Abstract: The present invention relates to an arrangement for increasing a relative change in resistance of a magnetoresistive memory cell (17) having in each case a memory layer (1) and a reference layer (3) on both sides of a tunnel barrier (2), the reference layer (3) being fashioned as a magnetically soft layer, and the magnetization thereof, which can be influenced by write operations, being oriented correctly again by a reference backup field or a reference magnetization current (11).

Abstract: Memory devices, arrays, and strings are included that facilitate the use of vertical floating gate memory cells in NAND architecture memory strings, arrays, and devices. NAND Flash memory strings, arrays, and devices, include vertical Flash memory cells to form NAND architecture memory cell strings and memory arrays. These vertical memory cell NAND architecture strings allow for an improved high density memory devices or arrays that can take advantage of the feature sizes semiconductor fabrication processes are generally capable of and still allow for appropriate device sizing for operational considerations.

Abstract: A method for implementing a counter in memory, e.g., non-volatile memory such as flash memory. A first number of first binary values indicating a first portion of a current number of the counter in a binary field may be stored in a portion of memory. Storing the first number may also include increasing the number of first binary values in the binary field. Additionally, a second number indicating a second portion of the current number of the counter may be stored in another portion of memory. The second number may specify the number of times the first binary values has comprised the entirety of the binary field. Thus, the first number and second number may specify the current number of the counter. Storing the first and second number may be performed a plurality of times to implement a counting function of the counter.

Abstract: A magnetoresistive element includes a first ferromagnetic layer having a first magnetization, the first magnetization having a first pattern when the magnetoresistive element is half-selected during a first data write, a second pattern when the magnetoresistive element is selected during a second data write, and a third pattern of residual magnetization, the first pattern being different from the second and third pattern, a second ferromagnetic layer having a second magnetization, and a nonmagnetic layer arranged between the first ferromagnetic layer and the second ferromagnetic layer and having a tunnel conductance changing dependent on a relative angle between the first magnetization and the second magnetization.

Abstract: Temporary lock-out is provided while programming a group of non-volatile memory cells to more accurately program the memory cells. After successfully verifying that the threshold voltage of a memory cell has reached the level for its intended state, it is possible that the threshold voltage will subsequently decrease to below the verify level during additional iterations of the programming process needed to complete programming of other memory cells of the group. Memory cells are monitored (e.g., after each iteration) to determine if they fall below the verify level after previously verifying that the target threshold voltage has been reached. Cells that pass verification and then subsequently fail verification can be subjected to further programming. For example, the bit line voltage for the memory cell of interest may be set to a moderately high voltage to slow down or reduce the amount of programming accomplished by each subsequent programming pulse.

Abstract: Embodiments of the invention provide techniques for reducing standby power consumption due to leakage currents in memory circuits. In some embodiments, systems are provided with one or more processors having) bit cells coupled to a word-line node and to a virtual ground node. The word-line node is to be at an active word-line voltage when the row is active and an inactive word-line voltage when the row is inactive. The virtual ground node is to be at an operational ground voltage when the memory array is enabled and at an elevated voltage when the memory array is in a standby mode. There is also a word-line driver circuit coupled to the bit cells through the word-line and virtual ground nodes. The current leakage in the bit cells and word-line driver circuit is reduced during the standby mode when the virtual ground node is at the elevated voltage.

Abstract: A method, apparatus, and system to enable a partial refresh scheme for DRAM which includes specifying at least a refresh start value, or a refresh start value and a refresh end value, to reduce the number of rows that must be refreshed during a refresh cycle, thus reducing the amount of power consumed during refresh.

Abstract: Systems and methods provide improved address decoding techniques for memory. For example, in accordance with an embodiment of the present invention, an integrated circuit includes an address register that receives a reset signal, a clock signal, and an address signal and provides a registered address signal. The registered address signal provides at least a true and a complement signal, with the true and complement signal set to approximately the same logical value upon assertion of the reset signal. An address pre-decoder, coupled to the address register, at least partially decodes the registered address signal to provide a pre-decoded output signal. A wordline driver, coupled to the address pre-decoder, receives a wordline enable signal and the pre-decoded output signal and provides a wordline signal based on the pre-decoded output signal upon assertion of the wordline enable signal.

Abstract: A search engine system (100) can include a key multiplexer (104) and logic circuit (108). A key from a previous operation can be received by logic circuit (108) and altered to generate an idle key. In a non-search operation, the idle key can be applied to a CAM section to draw current as in a normal search operation. Logic circuit (108) can ensure that an idle key value is always different than a previously applied key value.

Abstract: A non-volatile magnetic memory device is proposed, which provides sufficient magnetic shielding performance for external magnetic fields. A first magnetic shield layer 60a and a second magnetic shield layer 60b, both made of a soft magnetic metal, are formed respectively on the bottom surface of the transistor section 20, which is the mounting side of the MRAM device 10, and on the top surface of the bit line 50, which is opposite to the bottom surface of the mounting side of the MRAM device 10. On the second magnetic shield layer 60a, a passivation film 70 is formed. The magnetic flux penetrated from the external magnetic field, is suppressed below the inversion strength of the MRAM device 10, thereby improving reliability.

Abstract: Methods and apparatus for a more precise readout of fuse resistance than a conventional binary readout are provided. For some embodiments, a digital readout of fuse resistance may be obtained by selectively altering an effective reference resistance to which the fuse resistance is compared. For some embodiments, a direct analog readout may be obtained in addition to, or instead of, a digital resistance readout.

Abstract: An antifuse circuit and antifuse reading method for determining whether an antifuse is programmed or un-programmed. An antifuse circuit includes a sensing circuit having a sense node coupled to the antifuse that is configured to generate a reference current and compare a sense current at the sense node relative to the reference current. The sensing circuit generates an output signal having a first logic level in response to the sense current being greater than the reference current and generates the output signal having a second logic level in response to the sense current being less than the reference current. The logic level of the output signal indicative of whether the antifuse is programmed or un-programmed.

Abstract: One or more sense amplifiers for sensing the conduction current of non-volatile memory is controlled by signals that are timed by a reference sense amplifier having similar characteristics and operating conditions. In one aspect, a sensing period is determined by when the reference sense amplifier sensing a reference current detects an expected state. In another aspect, an integration period for an amplified output is determined by when the reference sense amplifier outputs an expected state. When these determined timings are used to control the one or more sense amplifiers, environment and systemic variations are tracked.

Abstract: An antifuse circuit and antifuse reading method for determining whether an antifuse is programmed or un-programmed. An antifuse circuit includes a sensing circuit having a sense node coupled to the antifuse that is configured to generate a reference current and compare a sense current at the sense node relative to the reference current. The sensing circuit generates an output signal having a first logic level in response to the sense current being greater than the reference current and generates the output signal having a second logic level in response to the sense current being less than the reference current. The logic level of the output signal indicative of whether the antifuse is programmed or un-programmed.

Abstract: An SRAM device and a method of placing a portion of memory cells of an SRAM device in an active mode is provided. In one embodiment, the SRAM device includes a hierarchical grouping of memory cells of memory cells and biasing circuitry, coupled to the hierarchical grouping of memory cells, configured to bias a subset of the set based on a memory address associated therewith. In another embodiment, a method includes receiving a memory address associated with the hierarchical grouping of memory cells and biasing a subset of the hierarchical grouping of memory cells based on the memory address.

Abstract: One or more sense amplifiers for sensing the conduction current of non-volatile memory is controlled by signals that are timed by a reference sense amplifier having similar characteristics and operating conditions. In one aspect, a sensing period is determined by when the reference sense amplifier sensing a reference current detects an expected state. In another aspect, an integration period for an amplified output is determined by when the reference sense amplifier outputs an expected state. When these determined timings are used to control the one or more sense amplifiers, environment and systemic variations are tracked.

Abstract: A ferroelectric reference circuit generates a reference voltage proportional to (P+U)/2 and is automatically centered between the bit line voltages corresponding to the P term and the U term across wide temperature and voltage ranges. To avoid fatiguing the reference ferroelectric capacitors generating (P+U)/2, the reference voltage is refreshed once every millisecond. To eliminate the variation of the reference voltage due to the leakage in the ferroelectric capacitors during this period of time, the reference voltage generated from the reference ferroelectric capacitors is digitized when it is refreshed. The digital value is fixed and converted to an analog value which is then fed into sense amplifiers for resolving the data states. The reference voltage is automatically at the center of the switching (P) and non-switching (U) signals and therefore the signal margin is maximized.

Abstract: An operation clock controller for preventing a semiconductor memory device from operating when an operation frequency of an external clock is higher than a predetermined frequency. The operation clock controller includes a clock buffer for buffering an external clock to output an internal clock; a unit delaying set for sequentially delaying the internal clock to output a plurality of delayed clocks; a phase detecting block for detecting logic levels of the delayed clocks at a rising edge of the internal clock to output phase detecting signals; a sampling pulse generator for outputting a sampling signal generated at a predetermined point of the internal clock; a latching block for outputting a phase detection latch signal by sampling and latching the phase detection signal at a point of the sampling signal being inputted; and a frequency detection block for outputting the frequency detection signal by logically combining the phase detection latch signal.

Abstract: A method and circuit for preventing the overprogramming of a memory cell. A fuse circuit is operable to be blown. A combinational logic circuit receives a signal from the fuse circuit, indicating whether or not the fuse has been blown, and controls the programming of the memory cell. The programming of the memory cell is prevented if the fuse circuit has been blown.

Abstract: A programmable device having a multi-boot capability is described. The programmable device may initially load first configuration data for configuring programmable resources of the device. Thereafter, a multi-boot operation may be triggered, causing the device to reconfigure and load second configuration data. Prior to loading the second configuration data, the device may store status information. In some cases, further multi-boot operations may be triggered for loading other configuration data.