Abstract: According to an embodiment of the present invention, a spin device includes an intermediate semiconductor region arranged between a first terminal and a second terminal, wherein the first terminal is adapted to provide a current having a first degree of spin polarization to the intermediate semiconductor region, and wherein the second terminal is adapted to output the current having a second degree of spin polarization.

Abstract: A variable resistance memory device includes a variable resistance memory cell array including a plurality of variable resistance memory cells; a plurality of global word lines configured to drive the variable resistance memory cell array; and a plurality of local word line decoders. Each of the plurality of local word line decoders includes a first transistor having a gate connected to the global word line. A voltage greater than an operation voltage of one or more of the plurality of local word line decoders is applied to a selected one of the plurality of global word lines.

Abstract: The timing of output signals can be controlled by coupling a digital signal through a signal distribution tree having a plurality of branches extending from an input node to respective clock inputs of a plurality of latches. A phase interpolator is included in a signal path common to all of the branches, and a respective delay line is included in each of the branches. Each of the latches couples a signal applied to its data input to an output terminal responsive to a transition of the digital signal applied to its clock input. The delay lines are adjusted so that the latches are simultaneously clocked. The delay of the phase interpolator is adjusted so that the signals are coupled to the output terminals of the latches with a predetermined timing relationship relative to signals coupled to output terminals of a second signal distribution tree.

Abstract: The present invention provides a Single-Event-Upset (SEU) and Single-Event-Gate-Rupture (SEGR) protection against incident radiation for any bi-stable circuit either in one state, having a 2 transistor, 1 capacitor integrated circuit coupled to a bi-stable circuit's outputs, or in both states, having a 4 transistor, 2 capacitor integrated circuit coupled to the bi-stable circuit's outputs. The protection against SEU and SEGR is achieved by the 2T1C or the 4T2C circuits, by providing the opposite drive to the SEU or SEGR event through capacitive coupling, and shunting electron-hole pair current, created by an ion tracking through the bi-stable circuit, into the power supplies. The 2T1C integrated circuit architecture, which only protects bi-stable circuits in one state, is to allow the bi-stable circuit to be a Single-Event-Upset (SEU) detector by capturing the effect of an incident ion and store that state.

Abstract: A method of operating a phase change random access memory (PRAM) device includes performing a program operation to store data in selected PRAM cells of the device, wherein the program operation comprises a plurality of sequential program loops. The method further comprises suspending the program operation in the middle of the program operation, and after suspending the program operation, resuming the program operation in response to a resume command.

Abstract: Voltage regulators, memories, and methods for providing a regulated output voltage are disclosed. For example, one such voltage regulator includes a comparator circuit, a driver circuit, an impedance circuit, and a modulation circuit. The comparator circuit generates an output voltage according to a difference between a reference voltage and a feedback voltage. The driver circuit is coupled to an output of the comparator circuit and drives the regulated output voltage at an output node according to the output voltage from the comparator circuit. The impedance circuit is coupled to the comparator circuit and provides the feedback voltage to the comparator circuit in response to a detection current from the output node. The modulation circuit is coupled to the impedance circuit and adjusts a modulation current component of the detection current to adjust the regulated output voltage.

Abstract: A dual data rate (DDR) memory controller and method are provided. The method includes: receiving a first data strobe at a first terminal from a first memory having a first rank; receiving a first data signal at a second terminal from the first memory having the first rank; calibrating the first data signal with the first data strobe to produce a first calibration value; receiving a second data strobe at the first terminal from a second memory having a second rank; receiving a second data signal at the second terminal from the second memory having the second rank; calibrating the second data signal with the second data strobe to produce a second calibration value; determining a final calibration value using the first and second calibration values; and using the final calibration value to time the first data signal and the second data signal during a read operation of the memories.

Abstract: A memory has a serial interface. The serial interface is programmable to either use separate dedicated input and output pads, or to use one bidirectional pad. When one bidirectional pad is used, the interface signal count is reduced by one.

Abstract: A memory device includes a clock buffer circuit. The clock buffer circuit includes a cross-coupled logic circuit. The cross-coupled logic circuit has at least two logic gates in which an output of at least one of the logic gates is coupled to an input of at least one of the logic gates. The cross-coupled logic circuit is coupled to an input for accepting a clock signal. The memory device also includes a clock driver operable to generate a clock signal from the output of the cross-coupled logic circuit. A feedback loop from the clock signal to the cross-coupled logic circuit controls the cross-coupled logic circuit. A buffer circuit including a tri-state inverter is coupled to the clock signal to maintain the clock signal while avoiding contention with the clock generator. The memory device is enabled by a chip select signal.

Abstract: A sense amplifier includes a first cascode transistor, a second cascode transistor, a first feedback circuit, a second feedback circuit, and a comparator. The drain of the first cascode transistor is connected directly to a first voltage source. The gate of the first cascode transistor is connected to the first feedback circuit and a first input of the comparator, and the source of the first cascode transistor is connected to the first feedback circuit and a first column decoder. The drain of the second cascode transistor is connected directly to a second voltage source. The gate of the second cascode transistor is connected to the second feedback circuit and a second input of the comparator, and the source of the second cascode transistor is connected to the second feedback circuit and a second column decoder.

Abstract: One embodiment includes a non-volatile memory cell array, and a read unit configured to disable read operation for the non-volatile memory cell array for a time period following writing of data in the non-volatile memory cell array.

Abstract: A memory device including current-limiting circuitry coupled to a first inverter inside a data register is provided. The current-limiting circuitry controls a voltage supplied to the first inverter and a reference voltage may be adjusted so that the voltage supplied to the first inverter is prevented from dropping below a voltage supplied to a second inverter inside the data register. The memory device may include a switch to allow coupling to the current-limiting circuitry for programming of the memory device.

Abstract: A soft programming pre-charge voltage provides boosting control during soft programming operations for non-volatile memory devices. A pre-charge voltage can be applied to the word lines of a block of memory cells to enable pre-charging of the channel region of a NAND string to be inhibited from soft programming. The level of boosting in the channel region of the inhibited NAND string is governed by the pre-charge voltage and the soft programming voltage. By controlling the pre-charge voltage, more reliable and consistent channel boosting can be achieved. In one embodiment, the pre-charge voltage is increased between applications of the soft programming voltage to reduce or eliminate a rise in the channel's boosted potential. In one embodiment, the soft programming pre-charge voltage level(s) is determined during testing that is performed as part of a manufacturing process.

Abstract: Various circuits include MOS transistors that have a bulk voltage terminal for receiving a bulk voltage that is different from a supply voltage and ground. The bulk voltage may be selectively set so that some MOS transistors have a bulk voltage set to the supply voltage or ground and other MOS transistors have a bulk voltage that is different. The bulk voltage may be set to forward or reverse bias pn junctions in the MOS transistor. The various circuits include comparators, operational amplifiers, sensing circuits, decoding circuits and the other circuits. The circuits may be included in a memory system.

Abstract: A system and method for writing to a magnetic memory written in a thermally assisted manner, each memory point formed by a magnetic tunnel junction, and having a substantially circular cross-section of the memory which is parallel to the plane of the layers forming the tunnel junction. The tunnel junction includes at least a trapped layer with a fixed magnetisation direction, a free layer with a variable magnetisation direction with an insulating layer arranged there between. The free layer is formed from at least one soft magnetic layer and a trapped layer, with the two layers being magnetically coupled by contact. During read operations and at rest, the operating temperature of the memory is lower than the blocking temperature of the free and trapped layers, respectively.

Abstract: An output circuit including a first circuit configured to provide a first output signal, a second circuit configured to provide a second output signal, and a third circuit. The third circuit is configured to receive a third output signal that is based on the first output signal and the second output signal. The third circuit is configured to provide enable signals that turn on one of the first circuit and the second circuit and turn off the other of the first circuit and the second circuit based on the third output signal that is updated via the turned on one of the first circuit and the second circuit.

Abstract: A multi-level non-volatile memory cell programming/lockout method and system are provided. The programming/lockout method and system advantageously prevent memory cells that charge faster than other memory cells from being over-programmed.

Abstract: A semiconductor integrated circuit includes a plurality of functional circuits, a plurality of signal transmission lines disposed to interconnect among the functional circuits for transfer of a plurality of control signals which are to be supplied to respective functional circuits and are different in timing from one another, and a control circuit for generation of the control signals. The control circuit has a plurality of stages of control signal generator circuits that generate and issue the control signals respectively. The control signal generator circuits are specifically linked together so that when one generator circuit at a certain stage generates at its output a control signal to be transferred over a corresponding signal line, another circuit at the next stage is activated in response to receipt of this control signal.

Abstract: A dual mode high voltage coupler is described for enabling a low current capacity high voltage generator to supply high voltage to an output load, such as a row or word line in an EEPROM memory device during a nonvolatile write or erase operation. The coupler limits the amount of current to defective cells or rows in the memory without limiting current to the cells and rows that are operating normally. In a first mode, a single stage charge pump, including a storage capacitor driven by a periodic voltage signal, develops a metered current through a diode to the output load whose amplitude is equal to the product of the capacitance of the storage capacitor, the change in voltage across the capacitor in each cycle of said periodic signal and the frequency of said signal. In a second mode, said high voltage is coupled directly to said output load without limiting the current whenever the voltage across said load exceeds a predetermined value.

Abstract: A circuit technique for biasing a complementary NPN-PNP Darlington Emitter Follower Stage without additional biasing resistors or current sources. Four diode-connected transistor are connected in series to provide biasing across the Darlington. Two transistors, one NPN and one PNP, are added with their bases and emitters connected in parallel with the top and bottom diodes, respectively, forming two current mirrors. The collector of the NPN transistor connects to the emitter of the first Darlington NPN transistor. The collector of the PNP transistor connects to the first Darlington PNP transistor. The current mirrors provide equal current to the two first Darlington transistors. These currents are also equal to the current through the four diodes for identically sized transistors.