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Technology Embedded software Embedded software Embedded software is a specialized application or firmware that runs on a processing cluster embedded into an SoC or IC. Almost any electronic product can contain one or several embedded processors, common in today’s automobiles, factor floor automation, avionics, medical devices and more. What are the different types of embedded software? Embedded software applications are specialized programming within non-PC devices – either as part of a microchip or as part of another application that sits on top of the chip – to control specific functions of the device. Unlike PC applications, which can be installed on various computer systems and modified to provide different levels of functionality, embedded software has fixed hardware requirements and capabilities. It is created exclusively for the particular device it runs on, with processing and memory restrictions tied directly to it’s specifications. In the context of this discussion, embedded software includes applications, firmware, middleware and operating systems that execute on a single microprocessor or cluster of microprocessors embedded” within additional logic. Related products: Capital Embedded AR Classic | Capital Embedded Integrator AR Classic | Capital Embedded Virtualizer AR Classic Characteristics and features of embedded systems Even though there are many types of embedded systems, they all share the same beneficial features and design characteristics. All embedded systems are task-specific They execute the same pre-programmed function throughout their usable life and cannot be altered. All embedded systems are high-efficiency The resource requirements of embedded software should never exceed the capacity of the hardware it is installed on, and the hardware’s specifications should never exceed the bare minimum requirements of the embedded software. Designed for stability All embedded systems are designed to be highly reliable and stable. They must perform their task with consistent response times and function throughout the lifetime of the device that houses them. What types of embedded software does Siemens offer? Siemens offers both automotive embedded software and embedded software engineering solutions. Siemens has discontinued offering standalone embedded software for SoCs with the retirement in November 2023 of the Nucleus, Nucleus Hypervisor, Nucleus ReadyStart, Sokol Flex Linux, Sokol Omni Linux, and Sourcery CodeBench products (including associated add-ons). Existing support contracts for these products are still being honored, please contact Siemens Support Center for more information. What are the different types of embedded software and their purposes? Operating system – An operating system (OS), in its most general sense, is software that allows a user to run other applications on a computing device. The operating system manages a processor’s hardware resources, including input devices such as a keyboard and mouse, output devices such as displays or printers, network connections, and storage devices such as hard drives and memory. The OS also provides services to facilitate the efficient execution and management of, and memory allocations for, software application programs. Firmware – Firmware is a type of software that is written directly for a piece of hardware. It operates without going through APIs, the operating system, or device drivers—providing the needed instructions and guidance to communicate with other devices or perform basic tasks and functions as intended. Middleware – Middleware is a software layer situated between applications and operating systems. Middleware is often used in distributed systems where it simplifies software development by providing the following: Hiding the intricacies of distributed applications Masking the heterogeneity of hardware, operating systems and protocols Providing uniform and high-level interfaces used to make interoperable, reusable and portable applications. Delivering a set of common services that minimizes duplication of efforts and enhances collaboration between applications Application – The end-user develops the final software application that runs on the operating system, uses or interacts with the middleware and firmware, and is the primary focus of the embedded systems’ target function. Each end application is unique, while operating systems and firmware can be identical from device to device. Embedded software vs embedded systems The hardware components within a device running embedded software are called an "embedded system." Some examples of hardware components used in embedded systems are power supply circuits, central processing units, flash memory devices, timers and serial communication ports. During a device’s early design phases, the hardware that will make up the embedded system – and its configuration within the device – is decided. Then, embedded software is developed from scratch to run exclusively on that hardware in that precise configuration. This makes embedded software design a specialized field requiring deep knowledge of hardware capabilities and computer programming. Examples of embedded software-based functions Almost every device with circuit boards and computer chips has these components arranged into an embedded software system. As a result, embedded software systems are ubiquitous in everyday life and are found throughout consumer, industrial, automotive, aerospace, medical, commercial, telecom and military technology. Common examples of embedded software-based features include: Image processing systems found in medical imaging equipment Fly-by-wire control systems found in aircraft Motion detection systems in security cameras Traffic control systems found in traffic lights Timing and automation systems found in smart home devices What are the different types of embedded systems? When based on performance and functional requirements, there are five main classes of embedded systems: Real-time embedded systems complete tasks in a deterministic and repeatable manner, which is affected by the operating systems’ underlying architecture and scheduling, as well as the performance of threads, branching and interrupting latency. General-purpose embedded systems do not contain a real-time requirement and can manage interrupts or branching without a dependency upon a completion time. Graphics displays and keyboard and mouse management are good examples of general systems. Stand-alone embedded systems can complete tasks without a host system or external processing resources. They can output or receive data from connected devices but are not reliant on them to complete their task. Stand-alone embedded systems can complete their task without a host system or external processing resources. They can output or receive data from connected devices but are not reliant on them to complete their task. Networked embedded systems depend on a connected network to perform assigned tasks. Based on the complexity of the system’s hardware architecture, there are three main types of embedded systems: Networked embedded systems depend on a connected network to perform assigned tasks. How end-markets affect embedded systems Embedded system requirements and components will differ according to the target market’s demands. Some examples include: Consumer – In applications like consumer goods such as washers, wearable devices and mobile phones embedded systems emphasize the reduced size of the System-on-chip, low-power consumption or battery operation and graphics interfaces. In these applications, configurable operating systems and the ability to shut off non-operating domains” of the design are valued. Networking – Applications that enable connectivity, communication, operations and management of an enterprise network. It provides the communication path and services between users, processes, applications, services and external networks/the internet. Embedded network applications...