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.
IoT Top News: M2M Propels Machines
Time and again, those keeping a pulse on the Internet of Things (IoT) space frequently hear about the “rise of the machines.” Humanity is not only discovering fascinating ways to integrate machines into our daily lives, but also finding new uses for machines as well. How? Machines are now “internet-connected” just like the smartphones we carry around in our pockets. And this isn’t just on the commercial side with the likes of smart thermostats or connected vehicles – even tractors and oil and gas machinery are industrial examples of where new “things” are now on the digital network. In fact, there are more M2M or “machine-to-machine” communication devices on this planet than humans. As GSMA Intelligence reported in 2014, there are 7.2bn M2M devices versus 7.19bn humans. Stuart Taylor from Cisco also wrote a prediction that “The Internet of Things (IoT) is a world where up to 50 billion things (or devices) will be connected to the Internet by 2020; or, the equivalent of 6 devices for every person on the planet.” Realizing the major role M2M devices continue to have in our connected world, specifically as it relates to the advent of machine learning, it’s only natural to highlight the impact of machines and M2M in the past, present and future. The Machines are Coming: How M2M Spawned the Internet of Things In the digital world, M2M wireless solutions will work for us quietly, in the background solving all our day-to-day needs. John Kennedy with Silicon Republic reports that, “M2M is at the heart of the industrial internet of things (IIoT), powering smart factories that can be run remotely from a tablet computer, and smart buildings that monitor their environment and feed data back to the cloud.” Is Machine Learning Over Hyped? In the now 24-hour news cycle, often the top news lingers around lighter topics. So how much hype should be given to machine learning (ML)? The Huffington Post respondent Scott Aaronson, theoretical computer scientist at MIT, seems to think that “There’s no doubt in my mind that people 30 years from now will agree with us about the central importance of ML, but which aspects of ML will they rage at us for ignoring, or laugh at us for obsessing about when we shouldn’t have? Machine Learning: Demystifying Linear Regression and Feature Selection Machine learning needs to integrate domain knowledge in order to improve the quality of data collected from analysts. Josh Lewis with Computerworld thinks that, “Business people need to demand more from machine learning so they can connect data scientists’ work to relevant action.” Machine Learning Examples Crop up for Data Center Management Data centers appear to be the perfect place for enterprises to implement machine learning to its fullest. Christopher Yetman, COO at Vantage Data said, “There are also sensors that generate data about air pressure, humidity, temperature and supply voltage and typically feed into a programmable logic controller.” M2M Technology Driving Agriculture’s Industrialization On a global front, M2M is driving agriculture’s industrialization in South Africa. IT News Africa informs us that, “Given the ability to automate many monitoring and control functions through intelligent devices, agriculture is a prime target for leveraging M2M capabilities.” We hope you have enjoyed this week’s roundup, and as M2M connections continue to pile-up, we urge you to consider the plethora of commercial and industrial use cases that can benefit from these innovations.
Critical (Outdoor) IoT Applications Need Robust Connectivity
It’s safe to assume that the majority of all Internet of Things (IoT) devices operate near large populations of people. Of course, right? This is where the action happens – smart devices, smart cars, smart infrastructure, smart cities, etc. Plus, the cost of getting “internet-connected” in these areas is relatively low – public access to Wi-Fi is becoming widely available, cellular coverage is blanketed over cities, etc. But what about the devices out in the middle of nowhere? The industrial technology that integrates and communicates with heavy machinery that isn’t always “IP connected,” operating in locations not only hard to reach, but often exposed harsh weather. The fact remains, this is where IoT connectivity is potentially most challenging to enable, but also perhaps the most important to have. Why? Because these numerous assets help deliver the lifeblood for our critical infrastructures – electricity, water, energy, etc. Without these legacy and geographically dispersed machines, a smart world may never exist. But let’s back up for a second and squash any misconceptions about the “industrial” connectivity picture we’re painting above. Take this excerpt from Varun Nagaraj in a past O’Reilly Radar article: “… unlike most consumer IoT scenarios, which involve digital devices that already have IP support built in or that can be IP enabled easily, typical IIoT scenarios involve pre-IP legacy devices. And unfortunately, IP enablement isn’t free. Industrial device owners need a direct economic benefit to justify IP enabling their non-IP devices. Alternatively, they need a way to gain the benefits of IP without giving up their investments in their existing industrial devices — that is, without stranding these valuable industrial assets. Rather than seeing industrial device owners as barriers to progress, we should be looking for ways to help industrial devices become as connected as appropriate — for example, for improved peer-to-peer operation and to contribute their important small data to the larger big-data picture of the IoT.” It sounds like the opportunity ahead for the industrial IoT is to provide industrial devices and machines with an easy migration path to internet connectivity by creatively addressing its constraints (outdated protocols, legacy equipment, the need for both wired and wireless connections, etc.) and enabling new abilities for the organization. Let’s look at an example of how this industrial IoT transformation is happening. Voice, Video, Data & Sensors Imagine you are a technician from a power plant in an developing part of the world with lots of desert terrain. The company you work for provides power to an entire region of people, which is difficult considering the power plant location is in an extremely remote location facing constant sand blasts and extreme temperatures. The reliance your company places on the industrial devices being used to monitor and control all facets of the power plant itself is paramount. If they fail, the plant fails and your customers are without power. This is where reliable, outdoor IoT connectivity is a must: With a plethora of machinery and personnel onsite, you need a self-healing Wi-Fi mesh network over the entire power plant so that internet connections aren’t lost mid-operation. Because the traditional phone-line system doesn’t extend to the remote location of the power plant, and cell coverage is weak, the company requires Voice over IP (VoIP) communications. Also, because there’s no physical hardware involved, personnel never needs to worry about maintenance, repairs or upgrades. The company wants to ensure no malfeasance takes place onsite, especially due to the mission-critical nature of the power plant. Therefore, security camera control and video transport is required back to a central monitoring center. Power plants require cooling applications to ensure the integrity and safety of the power generation taking place. The company requires Supervisory Control and Data Acquisition (SCADA) networking for monitoring the quality of the inbound water being used to cool the equipment. The company wants to provide visibility to its customers in how much energy they are consuming. This requires Advanced Metering Infrastructure (AMI) backhaul networking to help manage the energy consumption taking place within the smart grid. Since the power plant is in a remote location, there is only one tiny village nearby being used by the families and workers at the power plant. The company wants to provide a
DistribuTECH 2016 Day 2 Recap: Renewables Rule
After the initial excitement the opening keynote, everyone spent time checking out innovations from around the industry.
Remote Wi-Fi: Enabling Wireless Video Transport
(Image courtesy Flickr Creative Commons) The topic is not new, but it is increasingly common in conversations with customers and potential users of wireless networks for M2M and IIoT applications. In fact, this topic now occurs in almost every conversation regarding networks and their wireless video transmission capabilities. Our topic is the transport of video and the applications it enables. As reference, a few areas where wireless video is being used are: Security operations, such as facility assess control and perimeter monitoring Work safety to monitor hazardous areas Deterrence of vandalism and theft Process monitoring for improved quality and efficiency For these video integrated systems, they perform several functions: Capture video of the area or process being monitored Transport the video stream to the video analytics, which typically resides in the enterprise network and not at the remote site with the video camera Analysis of the video stream to derive actionable information or data from the real-time feed, and Act upon the information or data extracted from the video where the system may or may not be collocated with the video camera. High-speed wireless networks are well suited for transporting data from remote sites to centralized locations, and again transporting information from the centralized location to remote or other sites where it is acted upon. These high-speed networks require high data rates, low latency and quality of services (QoS) capabilities. Application Examples An example of an integrated wireless video system employing a high-speed wireless network is remote facility access control. The video stream is transported from a remote site to the analytics engine located in the enterprise network where facial or license plate recognition is performed on the video stream. If the person or vehicle is to be on site, the on-site assess control system locks or unlocks a gate or door. In this example, the integrated system has the video source and assess the control system collocated. Another example is improving worker safety through transporting video and analytics where the analytics detects worker presence and activity. If the activity stops, the worker can be contacted through an emergency management system. If the worker does not respond to the contact, an emergency response team can be dispatched. In this example, video transported from the remote site is analyzed and drives inputs into emergency response systems that are not collocated. Video analytics is promising with a wide range of possible applications. However, it is the wireless high-speed network that makes these services viable and cost effective since the wireless network has the bandwidth to be used for multiple applications (voice, video, data and sensor) across multiple departments within the enterprise.
IIoT Top News: Wireless and Wi-Fi
Gone are the days of limited connectivity—at least that’s the plan this year. According to Wireless Design Magazine, The Broadband Alliance has announced plans to hosts a world Wi-Fi-day. This global initiative has teamed up with more than 135 technology companies to help encourage all utilize the IoT and IIoT to its fullest, by taking steps to help business, industry and neighborhoods have access to quality wireless. Now as you reach for your smart device, smart machine or connected thing, hold on tight wireless is taking you to the deep end. Don’t worry you can handle it. Enjoy this week’s reading, and as always tell us what we missed! Army Command Post Gets Secure Gigabit Wi-Fi (GCN) The army is hoping to save countless hours tearing down wired battle systems networks with a new secure gigabit Wi-Fi. Mark Pomerleau with GCN reports that “Wireless capability speeds that configuration, improves troop mobility and provides greater flexibility for commanders.” Subsea Fiber Optic Networks: Past, Present and Future (RCR Wireless News) In this interconnected world, it is amazing to think about the amount of subsea fiber optic networks connecting the planet today, tomorrow and yesterday. Joey Jackson with RCR Wireless News reminds us all that “Subsea fiber optic networks are responsible for the transmission of 90% of the world’s international data.” Type With Your Brain: Future Tech Ditches Keyboard (Discovery News) The future of wireless could allow you to get rid of the keyboard all together and simply type with your brain. Eric Niiler, with Discovery News, tells us that “Scientists are already working on technology that connects the brain to electronic gadgets and two new devices unveiled this week could help usher in a future without keyboards: a wireless brainwave headset and a brain sensor that dissolves in the body after completing its job.” The Future of Wireless Technology is Coming at Light Speed (The Telegraph) One hundred times faster than Wi-Fi, the future of wireless is expected to reach light speed. Rob Waugh with the Telegraph believes that “The speed boost will come from an unlikely source: the lighting above your head. Instead of Wi-Fi radio aerials beaming data through buildings to your laptop, computer-controlled LED bulbs will flicker above your head, beaming out signals like a super-fast Morse code.” The Future of Public Wi-Fi: What To Do Before Using Free, Fast Hot Spots (Wall Street Journal) Setting up an office on the sidewalk isn’t a realistic option year-round, but change is coming. It is good to know what to do before you jump on that free public Wi-Fi.Joanna Stern with the Wall Street Journal informs us, “Wi-Fi networks with widespread coverage and new standards are popping up to allow us to cut back on paying the carriers an arm and a leg for cellular data.”
Can You Hear Me Now? Remote Wi-Fi in the Connected World
(Image courtesy of Tony Webster, via Flickr Creative Commons) One of the more fascinating aspects of our eternal march toward ‘the future’ is the occasional, but impacting, intersection of our critical infrastructure and the general consumer. Like a sine wave across the axis, our connected world meets at points in time that catalyze technological explosions. The transition of computers from behemoth industrial-sized calculators into the first iteration of the personal computer is a good, somewhat recent example. So is the Internet. Each of those began as a fairly raw tool used for enterprise industrial services before intersecting with the consumer and birthing new innovations and applications.Today, the connected world on the horizon, envisioned by dreamers and pragmatists alike, is taking form on the backbone of wireless connectivity in a way that has the ability to impact our critical industries, our smart cities, our homes and our daily lives like never before. Remote Wi-Fi is a tool that has enabled connectivity and data transport for industries like oil and gas, precision agriculture, utilities and seismic monitoring, leading to a boom in the use of predictive analytics to better streamline the work processes in the field for these traditionally remote areas. However, two of the main problems with traditional remote wi-fi network deployment are the security of these networks, as well as the latency of the data transmission. To combat this, these industries have turned to the use of shorthaul (between 1-5 miles) wi-fi hotspots to utilize built-in security measures and decrease latency for data-intensive applications like voice, video, data and sensor connectivity. As a result, these industries have been better able to collect and transport data throughout an entire smart ecosystem, affecting everything from decision-making in the field, to the way the consumer can track personalized utility usage. Our smart cities and municipalities depend on data collected remotely to anticipate infrastructure-related resiliency issues, like grid outages, seismic events and disaster preparedness. Companies in these industries depend on remote data to solve production, maintenance and transport problems. Wi-Fi Will Save the Connected World In early January, the Wi-Fi Alliance, a worldwide network of companies trying to standardize global Wi-Fi provision, announced a new protocol that promises to trigger changes throughout the industrial landscape. Wi-Fi HaLow, as it is called, is an addendum to the IEEE 802.11ah protocol that is set to be finalized later in 2016. HaLow operates in frequencies below 1 GHz and can potentially provide a longer range than Wi-Fi has traditionally offered. The implications for remote Wi-Fi and the Industrial Internet of Things are huge. The addendum means more efficient battery usage due to operating on a lower frequency and with a lower data rate, which, in turn means a greater range and lower transmission power. This standard is still awaiting a final vote, so before we anoint HaLow as the magic bullet for which the Internet of Things has been waiting, the IEEE standards committee will have its say. To come full circle, the potential advent of better long-range Wi-Fi in remote settings could be the next intersection of the axis and the sine wave, enabling innovation and growth at both the industrial and consumer levels of connected-world technology.
Earth-Shaking: Resiliency & Smart Infrastructure Lead Seismic Monitoring Efforts
Seismic monitoring tends to pop up in the news only during disaster situations, or, more recently, in conjunction with North Korea’s possible detonation of a hydrogen bomb. Earlier in 2015, The New Yorker ran a piece, “The Really Big One,” looking at the probability of a large earthquake destroying the Pacific Northwest. The earthquake off the coast of Japan in 2011 triggered one of the largest nuclear plant meltdowns of recent history, the impact of which we are still dealing with today. Point being, the typical association with seismic monitoring – earthquakes and explosions – is negative. The day-to-day reality, however, is much more interesting. Every day, vast amounts of seismic data are being collected the world over, and that data is being reflected by cities taking action to create smarter, more resilient infrastructures – especially in areas where seismic activity either happens frequently or would be devastating were an event to occur. Geological hazard monitoring has become a primary focus for many areas of the world, and as the technology has matured, so has the ability to transport data in real time. In turn, with real-time data transport comes the ability to incorporate predictive analytics and more intelligent decision making for city planning and civil engineers. New Zealand is an excellent example of the renewed emphasis on earthquake monitoring and preparedness. Each year, there are more than 250 significant earthquakes throughout New Zealand, so collecting that data allows scientists to detect, analyze and respond to the seismic activity. As the data is processed, the predictive analytics come into play. Data from these monitoring sites can be used to examine ground movement, which can indicate stress points, and to gauge the probability of an earthquake in the future. Today’s technology now allows all of that data to be transferred in real time from the monitoring sites to the back office, greatly increasing the ability to deploy it into actionable intelligence. In 2011, when Christchurch, New Zealand, was hit with a series of devastating earthquakes and aftershocks – including an aftershock that “produced the highest peak ground accelerations on record” – the recovery effort was basically twofold: how could the city not only rebuild the structures and civic needs, but simultaneously make that infrastructure smarter and more resilient, able to predict and handle future seismic events without the crippling aftereffects. And the truth is, those exact questions are being asked by cities in similar positions on a daily basis. What this all points toward is an evolving ability to synthesize IIoT communications technology, data collection and predictive analytics into a smarter and more resilient infrastructure for areas prone to seismic events. Things that used to fall into the realm of “the future” are now very real and very tangible solutions to nature’s enigmatic temperaments.
IIoT Top News: 2015 News Round-Up
Let’s take a moment and appreciate the excitement 2015 brought for the IIoT: As we look back at the top articles from the year, we were intrigued to learn that cooperative utilities actually have the largest penetration of smart grid meters per percentage of customers, according to Greentech Media and the U.S. Energy Information Administration. It’s interesting to see the largest publicly-owned utility companies in the U.S. are not the leader in deploying smart meter systems. Another topic that caught our eye this year focused on big data initiatives and how they will improve operational efficiencies by the large-scale storage and transfer of volumes of information safely and securely. Companies don’t always see the value in updating information governance policies because there isn’t always a direct reward and no direct penalty for non-compliance. Tim Jennings, Ovum chief research officer, believes as big data continues to grow within the company infrastructure, it is time to consider the security, availability, and time spent storing data. Speaking of Big Data… It is hard to grasp the magnitude of data transferred throughout the cloud. Today, as big data goes to work, it is transforming industrial facilities, and as Forbes states, “they have grown increasingly complex and yes, every machine, every pipeline, every transmission point collects data ready to be read.” Of course, a 2015 news review would not be complete without at least one mention of unmanned systems. Whether the want/need was for industrial, commercial or government applications, the thing on everyone’s mind was how many cool ways this technology could be deployed in the future. While there were many examples to choose from, DARPA certainly caught a lot of attention from its new autonomous submarine-hunting ocean drone. Yes, you read that right! Finally, as we ease our way into 2016, we would like to share the rest of the top technology and IIoT stories from 2015. This year’s round-up highlights articles about: utilities, manufacturing, oil and gas, wireless, big data, security, drones and industry analyst perspectives. Hope you enjoy this week’s roundup, and as always, tell us what we missed! Energy Six Ways IoT Enables Innovation in the Energy Industry (IT World Canada) The energy industry is learning to use IoT to its advantage. IT World Canada details six ways IoT is enabling innovation and improving overall cost and efficiency for the industry. Yogi Schulz with IT World Canada believes that “Applying these IoT advances to a range of energy industry problems will be a major factor in helping the industry return to profitability in the new, lower commodity price environment through innovation based on better data.” Manufacturing Machine Learning (The Economist) As manufacturing becomes digitized, the industry has to adjust from being a product-focused world to a services market, with smart machines installed on the shop floor. The Economist believes that “For many manufacturers—in Germany and beyond—the principal sticking-point in making this digital leap is often cultural.” Manufacturing’s Digital Future (Industry Week) The digital future of manufacturing will incorporate the data analytics, cloud and many other wireless IoT solutions. Industry Week believes “many companies are leveraging interconnectivity to improve their own factory productivity, the factory-floor blocking and tackling of reducing downtime, cutting costs, reducing cycle time, improving OEE, etc.” Oil and Gas In the Digital Oilfield, “No Wires is a No-Brainer (World Oil) With the digital progression of our world, it seems only fitting we would find IoT in the oilfield. The question we must ask is: “Why, in 2015, has wireless I/O not overtaken hardwired infrastructure as the industry standard throughout the OFS sector?” Big Data Internet of Things Transforming Oil and Gas Operations (RigZone) Analytical movement has increased as the cost of oil continues to drop, therefore forcing the oil industry to gravitate toward more big data and IoT. It has been said, “the amount of data generated by oil and gas operations is starting to explode as real-time information from sensors is being collected at a rate of four milliseconds.” Wireless Tech Darpa’s RadioMap Detects RF Spectrum Congestion (GCN) An interconnected connected wireless world has created congested airways, thus making military communication and intelligence gathering requiring radio frequencies be managed. “RadioMap adds value to existing radios, jammers and other RF electronic equipment used by our military forces in the field,” said John Chapin, DARPA program manager. Big Data The Ethics of Big Data (Tech.Co) Big data has been defined as information that has been either unstructured or multi-structured as way to transform data into value. Once you have given value to the data, it is important to realize who owns the data. Tech.CO says that “when it comes to big data ethics, privacy is not necessarily dead, shared information can still have a reasonable degree of confidentially, but big data can still compromise identity and other information that customers and businesses prefer to be confidential.” Security IoT Security Needs to Stop Being an Afterthought (PCR) In the age of smart homes and smart devices it is time to improve the IoT security across the board. The Internet Society (ISOC) recently released a white paper stating, “the vendors who use IoT should take more responsibility for the security issues that can occur with IoT products.” Drones Robo-Bulldozers Guided By Drones Are Helping Ease Japan’s Labor Shortage (The Verge) Komatsu had to find a way to complete construction projects, as Japan gets closer to the 2020 Olympics. The aging population makes it hard to find anyone able to complete the work. The fix Komatsu has found is to offer a service called Smart Construction where, “a team of robotic vehicles scoops rock and pushes dirt without a human behind the wheel. They are guided in their work by a fleet of drones, which map the area in three dimensions and update the data in real time to track how the massive volumes of soil and cement are moving around the site.” Deforestation: British Firm Developing Tree-Planting Drone to Counter Industrial-Scale Logging (The Independent) A British engineering company is hoping to get international backing for an automated tree planting drone system. The purpose of these drone planting fleet’s, would be not
Today’s IIoT Security Challenges
For decades, Supervisory Control and Data Acquisition (SCADA) systems have played a significant role in industrial operations. Industries like oil and gas, electric power/smart grid, agriculture and utilities have implemented SCADA systems and networks to collect data and automate processes, and are always looking to automation systems for more effective ways to operate. The ability to collect more data from geographically dispersed field assets in remote locations has driven the need for enhanced communication technologies. With the emergence of continuously improving wireless machine-to-machine (M2M) technologies, networks have more access to data points than ever before. The number of sensors and data points collected will continue to rise dramatically with improved connectivity. This collected data helps operators improve operational decisions, save manpower and, in many instances, keep employees safe by avoiding dangerous environments. Today, industrial network operators are increasingly implementing end-to-end Internet Protocol (IP) connectivity or the Internet of Things (IoT), enabling more capabilities at the edge of these networks. This does not make SCADA systems obsolete by any means; it opens the door to greater possibilities of enabling new applications and analytics with every single data point being captured in the system. So What’s the Security Tradeoff? There are many implications for the concept of a completely connected enterprise in terms of network security. Critical infrastructure projects are only as reliable and secure as the technology serving them. Security, therefore, will ultimately be the limiting factor on how much IoT technology is deployed. With security, the traditional trade-off is either “easy to use” or “secure”— but not both. We often consider a third tradeoff as well of features, though in most cases, operators are not willing to trade off features, but it is certainly part of the equation. An operator striving for an Industrial IoT (IIoT) network must look at SCADA security, the convergence of Operations Technology (OT) and Information Technology (IT), and make a thorough assessment of what will allow them to achieve a secure data communications network. Some of the top security challenges for the IIoT today include: With more data being transported than ever before, it’s important not only to secure assets, but to secure the communication link itself. Traditionally, SCADA systems have been on the outside of a firewall from the corporate IT network. Newer SCADA systems that use Ethernet devices are more security focused with measures such as VPN, secure sockets, encryption and dedicated log-ins on the devices. One Final Thought There are many benefits to the concept of a completely connected IoT system, but this also implies more crossover between IT and OT systems. Companies need to prioritize security in their quest to create end points for all of their field assets. Some industries, like the smart grid, are already experiencing mandates that ensure a more cyber-secure network. With others, however, it is still up to the organization to make security a top priority.