WO2003052766A1 - Method and system for programming and inhibiting multi-level, non-volatile memory cells - Google Patents

Method and system for programming and inhibiting multi-level, non-volatile memory cells Download PDF

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Publication number
WO2003052766A1
WO2003052766A1 PCT/US2002/037972 US0237972W WO03052766A1 WO 2003052766 A1 WO2003052766 A1 WO 2003052766A1 US 0237972 W US0237972 W US 0237972W WO 03052766 A1 WO03052766 A1 WO 03052766A1
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WIPO (PCT)
Prior art keywords
memory cells
reached
exceeded
level
store
Prior art date
Application number
PCT/US2002/037972
Other languages
French (fr)
Inventor
Khandker N. Quader
Khanh T. Nguyen
Feng Pan
Long C. Pham
Alexander K. Mak
Original Assignee
Sandisk Corporation
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Publication date
Application filed by Sandisk Corporation filed Critical Sandisk Corporation
Priority to KR1020047009586A priority Critical patent/KR100932891B1/en
Priority to AT02794038T priority patent/ATE524811T1/en
Priority to AU2002359496A priority patent/AU2002359496A1/en
Priority to JP2003553575A priority patent/JP4477352B2/en
Priority to EP02794038A priority patent/EP1456852B1/en
Publication of WO2003052766A1 publication Critical patent/WO2003052766A1/en

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Classifications

    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11CSTATIC STORES
    • G11C16/00Erasable programmable read-only memories
    • G11C16/02Erasable programmable read-only memories electrically programmable
    • G11C16/04Erasable programmable read-only memories electrically programmable using variable threshold transistors, e.g. FAMOS
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11CSTATIC STORES
    • G11C16/00Erasable programmable read-only memories
    • G11C16/02Erasable programmable read-only memories electrically programmable
    • G11C16/04Erasable programmable read-only memories electrically programmable using variable threshold transistors, e.g. FAMOS
    • G11C16/0483Erasable programmable read-only memories electrically programmable using variable threshold transistors, e.g. FAMOS comprising cells having several storage transistors connected in series
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11CSTATIC STORES
    • G11C11/00Digital stores characterised by the use of particular electric or magnetic storage elements; Storage elements therefor
    • G11C11/21Digital stores characterised by the use of particular electric or magnetic storage elements; Storage elements therefor using electric elements
    • G11C11/34Digital stores characterised by the use of particular electric or magnetic storage elements; Storage elements therefor using electric elements using semiconductor devices
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11CSTATIC STORES
    • G11C11/00Digital stores characterised by the use of particular electric or magnetic storage elements; Storage elements therefor
    • G11C11/56Digital stores characterised by the use of particular electric or magnetic storage elements; Storage elements therefor using storage elements with more than two stable states represented by steps, e.g. of voltage, current, phase, frequency
    • G11C11/5621Digital stores characterised by the use of particular electric or magnetic storage elements; Storage elements therefor using storage elements with more than two stable states represented by steps, e.g. of voltage, current, phase, frequency using charge storage in a floating gate
    • G11C11/5628Programming or writing circuits; Data input circuits
    • GPHYSICS
    • G11INFORMATION STORAGE
    • G11CSTATIC STORES
    • G11C16/00Erasable programmable read-only memories
    • G11C16/02Erasable programmable read-only memories electrically programmable
    • G11C16/06Auxiliary circuits, e.g. for writing into memory
    • G11C16/34Determination of programming status, e.g. threshold voltage, overprogramming or underprogramming, retention
    • G11C16/3436Arrangements for verifying correct programming or erasure
    • G11C16/3468Prevention of overerasure or overprogramming, e.g. by verifying whilst erasing or writing
    • G11C16/3486Circuits or methods to prevent overprogramming of nonvolatile memory cells, e.g. by detecting onset or cessation of current flow in cells and using the detector output to terminate programming

Definitions

  • the present invention relates to non-volatile memories, and more specifically, to a method and system for programming and inhibiting multi-level, non-volatile memory cells.
  • Non-volatile memories are configured to store data.
  • a flash electrically- erasable, programmable read only memory (EEPROM) is one type of non-volatile memory.
  • a flash EEPROM may comprise an array of memory cells arranged in columns and rows. Each memory cell may comprise a transistor with a floating gate or a dielectric layer configured to store at least two charge levels.
  • a method and system for programming and inhibiting multi-level, non- volatile memory cells are provided in accordance with the present invention.
  • the programming/inhibiting method and system advantageously prevents memory cells that charge faster than other memory cells from being over-programmed.
  • One aspect of the invention relates to a method of programming a plurality of non- volatile memory cells to have a plurality of threshold voltage levels.
  • the method comprises programming the memory cells with at least one voltage pulse. After at least one voltage pulse, the method continues programming if no memory cell has reached or exceeded a first predetermined threshold voltage level.
  • the first predetermined threshold voltage level represents a first set of data bits.
  • the method inhibits programming of any memory cell that has reached or exceeded the first predetermined threshold voltage level.
  • the method determines whether all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level. If at least one memory cell selected to store the first set of data bits has not reached or exceeded the first predetermined threshold voltage level, the method continues programming of uninhibited memory cells.
  • the method determines whether all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level. If at least one memory cell selected to store second or third sets of data bits has not reached or exceeded the first predetermined threshold voltage level, the method continues programming uninhibited memory cells until all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level. If all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level, the method continues programming all memory cells selected to store second or third sets of data bits.
  • the memory cells comprise a first set of one or more memory cells selected to store a charge level equal to or greater than a first predetermined charge level corresponding to a first set of data bits, a second set of one or more memory cells selected to store a charge level equal to or greater than a second predetermined charge level corresponding to a second set of data bits and a third set of one or more memory cells selected to store a charge level equal to or greater than a third predetermined charge level corresponding to a third set of data bits.
  • the method comprises simultaneously storing charge in the first, second and third sets of memory cells to store charge in the memory cells.
  • the method continues storing charge in the memory cells if no memory cell has reached or exceeded the first predetermined charge level.
  • the method inhibits charging of any memory cell in the first, second and third sets that has reached or exceeded the first predetermined charge level.
  • the method determines whether all memory cells in the first set have reached or exceeded the first predetermined charge level. If at least one memory cell in the first set has not reached or exceeded the first predetermined charge level, the method continues storing charge in uninhibited memory cells.
  • Another aspect of the invention relates to a method of programming a plurality of non-volatile memory cells to have a plurality of threshold voltage levels.
  • the method comprises programming the memory cells with at least one voltage pulse. After at least one voltage pulse, the method continues programming if no memory cell has reached or exceeded a first predetermined threshold voltage level.
  • the first predetermined threshold voltage level represents a first set of data bits.
  • the method inhibits programming of any memory cell that has reached or exceeded the first predetermined threshold voltage level.
  • the method determines whether all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level. If at least one memory cell selected to store the first set of data bits has not reached or exceeded the first predetermined threshold voltage level, the method continues programming of uninhibited memory cells.
  • the method determines whether any memory cell has reached or exceeded a second predetermined threshold voltage level.
  • the second predetermined threshold voltage level represents a second set of data bits. The method inhibits programming of any memory cell that has reached or exceeded the second predetermined threshold voltage level and continues programming of uninhibited memory cells.
  • the memory cells comprise a first set of one or more memory cells selected to store a charge equal to or greater than a first predetermined charge level corresponding to a first set of data bits; and a second set of one or more memory cells selected to store a charge equal to or greater than a second predetermined charge level corresponding to a second set of data bits.
  • the memory device is configured to simultaneously program the first and second sets of memory cells and inhibit programming of any memory cell that reaches or exceeds the first predetermined charge level until all memory cells in the first set have reached or exceeded the first predetermined charge level.
  • Another aspect of the invention relates to a method of programming a plurality of non- volatile memory cells.
  • the method comprises storing charge in a first set and a second set of memory cells; continuing storing charge in the memory cells if no memory cell has reached or exceeded a first predetermined charge level, the first predetermined charge level representing at least two data bits; inhibiting storing charge in any memory cell that has reached or exceeded the first predetermined charge level; determining whether all memory cells in the first set of memory cells have reached or exceeded the first predetermined charge level; if at least one memory cell in the first set has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells; and if all memory cells in the first set have reached or exceeded the first predetermined charge level, continuing storing charge in the first set of memory cells.
  • Another aspect of the invention relates to a method of programming a plurality of non-volatile memory cells in parallel from a common threshold level into at least first and second threshold levels as designated by data being stored in the memory cells.
  • the method comprises applying programming conditions to all of the plurality of memory cells designated for the first and second threshold levels; terminating application of the programming conditions to individual ones of the plurality of memory cells designated for the first and second threshold levels as the cells designated for the first and second threshold levels individually reach said first threshold level; after those of the memory cells designated for the first threshold level have all reached the first threshold level, applying programming conditions to those of the plurality of memory cells designated for the second threshold level; and terminating application of the programming conditions to individual ones of the plurality of memory cells designated for the second threshold level as the cells designated for the second threshold level individually reach said second threshold level.
  • Figure 1 illustrates one embodiment of a non- volatile memory system in which the various aspects of the present invention may be implemented.
  • Figure 2 illustrates one embodiment of a NAND-type flash EEPROM memory cell array that may be implemented in the system of Figure 1.
  • Figure 3 illustrates another embodiment of a non-volatile memory system in which the various aspects of the present invention may be implemented.
  • Figure 4A illustrates a part of one embodiment of a NOR-type flash EEPROM memory cell array that may be implemented in the system of Figure 3.
  • Figure 4B illustrates one embodiment of a NOR-type flash EEPROM memory cell that may be implemented in the system of Figure 3.
  • Figure 5 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to a plurality of threshold voltage storage states.
  • Figure 6 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to a plurality of threshold voltage storage states, including fast bits in Vt2 and Vt3 state distributions.
  • Figure 7 illustrates one embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory array of Figure 1 or the memory array in Figure 3.
  • Figure 8 illustrates another embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory array of Figure 1 or the memory array in Figure 3.
  • Figure 9 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to a threshold voltage Vtl storage state with no over-programmed memory cells.
  • Figure 10 illustrates distributions of memory cells in the memory array in
  • Figure 1 or the memory array in Figure 3 that are programmed to threshold voltage Vtl and Vt2 storage states with no over-programmed bits.
  • FIG 11 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to threshold voltage Vtl, Vt2 and Vt3 storage states with no over-programmed bits.
  • Figure 12A illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 after a first page programming process.
  • Figure 12B illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 after a second page programming process.
  • a memory array 1 in Figure 1 comprises a plurality of memory cells or memory elements (Ms) arranged in a row and column matrix.
  • the memory cell array 1 is controlled by a column control circuit 2, a row control circuit 3, a c-source control circuit 4 and a c-p-well control circuit 5.
  • the column control circuit 2 in Figure 1 is coupled to bit lines (BLs) of the memory cell array 1.
  • the column control circuit 2 controls potential levels of the bit lines (BLs), i.e., to apply programming or inhibit programming, to determine states of the memory cells (Ms) during a program operation, and to read data stored in the memory cells (Ms).
  • the row control circuit 3 in Figure 1 is coupled to word lines (WLs) to select one of the word lines (WLs), to apply program voltages combined with the bit line potential levels controlled by the column control circuit 2, to apply read voltages, and to apply an erase voltage.
  • the erase voltage may be coupled with a voltage of a p- type region ("c-p-well ”) on which the memory cells (Ms) are formed.
  • the c-source control circuit 4 in Figure 1 controls a common source line (labeled as "c-source” in Figure 3) connected to the memory cells (Ms).
  • the c-p-well control circuit 5 controls a c-p-well voltage.
  • the column control circuit 2 may read out data stored in the memory cells
  • the external I/O lines 101 are connected to a controller 20.
  • the external I/O lines 101 may transfer program data to be stored in the memory cells to the data input/output buffer 6, which transfers the data to the column control circuit 2.
  • Command data for controlling the flash memory device 100 may be input to a command interface (not shown) coupled to external control lines 102, which are coupled to the controller 20.
  • the command data may inform the memory system 100 of a requested operation.
  • the controller 20 transfers the input command to a state machine 8, which controls the column control circuit 2, the row control circuit 3, the c-source control circuit 4, the c-p-well control circuit 5 and the data input output buffer 6.
  • the state machine 8 can output a status data of the flash memory such as READY/BUSY or PASS/FAIL.
  • the controller 20 in Figure 1 is connected or connectable with a host system (not shown) such as a personal computer, a digital camera or a personal digital assistant (PDA).
  • the host system initiates commands, such as store and read data, to and from the memory array 1 , and provides and receives such data, respectively.
  • the controller 20 converts such commands into command signals that can be interpreted and executed by the command circuits 7.
  • the controller 20 may contain buffer memory for the user data being written to or read from the memory array 1.
  • a memory system 100 may include an integrated circuit chip 21 that includes the controller 20, and one or more integrated circuit chips 22 that each contain a memory array 1 and associated control, command, input/output and state machine circuits 2, 3, 4, 5, 6, 7, 8.
  • the controller 20 (and possibly other control circuits) and one or more memory arrays 1 are integrated together on one or more integrated circuit chips.
  • the memory system 100 may be embedded as part of the host system, or may be included in a memory card that is removably insertable into a mating socket of a host system. Such a card may include the entire memory system 100, or the controller 20 and memory array 1, with associated peripheral circuits. In another embodiment, the associated peripheral circuits may be provided in separate cards.
  • the memory cell array 1 in Figure 1 may comprise any number of memory cells.
  • the memory cell array 1 may be structured as one or more types of flash EEPROM cell arrays, such as NAND-type or NOR-type arrays. Examples of NAND- type or NOR-type arrays are described in co-assigned U.S. Patent No. 6,151,248, entitled “Dual Floating Gate EEPROM Cell Array With Steering Gates Shared By Adjacent Cells," U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, entitled “Semiconductor Device And Memory System,” assigned to Toshiba, which are hereby incorporated by reference in their entireties. Some examples of flash EEPROM cell arrays are described below. NAND-Type Memory Array
  • Figure 2 illustrates one embodiment of a NAND-type flash EEPROM memory cell array 200 that may be implemented in the system 100 of Figure 1.
  • the array 200 comprises a plurality of blocks 202A-202N.
  • Each block 202 comprises a plurality of pages of memory cells.
  • a block 202 may comprise 8 or 16 pages of memory cells.
  • a "block” is the smallest unit of cells that may be simultaneously erased
  • a "page” is the smallest unit of cells that may be simultaneously programmed.
  • a page in Figure 2 may comprise a row of memory cells coupled to a word line, such as word line WL2, and particular bit lines, such as even bit lines BleO- Ble4255.
  • Each column in a block 202 may comprise a group or "string" 210 of memory cells, such as 4, 8, 16 or 32 cells, connected in series between a bit line 204 and a reference potential line 206 via select transistors 208A, 208B at either end.
  • the array 200 in Figure 2 may comprise any number of cells.
  • Word lines 212 are coupled to control gates of cells in several series strings, as shown in Figure 2. An example of a NAND-type array is further described in U.S. Patent
  • Figure 3 illustrates another embodiment of a non-volatile memory system 300 in which the various aspects of the present invention may be implemented.
  • the system 300 in Figure 3 is described in U.S. Patent No. 6,151,248, which has been incorporated by reference.
  • the system 300 comprises a memory array 311, among other components.
  • Figure 4A illustrates a part 400 of one embodiment of a NOR-type flash EEPROM memory cell array that may be implemented in the system 300 of Figure 3.
  • the array part 400 comprises a plurality of memory cells, such as the memory cell 408 connected between adjacent bit lines (BLs)(columns) BL4 and BL5 and a select transistor connected to a word line (row) WLl.
  • BLs bit lines
  • BL4 and BL5 bit lines
  • select transistor connected to a word line (row) WLl.
  • FIG 4B illustrates one embodiment of a NOR-type flash EEPROM memory cell 408 that may be implemented in the system 300 of Figure 3.
  • Each cell 408 comprises two transistors Tl-left, Tl-right with floating gates 402, 404 and a select transistor T2 between the two floating gate transistors.
  • NOR-type arrays examples are described in U.S. Patent Nos. 5,095,344, 5,172,338, 5,602,987, 5,663,901, 5,430,859, 5,657,332, 5,712,180, 5,890,192, and 6,151,248, and U.S. Patent Appl. Serial Nos. 09/505,555, filed February 17, 2000, and 09/667,344, filed September 22, 2000, assigned to SanDisk Corporation, which are hereby incorporated by reference in their entireties.
  • Other examples of NOR-type arrays and their operation are described in U.S. Patent No. 6,046,935, which has been incorporated by reference in its entirety.
  • a floating gate transistor such as the floating gate transistor Tl-left in Figure 4B, comprises a control gate terminal 406, a floating gate 402, a source terminal 412 and a drain terminal 414.
  • Control circuits in Figure 3 may apply a programming voltage to the transistor Tl-left.
  • the floating gate 402 is configured to store a charge level that falls within one of several of different charge level ranges. Examples of programming voltages are disclosed in U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, which have been incorporated by reference.
  • Each charge level range corresponds to a range of threshold voltage levels, such as a range 503 in Figure 5, which would cause the transistor Tl-left ( Figure 4B) to "turn on,” i.e., pass current between the source and drain terminals 412, 414, when a sufficient read or verify voltage is applied to the control gate 406.
  • each range of threshold voltage levels defines a storage state, such as a "VtO" state in Figure 5.
  • Figure 5 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory array 311 in Figure 3 that are programmed to a plurality of threshold voltage storage states, e.g., VtO, Vtl, Vt2 and Vt3.
  • Each storage state is defined by a range of threshold voltage levels.
  • the storage state Vtl may be defined by threshold voltage range 505 with a minimum threshold voltage 504.
  • the "Verify 1" voltage in Figure 5 may be set at the minimum threshold voltage 504 or offset by a small margin to account for non-ideal sensing conditions, such as noise.
  • the floating gate transistor Tl-left has two programmable states, such as the VtO and Vtl states in Figure 5.
  • the transistor Tl-left may store one binary bit of data, where the VtO state may correspond to a "1" data bit and the Vtl state may correspond to a "0" data bit.
  • the floating gate transistor Tl-left has four programmable states, such as the VtO, Vtl , Vt2 and Vt3 states in Figure 5.
  • the transistor Tl-left may store two binary bits of data, where the VtO, Vtl, Vt2 and Vt3 states may correspond to "00,” “01,” “10,” “1 1 " in any configurable order.
  • the VtO, Vtl , Vt2 and Vt3 states may correspond to "11,” “10,” “01,” and "00,” respectively.
  • VtO, Vtl , Vt2 and Vt3 states may correspond to "00,” “01,” “10,” and “1 1,” respectively.
  • One way to minimize the size of the memory system 100 in Figure 1 is to shrink the size of the memory array 1.
  • One solution is to increase the data storage density of the memory array 1 by storing more than one bit of data in each floating gate transistor.
  • a floating gate transistor may be programmed to any number of storage states, such as 4, 8, 16 or 32 states. Each floating gate transistor may have a total range or window of threshold voltages in which the transistor may operate.
  • a total range 500 in Figure 5 comprises ranges 503, 505", 507, 509 that define four states VtO, Vtl, Vt2 and Vt3 for a particular transistor 400 plus margins between the ranges 503, 505, 507, 509 to allow the states to be clearly differentiated from one another.
  • a multi-level non- volatile memory system such as the system 100 in Figure 1 or the system 300 in Figure 3, typically erases a large number of selected memory cells organized as a "block" prior to programming or reprogramming.
  • the system 100 then simultaneously programs selected cells in a "page" within the block from an erase state into individual states corresponding to incoming data to be stored in the memory array 1.
  • the system 100 is configured to simultaneously program more than 1000 cells, such as 4,256 cells.
  • the system 100 alternately applies programming voltage pulses to selected memory cells in parallel and reads the states (i.e., verifying the threshold voltages) of the cells to determine whether individual cells have reached or exceeded their intended states.
  • states i.e., verifying the threshold voltages
  • Examples of programming and verifying methods, including programming and verifying voltage levels, are described in U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, which have been incorporated by reference.
  • the system 100 inhibits programming for any cell that is verified to have reached its intended minimum threshold voltage level, such as the minimum threshold level 504 in Figure 5, by using a verify voltage, e.g., "Verifyl in Figure 5. Programming of other cells in the page may continue until all cells in the page are sufficiently programmed.
  • a verify voltage e.g., "Verifyl in Figure 5.
  • the non- volatile memory system 100 in Figure 1 may program one or more pages of memory cells to various states, such as the VtO, Vtl, Vt2 and Vt3 states in Figure 5, according to a received data pattern of l 's and 0's.
  • All multilevel memory cells in the page of the memory array 1 ( Figure 1) start with a completely erased state, such as VtO in one embodiment.
  • VtO is the lowest state in Figure 5
  • Vt3 is the highest state to be programmed.
  • Memory cells selected to store data (e.g., 00) corresponding to the VtO state do not need program pulses and will be program inhibited.
  • Memory cells selected to store data (e.g., 01, 10 and 11) corresponding to the Vtl, Vt2 and Vt3 states are programmed from the VtO state.
  • Vt data programmed data associated with a particular Vt state
  • Vtl data programmed data associated with a particular Vt state
  • the memory system 100 may program Vt2 and Vt3 data into selected memory cells simultaneously during Vtl programming. This programming method reduces total programming time.
  • each programming pulse is assumed to increase the threshold voltage level of each memory cell by a particular ⁇ Vt, which is less than a programming step size.
  • the voltage difference between programming pulses determines the widths of the VtO, Vtl, Vt2 and Vt3 memory cell distributions in Figure 5. For example, the smaller the difference between programming pulses, the narrower the widths of the VtO, Vtl, Vt2 and Vt3 distributions in Figure 5. But programming pulses with relatively small voltage differences may take a longer period of time to program memory cells compared to programming. pulses with larger voltage differences.
  • the memory cells selected to store Vtl data When the memory cells selected to store Vtl data are completely programmed and verified, the memory cells with Vtl data will have a threshold voltage level at least higher than a Vtl verify level ("Verify 1" in Figure 5) and may have a distribution width close to the programming step size. These memory cells with Vtl data are inhibited from any future programming. At this time, most of the cells selected to be programmed to Vt2 or Vt3 states have threshold voltage levels at about the threshold voltage level associated with the Vtl state, i.e., increased from the threshold voltage level of the starting state of VtO. In one method, the memory cells selected for Vt2 and Vt3 states are not verified or program-inhibited at the Vtl state, which may cause problems as described below.
  • the memory system 100 in Figure 1 then programs and verifies memory cells with Vt2 data, while memory cells with VtO and Vtl data are program inhibited, and memory cells selected to have Nt3 data are programmed simultaneously.
  • the memory system 100 then finishes programming memory cells selected to have Vt3 data. Slow Bits and Fast Bits
  • the programming method described above is acceptable if the threshold voltage levels of the memory cells increase in parallel without too many "fast bits” or “slow bits,” which are memory cells with floating gates that experience a fast or slow increase in charge and threshold voltage levels.
  • Fast bits and slow bits may be caused by a number of factors, such as variations or imperfections in transistor fabrication, altered transistor properties due to repeated programming and erasing, etc. If there is a significant number of fast bits and/or slow bits, then the preceding method may result in over-programmed or under-programmed memory cells.
  • memory cells selected to store Vt2 and Vt3 data are programmed simultaneously during Vtl programming. There may be some fast bits in the Vt2 and Vt3 distributions (memory cells selected to store Vt2 data or Vt3 data) that have passed the Vtl verify level ('Nerifyl" in Figure 5) while Vtl programming is not yet completed. Also, there may be some fast bits in the Vt3 distribution (memory cells selected to store Vt3 data) during Vt2 data programming.
  • Figure 6 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory array 311 in Figure 3 that are programmed to a plurality of threshold voltage storage states, including fast (over-programmed) bits in the Vt2 and Vt3 state distributions 600.
  • the fast bits in the Vt2 and Vt3 distributions 600 are not verified and locked out (program inhibited) during Vtl verify.
  • the fast bits in the Vt2 and Vt3 distributions 600 will receive additional programming pulses needed to complete Vtl programming.
  • the fast bits in the Vt2 and Vt3 distributions 600 could potentially move too fast and reach a Vt3 verify level ("Verify3" in Figure 6) after Vtl programming is completed. At this time, there is no way to recover fast bits in the Vt2 distribution.
  • multi-level memory cells it is also desirable for multi-level memory cells to have states with tight distributions to reduce the highest voltage applied during a READ operation and minimize an amount of cell coupling or the Yupin effect described in U.S. Patent Application Serial No. 09/893,277, which has been incorporated by reference.
  • Figure 7 illustrates one embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory a ⁇ ay 1 of Figure 1 or the memory a ⁇ ay 311 in Figure 3.
  • the controller 20 in Figure 1 receives a mixed data pattern, which co ⁇ esponds to multiple states such as VtO, Vtl, Vt2 and Vt3, to be written to one or more pages of memory cells in the memory a ⁇ ay 1.
  • the system 100 ( Figure 1) inhibits programming of all memory cells selected to be in a VtO state in the memory page(s).
  • the system 100 simultaneously programs all memory cells selected to store Vtl data, all memory cells selected to store Vt2 data and all memory cells selected to store Vt3 data with programming pulses in a block 700.
  • the system 100 ( Figure 1) performs a verify operation by applying a read voltage condition to the programmed memory cells in the page(s) and determining whether any programmed memory cell has a threshold voltage higher than "Verify 1" in Figure 9, i.e., reached the Vtl state.
  • the "Verify 1" voltage in Figure 9 may be set at the minimum threshold voltage 902 or offset by a small margin to account for non-ideal sensing conditions, such as noise.
  • There are several ways to verify the programming of a memory cell such as monitoring a cu ⁇ ent or voltage level, which are known to those of ordinary skill in the art.
  • This Vtl verify operation is performed on all memory cells in the memory block(s) selected to store Vtl, Vt2 or Vt3 data.
  • memory cells selected to store Vt2 or Vt3 data are programmed and verified at the Vtl state with the "Verifyl" voltage simultaneously with memory cells selected to store Vtl data. If no programmed memory cells have reached the Vtl state, the system 100 returns to block 700. If one or more programmed memory cells have reached the Vtl state, the system 100 proceeds to block 704. In a block 704 ( Figure 7), the system 100 ( Figure 1) locks out or inhibits the programming of each memory cell that has reached the Vtl state for the rest of the Vtl programming process.
  • the lock out or program inhibit prevents fast Vt2 and Vt3 bits from being over-programmed as in the Vt2 and Vt3 memory cell distributions 600 in Figure 6.
  • Figure 9 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory a ⁇ ay 311 in Figure 3 that are programmed to a threshold voltage Vtl storage state with no over-programmed memory cells.
  • a block 706 the system 100 performs a verify operation to determine whether all memory cells selected to store Vtl data have reached the Vtl state with a Verifyl voltage (Figure 9). If at least one memory cell selected to store Vtl data has not reached the Vtl state, the system 100 returns to block 700. Otherwise, the system proceeds to either block 708 in Figure 7 or block 800 in Figure 8.
  • a block 708 all memory cells selected to store Vtl data have reached the Vtl state.
  • the system 708 performs a verify operation to determine whether all memory cells selected to store Vt2 data or Vt3 data have reached the Vtl state. If the memory cells selected to store Vt2 data or Vt3 data have not all reached the Vtl state, the system 100 repeats blocks 700-704 for the memory cells selected to store Vt2 data or Vt3 data and returns to block 708.
  • the system 100 continues programming and verifying the memory cells selected to store Vt2 data or Vt3 data in a process similar to the process in blocks 700- 706. Specifically, the system 100 programs all memory cells selected to store Vt2 data and all memory cells selected to store Vt3 data with programming pulses.
  • the system 100 After one or more pulses, the system 100 performs a verify operation to determine whether any memory cell has reached the Vt2 state.
  • the system 100 locks out or inhibits the programming of each memory cell that has reached the Vt2 state for the rest of the Vt2 programming process.
  • the system 100 performs a verify operation to determine whether all memory cells selected to store Vt2 data have reached the Vt2 state with the Verify2 voltage ( Figure 10). If at least one memory cell selected to store Vt2 data has not reached the Vt2 state, the system 100 continues Vt2 programming. Otherwise, the system proceeds with Vt3 programming.
  • Figure 10 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory a ⁇ ay 311 in Figure 3 that are programmed to threshold voltage Vtl and Vt2 storage states with no over-programmed bits.
  • Figure 11 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory a ⁇ ay 311 in Figure 3 that are programmed to threshold voltage Vtl, Vt2 and Vt3 storage states with no over-programmed bits.
  • Figure 8 illustrates another embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory a ⁇ ay 1 of Figure
  • a block 800 the system 100 performs a verify operation to determine whether any memory cell selected to store Vt2 data has reached the Vt2 state with a Verify2 voltage in Figure 10. If one or more memory cells selected to store Vt2 data have reached the Vt2 state, the system 100 proceeds to block 802. In a block 802, the system 100 locks out or inhibits the programming of each memory cell that has reached the Vt2 state for the rest of the Vt2 programming process. The system 100 proceeds to a block 806.
  • the system 100 programs the memory cells selected to store Vt2 data with programming pulses in a block 804. After one or more programming pulses, the system returns to block 800.
  • the system 100 performs a verify operation with the Verify2 voltage to determine whether all memory cells selected to store Vt2 data have reached the Vt2 state. If one or more memory cells selected to store Vt2 data have not reached Vt2 state, the system 100 returns to block 804 and continues programming. If all memory cells selected to store Vt2 data have reached the Vt2 state, the system 100 has successfully locked out fast bits in the Vt2 and Vt3 distributions and achieved a memory cell distribution similar to the distribution shown in Figure 10.
  • the system 100 performs a verify operation with a Verify3 voltage in Figure 10 to determine whether any memory cell selected to store Vt3 data has reached the Vt3 state.
  • the system 100 locks out or inhibits programming of each memory cell that has reached the Vt3 state for the rest of the Vt3 programming process. The system 100 then continues programming memory cells selected to store Vt3 data that have not been locked out and verifying the level of programming.
  • the method of Figure 8 completely locks all fast bits in the Vt2 and Vt3 distributions to achieve memory cell distributions similar to Figure 11.
  • Any slow bits (memory cells with slow programming) selected to store Vt2 or Vt3 data that do not pass the Vtl verify process (blocks 700-706 in Figure 7) will be programmed and verified at the Vt2 state with Verify2 voltage, as shown in blocks 800-806 in Figure 8.
  • slow bits selected to store Vt2 or Vt3 data do not cause a problem.
  • the programming sequences for state transitions in Figures 7 and 8 described above may be applied to any state transition sequence, as long as there are more than two states being simultaneously programmed from one or more lower states.
  • the system 100 of Figure 1 may include data latches or registers in the column control circuits 2 (or the controller 20, the command circuits 7 or the data input/output circuits 6).
  • the data latches are configured to hold data to be written to the memory array 1 and data read from the memory a ⁇ ay 1. Examples of data latches or registers and their operations are described in Figure 7 of U.S. Patent Application Serial No. 09/893,277 and in U.S. Patent No. 6,046,935, which have been incorporated by reference.
  • memory cells programmed to each state in Figure 11 should have a Vt distribution width (e.g., widths 503, 595, 507, 509) less than or equal to the program step-up size.
  • Vt distribution widths and program step-up sizes are provided in U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, which have been incorporated by reference.
  • Figure 12A illustrates distributions of memory cells in the memory array 100 in Figure 1 or the memory a ⁇ ay 311 in Figure 3 after a first page programming process.
  • the first page may be refe ⁇ ed to as an "upper" page or a "lower” page.
  • Some memory systems program a lower page first, as described in U.S. Patent Application Serial No. 09/893,277 (see Figures 10A-10B).
  • Figure 12B illustrates distributions of memory cells in the memory a ⁇ ay 100 in Figure 1 or the memory a ⁇ ay 311 in Figure 3 after a second page programming process.
  • the second page may be refe ⁇ ed to as an "upper" page or a "lower” page.
  • the memory cells at the second state 1202 may be program-inhibited at the second state 1202 or programmed to the third state 1203.
  • the memory cells at the first state 1201 may be program-inhibited at the first state 1201 or programmed to a third state 1203 and then programmed to a fourth state 1204.
  • some memory cells in the first and second states 1201, 1202 are simultaneously programmed to the third state 1203.
  • the programming method may verify whether any memory cell intended to reach the fourth state 1204 has been programmed from the first state 1201 to the third state 1203. If any memory cell intended to reach the fourth state 1204 has reached the third state 1203, the method may lock out/program inhibit each such memory cell until all such memory cells have reached the third state 1203. Thus, some memory cells in the first and second states 1201, 1202 are simultaneously programmed and verified at the third state 1203. After all memory cells intended to reach the fourth state 1204 have been verified at the third state 1203, the method may program such cells to the fourth state 1204, as shown in Figure 12B.
  • the preceding method catches fast bits when memory cells at the first state 1201 are programmed to the fourth state 1204 and reduces the probability of fast bits from over-shooting the fourth state distribution in Figure 12B.

Abstract

A multi-level non-volatile memory cell programming/lockout method and system (100) are provided. The non-volatile memory cell comprising a first set of one or more memory cells selected to store a charge equal or greater than a first predetermined charge level (504), a second set of one or more memory cells selected tos tore a charge equal or greater than a second predetermined charge level, the memory device is configured to simultaneously program the first and second sets of memory cells and inhibit progamming of any memory cell that reaches or exceeds the first predetermined charge level until all memory cells in the first set have reached or exceeded the first predetermined charge level.

Description

METHOD AND SYSTEM FOR PROGRAMMING AND INHIBITING MULTI-LEVEL, NON-VOLATILE MEMORY CELLS
FIELD OF THE INVENTION
The present invention relates to non-volatile memories, and more specifically, to a method and system for programming and inhibiting multi-level, non-volatile memory cells.
BACKGROUND OF THE INVENTION
Non-volatile memories are configured to store data. A flash electrically- erasable, programmable read only memory (EEPROM) is one type of non-volatile memory. A flash EEPROM may comprise an array of memory cells arranged in columns and rows. Each memory cell may comprise a transistor with a floating gate or a dielectric layer configured to store at least two charge levels.
SUMMARY OF THE INVENTION A method and system for programming and inhibiting multi-level, non- volatile memory cells are provided in accordance with the present invention. The programming/inhibiting method and system advantageously prevents memory cells that charge faster than other memory cells from being over-programmed.
One aspect of the invention relates to a method of programming a plurality of non- volatile memory cells to have a plurality of threshold voltage levels. The method comprises programming the memory cells with at least one voltage pulse. After at least one voltage pulse, the method continues programming if no memory cell has reached or exceeded a first predetermined threshold voltage level. The first predetermined threshold voltage level represents a first set of data bits. The method inhibits programming of any memory cell that has reached or exceeded the first predetermined threshold voltage level. The method determines whether all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level. If at least one memory cell selected to store the first set of data bits has not reached or exceeded the first predetermined threshold voltage level, the method continues programming of uninhibited memory cells. If all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level, the method determines whether all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level. If at least one memory cell selected to store second or third sets of data bits has not reached or exceeded the first predetermined threshold voltage level, the method continues programming uninhibited memory cells until all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level. If all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level, the method continues programming all memory cells selected to store second or third sets of data bits.
Another aspect of the invention relates to a method of programming a plurality of non-volatile memory cells. The memory cells comprise a first set of one or more memory cells selected to store a charge level equal to or greater than a first predetermined charge level corresponding to a first set of data bits, a second set of one or more memory cells selected to store a charge level equal to or greater than a second predetermined charge level corresponding to a second set of data bits and a third set of one or more memory cells selected to store a charge level equal to or greater than a third predetermined charge level corresponding to a third set of data bits. The method comprises simultaneously storing charge in the first, second and third sets of memory cells to store charge in the memory cells. The method continues storing charge in the memory cells if no memory cell has reached or exceeded the first predetermined charge level. The method inhibits charging of any memory cell in the first, second and third sets that has reached or exceeded the first predetermined charge level. The method determines whether all memory cells in the first set have reached or exceeded the first predetermined charge level. If at least one memory cell in the first set has not reached or exceeded the first predetermined charge level, the method continues storing charge in uninhibited memory cells.
Another aspect of the invention relates to a method of programming a plurality of non-volatile memory cells to have a plurality of threshold voltage levels. The method comprises programming the memory cells with at least one voltage pulse. After at least one voltage pulse, the method continues programming if no memory cell has reached or exceeded a first predetermined threshold voltage level. The first predetermined threshold voltage level represents a first set of data bits. The method inhibits programming of any memory cell that has reached or exceeded the first predetermined threshold voltage level. The method determines whether all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level. If at least one memory cell selected to store the first set of data bits has not reached or exceeded the first predetermined threshold voltage level, the method continues programming of uninhibited memory cells. If all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level, the method determines whether any memory cell has reached or exceeded a second predetermined threshold voltage level. The second predetermined threshold voltage level represents a second set of data bits. The method inhibits programming of any memory cell that has reached or exceeded the second predetermined threshold voltage level and continues programming of uninhibited memory cells.
Another aspect of the invention relates to a memory device comprising a plurality of non- volatile memory cells. The memory cells comprise a first set of one or more memory cells selected to store a charge equal to or greater than a first predetermined charge level corresponding to a first set of data bits; and a second set of one or more memory cells selected to store a charge equal to or greater than a second predetermined charge level corresponding to a second set of data bits. The memory device is configured to simultaneously program the first and second sets of memory cells and inhibit programming of any memory cell that reaches or exceeds the first predetermined charge level until all memory cells in the first set have reached or exceeded the first predetermined charge level.
Another aspect of the invention relates to a method of programming a plurality of non- volatile memory cells. The method comprises storing charge in a first set and a second set of memory cells; continuing storing charge in the memory cells if no memory cell has reached or exceeded a first predetermined charge level, the first predetermined charge level representing at least two data bits; inhibiting storing charge in any memory cell that has reached or exceeded the first predetermined charge level; determining whether all memory cells in the first set of memory cells have reached or exceeded the first predetermined charge level; if at least one memory cell in the first set has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells; and if all memory cells in the first set have reached or exceeded the first predetermined charge level, continuing storing charge in the first set of memory cells. Another aspect of the invention relates to a method of programming a plurality of non-volatile memory cells in parallel from a common threshold level into at least first and second threshold levels as designated by data being stored in the memory cells. The method comprises applying programming conditions to all of the plurality of memory cells designated for the first and second threshold levels; terminating application of the programming conditions to individual ones of the plurality of memory cells designated for the first and second threshold levels as the cells designated for the first and second threshold levels individually reach said first threshold level; after those of the memory cells designated for the first threshold level have all reached the first threshold level, applying programming conditions to those of the plurality of memory cells designated for the second threshold level; and terminating application of the programming conditions to individual ones of the plurality of memory cells designated for the second threshold level as the cells designated for the second threshold level individually reach said second threshold level.
BRIEF DESCRIPTION OF THE DRAWINGS
Figure 1 illustrates one embodiment of a non- volatile memory system in which the various aspects of the present invention may be implemented. Figure 2 illustrates one embodiment of a NAND-type flash EEPROM memory cell array that may be implemented in the system of Figure 1.
Figure 3 illustrates another embodiment of a non-volatile memory system in which the various aspects of the present invention may be implemented.
Figure 4A illustrates a part of one embodiment of a NOR-type flash EEPROM memory cell array that may be implemented in the system of Figure 3.
Figure 4B illustrates one embodiment of a NOR-type flash EEPROM memory cell that may be implemented in the system of Figure 3.
Figure 5 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to a plurality of threshold voltage storage states.
Figure 6 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to a plurality of threshold voltage storage states, including fast bits in Vt2 and Vt3 state distributions. Figure 7 illustrates one embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory array of Figure 1 or the memory array in Figure 3.
Figure 8 illustrates another embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory array of Figure 1 or the memory array in Figure 3.
Figure 9 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to a threshold voltage Vtl storage state with no over-programmed memory cells. Figure 10 illustrates distributions of memory cells in the memory array in
Figure 1 or the memory array in Figure 3 that are programmed to threshold voltage Vtl and Vt2 storage states with no over-programmed bits.
Figure 11 illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 that are programmed to threshold voltage Vtl, Vt2 and Vt3 storage states with no over-programmed bits.
Figure 12A illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 after a first page programming process.
Figure 12B illustrates distributions of memory cells in the memory array in Figure 1 or the memory array in Figure 3 after a second page programming process.
DETAILED DESCRIPTION The principles of the present invention may be applied to various types of nonvolatile memories that currently exist, such as an erasable programmable read-only memory (EPROM) or an electrically-erasable programmable read-only memory (EEPROM). The principles of the present invention may also be applied to various types of non-volatile memories that use new technologies. Implementations of the present invention are described herein with respect to a flash EEPROM, where each memory cell comprises at least one charge storage element, such as a transistor with a floating gate or a dielectric layer. Figure 1 illustrates one embodiment of a non- volatile memory system 100 in which the various aspects of the present invention may be implemented. The system 100 in Figure 1 is described in co-assigned U.S. Patent Application Serial No. 09/893,277, entitled "Operating Techniques For Reducing Effects Of Coupling Between Storage Elements Of A Non- Volatile Memory Operated In Multiple Data States" (Attorney Docket No. M- 10321), filed on June 27, 2001, which is hereby incorporated by reference in its entirety.
A memory array 1 in Figure 1 comprises a plurality of memory cells or memory elements (Ms) arranged in a row and column matrix. The memory cell array 1 is controlled by a column control circuit 2, a row control circuit 3, a c-source control circuit 4 and a c-p-well control circuit 5.
The column control circuit 2 in Figure 1 is coupled to bit lines (BLs) of the memory cell array 1. The column control circuit 2 controls potential levels of the bit lines (BLs), i.e., to apply programming or inhibit programming, to determine states of the memory cells (Ms) during a program operation, and to read data stored in the memory cells (Ms).
The row control circuit 3 in Figure 1 is coupled to word lines (WLs) to select one of the word lines (WLs), to apply program voltages combined with the bit line potential levels controlled by the column control circuit 2, to apply read voltages, and to apply an erase voltage. The erase voltage may be coupled with a voltage of a p- type region ("c-p-well ") on which the memory cells (Ms) are formed.
The c-source control circuit 4 in Figure 1 controls a common source line (labeled as "c-source" in Figure 3) connected to the memory cells (Ms). The c-p-well control circuit 5 controls a c-p-well voltage. The column control circuit 2 may read out data stored in the memory cells
(Ms) of the array 1 and output the data to external I/O lines 101 via a data input/output buffer 6. The external I/O lines 101 are connected to a controller 20. The external I/O lines 101 may transfer program data to be stored in the memory cells to the data input/output buffer 6, which transfers the data to the column control circuit 2. Command data for controlling the flash memory device 100 may be input to a command interface (not shown) coupled to external control lines 102, which are coupled to the controller 20. The command data may inform the memory system 100 of a requested operation. The controller 20 transfers the input command to a state machine 8, which controls the column control circuit 2, the row control circuit 3, the c-source control circuit 4, the c-p-well control circuit 5 and the data input output buffer 6. The state machine 8 can output a status data of the flash memory such as READY/BUSY or PASS/FAIL.
The controller 20 in Figure 1 is connected or connectable with a host system (not shown) such as a personal computer, a digital camera or a personal digital assistant (PDA). The host system initiates commands, such as store and read data, to and from the memory array 1 , and provides and receives such data, respectively. The controller 20 converts such commands into command signals that can be interpreted and executed by the command circuits 7. The controller 20 may contain buffer memory for the user data being written to or read from the memory array 1. As shown in Figure 1, a memory system 100 may include an integrated circuit chip 21 that includes the controller 20, and one or more integrated circuit chips 22 that each contain a memory array 1 and associated control, command, input/output and state machine circuits 2, 3, 4, 5, 6, 7, 8. In another embodiment, the controller 20 (and possibly other control circuits) and one or more memory arrays 1 are integrated together on one or more integrated circuit chips. The memory system 100 may be embedded as part of the host system, or may be included in a memory card that is removably insertable into a mating socket of a host system. Such a card may include the entire memory system 100, or the controller 20 and memory array 1, with associated peripheral circuits. In another embodiment, the associated peripheral circuits may be provided in separate cards.
The memory cell array 1 in Figure 1 may comprise any number of memory cells. The memory cell array 1 may be structured as one or more types of flash EEPROM cell arrays, such as NAND-type or NOR-type arrays. Examples of NAND- type or NOR-type arrays are described in co-assigned U.S. Patent No. 6,151,248, entitled "Dual Floating Gate EEPROM Cell Array With Steering Gates Shared By Adjacent Cells," U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, entitled "Semiconductor Device And Memory System," assigned to Toshiba, which are hereby incorporated by reference in their entireties. Some examples of flash EEPROM cell arrays are described below. NAND-Type Memory Array
Figure 2 illustrates one embodiment of a NAND-type flash EEPROM memory cell array 200 that may be implemented in the system 100 of Figure 1. The array 200 comprises a plurality of blocks 202A-202N. Each block 202 comprises a plurality of pages of memory cells. For example, a block 202 may comprise 8 or 16 pages of memory cells. In one embodiment, a "block" is the smallest unit of cells that may be simultaneously erased, and a "page" is the smallest unit of cells that may be simultaneously programmed.
A page in Figure 2 may comprise a row of memory cells coupled to a word line, such as word line WL2, and particular bit lines, such as even bit lines BleO- Ble4255. Each column in a block 202 may comprise a group or "string" 210 of memory cells, such as 4, 8, 16 or 32 cells, connected in series between a bit line 204 and a reference potential line 206 via select transistors 208A, 208B at either end. The array 200 in Figure 2 may comprise any number of cells. Word lines 212 are coupled to control gates of cells in several series strings, as shown in Figure 2. An example of a NAND-type array is further described in U.S. Patent
Application Serial No. 09/893,277, which has been incorporated by reference. Other examples of such NAND-type arrays are described in U.S. Patent Nos. 5,570,315, 5,774,397 and 6,046,935, and Patent Appl. Serial No. 09/667,610, assigned to Toshiba, which are hereby incorporated by reference in their entireties. NOR-Type Memory Array
Figure 3 illustrates another embodiment of a non-volatile memory system 300 in which the various aspects of the present invention may be implemented. The system 300 in Figure 3 is described in U.S. Patent No. 6,151,248, which has been incorporated by reference. The system 300 comprises a memory array 311, among other components.
Figure 4A illustrates a part 400 of one embodiment of a NOR-type flash EEPROM memory cell array that may be implemented in the system 300 of Figure 3. The array part 400 comprises a plurality of memory cells, such as the memory cell 408 connected between adjacent bit lines (BLs)(columns) BL4 and BL5 and a select transistor connected to a word line (row) WLl. Although a particular number of memory cells are shown in Figure 4A as an example, the array part 400 may comprise any number of cells. The cells may be organized in blocks and/or pages.
Figure 4B illustrates one embodiment of a NOR-type flash EEPROM memory cell 408 that may be implemented in the system 300 of Figure 3. Each cell 408 comprises two transistors Tl-left, Tl-right with floating gates 402, 404 and a select transistor T2 between the two floating gate transistors.
Examples of NOR-type arrays and their use in storage systems are described in U.S. Patent Nos. 5,095,344, 5,172,338, 5,602,987, 5,663,901, 5,430,859, 5,657,332, 5,712,180, 5,890,192, and 6,151,248, and U.S. Patent Appl. Serial Nos. 09/505,555, filed February 17, 2000, and 09/667,344, filed September 22, 2000, assigned to SanDisk Corporation, which are hereby incorporated by reference in their entireties. Other examples of NOR-type arrays and their operation are described in U.S. Patent No. 6,046,935, which has been incorporated by reference in its entirety. Floatine Gate Transistor and Programmable States A floating gate transistor, such as the floating gate transistor Tl-left in Figure 4B, comprises a control gate terminal 406, a floating gate 402, a source terminal 412 and a drain terminal 414. Control circuits in Figure 3 may apply a programming voltage to the transistor Tl-left. After the programming voltage, the floating gate 402 is configured to store a charge level that falls within one of several of different charge level ranges. Examples of programming voltages are disclosed in U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, which have been incorporated by reference.
Each charge level range corresponds to a range of threshold voltage levels, such as a range 503 in Figure 5, which would cause the transistor Tl-left (Figure 4B) to "turn on," i.e., pass current between the source and drain terminals 412, 414, when a sufficient read or verify voltage is applied to the control gate 406. Thus, each range of threshold voltage levels defines a storage state, such as a "VtO" state in Figure 5.
Figure 5 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory array 311 in Figure 3 that are programmed to a plurality of threshold voltage storage states, e.g., VtO, Vtl, Vt2 and Vt3. Each storage state is defined by a range of threshold voltage levels. For example, the storage state Vtl may be defined by threshold voltage range 505 with a minimum threshold voltage 504. The "Verify 1" voltage in Figure 5 may be set at the minimum threshold voltage 504 or offset by a small margin to account for non-ideal sensing conditions, such as noise.
If the floating gate 402 in Figure 4B has two programmable threshold voltage ranges, i.e., two ranges of stored charge levels, such as ranges 503, 505 in Figure 5, the floating gate transistor Tl-left has two programmable states, such as the VtO and Vtl states in Figure 5. Thus, the transistor Tl-left may store one binary bit of data, where the VtO state may correspond to a "1" data bit and the Vtl state may correspond to a "0" data bit.
If the floating gate 402 in Figure 4 has four programmable threshold voltage ranges, such as the ranges 503, 505, 507, 509 in Figure 5, the floating gate transistor Tl-left has four programmable states, such as the VtO, Vtl , Vt2 and Vt3 states in Figure 5. The transistor Tl-left may store two binary bits of data, where the VtO, Vtl, Vt2 and Vt3 states may correspond to "00," "01," "10," "1 1 " in any configurable order. For example, the VtO, Vtl , Vt2 and Vt3 states may correspond to "11," "10," "01," and "00," respectively. As another example, the VtO, Vtl , Vt2 and Vt3 states may correspond to "00," "01," "10," and "1 1," respectively. One way to minimize the size of the memory system 100 in Figure 1 is to shrink the size of the memory array 1. One solution is to increase the data storage density of the memory array 1 by storing more than one bit of data in each floating gate transistor. A floating gate transistor may be programmed to any number of storage states, such as 4, 8, 16 or 32 states. Each floating gate transistor may have a total range or window of threshold voltages in which the transistor may operate. For example, a total range 500 in Figure 5 comprises ranges 503, 505", 507, 509 that define four states VtO, Vtl, Vt2 and Vt3 for a particular transistor 400 plus margins between the ranges 503, 505, 507, 509 to allow the states to be clearly differentiated from one another.
Programming Multiple States
A multi-level non- volatile memory system, such as the system 100 in Figure 1 or the system 300 in Figure 3, typically erases a large number of selected memory cells organized as a "block" prior to programming or reprogramming. The system 100 then simultaneously programs selected cells in a "page" within the block from an erase state into individual states corresponding to incoming data to be stored in the memory array 1. In one embodiment, the system 100 is configured to simultaneously program more than 1000 cells, such as 4,256 cells.
In one embodiment, the system 100 alternately applies programming voltage pulses to selected memory cells in parallel and reads the states (i.e., verifying the threshold voltages) of the cells to determine whether individual cells have reached or exceeded their intended states. Examples of programming and verifying methods, including programming and verifying voltage levels, are described in U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, which have been incorporated by reference.
The system 100 inhibits programming for any cell that is verified to have reached its intended minimum threshold voltage level, such as the minimum threshold level 504 in Figure 5, by using a verify voltage, e.g., "Verifyl in Figure 5. Programming of other cells in the page may continue until all cells in the page are sufficiently programmed.
For example, the non- volatile memory system 100 in Figure 1 may program one or more pages of memory cells to various states, such as the VtO, Vtl, Vt2 and Vt3 states in Figure 5, according to a received data pattern of l 's and 0's. All multilevel memory cells in the page of the memory array 1 (Figure 1) start with a completely erased state, such as VtO in one embodiment. In this embodiment, VtO is the lowest state in Figure 5, and Vt3 is the highest state to be programmed. Memory cells selected to store data (e.g., 00) corresponding to the VtO state do not need program pulses and will be program inhibited. Memory cells selected to store data (e.g., 01, 10 and 11) corresponding to the Vtl, Vt2 and Vt3 states are programmed from the VtO state.
As used herein, programmed data associated with a particular Vt state may be referred to as "Vt data." For example, "01" data associated with a Vtl state may be referred to as "Vtl data." Simultaneous Programming In one embodiment, since memory cells selected to store Vt2 and Vt3 data need to be programmed to higher threshold voltage levels, the memory system 100 (Figure 1) may program Vt2 and Vt3 data into selected memory cells simultaneously during Vtl programming. This programming method reduces total programming time. In this embodiment, each programming pulse is assumed to increase the threshold voltage level of each memory cell by a particular ΔVt, which is less than a programming step size.
The voltage difference between programming pulses determines the widths of the VtO, Vtl, Vt2 and Vt3 memory cell distributions in Figure 5. For example, the smaller the difference between programming pulses, the narrower the widths of the VtO, Vtl, Vt2 and Vt3 distributions in Figure 5. But programming pulses with relatively small voltage differences may take a longer period of time to program memory cells compared to programming. pulses with larger voltage differences.
When the memory cells selected to store Vtl data are completely programmed and verified, the memory cells with Vtl data will have a threshold voltage level at least higher than a Vtl verify level ("Verify 1" in Figure 5) and may have a distribution width close to the programming step size. These memory cells with Vtl data are inhibited from any future programming. At this time, most of the cells selected to be programmed to Vt2 or Vt3 states have threshold voltage levels at about the threshold voltage level associated with the Vtl state, i.e., increased from the threshold voltage level of the starting state of VtO. In one method, the memory cells selected for Vt2 and Vt3 states are not verified or program-inhibited at the Vtl state, which may cause problems as described below.
The memory system 100 in Figure 1 then programs and verifies memory cells with Vt2 data, while memory cells with VtO and Vtl data are program inhibited, and memory cells selected to have Nt3 data are programmed simultaneously. The memory system 100 then finishes programming memory cells selected to have Vt3 data. Slow Bits and Fast Bits
The programming method described above is acceptable if the threshold voltage levels of the memory cells increase in parallel without too many "fast bits" or "slow bits," which are memory cells with floating gates that experience a fast or slow increase in charge and threshold voltage levels. Fast bits and slow bits may be caused by a number of factors, such as variations or imperfections in transistor fabrication, altered transistor properties due to repeated programming and erasing, etc. If there is a significant number of fast bits and/or slow bits, then the preceding method may result in over-programmed or under-programmed memory cells.
For example, when the memory system 100 (Figure 1) programs and verifies Vtl data, some memory cells selected to store Vtl data will need a few extra programming pulses. These memory cells may be referred to as slow bits or under- programmed cells.
In addition, memory cells selected to store Vt2 and Vt3 data are programmed simultaneously during Vtl programming. There may be some fast bits in the Vt2 and Vt3 distributions (memory cells selected to store Vt2 data or Vt3 data) that have passed the Vtl verify level ('Nerifyl" in Figure 5) while Vtl programming is not yet completed. Also, there may be some fast bits in the Vt3 distribution (memory cells selected to store Vt3 data) during Vt2 data programming.
Figure 6 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory array 311 in Figure 3 that are programmed to a plurality of threshold voltage storage states, including fast (over-programmed) bits in the Vt2 and Vt3 state distributions 600. As shown in Figure 6, the fast bits in the Vt2 and Vt3 distributions 600 are not verified and locked out (program inhibited) during Vtl verify. Thus, the fast bits in the Vt2 and Vt3 distributions 600 will receive additional programming pulses needed to complete Vtl programming. The fast bits in the Vt2 and Vt3 distributions 600 could potentially move too fast and reach a Vt3 verify level ("Verify3" in Figure 6) after Vtl programming is completed. At this time, there is no way to recover fast bits in the Vt2 distribution.
In one embodiment, it is also desirable for multi-level memory cells to have states with tight distributions to reduce the highest voltage applied during a READ operation and minimize an amount of cell coupling or the Yupin effect described in U.S. Patent Application Serial No. 09/893,277, which has been incorporated by reference.
If the number of storage states per charge storage element increases, for example from four to eight, the programming time will usually increase since the smaller voltage ranges for the individual states require a greater precision of programming. The increased programming time may have a significant adverse impact on the performance of the memory system. A Programming and Lockout Method
The objectives and problems described above are addressed by the methods described below with reference to Figures 7-12B. Although the methods described below refer to the system 100 in Figure 1, the methods may be performed by the system 300 in Figure 3. The methods described below may be performed for any type of memory array, such as NAND or NOR-type cell arrays.
Figure 7 illustrates one embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory aπay 1 of Figure 1 or the memory aπay 311 in Figure 3. In a block 700 of Figure 7, the controller 20 in Figure 1 receives a mixed data pattern, which coπesponds to multiple states such as VtO, Vtl, Vt2 and Vt3, to be written to one or more pages of memory cells in the memory aπay 1. The system 100 (Figure 1) inhibits programming of all memory cells selected to be in a VtO state in the memory page(s). The system 100 simultaneously programs all memory cells selected to store Vtl data, all memory cells selected to store Vt2 data and all memory cells selected to store Vt3 data with programming pulses in a block 700.
In a block 702, after one or more programming pulses, the system 100 (Figure 1) performs a verify operation by applying a read voltage condition to the programmed memory cells in the page(s) and determining whether any programmed memory cell has a threshold voltage higher than "Verify 1" in Figure 9, i.e., reached the Vtl state. The "Verify 1" voltage in Figure 9 may be set at the minimum threshold voltage 902 or offset by a small margin to account for non-ideal sensing conditions, such as noise. There are several ways to verify the programming of a memory cell, such as monitoring a cuπent or voltage level, which are known to those of ordinary skill in the art.
This Vtl verify operation is performed on all memory cells in the memory block(s) selected to store Vtl, Vt2 or Vt3 data. Thus, memory cells selected to store Vt2 or Vt3 data are programmed and verified at the Vtl state with the "Verifyl" voltage simultaneously with memory cells selected to store Vtl data. If no programmed memory cells have reached the Vtl state, the system 100 returns to block 700. If one or more programmed memory cells have reached the Vtl state, the system 100 proceeds to block 704. In a block 704 (Figure 7), the system 100 (Figure 1) locks out or inhibits the programming of each memory cell that has reached the Vtl state for the rest of the Vtl programming process. The lock out or program inhibit prevents fast Vt2 and Vt3 bits from being over-programmed as in the Vt2 and Vt3 memory cell distributions 600 in Figure 6. Figure 9 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory aπay 311 in Figure 3 that are programmed to a threshold voltage Vtl storage state with no over-programmed memory cells.
In a block 706, the system 100 performs a verify operation to determine whether all memory cells selected to store Vtl data have reached the Vtl state with a Verifyl voltage (Figure 9). If at least one memory cell selected to store Vtl data has not reached the Vtl state, the system 100 returns to block 700. Otherwise, the system proceeds to either block 708 in Figure 7 or block 800 in Figure 8.
In a block 708, all memory cells selected to store Vtl data have reached the Vtl state. The system 708 performs a verify operation to determine whether all memory cells selected to store Vt2 data or Vt3 data have reached the Vtl state. If the memory cells selected to store Vt2 data or Vt3 data have not all reached the Vtl state, the system 100 repeats blocks 700-704 for the memory cells selected to store Vt2 data or Vt3 data and returns to block 708.
If the memory cells selected to store Vt2 data or Vt3 data have all reached the Vtl state, the system 100 continues programming and verifying the memory cells selected to store Vt2 data or Vt3 data in a process similar to the process in blocks 700- 706. Specifically, the system 100 programs all memory cells selected to store Vt2 data and all memory cells selected to store Vt3 data with programming pulses.
After one or more pulses, the system 100 performs a verify operation to determine whether any memory cell has reached the Vt2 state. The system 100 locks out or inhibits the programming of each memory cell that has reached the Vt2 state for the rest of the Vt2 programming process. The system 100 performs a verify operation to determine whether all memory cells selected to store Vt2 data have reached the Vt2 state with the Verify2 voltage (Figure 10). If at least one memory cell selected to store Vt2 data has not reached the Vt2 state, the system 100 continues Vt2 programming. Otherwise, the system proceeds with Vt3 programming.
Figure 10 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory aπay 311 in Figure 3 that are programmed to threshold voltage Vtl and Vt2 storage states with no over-programmed bits.
Figure 11 illustrates distributions (numbers) of memory cells in the memory array 1 in Figure 1 or the memory aπay 311 in Figure 3 that are programmed to threshold voltage Vtl, Vt2 and Vt3 storage states with no over-programmed bits.
The method described above with reference to Figures 7-11 allows memory cells selected to store Vt2 data to start the Vt2 programming/verifying process with a tight (naπow) memory cell distribution and results in a Vt2 distribution shown in Figure 10. Similarly, memory cells selected to store Vt3 data will start the Vt2 and Vt3 programming/verifying processes with a tight (naπow) memory cell distribution and result in a Vt3 distribution shown in Figure 11. Another Programming and Lockout Method
Figure 8 illustrates another embodiment of a method of programming, verifying and locking out a plurality of memory cells in the memory aπay 1 of Figure
1 or the memory aπay 311 in Figure 3. At the start of the method in Figure 8, the system 100 of Figure 1 has programmed and verified all memory cells selected to store Vtl data, according to blocks 700-706 in Figure 7 and shown in Figure 9.
In a block 800, the system 100 performs a verify operation to determine whether any memory cell selected to store Vt2 data has reached the Vt2 state with a Verify2 voltage in Figure 10. If one or more memory cells selected to store Vt2 data have reached the Vt2 state, the system 100 proceeds to block 802. In a block 802, the system 100 locks out or inhibits the programming of each memory cell that has reached the Vt2 state for the rest of the Vt2 programming process. The system 100 proceeds to a block 806.
If none of the memory cells selected to store Vt2 data have reached the Vt2 state (block 800), the system 100 programs the memory cells selected to store Vt2 data with programming pulses in a block 804. After one or more programming pulses, the system returns to block 800.
In block 806, the system 100 performs a verify operation with the Verify2 voltage to determine whether all memory cells selected to store Vt2 data have reached the Vt2 state. If one or more memory cells selected to store Vt2 data have not reached Vt2 state, the system 100 returns to block 804 and continues programming. If all memory cells selected to store Vt2 data have reached the Vt2 state, the system 100 has successfully locked out fast bits in the Vt2 and Vt3 distributions and achieved a memory cell distribution similar to the distribution shown in Figure 10.
In a block 808, the system 100 performs a verify operation with a Verify3 voltage in Figure 10 to determine whether any memory cell selected to store Vt3 data has reached the Vt3 state. In a block 810, the system 100 locks out or inhibits programming of each memory cell that has reached the Vt3 state for the rest of the Vt3 programming process. The system 100 then continues programming memory cells selected to store Vt3 data that have not been locked out and verifying the level of programming.
Thus, the method of Figure 8 completely locks all fast bits in the Vt2 and Vt3 distributions to achieve memory cell distributions similar to Figure 11. Any slow bits (memory cells with slow programming) selected to store Vt2 or Vt3 data that do not pass the Vtl verify process (blocks 700-706 in Figure 7) will be programmed and verified at the Vt2 state with Verify2 voltage, as shown in blocks 800-806 in Figure 8. Thus, slow bits selected to store Vt2 or Vt3 data do not cause a problem.
The programming sequences for state transitions in Figures 7 and 8 described above may be applied to any state transition sequence, as long as there are more than two states being simultaneously programmed from one or more lower states. The system 100 of Figure 1 may include data latches or registers in the column control circuits 2 (or the controller 20, the command circuits 7 or the data input/output circuits 6). The data latches are configured to hold data to be written to the memory array 1 and data read from the memory aπay 1. Examples of data latches or registers and their operations are described in Figure 7 of U.S. Patent Application Serial No. 09/893,277 and in U.S. Patent No. 6,046,935, which have been incorporated by reference.
In the method of Figure 7 and/or the method of Figure 8, when data latches in the system 100 are reset by Vt2 and Vt3 program data, the memory cells with Vtl or VtO data will be program inhibited. Then Vt2 and Vt3 data are programmed and verified to the Vt2 state.
By using one of the methods described above, memory cells programmed to each state in Figure 11 should have a Vt distribution width (e.g., widths 503, 595, 507, 509) less than or equal to the program step-up size. Examples of Vt distribution widths and program step-up sizes are provided in U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, which have been incorporated by reference. Upper Page and Lower Page Programming
The programming sequences in Figures 7 and 8 described above may be implemented in a memory system that programs memory cells with upper page and lower page programming techniques. Examples of upper page and lower page programming techniques are described in U.S. Patent Application Serial No. 09/893,277 and U.S. Patent No. 6,046,935, which have been incorporated by reference. Figure 12A illustrates distributions of memory cells in the memory array 100 in Figure 1 or the memory aπay 311 in Figure 3 after a first page programming process. The first page may be refeπed to as an "upper" page or a "lower" page. Some memory systems program a lower page first, as described in U.S. Patent Application Serial No. 09/893,277 (see Figures 10A-10B). Other memory systems program an upper page first, as described in U.S. Patent No. 6,046,935 (see Figures 44B-44C). During first page programming, some memory cells may be program- inhibited at a first state 1201 in Figure 12 A, while other memory cells are programmed from the first state 1201 to a second state 1202.
Figure 12B illustrates distributions of memory cells in the memory aπay 100 in Figure 1 or the memory aπay 311 in Figure 3 after a second page programming process. The second page may be refeπed to as an "upper" page or a "lower" page. During second page programming, the memory cells at the second state 1202 may be program-inhibited at the second state 1202 or programmed to the third state 1203. The memory cells at the first state 1201 may be program-inhibited at the first state 1201 or programmed to a third state 1203 and then programmed to a fourth state 1204. Thus, some memory cells in the first and second states 1201, 1202 are simultaneously programmed to the third state 1203.
The methods described above with reference to Figures 7 and 8 may be applied to the second page programming process in Figure 12B. The programming method may verify whether any memory cell intended to reach the fourth state 1204 has been programmed from the first state 1201 to the third state 1203. If any memory cell intended to reach the fourth state 1204 has reached the third state 1203, the method may lock out/program inhibit each such memory cell until all such memory cells have reached the third state 1203. Thus, some memory cells in the first and second states 1201, 1202 are simultaneously programmed and verified at the third state 1203. After all memory cells intended to reach the fourth state 1204 have been verified at the third state 1203, the method may program such cells to the fourth state 1204, as shown in Figure 12B.
The preceding method catches fast bits when memory cells at the first state 1201 are programmed to the fourth state 1204 and reduces the probability of fast bits from over-shooting the fourth state distribution in Figure 12B. In one embodiment, it is desirable to keep the distribution width of the fourth state 1204 as naπow as possible, i.e., prevent memory cells programmed to the fourth state 1204 from "overshooting," for at least two reasons. If a memory cell in an NAND aπay string, such as the string 210 in Figure 2, has a threshold voltage that is higher than an acceptable level above the fourth state 1204, then neighboring memory cells may not conduct properly. Thus, the chain cannot be read or verified properly.
The programming sequences in Figures 7 and 8 described above may be combined with one or more programming and verifying methods described in the above-mentioned U.S. Patent Application Serial No. 09/893,277 to tighten the memory cell Vt state distributions before programming and verifying memory cells with other Vt states.
The programming sequences for state transitions in Figures 7 and 8 described above may be modified. The above-described embodiments of the present invention are merely meant to be illustrative and not limiting. Various changes and modifications may be made without departing from the invention in its broader aspects. The appended claims encompass such changes and modifications within the spirit and scope of the invention.

Claims

WHAT IS CLAIMED IS:
1. A method of programming a plurality of non-volatile memory cells to have a plurality of threshold voltage levels, the method comprising: programming the memory cells with at least one voltage pulse; after at least one voltage pulse, continuing programming if no memory cell has reached or exceeded a first predetermined threshold voltage level, the first predetermined threshold voltage level representing a first set of data bits; inhibiting programming of any memory cell that has reached or exceeded the first predetermined threshold voltage level; determining whether all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level; if at least one memory cell selected to store the first set of data bits has not reached or exceeded the first predetermined threshold voltage level, continuing programming of uninhibited memory cells; if all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level, determining whether all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level; if at least one memory cell selected to store second or third sets of data bits has not reached or exceeded the first predetermined threshold voltage level, continuing programming uninhibited memory cells until all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level; and if all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level, continuing programming all memory cells selected to store second or third sets of data bits.
2. The method of Claim 1 , further comprising receiving a plurality of data bits coπesponding to a plurality of predetermined threshold voltage levels to be programmed in the memory cells.
3. The method of Claim 1, further comprising selecting a group of memory cells to program.
4. The method of Claim 3, wherein the selected group comprises over 1000 cells.
5. The method of Claim 1, wherein the non- volatile memory cells are configured in a NAND-type aπay.
6. The method of Claim 1, wherein the non- volatile memory cells are configured in a NOR-type aπay.
7. The method of Claim 1, wherein the non- volatile memory cells form an electrically-erasable, programmable read only memory (EEPROM).
8. The method of Claim 1, wherein the non- volatile memory cells form a flash memory.
9. The method of Claim 1, wherein programming comprises applying a voltage pulse with a predetermined amplitude.
10. The method of Claim 1, wherein programming comprises storing charge on a floating gate transistor in each uninhibited memory cell.
11. The method of Claim 1, wherein continuing programming if no memory cell has reached or exceeded a first predetermined threshold voltage level comprises applying a voltage pulse to the memory cells with an amplitude higher than an amplitude of a previous voltage pulse.
12. The method of Claim 1, further comprising determining whether any memory cell has reached or exceeded a first predetermined threshold voltage level.
13. The method of Claim 12, wherein determining whether memory cells have reached or exceeded a first predetermined threshold voltage level comprises applying a first verify voltage to the memory cells and determining whether the memory cells are activated.
14. The method of Claim 1, wherein inhibiting programming of any memory cell that has reached or exceeded the first predetermined threshold voltage level comprises: inhibiting programming of memory cells selected to store the first set of data bits during a remainder of the method; and inhibiting programming of memory cells selected to store second or third sets of data bits during a first programming period.
15. The method of Claim 1, wherein determining whether all memory cells selected to store second or third sets of data bits have reached or exceeded the first predetermined threshold voltage level comprises applying a first verify voltage to the memory cells and determining whether the memory cells are activated.
16. The method of Claim 1, further comprising: after at least one voltage pulse, continuing programming of uninhibited memory cells if no memory cell has reached or exceeded a second predetermined threshold voltage level, the second predetermined threshold voltage level representing the second set of data bits; inhibiting programming of any memory cell that has reached or exceeded the second predetermined threshold voltage level; determining whether all memory cells selected to store second or third sets of data bits have reached or exceeded a second predetermined threshold voltage level; if at least one memory cell selected to store the second or third sets of data bits has not reached or exceeded the second predetermined threshold voltage level, continuing programming of uninhibited memory cells; if all memory cells selected to store the second or third sets of data bits have reached or exceeded the second predetermined threshold voltage level, determining whether all memory cells selected to store the third set of data bits have reached or exceeded the second predetermined threshold voltage level; if at least one memory cell selected to store the third set of data bits has not reached or exceeded the second predetermined threshold voltage level, continuing programming uninhibited memory cells selected to store the third set of data bits until all memory cells selected to store the third set of data bits have reached or exceeded the second predetermined threshold voltage level; and if all memory cells selected to store the third set of data bits have reached or exceeded the second predetermined threshold voltage level, continuing programming all memory cells selected to store the third set of data bits.
17. The method of Claim 1, wherein the memory cells are coupled to a word line.
18. The method of Claim 1, further comprising inhibiting programming of memory cells that are selected to store a fourth set of data bits.
19. The method of Claim 1, further comprising repeating the method for another group of memory cells.
20. A method of using a plurality of non- volatile memory cells, the method comprising: storing charge in the memory cells; continuing storing charge in the memory cells if no memory cell has reached or exceeded a first predetermined charge level, the first predetermined charge level representing at least two data bits; inhibiting storing charge in any memory cell that has reached or exceeded the first predetermined charge level; determining whether all memory cells selected to store the first predetermined charge level have reached or exceeded the first predetermined charge level; if at least one memory cell selected to store the first predetermined charge level has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells; if all memory cells selected to store the first predetermined charge level have reached or exceeded the first predetermined charge level, determining whether all memory cells selected to store second or third predetermined charge levels have reached or exceeded the first predetermined charge level; and if at least one memory cell selected to store second or third predetermined charge levels has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells until all memory cells selected to store second or third predetermined charge levels have reached or exceeded the first predetermined charge level.
21. The method of Claim 20, further comprising: if all memory cells selected to store second or third predetermined charge levels have reached or exceeded the first predetermined charge level, continuing storing charge in all memory cells selected to store second or third predetermined charge levels.
22. The method of Claim 20, wherein each memory cell comprises at least one floating gate transistor configured to store charge.
23. A method of programming a plurality of non- volatile memory cells, the memory cells comprising a first set of one or more memory cells selected to store a charge level equal to or greater than a first predetermined charge level coπesponding to a first set of data bits, a second set of one or more memory cells selected to store a charge level equal to or greater than a second predetermined charge level coπesponding to a second set of data bits and a third set of one or more memory cells selected to store a charge level equal to or greater than a third predetermined charge level coπesponding to a third set of data bits, the method comprising: simultaneously storing charge in the first, second and third sets of memory cells; continuing storing charge in the memory cells if no memory cell has reached or exceeded the first predetermined charge level; inhibiting storing charge of any memory cell in the first, second and third sets that has reached or exceeded the first predetermined charge level; determining whether all memory cells in the first set have reached or exceeded the first predetermined charge level; and if at least one memory cell in the first set has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells.
24. The method of Claim 23, further comprising: if all memory cells in the first set have reached or exceeded the first predetermined charge level, determining whether all memory cells in the second and third sets have reached or exceeded the first predetermined charge level; if at least one memory cell in the second or third sets has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells in the second and third sets until all memory cells in the second and third sets have reached or exceeded the first predetermined charge level; and if all memory cells in the second and third sets have reached or exceeded the first predetermined charge level, continuing storing charge in all memory cells in the second and third sets.
25. A method of programming a plurality of non- volatile memory cells to have a plurality of threshold voltage levels, the method comprising: programming the memory cells with at least one voltage pulse; after at least one voltage pulse, continuing programming if no memory cell has reached or exceeded a first predetermined threshold voltage level, the first predetermined threshold voltage level representing a first set of data bits; inhibiting programming of any memory cell that has reached or exceeded the first predetermined threshold voltage level; determining whether all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level; if at least one memory cell selected to store the first set of data bits has not reached or exceeded the first predetermined threshold voltage level, continuing programming of uninhibited memory cells; if all memory cells selected to store the first set of data bits have reached or exceeded the first predetermined threshold voltage level, determining whether any memory cell has reached or exceeded a second predetermined threshold voltage level, the second predetermined threshold voltage level representing a second set of data bits; and inhibiting programming of any memory cell that has reached or exceeded the second predetermined threshold voltage level and continuing programming of uninhibited memory cells.
26. The method of Claim 25, further comprising: determining whether all memory cells selected to store the second or third sets of data bits have reached or exceeded the second predetermined threshold voltage level; if all memory cells selected to store the second or third sets of data bits have reached or exceeded the second predetermined threshold voltage level, determining whether all memory cells selected to store the third sets of data bits have reached or exceeded the third predetermined threshold voltage level; and inhibiting programming of any memory cell that has reached or exceeded the third predetermined threshold voltage level and continuing programming of uninhibited memory cells.
27. A method of using a plurality of non-volatile memory cells, the method comprising: storing charge in the memory cells; continuing storing charge in the memory cells if no memory cell has reached or exceeded a first predetermined charge level, the first predetermined charge level representing at least two data bits; inhibiting storing charge in any memory cell that has reached or exceeded the first predetermined charge level; determining whether all memory cells selected to store the first predetermined charge level have reached or exceeded the first predetermined charge level; if at least one memory cell selected to store the first predetermined charge level has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells; if all memory cells selected to store the first predetermined charge level have reached or exceeded the first predetermined charge level, determining whether any memory cell selected to store second or third predetermined charge levels has reached or exceeded the second predetermined charge level; inhibiting storing charge in any memory cell that has reached or exceeded the second predetermined charge level; and if no memory cell selected to store second or third predetermined charge levels has reached or exceeded the second predetermined charge level, continuing storing charge in uninhibited memory cells.
28. The method of Claim 27, further comprising: determining whether all memory cells selected to store the second predetermined charge level have reached or exceeded the second predetermined charge level; if at least memory cell selected to store the second predetermined charge level has not reached or exceeded the second predetermined charge level, continuing storing charge in uninhibited memory cells; and if all memory cells selected to store the second predetermined charge level have reached or exceeded the second predetermined charge level, determining whether any memory cell selected to store the third predetermined charge level has reached or exceeded the third predetermined charge level; if at least memory cell selected to store the third predetermined charge level has not reached or exceeded the second predetermined charge level, continuing storing charge in all memory cells selected to store the third predetermined charge level, until all memory cells selected to store the third predetermined charge level have reached or exceeded the third predetermined charge level.
29. The method of Claim 27, wherein each memory cell comprises at least one floating gate transistor configured to store charge.
30. A method of programming a plurality of non-volatile memory cells, the memory cells comprising a first set of one or more memory cells selected to store a charge level equal to or greater than a first predetermined charge level corresponding to a first set of data bits, a second set of one or more memory cells selected to store a charge level equal to or greater than a second predetermined charge level coπesponding to a second set of data bits and a third set of one or more memory cells selected to store a charge level equal to or greater than a third predetermined charge level corresponding to a third set of data bits, the method comprising: simultaneously storing charge in the first, second and third sets of memory cells; continuing storing charge in the memory cells if no memory cell has reached or exceeded the first predetermined charge level; inhibiting charging of any memory cell in the first, second and third sets that has reached or exceeded the first predetermined charge level; determining whether all memory cells in the first set have reached or exceeded the first predetermined charge level; if at least one memory cell in the first set has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells; if all memory cells in the first set have reached or exceeded the first predetermined charge level, determining whether any memory cell in the second set has reached or exceeded the second predetermined charge level; and if at least one memory cell in the second set has not reached or exceeded the second predetermined charge level, continuing storing charge in uninhibited memory cells in the second and third sets.
31. A memory device comprising : a plurality of non- volatile memory cells, the memory cells comprising: a first set of one or more memory cells selected to store a charge equal to or greater than a first predetermined charge level coπesponding to a first set of data bits; a second set of one or more memory cells selected to store a charge equal to or greater than a second predetermined charge level coπesponding to a second set of data bits, wherein the memory device is configured to simultaneously program the first and second sets of memory cells and inhibit programming of any memory cell that reaches or exceeds the first predetermined charge level until all memory cells in the first set have reached or exceeded the first predetermined charge level.
32. The memory device of Claim 31, wherein the memory device is further configured to continue programming until all memory cells in the second set have reached or exceeded the first predetermined charge level.
33. The memory device of Claim 31, wherein the memory device is further configured to verify whether memory cells have reached or exceeded the first predetermined charge level by applying a first test voltage to the memory cells.
34. The memory device of Claim 31, wherein the memory device is further configured to continue programming until all memory cells in the second set have reached or exceeded the second predetermined charge level.
35. The memory device of Claim 34, wherein the memory device is further configured to verify whether memory cells have reached or exceeded the second predetermined charge level by applying a second test voltage to the memory cells.
36. The memory device of Claim 31, wherein each memory cell comprises a floating gate transistor configured to store charge.
37. The memory device of Claim 31, wherein the memory cells are organized in a plurality of rows and columns.
38. The memory device of Claim 31, wherein the first and second sets of memory cells are within an activated row of memory cells.
39. A method of programming a plurality of non- volatile memory cells, the method comprising: storing charge in a first set and a second set of memory cells; continuing storing charge in the memory cells if no memory cell has reached or exceeded a first predetermined charge level, the first predetermined charge level representing at least two data bits; inhibiting storing charge in any memory cell that has reached or exceeded the first predetermined charge level; determining whether all memory cells in the first set of memory cells have reached or exceeded the first predetermined charge level; if at least one memory cell in the first set has not reached or exceeded the first predetermined charge level, continuing storing charge in uninhibited memory cells; and if all memory cells in the first set have reached or exceeded the first predetermined charge level, continuing storing charge in the first set of memory cells.
40. The method of Claim 39, wherein the first set of memory cells have a first initial charge level, and the second set of memory cells have a second initial charge level, wherein the second initial charge level is higher than the first initial charge level, and the predetermined charge level is higher than both the first and second initial charge levels.
41. A method of programming a plurality of non-volatile memory cells in parallel from a common threshold level into at least first and second threshold levels as designated by data being stored in the memory cells, the method comprising: applying programming conditions to all of the plurality of memory cells designated for the first and second threshold levels; terminating application of the programming conditions to individual ones of the plurality of memory cells designated for the first and second threshold levels as the cells designated for the first and second threshold levels individually reach said first threshold level; after those of the memory cells designated for the first th-feshold level have all reached the first threshold level, applying programming conditions to those of the plurality of memory cells designated for the second threshold level; and terminating application of the programming conditions to individual ones of the plurality of memory cells designated for the second threshold level as the cells designated for the second threshold level individually reach said second threshold level.
42. The method of Claim 41, wherein applying programming conditions to those of the plurality of memory cells designated for the second threshold level commences after all those of the memory cells designated for the second threshold level have reached said first threshold level.
43. The method of claim 41, wherein the common threshold level is also a programmed level designated by the data being stored in the memory cells and those of the plurality of the memory cells that are designated for the common level are locked out from receiving programming conditions.
44. A means for storing data comprising: a plurality of non-volatile memory cells, the memory cells comprising: a first set of one or more memory cells selected to store a charge equal to or greater than a first predetermined charge level coπesponding to a first set of data bits; a second set of one or more memory cells selected to store a charge equal to or greater than a second predetermined charge level corresponding to a second set of data bits, wherein the memory device is configured to simultaneously program the first and second sets of memory cells and inhibit programming of any memory cell that reaches or exceeds the first predetermined charge level until all memory cells in the first set have reached or exceeded the first predetermined charge level.
45. The means for storing data in Claim 44, further comprising a means for selecting the first and second sets of memory cells for programming.
PCT/US2002/037972 2001-12-18 2002-11-26 Method and system for programming and inhibiting multi-level, non-volatile memory cells WO2003052766A1 (en)

Priority Applications (5)

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KR1020047009586A KR100932891B1 (en) 2001-12-18 2002-11-26 Method and system for programming and suppressing multilevel, nonvolatile memory cells
AT02794038T ATE524811T1 (en) 2001-12-18 2002-11-26 METHOD AND SYSTEM FOR PROGRAMMING AND LOCKING MULTI-LEVEL NON-VOLATILE MEMORY CELLS
AU2002359496A AU2002359496A1 (en) 2001-12-18 2002-11-26 Method and system for programming and inhibiting multi-level, non-volatile memory cells
JP2003553575A JP4477352B2 (en) 2001-12-18 2002-11-26 Method and system for performing programming and inhibition of multi-level non-volatile memory cells
EP02794038A EP1456852B1 (en) 2001-12-18 2002-11-26 Method and system for programming and inhibiting multi-level, non-volatile memory cells

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US10/025,749 US6967872B2 (en) 2001-12-18 2001-12-18 Method and system for programming and inhibiting multi-level, non-volatile memory cells
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US20060007736A1 (en) 2006-01-12
US20030112663A1 (en) 2003-06-19
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ATE524811T1 (en) 2011-09-15
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