Alternatives to RIOT

TinyOS is a freely available operating system under the BSD license, specifically crafted for energy-efficient wireless devices that are utilized in various applications like sensor networks, ubiquitous computing, personal area networks, smart buildings, and smart meters. Its development and support come from a global community comprised of both academic and industrial contributors, with an impressive average of 35,000 downloads annually. Recently, the transition to GitHub for hosting has been finalized, which involves gradually phasing out the existing TinyOS development mailing lists for bug tracking and issues, in favor of utilizing GitHub's tracking system. We extend our gratitude to all the dedicated developers who are actively enhancing TinyOS and facilitating pull requests for improvements, thereby fostering a collaborative development environment that benefits all users. This evolution signifies a major step forward in streamlining communication and collaboration within the TinyOS community.

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.

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.

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.

Android Things provides an opportunity to create devices on a reliable platform, even for those who lack prior experience in embedded system design: You can utilize the Android SDK and Android Studio for development, interact with hardware components like displays and cameras through the Android framework, and utilize the Android Things Console to deliver over-the-air updates for features and security. This platform allows developers to create applications on widely-used hardware systems such as the Raspberry Pi 3. Google's management of the Board Support Package (BSP) means that developers are free from the need to engage in kernel or firmware development. Through the Android Things Console, software images are constructed and sent to devices, ensuring a dependable development environment with regular updates and patches from Google. Consequently, developers can focus on innovation while relying on a robust framework that simplifies the process of building and maintaining their devices.

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.

Contiki-NG is a free and open-source operating system designed for the next generation of Internet of Things (IoT) devices, emphasizing reliable and secure low-power communication along with standard protocols like IPv6/6LoWPAN, 6TiSCH, RPL, and CoAP. The platform is accompanied by comprehensive documentation, tutorials, a clear roadmap, and a structured development process that facilitates the integration of contributions from the community. By default, unless stated otherwise, the sources of Contiki-NG are available under the 3-clause BSD license, which permits users to utilize and share the code in both binary and source formats, provided that the copyright notice is preserved in the source materials. This licensing model supports an open collaborative environment that promotes innovation and community engagement in IoT development. Contiki-NG aims to foster a vibrant ecosystem for developers and users alike, ensuring that they can build upon and enhance the existing frameworks.

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.

Mongoose OS is an open-source operating system available in two variants: Community and Enterprise. It offers reliable Over-The-Air updates, secure device provisioning, and remote management, ensuring trusted and proven performance in various applications. Released under the Apache 2.0 license, it allows for commercial licensing and support options. Mongoose OS has been integrated into numerous commercial products, with hundreds of millions of devices actively deployed in production settings. As a recognized partner of Google Cloud IoT Core, it is also recommended by Microsoft Azure IoT for its capabilities in OTA updates, automatic device management, and large-scale firmware deployment. The Azure IoT Hub showcases how to effectively manage firmware updates for devices using Mongoose OS through Over-The-Air capabilities, while Google Cloud IoT Core utilizes MQTT for seamless communication between devices. This robust platform continues to evolve, catering to the needs of developers and organizations focusing on IoT solutions.

The advent of containers is set to transform the landscape of connected devices, with balenaOS standing out as the premier solution for their deployment. Designed to endure challenging networking scenarios and sudden power losses, it is a stripped-down version of Linux that includes only the essential services for running Docker efficiently on embedded hardware. Built on the foundation of Yocto Linux, it allows for seamless adaptation across a wide range of device types and CPU architectures. The project is actively maintained in a transparent manner, fostering a community that is encouraged to contribute. In our initiative to create balenaCloud—a platform that integrates modern software development tools with connected hardware—we began by adapting Docker for ARM processors in 2013. This experience highlighted the necessity for a dedicated operating system tailored to this specific use case: a lightweight OS perfectly suited for executing containers on embedded devices. Furthermore, this focus on optimization ensures that developers can maximize the potential of their connected solutions.

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.

Fuchsia is an innovative open-source operating system developed by Google that is currently undergoing continuous enhancement. The system is being constructed from the kernel upwards to address the demands of today’s expanding network of connected devices. Although Fuchsia is still in a state of rapid evolution, its foundational principles and values have remained largely consistent throughout its development. The main architectural principles that steer Fuchsia’s design are rooted in security, updatability, inclusivity, and pragmatism. These guiding principles—secure, updatable, inclusive, and pragmatic—form the backbone of Fuchsia's ongoing design and development efforts. As a community-driven project, Fuchsia encourages high-quality, well-tested contributions from anyone interested in participating. Even though there are various frameworks that have been suggested to influence its design, Fuchsia remains a dynamic work in progress. As it continues to evolve, Fuchsia aims to adapt to the changing needs of developers, manufacturers, and consumers alike, ensuring it remains relevant in an ever-shifting technological landscape. The commitment to an open-source model underlines the importance of collaboration and community engagement in shaping the future of Fuchsia.

With the Toradex Easy Installer, TorizonCore can be set up effortlessly in just one click. You will find that the Graphical User Interface (GUI) and Debian containers equipped with the APT Package Manager allow for a quick and easy start. Moreover, a growing array of development tools, including the Flash Analytics tool, facilitates the rapid development of dependable products. Built with the Yocto Project and based on the Toradex Embedded Linux BSP, TorizonCore is open-source, allowing for extensive customization options. Additionally, Torizon seamlessly integrates with Visual Studio 2019, empowering developers to utilize a Windows development PC while benefiting from the robust Linux ecosystem. Although Toradex continues to offer support for Windows Embedded Compact / WinCE, transitioning to Torizon with Visual Studio presents a compelling opportunity for developers eager to embrace the advantages of Linux. This combination not only enhances productivity but also encourages innovation in software development.

The Device OS provides a user-friendly programming framework that simplifies the creation of applications for your devices. With just a single line of code, you can securely transmit messages to the web. There are four essential communication primitives available for interaction with the web via the Device Cloud. This platform stands out as the only IoT solution that offers a complete integration of hardware, software, connectivity, and cloud infrastructure right from the start, enabling you to quickly and safely execute OTA updates of any size. The setup process is straightforward, allowing you to implement remote updates within minutes without the need for custom integrations. Our distinctive Intelligent Firmware Release feature incorporates context awareness, allowing fleet-wide OTA firmware updates to be completed in mere minutes. Moreover, Particle supports both individual device and fleet-wide OTA functionalities that effortlessly scale with your fleet, accommodating everything from prototypes to full-scale production. This ensures that as your needs evolve, the platform can adapt accordingly.

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.

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.

Address the requirements of your application by selecting from a variety of open-source networking frameworks such as Bluetooth Low Energy 5, Bluetooth Mesh, Wi-Fi, LoRaWAN, and several others. It is crucial to incorporate security directly into the code, along with effective lifecycle management for your product. Prepare your IoT ecosystem, which may comprise billions of devices, for tasks related to remote monitoring, troubleshooting, management, and upgrades. You can create, adjust, and develop your image in a matter of hours or even mere minutes, streamlining the deployment process significantly. This flexibility enables rapid adaptation to changing needs and enhances overall efficiency.

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.

To set up your first user on an Ubuntu Core installation, you'll need an Ubuntu SSO account. This guide will detail the process of flashing Ubuntu Core onto a Raspberry Pi 2, 3, 4, or CM3. By the conclusion of these steps, your board will be fully prepared for either production use or testing snaps. Once the installation is complete, you will be ready to install snaps using the snap command. The Snap Store offers a variety of top-tier Linux applications packaged as snaps, enabling you to enhance your Ubuntu device and embark on your secure IoT journey. With this setup, you'll be equipped to explore numerous applications tailored for your needs.

By developing on the Windows platform, you become part of a global network of partners that encompasses a range of hardware and software solutions, integrations, and services. You can take advantage of our ever-evolving feature set and developer-friendly tools, ensuring a seamless experience in building devices. Windows IoT offers a guaranteed 10-Year OS Lifecycle Support through our Long-Term Servicing Channel (LTSC), with no unexpected costs involved. Furthermore, it maintains backward compatibility in accordance with Microsoft's application compatibility promise. Leveraging Windows IoT, you can utilize Azure services to create tailored IoT solutions that meet your specific needs. Azure boasts the most extensive portfolio of cloud services and capabilities, designed to align with the demands of various industries. Additionally, Windows IoT seamlessly integrates with existing device management solutions, enhancing your operational efficiency in the IoT landscape. The combination of these features empowers developers to innovate and streamline their projects effectively.

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.

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.

MindSphere® stands out as a premier solution for industrial IoT delivered as a service. Leveraging cutting-edge analytics and artificial intelligence, it facilitates the development of IoT applications that span from edge devices to the cloud, utilizing data from interconnected products, facilities, and systems to enhance operational efficiency, improve product quality, and foster innovative business models. Constructed on the Mendix application platform, MindSphere enables clients, partners, and the Siemens team to swiftly create and integrate tailored IoT applications. Our knowledgeable team is ready to assist you with any inquiries and guide you in initiating your journey with MindSphere. By connecting assets and transferring data to the cloud, users can gather, oversee, and interpret information in real-time, thus capitalizing on applications and solutions that address genuine challenges. Additionally, you can develop applications that amplify the financial value derived from your data and benefit from an open development and operational environment, allowing for greater flexibility and innovation in your projects. The possibilities with MindSphere are extensive, paving the way for transformative advancements in your business operations.

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.

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.

Torizon enhances developer efficiency and facilitates the creation of products that are easy to maintain. With integrated over-the-air updates and device monitoring, it enables earlier shipping, bug patching in the field, the rollout of new features, and quicker issue detection. The use of software containerization not only simplifies maintenance but also adds an extra layer of resilience. Regular validation on Toradex System on Modules (SoMs) ensures that developers can concentrate entirely on their applications without worrying about the operating system. Torizon supports an agile and iterative development process, allowing teams to adapt quickly to changes. Its seamlessly integrated remote update capabilities make deploying new software a breeze, while real-time device monitoring provides immediate insights into performance and potential problems, enhancing overall product reliability. This combination of features ultimately empowers developers to innovate and respond to market demands more effectively.

Accelerate the launch of your critical embedded systems with our commercial real-time operating system (RTOS), along with our comprehensive development tools and services. BlackBerry QNX provides a proven RTOS, hypervisor, and a suite of embedded software designed to ensure your success. Our platform is the preferred choice for applications ranging from ventilators and train control systems to factory automation and medical robotics. Regardless of whether your focus is on achieving safety certification, enhancing security, or maximizing performance, our solutions can help you develop more dependable products. If your goals include improving security or ensuring safety, or if you aim to simplify your cross-platform development workflow, we are here to assist. We specialize in bringing your projects to fruition with an RTOS and hypervisor specifically designed for embedded systems, including options that come pre-certified. Our modular microkernel architecture not only enhances reliability but also reduces the need for duplicative OS development efforts across various products, allowing for more efficient use of resources. By choosing BlackBerry QNX, you are investing in the future of embedded systems development.

The MicroPython pyboard is a small yet powerful electronic circuit board that operates MicroPython directly on the hardware, enabling a low-level Python environment suitable for managing various electronic projects. This implementation of MicroPython is rich in features, including an interactive prompt, arbitrary precision integers, closures, list comprehension, generators, and exception handling, among others. Remarkably, it is designed to fit and function within a mere 256k of code space and 16k of RAM. MicroPython's primary goal is to maintain a high degree of compatibility with standard Python, facilitating seamless code transfer from desktop environments to microcontrollers or embedded systems. Additionally, this flexibility makes it an excellent choice for hobbyists and professionals alike, as they can leverage their existing Python skills in new hardware applications.

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.

Raspberry Pi Imager offers a fast and straightforward method for installing Raspberry Pi OS along with various other operating systems onto a microSD card, making it ready for your Raspberry Pi. To understand the installation process, check out our brief 45-second video tutorial. Begin by downloading and installing Raspberry Pi Imager on a computer equipped with an SD card reader. Insert the microSD card intended for your Raspberry Pi into the reader and launch Raspberry Pi Imager. You can explore a variety of operating systems available from both Raspberry Pi and external providers, allowing you to download and install them manually as needed. This tool streamlines the setup process and enhances your Raspberry Pi experience.

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.

CloudMQTT serves as an excellent platform for facilitating "Internet of Things" communication among low-energy sensors or mobile devices, including smartphones, embedded systems, and microcontrollers like the Arduino. It streamlines every aspect of setting up and operating a hosted Mosquitto message broker, allowing your team to concentrate on product development without the hassle of server management. By entrusting these responsibilities to specialists, you can ensure optimal performance and reliability. With the CloudMQTT WebSocket client, you can effortlessly observe messages transmitted from your device to the browser, or vice versa, making it a valuable tool for testing and troubleshooting, as you can visualize real-time data from sensors or devices. Additionally, by inviting team members, you can maintain distinct CloudMQTT accounts while managing a shared pool of instances, giving you control over notification routing and billing responsibilities. This flexibility enhances collaboration while keeping everyone aligned with the project’s objectives.

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.

Nubix is an innovative container platform designed to simplify the development and deployment of Internet of Things (IoT) and edge applications. It is capable of operating on the smallest microprocessors, allowing developers to seamlessly process data directly on the sensor devices that generate it. Unlike traditional methods that necessitate complete firmware replacements—which can sometimes lead to devices becoming inoperable—Nubix mitigates this risk by utilizing tiny containers whose code operates independently from the underlying operating system, thereby enhancing release speed and reducing potential failures. Many existing edge architectures fail to provide true edge computing, compelling developers to send data to the cloud or intermediate gateways for processing. In contrast, Nubix's edge-native architecture empowers processing to occur directly on the devices where data originates, thus eliminating the latency and inefficiencies associated with external networking and remote data handling. Moreover, Nubix is founded on open source technologies, ensuring that users are not confined to proprietary languages and libraries, which enhances flexibility and long-term viability. This commitment to openness also fosters a community-driven approach to innovation, making it a compelling choice for developers seeking to advance their IoT initiatives.

Microshare® IoT provides instantaneous insights into your facilities through an extensive selection of thousands of sensing devices, enabling visibility into every area. With starter kits designed for a quick setup in just one day and without the need for IT involvement, our solution utilizes the open Low-Power, Long-range LoRaWAN™ network, allowing you to cut costs, boost operational efficiency, and enhance customer satisfaction simultaneously. This proven IoT solution is trusted by the world’s largest commercial real estate services and investment firms. Featuring carrier-grade LoRaWAN connectivity, our system offers easy installation, extended battery life, and secure, low-power communication for hundreds of sensors. Furthermore, our Smart Facilities solutions enhance this robust ecosystem of providers, giving airport operators increased options and improved value. We also collaborate with all major suppliers of LoRaWAN™ network servers, including Actility, Kerlink, Loriot, Orbiwise, The Things Network, and TrackNet, ensuring flexibility in deploying our solutions through private or dedicated networks, tailored to meet diverse operational needs. This commitment to versatility and reliability positions us as a leader in the IoT landscape.

The OpenPLC Editor is a completely free and open-source tool that adheres to the IEC 61131-3 standard for PLC editing. This software allows users to upload PLC code directly to any compatible board or system utilizing OpenPLC Runtime. OpenPLC represents a revolutionary shift in programmable logic controllers, offering an intuitive software interface that is fully open-source for both software and hardware aspects. The project was developed in line with the IEC 61131-3 standard, which outlines essential software architecture and programming languages for PLCs. It finds its primary applications in various fields, including industrial automation, home automation, IoT implementations, and SCADA research. The Runtime component is versatile, capable of operating on everything from minimal microcontrollers, such as Arduino, to powerful cloud servers. It plays a crucial role in executing the PLC programs that users develop through the Editor. Thus, the OpenPLC Editor serves as the primary interface for users to design and implement their PLC applications effectively.

QuarkLink, created by Crypto Quantique, is an all-encompassing security platform for IoT devices that aims to streamline and hasten the adoption of security-by-design practices within embedded systems. This Software-as-a-Service (SaaS) offering integrates effortlessly into current software development processes, such as CI/CD pipelines, enabling the management of device identities, secure boot procedures, firmware updates over the air, and the lifecycle management of keys and certificates. It accommodates a diverse array of hardware platforms, ranging from microcontrollers operating on bare metal to industrial PCs running Linux, and is compatible with leading semiconductor manufacturers. The modular design of QuarkLink permits the independent utilization of its various components, which include provisioning and secure boot, OTA updates, service onboarding, and fleet management alongside certificate management. By offering such versatility, QuarkLink empowers developers to tailor their security implementations to meet specific project needs effectively. Ultimately, this platform stands as a pivotal tool in enhancing the security landscape for IoT devices.

Eclipse Mosquitto is a message broker that is open source and licensed under EPL/EDL, designed to support various versions of the MQTT protocol, including 5.0, 3.1.1, and 3.1. This broker is notably lightweight, making it ideal for deployment on a wide range of devices, from low-power single-board computers to robust server systems. The MQTT protocol itself offers an efficient way to handle messaging through a publish/subscribe architecture, which is particularly well-suited for applications in the Internet of Things, enabling communication with low-power sensors or mobile devices like smartphones, embedded systems, and microcontrollers. In addition to the broker, the Mosquitto project also includes a C library that facilitates the creation of MQTT clients, alongside the widely used command line clients, mosquitto_pub and mosquitto_sub, which enhance user interaction with the MQTT protocol. Overall, Mosquitto serves as a versatile tool for developers aiming to implement messaging solutions in a variety of applications.

Safeguard your IoT data from initial creation to final consumption, ensuring protection at every stage of the journey. Protected Sessions revolutionizes data security by enabling secure bi-directional communication while eliminating the constraints imposed by various network protocols and diverse IoT environments. Tailored specifically for the IoT landscape, session lifecycles are designed to accommodate low-power microcontroller units (MCUs) that operate on low-power networks with sporadic connectivity, allowing Protected Sessions to uphold the integrity of your communication channels for durations ranging from mere seconds to several months. Employing robust, industry-standard encryption, CENTRI Protected Sessions is fine-tuned for resource-constrained devices, featuring data compression and a minimal footprint, thus ensuring both security and operational efficiency between the endpoint devices and the cloud infrastructure. By facilitating secure bi-directional communication between your IoT devices and application servers or cloud platforms, Protected Sessions fortifies your IoT ecosystem against potential vulnerabilities. This comprehensive approach not only enhances the reliability of IoT communications but also streamlines integration across various applications and services.

The emerging landscape of digital currency is rooted in transparency, yet this comes at a significant cost, as all your financial interactions are fully visible to your counterparties. Aztec serves as the ultimate fortress for safeguarding user and business information within Web3.0, ensuring that data remains confidential. By utilizing cryptographic techniques, it conceals the identities of both senders and recipients. Furthermore, the amounts involved in transactions are encrypted, preserving the privacy of your cryptocurrency holdings. Observers on the network are unable to determine the specific asset or service tied to any transaction, enhancing security. Developed on PLONK, a cutting-edge standard in universal SNARK technology, Aztec's solutions are crafted by an elite team of cryptographers. Transactions are processed in mere seconds across all devices, while our rollup service efficiently reduces gas fees and settles in just minutes. You can manage your DeFi positions discreetly and conduct trades under the protective umbrella of Aztec's privacy features. Whether it's programming private money, setting up escrow, facilitating money streaming, or handling micropayments, the possibilities are boundless. In this innovative ecosystem, privacy is not just an option; it is a fundamental principle that empowers users to transact freely without fear of exposure.

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.

HyperConnect serves as a robust, open-source framework designed for enterprise-level Internet-of-Things applications, leveraging the Elastos Peer-to-Peer Carrier Network to efficiently direct traffic among connected devices. Its modular design ensures a reliable foundation suitable for various industry sectors within the IoT landscape. Critical aspects such as communication, data transmission, and storage are essential components of the Internet of Things ecosystem. By visualizing data, users can extract valuable metrics, identify trends, and gain deeper insights. The integrated compiler enables the creation, management, and validation of Python scripts tailored for sensor management at a granular level. Furthermore, it enables real-time data collection from diverse sources, transforming raw inputs into actionable insights automatically. Users can effortlessly oversee and control numerous devices and sensors, whether on-site or from a distance, maintaining security throughout the process. The intuitive Graphical User Interface (GUI) is designed for maximum adaptability, allowing users to operate with little or no coding required. Additionally, the framework ensures secure peer-to-peer communication across the IoT network, empowering users to retain ownership of their data while enhancing overall system integrity and performance. This comprehensive approach not only simplifies the management of IoT systems but also promotes innovative applications across different sectors.

Address the complexities of overseeing IoT field area networks that encompass thousands or even millions of interconnected devices. The Cisco IoT Field Network Director (FND) serves as the comprehensive network management platform tailored for extensive FAN deployments. Factors such as environmental fluctuations and variations in cellular network coverage can significantly impact the connectivity and bandwidth of IoT gateways and devices. Cisco FND is specifically built to assist operations teams in navigating the lifecycle management of large-scale FANs, adapting to dynamic conditions and network limitations to maintain continuous functionality. It offers zero-touch deployment alongside secure enrollment for vast numbers of IoT gateways and endpoints. Additionally, it features role-based access controls, user audit trails, and secure communication methods for transporting IoT data via networks and VPN tunnels. Furthermore, it ensures dependable communication over both cellular and low-power networks for effective lifecycle management, alongside 24/7 real-time monitoring and alert systems. With automated enrollment and provisioning processes for gateways and endpoints, operational efficiency is greatly enhanced. This comprehensive suite of features positions Cisco FND as a vital tool in managing the evolving landscape of IoT networks.

The Cisco 2010 Connected Grid Router, marking the inaugural model in the Cisco 2000 Series, serves as an exceptional platform tailored to meet the communication demands of the energy delivery ecosystem spanning generation, transmission, and distribution sectors. This device has undergone rigorous testing and achieved KEMA certification, ensuring it adheres to stringent substation compliance standards such as IEEE 1613 and IEC 61850-3. The integration of Cisco IOS Software enhances this router's capabilities by providing robust security features necessary for NERC/CIP compliance, ensuring quality of service, and facilitating effective network management, which is critical for maintaining the integrity and prioritization of operational data communications. Its rugged industrial design is specifically engineered to withstand the harsh conditions of utility substation environments while adhering to IEC-61850-3 and IEEE 1613 standards. Additionally, the router supports a wide array of WAN connectivity options through the use of Grid Router WAN Interface Cards (GRWICs), allowing for greater flexibility and scalability in network deployments. With its combination of durability and advanced technology, the Cisco 2010 Connected Grid Router is poised to play a vital role in the future of energy infrastructure communications.