Abstract: Numerous embodiments of an improved charge pump design are disclosed for generating the high voltages necessary to perform erase and program operations in non-volatile flash memory devices. In these embodiments, each boost stage in the charge pump is modified to overcome a deficiency in prior art charge pumps whereby voltage actually would decrease in the final boost stage. These modifications include the addition of one or more of a clock doubling circuit, a local self-precharge circuit, a feed-forward precharge circuit, a feed-backward precharge circuit, and a hybrid circuit comprising NMOS and PMOS transistors and diodes.

Abstract: Numerous embodiments of an improved charge pump design are disclosed for generating the high voltages necessary to perform erase and program operations in non-volatile flash memory devices. In these embodiments, each boost stage in the charge pump is modified to overcome a deficiency in prior art charge pumps whereby voltage actually would decrease in the final boost stage. These modifications include the addition of one or more of a clock doubling circuit, a local self-precharge circuit, a feed-forward precharge circuit, a feed-backward precharge circuit, and a hybrid circuit comprising NMOS and PMOS transistors and diodes.

Abstract: Numerous embodiments of an improved charge pump design are disclosed for generating the high voltages necessary to perform erase and program operations in non-volatile flash memory devices. In these embodiments, each boost stage in the charge pump is modified to overcome a deficiency in prior art charge pumps whereby voltage actually would decrease in the final boost stage. These modifications include the addition of one or more of a clock doubling circuit, a local self-precharge circuit, a feed-forward precharge circuit, a feed-backward precharge circuit, and a hybrid circuit comprising NMOS and PMOS transistors and diodes.

Abstract: Numerous embodiments of an improved charge pump design are disclosed for generating the high voltages necessary to perform erase and program operations in non-volatile flash memory devices. In these embodiments, each boost stage in the charge pump is modified to overcome a deficiency in prior art charge pumps whereby voltage actually would decrease in the final boost stage. These modifications include the addition of one or more of a clock doubling circuit, a local self-precharge circuit, a feed-forward precharge circuit, a feed-backward precharge circuit, and a hybrid circuit comprising NMOS and PMOS transistors and diodes.

Abstract: In one embodiment, a method of performing an active polling operation can include: (i) detecting a self-timed operation that is to be executed on a serial memory device; (ii) determining if an active polling mode has been enabled; (iii) determining when the self-timed operation has completed execution on the serial memory device; and (iv) providing a completion indication external to the serial memory device when the self-timed operation has completed execution and the active polling mode is enabled.

Abstract: In one embodiment, a method of performing an active polling operation can include: (i) detecting a self-timed operation that is to be executed on a serial memory device; (ii) determining if an active polling mode has been enabled; (iii) determining when the self-timed operation has completed execution on the serial memory device; and (iv) providing a completion indication external to the serial memory device when the self-timed operation has completed execution and the active polling mode is enabled.

Abstract: A post-erase channel clearing procedure for double well, floating gate, non-volatile memory cells. The channel is cleared of charged particles coming from the floating gate after an erase operation in two steps. In the first step the charged particles are pushed into an upper substrate well below the floating gate but not allowed into a deeper well of opposite conductivity type relative to the upper well. After a brief time, T, the charged particles are pushed by a bias voltage into the deeper well from the upper well. This two step clearing procedure avoids device latchup that might occur otherwise.

Abstract: A post-erase channel clearing procedure for double well, floating gate, non-volatile memory cells. The channel is cleared of charged particles coming from the floating gate after an erase operation in two steps. In the first step the charged particles are pushed into an upper substrate well below the floating gate but not allowed into a deeper well of opposite conductivity type relative to the upper well. After a brief time, T, the charged particles are pushed by a bias voltage into the deeper well from the upper well. This two step clearing procedure avoids device latchup that might occur otherwise.

Abstract: A memory system incorporating redundancy utilizes a content addressable memory to monitor addresses during memory accesses. The content addressable memory provides a pointer to an alternate memory location when a previously determined faulty location is requested. Redundant memory cells are accessed by use of column redundancy information output from the content addressable memory. During a memory access cycle a register in the content addressable memory latches a memory address. The content addressable memory decodes the address and produces column redundancy information as an output. The column redundancy information is latched during a period complementary to the memory access cycle. By utilizing complementary memory access phases to latch memory addresses in contrast with a utilization of column redundancy information, a single set of registers may be used. Additionally, concurrent read and write operations are supported.

Abstract: Programming redundant columns for a multi-plane EEPROM includes identifying a defective memory column during a back-end testing operation to provide redundancy information in the form of the original address for the defective column and the address for corresponding fuse links that are programmed to access a redundant column instead of the defective column. From the address for the corresponding fuse links are provided redundant column word-line select (COL RED WL Select) signals to WL input terminals of a Column Redundancy CAM. From the address for the corresponding fuse links are provided column address decoded COL Address Decoded signals to decoded column address input terminals of the Column Redundancy CAM. All of the fuse links are simultaneously programmed.