What Is: Edge Computing?

Hello and welcome back to “What Is:______?” our (bi-)monthly(-ish) blog where we cover complex IT topics in plain English. This week, we’ll be covering edge computing.

You may have heard of edge computing – it’s a kind of anti-cloud computing model that is becoming increasingly common at businesses with real-time or low-latency data needs or organizations that process and transmit vast quantities of data.

In this article, we’ll take a look at edge computing – what it is, why it’s becoming more common, and how you can take advantage of it as a business owner.

What is Edge Computing?

Edge computing is the practice of processing data closer to where it is generated rather than sending it to centralized cloud servers or data centers. Whereas typically data is centralized in one location, edge computing breaks things down, making data closer to where it’s needed, rather than having to cross thousands of miles.

This decentralized approach allows for faster processing times, reduced latency, and improved overall performance. There’s a reason why organizations of many shapes and sizes are transitioning to edge computing as their primary model.

Edge computing is particularly critical for applications that require real-time data processing, such as autonomous vehicles, IoT devices, and smart cities​ – things that are only going to continue trending upward in terms of widespread adoption.

How Does Edge Computing Work?

In a traditional cloud computing model, data from various devices is sent to a central data center for processing and analysis. While this method works for many applications, it can result in high latency, especially when data needs to travel long distances. With edge computing, the data is processed locally—either on the device itself or on a nearby server—reducing the time it takes to process and analyze the data.

The best example of edge computing is in autonomous vehicles. In order for autonomous vehicles to work at scale, they need to be able to generate and process data at superhuman speed. An autonomous vehicle’s sensors and cameras generate vast amounts of data that need to be processed in real-time to make immediate driving decisions. By utilizing edge computing, this data can be processed locally within the vehicle, ensuring a faster and more reliable response.

Differences Between Edge Computing and Traditional Computing Systems

Centralized vs. Decentralized Architecture

Traditional cloud computing relies on centralized data centers where all the data is sent for processing and analysis. This model works well for applications that do not require real-time data processing, but it struggles with latency and bandwidth issues when handling large amounts of data from dispersed devices.

Edge computing, on the other hand, employs a decentralized architecture. This means that the processing occurs closer to the data source—whether on the device itself or a nearby edge server. This proximity dramatically reduces the time it takes to process the data, thereby cutting down on latency. It also decreases the strain on bandwidth since only the essential or processed data needs to be sent to the cloud.

Latency and Speed

One of the biggest advantages of edge computing over traditional computing models is the reduction in latency. In applications where milliseconds matter—such as in industrial automation, healthcare, or autonomous vehicles—edge computing provides the speed necessary to make real-time decisions. It can even have benefits for businesses like film production and game development, where vast quantities of data are sent around the world.

Traditional cloud models can take longer to process data, which could lead to delays that are unacceptable in time-sensitive situations. Over time, businesses will become intolerant of traditional cloud models – humans don’t deal with impatience well. This is why we’ll see more and more edge computing in the future.

Scalability and Efficiency

Edge computing also offers greater scalability compared to traditional systems. In industries where large numbers of IoT devices are deployed, the sheer volume of data generated can overwhelm centralized cloud systems. Edge computing helps by distributing the processing load across numerous local devices and servers, preventing bottlenecks and ensuring smoother operations.

Furthermore, bandwidth efficiency is enhanced with edge computing, as less raw data needs to be transmitted over long distances. Only the relevant or processed data is sent to central servers, conserving bandwidth and lowering operational costs.

Who Is Using Edge Computing?

Growth and Adoption Across Industries

Edge computing is no longer a niche technology—its adoption is widespread across multiple industries.

According to IDC, global spending on edge computing is expected to reach $232 billion in 2024, driven by the increasing demand for real-time data processing in sectors such as healthcare, manufacturing, and retail.

Businesses are rapidly adopting edge computing to meet the demands of modern digital ecosystems, where immediacy and data-driven decision-making are critical.

Benefits of Edge Computing

We’ve already covered this, but let’s put it in easy-to-read, obvious terms. Edge computing offers numerous benefits that make it a game-changer for modern businesses.

• Reduced Latency: Since data is processed closer to its source, the time it takes to analyze and respond to data is significantly decreased.
• Improved Security: By keeping sensitive data closer to the source, edge computing reduces the risk of data breaches during transmission to central servers.
• Lower Bandwidth Costs: Edge computing reduces the amount of data that needs to be sent to central servers, which can lower bandwidth usage and costs.
• Enhanced Real-Time Decision-Making: Applications such as industrial automation, smart cities, and healthcare can greatly benefit from the ability to process data and make decisions in real time.

Examples of Edge Computing Use Cases

• Healthcare: In healthcare, edge computing is being used to enable real-time monitoring and diagnostics. For example, wearable devices equipped with edge computing capabilities can track patient vitals and alert healthcare providers instantly if a critical condition is detected.
• Manufacturing: In the industrial sector, edge computing allows for real-time monitoring and control of machinery. This helps to optimize production lines and improve efficiency by minimizing downtime and enhancing predictive maintenance.
• Retail: Retailers are increasingly adopting edge computing to analyze in-store customer behavior in real time. This data is used to personalize the shopping experience, optimize inventory management, and improve overall customer satisfaction.
• Autonomous Vehicles: Perhaps one of the most well-known applications of edge computing is in autonomous vehicles, where real-time processing of data from sensors is crucial for safe driving. Edge computing ensures that these vehicles can make split-second decisions without the latency involved in cloud computing.

How Many Businesses Are Using Edge Computing?

Edge computing adoption is accelerating across the globe. A report from GSMA Intelligence and AECC revealed that 73% of surveyed companies across industries are planning to increase their investments in edge computing infrastructure by 10-15% in 2024.

The use of edge computing is particularly prevalent in industries where real-time processing is a competitive advantage, such as telecommunications, automotive, and healthcare.

In addition, by 2030, the number of IoT devices is expected to nearly double, further driving the demand for edge computing – expanding the adoption of edge computing into more industries and even into homes.

How Much Does It Cost to Transition to Edge Computing?

The costs of transitioning to edge computing can vary widely based on several factors, such as the scale of deployment, the number of edge devices required, and the specific use cases involved – but we have to be honest, the initial investment in edge computing isn’t cheap.

If you can stomach the initial investment; however, the benefits of edge computing can be absolutely massive for your business long term. Take your time and do your diligence and you’ll be able to decide whether it’s worth it to upgrade or wait a few years.

1. Hardware Costs

• Edge Devices: Businesses will need to purchase edge devices such as local servers, gateways, IoT sensors, and storage solutions. Costs can range from a few thousand dollars for a small deployment to hundreds of thousands for larger, enterprise-grade systems.
• Upgrades to Existing Systems: Some businesses may need to upgrade their existing infrastructure to support edge computing, including enhancing network bandwidth, installing new servers, or acquiring specialized hardware.

2. Software and Licensing Costs

• Edge Computing Platforms: Many businesses will need to invest in edge computing platforms or software that can manage the distributed processing and communication between devices. These platforms may come with licensing fees based on the number of devices or users.
• Integration with Existing Systems: There will also be costs associated with integrating edge computing solutions with existing cloud or on-premise systems. This could involve custom software development, APIs, or middleware solutions.

3. Installation and Setup Costs

• Initial Setup and Configuration: Setting up and configuring edge devices can require substantial labor costs, especially if the company needs to hire third-party specialists.
• Testing and Optimization: Once the edge computing infrastructure is in place, businesses will need to test and optimize their systems, which can incur additional costs.

4. Maintenance and Ongoing Costs

• Monitoring and Maintenance: Edge computing systems require ongoing monitoring and maintenance, which could involve hiring dedicated IT staff or paying for managed services.
• Security Management: Securing edge devices, particularly those in remote or unsecured locations, will require continuous investments in security protocols, updates, and tools.

5. Training and Workforce Development

• Training Costs: Employees will need to be trained on how to use and maintain the new edge systems. This training can include educating IT teams on managing edge devices, security practices, and new workflows.

In general, small to mid-sized businesses could expect to spend somewhere between $10,000-$50,000, while large enterprises might face millions of dollars in expenses – depending on the scope and scale of their edge deployment.

The Process of Transitioning to Edge Computing

1. Assessment and Planning

• Evaluate Current Infrastructure: Begin by assessing the existing infrastructure. Identify which processes and applications will benefit most from edge computing, such as those that require low latency or real-time data processing.
• Determine Use Cases: Clearly define the use cases for edge computing within the business. Examples might include real-time analytics for manufacturing, autonomous systems in logistics, or personalized customer experiences in retail.
• Cost-Benefit Analysis: Conduct a thorough cost-benefit analysis to determine if the potential gains in efficiency, speed, and security outweigh the initial setup and ongoing costs.

2. Choose Edge Computing Platforms and Providers

• Select Hardware and Software: Identify the appropriate edge devices (e.g., servers, sensors, gateways) and edge computing platforms that will meet your business needs. This might involve working with vendors who specialize in edge solutions for specific industries.
• Vendor Assessment: Evaluate vendors for reliability, support, and scalability. Ensure that the chosen platform aligns with your existing systems and allows for future expansion without excessive vendor lock-in.

3. Infrastructure Deployment

• Install Edge Devices: Begin deploying edge devices in strategic locations close to where the data is generated. For example, in a manufacturing plant, this could be at the site of machinery; in retail, it could be near point-of-sale systems.
• Network Configuration: Set up local networks and connectivity to ensure that the edge devices can communicate effectively with each other and with the central cloud infrastructure if needed.

4. Data Management and Integration

• Establish Data Flows: Configure how data will be collected, processed, and transmitted. For some processes, data will be processed entirely at the edge; for others, data may be filtered and sent to the cloud for further analysis or storage.
• Integrate with Existing Systems: Ensure that the new edge infrastructure works seamlessly with the company’s existing systems, such as ERP, CRM, or centralized cloud systems.

5. Testing and Optimization

• Pilot Testing: Before full deployment, run pilot tests to ensure that the edge computing system is working as expected. This testing phase allows businesses to identify bottlenecks or inefficiencies and make necessary adjustments.
• Performance Optimization: Fine-tune the system for maximum efficiency, ensuring that data processing at the edge is reliable and that any latency is minimized.

6. Ongoing Management and Maintenance

• Monitoring Systems: Continuously monitor the performance of edge devices and applications. Set up alerts and reporting mechanisms to identify potential issues before they cause disruptions.
• Regular Security Audits: Ensure that security protocols are kept up-to-date to protect against cyber threats. Regular security audits should be a part of the ongoing maintenance strategy.

Edge Computing Vendors and Providers

• Amazon Web Services (AWS) IoT Greengrass
  • AWS IoT Greengrass extends AWS services to edge devices so they can act locally on the data they generate while still using the cloud for management, analytics, and storage.
• Microsoft Azure IoT Edge
  • Microsoft Azure IoT Edge is a fully managed service that allows businesses to deploy cloud workloads—such as AI and analytics—to run on IoT edge devices.
• Cisco Edge Computing Solutions
  • Cisco offers a range of edge computing hardware and software solutions, including networking equipment, IoT gateways, and edge computing platforms designed to enhance operational efficiency and security.
  • Visit Cisco Edge Computing Solutions
• HPE Edgeline Converged Edge Systems
  • Hewlett Packard Enterprise (HPE) offers Edgeline systems that combine enterprise IT with operational technology (OT) to manage edge devices and data. These systems are optimized for harsh environments like industrial and manufacturing.
• Dell Technologies Edge Solutions
  • Dell offers edge solutions that help businesses securely process data at the edge while integrating with cloud and data center systems. Their portfolio includes rugged edge servers and IoT solutions for industries like manufacturing and healthcare.
• NVIDIA Edge Computing
  • NVIDIA offers powerful edge computing solutions that leverage GPUs to support AI-driven tasks at the edge. Their Jetson platform is designed for AI processing in edge applications such as robotics and smart cities.

IoT and Edge Device Providers

• Bosch IoT Edge Solutions
  • Bosch provides edge computing hardware and software designed for industrial IoT, enabling businesses to improve process efficiency and reduce latency in critical operations.
• Intel Edge Computing Solutions
  • Intel provides a range of hardware solutions for edge computing, from IoT gateways to processors optimized for real-time data processing at the edge. They also offer software tools to help developers manage edge applications.
• Siemens Edge Computing for Industry
  • Siemens offers edge computing solutions tailored for industrial environments, such as manufacturing, transportation, and energy. Their offerings help integrate OT and IT for real-time data analytics and control.

Edge Computing Software and Platforms

• Foghorn Edge Intelligence
  • FogHorn’s edge intelligence platform enables real-time processing and AI at the edge, ideal for industrial IoT applications such as manufacturing, oil & gas, and utilities.
• EdgeIQ
  • EdgeIQ provides a platform that simplifies the deployment, monitoring, and management of IoT and edge devices. It is designed to help businesses integrate edge data into their enterprise systems seamlessly.
• ClearBlade Edge Platform
  • ClearBlade offers an edge computing platform that helps businesses rapidly deploy, manage, and scale edge IoT applications across multiple devices and environments.
• Vapor IO Kinetic Edge Platform
  • Vapor IO delivers edge colocation, interconnection, and networking services for enterprises looking to distribute workloads across multiple edge sites. Their Kinetic Edge platform supports high-performance edge deployments in sectors like telecommunications and media.

Conclusion

Edge computing is revolutionizing the way data is processed and analyzed in today’s digital landscape – and it’s going to quickly become the standard for ALL industries across the world. There are simply too many benefits to edge computing for people to not adopt this growing tech.

By bringing computation closer to the source of data, edge computing offers faster processing times, reduced latency, and enhanced security. As new technologies such as AI and 5G continue to develop, the role of edge computing will only become more critical for businesses looking to stay competitive in a data-driven world.

If you’re looking to invest in edge computing, now is the time. With the market expected to grow significantly in the coming years, adopting edge computing technologies can provide businesses with a competitive advantage in terms of efficiency, cost savings, and real-time data processing.

That’s all from us in this week’s “What Is:______”. See you next time with a simple breakdown of a complex IT topic!

Additional Resources

• Grand View Research: Edge Computing Market Size & Forecast
• IDC: Edge Computing Spending Guide