A reverse bias trim operation for the reset state of a non-volatile memory system is disclosed. Non-volatile memory cells including a resistance change element undergo a reverse bias reset operation to change their resistance from a set state at a first level of resistance to a reset state at a second level of resistance. Certain memory cells in a set of cells that was reset may be deeply reset to a level of resistance beyond a target level for the reset state. A second reverse bias is applied to the set of memory cells to move the resistance of each cell that was deeply reset toward the target level of the reset state. A smaller reverse bias than used for the reset operation can shift the resistance of the cells back toward the set level and out of their deeply reset condition. The operation is self-limiting in that cells stop their resistance shifts upon reaching the target level. Cells that were not deeply reset are not affected.

A one-time field programmable (OTP) memory cell with related manufacturing and programming techniques is disclosed. An OTP memory cell in accordance with one embodiment includes at least one resistance change element in series with a steering element. The memory cell is field programmed using a reverse bias operation that can reduce leakage currents through the array as well as decrease voltage levels that driver circuitry must normally produce in program operations. An array of memory cells can be fabricated by switching the memory cells from their initial virgin state to a second resistance state during the manufacturing process. In one embodiment, the factory switching operation can include popping an anti-fuse of each memory cell to set them into the second resistance state. The array of memory cells in the second resistance state are provided to an end-user. Control circuitry is also provided with the memory array that can switch the resistance of selected cells back toward their initial resistance state to program the array in accordance with data received from a user or host device.

A one-time field programmable (OTP) memory cell with related manufacturing and programming techniques is disclosed. An OTP memory cell in accordance with one embodiment includes at least one resistance change element in series with a steering element. The memory cell is field programmed using a reverse bias operation that can reduce leakage currents through the array as well as decrease voltage levels that driver circuitry must normally produce in program operations. An array of memory cells can be fabricated by switching the memory cells from their initial virgin state to a second resistance state during the manufacturing process. In one embodiment, the factory switching operation can include popping an anti-fuse of each memory cell to set them into the second resistance state. The array of memory cells in the second resistance state are provided to an end-user. Control circuitry is also provided with the memory array that can switch the resistance of selected cells back toward their initial resistance state to program the array in accordance with data received from a user or host device.

A passive element memory device is provided that includes memory cells comprised of a state change element in series with a steering element. Controlled pulse operations are used to perform resistance changes associated with set and reset operations in an array of memory cells. Selected memory cells in an array are switched to a target resistance state in one embodiment by applying a positive voltage pulse to selected first array lines while applying a negative voltage pulse to selected second array lines. An amplitude of voltage pulses can be increased while being applied to efficiently and safely switch the resistance of cells having different operating characteristics. The cells are subjected to reverse biases in embodiments to lower leakage currents and increase bandwidth. The amplitude and duration of voltage pulses are controlled, along with the current applied to selected memory cells in some embodiments. These controlled pulse-based operations can be used to set memory cells to a lower resistance state or reset memory cells to a higher resistance state in various embodiments.

A reverse bias trim operation for the reset state of a non-volatile memory system is disclosed. Non-volatile memory cells including a resistance change element undergo a reverse bias reset operation to change their resistance from a set state at a first level of resistance to a reset state at a second level of resistance. Certain memory cells in a set of cells that was reset may be deeply reset to a level of resistance beyond a target level for the reset state. A second reverse bias is applied to the set of memory cells to move the resistance of each cell that was deeply reset toward the target level of the reset state. A smaller reverse bias than used for the reset operation can shift the resistance of the cells back toward the set level and out of their deeply reset condition. The operation is self-limiting in that cells stop their resistance shifts upon reaching the target level. Cells that were not deeply reset are not affected.