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    Components of Embedded System

    Guide to Components of the Embedded System. Here we discuss introduction to Components of Embedded System with 6 different and 3 hardware components

    Components of Embedded System

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    Embedded System Engineers

    Home » Software Development » Software Development Tutorials » Computer Tutorial » Components of Embedded System

    Introduction to Components of Embedded System

    The embedded system is classified as a type of system that is made up of software and hardware components that is used for performing specific functions. The embedded systems can be used in various sectors like industries, agricultural devices, medical devices and automobiles industry, and many more sectors. The embedded system can be used to perform a single task or more than one task at the same time. There are multiple components involved in the design of an embedded system. The components used are software components and hardware components.

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    Chapter 8 Embedded Hardware Design and Development (second portion)

    - Analog Electronic Components - Digital Electronic Components - VLSI and Integrated Circuit Design

    Chapter 8 Embedded Hardware Design and Development (second portion)

    Moe Moe Myint Jul. 05, 2018 • 6 likes • 6,081 views

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    - Analog Electronic Components

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    Smart Integration: Combining Analog Components with Arm Microcontroller Cores to Solve Tough Embedded System Problems

    The design of tomorrow’s embedded systems presents complex challenges given the aggressive goals of improvement in areas of performance, cost, power, size, new features, and efficiency. There is, however, an emerging design option to address these complex problems—analog components smartly integrated with ARM® microcontroller cores. The difference

    Smart Integration: Combining Analog Components with Arm Microcontroller Cores to Solve Tough Embedded System Problems

    by Colin Duggan and Denis Labrecque Download PDF

    The design of tomorrow’s embedded systems presents complex challenges given the aggressive goals of improvement in areas of performance, cost, power, size, new features, and efficiency. There is, however, an emerging design option to address these complex problems—analog components smartly integrated with ARM® microcontroller cores. The difference between this and traditional analog integration is the high level of performance now being offered and the optimizations made to solve specific system level problems. While every market will have their own order ranking of these areas to improve, satisfying multiple factors simultaneously is highly desirable and can come from the integration of numerous discrete components. Logically, combining parts could solve many of these embedded system goals, but simply putting several discrete components and a processor in one package is not the answer; the solution is far more complex, requiring smart integration.

    Smart Integration of Analog and Digital

    Smart integration of high performance analog components (amplifiers, ADCs, DACs, voltage references, temperature sensors, wireless transceivers, etc.) and 32-bit processor cores from ARM with the right digital peripherals can address goals that discrete solutions cannot. In order to create the optimum mixed-signal control processor, a strong knowledge of the overall system along with the availability of the right intellectual property (IP), and expertise in that intellectual property, is required. Needless to say, chip designers and system engineers specifying the features of these integrated devices must have an exceptional understanding of the end application requirements. This domain knowledge is critical and includes a solid understanding of board level requirements such as form factor, temperature ranges, manufacturing considerations, power consumption, cost, and complementary components in the signal chain. Figure 1 shows the analog and digital IP blocks that are often used in devices that are smartly integrated.

    Figure 1. Smart Integration: Analog and Digital IP Combined and Optimized for Target Applications.

    Availability of the right IP provides a strong starting point for meeting system level goals. This starting point is needed to keep the development period of the mixed-signal control processor short. Increasingly, the acquisition/creation and implementation of the IP itself, appropriate for the application, needs to be facilitated by the semiconductor manufacturer. This IP then needs to be modified to meet two requirements in particular. The first is to maximize system level benefits by optimizing performance and operation based on the needs of the primary target application. The next is to optimize the IP to work very well and very easily with the other complementary IP blocks in the mixed-signal control processor.

    And finally, there needs to be the opportunity at a business level for collaboration, combining the expertise and knowledge of the system manufacturer and semiconductor manufacturer, and resulting in an optimized, unique design.

    Mixed-signal Control Processor Applications

    There are many applications that can benefit from a device that integrates high performance analog with ARM microcontroller cores, including temperature sensing, pressure sensing, gas detection, solar inverters, motor control, healthcare vital signs monitoring, automotive monitoring systems, and gas/water/electric meters. This article will look at two applications areas where integration of optimized high performance analog and ARM microcontroller cores leads to significant benefits in cost, power, size, and performance:

    Inverters for solar photovoltaic (PV) systems with goals of increased efficiency, bill of material (BOM) cost reduction, and integration of intelligence to support interfacing to the smart grid.

    Motor control, with the goals of improved efficiency for environmental benefits and cost reduction.

    Note that while these smartly integrated mixed-signal devices are optimized for particular end applications, they can also work well for numerous adjacent applications having similar functional requirements to the primary target application.

    Solar Photovoltaic Inverters: Cost Reduction for Wider Use and Intelligence for the Smart Grid

    While solar PV electricity generating systems have seen greater than 50% annualized growth over the past five years, they still only account for a very small percentage of overall electricity generation worldwide. Although in some regions solar PV generated electricity has reached cost parity with fossil fuel generated electricity, in most regions it has not and generally this parity is dependent on government subsidies.

    To better compete against traditional energy sources such as natural gas, coal, and oil, cost reductions of solar PV generated electricity is best achieved by both increases in efficiency and reduction in system BOM costs. As cost and efficiency of the panels themselves trend in the right direction, new technologies also promise advancement for solar PV inverters—the interface between the power generated by a solar panel and the grid. These new technologies include NPC 3 level/5 level/multilevel, high frequency switching topologies, utilizing fast power transistors based on silicon carbide (SiC) and gallium nitrite (GaN) materials.

    स्रोत : www.analog.com

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