Static information storage and retrieval – Systems using particular element – Magnetic thin film
Reexamination Certificate
2001-07-24
2003-02-04
Nelms, David (Department: 2824)
Static information storage and retrieval
Systems using particular element
Magnetic thin film
C365S173000
Reexamination Certificate
active
06515896
ABSTRACT:
TECHNICAL FIELD
The technical field is resistive cross point memory devices. More specifically, the technical field is memory devices having short read times.
BACKGROUND
Magnetic Random Access Memory (“MRAM”) is a proposed type of non-volatile memory. Accessing data from MRAM devices is much faster than accessing data from conventional long term storage devices such as hard drives. Additionally, MRAM is compact and consumes less power than conventional long term storage devices.
FIG. 1
illustrates a conventional MRAM memory array
10
having resistive memory cells
12
located at cross points of word lines
14
and bit lines
16
. The word lines
14
extend horizontally along rows of the memory array
10
, and the bit lines
16
extend vertically along columns of the memory array
10
. Each memory cell
12
is capable of storing the binary states of “1” and “0.”
FIG. 2
illustrates a conventional memory cell
12
. The memory cell
12
is a spin dependent tunneling (“SDT”) device. The memory cell
12
includes a pinned layer
24
and a free layer
18
. The pinned layer
24
has a magnetization that has a fixed orientation, illustrated by the arrow
26
. The magnetization of the free layer
18
, illustrated by the bidirectional arrow
28
, can be oriented in either of two directions along an “easy axis” of the free layer
18
. If the magnetizations of the free layer
18
and the pinned layer
24
are in the same direction, the orientation of the memory cell
12
is “parallel.” If the magnetizations are in opposite directions, the orientation is “anti-parallel.” The two orientations correspond to the binary states of “1” and “0,” respectively.
The free layer
18
and the pinned layer
24
are separated by an insulating tunnel barrier layer
20
. The insulating tunnel barrier layer
20
allows quantum mechanical tunneling to occur between the free layer
18
and the pinned layer
24
. The tunneling is electron spin dependent, making the resistance of the memory cell
12
a function of the relative orientations of the magnetizations of the free layer
18
and the pinned layer
24
. The resistance of the memory cell
12
has a “low” value of R if the orientation is parallel, and a “high” value of R+&Dgr;R if the orientation is anti-parallel.
Each memory cell
12
in the memory array
10
can have its binary state changed by a write operation. Write currents supplied to the word line
14
and the bit line
16
crossing at a specific memory cell
12
switch the magnetization of the free layer
18
between parallel and anti-parallel with the pinned layer
24
. A current Iy passing through the bit line
16
results in the magnetic field Hx. A similar magnetic field Hy is created when a current Ix passes through the word line
14
. The magnetic fields Hx and Hy combine to switch the magnetic orientation of the memory cell
12
. The change in resistance due to the changing memory cell magnetization is readable to determine the binary state of the memory cell
12
.
Each of the bit lines
16
in the memory array
10
is connected to a switch (not shown), and each switch is connected to an input of a sense amplifier (not shown). The binary state, or “bit,” of a selected memory cell
12
is read by applying a read voltage to the word line
14
of a particular memory cell
12
while the bit line
16
crossing the memory cell
12
is connected to the input of the sense amplifier. The switch connecting the selected bit line
16
to the sense amplifier is alternately opened and closed to read the selected memory cell
12
.
The read operation in the conventional memory array
10
is slowed by the requirement for the memory array
10
to “settle” between reading memory cells
12
. The memory array
10
must settle because each time a switch connecting a selected bit line
16
to the sense amplifier is opened or closed, the potential at the end of the bit line
16
changes. The change in potential at the end of the bit line causes the voltage across the memory cells
12
to change to a different equilibrium state. The microprocessor controlling the read operation must therefore incorporate a settling time into the read operation to allow the memory array
10
to settle to the desired equilibrium state between reading of memory cells
12
. A settling time is undesirable because fewer memory cells
12
can be read per unit time.
A need therefore exists to decrease the read time in memory arrays.
SUMMARY
According to a first aspect, a memory device achieves a reduced read time. The memory device includes a memory array of memory cells, and intersecting word lines and bit lines. A bank of sense amplifier select switches selectively couples the bit lines to a sense amplifier. Each switch in the bank of sense amplifier select switches may be closed to allow the sense amplifier to sense the binary state of a selected memory cell. A bank of read/write select switches selectively couples the bit lines to a column write current source, and to a reference potential voltage. The switches in the bank of read/write select switches may each be closed to couple a selected bit line to the reference potential voltage. During read operations, the bank of sense amplifier select switches and the bank of read/write select switches are operated so that the bit lines in the memory array remain in an equipotential state.
According to the first aspect, the array is not disturbed by the connection and disconnection of bit lines with the sense amplifier. The sense amplifier, which is set at the reference potential voltage, provides the same potential to the bit lines as the bank of read/write switches. Because the bit lines in the memory array are not disturbed from the equipotential state, a settling time due to switching to the amplifier is not required. Read times are therefore shorter than in conventional devices.
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Hewlett--Packard Company
Nelms David
Nguyen Thinh T.
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