Abstract: A non-volatile storage apparatus includes a plurality of non-volatile memory cells formed on a memory die, each non-volatile memory cell configured to hold a plurality of bits of data, and a control circuit formed on the memory die. The control circuit is configured to calculate parity data for data to be stored in the memory cells and program the memory cells to first distributions. The control circuit is also configured to read memory cells in the first distributions, recover the data from results of reading the memory cells in the first distributions combined with the parity data, and further program the memory cells from the first distributions to second distributions to store the data.

Abstract: A storage apparatus includes non-volatile memory cells formed on a memory die, each memory cell configured to hold bits of data, and a control circuit formed on the memory die. The control circuit is configured to calculate parity data for data to be stored in the memory cells and program the memory cells to first distributions. The control circuit is also configured to read the memory cells in the first distributions, recover the data from results of reading the memory cells in the first distributions combined with the parity data, and further program the memory cells from the first distributions to second distributions to store the data. In some cases, the recovered data may have a high bit error rate. To handle higher bit error rates, the use of soft bit data is incorporated into an encoded foggy-fine scheme.

Abstract: A storage apparatus includes non-volatile memory cells formed on a memory die, each memory cell configured to hold bits of data, and a control circuit. The control circuit is configured to calculate parity data for data to be stored in the memory cells and program the memory cells to first distributions. The control circuit is also configured to read memory cells in the first distributions, recover the data from results of reading the memory cells in the first distributions combined with the parity data, and further program the memory cells from the first distributions to second distributions to store the data. To improve the accuracy of recovering the encoded foggy phase data, techniques are presented to calibrate the voltage levels used in sensing the foggy state distributions.

Abstract: A storage apparatus includes non-volatile memory cells formed on a memory die, each memory cell configured to hold bits of data, and a control circuit. The control circuit is configured to calculate parity data for data to be stored in the memory cells and program the memory cells to first distributions. The control circuit is also configured to read memory cells in the first distributions, recover the data from results of reading the memory cells in the first distributions combined with the parity data, and further program the memory cells from the first distributions to second distributions to store the data. To improve the accuracy of recovering the encoded foggy phase data, techniques are presented to calibrate the voltage levels used in sensing the foggy state distributions.

Abstract: A storage apparatus includes non-volatile memory cells formed on a memory die, each memory cell configured to hold bits of data, and a control circuit formed on the memory die. The control circuit is configured to calculate parity data for data to be stored in the memory cells and program the memory cells to first distributions. The control circuit is also configured to read memory cells in the first distributions, recover the data from results of reading the memory cells in the first distributions combined with the parity data, and further program the memory cells from the first distributions to second distributions to store the data. In some cases, the recovered data may have a high bit error rate. To handle higher bit error rates, the use of soft bit data is incorporated into an encoded foggy-fine scheme.

Abstract: A non-volatile storage apparatus includes a plurality of non-volatile memory cells formed on a memory die, each non-volatile memory cell configured to hold a plurality of bits of data, and a control circuit formed on the memory die. The control circuit is configured to calculate parity data for data to be stored in the memory cells and program the memory cells to first distributions. The control circuit is also configured to read memory cells in the first distributions, recover the data from results of reading the memory cells in the first distributions combined with the parity data, and further program the memory cells from the first distributions to second distributions to store the data.

Abstract: Systems and methods are provided for acquiring status information from a plurality of memory die. An apparatus is provided that includes a plurality of memory die and a memory controller. The memory controller is configured to broadcast a first status command to the plurality of memory die, receive a first status response concurrently from the plurality of memory die based on the first status command, and send a repair command to one or more of the plurality of memory die in response to the first status response not satisfying first predetermined status criteria.

Abstract: Systems and methods for increasing performance and reducing power consumption of a non-volatile memory system while the system acquires status information from a plurality of memory die are described. The non-volatile memory system may include a plurality of memory die and a system controller for controlling operations performed by each memory die of the plurality of memory die (e.g., read operations, write operations, or erase operations). The system controller may transmit or broadcast a first status command to each memory die of the plurality of memory die and in response simultaneously or concurrently receive one or more sets of status information from each memory die of the plurality of memory die. The status information may include ready/busy status information (e.g., indicating that a memory die is able to receive new data), programming loop count information, and erase loop count information.

Abstract: Systems and methods are provided for acquiring status information from a plurality of memory die. An apparatus is provided that includes a plurality of memory die and a memory controller. The memory controller is configured to broadcast a first status command to the plurality of memory die, receive a first status response concurrently from the plurality of memory die based on the first status command, and send a repair command to one or more of the plurality of memory die in response to the first status response not satisfying first predetermined status criteria.

Abstract: Systems and methods for increasing performance and reducing power consumption of a non-volatile memory system while the system acquires status information from a plurality of memory die are described. The non-volatile memory system may include a plurality of memory die and a system controller for controlling operations performed by each memory die of the plurality of memory die (e.g., read operations, write operations, or erase operations). The system controller may transmit or broadcast a first status command to each memory die of the plurality of memory die and in response simultaneously or concurrently receive one or more sets of status information from each memory die of the plurality of memory die. The status information may include ready/busy status information (e.g., indicating that a memory die is able to receive new data), programming loop count information, and erase loop count information.

Abstract: A method and apparatus for dynamic programming and dynamic reading of a select non-volatile memory cell in a virtual grounds array is disclosed. In the dynamic read operation the global bit lines and the associated local bit lines are connected to a precharged voltage. One of the first or second global bit lines is connected to a low voltage such as ground, wherein the one global bit line connected to ground also connects to the local bit line for sensing the select non-volatile memory cell. The state of the select non-volatile memory cell is detected by detecting the sense amplifier connected to the global bit line, other than the one global bit line. In a dynamic programming operation, the first and second global bit lines and their associated local bit lines are precharged to a first voltage. One of the first or second global bit line and its associated local bit lines is connected to a second voltage.

Abstract: A method and apparatus for dynamic programming and dynamic reading of a select non-volatile memory cell in a virtual grounds array is disclosed. The array of non-volatile memory cells are arranged in a plurality of rows and columns, wherein each cell in the same column share a first local bit line to one side and share a second local bit line to another side. Alternating local bit lines are connected to a first global bit line and other alternating local bit lines are connected to a second global bit line with the global bit lines connected to a sense amplifier. In the dynamic read operation the global bit lines and the associated local bit lines are connected to a precharged voltage. One of the first or second global bit lines is connected to a low voltage such as ground, wherein the one global bit line connected to ground also connects to the local bit line for sensing the select non-volatile memory cell.

Abstract: A bi-directional read/program non-volatile memory cell and array is capable of achieving high density. Each memory cell has two spaced floating gates for storage of charges thereon. The cell has spaced apart source/drain regions with a channel therebetween, with the channel having three portions. One of the floating gate is over a first portion; another floating gate is over a second portion, and a gate electrode controls the conduction of the channel in the third portion between the first and second portions. An independently controllable control gate is insulated from each of the source/drain regions, and is also capacitively coupled to the floating gate. The cell programs by hot channel electron injection, and erases by Fowler-Nordheim tunneling of electrons from the floating gate to the gate electrode. Bi-directional read permits the cell to be programmed to store bits, with one bit in each floating gate.

Abstract: A first embodiment of a word line voltage boosting circuit for use with an array of non-volatile memory cells has a capacitor, having two ends, connected to the word line. One end of the capacitor is electrically connected to the word line. The other end of the capacitor is electrically connected to a first voltage source. The word line is also connected through a switch to a second source voltage source. A sequencing circuit activates the switch such that the word line is connected to the second voltage source, and the other end of the capacitor is not connected to the first voltage source. Then the sequencing circuit causes the switch to disconnect the word line from the second voltage source, and connect the second end of the capacitor to the first voltage source. The alternate switching of the connection boosts the voltage on the word line. In a second embodiment, a first word line is electrically connected to a first switch to a first voltage source.

Abstract: A bi-directional read/program non-volatile memory cell and array is capable of achieving high density. Each memory cell has two spaced floating gates for storage of charges thereon. The cell has spaced apart source/drain regions with a channel therebetween, with the channel having three portions. One of the floating gate is over a first portion; another floating gate is over a second portion, and a gate electrode controls the conduction of the channel in the third portion between the first and second portions. An independently controllable control gate is insulated from each of the source/drain regions, and is also capacitively coupled to the floating gate. The cell programs by hot channel electron injection, and erases by Fowler-Nordheim tunneling of electrons from the floating gate to the gate electrode. Bi-directional read permits the cell to be programmed to store bits, with one bit in each floating gate.

Abstract: A bi-directional read/program non-volatile memory cell and array is capable of achieving high density. Each memory cell has two spaced floating gates for storage of charges thereon. The cell has spaced apart source/drain regions with a channel therebetween, with the channel having three portions. One of the floating gate is over a first portion; another floating gate is over a second portion, and a gate electrode controls the conduction of the channel in the third portion between the first and second portions. An independently controllable control gate is insulated from each of the source/drain regions, and is also capacitively coupled to the floating gate. The cell programs by hot channel electron injection, and erases by Fowler-Nordheim tunneling of electrons from the floating gate to the gate electrode. Bi-directional read permits the cell to be programmed to store bits, with one bit in each floating gate.

Abstract: A bi-directional read/program non-volatile memory cell and array is capable of achieving high density. Each memory cell has two spaced floating gates for storage of charges thereon. The cell has spaced apart source/drain regions with a channel therebetween, with the channel having three portions. One of the floating gate is over a first portion; another floating gate is over a second portion, and a gate electrode controls the conduction of the channel in the third portion between the first and second portions. A control gate is connected to each of the source/drain regions, and is also capacitively coupled to the floating gate. The cell programs by hot channel electron injection, and erases by Fowler-Nordheim tunneling of electrons from the floating gate to the gate electrode. Bi-directional read permits the cell to be programmed to store bits, with one bit in each floating gate.

Abstract: A stacked gate nonvolatile memory floating gate device has a control gate. Programming of the cell in the array is accomplished by hot channel electron injection from the drain to the floating gate. Erasure occurs by Fowler-Nordheim tunneling of electrons from the floating gate to the control gate. Finally, to increase the density, each cell can be made in a trench.

Abstract: A digital multilevel non-volatile memory includes a massive sensing system that includes a plurality of sense amplifiers disposed adjacent subarrays of memory cells. The sense amplifier includes a high speed load, a wide output range intermediate stage and a low impedance output driver. The high speed load provides high speed sensing. The wide output range provides a sensing margin at high speed on the comparison node. The low impedance output driver drives a heavy noisy load of a differential comparator. A precharge circuit coupled to the input and output of the sense amplifier increases the speed of sensing. A differential comparator has an architecture that includes analog bootstrap. A reference sense amplifier has the same architecture as the differential amplifier to reduce errors in offset. The reference differential amplifier also includes a signal multiplexing for detecting the contents of redundant cells and reference cells.

Abstract: An isolation-less, contact-less nonvolatile memory array has a plurality of memory cells each with a floating gate for the storage of charges thereon, arranged in a plurality of rows and columns. Each memory cell can be of a number of different types. All the bit lines and source lines of the various embodiments are buried and are contact-less. In a first embodiment, each cell can be represented by a stacked gate floating gate transistor coupled to a separate assist transistor. The entire array can be planar; or in a preferred embodiment each of the floating gate transistors is in a trench; or each of the assist transistors is in a trench. In a second embodiment, each cell can be represented by a stacked gate floating gate transistor with the transistor in a trench. In a third embodiment, each cell can be represented by two stacked gate floating gate transistors coupled to a separate assist transistor, positioned between the two stacked gate floating gate transistors.