Carnegie Mellon engineers revolutionized magnetic recording computer disk drive chip

 

February 17, 2016

Digital devices have come a long way in the last few decades, particularly as they continue to shrink in size. Many advances, including new recording media, disk drive heads, and disk architectures, have contributed to making today’s computer drives compact while being able to store and read amazing amounts of data. But as the size of disk drives became relentlessly smaller and were able to store tremendously more data, a major challenge developed. 

How can the computer successfully recover and read the bits of data stored on miniature disk drives?

Over the last 30 years, Carnegie Mellon engineers have contributed in many different ways to the progress of disk drive storage and, and in particular, significantly contributed to solving the challenge of accurately reading bits of data crammed into minuscule places. 

Back in the 1950s, a typical computer disk drive was approximately five feet in diameter and could store no more than 1 million, or a megabyte (MB), of data.  For reference, an MP3 audio file a few minutes in length, or a 10 million-pixel image from a digital camera, typically takes up several tens of megabytes. Fast forward to present day where disk drives are a few inches in diameter and can store terabytes (TB) of data (1 TB  = 1 million MB).

As disk drives decreased in size and the amount of data being stored increased exponentially, researchers became concerned about the ability to accurately recover and successfully read the stored bits of data. Carnegie Mellon’s Data Storage Systems Center (DSSC) is a world-leading academic research institution in data storage that focuses on magnetic data storage technology for hard disk drive applications.

In the early 1990s, José Moura, a professor in Carnegie Mellon’s College of Engineering, along with his then Ph.D. student Aleksandar Kavcic, now a professor at the University of Hawaii, set out to find an innovative way to accurately recover bits from the ever-shrinking storage disk drives of the future.

Kavcic and Moura invented and patented a detector that could safely and accurately extract recorded data from disk drives. When the early 2000s recording technology changed to perpendicular recording, their detector algorithm invention became a must-have technology. 

“Alek Kavcic and I chose to target the limitations that were sure to arise in reading bits in magnetic recording in the future,” says Moura. “Instead of looking for quick payoffs from incremental improvements, we invested our efforts in understanding and abstracting the fundamentals. In a moment of serendipity, we were able to develop a simple, fundamental new way to account for the main physical limitations of magnetic recording and to invent a detector that outperformed all others.”

It is estimated that the disk drives in 60% of computers (over 3 billion) made in the last 14 years contain this detector technology enabling users to recover saved data. 

“Our patience paid off in the 2000s when industry faced the inevitability of its own success,” says Moura, “It needed a fundamentally new approach that was simple to implement and could read back the enormous amount of data being packed into very small spaces. The rest is history and our patents became crucial to read channel chip manufacturers.” 

Looking to the future, Moura is developing algorithms that digest the tremendous amount of data being collected from multiple sources in everyday life. Nowadays, cities are covered in sensors that monitor security, weather, traffic patterns, energy consumption, pollution levels, and more. The data from these sensors allow us to understand the normal social behavior in a particular city. By addressing these data-rich environments, Moura hopes to understand the normal—and abnormal—behaviors of cities, from traffic jams to inconspicuous sources of pollution to unbearable sources of noise. Ultimately, Moura’s data analytics may help urban planners rethink the way they envision cities.

“If urban planners better understand city bottlenecks, they could reimagine a city and have major social and environmental impact,” says Moura. "And give city dwellers a more pleasant day-to-day life. We live in interesting times. For the past few decades, society has shaped technology. Moving forward, technology is helping to shape society. And that is pretty amazing.”


The impact of signal processing 

Signal processing is the technology behind technology. It develops algorithms to process the massive amounts of data generated, collected, and stored in disk drives and extracts knowledge and actionable wisdom. This enabling technology is vital in many fields, including wireless communications, smartphones, medical MRI/CAT scans, drilling for oil, aviation, cable and broadcast TV, radar, or sonar. 

A simple cellphone conversation is a prodigy of successful technologies; but having that conversation would not be possible without the algorithms derived from signal processing. When we speak into a cellphone, our voice is a sound wave converted into an electrical signal that, in turn, is sent to a wireless cell tower by electromagnetic waves. These waves are transferred to a fiber optic or satellite link, then travel around the world to be delivered to a user thousands of miles away. The process is almost instantaneously reversed, and the parties can continue their conversation.

“Signal processing is often referred to as a stealth technology,” says Moura. “It’s something users can’t see, but it is vital to our everyday life.” 

Related People:

José Moura

Related Links:

Carnegie Mellon homepage article