Patent application number | Description | Published |
20080229144 | FLEXIBLE ROW REDUNDANCY SYSTEM - A row redundancy system is provided for replacing faulty wordlines of a memory array having a plurality of banks. The row redundancy system includes a remote fuse bay storing at least one faulty address corresponding to a faulty wordline of the memory array; a row fuse array for storing row fuse information corresponding to at least one bank of the memory array; and a copy logic module for copying at least one faulty address stored in the remote fuse bay into the row fuse array; wherein the copy logic module is programmed to copy the at least one faulty address into the row fuse information stored in the row fuse array corresponding to a predetermined number of banks in accordance with a selectable repair field size. | 09-18-2008 |
20080316789 | Random Access Electrically Programmable E-Fuse Rom - A one-time-programmable-read-only-memory (OTPROM) is implemented in a two-dimensional array of aggressively scaled suicide migratable e-fuses. Word line selection is performed by decoding logic operating at V | 12-25-2008 |
20090103390 | Three Dimensional Twisted Bitline Architecture for Multi-port Memory - Embodiments of the present invention provide a memory array of dual part cells and design structure thereof. The memory array has a pair of twisted write bit lines and a pair of twisted read bit lines for each column. The twist is made by alternating the vertical position of each bit line pair in each section of a column, with the result of generating common mode nose and of reducing differential mode noise. | 04-23-2009 |
20090212850 | Method and Circuit for Implementing Efuse Resistance Screening - A method and circuit for implementing eFuse resistance screening, and a design structure on which the subject circuit resides are provided. An eFuse is sensed using a first reference resistor. Responsive to the eFuse being sensed as blown with the first reference resistor, the eFuse is sensed using a second reference resistor having a higher resistance than the first reference resistor. Responsive to the eFuse being sensed as unblown with the second reference resistor, the eFuse is recorded as poorly blown. Reliability concerns are identified quickly and accurately without being required to measure the resistance of the eFuse. | 08-27-2009 |
20100067319 | Implementing Precise Resistance Measurement for 2D Array Efuse Bit Cell Using Differential Sense Amplifier, Balanced Bitlines, and Programmable Reference Resistor - A method and circuit for implementing precise eFuse resistance measurement, and a design structure on which the subject circuit resides are provided. An eFuse sense amplifier coupled to an eFuse array and used for current measurements includes balanced odd and even bitlines, and a plurality of programmable reference resistors connected to the balanced odd and even bitlines. First a baseline current measurement is made through one of the programmable reference resistors, and used to identify a network baseline resistance. A current measurement is made for an eFuse path including a selected eFuse and used to identify the resistance of the selected eFuse. | 03-18-2010 |
20110199837 | High Voltage Word Line Driver - A word line driver circuit coupled to a memory circuit word line includes pull-up, pull-up clamp, pull-down and pull-down clamp transistors, each having a source, a drain and a gate. For the pull-up transistor, the source is coupled to a first power supply, and the gate to a pull-up control signal. For the pull-up clamp transistor, the source is coupled to the drain of the pull-up transistor, the drain to the word line, and the gate to a pull-up clamp gate signal. For the pull-down transistor, the source is coupled to a second power supply, and the gate to a pull-down control signal. For the pull-down clamp transistor, the source is coupled to the drain of the pull-down transistor, the drain to the word line, and the gate to a pull-down clamp gate signal. The word line is coupled to one or more DRAM cells. Source to drain voltage magnitudes of the pull-up and pull-down transistors are less than a voltage between the first and second power supplies. | 08-18-2011 |
20130133031 | Retention Based Intrinsic Fingerprint Identification Featuring A Fuzzy Algorithm and a Dynamic Key - A random intrinsic chip ID generation employs a retention fail signature. A 1 | 05-23-2013 |
20140100807 | CHIP AUTHENTICATION USING MULTI-DOMAIN INTRINSIC IDENTIFIERS - Embodiments of the present invention provide a chip authentication system using multi-domain intrinsic identifiers. Multiple intrinsic identifiers taken from multiple domains (areas or sections of the chip) are compared against the intrinsic identifiers collected during the manufacture of the chip. If at least one intrinsic identifier matches those collected during manufacture, the chip may be designated as authentic. | 04-10-2014 |
20140165141 | SELF-AUTHENTICATING CHIP - Embodiments of the present invention provide an authenticating service of a chip having an intrinsic identifier (ID). In a typical embodiment, an authenticating device is provided that includes an identification (ID) engine, a self-test engine, and an intrinsic component. The intrinsic component is associated with a chip and includes an intrinsic feature. The self-test engine retrieves the intrinsic feature and communicates it to the identification engine. The identification engine receives the intrinsic feature, generates a first authentication value using the intrinsic feature, and stores the authentication value in memory. The self-test engine generates a second authentication value using an authentication challenge. The identification engine includes a compare circuitry that compares the first authentication value and the second authentication value and generates an authentication output value based on the results of the compare of the two values. | 06-12-2014 |
20140253220 | ELECTRONIC FUSE CELL AND ARRAY - Embodiments may include an eFuse cell. The eFuse cell may include an eFuse having a first end and a second end. A blowFET has a first source/drain area, a second source/drain area, and a first gate. The first source/drain area is coupled to the second end of the eFuse, the second source/drain area is coupled to ground, and the first gate is coupled to a first node. The eFuse cell includes a senseFET having a third source/drain area, a fourth source/drain area, and a second gate. The second gate is coupled to the first node, and the third source/drain area is coupled to a second node. The second node is coupled to an operation signal and the second end of the eFuse. The eFuse cell includes a select eFuse logic element having an input to receive a select eFuse signal and an output coupled to the first node. | 09-11-2014 |