The internet of things (IoT) is breaking rules. For example, in many cases IoT designers purposely limit the processing power and connectivity of IoT devices. Making devices with less processing power and connectivity may buck the IT trends of recent years, but IoT is changing some of the assumptions and approaches of traditional IT. IT professionals moving toward IoT will need to learn some new skills, strategies and technologies.

IoT devices are smart (having their own embedded processor) and connected (often using wireless networks). But setting up, configuring, programming and maintaining an IoT device is very different from doing those tasks on a traditional computer. The typical IoT device is purposely configured with extremely limited processing power, memory and data communication capabilities. A device may not have a user interface other than perhaps a power button and a few LED lights. These constraints have positive effects; they make IoT devices both inexpensive to produce and downright miserly in their use of electrical energy. And IoT devices may even extract energy from the environment around them, a feat called energy harvesting. This design strategy enables devices to be located anywhere, even in remote locations where electrical power sources and connectivity may be limited.

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Which of the following best describes how you currently monitor and manage systems across your hybrid cloud environment?(Required)

Multiple separate tools for different environments

Multiple separate tools for different monitoring and management functions

Single consolidated dashboard

Custom built monitoring and management solution

No full monitoring and management solution

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How valuable would it be for your monitoring and management solution to incorporate predictive analytics to help you identify and address system issues that are critical and not waste time or effort working through all the data and “noise” that is not critical?(Required)

Extremely valuable

Moderately valuable

Somewhat valuable

Slightly valuable

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How do you most typically address potential system issues BEFORE they impact your operations?(Required)

Automated workflows and playbooks to remediate potential issues as soon as they are detected

An orchestrated response process that leverages automation, AI, and human expertise to rapidly respond to potential issues

Advanced monitoring tools such as predictive analytics and anomaly detection to proactively identify and address potential issues

Respond to issues as they arise, using manual processes and troubleshooting techniques

A combination of automated remediation, orchestrated response, and/or proactive monitoring to address potential system issues

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What methods does your organization use to control and monitor cloud/IT spending?(Required)

Centralized procurement processes

Pre-approved budget thresholds

Automated cost monitoring tools

Department-level spending controls

Regular cost audits and reviews

Cloud cost optimization platform

Approval workflows for resource provisioning

Native financial operations tools provided by the cloud provider

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Which methods do you rely on most to detect security vulnerabilities in your systems?(Required)

Automated scanning tools

Manual assessments

Vendor notifications

Threat modeling (for early detection)

None of these

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What are the TWO most common ways you prioritize vulnerabilities to address within your environment?(Required)

Based on potential impact

Based on exploitability

Regulatory compliance requirements

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How do you typically handle system updates and security patches?(Required)

Automated updates and patches

Manually review and apply updates and patches on a regular schedule

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Apply updates and patches on an as-needed basis.

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Sensors on IoT devices can collect a mind-boggling variety of readings, such as the temperature of frozen food in a delivery truck, the volume of traffic passing through an intersection, the quality of soil in a particular location of a farmer’s field and countless other measurements. The sheer volume of data produced by IoT devices must be processed, interpreted and handled securely. At the same time that IoT is dramatically increasing data volumes, it is also creating new challenges to keep that data secure and private.

Real-time data processing and networking enable data to be collected, processed and acted on very quickly. Based on intelligence provided by the data, an immediate, automated response may need to be triggered. For example, the temperature in the refrigerated delivery truck may need to be adjusted. The brakes in a smart car may need to be activated to avoid a collision. Or the mix of chemicals may need to be modified as a spraying machine advances through a farmer’s field, based on soil samples taken at the sprayer’s exact geographic location. The ability to process and act upon data so quickly seems at odds with the limited power and capabilities of the typical IoT device. But special operating systems and data processing strategies enable these real-time operations to be performed efficiently.

Edge computing provides another strategy for processing the data from IoT devices. Rather than perform all heavy processing tasks in the cloud, edge computing moves some processing tasks back to the edge—where the local network meets the cloud. This means placing some sort of heavy processing capability near the IoT devices, and using an IoT gateway to “do the heavy lifting” on behalf of IoT devices. The gateway can handle all communication with the cloud, so the IoT devices themselves can use lightweight communication protocols and (safely behind a firewall) won’t require the same security capabilities (such as heavyweight encryption processing) that they would require if they were directly connected to the internet.

New methods of data processing and analysis are used to make sense of the massive quantities of data produced by IoT. Data analytics tools such as Azure Stream Analytics, Vitria, and Statistica are geared toward IoT. Big data and cloud storage technologies, such as Hadoop and NoSQL database systems, take on new importance with IoT.  So do more traditional skills such as SQL. Machine learning and artificial intelligence technologies will also play a critical role for processing IoT data.

IT professionals preparing to move to IoT should consider adding some of the following skills to their portfolio:

• Working with microcontrollers, sensors and actuators.
• Programming real-time operations on microcontrollers.
• Embedded device power management and deployment of energy harvesting technologies.
• Selecting, installing and configuring real time operating systems.
• Setting up and configuring sensor networks and IoT gateways, including communication technologies geared toward these networks, such as MQTT, 6LoWPAN, Thread and Zigbee.
• Managing cybersecurity on embedded devices and sensor networks.
• Working with data analytics tools, advanced SQL, cloud storage and NoSQL databases, artificial intelligence and machine learning.

CertNexus is looking for IT professionals to take the CIoTP beta exam. The Certified IoT Practitioner is meant for those seeking vendor-neutral, cross-industry, foundational knowledge on the internet of things. If you are interested in taking the CIoTP beta exam, please email info@certnexus.com.

— Brian Wilson