1. Field of the Invention
The present invention relates to a semiconductor memory device including a plurality of memory arrays. More particularly, the present invention relates to a hierarchical bit line architecture in which a plurality of sub-bit lines are connected to one main bit line.
2. Description of the Background Art
Various types of semiconductor memory devices, such as DRAMs (dynamic random access memories), SRAMs (static random access memories) and ROMs (read-only memories), are used in various applications, but they share some common internal configurations. Main components of a semiconductor memory device include a memory array portion being a storage portion including a plurality of memory cells arranged in a regular pattern, and a peripheral portion provided around the memory array portion and including control circuits such as a row decoder and an amplifier.
One factor that dictates the overall performance of a semiconductor memory device is its memory capacity (the number of memory cells), and it is an object of research and development to make as many memory cells as possible per unit area. Generally, there are two possible approaches to this object. One is to reduce the size of a memory cell itself, and the other is to reduce the size of a non-memory cell portion such as a peripheral circuit.
The memory cell size has been reduced to the limit by using state-of-the-art processes and custom-designed mask patterns. The size of the non-memory cell portion has also been reduced by reducing the circuits, for example. With state-of-the-art processes, the area of the memory cell portion has been reduced to the limit, resulting in a side effect being an influence from neighboring patterns such as the loading effect. Therefore, it is necessary to give some considerations not only for memory cells themselves but also for neighboring patterns.
In a memory array including a plurality of memory cells arranged in a matrix pattern, a central memory cell located in a central portion of the memory array is surrounded by memory cells of the same shape. Therefore, there is a uniform influence of, for example, pattern reflections from surrounding cells during lithography, thus enabling a stable formation of patterns. However, a peripheral memory cell located in a peripheral portion of a memory array is surrounded by memory cell patterns and other circuits. Since the layout pattern of a memory cell is different from those of other circuits, peripheral memory cells are subject to non-uniform influence from the surroundings. Therefore, the resulting pattern of a peripheral memory cell will be different from that of a central memory cell, thus resulting in variations between these memory cells in terms of memory cell transistor characteristics such as the transistor size and the threshold value. The performance of a semiconductor memory device is very much dependent on the memory cell characteristics, and variations among memory cells directly affect the performance of the semiconductor memory device. Depending on the amount of variations, the performance of the semiconductor memory device is deteriorated significantly. In view of this, dummy patterns having the same shape as memory cells are provided in the memory array peripheral portion for stabilizing the pattern formation.
U.S. Pat. No. 5,267,208 discloses an example of a memory (SRAM), which is divided into sections by wiring regions, thereby resulting in non-uniform patterns, wherein a dummy pattern is provided in the non-uniform portion (under the wiring region).
In recent years, there are strong demands for higher speeds, and in order to meet such demands, a semiconductor memory device now often employs a hierarchical architecture in which a memory array is divided into sections so as to reduce the load on the circuit. Particularly, division in the bit line direction is effective in realizing a higher speed and a stable operation. However, this trend has resulted in an increase in the number of sections into which a memory array is divided, and thus an increase in the total number of peripheral memory cells and the total amount of dummy pattern to be formed.
U.S. Pat. No. 5,267,208 only addresses a pattern non-uniformity caused by wiring. Moreover, the inserted pattern is a dummy pattern that is not used as a functional circuit portion. Furthermore, this patent fails to disclose the use of a hierarchical architecture. Although the use of dummy patterns is effective in improving the pattern uniformity, the provision of any pattern that is not used as a functional circuit portion leads to an increase in the total area.
In order to solve the problems set forth above, the present invention provides a semiconductor memory device having a hierarchical bit line architecture, in which a memory array is divided into sections, wherein a connecting section that connects a sub-bit line connected to memory cells with a main bit line is formed by a pattern having the same shape as that of a memory cell.
Thus, it is possible to maintain a layout pattern uniformity between a memory cell and a connecting section and to reduce the total amount of dummy pattern that is not used as a functional circuit portion, thus significantly reducing the total area.
Since the present invention realizes a layout pattern uniformity across a semiconductor memory device, it is possible not only to reduce characteristics variations of peripheral memory cells but also to eliminate the need for dummy pattern cells. Thus, it is possible to realize both a reduction in the total area and an improvement in the production yield.
Embodiment 1 will now be described with reference to
Particularly, the present embodiment is directed to a mask ROM among other types of semiconductor memory devices.
Add and Con are an address signal and a control signal input to the ROM. MC1 to MCn are mask ROM memory cells, each including one NMOS transistor.
BT11 and BT21 are block selection transistors, each connecting a sub-bit line to a main bit line, and SB11, SB12, SB13, SB21, . . . are memory blocks into which the memory array 3 is divided, each including memory cells and a block selection transistor.
LB11 and LB21 are sub-bit lines to which the memory cells are connected. GB1 and GB2 are main bit lines, each being connected to a plurality of memory blocks via block selection transistors.
SA1 and SA2 are sense amplifiers for amplifying the potentials of the main bit lines GB1 and GB2 and outputting the amplified potentials to the output terminals DO1 and DO2, respectively.
WL* is a word line extending from the row decoder 1 and connected to the gates of memory cells for driving intended memory cells based on the input address Add.
BS* is a block selection signal line extending from the control section 2 and connected to the gates of block selection transistors for accessing an intended block also based on the input address Add.
A memory cell MC* has its source connected to the ground line (VSS) and its drain to a sub-bit line, and shares a common source line (ground line) with another memory cell adjacent thereto in the bit line direction. V1 to Vn each denote an intersection between a memory cell and a sub-bit line. The connection between each memory cell and a corresponding bit line is dictated by the presence/absence of a connection (i.e., the presence/absence of a contact layer) at this intersection, thus representing the ROM data (the program information).
While the following description is directed to the DO1 section, the same applies to the DO2 section, and so forth. Although a precharge circuit is needed for setting each of the main and sub-bit lines to an intended potential, the precharge circuit is not shown in the figure.
With the configuration of
Moreover, a word line corresponding to the block selection signal line is selected and brought to the H potential, thereby selecting a memory cell. Each sub-bit line is precharged in advance to the H potential (VDD). Therefore, if there is a connection at the intersection V* between the memory cell and the sub-bit line, the charge of the sub-bit line is drawn by the memory cell to VSS, and the potential of the sub-bit line lowers to L (it remains H if there is no connection). This information is output from the main bit line to the sense amplifier SA* and to the output terminal DO*, via the selected block selection transistor.
As opposed to the illustrated example, the bit line division is often not employed in the prior art, in which case a memory cell directly drives a bit line (corresponding to a main bit line in
In contrast, the bit line division structure (hierarchical bit line architecture) as shown in
The memory cell columns X1, X2, . . . , correspond to SB11, SB21, . . . , of
The four activation regions OD in the Y1 row form block selection transistors, and the eight activation regions OD in the Y2 and Y3 rows form memory cells. The gates GA1 and GA2 running over the activation regions OD in the Y2 and Y3 are word lines of the memory cells, each extending in the X direction and being shared by a plurality of cells therealong. The VSS lines running over the activation regions OD in the Y2 and Y3 rows are formed as first-layer wires, and each VSS line is connected to memory cells via the contact CA2 as the source of each memory cell. Each of the VSS lines extends in the X direction and is shared by a plurality of cells.
The sub-bit lines LB11, LB21, LB31 and LB41 (LB31 and LB41 are not shown in
A sub-bit line and a main bit line are connected to each other by using, in parallel, two transistors in each activation region OD in the Y1 column.
As shown in
As is clear from
Since memory cells and connecting sections are both NMOS, it is also not necessary to provide a well isolation, which is required when PMOS is used, thereby providing an even greater effect in reducing the total area.
In the present embodiment, the memory cells and the connecting sections share the same shape not only with respect to the activation region OD but also to the gates GA and the contacts CA*, thereby providing an even greater effect in reducing transistor variations.
Variation 1 of Embodiment 1 will now be described with reference to
A discharge transistor DT* is connected to VSS via the contact CA2, as shown in
The discharge circuit added in the illustrated configuration can also be formed by the same shape as a memory cell transistor, as in Embodiment 1, whereby it is possible to eliminate the need for the dummy region.
Thus, not only the block selection transistor but also the discharge transistor can be formed by regions of the same shape as a memory cell transistor. This can similarly be applied to other types of circuits.
Also in the present variation, the memory cells and the connecting sections share the same shape not only with respect to the activation region OD but also to the gates GA and the contacts CA*, thereby providing an even greater effect in reducing transistor variations.
Variation 2 of Embodiment 1 will now be described with reference to
In
The sub-bit line LB11 is connected in parallel to the regions D1 and D2 of four activation regions OD (eight transistors) of the block selection transistors BT11 in the Y2 row via first-layer wires LB1′, and the main bit line GB1 is connected in parallel to the regions S of the block selection transistors BT11 in the Y2 row via a first-layer wire GB1′.
Due to the parallel use of four activation regions OD, the arrangement of block selection transistors differs between adjacent sub-bit lines. Specifically, the block selection transistor BT21 of the sub-bit line LB21 corresponds to the X2-Y1 cell in
With the present configuration, the size of the block selection transistor can be changed in the same manner for any sub-bit lines, whereby it is possible to reduce the total area without lowering the memory characteristics. With the present configuration, it is possible to realize uniform OD, GA and CA patterns.
While each set includes four activation regions OD in
Variation 3 of Embodiment 1 will now be described with reference to
In
In
The present configuration can be realized, based on the configuration shown in the layout diagram of
Embodiment 2 will now be described with reference to
The local sense amplifier LSA* has an amplifier function of amplifying the potential of the sub-bit line and outputting the amplified potential to the main bit line, and a precharge function of setting the sub-bit line to an intended potential.
The local sense amplifier LSA* is provided between the block selection transistor BT11 and the main bit line GB1, and receives a control signal PS11 (or an inverted signal /PS11 thereof) from the control section 2 or another control circuit.
The internal configuration of the local sense amplifier LSA* will be described with reference to
In
As the control signal PS11 goes to L, the signal line LB11′ is set (precharged) to VDD (H potential). After releasing the precharge, the memory starts a read operation, whereby the signal line LB11′ transitions (stays H when the data is H, and goes to L when the data is L). Receiving the potential of the signal line LB11′, the amplifier AMP amplifies the potential and outputs the amplified potential to the main bit line GB1.
With the configurations described above and shown in
Variation 1 of Embodiment 2 will now be described with reference to
In
The amplifier input signal line LB112 is connected to the regions D1 and D2 of the precharge transistor PT11N (where the four activation regions OD are connected in parallel, the region S is connected to VDD, and the gates are both /PS11), and to the four gates of a transistor section N1. The regions D1 and D2 of the transistor section N1 are connected to the main bit line GB1. The regions D1 and D2 of a transistor section N2 are connected to the main bit line GB1, the region S thereof is connected to VDD. The transistor section N1 uses twice as many cells as other transistor sections so as to improve the access speed of the main bit line GB1, but the number of cells is not limited to this.
The circuit CT11 includes a PMOS transistor whose source is connected to VDD, whose drain is connected to the signal line LB112, and whose gate is connected to the main bit line GB1.
When the main bit line GB1 is L, i.e., when the signal line LB112 is H, the circuit CT11 is ON, thereby connecting the signal line LB112 with VDD.
Embodiment 3 will now be described with reference to
The OD sections in the X1 to X4 columns are memory cells, and the SE section in
In the SE section, backing is provided on the word line being the gate GA, the substrate potential of the NMOS memory cell is supplied, and the power supply wiring (VSS) is provided (where M1 is the first-layer wire, M2 is the second-layer wire, M3 is the third-layer wire, and M4 is the fourth-layer wire).
In the memory configurations described above, the memory cell gates are word lines WL and are connected (shared) in the same word line direction, but a gate is often a high-resistance line of polysilicon, or the like. Therefore, as the wiring length increases, there is a characteristics deterioration due to delay. In view of this, a backing connection is made in an upper-layer wire WL′ having a lower resistance. In the configuration of
By providing an OD pattern similar to a memory cell pattern under the backing section, it is possible to maintain a pattern uniformity between adjacent memory cells.
However, since the wiring width of a gate GA is small, it is in some cases difficult to provide a backing contact thereon. Therefore, the gate GA is widened in the activation region OD in the SE section so as not to extend beyond the activation region OD to ensure a sufficient contact area for allowing the provision of the backing contact (see
Since the distance between adjacent activation regions OD is equal (lod) in the SE section and in the memory cell section, the influence from adjacent cells can be made uniform.
Moreover, in the SE section, the ground line (VSS), which in the prior art extends in the same direction as word lines, is provided in the fourth-layer wire so as to extend in a direction crossing word lines.
Moreover, as the region S of the activation region OD in the SE section is provided as a P-type region, which is reverse to the polarity of the source/drain region of the memory cell section, the connection with the substrate is made possible, thus reinforcing the substrate potential.
Embodiment 4 will now be described with reference to
In
Moreover, the connection with the VSS (ground line) being on the opposite side from the connecting point with the main bit line can also be shared between opposing memory blocks SB**, thereby reducing the area.
Embodiment 5 will now be described with reference to
The transistors Td1 and Tl1 share a common gate GA_S, the transistors Tl2 and Td2 share a common gate GA_S, the transistors Td1 and Tl1 share a common drain that is connected in the wiring layer with the gates of the transistors Tl2 and Td2, and the transistors Tl2 and Td2 share a common drain that is connected in the wiring layer to the gates of the transistors Tl1 and Td1.
In
The transistors Tl1 and Tl2 in the activation region used in the SRAM memory cell are used as precharge transistors and the transistors Ta1 and Ta2 as block selection transistors.
The sub-bit lines LB1 and /LB1 are connected to the source/drain regions of the transistors Ta1 and Ta2, and the line BS1 is connected to the gates of the transistors Ta1 and Ta2 using the third-layer wire (M3). The gate GA_S is disconnected, the transistors Td1 and Td2 are removed, and the opposite side to the connection between the transistors Ta1 and Ta2 and the sub-bit lines LB1 and /LB1 is connected to the main bit lines GB1 and /GB1. The gates of the transistors Td1 and Td2 are connected together and to the line BS1, and the drain sections are connected to the sub-bit lines LB1 and /LB1, thereby providing a precharge function.
With the present configuration, OD patterns can be formed without changing the conventional SRAM memory patterns.
As described above, also in an SRAM, the block selection transistor section, etc., can be formed by using memory cell patterns. Thus, it is possible to maintain the area-reducing effect also with SRAMs.
The present invention addresses the problem of dummy patterns in a peripheral portion of a memory array, and is directed particularly to a semiconductor memory device of a hierarchical bit line architecture employing a bit line division structure, capable of providing a pattern uniformity across the memory array, whereby it is possible to achieve both a reduced variation in the transistor characteristics and a reduction in the total area. Thus, the configuration of the present invention significantly contributes to improving the performance of any semiconductor memory device employing such a configuration.
Number | Date | Country | Kind |
---|---|---|---|
2008-006805 | Jan 2008 | JP | national |