A memory device includes an open-for-contact region located between the memory blocks, and a row decoder disposed between global lines to which an operating voltage is supplied and the local lines and configured to transfer the operating voltage to one memory block among the memory blocks in response to a row address, wherein a plurality of contacts are formed in the open-for-contact region and configured to transmit a voltage between the bit lines and a peripheral circuit, wherein a dummy region is included in the row decoder and disposed paced apart from the open-for-contact region in the second direction, and wherein a discharge switch is included in the dummy region and configured to discharge the global lines in response to a discharge signal.

A memory device includes an open-for-contact region located between the memory blocks, and a row decoder disposed between global lines to which an operating voltage is supplied and the local lines and configured to transfer the operating voltage to one memory block among the memory blocks in response to a row address, wherein a plurality of contacts are formed in the open-for-contact region and configured to transmit a voltage between the bit lines and a peripheral circuit, wherein a dummy region is included in the row decoder and disposed paced apart from the open-for-contact region in the second direction, and wherein a discharge switch is included in the dummy region and configured to discharge the global lines in response to a discharge signal.

A memory circuit includes a memory array and a control circuit. A first column of the memory array includes a select line, first and second bit lines, a first subset of memory cells coupled to the select line and the first bit line, and a second subset of memory cells coupled to the select line and the second bit line. The control circuit is configured to simultaneously activate each of the select line and the first bit line and, during a period in which the select line and first bit line are simultaneously activated, activate a first plurality of word lines, each word line of the first plurality of word lines being coupled to a memory cell of the first subset of memory cells.

A memory circuit includes a memory array and a control circuit. A first column of the memory array includes a select line, first and second bit lines, a first subset of memory cells coupled to the select line and the first bit line, and a second subset of memory cells coupled to the select line and the second bit line. The control circuit is configured to simultaneously activate each of the select line and the first bit line and, during a period in which the select line and first bit line are simultaneously activated, activate a first plurality of word lines, each word line of the first plurality of word lines being coupled to a memory cell of the first subset of memory cells.

The present invention provides a flash memory controller, wherein the flash memory controller is arranged to access a flash memory module, and the flash memory controller includes a ROM, a microprocessor and a timer. The ROM stores a program code, the microprocessor is configured to execute the program code to control the access of the flash memory module, and the timer is used to generate time information. In the operations of the flash memory controller, the microprocessor refers to the time information to perform dummy read operations upon at least a portion of the blocks, wherein the dummy read operations are not triggered by read commands from a host device.

The present invention provides a flash memory controller, wherein the flash memory controller is arranged to access a flash memory module, and the flash memory controller includes a ROM, a microprocessor and a timer. The ROM stores a program code, the microprocessor is configured to execute the program code to control the access of the flash memory module, and the timer is used to generate time information. In the operations of the flash memory controller, the microprocessor refers to the time information to perform dummy read operations upon at least a portion of the blocks, wherein the dummy read operations are not triggered by read commands from a host device.

A method of writing data to a memory array of three-terminal memory cells includes simultaneously programming a first subset of memory cells in a first column of the memory array to a first logic level by activating a first select line of the first column and a first bit line of the first column, and simultaneously programming a second subset of memory cells in the first column to the first logic level by activating the first select line and a second bit line of the first column.

A method of writing data to a memory array of three-terminal memory cells includes simultaneously programming a first subset of memory cells in a first column of the memory array to a first logic level by activating a first select line of the first column and a first bit line of the first column, and simultaneously programming a second subset of memory cells in the first column to the first logic level by activating the first select line and a second bit line of the first column.

A memory having a plurality of blocks is coupled with control circuits having logic to execute a no-current read setup operation, the read setup operation comprising simultaneously applying a read setup bias to a plurality of memory cells of a selected block of the plurality of blocks while disabling current flow. Logic to traverse the blocks in the plurality of blocks can apply the read setup operation to the plurality of blocks. The blocks in the plurality of blocks can include, respectively, a plurality of sub-blocks. The read setup operation can traverse sub-blocks in a block to simultaneously apply the read setup bias to more than one individual sub-block of the selected block. A block status table can be used to identify stale blocks for the read setup operation. Also, the blocks can be traversed as a background operation independent of read commands addressing the blocks.

A memory cell includes a memory circuit and a multiplier circuit. The multiplier circuit includes an output node configured to output the output signal, a first transistor and an initialization circuit. The first transistor is coupled to the output node and the memory circuit, and is configured to receive at least the second signal. The initialization circuit is coupled to the first transistor by the output node, and is configured to initialize the multiplier circuit in response to at least a third signal or a fourth signal. The memory circuit is configured to store a first value of a first signal of a first storage node. The multiplier circuit is coupled to the memory circuit. The multiplier circuit is configured to generate an output signal in response to the first signal and a second signal. The output signal corresponds to a product of the first signal and the second signal.