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Claims  |
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What is claimed is:
1. A multiplexing sense amplifier circuit for use with a memory array
comprising:
a disabling sense amplifier stage having at least two disabling sense
amplifier circuits, a first disabling sense amplifier circuit connected to
a first input line and a first complement input line and a second
disabling sense amplifier circuit connected to a second input line and a
second complement input line, each disabling sense amplifier circuit
having two outputs, a true output and a complement output, and a select
input, responsive to a select signal, for enabling or disabling the
disabling sense amplifier circuits, wherein the first disabling sense
amplifier circuit is disabled when the second disabling sense amplifier
circuit is enabled and when the first disabling sense amplifier circuit is
enabled, the second disabling sense amplifier circuit is disabled and
wherein selection of signals from one of the two disabling sense amplifier
circuits may be accomplished; and
a second stage having a true output and a complement output and multiple
true and complement inputs, the second stage true and complement inputs
being connected to the true and complement outputs of the disabling sense
amplifier stage, wherein data on the true output and the complement output
of the second stage are controlled by data on the outputs of the disabling
sense amplifier stage.
2. A multiplexing sense amplifier circuit for use with a memory array
comprising:
a disabling sense amplifier stage having at least two disabling sense
amplifier circuits, a first disabling sense amplifier circuit connected to
a first input line and a first complement input line and a second
disabling sense amplifier circuit connected to a second input line and a
second complement input line, each disabling sense amplifier circuit
having two outputs, a true output and a complement output, and a select
input, responsive to a select signal, for enabling or disabling the
disabling sense amplifier circuits, wherein the first disabling sense
amplifier circuit is disabled when the second disabling sense amplifier
circuit is enabled and when the first disabling sense amplifier circuit is
enabled, the second disabling sense amplifier circuit is disabled and
wherein selection of signals from one of the two disabling sense amplifier
circuits may be accomplished; and
a second stage having a true output and a complement output and multiple
true and complement inputs, the second stage true and complement inputs
being connected to the true and complement outputs of the disabling sense
amplifier stage, wherein data on the true output and the complement output
of the second stage are controlled by data on the outputs of the disabling
sense amplifier stage, wherein both outputs of the disabling sense
amplifier circuits are forced low in response to disablement of one of the
two disabling sense amplifier circuits.
3. A multiplexing sense amplifier circuit for use with a memory array
comprising:
a disabling sense amplifier stage having at least two disabling sense
amplifier circuits, a first disabling sense amplifier circuit connected to
a first input line and a first complement input line and a second
disabling sense amplifier circuit connected to a second input line and a
second complement input line, each disabling sense amplifier circuit
having two outputs, a true output and a complement output, and a select
input, responsive to a select signal, for enabling or disabling the
disabling sense amplifier circuits, wherein the first disabling sense
amplifier circuit is disabled when the second disabling sense amplifier
circuit is enabled and when the first disabling sense amplifier circuit is
enabled, the second disabling sense amplifier circuit is disabled and
wherein selection of signals from one of the two disabling sense amplifier
circuits may be accomplished; and
a second stage having a true output and a complement output and multiple
true and complement inputs, the second stage true and complement inputs
being connected to the true and complement outputs of the disabling sense
amplifier stage, wherein data on the true output and the complement output
of the second stage are controlled by data on the outputs of the disabling
sense amplifier stage, wherein the second stage is a multiplexing sense
amplifier.
4. The multiplexing sense amplifier circuit of claim 1 further comprising:
an amplifier stage connected to the true output and the complement output
of the second stage, the amplifier having a pair of outputs, wherein the
amplifier generates logic 1 and logic 0 signals at the pair of outputs in
the amplifier stage in response to signals from the true output and
complement output of the second stage.
5. The multiplexing sense amplifier circuit of claim 2, wherein said second
stage comprises a first pair of transistors and a second pair of
transistors, each pair of transistors having a first transistor connected
in parallel with a second transistor in the pair, the gate of the first
transistor in the first pair being connected to the true output of the
first disabling sense amplifier circuit, the gate of the second transistor
in the first pair being connected to the true output of the second
disabling sense amplifier circuit, the gate of the first transistor in the
second pair being connected to the complement output of the first
disabling sense amplifier circuit, and the gate of the second transistor
in the second pair being connected to the complement output of the second
disabling sense amplifier circuit, wherein the two pairs of transistors
control the true output and the complement output of the second stage.
6. The multiplexing sense amplifier circuit of claim 5, wherein the
amplifier stage is a p-channel cross-coupled amplifier comprising two
p-channel FETs, each p-channel metal-oxide transistor having a gate
connected to a drain of the other p-channel FET, and two n-channel FETs,
each n-channel FET having a drain connected to the drain of a p-channel
FET, wherein the true output of the second stage is connected to the gate
of the first n-channel FET and the complement output of the second stage
is connected to the gate of the second n-channel FET.
7. The multiplexing sense amplifier circuit of claim 5, wherein the second
stage comprises a pair of current mirrors, a first current mirror and a
second current mirror, the first current mirror having an output
controlled by the outputs of the first and second disabling sense
amplifier circuits and the second current mirror having an output
controlled by the outputs of the first and second disabling sense
amplifier circuits.
8. A multiplexing sense amplifier circuit for use with a memory array
comprising:
a disabling sense amplifier stage having at least two disabling sense
amplifier circuits, a first disabling sense amplifier circuit connected to
a first input line and a first complement input line and a second
disabling sense amplifier circuit connected to a second input line and a
second complement input line, each disabling sense amplifier circuit
having two outputs, a true output and a complement output, and a select
input, responsive to a select signal, for enabling or disabling the
disabling sense amplifier circuits, wherein the first disabling sense
amplifier circuit is disabled when the second disabling sense amplifier
circuit is enabled and when the first disabling sense amplifier circuit is
enabled, the second disabling sense amplifier circuit is disabled and
wherein selection of signals from one of the two disabling sense amplifier
circuits may be accomplished; and
a second stage having a true output and a complement output and multiple
true and complement inputs, the second stage true and complement inputs
being connected to the true and complement outputs of the disabling sense
amplifier stage, wherein data on the true output and the complement output
of the second stage are controlled by data on the outputs of the disabling
sense amplifier stage, wherein each current mirror includes four control
transistors for controlling the output of the current mirror.
9. The multiplexing sense amplifier circuit of claim 8, wherein the first
control transistor has its gate connected to the true output of the first
disabling sense amplifier circuit, the second control transistor is
connected in parallel with the first control transistor and has its gate
connected to the true output of the second disabling sense amplifier
circuit, the third control transistor has a gate connected to the
complement output of the first disabling sense amplifier circuit, and the
fourth control transistor is connected in parallel with the third control
transistor and has a gate connected to the complement output of the second
disabling sense amplifier circuit.
10. A multiplexing sense amplifier circuit for use with a memory array
comprising:
a disabling sense amplifier stage having at least two disabling sense
amplifier circuits, a first disabling sense amplifier circuit connected to
a first input line and a first complement input line and a second
disabling sense amplifier circuit connected to a second input line and a
second complement input line, each disabling sense amplifier circuit
having two outputs, a true output and a complement output, and a select
input, responsive to a select signal, for enabling or disabling the
disabling sense amplifier circuits, wherein the first disabling sense
amplifier circuit is disabled when the second disabling sense amplifier
circuit is enabled and when the first disabling sense amplifier circuit is
enabled, the second disabling sense amplifier circuit is disabled and
wherein selection of signals from one of the two disabling sense amplifier
circuits may be accomplished; and
a second stage having a true output and a complement output and multiple
true and complement inputs, the second stage true and complement inputs
being connected to the true and complement outputs of the disabling sense
amplifier stage, wherein data on the true output and the complement output
of the second stage are controlled by data on the outputs of the disabling
sense amplifier stage, wherein each disabling sense amplifier circuit
includes two current mirrors.
11. A multiplexing sense amplifier circuit for use with a memory array
comprising:
a disabling sense amplifier stage having at least two disabling sense
amplifier circuits, a first disabling sense amplifier circuit connected to
a first input line and a first complement input line and a second
disabling sense amplifier circuit connected to a second input line and a
second complement input line, each disabling sense amplifier circuit
having two outputs, a true output and a complement output, and a select
input, responsive to a select signal, for enabling or disabling the
disabling sense amplifier circuits, wherein the first disabling sense
amplifier circuit is disabled when the second disabling sense amplifier
circuit is enabled and when the first disabling sense amplifier circuit is
enabled, the second disabling sense amplifier circuit is disabled and
wherein selection of signals from one of the two disabling sense amplifier
circuits may be accomplished; and
a second stage having a true output and a complement output and multiple
true and complement inputs, the second stage true and complement inputs
being connected to the true and complement outputs of the disabling sense
amplifier stage, wherein data on the true output and the complement output
of the second stage are controlled by data on the outputs of the disabling
sense amplifier stage, wherein each disabling sense amplifier circuit
includes a p-channel cross-coupled amplifier.
12. A multiplexing sense amplifier circuit for use with a memory array
comprising:
a disabling sense amplifier stage having at least two disabling sense
amplifier circuits, a first disabling sense amplifier circuit connected to
a first input line and a first complement input line and a second
disabling sense amplifier circuit connected to a second input line and a
second complement input line, each disabling sense amplifier circuit
having two outputs, a true output and a complement output, and a select
input, responsive to a select signal, for enabling or disabling the
disabling sense amplifier circuits, wherein the first disabling sense
amplifier circuit is disabled when the second disabling sense amplifier
circuit is enabled and when the first disabling sense amplifier circuit is
enabled, the second disabling sense amplifier circuit is disabled and
wherein selection of signals from one of the two disabling sense amplifier
circuits may be accomplished; and
a second stage having a true output and a complement output and multiple
true and complement inputs, the second stage true and complement inputs
being connected to the true and complement outputs of the disabling sense
amplifier stage, wherein data on the true output and the complement output
of the second stage are controlled by data on the outputs of the disabling
sense amplifier stage, wherein each disabling sense amplifier includes a
differential amplifier. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates generally to the field of microelectronics
and in particular to a method and apparatus for sensing signals from a
memory array. Still more particularly, the present invention relates to a
method and apparatus for selecting and sensing signals from a memory
array.
2. Description of the Prior Art
Memories are devices that respond to operational orders, usually from a
central processing unit (CPU) of a digital computer. A sense amplifier is
typically employed to detect attenuated signals from a memory array. Two
types of sense amplifiers are typically used: a static sense amplifier and
a dynamic sense amplifier. Dynamic sense amplifiers are often used because
they have low current consumption and the sense amplifiers are activated
only when required to perform sensing functions.
Referring to FIG. 1, a memory array 100, a multiplexer 102, and a sense
amplifier 104 are depicted in a configuration known to those skilled in
the art. Memory array 100 contains a number of bit line pairs that may be
accessed using word lines (not shown). Frequently in memory arrays, such
as memory array 100, sense amplifier 104 is shared among many columns of
the memory array. In addition, the data fed into sense amplifier 104 might
be multiplexed between different blocks of columns within memory array
100. In the depicted example, left block 100a and right block 100b of
memory array 100 share sense amplifier 104. Two pairs of data lines, LBT,
LBC, RBT, and RBC originate from memory array 100 and are connected to
multiplexer 102. Data lines LBT and LBC originate from left block 100a of
memory in memory array 100; data lines RBT and RBC originate from right
block 100b in memory array 100. Data lines LBT and LBC carry left block
true and complement data signals respectively, while data lines RBT and
RBC carry right block true and complement data signals respectively.
Multiplexer 102 is used to select data from one pair of data lines and is
connected to sense amplifier 104. Sense amplifier 104 may include a number
of different stages.
Referring next to FIG. 2, sense amplifier 104 may include the following
stages: level shifter 106, current mirror 108, and p-channel cross-coupled
amplifier 110. A level shifter is typically employed to shift the voltage
of the multiplexed signals in order to optimize the other stages of the
sense amplifier. Typically, level shifter 106 is used to adjust the
voltage of the signal selected by multiplexer 102 in order to optimize the
performance of the other stages within sense amplifier 104. Sense
amplifier 104 is employed to detect signals, in lines MUXC and MUXT,
selected by multiplexer 102 from memory array 100. Typically, sense
amplifier 104 includes p-channel cross-coupled amplifier 110 with a high
common-mode rejection in order to reject picked-up interference due to
cross-talk from other parts of the system.
With reference now to FIG. 3, a schematic diagram of a known multiplexer is
illustrated. The multiplexer is constructed with transistors MA-MM. The
transistors are p-channel metal-oxide semiconductor field effect
transistors (MOSFETs). Multiplexer 102 is powered by connecting
transistors ME, MG, MH, MI, MJ, and ML to power supply VCC. Points 111,
113, and 115 are points at which an equalization signal is applied to
multiplexer 102.
Data from data line LBT is fed into the multiplexer 102 at input point 112;
data from the data line LBC is fed into multiplexer 102 at input point
114; data from data line RBT is fed into multiplexer 102 at input point
116; and data from data line RBC is fed into multiplexer 102 at input
point 118.
The selection between the right block signals and the left block signals
are made utilizing transistors MA, MB, MC, and MD. These transistors are
p-channel MOSFETs. A low select signal into input point 120, connected to
the gates of transistors MA and MB, turns on transistors HA and MB causing
the selection of signals from data lines LBT and LBC to be selected and
sent out at output points 122 and 124, as true complement signals in data
lines MUXT and MUXC respectively. A low select signal into input point
126, which is connected to the gates of transistors MC and MD, causes the
true signal in data line RBT to be sent to sense amplifier 104 via output
122 connected to line MUXT and the complement signal from data line RBC to
be sent to sense amplifier 104 via output point 124 connected to line
MUXC. The use of multiplexer 102 typically causes a signal drop. It is
desirable to have as much signal as possible for speed and reliability.
More information on semiconductor memories and sense amplifiers may be
found in the following references: Prince, Semiconductor Memories, John
Wiley and Sons (2nd Ed. 1991) and Haznedar, Digital Microelectronics, The
Benjamin/Cummings Publishing Company, Inc. (1991).
Therefore, it would be desirable to have a method and apparatus for
multiplexing and sensing a data signal from a memory array without
diminishing the data signal being sensed.
SUMMARY OF THE INVENTION
The present invention provides a memory system that includes a memory array
having at least two pairs of data lines the first and second pair of data
lines correspond to columns in the memory array. The memory array also
includes two disabling sense amplifier circuits, a first disabling sense
amplifier circuit connected to the first data lines and a disabling sense
amplifier circuit connected to the second data lines, wherein the
disabling sense amplifier circuits produce output signals and may be
enabled and disabled. A selection signal is provided for selectively
enabling and disabling the disabling sense amplifier circuits, wherein one
pair of data lines may be selected. An amplification circuit connected to
the disabling sense amplifier circuits provides for amplifying the output
signals from the disabling sense amplifier circuits.
BRIEF DESCRIPTION OF THE DRAWINGS
The novel features believed characteristic of the invention are set forth
in the appended claims. The invention itself however, as well as a
preferred mode of use, and further objects and advantages thereof, will
best be understood by reference to the following detailed description of
an illustrative embodiment when read in conjunction with the accompanying
drawings, wherein:
FIG. 1 is a block diagram of a portion of a memory system illustrating a
configuration of a memory array, a multiplexer, and a sense amplifier
known in the prior art;
FIG. 2 is a block diagram of a sense amplifier known in the prior art;
FIG. 3 is a schematic diagram of a multiplexer known in the prior art;
FIG. 4 is a block diagram of a portion of a memory system configured
according to the present invention;
FIG. 5 is a schematic diagram of a cross-coupled level shifter according to
the present invention;
FIG. 6 is a schematic diagram of a pair of current mirrors and a p-channel
cross-coupled amplifier according the present invention;
FIG. 7 is a schematic diagram of a p-channel cross-coupled amplifier
according to the present invention;
FIG. 8 is a schematic diagram of a differential amplifier according to the
present invention;
FIG. 9 is a schematic diagram of a level shifters according to the present
invention;
FIG. 10 is a block diagram of a portion of a memory system configured
according to the present invention;
FIG. 11 is a block diagram of a disabling sense amplifier according to the
present invention;
FIG. 12 is a schematic diagram of a disabling sense amplifier incorporating
two current mirrors;
FIG. 13 is a schematic diagram of a disabling sense amplifier employing a
p-channel cross-coupled amplifier; and
FIG. 14 is a schematic diagram of a disabling sense amplifier using a
differential amplifier.
DESCRIPTION OF THE PREFERRED EMBODIMENT
In accordance with a preferred embodiment of the present invention, the
multiplexing function is incorporated into the sense amplifier in order to
reduce the effects of having a separate multiplexer selecting signals as
illustrated in the prior art design in FIG. 1.
Referring now to FIG. 4, a block diagram of a portion of a memory system
configured according to the present invention is illustrated. Memory array
100 again includes left block 100a and right block 100b. Signals from data
lines LBT, LBC, RBC, and RBT are fed directly into sense amplifier 130
instead of a multiplexer. Signals from data lines LBT and RBT are true
signals, while signals from data lines LBC and RBC are complement signals.
In accordance with a preferred embodiment of the present invention, sense
amplifier 130 includes level shifter 132, level shifter 134, current
mirror stage 136, and amplifier stage 138. Multiplexing functions are
incorporated into level shifters 132 and 134 in accordance with a
preferred embodiment of the present invention.
Referring now to FIG. 5, a schematic diagram of a cross-coupled level
shifter according to the present invention is depicted. Transistors M1-M8
comprise the cross-coupled level shifter. These transistors are n-channel
and p-channel MOSFETs. Transistors M1, M2, M4-M8 are n-channel MOSFETs,
and transistor M3 is a p-channel MOSFET in accordance with the preferred
embodiment of the present invention. Input points 150 and 152 receive
either signals from data lines LBT and LBC, or signals from data lines RBT
and RBC, respectively. These signals control the gates of transistors M1
and M2 respectively. Transistors M7 and M8 are shown in a cross-coupled
connection. Other configurations may be used, such as, tying the drain of
each transistor, M7 and M8, to the transistor's own gate or by tying the
gates to a bias voltage. The drain of transistor M3 is connected to power
supply VCC, and the sources of transistors M5-M8 are connected to power
supply VSS. These connections provide power to operate the circuit. Power
supply VCC is at a higher voltage relative to power supply VSS.
The level shifter incorporates a multiplexing function in accordance with a
preferred embodiment of the present invention. This multiplexing function
is controlled by a select signal at input point 154 in level shifters 132
and 134. The select signal controls the gate of transistor M3. If the gate
of transistor M3 is turned on, the level shifter allows the passage of the
true and complement signals through output points 156 and 158
respectively. A high signal at input point 154 disables the level shifter,
forcing the output at output points 156 and 158 to be low. On the other
hand, when the signal at input point 154 is low, the level shifter
performs normally in accordance with a preferred embodiment of the present
invention.
By selecting only one of the two level shifters, 132 or 134, as depicted in
FIG. 4, a 2 to 1 multiplexing of the signals from the memory array is
achieved without diminishing signal strength in accordance with a
preferred embodiment of the present invention. The output from output
point 156 is a signal LSLT in level shifter 132 and a signal LSRT, right
block true signal, in level shifter 134; the output from output point 158
is a signal LSLC, left block complement signal, in level shifter 132 and a
signal LSRC, right block complement signal, in level shifter 134. In
accordance with a preferred embodiment of the present invention, more than
two level shifters may be used depending on the design of the memory
system.
Next, FIG. 6 illustrates a schematic diagram of a pair of current mirrors
and a p-channel cross-coupled amplifier within a sense amplifier in
accordance with a preferred embodiment of the present invention. Current
mirror stage 136 includes current mirrors 200 and 202. Current mirror 200
is constructed from transistors M9-M14; current mirror 202 is constructed
from transistors M19-M24. Transistors M9, M10, M22, and M23 are p-channel
MOSFETs while the rest of the transistors in the two current mirrors are
n-channel MOSFETs in accordance with the preferred embodiment of the
present invention. P-channel cross-coupled amplifier 204 is constructed
from transistors M25-M32. Transistors M25, M26, M30, M31, and M32, are
p-channel transistors, while transistors M27, M28, and M29 are n-channel
transistors in p-channel cross-coupled amplifier 204. Transistors M25-M28
form a flip-flop in this circuit. Transistor M32 is employed to provide
balancing within the circuit, and transistors M30 and M31 are utilized to
pre-charge the circuit.
Transistors M15-M18 are employed to enable, disable, and pre-charge the
sense amplifier in accordance with a preferred embodiment of the present
invention. The current mirrors and the amplifier are powered by connecting
the drains of transistors M9, M10, M15, M18, M22, M23, M25, M26, M30, and
M31 to power supply VCC, while the sources of transistors M16, and M29 are
connected to power supply VSS. Power supply VCC is typically at a higher
voltage than power supply VSS.
Signals at input points 206, 207, and 208 enable and disable the circuits.
Input points 210 and 212 carry signals LSRC and LSRT from level shifter
134 while input points 214 and 218 carry signal LSLT from level shifter
132. Input points 216 and 220 carry signal LSLC from level shifter 132.
Signal LSRC controls the gates of transistors M11 and M20; signal LSRT
controls the gates of transistors M12 and M21. Transistors M13 and M24 are
controlled by signal LSLT; transistors M14 and M19 are controlled by
signal LSLC.
In accordance with a preferred embodiment of the present invention, current
mirrors 200 and 202 are current mirrors with additional transistors added
in parallel to control the output of the current mirrors. Transistors M12
and M13 are connected in parallel; transistors M11 and M14 are in
parallel; transistors M21 and M24 are connected in parallel; and
transistors M20 and M19 are connected in parallel. These transistors
control the current flow in the current mirrors.
If level shifter 134 is not selected and level shifter 132 has been
selected, the signals at input points 210 and 212 are low. A low signal is
a signal that turns the transistor off. As a result, transistors M11, M12,
M20, and M21 are turned off. The signals at input points 214, 216, 218 and
220 correspond to the output from level shifter 132, resulting in various
levels of current flowing through transistors M13, M14, M24, and depending
on the voltage at the gates of transistors by signals supplied by lines
LSLT and LSLC. The output signals, OUTT and OUTC, from these two current
mirrors control the gates of transistors M27 and M28 in p-channel
cross-coupled amplifier 204 resulting in output signals DATAT and DATAC at
output points 222 and 224 respectively. Signal DATAC is the complement of
signal DATAT.
Current mirror stage 136 in FIG. 4 may be replaced by a number of different
stages in accordance with a preferred embodiment of the present invention.
For example, a multiplexing sense amplifier circuit such as a p-channel
cross-coupled amplifier 298, depicted in FIG. 7, may be utilized in place
of the two current mirrors 200 and 202 forming the multiplexing sense
amplifier circuit illustrated in FIG. 6. P-channel cross-coupled amplifier
298 is constructed from transistors T1-T11. Transistors T1, T2, T8, T10,
and T11 are p-channel MOSFETs. The remaining transistors are n-channel
MOSFETs. P-channel cross-coupled amplifier 298 is powered by connecting
transistors T1, T2, T10, and T11 to power supply VCC and connecting the
drain of transistor T7 to power supply VSS.
P-channel cross-coupled amplifier 298 is enabled when a select signal is
high at input points 300, 301, 302, and 303. These signals control the
gates of transistors T1, T2, T7, and T8. Input points 304 and 306 are
connected to the gates of transistors T3 and T4 respectively; input points
308 and 310 are connected to the gates of transistors T5 and T6
respectively. Again, a parallel configuration of transistor T3 in parallel
with transistor T4 and transistor T5 in parallel with transistor T6 is
employed in accordance with a preferred embodiment of the present
invention. Signal LSLT enters input point 304; signal LSRT enters input
point 306; signal LSRC enters input point 308; and signal LSLC enters
input point 310. If level shifter 134 is disabled and level shifter 132 is
selected, signals LSRT and LSRC will be low, causing transistors T4 and T5
to be turned off. Signals LSLT and LSLC will correspond to the output from
level shifter 132, allowing various amounts of current to flow through
transistors T3 and T6 in response to different voltages being applied to
the gates of these two transistors in accordance with a preferred
embodiment of the present invention.
Transistors T10 and T11 are the cross-coupled p-channel MOSFETs within the
amplifier. Signal OUTC travels from output point 312 to transistor M28 in
amplifier 204 in FIG. 6. Signal OUTT travels from output point 314 to
transistor M27 in amplifier 204 in FIG. 6. The depicted embodiment in FIG.
6 illustrates employing an amplifier connected to the current mirrors to
produce a logic signal. According to the present invention, some other
logic circuit may be used in place of amplifier 204. Furthermore, the
circuit below current mirrors 200 and 202 may be eliminated, and the
output from current mirrors 200 and 202 may be directly used as the output
of the sense amplifier.
Referring now to FIG. 8, a schematic diagram of a multiplexing differential
amplifier, which may be substituted in place of current mirrors 200 and
202 in FIG. 6, is illustrated in accordance with a preferred embodiment of
the present invention. Differential amplifier 350 is comprised of
transistors T20-T29. Transistors T20-T23 and T26 are p-channel MOSFETs
while the remaining transistors are n-channel MOSFETs. This circuit is
powered by connecting the drains of transistors T20, T21, T22, and T23 to
power supply VCC and connecting the source of transistor T29 to power
supply VSS.
Transistors T20, T23, T26 and T29 enable and disable differential amplifier
350. These transistors are controlled by control signals at input points
352, 354, 356, and 358. A bias signal (or ground) is applied to the
amplifier at input point 360, which controls the gates of transistors T21
and T22. Transistor T28 is controlled by signal LSLT at input point 362.
Transistor T27 is controlled by signal LSRT at input point 364. Transistor
T25 is controlled by signal LSRC at input point 366. Transistor T24 is
controlled by signal LSLC at input point 368. Output point 353 is
connected to the gate of transistor M28 in amplifier 204 and provides a
complement output signal OUTC, while output point 355 is connected to the
gate of transistor M27 in amplifier 204 and provides an output signal,
OUTT.
Referring now to FIG. 9, transistors T40-T50 are utilized to form a
multiplexing level shifter that may be utilized in place of current
mirrors 200 and 202 in FIG. 6. Transistors T40, T46, and T50 are p-channel
MOSFETs, while transistors T41, T42, T43, T44, T47, T48, and T49 are
n-channel MOSFETs in accordance with a preferred embodiment of the present
invention. Transistors T40, T46, T49, and T50 are employed to enable and
disable the circuit. Control signals at input points 400, 402, 404, and
406 control the gates of these transistors. The circuit is powered by
connecting the drains of transistors T40, T41, T44, and T46 to power
supply VCC, while connecting the source of transistor T49 to power supply
VSS.
Transistor T41 is controlled by signal LSLT applied to input point 408.
Transistor T42 is controlled by signal LSRT applied to input point 410;
transistor T43 is controlled by signal LSRC applied to input point 412;
and transistor T44 is controlled by signal LSLC applied to input point
414. Transistors T41 and T42 are in parallel; transistors T43 and T44 are
in parallel. Output point 416 is connected to the gate of transistor M27
in amplifier 204 in FIG. 6. Output point 418 is connected to the gate of
transistor M28 in amplifier 204 is FIG. 6. The output signals at output
points 416 and 418 are determined by the input signals at input points
408, 410, 412, and 414. For example, if level shifter 134 is disabled and
level shifter 132 is selected, transistors T41 and T44 would be turned on,
while transistors T42 and T43 would be turned off. The output at output
point 416 would depend on signal LSLT at input point 408, which controls
transistor T41. The output at output point 418 would depend on signal LSLC
at input point 414, controlling transistor T44.
FIG. 10 is a block diagram of an alternative embodiment of a portion of a
memory system similar to the memory system in FIG. 4, except that level
shifter 132 and level shifter 134 have been replaced by disabling sense
amplifier (DSA) 500 and disabling sense amplifier (DSA) 502. Multiplexing
functions are incorporated into DSAs 500 and 502 in accordance with a
preferred embodiment of the present invention. DSA 500 and DSA 502 may be
alternately enabled and disabled to select signals from data lines LBC and
LBT and data lines RBC and RBT.
Referring now to FIG. 11, a block diagram of a DSA according to the present
invention is illustrated. DSA 501 includes amplifier block 503, which has
a true input (IN) connected to input point 504 and a complement input
(/IN) connected to input point 506. A data line such as LBT in FIG. 10 may
be connected to input point 504 and a data line such as LBC in FIG. 10 may
be connected to input point 506. A true output (OUT) and a complement
output (/OUT) may be connected to current mirror 136 in FIG. 10 via output
points 508 and 510.
Amplifier block 503 also is connected to transistors Q1-Q3, which are
MOSFETs. Transistor Q1 is a p-channel MOSFET, while transistors Q2 and Q3
are n-channel MOSFETs. Transistor Q1 has a source connected to power
supply voltage VCC, while transistors Q2 and Q3 have sources connected to
power supply voltage VSS.
The gates of these transistors are controlled by a select signal applied to
point 512. DSA 501 may be selected or enabled by applying a low signal to
point 512. A low signal turns on transistor Q1 and provides power to
amplifier block 503. Additionally, a low signal at point 512 turns off
transistors Q2 and Q3 and allows signals connected to input points 504 and
506 to be sent through amplifier block 503 to output points 508 and 510.
On the other hand, a high signal applied to point 512, results in power to
amplifier block 503 being turned off and the outputs at output points 508
and 510 being pulled low by transistors Q2 and Q3, which are turned on in
response to the low signal applied to point 512.
Referring now to FIG. 12, a schematic diagram of a preferred embodiment of
DSA 501 is illustrated. Amplifier block 503 from FIG. 11 includes
transistors R1-R9. Transistors R1-R4 are p-channel MOSFETs while
transistors R6-R9 are n-channel MOSFETs. This particular configuration of
DSA 501 includes two current mirrors. One current mirror is formed by
transistors R1 and R2, while a second current mirror is formed by
transistors R3 and R4. Input point 504 is connected to the gates of
transistors R5 and R7, while the input point 506 is connected to the gates
of transistors R6 and R8. The circuit is powered by connecting the sources
of transistors R1-R4 to the drain of transistor Q1, which provides a
connection to power supply voltage VCC. The drain of transistor R9 is
connected to power supply voltage VSS. R9 acts as a current source and may
not be required in some cases.
FIG. 13 is a schematic diagram illustrating another configuration for DSA
501. Amplifier block 503 includes transistors R10-R14. Transistors R10 and
R11 are p-channel MOSFETs, while transistors R12-R14 are n-channel
MOSFETs. Amplifier block 503 incorporates a p-channel cross-coupled
amplifier. Transistors R10-R11 are cross-coupled p-channel MOSFETs within
the amplifier block 503. The circuit is powered by connecting the sources
of transistors R10 and R11 to the drain of transistor Q1, which provides a
connection to power supply voltage VCC. The source of transistor R14 is
connected to power supply voltage VSS. R14 acts as a current source and
may not be required in some cases.
FIG. 14 is a schematic diagram illustrating another preferred embodiment
for DSA 501 in FIG. 11. Amplifier block 503 includes a differential
amplifier comprised of transistors R15-R19. Transistors R15 and R16 are
p-channel MOSFETs, while the remaining transistors are n-channel MOSFETs.
This circuit is powered by connecting the sources of transistors R15 and
R16 to transistor Q1. Transistor Q1 provides a connection to power supply
voltage VCC. The sources of transistors R17 and R18 are connected to
transistor R19, which provides a connection to power supply voltage VSS.
R19 acts as a current source and may not be needed in some cases. A bias
signal (or ground) may be applied to the differential amplifier at point
507, which controls the gates of transistors R15 and R16.
In each amplifier depicted in FIGS. 11-14, disablement of the DSA is
accomplished by sending a high signal through point 512. As a result,
transistors Q2 and Q3 are turned on pulling the outputs at output points
508 and 510 low. These low signals disable later stages such as current
mirror 136 in FIG. 10. As a result, when level shifting is not required,
DSAs may be employed to provide selection of data from various data lines
in a memory system. The DSA's work in conjunction with the multiplexing
sense amplifiers shown in FIGS. 6-9.
Signals may be selected by enabling and disabling a pair of level shifters,
instead of using a separate multiplexer. Transistors controlling the
output in later stages are placed in parallel and controlled by the output
signals from the level shifters. Although, two level shifters are
depicted, other numbers of level shifters may be utilized in different
memory array configurations. Although one depicted embodiment illustrates
the selection of signals by enabling and disabling a pair of level
shifters, other circuits other than level shifters may be manipulated in a
similar function within a sense amplifier to provide selection of signals
such as the DSAs depicted in FIGS. 10-14.
According to the present invention, the level shifters may be replaced with
DSAs in cases where level shifting is not required. The DSAs are employed
to enable and disable later stages by providing true and complement
outputs that are low, rendering the pair of inputs in the multiplexing
sense amplifier nonconductive.
In addition, the depicted embodiment illustrates an implementation
involving pairs of data lines, carrying true and complement signals. Those
of ordinary skill in the art will appreciate that a single data line
implementation, instead of a pair of data lines, may be employed according
to the present invention. A differential amplifier may be used to produce
a true and complement signal from a single data line.
One advantage of the present invention is that it provides a faster and
more sensitive sense amplifier because signal losses resulting from
signals propagating through a transmission gate in a multiplexer stage are
eliminated. Additionally, the present invention provides for smaller and
simpler circuitry for selecting and sensing signals from data lines in
multiple blocks of memory. The present invention is depicted using MOS
technology. Other types of technology and transistors may be utilized in
accordance with a preferred embodiment of the present invention.
While the invention has been particularly shown and described with
reference to a preferred embodiment, it will be understood by those
skilled in the art that various changes in form and detail may be made
therein without departing from the spirit and scope of the invention.
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