These processors are built around

Industry 4.0 has come a long way since it was coined at the 2011 Hannover industrial fair. The journey to intelligent manufacturing continues, but what has really made a difference in recent years is the take-off of the Internet of things (IOT) and the advent of artificial intelligence (AI) solutions. It is worth mentioning here that in 2012, General Electric coined the term "industrial Internet", which means intelligently connecting a variety of industrial devices to create systems that can monitor, collect, exchange, analyze and provide valuable insights. Finally, the concepts of industry 4.0 and industrial Internet began to merge, and eventually reached industrial IOT or iiot. Whether it is industry 4.0 or industrial Internet of things, the fundamental goal is to realize the fourth industrial revolution with the help of steam engine, conveyor belt and information technology (it) with the help of cutting-edge electronic technology. It takes manufacturing and process automation Commercial Induction Cooktop to a whole new level, and tomorrow's plant will build connectivity systems including sensors, actuators and control systems, all of which are linked together through different types of networks via Internet Protocol (IP). Figure 1: industry 4.0 marks a new height in digital transformation. The integration of AI applications such as fault detection and classification has also driven industry 4.0. The combination of Internet of things and artificial intelligence technology has changed engineers to manage data, spread information and make real-time in the production environmentHow to make decisions. The use of machine learning algorithms and robot based process processing can further save costs and man hours, thus further optimizing modern manufacturing. Industry 4.0 can be seen at the general electric plant in Schenectady, Cold Sparkler Fountain New York. More than 10000 sensors have been installed in the nickel sodium battery manufacturing plant, which is located in 180000 square feet of manufacturing space. All of these sensors are connected via high-speed Ethernet. This brings us to one of the fundamental components of industry 4.0 design: connected sensors. Sensors the Internet of sensors, connected by wired or wireless links, form the backbone of industry 4.0 or iiot systems. Machine data sent from sensors to the cloud can optimize manufacturing, predict failures, schedule maintenance schedules, and automatically replenish inventory. The new feature of industry 4.0 sensors is the integration of localization and communication to create accurate indoor positioning systems. This allows the factory to monitor tools and manage worker usage in real time to improve Electric Cooking Stove Manufacturerassembly line efficiency, safety and quality control. These high-precision and location aware systems use intelligent wireless sensor solutions. Taking the intelligent cab as an example, Bosch, the sensor supplier, and cab concept cluster (CCC) jointly developed the intelligent cab. It integrates cameras and drones into agricultural vehicles and turns them into a control center connected to the field. Figure 2: in addition to intelligent manufacturing, the industry 4.0 initiative is expanding to other fieldsDomain, such as Internet agriculture. Image: Cab concept cluster) the solution provides farmers with detailed pictures of crop conditions captured by camera drones and then processed in the cloud. The camera drone can also perform object recognition to alert farmers about obstacles such as deer. In addition, farmers can perform specific functions, such as adjusting nozzle settings based on weather or soil conditions. Bosch also claims to have increased the productivity of its ABS / ESP brake system manufacturing at its factory in blakkach, Germany, by recording the movement of the cylinder, the cycle time of the fixture, and the temperature and pressure levels during the manufacturing process. The data collected from RFID tags will be transferred to a massive database, which maps the internal cargo flow digitally. Industry 4.0 chip semiconductor devices are another key element in industry 4.0 and iiot design. These include processors for edge computing, memory for data storage, data converters, and wired or wireless connectivity chips for remote sensing and cloud platform connectivity. One example is ti's Sitara am6x processor family, which supports Gigabit industrial communications subsystems for factory automation, motor drives, and grid infrastructure. These processors are built around the integration of Ethernet and real-time data traffic on a single network. They support a variety of protocols, including time sensitive network (TSN), EtherCAT, Ethernet / IP and PROFINET in this paperFigure 3: block diagram of the Sitara am6548 Multiprotocol Processor that provides Gigabit throughput for industrial connectivity standards such as TSN. The TSN enabled processor integrates a dual core microcontroller (MCU) subsystem based on arm cortex-r5f, which can run in optional lockstep mode and support error correction code (ECC) protection for on-chip memory and external dual data. Rate (DDR) memory. These features enable the processor to improve security and reduce the system level complexity of applications such as programmable logic controllers (PLCs) and multi axis motor drivers. The industrial 4.0 platform has higher and higher requirements for high-performance PLC, supplemented by safe connection and human-machine interface (HMI). PLC must also reduce the overall size and process value chain, while increasing the number of I / O channels (analog and digital). These PLCs will need to support new I / O protocols such as IO link. In addition, the emergence of powerful system on chip (SOC) solutions makes it possible to create a digital twin, which couples the virtual world with the physical world and creates a data pool that maps and links all the steps of industrial manufacturing together. These network physical systems create virtual copies of the physical world, making it cheaper and more efficient to monitor physical processes. In the vision of industry 4.0, the factory of the future will revive in the production field through end-to-end sensor solutions and services. It promotes smarter decisionsPolicy, improve operational efficiency, increase production, improve engineering efficiency and greatly improve business performance. With the acceleration of the availability of IOT sensors, big data and AI applications, the reality of industry 4.0 is finally moving forward. According to Gartner Inc., there were more than 6 billion IOT devices in this field in 2018, and the number is expected to grow to more than 20 billion by 2022. Factories in the future will develop steadily and steadily through more powerful processing nodes, more automated production processes and more intelligent data analysis tools that can process and analyze large amounts of factory data in near real time. Become a reality, providing one IOT sensor solution at a time.