Semiconductor memory device capable of reducing leakage...

Static information storage and retrieval – Powering – Conservation of power

Reexamination Certificate

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Details Semiconductor memory device capable of reducing leakage... Semiconductor memory device capable of reducing leakage...

: 2001-11-14
: 2002-06-25
: Tran, Andrew Q. (Department: 2824)
: Static information storage and retrieval
: Powering
: Conservation of power

: C365S226000, C365S189020, C365S189070, C365S189090
: Reexamination Certificate
: active
: 06411560
: ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a semiconductor memory device, and particularly, to a semiconductor memory device with plural power supply voltages at respective different voltage levels, capable of reducing a leakage current flowing into a substrate.
2. Description of the Background Art
Attention has been focused on DRAM (Dynamic Random Access Memory), SRAM (Static Random Access Memory) and so on as a memory capable of inputting/outputting data at high speed.
Referring to
FIG. 33
, a prior art semiconductor memory device
1000
includes: memory cells
1001
and
1002
; a sense amplifier
1010
; a gate circuit
1020
; peripheral circuit
1030
; and a bit line driver
1070
. Note that
FIG. 33
shows only a part of semiconductor memory device
1000
since the figure is to describe fundamental operation of semiconductor memory device
1000
.
Memory cell
1001
is connected to a bit line BL and a word line W
1
. Memory cell
1002
is connected to a bit line /BL and a word line W
2
. When word line W
1
is activated, memory cell
1001
outputs data onto bit line BL or data is inputted to memory cell
1001
from bit line BL. When word line W
2
is activated, memory cell
1002
outputs data onto bit line /BL or data is inputted to memory cell
1002
from bit line /BL.
Sense amplifier
1010
includes P channel MOS transistors
1011
to
1013
; and N channel MOS transistors
1014
to
1016
. P channel NOS transistor
1011
is connected between a power supply node
1017
and a node
1031
and receives a sense amplifier activation signal /SE at the gate terminal thereof. P channel MOS transistor
1012
and N channel MOS transistor
1014
are connected in series between nodes
1031
and
1032
. P channel MOS transistor
1013
and N channel MOS transistor
1015
are connected in series between nodes
1031
and
1032
. P channel MOS transistor
1012
and N channel MOS transistor
1014
in series connection are connected in parallel to P channel MOS transistor
1013
and N channel MOS transistor
1015
in series connection. N channel MOS transistor
1016
is connected between node
1032
and a ground node
1018
and receives a sense amplifier activation signal SE at the gate terminal thereof.
A node
1033
is connected to bit line BL. A node
1034
is connected to bit line /BL. P channel MOS transistor
1012
and N channel MOS transistor
1014
receive a voltage on bit line BL at the gate terminals thereof. P channel MOS transistor
1013
and N channel MOS transistor
1015
receive a voltage on bit line /BL at the gate terminals thereof. An array power supply voltage VccA is supplied onto power supply node
1017
and ground voltage is supplied onto ground node
1018
.
When word line W
1
is activated and data [
1
] is read out from memory cell
1001
, the voltage on bit line BL comes to be voltage VccA/
2
+&agr; slightly higher than a precharge voltage VccA/
2
and bit line /BL assumes a precharge voltage VccA/
2
. In such a state, sense amplifier activation signal SE at H (logical high) level is inputted to sense amplifier
1010
. Thereby, sense amplifier
1010
is activated. Voltage VccA/
2
+&agr; is transmitted along bit line BL and applied onto the gate terminals of P channel MOS transistor
1012
and N channel MOS transistor
1014
. Then, P channel MOS transistor
1012
is turned off, while N channel MOS transistor
1014
is turned on, with the result that a voltage on node
1034
is lowered to ground voltage (0 V) and in turn, a voltage on bit line /BL comes to 0 V.
Since a voltage on bit line /BL is applied to the gate terminals of P channel MOS transistor
1013
and N channel MOS transistor
1015
, P channel MOS transistor
1013
is turned on, while N channel MOS transistor
1015
is turned off to cause a voltage on node
1033
to be array power supply voltage VccA. Then, a voltage on bit line BL becomes array power supply voltage VccA. In such operation, voltages on bit lines BL and /BL showing data [
1
] read out from memory cell
1001
are amplified from (VccA/
2
+&agr;, VccA/
2
) to (VccA,
0
), respectively.
When data [
0
] is read out from memory cell
1001
, a voltage on bit line BL becomes a voltage VccA/
2
−&agr; slightly lower than precharge voltage VccA/
2
, and a voltage on bit line /BL becomes precharge voltage VccA/
2
. Voltage VccA/
2
is transmitted along bit line /BL and applied onto the gate terminals of P channel MOS transistor
1013
and N channel MOS transistor
1015
of sense amplifier
1010
. Then, P channel MOS transistor
1013
is turned off, while N channel MOS transistor
1015
is turned on to cause a voltage on node
1033
to be ground voltage (0V). Thus, a voltage on bit line BL becomes 0 V.
Since a voltage on bit line BL is applied onto the gate terminals of P channel MOS transistor
1012
and N channel MOS transistor
1014
, P channel MOS transistor
1012
is turned on, while N channel MOS transistor
1014
is turned off to cause a voltage on node
1034
to be array power supply voltage VccA. Then, a voltage on bit line /BL becomes array power supply voltage VccA. In such operation, voltages on bit lines BL and /BL showing data [
0
] read out from memory cell
1001
are amplified from (VccA/
2
−&agr;, VccA/
2
) to (
0
, VccA), respectively.
When data is read out from memory cell
1002
, as well, sense amplifier
1010
amplifies voltages on bit lines BL and /BL performing the above operation.
When data is written onto memory cells
1001
and
1002
, sense amplifier
1010
transfers voltages transmitted from a global data line pair GIO and /GIO as VccA and
0
(or
0
and VccA) onto bit line pair BL and /BL, respectively.
Therefore, sense amplifier
1010
amplifies data read out from memory cells
1001
and
1002
using a cross-coupled latch, or alternatively transfers data written from outside semiconductor memory device
1000
onto bit lines BL and /BL using the cross-coupled latch.
Gate circuit
1020
includes N channel MOS transistors
1021
and
1022
. N channel MOS transistor
1021
is connected to bit line BL at the drain terminal thereof and to global data line GIO at the source terminal, and receives a column select signal VACSL at the gate terminal thereof. N channel MOS transistor
1022
is connected to bit line /BL at the drain terminal thereof and to global data line /GIO at the source terminal, and receives column select signal VACSL at the gate terminal thereof. Therefore, N channel MOS transistor
1021
is turned on when receiving column select signal VACSL at H level at the gate terminal thereof to connect global data line GIO to bit line BL. N channel MOS transistor
1022
is turned on when receiving column select signal VACSL at the gate terminal thereof to connect global data line /GIO to bit line /BL.
Peripheral circuit
1030
includes: a GIO line write driver
1040
; a read amplifier
1050
; and a GIO line equalize circuit
1060
. GIO line write driver
1040
includes: inverters
1041
and
1044
to
1047
; NAND gates
1042
and
1043
; P channel MOS transistors
1048
and
1051
; and N channel MOS transistors
1049
and
1052
. Inverter
1041
inverts a signal inputted at terminal
1028
to output the inverted input to one terminal of NAND gate
1043
. NAND gate
1042
receives a signal inputted at terminals
1028
and
1029
to invert a logical product of the received two signals and output the inverted logical product as a signal. NAND gate
1043
receives an output signal of inverter
1041
and a signal inputted at terminal
1029
to invert a logical product of the received two signals and output the inverted logical product as a signal. Inverter
1044
inverts an output signal of NAND gate
1042
. Inverter
1045
inverts an output signal of NAND gate
1043
. Inverter
1046
inverts an output signal of inverter
1044
. Inverter
1047
inverts an output signal of inverter
1045
.
P channel MOS transistor
1048
and N channel MOS transistor
1049
are connected in series between a power supply node
1053
and

Affiliated with

Hidaka Hideto

Inventor

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Ishikawa Masatoshi

Inventor

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Kato Hiroshi

Inventor

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Maruta Masanao

Inventor

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Niiro Mitsutaka

Inventor

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Also associated with

McDermott & Will & Emery

Law Firm

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Mitsubishi Denki & Kabushiki Kaisha

Corporate Assignee

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Tran Andrew Q.

Examiner

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