Your search keyword '"Paul I. Bunyk"' showing total 3 results

1. Vision for single flux quantum very large scale integrated technology

Author

Arnold H. Silver, A. W. Kleinsasser, Paul I. Bunyk, and J.W. Spargo

Subjects

Digital electronics, Very-large-scale integration, Josephson effect, Physics, business.industry, Metals and Alloys, Electrical engineering, Condensed Matter Physics, CMOS, Rapid single flux quantum, Magnetic flux quantum, Hardware_INTEGRATEDCIRCUITS, Materials Chemistry, Ceramics and Composites, Electronics, Electrical and Electronic Engineering, business, Electronic circuit

Abstract

Single flux quantum (SFQ) electronics is extremely fast and has very low on-chip power dissipation. SFQ VLSI is an excellent candidate for high-performance computing and other applications requiring extremely high-speed signal processing. Despite this, SFQ technology has generally not been accepted for system implementation. We argue that this is due, at least in part, to the use of outdated tools to produce SFQ circuits and chips. Assuming the use of tools equivalent to those employed in the semiconductor industry, we estimate the density of Josephson junctions, circuit speed, and power dissipation that could be achieved with SFQ technology. Today, CMOS lithography is at 90?65?nm with about 20 layers. Assuming equivalent technology, aggressively increasing the current density above 100?kA?cm?2 to achieve junction speeds approximately 1000?GHz, and reducing device footprints by converting device profiles from planar to vertical, one could expect to integrate about 250?M Josephson junctions cm?2 into SFQ digital circuits. This should enable circuit operation with clock frequencies above 200?GHz and place approximately 20?K gates within a radius of one clock period. As a result, complete microprocessors, including integrated memory registers, could be fabricated on a single chip.

Published

2006

2. Development of superconductor electronics technology for high-end computing

Author

L. Abelson, A. W. Kleinsasser, A. Silver, Paul I. Bunyk, Quentin P. Herr, G. Kerber, and Mikhail Dorojevets

Subjects

Very-large-scale integration, business.industry, Computer science, Clock rate, Metals and Alloys, 8-bit, Electrical engineering, 32-bit, Condensed Matter Physics, Chip, Electric power transmission, Materials Chemistry, Ceramics and Composites, Electronics, Electrical and Electronic Engineering, business, Electronic circuit

Abstract

This paper describes our programme to develop and demonstrate ultra-high performance single flux quantum (SFQ) VLSI technology that will enable superconducting digital processors for petaFLOPS-scale computing. In the hybrid technology, multi-threaded architecture, the computational engine to power a petaFLOPS machine at affordable power will consist of 4096 SFQ multi-chip processors, with 50 to 100 GHz clock frequency and associated cryogenic RAM. We present the superconducting technology requirements, progress to date and our plan to meet these requirements. We improved SFQ Nb VLSI by two generations, to a 8 kA cm−2, 1.25 µm junction process, incorporated new CAD tools into our methodology, demonstrated methods for recycling the bias current and data communication at speeds up to 60 Gb s−1, both on and between chips through passive transmission lines. FLUX-1 is the most ambitious project implemented in SFQ technology to date, a prototype general-purpose 8 bit microprocessor chip. We are testing the FLUX-1 chip (5K gates, 20 GHz clock) and designing a 32 bit floating-point SFQ multiplier with vector-register memory. We report correct operation of the complete stripline-connected gate library with large bias margins, as well as several larger functional units used in FLUX-1. The next stage will be an SFQ multi-processor machine. Important challenges include further reducing chip supply current and on-chip power dissipation, developing at least 64 kbit, sub-nanosecond cryogenic RAM chips, developing thermally and electrically efficient high data rate cryogenic-to-ambient input/output technology and improving Nb VLSI to increase gate density.

Published

2003

3. Synchronization of multiple coupled rf-SQUID flux qubits

Author

Bruce Bumble, Anupama B. Kaul, Andrew J. Berkley, Siyuan Han, A. Fung, J. Johansson, Trevor Lanting, Richard Harris, Mark W. Johnson, Paul I. Bunyk, Frederico Brito, A. Kleinsasser, and E. Ladizinsky

Subjects

Physics, Josephson effect, Flux qubit, Condensed Matter - Mesoscale and Nanoscale Physics, FOS: Physical sciences, General Physics and Astronomy, Synchronizing, Persistent current, Quantum Physics, Topology, Chip, 01 natural sciences, 010305 fluids & plasmas, Inductance, Computer Science::Emerging Technologies, Condensed Matter::Superconductivity, Qubit, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), 0103 physical sciences, Hardware_ARITHMETICANDLOGICSTRUCTURES, 010306 general physics, Quantum computer

Abstract

A practical strategy for synchronizing the properties of compound Josephson junction rf-SQUID qubits on a multiqubit chip has been demonstrated. The impacts of small ($\sim1%$) fabrication variations in qubit inductance and critical current can be minimized by the application of a custom tuned flux offset to the CJJ structure of each qubit. This strategy allows for simultaneous synchronization of the qubit persistent current and tunnel splitting over a range of external bias parameters that is relevant for the implementation of an adiabatic quantum processor.

Published

2009