Modular jack type connector

A modular jack type connector includes a dielectric housing defining a plug-receiving cavity. A plurality of terminals are mounted on the housing. Each terminal includes a spring beam contact portion extending in cantilever fashion in a single row within the plug-receiving cavity, with the contact portions extending from curved base portions located in the housing, and tail portions projecting from the housing in two rows generally parallel to the single row such that each pair of adjacent terminals includes a tail portion in each row thereof. Intermediate portions extend between the curved base portions and the tail portions, with the intermediate portions of at least one of the pair of adjacent terminals being separated from each other in a direction generally parallel to the rows. Bowed portions join the intermediate portions and the tail portions of the one pair of adjacent terminals, with the bowed portions overlapping each in a plane transverse to the rows. Enlarged sections of the intermediate portions of at least another pair of terminals overlap each other in a plane generally parallel to the rows to define a physical capacitor between the another pair of terminals. The terminals are formed by first and second metallic lead frames of identical construction that are reverse-mounted and superimposed on the dielectric housing.

FIELD OF THE INVENTION 
This invention generally relates to the art of electrical connectors and, 
particularly, to a modular jack type connector having a terminal system to 
reduce crosstalk. 
BACKGROUND OF THE INVENTION 
Generally, a modular jack type connector includes "spring beam contacts" 
which protrude from a portion of the jack housing into a plug-receiving 
cavity of the housing, the contacts or terminals usually being separated 
from each other by molded portions of the housing. The terminals include 
terminal portions, usually in the form of pins for mating with the 
terminals of a complementary electrical device. For instance, the terminal 
pins may form solder tails for insertion into holes in a printed circuit 
board and for solder connection to circuit traces on the board and/or in 
the holes. In some instances, the terminal pins or solder tails are 
arranged in a single row, but in many other instances the terminal pins or 
solder tails are arranged in two rows of an alternatingly staggered array. 
The spring beam contacts protrude into the plug-receiving cavity normally 
in a single row. 
As is well known in this art, such modular jack type connectors are quite 
small or miniaturized and, consequently, the terminals are very closely 
spaced. Consequently, there exists a never-ending problem of noise or 
crosstalk between adjacent terminals, particularly in elongated 
straight/parallel portions of the terminals. Various approaches have been 
made to eliminate or reduce the crosstalk, such as providing ground planes 
on the jacks, and coupling filter components, such as capacitor filters, 
between the terminals and the ground plane. Adding such additional 
components as ground planes to such miniaturized connectors adds 
significantly to the costs of the connectors. 
These problems further are complicated because of the standards in the 
telecommunications industry for high data rate transmission over twisted 
pair cables. In other words, the twisted cables which form the tip and 
ring wires of the transmission system must be coupled within the jack in a 
particular order. 
The present invention is directed to solving these problems by providing a 
unique terminal configuration and/or array for reducing crosstalk between 
the terminals of the jack without adding components such as ground planes 
to the jack construction. 
SUMMARY OF THE INVENTION 
An object, therefore, of the invention is to provide a new and improved 
modular jack type connector of the character described above. 
In the exemplary embodiment of the invention, the connector includes a 
dielectric housing means defining a plug-receiving cavity open at one end 
of the housing. A plurality of terminals are mounted on the housing with 
spring beam contact portions extending in cantilever fashion in a single 
row within the plug-receiving cavity. The contact portions extend from 
curved base portions fixed in the housing. The terminals include tail 
portions projecting from the housing in two rows generally parallel to the 
single row of contact portions, such that each pair of adjacent terminals 
includes a tail portion in each row thereof. 
The invention contemplates that the terminals include intermediate portions 
extending between the curved base portions and the tail portions with the 
intermediate portions of at least one of the pair of adjacent terminals 
being separated from each other in a direction generally parallel to the 
rows. The terminals include bowed portions joining the intermediate 
portions and the tail portions of the at least one pair of adjacent 
terminals, with the bowed portions overlapping each other in a plane 
generally parallel to the rows. Enlarged sections of the intermediate 
portions of at least one other pair of terminals overlap each other in a 
plane generally parallel to the rows to define a physical capacitor 
between the other pair of terminals. 
As disclosed in the preferred embodiment herein, the enlarged sections of 
the intermediate portions of the terminals comprise generally parallel 
overlapping planar sections. An adjacent pair of terminals at each 
opposite end of the row thereof includes the separated intermediate 
portions and the bowed portions. Two pairs of terminals, between the 
adjacent pairs at each opposite end of the row, include the enlarged 
sections to define two physical capacitors. 
The invention also contemplates that first and second metallic lead frames 
be provided, with each lead frame including a plurality of the terminals. 
The lead frames are superimposed over each other on the dielectric housing 
means. The first and second lead frames are identically constructed but 
are reverse-mounted on the dielectric housing means in a left-to-right 
direction transversely of the lead frames. Still further, an insulating 
plate is superimposed between the two superimposed lead frames within the 
dielectric housing means. 
Other objects, features and advantages of the invention will be apparent 
from the following detailed description taken in connection with the 
accompanying drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring to the drawings in greater detail, and first to FIGS. 1 and 2, 
the invention is embodied in a modular jack type connector, generally 
designated 10 in FIG. 1. As seen in FIG. 2, in assembly, the connector 
includes three main components, namely: a dielectric housing means, 
generally designated 12; a shield, generally designated 14; and a terminal 
module, generally designated 16. 
Housing 12 is unitarily molded of dielectric material such as plastic or 
the like in a generally cube-shaped configuration to define a mating face 
18 and a mounting face 20. The housing defines a plug-receiving cavity, 
generally designated 22, extending inwardly from mating face 18 for 
receiving a complementary jack plug as is known in the art. The housing is 
adapted for mounting to a printed circuit board (not shown), and one or 
more integrally molded mounting posts 24 project from mounting face 20 for 
insertion into appropriate mounting holes in the board. 
Shield 14 is stamped and formed of sheet metal material and, like housing 
12, includes a mating face 26 and a mounting face 28. Actually, the 
mounting face is formed by the edges of four side walls 30 of the shield. 
The shield is generally box-shaped and is adapted to be mounted over 
housing 12, such as in the direction of arrow "A" (FIG. 2). One or more 
mounting feet 32 are stamped integrally with one or more of side walls 30 
and project from edges 28 for insertion into appropriate holes in the 
printed circuit board. The feet are soldered to appropriate ground traces 
on the board and/or in the holes. 
Terminal module 16 includes a plurality of terminals, generally designated 
34, which are insert molded into a dielectric terminal block 36. Terminal 
module 16 is assembled into housing 12 in the direction of arrow "B" (FIG. 
2), the module being located in an interior cavity 38 of the housing. 
Referring to FIG. 3 in conjunction with FIGS. 1 and 2, terminals 34 include 
spring beam contact portions C1-C8 which extend in cantilever fashion in a 
single row within plug-receiving cavity 22 of the housing. The spring beam 
contact portions extend from curved base portions 42 located within the 
housing outside the plug-receiving cavity. Tail portions T1-T8 of the 
terminals project from terminal block 36 and mounting face 20 of housing 
12 for insertion into holes in the printed circuit board for solder 
connection to circuit traces on the board and/or in the holes. Tail 
portions T1-T8 are in two rows generally parallel to the single row of 
contact portions C1-C8. Each pair of adjacent terminals 34 includes a tail 
portion in each row thereof. 
FIG. 4 shows somewhat schematically the mating face 26 of connector 10 with 
contact portions C1-C8 visible within plug-receiving cavity 22 and tail 
portions T1-T8 projecting from the bottom of the connector. The top of 
FIG. 4 shows the arrangement of the terminals (i.e. contact portions 
C1-C8) according to current telecommunications industry standards in 
interconnecting twisted pair cables or wires. Specifically, pair "A" is 
centrally positioned. Pair "B" straddles pair "A". Pairs "C" and "D" are 
positioned on opposite sides of pair "B". In other words, according to 
this cabling system, the twisted pairs of cables or wires would correspond 
to the contact portions of terminals 34, as follows: C1/C2, C3/C6, C4/C5 
and C7/C8. 
With the above description of the cabling system and contact pairing in 
relation to FIG. 4, it can be understood that crosstalk within the jack is 
the worst between terminal pair "B", i.e. C3/C6 and every other pair. That 
is because the terminals comprising contact pair C3/C6 is the only pair 
that includes a contact close to all of the other pairs of contacts or 
terminals within the jack. This can be followed by noting that contact 
portion C3 is close to contact portion C2, which develops crosstalk 
between contact pairs C3/C6 and C1/C2. Contact portion C3 also is close to 
contact portion C4, which develops crosstalk between contact pairs C3/C6 
and C4/C5. Similarly, contact portion C6 is close to contact portion C5, 
which develops crosstalk between contact pairs C3/C6 and C4/C5. Contact 
portion C6 also is close to contact portion C7, which develops crosstalk 
between contact pairs C3/C6 and C7/C8. 
The invention is directed to significantly reducing the above-outlined 
crosstalk problems by configuring the terminals to have certain "looped" 
pairs of terminals while other pairs of terminals define physical 
capacitors within the jack, all being afforded by a manufacturing 
technique of reversely superimposing a pair of identical metallic lead 
frames. 
More particularly, FIG. 5 shows a first lead frame, generally designated 
50, and FIG. 6 shows a second lead frame, generally designated 52. The 
lead frames are stamped from sheet metal material and are carried through 
a manufacturing process by carrier strips 54 which include indexing holes 
56 and notches 58 as is known in the art. Lead frames 52 and 54 are 
configured to form terminals 34 of jack 10 according to the invention. In 
order to correlate the portions of the lead frames with the 
above-description of terminal contact portions C1-C8 and terminal tail 
portions T1-T8, the contact portions and the tail portions are 
correspondingly designated in FIGS. 5 and 6. First lead frame 50 and 
second lead frame 52, in essence, define terminals 34. The lead frames are 
identically constructed but are reversely oriented as viewed in comparing 
FIGS. 5 and 6. When the two lead frames are mounted within the jack, the 
lead frames are superimposed in a reverse-mounting orientation in a 
left-to-right direction transversely of the lead frames. Simply put, if 
lead frame 50 as shown in FIG. 5 is superimposed over lead frame 52 as 
shown in FIG. 6, this is the orientation of the portions of the terminals 
within the jack, as is shown in FIG. 7. 
It can be seen in FIG. 7 that contact portions C1-C8 are in seriatim 
numerical order at the top of the subassembly shown in FIG. 7. Similarly, 
tail portions T1-T8 likewise are in numerical order. Therefore, the given 
order of the contact portions at the mating end of the jack is the same as 
the given order of the terminating or tail portions at the terminating end 
of the jack. 
Referring back to FIGS. 5 and 6, it can be seen that contact portion C1 is 
joined to tail portion T1 by an intermediate portion I1, and contact 
portion C2 is joined to tail portion T2 by an intermediate portion I2 
which is similarly configured to intermediate portion I1. When this pair 
of terminals are superimposed as shown in FIG. 7, intermediate portions I1 
and I2 of terminal pair "C" (FIG. 4) are separated from each other in a 
direction generally parallel to the row of terminals. Similarly, contact 
portion C7 is joined to tail portion T7 by an intermediate portion I7, and 
contact portion C8 is joined to tail portion T8 by an intermediate portion 
I8. When these two terminals, i.e. terminal pair "D" (FIG. 4) are 
superimposed as shown in FIG. 7, intermediate portions I7 and I8 are 
separated from each other in a direction parallel to the row of terminals. 
Each of the terminals in each of pairs "C" and "D" include bowed portions 
60 which join the respective intermediate portions and the respective tail 
portions of the terminals. The bowed portions of each of the pairs of 
terminals overlap each other in a plane transverse to the row of 
terminals. Bowed portions 62 also join intermediate portions I1, I2, I7 
and I8 with contact portions C1, C2, C7 and C8, respectively, so that the 
terminals overlap both above and below the intermediate portions in order 
to maintain the same sequential numerical order of contact portions C1-C8 
as well as tail portions T1-T8. 
Summarizing the construction and functioning of the terminals in pairs "C" 
and "D" at opposite ends of the terminal array in jack 10, the separated 
and overlapped intermediate portions I1, I2, I7 and I8 of these terminals 
effectively perform the following functions: 
(1) They separate the terminals in each pair as much as possible in the 
areas of the intermediate portions, and they limit the overall parallel 
length between two adjacent terminals of two different pairs, I.E. between 
terminal 7 from pair "D" and terminal 6 from pair "B" and between terminal 
2 from pair "C" and terminal 3 from pair "B". 
(2) Due to the overlapping of bowed portions 60 and 62, these pairs of 
terminals simulate twisted pairs of cables. 
(3) The two cross-overs at the bowed portions maintain the same sequence or 
numerical order of contact portions C1-C8 as well as terminal or tail 
portions T1-T8. 
(4) The terminals in each pair have the same lengths and, consequently, the 
same electrical resistance. 
The terminals in terminal pair "A" and "B" are provided by the terminals 
shown in FIGS. 5 and 6 with contact portions C3-C6. However, the terminals 
in pair "A" include contact portions C4 and C5, whereas the terminals in 
pair "B" include contact portions C3 and C6. The invention contemplates 
reducing the crosstalk between these pairs of terminals, which, as 
described above, present the worst crosstalk problems within the jack, by 
providing physical capacitors between the terminals. Specifically, 
physical capacitors are provided between each terminal of each pair "A" 
and "B" and a terminal of the opposite pair. 
More particularly, referring back to FIGS. 5-7, contact portion C3 is 
joined to tail portion T3 of the respective terminal by an enlarged 
intermediate portion or section I3. Contact portion C4 is connected to 
tail portion T4 by an enlarged intermediate portion or section I4. Contact 
portion C5 is connected to tail portion T5 by an enlarged intermediate 
section or portion I5. Contact portion C6 is connected to tail portion T6 
by an enlarged intermediate section or portion I6. 
When first lead frame 50 shown in FIG. 5 is superimposed over reversed lead 
frame 52 in FIG. 6, as is shown in FIG. 7, enlarged intermediate portion 
I3 is superimposed over enlarged intermediate portion I5 to form a 
physical capacitor therebetween, including a terminal from each pair "A" 
and "B" thereof. Similarly, enlarged intermediate portion I4 is 
superimposed over enlarged intermediate portion I6 to form a physical 
capacitor therebetween and, again, including a terminal from both pairs 
"A" and "B". These physical capacitors significantly reduce the crosstalk 
associated with pair "A" of terminals which include contact portions C4 
and C5, and particularly the worst crosstalk scenario pair "B" which 
includes contact portions C3 and C6. 
FIG. 7 also shows another feature of the invention wherein an insulating 
strip or plate 70 is inserted between the two superimposed lead frames. In 
other words, this insulating plate extends generally parallel to the row 
of terminals and comprises a subassembly therewith. This subassembly then 
is insert molded within terminal block 36 as shown in FIG. 8 which, in 
turn, eventually becomes terminal module 16 shown in FIGS. 3 and 4. After 
insert molding superimposed lead frames 50 and 52, along with insulating 
plate 70, within terminal block 36, contact portions C1-C8 and tail 
portions T1-T8 are formed into their jack-mounted configurations as shown 
in FIGS. 9 and 10, to form the completed terminal module 16 which is 
assembled within housing 12, as described above and further shown in FIG. 
11. 
It will be understood that the invention may be embodied in other specific 
forms without departing from the spirit or central characteristics 
thereof. The present examples and embodiments, therefore, are to be 
considered in all respects as illustrative and not restrictive, and the 
invention is not to be limited to the details given herein.