Static information storage and retrieval – Read/write circuit – Bad bit
Reexamination Certificate
2000-04-06
2001-03-13
Nguyen, Tan T. (Department: 2818)
Static information storage and retrieval
Read/write circuit
Bad bit
C365S230060
Reexamination Certificate
active
06201745
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to semiconductor memory devices, and more particularly to a semiconductor memory device with a redundancy structure capable of realizing a high-speed access and a method for driving a row thereof.
BACKGROUND OF THE INVENTION
Conventionally, semiconductor memory devices such as dynamic random access memories (DRAMs) that have high levels of integration also have high defect rates. In particular, many defects occur in memory element regions (e.g., memory cell arrays). To repair semiconductor memory devices containing such defects, the semiconductor memory devices typically include redundant row or column structures in the memory arrays.
FIG. 1
shows a layout of a conventional semiconductor memory device, and for brevity and clarity does not illustrate any peripheral circuits. More specifically,
FIG. 1
illustrates a conventional dynamic random access memory device (DRAM)
10
having a sub word line driver (SWD) structure (sometimes referred to as “a divided word line structure” or “a hierarchical structure”). U.S. Pat. No. 5,581,508, entitled “SEMICONDUCTOR MEMORY HAVING SUB-WORD LINE REPLACEMENT,” and U.S. Pat. No. 5,761,135, entitled “SUB-WORD LINE DRIVERS FOR INTEGRATED CIRCUIT MEMORYDEVICES AND RELATED METHODS,” which are hereby incorporated by reference, disclose known sub word line driver structures.
The DRAM device
10
includes a plurality of memory cell blocks
12
arranged in row and column directions. Each of the memory cell blocks has a plurality of sub word lines SWL extending in the row direction and a plurality of redundant sub word lines RSWL extending in the row direction. The DRAM device
10
further includes a plurality of sub word line drivers (SWD)
14
, a plurality of sense amplifiers (S/A)
16
, a plurality of redundant sub word line drivers (RSWD)
18
, a plurality of main word line decoder drivers
22
, and a plurality of redundant main word line decoder drivers
24
. Although not illustrated in
FIG. 1
, the main word line decoder drivers
22
drive multiple main word lines, and the redundant word line decoder drivers
24
drive multiple redundant main word lines.
The DRAM device
10
further includes a plurality of sub row decoders
26
and a plurality of drivers
28
. Most of the sub row decoders
26
are between one of the main word line decoder drivers
22
and one of the redundant main word line decoder drivers
24
. Most of the drivers
28
are between one of the sub word line drivers
14
and one of the redundant sub word line drivers
18
. As shown in
FIG. 1
, the memory cell blocks
12
are separated in the row direction by the sub word line drivers
14
and in the column direction by the sense amplifiers
16
.
In the sub word line driver structure of
FIG. 1
, when a sub word line is defective, a row redundancy operation replaces a main word line and associated structures including the defective sub word line with a redundant main word line and associated redundant structures. Accordingly, the row redundancy operation deselects (or deactivates) a main word line decoder driver
22
that drives the main word line coupled to a set of sub word lines including the defective sub word line. The row redundancy operation selects (or activates) a redundant main word line decoder driver
24
that drives the redundant main word line that replaces the main word line.
FIG. 2
is a circuit diagram showing a main word line decoder driver according to a first redundancy scheme. As illustrated in
FIG. 2
, the main word line decoder driver
22
includes a fuse
59
for a redundancy operation. The fuse
59
is blown (or cut) during a row redundancy operation to deselect a corresponding main word line MWLi even when three decode signals DRA
0
, DRA
1
and DRA
2
are activated. This redundancy scheme has the drawback of increasing the layout area due to the fuse
59
, which is in each main word line decoder driver
22
.
FIG. 3
is a circuit diagram showing a main word line decoder driver according to a second redundancy scheme, and
FIG. 4
is a timing diagram showing timing relationships among control signals in the main word line decoder driver of FIG.
3
.
In
FIGS. 3 and 4
, a signal PR has a logic low level during a row precharge period (when {overscore (RAS)} is high) and a logic high level during a row active period (when {overscore (RAS)} is low). Decode signals DRAi (i=0, 1, 2), which are signals derived by decoding row address bit signals at a previous stage (for example, a row predecoder), designate or select a main word line MWLi. A signal PRREB controls whether a main word line or a redundant main word line is selected. The signal PRREB is at a logic low level to disable use of the main word line MWLi corresponding to the row address bit signals and selects a redundancy main word line (not shown in FIG.
3
). When the signal PRREB is at a logic high level, the main word line MWLi is usable. U.S. Pat. No. 5,798,974, entitled “SEMICONDUCTOR MEMORY DEVICE REALIZING HIGH SPEED ACCESS AND LOW POWER CONSUMPTION WITH REDUNDANT CIRCUIT,” which is hereby incorporated by reference, discloses the redundancy system of FIG.
3
and an address programming circuit generating the signal PRREB.
When the signal (referred to as “a row active signal”) PR remains low (e.g., during a row precharge period), an output signal PDPX of a level shifter
80
remains low, and a PMOS transistor
69
and an invertor
71
precharge a main word line MWLi at a logic low level (for example, a ground voltage). When the signal PR goes to a logic high level (when a row address designating a sub word line is input), the output signal PDPX of the shifter
80
transitions from low to high, thereby turning off the PMOS transistor
69
. As illustrated in
FIG. 4
, the decode signals DRA
0
-DRA
2
go to a logic high level for a row address selecting the main word line MWLi. When the signal PRREB remains high, an output signal PNWR of an invertor
75
becomes high and turns on the NMOS transistor
79
. This makes the invertor
71
activate the main word line MWLi. On the other hand, if the signal PRREB transitions from high to low as illustrated by the dashed line in
FIG. 4
, the NMOS transistor
79
remains off, and the main word line MWLi remains in a precharged state, for example, at the ground voltage.
Referring to
FIG. 3
, to prevent a main word line and a redundant main word line from being activated at the same time, an invertor chain
76
provides a delay in the main word line decoder driver
22
. In particular, discrimination of whether row address bit signals correspond to a programmed defective row address in the address programming circuit determines whether the signal PRREB activates or deactivates a main word line corresponding to the row address bit signals. As well understood in
FIG. 4
, the transition of the decode signals DRA
0
-DRA
2
precedes the transition of the signal PRREB. If invertor chain
76
of
FIG. 3
were absent, a transition of the decode signals DRA
0
-DRA
2
could activate the main word line MWLi, and then a transition of the signal PRREB during the activation of the main word line, could activate a redundancy main word line. Accordingly, without the delay chain
76
, the main word line and the redundant main word line may be activated at the same time when the signal PRREB transitions from a logic high level to a logic low level as illustrated by a dashed line in FIG.
4
.
According to the second redundancy scheme, a main word line decoder driver activates or deactivates a main word line MWLi after discriminating whether a row replacement is performed or not (or whether the signal PRREB is activated or not). Therefore, the invertor chain
76
, which includes series-connected invertors
72
and
73
, delays the activation of the signal PNWR (and activation of the main word line MWLi) by a delay time t
D
. This increases an access time from a row active (and reduces access speed), which is determined by t
RCD
+t
CAC
. The t
RCD
and t
CAC
indicate {overscore (RAS)} to {overscore (CAS)} delay
Bae Won-Il
Ryu Hoon
Millers David
Nguyen Tan T.
Samsung Electronics Co,. Ltd.
Skjerven Morrill & MacPherson LLP
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