Abstract:
An integrated circuit device includes a two-dimensional array of ferroelectric memory cells in which plate lines within the array are grouped. The grouping of plate lines accommodates the use of larger plate line drivers, such as CMOS driver inverters. Each plate line group may include some but not all of the rows of memory cells and some but not all of the columns of memory cells within the array.

Description:
TECHNICAL FIELD  
         [0001]    The invention relates generally to memory devices and more particularly to driving ferroelectric capacitors within an array of ferroelectric random access memory cells.  
         BACKGROUND ART  
         [0002]    There are a number of different types of integrated memory technologies. In a particular application, the selection of the type of memory will depend upon the requirements of the application. It is typical to use dynamic random access memory (DRAM) for dense storage of data where periodic memory refreshing is not an issue, while static random access memory (SRAM) is best suited for small but fast data storage and data retrieval where the large cell size of SRAM is acceptable. Flash memory provides nonvolatile storage of data, so that the data will still be available after power has been terminated. Selecting the memory technology on the basis of the application is more difficult when the needs occur within the same integrated circuit chip, such as within a system on a chip (SOC) design. One difficulty is the different memory technologies require different fabrication steps and specialized processes to individually maximize their performances.  
           [0003]    One solution to the difficulties that arise when there is a desire to use the advantages of all three memory technologies (i.e., DRAM, SRAM, and Flash) within a single integrated circuit chip is to use the memory technology referred to as ferroelectric random access memory (FeRAM). FeRAM provides high data density, like DRAM, does not require a periodic memory refresh, unlike DRAM, and retains data when power is terminated, similar to Flash memory.  
           [0004]    With reference to FIG. 1, a portion of a FeRAM array  10  is shown as including four memory cells  12 ,  14 ,  16  and  18 . Within the FeRAM array, the memory cells are arranged in rows and columns. Merely by example, there may be 512 rows and 1024 columns of memory cells. Each FeRAM memory cell includes a pass transistor  20  and a ferroelectric capacitor  22 . As is well known in the art, data storage in a ferroelectric capacitor  22  is through charge polarization to a “0” or a “1” state. In the orientation shown in FIG. 1, the bottom electrode of the ferroelectric capacitor  22  is referred to as the plate electrode. Plate lines (PL)  24  and  26  link the plate electrodes of each capacitor within a row. Similarly, word lines (WL)  28  and  30  couple all of the pass transistor gates of the same row. Bit lines (BL)  32  and  34  connect all of the corresponding source/drains of a particular column, so that data can be written into the ferroelectric capacitors. As one example, in order to polarize the ferroelectric capacitor  22  of the first memory cell  12  to a “0” state, the pass transistor  20  of that cell is activated via the first word line  28 , while the corresponding bit line  32  is at “0” and the appropriate plate line  24  is set at “1.” On the other hand, to polarize the same ferroelectric capacitor  22  of the memory cell  12  to a “1” state, the word line  28  activates the pass transistor, the bit line  32  is forced to a “1” and the appropriate plate line  24  forces a “0” to the plate electrode of the capacitor. In a read operation, the plate electrode of the ferroelectric capacitor is pulsed “high” and the capacitor will dump the polarization charge associated with a “1” or “0” through the memory cell pass transistor onto the bit line.  
           [0005]    One issue in the design of a FeRAM array  10  is the selection of a plate-line architecture for driving the plate lines  24  and  26 . As one possibility, a global plate line driver may be connected to all of the plate lines, so that the rows share the same connection. This global plate line architecture is represented in FIG. 2, which shows a single driver  36  connected to 512 rows. The advantage of the architecture is that the single driver  36  does not require a large amount of chip real estate, so that the required area efficiency is relatively high. A disadvantage is that at any one time there is one active row and  511  unselected rows that nevertheless contribute to the total capacitive load. The resulting relatively high capacitive load slows the rise and fall times of the plate line signal. Thus, the speed of the FeRAM array must be slowed accordingly. Another disadvantage is that since all connected memory cells experience disturb pulses even when they are unselected, the plate electrode of every ferroelectric capacitor within the array will recurringly experience the disturb pulses as the plate driver  36  is cycled.  
           [0006]    An alternative plate drive architecture is shown in FIG. 3. In this segmented architecture, there is a single global plate line driver  38 , but every local plate line (LPL) is connected to the driver through a transmission gate  40 . Typically, the transmission gate is an NMOS device (n-channel metal oxide semiconductor device), with the global plate driver  38  being a CMOS device (complimentary metal oxide semiconductor device). The advantage of the architecture of FIG. 3 relative to the architecture of FIG. 2 is that the use of the transmission gates reduces the capacitive load on the global plate line driver  38 , so that the operational speed of the memory array may be increased. A disadvantage is that the NMOS transmission gates require voltage boosting at their transistor gates in order to overcome the threshold of the NMOS device. As the desire for low voltage circuitry increases, this voltage boosting requirement increases in its importance. Another concern is that unselected bit lines will be allowed to “float” electrically, unless additional circuitry is used to tie unselected lines to electrical ground.  
           [0007]    Another plate line architecture is represented in FIG. 4. In this architecture, each row of a ferroelectric memory array has a separate plate line driver  42 . The drivers may be NMOS devices that require the voltage boost described with reference to FIG. 3. Thus, the use of the architecture in low-voltage applications is difficult. Moreover, the large number of drivers reduces the area efficiency of the memory array.  
           [0008]    While the use of transmission gates or plate line drivers is not described, an alternative arrangement of connecting plate electrodes in a FeRAM memory array is set forth in U.S. Pat. No. 6,314,018 to Pöchmüller. Specifically, the patent describes an arrangement in which all of the plate electrodes of more than one word line row (or alternatively more than one bit line column) are connected to form a plate line segment.  
           [0009]    The availabilities of the different prior art architectures allow a FeRAM memory array designer to select an architecture on a basis of a variety of factors, including available chip real estate and the target supply voltage (e.g., low-voltage application). However, each architecture also has disadvantages. What is needed is a FeRAM integrated circuit design and plate drive method which enable low-voltage, area-efficient implementations and which control the capacitive load placed on plate drivers, so that the integrated circuit may be operated at a relatively fast speed.  
         SUMMARY OF THE INVENTION  
         [0010]    An integrated circuit device includes n lines by m lines of memory cells that are grouped with respect to common connections to plate electrodes of ferroelectric capacitors. Each group includes shared connections to ferroelectric capacitors of more than one of the n lines and more than one of the m lines. In one embodiment, the n lines are rows of memory cells and the m lines are columns of the memory cells. The multi-row, multi-column grouping of plate line connections enables greater flexibility with regard to the selection of a plate line drive scheme that satisfies both voltage-related requirements and area-related limitations.  
           [0011]    While each group of plate line connections links ferroelectric capacitors of more than one column and more than one row, each group typically includes less than all of the columns and less than all of the rows. The selection of the number of columns and the number of rows within a group is based upon factors that include the total numbers of rows and columns and the intended type of plate line drivers. CMOS plate line drivers require a greater amount of chip real estate than is required by a pass transistor (e.g., an NMOS transistor). In the FeRAM design in accordance with the invention, there is a trade off between selecting large groups in order to minimize the number of required CMOS plate line drivers and selecting small groups that do not include a number of inactive rows for every active row within a group, since all rows of a plate line group will contribute to the capacitive load imposed upon the associated driver. As an example, an array having 512 rows may have plate line groups consisting of  32  rows each, so that there will be at least 16 (=512/32) plate line groups. If each group includes less than the total number of columns, the total number of plate line groups will be a multiple of 16. For example, if there are 1024 columns and each group includes 64 columns, the FeRAM array will be 16 groups wide by 16 groups high.  
           [0012]    As a first aspect of the invention, the grouping of plate lines enables the use of CMOS plate line drivers. While such drivers require a significant amount of area compared to NMOS transmission transistors, the plate line grouping allows the total number of CMOS drivers to be controlled. Moreover, the capacitive load per plate line is largely reduced, because a single plate line driver only needs to drive the cells of one active row and a relatively small number of cells on inactive rows (e.g., 31 rows). Since the load of an inactive row is approximately one percent of the load of the active row, the capacitive load upon a particular CMOS driver is manageable. In addition to the CMOS driver, each plate line group may be operatively associated with a separate decoder, while the overall circuitry is maintained within the area-related limitations of the integrated circuit chip. The use of CMOS drivers rather than NMOS eliminates the need for a boosted gate voltage in order to drive the plate voltage to the full supply level. Consequently, low-voltage applications of the architecture result in lower power and less gate oxide stress.  
           [0013]    Thus, in accordance with the first aspect of the invention, CMOS drivers are used in a one-to-one correspondence with groups of plate lines. A plate line group may be associated with 32 word line rows. There may also be a one-to-one correspondence between the plate line drivers and decoders, such as NAND gate decoders. Each plate line group may extend through all of the columns, or may be limited to only a segment of the bit line columns. On the other hand, in accordance with a second aspect of the invention, the selection of a plate line driver is not limited to CMOS circuitry, but plate electrodes of the ferroelectric capacitors are interconnected on the basis of a partial group of rows and a partial segment of columns. The division of plate electrode connectivity based upon both row grouping and column segmenting may provide significant advantages in some applications, even when CMOS plate line drivers are not used. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0014]    [0014]FIG. 1 is a schematic diagram of a FeRAM array of the type used in the present invention.  
         [0015]    [0015]FIG. 2 is a schematic diagram of plate line connections using a known global plate line driver architecture.  
         [0016]    [0016]FIG. 3 is a schematic diagram of plate line drivers using a known segmented plate line driver architecture.  
         [0017]    [0017]FIG. 4 is a schematic diagram of plate line drivers using a known local plate line driver architecture.  
         [0018]    [0018]FIG. 5 is a schematic diagram of a circuit layout of plate line drivers for one segment of plate line groups for operating a FeRAM memory array in accordance with the invention.  
         [0019]    [0019]FIG. 6 is a schematic diagram of a decoder and a CMOS circuit for use in the segment of FIG. 5.  
         [0020]    [0020]FIG. 7 is a schematic diagram of a layout of plate line groups for use in a FeRAM array in accordance with the invention. 
     
    
     DETAILED DESCRIPTION  
       [0021]    With reference to FIG. 5, a single segment  78  of the plate line driver architecture is illustrated. In one possible implementation, the segment has 512 rows and 64 columns. A column may consist of either one bit line (open bit line) or two bit lines (folded bit line). Other arrangements may be used without diverging from the scope of the invention.  
         [0022]    Referring briefly to FIG. 7, three segments  128 ,  130  and  132  are illustrated as being divided into different plate line groups. Each circle that is bisected by one of the bit lines (BLm) and by one of the local plate lines (PLn) represents a single FeRAM cell. As was described with reference to FIG. 1, each FeRam cell  12 ,  14 ,  16  and  18  includes a switching device, such as a pass transistor  20 , and a ferroelectric capacitor  22 . A logical high at the output of a word line driver will turn “on” the pass transistors of the row of memory cells in the associated row in order to read or write data from or to the cells. Word line decoders and word line drivers are connected to activate pass transistors through all of the corresponding rows within a particular segment. Bit access via the bit lines may be controlled by means of the sense amplifiers  98  of FIG. 5. A conventional interdigitated column approach, as formed in many DRAMs, may be used.  
         [0023]    In FIG. 5, plate group line drivers  106  and  108  are used to drive plate electrodes of FeRAM cells. In the encoding scheme for the illustrated embodiment, the letter “j” distinguishes a particular section of cells, while the letter “k” distinguishes a particular segment from the other segments of cells.  
         [0024]    The number at the end of each plate group timed enable (PLGRPTEN) signal designates which one of the 16 plate groups is being addressed. However, the use of a NAND gate decoder  110  for each plate group ensures that there is access to the plate electrodes of the ferroelectric capacitors within the 32 rows of the associated group only when the segment  78  is active. When segment  78  is selected, a first driver  112  provides the necessary signal at one input of each NAND gate  110 . The particular plate group to be driven, PL 0 -PL 15 , is triggered by its respective PLGRPTEN signal on the second input.  
         [0025]    Dimensionally, the pitch of the word lines may be 0.6 μm. Consequently, the 32 word lines operatively associated with each plate group driver have a total height of 32×0.6 =19.2 μm. To drive 64 columns requires a simple p-channel driver width within the range of 40 μm to 60 μm, depending on the desired speed for operating the memory array. The width needed to layout the plate group driver, including the NAND gate decoding, can be less than 10 μm. Consequently, the overhead for the plate group drivers used with a column pitch of 1.8 μm is less than eight percent (i.e., 10 μm/(1.8 μm×64)).  
         [0026]    Referring to FIGS. 5 and 6, each plate line group is associated with a NAND gate  110  and a driver  106 , which is preferably a CMOS circuit having cooperative n-channel and p-channel transistors  114  and  116  that enable low-voltage applications, since the CMOS circuit does not require voltage boosting. Moreover, since only one word line of the 32 rows is active at any one time, the plate group driver associated with the word line drives only 64 active cells. The memory cells within the remaining 31 rows are inactive and present only a smaller additional capacitive load to the driver. The additional load is a result of the ferroelectric capacitors in series with the much smaller storage node parasitic capacitances. By associating 32 rows with a single driver, sufficient height is available to layout a practical inverter driver and the small decoder. By connecting the CMOS driver directly to the plate line group, a very fast transition time can be achieved, allowing faster access time and shorter cycle times for the operation of the memory array.  
         [0027]    [0027]FIG. 7 shows the plate line drive architecture from a multi-segment perspective. Each segment  128 ,  130  and  132  has 64 columns, but the embodiment of FIG. 7 has a plate line grouping of four rows (rather than the 32-row grouping of FIG. 5). A segment enable driver  129 ,  131  and  133  in each of the three illustrated segments  120 ,  130  and  132  provides one of the inputs for each NAND gate decoder  122 ,  124  and  126 . The second input for each decoder is the plate group select signal. The output of each decoder connects to the operatively associated plate line driver  134 ,  136  and  138 .  
         [0028]    The segment enable drivers  129 ,  131  and  133  are individually connected to decoders (not shown) which are used to isolate the triggering of the drivers. Thus, a single segment  128 ,  130  and  132  of plate lines will be active at any one time. Moreover, the operations of the NAND gate decoders  122 ,  124  and  126  ensure that a single plate group will be driven within the active segment.  
         [0029]    While only nine plate line groups are shown, a significantly larger number of plate line groups may be accommodated. Each group is operatively associated with a decoder  122 ,  124  and  126  and a plate line driver  134 ,  136  and  138 . One advantage of the architecture is that the capacitive load per plate line is significantly reduced, as compared to architectures in which the global plate line driver  120  is connected directly to all of the plate lines. As described previously, the load of an active row is approximately 100 times larger than the load of an inactive row. Consequently, the three rows (in the embodiment shown in FIG. 7) that are not accessed via a word line do not add significantly to the capacitive load to the plate line driver. Moreover, the sharing of the plate lines allows the architecture to be very area efficient. The plate line drivers may be CMOS circuits, as described with reference to FIG. 6, but other types of drivers may be substituted. However, an advantage of using CMOS drivers is that a boosted gate voltage is not required.