Patent application number | Description | Published |
20090185409 | ENHANCED STATIC RANDOM ACCESS MEMORY STABILITY USING ASYMMETRIC ACCESS TRANSISTORS AND DESIGN STRUCTURE FOR SAME - A memory circuit includes a plurality of bit line structures (each including a true and a complementary bit line), a plurality of word line structures intersecting the plurality of bit line structures to form a plurality of cell locations and a plurality of cells located at the plurality of cell locations. Each of the cells includes a logical storage element, a first access transistor selectively coupling a given one of the true bit lines to the logical storage element, and a second access transistor selectively coupling a corresponding given one of the complementary bit lines to the logical storage element. One or both of the first and second access transistors are configured with asymmetric current characteristics to enable independent enhancement of READ and WRITE margins. Also included within the | 07-23-2009 |
20110172979 | CIRCUIT-LEVEL VALIDATION OF COMPUTER EXECUTABLE DEVICE/CIRCUIT SIMULATORS - A method is disclosed for evaluating a model, characterized as being a computer executable device and circuit simulator. The method includes accepting measured parameters of devices, which devices are essentially identical with, or are actually from, a simulated circuit instance. The model is executed with adjusted input parameters to generate simulated values for properties of the circuit instance. These simulated values are compared with measured values of the same properties. The goodness of the model is determined based on the degree of direct, or statistical, agreement between the simulated and measured values. | 07-14-2011 |
20120185817 | Enhanced Static Random Access Memory Stability Using Asymmetric Access Transistors and Design Structure for Same - A memory circuit includes a plurality of bit line structures (each including a true and a complementary bit line), a plurality of word line structures intersecting the plurality of bit line structures to form a plurality of cell locations; and a plurality of cells located at the plurality of cell locations. Each of the cells includes a logical storage element, a first access transistor selectively coupling a given one of the true bit lines to the logical storage element, and a second access transistor selectively coupling a corresponding given one of the complementary bit lines to the logical storage element. One or both of the first and second access transistors are configured with asymmetric current characteristics to enable independent enhancement of READ and WRITE margins. Also included within the 6-T scope are one or more design structures embodied in a machine readable medium, comprising circuits as set forth herein. | 07-19-2012 |
20130138403 | USAGE-BASED TEMPORAL DEGRADATION ESTIMATION FOR MEMORY ELEMENTS - Methods and systems for computing threshold voltage degradation of transistors in an array of memory cells are disclosed. In accordance with one method, a process that models an expected usage of the array is selected. In addition, a hardware processor can run the process to populate the array with data over time to simulate the expected usage of the array. The method further includes compiling data that detail different durations at which each of the memory cells in the array stores 1 or at which each of the memory cells in the array stores 0. For each separate grouping of memory cells that share a common duration of the different compiled durations, a threshold voltage degradation is determined for each transistor in the corresponding grouping of cells based on at least one biased temperature instability model. | 05-30-2013 |
20130138407 | USAGE-BASED TEMPORAL DEGRADATION ESTIMATION FOR MEMORY ELEMENTS - Methods and systems for computing threshold voltage degradation of transistors in an array of memory cells are disclosed. In accordance with one method, a process that models an expected usage of the array is selected. In addition, a hardware processor can run the process to populate the array with data over time to simulate the expected usage of the array. The method further includes compiling data that detail different durations at which each of the memory cells in the array stores 1 or at which each of the memory cells in the array stores 0. For each separate grouping of memory cells that share a common duration of the different compiled durations, a threshold voltage degradation is determined for each transistor in the corresponding grouping of cells based on at least one biased temperature instability model. | 05-30-2013 |
20130212414 | REDUCING PERFORMANCE DEGRADATION IN BACKUP SEMICONDUCTOR CHIPS - A system has at least a first circuit portion and a second circuit portion. The first circuit portion is operated at normal AC frequency. The second circuit portion is operated in a back-up mode at low AC frequency, such that the second circuit portion can rapidly come-online but has limited temperature bias instability degradation. The second circuit portion can then be brought on-line and operated at the normal AC frequency. A system including first and second circuit portions and a control unit, as well as a computer program product, are also provided. | 08-15-2013 |
20130253868 | ESTIMATING DELAY DETERIORATION DUE TO DEVICE DEGRADATION IN INTEGRATED CIRCUITS - A method for estimating delay deterioration in an integrated circuit comprising estimating degradation in at least one characteristic of each device defined within the integrated circuit using voltages and logic values monitored during a simulation of the digital circuit. Generating an end-of-life netlist in which the at least one device characteristic of each device has been modified to reflect the estimated degradation or estimating a change in timing delay of each device directly from the estimated degradation of the at least one characteristic of each device. Performing a timing analysis using the estimated change in timing delay of each device to determine circuit path delays. The timing analysis being static or statistical. | 09-26-2013 |
20130254731 | ESTIMATING DELAY DETERIORATION DUE TO DEVICE DEGRADATION IN INTEGRATED CIRCUITS - A method for estimating delay deterioration in an integrated circuit comprising estimating degradation in at least one characteristic of each device defined within the integrated circuit using voltages and logic values monitored during a simulation of the digital circuit. Generating an end-of-life netlist in which the at least one device characteristic of each device has been modified to reflect the estimated degradation or estimating a change in timing delay of each device directly from the estimated degradation of the at least one characteristic of each device. A timing analysis is performed using the estimated change in timing delay of each device to determine circuit path delays. The timing analysis is static or statistical. | 09-26-2013 |
20130320340 | CIRCUIT TECHNIQUE TO ELECTRICALLY CHARACTERIZE BLOCK MASK SHIFTS - A physical test integrated circuit has a plurality of repeating circuit portions corresponding to an integrated circuit design. A first of the portions is fabricated with a nominal block mask location, and additional ones of the portions are deliberately fabricated with predetermined progressive increased offset of the block mask location from the nominal block mask location. For each of the portions, the difference in threshold voltage between a first field effect transistor and a second field effect transistor is determined. The predetermined progressive increased offset of the block mask location is in a direction from the first field effect transistor to the second field effect transistor. The block mask overlay tolerance is determined at a value of the progressive increased offset corresponding to an inflection of the difference in threshold voltage from a zero difference. A method for on-chip monitoring, and corresponding circuits, are also disclosed. | 12-05-2013 |
20140013131 | POWER NAPPING TECHNIQUE FOR ACCELERATED NEGATIVE BIAS TEMPERATURE INSTABILITY (NBTI) AND/OR POSITIVE BIAS TEMPERATURE INSTABILITY (PBTI) RECOVERY - A logic circuit is operated in a normal mode, with a supply voltage coupled to a supply rail of the logic circuit, and with a ground rail of the logic circuit grounded; It is determined that at least a portion of the logic circuit has experienced degradation due to bias temperature instability. Responsive to the determining, the logic circuit is operated in a power napping mode, with the supply voltage coupled to the ground rail of the circuit, with the supply rail of the circuit grounded, and with primary inputs of the circuit toggled between logical zero and logical one at low frequency. A logic circuit and corresponding design structures are also provided. | 01-09-2014 |