Abstract: A disturb management technique for a non-volatile memory including first and second memory cells includes programming the first memory cell by applying a first voltage to a first word line coupled to the first memory cell and a second voltage to a terminal, such as a source terminal, shared by the first memory cell and the second memory cell. A non-zero third voltage having the same sign as the second voltage is applied to a second word line coupled to the second memory cell. The applied non-zero third voltage reduces a tunnel current across a gate oxide that insulates the second word line from a substrate of the second memory cell. This results in the second memory cell having a lower likelihood of being disturbed when programming the first memory cell.

Abstract: A disturb management technique for a non-volatile memory including first and second memory cells includes programming the first memory cell by applying a first voltage to a first word line coupled to the first memory cell and a second voltage to a terminal, such as a source terminal, shared by the first memory cell and the second memory cell. A non-zero third voltage having the same sign as the second voltage is applied to a second word line coupled to the second memory cell. The applied non-zero third voltage reduces a tunnel current across a gate oxide that insulates the second word line from a substrate of the second memory cell. This results in the second memory cell having a lower likelihood of being disturbed when programming the first memory cell.

Abstract: A disturb management technique for a non-volatile memory including first and second memory cells includes programming the first memory cell by applying a first voltage to a first word line coupled to the first memory cell and a second voltage to a terminal, such as a source terminal, shared by the first memory cell and the second memory cell. A non-zero third voltage having the same sign as the second voltage is applied to a second word line coupled to the second memory cell. The applied non-zero third voltage reduces a tunnel current across a gate oxide that insulates the second word line from a substrate of the second memory cell. This results in the second memory cell having a lower likelihood of being disturbed when programming the first memory cell.

Abstract: A disturb management technique for a non-volatile memory including first and second memory cells includes programming the first memory cell by applying a first voltage to a first word line coupled to the first memory cell and a second voltage to a terminal, such as a source terminal, shared by the first memory cell and the second memory cell. A non-zero third voltage having the same sign as the second voltage is applied to a second word line coupled to the second memory cell. The applied non-zero third voltage reduces a tunnel current across a gate oxide that insulates the second word line from a substrate of the second memory cell. This results in the second memory cell having a lower likelihood of being disturbed when programming the first memory cell.

Abstract: Read-only (“RO”) data to be permanently imprinted in storage cells of a memory array are written to the memory array. One or more over-stress conditions such as heat, over-voltage, over-current and/or mechanical stress are then applied to the memory array or to individual storage cells within the memory array. The over-stress condition(s) act upon one or more state-determining elements of the storage cells to imprint the RO data. The over-stress condition permanently alters a value of a state-determining property of the state-determining element without incapacitating normal operation of the storage cell. The altered value of the state-determining property biases the cell according to the state of the RO data bit. The bias is detectable in the cell read-out signal. A pre-written ferroelectric random-access memory (“FRAM”) array is baked. Baking traps electric dipoles oriented in a direction corresponding to a state of the pre-written data and forms am RO data imprint.

Abstract: A method for use in erasing data stored in a memory cell includes asserting a voltage differential across a tank region and a gate region of the memory cell, wherein the tank region has a first conductivity type and the tank region is located within a well region of a second conductivity type. The method also includes floating the voltage level of a source region and a drain region of the memory cell, wherein the source region and the drain region are located within the tank region and have the second conductivity type. The method additionally includes discharging a charge stored in the drain region by electrically connecting the source region to an electric potential lower than the potential of the drain region and electrically connecting the well region and the tank region to a potential lower than their existing potentials.

Abstract: A method and system for minimizing bit stress in a non-volatile memory during an erase operation are disclosed, which can increase the absolute value of the gate voltage of a memory cell incrementally with each subsequent high voltage erase pulse during the erase operation, instead of ramping up the absolute value of the gate voltage completely during each pulse. Also, each high voltage pulse can be conditioned so that its leading edge does not transition too quickly. Furthermore, a state machine for a flash memory device is disclosed, which can perform, among other things, the erase functions and/or algorithms used for the flash memory.

Abstract: A method for use in erasing data stored in a memory cell includes asserting a voltage differential across a tank region and a gate region of the memory cell, wherein the tank region has a first conductivity type and the tank region is located within a well region of a second conductivity type. The method also includes floating the voltage level of a source region and a drain region of the memory cell, wherein the source region and the drain region are located within the tank region and have the second conductivity type. The method additionally includes discharging a charge stored in the drain region by electrically connecting the source region to an electric potential lower than the potential of the drain region and electrically connecting the well region and the tank region to a potential lower than their existing potentials.