Alternatives to TI-RTOS

Huawei LiteOS is a software platform designed specifically for the Internet of Things (IoT), combining an operating system with middleware. With a remarkably small kernel size of less than 10 KB, it operates efficiently on minimal power, capable of lasting up to five years on a single AA battery. Its quick startup time and secure connectivity features further enhance its usability. These attributes position Huawei LiteOS as an effective one-stop solution for developers, facilitating easier entry into the market and expediting product launch timelines. The platform offers a cohesive open-source API applicable across various IoT sectors, including smart homes, wearables, the Internet of Vehicles, and smart manufacturing. By fostering an open IoT ecosystem, Huawei LiteOS empowers partners to innovate swiftly and propel the development of IoT solutions forward. Its versatility and reliability make it an essential tool in the rapidly evolving landscape of IoT technology.

VxWorks®, a leading real-time operating platform in the industry, provides all the performance, reliability, safety and security capabilities you need for the most critical infrastructure's embedded computing systems. VxWorks is a preemptive, deterministic RTOS that prioritizes real-time embedded applications. It has low latency and minimaljitter. VxWorks has many security features that address the evolving security threats connected devices face at every stage, from boot-up to operation to data transfer to powered off. VxWorks has been certified to IEC 61508, ISO 26262, and DO-178C safety standards. VxWorks is built on an extensible, future-proof architecture that allows you to quickly respond to changing market demands, customer needs, technological advancements, and preserves your investment.

The MQX real-time operating system (RTOS) delivers excellent real-time capabilities while maintaining a compact and customizable footprint. This RTOS is seamlessly integrated with NXP's 32-bit MCUs and MPUs and comes with essential device drivers commonly utilized in embedded applications. Designed with a contemporary, component-oriented microkernel architecture, the MQX RTOS allows engineers to tailor features, size, and performance by selectively integrating components, thus adhering to the stringent memory limitations typical of embedded systems. Remarkably, it can be set up to use as little as 8 KB of ROM and 2.5 KB of RAM on the Arm Cortex M4, accommodating the kernel, two task applications, one lightweight semaphore, the interrupt stack, queues, and the memory manager. This configuration ensures a complete RTOS core is available while offering additional optional services as needed. By linking components only when required, the system effectively avoids unnecessary memory bloat from unused functions. Moreover, key components are offered in both standard and lightweight configurations, providing further flexibility regarding size, RAM and ROM usage, and performance options, making it a versatile choice for various applications.

Nucleus® RTOS empowers system developers to meet the intricate demands of modern embedded designs. By combining a robust kernel with essential tooling features, Nucleus is perfectly suited for applications that prioritize scalability, connectivity, security, power efficiency, and reliable deterministic performance. This real-time operating system is not only proven and dependable but also fully optimized for various applications. It has demonstrated success in demanding sectors that require stringent safety and security standards, including industrial systems, medical devices, airborne systems, and automotive applications. Nucleus features a stable deterministic kernel designed to occupy minimal memory, complemented by a lightweight process model that enhances memory partitioning. Additionally, it supports dynamic loading and unloading of processes, allowing for increased modularity in applications, thus providing developers with the flexibility needed for diverse project requirements. This adaptability ensures that Nucleus RTOS can effectively cater to the evolving landscape of embedded technology.

INTEGRITY employs hardware memory protection to effectively isolate and safeguard embedded applications. By utilizing secure partitions, it ensures that every task has the necessary resources to operate correctly while simultaneously shielding the operating system and user tasks from erroneous and harmful code, which encompasses threats like denial-of-service attacks, worms, and Trojan horses. To facilitate developers in expediting their product creation, Green Hills Software provides a comprehensive suite of middleware that has been integrated and validated for use with INTEGRITY, featuring options like FFS, FAT, NFS, and journaling file systems, alongside both IPv4 and IPv6 host and routing networking stacks, as well as a FIPS 140-2 certified Suite B embedded encryption library, among other tools. Notably, each middleware package has undergone pre-integration and rigorous testing to ensure it operates smoothly with INTEGRITY’s sophisticated RTOS features. Furthermore, Green Hills Software also presents tailored platforms for various industries, which encompass a fully integrated ecosystem that includes the INTEGRITY RTOS along with essential development tools, aiming to streamline the development process even further. This cohesive approach not only boosts efficiency but also enhances the overall security of embedded applications.

Arm Mbed OS is an open-source operating system tailored for IoT applications, providing all the essential tools for creating IoT devices. This robust OS is equipped to support smart and connected products built on Arm Cortex-M architecture, offering features such as machine learning, secure connectivity stacks, an RTOS kernel, and drivers for various sensors and I/O devices. Specifically designed for the Internet of Things, Arm Mbed OS integrates capabilities in connectivity, machine learning, networking, and security, complemented by a wealth of software libraries, development boards, tutorials, and practical examples. It fosters collaboration across a vast ecosystem, supporting over 70 partners in silicon, modules, cloud services, and OEMs, thereby enhancing choices for developers. By leveraging the Mbed OS API, developers can maintain clean, portable, and straightforward application code while benefiting from advanced security, communication, and machine learning functionalities. This cohesive solution ultimately streamlines the development process, significantly lowering costs, minimizing time investment, and reducing associated risks. Furthermore, Mbed OS empowers innovation, enabling developers to rapidly prototype and deploy IoT solutions with confidence.

Ranging from basic embedded environmental sensors and LED wearables to advanced embedded controllers, smartwatches, and IoT wireless applications, this system incorporates configurable architecture-specific stack-overflow protection, kernel object and device driver permission tracking, and thread isolation enhanced by thread-level memory protection across x86, ARC, and ARM architectures, as well as userspace and memory domains. For systems lacking MMU/MPU and those limited by memory capacity, it enables the integration of application-specific code with a tailored kernel to form a monolithic image that can be loaded and run on the hardware of the system. In this setup, both the application and kernel code operate within a unified address space, facilitating efficient resource utilization and performance optimization. This design ensures that even resource-constrained environments can effectively leverage complex applications and functionalities.

PikeOS is a separation kernel-based hypervisor that supports multiple partitions for many operating systems and applications. It allows you to create smart devices for the Internet-of-Things. PikeOS is the best choice for systems that require protection against Cyber-Security attack due to its separation kernel approach. It is widely used in millions of edge and IoT systems. However, it has also been deployed in critical communications infrastructures. PikeOS combines virtualization and real time with unique technologies that have never been seen before. It allows you to move multiple complex embedded circuit boards into one hardware. It is also able to handle new hardware concepts like Big-SoCs that have multiple heterogeneous cores. PikeOS can run on multiple architectures and support processors that have a memory management unit (MMU).

Since its inception in 1980, QNX has been the choice of thousands of enterprises seeking to implement real-time operating systems that deliver an optimal blend of performance, security, and reliability for their mission-critical operations. Central to QNX's innovation is the QNX Neutrino® Real-time Operating System (RTOS), which is a comprehensive solution that facilitates the development of next-generation products across various sectors where dependability is paramount, such as automotive, healthcare devices, robotics, transportation, and industrial embedded environments. Thanks to its microkernel architecture, QNX ensures that a failure in one component does not disrupt the operation of others or compromise the kernel, as the malfunctioning part can be simply halted and restarted without negatively impacting the overall system. The QNX Neutrino RTOS stands out by providing the determinism unique to real-time operating systems, employing methods like adaptive partitioning to ensure that essential processes receive the necessary processing cycles to perform their tasks promptly, all while sustaining the performance expectations of intricate embedded systems. This combination of features makes QNX Neutrino RTOS a preferred choice for developers looking to create robust and resilient applications. As technology continues to evolve, the adaptability of QNX's offerings ensures that they remain at the forefront of real-time operating system solutions.

FreeRTOS is a real-time operating system that is open source and tailored for microcontrollers, simplifying the programming, deployment, security, connectivity, and management of small, low-power edge devices. Available at no cost under the MIT open source license, FreeRTOS features a kernel alongside an expanding array of software libraries that cater to various industries and applications. This system allows seamless and secure integration of compact, low-energy devices with AWS Cloud services, such as AWS IoT Core, as well as with more robust edge devices running AWS IoT Greengrass. Designed with a focus on both reliability and user-friendliness, FreeRTOS provides the assurance of long-term support releases, making it an attractive choice for developers. Microcontrollers, which are characterized by their simple and resource-limited processors, can be found in a diverse range of products, from home appliances and sensors to fitness trackers, industrial automation systems, and vehicles. As the demand for efficient and manageable IoT solutions grows, FreeRTOS remains a crucial tool for developers working in this expanding field.

OpenWrt is an adaptable GNU/Linux distribution designed specifically for embedded devices, especially wireless routers. In contrast to many other router distributions, OpenWrt is engineered from the ground up to function as a comprehensive and easily customizable operating system for embedded systems. This design philosophy ensures that users can access all essential features without unnecessary bloat, thanks to its reliance on a modern Linux kernel. Rather than offering a single, unchangeable firmware, OpenWrt features a fully writable filesystem accompanied by optional package management. This versatility liberates users from the limitations imposed by manufacturers regarding application choices and configurations, allowing for tailored modifications to meet any specific application needs. Furthermore, for developers, OpenWrt serves as a robust framework that enables the creation of applications without the necessity of building an entire firmware image or distribution around them, thus simplifying the development process. Ultimately, this makes OpenWrt an appealing choice for both end-users and developers alike.

Developed in collaboration with top chip manufacturers over a span of 15 years, FreeRTOS is now downloaded approximately every 170 seconds and stands as a top-tier real-time operating system (RTOS) tailored for microcontrollers and small microprocessors. Available at no cost under the MIT open source license, FreeRTOS encompasses a kernel along with an expanding collection of IoT libraries that cater to various industries. Prioritizing reliability and user-friendliness, FreeRTOS is renowned for its proven durability, minimal footprint, and extensive device compatibility, making it the go-to standard for microcontroller and small microprocessor applications among leading global enterprises. With a wealth of pre-configured demos and IoT reference integrations readily available, users can easily set up their projects without any hassle. This streamlined process allows for rapid downloading, compiling, and quicker market entry. Furthermore, the ecosystem of partners offers a diverse range of options, including both community-driven contributions and professional support, ensuring that users have access to the resources they need for success. As technology continues to evolve, FreeRTOS remains committed to adapting and enhancing its offerings to meet the ever-changing demands of the industry.

Azure RTOS serves as a comprehensive suite for embedded development, featuring a compact yet powerful operating system that delivers reliable and ultra-fast performance tailored for devices with limited resources. Its user-friendly design and proven market success are evident, with deployment figures exceeding 10 billion devices globally. This operating system is compatible with the leading 32-bit microcontrollers and embedded development platforms, allowing teams to leverage their existing expertise effectively. With Azure RTOS, developers can seamlessly integrate cloud and local network connectivity, create robust flash file systems, and craft sophisticated user interfaces. Additionally, the code adheres to rigorous industry safety and security standards, ensuring its reliability. Clean and straightforward code not only enhances usability and maintenance but also contributes to a reduced total cost of ownership. Furthermore, achieving most safety-related certifications necessitates the submission of the entire source code for the software, including components of the RTOS, which underscores the importance of transparency in development processes. Each of these features collectively enhances the overall effectiveness of the development lifecycle.

RT-Thread, short for Real Time-Thread, is an embedded real-time multi-threaded operating system. It has been designed to support multi-tasking, allowing multiple tasks to run simultaneously. Although a processor core can only run one task at a time, RT-Thread executes every task quickly and switches between them rapidly according to priority, creating the illusion of simultaneous task execution. RT-Thread is mainly written in the C programming language, making it easy to understand and port. It applies object-oriented programming methods to real-time system design, resulting in elegant, structured, modular, and highly customizable code. The system comes in a few varieties. The NANO version is a minimal kernel that requires only 3KB of flash and 1.2KB of RAM. For resource-rich IoT devices, RT-Thread can use an online software package management tool, together with system configuration tools, to achieve an intuitive and rapid modular design.

Deos™, developed by DDC-I, is a safety-critical real-time operating system (RTOS) that has been rigorously verified according to DO-178C/ED-12C Design Assurance Level A (DAL A) standards specifically for avionics applications. This RTOS supports ARINC 653 APEX and rate monotonic scheduling (RMS), and it is designed to meet the FACE Safety Base Profile requirements. Since its initial verification by Transport Canada in 1998, it has been a trusted solution in the aviation industry, with its certification allowing it to operate in tens of thousands of aircraft. Over the past two decades, Deos has adapted and evolved to incorporate new processors and features, demonstrating its flexibility and resilience. It has also undergone successful audits by a range of global certification authorities, including the FAA, ENAC, JAA, EASA, and CAAC, as well as by designated engineering representatives from various airframe and avionics suppliers, ensuring its continued compliance with industry standards. Its proven track record and ongoing development make it a pivotal component in modern aviation safety systems.

We work alongside both open-source communities and commercial entities to ensure that MIPS is well-supported across many leading Real Time Operating Systems (RTOS) as well as emerging IoT-targeted Operating Systems. Furthermore, we have created the MIPS Embedded Operating System (MEOS), which incorporates Virtualization extensions specifically designed for deeply embedded applications and the IoT sector. As MIPS’ proprietary real-time operating system, MEOS is prioritized for updates, ensuring it is the first to incorporate new cores and architectural advancements. The latest release, version 3.1, introduces a virtualization library that transforms MEOS into a hypervisor compatible with MIPS cores featuring the MIPS Virtualization module. Additionally, we are committed to fostering the development of open-source real-time and IoT operating systems by providing engineering resources and supplying necessary development hardware and tools whenever feasible. This collaborative approach not only enhances the ecosystem but also accelerates innovation in the field.

LynxOS has been utilized in countless embedded devices, demonstrating dependable performance for over three decades in various safety and security-sensitive markets. This operating system offers a proven method for running applications within a Unix-like environment, where a unified kernel manages all resources and application services, making it particularly effective for hardware designs that were developed before the advent of virtualization. We aim to ensure our customers purchase only what is necessary for their specific needs. While real-time operating systems (RTOS) can deliver significant advantages, they are not essential for every embedded system configuration. For a more extensive overview of our resources related to RTOS, we invite you to explore our Embedded Systems Learning Center, which provides valuable information to assist you in making informed software purchasing choices as you design or enhance your system and evaluate potential real-time platform vendors. Moreover, this center is a great resource to help you understand the trade-offs and benefits associated with various embedded system approaches.

Enea OSE is a powerful and efficient real-time operating system specifically designed for multi-processor environments that demand genuine deterministic real-time performance and exceptional reliability. By streamlining the development process, it improves system reliability and minimizes long-term maintenance expenses across a diverse array of applications, including wireless technology, automotive solutions, medical devices, and telecom infrastructure. Tailored for communication and control systems, Enea OSE excels in delivering high performance alongside stringent real-time requirements. Its widespread implementation spans several sectors, including telecommunications, industrial automation, and embedded systems, ensuring its relevance in modern technology. Notably, the Enea OSE multicore kernel, which has garnered two prestigious awards, combines the user-friendly aspects of Symmetric Multi-Processing (SMP) with the scalability and deterministic benefits of Asymmetric Multi-Processing (AMP), all while maintaining the high performance characteristic of bare metal operation. This unique architecture makes Enea OSE a compelling choice for developers seeking reliability and efficiency in their multi-core applications.

embOS stands as a priority-driven real-time operating system (RTOS) that serves as a robust foundation for embedding applications, with ongoing development since its inception in 1992. It supports all major processor architectures, compilers, and development environments, having found its way into billions of devices across diverse sectors. Engineers have consistently favored embOS in the embedded market due to its reliability and user-friendly nature. The system ensures 100% deterministic real-time performance for all types of embedded devices, making it a trusted choice. Highly portable and fully source-compatible across different platforms, embOS allows for straightforward application migration between various cores. Developers can create tasks with ease and facilitate secure communication among them through mechanisms such as semaphores, mailboxes, and events. Furthermore, embOS offers a free version for non-commercial applications, such as educational and evaluative purposes, which comes without any technical restrictions. This accessibility encourages experimentation and innovation in the field of embedded systems.

NuttX is a real-time operating system (RTOS) that prioritizes compliance with standards and maintains a compact footprint. It is adaptable, functioning effectively across microcontroller environments ranging from 8-bit to 32-bit, with its core standards being Posix and ANSI. To enhance its functionality, NuttX integrates additional standard APIs from Unix and various popular RTOSs, including VxWorks, particularly for features not encompassed by these core standards or unsuitable for deeply embedded systems, like the fork() function. Currently, Apache NuttX is in the Incubation phase at The Apache Software Foundation (ASF), with support from the Incubator. This incubation phase is mandatory for all newly accepted projects until a thorough evaluation confirms that their infrastructure, communication, and decision-making processes have reached a level of stability comparable to that of established ASF projects. The goal is to ensure that all projects can operate effectively and contribute meaningfully to the community.

DuinOS is a compact real-time operating system (RTOS) that supports multithreading and is built on the FreeRTOS kernel, designed specifically for boards compatible with Arduino. The project is undergoing a redevelopment using a fresh strategy, currently utilizing FreeRTOS 10 and plans to incorporate ARM Cortex-M technology in the near future; if you are interested in becoming a Beta Tester, please reach out via the project's official website. This initiative aims to enhance the functionality and performance of Arduino platforms significantly.

Tizen is a versatile and open-source operating system designed from its inception to meet the diverse requirements of all participants in the mobile and connected device landscape, which encompasses manufacturers, mobile network operators, app developers, and independent software vendors (ISVs). This platform is utilized commercially across various devices, including smart TVs, smartphones, wearable technology like the Gear S and Gear Fit, as well as smart home gadgets. Despite its broad applications, there has been a notable lack of focus on entry-level and budget-friendly IoT devices, such as home appliances that lack displays and wearable bands featuring minimal LCD screens. The aim of TizenRT is to broaden the reach of the Tizen platform to include these types of low-end devices, thereby enhancing its versatility and accommodating a wider array of connected technologies. By doing so, TizenRT hopes to foster innovation and accessibility in the IoT market, ensuring that even the simplest devices can benefit from advanced connectivity.

The µ-velOSity RTOS stands out as the most compact option within Green Hills Software's suite of real-time operating systems. Developed as a C library, it is highly adaptable for various target architectures, facilitating easy integration. Its streamlined architecture is closely aligned with the MULTI IDE, making µ-velOSity not only straightforward to learn but also user-friendly. By providing a clear and concise API, it helps to shorten development timelines and enhance the maintainability of products. Consequently, this can lead to cost reductions and faster time-to-market for developers transitioning from standalone or no-OS setups. Thanks to its efficient architecture and small memory footprint, µ-velOSity outperforms many competitors by fitting seamlessly within on-chip memory. This design choice eliminates reliance on off-chip memory, significantly boosting execution speed. Furthermore, the RTOS has been engineered to minimize CPU clock cycles during booting, an essential feature for embedded systems that demand rapid startup times. Additionally, µ-velOSity is exceptionally suited for embedded devices that have strict power consumption constraints, ensuring optimal performance without compromising energy efficiency. In summary, µ-velOSity provides a robust solution for developers seeking a reliable and efficient RTOS for various embedded applications.

The SCIOPTA architecture is meticulously crafted to ensure outstanding real-time performance while maintaining a compact size. Its internal data structures, memory management, interprocess communication, and time management are all finely tuned for efficiency. Functioning as a pre-emptive real-time kernel, SCIOPTA allows interrupts to be handled at any moment, even during kernel execution. This operating system relies on a message-based model, providing a robust array of system calls for effective resource management. With standardized processes and interprocess communication protocols, SCIOPTA promotes clear system designs that are both easy to implement and maintain. The well-defined messaging system allows processes to communicate seamlessly and enables the grouping of processes into modules, making SCIOPTA particularly advantageous for collaborative efforts in large projects. The streamlined design significantly accelerates time-to-market, enhancing overall project efficiency. Moreover, the direct message passing capability between processes facilitates not only interprocess communication but also synchronization, further optimizing system performance.

At the core of every embedded operating system lies a kernel, which plays a crucial role in task scheduling and multitasking to guarantee that the timing demands of your application code are fulfilled, even as you frequently enhance and modify that code with new functionalities. However, Micrium OS offers more than just a kernel; it includes a variety of supplementary modules designed to assist you in addressing the specific requirements of your project. Furthermore, Micrium OS is available completely free for use on Silicon Labs EFM32 and EFR32 devices, allowing you to integrate Micrium’s high-quality components into your projects today without incurring any licensing costs. This accessibility encourages innovation and experimentation, ensuring that developers can focus on creating robust applications without the worry of financial constraints.

The Keil RTX is a deterministic, royalty-free real-time operating system tailored for ARM and Cortex-M devices, enabling the development of applications that can handle multiple tasks concurrently, resulting in more organized and maintainable code. This RTOS comes with source code, allowing for greater flexibility in programming. While it is feasible to implement real-time applications without an RTOS by using a Super-loop to run one or more functions, doing so can lead to various challenges related to scheduling, maintenance, and timing, all of which are efficiently managed by the Keil RTX. For those interested in understanding the benefits of an RTOS compared to a Super-loop approach, a detailed comparison highlights the advantages of adopting an RTOS. Additionally, Keil RTX offers high-speed real-time operations with minimal interrupt latency and a compact footprint suitable for resource-limited systems. It supports an unlimited number of tasks, each capable of having up to 254 levels of priority, as well as an infinite number of mailboxes, semaphores, mutexes, and timers, making it an ideal choice for applications requiring multithreading and thread-safe functionality. Overall, the Keil RTX provides developers with a powerful toolset for creating efficient and robust real-time applications.

SAFERTOS® serves as a pre-certified safety Real Time Operating System (RTOS) specifically designed for embedded processors, offering outstanding performance alongside reliable dependability while consuming minimal resources. Customized for your unique processor/compiler combination, SAFERTOS® comes with complete source code and our comprehensive Design Assurance Pack (DAP). This DAP provides full visibility into the entire Design Life Cycle and showcases the exceptional quality of our RTOS solution. Leveraging our significant expertise in Safety Critical design, we have streamlined the certification of SAFERTOS® as part of a product, making the process straightforward and efficient. Developed with a focus on the safety sector, SAFERTOS® incorporates deterministic priority-based scheduling as a core Safety Requirement, ensuring that all efforts are directed towards maintaining predictable behavior throughout its operation. This commitment to reliability not only enhances system performance but also instills confidence in users who rely on such critical applications.

Wind River's eLxr Pro is a robust, commercial-grade Linux solution tailored for a wide range of cloud-to-edge applications, capable of handling critical workloads such as artificial intelligence, machine learning, and computer vision tasks. This solution is derived from the open-source eLxr distribution and delivers adaptable, long-term support alongside continuous security monitoring and updates. It guarantees compatibility with various hardware accelerators and meets necessary industry compliance standards. Additionally, eLxr Pro enhances business operations by offering specialized consulting services and performance improvements, enabling organizations to efficiently scale their edge computing capabilities while effectively managing expenses, ensuring security, and optimizing resource use. By integrating these features, eLxr Pro positions businesses to thrive in an increasingly digital landscape.

Semantic Kernel is an open-source development toolkit that facilitates the creation of AI agents and the integration of cutting-edge AI models into applications written in C#, Python, or Java. This efficient middleware accelerates the deployment of robust enterprise solutions. Companies like Microsoft and other Fortune 500 firms are taking advantage of Semantic Kernel's flexibility, modularity, and observability. With built-in security features such as telemetry support, hooks, and filters, developers can confidently provide responsible AI solutions at scale. The support for versions 1.0 and above across C#, Python, and Java ensures reliability and a commitment to maintaining non-breaking changes. Existing chat-based APIs can be effortlessly enhanced to include additional modalities such as voice and video, making the toolkit highly adaptable. Semantic Kernel is crafted to be future-proof, ensuring seamless integration with the latest AI models as technology evolves, thus maintaining its relevance in the rapidly changing landscape of artificial intelligence. This forward-thinking design empowers developers to innovate without fear of obsolescence.

Following an extensive development process that included numerous beta versions and release candidates to ensure perfection, we are excited to introduce the new stable release. This version features comprehensive updates across the system, incorporating the latest development tools, as well as updated applications, window managers, desktop environments, and utilities. The Linux kernel has been upgraded to version 4.4.14, which is part of the long-term support 4.4.x kernel series, ensuring ongoing maintenance and security. We have meticulously curated a selection of modern components and enhanced them to create a seamless user experience. For those familiar with Slackware, you will find that this release feels just like home. If you're interested in trying Slackware 14.2 without making any changes to your hard drive, the Slackware Live Edition is an excellent option. This version allows you to run a full Slackware installation directly from a CD, DVD, or USB drive. Additionally, we provide build scripts for a wide array of supplementary software tailored for Slackware 14.2, ensuring that users have everything they need to customize their experience. With this release, we aim to continue the legacy of reliability and performance that Slackware is known for.

Introducing a Real-Time Engagement Platform designed to foster genuine human interactions. When individuals can see, hear, and respond to one another, their engagement time increases significantly. With Agora, you can seamlessly integrate immersive voice and video capabilities into any application, accessible on any device and from anywhere. Agora offers a suite of SDKs and foundational elements that unlock a myriad of real-time engagement opportunities. Our network actively tracks performance, selecting the optimal routing path to ensure sub-second latency across a global infrastructure of over 200 data centers. It is designed to work with all major development platforms and is optimized for mobile devices to minimize battery drain. Built to handle sudden increases in traffic, it can effortlessly scale from one user to millions, meeting your business needs. Developers have the freedom to craft bespoke experiences through our comprehensive APIs, customizable user interfaces, and readily available third-party integrations. By choosing Agora, you provide your users with superior quality real-time voice and video, featuring intelligent routing and ultra-low latency for an unmatched experience. With such capabilities, Agora positions itself as a leader in the realm of real-time communications.

Atmel START serves as a groundbreaking online platform designed for the straightforward, visual setup of embedded software projects. This tool enables users to choose and configure a variety of software components, drivers, middleware, and even complete example projects that are customized to meet specific application requirements. During the configuration process, you can assess the relationships among software components, identify potential conflicts, and understand hardware limitations. If any conflicts arise, Atmel START promptly offers tailored solutions that align with your unique configuration. With its user-friendly graphical interface for pin-multiplexing and clock settings, you can seamlessly integrate your software and drivers with your actual hardware design. Additionally, the tool offers automated support to facilitate the adaptation of projects and applications across different devices. This makes it incredibly simple to get sample code operational on your hardware. Once you've finished configuring your project, you can easily download it for integration with your chosen integrated development environment (IDE), streamlining the entire development process even further. Overall, Atmel START enhances the efficiency and effectiveness of developing embedded software projects.

TotalAPI is designed as a sophisticated software development platform that addresses the complex task of organizing modern enterprise software solutions. By utilizing this platform, developers can focus on solving business logic issues without the burden of managing software infrastructure. The TotalAPI framework enables the creation of scalable software packages that are optimized for distributed environments from the outset. It offers an intuitive interface that minimizes labor costs and reduces the risks associated with challenges typical in distributed business applications. For instance, it simplifies the setup for message exchanges between different components of the software package and facilitates access to business objects and interfaces of software modules. Moreover, developers tasked with implementing essential server-side business logic can seamlessly integrate TotalAPI kernel modules, which facilitate communication between diverse information systems. In this way, TotalAPI not only enhances efficiency but also empowers developers to innovate and adapt to changing demands in the enterprise software landscape.

Minoca OS is a versatile, open-source operating system tailored for advanced embedded devices. It combines the expected high-level features of an OS while significantly reducing the memory usage. By utilizing a driver API that decouples device drivers from the kernel, it ensures that driver binaries remain compatible across kernel updates. This separation of drivers facilitates dynamic loading and unloading based on demand. The hardware layer API creates a cohesive kernel, eliminating the need for a separate kernel fork, even on ARM architecture. Additionally, a unified power management system enables more intelligent energy-saving decisions, ultimately enhancing battery longevity. With fewer background processes and reduced wake-ups from idle states, devices can enter deeper power-saving modes, thereby optimizing energy consumption further. The availability of both proprietary and non-GPL source licenses provides flexibility for customers and end-users, ensuring a broad range of options for deployment. This adaptability makes Minoca OS an appealing choice for developers seeking efficiency and performance in embedded systems.

Developers experience significantly higher productivity levels when using Ubuntu compared to custom embedded Linux systems. By utilizing a shared platform, costs can be reduced, as licensing becomes more affordable, updates are more thoroughly tested, and maintenance responsibilities are distributed. The widespread familiarity and usage of Ubuntu facilitate seamless CI/CD processes, access to superior tools, quicker updates, and more reliable kernels. In this context, Linux itself does not provide a competitive edge; instead, leveraging pre-configured boards allows teams to concentrate on software that is distinctively aligned with their objectives. Managing a well-known environment and platform proves to be both easier and more cost-effective than operating a specialized operating system. Unsurprisingly, a larger number of Linux developers prefer Ubuntu, resulting in a richer and more diverse talent pool. By tapping into this expansive talent reservoir, organizations can benefit from Ubuntu's clear advantages across various metrics. Ultimately, productivity thrives on the principle of reuse, and developers can be empowered by accessing the widest selection of packages available. This strategy not only streamlines processes but also accelerates project timelines, leading to enhanced outcomes.

Amazon Simple Queue Service (SQS) is a fully managed message queuing platform designed to help you decouple and scale microservices, distributed systems, and serverless applications. By removing the complexity and overhead typically associated with message-oriented middleware, SQS allows developers to concentrate on more impactful tasks. With SQS, you can effortlessly send, store, and receive messages between various software components at any scale, ensuring message integrity and independence from other services. You can quickly begin using SQS in just minutes through the AWS console, Command Line Interface, or your preferred SDK, executing three straightforward commands. This service enables the transmission of any data volume at any throughput level while maintaining message reliability and service independence. Additionally, SQS facilitates the decoupling of application components, which allows them to operate and fail independently, ultimately enhancing the fault tolerance of the overall system. By leveraging SQS, organizations can achieve greater resilience and adaptability in their application architecture.

Keil® MDK stands out as the ultimate software development package for Arm®-based microcontrollers, encompassing all necessary elements for crafting, building, and troubleshooting embedded applications. The foundation of MDK-Core lies in µVision (exclusive to Windows), offering exceptional support for Cortex-M devices, especially with the introduction of the advanced Armv8-M architecture. Within MDK, users gain access to the Arm C/C++ Compiler, which is accompanied by an assembler, linker, and highly efficient run-time libraries designed for optimal code size and performance. Additionally, users can enhance MDK-Core at any moment by integrating Software Packs, allowing for seamless updates in device support and middleware that are independent of the toolchain. These packs consist of device support, CMSIS libraries, middleware, board support, code templates, and illustrative example projects. Furthermore, the integrated IPv4/IPv6 networking communication stack is augmented with Mbed™ TLS, facilitating secure online connections. This powerful tool is ideal for product evaluation, smaller projects, and educational purposes, although it does impose a restriction on code size to a maximum of 32 Kbytes, making it suitable for various embedded applications while still being resource-efficient.

As a component of the TestGenius Pre-Employment Testing Suite, CritiCall software assesses the essential multitasking and computer skills of applicants for roles such as 911 dispatcher, public-safety dispatcher, call taker, and telecommunicator, which are critical in the modern dispatch and telecommunication landscape. This innovative tool empowers agencies to measure the specific skills and multitasking capabilities needed in a computer-driven telecommunication setting. CritiCall offers flexibility by being accessible online without supervision or available for supervised testing in-person. It is designed to become an integral element of your organization’s evaluation process for dispatcher and call-taker candidates. The testing is fully automated, and CritiCall's modular design supports tailored assessments to meet the unique requirements of each agency. Moreover, the Test Writer feature enables the creation of custom tests in various formats, ensuring that your testing needs can be met effectively. Thus, CritiCall stands out as a versatile solution for agencies looking to enhance their applicant assessment strategies.

Transform your Postman collection into comprehensive test suites that seamlessly integrate with your CI/CD pipeline. By simply providing a link to your Postman collection, you can generate detailed test suites efficiently. Additionally, you can engage Kusho AI with fundamental API details for manual prompts. This tool operates in harmony with your development workflow and automatically updates as needed. In today's fast-paced software teams, multitasking is essential, yet the process of writing test cases can consume significant time that developers could spend on other critical tasks. At KushoAI, we are creating an innovative AI agent designed to alleviate the burden of API testing from developers. This allows them to concentrate on their core competencies, resulting in smoother product releases than ever before. You can generate thorough test suites for each API, ultimately saving countless hours of manual effort. The system is adaptable to align with your organization's specific needs; just provide additional prompts in natural language and receive test code in mere seconds. KushoAI adeptly interprets your natural language requests and delivers test case code instantly. Furthermore, KushoAI has the capability to automatically execute pertinent test suites at any phase of your CI/CD pipeline, ensuring that your testing process remains efficient and effective. Embrace a future where developers can maximize their productivity while relying on intelligent tools like KushoAI for thorough and timely testing.

Langflow serves as a low-code AI development platform that enables the creation of applications utilizing agentic capabilities and retrieval-augmented generation. With its intuitive visual interface, developers can easily assemble intricate AI workflows using drag-and-drop components, which streamlines the process of experimentation and prototyping. Being Python-based and independent of any specific model, API, or database, it allows for effortless integration with a wide array of tools and technology stacks. Langflow is versatile enough to support the creation of intelligent chatbots, document processing systems, and multi-agent frameworks. It comes equipped with features such as dynamic input variables, fine-tuning options, and the flexibility to design custom components tailored to specific needs. Moreover, Langflow connects seamlessly with various services, including Cohere, Bing, Anthropic, HuggingFace, OpenAI, and Pinecone, among others. Developers have the option to work with pre-existing components or write their own code, thus enhancing the adaptability of AI application development. The platform additionally includes a free cloud service, making it convenient for users to quickly deploy and test their projects, fostering innovation and rapid iteration in AI solutions. As a result, Langflow stands out as a comprehensive tool for anyone looking to leverage AI technology efficiently.

You set it up once and then enjoy its benefits indefinitely. There's no need to fret every six months about significant system upgrades that could potentially render your device unusable. Instead, you receive regular updates that not only tackle security vulnerabilities and eliminate bugs but also introduce the latest features and advancements, including updated kernels, new drivers, and the most current desktop environment versions. Each update undergoes rigorous testing in line with industry-leading quality standards, utilizing a build service that other Linux distributions aspire to emulate. Not only is every new package version tested individually, but various clusters of versions are also compared to ensure your system's internal consistency. With just one command, you can update thousands of packages, revert to a snapshot from the previous week, fast-forward to the latest changes, and even preview what future releases will look like. This streamlined process allows users to seamlessly manage their systems without the usual headaches associated with traditional upgrades.

RTMaps is a component-based middleware for development and execution that is highly optimized. RTMaps allows developers to design complex real-time algorithms and systems for their autonomous applications, such as mobile robots and railways. RTMaps offers a variety of benefits to help you develop and execute an application. • Asynchronous data acquisition • Optimised performance • Synchronized recording and playback • Comprehensive component libraries: Over 600 I/O components available • Flexible algorithm development - Share and collaborate Multi-platform processing • Scalable and cross-platform: from PCs, embedded targets, to Cloud. • Rapid prototyping & testing • Integration with dSPACE Tools • Time and Resource Savings • Limiting development risks, errors and effort • Certification ISO26262 ASIL-B: on demand

Superexpert.AI is a collaborative open-source platform designed to empower developers to create advanced, multi-tasking AI agents without the necessity of coding. This platform facilitates the development of a wide range of AI applications, ranging from basic chatbots to highly sophisticated agents capable of managing numerous tasks simultaneously. Its extensible nature allows for the seamless integration of custom tools and functions, and it is compatible with multiple hosting services such as Vercel, AWS, GCP, and Azure. Among its features, Superexpert.AI includes Retrieval-Augmented Generation (RAG) for optimized document retrieval and supports various AI models, including those from OpenAI, Anthropic, and Gemini. The architecture is built using modern technologies like Next.js, TypeScript, and PostgreSQL, ensuring robust performance. Additionally, the platform offers an intuitive interface that simplifies the configuration of agents and tasks, making it accessible even for individuals without any programming background. This commitment to user-friendliness highlights a broader goal of democratizing AI development for a wider audience.

Yandex Cloud allows users to build fully operational applications using a collection of seamlessly integrated components. These applications come pre-configured with necessary integrations to Yandex Cloud services, and the deployment process is streamlined and automated. You have the flexibility to deploy your application's source code directly within your own cloud environment, making it easy to tailor the code to your specific requirements. The platform employs templates that have been developed and rigorously tested by the Yandex Cloud team to facilitate application deployment. Utilizing cloud applications can help you maximize efficiency in the cloud, ultimately saving time that would typically be spent on component rollouts. A comprehensive suite of tools is available for deploying code alongside Yandex Cloud services. Although there are costs associated with the services, the applications themselves can be accessed free of charge. The service automatically manages the deployment and configuration of all necessary Yandex Cloud components for the application to operate effectively. Resources are allocated under the specific service account designated for the application, and the platform also keeps a record of the resources created. This systematic approach ensures that all aspects of application deployment are handled with precision and efficiency.

The latest release of DragonFly, version 6.2.2, introduces several enhancements, including hardware compatibility for type-2 hypervisors utilizing NVMM, an upgraded amdgpu driver, and the experimental feature of remote-mounting HAMMER2 volumes, alongside a variety of other updates. As a member of the BSD family of operating systems, DragonFly shares its roots with Linux and other BSD variants, adhering to the foundational principles and APIs of UNIX while also diverging in terms of development direction from FreeBSD, NetBSD, and OpenBSD. This divergence allows DragonFly to pursue unique innovations, such as its sophisticated HAMMER filesystem, which offers high performance, built-in mirroring, and historical access capabilities. Additionally, one of the standout features is the implementation of virtual kernels, enabling the execution of a complete kernel as a user process, which facilitates resource management, kernel development, and debugging in an accelerated environment. These features collectively position DragonFly as a distinctive option within its operating system category, appealing to users seeking alternatives beyond conventional solutions.