[0001] This invention relates to electrical connectors and in particular to the reduction
of cross-talk between wires in telecommunications connectors. The term telecommunications
connector used throughout includes connectors for both voice and data applications.
[0002] High speed data transmission is prone to interference problems which must be controlled.
One of the most important forms of interference is cross-talk which may be defined
as the voltage generated in one wire due to interference from a signal passing in
an adjacent wire. The induced signal will have some inductive and capacitive components
and will, therefore, vary with frequency. Cross-talk is a particular problem at higher
frequencies and an especially difficult problem to control in data transmission lines
as the induced cross-talk signal is a true data signal and is recognised, accepted
and processed as such by the associated data processing equipment.
[0003] The Standard Connector used in Data Communications Interfaces is the RJ 45 connector.
The specification for this connector is defined in International Standard IEC 603-7
of the International Electrotechnical Commission. The RJ 45 connector, available from
AT & T corporation of Warren, New Jersey, USA, is a miniature connector having eight
parallel contacts formed from spring wire.
[0004] It is well known that cross-talk may be reduced in communications cabling systems
by twisting pairs of conductors used for a single circuit. As the current flows 'out'
through one conductor and 'back' through the other, the nett interference effect of
these two current flows is destructive as they are mutually cancelling; the electromagnetic
and electrostatic fields induced by the outward flow will exactly cancel those induced
by the return flow.
[0005] The nature of the RJ 45 interface and the standardised connection practice involved
results in a significant portion of the signal transmission path between adjacent
conductor circuits being parallel, untwisted and transposed between pairs, resulting
in a considerable degradation in the cross-talk performance of the connector. This
problem may be appreciated from consideration of Figure 1 which shows the 258A or
EIA T560D sequence standard connection arrangement.
[0006] The cross-talk between pairs 1 and 3 will be higher than that between other pairs
as the contact wires for pair 1 are arranged between the contact wires for pair 3.
[0007] The invention aims to reduce the effect of cross-talk between communications contacts.
[0008] The invention in its various aspects resides in various arrangements which reduce
the problem of cross-talk in the situations discussed.
[0009] More specifically the invention is defined by claim 1 to which reference should be
made.
[0010] Embodiments of the invention will now be described, by way of example, and with reference
to the accompanying drawings, in which:
Figure 1, referred to previously, shows the arrangement of contacts in an RJ 45 connector
according to the EIA T560D sequence;
Figure 2, illustrates the conventional twisted pair configuration for the contact
arrangement of Figure 1;
Figure 3, illustrates a twisted pair arrangement according to a first embodiment of
the invention.
Figure 4, illustrates a twist arrangement according to a second embodiment of the
invention;
Figure 5, illustrates a twist arrangement according to a third embodiment of the invention;
and
Figure 6, illustrates a portion of a modular jack and wire assembly showing how the
invention is incorporated in a modular jack.
[0011] Referring again to Figure 1, cross-talk arises between pairs 1 and 3 as a long section
of wire for each conductor of each pair is laid in the connector in close proximity.
A typical length is about 25 mm. Wire 3 induces cross-talk in wire 4 and the opposite
sense of flow in wire 6 induces cross-talk in wire 5 in the opposite sense to that
induced in wire 4.
[0012] As the current flows in wires 4 and 5 which make up pair 1 are of opposite sense,
the two induced voltages mutually reinforce each other doubling the cross-talk.
[0013] The various embodiments of the invention reduce the cross-talk between pairs 1 and
3 dramatically by deliberately inducing cross-talk but of opposite sense such that
the effects cancel out and cross-talk is eliminated or reduced. Thus, in Figure 1
wire No. 3 of pair 3 is arranged to interfere with wire 5 of pair 1 and wire 6 to
interfere with wire 4.
[0014] Solutions to the problem of cross-talk must take into account the effects of parallel
conductor paths in both the plug and the receptacle.
[0015] Figure 2 shows the normal twist of the wire pairs illustrated in Figure 1 according
to the prior art. Thus, the wires of each pair are twisted one with the other. The
first embodiment of the invention, shown in Figure 3 departs from this by twisting
wire 3 from pair 3 with wire 5 from pair 1, and wire 6 from pair 3 with wire 4 from
pair 1. This arrangement is adopted for a short length which can be determined experimentally
or mathematically to cancel the cross-talk in the receptacle.
[0016] Instead of twisting the wires in the manner outlined above, they may be simply crossed
over and laid parallel in a similar manner to the way in which they are situated in
the receptacle.
[0017] As an alternative to the twist arrangement shown, the wires may be connected to the
rear insulation displacement connector at a fixed wiring interface such that they
are transposed relative to their position in the receptacle. Thus, in Figure 1, wire
3 is transposed to be adjacent wire 5 and wire 4 is adjacent to wire 6.
[0018] Figure 4 shows a second embodiment of the invention, again, the eight parallel wires
are numbered 1 through 8 and their standard wiring pairs are indicated above. Thus,
wires 4 and 5 form pair 1 line 4 being the 'out' line and wire 5 the 'return'. Wires
1 and 2 form pair 2, wires 3 and 6 pair 3 and wires 7 and 8 pair 4. This configuration
is adopted by convention although the fourth pair is sometimes omitted if not needed.
[0019] As discussed earlier cross-talk is greatest between the wires of the first and third
pairs. The solution to this problem is illustrated in the figure as a series of twists
between pairs of wires in clockwise and counter-clockwise directions. Table 1 below
shows the wires in each pair, the chamber of twists per unit length and their sense.
TABLE 1
JACK WIRES (RJ45) |
TWISTS PER UNIT LENGTH |
SENSE |
1 + 3 |
4 |
CW (=clockwise) |
6 + 8 |
2 |
CCW (= counter clockwise) |
4 + 7 |
3 |
CW |
2 + 5 |
2 |
CCW |
4 + 6 |
2 |
CW |
4 + 5 |
3 |
CCW |
1 + 2 |
2 |
CCW |
3 + 6 |
2 |
CW |
7 + 8 |
2 |
CW |
[0020] It will be appreciated from table 1 and figure 4 that each wire is twisted with at
least two other wires, and three in the case of 4. The net effect is to present the
wires for termination at the IDC in the correct pairs with wires of each pair being
adjacent. It will be appreciated that the position of the wires of pair 1 at the IDC
have been reversed, thus wire 5 is on the left of wire 4.
[0021] In figure 4, wires 1 and 3 are twisted four times per unit length (P.U.L.) in a clockwise
direction. Wires 6 and 8 are twisted twice (P.U.L.) in a counter-clockwise direction,
wires 4 and 7 three times P.U.L. clockwise and wires 2 and 5 twice P.U.L. counter-clockwise.
The relative positions of the wires is shown at A in the figure.
[0022] Wire 4 is then twisted twice P.U.L. with wire 6 in a clockwise direction and then
three times with wire 5 counter-clockwise. Wires 1 and 2 are twisted twice counter-clockwise,
wires 3 and 6 twice clockwise and wires 7 and 8 also twice clockwise. The result is
the wire configuration at the IDC and is shown at B in the figure.
[0023] Figure 5 shows an alternative twist configuration which is set out in table 2 below.
Although not shown in the drawings, the wires of each pair, after twisting according
to table 2 below are twisted together continuously to the edge of the connector. Thus,
wire 1 is first twisted two twists clockwise with wire 3 whilst wire 2 is twisted
with wire 5 two twists counter clockwise. Wires 1 and 2 are then braided in their
normal configuration. It should be noted that in the table 2 configuration the first
recited wire is twisted over the second wire. Thus, wire 1 is twisted over wire 3.
TABLE 2
JACK WIRES |
NO. OF TWISTS |
SENSE |
1 + 3 |
2 |
CW |
5 + 2 |
2 |
CCW |
4 + 7 |
2 |
CW |
6 + 8 |
2 |
CCW |
4 + 6 |
2 |
CW |
[0024] It will be noted that the number of twists in figure 5 is the same for each twist
pair in contrast to the embodiment of figure 4. The twist rate is the figure 5 embodiments
should be approximately 4-5 twists per inch and the twist length 9 to 12 mm measured
from the jack to the V of the wires in each of the first, or previous twist pairs.
This is best appreciated from figure 6 which shows a WE8W carrier 10 which carries
eight contact wires A - H. The insulated wires 1 - 8 are each attached to a respective
contact wire A - H and the twists occur in the region proximate the end 12 of the
carrier 10 into which the insulated wires are inserted. Although not shown the carrier
and wires are mounted in a body to form a modular jack or connector.
[0025] The net effect of the clockwise and counter-clockwise twisting is to reduce cross-talk
greatly. It will be appreciated that as well as twisting each wire with its pair member,
each wire is twisted with at least one wire from a different pair. Other configurations
which achieve the result may be determined by those skilled in the art.
1. A telecommunications connector comprising a wire carrier having a plurality of contact
wires and a plurality of insulated wires each connected to a respective contact wire
and forming at least three conductor pairs, wherein an insulated wire of a conductor
pair is twisted or crossed with an insulated wire of another conductor pair to form
a twisted or crossed wire pair.
2. A telecommunications connector according to claim 1, wherein an insulated wire of
each conductor pair is twisted with an insulated wire of another conductor pair to
form a least three twisted wire pairs.
3. A telecommunications connector according to claim 2, wherein each twisted pair comprises
two wire twists.
4. A telecommunications connector according to claim 2 or 3, wherein the twisted pairs
are twisted alternatively in a clockwise and counter clockwise direction.
5. A telecommunications connector according to claim 2, 3 or 4, wherein an insulated
wire of at least one twisted pair is further twisted with an insulated wire of another
twisted pair.
6. A telecommunications connector according to any of claims 1 to 5, comprising eight
insulated wires divided into four conductor pairs, wherein a first wire of the first
conductor pair is twisted in a counter clockwise sense with a first wire of the second
pair, to form a first twisted pair, a second wire of the first pair is twisted with
a first wire of the fourth pair in a clockwise sense to form a second twisted pair,
a second wire of the second conductor pair is twisted with a first wire of the third
conductor pair in a clockwise sense to form a third twisted pair, and the second wire
of the fourth pair is twisted in a counter clockwise sense with the second wire of
the fourth pair to form a further twisted pair.
7. A telecommunications connector according to claim 6, wherein a first wire of the fourth
twisted pair is twisted with a first wire of the second twisted pair to form a fourth
twisted pair.
8. A telecommunications connector according to claim 6 or 7, wherein each wire of each
twisted pair is braided with the wire with which it formed a conductor pair.
9. A telecommunications connector according to claim 6, 7 or 8, wherein the fourth and
fifth insulated wires for the first conductor pair, the first and second insulated
wires form the second conductor pair, the third and sixth insulated wires form the
third conductor pair and the seventh and eighth wires form the fourth conductor pair,
and wherein the fifth and second insulated wires form the first twisted pair, the
fourth and seventh insulated wires form the second twisted pair, the first and third
insulated wires form the third twisted pair, and the sixth and eighth insulated wires
form the fourth twisted pair.
10. A telecommunications connector according to claim 9, wherein the fourth and sixth
insulated wires form the further twisted pair.
11. A telecommunications connector according to claim 1, 2, 6 or 7, wherein the number
of twists in each twisted pair is not equal.
12. A telecommunications connector according to claim 6, wherein a second wire of the
second twisted pair is twisted with a second wire of the fourth twisted pair to form
a second further twisted pair, a first wire of the first twisted pair is twisted with
a first wire of the third twisted pair to form a third further twisted pair, a second
wire of the third twisted pair is twisted with a first wire of the further twisted
pair to form a fourth further twisted pair and the second wire of the first twisted
pair is twisted with the second wire of the further twisted pair to form a fifth further
twisted pair.