[transhumantech] Researchers demo wireless chip-interconnect scheme
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- Subject: [transhumantech] Researchers demo wireless chip-interconnect scheme
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- Date: Thu, 2 Mar 2000 13:22:39 +1000
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From: Alejandro Dubrovsky <s335984@student.uq.edu.au>
http://www.eetimes.com/story/OEG20000301S0031
By David Lammers <mailto:dlammers@cmp.com>
EE Times <http://www.eetimes.com>
(03/01/00, 4:26 p.m. EST)
AUSTIN, Texas - With wireless technology now successfully connecting
millions of users across the global cellular network, can wireless
interconnects for chips be far behind?
Among those asking the question is a research group from the University of
Florida at Gainesville that has responded with a working test chip that uses
radio frequency to distribute a clock signal at 7.4 GHz. The technology also
could prove useful in distributing a synchronous clock across ICs on a
module.
The program has been under way for three years, supported by modest funding
- about $150,000 per year - from Semiconductor Research Corp. At last
month's International Solid-State Circuits Conference in San Francisco,
associate electronics engineering professor Kenneth O, and two graduate
students participating in the project, Brian Floyd and Kihong Kim, described
a successful test chip with a limited number of active circuits between the
transmit and receive modules on the edges of the die.
"We are basically creating a new architecture," O said. "The goal is to
investigate the trade-off between driving large wires across the chip, as in
a conventional approach, or the ability with this clock transmitter to
synchronize the clock across a large die size, or even to break the
bottleneck between 2D and 3D structures."
"People are somewhat skeptical whether this approach will be able to
overcome the noise issue," said Bob Havemann, an interconnect expert with
Texas Instruments Inc. who is now on assignment to International Sematech
here. "But the chip sizes are not getting any smaller, and unless the
industry moves to an asynchronous clock, the long interconnects for the
clock are going to be a problem."
Collision course
"My biggest concern is that the industry is not doing enough to understand
the design issues in these very high-frequency circuits," Havemann said. "We
are on a collision course between digital and RF as we move to a gigahertz
and beyond." Havemann likened the Florida research to the communications
systems of Star Trek's Borg spaceship, in which everyone on board is
connected to a wireless comms system.
O acknowledged that maintaining a good signal-to-noise ratio is the major
challenge in sending a radio signal across a die with millions of switching
transistors and interference from metal structures.
The test chip includes antennas measuring 2 millimeters long and 10
micrometers wide, fabricated in the metal-five layer and separated from the
substrate by about 7 micrometers of oxide. "What we are trying to do is get
a lower clock skew, but it is not clear if that will be possible," O said.
Floyd said the next step is to increase the frequency of the transmit and
receive circuits to 20 GHz or higher, with 30 GHz as a "conservative goal"
even as the antennas get smaller. While it will not be difficult to increase
the frequency of the antennas in more advanced design rules, synchronization
across the chip may present a challenge, he said.
The structures include low-noise amplifiers and buffers that shift the
voltage level to a series of frequency dividers. To achieve an acceptable
signal-to-noise ratio, the high-frequency transmit signal is divided - in
this case in an 8:1 architecture - to the local clock frequency. But O said
it remains to be seen whether the approach can overcome the signal-to-noise
problem.
The Florida project is competing with efforts at Vanderbilt University and
elsewhere to use optical interconnects, but the Florida group is ahead in
the sense that it has demonstrated send and receive capabilities. Any "free
space" interconnect scheme, in which a signal can be "seen" by all of the
circuits on a device, presents shielding and other challenges.
Also, building the tiny antenna and receive modules in an RF interconnect
approach takes up silicon real estate. Optical interconnect has a similar
challenge: Building an on-chip laser requires, in most cases, a compound
semiconductor process.
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