Image analysis – Applications – Manufacturing or product inspection
Reexamination Certificate
1999-11-16
2001-05-01
Boudreau, Leo H. (Department: 2621)
Image analysis
Applications
Manufacturing or product inspection
C702S187000
Reexamination Certificate
active
06226394
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates in general to methods for manufacturing integrated circuit (IC) devices. More specifically, the invention relates to non-lot based IC device manufacturing methods in which individual devices can be uniquely identified during their assembly, which enables individual tracking of the devices through assembly and, in turn, enables assembly of the devices in a substantially continuous manner.
2. State of the Art
As shown in
FIG. 1
, a process
10
for manufacturing integrated circuit (IC) devices typically begins with ICs being fabricated on the surfaces of wafers
12
of semiconductor material, such as silicon. Less typically, ICs may also be formed in layers of silicon deposited on layers of sapphire known as Silicon-on-Sapphire (SOS), Silicon-on-Insulator (SOI), or Silicon-on-Glass (SOG).
Once fabricated, ICs are electronically probed to determine whether they are functional (i.e., “good”) or nonfunctional (i.e., “bad”). A computer then stores electronic wafer maps
14
of the wafers
12
identifying the locations of the good and bad ICs on the wafers
12
.
After being probed, ICs are sawed from their wafers
12
into discrete IC dice (also known as “chips”) using high-speed precision dicing equipment. IC dice identified as good by their wafer maps
14
are then each “picked” by automated equipment from their sawed wafers
12
and “placed” on an epoxy coated bonding site of one of a set of lead frames
16
, while IC dice identified as bad are discarded into a scrap bin
18
. The epoxy attaching the good IC dice to their lead frames
16
is allowed to cure, and the attached dice are then wire bonded to their lead frames
16
using high speed bonding equipment. At this point in the process
10
, the lead frames
16
of IC dice are still interconnected.
Once wire bonded, IC dice and their lead frames
16
are formed into IC packages using a hot thermosetting plastic encapsulant injected into a mold. Leads of the lead frames
16
project from the IC packages after encapsulation, and these leads are dipped in a cleansing chemical bath in a process referred to as “de-flash.” After de-flash, IC packages are cured to set their plastic encapsulant, and their projecting leads are then electroplated with a lead/tin finish.
After lead finishing, connections between the lead frames
16
of different IC packages are cut to “singulate” the IC packages into discrete IC devices, and the leads projecting from each IC device are then trimmed and formed into their final form. The IC devices are then tested in a simple electronic test that checks for “opens” (i.e., no connection) in the devices where connections should exist and “shorts” (i.e., a connection) where connections should not exist. Devices that fail the opens/shorts test are discarded into the scrap bin
18
, and devices that pass proceed to extensive back-end test procedures where they are tested for functionality before being shipped to customers.
ICs are typically tracked by lot number through the fabrication, probe, assembly, and back-end test steps described above so the location of particular lots of ICs within the manufacturing process
10
can be determined. Lot numbers are first assigned to ICs when they are fabricated on semiconductor wafers
12
. Typically, a group of 20-50 wafers
12
receives a unique lot number (e.g., 36/1/9970). As the group of wafers
12
proceeds to probe, the wafers
12
are typically split into several sub-lots, with each sub-lot being assigned a new lot number (sometimes referred to as a “sublot” number) that is a modified form of the group's original lot number (e.g., 36/1/9970/0, 36/1/9970/1, . . .). As the group continues through the manufacturing process
10
, sub-lots are split and resplit for a variety of reasons until the group is typically split into many sub-lots, all having a unique lot number that is a modified form of the group's original lot number.
An example of ICs being tracked through a portion of assembly using lot numbers is shown in FIG.
2
. In the example, ICs are first processed on molding equipment to encapsulate them. Once encapsulated, ICs are fed into output carriers
20
, each of which has a unique carrier number (e.g, a bar code). The lot numbers of ICs fed into a particular output carrier
20
are stored in association with the carrier number of the carrier
20
in a data store
22
, such as a computer memory system. The output carriers
20
containing the encapsulated ICs are then placed on shelves, with the carrier number of each output carrier
20
being stored in the data store
22
in association with a unique shelf number of the shelf on which the output carrier
20
is placed (e.g., by scanning in the bar code of each output carrier
20
and a bar code of the shelf on which it is placed). Later, selected ICs are retrieved by lot from the shelves for processing on de-flash equipment by first identifying the output carriers
20
associated in the data store
22
with the lot number of the selected ICs, then identifying the shelves associated in the data store
22
with the carrier numbers of the identified output carriers
20
, and finally retrieving the identified output carriers
20
from the identified shelves for processing.
Unfortunately, the conventional lot-based tracking procedure described above is not as efficient as desired, as is illustrated by FIG.
3
. In a typical assembly step
24
, a sub-lot (e.g, sub-lot H) is received from an input queue
26
where sub-lots wait to proceed through the assembly step
24
. The assembly step
24
may be any step in the IC assembly process of
FIG. 1
, including, for example, wafer saw, die attach, die cure, wire bond, molding, de-flash, lead finish, trim and form, and opens/shorts testing.
As a sub-lot advances through the assembly step
24
, data
28
related to the assembly step
24
is generated. Such data
28
may include, for example: an identification of the processing equipment and the operating personnel for the assembly step
24
; information regarding the set-up of the assembly step
24
; and the time and date the sub-lot advanced through the assembly step
24
.
Once a sub-lot has advanced through the assembly step
24
, a process report
30
is manually or automatically generated based on the generated data
28
. To associate the process report
30
, and hence the data
28
, with the ICs in the sub-lot, and thus track the ICs through the assembly step
24
, the process report
30
lists the lot number (e.g, “H”) of the ICs in the sub-lot. Typically, the process report
30
(often referred to as a “lot traveler”) also physically accompanies the sub-lot through the remainder of the manufacturing process to ensure that the data
28
is correlated with the ICs in the sub-lot.
With the process report
30
generated, a processed sub-lot (e.g, sub-lot H) is cleared from equipment associated with the assembly step
24
to an output queue
32
to prepare the assembly step
24
for processing the next sub-lot (e.g, sub-lot
1
). Once the processed sub-lot is cleared, the next sub-lot can be processed. This “clearing” process is necessary because if two sub-lots (e.g., sub-lots H and I) proceed through the assembly step
24
in a continuous manner, the conventional lot-based tracking procedure described above is unable to correlate the data
28
and the process report
30
generated as each of the two sub-lots proceeds with the correct sub-lot Instead, the data
28
for the two sub-lots is mixed, causing the conventional tracking procedure to fail to uniquely track the two sub-lots through the assembly step
24
.
Thus, the described conventional lot-based tracking procedure is inefficient because it makes inefficient use of often very expensive manufacturing equipment and other resources by leaving sub-lots “parked” in input queues while process reports are generated and the equipment is cleared of already processed sub-lots. In assembly steps which use multiple machines in parallel to process a sub-lot (e.g., wire bond), some mac
Hjorth Ron
Wilson Kevin
Boudreau Leo H.
Britt Trask
Micron Tecnology, Inc.
Werner Brian P.
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