Energy efficient encryption for the internet of things
MIT researchers have built a new chip, hardwired to perform public-key encryption,
that consumes only 1/400 as much power as software execution of the same protocols would.
It also uses about 1/10 as much memory and executes 500 times faster by
Massachusetts Institute of Technology.
Most sensitive web transactions are protected by public-key cryptography,
a type of encryption that lets computers share information securely without first agreeing on a secret encryption key.
Public-key encryption protocols are complicated, and in computer networks,
they're executed by software. But that won't work in the internet of things,
an envisioned network that would connect many different sensors—embedded in vehicles, appliances, civil structures, manufacturing equipment, and even livestock tags—to online servers.
Embedded sensors that need to maximize battery life can't afford the energy and memory space that software execution of encryption protocols would require.
MIT researchers have built a new chip, hardwired to perform public-key encryption, that consumes only 1/400 as much power as software execution of the same protocols would.
It also uses about 1/10 as much memory and executes 500 times faster.
The researchers describe the chip in a paper they're presenting this week at the International Solid-State Circuits Conference.
The researchers' chip uses a technique called elliptic-curve encryption.
As its name suggests, elliptic-curve encryption relies on a type of mathematical function called an elliptic curve.
In the past, researchers—including the same MIT group that developed the new chip—have built chips hardwired to handle specific elliptic curves or families of curves.
What sets the new chip apart is that it is designed to handle any elliptic curve.
"Cryptographers are coming up with curves with different properties, and they use different primes," says Utsav Banerjee, an MIT graduate student in electrical engineering and computer science and first author on the paper. "There is a lot of debate regarding which curve is secure and which curve to use, and there are multiple governments with different standards coming up that talk about different curves. With this chip, we can support all of them, and hopefully, when new curves come along in the future, we can support them as well."
that consumes only 1/400 as much power as software execution of the same protocols would.
It also uses about 1/10 as much memory and executes 500 times faster by
Massachusetts Institute of Technology.
Most sensitive web transactions are protected by public-key cryptography,
a type of encryption that lets computers share information securely without first agreeing on a secret encryption key.
Public-key encryption protocols are complicated, and in computer networks,
they're executed by software. But that won't work in the internet of things,
an envisioned network that would connect many different sensors—embedded in vehicles, appliances, civil structures, manufacturing equipment, and even livestock tags—to online servers.
Embedded sensors that need to maximize battery life can't afford the energy and memory space that software execution of encryption protocols would require.
MIT researchers have built a new chip, hardwired to perform public-key encryption, that consumes only 1/400 as much power as software execution of the same protocols would.
It also uses about 1/10 as much memory and executes 500 times faster.
The researchers describe the chip in a paper they're presenting this week at the International Solid-State Circuits Conference.
The researchers' chip uses a technique called elliptic-curve encryption.
As its name suggests, elliptic-curve encryption relies on a type of mathematical function called an elliptic curve.
In the past, researchers—including the same MIT group that developed the new chip—have built chips hardwired to handle specific elliptic curves or families of curves.
What sets the new chip apart is that it is designed to handle any elliptic curve.
"Cryptographers are coming up with curves with different properties, and they use different primes," says Utsav Banerjee, an MIT graduate student in electrical engineering and computer science and first author on the paper. "There is a lot of debate regarding which curve is secure and which curve to use, and there are multiple governments with different standards coming up that talk about different curves. With this chip, we can support all of them, and hopefully, when new curves come along in the future, we can support them as well."
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