All IPs > Analog & Mixed Signal > A/D Converter
In the realm of Analog & Mixed Signal technology, A/D Converter semiconductor IPs play a critical role. These IPs, also known as Analog-to-Digital Converters, are essential components in modern electronics that convert real-world analog signals, such as sound, light, or pressure, into digital signals that can be processed by digital circuitries. This conversion is vital for various applications across several industries, including telecommunications, healthcare, consumer electronics, and automotive sectors.
The primary function of an A/D Converter semiconductor IP is to enable seamless interaction between analog input sources and digital processing units. High-quality A/D Converters ensure accurate data capture and conversion, minimizing loss of information during the transformation process. As the demand for more precise and faster data processing increases, the importance of these IPs grows, driving innovations in resolution, sampling rates, and power efficiency.
In Silicon Hub’s A/D Converter category, you'll find a diverse range of semiconductor IPs tailored to meet specific needs of system designers and engineers. Whether you require low-power solutions for battery-operated devices or high-speed converters for data-intensive applications, our catalog offers the perfect fit. Products range from delta-sigma modulators for audio applications to high-speed pipeline converters often used in video processing or RF communication systems.
Developers and manufacturers can greatly benefit from integrating these cutting-edge A/D Converter IPs into their electronic designs. They not only improve the functionality and accuracy of electronic devices but also enable the creation of innovative products that respond adeptly to the challenges of the modern digital era. Explore Silicon Hub’s collection today to find the right A/D Converter IP that matches your technical requirements and enhances the performance of your products.
The agileADC analog-to-digital converter is a traditional Charge-Redistribution SAR ADC that is referenced to VDD, VSS. The architecture can achieve up to 12-bit resolution at sample rates up to 64 MSPS. It includes a 16-channel input multiplexor that can be configured to be buffered or unbuffered, and support differential or single-ended inputs. Agile Analog designs are based on tried and tested architectures to ensure reliability and functionality. Our automated design methodology is programmatic, systematic and repeatable leading to analog IP that is more verifiable, more robust and more reliable. Our methodology also allows us to quickly re-target our IP to different process options. Our highly configurable and multi-node analog IP products are developed to meet the customer’s exact requirements. These digitally-wrapped and verified solutions can be seamlessly integrated into any SoC, significantly reducing complexity, time and costs.
The KL730 AI SoC is equipped with a state-of-the-art third-generation reconfigurable NPU architecture, delivering up to 8 TOPS of computational power. This innovative architecture enhances computational efficiency, particularly with the latest CNN networks and transformer applications, while reducing DDR bandwidth demands. The KL730 excels in video processing, offering support for 4K 60FPS output and boasts capabilities like noise reduction, wide dynamic range, and low-light imaging. It is ideal for applications such as intelligent security, autonomous driving, and video conferencing.
The Single-Channel, 12-Bit, 1-MSPS SAR ADC is designed as a versatile analog-to-digital converter for various applications requiring precise data conversion at high speeds. This ADC utilizes a Successive Approximation Register (SAR) architecture to deliver 12-bit resolution at sampling rates up to 1 Megasample per second (MSPS). It is ideal for use in systems demanding high throughput and accuracy. This ADC is engineered to support a wide range of signal conditions and integrates features that ensure noise reduction and signal integrity. High resolution combined with fast sampling makes it suitable for real-time data acquisition in medical devices, industrial automation, and other applications where fine data precision is critical. Functionally, the ADC supports a streamlined interface for easy integration into broader system architectures. Its design encompasses configurable sample rates and built-in features that enhance signal fidelity, making it a desirable choice for applications requiring robust performance coupled with low power consumption.
The AFX010x Product Family by SCALINX showcases a line of highly sophisticated Analog Front Ends (AFEs) that are perfect for applications where low power usage, superior signal integrity, and high sampling rates are crucial. Each AFE chip contains four independent channels, integrating a programmable input capacitance, a single-ended-input to differential-output Programmable Gain Amplifier (PGA), an offset DAC, an ADC, and a digital processor. The design promises high-level integration, ensuring a compact PCB footprint and significant power reduction, leveraging the SCCORETM technology. The AFX010x products bring user flexibility with features such as digitally-selectable bandwidths, varying programmable analog and digital gain ranges, and low harmonic distortion. With resolutions of up to 16-bit and sampling rates stretching to 5 Gsps, they stand out as top performers in environments requiring precise signal conversion. These AFEs are housed in a standard 12 mm × 12 mm, 196-Ball BGA package, which guarantees a pin-to-pin compatibility across the different variants. This family is tailored for a multitude of applications such as high-resolution data acquisition, USB and PC-based oscilloscopes, non-destructive testing tools, and more, offering a versatile solution for numerous sectors.
The ADQ35 is a versatile dual-channel digitizer designed for high-performance data acquisition at a sampling rate of 10 GSPS. With its flexible configuration, the ADQ35 supports both a two-channel operation at 5 GSPS and a single-channel mode at the full 10 GSPS. The device is DC-coupled with a bandwidth capacity of up to 2.5 GHz, which suits it for a variety of conditions where signal integrity is key. A highlight of the ADQ35 is its open onboard Xilinx Kintex Ultrascale KU115 FPGA, offering extensive capabilities for custom digital signal processing. This device also facilitates peer-to-peer streaming at a rapidity of 14 Gbyte/s, enabling direct and efficient data transfer to GPUs or CPUs. This makes it exceptional for applications that rely on large-scale data handling and processing efficiency. The ADQ35 is engineered for use in various high-demand applications such as Time-of-Flight Mass Spectrometry, LiDAR systems, and scientific instrumentation. This flexibility is further enhanced by an array of standard and optional firmware packages, which empower users to tailor the device's capabilities according to specific project needs.
Turbo Encoders/Decoders by Creonic represent key components for achieving effective forward error correction in communication systems. Utilizing turbo coding, these IP cores enhance data throughput by rapidly encoding and decoding signals, ensuring minimal error propagation and optimal data integrity. Widely used in standards like DVB-RCS2 and LTE, Turbo coding provides excellent performance gains in error correction. These cores are specifically designed to handle large volumes of data with high efficiency, allowing technologies like 4G and upcoming 5G networks to deliver their promised speeds reliably. Creonic’s Turbo Encoders/Decoders support a range of code rates, making them adaptable for various transmission conditions and enabling dynamic applications across different communication landscapes. Importantly, they incorporate advanced algorithmic techniques to accelerate processing speeds and reduce latency – essential qualities for real-time applications. Supported with a suite of testing environments and simulation models, these IP cores ensure straightforward integration into user hardware, providing considerable flexibility for both FPGA and ASIC implementation scenarios.
Polar Encoders/Decoders from Creonic are designed with the latest communication standards in mind, delivering exceptional performance in error correction through polar coding techniques. Originally developed for 5G systems, polar coding offers strong error correction capabilities with high efficiency, making these cores critical for next-generation communication systems. These encoders/decoders provide a consistent performance boost by efficiently utilizing channel capacity, which is particularly beneficial in high-throughput scenarios such as wireless backhaul and cellular networks. Creonic’s implementation focuses on minimizing complexity while maximizing speed, ensuring the cores can handle demanding communication tasks without excessive processing overhead. The Polar Encoders/Decoders IP cores are packed with a rich set of features that include adjustable code rates and length, providing adaptability to various requirements. With comprehensive support for both FPGA and ASIC deployments, they offer a robust, flexible solution for those looking to enhance their existing digital communication frameworks.
The ADQ35-WB is a robust data acquisition module designed to handle both high-frequency and dual-channel applications at a high sampling rate. It offers either a dual-channel configuration at 5 GSPS or a single-channel setup at 10 GSPS. The digitizer boasts a significant 9.0 GHz usable analog input bandwidth, making it ideal for complex and high-demand applications such as RADAR, LiDAR, and scientific research. Equipped with an open onboard Xilinx Kintex Ultrascale KU115 FPGA, the ADQ35-WB provides substantial resources for custom real-time digital signal processing. This module also supports high-speed peer-to-peer streaming of data to GPUs or CPUs at speeds up to 14 Gbyte/s. This high throughput is complemented by advanced triggering options, making it highly functional for sophisticated data handling and processing. In terms of practical usage, the ADQ35-WB includes a comprehensive suite of hardware options, firmware, and software tools designed for straightforward integration into existing systems. This includes the default data acquisition firmware, optional waveform averaging, and pulse detection firmware, as well as a development kit for customized FPGA development.
The High-Resolution ADC or Analog-to-Digital Converter by Eureka Technology is designed to offer superior digital conversion accuracy for high precision applications. This ADC ensures minimal error rates, making it ideal for use in rigorous data acquisition tasks and instrumentation. It integrates advanced digital processing capabilities to efficiently translate analog signals into precise digital data. Designed to cater to sophisticated design requirements, it offers customizable features that enhance performance metrics in specific applications. These attributes make it adaptable for use in scientific research domains, telecommunication systems, and complex sensor networks. The ADC stands out for maintaining signal integrity while enhancing operational ease across a range of input conditions. Optimized for efficient digital transformation, the High-Resolution ADC plays a crucial role in developing reliable and high-performance computing systems. By ensuring seamless integration with existing semiconductor frameworks, Eureka's ADC addresses both standard and custom application needs.
Vantablack S-VIS Space Coating is a pioneering solution designed for the suppression of stray light in space applications. This coating excels in optical performance by absorbing nearly all incident light, thereby providing unmatched minimization of reflection. As a result, it enhances the calibration of optical instruments used in space, critical for precise astronomical measurements and other space exploration applications. Vantablack S-VIS is formulated to withstand the harsh conditions of space, maintaining its superior blackening properties without degradation even in extreme environments. The use of Vantablack S-VIS offers significant advantages to scientific missions by improving the accuracy and reliability of data collected through telescopes and other space-borne instruments. Unlike traditional paints and coatings, Vantablack S-VIS can be applied to complex optical structures without affecting their functionality. This makes it an essential component in designing systems that operate in high-precision, and high-sensitivity environments where error margins are minimal. In addition to its functional applications, the aesthetic appeal of Vantablack S-VIS is unmatched, creating a breathtaking void of light when applied. This aspect has also found applications in art and design, where the darkest black available transforms ordinary surfaces into seemingly infinite voids. As such, Vantablack S-VIS serves both scientific and creative endeavors by harnessing its unique optical properties to transform how surfaces are seen and used in various industries.
Xinglian-500 serves as an advanced interconnect fabric IP, supporting coherency across multi-core CPU and SoC designs. This product ensures memory consistency through its network-on-chip (NoC) architecture, facilitating the connection of multiple CPU clusters, IO devices, and DDR, all within the confines of an SoC. This feature is crucial for maintaining synchronization across multiple processing units, thereby enhancing the scalability and performance of complex systems.
The ADQ7DC is a state-of-the-art digitizer that offers a blend of high resolution with 14 bits and a rapid 10 GSPS sampling rate. This model surpasses previous limitations in high-speed applications, opening new possibilities for advanced measurement and processing tasks. It operates in both single-channel at 10 GSPS and dual-channel at 5 GSPS modes, offering versatility in data capture requirements. Its DC-coupled input boasts a commendable 3 GHz input bandwidth, with capabilities for programmable DC-offsets and a digital noise reduction filter. The onboard Xilinx Kintex Ultrascale KU115 FPGA provides ample resources for diverse real-time digital signal processing tasks. With peer-to-peer data streaming to GPUs facilitated at 7 Gbyte/s, users gain enhanced efficiency for intensive data handling applications. With its broad compatibility with various form factors like PCIe and PXIe, ADQ7DC is ideal for high-speed RF data recording, scientific instruments, and more. The built-in firmware offers a rich selection of application-specific functions that can be accessed without any need for FPGA development, significantly simplifying its operation and integration.
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.
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.
Creonic's LDPC Encoders/Decoders are designed to provide high-efficiency error correction for modern communication systems. These IP cores follow advanced LDPC (Low-Density Parity-Check) coding schemes to offer a balance of performance and flexibility. They are suitable for use in a plethora of standards such as DVB-S2, DVB-S2X, 5G, and CCSDS, ensuring robust data transmission across various signal conditions. The LDPC solutions by Creonic are known for their high throughput, making them fit for applications that demand speed and accuracy. Their capability to process and correct errors efficiently ensures data integrity, especially in bandwidth-critical systems. Users can expect comprehensive integration support with available design kits and simulation models that aid seamless incorporation within existing hardware platforms. With flexibility for both FPGA and ASIC implementations, Creonic's LDPC encoders and decoders come equipped with adaptive features that allow for various code rates and block lengths. This adaptability ensures that users can tailor the application to meet specific requirements, benefiting from the cores' proven reliability in delivering high-quality data communication.
The Delta-Sigma ADC provides a striking 14-bit resolution paired with a rapid 20Msps sampling rate, setting it apart in high-speed, high-precision conversions. It's engineered to support demanding applications, where accurate signal conversion is crucial, such as wireless communications and advanced instrumentation. The ADC employs delta-sigma modulation, which results in minimal signal distortion and enhanced dynamic range. This high-performance solution aids in capturing pure signals, eliminating detrimental noise components effectively. Manufactured with TSMC's 65nm process node, this silicon-proven ADC is ready for integration into sophisticated electronic systems, offering reliability and advanced technology to address modern industry challenges in data conversion.
YouADC provides a variety of ADC options with architectures including SAR and Pipeline configurations. Available resolutions range from 12 to 16 bits with sampling rates of 500K to 170Msps, ensuring high versatility for different data conversion needs. Brite's ADCs have passed tape-outs, proving their effectiveness in customer products. The advanced features strike a balance between high precision and efficient operation.
InPsytech's ADC solutions include SAR, Pipeline, and SigmaDelta converters, catering to a variety of precision and high-speed conversion needs. These converters are integral in converting analog signals to digital form in a range of applications, from consumer electronics to high-precision instruments. The ADC solutions are designed to deliver accurate, fast results, essential for detailed signal processing tasks.
The General-purpose SAR ADC, featuring 8 channels, 12-bit resolution, and a sampling rate of 1Msps, is designed for versatile applications requiring precise digital conversion of analog signals. It stands out with its robust performance and low power consumption, making it ideal for battery-operated and space-constrained systems. This SAR ADC operates efficiently at a supply voltage of 3.3V, ensuring high accuracy and stability. Suitable for a wide range of industrial and commercial applications, this ADC supports a sampling rate of 1Msps, allowing it to quickly and accurately capture and process analog signals. Its multi-channel architecture ensures the capability to handle diverse input signals simultaneously, providing flexibility in various system configurations. Enhanced with silicon-proven reliability, this ADC is available in process nodes provided by Magna, utilizing both 180nm and 130nm technologies. Its proven track record in silicon adds a layer of confidence for engineers seeking performance consistency in demanding environments.
The 8-bit Delta-Sigma ADC, with a sampling rate of 2Ksps, is optimized for low-frequency, high-precision applications. By leveraging delta-sigma modulation, it ensures excellent noise shaping and high dynamic range, making it an ideal choice for environments where signal integrity is paramount. This ADC is versatile and designed for low power consumption, thus being suitable for portable and battery-powered devices. Its architecture allows for effective filtering of out-of-band noise, reinforcing its ability to deliver precise digital representations of analog signals. This silicon-proven product is available in SMIC's 180nm process, making it a reliable choice for applications such as environmental monitoring instruments and low-speed data logging systems where accuracy and efficiency are crucial.
The aLFA-C is a sophisticated interfacing ASIC designed for use in space-borne infrared readout integrated circuits (ROICs) and other types of image sensors. It serves to replace much of the traditional infrastructure found in classic front-end electronics, thereby streamlining operations and improving efficiency. Notably, the device can function on a minimal single unregulated power supply, facilitated by on-chip Low Dropout regulators (LDOs) and Regulators. The aLFA-C's architecture allows it to run on either an external clock or a crystal oscillator interface, contributing to versatile deployment scenarios. With SpaceWire as its interface for external communication, the device can integrate smoothly into a range of systems. The aLFA-C also features a fully programmable sequencer to manage the ROIC, offering eight levels of nesting and dynamic reprogrammability. In terms of adaptability, the aLFA-C provides 32 programmable level single-ended digital outputs that can be transformed into 16 differential outputs using CMOS, LVDS, or CML formats. Additionally, it includes 16 programmable threshold single-ended digital inputs, which can be configured into LVDS or CML inputs. With capabilities for resistance, voltage, and current measurement, and a wide operating temperature range from 35K to 330K, the aLFA-C is robust and suited for demanding environments.
Aimed primarily at high-performance sensor arrays, this IP suite provides a robust solution for analog conversion and amplification needs in modern electronic systems. SystematIC ensures that these converters and amplifiers meet stringent requirements for low noise and high accuracy, facilitating seamless integration with a variety of sensor types. This component family includes SAR and Sigma-Delta A/D converters, with resolutions from 10 to 16 bits, designed to handle dense data processing tasks reliably. SystematIC offers comprehensive support for integrating these components into larger systems, making them ideal for applications requiring precise analog data processing.
Notus provides a comprehensive platform for SI/PI, thermal, and stress analysis, crucial for engineers striving to optimize electronic circuit performance under various environmental conditions. Integrating signal integrity, power integrity, and multi-physics simulation within a single tool, Notus offers unmatched analytical capabilities that ensure designs meet rigorous operational standards. Designed to tackle complex simulations, Notus helps in identifying potential problems before they become costly failures. Its detailed analyses encompass a range of scenarios, aiding in the prediction and enhancement of circuit reliability and longevity. This integrated approach supports forward-thinking design strategies that are essential in today's competitive electronics marketplace. Notus enhances productivity by simplifying the design process and reducing the need for multiple software tools, thereby accelerating time-to-market. The powerful simulations it provides are indispensable for engineers working on high-stakes projects where precision and reliability are non-negotiable.
SnpExpert is a dedicated platform designed for in-depth S-parameter analysis, which is vital in understanding the behavior of RF and high-speed digital circuits. By providing an unparalleled view of network parameters, this tool helps engineers ensure that designs will perform as expected across different frequencies and scenarios. The precision and clarity offered by SnpExpert simplify the analysis of complex interactions within electronic systems, allowing for efficient troubleshooting and optimization. This feature is particularly valuable when modifications are needed to enhance circuit performance, enabling refined design choices that foster innovation and reliability. SnpExpert's robust analytical capabilities make it an essential tool for tackling the intricate challenges associated with RF design and testing. Its insights into S-parameter metrics enable designers to achieve the optimal performance required in today's demanding technological landscape.
XPLM is an innovative solution for managing simulation processes and data in the ever-evolving field of electronic design. This tool provides a centralized platform for storing, organizing, and accessing large volumes of data, ensuring that design teams can operate efficiently and effectively. By integrating data management into the design process, XPLM reduces the complexity associated with handling vast amounts of information, thereby streamlining workflows and enhancing productivity. It supports engineers in maintaining version control and collaboration across different projects, helping manage resources and timelines more effectively. XPLM's comprehensive data handling capabilities make it indispensable for organizations committed to maintaining a competitive edge in the semiconductor industry. By simplifying the intricacies of data management, XPLM helps transform simulation insights into actionable strategies, driving design innovation and operational excellence.
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.
Designing effective ADCs requires flexibility to cater to varying resolutions, sample rates, and process nodes. Analog to Digital Converters from Analog Circuit Works are tailored to the specific requirements of each application, surpassing the capabilities of standard designs. With a diverse array of options, their ADC offerings can achieve high performance in numerous semiconductor processes, ensuring that each customer's unique needs are met. In creating these ADCs, the company focuses on optimizing circuits for maximum accuracy and efficiency. Typical configurations offer different resolutions and sampling rates, adjusting to the application's constraints. This ensures that clients receive a product that flawlessly integrates into their systems while delivering top-notch data conversion performance. Their expert team ensures that each ADC design maintains signal integrity and noise reduction, critical for the functionality of high precision devices. These converters are fundamental to applications ranging from simple electronics to complex industrial systems, and the company thrives on adapting these components to the intricacies of each project.
Enosemi's analog and mixed-signal devices are engineered for seamless integration into advanced photonic circuits, enabling high-speed data processing and signal conversion. These devices leverage cutting-edge technologies to offer both low and high-speed functionalities, catering to a wide range of applications, including telecommunications and data communications. The IP is silicon-verified, which ensures reliability and reduces integration times, offering a cost-effective solution for complex photonic systems.
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.
MeasureExpert is engineered for automated measurement and analysis, providing detailed insights essential for maintaining quality and performance in electronic products. By automating tests and measurements, this tool enables large-scale data management and quick iteration, streamlining the verification phase of electronic design. The tool's capability to handle multiple testing scenarios simultaneously makes it invaluable in ensuring that a product meets the specified requirements before production. MeasureExpert assists engineers by simplifying the testing process, reducing the potential for human error and increasing the efficiency of the quality assurance stage. MeasureExpert's automation prowess supports the production of high-reliability electronic systems, offering detailed analytical feedback that helps refine designs and confirm their readiness for market launch. It is a crucial component of any design cycle focused on high standards of precision and efficiency.
This innovative system by WiTricity ensures optimal alignment and compatibility detection within wireless power transfer setups. It is specifically designed to automate the alignment process, ensuring that power transfers are executed with maximum efficiency and minimal loss. With a focus on adaptability, the system automatically adjusts to the specific power needs and alignment requirements of different devices. This adaptability is key in applications like EV charging, where placement accuracy can greatly influence charging effectiveness and duration. Compatibility detection further adds a layer of intelligence, ensuring that only compatible devices are charged, thereby preventing damage to both the charger and device. WiTricity prioritizes ease of use and practicality with this system, integrating seamlessly into existing power infrastructure. It is engineered to enhance the operational profile of wireless charging setups in both residential and commercial environments, facilitating a more user-friendly experience.
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.
The ADC-12-35M-TJ is a robust pipeline analog-to-digital converter that delivers 12-bit resolution at speeds of up to 35 MS/s. Utilizing TowerJazz's 0.18 μm technology, it is designed for high-speed signal processing applications that demand precision and efficiency. This ADC's enhanced noise performance and linearity make it well-suited for use in communication systems, data acquisition instruments, and medical devices. Characterized by its high effective number of bits, the ADC-12-35M-TJ provides superior dynamic range and low jitter, ensuring that it can handle a wide variety of signals with minimal distortion. Moreover, its power-efficient design contributes to reduced thermal output, making it suitable for compact systems. With its superior digital output accuracy, this ADC is particularly beneficial for applications that require accurate data representation and minimal error. Its ability to maintain performance across variable conditions makes it an appealing option for advanced signal processing systems.
WiTricity's Wireless Non-Radiative Energy Transfer technology is engineered to offer efficient power transmission without physical connectors. It uses resonant magnetic coupling to transfer power over certain distances, targeting applications in electric vehicle charging and other large-scale energy systems. This technology promises high efficiency, mirroring traditional plug-in systems, minus the encumbrances of physical sagging cables. The wireless nature of this technology offers unparalleled convenience while ensuring a robust energy supply chain. It is particularly effective in automotive environments, where seamless power transfer can significantly improve user experience and operational uptime. Furthermore, the system has been designed to minimize electromagnetic interference, ensuring its operation does not disrupt other electronic devices nearby. With a focus on scalability and efficiency, WiTricity's non-radiative energy technology is set to redefine standards in various sectors, supporting a host of innovative applications such as autonomous vehicle charging and smart grid power distribution.
The ADQ35-PDRX is a high-performance single-channel digitizer that offers 5 GSPS sampling speed, making it perfectly suited for pulse data systems. This innovative device integrates dual-gain channel technology to extend its dynamic range by 3 bits, presenting the equivalent of a 16-bit digitizer with the advantage of higher sample rates. This makes ADQ35-PDRX particularly suitable for applications requiring detailed and precise signal capture without saturation. The device features a DC-coupled input with a bandwidth up to 2 GHz, tailored to ensure optimal signal detection. The onboard Xilinx Kintex Ultrascale KU115 FPGA supports custom real-time signal processing, ensuring high flexibility and adaptability to various specific requirements. This digitizer includes comprehensive firmware options to enhance its functionality and user-friendliness, supporting efficient peer-to-peer streaming to CPUs or GPUs. It's optimized for demanding environments like Time-of-Flight Mass Spectrometry and LiDAR, ensuring robust performance across different sectors.
The ARKT28HPCP_LDO100 Voltage Regulator is designed for applications requiring a stable and precise power source for digital and analog circuits. Operating within a narrow input voltage range of 1.62V to 1.98V, this LDO regulator delivers a fixed output of 0.9V with an impressive accuracy of 3%. It can support load currents up to 100mA, making it suitable for low-power applications where efficiency is crucial. Manufactured using TSMC's 28nm process technology, this regulator is currently under development, promising advanced integration for modern electronic designs. The compact design and high performance of the ARKT28HPCP_LDO100 ensure that it meets the stringent voltage regulation needs of different system architectures. Ideal for use in battery-powered devices, communication systems, and portable electronics, the ARKT28HPCP_LDO100 offers reliable power management solutions. As part of Arkchips' innovative product lineup, it represents a significant step forward in low dropout regulation technology.
The ELFIS2 Image Sensor is a high-performance visible light imager designed to withstand harsh environments. Its standout feature is the robust radiation hardness, making it ideal for applications requiring extreme reliability under radiation exposure. The design ensures resistance against total ionizing dose (TID), single event latch-up (SEL), and single event upset (SEU), confirming its suitability for demanding operational environments. The sensor boasts a true High Dynamic Range (HDR) capability, allowing it to capture a wide spectrum of illumination levels without compromising on image quality. This functionality is complemented by a Motion Artifact Free (MAF) global shutter, ensuring sharp and distortion-free images even in high-speed scenarios. Furthermore, the back-side illumination (BSI) design enhances light absorption, improving image performance in low-light conditions. With an emphasis on durability and versatility, the ELFIS2 offers users a reliable imaging solution that meets the requirements of specialized scientific and industrial applications. It stands out not only for its technical specifications but also for its ability to drive new possibilities in imaging applications from space exploration to cutting-edge microscopy.
The Magnetic Hall Sensor developed by SystematIC excels in isolated current sensing at both direct current and low frequencies. These Hall sensors perform well in integrating the sensor elements along with associated readout electronics using standard CMOS technology. SystematIC has successfully developed cost-effective, fully integrated current sensor ICs that are capable of delivering high gain accuracy and low offset. The sensor is adaptable for wide operating temperatures, ensuring its robustness and reliability. With this technology, customers benefit from good isolation properties and zero magnetic hysteresis, vital for accurate current measurement in applications requiring high-frequency response and low noise.
The Pipelined SAR ADC with 16 channels offers a 12-bit resolution and a sampling rate of 1.5Msps, making it suitable for applications needing high-speed and high-resolution data acquisition. This advanced ADC employs a pipelined architecture, which enhances its throughput while maintaining accuracy and low latency. Engineered for precision, the ADC operates at a supply voltage of 5.0V, providing robust performance across varying conditions. The architecture is designed to efficiently handle large datasets, making it suitable for data-intensive applications. Its ability to manage multiple channels simultaneously adds to its versatility. The device is silicon-proven with Samsung, operating on a 65nm process node, which ensures reliability and integration ease for complex systems. Its superior performance characteristics make it ideal for automotive, industrial, and communications applications where high data integrity and speed are critical.
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.
ParkerVision has pioneered the use of energy sampling technology in RF receivers, setting a new standard in the industry with this innovative approach. Traditionally, handset receivers relied on super-heterodyne technology, which required high local oscillator power levels and multiple down-conversion steps to achieve optimal performance. ParkerVision's energy sampling technology, however, has revolutionized signal processing in RF, presenting a matched-filter correlator for frequency down-conversion as a more practical solution. By minimizing the division of the RF signal into separate I and Q paths, power consumption is reduced, and demodulation accuracy is significantly improved. \n\nMoreover, energy sampling technology offers remarkable benefits such as enhanced selectivity and interference rejection, making it ideal for direct-conversion receivers. Its compact and cost-effective nature is particularly suited to CMOS technology, allowing multimode receivers to be implemented in progressively smaller geometries with lower voltages, facilitating higher levels of functional integration. \n\nThis innovative technology has broad applicability across various applications, including smartphones, embedded modems, and tablets capable of operating across multiple standards like GSM, EDGE, CDMA, UMTS, TD-CDMA, and LTE. By improving dynamic range, the technology reduces the need for external filters, offering a more streamlined solution. \n\nThe energy sampling technology by ParkerVision continues to be a critical component in advancing RF receivers, providing solutions that are highly efficient in power consumption and capable of handling high data rates from modern wireless communication demands.
This technology from WiTricity focuses on enhancing wireless energy transfer by managing interference. By leveraging advanced algorithms and resonant magnetic systems, it ensures efficient power delivery even in environments where interference might be an issue. The system is adept at quantifying and minimizing potential disruptions, thus providing a stable power transfer solution ideal for sensitive applications. Enhancements in interference management ensure that the energy transfer remains robust and consistent, which is crucial for complex environments such as urban settings where multiple wireless signals coexist. The technology caters to high-demand applications, providing reliable energy transfer for devices like EVs, which require consistent power flow. This approach not only amplifies the effectiveness of energy transfer but also encapsulates safety and control mechanisms that prevent overheating and overloading, thereby extending the operational lifespan of devices. WiTricity's interference enhancement ensures that wireless power systems can operate unimpeded, maintaining performance irrespective of competing signals.
The Delta-Sigma ADC is a high-resolution data converter offering 16-bit precision at a sampling rate of 28Ksps. Utilizing delta-sigma modulation, this ADC is crafted for applications requiring high accuracy and low power consumption over slower signal bandwidths. Its high dynamic range and noise modulation capabilities make it particularly suitable for high-fidelity audio and precision measurement applications. Operating at various process nodes, the ADC's design focuses on minimizing power usage while maximizing output accuracy. It demonstrates a high degree of linearity and precision across its conversion range, thanks to its state-of-the-art modulation techniques. The ADC's under-development status with Samsung at a 65nm process node suggests cutting-edge advancements in ADC technology, offering future-ready solutions for evolving technological needs in sectors like instrumentation and consumer electronics.
Xinglian-700 is an advanced interconnect solution offering high scalability and performance. It's designed to connect up to 256 CPU cores while maintaining memory coherency across the SoC. This IP is particularly valuable for constructing large-scale processing networks that demand efficient and coherent memory systems. Its architecture supports enhanced scalability, making it an ideal choice for high-performance computing environments.
Akronic specializes in designing state-of-the-art analog and mixed-signal integrated circuits. Their extensive experience covers all essential building blocks used in modern telecom and radar transceiver radios. Akronic's portfolio includes low-pass filters, often utilizing Leapfrog, OPAMP, or Gm-C architectures. These incorporate sophisticated configurations like Chebyshev or Butterworth to achieve high cut-off frequencies exceeding 1GHz. Their ICs also encompass base-band functions such as bandgap voltage references and gain-control operations, ensuring precise signal management. The company's expertise extends to high-speed signal converters, featuring both switched-capacitor and current-source DACs, along with advanced ADC designs like successive-approximation and time-interleaved architectures. Additionally, Akronic's frequency synthesis capabilities embody both fractional and integer-N PLL technologies, complete with multi-modulus prescalers and loop filters. Their focus on minutiae extends through aspects like VCO design, including innovative drivers and multiplexing solutions, making their analog and mixed-signal ICs a hallmark of advanced integrated design. Akronic integrates power-efficient designs with meticulous attention to signal integrity and stability. They provide linear-in-dB or stepped gain-control mechanisms and boast advanced AGC and ALC loop designs. Their emphasis on advanced compensation techniques, like LO leakage control, ensures optimal real-world performance, reinforcing Akronic’s authority in analog and mixed-signal innovation.
Archband Labs' SAR ADC is a standout technology for applications requiring precision in analog-to-digital conversion. Known for its efficiency, the Successive Approximation Register (SAR) design is ideal for projects demanding low power consumption, making it an excellent fit for portable and battery-operated devices. Its design architecture allows it to deliver rapid conversions, which is crucial for real-time applications where speed and accuracy are paramount. This ADC is particularly useful in consumer electronics, automotive systems, and various industrial applications, where consistent performance and reliability are critical. The ADC supports a wide range of inputs, from simple analog signals to more complex waveforms, providing flexibility and versatility to engineers. Its cutting-edge performance plays a vital role in enhancing the overall functionality of devices, underpinning superior quality in signal processing tasks.
The 24-bit Sigma-Delta Analog-to-Digital Converter (ADC) with Analog Front End (AFE) is a high precision solution from RafaelMicro. Designed for applications requiring exceptional accuracy and noise performance, this ADC integrates seamlessly into various types of sensory equipment, providing a robust bridge between the analog world and digital processing environments.
This 12-bit Analog to Digital Converter (ADC) achieves a maximum conversion speed of 1MSPS, with a typical power consumption of 8.0mW. It operates over a wide voltage range from 2.7V to 5.5V, making it suitable for diverse applications. Its design ensures minimal non-linearity errors, with a DNL of ±1 LSB and INL of ±1.5 LSB. This ADC supports 16-channel single-ended inputs, adhering to stringent noise performance standards, such as 70.7dB SNT and an SFDR of 83.6dB.
This Sigma-Delta ADC provides a high-resolution 16-bit output at a conversion rate of 16KSPS. It features programmable gain settings from 0 to 50dB, allowing fine-tuning for various applications. With selectable microphone bias settings, it supports mono audio inputs across four fully differential channels. The ADC ensures high noise immunity with a Signal-to-Noise Ratio (SNR) of 90dB, supported by both PDM and I2S interfaces for digital output, making it suitable for precision audio processing.
The 10-bit SAR ADC by X-FAB is designed for high accuracy conversions in diverse electronic applications. It employs a successive approximation register (SAR) architecture, which is well-suited for precise analog-to-digital conversions. This ADC operates with a single-ended input and is capable of sample rates as high as 100kSPS, while maintaining a signal-to-noise ratio (SNR) of 60dB, demonstrating its excellent performance in terms of precision and reliability. The SAR ADC is a crucial component for systems where accuracy and speed are of paramount importance, such as in medical and industrial applications.