Abstract: Methods of operating memories facilitate compensating for memory cell signal line propagation delays, such as to increase the overall threshold voltage range and non-volatile memory cell states available. Methods include selecting a memory cell signal line of a memory and characterizing the memory cell signal line by determining an RC time constant of the memory cell signal line.

Abstract: Memory devices and methods adapted to process and generate analog data signals representative of data values of two or more bits of information facilitate increases in data transfer rates relative to devices processing and generating only binary data signals indicative of individual bits. Programming of such memory devices includes programming to a target threshold voltage range representative of the desired bit pattern. Reading such memory devices includes generating an analog data signal indicative of a threshold voltage of a target memory cell. Warning of cell deterioration can be performed using reference cells programmed in accordance with a known pattern such as to approximate deterioration of non-volatile memory cells of the device.

Abstract: The present disclosure includes methods, devices, modules, and systems for reducing noise in semiconductor devices. One method embodiment includes applying a reset voltage to a control gate of a semiconductor device for a period of time. The method further includes sensing the state of the semiconductor device after applying the reset voltage.

Abstract: Self-calibration for a memory controller is performed by writing a voltage to a selected cell. Adjacent cells around the selected cell are programmed. After each of the adjacent programming operations, the voltage on the selected cell is read to determine any change in voltage caused by systemic offsets such as, for example, floating gate-to-floating gate coupling. These changes are averaged and stored in a table as an offset for use in adjusting a programming voltage or a read voltage in a particular area of memory represented by the offset. Self calibration method for temperature is determined by writing cells at different temperatures and reading at different temperatures to generate temperature offset tables for the write path and read path. These offset tables are used to adjust for systematic temperature related offsets during programming and during read.

Abstract: Methods and memory devices are disclosed, for example a memory device that has both an analog path and a digital path that both share the same input/output pad. One of the two paths on each pad is selected in response to command signals that indicate the nature of the signal being either transmitted to the device or read from the device. Each digital path includes a latch for latching digital input data. Each analog path includes a sample/hold circuit for storing either analog data being read from or analog data being written to the memory device.

Abstract: In one or more of the disclosed embodiments, memory cells in a memory device are refreshed upon an indication of a fatigue condition. In one such embodiment, controller monitors behavior parameters of the cells and determines if any of the parameters are outside of a normal range set for each one, thus indicating a fatigue condition. If any cell indicates a fatigue condition, the data from the block of cells indicating the fatigue is moved to another block. In one embodiment, an error detection and correction process is performed on the data prior to being written into another memory block.

Abstract: An analog-to-digital conversion window is defined by reference voltages stored in reference memory cells of a memory device. A first reference voltage is read to define an upper limit of the conversion window and a second reference voltage is read to define a lower limit of the conversion window. An analog voltage representing a digital bit pattern is read from a memory cell and converted to the digital bit pattern by an analog-to-digital conversion process using the conversion window as the limits for the sampling process. This scheme helps in real time tracking of the ADC window with changes in the program window of the memory array.

Abstract: The present disclosure includes methods, devices, modules, and systems for operating memory cells. One method embodiment includes applying a ramping voltage to a control gate of a memory cell and to an analog-to-digital converter (ADC). The aforementioned embodiment of a method also includes detecting an output of the ADC at least partially in response to when the ramping voltage causes the memory cell to trip sense circuitry.

Abstract: The present disclosure includes methods, devices, and systems for sensing memory cells. One or more embodiments include providing an output of a first counter to a digital-to-analog converter (DAC). An output of the DAC can correspond to a ramping voltage provided to a control gate of the memory cell. An output of a second counter can be provided to sensing circuitry coupled to a sense line of the memory cell. Conduction of the sense line in response to the ramping voltage can be sensed, and an output value of the second counter can be determined in response to the sensed conduction of the sense line.

Abstract: Apparatus having a string of memory cells are useful in semiconductor memory. Some apparatus have circuitry configured to program memory cells of the string in a particular sequence. Some apparatus have circuitry configured to program a threshold voltage of a selected memory cell in the string to match a target voltage compensating, at least in part, for a voltage drop across any unselected memory cells in the string on a source side of the selected memory cell during a sensing operation. Some apparatus have circuitry configured to maintain a resistance presented by source-side unselected memory cells of the string the same between a program verify operation and a later read operation.

Abstract: A memory device and programming and/or reading process is described that compensates for memory cell signal line propagation delays, such as to increase the overall threshold voltage range and non-volatile memory cell states available. Memory cell signal line propagation delay compensation can be accomplished by characterizing the memory cell signal line propagation delay, such as determining an amount of error due to the delay, and pre-compensating the programmed threshold voltage of the memory cells based on the amount of error induced by the memory cell signal line propagation delay and cell location on the selected memory cell signal line. Alternatively, memory cell signal line propagation delay can be post-compensated for, or the pre-compensation fine tuned, after sensing the threshold voltages of the selected memory cells based on the amount of error induced by the memory cell signal line propagation delay and cell location on the selected memory cell signal line. Other methods, devices, etc.

Abstract: Self-calibration for a memory controller is performed by writing a voltage to a selected cell. Adjacent cells around the selected cell are programmed. After each of the adjacent programming operations, the voltage on the selected cell is read to determine any change in voltage caused by systemic offsets such as, for example, floating gate-to-floating gate coupling. These changes are averaged and stored in a table as an offset for use in adjusting a programming voltage or a read voltage in a particular area of memory represented by the offset. Self calibration method for temperature is determined by writing cells at different temperatures and reading at different temperatures to generate temperature offset tables for the write path and read path. These offset tables are used to adjust for systematic temperature related offsets during programming and during read.

Abstract: Memory devices and methods adapted to process and generate analog data signals representative of data values of two or more bits of information facilitate increases in data transfer rates relative to devices processing and generating only binary data signals indicative of individual bits. Programming of such memory devices includes programming to a target threshold voltage range representative of the desired bit pattern. Reading such memory devices includes generating an analog data signal indicative of a threshold voltage of a target memory cell. Warning of cell deterioration can be performed using reference cells programmed in accordance with a known pattern such as to approximate deterioration of non-volatile memory cells of the device.

Abstract: Methods and memory devices are disclosed, for example a memory device that has both an analog path and a digital path that both share the same input/output pad. One of the two paths on each pad is selected in response to command signals that indicate the nature of the signal being either transmitted to the device or read from the device. Each digital path includes a latch for latching digital input data. Each analog path includes a sample/hold circuit for storing either analog data being read from or analog data being written to the memory device.

Abstract: An analog-to-digital conversion window is defined by reference voltages stored in reference memory cells of a memory device. A first reference voltage is read to define an upper limit of the conversion window and a second reference voltage is read to define a lower limit of the conversion window. An analog voltage representing a digital bit pattern is read from a memory cell and converted to the digital bit pattern by an analog-to-digital conversion process using the conversion window as the limits for the sampling process. This scheme helps in real time tracking of the ADC window with changes in the program window of the memory array.

Abstract: Method of programming memory cells of series strings of memory cells include programming a target memory cell of a series string of memory cells after programming each memory cell of the string located between the target memory cell and a first end of the string, and verifying the programming of the target memory cell by applying a bias at a second end of the string opposite the first end and sensing a voltage developed at the first end in response to the bias.

Abstract: A memory device that includes a sample and hold circuit coupled to a bit line. The sample and hold circuit stores a target threshold voltage for a selected memory cell. The memory cell is programmed and then verified with a ramped read voltage. The read voltage that turns on the memory cell is stored in the sample and hold circuit. The target threshold voltage is compared with the read voltage by a comparator circuit. When the read voltage is at least substantially equal to (i.e., is substantially equal to and/or starts to exceed) the target threshold voltage, the comparator circuit generates an inhibit signal.

Abstract: The present disclosure includes methods, devices, modules, and systems for operating memory cells. One method embodiment includes applying a ramping voltage to a control gate of a memory cell and to an analog-to-digital converter (ADC). The aforementioned embodiment of a method also includes detecting an output of the ADC at least partially in response to when the ramping voltage causes the memory cell to trip sense circuitry.

Abstract: Embodiments of the present disclosure provide methods, devices, modules, and systems for non-volatile multilevel memory cell data retrieval with data read of reference cells. One method includes programming at least one data cell of a number of data cells coupled to a selected word line to a target data threshold voltage (Vt) level corresponding to a target state; programming at least one reference cell of a number of reference cells coupled to the selected word line to a target reference Vt level, the number of reference cells interleaved with the number of data cells; determining a reference state based on a data read of the at least one reference cell; and changing a state read from the at least one data cell based on a change of the at least one reference cell.

Abstract: A memory device and programming and/or reading process is described that programs and/or reads the cells in the memory array with higher threshold voltage resolution than required. In programming non-volatile memory cells, this allows a more accurate threshold voltage placement during programming and enables pre-compensation for program disturb, increasing the accuracy of any subsequent read or verify operation on the cell. In reading/sensing memory cells, the increased threshold voltage resolution allows more accurate interpretations of the programmed state of the memory cell and also enables more effective use of probabilistic data encoding techniques such as convolutional code, partial response maximum likelihood (PRML), low-density parity check (LDPC), Turbo, and Trellis modulation encoding and/or decoding, reducing the overall error rate of the memory.