Smart Grid: IoT’s Next Frontier
If smart grids across the world are headed towards an IoT frontier, what come’s next? According to a recent report, Ericsson estimated there will be 1.5 billion IoT devices adopted by the utility and energy industries as early as 2020. The rise of the smart grid seeks to tackle energy producers’ needs to direct power and resources as efficiently as possible. It’s not enough to know where all the utility lines are located, the modern digital age requires monitoring and sensors placed across all assets in the field, so that providers can relay actionable intelligence across the enterprise as quickly as possible. In the event of a power outage, for example, sensors can inform the field technicians where along the line the fault has happened, thus saving time on troubleshooting and enabling faster restoration of power to the customer base affected. An example would be Florida Power & Lighting (FPL), who is in the process of installing 20,000 smart grid devices across their state. Already these devices are saving an estimated 100,000 visits from technicians, since these smart grid devices can automatically fix small outages automatically. Computer Business Review reports that, “The world’s traditional electrical network – simple and linear, with centralized energy production and passive consumption – is undergoing a transformation to a much more complex, interconnected, and interactive model: the Smart Grid. However, for this network to become intelligent, users will require connectivity, simplicity, and security. They will also need access to a reliable and safe energy source that guarantees optimal operation of their installations, infrastructures, and equipment.” Perhaps more advanced smart grid solutions comes with a price, as many early IoT adopters are finding out. Storing, transferring and relying mission-critical commands across an IP address does expose potential cybersecurity risks as information and remote controls move from Sensor-2-Server. Experts are saying it’s not if a cyber attack will happen, but when the smart grid will be hit. Despite the need to adopt new technologies within the evolving digital landscape, utilities must establish a holistic security plan to not only address physical security measures, but also the data transmission paradigm from each individual end point on the network and back to the corporate IT office. Security through obscurity is not a solution. There are many common attack vectors for industrial devices that become even more relevant when considering that smart grid infrastructures are becoming fully networked, geographically dispersed projects.
IoT Top News: A Sensor Driven World
Much of the world around us is becoming driven by sensors, where we are able to track and map numerous possibilities with countless M2M and IoT solutions. So, we wanted to highlight some of the trending use applications of sensors today. The Army is looking at installing sensors to their combat soldiers The Army is looking for a way to better track the health and well-being of their soldiers in combat, and current health fitness sensors have too many irregular findings. Jennings Brown with Vocativ informs us that “The United States Department of Defense is interested in monitoring the health of soldiers in real-time.” Although it is interesting to see Army uses of sensors. One must ask how sensors impact the industry at large? IoT is responsible for propelling sensors further into our world. Recent findings from ABI Research show that you can’t have one without the other — meaning, as we continue to explore the numerous IoT and M2M solutions it is only natural that we also see a dramatic increase in sensors used across the board. Peter Clarke with EET Asia reports, “ABI Research reckons sensors and peripherals will be 65 percent of an installed base of 47 billion units by 2021, double the 2016 level.” The latest IoT Sensors Market Report for 2015-2023 sheds light on the global growth of sensors. An increased demand for sensors is expected to impact the industrial and automotive IoT sectors according the the recent ReportBuyer’s IoT Sensors Market research. Electronic News has shared the latest findings from the ReportBuyer’s IoT Sensors Market 2015-2023 report which states, ” There will be a number of opportunities for the global IoT sensors market. One such opportunity is the increasing development of ‘smart cities’ around the world. IoT sensors will need to be used in aspects such as smart meters, smart grids, intelligent traffic management systems and smart packing, among others.” Sensors are being used in both industrial and consumer IoT applications across the board. As technology improves, it is now easier to create higher quality sensors for a fraction of the cost, opening the doors for more industrial and consumer IoT applications. Mary Catherine O’Connor with IoT Journal believes that with the growth of IoT sensor applications, That means there is a big opportunity for systems integrators in this market. There may also be an opportunity for companies that develop their own sensor-integration capabilities. It will be fascinating to watch the market develop.” With that said, we can’t forget to realize that implementation of any IoT sensors will require a sensor-2-server plan, that will ensure the data makes it safely in real-time to the intended end-user.
Machine Hackathon: DARPA Plays Cyber Capture the Flag
A machine hackathon is about to take on a whole new meaning as Defense Advanced Research Projects Agency (DRAPA) prepares to hold it’s first ever machine-only hackathon. With a specific focus on cybersecurity, this cyber version of Capture the Flag (CTF), is DARPA’s way of combating the onset of cyber attacks in real-time. DARPA’s normal approval process is lengthy; once a potential threat is recognized and a software solution has been created, it has to be tested and approved before it can be implemented, and by the time the software fix is ready to be used across the board, another threat looms on their horizon. Some of you might be asking, “What is DARPA and who are their finalists in this cyber challenge?” Not to worry, the short video below provides some background and context. The contest is truly a battle of the minds, as hacker teams try their hand at reverse-engineering software to seek out and find weakness in the system and fix those holes while attacking other machines at the same time. Those teams that are successful in both attacking and fixing holes capture the digital flag and win points in the ongoing process. This competition will take place in conjunction with the annual DEFCON, the longest running annual hacker competition. Before we start thinking that we’re living a modernized version of “Hackers,” there are a few more things to know. First, this is really a battle of software. The final teams were given a DARPA computer to code and must create a software platform to interact with the DARPA database. Once the competition begins, the teams will not be able to intervene if their software fails to see a weakness or is attacked by another team. The goal is to create an artificial intelligence (AI) software that is capable of responding in real-time to potential threats and weakness within its databases. Wired has added this contest to their radar, saying, “DARPA has gone full Tron. It might feel more like a video game, than a hacking contest, as DARPA has arranged for a visual diagram to be displayed on the big screen, that will show each attack and from what machine the attack came from.” Whether you believe Wired or the other tech experts, this type of machine AI is hoping to turn the tables on the war on cyber safety. Instead of waiting for an attack to strike, DARPA’s intuitive software will attempt to seek out weakness autonomously giving the Defense Department the added edge it needs to prevent leaks in the system. This is another intriguing example of how machine learning is becoming integrated into so many facets of the world at-large. Whether you make your way to Las Vegas to witness the DARPA’s version of CTF or not, that fact is we continue to add more M2M and IoT solutions to our daily lives. It’s only natural we find new ways to have machines assist us.
IoT Top News: Fog Computing Influences Apps
This week BI Intelligence revealed the key benefits of fog computing along with a list of industries adapting this methodology. It is estimated that 5.6 billion IoT devices owned by enterprise and government will soon use fog computing for gathering and processing data. Let’s dive into some recent news from the past week and start by taking a closer look at the latest development in fog (edge or access layer) computing. Fog Computing in the IoT Forecasts industries and adoption benefits Edge or fog computing will become a priority as enterprise deals with the exploding amount of data waiting to be collected, sorted and processed. “The ‘Internet of Everything’ — all of the people and things connected to the internet — will generate 507.5 zettabytes (1 zettabyte = 1 trillion gigabytes) of data by 2019, according to Cisco. A deeper dive into this week’s top news show us a few IoT applications ready to change our world, from farmer robots to drones reconstructing car crashes. Robots are coming to a farm near you The cost of adding robots to agriculture still remains high, yet these IoT machines are threating to shake up the farming community around the globe. Sara Olson, Lux Research Analyst recently reported that, “However, the costs of many systems are coming down, while wages rise due to labor shortages in some areas, and the benefits robots bring in the form of increased accuracy and precision will start to pay off in coming years.” Drones expected to reconstruct car crashes The Justice Department has plans this week to start running tests gauging the ability of drones to accurately reconstruct car crashes. Jeramie Scott, director of the Electronic Privacy Information Center’s Domestic Surveillance Project suggests that, “There should be public, transparent policies spelling out specific use cases to “ensure law enforcement drones acquired for one purpose,” like crash scene reconstruction, “are not then used for secondary purposes that undermine privacy and civil liberties,” like mass surveillance of the public.” We hope you have enjoyed this week’s short round up. Next time you see a smart device at work or around town, think about all the IoT sensors, Wi-Fi, automation and smart applications that come together to bring you state of the art technology experiences, and ask yourself “what will they think of next?”
Drone World: Applying IIoT Applications
“Drone World” may seem a bit overboard, but the fact is, drones are here to stay. We’ve spent time in these pages looking at unique and innovative drone applications in industries like utilities, precision agriculture, and even lifeguarding. Today, in honor of Memorial Day, we would like to take a moment and honor those men and women serving in the armed forces, by highlighting interesting government drone technology uses. Drones ‘Shot Into The Sky’ By The U.S. Navy The BBC News informs us how these innovative instant flight drones could be used as a method of defense for ships at sea suddenly burdened by a swarm of enemy drones. This project is known as LOCUST and it aims to launch a swarm of drones at high speed. Elizabeth Quintana from the military think tank Rusi believes that, “Drones could be used to take out enemy swarms at sea.” Drones That Can Sniff Out Radiation The Nevada National Security Site (NNSS) officials have recently purchased two drones to be a view from the sky in case of an emergency to sniff out and detect signs of radiation. It will be important to use these unmanned aerial systems (UAS) in situations that are to dangerous for humans. Other Applications of Drones Drones aren’t just for the government anymore, in fact we are already starting to see the industries below finding ways to improve safety, service and efficiency with the implementation of drones. Emergency Response Enables immediate action, providing emergency response teams with fast, flexible visibility to assess critical situations. Utilities Safely allows for the quick inspection of high voltage power lines and wind turbines, helping mitigate worker risk and improve monitoring. Military & Defense Assisting with intelligent surveillance and reconnaissance missions to deliver timely, relevant, and assured information to thwart potential threats. Oil & Gas Protects and helps maintain extensive miles of pipeline covering large, remote areas that would otherwise require enormous amounts of time and resources. Agriculture Creates more efficient farms by monitoring inventory, growth, water and fertilizer levels, and crop health to facilitate production and increase yields. Public Safety Supporting firefighting operations by providing more up-to-date information at a lower cost, while reducing the number of responders in harm’s way. We hope you have enjoyed our quick drone world recap, and as always tell us what we missed. The next time you see a drone flying in the sky, think about all the possibilities that drone or fleet of drones could be providing.
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
First Responders: Saving Lives, Time and Money Through Innovation
How the Internet of Things is Changing the Landscape for First Responders and Industry According to the National Fire Protection Association, in 2013 there were 369,500 home fires causing some $6.8 billion in damages1 — plus an additional 98,000 apartment structure fires contributing an additional $1.6 billion in losses2. A frightening picture, isn’t it? The numbers are staggering — and yet innovation for emergency responders at both a local and national has not been a priority. The Internet of Things (IoT) aims to change that. Companies are now exploring how IoT technology can disrupt the way emergency responders do their jobs, saving countless lives and millions of dollars in the process. The IoT also holds immense promise for industrial applications, which often take place in remote locations where connectivity and communication platforms are rarely available. The IoT is a vast world, enabling the physical world to communicate with the digital world in new and amazing ways. But thanks to innovations fueled by companies focused on industrial, military, and government applications, we can traverse beyond a network of connected thermostats and smart TVs into an environment where first responders, industrial crews, and our military can communicate and receive critical information in real time. An example of technology that is changing the world of emergency responders as well as industries like Oil and Gas, the Military, and Utilities are ruggedized, industrial shorthaul and Wi-Fi platforms that offer secure collection, control and transport of Voice, Video, Data and Sensor information at incredible speeds. So what does this mean for the industries mentioned above? Imagine first responders being enabled to pull up building plans and architectural details as they arrive on scene. Structural notes are delivered at incredible speeds, giving the emergency responders valuable insight into stairway and fire escape placements and potential danger zones. Communication between police, fire crews and ambulance drivers is streamlined — delivered at blazing fast speeds. In other situations, police can access vehicle databases or hospital services, preserving precious minutes than can mean the difference between life and death. For industrial applications, the IoT holds promise for new levels of connectivity — enabling crews to access and consume information at a moment’s notice. This means workers can collect and transmit important data quickly and securely — even in harsh conditions. Beyond connectivity, the Internet of Things also holds massive promise for the monitoring of emergency responders and industrial crews in the field. Critical sensor data — such as oxygen levels, body and ambient temperature, heart rate and more — can be viewed in real time, giving the ability to monitor the vitals of emergency responders and workers in an instant and watch for danger signs and track bio data in the field. This data can be logged and analyzed, fueling innovation that will help keep these employees safe. The IoT is a vast and ever-growing field — and it holds incredible promise for making our cities a better and safer place to live and work. For emergency responders, where seconds saved can be lives saved, and industries where time is money, the IoT holds remarkable promise for changing the way we communicate, gather data, and work in the field. ————- Sources: 1 – http://www.nfpa.org/research/reports-and-statistics/fires-by-property-type/residential/home-fires 2 – http://www.nfpa.org/research/reports-and-statistics/fires-by-property-type/residential/apartment-structure-fires
Difference Between Data Sheet Transmit Power & Data Stream Transmit Power
Image courtesy of Flickr Creative Commons You need to link a two production sites together in your IIoT network in order to move critical voice, video, data and sensor data (VVDS™) between the sites by deploying access points. So, you consider using industrial Wi-Fi Access Points to implement this short-haul, point-to-point (PTP) RF link between the two sites. Short-haul RF links out to 8 miles are very doable using industrial Wi-Fi Access Points with directional antennas. You evaluate potential Wi-Fi Access Points from their data sheet specs. This is given, and you select one. Now, there is one specification that is commonly misunderstood and leads to confusion when evaluating MIMO capable Wi-Fi Access Points and using them in either PTP or point-to-multipoint (PMP) IIoT networks as wireless infrastructure. Confusion and mistakes arise from the difference between the transmit power stated on the product data sheet and the transmit power of a single MIMO data stream of the Access Point. For example, a 3×3 MIMO Access Point data sheet states the transmit power is 27dBm for MCS4/12/20 data encoding in either the 2.4 or 5GHz band. This is typical, and not a surprise, but what is this transmit power really stating. The FCC limits and regulates maximum transmit power from an intentional emitter, e.g. Wi-Fi Access Points. For Wi-Fi devices, the limits apply to the aggregate transmit power of the device. In above product spec example, the transmit power stated is the aggregate transmit power for the 3 MIMO data streams. Still good? Yes. You have a Wi-Fi Access Point and the total transmit power is 27dBm. Now, you design your short-haul PTP link using Wi-Fi Access Points and directional antennas. What transmit power do you use in your RF link budget? 27dBm since it is the transmit power for the Access Point for the data encoding and the band you plan to use. Right? No. While 27dBm is the total aggregate transmit power for the Access Point, it is not the transmit power of an individual data stream. The individual data stream transmit power is roughly 5dB less than the aggregate transmit power found in the data sheet for a 3×3 MIMO product. Difference in Transmit Power versus Aggregate Power 1 Data Stream transmitting at 22dBm — Aggregate Transmit Power is 22dBm 2 Data Streams transmitting at 22dBm — Aggregate Transmit Power is 25dBm 3 Data Streams transmitting at 22dBm — Aggregate Transmit Power is 27dBm So here it is… If you use the transmit power from the data sheet in your RF link calculation without correction, your actual link distance will be approximately half what you expect for the planned fade margin or the link reliability will be less than what you expect for the planned link distance. When designing RF links for the IIoT networks, make certain you are using the correct transmit power in your RF link budget calculations.
Video: What are the Future Uses of Drones?
While drones are responsible for one of the latest tech crazes to hit the mainstream, it’s safe to say that you should not expect them to invade your airspace anytime soon. However, the influx of these flying smart machines may not be as far off as you might think. With heavy-hitters like Amazon, Google and Walmart recognizing the immense opportunity of using drones for shipping and logistics purposes, its no wonder that people are saying “the drones are coming!” Industrial Applications for Drones What could prove to be more promising than the consumer-driven demand for flying drones is the use of that technology in industrial settings and applications. Already, we see companies using drones for the following scenarios: Emergency Response Enables immediate action, providing emergency response teams with fast, flexible visibility to assess critical situations. Utilities Safely allows for the quick inspection of high voltage power lines and wind turbines, helping mitigate worker risk and improve monitoring. Military & Defense Assisting with intelligent surveillance and reconnaissance missions to deliver timely, relevant, and assured information to thwart potential threats. Oil & Gas Protects and helps maintain extensive miles of pipeline covering large, remote areas that would otherwise require enormous amounts of time and resources. Agriculture Creates more efficient farms by monitoring inventory, growth, water and fertilizer levels, and crop health to facilitate production and increase yields. Public Safety Supporting firefighting operations by providing more up-to-date information at a lower cost, while reducing the number of responders in harm’s way. So what does the future hold for these next-generation technologies? It’s hard to say really. One of the biggest hurdles still to jump is figuring out how these aircrafts will fit into the Federal Aviation Administration’s (FAA) existing airspace regulations. There is no doubt there will be new policies that are drone-specific on the horizon. In fact, the FAA has already taken steps in that direction by requiring drone owners to register their aircrafts as a first step in ensuring the safety of everyone who uses the skies. Let’s just assume that over then next five years policy and technology come together and we finally have lift-off in the drone world. What’s next? Check out this video courtesy of Be Amazed that explores 10 amazing futuristic uses of drones:
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.
