All IPs > Analog & Mixed Signal > RF Modules
In the dynamic world of semiconductor IPs, RF Modules play a crucial role in ensuring seamless wireless communication across a wide range of devices. RF, standing for Radio Frequency, refers to the technology that utilizes electromagnetic spectrum frequencies to transmit data wirelessly, thereby eliminating the need for physical connection and enabling greater flexibility and convenience in electronic systems. Our RF Modules category within the Analog & Mixed Signal primary category consists of a diverse collection of products designed to facilitate this wireless interaction by offering effective solutions for complex radio frequency circuits.
The applications of RF Modules semiconductor IPs are vast and versatile, encompassing a multitude of industries including consumer electronics, telecommunications, automotive, and industrial systems. In consumer electronics, RF modules are crucial for developing devices such as smartphones, smartwatches, and wireless earbuds, where they help in managing and optimizing data transmission over wireless networks. Telecommunications heavily rely on these modules for building robust infrastructure, enabling efficient data handling in mobile networks and satellite communications.
Moreover, in the automotive sector, RF modules contribute to the advancement of vehicle connectivity technologies, supporting features like keyless entry, tire pressure monitoring systems, and vehicle-to-everything (V2X) communication. Similarly, in the industrial domain, these modules are fundamental components in systems that require reliable long-distance wireless communication, such as in smart grid applications and remote monitoring systems.
Within the RF Modules category, you will discover a comprehensive selection of semiconductor IPs tailored to meet various design specifications. These include components that support different frequency bands, offer varying levels of integration, and are designed to comply with a range of communication standards and protocols. Whether you need baseband processors, RF transceivers, or complete system-on-chip solutions, our RF Modules in Analog & Mixed Signal provide ample choices for engineers and designers looking to enhance the performance, reliability, and functionality of wireless-enabled products.
The Vantablack S-VIS Space Coating is engineered for space applications, where it serves as an advanced stray light suppression and blackbody coating. Suitable for use on satellite instruments, this coating helps to minimize the light reflection that can occur in space environments, thereby ensuring higher accuracy in optical measurements and instrument calibration. Vantablack S-VIS offers exceptional spectral absorption from ultraviolet through to the terahertz range, crucial for a variety of optical systems. Its lightweight and highly absorbent properties allow for more compact baffle and calibration systems without compromising performance. The coating has demonstrated reliability in space missions, offering consistent absorption over extended periods. This coating is particularly critical for optical systems that operate under the challenging conditions of space, including variations in temperature and pressure, as well as the intense radiation environment. It has been applied successfully in low earth orbit operations, enhancing the operability of instruments by reducing system complexity and improving the accuracy of optical sensors.
The RIOT100 sensor by NOVELIC is a sophisticated device focused on accurate human presence detection through advanced radar technology. Engineered to be highly sensitive, this sensor excels in detecting micromovements, whether occupants are in motion or stationary. This capability makes it particularly useful for energy-saving applications in smart lighting and IoT systems. Operating efficiently across diverse environments, the RIOT100 can be integrated invisibly behind materials like glass or wood, making it adaptable for both residential and commercial applications. Its customizable detection range, up to 25 meters, allows it to ignore irrelevant movements, focusing on designated areas to maintain privacy and confidentiality in sensitive locations. With built-in signal processing, the RIOT100 provides immediate feedback and requires no external data processing units, streamlining installation and functionality. Such features enable the sensor to serve in high-precision applications like security systems, hospitality, and public spaces, ensuring both reliability and efficiency across a broad spectrum of uses.
Designed for high-speed transmission, the 16x112G Tx Chiplet showcases superior integration with 16 channels, each operating at 112Gbps. It includes a modulator and driver within a single silicon unit, optimized for optical communication systems requiring high-speed, high-bandwidth data transfer. This sophisticated chiplet ensures seamless modulation of optical signals, supporting efficient driver control and optimized data transmission. The integrated design simplifies system architecture, reducing the overall footprint while maintaining exceptional reliability and performance. Its built-in digital control aids in managing complex signal processing requirements, suitable for diverse applications within optical networking infrastructures. Verifying its design through silicon-proven processes assures users of its capability to meet rigorous industry standards. The application of this chiplet spans high-speed data centers, telecommunications networks, and beyond, where its efficiency and performance are indispensable. The innovation behind its creation reflects Enosemi's dedication to advancing optical technology, offering clients robust and reliable tools to meet current and future communication needs.
EW6181 is an IP solution crafted for applications demanding extensive integration levels, offering flexibility by being licensable in various forms such as RTL, gate-level netlist, or GDS. Its design methodology focuses on delivering the lowest possible power consumption within the smallest footprint. The EW6181 effectively extends battery life for tags and modules due to its efficient component count and optimized Bill of Materials (BoM). Additionally, it is backed by robust firmware ensuring highly accurate and reliable location tracking while offering support and upgrades. The IP is particularly suitable for challenging application environments where precision and power efficiency are paramount, making it adaptable across different technology nodes given the availability of its RF frontend.
The ORC3990 SoC is a state-of-the-art solution designed for satellite IoT applications within Totum's DMSS™ network. This low-power sensor-to-satellite system integrates an RF transceiver, ARM CPUs, memories, and PA to offer seamless IoT connectivity via LEO satellite networks. It boasts an optimized link budget for effective indoor signal coverage, eliminating the need for additional GNSS components. This compact SoC supports industrial temperature ranges and is engineered for a 10+ year battery life using advanced power management.
The CT25203 represents a key building block designed for creating PMD transceivers compliant with the OA TC14 specification. It partners seamlessly with the CT25205 to communicate over the OA 3-pin interface with host MCUs, Zonal Gateway Controllers, or Ethernet switches integrated with a 10BASE-T1S digital PHY. This IP core supports high-performance transceivers encased in compact 8-pin packages. Manufactured with high-voltage process technology, it ensures top-tier electromagnetic compatibility. This capability makes the CT25203 an ideal choice for industrial and automotive applications where reliable communication and exceptional EMC performance are crucial.
The THOR platform is a versatile tool for developing application-specific NFC sensor and data logging solutions. It incorporates silicon-proven IP blocks, creating a comprehensive ASIC platform suitable for rigorous monitoring and continuous data logging applications across various industries. THOR is designed for accelerated development timelines, leveraging low power and high-security features. Equipped with multi-protocol NFC capabilities and integrated temperature sensors, the THOR platform supports a wide range of external sensors, enhancing its adaptability to diverse monitoring needs. Its energy-efficient design allows operations via energy harvesting or battery power, ensuring sustainability in its applications. This platform finds particular utility in sectors demanding precise environmental monitoring and data management, such as logistics, pharmaceuticals, and industrial automation. The platform's capacity for AES/DES encrypted data logging ensures secure data handling, making it a reliable choice for sectors with stringent data protection needs.
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 Dual-Drive™ Power Amplifier FCM1401 exemplifies advanced engineering in power amplification, designed specifically for extreme efficiency in wireless communication devices. Operating at a center frequency of 14 GHz, it boasts a sophisticated architecture that minimizes silicon area while enhancing performance metrics. One of the standout features of the FCM1401 is its impressive core drain efficiency, which reaches up to 62%, offering significant power savings and extended battery life for end users. Such efficiencies are particularly crucial in mobile devices, where power remains a critical resource. Moreover, this power amplifier features a dual-stage design to facilitate better signal strength and lower transmission losses. With an optimally configured supply voltage range, the FCM1401 performs without efficiency bottlenecking, crucial for systems with constrained power budgets. Its meticulous construction results in an efficiency at device output around 70%, allowing it to outperform competitors across various metrics. These enhancements not only make the FCM1401 ideal for mobile and satellite communications but also align perfectly with initiatives to lower telecommunication costs through energy-efficient technology. Supported by a drain efficiency that peaks even under full load conditions, Falcomm’s FCM1401 assures users of reliability under diverse operational scenarios. The assurance of minimal loss in complex QAM scenarios further underscores its potential for diverse communication applications. This exemplary power amplifier serves as a testament to Falcomm's commitment to innovation, combining unprecedented efficiency with practical applications in everyday technology.
The 802.11ah HaLow Transceiver from Palma Ceia is optimized for IoT and mobile device applications demanding long battery life and extended range. Operating under the Wi-Fi HaLow standard, the transceiver provides minimal power consumption while ensuring significant connectivity distances. By supporting a variety of modulation bandwidths—1 MHz, 2 MHz, and 4 MHz—it remains highly adaptable to varying application needs. A standout feature of this transceiver is its low-noise, direct-conversion receiver which supports a highly linear RF path and integrated DC correction, ensuring clean signal reception even in challenging environments. The use of a balanced architecture in the receiver allows for processing a range of signal strengths, which enhances communication reliability over extended distances. With comprehensive interface support, including options for SPI, JTAG, UART, and I2C, the transceiver is ready for integration into a multitude of electronic systems. Its capabilities make it ideal for a range of IoT applications, from building security systems to smart metering and environmental sensing solutions, providing the connectivity backbone these applications require while adhering to stringent power efficiency requirements.
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.
Functioning as a comprehensive cross-correlator, the XCM_64X64 facilitates efficient and precise signal processing required in synthetic radar receivers and advanced spectrometers. Designed on IBM's 45nm SOI CMOS technology, it supports ultra-low power operation at about 1.5W for the entire array, with a sampling performance of 1GSps across a bandwidth of 10MHz to 500MHz. The ASIC is engineered to manage high-throughput data channels, a vital component for high-energy physics and space observation instruments.
EnSilica’s eSi-Analog suite offers a broad array of Analog IP solutions essential for integrating analog functions into custom ASIC and SoC devices. Proven across various process nodes, these solutions are renowned for their performance, power efficiency, and adaptability to customer specifications, thereby expediting time-to-market and lowering costs. With an extensive range of easy-to-integrate IPs, eSi-Analog encompasses high-performance blocks like oscillators, SMPSs, PLLs, LDOs, and more, each optimized for low power consumption and high resolution. The flexibility of this IP suite allows for adaptation to various application needs, supporting industries as diverse as automotive and healthcare with critical analog capabilities. Specialized in enabling SoC platforms with robust analog interfaces, this IP package features components like temperature sensors and ultra-low power radios. The solutions in eSi-Analog are designed to integrate seamlessly across major foundry technologies, offering a competitive edge for customers seeking to enhance system performance with reliable analog solutions.
The PLL12G, serving as a Clock Multiplication Unit, is engineered to generate clock outputs in the 8.5GHz to 11.3GHz range, complementing a host of transceiver standards like 10GbE and OC-192. It operates with low power consumption, courtesy of IBM's 65nm process, making it suitable for various clocking modes crucial in phase-locked loop systems. Its diverse functionality ensures it's integral to telecommunications infrastructures where multiple clocking modes, including FEC support, are required.
The XCM_64X64_A is a powerful array designed for cross-correlation operations, integrating 128 ADCs each capable of 1GSps. Targeted at high-precision synthetic radar and radiometer systems, this ASIC delivers ultra-low power consumption around 0.5W, ensuring efficient performance over a wide bandwidth range from 10MHz to 500MHz. Built on IBM's 45nm SOI CMOS technology, it forms a critical component in systems requiring rapid data sampling and intricate signal processing, all executed with high accuracy, making it ideal for airborne and space-based applications.
The mmWave PLL is a sophisticated phase-locked loop tailored for millimeter-wave frequencies, playing a crucial role in high-frequency applications such as 5G and beyond. It delivers exceptional frequency stability and low phase noise, which are vital for maintaining signal integrity in advanced communication systems. This product is engineered to handle the complexities of mmWave spectrum, providing precise frequency control necessary for next-generation wireless networks. Its capability to operate at high frequencies makes it an ideal fit for telecom infrastructure and consumer devices aiming to benefit from the expanded bandwidth of mmWave technology. The mmWave PLL is optimized for integration into compact designs, reducing overall system size while enhancing performance quality. By utilizing process technology that supports high-speed operations, the mmWave PLL ensures reliability and efficient energy use. With its precision engineering, the mmWave PLL is a critical component for companies looking to leverage mmWave spectrum advantages, offering the substantial benefits of improved data rates and connectivity. It is an essential element in RF module design, setting a new standard for high-frequency operation versatility across various sectors.
The DIV60G is a high frequency, fully differential frequency divider reaching up to 60GHz, ideal for sophisticated PLL applications and broadband measurement equipment. It includes an active balun with differential I/Q outputs, offering unparalleled frequency dividing capabilities. Its ultra-high frequency operating parameters are supported by a 0.18um SiGe process, making it particularly effective for use in environments requiring precision and low phase noise. Tailored for advanced industrial use, this divider provides substantial flexibility with differential inputs and outputs.
ArrayNav is a groundbreaking GNSS solution utilizing patented adaptive antenna technology, crafted to provide automotive Advanced Driver-Assistance Systems (ADAS) with unprecedented precision and capacity. By employing multiple antennas, ArrayNav substantially enhances sensitivity and coverage through increased antenna gain, mitigates multipath fading with antenna diversity, and offers superior interference and jamming rejection capabilities. This advancement leads to greater accuracy in open environments and markedly better functionality within urban settings, often challenging due to signal interference. It is designed to serve both standalone and cloud-dependent use cases, thereby granting broad application flexibility.
LightningBlu is a sophisticated mmWave connectivity solution explicitly designed for high-speed rail environments. This advanced system offers continuous, on-the-move multi-gigabit connectivity between trackside infrastructure and trains, ensuring seamless internet access, entertainment services, and real-time updates for passengers. Operating within the 60 GHz spectrum and compliant with IEEE 802.11 ad and ay standards, LightningBlu provides robust and efficient wireless communication for the rail industry. The LightningBlu system's standout feature is its ability to maintain reliable service even at speeds of over 300 km/h, enhancing the passengers' travel experience with fast and dependable connectivity. Its architecture allows for dynamic interaction between train-mounted and trackside units, facilitating uninterrupted data transfer essential for modern transport needs. This product not only addresses current connectivity requirements but also positions itself as a future-proof solution adaptable to evolving technological landscapes. Adopting a highly functional design, LightningBlu effectively eliminates the dependency on cabled infrastructure, making it an ideal choice for upgrading existing rail systems or deploying in new corridors. By supporting innovative services and enhancing passenger contentment, LightningBlu contributes significantly to modernizing the rail sector, aligning with the increasing push towards digital transformation in mass transit.
ParkerVision's Direct-to-Data (D2D) Technology marks a transformative development in RF communication, significantly enhancing the performance of modern smartphones and wireless devices. This innovative technology replaces the century-old super-heterodyne downconverter with a new RF downconverter that operates efficiently within CMOS architectures. D2D allows RF receivers to connect more seamlessly across global bands while processing high data rates essential for today's media and communication needs. D2D RF receivers built on ParkerVision technology minimize power usage while delivering fast data speeds, substantially contributing to the functionality and efficiency of modern smartphones. These receivers are capable of handling a wide spectrum of data rates from streaming video to large data transfers, thanks to their high-performance design capable of managing a range of signal strengths from various distances with cellular towers. This patented technology plays a crucial role in the smartphone revolution, with its incorporation leading to smarter, faster devices. These developments are enabled by a precise downconversion mechanism that transforms high-frequency RF signals into data-efficient formats. The D2D technology reduces the traditional noise and signal loss, making it a cornerstone in the advancement of mobile and IoT device communication strategies.
The pPLL08 Family is a series of all digital RF Frequency Synthesizer PLLs designed to deliver exceptional performance in RF applications, such as 5G and WiFi, operating at frequencies up to 8GHz. This family features industry-leading jitter performance, less than 300fs, and a compact footprint, making it well-suited for use as a local oscillator or for clocking high-performance ADCs/DACs. Its versatility allows it to excel in demanding applications where size, power efficiency, and precision are critical priorities, supporting a wide array of wireless standards within a compact and low-power package. The pPLL08N series, part of this family, supports fractional multiplication with frequencies up to 8GHz and integrates seamlessly into systems as a clock source. It is specifically built for usage in RF ADC/DAC clocking, 5G, LTE radio (3GPP), WiFi Radio (802.11ax), SerDes, and optical transceiver applications. The pPLL08 Family is optimized for multi-PLL configurations within single systems, thus enabling a high level of flexibility and efficiency in design. The series is available in several technologies including UMC 40LP, GlobalFoundries 22FDX, Samsung 8LPP, Samsung 14LPP, GlobalFoundries 12LPP/14LPP, and TSMC N6/N7. This adaptability ensures that engineers can integrate the PLL into a wide range of semiconductor environments, providing a robust solution to meet varied design challenges effectively.
The Dynamic PhotoDetector (DPD) by ActLight specifically designed for smartphone applications marks a considerable advancement in mobile light sensing technology. This sensor is crafted with enhanced sensitivity and efficiency, capable of adjusting its operational parameters dynamically based on ambient light conditions. It ensures the optimum performance of smartphone features reliant on light sensing, such as automatic screen brightness adjustment and camera functionalities. Notably, the DPD achieves this while maintaining a lower power consumption profile than conventional alternatives, which is a significant advantage for today's power-hungry smartphones that demand long battery life. Its state-of-the-art design encapsulates high-performance metrics in a small, cost-effective package, allowing manufacturers to integrate it into devices without substantial adjustments in design and costs. This technology not only improves user experience by providing smoother, more responsive control over light-related smartphone features but also supports the burgeoning trend towards more eco-friendly, energy-efficient consumer electronics, reducing the overall energy footprint of modern mobile devices.
The MVDP2000 Series showcases a line of highly sensitive differential pressure sensors designed for precision and robustness in demanding environments. These sensors apply a proprietary capacitive sensing technology that ensures digital calibration across temperature and pressure variables, thus enhancing accuracy and reliability. With a compact size and power efficiency, the MVDP2000 sensors are ideal for applications requiring fast response and low power usage, such as portable and OEM devices. Their range of use includes respiratory equipment, gas flow instruments, and pressure monitoring systems in various industries. These sensors provide quick analog and digital outputs with resolutions between 15 to 21 bit, maintaining an error band of less than 1% FS. Their broad operating range and low power draw further bolster the sensors’ applicability, catering especially to consumer and medical industries.
As part of the advanced communication toolkit, the DSER12G addresses the need for robust data/clock recovery and deserialization at rates between 8.5Gb/s to 11.3Gb/s. Prominent in 10GbE, OC-192, and equivalent setups, it boasts ultra-low power design principles grounded in IBM's 65nm technology. Supporting high noise immunity and compact integration, it is a cornerstone in systems requiring efficient data management and communications interfaces across various digital infrastructures.
The EAMD12G serves as a modulator driver for EA/MZ applications, tailored specifically to drive up to 11.3Gb/s in fiber optic communications. It features programmable output voltage swing and DC offset adjustment, with built-in monitoring capabilities to ensure precision in modulation tasks. Integrated within the robust TowerJazz 0.18um SiGe process, it is adept for high-frequency operation necessary for effective data transmission in modern broadband setups.
Designed for high-capacity data transfer over fiber optic networks, the SER12G facilitates 32:1 serialization for robust telecommunications. Capable of sustaining data rates from 8.5Gb/s to 11.3Gb/s, this module is essential for SONET/SDH and 10GbE operations, embracing IBM's 65nm CMOS technology. The design boasts low power requirements and integrates CMU and frac N PLL, making it suitable for both line and host side transmission, effectively enhancing data throughput and signal integrity.
The FCM3801-BD extends Falcomm’s exceptional legacy in dual-drive™ power amplification, offering unparalleled efficiency and performance at a center frequency of 38 GHz. This power amplifier is engineered to deliver unprecedented amplification capabilities with a focus on reducing energy wastage. As part of Falcomm's suite of next-generation amplifiers, the FCM3801-BD empowers telecommunications with its precise and reliable performance metrics, engineered for the most sophisticated communication systems. Thanks to its unique integration of GaAs and CMOS technologies, the FCM3801-BD offers outstanding energy performance, making it an ideal choice for resource-intensive applications. Its high modularity and ease of integration allow it to seamlessly fit into existing systems while offering robust improvements in both output and operational efficiency. These characteristic enhancements are crucial for developers and engineers focused on achieving best-in-class performance in signal-intensive applications. The FCM3801-BD is engineered with an eye towards the future, accommodating the evolving demands of telecommunications, and space communication technologies. This power amplifier helps to minimize operational costs through effective energy utilization and is well-poised to meet the efficiency challenges of tomorrow's wireless devices. Falcomm’s commitment to developing such products ensures they remain at the forefront of innovation, setting new standards in power amplification across a variety of platforms.
The MIPITM V-NLM-01 is a specialized non-local mean image noise reduction product designed to enhance image quality through sophisticated noise reduction techniques. This hardware core features a parameterized search-window size and adjustable bits per pixel, ensuring a high degree of customization and efficiency. Supporting HDMI with resolutions up to 2048×1080 at 30 to 60 fps, it is ideally suited for applications requiring image enhancement and processing.
The VoSPI Rx for FLIR Lepton IR Sensor is designed to cater to infrared sensor needs for various applications. Specially configured to support the FLIR Lepton sensor, this receiver facilitates effective and precise data handling of infrared signals, crucial in environments demanding high thermal accuracy. It provides real-time processing capabilities, aligning with the rigorous demands of security and monitoring applications. This receiver excels in maintaining data integrity, ensuring that the thermal data transmitted across platforms is of the highest accuracy. Its sophisticated engineering allows it to work seamlessly with other system components, enhancing system performance and reliability. The receiver is integrated with features that boost signal processing while minimizing latency, providing a seamless operational environment. This ensures that users can rely on it for consistent performance across various industry applications, boosting both efficiency and reliability.
The CC-205 Wideband CMOS Rectifier stands out for its wide frequency rectification range, effectively working from 6 MHz to 5.8 GHz. This rectifier is capable of handling input power signals from -18 dBm up to +33 dBm, whilst maintaining impressive conversion efficiency between 40% to 90%. Without the need for a matching network, it directly interfaces with antennas, facilitating efficient power transfer. Its design includes a low S11 return loss of -40 dB, ensuring optimal power reception and usability in applications requiring broad frequency operation.
The MIPITM SVRPlus2500 provides an efficient solution for high-speed 4-lane video reception. It's compliant with CSI2 rev 2.0 and DPHY rev 1.2 standards, designed to facilitate easy timing closure with a low clock rating. This receiver supports PRBS, boasts calibration capabilities, and offers a versatile output of 4/8/16 pixels per clock. It features 16 virtual channels and 1:16 input deserializers per lane, handling data rates up to 10Gbps, making it ideal for complex video processing tasks.
CoreVCO offers a highly customizable voltage-controlled oscillator crucial for generating precise frequencies in communication systems. With its robust design, CoreVCO ensures minimal phase noise and offers exceptional tuning capabilities, making it an indispensable component in RF and mixed-signal applications. It is tailored to support a broad frequency range, aligning with the diverse requirements of modern technological applications. The product is designed to operate efficiently across various environments, providing reliable performance in both consumer electronics and industrial settings. Its adaptability enables easy integration into complex systems, where precise frequency modulation is required. CoreVCO’s optimized power efficiency and compact form factor make it ideal for portable and space-constrained devices, demanding a balance between performance and size. By ensuring stable operation across various temperatures and conditions, CoreVCO supports mission-critical applications where consistent performance is non-negotiable. Its wideband characteristics and high linearity distinguish it as a leading choice for engineers looking to enhance signal processing capabilities in their designs.
The MVUM1000 is a state-of-the-art ultrasound sensor array tailored for medical imaging applications. This linear array comprises up to 256 elements and is based on capacitive micromachined ultrasound transducers (CMUT), providing exceptional sensitivity and integrability with electronic interfaces. Boasting multiple imaging modes, such as time-of-flight and Doppler, these sensors can address a variety of medical diagnostic needs including point-of-care and handheld devices. The low power consumption combined with high sensitivity makes these sensors highly efficient for portable medical equipment. Functional across a wide range of frequencies, the MVUM1000 supports medical imaging with precision, offering device manufacturers flexibility in design with the possibility of integrating front-end electronics. It opens up new avenues for innovation in ultrasound technology while catering to ever-growing portable healthcare needs.
The DIV50G1 is a programmable prescaler operating up to 50GHz with various dividing coefficients. Its design caters to high-precision applications requiring careful frequency management and offers single-ended or differential inputs with differential outputs. This flexibility supports integration into complex PLL circuits and broadband measurement gear. The technological foundation is a robust 0.18um SiGe process, ensuring reliability and superior performance for advanced technological applications demanding frequency adjustability and precision.
The MIPITM CSI2MUX-A1F is an innovative video multiplexor designed to manage and aggregate multiple video streams effortlessly. It supports CSI2 rev 1.3 and DPHY rev 1.2 standards, handling inputs from up to four CSI2 cameras and producing a single aggregated video output. With data rates of 4 x 1.5Gbps, it is optimal for applications requiring efficient video stream management and consolidation.
Sentire Radar represents a pioneering range of intelligent radar systems that can detect precise range and speed, enabling sophisticated spatial mapping through advanced signal processing. Used extensively in perimeter surveillance and autonomous vehicle navigation, Sentire Radar operates efficiently across various frequency bands, including 24 GHz and 77/79 GHz for traffic applications. The systems incorporate multi-channel antennas and high-frequency circuits, managed by onboard digital boards that process radar signals and data classification using AI methods. As a complete solution, Sentire Radar ensures robust signal interpretation and accurate real-time response across multiple environments.
UWB Technology & IP features advanced ultra-wideband solutions designed for precision connectivity in short-range communications. Offering high data efficiency and robust interference resistance, UWB is ideal for applications such as indoor positioning and short-range radar. TES's UWB technology is designed to seamlessly integrate into various systems, enhancing connectivity and interaction in complex network environments.
ActLight's Dynamic PhotoDetector (DPD) for Smart Rings introduces a new dimension of light sensitivity tailored to the intricacies of ring-sized wearable technology. This innovation focuses on maximal efficiency and minimal size, offering wearers enhanced interaction and monitoring capabilities through improved light detection. Perfectly suited for devices requiring continuous power management, the DPD allows smart rings to maintain functionality over extended periods without draining their compact power sources. The sensor’s ability to adjust dynamically to ambient lighting conditions also enhances its utility in diverse environments, providing accurate readings no matter the surrounding light conditions. This feature is particularly beneficial for applications in fitness and health tracking, where accurate data collection is paramount. Additionally, integrating seamlessly into a ring form factor, the DPD supports the creation of elegant, minimalist designs that consumers in the smart jewelry market seek. The DPD technology presents an ideal solution for smart rings that need to deliver robust functionality, efficient power usage, and exquisite design all in one, ultimately enabling makers to craft next-generation smart jewelry that pushes the boundaries of what's possible in wearables.
Moonstone Laser Sources by Lightelligence provide cutting-edge photonic solutions aimed at facilitating advanced optical computing applications. These laser sources are tailored for high precision and efficiency, essential for tasks demanding robust photonic performance. The unique attributes of Moonstone make it suitable for integration into diverse technological frameworks where precision and reliability are paramount. As the backbone of optical computing, laser sources like Moonstone ensure that photonic applications achieve desired speed and accuracy, fostering greater innovation in photonics-driven technologies. With their focus on precision and application flexibility, Moonstone Laser Sources empower industries to explore new frontiers in photonics, supporting the evolution of next-generation computing technologies.
The second-generation MIPITM SVRPlus-8L-F is a high performance serial video receiver built for FPGAs. Complying with CSI2 revision 2.0 and DPHY revision 1.2 standards, it supports 8 lanes and 16 virtual channels, offering efficient communication with 12Gbps data throughput. This receiver comes with features like 4 pixel output per clock, calibration support, and communication error statistics, making it suitable for high-speed video transmission and processing applications.
Bridging complex data communication requirements, the SERDES12G offers comprehensive serialization/deserialization capabilities, supporting 32:1 and 1:32 operations at speeds of 8.5Gb/s to 11.3Gb/s. With robust low power features, its design leverages IBM's 65nm technology, vital for SONET/SDH and XFI protocols in modern telecommunication systems. By integrating CDR and CMU, it provides high performance and stability, ensuring seamless data handling across a wide array of applications.
ParkerVision's Energy Sampling Technology has revolutionized the paradigm of RF signal processing with an inventive approach for frequency down-conversion. Traditionally dominated by super-heterodyne techniques, which used high L.O. power to achieve sensitivity and linearity, these were not suited for low-power CMOS applications as well as modern integrated transceivers. Energy Sampling Technology provides the highest sensitivity and dynamic range required for modern receivers while enhancing selectivity and interference rejection. By eliminating RF signal division between I and Q paths, ParkerVision's technology helps in reducing power consumption and improving demodulation accuracy. It offers a compact and cost-effective solution feasible with CMOS technologies, allowing for the development of multimode receivers compatible with advancing CMOS geometries and power levels. The benefits span various transmission standards like GSM, EDGE, CDMA, UMTS, and LTE, making it relevant for devices such as handsets and embedded modems. This technology fundamentally shifts RF signal processing by using matched-filter correlators, enhancing the overall performance capabilities of direct conversion receivers. The elimination of redundant components reduces silicon area, and improved dynamic range lessens the need for external filters. This technology paves the way for a wide array of innovative applications across contemporary wireless ecosystems, thereby facilitating rapid technological leaps in the communication field.
The CurrentRF CC-100 Power Optimizer is central to the company's innovative energy harvesting technology, utilized in devices like the PowerStic and Exodus. This optimizer is engineered to be a fundamental component in intercepting digital noise currents and recycling them back into the system, effectively reducing operational power. It supports the enhancement of system battery life by up to 40%, serving as a critical device in power-conscious design strategies for integrated circuits and electric vehicles. The CC-100 ensures power savings when systems remain active, making it a vital tool for extending battery life in IC and systems design.
With an emphasis on performance, the MIPITM SVTPlus2500 is a robust 4-lane video transmitter adhering to CSI2 rev 2.0 and DPHY rev 1.2 standards. It facilitates timing closure with its low clock rating and supports PRBS for precise data management. The transmitter can handle 8/16 pixel inputs per clock and offers programmable timing parameters. Equipped with 16 virtual channels, this IP is engineered for high-speed video transmission.
The Dual-Drive™ Power Amplifier FCM2801-BD represents another leap forward in Falcomm's quest to redefine power efficiency in mmWave-based devices. Centered at 28 GHz, this power amplifier emerges as a pivotal component for next-generation wireless communication technology. The architecture of the FCM2801-BD is engineered to deliver industry-leading drain efficiencies, optimizing both power consumption and performance. It is notably characterized by its robust reliability and exceptional energy management capabilities, tailored for applications where performance excellence is paramount. With a core design that exploits the potentials of GaN and SiGe technologies, the FCM2801-BD ensures superior amplification with minimized energy wastage. Its sophisticated signal processing enhances device output without significant power blowouts. The advanced manufacturing processes adopted promise reduced manufacturing footprint, making it an ideal choice for highly compact and low-footprint technology designs. Engineered for space communications, wearables, and innovative telecommunication systems, the FCM2801-BD champions Falcomm’s vision of marrying exceptional performance with eco-friendly designs. This model’s dependability in high-demand scenarios complements its capability to lower operational expenses across communication systems internationally. In conclusion, the FCM2801-BD is not only a technological marvel from Falcomm but also a commitment to the ethos of sustainability and resource efficiency.
The DVB-C Modulator is specifically designed to perform modulations for head-end video and broadband data transmission systems, such as Cable Modem Termination Systems (CMTS). This modulator core is optimized for use in various cable modem test equipment and supports both point-to-point (PTP) and point-to-multipoint microwave radio links. It boasts compliance with the J83 standard modulation schemes, enhancing its flexibility and usability across different platforms.
The VCOMB12G is an advanced low noise multi-band LC voltage-controlled oscillator designed for sophisticated phase-locked loop applications, particularly in fiber optic systems. This oscillator offers a wide frequency range and supports multiple clocking modes, providing essential flexibility in cutting-edge communication systems. It is capable of integrating seamlessly into complex digital frameworks where accurate frequency tuning is crucial. Its design ensures minimal power consumption, promoting energy efficiency without sacrificing performance.
Designed for modern communication standards, the WiFi6, LTE, and 5G Front-End Module enhances connectivity in cellular and wireless networks. This sophisticated module operates across multiple frequency bands, specifically between 2.4 and 5-7 GHz, catering to a diverse range of communication protocols including WiFi6, LTE, and emerging 5G technology. Featuring integrated components such as low-noise amplifiers (LNAs), power amplifiers (PAs), and RF switches, this module significantly boosts signal reception and transmission efficiency while maintaining low power consumption. Aimed at improving data throughput and connectivity reliability, it supports seamless transitioning between different network types, which is crucial for devices like smartphones and IoT gadgets. Engineers have crafted this module to address the next-generation requirements of wireless communication by ensuring compatibility with global network specifications. Its deployment is essential in paving the way for devices that demand high-speed data, stable connections, and reduced latency, thus making it ideal for consumer electronics, telecommunication infrastructure, and advanced wireless applications.
The DVB-Satellite Modulator is a high-performance modulator core designed to adhere to DVB-S, DSNG, DVB-S2, and DVB-S2X satellite forward-link specifications. This versatile modulator core is engineered for both broadcasting and interactive applications, accommodating a variety of modulation schemes including (A)PSK. Its robust framework is capable of delivering efficient and reliable operations in challenging satellite communication environments. The modulator's design prioritizes support for advanced satellite communication standards, ensuring its place in future-ready satellite systems.
Optical Component Building Blocks by Enosemi comprise a suite of essential components engineered to streamline the creation of sophisticated optical systems. These building blocks include a variety of optical devices such as waveguides, modulators, and detectors, each designed to ensure seamless optical signal routing and processing. With a focus on reliability and integration, these components are developed through extensive testing and validation processes. They ensure high performance and compatibility, enabling the construction of efficient and scalable optical networks. By adopting these building blocks, developers can reduce design complexity and enhance system robustness. The versatility of these components allows them to be used across various sectors, including telecommunications, data centers, and imaging systems. Their innovative design supports rapid prototyping and deployment, offering clients a significant advantage in the fast-paced world of optical technology.
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