Researchers Crack The World’s Toughest Encryption By Listening To The Tiny Sounds Made By Your Computer’s CPU

Researchers crack the world’s toughest encryption by listening to the tiny sounds made by your computer’s CPU

Researchers crack the world’s toughest encryption by listening to the tiny sounds made by your computer’s CPU

Security researchers have successfully broken one of the most secure encryption algorithms, 4096-bit RSA, by listening – yes, with a microphone — to a computer as it decrypts some encrypted data. The attack is fairly simple and can be carried out with rudimentary hardware. The repercussions for the average computer user are minimal, but if you’re a secret agent, power user, or some other kind of encryption-using miscreant, you may want to reach for the Rammstein when decrypting your data.

This acoustic cryptanalysisside channel attack. A side channel is an attack vector that is non-direct and unconventional, and thus hasn’t been properly secured. For example, your pass code prevents me from directly attacking your phone — but if I could work out your pass code by looking at the greasy smudges on your screen, that would be a side channel attack. In this case, the security researchers listen to the high-pitched (10 to 150 KHz) sounds produced by your computer as it decrypts data.

This might sound crazy, but with the right hardware it’s actually not that hard. For a start, if you know exactly what frequency to listen out for, you can use low- and high-pass filters to ensure that you only have the sounds that emanate from your PC while the CPU decrypts data. (In case you were wondering, the acoustic signal is actually generated by the CPU’s voltage regulator, as it tries to maintain a constant voltage during wildly varied and bursty loads). Then, once you have the signal, it’s time for the hard bit: Actually making sense of it.

In terms of real-world repercussions, acoustic cryptanalysis is actually surprisingly dangerous. Imagine if you were decrypting some files in a library, coffee shop, or other public space — someone could obtain your decryption key just by placing their phone near your computer. Alternatively, an attacker could use spear phishing to put malware on your phone that listens for the decryption key. With HTML5 and Flash able to access the microphone, it would be possible to build a website that listens for encryption keys too. The researchers propose one particularly nefarious scenario: Put a microphone into a co-located server, slot it into a rack in a data center, and then scoop up the encryption keys from hundreds of nearby servers.

If you want to keep your data secure, you only really have two viable options: Heavy-duty encryption, physical security, and ideally both at the same time. If an attacker can’t get physically close to your data, it instantly becomes much harder to steal it. As far as mitigating acoustic cryptanalysis attacks, you either implement physical security — keep your laptop in a sound-tight box, or never let anyone near your computer when you’re decrypting data — or you need to use a “sufficiently strong wide-band noise source.” Something like a swooping, large-orchestra classical concerto would probably do it.