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.
CoreVCO represents CoreHW's commitment to delivering innovative wideband voltage-controlled oscillator (VCO) solutions, particularly suited for extremely demanding environments. Constructed utilizing robust SiGe technologies, the CoreVCO incorporates dual radiation-hardened VCOs, catering effectively to applications requiring minimal phase noise and resilient performance. The VCO operates over wide frequency ranges—0.7 GHz to 6.6 GHz—utilizing two distinct oscillator designs (VCOPMOS and VCOBJT). Its ability to maintain low phase noise under harsh conditions makes it ideal for critical applications like military communication systems and space exploration. The design's intrinsic radiation hardness ensures operational continuity where reliability is paramount. CoreHW's CoreVCO incorporates a host of integrated features such as bandgap references, low-dropout regulators, and SPI interfaces for precise control and tuning. With its small form factor, it serves as an efficient solution for a range of high-reliability wireless and communication systems, offering consistent performance across various operating conditions.
The pPLL03F-GF22FDX is a specialized all-digital PLL crafted for performance computing applications. Optimized for use in GlobalFoundries' 22FDX, it delivers low-jitter clocking, suitable for complex SoCs with multiple clock domains. This PLL can handle frequencies up to 4GHz, ensuring high performance for ADC/DAC systems with moderate SNR requirements. Designed with Perceptia's second-generation PLL technology, it offers a compact footprint and minimal power draw, catering to performance computing and critical timing needs. It features fractional multiplication, offering flexible frequency selection, and supports integration into SoCs through standard views and back-end models. The pPLL03F-GF22FDX includes two separately programmable PLL outputs and is equipped with a lock-detect function to enhance system reliability. This technology ensures consistent performance across various process nodes and offers customization and migration support to meet varied technological demands.
The LC-PLLs from Silicon Creations are characterized by their low jitter performance, making them suitable for demanding clocking tasks within integrated circuits. These PLLs integrate seamlessly into a variety of SoC architectures, providing ultra-low jitter thanks to their advanced design. Ideal for applications needing precision and stability, such as high-speed data transfer and timing critical operations, LC-PLLs feature a sophisticated design that supports both fractional-N and integer-N configurations. The focus on power efficiency and die area optimization makes them a valuable addition in environments where both performance and resource saving are crucial.
Silicon Creations provides a wide range of ring PLLs, offering robust clocking solutions for modern SoC environments. These PLLs deliver highly programmable frequency synthesis with considerations for power efficiency and minimal jitter. With flexibility in both fractional-N and integer-N configurations, they cater to diverse application needs ranging from system clocking to precision converter timing. Particularly notable is the capability to achieve excellent jitter performance with substantial power and area savings when compared to traditional designs. This makes Silicon Creations' ring PLLs a go-to choice for applications spanning battery-operated devices and high-performance computing systems.
Specially optimized for high-performance computing environments, the Ultra-Low Latency 10G Ethernet MAC IP delivers unparalleled speed and efficiency within FPGA designs. Crafted to accommodate high data throughput, this IP core excels in applications demanding high-speed data connectivity with stringent latency requirements. Harnessing cutting-edge technology, the Ethernet MAC design minimizes latency significantly, facilitating smooth and rapid data transmission across network layers. Its architecture supports high data throughput while maintaining efficiency within the FPGA, ensuring competitive performance in various network settings. Engineers can benefit from the Ultra-Low Latency 10G Ethernet MAC's versatile licensing, allowing for integration in diverse project specifications and budget parameters. By utilizing this IP core, systems not only achieve optimized speed but also enhance their reliability and responsiveness in handling data operations.
The 10G Ethernet MAC and PCS solution provides ultra-low latency Ethernet connectivity for FPGAs, specifically catering to applications requiring high-speed data transfer. Supporting throughput rates up to 10Gbps with minimal FPGA resource usage, this IP block is designed to integrate seamlessly with existing FPGA infrastructures, enhancing both performance and efficiency. The MAC/PCS integrates all necessary functionalities, reducing the need for additional components and ensuring a compact implementation. Chevin Technology's expertise allows for the offering of Ethernet IP solutions that are compliant with industry standards such as IEEE 802.3. The MAC/PCS leverages technologies that provide both ease of integration and scalability, which are pivotal for applications anticipating future growth or changes in data demands. In this way, the MAC/PCS maintains flexibility while ensuring reliable network communication. Focused on delivering quality performance, this MAC/PCS suit offers measures to minimize delay and jitter, crucial for applications where timing and reliability are paramount. It also includes advanced capabilities such as VLAN tagging and QoS support, enabling enhanced data traffic management and prioritization, which are vital in sophisticated network environments.
The OT3122t130 is a phase-locked loop (PLL) designed specifically for TSMC's 130nm process node. This device provides high-performance clock synthesis, crucial for synchronizing high-frequency digital circuits, especially in SoC and microprocessor applications. Its precision and adaptive clocking ensure improved jitter performance, which is vital for maintaining signal integrity across diverse operating conditions. Incorporating the latest in PLL design, this module manages to deliver a remarkably stable clock output while keeping power consumption to a minimum. Its architecture supports high-speed applications which demand stringent timing accuracy, thus facilitating enhanced performance in high-speed data transfer and processing tasks. This particular PLL is optimized for integration into a wide range of devices, thanks to its adaptable design that can be tuned to specific application needs. The module’s versatility is further highlighted by its ability to function efficiently under varying voltage conditions, making it a preferred choice for engineers and designers working on leading-edge technology solutions.
The RF/Analog offerings from Certus Semiconductor represent cutting-edge solutions designed to maximize the potential of wireless and high-frequency applications. Built upon decades of experience and extensive patent-backed technology, these products comprise individual RF components and full-chip transceivers that utilize sophisticated analog technology. Certus's solutions include silicon-proven RF IP and full-chip RF products that offer advanced low-power front-end capabilities for wireless devices. High-efficiency transceivers cover a range of standards like LTE and WiFi, alongside other modern communication protocols. The design focus extends to optimizing power management units (PMU), RF signal chains, and phase-locked loops (PLLs), providing a full-bodied solution that meets high-performance criteria while minimizing power requirements. With the ability to adapt to various process nodes, products in this category are constructed to offer definitive control over power output, noise figures, and gain. This adaptability ensures that they align seamlessly with diverse operational requirements, while cutting-edge developments in IoT and radar technologies exemplify Certus's commitment to innovation. Their RF/Analog IP line is a testament to their leadership in ultra-low power solutions for next-generation wireless applications.
Digital DPLL Units created by Granite SemiCom represent a sophisticated solution for precise frequency synthesis and distribution. These units integrate fractional-N division capabilities, accommodating a wide range of applications including clocks in SERDES structures and high-speed data transfer systems. Designed to minimize power consumption while ensuring accuracy, these DPLL units offer features like integrated feedback dividers and programmable input amplifiers. Operating within a wide frequency range under varied process conditions, they provide robust solutions for contemporary digital communication challenges.
SkyeChip’s High-Speed PLL excels in offering frequency synthesis for a wide range of applications. Capable of supporting reference clock frequencies from 100MHz to 350MHz, it incorporates a versatile FBDIV range, enhancing its division capabilities. The PLL can generate output frequencies ranging from 300MHz to 3.2GHz, marking its adaptability in high-speed data processing. It is designed to consume minimal power, making it an optimal choice in energy-constrained environments. This PLL ensures stability and precision across its frequency range, proving indispensable for modern high-speed digital designs.
The mmWave PLL by CoreHW is a sophisticated frequency synthesizer designed to meet the demands of modern wireless communication networks and radar systems. It features a high-accuracy fractional-N PLL frequency synthesizer with a very low noise voltage-controlled oscillator (VCO). This design supports efficient generation of low phase noise carriers and rapid chirp frequency modulations required for fast-frequency modulated continuous wave (FMCW) radar. Operating initially in the frequency range of 19.00-20.15 GHz, the mmWave PLL is engineered to extend to radar frequency bands from 38-40.5 GHz and even further to 76-81 GHz through frequency multipliers. Its scalable frequency configuration makes it suitable for diverse applications including 5G networks and various mmWave communication devices, providing flexibility for adaptation to specific needs. Key features include integrated bandgap references, low-dropout regulators (LDOs), and integrated frequency multipliers. The PLL supports fractionally precise chirp modulation capabilities, making it ideal for automotive radar applications like collision avoidance and distance measurement. The device is robust, maintaining optimal performance across a wide temperature range, and includes comprehensive built-in self-test and calibration features to facilitate reliable deployment in high-demand environments.
Analog Bits provides highly customizable and efficient clocking solutions, proven at advanced nodes such as 5nm and 3nm. Their clocking IP encompasses ultra-low jitter and low power fractional and integer PLLs, ideal for integration across a plethora of applications including automotive, server, and consumer electronics. Their clocking IP ensures seamless operation within SOCs, enhancing both performance reliability and power efficiency through specialized designs accessible in high-volume production at leading foundries.
Hermes 3D is crafted for the simulation of arbitrary 3D structures, offering unparalleled insights into electromagnetic performance across a variety of applications. Its core strength lies in providing high-precision FEM simulations that support the evaluation of complex geometrical designs typical in today's advanced electronic circuits. Hermes 3D empowers engineers with the capability to investigate and optimize diverse electromagnetic interactions within detailed 3D structures. This function is particularly essential when working with components that require precise behavior predictions under various operational conditions, ensuring that systems maintain their integrity and performance over time. By facilitating rigorous analysis, Hermes 3D aids in reducing costly design iterations and enhances efficiency in the product development cycle. Its application in arbitrary structural simulations makes it an essential tool for any designer seeking to ensure their systems are both innovative and reliable.
The pPLL02F Family is engineered for general-purpose applications, delivering all-digital Fractional-N PLL capabilities. Ideal for moderate-speed digital systems and microprocessors, this family supports frequencies up to 2GHz. Its architecture ensures low-jitter performance (<18ps RMS), minimal power consumption (<3.5mW), and a compact footprint (<0.01 sq mm), making it suitable for diverse clocking demands. The second-generation digital PLL architecture offers integer and fractional multiplication, enabling an output frequency up to 400 times the input reference. It provides two additional PLL outputs through programmable post-scalers. Engineered for high testability, the pPLL02F Family includes ATPG vectors and supports industry-standard flows for seamless integration into SoC designs. This PLL is available across various foundries, including GlobalFoundries, Samsung, TSMC, and UMC. The versatile PLL is designed to deliver consistent performance across different processes, making it a robust choice for systems requiring integrated power supply regulation and multi-domain clock systems.
The Digital PreDistortion (DPD) Solution by Systems4Silicon is crafted to elevate the power efficiency of RF amplifiers. This adaptive technology thrives on various platforms, being vendor-independent and offering scalability for FPGAs and ASICs. The solution can handle bandwidths over 1 GHz and supports a plethora of communication standards, including 5G, enabling operations with multi-carrier and multi-standard single-antenna transmissions. Operating efficiently across different transistor technologies, the DPD advances amplifier performance by compensating for memory effects and facilitating operation in non-linear regions, achieving efficiency improvements above 50% under certain configurations.
Specialized in RF applications, the pPLL08 Family supports advanced technologies such as 5G and WiFi. These all-digital RF frequency synthesizer PLLs are precise, delivering sub-300fs jitter performance, crucial for RF and high-speed data applications. The family is versatile, supporting frequency operations up to 8GHz through fractional-N PLL architecture, aiding in standard compliance across multiple wireless platforms. The small form factor and low power requirement make it optimal for use in loaded RF environments through easy integration. The pPLL08 Family leverages Perceptia's second-gen technological advancements, making it adaptable across different foundries and nodes. Its superior architecture guarantees minimal interference and supports challenging SNDR standards, rendering it ideal for SoC designs demanding high fidelity and speed.
The FCM1401 is part of Falcomm's innovative Dual-Drive™ series, designed to offer exceptional efficiency in power amplification. This model, operating at a center frequency of 14.5 GHz, harnesses advanced dual-drive technology to achieve milestones in power efficiency, outperforming traditional power amplifier solutions. With a meticulous design focusing on minimal silicon area usage and high efficiency, it presents a compelling option for enhancing battery life and reducing energy consumption in wireless communications. Falcomm's FCM1401 achieves impressive benchmarks, such as world-class efficiencies validated in commercial CMOS SOI platforms. The power amplifier is notable for its substantial reduction in silicon area, evidenced by the significant power-added efficiency (PAE) results of 34% using a 64QAM signal, averaged at 14.1dBm while maintaining a drain efficiency of 70% at device output. Such enhancements are crucial for applications requiring sustained high efficiency without the downside of increased power draw. This power amplifier caters to high-demand sectors like space communications and modern telecommunications where efficient power use is vital. Operating without efficiency degradation at supply voltages ranging from 1.6V to 2.0V, it offers substantial improvements in signal strength while reducing the operational costs for network operators.
The Bandgap Reference Block provided by VivEng is a crucial component in many analog and digital circuits, known for its stability and precision. This block generates a stable voltage reference, which is vital for the consistent operation of other circuit elements such as ADCs and DACs. The block is equipped with features like trimmable reference voltage, bias currents, and alerts for over and under temperature conditions. Additionally, it includes a power-on reset feature, ensuring that it operates reliably under various environmental conditions and power supply fluctuations.
Aeonic Generate focuses on efficient clock generation for systems-on-chip (SoCs), offering synthesizable solutions with robust observability and programmable features. It enables fine-grained droop and DVFS response through distributed clocking strategies. The product line is process portable, ensuring functionality across different nodes, and delivers substantial area efficiency compared to analog PLLs, maintaining performance even under varying silicon conditions.
Certus Semiconductor's Analog I/O solutions focus on delivering ultra-low capacitance and extreme ESD protection, making them ideal for sophisticated applications that demand high reliability. These solutions are adept for high-speed SerDes and RF communications thanks to their ability to manage impedance matching and maintain strong signal integrity. The analog libraries include comprehensive solutions that accommodate ESD and power clamps within macro cells, optimizing performance while minimizing impact on overall chip design. Advanced tolerance levels for signal swings including those below ground are supported, ensuring robust performance in a variety of operational conditions. Specialized macro cells cater to frequency ranges above 30 GHz and data rates surpassing 112 Gbps, demonstrating their capability to handle demanding technical requirements. Certus's expertise in analog design translates into solutions adept at withstanding levels of stress far beyond industry standard HBM and CDM requirements. This resilience, coupled with high-temperature tolerance and radiation-hardening, provides a safety net against diverse environmental challenges.
The C3-PLL-2 offers a distinctive solution in clock generation with its adept design and implementation. Utilizing DIGICC technology, this phase-locked loop caters to telecommunication interfaces where reliable timing is crucial. The core's fully digital methodology replaces traditional analog blocks, resulting in a flexible and cost-effective solution. This PLL can seamlessly integrate into a variety of systems needing precise clock management.
The JPEG2000 Video Compression Solution by StreamDSP is crafted to provide flexible, high-grade compression and decompression capabilities for video and still images. This solution stands out due to its capability to perform both lossy and lossless compression within a single codestream, making it ideal for applications that require a balance between quality and compression efficiency. Optimized for FPGA implementations, this solution circumvents the need for external processing units, streamlining integration complexities. JPEG2000's robustness caters to diverse fields such as medical imaging, digital cinema, and remote sensing, where clarity and precision are paramount. The architecture's flexibility allows it to be molded to specific project demands, ensuring that each application from digital photography to scientific imaging benefits from superior image integrity and compression ratios.
Paired for low power and low voltage applications, the pPLL05 Family excels in embedding clocks for IoT and digital systems. Operating efficiently below standard core voltages, this family offers fractional-N PLL capability for systems running at frequencies up to 1GHz, revolutionizing power efficiency in design. Utilizing the second-generation all-digital PLL architecture, the pPLL05 Family sustains a compact size and maintains excellent functional performance across processes. It offers fine-grained control over input/output frequencies, facilitating ease in porting across different technologies and foundries. Aimed at enhancing integration in digital environments, the pPLL05 features high testability and offers several deliverables including detailed behavioral models and integration guides. This design guarantees consistent results and supports high precision with use across multiple nodes and foundries.
CorePLL is a dual PLL frequency synthesizer developed by CoreHW, optimized for performance in compact and low-power systems. The synthesizer integrates two wideband PLLs, making it a highly flexible solution for a variety of wireless applications. With an ultra-low power consumption of 24mW, CorePLL efficiently handles frequency synthesis from sub-GHz to multi-GHz ranges. This synthesizer is equipped with integrated voltage-controlled oscillators (VCO) and loop filters, supporting frequency synthesis for LTE and GSM applications, among others. The high level of integration and the inclusion of fast settling features enhance its suitability for modern communication systems that require swift frequency changes and reliable signal stability. The CorePLL maintains superior performance with minimal energy usage, supporting numerous wireless standards, including GSM, WCDMA, and LTE, up to the most recent iterations. It provides robust and low-jitter signal generation, alongside comprehensive calibration and lock detection features, accommodating a wide array of digital communication infrastructures.
The Analog-PLL provided by M31 Technology serves as a versatile frequency synthesizer suitable for a broad spectrum of application needs. With input frequencies ranging from 10 MHz to 240 MHz, it accommodates a wide 3:1 output frequency range. The core works on I/O supply voltage, granting significant supply noise rejection in noisy SoC environments. This PLL is programmable in integer mode and performs with low jitter, optimizing efficiency for advanced frequency tasks.
The hellaPHY Positioning Solution is renowned for its exceptional capabilities in cellular positioning, particularly within massive IoT environments. It leverages the strength of 5G networks to provide scalable, low-cost, positioning services with high precision. PHY Wireless has engineered it to require significantly less data than other solutions, thanks to its unique algorithmic approaches. This reduces network interactions and enhances spectral efficiency, making it an enticing option for operators and developers alike. One of the key components of this solution is its ability to function indoors and outdoors with near GNSS accuracy. By employing edge computing, the position calculations are done locally on devices, protecting user privacy and maintaining tight security on location data. The software’s minimal footprint allows for integration into existing infrastructure, offering backward compatibility and ensuring future readiness. hellaPHY stands out in the realm of positioning technology by achieving unparalleled accuracy, thanks to its efficient data utilization. It supports efficient location tracking in challenging environments, such as urban areas, where traditional GPS might falter. Furthermore, the technology offers the flexibility of over-the-air updates, keeping network utility optimal and guardband costs low through advanced spectral efficiency.
The MIPI D-PHY Analog Transceiver is a crucial component for applications requiring efficient data communication between processors and displays or cameras. This transceiver IP core supports multiple MIPI standards, integrating easily with MIPI CSI-2 and DSI specifications to deliver superior data transmission capabilities. This IP is characterized by its robust analog front-end, which handles electrical signal generation and reception, providing seamless control over I/O activities. The D-PHY transceiver boasts low power operation, essential for consumer electronics such as smartphones and tablets that demand both high performance and energy efficiency. Widely utilized in the industry, the IP supports configurations as a transmitter, receiver, or transceiver, ensuring flexible adoption for varied applications. Its adaptability across different product designs allows it to quickly integrate into systems, propelling fast development cycles and enhancing market competitiveness.
The SMS Fully Integrated Gigabit Ethernet & Fibre Channel Transceiver Core is a state-of-the-art solution embedded with advanced high-speed serial front-end features. This transceiver includes essential components such as high-speed drivers, robust clock recovery DLLs, and PLL architectures. An integrated Serializer/Deserializer (SERDES) unit and sophisticated data alignment capabilities ensure high-performance data transmission. A distinctive low jitter PECL and comma detect function enhance data integrity, making it a reliable choice for high-bandwidth data communications applications. Engineered for compliance with the IEEE 802.3z Gigabit Ethernet standards, this transceiver core supports full-duplex operations and employs a 10-bit controller interface for both receive and transmit data paths. The inclusion of programmable receive cable equalization diminishes the need for external components, thus streamlining the integration process into System-On-Chip (SOC) designs. The design prioritizes cost, power efficiency, and performs well over a diverse range of operating environments.
The eSi-Analog IP by EnSilica features an extensive portfolio of analog IP blocks optimized for integration into custom ASIC and SoC solutions. These IPs cover a diverse range of functionalities essential for high-performance analog circuit design, contributing significantly to a system's overall capability.\n\nFocusing on high-resolution performance and low power usage, these analog IP blocks enable efficient integration across multiple process nodes. Notably, EnSilica's selection includes oscillators, power management modules such as SMPS and LDOs, and various sensor interfaces, which are silicon proven in leading foundry processes to meet specific application requirements.\n\nThe adaptability of these IPs ensures that they can be customized to meet precise specifications, facilitating seamless SoC integration. This flexibility not only reduces time-to-market but also enhances design efficiency, making them suitable for a wide array of applications including wireless communication, medical devices, and consumer electronics.
Moonstone, an offering from Lightelligence, is a highly versatile laser source available in both single and multi-wavelength configurations. Unlike conventional laser packages, Moonstone features a compact design and enhanced temperature management, making it a cost-effective and modular solution for diverse applications including telecommunications, LiDAR, and sensor technologies. The product leverages an automated optical packaging process that integrates off-the-shelf laser chips with the Moonstone carrier through advanced techniques like eutectic soldering and die-bonding. The ensuing laser assembly enables a free-space coupling method for single wavelength use, and a multiplexing approach for multi-wavelength scenarios, optimizing optical signal combination and transmission efficiencies. Moonstone's precision engineering and thermal regulation provide low coupling losses and high output power, suitable for demanding environments where high-speed and high-bandwidth data transmission are crucial. It serves a vital role in optical computing, offering substantial power delivery while maintaining a low phase noise footprint, thus bolstering AI computational capacities significantly.
The Band-Gap Reference offers precise voltage references ranging from 0.6V to 1.2V, critical for stable system performance. It features an operating current of 25uA and maintains high accuracy between 1% to 3% across its operating range of 2.2V to 5.5V, making it suitable for a variety of analog circuits. This versatile reference is engineered for integration into applications requiring stable voltage signals despite temperature variations, such as in sensor interfacing and analog data processing. Its design ensures minimal drift and robust performance across variable environmental conditions. Manufactured utilizing Magna, Samsung, and TSMC's process nodes down to 65nm, this band-gap reference is silicon-proven to offer reliability and high precision for critical electronics where voltage stability is pivotal.
The Digital-PLL from M31 Technology is engineered for precision in frequency synthesis, offering flexibility across multiple operation modes including standalone oscillator functionality. Ideal for integration into ASIC/SoC designs, its core-power-observant design features robust immunity to power supply noise, critical for operational stability. This digital PLL supports low jitter operation due to fractional-N architecture, making it suitable for noisy ASIC applications.
Operating at 28 GHz, the FCM2801-BD is another flagship model within Falcomm's Dual-Drive™ lineup, exemplifying the company's leadership in power amplifier technology. This two-stage amplifier features unmatched efficiency and performance metrics, setting new standards in the industry for wireless communications. Suitable for both commercial and cutting-edge applications, it stands as a testament to Falcomm's innovative spirit and technical prowess. The FCM2801-BD is constructed to deliver record-setting power-added efficiency and drain efficiency, validated within a robust CMOS SOI framework. The dual-drive core achieves up to 62% drain efficiency at device output levels, cementing its capability to handle high-data throughput scenarios while conserving energy. Such impressive efficiencies directly contribute to lowering battery consumption and enhancing the operational lifespan of connected devices. Moreover, this PA is a strategic choice in telecommunications and space communications fields, where power efficiency and signal quality are paramount. Its versatile design supports operations over the required frequency band without efficiency losses, emphasizing adaptability in various network environments. By incorporating this PA, service providers and satellite operators can advance their operational goals with reduced power expenditure, aligning with sustainable energy practices.
Laser Triangulation Sensors are fundamental in non-contact measuring applications, particularly when exacting precision in position and dimension checks is essential. Designed to provide a reliable solution, these sensors utilize advanced laser technology to deliver accurate measurements over a broad range. The devices are capable of measuring distances and displacements efficiently, making them invaluable in industries where precision is non-negotiable. These sensors are constructed to function seamlessly in dynamic environments, providing measurements with a minimal margin of error. The sensors employ a unique mechanism utilizing both blue and IR lasers, which aids in capturing precise data from target surfaces. They offer capabilities to measure across ranges from as little as 2mm to expansive stretches up to 2.5m, all while maintaining a measurement error margin of ±1 μm. Such accuracy is complemented by a high sampling frequency of up to 160 kHz, ensuring rapid data acquisition in varying industrial conditions. Laser Triangulation Sensors come equipped with robust features that allow them to address complex measurement challenges. Whether it's monitoring surface contours or inspecting objects in motion, these sensors adapt readily, ensuring comprehensive data for operators. Their versatility is evident as they can be applied to countless applications, maximizing efficiency across industrial operations.
The FCM3801-BD further expands Falcomm's Dual-Drive™ series, addressing the high-frequency demands of 38 GHz applications. This power amplifier is meticulously engineered to optimize energy efficiency without compromising on power output, making it an ideal choice for modern, power-constrained environments. As a testament to Falcomm's innovative strides, it blends cutting-edge technology with practicality, meeting diverse needs across various sectors. Engineered within a CMOS SOI platform, the FCM3801-BD achieves a balance between power conservation and performance. It embodies the apex of power amplifier design, showcasing drain efficiencies up to 70% at device output. Such performance metrics offer sizable reductions in operational costs, enhancing the environmental sustainability of wireless communication networks. Furthermore, the core design benefits from minimized silicon area footprint, further enhancing its appeal in compact device architectures. Targeting crucial industry areas like space and telecommunications, the FCM3801-BD provides the needed functionality to extend signal reach significantly while boosting power savings. It operates efficiently across varied voltage ranges without sacrificing its adept energy performance. These characteristics highlight its exceptional capabilities for stakeholders prioritizing efficiency, reliability, and technological advancement in their service delivery models.
The CP-70-90-B-U is a highly efficient charge pump circuit designed to convert a 1.8V input to a 3.3V output. Boasting a load current capability of up to 70mA, it incorporates a bypass switch for enhanced versatility. Based on a 0.09 μm technology from UMC, this charge pump offers a balanced combination of power efficiency and performance, making it ideal for applications requiring stable voltage regulation in compact form factors. Designed with reliability in mind, the CP-70-90-B-U charge pump is expected to perform exceptionally in variable operational environments. Its sophisticated design minimizes energy loss, offering a superior solution for power conversion in modern electronic devices. The device is particularly suited for portable electronics where space efficiency and energy conservation are critical. The innovative design ensures thermal stability while maintaining low power dissipation, positioning it as a preferred choice in energy-sensitive applications.
The SMPTE 2059-2 Synchronization Solution from Korusys integrates sophisticated FPGA logic to align video and audio signals precisely using a reference PTP time source. Designed with the professional broadcast industry in mind, this solution uses the IEEE1588v2 protocol to provide low-latency synchronization essential for modern AV systems. The integration is further simplified by an intuitive management interface that allows users to configure and manage the system with ease. Featuring software-driven algorithms and precise FPGA timestamping, the product ensures accurate video and audio alignment across IP networks. Engineers can deploy this technology seamlessly, benefiting from its flexibility and customization options to meet specific broadcast requirements. By adopting a modular approach, this solution becomes not only effective but also highly adaptable for a range of applications. Deployed in professional settings, the SMPTE 2059-2 Synchronization Solution facilitates the handling of AV content with high accuracy, making it invaluable in environments where precise timing of media content is critical. Whether for live broadcasts or other broadcast media, this powerful tool optimizes synchronization every step of the way.
The RF-SOI and RF-CMOS platform developed by Tower Semiconductor is a critical solution for wireless communication applications, providing the necessary framework for the development of high-performance, low-power RF components. This platform is tailored to meet the complex demands of modern wireless technologies, facilitating enhanced signal processing and transmission efficiency. Using SOI (Silicon on Insulator) and CMOS processes, this technology enables the creation of RF components that are not only reliable but also feature reduced parasitic capacitance, leading to higher speed and lower power dissipation. It is particularly suited for mobile devices, Internet of Things (IoT) applications, and telecommunications infrastructure, where performance and battery longevity are key considerations. The platform is adaptable to different frequency bands, providing support for both standard and customized RF circuit designs. By enabling excellent isolation and linearity, Tower Semiconductor’s RF platform ensures that devices can operate with superior signal integrity in diverse environments. Overall, the RF-SOI and RF-CMOS platform provides a robust environment for innovation in wireless communication, supporting the continuous evolution of mobile technologies by enabling the integration of sophisticated RF features with scalable production methodologies.
The General Use PLL is a comprehensive phase-locked loop solution designed for a broad range of applications. It offers an integer-N configuration suitable for any division between 1 and 32 or 1 and 64 at lower frequencies. Key features include low noise, minimal spurs, and auto-calibration, alongside a fast lock feature that ensures rapid response and stability. This PLL is engineered for general use, supporting input and feedback at low noise levels, which enhances its applicability in noise-sensitive environments. It effectively covers frequency ranges from 0.5 GHz to 4.0 GHz, making it ideal for communication systems and other frequency-modulated applications. The PLL's design supports adaptability and reliability, crucial for maintaining consistent performance across diverse operating conditions. Compatible with TSMC 28HPC and 16FSC processes, its power efficiency is underscored by a low power consumption of just 4 mA at 400 MHz. The estimated availability for this product is December 2024, aligning with industry timelines for new technology rollouts, making it a forward-thinking choice for developers.
The CC-205 Wideband CMOS Rectifier offers high-efficiency full-wave rectification across a broad frequency spectrum, ranging from 6 MHz to 5.8 GHz. Ideal for interfacing directly with antennas without the need for a matching network, it maintains conversion efficiencies between 40% and 90%. The rectifier handles input powers significantly, making it a versatile component in RF systems where power efficiency is paramount.
The PLL for Satellite Receiver is dedicated to enhancing the fidelity and stability of frequency synthesis in satellite receivers. Operating at a high frequency of 15 GHz, this PLL component is crucial for maintaining the signal integrity required for satellite communications. It is engineered to handle the high demands of frequency stability and precision needed in today's advanced satellite systems, which are pivotal for effective data transfer and communication.
Tower Semiconductor's SiGe BiCMOS technology caters to the heightened requirements of RF applications. This technology is a cornerstone for developing high-frequency circuits and systems, boasting impressive RF performances and providing enhanced versatility and integration possibilities. The SiGe BiCMOS process is ideally suited for wireless communication infrastructure, enabling the creation of robust and efficient RF solutions while minimizing power consumption and maximizing signal integrity. Developed with advanced capabilities, this technology harnesses the potential of Silicon-Germanium (SiGe) to significantly amplify speed and functionality, accommodating the demands of sophisticated wireless systems. It supports an extensive variety of RF applications, ranging from mobile communication devices to radar systems, proving critical in enabling connectivity in the modern digital age. Furthermore, the flexibility of this technology empowers designers to achieve optimized results for a spectrum of frequency bands and power levels. Through strategic enhancements in its semiconductor compositions, Tower Semiconductor has created a process that decisively influences performance improvements and bandwidth efficiency. Integrating SiGe BiCMOS technology into design processes ultimately yields platforms that are not only nimble and highly capable but also cost-effective, allowing enterprises to harness innovative circuits without escalating production expenses.
This Analog Front End (AFE) supports the EPC Gen 2 UHF standard, providing the necessary interface for analog signal processing in RFID systems. The AFE manages essential tasks such as modulation and demodulation, signal amplification, and data conversion, ensuring seamless interaction with the digital protocol engine. Its ability to maintain signal integrity and quality across varying conditions makes it a critical component in the reliable operation of RFID technologies.
High-performance PLLs and DLLs from Pico Semiconductor are engineered to meet the needs of applications requiring precise timing and clock management. These products include low noise and low spur PLLs suitable for various frequencies. The PLLs are designed to operate at significant performance frequencies like 3.25GHz and 5GHz on 40nm TSMC technology, with variations available on other nodes like 90nm UMC.\n\nThese timing solutions are pivotal in ensuring signal integrity and synchronization across digital systems. The various PLL models address the needs of both standard and custom clocking applications with adjustable frequency ranges and robust noise minimization features.\n\nOpting for Pico’s PLLs and DLLs grants designers the flexibility to integrate precise and stable timing solutions within their systems, supporting a wide range of consumer electronics, communications, and other high-tech industries where timing precision is critical.
The Low Jitter Digital PLL from Terminus Circuits offers a versatile frequency synthesizer solution, capable of generating outputs at 1.25G, 2.5G, and 5G, meeting the demands of applications like USB 3.0/3.1 and WiFi transceivers. This synthesizer is recognized for its low jitter and quadrature outputs, ensuring reliable performance for high-speed digital communication. Its architecture includes Type II, 3rd order PLL design, features auto-calibration mechanisms that adjust for variations in temperature and processing conditions, and allows frequency settings via CSR registers. The system is engineered for minimal silicon usage, making it ideal for compact device integrations where space and power efficiency are critical. Deliverables include detailed GDS II layouts, integration notes, LEF abstracts, and Verilog models, equipping developers with comprehensive resources for implementing high-speed clock solutions in their designs. With an operating temperature range of -40 to 125 degrees Celsius, this PLL supports robust operation in both consumer and industrial environments.
Advinno's PLL is a phase-locked loop circuit designed for applications requiring frequency synthesis and synchronization. This robust component is integral in achieving precise timing control across digital signal processing units, ensuring stability and reliability in operations. The PLL's capabilities extend to fine-tuning frequencies for various electronic systems, making it an indispensable asset in diverse applications ranging from telecommunications to consumer electronics. Key features of the PLL include its adaptability across different process nodes and foundries, allowing for higher integration in tailored semiconductor solutions. Its architecture is optimized for low jitter and fast lock times, securing high performance even in intense operational environments. This product exemplifies Advinno’s commitment to delivering high-precision and quality-driven components. The PLL is recognized for its energy efficiency, maintaining optimal functionality while minimizing power consumption, a crucial factor for modern electronic devices. Additionally, its design incorporates advanced modulation techniques to support complex signal processing tasks. Advinno's PLL offers a scalable solution that evolves with technological advancements, ensuring future-ready integration in sophisticated electronics systems.
The RF Front-End for Satellite Reception Beam-Forming is designed for applications in satellite reception. This phased array system operates in the Ku band, ranging from 11 to 13 GHz. It facilitates advanced signal processing for satellite communication, focusing on enhancing reception quality and efficiency through precise beam-forming techniques. This technology is vital for improving the clarity and reliability of satellite data transfer, making it an essential asset in satellite communication infrastructures.
The CC-100IP RF is designed to address RF emissions within integrated circuits, enhancing on-chip cybersecurity while drastically reducing dynamic currents. This IP block reduces emissions by creating low impedance pathways in power grids, benefiting systems with a six-fold increase in reservoir capacitance efficiency. Its innovative design mitigates digital noise, acting as a critical technological advancement in chip design.
The Cobalt GNSS receiver by Ubiscale is an ultra-low-power IP core designed to expand the IoT System-on-Chip (SoC) market scope by integrating GNSS functionalities. This receiver is specifically crafted to meet the stringent power and size constraints of modern IoT applications, ensuring efficient geolocation processes. Engineered to optimize power consumption through advanced embedded processing and cloud collaboration, Cobalt ensures the lowest possible energy use while maintaining high-performance standards. It delivers an easy GNSS integration option into NB-IoT SoCs, offering a cost-effective solution through shared resources between the GNSS system and the modem. Designed for mass-market applications such as logistics, agriculture, and goods protection, Cobalt operates across multiple satellite constellations including Galileo, GPS, and Beidou. It supports both standalone and cloud-assisted positioning which enhances GNSS operation efficiency and system integration flexibility. The solution is bolstered by collaboration with key players like CEVA DSP and backing from the European Space Program Agency. Cobalt's software-defined receiver provides robust sensitivity with minimal processing and memory needs, making it ideal for integration in modern IoT devices. This highly efficient design is perfect for size and cost-constrained applications, providing durable and precise tracking and positioning solutions that target a variety of industries.
The iniADPLL from Inicore is a state-of-the-art all-digital phase-locked loop core, engineered for precise clock management in complex electronic systems. It delivers remarkable frequency synthesis capabilities, ensuring stable and reliable signal synchronization across diverse applications. The iniADPLL's digital nature facilitates seamless integration into both ASIC and FPGA environments, offering a high degree of customization for developers. It supports a wide range of frequencies, serving various sectors such as telecommunications, networking, and consumer electronics with unparalleled accuracy. Its design allows for low jitter and minimal phase noise, crucial for maintaining signal integrity in high-precision operations. This ADPLL module is especially useful for projects demanding exact frequency control and synchronization, thereby standing out as a vital component in advanced signal processing applications.