Methods, systems, and devices for operating memory cell(s) are described. A resistance of a storage element included in a memory cell may be programmed by applying a voltage to the memory cell that causes ion movement within the storage element, where the storage element remains in a single phase and has different resistivity based on a location of the ions within the storage element. In some cases, multiple of such storage elements may be included in a memory cell, where ions within the storage elements respond differently to electric pulses, and a non-binary logic value may be stored in the memory cell by applying a series of voltages or currents to the memory cell.

A switching resistor has a low resistance state and a high resistance state. The switching resistor comprises a dielectric layer disposed between a first electrode and a second electrode. The switching resistor further comprises a textured boundary surface between the first electrode and the dielectric layer. The textured boundary surface promotes the formation of a conductive pathway in the dielectric layer between the first electrode and the second electrode.

A memory device may include a memory cell array including a plurality of memory cells and a compensation resistor electrically connected to the memory cell array. The compensation resistor may generate a cell current compensating for a voltage drop generated in a parasitic resistor of a signal line connected to at least one memory cell of the plurality of memory cells. The compensation circuit may control a magnitude of resistance of a compensation resistor upon receiving an address corresponding to the memory cell. The compensation circuit may increase a magnitude of the cell current based on adjusting the magnitude of resistance of the compensation resistor to be substantially equal to a resistance value of the parasitic resistor.

Some embodiments include apparatuses having a resistive memory device and methods to apply a combination of voltage stepping current stepping and pulse width stepping during an operation of changing a resistance of a memory cell of the resistive memory device. The apparatuses also include a write termination circuit to limit drive current provided to a memory cell of the resistive memory device during a particular time of an operation performed on the memory cell. The apparatuses further include a programmable variable resistor and resistor control circuit that operate during sensing operation of the memory device.

Some embodiments include apparatuses having a resistive memory device and methods to apply a combination of voltage stepping current stepping and pulse width stepping during an operation of changing a resistance of a memory cell of the resistive memory device. The apparatuses also include a write termination circuit to limit drive current provided to a memory cell of the resistive memory device during a particular time of an operation performed on the memory cell. The apparatuses further include a programmable variable resistor and resistor control circuit that operate during sensing operation of the memory device.

The present technology can detect potential labeling conflicts made during different labeling tasks when those tasks are checked in to ensure that a map database is free from conflicts that might interrupt publishing of a map. The present technology can determine whether a first labeled version of map portion is based on a most recent version for the map portion that is stored in the map database, and when it is determined that it is not, and there is an intervening version, the present technology can identify differences between the intervening version of the map portion and the first version of the map portion and identify differences between the second version of the map portion and the first version of the map portion. Based on the identified differences, the present technology can determine whether any of those differences are conflicting.

A programming method of a memory device comprising a multi-level cell is introduced. The programming method includes applying a sequence of program pulses comprising at least one set pulse and at least one reset pulse to the multi-level cell; determining whether the resistance of the multi-level cell is in a target range after each program pulse of the sequence of program pulses is applied to the multi-level cell; keeping applying the sequence of program pulses to the multi-level cell in response to determining that the resistance of the multi-level cell is not in the target range; and stopping applying the sequence of program pulses to the multi-level cell in response to determining that the resistance of the multi-level cell is in the target range.

According to one embodiment, a resistance change memory device comprises a memory cell array in which a plurality of resistance change storage elements each to store one of multiple resistance states as data represented in two or more bits are arranged, and a read unit to read the data of a selected one of the storage elements. In reading the data of the storage element, the read unit, selecting one at a time, applies multiple types of constant voltages to the storage element.

Providing for improved manufacturing of silver-based electrodes to facilitate formation of a robust metallic filament for a resistive switching device is disclosed herein. By way of example, a silver electrode can be embedded with a non-silver material to reduce surface energy of silver atoms of a silver-based conductive filament, increasing structural strength of the conductive filament within a resistive switching medium. In other embodiments, an electrode formed of a base material can include silver material to provide mobile particles for an adjacent resistive switching material. The silver material can drift or diffuse into the resistive switching material to form a structurally robust conductive filament therein.

Devices and methods for accessing resistive change elements in a resistive change element array to determine resistive states of the resistive change elements are disclosed. According to some aspects of the present disclosure the devices and methods access resistive change elements in a resistive change element array through a variety of operations. According to some aspects of the present disclosure the devices and methods supply an amount of current tailored for a particular operation. According to some aspects of the present disclosure the devices and methods compensate for circuit conditions of a resistive change element array by adjusting an amount of current tailored for a particular operation to compensate for circuit conditions of the resistive change element array.