Industrial Internet Of Things America
A representation of the Internet of things (IoT).The Internet of things ( IoT) is the extension of connectivity into physical devices and everyday objects. Embedded with, and other forms of hardware (such as ), these devices can communicate and interact with others over the Internet, and they can be remotely monitored and controlled.The definition of the Internet of things has evolved due to the convergence of multiple technologies, real-time, commodity sensors,. Traditional fields of embedded systems, (including and ), and others all contribute to enabling the Internet of things.
In the consumer market, IoT technology is most synonymous with products pertaining to the concept of the 'smart home', covering devices and appliances (such as lighting fixtures, thermostats, home security systems and cameras, and other home appliances) that support one or more common ecosystems, and can be controlled via devices associated with that ecosystem, such as and.The IoT concept has faced prominent criticism, especially in regards to and concerns related to these devices and their intention of pervasive presence. An smart lock connected to the InternetThe extensive set of applications for IoT devices is often divided into consumer, commercial, industrial, and infrastructure spaces. Consumer applications A growing portion of IoT devices are created for consumer use, including connected vehicles, (as part of Internet of Wearable Things (IoWT) ), connected health, and appliances with remote monitoring capabilities. Smart home IoT devices are a part of the larger concept of home automation, which can include lighting, heating and air conditioning, media and security systems. Long-term benefits could include energy savings by automatically ensuring lights and electronics are turned off.A smart home or automated home could be based on a platform or hubs that control smart devices and appliances. For instance, using 's, manufacturers can have their home products and accessories controlled by an application in devices such as the and the. This could be a dedicated app or iOS native applications such as.
On the other hand, South America looks to be ramping up its internet of things investments. According to the report, 60% of developers in that region are planning to begin projects related to the internet of things, while 22% already do. Current industrial IoT deployments. Oct 15, 2014 World Economic Forum®. 2 Industrial Internet of Things. Executive summary During the past 15 years, the Internet revolution has redefined business-to-consumer (B2C) industries such as media, retail and financial services. In the next 10 years, the Internet of Things revolution will dramatically alter. At IoT America, we’re bringing the Internet of Things (IoT) to rural America in ways never before imagined to help growers, ranchers, towns and businesses of all descriptions save time and money boost productivity increase farm yields and conserve our valuable natural resources.
This can be demonstrated in the case of Lenovo's Smart Home Essentials, which is a line of smart home devices that are controlled through Apple's Home app or Siri without the need for a Wi-Fi bridge. There are also dedicated smart home hubs that are offered as standalone platforms to connect different smart home products and these include the, Apple's, and Samsung's. In addition to the commercial systems, there are many non-proprietary, open source ecosystems; including Home Assistant, OpenHAB and Domoticz. Elder care One key application of a smart home is to provide. These home systems use assistive technology to accommodate an owner's specific disabilities. Can assist users with sight and mobility limitations while alert systems can be connected directly to worn by hearing-impaired users. They can also be equipped with additional safety features.
These features can include sensors that monitor for medical emergencies such as falls or seizures. Smart home technology applied in this way can provide users with more freedom and a higher quality of life.The term 'Enterprise IoT' refers to devices used in business and corporate settings. By 2019, it is estimated that the EIoT will account for 9.1 billion devices. Commercial application Medical and healthcare The Internet of Medical Things (also called the internet of health things) is an application of the IoT for medical and health related purposes, data collection and analysis for research, and monitoring. This 'Smart Healthcare', as it is also called, led to the creation of a digitized healthcare system, connecting available medical resources and healthcare services.IoT devices can be used to enable. These health monitoring devices can range from blood pressure and heart rate monitors to advanced devices capable of monitoring specialized implants, such as pacemakers, Fitbit electronic wristbands, or advanced hearing aids.
Some hospitals have begun implementing 'smart beds' that can detect when they are occupied and when a patient is attempting to get up. It can also adjust itself to ensure appropriate pressure and support is applied to the patient without the manual interaction of nurses. A 2015 Goldman Sachs report indicated that healthcare IoT devices 'can save the United States more than $300 billion in annual healthcare expenditures by increasing revenue and decreasing cost.' Moreover, the use of mobile devices to support medical follow-up led to the creation of 'm-health', used 'to analyze, capture, transmit and store health statistics from multiple resources, including sensors and other biomedical acquisition systems'.Specialized sensors can also be equipped within living spaces to monitor the health and general well-being of senior citizens, while also ensuring that proper treatment is being administered and assisting people regain lost mobility via therapy as well. These sensors create a network of intelligent sensors that are able to collect, process, transfer, and analyse valuable information in different environments, such as connecting in-home monitoring devices to hospital-based systems. Other consumer devices to encourage healthy living, such as connected scales or, are also a possibility with the IoT. End-to-end health monitoring IoT platforms are also available for antenatal and chronic patients, helping one manage health vitals and recurring medication requirements.Advances in plastic and fabric electronics fabrication methods have enabled ultra-low cost, use-and-throw IoMT sensors.
These sensors, along with the required RFID electronics, can be fabricated on or for wirelessly powered disposable sensing devices. Applications have been established for, where portability and low system-complexity is essential.As of 2018 IoMT was not only being applied in the industry, but also in the healthcare and health insurance industries. IoMT in the healthcare industry is now permitting doctors, patients, and others involved (i.e. Guardians of patients, nurses, families, etc.) to be part of a system, where patient records are saved in a database, allowing doctors and the rest of the medical staff to have access to the patient's information. Moreover, IoT-based systems are patient-centered, which involves being flexible to the patient's medical conditions.
IoMT in the insurance industry provides access to better and new types of dynamic information. This includes sensor-based solutions such as biosensors, wearables, connected health devices, and mobile apps to track customer behaviour. This can lead to more accurate underwriting and new pricing models.The application of the IOT in healthcare plays a fundamental role in managing chronic diseasesand in disease prevention and control. Remote monitoring is made possiblethrough the connection of powerful wireless solutions. The connectivity enables healthpractitioners to capture patient’s data and applying complex algorithms in health data analysis. Transportation.
Digital variable speed-limit sign.The IoT can assist in the integration of communications, control, and information processing across various. Application of the IoT extends to all aspects of transportation systems (i.e. The vehicle, the infrastructure, and the driver or user). Dynamic interaction between these components of a transport system enables inter- and intra-vehicular communication, smart parking, s and, safety, and road assistance. In Logistics and Fleet Management, for example, an IoT platform can continuously monitor the location and conditions of cargo and assets via wireless sensors and send specific alerts when management exceptions occur (delays, damages, thefts, etc.). This can only be possible with the IoT and its seamless connectivity among devices.
Sensors such as GPS, Humidity, and Temperature send data to the IoT platform and then the data is analyzed and then sent to the users. This way, users can track the real-time status of vehicles and can make appropriate decisions. If combined with, then it also helps in reducing traffic accidents by introducing alerts to drivers and providing self-driven cars too.V2X communications IoT enables vehicle-to-everything communication (V2X), which consists of three main components of the connected environment: vehicle to vehicle communication (V2V), vehicle to infrastructure communication (V2I) and vehicle to pedestrian communications (V2P). V2V empowers vehicles to exchange data, V2I allows them to network with the transport infrastructure (traffic signs and lights, etc.) and V2P senses signals from the user's smartphones to prevent collisions, involving pedestrians. By constantly analyzing real-time data, V2X designs a transport ecosystem where vehicles, infrastructure, and people are interconnected with each other to keep the environment safe from any type of accidents. V2X is the first step to autonomous driving and connected road infrastructure that provides connected cars with needed safety. Building and home automation IoT devices can be used to monitor and control the mechanical, electrical and electronic systems used in various types of buildings (e.g., public and private, industrial, institutions, or residential) in and systems.
In this context, three main areas are being covered in literature:. The integration of the Internet with building energy management systems in order to create energy efficient and IOT-driven 'smart buildings'. The possible means of real-time monitoring for reducing energy consumption and monitoring occupant behaviors.
The integration of smart devices in the built environment and how they might to know how to be used in future applications.Industrial applications. Main article: Manufacturing The IoT can realize the seamless integration of various manufacturing devices equipped with sensing, identification, processing, communication, actuation, and networking capabilities. Based on such a highly integrated smart cyberphysical space, it opens the door to create whole new business and market opportunities for manufacturing.Network control and management of, and situation management, or manufacturing bring the IoT within the realm of industrial applications and smart manufacturing as well. The IoT intelligent systems enable rapid manufacturing of new products, dynamic response to product demands, and real-time optimization of manufacturing production and, by networking machinery, sensors and control systems together.to automate process controls, operator tools and service information systems to optimize plant safety and security are within the purview of the IoT. But it also extends itself to asset management via, and measurements to maximize reliability. Industrial management systems can also be integrated with, enabling real-time energy optimization.
Measurements, automated controls, plant optimization, health and safety management, and other functions are provided by a large number of networked sensors.Industrial IoT (IIoT) in manufacturing could generate so much business value that it will eventually lead to the, also referred to as. The potential for growth from implementing IIoT may generate $12 trillion of global GDP by 2030. Design architecture of cyber-physical systems-enabled manufacturing systemanalytics will play a vital role in manufacturing asset predictive maintenance, although that is not the only capability of industrial big data.
(CPS) is the core technology of industrial big data and it will be an interface between human and the cyber world. Cyber-physical systems can be designed by following the 5C (connection, conversion, cyber, cognition, configuration) architecture, and it will transform the collected data into actionable information, and eventually interfere with the physical assets to optimize processes.An IoT-enabled intelligent system of such cases was proposed in 2001 and later demonstrated in 2014 by the Industry/University Collaborative Research Center for (IMS) at the University of Cincinnati on a machine in IMTS 2014 in Chicago. Bandsaw machines are not necessarily expensive, but the bandsaw belt expenses are enormous since they degrade much faster. However, without sensing and intelligent analytics, it can be only determined by experience when the band saw belt will actually break. The developed system will be able to recognize and of band saw belts even if the condition is changing, advising users when is the best time to replace the belt. This will significantly improve user experience and operator safety and ultimately save on costs.
Agriculture There are numerous IoT applications in farming such as collecting data on temperature, rainfall, humidity, wind speed, pest infestation, and soil content. This data can be used to automate farming techniques, take informed decisions to improve quality and quantity, minimize risk and waste, and reduce effort required to manage crops. For example, farmers can now monitor soil temperature and moisture from afar, and even apply IoT-acquired data to precision fertilization programs.In August 2018, began a partnership with to create tools using the application suite for IoT technologies related to water management. Developed in part by researchers from, the water pump mechanisms use to count the number of fish on a, analyze the number of fish, and deduce the effectiveness of water flow from the data the fish provide. The specific used in the process fall under the Azure Machine Learning and the Azure IoT Hub platforms.
Infrastructure applications Monitoring and controlling operations of sustainable urban and rural infrastructures like bridges, railway tracks and on- and offshore wind-farms is a key application of the IoT. The IoT infrastructure can be used for monitoring any events or changes in structural conditions that can compromise safety and increase risk.
The IoT can benefit the construction industry by cost saving, time reduction, better quality workday, paperless workflow and increase in productivity. It can help in taking faster decisions and save money with Real-Time Data Analytics. It can also be used for scheduling repair and maintenance activities in an efficient manner, by coordinating tasks between different service providers and users of these facilities. IoT devices can also be used to control critical infrastructure like bridges to provide access to ships.
Usage of IoT devices for monitoring and operating infrastructure is likely to improve incident management and emergency response coordination, and, and reduce costs of operation in all infrastructure related areas. Even areas such as waste management can benefit from and optimization that could be brought in by the IoT. Metropolitan scale deployments There are several planned or ongoing large-scale deployments of the IoT, to enable better management of cities and systems. For example, South Korea, the first of its kind fully equipped and wired, is gradually being built, with approximately 70 percent of the business district completed as of June 2018. Much of the city is planned to be wired and automated, with little or no human intervention.Another application is a currently undergoing project in, Spain.
Industrial Internet Of Things Security
For this deployment, two approaches have been adopted. This city of 180,000 inhabitants has already seen 18,000 downloads of its city smartphone app.
The app is connected to 10,000 sensors that enable services like parking search, environmental monitoring, digital city agenda, and more. City context information is used in this deployment so as to benefit merchants through a spark deals mechanism based on city behavior that aims at maximizing the impact of each notification.Other examples of large-scale deployments underway include the Sino-Singapore Guangzhou Knowledge City; work on improving air and water quality, reducing noise pollution, and increasing transportation efficiency in San Jose, California; and smart traffic management in western Singapore. Using its RPMA (Random Phase Multiple Access) technology, San Diego-based has built a nationwide public network for low-bandwidth data transmissions using the same unlicensed 2.4 gigahertz spectrum as Wi-Fi. Ingenu’s “Machine Network” covers more than a third of the US population across 35 major cities including San Diego and Dallas.
French company, commenced building an wireless data network in the in 2014, the first business to achieve such a deployment in the U.S. It subsequently announced it would set up a total of 4000 to cover a total of 30 cities in the U.S. By the end of 2016, making it the largest IoT network coverage provider in the country thus far.
Cisco also participates in smart cities projects. Cisco has started deploying technologies for Smart Wi-Fi, Smart Safety & Security, Smart Lighting, Smart Parking, Smart Transports, Smart Bus Stops, Smart Kiosks, Remote Expert for Government Services (REGS) and Smart Education in the five km area in the city of Vijaywada.Another example of a large deployment is the one completed by New York Waterways in New York City to connect all the city's vessels and be able to monitor them live 24/7. The network was designed and engineered by Networks, a Chicago-based company developing wireless networks for critical applications.
The NYWW network is currently providing coverage on the Hudson River, East River, and Upper New York Bay. With the wireless network in place, NY Waterway is able to take control of its fleet and passengers in a way that was not previously possible. New applications can include security, energy and fleet management, digital signage, public Wi-Fi, paperless ticketing and others.
Energy management Significant numbers of energy-consuming devices (e.g. Switches, power outlets, bulbs, televisions, etc.) already integrate Internet connectivity, which can allow them to communicate with utilities to balance and energy usage and optimize energy consumption as a whole. These devices allow for remote control by users, or central management via a -based interface, and enable functions like scheduling (e.g., remotely powering on or off heating systems, controlling ovens, changing lighting conditions etc.).
The is a utility-side IoT application; systems gather and act on energy and power-related information to improve the efficiency of the production and distribution of electricity. Using Internet-connected devices, electric utilities not only collect data from end-users, but also manage distribution automation devices like transformers. Environmental monitoring applications of the IoT typically use sensors to assist in environmental protection by monitoring air or, or, and can even include areas like monitoring the and their. Development of resource-constrained devices connected to the Internet also means that other applications like or can also be used by emergency services to provide more effective aid. IoT devices in this application typically span a large geographic area and can also be mobile. It has been argued that the standardization IoT brings to wireless sensing will revolutionize this area.Living LabAnother example of integrating the IoT is Living Lab which integrates and combines research and innovation process, establishing within a public-private-people-partnership. There are currently 320 Living Labs that use the IoT to collaborate and share knowledge between stakeholders to co-create innovative and technological products.
For companies to implement and develop IoT services for smart cities, they need to have incentives. The governments play key roles in smart cities projects as changes in policies will help cities to implement the IoT which provides effectiveness, efficiency, and accuracy of the resources that are being used. For instance, the government provides tax incentives and cheap rent, improves public transports, and offers an environment where start-up companies, creative industries, and multinationals may co-create, share common infrastructure and labor markets, and take advantages of locally embedded technologies, production process, and transaction costs. The relationship between the technology developers and governments who manage city's assets, is key to provide open access of resources to users in an efficient way.Trends and characteristics. Crash bandicoot remastered pc download. Technology roadmap: Internet of things.The IoT's major significant trend in recent years is the explosive growth of devices connected and controlled by the Internet. The wide range of applications for IoT technology mean that the specifics can be very different from one device to the next but there are basic characteristics shared by most.The IoT creates opportunities for more direct integration of the physical world into computer-based systems, resulting in efficiency improvements, economic benefits, and reduced human exertions.The number of IoT devices increased 31% year-over-year to 8.4 billion in the year 2017 and it is estimated that there will be 30 billion devices by 2020. The global market value of IoT is projected to reach $7.1 trillion by 2020.
Intelligence and autonomous control are not part of the original concept of the Internet of things. Ambient intelligence and autonomous control do not necessarily require Internet structures, either. However, there is a shift in research (by companies such as ) to integrate the concepts of the IoT and autonomous control, with initial outcomes towards this direction considering objects as the driving force for autonomous IoT. A promising approach in this context is where most of IoT systems provide a dynamic and interactive environment. Training an agent (i.e., IoT device) to behave smartly in such an environment cannot be addressed by conventional machine learning algorithms such as. By reinforcement learning approach, a learning agent can sense the environment’s state (e.g., sensing home temperature), perform actions (e.g., turn on or off) and learn through the maximizing accumulated rewards it receives in long term.IoT intelligence can be offered at three levels: IoT devices,.
The need for intelligent control and decision at each level depends on the time sensitiveness of the IoT application. For example, an autonomous vehicle's camera needs to make real-time obstacle detection to avoid an accident. This fast decision making would not be possible through transferring data from the vehicle to cloud instances and return the predictions back to the vehicle.
Instead, all the operation should be performed locally in the vehicle. Integrating advanced machine learning algorithms including into IoT devices is an active research area to make smart objects closer to reality. Moreover, it is possible to get the most value out of IoT deployments through analyzing IoT data, extracting hidden information, and predicting control decisions.
A wide variety of machine learning techniques have been used in IoT domain ranging from traditional methods such as, and to advanced ones such as, and.In the future, the Internet of Things may be a non-deterministic and open network in which auto-organized or intelligent entities (, components) and virtual objects (avatars) will be interoperable and able to act independently (pursuing their own objectives or shared ones) depending on the context, circumstances or environments. Autonomous behavior through the collection and reasoning of context information as well as the object's ability to detect changes in the environment (faults affecting sensors) and introduce suitable mitigation measures constitutes a major research trend, clearly needed to provide credibility to the IoT technology. Modern IoT products and solutions in the marketplace use a variety of different technologies to support such context-aware automation, but more sophisticated forms of intelligence are requested to permit sensor units and intelligent cyber-physical systems to be deployed in real environments. Architecture. This section needs attention from an expert in Technology. The specific problem is: The information is partially outdated, unclear, and uncited.
Requires more details, but not so technical that others won't understand it. May be able to help recruit an expert.
( July 2018)IoT system architecture, in its simplistic view, consists of three tiers: Tier 1: Devices, Tier 2: the Edge Gateway, and Tier 3: the Cloud. Devices include networked things, such as the sensors and actuators found in IIoT equipment, particularly those that use protocols such as Modbus, Zigbee, or proprietary protocols, to connect to an Edge Gateway. The Edge Gateway consists of sensor data aggregation systems called Edge Gateways that provide functionality, such as pre-processing of the data, securing connectivity to cloud, using systems such as WebSockets, the event hub, and, even in some cases, edge analytics or fog computing. The final tier includes the cloud application built for IIoT using the microservices architecture, which are usually polyglot and inherently secure in nature using HTTPS/OAuth.
It includes various database systems that store sensor data, such as time series databases or asset stores using backend data storage systems (e.g. Cassandra, Postgres). The cloud tier in most cloud-based IoT system features event queuing and messaging system that handles communication that transpires in all tiers. Some experts classified the three-tiers in the IIoT system as edge, platform, and enterprise and these are connected by proximity network, access network, and service network, respectively.Building on the Internet of things, the is an architecture for the application layer of the Internet of things looking at the convergence of data from IoT devices into Web applications to create innovative use-cases. In order to program and control the flow of information in the Internet of things, a predicted architectural direction is being called which is a blending of traditional process management with process mining and special capabilities to automate the control of large numbers of coordinated devices. Network architecture The Internet of things requires huge scalability in the network space to handle the surge of devices.
Would be used to connect devices to IP networks. With billions of devices being added to the Internet space, will play a major role in handling the network layer scalability., and would provide lightweight data transport.is a viable alternative to prevent such large burst of data flow through Internet.
The ' computation power to analyse and process data is extremely limited. Limited processing power is a key attribute of IoT devices as their purpose is to supply data about physical objects while remaining autonomous. Heavy processing requirements use more battery power harming IoT's ability to operate. Scalability is easy because IoT devices simply supply data through the internet to a server with sufficient processing power.
Complexity In semi-open or closed loops (i.e. Value chains, whenever a global finality can be settled) the IoT will often be considered and studied as a due to the huge number of different links, interactions between autonomous actors, and its capacity to integrate new actors. At the overall stage (full open loop) it will likely be seen as a environment (since always have finality).As a practical approach, not all elements in the Internet of things run in a global, public space. Subsystems are often implemented to mitigate the risks of privacy, control and reliability. For example, domestic robotics (domotics) running inside a smart home might only share data within and be available via a. Managing and controlling a high dynamic ad hoc IoT things/devices network is a tough task with the traditional networks architecture, Software Defined Networking (SDN) provides the agile dynamic solution that can cope with the special requirements of the diversity of innovative IoT applications. Size considerations The Internet of things would encode 50 to 100 trillion objects, and be able to follow the movement of those objects.
Human beings in surveyed urban environments are each surrounded by 1000 to 5000 trackable objects. In 2015 there were already 83 million smart devices in people's homes. This number is expected to grow to 193 million devices by 2020.The figure of online capable devices grew 31% from 2016 to 8.4 billion in 2017. Space considerations In the Internet of things, the precise geographic location of a thing—and also the precise geographic dimensions of a thing—will be critical. Therefore, facts about a thing, such as its location in time and space, have been less critical to track because the person processing the information can decide whether or not that information was important to the action being taken, and if so, add the missing information (or decide to not take the action). (Note that some things in the Internet of things will be sensors, and sensor location is usually important.
) The and are promising applications that become possible when things can become organized and connected by location. However, the challenges that remain include the constraints of variable spatial scales, the need to handle massive amounts of data, and an indexing for fast search and neighbor operations. In the Internet of things, if things are able to take actions on their own initiative, this human-centric mediation role is eliminated. Thus, the time-space context that we as humans take for granted must be given a central role in this information ecosystem. Just as standards play a key role in the Internet and the Web, geospatial standards will play a key role in the Internet of things. A solution to 'basket of remotes' Many IoT devices have a potential to take a piece of this market. (Apple initial alumni team, and BeOS co-founder) has addressed this topic in an article on Monday Note, where he predicts that the most likely problem will be what he calls the 'basket of remotes' problem, where we'll have hundreds of applications to interface with hundreds of devices that don't share protocols for speaking with one another.
For improved user interaction, some technology leaders are joining forces to create standards for communication between devices to solve this problem. Others are turning to the concept of predictive interaction of devices, 'where collected data is used to predict and trigger actions on the specific devices' while making them work together. Enabling technologies for IoT There are many technologies that enable the IoT.
Crucial to the field is the network used to communicate between devices of an IoT installation, a role that several wireless or wired technologies may fulfill: Addressability The original idea of the is based on RFID-tags and distinct identification through the. This has evolved into objects having an IP address. An alternative view, from the world of the focuses instead on making all things (not just those electronic, smart, or RFID-enabled) addressable by the existing naming protocols, such as. The objects themselves do not converse, but they may now be referred to by other agents, such as powerful centralized servers acting for their human owners. Integration with the Internet implies that devices will use an as a distinct identifier. Due to the of (which allows for 4.3 billion different addresses), objects in the IoT will have to use of the Internet protocol to scale to the extremely large address space required.Internet-of-things devices additionally will benefit from the stateless address auto-configuration present in IPv6, as it reduces the configuration overhead on the hosts, and the header compression.
To a large extent, the future of the Internet of things will not be possible without the support of IPv6; and consequently, the global adoption of IPv6 in the coming years will be critical for the successful development of the IoT in the future. This section needs expansion. You can help. ( September 2016)This is a list of for the IoT, most of which are, and the that aspire to successfully setting them. Short nameLong nameStandards under developmentOther notesAuto Identification CenterNetworked (radiofrequency identification) and emerging technologiesElectronic Product code TechnologyStandards for adoption of (Electronic Product Code) technologyU.S.
Food and Drug Administration(Unique Device Identification) system for distinct identifiers for—Standards for ('unique' identifiers) and RFID of (consumer packaged goods), health care supplies, and other thingsParent organization comprises member organizations such asInstitute of Electrical and Electronics EngineersUnderlying communication technology standards such asInternet Engineering Task ForceStandards that comprise (the Internet protocol suite)MTConnect Institute—is a manufacturing industry standard for data exchange with and related industrial equipment. GE Digital CEO William Ruh speaking about GE's attempts to gain a foothold in the market for IoT services at the first TechIgnite conference. Lack of interoperability and unclear value propositions Despite a shared belief in the potential of the IoT, industry leaders and consumers are facing barriers to adopt IoT technology more widely. Mike Farley argued in that while IoT solutions appeal to, they either lack interoperability or a clear use case for end-users.
A study by Ericsson regarding the adoption of IoT among Danish companies suggests that many struggle 'to pinpoint exactly where the value of IoT lies for them'. Privacy and security concerns According to a recent study by Noura Aleisa and Karen Renaud at the University of Glasgow, 'the Internet of things' potential for major privacy invasion is a concern' with much of research 'disproportionally focused on the security concerns of IoT.'
Among the 'proposed solutions in terms of the techniques they deployed and the extent to which they satisfied core privacy principles', only very few turned out to be fully satisfactory. Louis Basenese, investment director at Wall Street Daily, has criticized the industry's lack of attention to security issues:'Despite high-profile and alarming hacks, device manufacturers remain undeterred, focusing on profitability over security.
Consumers need to have ultimate control over collected data, including the option to delete it if they choose.Without privacy assurances, wide-scale consumer adoption simply won't happen.' In a post- world of, consumers take a more active interest in protecting their privacy and demand IoT devices to be screened for potential security vulnerabilities and privacy violations before purchasing them. According to the 2016 Digital Consumer Survey, in which 28000 consumers in 28 countries were polled on their use of consumer technology, security 'has moved from being a nagging problem to a top barrier as consumers are now choosing to abandon IoT devices and services over security concerns.' The survey revealed that 'out of the consumers aware of attacks and owning or planning to own IoT devices in the next five years, 18 percent decided to terminate the use of the services and related services until they get safety guarantees.'
This suggests that consumers increasingly perceive risks and security concerns to outweigh the of IoT devices and opt to postpone planned purchases or service subscriptions. Traditional governance structures. Town of Internet of Things in Hangzhou, ChinaA study issued by Ericsson regarding the adoption of Internet of things among Danish companies identified a 'clash between IoT and companies' traditional structures, as IoT still presents both uncertainties and a lack of historical precedence.' Among the respondents interviewed, 60 percent stated that they 'do not believe they have the organizational capabilities, and three of four do not believe they have the processes needed, to capture the IoT opportunity.' This has led to a need to understand in order to facilitate processes and to test new practices. A lack of digital leadership in the age of has also stifled innovation and IoT adoption to a degree that many companies, in the face of uncertainty, 'were waiting for the market dynamics to play out', or further action in regards to IoT 'was pending competitor moves, customer pull, or regulatory requirements.' Some of these companies risk being 'kodaked' – 'Kodak was a market leader until digital disruption eclipsed film photography with digital photos' – failing to 'see the disruptive forces affecting their industry' and 'to truly embrace the new business models the disruptive change opens up.'
Scott Anthony has written in that Kodak 'created a digital camera, invested in the technology, and even understood that photos would be shared online' but ultimately failed to realize that 'online photo sharing was the new business, not just a way to expand the printing business.' Business planning and models According to 2018 study, 70–75% of IoT deployments were stuck in the pilot or prototype stage, unable to reach scale due in part to a lack of business planning. Studies on IoT literature and projects show a disproportionate prominence of technology in the IoT projects, which are often driven by technological interventions rather than business model innovation. See also.
Industrial IoT USAJune 26th -27th 2020 Chicago, IllinoisThe 5th IIoT Summit returns to Chicago on June 26th-27th 2020. Jennifer ByrneJennifer is the Chief Technology Officer for Microsoft US, which serves the largest commercial customers in the US by helping them realize their key business objectives through digital transformation utilizing Microsoft’s full suite of enterprise cloud offerings. In this role, Jennifer leads the US customer success teams, national technical teams, strategic accounts program and is also responsible for operating the Microsoft Technology Centers. Adviser.
Jennifer Byrne. Chief Technology Officer - US. Microsoft.
Alan TillesWith over 30 years of wireless experience, Alan is viewed as one of the “go-to” attorneys in the industry regarding spectrum utilization. From radio manufacturers, to frequency coordinators, radio engineers, public safety agencies, railroads and utilities, he is frequently called upon to create innovative answers to complex technological problems. Alan’s work in wireless goes well beyond simply reviewing contracts and writing FCC comments. Adviser. Alan Tilles. Telecom. Data Privacy & Entertainment Attorney.
Shulman Rogers. Judy MartinezJudy is a Siemens certified Key Account Manager; within her 1st year at Siemens Judy was awarded the Siemens Top 25 award for Regional Account management, and Judy and her team have closed $1B in Midwest projects in the last 6 years. Judy leads a team of designers, engineers and product experts to consult on, develop, and implement smart city infrastructure projects in cities. Her projects are cross-sector, spanning energy, transportation, buildings, water/wastewater and the Internet of Things (IoT). Adviser. Judy Martinez. Chief City Executive.
Siemens. Nick TindallNick Tindall is a native of north-central Iowa where his family still farms. For nearly 11 years he has led the Association of Equipment Manufacturers agricultural policy efforts.
He has also worked for the National Marine Manufacturers Association, American Farm Bureau and U.S. Grains Council.
He earned his BA in political science from the University of Northern Iowa in 2001 and a masters in political management from George Washington University in 2003. Adviser. Nick Tindall.
Senior Director, Regulatory Affairs & Ag Policy. Association of Equipment Manufacturers. Madhuri AdettiwarMadhuri is a thought leader with extensive experience in driving digital transformations within the large global organizations, with huge revenue impacts, cost saves and operational excellence. She has a deft in building and leading large global teams to deliver digital products such as SaaS, PaaS, B2B Commerce Platforms, Big data & AI products for internal and external customers.
She currently heads the Digital Solar products portfolio at GE, based in San Ramon California. Adviser. Madhuri Adettiwar. Chief Digital Officer - Digital Solar Products. GE. Jim ClaunchJim Claunch is currently VP of Business Efficiency for Development and Production International in Equinor. He joined Equinor in 2009 as Vice President of Global Business Services in the Houston office and subsequently held VP of HR positions in Norway and in Houston.
He has over 30 years of experience in the energy sector including 14 years of international experience serving in various financial and shared services roles. Adviser. Jim Claunch. VP of Business Efficiency for Development and Production International. Equinor. Mark KarasekMy passion is new product development and the organizations that make it happen.
I believe that success comes from picking great people, aggressively coaching them, and giving them the freedom to act. So my goal is to bring great products to market working with smart, capable and enthusiastic people. Specialties: New Product Development, Innovation, Intellectual Property Management, Mentoring and Organizational Development, Business Development, Strategic Planning. Adviser. Mark Karasek. CTO & Executive VP, Engineering. Chamberlain Group.
Martin DavisMartin Davis is executive vice president of Southern Company Services and chief information officer of Southern Company, one of America’s most respected companies and a leading producer of clean, safe, reliable and affordable electricity. Davis leads more than 1,500 experts in information technology strategy development, operations and delivery across 120,000 square miles and supporting Southern Company’s nine subsidiaries, including Alabama Power, Georgia Power, Gulf Power and Mississippi Power. Adviser. Martin Davis. CIO. Southern Company.
Phillip DanaPhilip is IT Director at Netafim. His Technical Experience/Expertise focuses to whatever the business requires, with security and Data at the center of every business these are the primary focuses to the core of the business that i provide on a daily basis.
Philip excels in understanding a business and adding value to IT as a business partner more then a cost center providing innovative solutions that give business insight and create value to the business. Adviser. Phillip Dana. IT Director.
Netafim. Mark HearnMark is the Head of IoT Security at Irdeto. He is responsible for leading Business Development strategies to secure organization’s IoT applications and connected devices. Mark has been with Irdeto since 2003, through Irdeto’s acquisition of Cloakware. Mark is a seasoned Product Management executive with 20 years of bringing technology and business requirements together to solve market problems, particularly within Media Entertainment and Security markets.
Official Keynote. Mark Hearn.
Internet Of Things America Llc
Head of IoT Security. Irdeto. Sachin LullaSachin is responsible for EY’s go-to-market strategy for Internet of Things and Digital Transformation in the Americas, for automotive and manufacturing. He helps clients become more agile, capture evolving customer needs and develop an entrepreneurial mindset, through the use of emerging technologies such as IoT and AI. He’s equipping the world with strategies that will redefine mobility for the digital age. Presentation. Sachin Lulla.
Americas Digital Transformation Leader. EY. Todd BergerTodd Berger is responsible for the NALA Technical Solutions Team at BlackBerry. Joining BlackBerry in 2015, as part of the Good Technology acquisition where Todd managed the global Technical Solutions Team for 11 years, contributed to the transformation of BlackBerry to a software focused cybersecurity company. Todd has over 18 years of enterprise mobility and security consulting experience ranging from application development, security and collaboration to endpoint management. Presentation. Todd Berger.
Senior Director, Technical Solutions. Blackberry.
Jerry GooteeJerry has over 28 years of experience serving global organizations with their auditing, tax, transactions and consulting needs. He has held many Americas and Global leadership positions at EY and has led and coordinated client projects across many functions and business domains.
Some his areas of experience include: emerging digital technologies, finance and back-office transformation, site selection, external and internal audit co-sourcing and controls support. Presentation. Jerry Gootee. Global Industrial Products Manufacturing Sub-Sector Leader.
EY. Charles ByersCharles C. Byers is Associate CTO of the IIC, now incorporating OpenFog. He works on the architecture and implementation of edge-fog computing systems, common platforms, media processing systems, and the Internet of Things. Previously, he was a Principal Engineer and Platform Architect with Cisco, and a Bell Labs Fellow at Alcatel-Lucent. During his three decades in the telecommunications networking industry, he has made significant contributions in a variety of sectors.
Presentation. Charles Byers. Associate CTO. Industrial Internet Consortium.
Tom BatesTom is a Software Engineer with a successful track record of delivering projects on time with full functionality and high quality. As Principal Software Development Engineer at Actian he is responsible of: Implementation of support for Linux HA Clustering, defecting investigation and fixing, contribution and implementation of ideas related to re-factoring and multiple CPU scaling, co-implementation of ODBC 64-bit port. Presentation. Tom Bates.
Principal Software Development Engineer. Actian.