White House rallies industry support for Internet of Things labeling … – CyberScoop

Written by Suzanne Smalley and Tonya Riley

White House officials convened industry leaders, policy experts and government leaders on Wednesday to discuss plans for security and privacy standards on connected devices.

The meeting — billed as a workshop for a nascent White House Internet of Things labeling initiative — included top White House cyber official Anne Neuberger, Federal Communications Commission Chairwoman Jessica Rosenworcel, National Cyber Director Chris Inglis and Senator Angus King, I-Maine, alongside consumer tech associations, industry executives and the nonprofit consumer advocacy organization Consumer Reports.

Industry leaders from Google, AT&T, Comcast, Amazon, Cisco, Intel, Samsung and Sony attended the meeting, as did officials from the American National Standards Institute and the National Retail Federation, according to the White House.

The meeting focused on the implementation of the program with a focus on issues such as how to ensure labels match international standards, how to design a barcode to ensure consumers can find timely information about a product online and how to raise overall consumer awareness of IoT vulnerabilities.

CyberScoop first revealed White House plans for the meeting last week.

The labeling program is still in its early stages, but the White House expects to roll out a first set of standards in Spring 2023 and plans to launch the voluntary program with standards in place for particularly vulnerable internet-connected devices such as internet routers.

“It would be a more sophisticated way to approach cybersecurity than merely saying, ‘Oh, if it’s manufactured in one country, it’s safe; if it’s manufactured in another, it’s not.”

senior white house official

A White House official told reporters the program will likely rate devices based on standards that include vulnerability remediation, amount of information collected on consumers, whether data is encrypted and interoperability with other products.

“It would be a more sophisticated way to approach cybersecurity than merely saying, ‘Oh, if it’s manufactured in one country, it’s safe; if it’s manufactured in another, it’s not,” a senior administration official said.

Brandon Pugh, senior fellow and policy counsel at the R Street Institute think tank, said he left the meeting with the impression that more extensive privacy standards around data collection and sharing could also be considered as part of the rating system down the road.

Pugh said the lack of cybersecurity in Internet-connected devices merits immediate attention.

“As a consumer, you’re really just kind of taking a chance and hoping for the best,” Pugh said. A labeling program is “not perfect in every sense,” Pugh added, “but at least it would give consumers some level of knowledge that what they’re buying is secure.”

A senior White House official told reporters Wednesday that the label will include a barcode for consumers to scan so they can see a given manufacturer’s security practices in real time, ensuring that the “label remains fresh.”

“Given the way cybersecurity continuously evolves infinitely, vulnerabilities continuously evolve,” the official said.

A senior leader from the Federal Trade Commission attended the workshop to highlight compliance and enforcement tactics, the official added.

“They talked about their ability to enforce based on the labels and is the security in device meeting the standard within the label,” the official said, comparing the “model of market enforcement” to nutrition labels.

A Carnegie Mellon University CyLab Security and Privacy Institute researcher, who has spent more than four years working on a separate rating effort known as “privacy nutrition label for IoT devices,” demonstrated that approach at the meeting, noting that his prototype has been consumer-tested and could immediately be implemented across the IoT industry.

The researcher, Yuvraj Agarwal, said he has done several consumer studies to determine if people will spend more for products with heightened security and privacy standards.

The Carnegie Mellon University-designed privacy label for IoT devices has been tested with consumers and is ready to be deployed.

“Consumers are willing to pay significantly more of a premium over the base price of the device for a secure product,” Agarwal told CyberScoop. “Consumers really do want to pay for devices that are better in terms of their security and privacy.”

A Google official who participated in the workshop published a blog post Wednesday hailing the effort.

“We’re now putting more of our lives and trust in the hands of digital technology,” Dave Kleidermacher, head of security for Android and Google Play wrote. “Yet, the IoT industry still lacks a global harmonized way for measuring the security quality of connected products, which means consumers may not have the visibility they need into whether their IoT devices protect their data.”

Kleidermacher said Google’s leadership is “encouraged” by the White House effort to accelerate IoT security standardization so that people have “more transparency in the security of the IoT products they use every day.”

What Is IoT or Internet of Things? Definition & Meaning of IoT – EC-Council

Every day, technology advances, bringing with it new risks. IoT is no different. In fact, it may be even more dangerous due to the interconnectedness of devices. Let’s look at some of the risks associated with IoT so that you can be aware of them and take steps to protect yourself.

One of the biggest risks with the Internet of Things is data breaches. Because these devices are connected to the internet, especially LPWAN, they are vulnerable to hacking. If a malicious hacker can gain access to one device, they can often gain access to others on the same network. This could allow them to steal personal data or even cause physical damage (ARCHON).

Another risk is that of malware, which is software that is designed to damage or disable computers. It can be used to steal data, delete files, or even take control of a device. IoT devices are particularly susceptible to malware because they often have weak security.

The Internet of Things is a constantly growing network of interconnected devices that can communicate with each other. These devices range from simple everyday objects to complex industrial machines.

As the number of IoT devices and IoT-based projects continues to grow, so does their potential to solve various problems and improve our lives. However, there are also risks associated with this technology that must be considered before implementing it into your business or personal life.

If you want in-depth training on IoT security, consider EC-Council’s Certified Ethical Hacker v12 program. It trains learners on various operational technology (OT) and IoT attacks, hacking techniques, tools, and countermeasures. The course teaches participants the latest commercial-grade hacking tools, techniques, and methodologies used by hackers and information security professionals to lawfully hack an organization. Learn more about C|EH v12 program here.

Internet of things mobile connections will double by 2026 – Insider Intelligence

Beyond the chart: IoT enables everyday items, such as kitchen appliances and medical devices, to digitally collect and send data. 5G is a major factor in this surge, providing them faster broadband and better machine-to-machine interaction. As 5G expands to more regions, so will usage of IoT, which will also bring enhanced security in places such as hospitals and the home.

More like this:

Read yesterday’s Chart of the Day here.

How the Internet of Things Can Increase Productivity – Entrepreneur

Opinions expressed by Entrepreneur contributors are their own.

Production downtime and factory productivity are closely correlated, as a factory can lose up to 20% of its productivity due to downtime.

The most common cause of production downtime is a malfunction or breakdown of equipment. However, it is possible to reduce equipment failure and keep downtime low with a predictive maintenance strategy that uses the Internet of Things (IoT), cloud computing and analytics.

The collection of equipment and environmental data occurs through sensors. The data is used to predict and remediate equipment failures proactively. Over time, machine learning advancements can improve the accuracy of predictive algorithms and allow you to build advanced prediction models.

Related: How Cloud Agnostic Hardware Could be The Future of IoT

Why minimize downtime?

A study reveals that 46% of manufacturers fail to deliver services to customers due to an unexpected equipment failure. Unplanned downtime also leads to a loss of production time on a critical asset and hinders manufacturers’ ability to service or support specific assets or equipment.

Unplanned downtime affects all industries, and its impacts extend beyond the financial for some. According to an article in Petro Online, a single, unplanned downtime in an oil refinery or petrochemical plant releases a year’s worth of emissions into the atmosphere.

Why is predictive maintenance using IoT?

It is worth understanding what Internet of Things monitoring entails to grasp its implications for downtime. An IoT monitoring system consists of four elements:

1. Sensors

The first step in IoT monitoring is collecting data from the physical environment, which requires sensors. Sensors have specialty electronics that sense inputs from the physical environment and convert them to data for interpretation by machines or humans. The inputs include heat, light, moisture, sound, pressure or electromagnetic fields.

2. Connectivity

Sensors collect the data and send it over the cloud for analysis. Several methods are available to relay the data, including WiFi, satellite, cellular, Bluetooth or a direct connection to the internet via Ethernet. The type of connectivity used depends on factors such as power consumption, range, bandwidth, and security.

3. Data processing

When the data reaches the cloud, it is processed by software. There are many software solutions available for different IoT use cases. The solutions analyze the data and present it to end users in an easily understandable format. For example, you can set up sensors to display equipment vibration and temperature data every three seconds. Or you can run sophisticated analysis on a massive amount of IoT data and trigger appropriate action.

4. User interface

The end user can receive the data through a web, email, or text notification. For example, your factory manager may receive a text/web/email alert when the temperature sensor reading exceeds a certain threshold. The manager can then remotely adjust the temperature from their web or mobile app or trigger another remedial action that brings the temperature to a safe level.

Related: 4 Reasons to Be Excited by the ‘Internet of Things’

What is the role of IoT in reducing production downtime?

IoT can be the key to minimizing downtime and keeping productivity levels high. Here’s a discussion of the reasons for implementing an IoT-based predictive maintenance strategy.

1. You can monitor equipment in real-time

Real-time monitoring of asset condition and performance allows you to anticipate problems before they occur. Any maintenance required can happen moments after an alert, helping prevent a costly breakdown or any impact on plant performance. Timely maintenance is also helpful in maximizing the useful life of equipment — you can avoid having to replace equipment too soon and get the full return on your investment.

2. You can optimize the time taken to repair equipment

Predictive maintenance runs in the background, keeping you informed about machine condition and performance. You’re alerted to deviations from optimal conditions, which tell you whether or how your equipment is aging or degrading. Using the information, you can accurately predict when the system is likely to fail and determine when to repair it.

As anomalies are relayed soon after they’re detected, any issue with a machine is unlikely to go unnoticed and worsen. If deemed necessary, fixes in the early stage of equipment degradation won’t take the hours usually associated with unplanned and planned maintenance.

3. You can spend less on repairs and parts

Predictive maintenance is data-driven and analytical, allowing you to get to the root cause of a problem rather than only treating its symptoms. Knowing what might lead to equipment breakdown is useful to prevent the wear and tear responsible for equipment failure. For example, alerts on suboptimal humidity help reduce the electrostatic discharge produced in a low humidity environment. Component degradation can be avoided, and equipment repair costs and spare parts inventory can be optimized to the desired level.

4. You can keep workers safe

Putting sensors in charge of detecting equipment issues bodes well for worker safety. For example, checking for bearing failure, a common cause of downtime, may require workers to access difficult or dangerous bearings to reach. With predictive maintenance, workers can check the bearings’ condition without touching them. Smart sensors can gather information on the pressure and temperature of liquids flowing through pipes without requiring direct human intervention.

When to use IoT

  • Cut down on unplanned downtime
  • Reduce machine repair costs
  • Enhance worker safety
  • Shorten time to repair machines
  • Enable better utilization of equipment
  • Increase ROI of equipment

It is useful for critical assets that have the greatest impact on production rate and profitability. IoT monitoring is also valuable when minute changes in environmental conditions can significantly affect product quality or worker safety. For example, sensors detect an operator’s presence in a dangerous environment or faults in rotating machinery.

Data from IoT devices can be integrated with workforce solutions to develop work schedules that can reduce workers’ exposure to hazardous conditions. As a passive safety solution, IoT can help enhance worker confidence and morale.

Related: The ‘Internet of Things’ Is Changing the Way We Look at the Global Product Value Chain

Internet of things market continues to surge – ComputerWeekly.com

Noting that the surging need for wireless networking technologies continues to drive the entire market’s growth, online education and trading comparison provider TradingPlatforms.com has released research showing that the internet of things (IoT) has become one of the most important technologies available to businesses, providing seamless communication between people, processes and things, and is now set to generate global revenues of $19.5bn in 2022, a 13% year-over-year increase.

The study predicted such revenues to spike by 45% in the next three years, with a market engine being the fact that the IoT is one of the technologies driving Industry 4.0.

TradingPlatforms.com said it was not surprising that the market will enjoy a CAGR of over 12%. The analyst added that IoT improves data collection, security and efficiency and saves time, and that both personal and business possibilities of its use were “endless”.

The study added that such growth would come even as the global semiconductor shortage has slowed down the market supply and growth from pre-pandemic levels, as the global demand for smart offerings from industrial to security use cases is still rising. It cited a Statista survey from 2021 showing that global IoT revenues surged by 27% year-on-year to $17.3bn worldwide.

Even though growth decelerated in 2022, revenues were still up by $2.3bn, or 13.3%. However, Statista expects IoT revenues to spike by another 45% to $28.3bn by 2025.

TradingPlatforms.com also noted that smart home technologies remain the largest revenue stream of the IoT market, with $19bn in revenue in 2022, 13% more than last year. This segment of the IoT market is forecast to see a 45% growth in the next three years, with revenues rising to $27.7bn worldwide.

The other key segment of the IoT market, finance technologies, have seen a slight revenue drop to $570m in 2022, down from $580m a year ago. By 2025, this figure is expected to increase to $630m.

On a regional basis, TradingPlatforms.com highlighted the US as the market leader, but with China seeing higher revenue growth.

The US was the IoT market leader, with revenues of more than $4.7bn in 2022. The aforementioned Statista survey showed US revenues grew by 13.7% year-on-year in 2022, down from the 19.1% growth rate seen the year before.

By 2025, the US market is set to reach a $6.3bn value, growing by a CAGR of around 8% per year. TradingPlatforms.com expects China, not only the world’s second-largest IoT market but the leading manufacturer of IoT devices, to see revenues of $4.5bn this year, 18% more than a year ago.

Although both the US and China will see revenue growth slowing down in the following years, the Chinese market will still grow faster, with an average CAGR of 15% by 2025.

China is also forecast to become the world’s leading IoT market in the next three years, with revenues growing to $6.6bn.

IoT Basics: A Guide to the Internet of Things for Beginners – Robotics and Automation News

IoT implies physical objects linked via wireless and wired networks. It refers to a group of internet-connected devices that communicate independently over the internet without needing a person to mediate the information exchange.

You might wonder how this varies from the “internet” as most individuals realize it. It’s not that different; it’s just a form of communication on the internet that focuses on “things” rather than people. It is divided into several sectors like Telecommunication IoT branches, Medical IoT and Infrastructure IoT.

Let’s look at the fundamentals of IoT, why it’s important and how it’s being used in business and by consumers.

The Origins and History of the IoT

The concept “internet of things” was first used in 1999 by Kevin Ashton, the founder of the Auto-ID Center at MIT. Ashton first used the phrase in an RFID briefing while working on supply chain management for Procter & Gamble (radio frequency identification).

Photo by Lorenzo Herrera on Unsplash

However, the phrase “internet of things” did not become popular until around 2010, thanks partly to the introduction of Google Street View. Street View provided users with 360-degree panoramic images of the globe from street level and stored massive amounts of data on users’ wireless connections.

Not an Original Idea

The concept of the internet of things – that is, internet-connected devices – existed for many years before Ashton chose to give it a name. Previously, the sector referred to this notion as embedded internet or ubiquitous computing, with Intel driving the erstwhile label until it was clear that the term “IoT” was occurring in the public’s mind.

In 1982, a modified Coca-Cola vending machine became the first internet-connected appliance. The device at Carnegie Mellon University disclosed its assets and whether the beverages it contained were cold.

The notion of “moving small data packets to large sets of nodes” was described in IEEE Spectrum magazine in 1994 to integrate and streamline everything from household appliances to whole factories. In all but name, IoT.

IoT Fundamentals

The four pillars of IoT and the key concepts to grasp are as follows:

1. Data

IoT technologies offer numerous methods for gathering data about the physical realm. Data is the energy that drives the IoT, which is why it is essential.

2. Network

This allows for sharing data and insights, adding value to that information. This is the internet in the context of the internet of things.

3. Device

The essential physical elements or things that gather this data are called the “internet of things.”

4. Analytics

The technique of converting raw data into actionable insights makes collected data worthwhile.

Photo by JJ Ying on Unsplash

How does the IoT work?

The Internet of Things is powered by a combination of physical devices, wireless networking technology, advanced data analytics, and cloud computing.

The following is the basic process of how IoT works:

  • A collection of physical devices that are wired or wirelessly connected to one another and a central location.
  • Using some type of sensor, the devices gather data from the environment.
  • This information is stored either in an intermediary network location, the cloud, or the device itself.  The information is then analyzed, which is frequently done using artificial intelligence and machine learning.
    The physical device uses the processed data to perform some action.
  • As an example, consider how this process would work with a smart thermostat:
  • Over a wireless network, the thermostat sends periodic temperature readings to the energy provider’s external database.
  • A data analytics application uses data insights to increase energy efficiency by adapting thermostat temperature settings over time.
  • A sensor on the thermostat measures the temperature in the room.
  • The data is saved and processed by the thermostat.
  • The thermostat will automatically reduce the temperature to a predetermined level if the temperature climbs above a specific threshold.

Photo by GR Stocks on Unsplash

The Challenges of IoT Technology

Much like every technology, IoT faces several challenges, such as:

Interoperability

Many IoT devices run on proprietary protocols or have unique or specialized protocols that prevent them from interacting with other devices or services. There is also no ubiquitous standard set of terms and concepts for discussing IoT, nor is there a prevalent set of guidelines for when these devices become widely used in the public sphere.

Safety

IoT devices, particularly those used in medical, industrial, transportation, and infrastructure applications, are frequently tasked with tasks that, if mismanaged, could endanger lives. If a smart car’s alert system fails, the driver may fail to notice a hurdle or pedestrian. A faulty sensor in an industrial plant can be disastrous if a critical red flag is missed.

Data Privacy

As IoT becomes more widespread, there are also issues about data privileges and consumer data confidentiality. For instance, with more networked devices sharing data independently, accountability for all that data becomes difficult.

With billboards with spy cameras that monitor the demographic data of pedestrians who stop to peruse them and safeguard patient data collected by smart medical equipment in and out of the hospital.

IoT Security

Because IoT devices are frequently used to automate processes, people do not interact with them as regularly as consumer devices such as smartphones. For instance, a manager of an IoT device such as a camera sensor is more likely to ignore changing the factory-default password. As a result, an externally visible IoT device with a simple passcode to crack is created.

Environmental Consequences

Because of the heavy metals used in many IoT devices, it is hard to fabricate, dispose of, and reuse them without incurring significant human and environmental costs. As a result, some IoT distributors intentionally brick their products by deactivating the proprietary assistance that their devices require to function.

Photo by Alex Knight on Unsplash

Benefits of IoT Technology

The most immediate benefit of the internet of things for businesses is that it allows them to learn more about – and thus improve – their own business procedures and structure, ultimately focusing on providing superior products or more efficient services.

IoT expands the number and types of locations from which enterprises can autonomously retrieve data, offering much more data to work with. It also improves the responsiveness of internal systems.

The main advantages of IoT for customers are accessibility and ease of use, which are not negligible in the case of a healthcare device, for example. As IoT expands and permeates the public sphere, more meaningful and social benefits will emerge, such as:

  • Implementing a location-free voting system and combining biometric voter registration and verification with IoT to ease the casting of a vote and increase security are two examples of how this affects politics.
  • Smarter environmental decisions result from a better understanding of the environmental impact and pollution.
  • Smart cities transform the way urban environments operate.
  • As a result of these events, you observe changes in culture and politics. The massive amounts of data generated by IoT networks and smart cities will provide new insights into areas previously limited by the value of accurate data.

IoT in Businesses and Industries

Photo by Rafael Juárez on Unsplash

Manufacturing

IoT in the manufacturing and industrial sectors helps with various identification, processing, sensing, and communication processes in the factory and outside. For instance, digital control structures can automate these functions and facilitate plant safety, security, and effectiveness.

Examine how the Internet of Things is transforming manufacturing.

Retail

To enable digital interactions, retailers and distributors utilize innovative packaging with a barcode or NFC tag containing a unique identifier and digital product information. Similar technology allows contactless communication with officially used objects such as restaurants or innovative drinking fountains.

Photo by Olga Guryanova on Unsplash

Healthcare

Medical data collection, tracking, and analysis can all be done with IoT devices. Medical IoT, also known as smart health coverage, seeks to create a virtual healthcare service that links medical resources and assistance.

Here are some instances of IoT applications in this field:

  • Pacemakers and heart rate monitors that track a patient’s vital functions and can generate notifications via an emergency alert system.
  • Hearing aids that adapt their sensitivity to the user’s preferences.
  • Fitbits and smartwatches that collect biometric data.
  • Smart beds detect movement, notify a medical provider, or automatically switch settings to enhance comfort.
  • End-to-end health monitoring solutions assist patients, particularly those with chronic diseases, track their vitals and medication necessities.

Photo by Max Whitehead on Unsplash

Infrastructure

IoT devices have the prospect of improving public architecture. Here are a few examples:

  • The Development of Cities

Smart cities equipped with IoT sensors offer citizens services such as environmental control data and smartphone parking apps via smart meters.

IoT is used in agriculture to supervise and acquire agricultural data such as temperature, rainfall, wind speed, soil content, and pest infestation. Farmers can use data from IoT devices in their sector to improve product quality and reduce waste.

Smart parking, traffic control, electronic toll collection systems, and vehicle roadside assistance contribute to more efficient transportation.

  • Building and Home Automation

Efficient energy management system design monitors and controls a variety of infrastructure components.

  • Infrastructure monitoring

IoT devices can monitor architecture such as bridges and railway tracks for significant structural changes to optimize disaster response and emergency response processes.

Photo by Specna Arms on Unsplash

Military

The military employs intelligent technology and the Internet of Things to prepare for battle and collect intelligence and surveillance.

Smart drones are one instance of the DARPA Ocean of Things project, which also focuses on building an infrastructure of passive sensors at sea to trace the presence and action of commercial and military vessels.

Main image courtesy of NASA via Unsplash

Internet of things mobile connections will double by 2026 – Insider Intelligence

Beyond the chart: IoT enables everyday items, such as kitchen appliances and medical devices, to digitally collect and send data. 5G is a major factor in this surge, providing them faster broadband and better machine-to-machine interaction. As 5G expands to more regions, so will usage of IoT, which will also bring enhanced security in places such as hospitals and the home.

More like this:

Read yesterday’s Chart of the Day here.

How Internet of Things (IoT) Supports a Resilient Supply Chain – Acceleration Economy

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In How Cloud Computing Can Help Develop a More Resilient Supply Chain, I described how supply chains and their challenges will stay at the forefront of the news and government as long as consumers continue to experience a lack of timely delivery of goods such as computer chips, building supplies, and automobiles. I pointed out some of the ways that cloud-based technology could provide a solution to supply chain challenges and help the many company leaders struggling to meet consumer demands. In this article, I’ll dive into one such technology: the Internet of Things (IoT).

What is IoT?

Oracle describes IoT as a “network of physical objects — ‘things’ — that are embedded with sensors, software, and other technologies for the purpose of connecting and exchanging data with other devices and systems over the internet.” These “things” run the gamut from smart TVs and doorbells to motion-sensitive security cameras and temperature sensors for office HVAC systems.

While Oracle’s definition is true, it doesn’t really tell us why IoT is important. We have millions of connected gadgets all over the world, providing mass amounts of data, but how does that help our supply chain issues? I’ve pinpointed three ways IoT can help, such as:

  1. Enhancing logistical traceability
  2. Enabling scalability
  3. Improving microfactory performance

3 Ways IoT Supports the Supply Chain

1. Logistical Traceability

An important aspect of improving supply chain problems is gaining a better understanding of where goods are at any time. Goods are constantly on the move, starting with raw material transportation and production, then moving onto finished goods manufacturing, and finally ending up on store shelves or direct-to-consumer delivery. The past three have seen numerous disruptions to this process, however.

From factory staffing shortages to the slim availability of shipping containers, the causes of supply chain slowdowns have been numerous and complex. This is why the ability to obtain real-time updates on the location and trajectory of these goods can make all the difference in controlling and optimizing logistics processes.

Rather than depending on periodic manual updates, we can use IoT by including tracking devices in packages or shipping containers. Think of it as the difference between having a tracking number that tells you “package received at the regional center” or “package is in transit” and seeing a live feed of “where the truck carrying your package is right now.” Even in the warehouse, these tracking devices can let you know exactly where your pallets of goods are at any time, providing a quicker ability to locate products that need to be shipped or get real-time inventory counts.

2. Scalability

As I mentioned in my previous article, one of the fundamental causes of supply chain issues is the inability to adapt to changes in demand. Often, the disparity between demand and supply is a result of timing: The knowledge that demand has increased comes too late to ramp up production, and lead times suffer.

Here, real-time processes coupled with process automation and scalable cloud technology can help. By coupling the data provided by IoT devices along the supply chain with predictive analytics, you can get a much quicker alert that your demand is changing and requires quickly adjusting supply parameters and scaling up or down as needed.

3. Microfactories

Microfactories are another way to take advantage of IoT to create a nimble, resilient supply chain. What are …….

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What Is IoT or Internet of Things? Definition & Meaning of IoT – EC-Council

Every day, technology advances, bringing with it new risks. IoT is no different. In fact, it may be even more dangerous due to the interconnectedness of devices. Let’s look at some of the risks associated with IoT so that you can be aware of them and take steps to protect yourself.

One of the biggest risks with the Internet of Things is data breaches. Because these devices are connected to the internet, especially LPWAN, they are vulnerable to hacking. If a malicious hacker can gain access to one device, they can often gain access to others on the same network. This could allow them to steal personal data or even cause physical damage (ARCHON).

Another risk is that of malware, which is software that is designed to damage or disable computers. It can be used to steal data, delete files, or even take control of a device. IoT devices are particularly susceptible to malware because they often have weak security.

The Internet of Things is a constantly growing network of interconnected devices that can communicate with each other. These devices range from simple everyday objects to complex industrial machines.

As the number of IoT devices and IoT-based projects continues to grow, so does their potential to solve various problems and improve our lives. However, there are also risks associated with this technology that must be considered before implementing it into your business or personal life.

If you want in-depth training on IoT security, consider EC-Council’s Certified Ethical Hacker v12 program. It trains learners on various operational technology (OT) and IoT attacks, hacking techniques, tools, and countermeasures. The course teaches participants the latest commercial-grade hacking tools, techniques, and methodologies used by hackers and information security professionals to lawfully hack an organization. Learn more about C|EH v12 program here.