The Wayback Machine - https://web.archive.org/web/20120222065152/http://live.psu.edu/story/27265

Still Life

Lady Lions Alex Bentley, left, and Zhaque Gray celebrate their Big Ten championship after beating Ohio State 84-66 on Monday, Feb. 20, at the Bryce Jordan Center on Penn State's University Park campus. The Lady Lions clinched their first conference regular season title since 2004.

Lady Lions win Big Ten championship

THON 2012 shattered last year's total, raising $10,686,924.83 for the Four Diamonds Fund.

THON 2012 breaks $10 million

THON child Megan Eslinger, 4, chases bubbles blown by dancer Elizabeth Ferrari on Saturday afternoon, Feb. 18, during THON at the Bryce Jordan Center on Penn State's University Park campus. The 46-hour no-sitting, no-sleeping event raises millions of dollars each year for the Four Diamonds Fund.

THON 2012 going strong

Owen Divers and Quinn Allen started off strong for THON 2012 on Friday, Feb. 17.

THON 2012 under way

Mike Rybar made final adjustments to the Penn State Institute of Electrical and Electronic Engineering teams Goldberg machine prior to the 2012 Rube Goldberg competition held on Feb. 11 at Penn State's Nittany Lion Inn. Rybar and his team created a musically themed machine that needed to complete a simple task (inflate a balloon) in twenty or more elaborate steps. The annual competition is named for cartoonist Rube Goldberg who created famous artwork depicting overly complicated machines doing everyday tasks.

Rube Goldberg Competition: Feb. 11, 2012

Featured Video

We ... are Penn State (December 19, 2011)

We ... are Penn State (December 19, 2011)

Penn State's creamery, from the cow to the cone

Penn State's creamery, from the cow to the cone

Researchers use balloons to unlock mysteries posed by dying stars

Researchers use balloons to unlock mysteries posed by dying stars

Everyday virus proves potent against cancer cells.

Everyday virus proves potent against cancer cells.

Researchers push transmission rate of copper cables

Wednesday, November 14, 2007

Atlanta -- You may not be able to get blood out of a turnip, but according to Penn State engineers, you can increase the data transmission of Category-7 copper cables used to connect computers to each other and the Internet.

"Working with NEXANS, the company that manufactures the cable, we have examined the possibility of sending digital data at a rate of 100 gigabits per second over 100 meters of Category-7 copper cable," said Mohsen Kavehrad, the W.L. Weiss endowed chair professor of electrical engineering. "These are the current, new generation of Ethernet cables."

These cables are used to connect computers within a room or a building or to create parallel computing systems. While the long distance lines of most Internet systems are glass fiber optic cables, which are very fast, copper cable is generally used for short distances.

"In home networks, for example, it is expensive to use fiber optic cabling," said Ali Enteshari, graduate student in electrical engineering who presented the team's methods to the IEEE High Speed Study Group Wednesday (Nov. 14) in Atlanta.

All transmission cables are limited by the distance they can transmit data without degradation of the signal. Before errors and interference make the signals nonrecoverable, cable systems use repeaters -- which are similar to computer modems -- to capture, correct or recover data, and resend it. The distance between repeaters depends on the cable and the approach used by the modem to correct errors.

"What we are offering is a less expensive solution and one that is easier to build," said Jarir Fadlullah, graduate student in electrical engineering.

Using information on specifications and characteristics of the cables from NEXANS, the researchers modeled the cable with all its attributes including modeling crosstalk. They then designed a transmitter/receiver equipped with an interference canceller that could transfer up to 100 gigabits using error correcting and equalizing approaches.

Ethernet cable like the Category 7 is made up of four pairs of twisted wires shielded to reduce crosstalk. Category 7 is heavier weight wire with better shielding than Category 5 cable. Kavehrad's group did similar analysis on the Category 5 cables in 2003.

"A rate of 100 gigabit over 70 meters is definitely possible, and we are working on extending that to 100 meters, or about 328 feet," said Enteshari. "However, the design of a 100 gigabit modem might not be physically realizable at this time as it is technology limited. We are providing a roadmap to design a high speed modem for 100 gigabits."

The researchers believe that two or three generations in the future, the technology of chip circuitry will allow these modem designs to be built. Currently, chip design is at about 65 nanometers, but they expect in the next two generations to get to what is required, said Kavehrad.

The amount of data encompassed by 100 gigabits is amazing. The entire Encyclopedia Britannica contains 1 gigabyte of information. A byte is equivalent to 8 bits, so 1 Gigabyte is equal to 8 gigabits. A rate of 100 gigabits per second over 100 meters is the transmission of 12.5 Encyclopedia Britannica sets per second.