2017 Analyst Predictions – Industrial IoT
Predictions can be enlightening as we round out the end of the year, and industry analysts covering the Industrial Internet of Things (IIoT) have begun forecasting what to expect in 2017. In the ever changing digital business landscape, companies need to keep a pulse on the technology and regulatory environments to have direction on where to focus their efforts. Over the past few years, IIoT has taken on the shared title of industry 4.0, as new ways of connecting businesses and consumers impact systems infrastructures and technology integrations across many, if not all. business lines. In honor of reigning in 2017 as a strong year for the industrial internet, we have dedicated this week’s round up to highlight some of the top IIoT analyst predictions in the coming year. Gartner Predictions: Surviving the Storm Winds of Digital Disruption By Daryl C. Plummer, Martin Reynolds, Charles S. Golvin, Allie Young, Patrick J. Sullivan, Alfonso Velosa, Benoit J. Lheureux, Andrew Frank, Gavin Tay, Manjunath Bhat, Peter Middleton, Joseph Unsworth, @rayval, @DavidFurl, Werner Goertz, @JCribbs_Gartner, Mark A. Beyer, @Alex42Linden, @noahelkin, @nheudecker, Tom Austin, @mc_angela, Fabio Chesini, Hung LeHong | Published on @Gartner_inc “Digital business innovation creates disruptive effects that have a wide-ranging impact on people and technology. However, secondary ripple effects will often prove to be more disruptive than the original disruption. Digital strategists must actively identify secondary effects when planning change.” Gartner Also Suggests That its Time to, Harness IoT Innovation to Generate Business Value By @chetster | Published on @Gartner_inc “The Internet of Things is moving beyond concepts and trials, and has begun to deliver business benefits across a range of industries. Studying innovation and how early use cases have fared will help CIOs and IT leaders capture business value.” Forrester Predictions 2017: Cybersecurity Risks Intensify By @AmyDeMartine, Jeff Pollard, @infosec_jb, @acser, @heidishey, Christopher McClean, @jz415, @merrittmaxim, @sbalaouras, Trevor Lyness, Peggy Dostie | Published on @forrester “The connected world has arrived; we live and work in it. In this new reality, the next 12 months will see battles rage that will determine the amount of control individuals have over their own data and right to privacy as well as the offensive and defensive responsibilities of our governments. This report guides security and risk (S&R) pros through five predictions for 2017 that highlight escalating ramifications of poor security hygiene and how to mitigate potential damage.” Ovum 2017 Trends: Radio Access Networks By @sonixag | Published on @OvumICT “This is part of Ovum’s 2017 Trends to Watch series. This report looks at what Ovum believes will be the major trends next year when it comes to the radio access network (RAN) market.The RAN market remains a challenging area and the need for spectrum remains a constant concern. RAN vendors are looking for new growth areas, and everybody wants 5G and they want it now. All of these factors are driving market trends.” IDC 2017 Forecast: Manufacturing Worldwide By @kimknickle, Simon Ellis, @hashtonIDC, Christopher Holmes, @jeffhojlo, @ivanoortis, @VeronesiLor, Jing Bing Zhang | Published on @IDC “This IDC study provides manufacturers with the top 10 predictions and underlying drivers that we expect to impact manufacturers’ IT investments in 2017 and beyond. Technology leaders and their counterparts in the line-of-business (LOB) operations can use this document to guide their IT strategic planning efforts. According to Kimberly Knickle, research vice president, IT Priorities and Strategies, IDC Manufacturing Insights, “Technology continues to reshape the relationship between business and IT for innovation and digital transformation. Manufacturers want to work smarter using digital technologies in their products and processes and throughout the value chain. Our predictions create a framework for IT and line-of-business executives to plan and execute technology-related initiatives in the year ahead.” As we conclude our highlights this week, we should realize these predictions are just the tip of the digital iceberg anticipated for 2017. The future could see more intelligent technologies communicating in industry 4.0 with machines processing more data. We could also expect to finally dig deeper into our IoT connected understanding. All we can do is hold tight as the next corner of digital transformation unfolds.
Connected Traffic Management Systems
Connected traffic systems are the next push in our growing digital world. There is a massive opportunity to leverage modern technology for a variety of traffic applications. The rise of the Internet of Things (IoT) has led to advancements within many municipalities to optimize public transit, traffic management and public safety. As a result, cities around the country are looking to technology and connected devices to reduce congestion and improve traffic flow. Connected Traffic Systems Technology U.S. Commuters spend 14.5 million hours stuck in traffic every day. The Urban Mobility Scorecard from 2015 reported that commuters generally needed to allow 48 minutes for a trip that would take 20 without traffic. The report predicted that conditions would continue to worsen if dedicated programs, policies and projects are not expanded. From a public transportation perspective, many cities are dealing with outdated infrastructure that can lead to severe delays and transportation outages. Voters in San Francisco, for example, recently approved a measure for a $3.5 billion regional bond to update its aging BART transportation system. In addition to investing in and fixing ageing infrastructure, U.S. cities also aim to become smarter and prepare for the future by leveraging technology. The U.S. Department of transportation has recently offered nearly $65 million in grants to cities around the country that are working on advanced transportation initiatives. The grants support a number of projects including traffic signal technology to reduce congestion at street lights, transit trip planning technology and applications, ride-sharing services, and more. While the cities work on the ground, there are also efforts to improve air traffic congestion. AT&T recently announced that it is partnering with the National Aeronautics and Space Administration (NASA) to develop a traffic management system for drones. Sensor-2-Server for Traffic Management Sensor-2-Server (S2S) solutions offer reliable connectivity options for municipalities looking to fix traffic flow issues and create smoother traffic management. By leveraging S2S operations, the city or municipality can enable intelligent communications at the edge of the communication network, from the sensor at the traffic light back to a specific server, enabling advanced data analytics. Cities with outdated communication infrastructures, such as a T1 phone line for traffic control systems, can easily update their network with wireless S2S solutions. S2S technologies are created to perform in extreme weather, offering a real-time monitoring solution around the clock. The cost of operations is significantly reduced with S2S solutions and they deliver the connectivity needed for modern IoT networks. Some S2S solutions are equipped with the ability to introduce custom, third-party applications at the edge, which can help reduce costs and enable new automation capabilities. As cities throughout the U.S. embrace IoT and work to become Smart Cities, traffic management is a major initiative. While cities work to improve aging infrastructure, they can help improve traffic congestion by incorporating a traffic management system that can leverage data from an S2S network to optimize traffic flow.
A Very Thankful Time of Year in IIoT
Thanksgiving is the time of year where we reflect on the accomplishments of the prior year and to be thankful for all that we have
IIoT Top News: The Future of Wireless
Where wires once ruled the day, wireless data solutions are now entrenched into the very fabric of the business. It will be interesting to see what the future of wireless technology will be able to tackle. This past week, ITU Radio Communication Assembly met to figure out that very thing. The ITU only meets every three to four years, so it is important that they covered the current and expected wireless resolutions. Topping the list was a push for 5G systems expected to become a reality by 2020. 5G will offer extremely high definition video services, real-time low-latency applications and overall expansion of IoT. Yet another key point solved by the ITU meeting is that “RA-15 recognized that the globally connected world of IoT builds on the connectivity and functionality made possible by radio communication networks and that the growing number of IoT applications may require enhanced transmission speed, device connectivity, and energy efficiency to accommodate the significant amounts of data among a plethora of devices.” As the bright future of wireless grows across the globe, it will continue to evolve and transform the way we use wireless in our daily lives. ISA reported this week that automation is essential for the next-generation of industrial wireless. Businesses need to be switching to high-speed broadband wireless in order to capitalize on the technological applications available to move those industries forward. This surge to operate wirelessly has created a crowded technological highway, with everyone wanting their message to be heard. DARPA has recognized this noise and developed a RadioMap to detect radio frequency (RF) spectrum congestion. RadioMap is able to transmit this information through the radios already deployed for various reasons. This unique program helps create plans of action by identifying times when the frequency usage is jammed or clear, thus informing them of the best times to communicate. Now that the wireless traffic has been sorted, let’s consider the possibility of wireless power solutions. According to Oil Price, wireless power is already in use in some commercial spaces, and will continue to gain more support as technology improves. Michael McDonald with Oil Price boldly predicts wireless power could be used to support the massive energy needs of the defense and healthcare industries by 2016. Unfortunately, not everyone agrees that wireless technology has been a seamless transition. ECN recently asked a handful of industry experts about the challenges they face as they integrate wireless IoT into their business. For example, Vera Jorkitulppo, a senior product manager of GE’s embedded power product line at Critical Power Business, believes, “At the other end of the radio link, there will be a multitude of diverse IoT devices developed by innovative companies with new solutions to real-world consumer or industrial problems.” Now, the next-generation of wireless technology may have its challenges, but, overall, the future looks bright, so put on some shades and enjoy this evolution. Hope you enjoy this week’s reading. As always, tell us what we missed! The Future of Wireless Communication (MyBroadband) Last week, the ITU Radio Communication Assembly met to set the future direction of wireless communication. At this year’s assembly, Hans Groenendaal from mybroadband reported back that they had “reached significant decisions that will influence the future development of radio communications worldwide in an increasingly wireless environment.” Industrial Wireless Evolution (ISA) Establishing the next generation of industrial wireless classification, system requirements, I/O and network capabilities for the industry. Soliman Al-Walaie writes, “Wireless technology is an essential business enabler for the automation world.” What Wireless Networking Challenges Do You Foresee with the Onset of IoT? (ECN Mag) Jamie Wisniewski asked an assortment of experts what they see as possible wireless network problems with the integration of IoT. Greg Fyke, a marketing director of IoT wireless products at Silicon Labs, suggests that “There are three key wireless networking challenges for successful Industrial Internet of Things (IIoT) implementation, including reliable communication, security and control.” Darpa’s RadioMap Detects RF Spectrum Congestion (GCN) An interconnected connected wireless world has created congested airways, thus making the management of military communication and intelligence gathering radio frequencies of critical importance. “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. Will 2016 Be the Year of Wireless Energy? (Oil Price) Oil Price looks at the possibility of wireless energy being able to support defense, healthcare and other massive energy needs in the near future, maybe even by 2016. Michael McDonald’s research shows that, “Wireless power has been a dream of mankind’s for decades, but the technology finally appears to be gaining some traction.”
Ships that Sail Themselves
Is it time for ships to sail off on a journey by themselves? As the Internet of Things (IoT) connects the world, while the robotics industry continues to innovate, man and machine are merging together like never before. Unmanned aerial vehicles (UAVs) have impacted a number of industries from agriculture to security. If recent news is correct, it won’t be long before autonomous cars are traveling roads alongside us. Now, organizations and government agencies around the world are actively working to bring autonomous vessels to our oceans. What can we expect from unmanned ships operating in our largest bodies of water? IoT and robotics are being considered for a variety of commercial and military purposes at sea. For most of the world, it seems autonomous ships are in the testing phase, but there are big plans in the works around the globe: The British engine maker Rolls Royce Holdings, PLC is leading the Advanced Autonomous Waterborne Applications initiative with several other organizations and universities. The company is eyeing a timeline of remotely controlled ships setting sail by 2030 with completely autonomous ships in service by 2035. The timeline will be heavily dependent upon automation technologies’ ability to carry large amount of data from ship to shore to ensure safe operations. Recently, the UK’s Automated Ships Ltd and Norway’s Kongsberg Maritime, unveiled plans for a light-duty ship for surveying, delivering cargo to offshore installations and launching and recovering smaller remote-controlled and autonomous vehicles. “This ship is considered the world’s first unmanned ship for offshore operations and is being eyed for many uses including offshore energy, fish farming and scientific industries.” In the U.S., the Navy has begun to consider autonomous ships for a number of applications, but is cautiously approaching these new technology advancements. According to National Defense Magazine, “The Navy for now appears to be in no hurry to pour big money into drone ships and submarines. And there is little tolerance these days for risky gambles on technologies.” However, the article acknowledges that robots at sea could help do the jobs that are dangerous or costly for human operators, such as hunting enemy submarines, detonating sea mines, medical evacuations and ship repairs. The European Union (EU) appears to have a vested interest in sea robotics. As infrastructure costs rise for improving rails and roads, they have begun to seek alternative ways to move large quantities of cargo. According to Maritime Executive they have, “had a long-term goal of making short sea shipping more competitive with road and rail transport, which is under stress from the transportation bottlenecks caused by increasing volumes of internal trade.” As the EU faces massive infrastructure costs to upgrade road and rail, there is increased attention and effort directed at the “motorways of the sea.” The Defense Advanced Research Projects Agency (DARPA) has been testing a robotic ship called the “Continuous Trail Unmanned Vessel,” and has been running sea trials on its radar system. The radar is fastened to a parasail that enables heights of 500-1,500 feet. These are just a few of the autonomous vessel projects in the works. In order for unmanned vessels to operate, it is clear the ability to transport data in massive amounts will play a critical role in the success and safety of those sharing the sea with autonomous ships. As technologies evolve to meet these big data needs, we can eventually expect to see more unmanned vessels in the sea, improving offshore applications, making human jobs safer, and creating new efficiencies for organizations looking to optimize international trade.
Staying Connected at the Ski Resort
Getting connected at the ski resort, sounds like a dream come true. We can all probably admit that we often have an expectation for Wi-Fi availability at most places we go – our hotels, coffee shops, restaurants, shopping centers and more. Now, Wi-Fi is popping up in the places we would have ruled out for connectivity several years ago. Places like golf courses, campgrounds, marinas and ski resorts. This is catching on quickly. It is becoming a necessity to offer Wi-Fi at ski resorts and this is largely due to the fact that modern technology can allow it. The rise The Internet of Things (IoT) has opened the door to not only connectivity everywhere, but data that allows us to make better decisions. There are apps available today that allow skiers to compare lift line times and identify their location on a trail map. While the concept of complete connectivity is quickly catching on, there are still challenges to overcome. For example, Wi-Fi signals can be limited in strength; especially in snow-packed, rugged outdoor environments at ski resorts where temperatures are consistently well below the freezing-point. Connectivity at the Ski Resort Because the majority of their operations are outdoors, ski resorts require a rugged Wi-Fi option. This is true for all outdoor Wi-Fi applications – whether it’s a campground, marina, golf course or any other outdoor-based business. Each will face challenges due to varying landscapes and weather extremes. These businesses looking to bring connectivity to customers need to find a shorthaul solution that is rugged and secure enough to remain connected in the most extreme elements. They also need to enable high-speed, high throughput application solutions. In addition bringing connectivity to ski resorts – we’ve seen increased adoption of industrial Wi-Fi networks for security programs and disaster response. For the skiing industry, this may be beneficial to avalanche and rescue teams. With the added ability to track skiers on the mountain, as well as send targeted warning or emergency alert messages across the network, resorts would have an additional tool in the arsenal to facilitate safety measures across wide areas. Having reliable Wi-Fi during emergency communications, especially high-speed Voice, Video, Data and Sensor (VVDS) data transport, can help ensure secure lines of communication during emergency or disasters. Additionally, resorts can leverage the secure network from VVDS enabled Wi-Fi to increase resort security. The Rugged Solution Solutions are available today that will help ski resorts stay connected. These types of technologies are used every day in highly industrial environments like oil and gas, water/wastewater and even by the military. They function in the most remote, volatile, exposed environments. Now, they can be used in innovative ways to bring connectivity to ski resorts. Whether a ski resort wants to offer Wi-Fi to guests so they can better access their skiing apps and GPS, or if it’s to create a secure communication link for emergencies and rescue efforts – these solutions are designed to ensure connectivity. They offer robust, secure transport of VVDS information over rugged, shorthaul communication networks for edge devices and outdoor assets. They are specifically designed for outdoor Wi-Fi connectivity that has been tested and proven in extreme weather and environmental conditions.
IoT Emerge Recap
IoT Emerge bounced on the scenes of Chicago this week. Yes, aside from the long awaited World Series win, an IoT conference was happening in this windy, action-packed town. The conference boasted two days of keynotes, technical sessions, workshops, live demonstrations, hands-on training and plenty of opportunities for networking with industry peers. The IoT Emerge mission is to continue to educate and promote cross-industry functions with a focus in Industrial IoT, smart cities and IoT engineering. Below, we’ve highlighted the best moments from the week. IoT Emerge: What have we learned? Back in 2011, research firm Gartner said the Worlds of IT and Operational Technology Are Converging. We believe IT/OT convergence is a critical concept: it promotes a single view of an enterprise’s information and employs process management tools to help ensure that every person, machine, sensor, switch, device, etc. in an organization has accurate information in the best format and at the right time. We learned optimizing the business process is vitally important. Decisions will be made in real time with higher levels of confidence because more information will be available regarding the event or condition. For example, load shed or curtailment events will be based on energy availability (IT sources) and demand throughout the distribution network (OT sources). Event management in an IT/OT converged networkwill execute as a closed loop process by targeting a feeder or substation, issuing curtailment signals to customers under that substation or feeder. This gauges real-time response and repeats as required to achieve the target reduction time. What other insights did we gain from IoT Emerge? Myths about IoT Engineering: The Industrial Internet of Things (IIoT) is not ready to support predictive analytics With commentary from Eddie Garcia @freewavetech | Published on @ElectronicDesgn “When most people think about the IIoT, they think of machine-to-machine communications (mostly supported by RF technology) that have dominated the industrial sector for years. However, the convergence of IT and OT practices have seen intelligence moved closer to the access layer than ever before. New communication platforms have improved to the point where big data transport can come directly from the sensors at the edge (OT) all the way to the servers in the back office (IT). The industrial sector is closer than it’s ever been to supporting the future of data collection, transport, and aggregation, ultimately resulting in the huge data sets necessary to support predictive analytics at the IT/OT level.” IoT Emerge and Up-Close and Personal IoT Experience By @JKerns10 | Published on @MachineDesign “As IoT applications and case studies start piling up, some companies still wonder where the Industrial Internet of Things (IIoT) fits in their production lines. There’s lots of information on the internet about the IIoT, such as how IIoT worked in one application or how much a company could save by using a specific IIoT product. While examples and case studies offer ideas on how IIoT might fit your production line, having a chance to talk to experts directly about your applications and concerns can help ease concerns.” IoT Emerge: Looking ahead to the future By @IoTEmerge | Published on @cote_se IoT Emerge a chance to shed light on the possible digital future. Smart cities and Industrial IoT top the watch list. Along with the conference buzz, conference organizer Penton Publishing also launched the IoT Institute aimed at educating the growing IoT world. Color your IoT World By @IoTEmerge Coloring is not just for the kiddos. IoT Emerge worked with local Chicago artist Rawfa to create a wall sized coloring book. Conference goers got to take a break from the IoT information overload and color to their harts content. Industry thought leaders did an excellent job representing the broad range of emerging IoT applications this year, and as we move steadily toward the close of 2016, it’s clear that we can expect some exciting and innovative technology applications in the not-too-distant future.
Is Sensor-2-Server Technology the Next Big Wave for Oceanic Monitoring?
The National Geographic Society defines oceanography as, “an interdisciplinary science integrating the fields of geology, biology, chemistry, physics, and engineering to explore the ocean.” A brief history of oceanography, laid out by the National Geographic Society, begins with the first oceanographic studies completed by the H.M.S. Challenger Expedition from 1872-1876, which was the first voyage that collected data related to the oceanic environment. The more advanced forms of oceanography did not begin until World War II when the U.S. Navy studied the oceans to gain communication advantages across the Atlantic for submarine warfare. In the 1950s and 1960s, submersibles were introduced and ultimately became the technology that revolutionized oceanographic exploration. Modern technology has enabled more in depth exploration of the ocean. It offers tools to observe the environment, study the living beings living within it, and explore the unexplored. With the increasing adoption of the Internet of Things (IoT), it is safe to say that more innovation will continue to drive oceanic research and exploration as we are able to connect more sensors and devices to the equipment that helps us learn more about the vast and expansive oceans. IoT technology allows researchers to take a scientific approach to the examination of the ocean through recorded and analyzed data. Some of the technologies already in use today include, vessels and submersibles, observing systems and sensors, communication technologies, and diving technology. Sensor-2-Server Technology for Oceanic Monitoring As IoT adoption rapidly expands, and in many ways changes the way things work – researchers continue to find new and innovative ways to explore the ocean. Some technology manufacturers are offering Sensor-2-Server solutions (S2S) for monitoring and data collection. S2S is defined as intelligent communication that begins at the sensor level and targets servers for specific reasons. The concept of S2S is about creating intelligent transmission from a specific location back to the appropriate server with the appropriate intelligence to drive action for change. For oceanographic purposes, this type of technology unlocks the opportunity to incorporate more data points than ever before. Some Sensor-2-Server solutions offer platforms to host third-party applications in addition to creating the communication links for devices. This new class of wireless IoT communication solutions is starting to be adapted for oceanographic research today. Below are some real-life applications that leverage modern Sensor-2-Server technology: Communication with an ROV on the ocean over a distance of about two miles Vessel telemetry for units that operate in a variety of changing environments from quayside to middle of ocean Remote access to GPS stations in Alaska over approximately 13 miles to optimize the quality of data transfer for ocean mapping. Connecting remote coastal radar systems measuring ocean surface currents around Coral reefs during an upcoming experiment along the very remote NW Australian Coast. S2S technology will continue to lead to new and exciting ways for researchers to uncover some of the ocean’s mysteries, understand how it works, and learn the behavior of its creatures.
Robotics & IoT Merging Together
The Internet of Things (IoT) has made its appearance in a substantial number of industries, most recently manifesting itself in the the realm of robotics. IoT technologies and standards open the door for new robotic capabilities that are powered by cloud computing, communication with other robotic systems and sensor input from the environment around them. Recent research has pointed to a new opportunity for robotics to operate beyond the scope of what was possible just a few years ago. As we look at a future of data and connectivity at every end point – from our cars, to our homes, to our businesses – it’s clear that we’ve just begun to scrape the surface of what is possible with the rapid expansion of IoT throughout the world. In a recent report, ABI research coined the, “Internet of Robotic Things (IoRT),” defining the concept, “where intelligent devices can monitor events, fuse sensor data from a variety of sources, use local and distributed ‘intelligence’ to determine a best course of action, and then act to control or manipulate objects in the physical world, and in some cases while physically moving through that world.” The research certainly backs recent claims that robotics are going to leave a significant mark on the IoT industry. Take a look at the key statistics that Forbes recently reported on Robotics: 4% of developers are building robotics apps today. 45% of developers say that Internet of Things (IoT) development is critical to their overall digital strategy. 4% of all developers are building apps in the cloud today. RF Technology in the IoRT World As the entire technology landscape changes it is more important than ever for RF technology to adapt in order to meet new industry demands. Manufacturers in the hardened, wireless communication industry have taken note and set their eyes on all things IoT by developing Sensor-to-Server (S2S) communication solutions. Some of these wireless IoT communication solutions providers are offering platforms to host third-party applications in addition to creating the communication links for devices. This is an entirely new class of wireless IoT communication solutions that has the staying power needed in the midst of technology evolution. Robotic IoT Future Some companies using wireless S2S solutions, have already begun to incorporate IoRT into their networks. Real-life use case examples of robotics for IoT networks that are in the works today include: Semi-autonomous robotic geophysical surveying platforms for detection of unexploded ordnance. With an S2S communication solution, this use case will provide real time kinematic base station GPS corrections and combined geophysical data to a mobile command and control vehicle for concurrent advanced data processing by rear support group linked by MiFi or Satellite communications. A ‘ship-to-shore’ link for an ocean going wave-powered autonomous robot. As robotics systems adapt to the new technology landscape, they will increasingly integrate with IoT networks. With these new advanced robotics capabilities, businesses will see new opportunities for automation and efficiency to further advance operations and will be able to leverage this new technology for competitive advantage.
Securing Assets with Outdoor Wi-Fi
The video surveillance market is anticipated to grow to $42B by 2019. Many industries today are using video monitoring as part of their physical security efforts to protect assets. As the Internet of Things (IoT) is increasingly adopted by more industries, careful consideration must be made when leveraging Sensor-to-Server (S2S) solutions for video-based security applications. From a technology perspective, IoT is beneficial for video security because it enables more data collection to drive intelligent business and security decisions that will better protect assets. However, with more sensors and devices connected to an IT network comes increased exposure for cyberattacks. It was inevitable that IoT would cross over into the physical security space, but the idea of security devices connected into an IoT network is concerning to many security professionals. In 2015, HP reported that up to 70 percent of IoT devices are vulnerable to cyberattacks. Any intelligent communication that is leveraged in an IoT environment must be designed with security in mind and have the ability to protect the network against cyber-attacks. Without ample security in the environment, companies risk severe consequences such as compromised data or denial of service. Outdoor Assets Protected Some outdoor shorthaul, Wi-Fi-based S2S networks are now designed to securely monitor and transmit voice, video, data and sensor (VVDS) information for asset monitoring and control. Additionally, any industry looking for an outdoor network robust enough to provide Wi-Fi connectivity may also benefit from these outdoor Wi-Fi solutions. From emergency communications to municipalities, industrial networks to golf courses or campgrounds, and more, there are numerous use cases where Wi-Fi is beneficial for connectivity and also for high-speed shorthaul communications needed to enable VVDS data. In IoT environments there are sensors on every single asset, constantly pulling data, so they need to make sure that security features are part of the technology’s design. For the operator seeking outdoor Wi-Fi to connect physical security devices and enable video monitoring, it is important to be familiar with the technology they are selecting. The Wi-Fi networks best suited for outdoor environments will have a rugged design with proven reliability in extreme environmental conditions. When the right security measures are in place, these solutions can ensure that data is protected through a variety of means including encryption, authentication, virus and intrusion protection, and by being physically tamperproof. Although robust, outdoor Wi-Fi can provide the connectivity needed for VVDS applications, but it needs to be able to withstand and prevent cyber security attacks. When the right technology is selected and enabled, asset protection can be enhanced through video. How are you protecting your assets?