All IPs > Wireless Communication > UWB
Ultra-wideband (UWB) technology represents a breakthrough in wireless communication, where devices utilize a wide spectrum of frequencies for secure and efficient data transmission. UWB semiconductor IPs are critical components in developing these cutting-edge wireless solutions, enabling devices to operate with exceptional precision. These IPs support high data rates and are crucial for applications that require real-time data streaming and localization.
One of the most significant advantages of UWB semiconductor IPs is their ability to provide precise location and spatial awareness, making them indispensable in industries such as consumer electronics, automotive, and IoT. In consumer electronics, UWB technology allows for seamless connectivity with smart devices, ensuring fast and interference-free communication. Automotive applications benefit from UWB's precision in navigation and vehicular communication systems, enhancing safety and efficiency on the road.
In the realm of the Internet of Things (IoT), UWB technology facilitates high-speed, low-power communication necessary for smart home devices, industrial automation, and more. The robustness of UWB against interference from other wireless technologies makes it ideal for environments with dense wireless traffic. Moreover, UWB semiconductor IPs play a crucial role in enhancing security features due to their ability to operate with low probability of interception.
The range of products you will find within the UWB semiconductor IP category includes transceivers, modems, and baseband processors, each designed to harness the full potential of ultra-wideband technology. As UWB continues to evolve, innovations in semiconductor IPs will pave the way for more advanced and efficient wireless communication systems, ensuring that technology keeps pace with the needs of connectivity in modern applications.
The CANmodule-IIIx is an enhanced version of the traditional CAN controller, featuring an extensive set of 32 receive and 32 transmit buffers. This setup is particularly beneficial for applications demanding high-capacity data management and robust error handling. The module’s structure supports mailboxes with a prioritized arbitration mechanism, offering flexibility for advanced application-specific configurations.<br/><br/>Compliant with the CAN 2.0A/B standards and designed in an HDL that is adaptable to both FPGA and ASIC technologies, the CANmodule-IIIx includes on-chip SRAM to facilitate efficient data handling. It integrates seamlessly into ARM-based SoCs through its AMBA 3 Advanced Peripheral Bus, providing a high-performance, fully synchronous system interface.<br/><br/>Key features include single-shot transmissions, automatic RTR interrupt handling, and sophisticated message filtering capabilities that encompass ID, IDE, RTR, and initial data bytes. Outstanding for areas like aerospace and industrial automation, the CANmodule-IIIx ensures data integrity and responsiveness via its programmable interrupt controller and comprehensive test modes.
The eSi-Comms IP offers parameterizable and configurable solutions for modern air interface standards, such as Wi-Fi, LTE, and DVB. It features advanced DSP algorithms for synchronization, equalization, and modulation, thereby enhancing the robustness of communication links. Suitable for wireless sensor networks, remote metering, and broadcast applications, eSi-Comms delivers efficient transceiver designs optimized for power and area. Supported by C, SystemC, CUDA, and MATLAB libraries, it facilitates swift development and integration into existing systems, ensuring a reduced time-to-market and minimized risk.
The CANmodule-III is a sophisticated controller core that introduces a mailbox approach to CAN data handling. Conforming to the ISO 11898-1 standard, it boasts 16 receive buffers, each with a dedicated message filter, and 8 transmit buffers, featuring a prioritization system. This structure caters to advanced higher-layer protocols, making it ideal for applications requiring nuanced data management such as those in industrial automation or automotive communications.<br/><br/>Designed in a technology-independent HDL, it is compatible with both FPGA and ASIC platforms, leveraging on-chip SRAM for optimized performance. The integration with ARM-based SoC environments is facilitated by an AMBA 3 Advanced Peripheral Bus interface. This fully synchronous zero wait-state bus interface supports seamless connections to other system buses, thus enabling high throughput and low latency communications.<br/><br/>The CANmodule-III's robust architecture includes features like single-shot transmission, automatic RTR response management, and a comprehensive error capture system. The full suite of debugging capabilities includes loops and listen-only mode, ensuring that developers can maintain control over communication channels throughout the product lifecycle.
The CANmodule-IIx is a FIFO-based CAN controller designed for streamlined integration within FPGA and ASIC systems. This IP core complies fully with the CAN 2.0A/B standard and supports ISO 11898-1 compliance, making it a reliable choice for various communication needs in automotive and industrial applications.<br/><br/>Incorporating advanced message filtering, the CANmodule-IIx is equipped with three fully programmable filters, alongside a 32-message receive FIFO and a 16-message transmit FIFO. This allows the module to efficiently process and prioritize a wide range of messages, bolstered by a high-priority transmit buffer that can bypass the traditional FIFO path for critical communications.<br/><br/>Integration into ARM-based SoCs is facilitated via its AMBA APB interface, allowing seamless connectivity within complex system architectures. The CANmodule-IIx's design supports testing and debugging capabilities, including loopback modes and a dedicated SRAM-based message buffer, ensuring reliability and ease of use across its deployment.
Great River Technology's HOTLink II Product Suite is designed to support high-speed serial communication applications. This suite focuses on enabling reliable and efficient data transmission across various mission-critical platforms. It leverages technologies well-suited for environments demanding robustness and precision, such as infrared sensors and optical camera systems. The HOTLink II suite aids engineers in interfacing and implementing solutions that require high-throughput and low-latency performance characteristics. This suite, continuing to support existing FC-AV applications, ensures these systems can handle new challenges in fast-paced aerospace and defense sectors. The suite’s design tools and components are optimized for seamless integration into existing systems, facilitating the transition from legacy to cutting-edge technologies.
The VoSPI Rx for FLIR Lepton IR Sensor by BitSim NOW is tailored for capturing and managing infrared sensor data effectively. Designed to work with Xilinx-7 platforms, this IP is aimed at applications requiring precise thermal imaging and data processing. It optimizes the data acquisition process by ensuring successful and efficient data reception from infrared sensors, crucial in fields like surveillance, medical imaging, and industrial automation. This receiver is an essential component for those looking to integrate advanced thermal sensing capabilities into their technology solutions, offering robust performance and reliability.
The DCAN XL is an innovative CAN bus controller IP core that marks a significant advancement in automotive network communication. This core supports a wide spectrum of communication protocols, effectively bridging the gap between established technologies like CAN FD and high-speed protocols akin to 100Mbit Ethernet. With data rates peaking at 20 Mbit/s, the DCAN XL IP core transforms conventional automotive communications into a much more robust and faster solution. One of the standout features of the DCAN XL core is its dual-transceiver capability, incorporating both standard CAN transceivers for bit rates under 10Mbps and CAN SIC XL transceivers for higher bit rates, thereby ensuring comprehensive support for varied network conditions. This makes it particularly suitable for integration within automotive networks that require adaptability across different communication speeds and protocols, allowing seamless transition and interaction among various system components. The DCAN XL is not just about high speed and versatility; it also emphasizes compatibility, conforming fully to the ISO 11898-1:2015 standard. This assures seamless integration with existing network architecture, providing manufacturers with a reliable solution for advanced automotive applications. Its design fosters efficient and error-free communication across various networks, positioning it as a critical component for next-generation automotive technologies.
The Waves Dragonfly platform is a sophisticated IP solution designed to integrate full NB-IoT and GNSS support into smart IoT devices. It provides extensive features that cater to the needs of the cellular IoT market, offering embedded GPS capabilities for precise geolocation and tracking. With a robust, flexible architecture, this platform can support multiple standards for wide application in various IoT projects.
Wireless Sensor Modules by Granite SemiCom are designed to provide high flexibility and extended range for IoT applications. Utilizing LoRa transceivers, these modules operate over long distances, making them suitable for environments where connectivity over vast areas is required. Their design is optimized for battery efficiency, ensuring long operational lifetimes with low power consumption. These modules also support over-the-air updates, enhancing their functionality and adaptability in dynamic settings. With built-in encryption, they offer secure wireless communication, crucial for safeguarding data integrity across networks.
The Bluetooth Low Energy (BLE) Wireless Sensor Network Library is a versatile suite of software tools that simplifies the implementation of BLE-based wireless networks. Designed for low-power applications, this library supports the creation of efficient and scalable sensor networks suited for environmental monitoring, industrial automation, and smart homes. By enabling robust communication between devices while minimizing power consumption, it extends the operational life of sensor networks. This library is essential for developers looking to integrate BLE technology into their IoT solutions, providing a comprehensive framework that supports rapid development and deployment.
The 802.15.4 Transceiver Core is a compact and efficient solution tailored for wireless personal area network applications. Designed to support the IEEE 802.15.4 standard, it facilitates high-level communication for devices such as Zigbee and other low-rate wireless networks. This core is essential for applications demanding low power and reliable wireless connectivity. Utilizing advanced digital signal processing (DSP) techniques, the transceiver core enhances communication link quality and data integrity. Its adaptive RF interface ensures compatibility and efficient operation across various applications, including smart metering, home automation, and industrial control. With its low power consumption, the core is ideal for battery-operated devices, supporting extended usage duration and efficient energy management. The transceiver's architecture allows it to seamlessly integrate within diverse environments, encouraging the development of innovative IoT solutions. It empowers users to build robust networks with scalable performance, ensuring definitive advancements in wireless communication technologies for modern smart applications.
The CAN Controller from Inicore is engineered to comply with the sophisticated standards of the CAN 2.0 protocol. This module efficiently facilitates communication in distributed control applications, making it a valuable asset in automotive, aerospace, and industrial systems where quick and reliable data exchange is crucial.<br/><br/>The controller offers a range of communication modes, including FIFO-based buffer management and high-priority transmission, ensuring that critical data is always given precedence. Additionally, its design supports advanced error handling and diagnostic features, which help maintain consistent operation even under challenging conditions.<br/><br/>Equipped with an AMBA interface, the CAN Controller integrates seamlessly into modern SoC designs. This inclusion allows for tight coupling with processor cores and peripheral components, providing a comprehensive solution that enhances overall system efficiency and performance. Its capacity for expansive message filtering and adherence to ISO standards ensure that this IP core is not only powerful but also versatile across a multitude of application scenarios.
The PCE03D turbo encoder is a sophisticated device designed for DVB-RCS and IEEE 802.16 WiMAX applications, utilizing an eight-state configuration. It is optimized to provide high-speed encoding performance, essential for modern wireless communication systems. The encoder supports robust signal processing, ensuring data integrity and transmission efficiency across various network environments.
This PCD03VH turbo decoder supports 3GPP LTE and 3GPP2 1xEV-DO networks with its eight-state high-speed configuration. It is engineered to minimize latency through ping-pong input and output memory configurations. This feature allows for effective parallel processing, making it extremely efficient for LTE and advanced CDMA applications where rapid response and system flexibility are critical. The decoder's architecture is built for robust performance in demanding communication situations.
Designed for IEEE 802.16 WiMAX systems, the PCD03W4 turbo decoder features an eight-state duobinary setup. With its four parallel MAP decoders, it achieves high-speed performance necessary for modern broadband wireless access networks. The decoder's architecture is built to maximize data throughput while maintaining reliability and efficiency. Its duobinary configuration aids in enhancing data integrity, supporting seamless integration into existing network infrastructure.
LightningBlu offers a world-first, multi-gigabit track-to-train solution, ensuring uninterrupted on-the-move connectivity. With its deployment in challenging transport environments, this system uses mmWave technology to deliver flawless communication between trackside and train. With a capacity for a robust gigabit train experience, both trackside nodes and train-top equipment are qualified for their environments, ensuring rigorous and efficient data performance. The solution is currently in active use on some of the busiest railways, improving connectivity for all commuters significantly. Its technical prowess lies in its ability to provide an exceptional throughput of up to 3.5 Gbps, operating efficiently to surpass the offerings of traditional mobile networks while ensuring a low carbon footprint.
IPrium's QAM Demodulator is engineered for efficient demodulation of Quadrature Amplitude Modulation signals, a widely used scheme in digital communication for both wireless and wired networks. This IP core efficiently translates received QAM signals into digital data, maintaining high accuracy. The QAM Demodulator is suitable for a variety of applications, including broadband communication systems where bandwidth efficiency and data integrity are critical. Its modular design supports different QAM types, ensuring versatile usability across various platforms and scenarios. Leveraging advanced decision-making algorithms, IPrium's QAM Demodulator delivers precise signal interpretation, crucial for maintaining uninterrupted data streams in complex communication networks. Developers seeking to enhance their systems' demodulation capacity will find this IP core to be an invaluable component.