This application is based upon and claims the benefit of priority from prior Japanese Patent Application No. 2005-026713, filed Feb. 2, 2005, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a semiconductor memory device comprising a column that can be selected by a bit line selection signal.
2. Description of the Related Art
Recent years, the performance of semiconductor memory devices is further advanced, and more specifically, a higher operation speed and a lower consumption power, etc. are being promoted.
The operation of the above-described semiconductor memory device will now be described with use of a timing chart illustrated in
After a certain period of time, when an NSA driver activation signal SEN is set from the “L” level (for example, ground potential VSS) to the “H” level (for example, voltage VBLH), and a PSA driver activation signal SEP is set from the “H” level (for example, voltage VBLH) to the “L” level (for example, ground potential VSS), the data appearing on the bit line is amplified. Thus, the bit line on the “H” side is set to the voltage VBLH, and the bit line on the “L” side is set to the voltage VBLL (usually, the ground potential VSS). Then, a bit line selection signal CSL is set from the “L” level (for example, ground potential VSS) to the “H” level (for example, voltage VDD). By transferring data on the bit line BL,/BL a data line DQ,/DQ, the data is read, whereas by transferring data on a data line to a bit line, the data is written.
In accordance with the demand for a higher performance of devices (that is, higher operation speed and lower consumption power), the size of elements of a device has been reduced to a fine level based on the scaling rule. Accordingly, the power supply voltage applied to a transistor in a chip of the device has been lowered as the generation succeeded. Since the reduction in size of elements will further advance from now, it is considered that the fall of power supply voltage will be a more significant problem in designing.
As the power supply voltage is lowered, the threshold voltage of the transistor must be lowered. Therefore, in, for example, an SRAM (static random access memory), the increase in cell leakage caused by a fall of threshold voltage will be a problem. Meanwhile, in DRAMs (dynamic random access memories), as the size becomes finer, it is becoming difficult to secure the cell capacitance or to suppress the leak current from a cell. Therefore, when the power potential (high level bit line voltage VBLH) is lowered, the charge amount accumulated in a cell is decreased, thereby deteriorating the data maintaining performance. In order to deal with such a problem, it is expected that the power supply voltage of a memory cell portion should necessarily be set higher than that of the peripheral logic portion. In this case, however, as shown in
In the case where a transistor of a different type from that of the peripheral logic portion is used in a memory cell portion where the power supply voltage is high (note, for example, that a transistor used in the peripheral logic portion operated at a low voltage is characterized by its short gate length, a thin gate oxide film or the like, to achieve a high speed operation), it is necessary in the light of reliability to avoid application of a voltage VBLH that is used for a sense amplifier circuit to the circuits outside a pair of data lines DQ,/DQ. Here, the easiest way of the possible measures is to drive the bit line selection signal CSL at the power potential VDD. However, when data reverse to that held in the sense amplifier circuit is written to the memory cell, in other words, when the data of the bit line pair BL,/BL must be reversed, the data held in the sense amplifier circuit by the voltage VBLH must be reversed by a DQ gate driven by the power potential VDD which is lower than the voltage VBLH. Therefore, it is necessary here to enlarge the size of the transistor that makes up the DQ gate.
In a memory have such a structure that data are read and written at the same time by multi-bit, such as a combined memory in which a memory circuit and a logic circuit are combined, a great number of columns are connected to a bit line selection signal line CSL, which is usually one line. When a great number of columns are connected to one bit line selection signal line CSL, the wiring capacitance is increased naturally. Therefore, the rising or falling speed of the bit line section signal CSL slows down, which causes flattening of the pulse of the signal CSL. Further, a skew occurs between a portion of the signal CSL that is closer to the driver and another portion that is far from the drive. These drawbacks are considered to be possible factors for interfering with a high speed operation of the device. Further, in such a case as described above where the size of the transistor that forms the DQ gate needs to be enlarged, these possible factors make the situation even worse, and therefore the high speed operation will be extremely difficult.
In the meantime, as a conventional technique to the present invention, there has been proposed a semiconductor memory device having the following structure. That is, a main column selection portion containing a driver is connected to one end of a column selection line CSL, and a latch circuit that serves to drive a column selection line CSL upon reception of an output signal from the driver is connected to the other end. (See Jpn. Pat. Appln. KOKAI Publication No. 2000-123571.)
According to an aspect of the present invention, there is provided a semiconductor memory device comprising: a memory cell array including a plurality of memory cells arranged in matrix; a plurality of bit line pairs to transmit or receive data with the plurality of memory cells; a plurality of sense amplifier circuits connected to the plurality of bit line pairs, respectively, to amplify data transferred to the respective bit line pairs; a plurality of data line pairs to transmit or receive data with the plurality of bit line pairs; a plurality of selection circuits each arranged between a respective bit line pair and a respective data line pair, to set one of a connection status and a disconnection status between the respective bit line pair and respective data line pair in accordance with a bit line selection signal; a sense amplifier bank which contains a plurality of those sense amplifier circuits, data line pairs and selection circuits; a control circuit to control the bit line selection signal supplied to a respective one of the plurality of selection circuits; a global bit line selection signal line connected to the control circuit, to receive the bit line section signal therefrom; a plurality of drive circuit, input portions of which are connected to the global bit line selection signal line, to drive the bit line selection signal supplied to the bit line selection signal line and output it, the plurality of drive circuits being arranged within the sense amplifier bank; and a local bit line selection signal line connected to output portions of the plurality of drive circuits, to supply the bit line selection signal driven by a respective one of the plurality of drive circuits, to the respective one of the plurality of selection circuits.
According to another aspect of the present invention, there is provided a semiconductor memory device comprising: a memory cell array including a plurality of memory cells arranged in matrix; a plurality of bit line pairs to transmit or receive data with the plurality of memory cells; a plurality of sense amplifier circuits connected to the plurality of bit line pairs, respectively, to amplify data transferred to the respective bit line pairs; a common source line to supply a first voltage to the plurality of sense amplifier circuits; and a sense amplifier driver to drive the common source line; wherein each of the plurality of sense amplifier circuits includes a first MOS transistor and a second MOS transistor which are connected to each other by cross-coupling, a gate of the sense amplifier driver is arranged to normally cross with an extending direction of the plurality of bit line pairs, and a connection portion of the sense amplifier drive to the common source line is located on a distant side from a region where the first MOS transistor and the second MOS transistor are arranged and a connection portion of the sense amplifier driver to a power supply wiring is located on a close side to the region.
Embodiments of the present invention will now be described with reference to accompanying drawings. Throughout the drawings, common structural parts will be designated by common reference symbols in the following descriptions.
First, a semiconductor memory device according to the first embodiment of the present invention will now be described.
In the first embodiment, a plurality of re-drivers are provided in a sense amplifier bank, and each re-driver serves to re-drive a bit line selection signal CSL driven in a sense amplifier control circuit.
As shown in
The sense amplifier control circuit 13 includes a bit line selection signal control circuit (to be referred to as CSL control circuit hereinafter) 13A which controls bit line selection signals. Global bit line selection signal lines (to be referred to as GCSL lines hereinafter) are connected to the CSL control circuit 13A, and global bit line selection signals GCSL (to be referred to as signals GCSL hereinafter) are outputted to the GCSL lines from the CSL control circuit 13A. The GCSL lines are connected to input portions of a plurality of re-drivers RD, respectively, and output portions of the re-drivers RD are connected to a plurality of sense amplifiers SA, respectively. In other words, the re-drivers RD, provided for every several columns, are connection in parallel to the GCSL lines, and local bit line selection signal lines (to be referred to as LCSL lines hereinafter) are connected to the re-drivers RD, respectively. Further, the LCSL lines are connected respectively to DQ gates of a plurality of sense amplifiers SA.
A signal GCSL driven by the CSL control circuit 13A and then supplied to the respective GCSL line is re-driven by the respective re-driver RD, and then output as a local bit line selection signal (to be referred to as signal LCSL hereinafter) to the respective LCSL line. The signal LCSL output to the LCSL line is supplied to the DQ gate in the sense amplifier SA connected to that LCSL line. In this manner, the DQ gates of the sense amplifiers SA in the sense amplifier bank 12 are activated by signals LCSL supplied from the CSL control circuit 13A and driven by the re-drivers RD.
In more detail, 4 systems of GCSL0 line to GCSL3 are connected to the CSL control circuit 13A. The GCSL0 line is connected to the re-drivers RD01 and RD02, and the LCSL0 line is connected to the re-driver RD01. Further, a plurality of sense amplifiers SA are connected to the LCSL0 line. Although not shown in the figure, LCSL lines are connected to the re-driver RD02, and a plurality of sense amplifiers are connected to the LCSL lines. Meanwhile, the GCSL1 line is connected to the re-drivers RD11 and RD12, and the LCSL1 line is connected to the re-driver RD11. Further, a plurality of sense amplifiers SA are connected to the LCSL1 line. Although not shown in the figure, LCSL lines are connected to the re-driver RD12, and a plurality of sense amplifiers are connected to the LCSL lines. Similarly, the GCSL2 line is connected to the re-drivers RD21 and RD22, and the LCSL2 line is connected to the re-driver RD21. Further, a plurality of sense amplifiers SA are connected to the LCSL2 line. Although not shown in the figure, LCSL lines are connected to the re-driver RD22, and a plurality of sense amplifiers are connected to the LCSL lines. Similarly, the GCSL3 line is connected to the re-drivers RD31 and RD32, and the LCSL3 line is connected to the re-driver RD31. Further, a plurality of sense amplifiers SA are connected to the LCSL3 line. Although not shown in the figure, LCSL lines are connected to the re-driver RD32, and a plurality of sense amplifiers are connected to the LCSL lines.
In
Next, a semiconductor memory device according to the second embodiment of the present invention will now be described. In this embodiment, similar structural parts to those of the first embodiment will be designated by the reference symbols, and explanations for these parts will be omitted. The followings are descriptions of the parts different from those of the first embodiment.
In the second embodiment, a re-driver serving to re-drive a bit line selection signal CSL is provided in each of empty regions created in a sense amplifier bank adjacent to word line stitch regions.
As shown in
In the case where an empty region 12B exists between adjacent sense amplifier regions 12A in a sense amplifier bank 12 in a semiconductor memory device having such a structure as described above, a re-driver is provided in the empty region 12B. In other words, in the case where there is an empty region 12B in an area in a sense amplifier bank, that is adjacent to a word line stitch region 15, a re-driver is provided in the empty region 12B in the second embodiment. With this arrangement, it is possible to avoid an increase in the area of each of the sense amplifier banks 12 due to arrangement of the re-driver.
As shown in
In each of the memory cell arrays 11, a plurality of main word lines MWL are provided. Each of the main word lines MWL is connected to a main word line driver MWD serving to drive the respective main word line MWL. Each of the main word line MWL is connected to, for example, 4 sub-word lines SWL via sub-word line drivers SWD. An address signal is supplied to each of the sub-word line driver SWD, and each sub-word line driver SWD serves to drive the sub-word line SWL based on the address signal. It should be noted that the sub-word line driver SWD is provided in the respective sub-word line driver region 16. Each sub-word line driver region 16 is provided for every predetermined number of columns.
In the case of the layout shown in
Next, a semiconductor memory device according to the third embodiment of the present invention will now be described. In this embodiment, similar structural parts to those of the first embodiment will be designated by the reference symbols, and explanations for these parts will be omitted. The followings are descriptions of the parts different from those of the first embodiment.
In the third embodiment, a re-driver serving to re-drive a bit line selection signal CSL is provided in a region adjacent to a sense amplifier region in which sense amplifiers are repeatedly arranged.
As shown in
Here, let us suppose, for example, a case where there is one system of bit line selection signal line CSL. In this case, when a re-driver is provided in each region 12B adjacent to a respective word line stitch region 15 as in the second embodiment, all of sense amplifiers located in a sense amplifier bank are categorized for each word line stitch region, and the categorized sense amplifiers are connected by group to the LCSL line connected to the re-drivers arranged for each word line stitch region. With this structure, there is a number of sense amplifiers connected to the LCSL line and therefore the wiring capacity of the LCSL line becomes very large. Therefore, the size of the re-drivers should necessarily be increased to a certain level. However, when there is no such a large space assigned to the region 12B adjacent to the respective word line stitch region 15, it is naturally not possible to provide re-drivers of a sufficient size. As a result, the rising and falling speeds of the bit line selection signal LCSL supplied to the LCSL line falls. Supposing a case where there are 4 systems of bit line selection signals CSL, the number of sense amplifiers connected to each LCSL line is ¼ of that of the case where there is one system. However, even under that condition, the wiring capacitance of each LCSL line is not always made sufficiently small, but re-drivers for the 4 systems still need to be provided in the each word line stitch region. Thus, the circumstance where re-drivers of a sufficient size cannot be provided cannot be improved very much.
Under these circumstances, in the third embodiment, a re-driver is provided in a region adjacent to the sense amplifier region 12A in which sense amplifiers are repeatedly provided. With this structure, it becomes possible to form re-drivers of a sufficient size and increase the degree of freedom in the number of re-drivers provided, thereby allowing flexible designing of sense amplifiers. If an increment of the area caused by newly providing a region where re-drivers are provided is within an allowable range, the third embodiment is very effective measures to realize a high speed operation. It should be noted that the other advantages of the third embodiment that can be obtained by providing the re-drivers are similar to those of the first embodiment.
Next, a semiconductor memory device according to the fourth embodiment of the present invention will now be described. In this embodiment, similar structural parts to those of the first embodiment will be designated by the reference symbols, and explanations for these parts will be omitted. The followings are descriptions of the parts different from those of the first embodiment.
In the fourth embodiment, an active region for use of well contact, which serves to supply a well potential to a transistor of a sense amplifier, is not provided in a sense amplifier region in which sense amplifiers are repeatedly provided, but in place, the well contact-use active region is provided in a re-driver region where a plurality of re-drivers are arranged. That is, the well potential of the transistor included in a sense amplifier is supplied via the well contact-use active region arranged in the re-driver region in which a plurality of re-drivers are provided.
In order to form a well contact-use active region in a sense amplifier region in which a plurality of sense amplifiers are repeatedly provided, such a region must be created. On the other hand, the re-driver region provided adjacent to the sense amplifier region has an empty section, and therefore the well contact-use active region is formed in the empty section. The well potential of the sense amplifier is supplied via the well contact-use active region provided in the re-driver region. With this structure, the area of the well contact-use active region is reduced in the sense amplifier region, and thus the area of the sense amplifier bank including the sense amplifier region can be suppressed to a minimum.
Next, a semiconductor memory device according to the fifth embodiment of the present invention will now be described. In this embodiment, similar structural parts to those of the first embodiment will be designated by the reference symbols, and explanations for these parts will be omitted. The followings are descriptions of the parts different from those of the first embodiment.
In the fifth embodiment, LCSL lines each connected to output portions of a plurality of re-drivers are connected to each other in a sense amplifier bank.
In a sense amplifier bank 18 having the above-described structure, even if, for example, the output portion of a re-driver RD is disconnected from the LCSL line as shown in
Next, a semiconductor memory device according to a remodeled version of the fifth embodiment will now be described.
On the other hand, the fifth embodiment entails the following shortcomings. That is, in the case where a defect such as large leak occurs somewhere in the LCSL line as shown in
Here, this remodeled version provides such a structure that sense amplifiers (column) connected to an LCSL line in a normal column are included in a replacement unit of a redundancy column, that is, in other words, a plurality of sense amplifiers (including DQ gates) connected to the same LCSL line are arranged within a substitution unit of redundancy column. With this structure, if an error caused by a defective LCSL line occurs, such an error can be relieved. It should be noted that
Next, a semiconductor memory device according to the sixth embodiment of the present invention will now be described. In this embodiment, similar structural parts to those of the first embodiment will be designated by the reference symbols, and explanations for these parts will be omitted. The followings are descriptions of the parts different from those of the first embodiment.
In a re-driver region 19 where re-drivers are provided, global bit line selection signal lines (GCSL lines) are formed of the second metal wiring (M2). In the sixth embodiment, there are 4 systems of GCSL lines, which are made of the second metal wirings, and therefore it is difficult to make power supply lines for re-drivers using the second metal wiring. Under these circumstances, in the sixth embodiment, the ground potential (, which is equal to VBLL,) of a re-driver is supplied by connecting a VBLL wiring to which the voltage VBLL in the sense amplifier region 12A and a first metal wiring (M1) to each other.
Further, the layout shown in
In a region above where an NSA driver is provided, a signal line SEN is made of the second metal wiring in its gate direction. The NSA driver is a transistor serving to drive an N channel MOS transistor (NSA) included in a sense amplifier circuit. A drain of the NSA driver is connected to a common source line node. A sense amplifier activation signal SEN is supplied to a gate of the NSA driver, and a low level bit line voltage VBLL is supplied to a source of the NSA driver. The NSA driver serves to drive the NSA by supplying the voltage VBLL to the NSA via the NSA common source line. In order to achieve a stable sensing operation, the wiring for the power VBLL is made of a thick second metal wiring and provided in a region above where the N channel MOS transistor (NSA) and DQ gate included in a sense amplifier circuit are provided. Further, the common source line node of the NSA driver is arranged on a side (lower side) that is distant from the NSA and the DQ gate, and a VBLL wiring node is arranged on a side (upper side) that is close to the NSA and DQ gate. With this arrangement, the VBLL wiring made of the first metal wiring and the second metal wiring can be easily connected to each other.
Next, a semiconductor memory device according to the seventh embodiment of the present invention will now be described. In this embodiment, similar structural parts to those of the first embodiment will be designated by the reference symbols, and explanations for these parts will be omitted. The followings are descriptions of the parts different from those of the first embodiment.
In the case where, for example, one redundancy column is provided for every several normal columns, there is such a problem arises regarding the size of re-drivers serving to supply a bit line selection signal to a column group that includes the redundancy column.
As shown in
In order to avoid this, the size of re-drivers is determined in accordance with the number of sense amplifiers connected to the re-drivers in the seventh embodiment. In the sense amplifier bank 19 shown in
Next, a semiconductor memory device according to the eighth embodiment of the present invention will now be described. In this embodiment, similar structural parts to those of the first embodiment will be designated by the reference symbols, and explanations for these parts will be omitted. The followings are descriptions of the parts different from those of the first embodiment.
A semiconductor memory device in which different types of transistors are used depending on voltages at which these transistors are operated will now be described. For example, the transistors operated at a low voltage are characterized by their thin gate oxide film, short gate length, etc., which are designed so to as to realize a high-speed operation.
In a sense amplifier shown in
As described above, in the case where the bit line selection signal CSL is driven at the power supply voltage VDD, which is the same as that of the peripheral logic portion, a thin film transistor as well can be used for a re-driver. In the case where transistors with oxide films of different thicknesses are mixedly present in a semiconductor memory device, a large space is required between transistors in order to form oxide films of different thicknesses from each other. Therefore, if a re-driver made of a thin film transistor is provided in a sense amplifier which does not contain any thin film transistor, a large space is required, thereby increasing the area.
Here, let us consider the size of a transistor necessary for achieving a certain driving capability. A thin film transistor can achieve the required certain driving capability with a size smaller than that of a transistor with a thick oxide film, and therefore the area occupied by the transistor itself becomes smaller. Therefore, if the area reduction effect is larger than the increment in area due to the large space required to form the transistors of oxide films of various thicknesses, the increment in area caused by arranging the re-drivers in a certain way can be suppressed to a minimum level. Alternatively, if transistors having oxide film of the same thickness but having a threshold voltage lower than that of the transistor included in the sense amplifier and a current driving capability higher than that of the transistor are used for the re-drivers, the increment in area can be suppressed to a minimum level. It should be noted that the other advantages of the eighth embodiment that can be obtained by providing the re-drivers are similar to those of the first embodiment.
As described above, according to the embodiments of the present invention, it is possible to provide a semiconductor memory device that can surely supply a pulse of a bit line selection signal CSL to a DQ gate, and suppress skew of a bit line selection signal CSL in a sense amplifier bank, thereby making it possible to perform a high-speed reading and writing operation.
The above embodiments and modifications can be individually or in combination put to practical use. Furthermore, they contain a number of inventive aspects at different levels. Thus, a number of inventions at different levels can be extracted by properly selectively combining the structural elements disclosed above with respect to the embodiments and modifications.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
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2005-026713 | Feb 2005 | JP | national |