All IPs > Wireless Communication > Bluetooth
Bluetooth technology has become an integral component of modern wireless communication, allowing devices to connect and share data seamlessly over short distances. In the realm of semiconductor IP, Bluetooth solutions play a crucial role in enabling developers to integrate reliable wireless connectivity into a diverse range of applications. From consumer electronics to industrial solutions, Bluetooth IPs are designed to streamline communication, ensuring efficient performance and reduced energy consumption.
At the core of Bluetooth semiconductor IP are highly optimized protocols and design architectures that cater to a plethora of connectivity requirements. These IPs are meticulously crafted to support various Bluetooth standards, such as Classic and Low Energy (LE), providing flexibility for developers to incorporate quick pairing, data transfer, or beacon capabilities into their products. This versatility allows the creation of applications ranging from simple audio streaming devices to complex IoT ecosystems, enhancing both functionality and user experience.
Products within this category not only include IP cores for Bluetooth transceivers but also comprehensive development platforms, software stacks, and testing tools. IP users benefit from pre-certified designs that significantly reduce time-to-market, enabling companies to focus on innovation rather than compliance. With the rapid evolution of Bluetooth technology, including advancements like Bluetooth 5.0 and its subsequent iterations, semiconductor IP providers constantly update their offerings to meet the latest industry standards and performance benchmarks.
Overall, incorporating Bluetooth semiconductor IP into device designs ensures robust connectivity, enabling seamless integration of wireless functionality while maintaining energy efficiency. Developers seeking to enhance their products with cutting-edge communication features will find a reliable foundation in Bluetooth IP, supporting a broad spectrum of applications that demand high performance and power efficiency in the wireless domain. Whether it's for home automation, health monitoring, or personal electronics, Bluetooth IP is a cornerstone for building the interconnected world of tomorrow.
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 EW6181 is a cutting-edge multi-GNSS silicon solution offering the lowest power consumption and high sensitivity for exemplary accuracy across a myriad of navigation applications. This GNSS chip is adept at processing signals from numerous satellite systems including GPS L1, Glonass, BeiDou, Galileo, and several augmentation systems like SBAS. The integrated chip comprises an RF frontend, a digital baseband processor, and an ARM microcontroller dedicated to operating the firmware, allowing for flexible integration across devices needing efficient power usage. Designed with a built-in DC-DC converter and LDOs, the EW6181 silicon streamlines its bill of materials, making it perfect for battery-powered devices, providing extended operational life without compromising on performance. By incorporating patent-protected algorithms, the EW6181 achieves a remarkably compact footprint while delivering superior performance characteristics. Especially suited for dynamic applications such as action cameras and wearables, its antenna diversity capabilities ensure exceptional connectivity and positioning fidelity. Moreover, by enabling cloud functionality, the EW6181 pushes boundaries in power efficiency and accuracy, catering to connected environments where greater precision is paramount.
The eSi-Comms IP suite provides a highly adaptable OFDM-based MODEM and DFE portfolio, crucial for facilitating communications-oriented ASIC designs. This IP offers adept handling of many air interface standards in use today, making it ideal for 4G, 5G, Wi-Fi, and other wireless applications. The suite includes advanced DSP algorithms for ensuring robust links under various conditions, using a core design that is highly configurable to the specific needs of high-performance communication systems. Notably, it supports synchronization, equalization, and channel decoding, boasting features like BPSK to 1024-QAM demodulation and multi-antenna processing.
ASPER is an advanced 79 GHz mmWave radar offering expansive 180-degree field coverage, designed to excel in park assist solutions. This radar module replaces traditional ultrasonic systems with improved accuracy, capable of extended detection ranges from 5 cm to 100 meters. Its adaptability across various vehicle classes makes it ideal for applications in automotive, transportation, and industrial environments, delivering unparalleled performance even in adverse conditions.
Convolutional FEC codes are very popular because of their powerful error correction capability and are especially suited for correcting random errors. The most effective decoding method for these codes is the soft decision Viterbi algorithm. ntVIT core is a high performance, fully configurable convolutional FEC core, comprised of a 1/N convolutional encoder, a variable code rate puncturer/depuncturer and a soft input Viterbi decoder. Depending on the application, the core can be configured for specific code parameters requirements. The highly configurable architecture makes it ideal for a wide range of applications. The convolutional encoder maps 1 input bit to N encoded bits, to generate a rate 1/N encoded bitstream. A puncturer can be optionally used to derive higher code rates from the 1/N mother code rate. On the encoder side, the puncturer deletes certain number of bits in the encoded data stream according to a user defined puncturing pattern which indicates the deleting bit positions. On the decoder side, the depuncturer inserts a-priori-known data at the positions and flags to the Viterbi decoder these bits positions as erasures. The Viterbi decoder uses a maximum-likelihood detection recursive process to cor-rect errors in the data stream. The Viterbi input data stream can be composed of hard or soft bits. Soft decision achieves a 2 to 3dB in-crease in coding gain over hard-decision decoding. Data can be received continuously or with gaps.
The GNSS VHDL Library by GNSS Sensor Ltd is an advanced collection of VHDL modules crafted for GNSS integration. This library offers a customizable GNSS engine along with Fast Search Engine capabilities for systems like GPS, Glonass, and Galileo. The utility of these modules extends to supporting independent RF channels and includes features like Viterbi decoders and self-test modules, thereby ensuring comprehensive functionality. The library is architected to provide high flexibility and independence from specific CPU platforms, driven by a single configuration file that allows for seamless adaptation across different environments. It supports integration with various external bus interfaces through its innovative bridge modules, ensuring streamlined operations and interactions with other system components. With its extensive configurability, the library can accommodate a wide range of configurations, including the number of supported systems, channels, and frequency bands. This allows developers to adapt the architecture to specific project needs efficiently. Additionally, the library's RF front-end capabilities significantly reduce system development costs and complexities by offering a ready-to-use navigation solution suitable for FPGA development boards and beyond.
NeuroVoice is a powerful ultra-low-power neuromorphic front-end chip engineered for voice processing in environments plagued by irregular noises and privacy concerns. This chip, built on the NASP framework, improves real-time voice recognition, reducing reliance on cloud processing and providing heightened privacy. It is ideal for applications in hearables, smart home devices, and other AI-driven voice control systems, capable of efficiently processing human voice amidst noise. The NeuroVoice chip addresses key challenges faced by existing digital solutions, such as excessive power consumption and low latency in real-time scenarios. Its brain-inspired architecture processes voice commands independently of the cloud, which minimizes Internet dependency and enhances privacy. Furthermore, the chip's ability to manage voice detection and extraction makes it suitable for diverse environments ranging from urban noise to quiet domestic settings. Advanced features of the NeuroVoice chip include its ultra-fast inference capability, processing all data locally and ensuring user privacy without compromising performance. By supporting applications like smart earbuds and IoT devices, NeuroVoice optimizes energy efficiency while maintaining superior voice processing quality. This innovative technology not only empowers users with clearer communication abilities but also encourages adoption across multiple consumer electronics.
ArrayNav represents a significant leap forward in navigation technology through the implementation of multiple antennas which greatly enhances GNSS performance. With its capability to recognize and eliminate multipath signals or those intended for jamming or spoofing, ArrayNav ensures a high degree of accuracy and reliability in diverse environments. Utilizing four antennas along with specialized firmware, ArrayNav can place null signals in the direction of unwanted interference, thus preserving the integrity of GNSS operations. This setup not only delivers a commendable 6-18dB gain in sensitivity but also ensures sub-meter accuracy and faster acquisition times when acquiring satellite data. ArrayNav is ideal for urban canyons and complex terrains where signal integrity is often compromised by reflections and multipath. As a patented solution from EtherWhere, it efficiently remedies poor GNSS performance issues associated with interference, making it an invaluable asset in high-reliability navigation systems. Moreover, the system provides substantial improvements in sensitivity, allowing for robust navigation not just in clear open skies but also in challenging urban landscapes. Through this additive capability, ArrayNav promotes enhanced vehicular ADAS applications, boosting overall system performance and achieving higher safety standards.
The UHS-II solution is crafted to enhance data transfer rates within low-voltage environments. It particularly supports high-definition content transmission, which is critical for modern mobile devices requiring seamless streaming and heavy data loads. Utilizing a modular design approach, it ensures a robust and efficient layout that facilitates optimal performance and reliability.
Wireless IP developed by Analog Circuit Works provides essential capabilities for portable, medical, and sensor application domains. These IP blocks are critical in enabling wireless power and data transmission, thereby supporting the autonomy and versatility of modern devices that rely heavily on wireless technologies. The solutions offered are designed with a focus on maximizing frequency capabilities while ensuring efficiency across various environmental scenarios. This adaptability ensures that these IPs meet the rigorous demands of applications where wireless communication and power provisioning are at the forefront of user expectations. Analog Circuit Works' wireless solutions are fine-tuned to provide enhanced robustness and reliability, facilitating seamless integration within devices that require stable and sustained wireless operations. As a result, they are perfectly suited for innovations in IoT and other rapidly evolving technology landscapes requiring high-quality wireless interface and communication solutions.
The PCS1100 is a state-of-the-art Wi-Fi 6E 4x4:4 transceiver that supports tri-band operations, enhancing Wi-Fi networks built on the IEEE 802.11ax standard. It operates efficiently in the 2.4 GHz, 5 GHz, and 6 GHz bands, allowing for robust connectivity and optimal network performance in dense environments. The transceiver provides up to four spatial streams and supports dual-band simultaneous operation, which is crucial for maintaining high throughput and connectivity at extended ranges. Embedded within the PCS1100 is a sophisticated RF architecture that supports advanced modulation schemes including 1024-QAM, providing increased data throughput. With an emphasis on power optimization, this chip is designed for seamless integration into AP-access point or STA-station systems, significantly easing the complexities associated with RF integration. Moreover, the transceiver tackles signal integrity and phase noise issues effectively, ensuring its exceeds transmission and reception performance standards. Such features make the PCS1100 an ideal choice for modern applications demanding high efficiency, low latency, and reduced interference, all fundamental for enterprise and consumer-grade wireless solutions.
ntRSD core implements a time-domain Reed-Solomon decoding algorithm. The core is parameterized in terms of bits per symbol, maximum codeword length and maximum number of parity symbols. It also supports varying on the fly shortened codes. Therefore any desirable code-rate can be easily achieved rendering the decoder ideal for fully adaptive FEC applications. ntRSD core supports erasure decoding thus doubling its error correction capability. The core also supports continuous or burst decoding. The implementation is very low latency, high speed with a simple interface for easy integration in SoC applications.
Bruco's WiFi6, LTE, and 5G Front-End Module are tailored to meet the contemporary demands of wireless communication. Covering frequencies from 2.4 GHz to 5-7 GHz, this module incorporates key components like switches, LNA (Low-Noise Amplifiers), and PAs (Power Amplifiers) to facilitate improved signal transmission and reception across cellular and WiFi networks. This RF front-end solution is ideal for integration in modern smartphones and network devices, boosting connection speeds and reliability in both local area and wide area networks. The module's design aligns with the latest communication standards, ensuring compatibility and enhanced performance in next-generation wireless applications.
LightningBlu is a groundbreaking rail-qualified mmWave connectivity solution providing consistent high-speed communications for trains. Designed for seamless deployment across high-speed rail networks, this product is installed at trackside and train-top locations, creating a bridge between wireless connections and a trackside fiber network. Each unit supports two-sector radios to ensure uninterrupted data transfer and maintain speeds of approximately 3 Gbps. Currently operational on major routes such as South Western Rail and Caltrain, LightningBlu significantly enhances connectivity, offering passengers robust internet access and onboard services. Offering a transformative experience for travelers, LightningBlu supports continuous multi-gigabit connectivity even at speeds exceeding 300 km/h. Its operational efficiency surpasses traditional mobile data solutions, consuming less power than 4G or 5G while offering much faster data rates. This innovation results in improved safety and efficiency in rail operations, allowing real-time access to vast data streams. Technically advanced, LightningBlu's features include full environmental certification for rail use under EN50155 standards, compliance with CEPT and FCC regulations, and a mobile connection manager for optimal wireless link management. Its ability to operate over all six IEEE 802.11ad channels makes it a robust solution for high-speed rail systems, providing reliable and high-capacity data throughput for modern passenger requirements.
The L5-Direct GNSS Receiver by oneNav is a pioneering solution designed to acquire and process L5-band signals independently. This advanced receiver utilizes a unique Application Specific Array Processor (ASAP) to directly acquire L5 signals, ensuring high sensitivity and rapid location fixing. This innovation allows the receiver to function effectively without relying on the older L1 signals, providing a robust alternative in urban settings where signal interference can be a significant issue. The technology supports a multitude of satellite signals, including those from GPS, Galileo, QZSS, and BeiDou, enabling it to adapt to various constellations. Its design optimizes space and power through a single RF chain, reducing the need for complex dual-band systems. This results in a smaller footprint and lower costs, making it ideal for compact electronic devices such as wearables or IoT gadgets. One of the standout features of this technology is its ability to manage multipath errors using machine learning algorithms, which effectively discriminate between direct signals and reflections. The receiver's resilience against GPS spoofing and jamming enhances security and trustworthiness, critical in areas of contested or compromised signals. By integrating seamlessly with non-terrestrial networks, the L5-Direct GNSS Receiver ensures reliable connectivity and positioning in diverse environmental conditions. Moreover, oneNav's receiver is built for endurance and efficiency, with a design that allows for continuous, low-power tracking—a feature especially beneficial for battery-operated applications. The overall architecture demonstrates significant advancements in both GNSS receiver technology and the broader field of navigation systems, offering unparalleled performance, precision, and reliability in the GNSS domain.
The 802.15.4 Transceiver Core is essential for low-rate wireless personal area networks (LR-WPANs), supporting applications like Zigbee and other IoT communication standards. This core offers an excellent balance of low power consumption and reliable data transfer, crucial for devices that require sustained battery operation. Tailored for use in smart homes and industrial environments, this transceiver core provides robust security features and scalability to support a comprehensive range of connected devices. It simplifies the integration process by providing a complete RF solution that reduces total component count and cost. The transceiver is built on RF CMOS technology, enabling it to be stably implemented in varied settings without performance degradation. Its design ensures compatibility with a broad range of sensors and devices, reinforcing its position as a versatile and reliable choice for any networking need in IoT and automation applications.
Packetcraft's Bluetooth LE Audio Solutions represent a leading-edge offering in wireless communication, providing a robust and flexible framework for integrating advanced audio features. It accommodates a variety of audio configurations, including LC3 optimized codecs and support for Auracast broadcast audio, which is tailored for seamless integration into true wireless stereo (TWS) systems. This offering allows product manufacturers to leverage Bluetooth LE's low-energy capabilities while ensuring high-fidelity audio transmission, paving the way for a new generation of audio devices that are both energy-efficient and feature-rich. The solution has been successfully ported to several popular chipsets, granting product developers significant flexibility in product design and reducing time-to-market. By enabling a straightforward migration path from existing Bluetooth technologies, Packetcraft ensures that its customers can rapidly adopt the latest features of Bluetooth LE Audio, including extended capabilities for broadcast audio and advanced stereo output. Moreover, Packetcraft's comprehensive support infrastructure and ongoing updates guarantee that users can maximize the potential of their Bluetooth LE Audio implementations, remaining competitive in a rapidly evolving market. This is particularly valuable for companies looking to distinguish themselves through enhanced user experiences, broad compatibility, and energy-efficient performance.
The VoSPI Receiver is specifically designed to interface with the FLIR Lepton infrared sensor, handling video signal reception and processing for thermal imaging applications. This technology is crucial in delivering clear, detailed thermal imagery, particularly suited for security and surveillance markets requiring reliable thermal data processing. This receiver is optimized for use with Xilinx FPGAs, which enhances its adaptability to various technological environments. By focusing on minimized latency and efficient signal processing, the receiver ensures that real-time thermal monitoring and analysis can be conducted with high accuracy and speed. The integration of this VoSPI receiver into systems allows for enhanced thermal data interpretation, supporting applications in defense, industrial monitoring, and predictive maintenance. The technology enables conversion of thermal data from the sensor into usable digital outputs effectively, ensuring system compatibility and maximizing performance in analyzing thermal signatures. Robust signal processing capability makes this receiver an essential component in any setup where accurate thermal monitoring and precise data transformation are crucial. It combines a compact form with powerful functionalities, ensuring that even complex thermal imaging tasks can be handled with ease.
The Dynamic PhotoDetector (DPD) by ActLight optimizes light sensing for earphones and hearable devices, offering pinpoint precision in biometric data collection. This technology is aligned with the demand for real-time health monitoring in audio devices, presenting an edge in modern hearables that traditional sensors cannot match. It leverages reduced power consumption to extend operational life, a critical factor in uninterrupted use. Engineered to overcome challenges presented by light intensity fluctuations, ActLight's DPD ensures reliability and accuracy. It operates at lower voltages, decreasing the power demand while maintaining optimal functionality. This low-bias operation minimizes the need for bulky amplifiers, enabling refined, unobtrusive design in hearable devices. The novel DPD technology fosters innovative applications in hearables, making them not only more competitive but also more compatible with energy-efficient designs that modern consumers demand. It integrates seamlessly into competitive designs that are looking to offer accurate and sustainable solutions for health-focused products.
ntRSE core implements the Reed Solomon encoding algorithm and is parameterized in terms of bits per symbol, maximum codeword length and maximum number of parity symbols. It also supports varying on the fly shortened codes. Therefore any desirable code-rate can be easily achieved rendering the decoder ideal for fully adaptive FEC applications. ntRSE core supports continuous or burst decoding. The implementation is very low latency, high speed with a simple interface for easy integration in SoC applications.
PhantomBlu, specifically engineered for military applications, offers sophisticated mmWave technology for secure, high-performance communications across various tactical environments. This product is designed for strategic defense communications, enabling connectivity between land, sea, and air vehicles. PhantomBlu excels in supporting IP networking on robust anti-jam resistant mesh networks, ensuring communication security and reliability. Its configurable and adaptable design makes PhantomBlu suitable for diverse military scenarios, from convoys on the road to high-altitude surveillance operations. The system is distinguished by its stealth capabilities like low probability of interception (LPI) and detection (LPD), as well as its highly efficient data transmission rate, which exceeds that of Wi-Fi and 5G technologies. PhantomBlu's deployment requires no dependency on fiber networks, featuring a quick setup process suited for mobile and tactical requirements. Its design supports long-range communications, effective up to 4 km and allows seamless integration with existing defense infrastructure, making it a future-proof solution for all modern military communications needs. The product is licensed for operations over 57-71 GHz, offering scalable and high-data rate networks essential for today's demanding defense operations.
IMST GmbH offers customized wireless solutions that cater to specific client needs. These modules integrate various wireless communication standards like Zigbee, Bluetooth, and proprietary systems into existing or new applications. The solutions ensure seamless integration into customer systems, targeting efficiency and performance optimization in diverse environments.
TES's UWB Technology is a comprehensive Ultra Wideband solution, ideal for high-precision ranging and communication applications in competitive markets. This technology is implemented using VHDL, enabling seamless integration with ASIC and FPGA platforms. UWB is noted for enabling precise location tracking and high data rate communications in environments reliant on accurate positioning and robust connectivity.
Ceva-Waves Bluetooth Platforms are designed to provide comprehensive and energy-efficient Bluetooth connectivity solutions for SoCs. Supporting the latest Bluetooth profiles, including Bluetooth Low Energy (LE) and dual-mode standards, these platforms are optimized for seamless integration with existing wireless technologies, such as Wi-Fi and UWB.\n\nThe platform offers robust support for a wide range of Bluetooth applications, facilitating effective co-existence in dense wireless environments. Coupling an advanced baseband with a flexible software stack, it simplifies the deployment of Bluetooth technology across multiple product categories, catering to automotive, consumer electronics, and mobile communication device requirements.\n\nEquipped with next-generation capabilities like high data throughput and low energy consumption, the Ceva-Waves Bluetooth Platforms are pivotal for emerging smart devices that demand reliable, high-performance wireless connectivity.
SEMIFIVE's AIoT Platform caters to the integration of artificial intelligence into the Internet of Things (IoT) devices, enabling smart and efficient technology solutions. This platform supports the development of AI-driven IoT applications by providing a robust framework that combines AI compute power with IoT's connectivity and data processing capabilities. The AIoT Platform facilitates the rapid design and deployment of innovative solutions across various sectors such as smart homes, industrial IoT, and more. It optimizes system design through the seamless integration of IoT sensors, processors, and communication protocols, ensuring high performance with minimal power consumption. Backed by silicon-proven IPs, this platform ensures scalability and flexibility, allowing developers to create customized solutions with ease. The AIoT Platform is positioned to support smart technology innovations with its focus on energy efficiency, intelligent data processing, and enhanced connectivity features.
The 2.4GHz ISM Band RF IP by Actt provides high efficiency and performance in wireless communication applications. It is designed to be compatible with Bluetooth and Wi-Fi standards, including classic Bluetooth and contemporary Bluetooth Low Energy protocols. This RF IP accommodates the latest Bluetooth version 5.2 protocol standards, ensuring a versatile and future-proof solution for wireless applications.
AONDenoise stands out as a revolutionary single-microphone denoiser, capable of delivering crystal-clear audio by substantially reducing background noise. With less than 1ms latency, it employs sophisticated AI algorithms to enhance listening experiences across various scenarios, such as concerts or crowded places. Its compact and efficient design makes it ideal for integration into numerous applications where audio clarity is paramount.
YouRF by Brite Semiconductor is a suite of RF transceiver solutions tailored for low-power, high-efficiency wireless applications. Covering technologies such as Bluetooth Low Energy (BLE) and NB-IoT, YouRF integrates advanced 2.4GHz ISM band receivers and transceiver architectures specifically designed for robust IoT, smart device, and industrial applications. YouRF BLE provides a complete Bluetooth solution, with high precision receiving capabilities, enhanced efficiency amplifiers, and robust 2.4GHz transmission. It ensures seamless integration into modern devices demanding low power profiles. Meanwhile, the NB-IoT section is optimized for narrow-band technology stacks, offering Sub-1GHz transceiver utilization that covers frequency bands from 699MHz to 960MHz. These transceivers are a match for cutting-edge applications in smart metering and wireless sensor networks, empowering device manufacturers with the technology needed to stay ahead in dynamic and networked device ecosystems. Flexibility in use with proprietary 2.4G communications further broadens the possible application field for YouRF solutions.
The Wi-Fi 6 / BLEv5.4 Dual Band RF Transceiver offers robust capabilities for high-end applications requiring dual-band wireless communication. Operating at 2.4GHz and 5GHz ranges, this transceiver is engineered to deliver rapid data transfer rates, reduced latency, and optimal network performance. With features such as integrated linear power amplifiers, fractional-N synthesizers, and scalable MIMO configurations, it provides versatile solutions for various use cases including augmented reality, smart homes, and gaming networks. Designed for efficiency, it includes adaptable bias current settings and switchable bandwidth filters to enhance performance adaptability.
Tailored for efficient short-range communication, the IEEE 802.15.4 WPAN IP from Low Power Futures is designed to support energy-efficient wireless networking suitable for IoT devices. Its reliable platform facilitates communication using sub-gigahertz and 2.4GHz frequencies, integrating advanced modulation/demodulation capabilities such as BPSK and OQPSK, and optionally GFSK, to ensure stable connectivity across a wide range of field applications. This IP is further enhanced with robust security mechanisms, safeguarding data exchanges and contributing to the protection of sensitive information often exchanged over IoT networks. Ideal for low-power, low-rate communications, the IEEE 802.15.4 WPAN provides a dependable foundation for the development of smart environment products like smart lighting controls, remote monitoring systems, and home automation devices. Structured to accommodate a variety of hardware and firmware environments, this WPAN IP ensures seamless integration into existing systems, promoting its adaptability for future technology needs and expansion. By addressing the growing demand for efficient and secure wireless communications, Low Power Futures' IEEE 802.15.4 WPAN IP is a significant component for advancing the IoT revolution.
The OT3910bjc LVDS Transceiver is designed to provide excellent signal transmission over differential pairs, enhancing data integrity and transfer speed in complex electronic systems. With its superior noise performance and low voltage differential signaling, it is perfect for high-speed data transfer applications such as telecommunications and networking equipment. Its architecture is optimized to minimize power usage while maximizing transmission capabilities, supporting data rates required in both consumer and industrial electronics. The OT3910bjc transceiver integrates well within existing hardware configurations, offering unparalleled efficiency and reliability crucial for modern data communications infrastructure.
The SBR7320 is a dual-mode transceiver optimized for Bluetooth communications, supporting both classic and low-energy (LE) modes. Its ultra-low power capabilities make it an excellent fit for IoT applications that depend on efficient Bluetooth connectivity for continuous operations. Tailored for wearable devices and other mobile IoT gadgets, this transceiver ensures a balance of power efficiency and performance, providing reliable connectivity and prolonged battery life. The dual-mode support widens the application scope, allowing seamless integration with a variety of Bluetooth-enabled devices. In terms of design, the SBR7320 emphasizes minimal silicon area, reducing production costs while maintaining robust performance. Its high adaptability and strong connectivity make it essential in the landscape of smart electronics, particularly where energy conservation is paramount.
Designed to adhere to the latest Bluetooth Low Energy standards, the Bluetooth LE 5.2 IP from Low Power Futures provides comprehensive support for various connectivity configurations, making it a vital asset in the development of modern wireless communication systems. This IP offers seamless operation at multiple data rates: 1Mbps and 2Mbps, utilizing both uncoded and coded physical layers to ensure versatile application support. Integrated features like direction finding and AoA/AoD functionalities make this IP indispensable for expanding the capabilities of IoT networks. The robustness of Bluetooth LE 5.2 is further enhanced by its built-in security features, enabling reliable data transmission and safeguarding against potential cyber threats in IoT environments. It excels in reducing power consumption and area overhead, aligning perfectly with the demands of modern low-power applications such as smart wearable devices, remote sensing nodes, and compact consumer electronics. With its cutting-edge design that supports easy integration into existing systems, the Bluetooth LE 5.2 IP facilitates rapid deployment and development for device manufacturers. This IP's flexible interface allows it to adapt readily to various hardware configurations and application needs, ensuring optimal performance across diverse operating environments.
The NB-Iot C200 by Cortus is a meticulously designed narrowband IoT solution aimed at providing efficient connectivity. Tailored to meet the requirements of modern IoT landscapes, this offering excels in low-power wide-area coverage, crucial for a plethora of IoT applications. Designed to operate seamlessly in diverse environments, the NB-Iot C200 enables reliable communication capabilities which are fundamental for devices in the IoT ecosystem. With a focus on energy efficiency, it promises prolonged operational performance while maintaining robust connectivity which is essential for vast networks of IoT devices. This solution underscores Cortus's expertise in delivering state-of-the-art IoT technology, contributing to the development of smart cities, advanced industrial applications, and connected consumer electronics. The capability to support a wide range of IoT applications makes the NB-Iot C200 a cornerstone in Cortus's IoT product lineup, ensuring enhanced compatibility and functionality across different industries.
Channel Sounding is Packetcraft's pioneering technology in the domain of precise Bluetooth distance measurement. This innovative approach allows for high-accuracy distance and location determination, serving a multitude of applications that demand pinpoint spatial awareness. Key to its function is a sophisticated measurement technique that exploits Bluetooth signal properties to derive accurate positioning data. The technology's utility extends across various uses, from automotive systems requiring detailed spatial data to consumer electronics that need dependable indoor navigation capabilities. Packetcraft’s Channel Sounding solutions have been demonstrated in live test environments, showcasing their efficacy on international stages, such as automotive events in China. These applications highlight the robustness of Channel Sounding in real-world conditions. Packetcraft ensures that this advanced technology remains at the forefront of emerging innovations in Bluetooth connectivity by offering comprehensive support and a well-documented integration process. This allows developers to seamlessly incorporate Channel Sounding into their systems, ensuring precise spatial data collection and enhancing the performance of spatially aware applications.
The Bluetooth 5.2 Dual Mode IP from Low Power Futures offers a sophisticated blend of Bluetooth Low Energy and Basic Rate/Enhanced Data Rate (BR-EDR) functionalities, adhering to the latest Bluetooth specifications. This integration caters to diverse communication requirements, ensuring compatibility with a range of devices and enabling flexible connectivity options in IoT applications. The dual-mode IP places emphasis on power efficiency and compact design, making it ideal for resource-constrained settings where conserving power and space is crucial. Its comprehensive connectivity features include uncoded and coded PHY support for various data rates, along with integrated low-energy audio capabilities and direction finding technologies. Security remains a cornerstone of this IP, featuring reliable built-in measures that protect sensitive data in real-time operations. Engineered for seamless adaptability across different hardware configurations, the Bluetooth 5.2 Dual Mode IP is readily integrable into established systems and new designs alike. Therefore, this IP stands as an integral solution for driving next-generation IoT devices where robust and flexible wireless communication is paramount.
Designed with the latest Bluetooth 6.0 standards, the BLE 6.0 Linklayer, Stack & Profiles provides a feature-rich stack for developing IoT devices requiring low energy consumption and robust connectivity. It features advanced codecs like LC3 for audio-over-BLE applications and supports wide interoperability, allowing seamless integration into various platforms. The solution is optimized for low power use and tested for interoperability, ensuring smooth operation with a multitude of devices.
ADiiS specializes in the design and development of integrated imaging systems for aeronautical applications. With over 15 years collaborating with the aerospace industry's leading names, ADiiS has crafted a range of video solutions suited for high-altitude photography, including helicopter and fighter jet systems. Their cameras and multi-channel recorders adhere to stringent operational standards and continue to innovate with ITAR-free designs, maintaining compatibility with standards like DO160 and MIL810.
The D68HC11E is a synthesizable SOFT Microcontroller IP Core, fully compatible with the Motorola 68HC11E industry standard. It can be used as a direct replacement for: 68HC11E Microcontrollers and older 68HC11E versions: 68HC11A and 68HC11D In a standard configuration of the core, major peripheral functions are integrated on-chip. An asynchronous serial communications interface (SCI) and separate synchronous serial peripheral interface (SPI) are included. The main 16-bit, free-running timer system contains input capture and output- compare lines and a real-time interrupt function. An 8-bit pulse accumulator subsystem can count external events or measure external periods. Self-monitoring and on-chip circuitry is included to protect the D68HC11E against system errors. The Computer Operating Properly (COP) watchdog system protects against software failures. An illegal opcode detection circuit provides a non-maskable interrupt if an illegal opcode is detected. Two software-controlled power- saving modes – WAIT and STOP are available to preserve additional power. These modes make the D68HC11E IP Core especially attractive for automotive and battery-driven applications. The D68HC11E Microcontroller Core can be equipped with an ADC Controller, which allows using an external ADC Controller with standard ADC software. The ADC Controller makes external ADCs visible as internal ADCs in original 68HC11E Microcontrollers. The D68HC11E is fully customizable – it is delivered in the exact configuration to meet your requirements. There is no need to pay extra for unused features and wasted silicon. The D68HC11E comes with a fully automated test bench and a complete set of tests, allowing easy package validation at each stage of the SoC design flow. Each DCD’s D68HC11E Core has built-in support for DCD’s Hardware Debug System called DoCD™. It is a real-time hardware debugger that provides debugging capability of a whole System-on-Chip (SoC). Unlike other on-chip debuggers, the DoCD™ allows non-intrusive debugging of a running application. It can halt, run, step into or skip an instruction, and read/write any contents of the microcontroller, including all registers, and SFRs, including user-defined peripherals, data, and program memories. All DCD’s IP cores are technology agnostic, ensuring 100% compatibility with all FPGA and ASIC vendors.
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