All IPs > Analog & Mixed Signal > Amplifier
In the realm of analog and mixed signal applications, amplifier semiconductor IPs are crucial components that play a fundamental role. They are designed to amplify or boost the power, voltage, or current of a signal, ensuring that electronic devices perform efficiently and reliably. At Silicon Hub, our selection of amplifier semiconductor IPs caters to a variety of needs, from simple low-power audio amplifiers to complex RF power amplifiers used in wireless communication systems.
Amplifiers are a key part of many electronic products, including audio equipment, telecommunications infrastructure, and medical devices. For instance, in the audio sector, amplifiers enhance sound quality by increasing the amplitude of signals, thereby enabling concert-level sound in consumer devices. Similarly, in the telecom industry, RF amplifiers are vital for extending the range and clarity of wireless transmissions.
Our catalog at Silicon Hub includes a wide range of amplifier IPs tailored for different specifications and applications. These IPs are designed to meet stringent requirements for linearity, efficiency, and noise performance. Whether designing consumer electronics or sophisticated industrial systems, our amplifier solutions ensure optimal performance and scalability.
Choosing the right amplifier semiconductor IP can dramatically affect the overall performance of an electronic system. As the demand for more efficient and powerful electronic devices continues to grow, our amplifier IPs provide the necessary advancements to meet evolving technological challenges. Explore our broad selection to find the perfect match for your project requirements, and leverage Silicon Hub's expertise in delivering cutting-edge semiconductor solutions.
The KL730 AI SoC is powered by Kneron's innovative third-generation reconfigurable NPU architecture, delivering up to 8 TOPS of computing power. This architecture offers enhanced efficiency for the latest CNNnetwork architectures and serves transformer applications by reducing DDR bandwidth requirements significantly. The chip excels in video processing, supporting 4K 60FPS output and excelling in areas such as noise reduction and low-light imaging. It's ideal for applications in intelligent security, autonomous driving, and video conferencing, among others.
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 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 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.
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 THOR platform consists of silicon proven IP blocks that enable the development of a full NFC sensor and datalogging ASIC which can be customized to suit a wide range of monitoring and continuous data logging applications. It provides a flexible, low risk, and faster time to market solution for NFC sensing and data logging. The platform supports multi-protocol NFC operations and can be paired with external sensors such as pressure, humidity, motion, and luminance. It also features energy harvesting options, secure data logging with advanced encryption standards, and up to 24KB of memory, making it ideal for industrial and medical markets.
The GNSS VHDL Library from GNSS Sensor Ltd is designed to streamline satellite navigation system integration into FPGA platforms. This versatile library includes numerous modules such as configurable GNSS engines and fast search engines catering to GPS, GLONASS, and Galileo systems. Complementing these are special components like a Viterbi decoder and RF front-end control, ensuring comprehensive system integration support. Engineered to achieve maximum independence from CPU platforms, the GNSS VHDL Library is built upon a simple configuration file to deliver flexibility and ease of use. Users benefit from pre-built FPGA images compatible with both 32-bit SPARC-V8 and 64-bit RISC-V architectures. The library enables GNSS operations as a co-processor with SPI interface, supporting diverse external bus interfaces without requiring changes in the core library structure. The GNSS VHDL Library incorporates Simplified Core Bus (SCB) for interfacing, enabling interactions through a system-defined bridge module. This provides flexibility in design and ensures efficient data processing and integration with existing systems, simplifying the development process for both new and existing FPGA platforms. Whether enhancing current designs or developing new navigation solutions, this library equips developers with the tools needed for effective GPS, GLONASS, and Galileo integration.
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.
IRIS is a robust solution for RF and analog IC electromagnetic simulations, crucial for addressing parasitic effects at high frequencies. Integrated with Cadence Virtuoso, IRIS ensures designers can execute precise electromagnetic field simulations within their design environment. It employs advanced 3D planar EM solvers based on the method of moments (MoM) to accurately model materials' skin and proximity effects. Additionally, IRIS facilitates design cycle reduction through parallel processing capabilities and unparalleled integration of front-end and back-end design environments, optimizing both synthesis and verification processes for RF circuits.
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.
The low noise amplifier IPs from Analog Circuit Works target the theoretical limits of noise and power efficiency, positioning themselves as leaders in analog amplification technology. These amplifiers are designed to enhance signal strength while minimizing noise, ensuring clarity and high performance in signal transmission and reception applications. With proven efficacy across various processes and applications, these amplifiers have a wide scope of usage, particularly in systems that demand precision and heightened sensitivity. The focus on minimizing noise while maximizing gain ensures that systems can perform optimally, even in challenging electromagnetic environments. Analog Circuit Works ensures that these amplifiers are tailored to meet customer-specific needs, providing customization options that align with particular operational and environmental requirements. This adaptability enables clients to integrate high-performance amplifiers seamlessly into their systems, improving overall signal integrity and system reliability.
The 1D Optical Micrometers from RIFTEK are high-precision instruments aimed at measuring diameters, gaps, and displacements, with an operating range from 5 mm to 100 mm and a measuring error of ±0.3 µm. These micrometers are engineered to perform fast measurements at a rate of 10000 Hz, ensuring swift and accurate data acquisition, which is vital in automated production lines and quality control processes that demand uncompromised precision and speed.
The ADQ35-PDRX is engineered for pulse data systems, offering a high level of performance with a 12-bit resolution and 5 GSPS sampling rate. It features an extended dynamic range through a built-in dual-gain channel combination, effectively enhancing performance to match that of a 16-bit digitizer. The device is equipped with a DC-coupled input that supports up to 2 GHz bandwidth, and a programmable DC-offset to optimize positive or negative pulse detection.
The Telecommunication ADC is designed for asynchronous operations within telecommunication applications, providing efficient data conversion capabilities that are crucial in robust communication systems. With an 8-bit resolution, this ADC ensures accurate signal conversion, maintaining the integrity of telecommunication data streams. Fabricated using the TSMC 28HPC process, this component is engineered to support data throughput at speeds reaching 1.2 Gbps, ensuring rapid data processing capabilities ideal for high-bandwidth applications. It embodies a design that emphasizes both performance and precision, critical for maintaining the fidelity of transmitted data. This ADC distinguishes itself with its capability to handle asynchronous data, making it suitable for a varied range of telecommunication contexts. It's designed to cater to the advanced needs of modern digital communication systems, ensuring compatibility with various industry standards and enhancing overall system performance.
Enosemi's analog and mixed-signal devices are designed to handle both low and high-speed electrical signals, making them integral to the implementation and operation of advanced photonic circuits. These devices play a crucial role in ensuring signal integrity and seamless integration between various components within a circuit, facilitating high-fidelity data processing and transmission. The product range includes various amplifiers, filters, and converters, each meticulously crafted to enhance performance while minimizing power consumption and signal distortion. By leveraging these devices, engineers can achieve precise control over electrical signals, enabling the efficient operation of complex photonic systems. These devices are particularly well-suited for high-performance applications where accuracy and speed are paramount. By providing reliable and versatile solutions, Enosemi ensures that its products meet the highest standards required for next-generation photonic applications, aiding clients in achieving superior performance and reliability in their designs.
SiliconIntervention's Fractal-DTM Amplifier represents a cutting-edge architectural solution designed to enhance the efficiency of Class-D drivers across a spectrum of power levels. This innovative amplifier boasts a self-determining capability, allowing it to optimize efficiency dynamically throughout its operational range. The approach taken by SiliconIntervention involves a deep integration of architectural planning to address real-world challenges faced by Class-D amplifiers, achieved through groundbreaking analog signal processing methods. The Fractal-DTM Amplifier uniquely positions itself by utilizing sophisticated techniques that allow it to adapt its operational modes, ensuring superior performance at any given power setting. This adaptability is a testament to SiliconIntervention's commitment to leveraging the "New Analog" approach, propelling analog signal processing into territories traditionally dominated by digital counterparts. Through this product, SiliconIntervention not only highlights the potential of analog-based solutions in modern electronics but also sets a precedent for future developments in the field, where power efficiency and adaptability are increasingly critical.
The BG-1V2-U is a meticulously crafted ultra-low power Bandgap Reference Circuit that delivers consistent and precise voltage reference. It is designed to provide a stable 1.2V reference voltage, making it highly suitable for applications where power efficiency and reliability are critical. Manufactured using UMC's advanced 0.13 µm technology, it fits perfectly into modern electronic systems demanding precision and stability. This reference circuit exhibits impressive power-saving features, characterized by its zero power supply current, to support extended battery life in portable electronics. Its compact design ensures minimal space requirements, yet it does not compromise on performance, thanks to its sophisticated layout that minimizes thermal errors and offsets. Ideal for integration in a wide array of circuits, the BG-1V2-U's performance excels in both digital and analog designs. The circuit is particularly advantageous for use in voltage-sensitive devices like ADCs, DACs, and other precision electronic applications, ensuring optimal operation and minimal drift over varying conditions.
These High-Voltage Integrated Circuits (ICs) from Advanced Silicon are crafted to manage high-pin counts and multi-channel output drivers specifically for thin film technologies. Designed to provide a broad range of voltage drive capabilities, these ICs can handle detailed digital-to-analog conversion with various DAC resolutions and multiple channels. This product range encompasses foundational two-level drivers as well as precise DACs, which possess a remarkable capability in turning on or off thin film switching devices by driving the gate electrode in technologies like amorphous Silicon, Low-Temperature Poly-Silicon, and IGZO. Additionally, these ICs are suited for accurately driving analog components in MEMs devices and capacitive loads like those of ITO. Especially popular in flat panel displays like LCD, OLED, and even large formats like digital flat panel X-ray detectors, these line drivers hold up to 512 output channels and utilize a COF package. The DAC drivers, on the other hand, offer DACs with resolution capabilities reaching up to 1024 output voltage levels, making them apt for precise pixel capacitive loads.
The TIA Linear Amplifier is designed to handle extensive data transmission rates, supporting single-lane transmission from 25G up to 112G. With capabilities for both limited and unlimited linear amplification, it is fundamental in maintaining signal integrity across expansive bandwidths. These amplifiers are critical in data centers and high-speed communication links where reliable data integrity is non-negotiable.
The GNSS ICs AST 500 and AST GNSS-RF form a crucial component of Accord's expanding portfolio of semiconductor solutions. These chips are meticulously designed to enhance the capabilities of GPS and GNSS systems, enabling superior performance in diverse applications. The AST 500 is engineered to provide robust and reliable navigation solutions, making it indispensable for applications that demand precise positioning and timing. Meanwhile, the AST GNSS-RF is optimized for RF front-end operations, ensuring high-quality signal processing required for accurate global positioning across various environments, whether terrestrial or space.\n\nWith a strong focus on innovation, these ICs support a wide range of global navigation satellite systems, including GPS, Galileo, and BeiDou. This makes them exceedingly versatile for integration into a myriad of devices where positioning accuracy is paramount. Thanks to robust architecture, these ICs can efficiently handle multi-frequency and multi-constellation tracking, providing users with flexibility and reliability in their GNSS applications.\n\nDesigned with precision and robustness, these ICs incorporate advanced features like enhanced interference mitigation capabilities. This ensures they can maintain reliable operation even in environments with significant electronic noise, thereby elevating the reliability of GNSS systems. Overall, the AST 500 and AST GNSS-RF chips underscore Accord's commitment to delivering cutting-edge solutions that push the boundaries of what's achievable in satellite navigation technology.
The ATEK552 is a high-powered GaN-based power amplifier capable of delivering 6 watts of output power within the frequency range of 3 to 17 GHz. This amplifier is tailored for high-efficiency power applications where robustness and reliability are crucial. It offers a gain of 21 dB and operates with a supply voltage of 28 volts, consuming 510 mA of current. Such specifications make it an excellent choice for demanding environments where high power and reliability are needed. Its die package facilitates versatile application in designs that prioritize performance and space efficiency.
The CC-100IP RF by CurrentRF is engineered to tackle RF emissions and improve EMI characteristics in integrated circuits. It acts as an on-chip solution to reduce electromagnetic interference, targeting power grids on chips where digital dynamic currents are a concern. This IP forms the lowest impedance point in an IC power grid, significantly enhancing on-chip supply filtering capabilities. The CC-100IP RF notably trims down digital dynamic currents by up to 40%, effectively reducing unsought emissions and improving circuit performance. Emphasizing its cybersecurity benefits, this IP enhances on-chip security by cultivating a more controlled electromagnetic environment, minimizing potential points of attack that could be exploited through RF emissions. With applications extending to various digital and mixed-signal environments, it supports the intricate balance of maintaining low emissions while safeguarding data integrity. The design prowess of the CC-100IP RF showcases substantial improvements, achieving up to a 600-fold increase in reservoir capacitance, allowing for more efficient power management. The IP thus becomes indispensable in applications where energy efficiency and RF emission management are central goals, such as in consumer electronics and automotive sectors where demand for lower power consumption and heightened security is persistent.
These interface conditioners are designed to work with industrial sensors that use Wheatstone bridges, amplifying and processing their minute differential voltages for subsequent digital transmission. Granite SemiCom's design integrates advanced features such as digital signal transmission over an I2C interface and easy programming and debugging capabilities. Ideal for remote or distributed sensor systems, these conditioners support various configurations that enhance communication security and data integrity across potentially vast distances.
IQ-Analog is renowned for delivering the highest performance data conversion cores available globally. These Intellectual Property (IP) cores are typically part of expansive multi-core macros that seamlessly integrate Analog-to-Digital Conversion, Digital-to-Analog Conversion, Phase-Locked Loops (PLLs), Power Supply Regulation, and Digital Signal Processing (DSP), alongside other mixed-signal operations, into a unified macro. These comprehensive mixed-signal solutions provide customers with pre-licensed components for embedding into their System-on-Chip (SoC) designs, facilitating quick integration and potentially reducing time-to-market for new products. One of the primary offerings under its IP umbrella is a series of digital transceivers, acclaimed for their complete band conversion capabilities. These transceivers are configured to serve both commercial and military domains, delivering unparalleled performance with an efficiency tenfold greater than alternatives in the market. The fusion of data conversion precision with power and cost reductions reflects IQ-Analog's commitment to innovation. IQ-Analog's developments are manufactured using on-shore CMOS processes, ensuring dependability and performance consistency. Their products cater particularly to the demands of advanced radio and radar technologies by offering extended bandwidth and rapid sampling rates, thus meeting contemporary requirements with superior operational capabilities.
Engineered for Distributed Antenna Systems (DAS), this Programmable Gain Amplifier (PGA) enhances signal management, crucial for maintaining high-quality communications and data transmission in complex network architectures. The PGA's role in DAS involves the precise amplification of signals received by distributed antennas, balancing signal strength across wide areas to ensure consistent connectivity. Built using UMC's 55nm high-voltage process, this PGA maximizes the accuracy of weak signal amplification with minimal distortion, essential for effective signal distribution in challenging environments. It delivers adaptable signal gain, adjusting to varying network conditions while maintaining optimal performance levels. The PGA's robust design is critical for DAS deployments, ensuring stable signal management and network reliability. By improving signal strength and quality, this amplifier significantly enhances the overall capability of distributed antenna setups in telecommunications, supporting data-heavy and mission-critical applications where robust networking is essential.
The Programmable Gain Amplifier (PGA) engineered for sensors optimizes signal amplification to improve the performance of various analog front-end systems. This PGA is crucial for enhancing the readability of minute signals detected by sensor elements, ensuring that even small fluctuations are captured with great accuracy and subsequently converted for digital processing. The high-performance architecture of this PGA allows it to adapt easily to different sensor types and their respective signal characteristics, offering flexibility along with precise signal management. Its emphasis on maintaining low noise levels during amplification allows for clarity and integrity in signal acquisition, underscoring its utility in a wide array of sensor applications. Designed with SMIC's 180nm process, the PGA is tailored to improve sensor data accuracy, making it invaluable for use in automotive, industrial, and consumer electronics where signal sensitivity is critical. By fine-tuning signal gain in real-time, this PGA enhances the overall effectiveness of the systems it supports, helping to achieve accurate readings and precise operational control.
Tailored for weighing scales and sensor applications, this Programmable Gain Amplifier (PGA) excels in facilitating precision in signal amplification. Essential for detecting and amplifying signals in weight measurement and sensor data, its design ensures minimal signal loss and distortion during amplification. Manufactured using TSMC's 180nm technology, the PGA provides dynamic adjustment capabilities, enabling optimal performance across varying operational conditions. It is particularly beneficial for applications involving load sensors, where precise signal amplification is crucial for accuracy in measurement and weight determinations. Equipped to maintain signal integrity, the PGA is crucial for reliable data conversion and measurement systems, contributing to a broader spectrum of industrial processes that require exact weight detection and signal processing. This capability supports exacting standards in industries where measurement accuracy is integral to quality and efficiency.
Specialized for seismic applications, this Programmable Gain Amplifier (PGA) offers vital signal amplification required for seismic data acquisition and analysis. It enhances the readability of weak seismic signals, increasing the clarity and precision of data captured from seismic activities and geological events. This PGA is designed using TSMC's 180nm technology, providing fine-tuned gain control that adjusts in response to various signal characteristics inherent in seismic studies. By amplifying these subtle variations faithfully, the PGA ensures that subsequent digital conversions yield accurate representations of seismic phenomena, critical for effective monitoring and analysis. Strategically developed to operate in seismic environments, this PGA is equipped for robustness and long-term reliability, even under challenging conditions. By providing high fidelity in signal amplification, it supports the synthesis of vital information needed for geological assessments and earthquake preparedness measures, making it a cornerstone of modern geoscientific instrumentation systems.
TES's Very-low-Noise and Programmable very-high-Gain DC-Voltage Amplifier offers remarkable amplification versatility, capable of operating with low noise output and programmable gain settings. This amplifier supports a range of gains up to 400V/V, making it highly adaptable for precise amplification needs across multiple applications. Furthermore, its companion trimming function enhances accuracy by offsetting any potential gain discrepancies through an 8-bit dual DAC. Silicon-verified within XFAB's technology, it can be transferred for integration with other manufacturing processes, lending itself effectively to high-precision electronic applications, where signal integrity and accuracy are paramount for optimal performance.
VeriSyno's Analog Solutions encompass a comprehensive range of analog IPs crafted to enhance performance in various sectors. These solutions include elements such as analog-to-digital converters (ADC), digital-to-analog converters (DAC), Phase-Locked Loops (PLL), Low-Dropout Regulators (LDO), and more. Tailored to support process nodes from 28nm to 65nm, these analog components are vital in achieving precision and efficiency in data conversion and signal processing. The company provides customized migration services, ensuring that even clients using 65nm to 180nm processes have access to advanced analog IP tailored to their needs. This flexibility in customization reflects VeriSyno's commitment to catering not only to current technology demands but also to legacy systems still prevalent in the industry. By focusing on customer-specific requirements, they offer seamless integration and adaptation within existing technology frameworks. Moreover, these analog solutions are pivotal in improving the efficacy of various electronics, impacting sectors like healthcare, automotive, and telecommunications with innovative and reliable design. VeriSyno's analog offerings are robust and adaptable, providing essential infrastructural improvements across multiple technological fields.
The Transimpedance Amplifier is crafted to power some of the fastest cloud AI and carrier networks. This amplifier offers exceptional performance, making it a critical component in high-speed data connectivity applications. It ensures the delivery of clean and amplified signal output, essential for overcoming the challenges in data transmission over long distances. The Transimpedance Amplifier's design focuses on achieving efficient signal conversion, which is fundamental to enhancing the capabilities of AI-driven and carrier network infrastructures.
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