A load control device may include a semiconductor switch, a control circuit, and first and second terminals adapted to be coupled to a remote device. The load control device may include a first switching circuit coupled to the second terminal, and a second switching circuit coupled between the first terminal and the second terminal. The control circuit may be configured to render the first switching circuit conductive to conduct a charging current from an AC power source to a power supply of the remote device during a first time period of a half-cycle of the AC power source, and further configured to render the first and second switching circuits conductive and non-conductive to communicate with the remote device via the second terminal during a second time period of the half-cycle of the AC power source.

Memory devices might include a controller for access of an array of memory cells and a differential storage device comprising a pair of gate-connected non-volatile memory cells, wherein the controller is configured to cause the memory device to obtain information indicative of a data value stored in a particular memory cell of the array of memory cells, program additional data to the particular memory cell, determine if a power loss to the memory device is indicated while programming the additional data to the particular memory cell, and, if a power loss to the memory device is indicated, selectively program one memory cell of the pair of gate-connected non-volatile memory cells responsive to the information indicative of the data value stored in the particular memory cell.

A triplication register device includes a first register, a second register and a third register, the three registers being identical and containing the same information in common use, a majority vote device and a self-correction device, the correction being dependent on the result from the majority vote device, each register being controlled by an output of a dual-input multiplexer (mux), the first input corresponding to a functional write operation, the second input corresponding to the result of the majority vote, wherein the triplication device comprises a test device whose function is to block, on command and independently, either the functional write operation to the first register, or the functional write operation to the second register, or the functional write operation to the third register, or the self-correction. The test device may comprise a control register that may also be secured by triplication.

A memory may include multiple rows each coupled to multiple memory cells; a target row classification circuit suitable for classifying, as a target row, a row, among the multiple rows, that is susceptible to data loss as a result of activity of an adjacent row; and a target row signal generation circuit suitable for sequentially activating a target row active signal for activating the target row and a target row precharge signal for precharging the target row in response to a precharge command.

A semiconductor memory device includes a logic circuit disposed on a substrate having a cell region and a peripheral region outside the cell region; a source plate defined over the logic circuit; a slit separating the source plate into a cell source plate in the cell region and a dummy source plate in the peripheral region; and a memory cell array defined on the cell source plate. The dummy source plate is maintained at a constant voltage independent of operations of the memory cell array and the logic circuit.

Methods of operating memory might include storing information indicative of a data value of a digit of data stored in a particular memory cell of the memory prior to programming a subsequent digit of data to the particular memory cell, programming the subsequent digit of data to the particular memory cell, monitoring a voltage level of a supply voltage to the memory while programming the subsequent digit of data, and, if the voltage level of the supply voltage falls below a threshold while programming the subsequent digit of data and the information indicative of the data value of the digit of data has a particular logic level, causing a change in threshold voltage of one memory cell of a pair of gate-connected non-volatile memory cells, and inhibiting the other memory cell of the pair of gate-connected non-volatile memory cells from a change in threshold voltage.

A single-event-upset (SEU) stabilized memory cell includes a latch portion including a cross-coupled latch, and at least one cross coupling circuit path in the latch portion including a first series-connected pair of vertical resistors.

Circuitry and methods for restoring data in memory are disclosed. The memory may include at least one layer of a non-volatile two-terminal cross-point array that includes a plurality of two-terminal memory elements that store data as a plurality of conductivity profiles and retain stored data in the absence of power. Over a period of time, logic values indicative of the stored data may drift such that if the logic values are not restored, the stored data may become corrupted. At least a portion of each memory may have data rewritten or restored by circuitry electrically coupled with the memory. Other circuitry may be used to determine a schedule for performing restore operations to the memory and the restore operations may be triggered by an internal or an external signal or event. The circuitry may be positioned in a logic layer and the memory may be fabricated over the logic layer.

A CDMR memory cell, includes a first bitcell which is used to store a current data level and a second bitcell which is used to store the complementary data level. When a read operation is performed, a comparator compares the data levels read from the two bitcells. If these two levels are not complementary, the comparator outputs an indicator. This indicator serves as an alert that a storage error has, or may have, occurred.

A data storage circuit for storing data from volatile memory in response to a power loss, the data storage circuit including an input for receiving a power loss signal in response to a power loss from at least one power source, an input configured to receive data from a volatile memory, a single block of non-volatile matrix of memory cells and a driver circuit coupled to said single row of non-volatile matrix of memory cells. The driver circuit is configured to write data to and read data from said single block of non-volatile matrix of memory cells. The single block of non-volatile matrix of memory cells can be provided as a single row electrically erasable programmable read only memory (EEPROM).