Test contact fixture using flexible circuit tape

A test contact fixture which uses a flexible printed circuit tape to make contact to the integrated circuit and to a rigid printed circuit board which is part of the test equipment. The flexible printed circuit tape is held tightly against a hardened steel support allowing extremely accurate alignment both horizontally and vertically. The mounting plate provides a ground plane so that each lead may easily be configured as a 50 ohm transmission line. Leads of the integrated circuit under test are held in contact with the conductive lines on top of the flexible printed circuit tape by externally applied pressure allowing extremely rapid loading and unloading of the fixture. The body of the integrated circuit is held clear of the contact surfaces allowing heat control fixtures to be used to control the temperature of the integrated circuit during testing.

BACKGROUND OF THE INVENTION 
The present invention relates, in general, to fixtures for testing of 
electrical devices such as integrated circuits, and more particularly to a 
fixture which uses flexible printed circuit tape to make contact with 
integrated circuits mounted in tape automated bonded (TAB) packages. 
Tape automated bonding of integrated circuits has allowed a significant 
increase in the packaging density of high performance integrated circuits. 
This advance in packaging technology has placed severe demands on fixtures 
designed to facilitate testing of the integrated circuits. These fixtures 
must make reliable contact with every lead of the package, but must not 
require a lengthy setup and must not cause wear or damage to the package. 
With as many as 1024 leads per package and a need for minimal lead length 
the lead spacing must be extremely small. In the past, fixtures for 
testing integrated circuits have consisted of special sockets designed for 
the purpose. With the advent of surface mount technology and tape 
automated bonded integrated circuits a variety of these special sockets 
have been devised using compressible pins of some sort. These sockets have 
proven adequate for pins as close as a 0 508 mm pitch, but this pitch 
appears to be close to the practical limit to this approach. It is not 
practical to manufacture sockets of this type with a constant 50 ohm 
impedance, nor is the compressible pin alignment easy to adjust. Finally, 
the insertion and removal of integrated circuit parts requires several 
manual steps making such sockets unsuited to a high volume testing 
application. 
High density packages now require a fixture which can handle leads having a 
0.2032 mm pitch and a 0.1016 mm width. Leads this small and packed this 
closely require precise lateral and vertical alignment of both the 
integrated circuit leads and the test fixture contacts. In addition, high 
speed circuits such as application specific integrated circuits (ASIC) 
built using emitter coupled logic (ECL) can require a signal bandwidth of 
3 Ghz. With signals of this bandwidth a constant impedance throughout the 
entire signal path, including the test contact fixture, is essential for 
proper operation of the integrated circuit being tested. 
SUMMARY OF THE INVENTION 
Briefly stated, the present invention provides a new kind of test contact 
fixture which uses a flexible printed circuit tape to make contact to the 
integrated circuit and to the underlying rigid printed circuit board. The 
flexible printed circuit tape can be produced with an extremely fine pitch 
and line width. The flexible printed circuit tape is held tightly against 
a hardened steel mounting plate allowing extremely accurate alignment 
horizontally and vertically. The rigid mounting plate provides a ground 
plane so that each lead may easily be configured as a 50 ohm transmission 
line. Leads of the integrated circuit under test are held in contact with 
the conductive lines on top of the flexible printed circuit tape by 
externally applied pressure allowing extremely rapid loading and unloading 
of the fixture. The body of the integrated circuit is held clear of the 
contact surfaces allowing heat control fixtures to be used to control the 
temperature of the integrated circuit during testing. While the invention 
directly addresses integrated circuit requirements, the present invention 
is equally useful for testing any electrical device which requires a high 
density of signal connections.

DETAILED DESCRIPTION OF THE DRAWINGS 
FIG. 1 depicts a high density test fixture typical of the prior art. A test 
fixture typical of the prior art is detailed in J. Lyman, "Tiny module 
compresses interconnection grid", Electronic Design, July 28, 1988, 
Copyright 1988, VNU Business Publications, Inc. This article depicts an 
"INTERPOSER test socket" which is manufactured and sold commercially by 
AMP Incorporated (INTERPOSER and AMP are trademarks of AMP Incorporated). 
A support plate 19 is used to mount the components of the test fixture and 
to provide rigidity to the structure. Support plate 19 is electrically 
separated from a tester board 17 by an insulator 18. Tester board 17 is a 
printed circuit board which serves to electrically and mechanically 
connect the test contact fixture to a computer controlled automatic tester 
(not shown). An electrical device such as an integrated circuit 20 is 
mounted in a TAB leadframe 13. TAB leadframe 13 in turn is mounted in a 
protective carrier 12 which is used to protect integrated circuit 20 and 
TAB leadframe 13 from damage during manufacture, test, and shipment. 
Protective carrier 12 is held in place on the test fixture by a spring 
loaded top plate 11. An INTERPOSER socket 16 is placed between TAB 
leadframe 13 and tester board 17. Lateral alignment of protective carrier 
12 and TAB leadframe 13 with INTERPOSER socket 16 is provided by a set of 
two locator pins 15. A plurality of INTERPOSER pins 14 protrude from the 
top and bottom of INTERPOSER socket 16 in such a way as to make electrical 
contact with the areas provided for this purpose on TAB leadframe 13 and 
tester board 17. 
The "INTERPOSER test socket" can make contact to a TAB package having a 
lead pitch as small as 0.508 mm with a minimum width of 0.254 mm. Even so, 
higher density TAB packages now in use require a lead pitch of 0.2032 mm 
and lead width of 0.1016 mm, which is considerably smaller than the 
smallest such socket available. This socket system cannot easily be made 
to have a constant impedance signal transmission characteristic, so the 
maximum signal rate is below that required for high speed circuits. 
Clearly there is a need for a high density test contact fixture which can 
meet all of these requirements. 
FIG. 2 depicts a flexible printed circuit tape 22 which is used in 
conjunction with the present invention. Electrical contact is made using 
flexible printed circuit tape 22 rather than INTERPOSER pins 14 (FIG. 1). 
A plurality of electrically conductive patterns 54 are fabricated on 
flexible printed circuit tape 22 using high precision photographic 
techniques well known in the art. Flexible printed circuit tape 22 may 
easily be fabricated having a different number of electrically conductive 
patterns 54 to accommodate different lead counts for different 
applications without requiring modification of other components. The 
techniques used to fabricate flexible printed circuit tape 22 are similar 
to those used for TAB leadframe 13 (FIG. 1) which results in in similar 
minimum size constraints. Electrically conductive patterns 54 may be 
fabricated so as to allow tne contact fixture to be used with TAB 
leadframes 13 (FIG. 1) having a lead pitch and width far smaller than that 
possible using prior art. Two solid conductive areas 53 are fabricated at 
each end of flexible printed circuit tape 22 to provide a good electrical 
ground contact with a rigid mounting plate 21 (FIG. 3). A plurality of 
precision edges 55 serve to provide a highly accurate means to align 
flexible printed circuit tape 22 in a lateral direction while still 
allowing longitudinal movement. A contact area 56 comprises the small 
portion of flexible printed circuit tape 22 which actually touches the 
leads of TAB leadframe 13 (FIG. 1), and so is subject to wear and damage 
during use of the contact fixture. The preferred embodiment provides for 
this wear and damage by allowing flexible printed circuit tape 22 to be 
moved longitudinally a small amount thus providing fresh material for 
contact area 56 and extending the useful life of printed circuit tape 22. 
An alternate embodiment of flexible printed circuit tape 22 provides a 
plurality of precision alignment holes 57 which accurately position 
flexible printed circuit tape 22 in the vicinity of contact area 56 on the 
supporting structure by means of matching alignment pins. In another 
embodiment, alignment holes 57 are elongated into slots to allow flexible 
printed circuit tape 22 to be adjusted a small amount longitudinally to 
compensate for surface damage and wear at contact area 56. A small pitch 
between electrically conductive patterns 54 in the vicinity of contact 
area 56 results in a narrow overall width of flexible printed circuit tape 
22. In the area of flexible printed circuit tape 22 where electrical 
contact is made to a tester board 29 (FIG. 3), the pitch between 
electrically conductive patterns 54 is much greater, resulting in a 
relatively wide portion of flexible printed circuit tape 22. Flexible 
printed circuit tape 22 widens along its length to smoothly connect these 
two areas. 
FIG. 3 depicts a test contact fixture using flexible printed circuit tape 
22 as a preferred embodiment of the present invention. This test contact 
fixture uses flexible printed circuit tape 22 mounted on rigid mounting 
plate 21 fabricated from a hardened steel material. Rigid mounting plate 
21 has a plurality of channels 24 cut partway into its surface which serve 
as mounting places for flexible printed circuit tape 22. A pressure clamp 
28 fastens one end of flexible printed circuit tape 22, and a second 
pressure clamp 35 fastens the opposite end. Pressure clamps 28 and 35 
serve the dual purpose of mechanically attaching flexible printed circuit 
tape 22 firmly in place on rigid mounting plate 21 and of providing a low 
impedance electrical ground connection for those electrically conductive 
patterns 54 (FIG. 2) which must be electrically grounded. The ground 
connection is achieved by clamping solid conductive areas 53 (FIG. 2) onto 
rigid mounting plate 21 by pressure clamps 28 and 35. Channels 24 have a 
plurality of precision tape guide surfaces 23 along the sides, matching 
precision edges 55 (FIG. 2), which are positioned to ensure exact 
alignment of flexible printed circuit tape 22 in a lateral direction 
without requiring further adjustment. A plurality of lateral slots 26 are 
cut through rigid mounting plate 21 at the place where flexible printed 
circuit tape 22 makes electrical contact with conductive traces on tester 
board 29. Lateral slots 26 are used to allow a pressure clamp 31 to hold 
flexible printed circuit tape 22 in firm contact with tester board 29 thus 
ensuring good electrical contact between them. Pressure clamp 31 has a 
flexible pad 32 along its bottom edge so as to apply an even pressure to 
flexible printed circuit tape 22. In one preferred embodiment, flexible 
pad 32 is fabricated from a straightened section of rubber "O" ring. 
Flexible printed circuit tape 22 is clamped to the top surface of rigid 
mounting plate 21 within notch 24 by pressure clamp 28. Flexible printed 
circuit tape 22 is then routed through a slot 25 in rigid mounting plate 
21 to make electrical contact with tester board 29 positioned underneath 
rigid mounting plate 21. Flexible printed circuit tape 22 then passes 
around a tape former 27, passing over a contact surface 33 (FIG. 4) to the 
top side of rigid mounting plate 21 where the flexible tape is clamped 
into place by pressure clamp 35. 
TAB leadframe 13 and protective carrier 12 holding integrated circuit 20 
are held in contact with tape former 27 by spring loaded top plate 11. It 
is highly desirable to minimize the radius of flexible printed circuit 
tape 22 in the vicinity of the point at which contact is made to the leads 
of TAB leadframe 13, however a small bending radius will damage flexible 
printed circuit tape 22 by causing cracks or separation of electrically 
conductive patterns 54 from the underlying tape. If the useful life of 
flexible printed circuit tape 22 is to be maximized the shape of tape 
former 27 is highly critical. Tape former 27 is used to support and form 
flexible printed circuit tape 22 into a predetermined shape in the area 
where physical and electrical contact is made between TAB leadframe 13 and 
flexible printed circuit tape 22. The shape of tape former 27 is described 
in detail in FIG. 4 below. 
FIG. 3 depicts four channels 24. In a preferred embodiment, each channel 24 
has a flexible printed circuit tape 22. Each flexible printed circuit tape 
22 is threaded through rigid mounting plate 21, clamped in place and 
shaped by tape former 27 as discussed above. A typical TAB leadframe 13 
has leads extending from all four sides, and therefore a flexible printed 
circuit tape 22 is used to make contact with each of the four sides. TAB 
leadframes 13 having leads on other than four sides can easily be made and 
alternate embodiments having other than four channels 24 are made to 
match. 
FIG. 4 depicts a magnified cross section of tape former 27, which is part 
of rigid mounting plate 21 depicted in FIG. 3. Tape former 27 has an inner 
surface 52 which is oriented facing the center of rigid mounting plate 21. 
Tape former 27 supports, tensions, and shapes the surface of flexible 
printed circuit tape 22 in the area of contact surface 33 into a specific 
compound shape comprising a combination of flat and curved surfaces. The 
shape of contact surface 33 is the point at which contact is made between 
the leads of TAB leadframe 13 and flexible printed circuit tape 22, and is 
at the highest point of tape former 27. In the preferred embodiment, tape 
former 27 is fabricated having an overall height 30 of 17.78 mm, as 
measured from the lowest surface of rigid mounting plate 21, and a width 
34 of 2.54 mm. In the vicinity of the shaped top of tape former 27, one 
embodiment of this invention includes a locator pin 37 for the purpose of 
aligning and tensioning flexible printed circuit tape 22 by means of 
matching alignment holes 57 in flexible printed circuit tape 22. The top 
of tape former 27 is shaped with an arc shaped surface 38 having a radius 
of 15.875 mm. Arc shaped surface 38 smoothly meets a flat surface 39 
having a width 42 of 0.43942 mm and forming an angle 41 of 30 degrees with 
contact surface 33. Flat surface 39 meets with an arc shaped surface 43 
which passes through an angle 46 of 60 degrees, with a radius of 0.762 mm 
and having a center of rotation 44 which is 1.016 mm from inner surface 
52. Arc shaped surface 43 meets a flat surface 47 which forms an angle 49 
of 30 degrees with contact surface 33 and having a width 48 of 0.07366 mm. 
Flat surface 47 smoothly meets an arc shaped surface 51 having a radius of 
1.143 mm. Arc shaped surface 51 continues the surface to smoothly meet 
inner flat surface 52. 
Rigid mounting plate 21 provides an extremely firm support and can be 
fabricated to extremely precise dimensions allowing very precise alignment 
to be maintained between TAB leadframe 13 and flexible printed circuit 
tape 22 without requiring laborious adjustments by highly skilled 
personnel. In addition, the firm support provided by rigid mounting plate 
21 helps to support tester board 29, preventing flexure and maintaining a 
highly planar configuration of this critical component. The path of 
flexible printed circuit tape 22 through rigid mounting plate 21 allows a 
high level of tension in flexible printed circuit tape 22 which, combined 
with the shape of tape former 27, further enhance the precision alignment 
between traces of flexible printed circuit tape 22 and leads of TAB 
leadframe 13. The method of clamping flexible printed circuit tape 22 at 
either end also provides a short signal path to an electrical ground 
provided by rigid mounting plate 21. A short signal path to an electrical 
ground is highly desirable since this minimizes undesired inductance for 
leads which are tied to ground and leads which require capacitive 
decoupling. This has the effect of lowering the impedance of the actual 
ground path and minimizing both electrical noise and crosstalk between 
signals in the test contact fixture. 
Flexible printed circuit tape 22 (FIG. 3) is held tightly against rigid 
mounting plate 21 (FIG. 3) for the entire signal path, so well known 
stripline transmission line techniques are used when designing flexible 
printed circuit tape 22 to provide a constant 50 ohm impedance for each 
signal. The precision fabrication and rigid alignment of the fixture 
allows flexible printed circuit tape 22 to be optionally replaced or moved 
lengthwise when required to compensate for wear and damage at contact area 
56 (FIG. 2) without requiring skilled or lengthy adjustment. The body of 
integrated circuit 20 (FIG. 3) is held clear of the test contact fixture 
allowing heat control devices (not shown) to be used to control the 
temperature of integrated circuit 20 (FIG. 3) during testing. 
By now it should be apparent that use of a flexible printed circuit tape as 
a test contact fixture has many advantages over previous approaches, 
including an extremely high density of contacts combined with a constant 
impedance design. The fixture described in addition facilitates setup and 
alignment of the fixture as well as adjustment of flexible printed circuit 
tape 22 to compensate for wear. The test contact fixture of this invention 
is also suited to use of alignment pins to position TAB leadframe 13 in 
place on the fixture with a quick release type of clamp to facilitate 
rapid changing of integrated circuit parts for testing.