IWCE 2016: What to expect next week?
The International Wireless Communications Expo (IWCE), is an annual event for communication technology professionals working globally in a broad range of the communications field, including energy, utilities, emergency response and municipality/infrastructure. This conference will get under way next week, from March 21-25, in Las Vegas. An estimated 7,000 individual industry experts are expected to attend from government/military; public safety (law enforcement, fire service and first responders); utility, transportation and business enterprise. IWCE will also feature around 370 exhibitors ready to show you the latest product innovations and trends forecasted this coming year. Donny Jackson editor of Urgent Communications, the official tradeshow media partner, believes that this year’s IWCE will give industry professionals a chance to get educated about the latest critical-communications technology, all while making key network contacts with industry experts. So, what else can we look forward to? IWCE promises to offer engaging content–with their 5-day comprehensive conference program; more quality time with peers; industry experts providing the latest strategies and tactics; minimal expenses–when you take advantage of conference discounts; structured networking opportunities; tangible handouts you can use throughout the year; more face-to-face learning time and more educational opportunities will be available this year. Excitement is building! Here are just a few of the people and organizations excited for next week’s event! Tune in next week for our IWCE insider recaps. Vegas here we come!
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.
Sensor-2-Server: Benefits & Security for IIoT Communications
*This is part of a series of blogs examining Sensor-2-Server (S2S) communications, development, security and implementation. For the past two weeks, we’ve taken an in-depth look at what Sensor-2-Server communications are, how to implement these systems, and some of the specific aspects of communication that these systems facilitate. This week, for our final installment, we’ll examine some of the benefits, as well as security considerations, for S2S communications. Benefits of Sensor-2-Server Communications From a technology partnership perspective, Big Data vendors face the challenge of comparing data in motion versus data at rest. If the data has already moved through a SCADA system and has been aggregated, changed, stalled, or is not quite granular enough, it can be difficult to deliver high-value predictive analytics. The concept of predictive analytics is that an operator can make an accurate estimate that certain things can happen during operations. However, the operator needs to determine what the drivers are for the predicted actions to happen and must look at active data to determine if this is, in fact, happening. Without insight into the active data in motion, they are lacking an essential piece of the predictive analytics. This ability to compare data in motion at the access layer could benefit Big Data vendors when it comes to predictive analytics because it allows them to give higher value to their customers, which drives additional revenue. With S2S technology, they can deploy a tiered application infrastructure that allows data to intelligently move from one point to another. S2S also enables operators to go beyond a legacy SCADA data network. To operate a SCADA network, it requires a lot of institutional knowledge to truly understand, manage and work within the environment. S2S expands beyond moving the data into SCADA systems and allows operators to leverage more advanced technology, like predictive analytics. Essentially, S2S communications provide the opportunity to take advantage of new advanced tools, but the operator doesn’t necessarily have to sacrifice the institutional knowledge built into the SCADA data systems. As new generations enter the workforce, it’s likely that there will be a shift and some of that institutional knowledge will be replaced with technology that will allow operators to do more than they ever could before. The addition of new technology and IoT networks is where operators are starting to see the functional lines blur between the IT and production groups. As more technology is leveraged, these two disparate groups will have to work together more often. There is now a drive for a more holistic picture of what is going on in IT, what is going on in the field, and whether the technology used will be compatible with future needs. SCADA will likely always have value for industrial communications but, going forward, there will be an increase in the use other technologies as well. Additionally, with more technology physically in the field, there is always going to be a focus on data security. Security Sensors at the access layer present interesting security challenges. For example, consider a data concentrator sitting on an oil pad that is collecting data. This device is collecting data from a number of sensors and has data logging capabilities, which also means the other devices sitting at the remote site contain historical data. Technology providers need to insure that the technology used is taking advantage of all the security features that are available to make sure their data is protected through a variety of means including encryption, authentication, virus and intrusion protection, and by being physically tamperproof. With the growing interest in IIoT, the system is providing a communication path with highly valuable information. These sensors may be running an application on the edge of the network, and many of these devices are using IP. When there are Ethernet and IP devices going out to edge devices in the field, each one of those devices has the potential to become a threat to the entire corporate network if they’re not secure. Operators in IIoT environments need to be concerned with everything that could be introduced to the network at every single connection point. Data protection data is a fundamental and extremely important element in determining the effectiveness of S2S communication. Technology vendors must be mindful of security in every step of the design and installation process, and operators must require security features that will protect their data and networks. In addition to data security, the threat to physical infrastructures in very remote locations is driving the need for new security solutions such as intelligent video surveillance designed to maximize security and minimize cost. S2S solutions need to be physically capable of delivering the bandwidth to enable these new solutions. Where Do We Go From Here? Industrial communication is changing in the sense that IIoT enables the possibility for every device in a network to be connected – including those in the outer access layer. This has created a convergence of OT and IT operations in many instances or – at the very least – has brought the two departments to a closer working capacity. IoT and technology at the access layer enable the option for Sensor-2-Server, a form of intelligent communications that can move the sensor data to a specific server for detailed analysis. New data and technology are allowing operators to do things they’ve never done before, such as predictive analytics. As this shift continues, SCADA is not becoming an obsolete technology; rather it will become a piece in the bigger technology picture. Any operator choosing S2S technology, or any technology for that matter, must carefully consider the options and keep security as a top priority.
Sensor-2-Server (S2S): Implementing IIoT Communications
*This is part of a series of blogs examining Sensor-2-Server (S2S) communications, development and implementation. Last week, in part one of our series, we worked to define Sensor-2-Server (S2S) for IIoT communications, the access layer, and high-level applications. This week, we’re looking at the actual implementation of S2S communication systems. Implementing S2S Communications When implementing S2S networks, the operator needs to have a solid understanding of the following: What sensor data do I want to collect? What does the architecture look like? Where does the data need to come from and where does it need to go? For example, is it just going to SCADA or is it going to other data sources? These key details will drive the selection of the technology that best fits, in addition to the physical environment where it needs to transmit data. Carefully selecting the right pieces will help in architecting the network. In order to make S2S work, an operator needs to understand the physical environment needs. Everything is unique when it comes to RF in particular, and an operator must fully understand their environment if they want to be successful. The ability to collect the data is the first step in improving intelligence of Sensor-2-Server communication, which starts with technology selection. Four Tenets of Sensor-2-Server To establish the most effective S2S communications network, there are four core tenets that the technology must support: collecting the data, protecting the data, transmitting the data and controlling the data. Collect – The technology must allow the operator to collect data from any sensor – whether the sensors are analog or digital, wireless or wired. In some instances, the technology may need the extended ability to collect data at the access layer in a data logging fashion – allowing the operator to collect it, store it locally and make it available to SCADA systems. Protect- The intelligent communication must be able to protect the network against cyber-attacks. It must fix the boundary between the sensor and backbone network. Without ample security in the environment, many industries can be at risk for severe consequences such as compromised data or denial of service. Transport- The data must be transported to the appropriate location for analysis, no matter where the data is collected from. Operators should look for a system that offers seamless wireless data connectivity from Sensor-2-Server. Control- The Sensor-2-Server technology must add intelligenceto the access layer. Data logging is critical, and operators must have the capability to pull data in and control what happens with the data and where that data is stored. Users can leverage that data at the local level or back at the core network. S2S technology can be effectively deployed in the energy sector, whether it is oil and gas, electric power, solar, wind and or tide- based energy. Additionally, utilities, precision agriculture and irrigation can also benefit from intelligent S2S communication. With an intelligent communication system, operators can leverage new technology to improve the profitability of their businesses in ways previously considered impossible. For example, if an oil and gas company can use predictive analytics to estimate the price per barrel, the company can be more responsive – in real time – on its oil production levels. The data gathered from predictive analytics can help operators determine if production should be increased or decreased in certain areas, thus driving higher profitability. These technologies can also lead to cost reduction. For example, by deploying S2S technology at the oil well, the operator does not have to send as many workers out in the field to manually collect data. By enabling multiple benefits (profitability and cost reduction), S2S offers a value proposition that is getting the attention of many industrial operators. Next Week Next week, we’ll look at the benefits of intelligent Sensor-2-Server communications, as well as some of the important security considerations.
IIoT Top News: Utilities Powering Tomorrow
We’re fresh off a great week at DistribuTECH 2016 where we saw a gamut of technologies, thought leaders and trends. With utilities and energy still top-of-mind, our focus this week is on the changing face of the industry. This digital age means we have come to expect that the power will always charge, operate and run our numerous IoT devices. That’s why this week’s IIoT top news is dedicated to powering our electrical future. So, it should come as no surprise that, the electric power industry has made it their mission to protect and secure this precious power at all costs. The power initiative has teamed up with federal agencies, National Institute of Standards and Technology, and the North American Electric Reliability Corporation to continue to build its capabilities. Now as you hold tight to your digital devices, take a breath, relax, and enjoy this week’s top news roundup. Industry Pioneer: The Road to Electric Utility of the Future is Paved With Prosumer Technology (Forbes) Years later, after the initial big push for IoT with utilities, we are still hoping for better, cheaper and smarter utility solutions. Forbes suggests the future of utilities will be paved in prosumer technology. William Pentland writes, “In 2009, the U.S. government made the single largest investment ever in modernizing the U.S. power system. Nearly seven years and more than five billion in federal tax dollars later, the electric grid is technically a lot smarter than it used to be. So why do utility rates seem to be getting more – not less – stupid?” Utilities to Lead Surge of Electric-Car Charging in Southern California (Green Car Reports) Southern California now has the lead on electric-car charging stations as utility companies in the area task themselves with an aggressive plan to expand the number of station in the region. A recent report from Navigant Research suggests that, “The commencement of these projects marks a major transition for electric-car charging in California, as it marks the beginning of significant involvement from utilities.” Michigan Utilities Expected to Surpass Renewables Mandate (North American Wind Power) Each year the state of Michigan sets a level of renewable energy that must be met, only this year the Michigan Utilities is expected to surpass that mandate with a surprising amount of growth. According to the six-annual report from the Michigan Public Service Commission (MPSC), “There has been significant growth of wind generation in Michigan’s renewable energy certificate portfolio, from 7 percent in 2009 to 44 percent in 2014.” NRG Proved How Tough It Is To Change. So Who’s Poised to Become the Utility of the Future? (BreakingEnergy.com) A short time ago NRG set its sights on becoming the Google of the energy world, but as the IoT evolves it is very likely an unknown company will be the next market leader for energy worldwide. GreenTech Media argues that “the utility of the future will also have to be so much more to succeed — leveraging data, new technologies and personalization to transform the way customers consume and deliver power.” What Are Utilities Thinking Today About the Importance of Engaging with Their Customers? (Intelligent Utility) As world continues to become all things IoT, utilities need to consider how engaged they would like to be with their customers. ONZO survey results at DistribuTECH 2016 show, “Most utilities also plan to increase their investment in improving customer engagements and think that analytics are key to their ability to do so.”
Sensor-2-Server: Intelligent Communication at the Access Layer
*This is the first in a series of blogs examining Sensor-2-Server communications, development and implementation. Throughout history, industrial revolutions have hinged on the power of automating processes. While automation today offers many benefits, imagine if you could automate thousands – or even millions – of processes simultaneously? This is the next potential wave of innovation, and it’s the organizations that are “geographically dispersed” or “automation heavy” that will benefit the most. While long-range communications and connectivity have become increasingly easier to attain, businesses need to be able to break down their isolated islands of automation in industry to achieve comprehensive and connected automation at scale. For example, there always has been a clear line dividing operations technology (OT) and information technology (IT) networks. The emergence of the Internet of Things (IoT) blurs that line as industrial operations head in the direction of complete connectivity for all devices on a network – including those remotely located in the field. With new dedicated access layer platforms, IoT data can be analyzed, acted upon and transmitted from anywhere in an Industrial IoT (IIoT) network. The increasing shift toward Industrial Internet of Things (IIoT) tends to bring up a lot of questions about the continued value of Supervisory Control and Data Acquisition (SCADA) systems that have traditionally served as the driver for monitoring and control in industrial markets. Although OT and IT are beginning to converge, there is still high demand for SCADA data. However, new technology offers the opportunity for data to be used in ways that were previously not possible, such as predictive analytics. This doesn’t make SCADA obsolete, as many operators are using it and will continue to employ it. Going forward, industries will leverage new technologies designed to help them make better business decisions than with SCADA alone. Sensor-2-Server™ (S2S™) intelligent communications for the access layer can collect and transport the data that supports higher-level analytics. As IoT becomes adopted by industrial markets, there is going to be an increased demand for video, voice, data and sensor data communication from the outermost layer of the network (think sensors on oil pads or water tanks). Industries like oil and gas, electric power, agriculture and utilities are starting to pick up on the benefits of S2S when it comes to profitability and cost savings through more advanced data analytics. Defining Sensor-2-Server S2S is intelligent communication that begins at the sensor level and targets servers for specific reasons. These servers could include anything from a SCADA data server that collects and monitors through the SCADA system or a Big Data engine. S2S could be leveraged in a predictive analytics engine that compares data at rest stored in a database to data in motion in real time from the access layer of the network. The concept of S2S extends beyond transmitting data. It is about creating intelligent transmission from a specific location back to the appropriate server with the appropriate intelligence to drive action for change. What is the Access Layer? The access layer is the edge of the IT network. An IT infrastructure has a core that is home to all the Big Data and data analytics. At this core, the data is “at rest” because it has reached its final destination. Next is the distribution layer of the IT infrastructure which is where the major plants, sites and facilities are located. Further out is the aggregate layer where data at the next level in the network is collected. Extending out even further is the access layer. The access layer is the layer at the far edge of the IT network. In oil and gas, for example, oil pads would be part of the access layer because they are typically remotely located at the edge of the network. It is highly likely that sensors physically exist in this layer for monitoring and control of these devices. Additional examples of the access layer are tanks, refinery sites and ocean exploration vessels. In water/wastewater, the access layer could be the treatment facility that has the water meters, pumps, smart meters, etc. Essentially, in an industrial site, the S2S access layer is the furthest point at which the operators are collecting sensor data. Industrial organizations today need intelligent secure communication and transmission from the sensor data back to the appropriate server, and there are a number of available options. What’s Next? Next week, we’ll continue our Sensor-2-Server series with a look at implementation and some of the core tenets of communication system development.
DistribuTECH Day 3 Recap: Utilities-as-a-Service?
We’ve wrapped up another year at DistribuTECH, and we’re leaving Orlando feeling invigorated and excited about the industry
DistribuTECH 2016 Day 2 Recap: Renewables Rule
After the initial excitement the opening keynote, everyone spent time checking out innovations from around the industry.
DistribuTECH 2016 Day 1 Recap: People, Places and Things
Each year, we attend a wide variety of trade shows for many different vertical industries. These shows present several opportunities: we get to go talk about ourselves a little bit, we get to see what other companies and thought leaders are doing, and we get to talk with some very interesting folks who have varying perspectives on the industry, the trends and the technologies that drive growth. This year, at DistribuTECH 2016 in Orlando, Fla., we wanted to jot down some brief, daily thoughts on some of the things that we saw both around our booth and at the show in general. Record number of attendees! We were pretty excited to hear that there were a record number of attendees at this year’s show. It’s an exciting time to be a part of the utilities and energy industries. Lots of changes, some really great and innovative new technology, and a bevy of thoughtful people makes for a good trade show! Wearables?! Where are we, CES? No! Wearables are not just for the consumer-driven recreational technology market. Wearable technology has the chance to change the way our boots on the ground and in the field work. The adage about working ‘smarter, not harder’ certainly applies to some of the companies developing wearable technology for the industrial sector. Great speakers abound! With a huge portion of the journalism industry in shambles, publications like PowerGrid International (one of several from PennWell) really stand out for its consistently solid and informative material. It’s always great to see the ‘Ink-Stained Wretches’ get their due, and Teresa Hansen, editor in chief of PowerGrid International and Electric Light & Power, gave an excellent keynote on the first day. Hey, look at us! It’s always a little uncomfortable talking about yourself, but we are incredibly excited about the future at FreeWave, and many of the people we talked with who came through our booth – attendees, media, analysts, customers, etc. – were excited as well, namely about our new WavePro WP201 wireless shorthaul Wi-Fi solution. There are some features that we’re especially proud of, including the high-speed Voice, Video, Data and Sensor Data (VVDS) transmission capabilities, the self-healing one-mile industrial Wi-Fi hotspot and the ability to achieve maximum throughput. We’re excited for day 2 – keep an eye out for us!
IIoT Top News: The Future of Utilities
As utility companies continue to track usage, consumers are growing equally cognizant of individual energy use as well, especially with the growth of private alternative energy practices such as home solar panels or wind power. That’s why this week’s IIoT top news is focused on the utility technology of tomorrow. This practice of selling privately generated energy back to the smart grid is in its infancy, but consumers now expect device connectivity to track, say, the amount of energy used by lights or the refrigerator during nighttime, off-peak hours. Because of that, the onus lies on utility companies to gather data and deploy advanced analytics that can be translated into relevant information for the average user. Now, February may have started out cold for some of us, but it is about to heat up down south with the Distributech conference in Orlando, Fla. This annual utility conference attracts over 11,773 attendees from 67 countries with 400 utilities, 480 plus exhibitors, 81 conference sessions and over 350 speakers. In lieu of this conference next week, we have decided to focus this week’s IIoT top news round-up on utility technology. Hope you enjoy this week’s round-up, and as always tell us what we missed! 2016 Power and Utilities Industry Outlook (WSJ) In the 2016 industry outlook for the power and utilities, it is clear automation and optimization will sprout more technologies for the industry advancement. John McCue, the U.S. Energy & Resources leader at Deloitte LLP believes that “Exponential technologies are accelerating the transformation of the power and utilities industry. Sector companies can respond by being open to change, assessing the potential benefits, and considering where and how to apply these emerging technologies.” Ten Energy Efficiency Predictions (Energy Digital) This list of top ten energy efficiency predictions has been gathered together by a team of experts to clearly forecast the future of energy and utilities. Energy Digital reports, “Digital marketing and marketing technology means utilities can do more with less and deliver tailored messaging based on the their consumer’s past experience with them, specifically past engagement with energy efficiency.” Tech Trends That Will Impact the Utility Sectore in 2016 (Huffington Post) The tech trends impacting utility in 2016, will be based on reliability and proven technology that will move them into the next era without missing a beat. Seyi Fabode with Asha Labs thinks that the utility industry is unmatched in it’s reticence “in adopting innovative technology. Despite its reluctance, the industry inevitably adopts the technology it resists.” As Water Utilities Move Online, Hackers Take Note (Governing.com) A recent report by the Department of Homeland Security indicates hackers are moving into the digital water utilities world. Tod Newcombe with Governing states, “Water utilities have in recent years — like pretty much everything else — become more reliant on the Internet to operate its networks of pipes and pumps.” Driving Battery Storage IoT, Electric Transportation Mainstream (Green Biz) The forecast of the next five years shows and increase in the use of the Internet of Things (IoT), which in turn is driving more battery storage for electric transportation in the energy industry. According to Barbara Grady with Green Biz, “Battery storage is changing the utility sphere by enabling solar plus battery systems to replace grid supplied power on residential and commercial buildings and by enabling micro-grids as a substitute to grid connection.”