Abstract: A simple method and device for accurately measuring flash memory cell current. The sensing scheme comprises an integrator, an analog to digital converter, and a digital to analog converter. The method comprises the acts of applying an input current and a feedback output current to a summer, integrating the resulting summer output over time, passing the integrated output to a clocked comparator, outputting a comparator output which controls a feedback circuit that keeps the integrator's voltage at the same level as a reference voltage, and outputting a digital average current to a counter. Delta sigma modulation (averaging) is employed to cancel out noise that would otherwise affect the cell current measurement.

Abstract: A simple method and device for accurately measuring flash memory cell current. The sensing scheme comprises an integrator, an analog to digital converter, and a digital to analog converter. The method comprises the acts of applying an input current and a feedback output current to a summer, integrating the resulting summer output over time, passing the integrated output to a clocked comparator, outputting a comparator output which controls a feedback circuit that keeps the integrator's voltage at the same level as a reference voltage, and outputting a digital average current to a counter. Delta sigma modulation (averaging) is employed to cancel out noise that would otherwise affect the cell current measurement.

Abstract: A system for determining the logic state of a resistive memory cell element, for example an MRAM resistive cell element. The system includes a controlled voltage supply, an electronic charge reservoir, a current source, and a pulse counter. The controlled voltage supply is connected to the resistive memory cell element to maintain a constant voltage across the resistive element. The charge reservoir is connected to the voltage supply to provide a current through the resistive element. The current source is connected to the charge reservoir to repeatedly supply a pulse of current to recharge the reservoir upon depletion of electronic charge from the reservoir, and the pulse counter provides a count of the number of pulses supplied by the current source over a predetermined time. The count represents a logic state of the memory cell element.

Abstract: An apparatus and method is disclosed for reducing power consumption when sensing a resistive memory. A switch, with one end coupled to a terminal of a capacitive element at a node, is coupled from the other end to a bit line from a resistive memory array. A sensing device is further connected to the node, wherein the switch closes and opens to sample and store voltage signals transmitted on the bit line in the capacitive element. The sampled signal is then transmitted to a sensing apparatus that performs sensing operations on the signal.

Abstract: A system and methods optimize the operation of sensing circuitry. In one embodiment, the output of a sensing circuit is stored in a register and processed through logic gates to determine whether the sensing output contains a predetermined string of logic ones or zeroes. If a string of ones is detected, the logic gates activate a counter to increase the operating clock frequency for the sensing circuit. If a string of zeroes is detected, the logic gates activate the counter to decrease the frequency.

Abstract: An offset compensated memory element voltage supply including a differential amplifier with a compensation circuit, and a transistor with a gate connected to the output of the differential amplifier. The compensation circuit of the differential amplifier includes a compensation capacitor that stores a compensation voltage during a calibration phase, and applies the stored compensation voltage to a compensation input of the compensation circuit of the amplifier during a measurement phase. Feedback from a source of the transistor controls the output of the differential amplifier to maintain a standard voltage across a resistive memory element connected to the source during measurement of the resistance of the resistive memory element, and the compensation circuit improves the accuracy of the voltage across the resistive memory element by compensating for an offset voltage of the differential amplifier.

Abstract: An MRAM memory integrated circuit is disclosed. Resistance, and hence logic state, is determined by discharging a first charged capacitor through an unknown cell resistive element to be sensed at a fixed voltage, and a pair of reference capacitors. The rate at which the parallel combination of capacitors discharge is between the discharge rate associated with a binary ‘1’ and ‘0’ value, and thus offers a reference for comparison.

Abstract: An apparatus and method is disclosed for reducing power consumption when sensing a resistive memory. A switch, with one end coupled to a terminal of a capacitive element at a node, is coupled from the other end to a bit line from a resistive memory array. A sensing device is further connected to the node, wherein the switch closes and opens to sample and store voltage signals transmitted on the bit line in the capacitive element. The sampled signal is then transmitted to a sensing apparatus that performs sensing operations on the signal.

Abstract: A system for determining the logic state of a resistive memory cell element, for example an MRAM resistive cell element. The system includes a controlled voltage supply, an electronic charge reservoir, a current source, and a pulse counter. The controlled voltage supply is connected to the resistive memory cell element to maintain a constant voltage across the resistive element. The charge reservoir is connected to the voltage supply to provide a current through the resistive element. The current source is connected to the charge reservoir to repeatedly supply a pulse of current to recharge the reservoir upon depletion of electronic charge from the reservoir, and the pulse counter provides a count of the number of pulses supplied by the current source over a predetermined time. The count represents a logic state of the memory cell element.

Abstract: An offset compensated memory element voltage supply including a differential amplifier with a compensation circuit, and a transistor with a gate connected to the output of the differential amplifier. The compensation circuit of the differential amplifier includes a compensation capacitor that stores a compensation voltage during a calibration phase, and applies the stored compensation voltage to a compensation input of the compensation circuit of the amplifier during a measurement phase. Feedback from a source of the transistor controls the output of the differential amplifier to maintain a standard voltage across a resistive memory element connected to the source during measurement of the resistance of the resistive memory element, and the compensation circuit improves the accuracy of the voltage across the resistive memory element by compensating for an offset voltage of the differential amplifier.

Abstract: An MRAM memory integrated circuit is disclosed. Resistance, and hence logic state, is determined by discharging a first charged capacitor through an unknown cell resistive element to be sensed at a fixed voltage, and a pair of reference capacitors. The rate at which the parallel combination of capacitors discharge is between the discharge rate associated with a binary ‘1’ and ‘0’ value, and thus offers a reference for comparison.

Abstract: A memory device having an array of resistive memory cells with row lines that are maintained at ground potential during quiescent operation of the device. During a read operation, one of the row lines is adapted to be coupled to a non-ground potential. Such coupling configures a memory cell of the array to be sensed in a voltage divider with a column line coupled to a common node of the voltage divider. An amplifier adapted to amplify a voltage detected on the column line is provided and additional circuitry is provided to translate the amplified voltage of the amplifier as a logic state of digital data stored in the device.

Abstract: An offset compensated memory element voltage supply including a differential amplifier with a compensation circuit, and a transistor with a gate connected to the output of the differential amplifier. The compensation circuit of the differential amplifier includes a compensation capacitor that stores a compensation voltage during a calibration phase, and applies the stored compensation voltage to a compensation input of the compensation circuit of the amplifier during a measurement phase. Feedback from a source of the transistor controls the output of the differential amplifier to maintain a standard voltage across a resistive memory element connected to the source during measurement of the resistance of the resistive memory element, and the compensation circuit improves the accuracy of the voltage across the resistive memory element by compensating for an offset voltage of the differential amplifier.

Abstract: A system for determining the logic state of a resistive memory cell element, for example an MRAM resistive cell element. The system includes a controlled voltage supply, an electronic charge reservoir, a current source, and a pulse counter. The controlled voltage supply is connected to the resistive memory cell element to maintain a constant voltage across the resistive element. The charge reservoir is connected to the voltage supply to provide a current through the resistive element. The current source is connected to the charge reservoir to repeatedly supply a pulse of current to recharge the reservoir upon depletion of electronic charge from the reservoir, and the pulse counter provides a count of the number of pulses supplied by the current source over a predetermined time. The count represents a logic state of the memory cell element.

Abstract: A optical link for achieving electrical isolation between a controller and a memory device is disclosed. The optical link increases the noise immunity of electrical interconnections, and allows the memory device to be placed a greater distance from the processor than is conventional without power-consuming I/O buffers.

Abstract: An MRAM memory integrated circuit is disclosed. Resistance, and hence logic state, is determined by discharging a first charged capacitor through an unknown cell resistive element to be sensed at a fixed voltage, and a pair of reference capacitors. The rate at which the parallel combination of capacitors discharge is between the discharge rate associated with a binary ‘1’ and ‘0’ value, and thus offers a reference for comparison.

Abstract: A system for determining the logic state of a resistive memory cell element, for example an MRAM resistive cell element. The system includes a controlled voltage supply, an electronic charge reservoir, a current source, and a pulse counter. The controlled voltage supply is connected to the resistive memory cell element to maintain a constant voltage across the resistive element. The charge reservoir is connected to the voltage supply to provide a current through the resistive element. The current source is connected to the charge reservoir to repeatedly supply a pulse of current to recharge the reservoir upon depletion of electronic charge from the reservoir, and the pulse counter provides a count of the number of pulses supplied by the current source over a predetermined time. The count represents a logic state of the memory cell element.