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.
The Wireless Oilfield
As the Industrial IoT (IIoT) drives connectivity everywhere, wireless technology has become a mainstay in the energy landscape. Modern oil and gas companies rely on wireless communication solutions to control, monitor and transfer critical data for the most critical field operations. As technology decision makers continue to seek new ways to connect the oilfield, they are inundated with options. However, if they desire networks that will remain relevant as technology rapidly changes, they need to be focused on finding wireless solutions that can handle modern data needs. Wireless I/O solutions In the oilfield, different applications have different needs. For example, many assets are operating in hazardous environments where explosive gas is present. The technology operating in these environments needs a C1D1 certification for safe operations. The good news is that there is wireless technology designed and certified to perform in these environments. C1D1 wireless Input/output (I/O) technology can perform to the standards that ensure both safety and connectivity for the modern oilfield. When wireless I/O is incorporated into small field networks, medium plant operations and/or large SCADA systems, operators can receive wireless sensor measurements, physical control and communications between remote controllers from a single device. In the simplest of terms, wireless I/O is wire replacement, where the wireless communications link emulates wire in an existing application. No changes are required to the system architecture. Rather, wireless links are used to transmit the same data that the physical wire once carried. With a C1D1 certification, wireless I/O solutions offer a much needed hard wire replacement for extremely remote assets in hazardous environments. Wireless Oilfield Applications As more sensors are added along the wireless oilfield, there are many different applications that can be pulled into the wireless network. New C1D1 wireless I/O communication technology also is designed to provide the communication link for the IIoT network in order to achieve the level of connectivity needed for today’s IoT driven-marketplace. There are a number of applications that can be leveraged by the wireless communication network including: Separator: monitoring of flow, high level alarm, pressures and temperatures Production tanks: C1D1-cerfied measurement and high level alarm Backhaul: data collection and transport from the wellhead to SCADA system Wellhead: pressure monitoring, including – casing, tubing and surface pressures. Additional applications include, flow, plunger lift, valve actuator, and arrival sensor Control Panel: wirelessly connect PLC/RTU/Flow computer to sensors, link to IIoT, I/O expansion Flarestack: monitor flares, temperature and thermocouple Chemical injections: monitor tank level and temperatures Compressor: monitoring of pressures temperatures and monitor/control on/off statuses. These are some of the many applications that can be connected with modern wireless technology. As the oil and gas industry continues to embrace wireless technology, special attention needs to be paid to the solutions that will still be relevant years down the road. A C1D1 certified wireless radio solution that connects to the IIoT network is an ideal solution that not only supports field assets, but is designed with the future of wireless communications in mind.
FreeWave to Attend Three Industry Events This Week
FreeWave is taking on three major events across the globe this week to showcase our latest and greatest Industrial IoT Solutions, including a couple new product releases (read about them here and here). We will be attending IWCE, Internet of Things North America and IoT Asia. At IWCE and IoT Asia, we will be showcasing our latest technology in the exhibit halls. Find us at Booth #768 at IWCE and #E28 at IoT Asia. During exhibit hours, we will be offering live demos of our S2S communication solutions. We will also have company experts giving educational sessions at Internet of Things North America and IWCE. Here’s the rundown for each show: Speaking at IoT North America Sensor-2-Server: Execute Locally, Communicate Globally Wednesday, March 29 at 3:45 p.m. The idea of comparing data in motion (at the sensor level) to data at rest (in a big data server warehouse) with predictive analytics in the cloud is very appealing to many industrial customers. However, the problem is access to that data in motion at the sensor location. 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. Speaking at IWCE FAN, Smart Grid and SCADA: The Original IoT Thursday, March 30 in Room S224 from 10 a.m. – 11:15 a.m. 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, such as Field Area Networking (FAN), offers the opportunity for data to be used in ways that were previously not possible, such as predictive analytics. SCADA may not be obsolete, but examine how it and FAN fit into this new world of smart grids and smart cities. Network Management and Cybersecurity for IoT: The First Step to Smarter Cities Thursday, March 30 in Room S224 from 11:30 a.m. – 12:45 p.m. IoT management systems that are able to extend control over a wide net of dissimilar technologies and provide relevant personnel with timely actionable-intelligence are essential components to these next-generation networks. Examine the hardware and software of fully-automated management systems, able to function autonomously and “intelligently” beyond the network edge to collect, analyze and decide on the best course from a set of alternative actions. Then explore the security goals you need to have in place with the influx of IoT information and the resulting IT/ OT convergence, including who is responsible for the overall security of IoT management systems. Products Featured at IWCE Booth (#768) and IoT Asia Booth (#E28) WaveContact Family (https://www.freewave.com/wavecontact-wireless-oilfield/) – WaveContact Modular wireless systems provide rugged, simple and flexible communication solutions that are easily and quickly deployable. WaveContact products interface with a wide variety of sensors deployed in industrial and critical infrastructure markets such as oil and gas, electric power, water and wastewater and environmental monitoring. The product line is built for short-range field applications where simplicity and ease of use in Class 1 Division 1 hazardous locations are critical for success. ZumLink IIoT Programmable Radio (IPR) (https://www.freewave.com/products/zumlink-ipr-iiot-programmable-radio/) – The industry’s first wireless IIoT radio capable of supporting third party applications for Edge and Fog Computing in Industrial IoT (IIoT) communication networks. FreeWave’s IPR can support JAVA, Python, C, C+ and GO, and it connects to any IT device or sensor. The platform is capable of hosting third party and proprietary IoT applications for energy, utility, municipal, smart city, government and military use cases. ZumLink Z9-C and Z9-T (https://www.freewave.com/products/zumlink-900-series/) – Serial radio modules for OEM and Embedded wireless applications. The ZumLink Z9-C and Z9-T are ideally suited for unmanned systems and other industrial machines and solutions that require highly reliable, high-speed data communications and networking. WavePro (http://go.freewave.com/l/68372/2015-12-16/37myq8) – Designed to secure and transport Voice, Video, Data and Sensor (VVDS™) information, this cost-effective, high-speed, rugged wireless communication platform is specifically designed for outdoor industrial locations and has proven reliability in extreme environmental conditions. It’s an ideal field area network solution for oil and gas, utilities, mining, power plants, municipalities, disaster recovery or for any other applications that require remote and resilient Wi-Fi connectivity in nontraditional settings. Are you attending any of these events? Be sure to stop by the IWCE and IoT Asia booths for a demo of our latest offerings. Or, stop in for one of our educational sessions.
Busting the Myths About FHSS for Industrial IoT
IT/OT convergence has shaken the way businesses operate from a networking, connectivity and communications perspective. As IT decision makers look to find technology that will support the needs of modern digital networks, it is easy to overlook Radio Frequency (RF) solutions. Frequency Hopping Spread Spectrum (FHSS) technology is a viable option that has been around for decades. With the right solution in place, FHSS technology is reliable and robust enough to get important data from the field back to the central office. With newer, high-speed and high-throughput options, it can be ideal for helping solve modern convergence challenges. FHSS technology is well-known for its use in OT networks in industrial settings, but the IT side might not be as familiar with the technology. There are a number of myths about FHSS technology that need to be clarified in order for an IT decision maker to understand its potential. Today we’re going to bust three big myths: Myth One: FHSS Technology is Not Secure Enough for Modern IIoT Networks 900 MHz FHSS technology leverages an unlicensed spectrum which has led to the misperception that it is vulnerable to jamming and DoS attacks. The reality is that the signal is constantly hopping in the spectrum and does not stay on a single frequency for long. This one of its greatest strengths and makes it much more difficult to jam. IT decision makers who are greatly concerned with security should also know that some manufacturers offer two layers of security. The first is the natural built-in protection from the frequency hopping and the second is 128 or 256 bit AES encryption. Myth Two: Crowded Spectrums Lead to Poor Coverage Network congestion is a long-standing misperception associated with FHSS technology. Operators are often concerned that performance could be affected in an unlicensed spectrum if too many devices are trying to use it at once. However, the frequency hopping nature of the technology actually serves as a strength. The jumping allows the technology to identify the better channels, even in areas that are known for being noisy and congested. FHSS technology has been proven and trusted by the U.S. military for decades to perform in situations where lives are on the line. Myth Three: FHSS Technology is Best Suited for Industrial Environments Like Oil and Gas In oil and gas and military circles, FHSS is frequently used and widely known as a strong wireless communication option. However, the technology may not even be on the radar of an IT decision maker tasked with new responsibilities as the OT/IT divide closes. What IT decision makers need to know is that FHSS technology is also currently used in networks completely outside the scope of traditional industrial networking. Here are a handful of unique ways FHSS is currently being used: Oceanic Monitoring and mapping Auto and Boat Racing Testing for Electric Cars Plant Automation Asset Tracking in Healthcare Golf Course Communications and Golf Cart Monitoring Aquarium research A Good Fit FHSS technology fits nicely into the evolving technology landscape – especially when data needs to be transported from the access layer back to the business office. Despite the challenges that OT and IT teams face as they learn to work closer together, FHSS remains a proven, reliable option to help bridge the gap.
News Round-up: Wireless and Ethernet
As the Industrial Internet of Things (IIoT) drives the production of connected devices, wireless and Ethernet-based technologies have become an important piece of the connectivity conversation. Entire industries are making digital transformations and it’s changing the way businesses operate. There are billions of IoT devices in service and development continues to ramp up. Recently, we’ve seen several wireless and Ethernet technologies headlines in the news. Wireless and Ethernet News Is Ethernet Coming to the Network Edge? By David Greenfield | Published on @automationworld “We’ve tarBygeted a small scale, single-chip processing solution (to bring Ethernet to industrial edge devices) by reducing processor speed, memory and RAM size, reducing the interconnection complexity from processor to network interface, and reducing the pin count and complexity of the network interface,” said Weingartner. Essentially, “we’re bringing MAC into the PHY (the physical layer of the OSI model which connects a MAC to a cable), which is what Ethernet is all about. Doing this opens up possibilities not just for new implementations, but for brownfield applications as well.” Wireless Electric Cars About to Hit the Road By @robnikolewski | Published on @sdut “What’s called dynamic charging foresees a future where vehicles charge themselves as they drive. Using coils embedded in roads, EVs would refuel as they stay in transit, creating their own self-perpetuating electrical loop. It’s similar to the way some mobile devices get charged.” The Ethernet Ecosystem Today is Driven by Applications, not Speed Alone By David Chalupsky | Published on @networks_asia “For many years, Ethernet evolution was characterized by the “need for speed” as networks and data centers sought higher and higher throughput. But over time, Ethernet has found its way into applications unforeseen by the developers of the original specification, resulting in a broad and varied Ethernet ecosystem. Today the desire to bring the advantages of Ethernet into new applications necessitates a new approach where the needs of the application are considered first and foremost in defining new Ethernet incarnations.” Actualizing the Internet of Things Starts with Wireless By @robrueckert | Published on @TechCrunch “The most promising of wireless power technology seems to be radio frequency. With its apparent lack of serious problems and its unique strengths, radio frequency has the greatest long-term potential to become the market’s leading source of wireless power to fuel the Internet of Things. No significant evidence exists depicting radio frequency as posing a threat to humans. The human body consists mostly of water and radio waves do not transmit energy through water. Radio frequency is also highly configurable. Devices sending and receiving radio frequency power can easily be equipped with regulators, enabling control of how much power will be emitted and received.”
IoT Spurs Wireless and Ethernet Technology Growth
In 2017, we are more connected than ever before. From a consumer standpoint, our homes are smart – they can change temperature based on our presence or preferences; our cars act more like computers; we can monitor our nannies from our computers at work; and, we can remotely lock our doors –just to name a few. This growth in connectivity isn’t limited to the consumer realm though – it has impacted the vast majority of industrial applications as well. Our critical infrastructure is becoming more connected to conquer traffic management problems, monitor the environment and improve manufacturing. Digital technology is no longer a “nice to have” – it’s a necessity for optimal business operations and we see many industries turning to wireless solutions. Chances are that even the most remote oil pumpjack sitting 30 miles away from the nearest highway has several connected devices onsite and it is probably using wireless technology to control, monitor and connect. It seems that wireless and Ethernet technologies continue to have an important place in our increasingly connected world. The Future Looks Good for Wireless Smart Industry recently posted an article reviewing some statics provided by HMS that demonstrate the growth in wireless and Ethernet devices as the demand for connectivity continues to grow. In the article, Anders Hansson cites new big trends such as the Industrial IoT (IIoT) and Industry 4.0 as drivers behind the demand for more wireless devices. Here are some of the key statistics shared that demonstrate the demand and growth: Industrial Ethernet is growing faster than previous years with a 22 percent growth rate. Ethernet now makes up for 46 percent of the global market, compared to 38 percent last year. Wireless technologies are growing by 32 percent and now accounts for 6 percent of the total market. Fieldbuses are still the most widely used type of networks, with 48 percent of the market. Industrial Ethernet and wireless combined now account for more than half of the market at 52 percent. It will be interesting to see how the technology landscape is impacted by the deployment of more wireless technologies over time. How are you using wireless and/or Ethernet technology for your connectivity needs? Do you expect to use more wireless technology in the next six months to a year?
IIoT Apps are Brewing
General Electric recently published a piece with three important reasons software developers should focus on the industrial Internet of Things (IIoT). It cited the fact that IIoT apps can solve real-life problems in our cities, provide the opportunity for more than 18.5 million developers to advance digital infrastructure, and justify the big investments in IoT. FreeWave on App Development In our 2017 prediction series, we also highlighted the emerging opportunity for IIoT app development. We believe that IIoT app development will start to outpace consumer app development in 2017. IoT app development can play a significant role in driving Smart Data over Big Data for mission critical use cases. Organizations need to get the data they need when they need it, and new applications at the Edge can help send the right data to the right people. We also see a huge business opportunity for developers: the opportunity to leverage cybersecurity applications and the need for business apps that will coincide with IIoT apps to meet standards and interoperability challenges. Although it is early in the year, we’ve already begun to align with our prediction through our R&D efforts here at FreeWave. Recently we partnered with an app development company to offer something new to our customers. New Apps at the Edge FreeWave’s new partnership with Systech offers an industrial Tank Level Control application that resides on and executes from FreeWave’s ZumLink Industrial IoT (IIoT) Programmable Radio for edge networks. The new application was developed by Systech for FreeWave and features an easy-to-use “ITTT (If This Then That)” process control programming interface that will control analog, digital and RS485 sensors linked to the ZumLink programmable radio. The FreeWave ITTT App is designed for a user-friendly experience and requires no previous programming knowledge or practice. It is ideal for M2M and IIoT use cases at the access layer and will perform automated Sensor-2-Server (S2S) functions to streamline operations. We are watching IIoT app development closely and will certainly have more advancements and announcements in relation to our own journey with bringing apps to the ZumLink IIoT Programmable Radio. What kinds of IIoT apps would you like to see?
2017 IIoT Prediction Series, Part 5: Major Public Utility Company Closes Doors
As 2017 kicks into full gear and a particularly interesting 2016 fades into the rearview mirror, we took a look around the IIoT landscape to see what this year might potentially have in store. Today, we wrap up the 2017 series – let us know what you think! On Tuesday, we started our predictions by looking at the potential development of Fog Computing at the Edge and its impact on cybersecurity. Wednesday, we predicted that the rise of IIoT applications will outpace consumer IoT apps. Thursday, we wrote about the challenge facing IIoT businesses as the workforce ages and new skills are needed for the ongoing IT/OT Convergence factor. On Friday, we predicted that the growth of smart cities infrastructure would force a connectivity standard for the IIoT industry. A Public Utility Closure in 2017 The maturation of interoperability standards and evolution of remote data collection technologies are forcing critical infrastructure and utility organizations to adapt at a new pace, in light of aging infrastructure and high percentages of the workforce that are nearing retirement. Existing management continues to struggle to match the IT and operations resources needed to build a comprehensive, integrated portfolio of applications that must work together to support the organization’s goals. The prediction A public utility company will close its doors in 2017 due to challenges surrounding the adoption and implementation of modern IoT technologies. There are numerous forces that support the prediction. Here’s our take on the big ones: Are you Taking Advantage of Fog Computing at the Edge? According to analysts, utility organizations are becoming more comfortable hosting critical infrastructure data and applications in the Cloud. But, in an effort to further optimize processes and shorten response times, utilities need to explore ways to host applications at the device/sensor level (i.e., the Edge otherwise known as Fog Computing). A decentralized network architecture that brings computing power closer to where data is generated and acted upon enables utilities to analyze, control and automate closer to the “Things” in the Industrial Internet of Things. In electric power, for example, where even milliseconds are vital, certain processes can move away from the Cloud and closer to the Edge. In an industry where cloud computing presents its own sets of challenges, can utilities go one step farther to look at new ways to optimize the “things” at the edge? IT-OT Convergence Presents Plenty of Challenges With identifiable business benefits and rapidly developing technologies that are closing the IT/OT divide, there are functional and operational differences between IT and OT groups that exist and complicate integration or convergence. IT and OT groups typically have fundamentally different charters, focus and personnel within their respective organizations. The challenges to IT/OT convergence are not the sensors, hardware, software or technology, but how each group perceives each project or opportunity and in turn, the solutions, which are skewed by their respective domains. In order for IT/OT convergence to be successful, communication is essential and in turn, there needs to be a clear understanding of each group’s roles – something we see utility organizations struggle with mightily, especially as an aging workforce butts heads with the next generation of digital-centric employees. However, the careful selection of technology for IIoT or industrial applications can help drive the convergence of IT/OT systems. For example, in electric utilities, the rollout of Advanced Metering Infrastructure (AMI) and Distribution Automation (DA) networks is truly an OT application. The source of the data will fuel IT/OT convergence because it is the data analytics applications such as outage detection, fault management, prepay and others that bring value to the Smart Grid. If utilities can proactively take a systems level view of its infrastructure and integrate legacy systems with modern IT systems, the convergence of IT/OT groups may prove less strenuous. Cyber-threats to the Utility Utilities are at the forefront of the Industrial IoT with complex and comprehensive networks for advanced metering infrastructure, energy management, distribution management and substation automation. The estimated growth in IIoT applications for utilities and energy industries will increase to more than 1.5 billion devices by 2020. This explosive growth in networks, smart sensors and devices, and automated systems requires utilities to address, implement and monitor the security of their data networks because these are the networks providing command and control of critical infrastructure that is the Smart Gird. As technology has evolved, so has the intelligence and sophistication of cyber terrorists and their tactics. If utilities do not build a comprehensive security layer, especially across its internet-connected systems, there is little faith they’d be able to combat against such tactics as Denial of Service and Intrusion – the two top threats according to the Federal Communications Commission (FCC). If utilities don’t invest in hardened/proven networking and communications equipment, network access control programs, data encryption strategies, advanced monitoring technology and explore various other tactics for limiting exposure to harmful cybersecurity threats, they may be forced out of business anyways. Today, it is not a matter of “if” a cyber-attack is going to take place, but when. We hope you are ready. All in All We hope this prediction is one that doesn’t come to light in 2017, especially with all the direct investments being made in our critical infrastructure projects across the nation. However, a competitive organization is both agile and proactive in meeting market demands – something utilities need to learn from as business continues. That does it for our list of 2017 IIoT predictions – hope you enjoyed and please be sure to send your questions and comments below!
2017 IIoT Prediction Series, Part 4: Smart Cities Turn to Standardization
As 2017 kicks into full gear and a particularly interesting 2016 fades into the rearview mirror, we took a look around the IIoT landscape to see what this year might potentially have in store. We will be unveiling five IIoT-related predictions throughout this week and into next, so stay tuned and let us know what you think! On Tuesday, we started our predictions by looking at the potential development of Fog Computing at the Edge and its impact on cybersecurity. Wednesday, we predicted that the rise of IIoT applications will outpace consumer IoT apps. Yesterday, we wrote about the challenge facing IIoT businesses as the workforce ages and new skills are needed for the ongoing IT/OT Convergence factor. FreeWave Predictions 2017 Throughout the last year or so, we’ve paid especially close attention to the development of Smart infrastructure. People tend to think of smart cars, smart appliances, smart houses, and smart cities in this context, but what we’re more interested in is the growth of the infrastructural mechanisms that make these “smart” applications a reality. Because we play in the industrial sector, the growth of Smart Cities is where we most notice the growth of this infrastructure. Some cities around the world, especially India, have invested heavily in the infrastructure necessary to create a Smart City. Other countries, however, have been slower to follow suit for a variety of reasons. Our Smart City Prediction With the rise of Smart City initiatives the 802.11 ah (HaLow) wireless networking protocol will over power Bluetooth in 2017 for critical infrastructure applications like traffic management, public safety, energy efficiency and public infrastructure design. By the end of 2017, millions of smart IoT devices will be deployed into networks that use the HaLow protocol and it will eventually become the standard for IIoT. The “Standards” Problem One of the main challenges to Smart City growth so far has been the reluctance for industry leaders to choose a single standard for connectivity. So far, HaLow has been considered one of the titans, but there is yet to be a move to make it the standard for further development. This WiFi protocol brings many benefits to the table, including its high speed data transmission and the early backing of IEEE. Bluetooth or HaLow? Nipping on the heels of HaLow is the emergence of Bluetooth 5. Where HaLow shines – high-speed data transmission rates for longer distances – Bluetooth 5 falls flat. But Bluetooth 5 has perks of its own: low energy needs means longer battery life for the devices that use Bluetooth 5, and, of course, the cost factor cannot be ignored either – Bluetooth 5 is much cheaper to implement. Additionally, where Bluetooth 5 is already up and running, HaLow is still being rolled out, and will continue to be for the foreseeable future. Smart Cities Need Bandwidth, but… They also need cost-effective solutions that can be rolled out today. Where the benefits outweigh the cost is most likely the side to which Smart City developers will fall. As urban areas continue to expand outward, the need for high bandwidth solutions will become more important, which would seem to favor 802.11ah in the long run. Stay tuned Monday for our final prediction!
Industry 4.0 Top News Roundup
Industry 4.0, another term being batted around for the Industrial Internet of Things (IIoT) to explain the next-generation of industrial manufacturing and a new data exchange paradigm, is bleeding into multiple industry dialogues to describe the new landscape of how things are being made. With all the hype surrounding the idea of a “smart factory,” it seemed fitting to turn our attention towards highlighting our top news being reported on Industry 4.0. Industry 4.0: the urgency of data standardization By @Antoine_Rizk1 | Published on @ManufacturingGL “Sometimes presented as the new industrial revolution, Industry 4.0, primarily represents an advance in production means and practices. Characterized by interconnected machines and systems, it involves making production and supply chains smarter in order to improve efficiency in resource allocation and increase agility in production processes.” Industrial Analytics Based On Internet Of Things Will Revolutionize Manufacturing By @LouisColumbus | Published on @Forbes “Industrial Analytics (IA) describes the collection, analysis and usage of data generated in industrial operations and throughout the entire product lifecycle, applicable to any company that is manufacturing and selling physical products. It involves traditional methods of data capture and statistical modeling. However, most of its future value will be enabled by advancements in connectivity (IoT) and improved methods for analyzing and interpreting data (Machine Learning).” Drones will transform the way food is grown next year By @Harri8t | Published on @CNBC “Drones are transforming agriculture — giving farmers new tools to supervise crops and check on fields from the air — and 2017 will be be a pivotal year for adoption, say industry experts.” US Manufacturers Too Slow to Adopt Industry 4.0: BCG Study By IW Staff | Published on @IndustryWeek “Nearly 90% of manufacturing leaders surveyed by BCG regarded adopting Industry 4.0 technologies as a way to improve productivity, but only about one in four see opportunities to use these advances to build new revenue streams. Many are pursuing isolated initiatives scattered throughout the company, BCG found in its new report, “Sprinting to Value in Industry 4.0,” without a clear vision and coordination from the top.” Embracing ‘Industry 4.0’ By @alansmurray | Published on @FortuneMagazine “There’s a interesting new report out from BCG this morning on “Industry 4.0” – the German’s preferred term for how big data, cloud computing, sensors, advanced analytics, augmented reality and improved robotics are dramatically changing the world of manufacturing (known in GE-land as the “Industrial Internet”).” As we conclude another round of top news, we hope you were inspired and informed about the latest in Industry 4.0. It’s clear that business digitalization will only continue to add more technology, whether that be IoT, sensors, cloud computing and other solutions. Our job is to be ready and informed about how tomorrow’s technology could help enterprise digital transformation today.