According to one embodiment, a semiconductor memory device includes a plurality of data latches; and an inverter shared by the plurality of data latches. The inverter is inserted between complementary buses that sandwich the plurality of data latches.

A semiconductor memory device includes a plurality of memory banks in a first region, a data terminal to which an input data signal is input, the data terminal being in a second region, and an inverting circuit that inverts or non-inverts the input data signal in response to an inversion control signal indicating whether the input data signal has been inverted, wherein at least one inverting circuit is disposed for each of the plurality of memory banks.

A data storage device may be configured to write first data to a first set of storage elements of a non-volatile memory and to write second data to a second set of storage elements of the non-volatile memory. The first data may be processed by a data shaping operation, and the second data may not be processed by the data shaping operation. The data storage device may be further configured to read a representation of the second data from the second set of storage cells and to determine a block health metric of a portion of the non-volatile memory based on the representation of the second data. The portion may include the first set of storage elements and the second set of storage elements. As an illustrative, non-limiting example, the first portion may be a first block of the non-volatile memory.

A semiconductor memory device includes a plurality of memory banks in a first region, a data terminal to which an input data signal is input, the data terminal being in a second region, and an inverting circuit that inverts or non-inverts the input data signal in response to an inversion control signal indicating whether the input data signal has been inverted, wherein at least one inverting circuit is disposed for each of the plurality of memory banks.

According to one embodiment, a semiconductor memory device includes a plurality of data latches; and an inverter shared by the plurality of data latches. The inverter is inserted between complementary buses that sandwich the plurality of data latches.

A non-volatile memory device has a charge pump for providing a programming current and an array of non-volatile memory cells. Each memory cell of the array is programmed by the programming current from the charge pump. The array of non-volatile memory cells is partitioned into a plurality of units, with each unit comprising a plurality of memory cells. An indicator memory cell is associated with each unit of non-volatile memory cells. A programming circuit programs the memory cells of each unit using the programming current, when fifty percent or less of the memory cells of each unit is to be programmed, and programs the inverse of the memory cells of each unit and the indicator memory cell associated with each unit, using the programming current, when more than fifty percent of the memory cells of each unit is to be programmed.

A semiconductor memory device includes a plurality of memory banks in a first region, a data terminal to which an input data signal is input, the data terminal being in a second region, and an inverting circuit that inverts or non-inverts the input data signal in response to an inversion control signal indicating whether the input data signal has been inverted, wherein at least one inverting circuit is disposed for each of the plurality of memory banks.

To improve the write performance of PCM, the disclosed technology, in certain embodiments, provides a new write scheme, referred to herein as two-stage-write, which leverages the speed and power asymmetries of writing a zero bit and a one bit. Writing a data block to PCM is divided into two separated stages, i.e., write-0 stage and write-1 stage. Without violating power constraints, during the write-0 stage, all zero bits in this data block are written to PCM at an accelerated speed; during the write-1 stage, all one bits are written to PCM, with more bits being written concurrently. In certain embodiments, the disclosed technology provides a new coding scheme to improve the speed of the write-1 stage by further increasing the number of bits that can be written to PCM in parallel.

A memory device includes a group or block of k-level memory cells, where k>2, and where each of the k-level memory cells has k programmable states represented by respective resistance levels.

According to a magnetic disk apparatus of one embodiment, threshold voltages of memory cell transistors of a flash memory are set to a first section for a first value or to a second section for a second value. The second section is on a lower voltage side than the first section. The controller performs bit inversion of second data held in a volatile memory and writes the second data onto the flash memory when a power loss occurs while the second data corresponds to third data in which a number of the first values is larger than that of the second values. The controller writes the second data onto the flash memory without bit inversion when a power loss occurs while the second data corresponds to fourth data. The fourth data is data in which a number of the first values is smaller than that of the second values.