IoT Evolution Podcast Recap: Edge Computing Future
Edge computing has become a topic of hot conversation as the technology capable of supporting sensor-2-server data transport has matured. The realization of true edge computing is accompanied by a host of benefits, including real-time data transmission, maintenance needs and considerable savings for operational expenses. Is edge computing the cut-and-dry future? Ken Briodagh, editorial director with IoT Evolution, plays devil’s advocate on a recent podcast with FreeWave Technologies CMO Scott Allen. He asks, essentially, “If companies focus resources on the real-time data transport at the edge – sending small packages of data at a time in the interest of speed – are we losing the benefits of big data? Do we lose the information that big data sets can provide in terms of predictive analytics and, ultimately, machine learning if we discard bits and pieces of data at the edge that we’ve deemed irrelevant?” Listen to the podcast below for Allen’s response! Overall, edge computing has three main drivers: latency–our need to have the data in milliseconds; loss of communication–able to solve the factory problem without shutting down the entire plant; proximity–sensors in the field monitor the data back to the edge. Edge Computing Solution Depending on the industry, a mixed bag of both programmable and edge computing solutions is an answer to Briodagh’s question. In some cases, especially with the oil and gas industry, companies rely on a sensor-2-server stream of communication, where they need to have the information in real-time, and if there is a problem, be able to act locally and fix the issue before anything drastic happens. The network is a combination of radios communicating with sensors that pass the data to a gateway and up to a cloud system. The network uses only small data sets to transmit a continuous flow of intelligent, sensor-based information, optimizing bandwidth in situations where latency is crucial. Next for the Edge There will come a time when using edge technology will just become a regular line item expense needed to do business in this modern age. Some early adopters have already started using gateway systems as a cookie cutter roll-out for all future expansions. Many worry the cost of entry is still too high to integrate, even though the need for transmission is great. As our digital age grows, infrastructure complexity and the desire to implement the latest technology grow along with it. Altogether, edge computing is still in its infancy stage, so no one really knows what data we deem irrelevant today will be vital tomorrow.
Seismic Shift in IIoT Monitoring
There’s been a seismic shift in monitoring earthquakes via the Industrial Internet of Things (IIoT) with advanced Machine-to-Machine (M2M) technology have reshaped the industrial communication industry. Every device or machine along the network, even at the outermost edge, now has the opportunity to be fully-connected for automated collection and delivery of information. As Sensor-2-Server (S2S) communication technology evolves to keep up with the demand for this connectivity paradigm, new efficiencies are created and Big Data is available to drive actionable intelligence. Seismic Shift Data that Saves Lives The sheer quantity of available data, combined with the speed of automation can support mission critical applications that are designed to save lives. Research centers can leverage IoT networks to relay critical data in real-time from areas where earthquakes are a common threat to people living nearby. While natural events like earthquakes and volcanos are not avoidable or fully predictable, an IoT network can potentially help reduce the level of devastation through close, reliable seismic monitoring via highly sensitive and advanced sensor technology. S2S communications monitor and send data from remote areas where Earth changes are first detected, to the monitoring authorities who are closely tracking seismic activity. S2S solutions leveraged for early detection of these events can enable authorities to warn citizens in advance to take appropriate precautionary measures. When robust, rapid, real-time monitoring is combined with effective emergency communications, human casualties can be significantly decreased. Seismic Shift and the Ever Changing Landscape IoT has been adopted at such a rapid pace that the demand for modern, sophisticated communication technology is driving constant changes in remote, industrial communication networks that will further advance applications like seismic monitoring. These changes have clearly disrupted the traditional Supervisory Control and Data Acquisition (SCADA) market. While SCADA systems are not obsolete, industries like environmental monitoring will continue to leverage new technologies designed to help seismologists make more informed decisions than with just SCADA alone. Now, network operators can evolve and adapt their monitoring programs over time through the IoT with edge devices that allow third-party software applications to be deployed network-wide. This has not only opened new doors for software developers, but it opens up the opportunity for advancements in environmental monitoring to further improve natural event monitoring. Fast and accurate data transport from the sensor networks in seismic monitoring therefore requires robust and reliable technology that doesn’t fail in remote and sometimes harsh environments. RF technology, for example, is advancing to help field crews make intelligent decisions and closely monitor the elements that can help delivery early warning for natural events. Find us at JavaOne this Week
Friday Top 5 IIoT News Roundup
It’s time to nominate our Friday top five Industrial IoT news articles of the week. Much like the weather in Boulder this week, we couldn’t decide on just one vertical focus, so we cast a wide net of IoT topics. In this week’s roundup, you’ll find a splash of fog computing, manufacturing, smart grid, security and overall IoT updates. Dive in and see if you agree with our picks. Don’t miss the Friday bonus at the end of this short roundup. Making fog computing sensors clearly reliableBy @Patrick_Mannion | Published on @ednmagazinehttp://www.edn.com/design/sensors/4442602/Making-fog-computing-sensors-clearly-reliable“As fog computing rolls in, the onus is upon designers to figure out how much intelligence should be at each node of the system for optimal performance. This implies then that sensors will need to start being more intelligent, with some level of built-in processing, storage, and communications capability.” Army needs wide-area electro-optical sensors for manned and unmanned aircraftBy @jkeller1959 | Published on @IntelligentAerohttp://www.intelligent-aerospace.com/articles/2016/08/ia-wami-sensors.html“Army researchers are interested in moderate-resolution persistent-surveillance electro-optical sensors that operate during the day and at night over large areas to detect vehicles and people on foot. Researchers want to develop a sensor that consists of an imaging sensor, as well as a storage and processing unit.” Five essential IIoT DefinitionsBy @MMS_MattDanford | Published on @MMSOnlinehttp://www.mmsonline.com/blog/post/5-essential-iiot-definitions-“The idea is not just to exchange and collect data, but to act on that data to make things better. (One commonly cited example is a “smart” thermostat.) IIoT is the same concept applied to industry. Examples range from “smart” buildings and power grids to “smart” transportation networks. IIoT might initially take the form of a machine tool status monitoring system.” What makes a grid smart?By David Shadle | Published on @tdworldmaghttp://tdworld.com/grid-opt-smart-grid/what-makes-grid-smart“My point, however, is that the critical consideration is not the number of sensors, controls or data storage components we add to our system when we decide to move ahead with smart grid applications. The focus also needs to be on mastering the integration of these systems, many times across traditional IT and OT lines, to allow them to achieve their potential for intelligence.” Top ten security predictions through 2020By @Gartner_inc | Published on @Forbeshttp://www.forbes.com/sites/gartnergroup/2016/08/18/top-10-security-predictions-through-2020/#4d8ba8073cbe“Through 2018, more than 50% of Internet of Things (IoT) device manufacturers will not be able to address threats from weak authentication practices.” Friday Bonus! FreeWave Technologies announces partnership with Solis Energy By @SolisEnergy and @freewavetech | Published on @SolarNovus http://www.solarnovus.com/freewave-technologies-announces-partnership-with-solis-energy_N10256.html “Both companies are excited about the partnership and are already working through high profile opportunities to take advantage of the growing demand for smart systems and industrial connectivity.”
The Glue that Holds Our “Connected” Dreams Together
Image courtesy of Flickr Creative Commons The visage of our “smart” or “connected” destiny is often presented to us in broad strokes: self-driving vehicles, connected homes, logistics, wearables – the list continues on with each piece of evolving and maturing technology. Smart cities have a bright future, and the application possibilities seem expansive, but often lost in the conversation is the technology that actually enables the connected world. Within a smart city – or even at a micro level – within one specific industry deploying smart technology, are a wide range of considerations: how much data are we transporting? How will we transport that data? How can we make our system intelligent? Where do we need to install these intelligence-driving platforms? How can we connect our data, operational technology and information technology to the necessary access points? Who/what has access to this data and control over these machines? These are only a few of the considerations that companies must address that are responsible for the industrial services driving cities and municipalities. While security is indeed a critical piece of this landscape, before any kind of connected or smart city can be achieved, the literal communication platform upon which that connectivity is deployed must first be implemented in a way that is not only compatible with current technology, but that will also be compatible with future technologies as well. From our perspective, there are five critical elements behind a smart city connected infrastructure: Robust Cloud Services Infrastructure designed to support all consumers of smart city deliverables Core Network Architecture that can rapidly expand in bandwidth and reach Extended Access Layer network architecture that incorporates a wide range of wired and wireless technologies to reach every sensor and device or that needs to connect to the smart city infrastructure A wide range of reporting devices such as sensors, visibility devices and other end points that create the data that makes a smart city work Distributed intelligence technology that allows for local execution of applications at the access layer plus global communication of data/analytics and information While each one of these tools is important in its own right, there is a common, underlying thread that connects them: each facet depends on a robust, reliable and secure communication platform. For smart cities, these communication platforms must be capable of enabling multiple methods of connectivity, but most importantly, they must be able to provide industrial-strength Wi-Fi. Wireless connectivity is the backbone of communication between the sensors that power all facets of the connected industrial infrastructure and the big data transport that is critical to the analytics that power “smart” enterprise. Not all industrial Wi-Fi platforms are created equal, and one of the major questions facing the ongoing development of smart infrastructure centers on how to ensure that these networks are secure and compatible across multiple, and sometimes proprietary, technologies. This certainly opens up a veritable can of worms, including the idea of standardization, but without the driving force of reliable and robust communication technology, most smart city dreams will remain just that – a dream.
Berg Insight: Bright Days Ahead For Wireless Automation
A recent report published by Berg Insight details the bright future ahead for Industrial IoT through the implementation of wireless automation technologies. Berg Insight senior analyst Johan Svanberg made note that higher levels of automation and IoT solutions enable “shorter lead times, lower inventories, increased throughput as well as more flexibility and the ability to respond faster to changing customer needs.” The wireless IoT device market is served by a multitude of players from various backgrounds including global automation solution providers, automation equipment and solution vendors, industrial communication specialists and IoT communication specialists. This new report from Berg Insight informs us that: 2015 estimate of wireless devices for industrial automation applications reached 4.8 million units worldwide. Wireless devices installed for industrial applications have a forecasted growth rate of 27.7 percent from 14.3 million connections at the end of 2015 to 62.0 million devices by 2021. Key Findings from Berg Insight: Wireless connectivity is instrumental in the Internet of Things era and the use of wireless solutions in industrial automation is increasing rapidly at all levels of automation systems. Industrial automation systems utilize wireless communication to connect remote and local facilities and equipment to increase operational efficiency. A wireless automation system contains a mix of network technologies, equipment and systems including enterprise and automation systems, network equipment, control devices and field devices. The most common wireless technologies in industrial automation include cellular, 802.11.x Wi-Fi, proprietary unlicensed ISM radio, Bluetooth, various LPWAN technologies and 802.15.4 based protocols such as WirelessHART, ISA100.11a and ZigBee. Berg Insight estimates that shipments of wireless devices for industrial automation applications, including both network and automation equipment, reached 4.8 million units worldwide in 2015. Growing at a compound annual growth rate of 25.1 percent, shipments are expected to reach 18.3 million by 2021. The installed base of wireless devices in industrial applications is forecasted to grow at a compound annual growth rate of 27.7 percent from 14.3 million connections at the end of 2015 to 62.0 million devices by 2021. Wi-Fi is widely used for backbone communications as well as in monitoring and control applications within factory automation where Industrial Ethernet has got a strong foothold. Bluetooth is also popular – often as a point-to-point wire-replacement between for example a mobile HMI solution and a field device or control unit. 802.15.4 networks are often used to connect wireless sensors and instrumentation in process automation. Cellular connectivity is typically used for backhaul communication between plants, connecting remote devices in long haul SCADA applications and for third party access to machinery and robots. LPWAN technologies are increasingly used in certain low data, long range applications. Most of the major vendors of wireless IoT devices in industrial automation offer a wide range of devices with various wireless technologies in order to support many different applications. Key Takeaways, According to Berg Insight: Companies are now deepening the integration between industrial automation systems and enterprise applications and the promise of IoT is getting more tangible by the day. Large multinational corporations are beginning to systematically develop and adopt best practices to maximise the benefits of IoT technology in every part of their organisations. IT/OT convergence, smart factories, Industry 4.0 and the Industrial Internet of Things are concepts which are part of the ongoing evolution of industrial automation. Innovation in sensors, wireless connectivity, collaborative robots, big data and cloud solutions along with seamless exchange of information between devices, systems and people paves the way for improved performance, flexibility and responsiveness throughout the enterprise value chain. For more information, read the full report from Berg Insight.
Internet of Things Expo: What to expect this week
The Internet of Things (IoT) is essential for both enterprise and personal, everyday use. Leading research firms agree that IoT will experience an unbelievable boom, possibly into the tens of billion devices by 2020 as computers, smartphones and sensors all require connectivity. This week’s Things Expo is a SYS-CON Media annual event, designed to help make sure your enterprise is IoT-ready with 80 breakout sessions focusing on many aspects of IoT, including big data’s use with predictive analytics, smart grid and Industrial IoT (IIoT), wearables, identity in IoT and modem data centers, among many other tracks. Here is a sneak peek at keynote Internet of Things Expo speaker Chris Matthieu. Also…Check out this clip of a Things Expo Power Panel It is going to be an action-packed three days of IoT information dumps from the experts. If you have the chance to be in New York this week, be sure to check out this conference and soak up some knowledge. Scott Allen, CMO of FreeWave, will be presenting “Sensor-2-Server: Intelligent Communication at the Access Layer” at ThingsExpo on Tuesday, June 7th from 4:40 – 5:15p.m. EDT. (http://www.cloudcomputingexpo.com/event/session/3238). Sensor-2-Server™ (S2S™) intelligent communications for the access layer can collect and transport the data that supports higher-level analytics. As IoT becomes adopted by industrial markets, there is going to be an increased demand for video, voice, data and sensor data communication from the outermost layer of the network. Let us know what you think. Which aspects of IoT are most interesting to you? What needs more coverage and information?
IIoT + S2S = Industrial Innovation at the Access Layer
The Industrial Internet of Things (IIoT) is moving at a rapid pace towards a higher intelligence platform to help collect, protect, transport and control data at scale from a myriad of sources. The access layer in the IT landscape is now particularly becoming an innovative technology environment with many new sensory solutions available to bring intelligence back to the core systems and analytics engines. Another area to consider when discussing IIoT are the individuals working with these technologies today, tomorrow and in the future. To start, the younger/millennial generation is entering the workforce in droves and is arguably the first generation open to big data integration and as part of IoT application solutions. Now that IT and Operations personnel work closer together than ever before, there is a need to be able to share the sensor data across the access layer. On the other hand, the older generation is trusting of the SCADA data systems they have been using for years, and are slow at first to adapt to the new intelligence created in the access layer. How Does an Enterprise Address this Transition? One strategy is IT/OT convergence, which promotes a single view of an enterprise’s information. Process-management tools help ensure that every person, machine, sensor, switch and device in an organization has accurate information in the best form and at the right time. As OT products—for example, programmable logic controllers (PLCs) and remote terminal units (RTUs)—become more aligned with IT infrastructure and applications, getting OT information integrated efficiently with IT systems at a process level is difficult enough for many companies. Getting IT and OT systems to work together to maximize business efficiency — while avoiding negative consequences, risks and pitfalls in the process —makes the task more challenging. However, thanks to new technologies, this process is becoming more practical and is creating the opportunities for huge economic benefits when these two disciplines are successfully integrated. Evolution of Sensor-2-Server (S2S) (As described by Brandon Lewis, Technology Editor for IoT Design) S2S architectures define a method for communicating data collected by sensor platforms at the access layer of an IoT network back to servers at other layers, including but not limited to centralized servers in the core network. This type of architecture allows sensor data to be transmitted to points in the network that are best suited to the specific type of analysis, decision making, and control, which in an industrial deployment could be a SCADA controller located at the aggregation layer rather than a mass dump of heterogeneous data from hundreds or thousands of endpoints back to the core network. For critical IoT systems that require real-time or near-real-time analysis of sensor data, this more localized communications can speed decision cycles using data in motion rather than waiting to parse data at rest. Want to Learn More about S2S and the Future of Industrial IoT? For more information and a full discussion on S2S and the future of IIoT, please check out this recent interview with the IoT Roadshow and Scott Allen. You can also listen to the SoundCloud recording below!
Drone World: Applying IIoT Applications
“Drone World” may seem a bit overboard, but the fact is, drones are here to stay. We’ve spent time in these pages looking at unique and innovative drone applications in industries like utilities, precision agriculture, and even lifeguarding. Today, in honor of Memorial Day, we would like to take a moment and honor those men and women serving in the armed forces, by highlighting interesting government drone technology uses. Drones ‘Shot Into The Sky’ By The U.S. Navy The BBC News informs us how these innovative instant flight drones could be used as a method of defense for ships at sea suddenly burdened by a swarm of enemy drones. This project is known as LOCUST and it aims to launch a swarm of drones at high speed. Elizabeth Quintana from the military think tank Rusi believes that, “Drones could be used to take out enemy swarms at sea.” Drones That Can Sniff Out Radiation The Nevada National Security Site (NNSS) officials have recently purchased two drones to be a view from the sky in case of an emergency to sniff out and detect signs of radiation. It will be important to use these unmanned aerial systems (UAS) in situations that are to dangerous for humans. Other Applications of Drones Drones aren’t just for the government anymore, in fact we are already starting to see the industries below finding ways to improve safety, service and efficiency with the implementation of drones. Emergency Response Enables immediate action, providing emergency response teams with fast, flexible visibility to assess critical situations. Utilities Safely allows for the quick inspection of high voltage power lines and wind turbines, helping mitigate worker risk and improve monitoring. Military & Defense Assisting with intelligent surveillance and reconnaissance missions to deliver timely, relevant, and assured information to thwart potential threats. Oil & Gas Protects and helps maintain extensive miles of pipeline covering large, remote areas that would otherwise require enormous amounts of time and resources. Agriculture Creates more efficient farms by monitoring inventory, growth, water and fertilizer levels, and crop health to facilitate production and increase yields. Public Safety Supporting firefighting operations by providing more up-to-date information at a lower cost, while reducing the number of responders in harm’s way. We hope you have enjoyed our quick drone world recap, and as always tell us what we missed. The next time you see a drone flying in the sky, think about all the possibilities that drone or fleet of drones could be providing.
Data Drought: Rural Australian Wi-Fi
Data drought in the rural Australian outback has illuminated the myriad problems stemming from a lack of Wi-Fi connectivity. Precision agriculture today requires broadband and high-speed connectivity to compete in the innovative global marketplace. Yet, many rural areas lack the sufficient infrastructure needed, offering only spotty or basic wireless internet solutions. In fact, there are a total of 135,000 Austrian farms over 400 million hectares, that create enough food to feed 80 million people, representing 13 percent of the country’s total export revenue. With that in mind, Australia can no long afford to ignore the demand to increase farming innovation, and so it has begun to look at possible solutions for the geographically complicated continent. A recent FaceBook survey conducted by the Better Internet for Rural, Regional and Remote Australia (BIRRR) found that 88 percent of Australians feel they don’t have services to meet all of their needs. Many living in the rural areas have voiced concerns over the noticeable “data drought,” but these concerns were often thought as a one-off individual problem. The BIRRR results have helped to bring to light just how massive this data drought issue is to farmers and others living in the rural areas of the country. Living in the bush has proven hard to find reliable ways to connect even basic Wi-Fi long enough for remote education, banking and innovative agriculture tools. It’s not for a lack of trying, as nearly every farmer has at least one smartphone. Many have been forced back to the city, even just to rent office space, so they are able to conduct business and digital transactions without interruptions. Is there a solution? The National Broadband Network (NBN) launched satellite Sky Muster, earlier this year with an expected customer capacity of 240,000. Farmers lucky enough to live in range of this satellite are starting to see the benefits of real broadband connectivity. A second satellite is expected to launch later this year with the hope of reducing the data drought across the remote areas of the nation. Another possible solution has been presented by Prime Minister Malcolm Turnbull, who believes mobile technology is key to improving the agriculture and living conditions in the outback. Turnbull has promised to spend 60 million to improve mobile black spots in regional, rural and remote Australia. The AgForce vice-president and committee chair, Georgie Somerset recently said that the “increased investment in fixed wireless roll-out would also enable local Wi-Fi platforms, that can then support businesses and education in rural Queensland with high-speed reliable and affordable data.” It is important to note that, today’s IIoT technology marketplace has begun to produce exciting new solutions to address remote wi-fi needs similar to the challenges being faced in Australia today. The steps Australia takes to find a suitable solution to its connectivity problems can set the stage for solving similar challengs in remote areas across the globe.
Digital Oil: Wireless Means Safety & Efficiency
Production demands of the 21st-Century change at an extraordinary pace. Industrial markets, such as energy and oil & gas face challenges going forward, including the reliable monitoring of assets in the field, dealing with 24×7 production demands, and managing high costs in terms of both time and resources to manage assets in remote locations. These market forces have naturally led to the emergence of the industrial internet of things (IIoT) and wireless communications technology. If you’re an operator in the field, you’re well aware that wireless IoT technology is changing the level of safety, efficiency and monitoring available on the rigs. Let’s take a moment and look closer at how these changes are impacting the digital oil field of today. Why? The consequences of incidents, such as natural gas pipeline explosions, have contributed to the demand for more safety and monitoring regulations along pipelines. California for example, saw tightened state regulations as a result of the San Bruno disaster, which included more stringent requirements for pipeline monitoring. Across industries such as oil and gas, there are certainly areas with the presence of hazardous gasses and therefore potentially dangerous environments. Safety First Taking a closer look at safety on an oil field, we realize just how dangerous it can be for people to be on or even near a production site. Advancements in IoT are now more important than ever because they allow more oil and gas companies to enable a digital work environment – not just from an operational perspective, but from a worker health and safety point of view. Safety concerns to be addressed are the elimination of manually painstaking tasks related to checking on-site sensor data or heavy machinery that resides in potentially hazardous environments – for example where explosive gases are present. Safety is now being increased by taking away the pen and pad from the technician and automating wireless remote monitoring capabilities to enter readings, pressures, temperature and other production monitoring values from miles away. Because of this evolution, many technicians have updated their skills in order to provide value in a digital age and the skills gap here is also an emerging issue for energy producers to keep in mind. Jens Norgaard, SafeEx Business Development Director reports that, “There is no doubt that the younger generation…are running around with high tech equipment…and it’s much more sexy using an electronic tool than using pen and paper. Most technicians have taken a technical education because they want to use their hands and are not always very keen on doing administrative work. So if you can reduce the amount of that it will become much more attractive for younger people to do it.” Highly Efficient and Operational The hope with any advancement in technology is that our world will be able to run and function more smoothly. According to LR Energy’s annual 2015-2016 Oil & Gas Technology Radar survey of global oil and gas executives, “the top driver of innovation investment is operational efficiency.” As wireless IoT solutions continue to infiltrate the oil rigs and pads of today, it is only natural to question the operational and efficiency state of things. Over the next decade technological implementations are expected take more people off the drill floor and into the office allowing companies to fill the knowledge gap with remote drill sites, thus paving the way for more automated oil fields. Pierre Sames, DNV GL director of research and innovation in Norway suggests that, “These technologies will help the industry to be more cost efficient in operations, which is very much needed due to the current oil price crisis.” Keeping Production High with High-Tech Whether you are working with an offshore or onshore rig, the ability to seamlessly monitor and control the operations of a oil rig or well pad automatically from an office location is a key component of IoT and an evolution of the digital oilfield. Natural Gas Intel (NGI) informs us that, “One of the most anticipated technologies, automated drilling in the offshore and onshore, could reduce drilling times and costs by up to one-third versus conventional drilling rigs, ensuring more wells are economically feasible, able to hit smaller targets and generating more infill production.” It seems apparent that we are on the midst of an industrial revolution where blended technology ecosystems are going to be the core of what makes modern energy producers competitive. Just think of the combination that Voice, Video, Sensors and Data can have if applied together in a holistic fashion. “Expectations of fully automated drilling operations, autonomous pipeline inspections and the expanded use of natural gas to fuel trucks and railways are likely to be at the forefront by 2025,” industry consultant DNV GL said last month (see Daily GPI, April 6). By 2025, the energy industry will become increasingly “automated, digital and smarter,” according to DNV’s Technology Outlook 2025. What’s next for the oil and gas industry? Join us this week at the 91st International School of Hydrocarbon Measurements(ISHM) conference in Oklahoma. ISHM is designed to educate and update you on the latest technological advancements for the oil and gas industry. This year you will have an opportunity learn with both lecture and hands-on classes as well as network with fellow industry peers. Cannot join us in Oklahoma? Feel free to download the “Building the Digital Oilfield of the Future” white paper for insights into how wireless IoT technology is redefining oil field production and data communications.