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Ch. 4. The DNA of IoT The DNA of IoT 1 4.1 DCM: Device, Connect, and Manage IoT systems all have three layers. (Fig. 4.1) DCM (DNA) of IoT M •Vertical Applications •Server-side Middleware Platform •Data Management A C •Machine Type Communication •Edge Middleware •Pervasive Networks N D •Local/Ad-hoc Sensor Networks •Embedded Middleware •Sensors and Actuators D The three-layer DCM classification is more about the IoT value chain than its system architecture at runtime. For system architecture, some have divided the IoT system into as many as nine layers, from bottom to top: devices, connectivity, data collection, communication, device management, data rules, administration, application, and integration. The DNA of IoT 2 4.2 Devices: Things That Talk Devices or assets can be categorized as two groups: those that have inherent intelligence such as electric meters and heating, ventilation, and air-conditioning controllers, and those that are inert and must be enabled to become smart devices (e.g., RFID tagged) such as furniture or animals that can be electronically tracked and monitored – things that “talk”. A sensor (also called a detector) is a device that responds to a physical stimulus, measures the physical stimulus quantity, and converts it into a signal, usually electrical, which can be read by an observer or by an instrument. A sensor can be very small and itself can be a trackable devices. The sensor itself, if not connected, is not part of the IoT or WSN value chain. Table 4.1 List of Sensors and Types The DNA of IoT 3 Sensor, types of sensor and their applications Energy harvesting is the process by which energy is derived from external sources (e.g., solar power, thermal energy, wind energy salinity gradients, and kinetic energy), captured, and stored for small wireless autonomous devices, like those used in wearable electronics and WSNs. The DNA of IoT 4 4.3 Connect Via Pervasive Networks The communication layer is the foundational infrastructure of IoT. The general idea behind the NGN is that one network transports all information and service (voice, data, and all sorts of media such as video ) by encapsulating these into packets, similar to those used on the Internet. NGNs are commonly built around Internet protocol, and therefore the term all-IP is also sometimes used to describe the transformation toward NGN. With the growing abundance of embedded IoT systems comes the increased pressure at the edge of the network: multi[le access methods must be accommodated, implying the need for a common underlying converged core IP/MPLS (multi-protocol label switching) network. The connectivity domain enables broadband access, both wired and wireless. It also includes the transport and aggregation networks. There is no doubt that if all-IP is a reality, it will give the Internet of Things a huge lift and make the IoT dream come true much easier and faster. The DNA of IoT 5 IPv6 allows for vastly more numerical addresses (128 bits), but switching from IPv4 to IPv6 may be a different process. The DNA of IoT 6 4.3.1 Wired Networks Wired networks for IoT can be categorized as short-range field busbased access networks, mostly for SCADA applications, and IPbased networks, for M2M and SCADA applications. Table 4.2 List of Field Bus Standards 4.3.2 Wireless Networks Wireless networks for IoT can be categorized as follows: • Short-range • Long-range Radio spectrum refers to the part of the electromagnetic spectrum corresponding to radio frequencies: lower than 300 GHz. Wireless communication standards can also be categorized as standards for cellular communication networks (such as GSM, CDMA, HSPA, LTE, etc) and wireless connectivity networks (such as Bluetooth, WiFi, WiMax). The DNA of IoT 7 Short- and long-range wireless networks Broad geographic coverage GSM, W-CDMA, cdma 2000 City or suburb WiMAX ~100 m 802.11, HiperLan ~10 m Bluetooth, UWB WLAN: Personal area network WLAN: Local area network The DNA of IoT WMAN: Metro area network WWAN: Wide area network 8 4.3.3 Satellite IoT A communication satellite (COMSAT) is a specialized wireless transponder in space, receiving radio waves from one location and transmitting them to another. Satellite communications are especially important for transportation, aviation, maritime, and military use. The DNA of IoT 9 4.4 Manage: To Create New Business Value The layering of the value chain components or subsystems SCM ERP CRM/OA Real-time Factory Database MES PLM/PDM Middleware, Control and Automation PCS DCS PLC SCADA TGS FMS FFS FCS SSS F&G Other Systems Embedded Middleware, Gateway Middleware Industrial Devices (Instrumented, Interconnected, and Intelligent) The DNA of IoT 10 The vision of IoT augmented with advances in software technologies and methodologies such as SOA (service-oriented architecture), SaaS (software as a service), cloud computing, and others is causing a paradigm shift where devices can offer more advanced access to their functionality and business intelligence. 4.4.1 More Ingredients: LBS, GNSS, RTLS, and Others IoT Technologies Enabling Building Blocks These technologies directly contribute to the development of the IoT M2M interface and protocols of electronic communication Microcontrollers Synergistic Technologies These technologies may add value to the IoT Wireless communication Machine vision RFID technology Robotics Energy-harvesting technologies Sensors Augmented reality Mirror world Telepresence and adjustable autonomy Life recorders and personal black boxes Tangible user interfaces Clean technologies Actuators Location Technology Software Geotagging/geocaching Biometrics The DNA of IoT 11 A Mirror World is a representation of the real world in digital form. It attempts to map real-world structures in a geographically accurate way. The term differs from virtual worlds in that these have no direct connections to real models and thus are described as fictions, while mirror worlds are connected to real models and lay nearer to nonfiction. The DNA of IoT 12