ICs tailored for large-sized panels, including monitors, notebooks, and LCD TVs. These components are pivotal in driving high-resolution and vivid display outputs. With innovations that go beyond traditional applications, these drivers include timing controllers, source drivers, gate drivers, and programming gamma/Vcom operational buffers. The synchronization and precision of these units ensure that displays are not just functional but vibrant and user-friendly. Himax's display drivers are crafted to meet the needs of top panel manufacturers in Korea, Taiwan, China, and Japan, marking the company's strong foothold in the global market.<br> <br> The innovation underpinning these large-panel drivers also addresses critical power management and integration efficiencies, allowing for seamless incorporation into various digital ecosystems. As the demand for larger displays in both consumer and professional environments grows, Himax continues to push the boundaries, ensuring displays are not only clear but also energy-efficient and reliable.<br> <br> This commitment to quality and innovation underscores Himax's position as a leader in the display driver IC sector, providing solutions that enhance image clarity, reduce energy consumption, and support high-quality visual outputs for diverse applications.
The SMPTE 2059-2 solution by Korusys integrates accurately with video and audio signal alignment requirements using a precision PTP time source. This system is optimized for professional broadcast applications, offering high accuracy and low latency for aligning audio and visual content. The FPGA-based module comes complete with software-driven algorithms and timestamping capabilities, ensuring efficient deployment and integration. With a configurable and simple interface, the solution is tailored for seamless broadcast operations.
The CC-205 Wideband CMOS Rectifier from CurrentRF is designed for seamless antenna interfacing without the necessity of additional matching networks. It offers the flexibility of configuring both full-wave and half-wave rectification with novel efficiency. Distinguished by its minimal S11 return loss, quantified at -40 dB, this rectifier ensures that maximum power transfer is consistently maintained, making it ideal for applications demanding precise power management. CurrentRF's rectifier finds its prime applications in contexts where efficient RF power reception and conversion are critical. Useful in environments ranging from consumer electronics to specialized communication devices, it extends robust performance while maintaining optimal usability. Its simplistic interfacing with antenna systems fosters ease of integration into varied system architectures, ensuring rapid deployment and operational reliability. Designed as a highly versatile component, the CC-205 rectifier excels in mixed-signal and analog domains, offering reliability in signal processing and power conversion. Its low loss and high efficiency characteristics not only enhance system output but also contribute substantially to reducing operational costs by maximizing power gains and minimizing waste.
This Integer-N PLL-based HF Frequency Synthesizer and Clock Generator presents a robust solution for high-frequency signal generation. Its capacity to synthesize frequencies within the high-frequency range, specifically from 2.424 MHz to 9.697 MHz, by precise increments, ensures finely tuned output signals. This synthesizer supports flexible phase options, offering outputs in quadrature or non-shifted modes, which minimizes signal distortion and maximizes coherence. Silicon-proven within XFAB's XT018 technology, it can be adapted to other technological platforms as needed. This generator is ideal for applications demanding precise frequency control and stability, such as communications equipment and complex digital systems.
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