Press Release:
Topics:

HP Reveals Groundbreaking Design for Future Nano-electronic Circuits

New approach could enable low-cost, high-yield fabrication
PALO ALTO, Calif., June 9, 2005

» View the HP nanotech circuit illustration

HP today announced that its researchers have created a new way to design future nano-electronic circuits using coding theory, an approach currently being used in certain computer storage and telecommunications applications. The result could be nearly perfect manufacturing yields with equipment a thousand times less expensive than what might be required using future versions of current technologies.

In a paper appearing in the June 6 issue of "Nanotechnology," a publication of the Institute of Physics, HP Labs authors Phil Kuekes, Warren Robinett, Gadiel Seroussi and Stan Williams explain in detail a defect-tolerant interface to HP's patented crossbar architecture.

"We have invented a completely new way of designing an electronic interconnect for nano-scale circuits using coding theory, which is commonly used in today's digital cell phone systems and in deep-space probes," said Williams, HP Senior Fellow and director, Quantum Science Research at HP Labs. "By using a cross-bar architecture and adding 50 percent more wires as an 'insurance policy,' we believe it will be possible to fabricate nano-electronic circuits with nearly perfect yields even though the probability of broken components will be high."

Williams said he believes future chips will have to rely, at least in part, on the crossbar architecture, in which a set of parallel nanoscale wires are laid atop another set of parallel wires at approximately a 90 degree angle, sandwiching a layer of electrically switchable material in between. Where the material becomes trapped between the crossing wires, they can form a switch that represents a "1" or "0," the basic building blocks of computer code.

Future chips may be limited in the geometric complexity that can be created at the nano level because of problems with precision alignment. Crossbar structures are highly regular and therefore relatively easier and less expensive to fabricate than the complex array of wires, transistors and other elements in today's processors. The disadvantage of crossbars is that the conventional CMOS wires connecting them to the rest of the circuit require more space on the silicon substrate.

"We think the tradeoff of space versus manufacturing ease will become more an issue in the near future," said Williams.

Furthermore, as sizes of electronic features get down to a few nanometers, it will become either physically impossible - or economically unfeasible - to produce absolutely perfect circuits.

"Future chip manufacturers will have to deal with the reality of defects," said Williams.

HP's approach involves enhancing a device known as a demultiplexer, which enables data to be read and written in a circuit by connecting the crossbar array of nanowires to a small number of conventional wires. By adding a few more conventional wires and using basic coding theory, the HP researchers show that the demultiplexer will still work even if a significant number of the connections between the conventional wires and the nanowires are broken.

The coding approach was advanced by Seroussi, director of Information Theory Research at HP Labs. "Coding theory has been used in computer storage and communication for many years," said Seroussi. "Here, we apply it to the fabrication of a hardware circuit."

"It's like giving a distinctive name to a restaurant host to be sure you hear your party called above the noise of the crowd," said Kuekes, a senior computer architect, in explaining how coding theory works. "Instead of 'the Jones party,' you might put yourself down as 'the John Paul Jones party.' That way, when the host calls your name, you'll hear it, even if every word doesn't come through clearly."

Using defect tolerance to replace the need to produce "perfect" chips could provide a huge cost advantage for chip manufacturers in the future.

Williams said the HP Labs group has created working devices in the laboratory at the 30 nanometer half-pitch scale - about a third the size of today's chips. The International Technology Roadmap for Silicon, the standard for the industry, predicts that chips using features at 32 nanometers half pitch should be in production in about seven to eight years.

About HP

HP is a technology solutions provider to consumers, businesses and institutions globally. The company's offerings span IT infrastructure, global services, business and home computing, and imaging and printing. For the four fiscal quarters ended April 30, 2005, HP revenue totaled $83.3 billion. More information about HP (NYSE, Nasdaq: HPQ) is available at http://www.hp.com.


This news release contains forward-looking statements that involve risks, uncertainties and assumptions. If such risks or uncertainties materialize or such assumptions prove incorrect, the results of HP and its consolidated subsidiaries could differ materially from those expressed or implied by such forward-looking statements and assumptions. All statements other than statements of historical fact are statements that could be deemed forward-looking statements, including the expected development, performance or rankings of products or services; statements of expectation or belief; and any statement of assumptions underlying any of the foregoing. Risks, uncertainties and assumptions include the development, performance and market acceptance of products and services and other risks that are described from time to time in HP's Securities and Exchange Commission reports, including but not limited to HP's Quarterly Report on Form 10-Q for the fiscal quarter ended Jan. 31, 2005, and other reports filed after HP's Annual Report on Form 10-K for the fiscal year ended Oct. 31, 2004. HP assumes no obligation and does not intend to update these forward-looking statements.

About HP

HP Inc. creates technology that makes life better for everyone, everywhere. Through our portfolio of printers, PCs, mobile devices, solutions, and services, we engineer experiences that amaze. More information about HP Inc. is available at http://www.hp.com.