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MEDIA CONTACT: Megan Fellman at (847) 491-3115 or fellman@northwestern.edu
November 11, 2002
Keeping Information Secure With Noisy
Light
Prem Kumar |
EVANSTON, Ill. — Put aside images of World War II espionage
and codebreaking. Today cryptography is vital to the security
of a form of communication and commerce never imagined 60
years ago: the Internet. Researchers at Northwestern University
now have demonstrated a new high-speed quantum cryptography
method that uses the properties of light to encrypt information
into a form of code that can only be cracked by violating
the physical laws of nature.
In the open and global communication world of the Internet,
information security is a critical issue because conventional
cryptographic technologies cannot be relied upon for long-term
security. Once optimized, the Northwestern method could replace
the mathematical cryptography currently used by businesses,
financial institutions and the military for secure communication.
The innovative protocol promises security even against information
security’s greatest foe: the not-yet-invented but still-feared
powerful quantum computer, which could break almost any conventional
code.
"As computing power and data traffic grow and information
speeds get faster, cryptography is having a hard time keeping
up," said Prem Kumar, professor of electrical and computer
engineering at the McCormick School of Engineering and Applied
Science and co-principal investigator on the project. "New
cryptographic methods are needed to continue ensuring that
the privacy and safety of each person’s information is
secure.
"Our research team has succeeded in encrypting real
information, sending the message over a University fiber optics
system at very high speeds, and decrypting the information,
which is no small feat. Other quantum cryptography methods
are slow and impractical for long-distance or high-speed communication,
whereas ours shows great potential for real-world applications."
The researchers transmitted encrypted data at the rate of
250 megabits per second. Because it uses standard lasers,
detectors and other existing optical technology to transmit
large bundles of photons, the Northwestern protocol is more
than 1,000 times faster than its main competitor, a technique
based on single photons that is difficult and expensive to
implement.
"No one else is doing encryption at these high speeds,"
said Kumar, who has a secondary appointment in the department
of physics and astronomy at the Judd A. and Marjorie Weinberg
College of Arts and Sciences.
The Northwestern method, which is geared toward securing
the public fiber optic infrastructure, uses a form of "secret
key" cryptography. In this type of cryptography, the
two people communicating, say Alice and Bob, have the same
secret key. If Alice wants to send a secure message to Bob,
she sends a message in a "locked box," which Bob
can open.
In the case of the Northwestern method, to encode her message
Alice uses the key to manipulate the light, creating a pattern
more complex than just "on" or "off."
The method takes advantage of the granularity of light, known
as quantum noise, which is integrated with the secret key’s
pattern. (Random polarization is one way to change the light’s
granularity.) To someone without the key, say the eavesdropper
Eve, the information is indecipherable — the stolen message
contains too much "noise." Bob, with the secret
key, has the pattern and can receive the signal with much
less noise, allowing him to read Alice’s encoded message.
Having demonstrated that their high-speed encryption protocol
works on a real network with real data, the researchers now
are working toward speeds of 2.5 gigabits per second, which
is the rate at which regular information is currently transmitted
over the Internet’s fiber optic network.
"Current cryptographic schemes are vulnerable because
as computers get more powerful the cryptography gets slower
due to longer and longer keys," said Horace Yuen, professor
of electrical and computer engineering with a secondary appointment
in physics and astronomy. He is principal investigator and
theorist on the cryptography project.
"What we offer is a quantum cryptography system that
is unconditionally secure, fast, easy to manage and cost-efficient.
Our technology promises a realistic security solution to increasing
computing power. We expect to develop a practical application
within five years."
The Northwestern research team is working with two industrial
partners, Telcordia Technologies of Red Bank, N.J., and BBN
Technologies of Cambridge, Mass., to develop prototype systems
for integration into the core optical networks of the Internet.
Northwestern has filed a number of patents based on the
technology developed at the University.
The quantum cryptographic research project is supported
by a five-year, $4.7 million grant from the Defense Advanced
Research Projects Agency (DARPA). The communication protocol
that is the backbone of today’s Internet came out of
a computer networking system begun by DARPA in the 1960s.
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