Abstract:
A non-volatile semiconductor memory device including a memory cell array having a plurality of memory cells coupled to a plurality of bitlines and wordlines, each memory cell being programmed to one of plurality of data storage states. A node is connected to a selected bitline responsive to a storage state in a selected memory cell. A plurality of latched registers is connected to the node to store and output data bits corresponding the storage state, the data bits being assigned to the selected bitline. A circuit is adapted to precharge the selected bitline before sensing the selected memory cell and is adapted to equalize the selected bitline and the node after sensing the selected memory cell.

Description:
[0001]    This application claims priority from Korean Patent Application No. 2000-36097, filed on Jun. 28, 2000, the contents of which are herein incorporated by reference in their entirety.  
         FIELD OF THE INVENTION  
         [0002]    The present invention relates to integrated circuit memory devices and, more particularly, to non-volatile integrated circuit memory devices storing and being accessible with multi-state data.  
         BACKGROUND OF THE INVENTION  
         [0003]    Flash memories have recently been developed for personal computers. In this context, flash memories are advantageous because they are capable of storing and quickly erasing large amounts of information.  
           [0004]    Before reading information stored in the cells of a memory device, it is necessary to check the information storing state of a selected cell. Signals required to check the storing state of the selected memory cell are applied to circuits associated with the selected memory cell by use of a decoder circuit. A current or voltage signal indicative of the storing state of the selected memory cell is placed on a bit line. By doing so, the storing state indicative of the programmed information of a memory cell can be found by measuring the obtained current or voltage signal.  
           [0005]    When reading information stored in a NAND-type memory device, a selected transistor in a selected string is switched to the ON state. In addition, a voltage higher than that applied to the control gate of the selected memory cell is applied to the control gates of unselected memory cells. As a result, the unselected memory cells have a low equivalent resistance as compared to the selected memory cell. The magnitude of the current flowing through the string from the associated bit line thus depends on the information stored in the selected memory cell of the string. The voltage or current corresponding to the information stored in each selected memory cell is sensed by a sensing circuit e.g., a sense amplifier.  
           [0006]    Many schemes have been proposed to increase the information storage capacity of memory devices without a consequent increase in chip size. Conventionally, a memory cell stores a single bit of information. It is technically possible, however, to store at least two bits of information in a single memory cell. When 2 bits of information are stored in a single memory cell, the memory cell is programmed with either “00”, “01”, “10” or “11”. Accordingly, a memory device can store twice the information with the same number of memory cells as compared to a memory device wherein only a single bit is stored in a single memory cell. When storing 2 bits per memory cell, a multi-state memory device is provided wherein the threshold voltage of each memory cell can be programmed to have one of four different values. Because the memory capacity per memory cell is doubled, the chip size can be reduced while providing the same memory capacity. As the number of bits stored per memory cell increases, the data storage capacity of the multi-state memory device increases.  
           [0007]    The topology of integrated flash memory devices is becoming denser. As this happens, the amount of current passing through a bit line when a selected memory cell is an on-cell is reduced resulting in a longer developing time for the bit line. Accordingly, a need remains for a multi-bit flash memory device that addresses this and other disadvantages associated with the prior art. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0008]    The present invention will be described by way of exemplary embodiments, but not limitations, illustrated in the accompanying drawings in which like references denote similar elements.  
         [0009]    [0009]FIG. 1 is a block diagram of a preferred embodiment of the present invention.  
         [0010]    [0010]FIG. 2 is a graph of the distribution profiles of threshold voltages.  
         [0011]    [0011]FIG. 3 is a timing diagram of the circuit shown in FIG. 1. 
     
    
       [0012]    In the drawings, as in the following description, use of the suffix “B” for a signal name indicates that the signal is active in at logic low level (negative logic).  
       DESCRIPTION OF THE PREFERRED EMBODIMENT  
       [0013]    It should be understood that the description of this preferred embodiment is merely illustrative and that it should not be taken in a limiting sense. In the following detailed description, several specific details are set forth in order to provide a thorough understanding of the present invention. It will be obvious, however, to a person skilled in the art that the present invention may be practiced without these specific details.  
         [0014]    [0014]FIG. 1 shows a configuration of circuits for performing a read-out operation from memory cells storing multi-bit data bits. Referring now to FIG. 1, memory cell array  10  is constructed of a plurality of cell strings which are connected to their corresponding bitlines BL 1 ˜BL 4 . Each of the cell strings is formed of string selection transistor ST 1 , memory cells M 1 ˜M 16 , and ground selection transistor GT 1 . The string selection transistor ST 1  is connected to the bitline BL 1 , and the ground selection transistor GT 1  is connected to common source line CSL. The memory cells M 1 ˜M 16  are serially connected between the string and ground selection transistors. The number of the memory cells disposed in one cell string varies according to desired storage capacity and arrangement within the flash memory. A gate of a string selection transistor (like ST 1  in every cell string) is coupled to a string selection line SSL that transfers a string selection signal supplied from row decoder  15 . A gate of the ground selection transistor is coupled to ground selection line GSL that transfers a ground selection signal supplied from the row decoder  15 . Control gates of the memory cells M 1 ˜M 16  are coupled to corresponding wordlines WL 1 ˜WL 16 .  
         [0015]    NMOS enhancement transistors MH 1  and MH 2  are serially connected between bitlines BL 1  and BL 2 . NMOS enhancement transistors MH 6  and MH 7  are serially connected between bitlines BL 3  and BL 4 . Common source nodes CS 1  and CS 2  of transistors MH 1  and MH 2 , and MH 6  and MH 7 , respectively, are connected to voltage line VPWR. Voltage line VPWR is grounded. Gates of transistors MH 1  and MH 2  are coupled to signals VCON 1  and VCON 2 , respectively. Gates of transistor MH 6  and MH 7  are coupled to control signals VCON 3  and VCON 4 , respectively. NMOS enhancement transistor MH 3  connects BL 1  to node N 1  responsive to signal BLSHF 1 . NMOS enhancement transistor MH 4  connects BL 2  to N 1  responsive to signal BLSHF 2 . NMOS enhancement transistor MH 8  connects BL 3  to node N 1  responsive to signal BLSHF 3 . NMOS enhancement transistor MH 9  connects BL 4  to N 1  responsive to signal BLSHF 4 . NMOS enhancement transistors MH 5  and MH 10  connect node N 1  to latched register circuit  20  and  30  responsive to bitline selection signals BLSLT 1  and BLSLT 2 , respectively. The NMOS enhancement transistors MH 1 ˜MH 10  are adaptable to drive high voltages that are used in erasing memory cells. PMOS transistor MP 1  is connected between power supply voltage VDD and the node N 1 . PMOS transistor MP 1  is responsive to precharge signal PRCHGB.  
         [0016]    Register circuit  20  is connected to node N 1  through transistor MH 5 . PMOS transistor MP 2  is connected between VDD and output terminal Q 1 . The transistor MP 2  resets the register circuit  20  responsive to signal RST. NMOS transistor MN 1  is connected between output terminal Q 1  and ground voltage. Inverter INV 1  is connected in forward direction between the output terminal Q 1  and a gate of transistor MN 1 . NMOS transistors MN 2  and MN 3  are serially connected. Node N 2  is positioned at the gate of transistor MN 1 . The gate of transistor MN 2  is coupled to node N 1  and the gate of transistor MN 3  is coupled to latch enable signal ΦDLCH 1 .  
         [0017]    The register circuit  30  is connected to node N 1  through transistor MH 10 . PMOS transistor MP 3  is connected between VDD and output terminal Q 2 . The transistor MP 3  resets the register circuit  30  responsive to the signal RST. NMOS transistor MN 4  is connected between output terminal Q 2  and the ground voltage. Inverter INV 2  is connected in a forward direction between output terminal Q 2  and a gate of transistor MN 4  (node N 3 ). The gate of NMOS transistor MN 5  is connected to node M. NMOS transistor MN 5  is connected between nodes N 3  and N 4 . From N 3  to the ground, there are two parallel paths. The first path is formed of NMOS transistors MN 6  and MN 7  and the second path is formed of NMOS transistors MN 8  and MN 9 . The gate of transistor MN 6  is coupled to output terminal Q 1  and the gate of transistor MN 7  is coupled to latch enable signal ΦLCH 3 . The gate of transistor MN 8  is coupled to node N 2  and the gate of transistor MN 9  is coupled to latch enable signal ΦLCH 2 .  
         [0018]    A multi-bit storage state of a memory cell operates as follows. Referring to FIG. 2, a memory cell of the present invention stores one of four storage states, “00”, “01”, “10”, and “11”. Each of the four storage states corresponds to a threshold voltage of the memory cell. For example, as shown in FIG. 2, storage states “00”, “01”, “10”, and “11” are assigned threshold voltages within a distribution range as follows: 2.3˜2.7V (first voltage VF 3  is 2.3V), 1.3˜1.7V (VF 2  is 1.3V), 0.3˜0.7V (VF 1  is 0.3V), and under −2.7V, respectively. Detecting a memory cell storage state is determined by applying reference voltages positioned intermediately along the distribution range of the threshold voltages. For instance, if a reference voltage VR 1  is applied to a wordline corresponding to a selected memory cell that has been set into the threshold voltage assigned to “00”, the memory cell will be defined as an off-cell because the voltage VR 1  of 2V cannot turn it on. On the other hand, if the selected memory cell is programmed to “01”, “10”, or “11”, the memory cell will be defined as an on-cell because the reference voltage VR 1  is higher than the range of associated threshold voltages.  
         [0019]    Referring to FIG. 3, a read-out operation for the multi-bit storage memory cell is as follows. The operating sequence shown in FIG. 3 comprises three steps. Step  1  includes applying e.g., the first reference voltage VR 1  (2V) to detect that a selected memory cell is programmed to storage state “00”. Step  2  includes applying e.g., the second reference voltage VR 2  (1V) to detect that the selected memory cell is programmed to storage state “01”, if the selected memory cell was detected as an on-cell in the step  1 . Step  3  includes applying e.g., the third reference voltage VR 3  (0V) to detect whether the selected memory cell is programmed to storage states “10” or “11”, if the selected memory cell was detected as an on-cell in the step  2 . At step  3 , if the selected memory cell is detected as an off-cell, it is assigned to storage state “10”. If the selected memory cell is detected as an on-cell, it is assigned to storage state “11”. In the example explained above, the selected memory cell is M 1  assigned to wordline WL 1  and bitline BL 1  and the source voltage VDD is 3.3V. Also it is assumed that the selected memory cell M 1  is programmed to storage state “00”.  
         [0020]    During the reset period Ti, the circuitry except the memory cell array is reset by logic high signals VCON 1 ˜VCON 4 , BLSHF 1 ˜BLSHF 4 , PRCHGB, BLST 1 ˜BLST 2 , and RST setting node N 1  and output terminals Q 1  and Q 2  to logic low levels. The string selection line SSL and unselected word lines WL 2 ˜WL 16  are held to a read voltage Vr of about 6V throughout the entire Ti reset period. The ground selection line GSL is enable to the read voltage Vr (6V) for substantial sensing periods T 2 , T 4 , and T 6 . After the reset period Ti, the precharge signal PRCHGB is enable at a logic low level to provide the supply voltage VDD to node N 1  until an equalization between bitline BL 1  and node N 1  begins signals BLSHF 2 ˜BLSHF 4  not involved in the selected bitline BL 1  are disable with logic low levels.  
         [0021]    During period T 1 , signal BLSHF 1  goes to a first precharge level Vp 1  of about 0.7V after falling to 0V, so that bitline BL 1  is charged up to level Vp 1 -Vth. Vth is the threshold voltage of transistor MH 3 . Signal VCON 1  falls to a logic low level to disconnect bitline BL 1  from signal VPWR.  
         [0022]    During period T 2 , bitline BL 1  retains the precharge level Vp 1 -Vth and node N 1  is at the voltage supply VDD level because no current flows through cell M 1  which has a higher threshold voltage than the read voltage VR 1 . Sub-period Tcs of period T 2  allows for bitline sensing when BLSHF 1  is at a logic low level. It should be noted that, since BL 1  starts to be developed from the precharge level Vp 1 -Vth during Tcs, the time required to detect whether cell M 1  is an on-cell or an off-cell is shortened. On the other hand, if the selected memory cell M 1  is an on-cell that is turned on against reference voltage VR 1 , bitline BL 1  falls down to low level from the Vp 1 -Vth, as shown by the wave forms of DATA “01 ”, DATA “10”, or DATA “11”.  
         [0023]    The precharge signal PRCHGB is disabled to a logic high level at the end of period Tcs. During sub-period Teq of T 2 , signal BLSHF 1  rises from 0V to the second precharge level Vp 2  of about 1.3V in order to equalize node N 1  and bitline BL 1  at the supply voltage VDD level. The static capacitance of bitline BL 1  is large compared to that of node N 1  such that the voltage levels of bitline BL 1  and node N 1  can be equalized when signal BLSHF 1  is on the Vp 1 . In addition, a voltage difference between voltages Vp 1  and Vp 2 , of about 0.3˜0.4V, is established when the path between bitline BL 1  and node N 1  is opened, considering the small drain-to-source voltage of transistor MH 3 . Since there is no current through the cell string including cell M 1  of an off-cell, node N 1  retains supply voltage VDD (or high level) and output terminal Q 2  changes to data bit “1” (or high level) responsive to a logic high signal ΦDLCH 2 . A signal BLSHF 1  goes to a logic high level from the second precharge level Vp 2  and signal VCON 1  is enable to a logic high level, bitline BL 1  and node N 1  falls to ground (or 0V).  
         [0024]    While the aforementioned description is relevant to reading a memory cell with DATA “00”, if the selected memory cell M 1  is programmed with DATA “01”, the read-out operation (corresponding to the cycle including T 1  and T 2 ) would proceed until the end of period T 4  where cell M 1  is detected as an off-cell. A selected memory cell M 1  involved in DATA “10” or “11” would be put into read-out cycles extending to the end of period T 6 .  
         [0025]    As described above, the invention provides a faster read-out operation by means of precharging a selected bitline and a voltage node for sensing a storage state of a selected memory cell, overcoming the disadvantage, i.e., a longer bitline developing time due to a higher circuit density.