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Claims  |
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What is claimed is:
1. An integrated circuit comprising:
an internal bus having `N` data lines;
an embedded memory device coupled to the internal bus;
a multiplexer having `N` first data ports each coupled to a respective one
of the N data lines of the internal bus and `M` second data ports, where
`M` is less than `N`;
a controller coupled to the multiplexer and selecting a subset of `M` of
the `N` data lines in the internal bus to be coupled to the `M` second
data ports of the multiplexer; and
`M` I/O ports each coupled to a respective one of the `M` second data ports
of the multiplexer.
2. The integrated circuit of claim 1, further comprising data compression
circuitry including `N` data ports coupled to the `N` data lines of the
internal bus and `M` data ports coupled to the `M` second data ports of
the multiplexer.
3. The integrated circuit of claim 1, further comprising:
data compression circuitry including `N` data ports coupled to the `N` data
lines of the internal bus and `M` data ports coupled to the `M` second
data ports of the multiplexer; and
an embedded logic array including `N` data ports coupled to the `N` data
lines of the internal bus and a second set of ports coupled to dedicated
I/O ports, the embedded logic array having been formed on the integrated
circuit after functional testing of the embedded memory device.
4. The integrated circuit of claim 1 wherein the embedded memory device
comprises a random access memory device.
5. The integrated circuit of claim 1 wherein `N` is equal to a power of two
times `M`.
6. The integrated circuit of claim 1 wherein `M` has a value from one to
sixty four inclusive.
7. The integrated circuit of claim 1 wherein `M` is less than thirty two.
8. The integrated circuit of claim 1, further comprising:
a plurality of dedicated I/O ports; and
an embedded logic array including `N` data ports each coupled to a
respective one of the `N` data lines of the internal bus and including
data and control signal ports coupled to the plurality of dedicated I/O
ports.
9. The integrated circuit of claim 8 wherein the embedded logic array was
formed on the integrated circuit after functional testing of the embedded
memory device.
10. The integrated circuit of claim 8 wherein the embedded logic array was
formed on the integrated circuit after repair of the embedded memory
device.
11. The integrated circuit of claim 8 wherein the embedded logic array was
formed on the integrated circuit after replacement of portions of the
embedded memory device with redundant memory cells by blowing fuses in a
pattern corresponding to a pattern of defective memory cells in the
embedded memory device.
12. The integrated circuit of claim 1 wherein the embedded memory device
comprises a random access memory device including a matrix memory device
and redundant memory cells, defective memory cells of the matrix memory
device having been replaced by memory cells from the redundant memory
cells by blowing a series of fuses.
13. The integrated circuit of claim 12, further comprising an embedded
logic array having `N` data ports coupled to the `N` data lines of the
internal bus and a second set of ports coupled to dedicated I/O ports.
14. The integrated circuit of claim 13 wherein the embedded logic array was
formed on the integrated circuit after functional testing of the embedded
memory device and replacement of the defective matrix memory cells by the
redundant memory cells.
15. An integrated circuit comprising:
an internal bus having `N` data lines;
an embedded memory device coupled to the internal bus;
a multiplexer having `N` first data ports each coupled to a respective one
of the N data lines of the internal bus and `M` second data ports, where
`M` is less than `N`;
a controller coupled to the multiplexer and selecting a subset of `M` of
the `N` data lines in the internal bus to be coupled to the `M` second
data ports of the multiplexer;
`M` I/O ports each coupled to a respective one of the `M` second data ports
of the multiplexer; and
an embedded logic array including `N` data ports coupled to the `N` data
lines of the internal bus and a second set of ports coupled to dedicated
I/O ports, the embedded logic array having been formed on the integrated
circuit after functional testing of the embedded memory device.
16. The integrated circuit of claim 15, further comprising data compression
circuitry including `N` data ports coupled to the `N` data lines of the
internal bus and `M` data ports coupled to the `M` second data ports of
the multiplexer.
17. The integrated circuit of claim 15 wherein the embedded memory device
comprises a random access memory device.
18. The integrated circuit of claim 15 wherein `N` is equal to a power of
two times `M`.
19. The integrated circuit of claim 15 wherein `M` has a value from one to
sixty four inclusive.
20. The integrated circuit of claim 15, further comprising:
a plurality of dedicated I/O ports; and
an embedded logic array including `N` data ports each coupled to a
respective one of the `N` data lines of the internal bus and including
data and control signal ports coupled to the plurality of dedicated I/O
ports.
21. The integrated circuit of claim 20 wherein the embedded logic array was
formed on the integrated circuit after functional testing of the embedded
memory device.
22. The integrated circuit of claim 20 wherein the embedded logic array was
formed on the integrated circuit after repair of the embedded memory
device.
23. The integrated circuit of claim 20 wherein the embedded logic array was
formed on the integrated circuit after replacement of portions of the
embedded memory device with redundant memory cells by blowing fuses in a
pattern corresponding to a pattern of defective memory cells in the
embedded memory device.
24. The integrated circuit of claim 15 wherein the embedded memory device
comprises a random access memory device including a matrix memory device
and redundant memory cells, defective memory cells of the matrix memory
device having been replaced by memory cells from the redundant memory
cells by blowing a series of fuses.
25. The integrated circuit of claim 24, further comprising an embedded
logic array having `N` data ports coupled to the `N` data lines of the
internal bus and a second set of ports coupled to dedicated I/O ports.
26. An integrated circuit comprising:
an embedded memory device having `N` data bus terminals;
a multiplexer having `N` first data ports each coupled to a respective one
of the `N` data bus terminals and `M` second data ports, where `M` is less
than `N`; and
`M` I/O ports each coupled to a respective one of the second data ports.
27. The integrated circuit of claim 26 wherein the data bus terminals are
each coupled to a respective one of `N` columns of memory cells in the
memory device.
28. The integrated circuit of claim 26, further comprising a controller
coupled to the multiplexer and selecting a subset of `M` of the `N` data
bus terminals to be coupled to the "M" second data ports in response to
externally-supplied control signals.
29. The integrated circuit of claim 26 wherein `M` is less than thirty two.
30. The integrated circuit of claim 26, further comprising data compression
circuitry including `N` ports coupled to the `N` data bus terminals and
`M` ports coupled to the second data ports.
31. The integrated circuit of claim 26 wherein the embedded memory device
comprises a random access memory device including a matrix memory device
and redundant memory cells, defective memory cells of the matrix memory
device having been replaced by memory cells from the redundant memory
cells by blowing a series of fuses in the integrated circuit.
32. The integrated circuit of claim 26, further comprising a logic array
including `N` ports coupled to the `N` data bus terminals and including a
plurality of I/O ports coupled to a corresponding plurality of I/O pins.
33. The integrated circuit of claim 32 wherein the logic array was formed
on the integrated circuit after functional testing of the embedded memory
device.
34. The integrated circuit of claim 32 wherein the logic array was formed
on the integrated circuit after functional testing of the embedded memory
device and replacement of defective memory cells with redundant memory
cells.
35. An integrated circuit comprising:
an internal bus having a first data width;
an embedded matrix memory device coupled to the internal bus;
an embedded logic array coupled to the internal bus;
a first set of I/O ports coupled to the embedded logic array;
a multiplexer including a first set of data ports having the first data
width coupled to the internal bus and having a second set of data ports
having a second data width that is less than the first data width; and
a second set of I/O ports having the second data width, the second set of
I/O ports coupled to the second set of multiplexer data ports.
36. The integrated circuit of claim 35 wherein the multiplexer further
comprises a data compression circuit coupled between the second set of
multiplexer data ports and the internal bus.
37. The integrated circuit of claim 35 wherein the first data width is
greater than sixty-four bits.
38. The integrated circuit of claim 35, further comprising redundant memory
cells coupled to the embedded matrix memory device, defective memory cells
of the embedded matrix memory device having been replaced by redundant
memory cells.
39. The integrated circuit of claim 35 wherein the embedded logic array was
formed after functional testing of the embedded matrix memory device.
40. The integrated circuit of claim 35 wherein at least some of the I/O
ports in the first set comprise I/O ports in the second set of I/O ports.
41. A computer comprising:
a data and address bus;
a central processing unit coupled to the data and address bus;
an input device coupled to data and address bus;
a display coupled to the data and address bus;
a memory coupled to the central processing unit, the memory including a ROM
storing instructions providing an operating system for the central
processing unit and including a read-write memory providing temporary
storage of data; and
a function circuit coupled to the data and address bus, the function
circuit comprising:
an embedded memory device having `N` data bus terminals;
a multiplexer including `N` first data ports each coupled to a respective
one of the `N` data bus terminals and including `M` second data ports,
where `M` is less than `N`;
`M` I/O ports each coupled to a respective one of the `M` multiplexer
second data ports; and
an embedded logic array including `N` data ports coupled to the `N` data
bus terminals and also including I/O ports coupled to I/O pins.
42. The computer of claim 41 wherein the embedded logic array was formed on
the integrated circuit after functional testing of the embedded memory
device.
43. The computer of claim 42 wherein in the function circuit at least some
of the I/O ports in the first set comprise I/O ports in the second set of
I/O ports.
44. The computer of claim 41 wherein the function circuit comprises a
graphics and image processor.
45. A method of making an integrated circuit including an embedded memory
device, the method comprising:
forming the embedded memory device, redundant memory cells and a
multiplexer on the integrated circuit, the multiplexer including `N` data
ports coupled to `N` data bus terminals of the embedded memory device and
`M` data ports coupled to `M` I/O ports, where `M` is less than `N`;
testing the embedded memory device by coupling test signals into and out of
the embedded memory device through the multiplexer and `M` I/O ports to
determine if there are any defective memory cells in the embedded memory
device;
replacing defective memory cells in the embedded memory device with
redundant memory cells; and
forming an embedded logic array having `N` data ports coupled to the `N`
data bus terminals of the embedded memory device, the embedded logic array
including I/O ports coupled to pins of the integrated circuit.
46. The method of claim 45 wherein replacing defective memory cells
precedes forming an embedded logic array.
47. The method of claim 45 wherein replacing defective memory cells
comprises replacing defective memory cells with redundant memory cells by
blowing fuses on the integrated circuit in a pattern corresponding to a
pattern of addresses of defective embedded memory device cells.
48. The method of claim 45 wherein testing the embedded memory device
comprises:
coupling temporary interconnections to the `M` I/O ports;
supplying address data to the multiplexer;
supplying background data to the embedded memory device through the
temporary interconnections and the multiplexer;
reading read data from the embedded memory device through the temporary
interconnections and the multiplexer;
reading read data to corresponding expect data; and, when the real data do
not agree with the corresponding expect data:
recording an address for a defective embedded memory device memory cell.
49. The method of claim 48 wherein coupling temporary interconnections to
the `M` I/O ports comprises coupling wafer probe pins to the `M` I/O
ports.
50. The method of claim 45 wherein testing the embedded memory device
comprises:
coupling temporary interconnections to the `M` I/O ports;
coupling a group of `M` of the `N` data bus terminals of the embedded
memory device to the temporary interconnections;
testing the group of `M` data bus terminals of the embedded memory;
coupling a group of `M` data bus terminals adjacent the group of `M` data
bus terminals that were tested to the temporary interconnections; and
testing the group of `M` data bus terminals of the embedded memory adjacent
the group of `M` data bus terminals that were tested.
51. The method of claim 50, further comprising iterating coupling a group
of `M` rows adjacent the group of `M` rows that were tested to the
temporary interconnections and testing the group of `M` rows of the
embedded memory adjacent the group of `M` rows that were tested until all
`N` rows of the embedded memory have been tested.
52. A method of forming an embedded logic array on an integrated circuit
comprising:
coupling a group of temporary interconnections to `M` I/O pads;
coupling control signals to a multiplexer, the control signals causing the
multiplexer to direct which of `N` rows of an embedded memory device are
coupled to the `M` I/O pads, where `M` is less than `N`;
testing memory cells in the embedded memory device with signals coupled to
the embedded memory device through the temporary interconnections and the
multiplexer, and, when a memory cell fails, writing an address
corresponding to the failed memory cell to a memory contained in an
automated tester; and
forming the embedded logic array having `N` data ports coupled to the `N`
rows of the embedded memory device, the embedded logic array including I/O
ports coupled to at least some of the I/O pads of the integrated circuit.
53. The method of claim 52 wherein testing memory cells comprises:
supplying background data to the embedded memory device through the
temporary interconnections;
extracting read data from the embedded memory device in response to the
background data; and
comparing the read data to corresponding expect data; and, when the read
data do not agree with the corresponding expect data, identifying a memory
cell providing the read data that do not agree with the corresponding
expect data as a failed memory cell.
54. The method of claim 52, further comprising replacing failed memory
cells in the embedded memory device with redundant memory cells on the
integrated circuit.
55. The method of claim 54 wherein replacing failed memory cells comprises
blowing fuses on the integrated circuit in a pattern corresponding to a
pattern of failed memory cells in the embedded memory device.
56. The method of claim 52 wherein coupling a group of temporary
interconnections to a group of `M` I/O pads comprises coupling wafer probe
pins to the group of `M` I/O pads.
57. A method of forming an integrated circuit comprising:
coupling a group of temporary interconnections to `M` I/O pads;
coupling control signals to a multiplexer and data compressor on the
integrated circuit, the control signals directing a multiple of `M` of `N`
rows of a memory device to couple to the `M` I/O pads, where `M` is less
than `N`;
supplying background data to the memory device through the temporary
interconnections;
extracting read data from the memory device in response to the background
data;
comparing the read data to corresponding expect data; and, when the read
data do not agree with the corresponding expect data, writing failure data
to a memory contained in an automated tester, the failure data including
address information identifying a group of rows or columns of memory cells
including the memory cell providing the read data that do not agree with
the corresponding expect data; and
forming the embedded logic array including `N` data ports coupled to the
`N` rows of the embedded memory device, the embedded logic array including
I/O ports coupled to pins of the integrated circuit.
58. The method of claim 57, further comprising replacing rows or columns of
memory cells in the embedded memory device that include memory cells
providing read data that do not agree with corresponding expect data with
rows or columns of redundant memory cells.
59. The method of claim 58 wherein forming an embedded logic array occurs
after replacing rows or columns of memory cells in the embedded memory
device. |
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Claims |
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Description |
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TECHNICAL FIELD
The present invention relates generally to testing of integrated circuits,
and more specifically to a method and apparatus that permits accessing of
memory arrays embedded in the integrated circuits independent of any
embedded logic arrays associated with the integrated circuits.
BACKGROUND OF THE INVENTION
FIG. 1 is a simplified block diagram of an integrated circuit 10 according
to the prior art. The integrated circuit 10 includes an embedded memory
device 12, also known as a matrix memory device 12, together with spare or
redundant memory cells 12'. The embedded memory device 12 is coupled
through an internal bus 14 to an embedded logic array 16 that is also
coupled to I/O circuitry 18 dedicated to the embedded logic array 16. As
used herein, the term "embedded," as applied to circuitry contained on the
integrated circuit 10, refers to a circuit having one or more associated
busses that are not normally directly accessible from outside of the
integrated circuit 10.
In operation, the I/O circuitry 18 couples control and data signals from
external circuitry (not illustrated) to the embedded logic array 16. The
embedded logic array 16 operates on the data signals in accordance with
the control signals and generates intermediate or final results. These
results are coupled from the embedded logic array 16 through the internal
bus 14 and are stored in the embedded memory device 12. The embedded logic
aray 16 recalls these results at a later time and uses them to generate
output signals that are then coupled from the integrated circuit 10 to the
external circuitry through the embedded logic array 16 and the I/O
circuitry 18. While the above-described arrangement provides great
advantages in achieving high data transfer rates between the memory device
12 and the logic circuitry 16, it only permits the embedded memory device
12 to be externally accessed through the embedded logic array 16. In other
words, unless the embedded logic array 16 is operational, the embedded
memory device 12 cannot be easily accessed for purposes such as testing.
Further, the embedded memory device 12 may only be tested with those tests
that are pre-programmed into the embedded logic array 16 or through the
I/O circuitry 18 of the embedded logic array 16.
The internal bus 14 includes `N` data lines, where N may be large, e.g.,
the internal bus 14 may be 64, 128, 256 or 512 bits wide or may be even
wider. When the internal bus 14 is wide or very wide, it is impractical to
provide I/O pads dedicated to each bit or data line of the internal bus
14. Furthermore, if the I/O pads 24 are to be connected to externally
accessible terminals, then buffers, electrostatic discharge protection and
other circuitry (not illustrated) must be provided for each data line of
the internal bus 14. Yet this additional circuitry for each data line
would consume unacceptably large portions of the integrated circuit 10 in
order to provide external access to all of the data lines of the internal
bus 14.
In many applications, the embedded memory device 12 is formed prior to
forming the embedded logic array 16 for several different reasons. Many
memory circuits, such as the embedded memory device 12, require smaller
linewidths (i.e., minimum feature sizes) than are necessary for the
embedded logic array 16, in order for the embedded memory device 12 to
provide data storage densities consistent with economical fabrication of
the integrated circuit 10. Also, the processing steps required to
fabricate the embedded memory device 12 may be different than those
required to fabricate the embedded logic array 16. These reasons,
particularly in combination, often favor fabricating the embedded memory
device 12 prior to fabricating the embedded logic array 16.
A typical embedded memory device 12 in an integrated circuit 10 includes at
least one array of memory cells (not illustrated) arranged in rows and
columns. Each memory cell must be tested to ensure that it is operating
properly. In a typical prior art test method, data having a first binary
value (e.g., a "1") are written to and read from all memory cells in the
arrays, and thereafter data having a second binary value (e.g., a "0") are
typically written to and read from the memory cells. The data written to
the memory cells are known as "write" data, and the data read from the
memory cells are known as "read" data. The read data are compared to a
corresponding set of expect data. The expect data correspond to read data
that would be provided by the integrated circuit 10 if its embedded memory
device 12 was operating properly. A memory cell is considered to be
defective when the read data and the corresponding expect data do not
agree. As understood by one skilled in the art, other test data patterns
may be utilized in testing the memory cells, such as an alternating bit
pattern, e.g., 101010, . . . , written to the memory cells in each row of
the memory device 12.
Defective memory cells that are identified by testing are replaced with
non-defective memory cells from rows or columns of spare or redundant
memory cells 12'. In one conventional method for replacing defective
memory cells, fuses on the integrated circuit 10 are blown in a pattern
corresponding to the addresses of defective memory cells. The pattern is
then compared to incoming addresses to select the rows or columns of
redundant memory cells 12' to replace rows or columns in the memory device
12 containing the defective memory cells.
However, it is desirable to be able to test the embedded memory device 12
before the embedded logic array 16 has been formed. When fabrication
yields for the embedded memory device 12 are poor, or when fabrication
yields decrease, it may be undesirable to fabricate the embedded logic
array 16 and combine it with the memory device 12 prior to testing the
memory device 12. Further, discovering fabrication problems early in
forming the integrated circuit 10 allows corrective steps to be taken
early, reducing the number of integrated circuits 10 affected by a
particular fabrication problem. Early detection of fabrication problems
favors increased yields and reduced waste.
Accordingly, there is a need for an on-chip test circuit to permit testing
of embedded memory devices in integrated circuits prior to fabrication of
dedicated logic circuits for the integrated circuits.
SUMMARY OF THE INVENTION
In one aspect of the present invention, an integrated circuit includes an
embedded memory device coupled to an internal bus having a first number of
data lines, a multiplexer and an I/O port having a second number of data
lines that is less than the first number of data lines. The multiplexer
allows the I/O port to be coupled to a portion of the data lines of the
internal bus and thus to at least a portion of the embedded memory device.
As a result, the embedded memory device may be tested or repaired before
an embedded logic function associated with dedicated I/O pins or pads is
added to the integrated circuit. This promotes improved economic
efficiency by allowing a manufacturer to cull integrated circuits that do
not have acceptable fabrication yields prior to fabrication of the
embedded logic array.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a simplified block diagram of an integrated circuit according to
the prior art.
FIG. 2 is a simplified block diagram of an integrated circuit including an
on-chip testing circuit in accordance with an embodiment of the present
invention.
FIG. 3 is a flow chart of a process for forming the integrated circuit of
FIG. 2 in accordance with an embodiment of the present invention.
FIG. 4 is a simplified block diagram of a computer system including the
integrated circuit of FIG. 2 in accordance with an embodiment of the
present invention.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 2 is a simplified block diagram of an integrated circuit 20 including
an on-chip testing circuit 22 in accordance with an embodiment of the
present invention. The integrated circuit 20 includes the embedded memory
device 12 coupled to the on-chip testing circuit 22 and may include the
embedded logic array 16 as described above in association with FIG. 1. In
one embodiment, the embedded memory device 12 includes a memory circuit
such as a dynamic random access memory ("DRAM"). The on-chip testing
circuit 22 includes I/O pins or pads 24 and a multiplexer ("MUX") 26. The
on-chip testing circuit 22 includes a bus 27 that couples a bi-directional
buffer 28 to a first set of data ports of the MUX 26 and to the I/O pins
or pads 24.
In one embodiment, the I/O pads 24 are shared by the testing circuit 22 and
the I/O circuitry 18, i.e., the I/O pads 24 are a subset of the I/O
circuitry 18. As a result, the same I/O pads 24 and/or pins can be used
for testing and for normal operations.
The I/O pins or pads 24, the bus 27, the bi-directional buffer 28 and the
first set of data ports of the MUX 26 each include `M` digital data lines,
which is substantially fewer than the `N` data lines of the internal bus
14. In one embodiment, M may be related to N as in M=N/2.sup.n. For
example, M might be 16 while N might be 512, i.e., n=five, however, M may
be any number greater than or equal to one, but typically will be less
than thirty-two. The on-chip test circuit 22 also includes a test mode
logic circuit 30 having inputs coupled to the I/O circuitry 18 and having
outputs coupled to the MUX 26. The test mode logic circuit 30 provides
control signals to the MUX 26 to select a subset of the N data lines of
the internal data bus 14 to be coupled to the M I/O pins or pads 24. In
one embodiment, a subset of M of N second data ports of the MUX 26 is
coupled to a corresponding subset of M of the N data lines of the internal
bus 14. In another embodiment, a subset of M data ports of the MUX 26 is
coupled to a multiple of M of the N data lines of the internal bus 14
through optional compression circuitry 32.
In some applications, the I/O pins or pads 24 are accessed through probes
by an automated tester 34 prior to completion of packaging of the
integrated circuit 20, allowing testing of the embedded memory device 12
while the integrated circuit 20 is still in wafer form. The embedded
memory device 12 may be repaired, as discussed above, and the repair of
the embedded memory device 12 may precede fabrication of the embedded
logic array 16. In other embodiments, the I/O pins or pads 24 may be
bonded to pins in the completed, packaged integrated circuit 20, providing
external access to the embedded memory device 12 even in the event that
the embedded logic array 16 is not functional. Bonding the I/O pads 24 to
package pins also permits a broader range of tests than those tests that
are pre-programmed into the embedded logic array 16 to be applied to the
embedded memory device 12.
FIG. 3 is a flow chart of a process 40 for forming the integrated circuit
20 of FIG. 2 according to an embodiment of the present invention. The
process 40 begins after the embedded memory device 12 has already been
formed. In a step 42, a test port on a tester, such as the automated
tester 34, is coupled to the I/O pads 24. In one embodiment, a probe card
having a number of probes is used to make temporary connections to the I/O
pads 24. Any other temporary connections (power supply, control signals
for the MUX 26 etc.) required to be able to test the embedded memory
device 12 are also made to the integrated circuit 20. In a step 44, a
group of index variables m are selected that correspond to addresses for a
first group of rows (0:N/2.sup.n -1) that form a portion of the embedded
memory device 12 selected for testing. In a step 46, the MUX 26 is
programmed to couple the selected rows to the I/O pads 24. In a step 48,
background data are supplied to the selected rows of the embedded memory
device 12. In a step 50, read data are extracted from the selected portion
of the embedded memory device 12 through the I/O pads 24. In a query task
52, the automated tester 34 determines if the read data and the
corresponding expect data agree.
When the query task 52 determines that the read data and the corresponding
expect data do not agree, data describing the failed memory cell (e.g.,
the cell address) are written to a memory in the automated tester in a
step 54. When the query task 52 determines that the read data and the
corresponding expect data do agree, control passes to a query task 56.
The query task 56 determines if all of the columns in the embedded memory
device 12 have been tested. When the query task 56 determines that not all
of the columns in the embedded memory device 12 have been tested, control
passes to a step 58. In the step 58, a column counter is incremented and
control then returns to the step 48. When the query task 56 determines
that all of the columns in the embedded memory device 12 have been tested,
control passes to a query task 60.
The query task 60 determines if all of the rows in the embedded memory
device 12 have been tested. When not all of the rows in the embedded
memory device 12 have been tested, control passes to a step 62. In the
step 62, the control signals to the MUX 26 are incremented. In one
embodiment, the control signals to the MUX 26 are incremented to test the
rows adjacent to the rows that have just been tested. Since M=N/2.sup.n,
the index variables m corresponding to the rows being addressed are
incremented by N/2.sup.n in this embodiment. When all of the rows in the
embedded memory device 12 have been tested, control passes to a step 64.
In the step 64, the embedded memory device 12 is repaired. In one
embodiment, the defective memory cells in the embedded memory device 12
are replaced in a conventional manner by blowing fuses or antifuses in a
pattern corresponding to addresses of rows or columns including the
defective memory cells that were identified in the query task 52.
Antifuses are devices that are initially nonconductive but which may be
stressed or "blown" by an appropriate bias to become permanently
conductive.
In a step 66, the embedded logic array 16 and the remainder of the
integrated circuit 20 are formed through conventional fabrication
procedures. The process 40 then ends.
In a different embodiment of the process 40, some data compression is
employed in testing the embedded memory device 12. For example, in the
step 46, not only are M many rows selected by the MUX 26, but an
additional group of rows is also selected by the optional compression
circuitry 32. The additional group of rows might include, e.g., another M
many rows, or it might include, e.g., another 3M many rows. In the step
48, background data are supplied to all of the selected rows via the
optional compression circuitry 32. In the step 50, combinatorial logic in
the optional compression circuitry 32 combines the read data from all of
the selected rows such that the query task 52 is able to determine that
one of the several rows corresponding to one of the M I/O pads 24 includes
a defective memory cell. In one embodiment, the several rows associated
with the I/O pad 24 carrying the data indicative of a memory cell failure
are replaced with a group of rows from the redundant memory cells 12' to
repair the embedded memory device 12. This embodiment provides some speed
advantages in testing of the embedded memory device 12.
It will be appreciated that variations in the process 40 are possible. For
example, the steps relating to rows could be steps relating to columns and
vice versa.
FIG. 4 is a simplified block diagram of a portion of a computer system 80
including the memory integrated circuit 20 of FIG. 2 in accordance with an
embodiment of the present invention. The computer system 80 includes a
central processing unit 82 for performing various computing functions,
such as executing specific software to perform specific calculations or
tasks. The central processing unit 82 is coupled via a bus 84 to a memory
86, a user input interface 88, such as a keyboard or a mouse, function
circuitry 90 and a display 92. The memory 86 may or may not include a
memory management module (not illustrated). The memory 86 does include ROM
for storing instructions providing an operating system and also includes
read-write memory for temporary storage of data. The processor 82 operates
on data from the memory 86 in response to input data from the user input
interface 88 and displays results on the display 92. The processor 82 also
stores data in the read-write portion of the memory 86.
The function circuitry 90 is an example where the integrated circuit 20 of
FIG. 2 may be particularly effective. For example, when the function
circuitry 90 includes an encryption engine, a digital signal processing
chip (e.g., video processor, vocoder, 3-dimensional computer graphics,
image processing or the like) or provides some other dedicated or
programmable complex function, as described, for example, in "An
Access-Sequence Control Scheme to Enhance Random-Access Performance of
Embedded DRAMs," by K. Ayukawa et al., IEEE Journal of Solid State
Circuits 33 (5):800-806, 1998, the integrated circuit 20 will include both
read-write memory functions and logic functions, such as those provided by
the embedded memory device 12 and the embedded logic array 16,
respectively (see FIGS. 1 and 2). In turn, these functions may be realized
least expensively when the embedded memory device 12 can be evaluated
prior to completing fabrication of the embedded logic array 16.
Examples of systems where the computer system 80 finds application include
personal/portable computers, camcorders, televisions, automobile
electronic systems, microwave ovens and other home and industrial
appliances.
It is to be understood that even though various embodiments and advantages
of the present invention have been set forth in the foregoing description,
the above disclosure is illustrative only, and changes may be made in
detail, and yet remain within the broad principles of the invention.
Therefore, the present invention is to be limited only by the appended
claims.
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