Re: QC Hype Watch: Quantum cryptography gets practical

[Dave Howe]

R. A. Hettinga wrote:
Two factors have made this possible: the
vast stretches of optical fiber (lit and dark) laid in metropolitan areas,
which very conveniently was laid from one of your customers to another 
of your customers (not between telcos?) - or are they talking only 
having to lay new links for the last mile and splicing in one of the 
existing dark fibres (presumably ones without any repeaters on it)

RE: QC Hype Watch: Quantum cryptography gets practical

[Tyler Durden]

Yes, I am indeed a little suspicious. Clearly, this quantum repeater can't 
be doing an O/E, or no amount of hype will budge this product an inch.

Quantum Crypto utilizes pairs of correlated photons, so we can't be talking 
about an optical amplifer.

So since I've been away from the literature for a while, is there a device 
that can repair a deteriorating, about-to-be-collapsed superposition state? 
I can't see how this could occur without the requirement of acting on the 
other (correlated) photon either, and if that photon is physically removed 
from the first, then forget about it. (Though theoretically I think I can 
conceive of the possibility of two correlated quantum repeaters exchanging 
'information' (including gating) about the photon pair they are collectively 
handling*, but no way that can be useful commerically.)

*: This isn't quite as farfetched as it seems: Even 5 to 10 years ago it was 
shown that there can be quantum Forward Error Correction, and simple devices 
were demonstrated in the laboratory.

-TD


From: Bill Stewart [EMAIL PROTECTED]
To: Tyler Durden [EMAIL PROTECTED]
CC: [EMAIL PROTECTED], [EMAIL PROTECTED]
Subject: RE: QC Hype Watch: Quantum cryptography gets practical
Date: Fri, 01 Oct 2004 11:59:40 -0700
At 05:12 PM 9/30/2004, Tyler Durden wrote:
What's a quantum repeater in this context?
It's also known as a wiretap insertion point...
 As for Hype Watch, I tend to agree, but I also believe that Gelfond
 (who I spoke to last year) actually does have a 'viable' system.
 Commerically viable is another thing entirely, however.
Practical implies that there's a crossover point between
cost and benefit and that implementation is on the benefit side.
Implementation may now be possible, and the costs may be lower
than their previous infinite value, but the main benefits I see are
public relations hype to impress the rubes and protect against
zero-day exploits against Diffie-Hellman or Cisco IOS.
But you could protect against the Cisco exploits just as easily
with a conventional-key encryption hardware box,
and you wouldn't need contiguous fiber.
_
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RE: QC Hype Watch: Quantum cryptography gets practical

[Bill Stewart]

At 05:12 PM 9/30/2004, Tyler Durden wrote:
What's a quantum repeater in this context?
It's also known as a wiretap insertion point...
 As for Hype Watch, I tend to agree, but I also believe that Gelfond
 (who I spoke to last year) actually does have a 'viable' system.
 Commerically viable is another thing entirely, however.
Practical implies that there's a crossover point between
cost and benefit and that implementation is on the benefit side.
Implementation may now be possible, and the costs may be lower
than their previous infinite value, but the main benefits I see are
public relations hype to impress the rubes and protect against
zero-day exploits against Diffie-Hellman or Cisco IOS.
But you could protect against the Cisco exploits just as easily
with a conventional-key encryption hardware box,
and you wouldn't need contiguous fiber.

RE: QC Hype Watch: Quantum cryptography gets practical

[Tyler Durden]

What's a quantum repeater in this context?
As for Hype Watch, I tend to agree, but I also believe that Gelfond (who I 
spoke to last year) actually does have a 'viable' system. Commerically 
viable is another thing entirely, however.

-TD

From: R. A. Hettinga [EMAIL PROTECTED]
To: [EMAIL PROTECTED], [EMAIL PROTECTED]
Subject: QC Hype Watch: Quantum cryptography gets practical
Date: Thu, 30 Sep 2004 17:39:24 -0400
http://www.computerworld.com/printthis/2004/0,4814,96111,00.html
 - Computerworld
 Quantum cryptography gets practical
 Opinion by Bob Gelfond, MagiQ Technologies Inc.


  SEPTEMBER 30, 2004  (COMPUTERWORLD)  -  In theory and in labs, quantum
cryptography -- cryptography based on the laws of physics rather than
traditional, computational difficulty -- has been around for years.
Advancements in science and in the world's telecommunications
infrastructure, however, have led to the commercialization of this
technology and its practical application in industries where high-value
assets must be secure.
 Protecting information today usually involves the use of a cryptographic
protocol where sensitive information is encrypted into a form that would be
unreadable by anyone without a key. For this system to work effectively,
the key must be absolutely random and kept secret from everyone except the
communicating parties. It must also be refreshed regularly to keep the
communications channel safe. The challenge resides in the techniques used
for the encryption and distribution of this key to its intended parties to
avoid any interception of the key or any eavesdropping by a third party.
 Many organizations are advancing quantum technology and bringing it
outside academia. Research labs, private companies, international alliances
such as the European Union and agencies such as the Defense Advanced
Research Projects Agency are investing tens of millions of dollars in
quantum research, with projects specifically focused on the challenge of
key distribution.
 The trouble with key distribution
Huge investment in the late 1990s through 2001 created a vast
telecommunications infrastructure resulting in millions of miles of optical
fiber laid across the country and throughout buildings to enable high-speed
communications. This revolution combined a heavy reliance on fiber-optic
infrastructure with the use of open network protocols such as Ethernet and
IP to help systems communicate.
 Although this investment delivers increased productivity, dependence on
optical fiber compounds key distribution challenges because of the relative
ease with which optical taps can be used. With thousands of photons
representing each bit of data traveling over fiber, nonintrusive, low-cost
optical taps placed anywhere along the fiber can siphon off enough data
without degrading the signal to cause a security breach. The threat profile
is particularly high where clusters of telecommunications gear are found in
closets, the basements of parking garages or central offices. Data can be
tapped through monitoring jacks on this equipment with inexpensive handheld
devices. This enables data to be compromised without eavesdroppers
disclosing themselves to the communicating parties.
 Another important aspect of this problem is the refresh rate of the keys.
Taking large systems off-line to refresh keys can cause considerable
headaches, such as halting business operations and creating other security
threats. Therefore, many traditional key-distribution systems refresh keys
less than once per year. Infrequent key refreshing is detrimental to the
security of a system because it makes brute-force attacks much easier and
can thereby provide an eavesdropper with full access to encrypted
information until the compromised key is refreshed.
 Adding quantum physics to the key distribution equation
Companies are now in a position to use advancements in quantum
cryptography, such as quantum key distribution (QKD) systems, to secure
their most valued information. Two factors have made this possible: the
vast stretches of optical fiber (lit and dark) laid in metropolitan areas,
and the decreasing cost in recent years of components necessary for
producing QKD systems as a result of the over-investment in
telecommunications during the early 2000s.
 Based on the laws of quantum mechanics, the keys generated and
disseminated using QKD systems have proved to be absolutely random and
secure. Keys are encoded on a photon-by-photon basis, and quantum mechanics
guarantees that the act of an eavesdropper intercepting a photon will
irretrievably change the information encoded on that photon. Therefore, the
eavesdropper can't copy or read the photon -- or the information encoded on
it -- without modifying it, which makes it possible to detect the security
breach. In addition to mitigating the threat of optical taps, QKD systems
are able to refresh keys at a rate of up to 10 times per second, further
increasing the level of security of the encrypted data.
 Not for