All IPs > Analog & Mixed Signal > D/A Converter
The D/A Converter (Digital-to-Analog Converter) semiconductor IP serves as a crucial component in the translation of digital signals into analog formats, indispensable for numerous electronic devices. Within this category at Silicon Hub, you'll find a diverse range of D/A converter semiconductor IPs designed to offer high precision and reliability, essential for applications across consumer electronics, telecommunications, and automotive sectors.
D/A converters are pivotal in bridging the gap between digital systems and real-world analog outputs. These semiconductor IPs are implemented in a wide array of devices, from audio amplification systems to instrumentation equipment, where precise and efficient conversion is vital. With the proliferation of digital technologies, the demand for robust D/A conversion mechanisms has only increased, making these IP blocks a key focus for designers aiming to maintain signal integrity and performance across their products.
In consumer electronics, D/A converter semiconductor IPs facilitate features in devices like smartphones, televisions, and home audio systems, where digital signals need to be output as sound or video. Similarly, in telecommunications, these converters enable impeccable data transmission and reception capabilities by converting digital signals suitable for analog transmission over various media. In automotive applications, D/A converters are also used in digital dashboard displays and advanced driver-assistance systems (ADAS), requiring high precision and low power consumption.
Silicon Hub's selection of D/A Converter Semiconductor IPs encompasses a variety of specifications to meet design requirements such as resolution, sampling rate, and power efficiency. This ensures that developers can tailor their choice of D/A converter IPs to the specific needs of their applications, whether they require ultra-low power converters or high-speed and high-resolution variants. By providing access to these innovative semiconductor solutions, Silicon Hub supports the creation of cutting-edge technologies that rely on seamless digital-to-analog conversion.
The agileDAC is a digital-to-analog converter that uses a traditional capacitive DAC architecture. The agileDAC uses its own internal reference voltage. The architecture can achieve up to 10-bit resolution at sample rates up to 16 MSPS. 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 REFS IP block integrates a band-gap reference with PTAT (Proportional to Absolute Temperature) current outputs, vital for mixed-signal ICs requiring stable voltage references. Developed using IBM's 65nm 10LPe process, the REFS block offers multiple outputs, adjustable through internal and external resistors, providing flexibility for various analog applications. Its capability to program current outputs within ±30% demonstrates its adaptability, allowing for precise control in complex circuits. This feature, combined with its stability across temperature variations, makes the REFS block indispensable in RF, analog, and mixed-signal designs. Incorporating the REFS block into a system enhances operational reliability and efficiency, crucial for long-term functionality of semiconductor devices. Its robust design addresses the need for consistent performance under varying environmental conditions, a must for specialized electronic applications.
The ABX Platform by Racyics utilizes Adaptive Body Biasing (ABB) technology to drive performance in ultra-low voltage scenarios. This platform is tailored for extensive applications requiring ultra-low power as well as high performance. The ABB generator, along with the standard cells and SRAM IP, form the core of the ABX Platform, providing efficient compensation for process variations, supply voltage fluctuations, and temperature changes.\n\nFor automotive applications, the ABX Platform delivers notable improvements in leakage power, achieving up to 76% reduction for automotive-grade applications with temperatures reaching 150°C. The platform's RBB feature substantially enhances leakage control, making it ideal for automotive uses. Beyond automotive, the ABX Platform's FBB functionality significantly boosts performance, offering up to 10.3 times the output at 0.5V operation compared to non-bias implementations.\n\nExtensively tested and silicon-proven, the ABX Platform ensures reliability and power efficiency with easy integration into standard design flows. The solution also provides tight cornering and ABB-aware implementations for improved Power-Performance-Area (PPA) metrics. As a turnkey solution, it is designed for seamless integration into existing systems and comes with a free evaluation kit for potential customers to explore its capabilities before committing.
The XCM_64X64_A provides a sophisticated architecture featuring 128 ADC 2-bit 1GSps with VGA front ends, designed for cross-correlation applications in NASA projects. Utilizing 45nm IBM SOI CMOS technology, it achieves ultra-low power consumption of approximately 0.5W for the entire array. The structure is geared towards synthetic radar receivers, radiometers, and spectrometers, operating at bandwidths from 10MHz to 500MHz. It integrates seamlessly into systems requiring precise data acquisition and processing, ideal for advanced research and observational instruments. With a focus on low power and high data throughput, the XCM_64X64_A addresses the challenges faced in high-energy physics and observational technology arenas. Its efficient power usage and robust design ensure long-term performance and reliability in demanding applications.
The XCM_64X64 represents a complete cross-correlator solution with 64x64 channels, designed to cater to NASA's high-end synthetic radar receivers. Executed using IBM's 45nm SOI CMOS technology, this correlator emphasizes energy efficiency with a total power consumption of approximately 1.5W. It is engineered to support advanced radiometric and spectroscopic applications, with bandwidth capabilities ranging from 10MHz to 500MHz. The array's infrastructure supports precise signal analyses, making it ideal for use in scientific and exploratory sectors. Designed for optimum power-to-performance ratios, the XCM_64X64 excels in environments that demand high data integrity and reliable processing under stringent operational conditions. It is a vital component for synthetic aperture radar systems and other complex observational tools.
1D Optical Micrometers from RIFTEK utilize a shadow measurement principle to deliver precise, non-contact assessments of object diameters, gaps, and edge positions. These micrometers are essential in industrial settings for measuring cylindrical objects like wires and rods, ensuring meticulous quality control. The RF651 line employs a direct through-beam approach, allowing for extended measurement between transmitter and receiver, accommodating larger objects without losing precision. These models are adept at maintaining accuracy across varying distances and conditions due to their high scanning frequencies and sophisticated processing electronics. Similarly, the RF656 line, with its telecentric lens technology, pushes the boundaries of precision with high measurement accuracy and speed. These micrometers can be seamlessly integrated into manufacturing processes, delivering real-time measurement data through interfaces like RS232, RS485, and Ethernet, supporting efficiency and boosting quality assurance outcomes across diverse industrial applications.
The 3D Imaging Chip from Altek Corporation is engineered to cater to the rising demand for sophisticated depth-sensing technologies. This chip is designed to enhance perception capabilities, making it essential for applications that require precision in spatial awareness such as robotics and security systems. It utilizes years of research in 3D sensing to deliver robust and versatile modules that can be tailored for surveillance drones, transport robots, and other medium to long-range detection needs. Integrating both software and hardware seamlessly, the 3D Imaging Chip offers improved recognition accuracy which is crucial for automated systems operating in dynamic environments. This is achieved by leveraging Altek's proprietary depth-sensing algorithms that enhance image clarity and focus stability across various lighting conditions. Its compact form factor makes it suitable for a broad range of portable devices. The solution is pivotal for industries seeking high-performance imaging solutions that can adapt to varying operational requirements. With its enhanced depth-sensing capabilities, the 3D Imaging Chip not only meets but exceeds the critical demands of rapid recognition and accuracy required in advanced automation and control scenarios. Altek's focus on integration from modules to chips allows for a cohesive system that is easy to implement into existing infrastructures, providing clients with a reliable tool to elevate their imaging challenges.
Designed to push the limits of high-speed data transmission, Omni Design's Digital to Analog Converter IP leverages its proprietary technology to deliver superior performance in signal integrity and power efficiency. Targeted applications include expansive fields such as 5G network infrastructures, automotive communication systems, and sophisticated radar and LiDAR sensor arrays. The Swift™ DAC solutions stand out for their ability to manage both wide bandwidths and high degrees of linearity in transmission paths. These converters support resolutions from 6 to 16 bits, with output update rates that impressively range up to 100+ Gsps. They incorporate a current-steering architecture that addresses harmonic distortion and enhances spectral features, crucial for maintaining clean signals in sensitive communication channels. Built-in calibration runs continuously to ensure performance consistency throughout dynamic operational conditions. Omni Design's DAC IPs offer configurability as matched I/Q pairs or cohesive subsystems featuring integrated AFEs and digital interfaces. With support across multiple advanced process nodes, these solutions are engineered to integrate smoothly alongside other high-performance components, ensuring they meet the stringent requirements of modern data-centric and communication systems.
The CC-205 Wideband CMOS Rectifier is designed for seamless integration with antennas, required for full or half-wave rectification. Its engineering ensures minimal signal reflection with an impressive low S11 return loss of -40dB, allowing efficient power transfer and utilization. This component excels in reducing the complexity of RF designs by eliminating the need for additional matching networks, thus streamlining the signal management process. It's crafted for applications demanding highly efficient power handling from RF inputs, marking its place in advanced communication systems searching for top-tier performance.
The Digital to Analog (DAC) IP from Analog Circuit Works focuses on power efficiency while ensuring robust performance tailored to specific bandwidth requirements. Optimized for various applications, these DAC solutions excel in load driving capabilities, offering high precision and stability in conversion processes.\n\nTheir DAC IP is known for exceptional performance, tailored to meet specific customer needs, offering solutions with various resolutions and maximum sample rates suitable for diverse applications. This customization ensures significant improvements over traditional designs, especially in environments where exacting standards are necessary.\n\nThrough Analog Circuit Works' DAC IP, clients gain access to cutting-edge technology that enhances their system designs, providing high-quality analog output with minimal power consumption, thus optimally balancing performance with energy efficiency.
The Swift™ DAC ODT-DAC-6B1G-28HPCT is a high-performance digital to analog converter that features a current-steering architecture for efficient data handling and minimal power utilization. Operating at up to 1GSPS, this 6-bit DAC is crafted for high-resolution applications that require reliable data transmission and conversion. Based on a 28nm high-performance CMOS process, the ODT-DAC-6B1G-28HPCT is designed to deliver exceptional noise performance with very low power needs, perfectly aligning with the stringent demands of wireless communication systems and advanced signal processing applications. This balance ensures that the DAC supports high throughput capabilities while maintaining signal fidelity. Its high-speed characteristics and efficient power management make it suitable for incorporation into a broad spectrum of system architectures, ensuring versatile applicability across various industries. Whether deployed in telecom networks or automotive electronic systems, this DAC offers a robust solution for high-performance, energy-efficient data conversion challenges.
RIFTEK's 2D Optical Micrometers are specialized for inline non-contact batch measurements, offering unparalleled precision in assessing the linear dimensions, angles, and profiles of engineered components. Leveraging the shadow measurement principle, these micrometers ensure consistent and accurate data collection even at high speeds. The RF657.2D series shines with its extended range and rapid measurement rates, ideal for applications requiring detailed analysis at high throughput. Its design supports robust operations under varying conditions, minimizing downtime and maximizing productivity. The RF656.2D series offers an affordable entry without compromising on precision, catering to industries where budget constraints demand efficient yet thorough measurements. Optimized for real-time integration into production lines, these units provide versatile connectivity options, including Ethernet and 1000 Mbps interfaces, ensuring seamless data flow for process automation and quality control. Their resilient construction, combined with advanced environmental resistance, equips them to thrive in challenging manufacturing environments while maintaining top-level accuracy and repeatability.
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 JDA1 is a versatile DAC core cell, designed for high-fidelity audio processing. It integrates a delta-sigma DAC with a PLL, eliminating the need for external clock generation by deriving all necessary sampling clocks from a 27MHz input. The JDA1 processes digital PCM inputs from 16 to 24 bits wide, supporting various standard and custom audio sample rates, including 96kHz. Its efficient silicon use requires just 0.3 to 0.4 sqmm, adapting seamlessly to scaling digital IC technologies.
The C100 is a highly integrated, low-power IoT SoC chip designed to implement control and interconnection functionalities. It incorporates an advanced 32-bit RISC-V CPU, clocked at up to 1.5GHz, with embedded RAM and ROM for enhanced computational efficiency and capability. This chip integrates multiple transmission interfaces including Wi-Fi, and features components such as ADC, LDO, and temperature sensors, making it suitable for a broad range of IoT applications. Designed to facilitate simpler, faster, and wider application development, the C100 aims to offer high efficiency processing capabilities.
Designed to meet the rigorous demands of modern electronics, Advanced Silicon's High-Voltage Integrated Circuits are pivotal in applications involving complex switching devices. These ICs include versatile drivers and DACs that are essential for interfacing with thin-film technologies such as TFT and MEMS devices. They ensure precise voltage control over various capacitive loads, making them indispensable for applications such as flat-panel displays and complex X-ray detectors. The high-voltage line drivers are known for their adaptability across a multitude of display technologies, including LCD, OLED, and micro-LED systems, while maintaining robust radiation-hardness qualities crucial for specific industrial applications. Available in high pin counts, these ICs can support up to hundreds of output channels, a necessary feature for advanced display and detection systems. By providing DACs with extensive resolution options, these ICs facilitate the digital-to-analog conversion crucial for handling large and delicate pixel arrays, ensuring exact voltage application across panels. These capabilities establish Advanced Silicon’s High-Voltage ICs as an integral component of cutting-edge display and detection technology, contributing significantly to the efficiency and accuracy of electronic systems.
Crafted with next-generation digital television technology in mind, the SL 300X Universal Demodulator offers a compact and sophisticated solution for demodulating broadcast signals. As a universal demodulator, this IC addresses the needs of contemporary DTV and mobile broadcasting systems, accommodating a broad spectrum of modulation techniques. The SL 300X distinguishes itself with robust performance under varying signal conditions. It supports a swift adaptation to environmental changes, ensuring the highest quality in signal demodulation processes. The incorporation of software definability allows this demodulator to remain relevant in rapidly evolving tech ecosystems. Saankhya Labs prioritizes efficiency, integrating low-power consumption into the SL 300X's design. This quality extends its usage across a multitude of operational scenarios from portable devices to large-scale broadcast equipment. By using this demodulator, engineers can expect reliable, high-quality video and audio outputs, ensuring audience satisfaction across all platforms.
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.
Designed for the demands of high-speed data communications, the RT923 by RafaelMicro comprises a 10Gbps Trans-Impedance Amplifier (TIA). This critical component excels in optical or network communication systems, where it converts optical signals into electrical ones with remarkable efficiency and minimal noise.
The VR-3V3-1V2-1-55-U voltage regulator is an ultra-low-power design, adeptly converting a 3.3V input to a stable 1.2V output. Utilizing UMC's advanced 0.06 μm technology, this regulator can handle up to 1mA of output current, making it optimal for applications requiring stringent power efficiency and stability. With its high precision and efficiency, the VR-3V3-1V2-1-55-U caters to a variety of power-sensitive applications, ensuring consistent performance even under dynamic conditions. The regulator's Power Supply Rejection Ratio (PSRR) of 40 dB ensures minimal output voltage noise, making it especially valuable in noise-sensitive environments. The compact form factor of this voltage regulator, combined with its robust performance features, makes it ideal for integration into portable and miniaturized electronic systems. Its low quiescent current guarantees prolonged battery life, thus supporting the longevity and reliability of the electronic systems it powers.
The 10-bit Dual Digital-to-Analog Converter (DAC) from RafaelMicro is capable of operating at 80 Mega-samples per second (Msps). It is designed for applications that require fast and accurate digital-to-analog conversion, such as video processing or communication systems.
Omni Design Technologies' Swift™ Low Power Data Converter IP is a breakthrough in high-performance, low-power data processing for diverse applications, particularly within the telecommunications, automotive, and data networking sectors. This innovative data converter IP set is engineered to deliver unparalleled performance in system-on-chip (SoC) implementations, providing essential data conversion capabilities that power next-generation networks and devices. Designed with efficiency and adaptability in mind, it enables high-speed data transmission and signal processing with reduced power requirements, making it ideal for high-demand systems like those found in 5G networks and advanced automotive electronics. This IP series exploits Omni Design's proprietary technology to offer a robust solution to the complexities of integrating multiple digital and analog processes within a single chip. The Swift™ Data Converter IP stands out with its ability to handle diverse signal types and frequencies, aligning perfectly with the needs of rapidly evolving sectors such as wireless communication and automotive system design. Continuing to build on its reputation for reliability and high-performance metrics, Swift™ Data Converter IP also incorporates sophisticated calibration tools to maintain accuracy and reduce signal distortion. This ensures that the end devices it powers are both precise and efficient, helping to further the capabilities of modern smart technologies.
KeyASIC's Fundamental IP offerings include a versatile hybrid standard cell library specifically crafted for IoT and battery-efficient applications. This comprehensive collection comprises both foundry-sponsored memory IPs and general-purpose I/O options such as LVCMOS and programmable 5V-tolerant interfaces. For more specialized applications, users can utilize special-purpose I/Os like SSTL, HSTL, PCI, and others. To ensure robust power management, this IP suite features various regulators, low-dropout (LDO) regulators, cap-less LDOs, and other power components like DC-DC converters, PLLs for frequency synthesis, and crystal and RTC oscillators. This foundational set of IPs supports a wide range of applications, and all components are optimized for high efficiency, making them suitable for diverse commercial and industrial uses.