Robotics on the Battlefield
We’ve all seen those futuristic Sci-Fi movies where man and machine fight alongside each other in the throes of battle. While that might have seemed far fetched years ago, the reality is that robotics are increasingly becoming a part of our military today. In fact, the Pentagon recently requested prototypes of combined human-robot squads. As the robotics industry becomes increasingly important to military officials, technology providers are working hard to develop solutions that will support increasingly automated military efforts. A recent report estimates that robotics in the military will grow at a CAGR of 9.5 percent between now and 2023. According to the same report, robotics will be most used by the military in Europe during this time frame, followed by North America. The U.S. military continues to test out the possibilities for leveraging robots to protect soldiers, increase visibility in combat situations and generally streamline operations. Not only are these robotic applications groundbreaking — but they’re also really cool. News stories on new robotic technology boast of robotic ships, heavily armed unmanned ground vehicles, and robotic tanks – with more innovative technology coming out all the time. For example, there is a robotic insect called the “RoboBee” which was created for crop pollination and disaster relief efforts, but could also potentially lead to robotic insects used for military purposes as the true “fly on the wall” concept — equipped with audio and visual capabilities. There are also recent reports around the push for robots designed to carry wounded soldiers out of battle instead of forcing medics to enter live combat zones. These robotics may also support troops behind enemy lines in a variety of other ways to prevent risking more lives, such as dropping medical supplies to soldiers in dangerous areas. Future technologies may have the power to deliver specific medicine and even blood to wounded soldiers. While there are robotic models being tested and deployed around the world, perhaps the most uncertainty lies in the data. A Data Disaster? As recently reported in Popular Mechanics, the robotics of tomorrow may be facing a serious data problem. The article notes that for one, robots are both consumers and creators of data. Technology needs to be able to sustain the sheer amount of data required for robotic operations. The article also highlights the importance of collecting and using the right data instead of ALL the data. The good news — thanks to the Industrial Internet of Things (IIoT) — is that modern technology is becoming more favorable for managing data and it will further be supported by secure command and control (C2) links. Wireless data communications solutions are available that enable reliable C2 links have been trusted by the government and defense industry for decades. Not only are they proven in combat, but they are applicable for today’s complex data-centric systems, including robotics. With appropriate security measures and encryption capabilities in place, C2 links can be better protected to thwart malicious attacks on these automated systems – a critical function when the C2 links enable operations of the device. Further, when frequency-hopping techniques are used there is an additional layer of security, as these types of devices leverage coordinated, rapid changes in radio frequencies that naturally avoid interference. When FHSS technologies are combined with FIPS and AES security standards, as well as multiple user-defined cryptography keys (up to 32), they are equipped with a highly robust link that is well suited for military and combat operations. While robotics brings concerns to the data conversation, technology providers are working to keep up with modern data needs. With a secure C2 link, technology is further hardened for combat applications. It will be interesting to see the developments in robotics for the military in the next couple of years. What are some of the most interesting robotics applications you’ve seen?
Utilities & IIoT: The ‘Perfect Storm’ Meets the Revolution
In early 2017, John Kennedy at SiliconRepublic declared the Industrial Internet of Things (IIoT) the ‘perfect storm’ – a convergence of technologies with the capacity to create new economic benefits based on operational efficiency. On these blog pages, we’ve covered many different facets of industries adopting intelligent communication technologies likes sensors, programmable radios, and powerful analytics tools, but one industry in particular seems poised for the greatest upheaval: utilities. Many industry experts are pointing at utility markets as poised for revolution. So, what happens when the ‘perfect storm’ meets the revolution? Critical Infrastructure Transformation Given the way the human population is dispersed in the United States (and abroad), cities play a huge role in driving the growth of IIoT technologies in utilities. Water and wastewater treatment plants are perhaps one of the most important (and overlooked) pieces to modern infrastructure. Without these plants, after 1-2 uses, most of the water in North America would be unusable. Instead, companies are using sensors and other connected monitoring devices to create smart data that informs decision making, eliminates variables, and improves effective responsiveness. Similarly, the electric grid has seen significant transformation as well. In the era of the smart grid, we now have the ability to monitor grid activity more closely, deploy electricity more efficiently based on usage spikes, and allow consumers to track their own energy usage. The residual effect of this tracking is, perhaps, an increased awareness of how we use energy on a daily basis and could lead to better individual conservation efforts. Alternative Energy On The Rise And speaking of conservation efforts, with the ability to use energy more efficiently, alternative energy has exploded as viable alternatives to our traditional resources. Wind power has grown into a consistent source of energy, but for years, operators needed a better way to monitor the energy systems. Today, IIoT technology not only allows better monitoring, but provides real-time management capabilities for operators. The name of the game is efficiency, and if the operations are efficient, then the usage can be efficient as well. Business Convergence Since utility companies are now better equipped to understand when and how resources are being used or deployed, they can streamline some of the day-to-day operations by building a network of smaller solutions that are specifically designed to meet niche needs, creating more business opportunities for both traditional and alternative utility providers. Although many doomsday scenarios point to increased automation as the death of the worker, with a greater diversity of solutions, the economic impact might actually provide more jobs instead of fewer. Relying on the traditional model of the last half-century, however, does not. Ultimately, we are still looking at an industry that is right on the cusp of revolution. Utilities have, historically, been slightly slower to respond to technology overhauls at a high level, but with the added efficiency and financial benefits that accompany IIoT adoption, companies are rethinking old strategies and pushing into a new frontier – confronting the ‘perfect storm’ head-on to ensure the best possible landscape once the dust settles.
IIoT News Headlines: Trains, Agriculture, Underwater and More
Industries around the world are being transformed by the Industrial IoT. We recently shared a blog with a report that estimates IIoT will experience explosive growth and approach one trillion dollars by 2025. From trains and under water applications, to agriculture, we are already seeing IIoT expand its reach today. However, we continue to see security as one of the biggest challenges – which continues to top news headlines. Below are some of the recent IIoT stories that have caught our attention: How Siemens Is Using Big Data And IoT To Build The Internet Of Trains By: @BernardMarr | Published on: @Forbes “Siemens AG is one of the world’s largest providers of railway infrastructure, serving rail operators in over 60 countries. Through harnessing Big Data, sensors and predictive analytics they say they can now guarantee their customers close to 100% reliabilit It calls this the “Internet of Trains” – the on-rails segment of the wider ‘Internet of Things’ concept which describes how everyday objects of all shapes and sizes can now be connected together online and given the ability to communicate and capture data for analytic purposes.” Agriculture Is The No. 1 Opportunity For African Internet Of Things, Security The No. 1 Challenge By Tom Jackson | Published on: @AFKInsider “Agriculture, Africa’s largest economic sector, is likely to be central to the growth of IoT. There are many examples around the world where value can be unlocked from enhanced efficiencies along the value chain. Mining, oil and gas, telecommunications and manufacturing will have to adopt IoT to improve efficiencies.” The Internet of Underwater Things Published on: @NauticExpo_eMag “The development of an Internet of Underwater Things (IoUT), transmitting data throughout the ocean could make possible a system of roaming, autonomous vehicles and underwater sensors, all communicating with each other and relaying information to networks above the surface. This could be used for a wide range of submarine tasks, from pipeline repair and shipwreck surveys to seismic detection and ecological monitoring.” IIoT and The Cyberthreat: The Perfect Storm of Risk By: @ChrisGrove_Geek | Published on: @MBTwebsite “Many of these newfound risks did not previously exist, mostly due to the lack of interconnectivity and the network ‘air-gap’ — which has become a thing of the past. As industrial organizations race to keep up with advances in manufacturing technologies, IT is increasingly encroaching into the OT world. It’s no longer uncommon to find IT technologies like Ethernet, Wi-Fi, the Cloud and cybersecurity products like virus scanners, firewalls, Intrusion Detection/Prevention Systems and Security Information/Event Management (SIEM) products being managed outside the purview of IT.” It will be interesting to see how the IIoT continues to transform industries. What are some of the interesting use cases you are seeing as the IIoT growes? What are your biggest security concerns when it comes to IIoT?
Smart Border Protection
Plans for “The Wall” at the U.S./Mexico border appear to be driving forward. Recent reports indicate that building the border protection wall could cost upwards of $22 Billion. However, news coverage suggests that there is a more cost-effective solution in using drones to create a ‘virtual wall.’ Time will tell whether the current administration will consider replacing all or parts of the physical wall with modern drone technology to intelligently monitor rural and desolate parts of the border. In fact, some are reporting that it’s a possibility. On the other hand, several companies have already been selected to build prototypes of the border wall. Perhaps the final solution will be some combination of both, as The Department of Homeland is actively seeking border monitoring solutions in drones for Border Patrol. Drones at the Border In 2014, it was reported that Predator drones were patrolling nearly half the U.S./Mexico border. These drones were used to monitor rural areas for illegal immigrants, human traffickers and drug cartels – covering parts of the border where there are no US Customs and Border Patrol (CPB) agents, camera towers, ground sensors or fences. The Predator drones used for these purposes were designed for the battlefield, and unfortunately a report from December 2014 found that they did not achieve the intended results. Today, The Department of Homeland Security is looking to use smaller drones with facial recognition as part of its Silicon Valley Innovation Program – a program created to, “cultivate relationships with technology innovators, particularly non-traditional performers, from small start-ups to large companies, investors, incubators, and accelerators.” A contractor solicitation notice that was issued last summer (and closed on April 27, 2017) by DHS requested specific requirements for these border patrol drones. According to NBC News, the Department of Homeland Security was “flooded with bids” for these smaller drones. Here’s a small sampling of what the solicitation was requesting (see the full solicitation for the detailed list of requirements): Functional across a variety of weather conditions and times of day Ability to detect the following items of interest within required detection range: humans traveling on foot (alone and in groups), humans traveling on animals (e.g., horseback), and moving ground conveyances (e.g., All Terrain Vehicles, motorcycles, automobiles, and trucks Easy to navigate and operate Sophisticated sensors, with advanced capabilities – such as infrared and facial recognition capabilities sUAS capabilities (sUAS typically applies to smaller consumer-grade drones under 55 pounds) Hypothetical natural language voice command system While the request includes a broad range of desired capabilities, an article in The Verge suggested that, “the greatest challenge facing contractors is how to stream data from the devices, since much of the border lacks conventional cellular service.” Connecting Where Cellular Can’t From a technology standpoint, consumer-grade drones for border patrol are going to need secure, reliable and rugged command-and-control (C2) links. There are a number of secure wireless data communications solutions available that enable reliable C2 links. These solutions have been trusted by the government and defense industry for years, offering secure, reliable links with more than 60 miles Line of Site (LOS). There are C2 solutions providers that have operated in unmanned systems for millions of flight hours in some of the harshest weather conditions without a single broken communication link. Drone manufacturers also should consider these types of C2 solutions because they offer secure wireless data communication by leveraging data encryption capabilities that adhere to FIPS and AES standards. Some non-cellular solutions are also proven to be reliable and secure in nature which further boosts the overall data security scheme. Frequency-hopping techniques, for example, leverage coordinated, rapid changes in radio frequencies that “hop” in the radio spectrum, evading detection and the potential of interference. Some wireless products also deliver multiple user-defined cryptography keys (as many as 32 user-defined keys in some cases), providing a more robust link security by allowing the automatic and frequent changing of cryptographic keys. As drones are deployed more frequently for mission critical operations at our borders, it will be imperative to leverage secure C2 links that can support modern data needs in real-time while keeping the links secure. With the comfort of these powerful C2 links, Border Patrol agents can effectively monitor, assess and act upon threats in the most efficient manner possible.
Microgrids Promise Smart Industry Possibilities
The rise of microgrids, while not inevitable, is a natural next step in the progression of smart grid technology. As automation, data collection and transport, and monitoring capabilities have grown into standard smart grid technologies, companies, military bases, small towns and even cities are tapping into the possibilities for self-sustaining microgrids. What are Microgrids? Microgrids are, essentially, self-contained local energy grids. In most instances, they are attached to the greater grid (macrogrid), but can disconnect if necessary for autonomous operation. In other scenarios, they are local grids powered by alternative energy means. For instance, according to a 2014 article from Navigant Research, Alaska leads the world in microgrid deployment due to the small communities that rely almost exclusively on local energy – in some cases, 100 percent renewable energy. The viability of these kinds of energy distribution networks was not always apparent. For years, the United States has relied on a connected grid system that could be prone to huge shutdowns or security risks. As the technology has improved, microgrids that can disconnect from the macrogrid and function autonomously have opened huge possibilities for smart cities, the Industrial Internet of Things (IIoT), and more. Smart Cities Powered by Microgrids Smart cities rely strongly on the backbone of wireless technology. Imagine a scenario in which a city’s electricity grid went down, killing the wireless networks and effectively bringing any connected technology to a grinding halt. It could mean the shutdown of public transit, water and wastewater treatment facilities, electricity, vehicles, stoplights – the list can go on. Any IoT or IIoT systems would shut down. However, with a smart city set up with a microgrid concept, if a part of the macrogrid went down, microgrids could disconnect and allow normal functionality without service shutdowns. If hackers or other security concerns hit the macrogrid, microgrids can disconnect and protect the system from further threat. And, in many cases, microgrid technology is driving the rise of alternative energy and energy independence. Renewable Energy and Microgrids One of the main problems facing renewable energy has always been storage. How can renewable energy sources create excess energy and store that energy for future use in case of macrogrid failure? What cities and small towns are finding out is that by building a renewable energy system connected to a microgrid, they can effectively develop net-zero communities that don’t have to rely on energy storage in the instance of macrogrid failure. As these technologies have matured and become implemented in different use-case examples, the possibility for more intricate and complex systems is apparent. As the IIoT continues to adopt microgrid technologies and practices, industry practices will mature, creating greater efficiency both operationally and with regard to energy usage and distribution. The future of smart cities and a stronger connected infrastructure could be poised to accelerate along with the growth of microgrid applications.
Well-Pad Automation Through the CC1310 Wireless MCU
Oil companies use high-tech radios for production site automation in cool new ways. Competition in oil production can get pretty ugly, especially when the price of oil is low, as it has been for the past several years. To stay competitive against big players, smaller regional oil and gas companies are turning to well-pad automation practices to keep their costs low and their production reliable and steady. What is well-pad automation, you ask? Well, to put it simply, it’s the deployment of technology that monitors, measures and manages the production and storage of oil and gas at a well site or storage tank in real time. This technology includes sensors that measure pressure, temperature, flow, level and all sorts of other things that all need to work together in order for a well to produce, store or transport its product. Once these sensors are deployed, the next step is to add intelligence to automate certain functions that would otherwise require human intervention. Programmable logic controllers (PLCs) and remote terminal units (RTUs) are simple computing devices that automatically take action when certain conditions occur on the pad. But you thought this blog post was about fancy new high-tech radios – it is! Here’s where they come into the picture. Older radios transported sensor information from the well pad to an operations team, where they viewed the information and decided whether or not to take action. These radios generally transmitted at very low bandwidths (115Kbps-400Kbps), which severely limited the type and amount of data that could be transmitted. This limitation in many cases prevented companies from being able to take advantage of new automation technologies (like smart sensors and devices) that require more bandwidth. Today, companies like FreeWave Technology Inc. are leveraging technologies like TI’s SimpleLink™ Sub-1 GHz CC1310 wireless microcontroller (MCU) radio chipset as part of a new radio infrastructure that delivers much higher data rates. By combining the microcontroller, a highly optimized radio and an ARM® Cortex®-M3 48MHz application processor into one rugged, industrial-grade, low-power offering, well-pad automation can make a huge leap forward. These radio appliances can deliver data rates as high as 3.7Mbps over 20 miles in some cases, enabling oil producers to deploy more sensors and technologies that improve safety and operational efficiencies and reduce costs. Figure 1 below shows a picture of the FreeWave ZumLink Z9-PE IIoT Programmable Radio (IPR) with 512 MB of RAM and 1 GB of Flash. This device also runs third party and custom industrial applications. Another cool thing about these radio appliances is that they are programmable. They come with an integrated circuit board (shown in Figure 2 below) equipped with an ARM processor; 512MB of RAM; 1GB of flash storage; and a Linux kernel with support for Python, Java, If This Then That (IFTTT) and many other programming languages. Deploying advanced intelligence into the sensor networks that run their production helps oil companies eliminate additional costs, gather and store more information, and engineer new applications that improve production and safety. Tank-flow management, intelligent security surveillance, data logging and pump shut-off are just a few of the applications that oil companies can deploy in these new networks. To learn more, feel free to check out the ZumLink IPR product page. More information on other products within the SimpleLink MCU platform is also available here. *This post was originally published on TI’s E2E Community blog, which can be found here.
What’s New in IIoT
Industrial IoT (IIoT) is making waves as we inch closer to the end of the first quarter of 2017. Recently, Network World and Forbes, published articles exploring the proliferation of Smart Sensors deployed for Edge networks. We are starting to see more coverage addressing the big challenges of IIoT, as well as the big opportunities. Other, IIoT-focused publications continue to highlight the latest mega-trends and research from leaders in the IIoT trenches. Recent IIoT Headlines Four Artificial Intelligence Challenges Facing the Industrial IoT By @AAllsbrook | Published on @Forbes “Companies building IoT devices are solving this challenge by using gateways, also known as edge-based processing, to connect to cloud-based IoT platforms. This enables the machines to get data to the internet. However, connecting devices isn’t as easy as updating software; instead, it’s an investment in retrofitting old machines, replacing existing equipment, and enabling a workforce to leverage this equipment.” 5 Things to Think about for Industrial IoT Readiness By @ryan4francis | Published on @NetworkWorld “In order to achieve the full potential of the IIoT, the gap between these two cultures needs to be bridged so that the competing priorities of IT and OT are met. We’re beginning to see the emergence of “industrial technologists,” who bring a combined IT/OT perspective to the enterprise. These “industrial technologists” understand that for IIoT to be a reality, “always on” availability needs must be met. Because they live in both worlds, they play a key role in meeting both OT and IT priorities.” 3 Keys to Financial Success in the Industrial Internet of Things By @Scott_Nelson19 | Published on @CIOonline “One of the most frequent misperceptions about the IIoT is that it is all about the machines. Traditionally automation saves cost by reducing the number of people required to operate the line. The machines are important, but today operational improvement, particularly of legacy systems, comes from leveraging and facilitating human knowledge and action.” IoT Edge Shifts Data Gravity in the Enterprise By @AAllsbrook | Published on @iotagenda “But the internet of things is changing this gravitational constant in our technical universe. As IoT matures, the black holes of data gravity we have been placing into clouds will be ripped apart by millions of smaller data planets. These smaller planets will be located in our factories, warehouses, buildings, homes and everywhere else IoT runs to make data actionable.” Smart Grid: Overcoming Data Exchange to Increase Efficiency By @S_Allen_IIoT | Published on @SmartDataCo “As sensors bring connectivity to more endpoints than ever before, utility decision makers are able to obtain detailed data for Advanced Metering Infrastructure (AMI) and Distribution Automation (DA) networks. With rugged wireless solutions, the sensor data is readily available in real-time for IT decision makers. The unrestricted access to data from all network endpoints forces decision makers to shift their focus from Big Data to Smart Data – the data that matters most to the business. It also drives the need for real-time analytics in order to streamline operations. This not only simplifies the convergence issue, but it drives Smart Grid efficiency.”
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.
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.
IoT is for Automotive
The Internet of Things (IoT) has made an appearance in just about every industry (including automotive) that uses automation and has opened the door for the automation of pretty much anything and everything. Today, there are more devices than people and by 2020 there is expected to be 26 Billion – 50 Billion internet connected devices being used throughout the world. If one thing is true – and if the staggering stats above are any indication – we’re headed towards a fully connected world at a very high speed. Think about everything we can do now that wasn’t possible just a few years ago. We can lock our doors and shut off the thermostat from an app on our phone. At the push of a button, we can buy laundry detergent and have it shipped to our home. Industries with geographically dispersed and remotely located assets can cost-effectively add sensors and smart devices to every single network endpoint – to automate systems and drive intelligent business decisions locally and from afar. Racetracks are the next place IoT is surfacing, while automobiles with infotainment systems (connected by the IoT) continue to fill the streets. Autonomous Automobiles In the tech world, you’ve probably seen industry buzz and research data that verifies the reality of autonomous (or at least semi-autonomous) vehicles commonly traveling our roads in the near future. In fact, a few of the most innovative car manufacturers have already released vehicles with some autonomous features. If anything is for sure it is that the driverless car is much more than a fantasy today– there are people working to develop these vehicles right now. In the meantime, IoT has already begun to leave its mark on the automotive industry. So, what are some real life examples of unique ways that IoT communication solutions are being used in the automotive industry today? The Racing Industry The auto racing industry can automate many systems and processes for drivers and also generate data to support real-time decision making with IoT communication solutions. In one use case, IoT technology enables video data and high speed connections through a point-to-point system. With the data made available to drivers, they are able to adjust their racing strategy in real-time and make smarter decisions that decrease risk and save time. Electronic Car Testing For one electronic car manufacturer, IoT communication solutions are being used for engine testing and maintenance by using real time kinematics (RTK) base station communications to improve data and correlation. What Helps Drive the IoT for Automotive? Sensor-to-Server (S2S) communications have emerged as an essential solution for IoT networks in a variety of industries from industrial settings like oil and gas, to environmental monitoring, to the automotive industry. S2S solutions that are designed specifically for industrial-grade IoT networks, offer high speeds and extended distance connectivity via RF technology that can also support third-party applications. These solutions meet the demanding needs for collecting, protecting, transporting and controlling data from network end points all the way back to the server. As the world around us becomes more connected on a daily basis, we’ll continue to see new innovations released in many different marketplaces. In the automotive industry, IoT is leading to the inevitable release of autonomous vehicles. We can expect to see S2S communications play an increasingly important role for auto manufacturers looking to improve innovation and connect the network devices that were previously not connected.