How Better Data Compression Leads to Energy Savings

Did you know that by 2025, the global datasphere is predicted to reach more than 180 zettabytes? Managing this ever-growing mountain of data requires significant energy consumption and contributes to greenhouse gas emissions. Data compression, a process of reducing the size of data files, plays a crucial role in addressing this challenge. By minimizing the amount of data that needs to be stored and transmitted, data compression can lead to significant energy savings. 

In this article, we'll explore the concept of data compression, its benefits, and how implementing efficient data compression techniques can contribute to both energy savings and improved operational efficiency.

What Is Data Compression?

Data compression is a technique used to reduce the size of data files, making them easier to store and transmit. Using techniques such as delta encoding, the primary goal of data compression is to minimize the amount of space required to store data and the bandwidth needed to transmit it without compromising the quality or integrity of the original information or with an acceptable trade-off in quality.

Types of Data Compression Algorithms

There are two major types of data compression algorithms in use today: lossless and lossy compression algorithms.

• Lossless compression: This type of compression algorithm allows the original data to be perfectly reconstructed from the compressed data. Common algorithms include ZIP, GZIP, and PNG. Lossless compression works by identifying and removing redundancies in the data. For example, a text file containing repetitive phrases can be compressed by replacing those repetitions with shorter codes. This reduces the file size, and the placeholders can be replaced later without any loss in quality.
• Lossy compression: This type reduces data size by permanently eliminating certain information, especially redundant or nonessential data. This can result in a slight loss of quality but often to a degree that is imperceptible to the human eye. Common algorithms include JPEG for images, MP3 for audio, and MP4 for video. Lossy compression achieves smaller file sizes by discarding information deemed less important to the human user.

Advantages of Data Compression

Regardless of the type of data compression algorithm you use, the size of the original file/data is reduced, which gives many advantages, including:

• Storage efficiency: Compressed files take up less space on storage devices, allowing more data to be stored in the same physical space.
• Transmission efficiency: Compressed files require less bandwidth, leading to faster data transfer rates and reduced network congestion.
• Cost savings: By reducing storage and transmission needs, data compression can lower costs associated with data management.
• Improved backup and archiving: Data compression can significantly reduce the time and storage required for backups and archiving critical data.
• Faster processing: In some cases, compressed data can lead to faster processing times for applications that need to access and analyse the information. This is because less data needs to be moved around during processing.

Energy Consumption in Data Storage

Data storage systems, including data centers and cloud storage services, consume significant energy. This is due to the power needed for servers, maintaining optimal operating temperatures for hardware, and managing data redundancy and backup processes.

According to a report by Newmark, data centre power consumption in the US is set to reach 35GW by 2030. With the recent boom in cloud computing and artificial intelligence, this number has increased significantly.

Implementing data compression techniques can significantly reduce this energy usage and its environmental impact. For example, a company that adopts efficient data compression for its storage solutions could potentially reduce its energy consumption by up to 40%. By estimation, widespread data compression practices could reduce millions of tons of CO2 emissions annually.

How Data Compression Reduces Energy Usage

One notable example of the impact of data compression on energy consumption is Google's Brotli compression algorithm, introduced around 2016. Brotli achieves higher compression ratios than previous algorithms like Gzip, leading to faster page loads and reduced data transfer. This not only enhances user experience but also results in significant energy savings. According to Google, using Brotli compression can reduce data usage by up to 20%, leading to proportional energy savings in data transmission.

Like Brotli, data compression can help reduce energy consumption in data storage systems in several ways, including:

• Reduced storage space: Compressed data requires less physical storage space, which means fewer storage devices are needed. This leads to lower energy consumption for powering and cooling storage hardware.
• Efficient data management: Compressed data files are easier and faster to manage in several ways. They’re faster to retrieve and require less bandwidth to transfer across networks, reducing energy consumption during data transmission.
• Extended hardware lifespan: By minimizing the amount of data that needs to be stored, data compression can reduce wear and tear on storage devices, leading to longer hardware lifespans and less frequent replacements. This can lower the environmental impact of discarded hardware.

Benefits of Better Data Compression

In addition to energy savings and other advantages we've discussed already, implementing efficient data compression techniques can also offer the following benefits:

• Improved performance: Compressed data files are quicker to transmit and process, enhancing system performance and faster application response times. Faster data processing times can lead to quicker turnaround times for tasks like data analysis and report generation.
• Environmental sustainability: Reducing energy consumption through data compression contributes to lower greenhouse gas emissions, supporting corporate sustainability goals.
• Scalability: Efficient data compression allows businesses to scale their data operations more effectively. Compressed data archives require less physical storage space, allowing businesses to store more data on existing infrastructure before needing to invest in additional storage hardware.

Potential Drawbacks

While data compression offers many benefits, it is not without potential drawbacks, including:

• Processing overhead: Compressing and decompressing data requires computational resources, which can introduce processing overhead. However, modern hardware is often powerful enough to handle compression tasks efficiently. Advancements in hardware-assisted compression can also minimize the impact on processing power.
• Quality loss: In lossy compression, there is a trade-off between file size and data quality. This may not be acceptable for all types of data. It's important to choose the appropriate compression algorithm based on the specific data type and acceptable quality loss.
• Complexity: Implementing and managing data compression techniques can add complexity to data management processes. However, many modern storage solutions offer built-in compression features, simplifying the process for businesses.

Final Notes

Data compression is a powerful tool for managing the growing volume of data in today's digital landscape. By reducing the size of data files, data compression helps to minimize storage and transmission requirements, leading to significant energy savings. These energy savings result in cost reductions, improved performance, and environmental benefits.

For businesses seeking advanced data compression solutions, Pure Storage offers innovative products like FlashArray™ and FlashBlade®, which provide industry-leading data reduction and data deduplication capabilities. These solutions can help your business achieve significant energy and cost savings while enhancing the efficiency and performance of your data storage and transmission systems.