Abstract: Architecture for a programmable logic device is described which can operate at substantially faster clock rates than present programmable logic devices. The PLD uses BiCMOS circuit elements to make use of the speed advantages of bipolar technology while also enjoying the limited power consumption of CMOS technology.
Type:
Grant
Filed:
January 16, 1997
Date of Patent:
September 15, 1998
Assignee:
Dyna Logic Corporation
Inventors:
Paul T. Sasaki, Suresh M. Menon, Tsung C. Whang
Abstract: Architecture for a programmable logic device is described which can operate at substantially faster clock rates than present programmable logic devices. The PLD uses BiCMOS circuit elements to make use of the speed advantages of bipolar technology while also enjoying the limited power consumption of CMOS technology.
Type:
Grant
Filed:
January 16, 1997
Date of Patent:
April 28, 1998
Assignee:
Dyna Logic Corporation
Inventors:
Paul T. Sasaki, Suresh M. Menon, Tsung C. Whang
Abstract: Architecture for a programmable logic device is described which can operate at substantially faster clock rates than present programmable logic devices. Instead of employing passive circuit elements to interconnect the programmable logic elements and the input and output data buses, controllable active driver circuits are employed. These circuits eliminate essentially all of the resistance present in prior art passive connections.
Abstract: Architecture for a programmable logic device is described which can operate at substantially faster clock rates than present programmable logic devices. The PLD uses BiCMOS circuit elements to make use of the speed advantages of bipolar technology while also enjoying the limited power consumption of CMOS technology.
Type:
Grant
Filed:
June 5, 1995
Date of Patent:
March 25, 1997
Assignee:
Dyna Logic Corporation
Inventors:
Paul T. Sasaki, Suresh M. Menon, Tsung C. Whang
Abstract: A high speed switching technology suitable for implementing field programmable gate arrays using current mode logic in the high speed data path, and CMOS steering logic outside the high speed data path to enable the high speed switching logic and to implement multiplexer, selector and crossbar switch functions. High speed emitter follower logic compatible with the high speed switching logic for level shifting, buffering, and providing more current sink or source capacity is also disclosed.
Abstract: Architecture for a programmable logic device is described which can operate at substantially faster clock rates than present programmable logic devices. Instead of employing passive circuit elements to interconnect the programmable logic elements and the input and output data buses, controllable active driver circuits are employed. These circuits eliminate essentially all of the resistance present in prior art passive connections.
Abstract: A high speed switching technology suitable for implementing field programmable gate arrays using current mode logic in the high speed data path, and CMOS steering logic outside the high speed data path to enable the high speed switching logic and to implement multiplexer, selector and crossbar switch functions. High speed emitter follower logic compatible with the high speed switching logic for level shifting, buffering, and providing more current sink or source capacity is also disclosed.
Abstract: There is disclosed herein a method and apparatus for distributing high speed clock signals on an integrated circuit while eliminating clock skew. The invention is particularly useful in field programmable gate arrays where the signal paths are defined by the user after the integrated circuit leaves the place of manufacture and enables field programmable gate arrays to operate at clock speeds in excess of 200 MHz, a speed not previously attainable. Clock skew is eliminated by generating differential clock signals at each of four corners of the array from master differential clock signal delivered simultaneously to each of the four corners. The differential clock signals generated at each corner have ramps the rise time of which slightly exceeds the propagation delay of a clock signal traversing the array.