Abstract: A high speed high and low voltage driver provides an output voltage without taxing a pumped voltage. The pumped voltage is used only when the output node has risen substantially to a supply voltage without draining the pumped voltage.

Abstract: A memory device includes memory cells arranged in multiple blocks. A register is provided to track multiple open pages per block of the memory. In one embodiment, the register is located in the memory device and used to determine if a memory access is to be performed. In another embodiment, the register is located external to the memory and used by a processor and/or chip set to determine if an access request is needed.

Abstract: A flash memory has been described that has an interface corresponding to a rambus dynamic random access memory (RDRAM). The memory samples commands and addresses on a rising edge of a clock signal. The read and write data are provided on both the rising edge and the falling edge of the clock signal.

Abstract: A non-volatile memory device includes a memory array having erasable blocks or memory cells. The array has pages that are not one continuous array row. As such, the array row is segmented into page rows. The page rows are addressed contiguously across the page and a main erase block is divided into sub-erase blocks that follow the page row segmentation.

Abstract: A non-volatile memory device includes floating gate memory cells, a pulse counter and voltage pump control circuitry. The control circuitry selectively activates pumps in response to a count output of the counter. In one embodiment, the pump output current is increased as the counter output increases. The memory allows for erase operations that reduce leakage current during initiation of an erase operation.

Abstract: A high speed high and low voltage driver provides an output voltage without taxing a pumped voltage. The pumped voltage is used only when the output node has risen substantially to a supply voltage without draining the pumped voltage.

Abstract: A flash memory has been described that has an interface corresponding to a rambus dynamic random access memory (RDRAM). The memory samples commands and addresses on a rising edge of a clock signal. The read and write data are provided on both the rising edge and the falling edge of the clock signal.

Abstract: A flash memory has been described that has an interface corresponding to a rambus dynamic random access memory (RDRAM). The memory samples commands and addresses on a rising edge of a clock signal. The read and write data are provided on both the rising edge and the falling edge of the clock signal.

Abstract: A non-volatile memory device includes floating gate memory cells, a pulse counter and voltage pump control circuitry. The control circuitry selectively activates pumps in response to a count output of the counter. In one embodiment, the pump output current is increased as the counter output increases. The memory allows for erase operations that reduce leakage current during initiation of an erase operation.

Abstract: A non-volatile memory device includes floating gate memory cells, a pulse counter and voltage pump control circuitry. The control circuitry selectively activates pumps in response to a count output of the counter. In one embodiment, the pump output current is increased as the counter output increases. The memory allows for erase operations that reduce leakage current during initiation of an erase operation.

Abstract: A method and apparatus for discharging global bitlines in a flash memory to a voltage sufficiently low to avoid drain disturb for non-selected cells in a programming operation. A discharge device allows discharge of global bitlines coupled to local bitlines before a programming operation.

Abstract: A memory device is provided. The memory device has a memory array and control circuitry to control operations to the memory array. A redundant register having a bit is also included. The bit is at a first level when two rows of the memory array are shorted together or at a second level when four rows of the memory array are shorted together. The control circuitry instructs an address counter, during an erase operation, to increment row addresses of the rows of the memory array by two rows when the bit is at the first level or four rows when the bit is at the second level.

Abstract: An improved memory device and architecture has been detailed that enhances a Flash memory device that has an SDRAM compatible interface. The memory device employs a virtual paging scheme that allows for the architecture of the memory to implement an efficient Flash memory structure internally. Externally, the memory logically maps the internal Flash architecture to an SDRAM compatible interface and virtual architecture, allowing for memory access and operation with a compatible SDRAM controller device. A double data rate interface is provided to allow data to be input and output from the memory in synchronization with both rising and falling edges of a clock signal.

Abstract: A transition of an external enable signal generates a reset pulse to a counter to set the counter into a known state. The counter, clocked by the external clock signal, generates a clock signal that is decoded by a fuse decoder circuit. The fuse decoder circuit outputs a selection signal to a trim circuit. The trim circuit produces a voltage selection signal, such as a resistance value, that is indicated by the selection signal for use by an internal reference voltage generation circuit. The output of the internal reference voltage generation circuit is compared to the external reference voltage. The counter circuit continues counting until the internal reference voltage is equal to or greater than the external reference voltage. The counter is disabled and the final count that produced the proper internal reference voltage is stored in non-volatile memory cells for future use.

Abstract: A non-volatile memory device includes floating gate memory cells, a pulse counter and voltage pump control circuitry. The control circuitry selectively activates pumps in response to a count output of the counter. In one embodiment, the pump output current is increased as the counter output increases. The memory allows for erase operations that reduce leakage current during initiation of an erase operation.

Abstract: A set of high speed interconnect lines for an integrated circuit has an improved line-to-line capacitance and overall RC time constant. The high speed interconnect line set incorporates a series of interconnect lines, wherein shorter run lines are routed between longer run lines. As the short run interconnect lines reach their destination and fall away they open up the line spacing and improve the line-to-line capacitance that dominates capacitive effects in modern reduced feature size integrated circuits. Additionally, the cross sectional area of the interconnect lines can be increased to lower the line resistance of longer run lines and compensate for the line capacitance without increasing the line-to-line capacitance. The capacitances, resistances, and RC time constants can be optimized for a single line of a group or for the entire group of interconnect lines, providing a low average value or a uniform value across all lines for uniform propagation delay.

Abstract: A high speed high and low voltage driver provides an output voltage without taxing a pumped voltage. The pumped voltage is used only when the output node has risen substantially to a supply voltage without draining the pumped voltage.

Abstract: A transition of an external enable signal generates a reset pulse to a counter to set the counter into a known state. The counter, clocked by the external clock signal, generates a clock signal that is decoded by a fuse decoder circuit. The fuse decoder circuit outputs a selection signal to a trim circuit. The trim circuit produces a voltage selection signal, such as a resistance value, that is indicated by the selection signal for use by an internal reference voltage generation circuit. The output of the internal reference voltage generation circuit is compared to the external reference voltage. The counter circuit continues counting until the internal reference voltage is equal to or greater than the external reference voltage. The counter is disabled and the final count that produced the proper internal reference voltage is stored in non-volatile memory cells for future use.

Abstract: An improved memory device and architecture has been detailed that enhances a Flash memory device that has an SDRAM compatible interface. The memory device employs a virtual paging scheme that allows the memory to have an efficient Flash internal structure, while logically re-mapping this architecture externally to a compatible virtual SDRAM architecture. This allows for access and operation of the improved memory device with a compatible SDRAM controller device, while Flash specific functions can be performed with an SDRAM command sequence. Internal to the memory, memory array banks are divided into four equal segments by row range and logically re-mapped by placing the segments virtually beside each other. This forms a virtual memory bank structure of equivalent rows and columns as a comparable SDRAM device. Additionally, the improved memory device may also have an extended interface that allows for direct access to the internal Flash memory architecture without logical abstraction.

Abstract: A non-volatile memory device includes floating gate memory cells, a pulse counter and voltage pump control circuitry. The control circuitry selectively activates pumps in response to a count output of the counter. In one embodiment, the pump output current is increased as the counter output increases. The memory allows for erase operations that reduce leakage current during initiation of an erase operation.