Embedded systems control many devices in common use today. Examples of properties of typical embedded computers when compared with general-purpose counterparts are low power consumption, small size, rugged operating ranges, and low per-unit cost. This comes at the price of basics of embedded systems pdf processing resources, which make them significantly more difficult to program and to interact with.
However, by building intelligence mechanisms on top of the hardware, taking advantage of possible existing sensors and the existence of a network of embedded units, one can both optimally manage available resources at the unit and network levels as well as provide augmented functions, well beyond those available. For example, intelligent techniques can be designed to manage power consumption of embedded systems. Since the embedded system is dedicated to specific tasks, design engineers can optimize it to reduce the size and cost of the product and increase the reliability and performance. At the project’s inception, the Apollo guidance computer was considered the riskiest item in the Apollo project as it employed the then newly developed monolithic integrated circuits to reduce the size and weight. When the Minuteman II went into production in 1966, the D-17 was replaced with a new computer that was the first high-volume use of integrated circuits. Since these early applications in the 1960s, embedded systems have come down in price and there has been a dramatic rise in processing power and functionality.
In 1978 National Engineering Manufacturers Association released a “standard” for programmable microcontrollers, including almost any computer-based controllers, such as single board computers, numerical, and event-based controllers. Microcontrollers find applications where a general-purpose computer would be too costly. A comparatively low-cost microcontroller may be programmed to fulfill the same role as a large number of separate components. Although in this context an embedded system is usually more complex than a traditional solution, most of the complexity is contained within the microcontroller itself. Very few additional components may be needed and most of the design effort is in the software. Software prototype and test can be quicker compared with the design and construction of a new circuit not using an embedded processor.
Embedded systems are commonly found in consumer, cooking, industrial, automotive, medical, commercial and military applications. Transportation systems from flight to automobiles increasingly use embedded systems. Embedded systems within medical equipment are often powered by industrial computers. Embedded systems are used in transportation, fire safety, safety and security, medical applications and life critical systems, as these systems can be isolated from hacking and thus, be more reliable, unless connected to wired or wireless networks via on-chip 3G cellular or other methods for IoT monitoring and control purposes. For fire safety, the systems can be designed to have greater ability to handle higher temperatures and continue to operate.
In dealing with security, the embedded systems can be self-sufficient and be able to deal with cut electrical and communication systems. IC design to couple full wireless subsystems to sophisticated sensors, enabling people and companies to measure a myriad of things in the physical world and act on this information through IT monitoring and control systems. These motes are completely self-contained, and will typically run off a battery source for years before the batteries need to be changed or charged. Embedded Wi-Fi modules provide a simple means of wirelessly enabling any device that communicates via a serial port. Embedded systems are designed to do some specific task, rather than be a general-purpose computer for multiple tasks.