Patent Publication Number: US-7713094-B1

Title: Telecommunications connector configured to reduce mode conversion coupling

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention is generally related to communication connectors and their components, including telecommunications connectors. 
     2. Description of the Related Art 
     Conductors that are not physically connected to one another may nonetheless be coupled together electrically and/or magnetically. This creates an undesirable signal in the adjacent conductor referred to as crosstalk. 
     By placing two elongated conductors (e.g., wires) alongside each other in close proximity, a common axis can be approximated. If the opposing currents in the conductors are equal, the magnetic field ‘leakage’ from the conductors will decrease rapidly as the longitudinal distance along the conductors is increased. If the voltages are also opposite and equal, the electric field that is primarily concentrated between the conductors will also decrease as the longitudinal distance along the conductors is increased. This compact pair arrangement is often sufficient to avoid crosstalk if other similar pairs of conductors are in close proximity to the first pair of conductors. Twisting the pairs of conductors will tend to negate the residual field couplings and allow closer spacing of adjacent pairs. However, if for some reason the conductors within a pair are spaced far enough apart, undesired coupling and crosstalk may occur. 
     The structure of many conventional communication connectors is governed by standards including the RJ-45 type connector by FCC part 68 and the TIA/EIA 568 standards. Conventional telecommunications connectors typically include a communication plug and a communication jack configured to receive the plug. The jack typically provides an access point to a network, a communications device, and the like. Each of the plug and jack include a plurality of conductors or contacts. When the plug is received inside the jack, the contacts of the plug engage the corresponding tines of the jack. 
     The communication plug is typically physically connected to one end of a communication cable. The communication cable may be a 4-pair flexible cord, and the communication plug may be coupled thereto to create a patch cord. The cable (e.g., a patch cord) allows a communications device to communicate with the network, device, and the like connected to the jack. A convention for communication cables includes four twisted-wire pairs (also known as “twisted pairs”), which are each physically connected to the communication plug. Following this convention, a communication plug has eight contacts (P-T 1  to P-T 8 ) each connected to a different wire of the four twisted pairs (referred to as “twisted pair  1 ,” “twisted pair  2 ,” “twisted pair  3 ,” and “twisted pair  4 ” herein). Each twisted pair serves as a differential signaling pair wherein signals are transmitted thereupon and expressed as voltage and current differences between the wires of the twisted pair. A twisted pair can be susceptible to electromagnetic sources including another nearby cable of similar construction. Signals received by the twisted pair from such electromagnetic sources external to the cable&#39;s jacket are referred to as “alien crosstalk.” The twisted pair can also receive signals from one or more wires of the three other twisted pairs within the cable&#39;s jacket, which is referred to as “local crosstalk” or “internal crosstalk.” 
     The wires of the twisted pairs  1 - 4  are connected to the plug contacts P-T 1  to P-T 8  to form four differential signaling pairs: a first plug pair  1 , a second plug pair  2 , a third plug pair  3 , and a fourth plug pair  4 . The twisted pair  2  is connected to the plug pair  2 , which includes the adjacent plug contacts P-T 1  and P-T 2 . The twisted pair  4  is connected to the plug pair  4 , which includes the adjacent plug contacts P-T 7  and P-T 8 . The twisted pair  1  is connected to the plug pair  1 , which includes the adjacent plug contacts P-T 4  and P-T 5 . The twisted pair  3  is connected to the troublesome “split” plug pair  3 , which includes the plug contacts P-T 3  and P-T 6 . The plug contacts P-T 3  and P-T 6  flank the plug contacts P-T 4  and P-T 5  of the plug pair  1 . The plug pairs  2  and  4  are located furthest apart from one another and the plug pairs  1  and  3  are positioned between the plug pairs  2  and  4 . 
     A challenge of the structural requisites of conventional communication cabling standards relates to the fact that the two wires of twisted pair  3  are connected to widely spaced contacts P-T 3  and P-T 6  of the communication plug which straddle contacts P-T 4  and P-T 5  to which two wires of the twisted pair  1  are connected, while the wires of the twisted pair  2  are connected to contacts P-T 1  and P-T 2  and the wires of the twisted pair  4  are connected to contacts P-T 7  and P-T 8 . This places the twisted pair  2  and the twisted pair  4  on either side of the twisted pair  3 . This arrangement can cause the signal transmitted on twisted pair  3  to impart different voltages and/or currents onto twisted pair  2  and twisted pair  4  effectively causing differential voltages between the composite of both wires of twisted pair  2  and the composite of both wires of the twisted pair  4  as an undesired cable mode conversion coupling that unfortunately may enhance alien crosstalk elsewhere that is referred to hereafter as a “modal launch” or “mode conversion.” 
     Within the communication jack of the communication connector, the jack tines are positioned in an arrangement corresponding to the arrangement of the plug contacts P-T 1  to P-T 8  in the conventional communication plug. Likewise, the conventional communication cabling standards establish four differential signaling pairs: jack tine pair  2 , which includes adjacent communication jack tines J-T 1  and J-T 2 ; jack tine pair  4 , which includes adjacent communication jack tines J-T 7  and J-T 8 , jack tine pair  1 , which includes adjacent communication jack tines J-T 4  and J-T 5 ; and a troublesome “split” jack tine pair  3 , which includes communication jack tines J-T 3  and J-T 6 . The jack tines J-T 3  and J-T 6  of the jack tine pair  3  flank the jack tines J-T 4  and J-T 5  of the jack tine pair  1 . Further, the jack tine pairs  2  and  4  are located furthest apart from one another and the jack tine pairs  1  and  3  are positioned between the jack tine pairs  2  and  4 . 
     The “split” jack tine pair  3 , with the relatively wide spacing of its jack tine J-T 3  with respect to its jack tine J-T 6 , is especially problematic. 
     For illustrative purposes, the differential signal carried by the wires and associated fields of the twisted pair  3  through a conventional communication connector will now be described. First, the differential signal is associated with the wires of the twisted pair  3  into the communication plug. Within the communication plug, the wires of the twisted pair  3  are untwisted and spaced apart to connect to the split plug contacts P-T 3  and P-T 6 . The differential signal is conducted by the split plug pair  3  to the split jack tines J-T 3  and J-T 6 . Within the communication jack, the jack tines J-T 3  and J-T 6  extend inwardly toward one another to place themselves in close proximity to one another. Conductors (e.g., wires) may be connected to the jack tines J-T 1  to J-T 8  to carry the signal from the communication jack to a destination (e.g., a network, a device, a cable, and the like). The wires connected to the jack tines J-T 3  and J-T 6  of the jack tine pair  3  may be twisted together to form a twisted pair to further reduce unwanted crosstalk. 
     In the conventional communication connector, the mode of coupling of present concern is where the wires of twisted pair  3  are split apart within the plug (as the positions of P-T 3  and P-T 6  are approached) and/or the jack (J-T 3  and J-T 6 ). This splitting of wires of twisted pair  3  creates selective capacitive coupling from the two opposing signals on twisted pair  3  and increases the aperture defined by the area between the wires of pair  3  thus causing an increase of magnetic coupling between twisted pair  3  and the composite sets of wires comprising twisted pair  2  and twisted pair  4  where twisted pair  2  is treated as a two-stranded or “composite” wire as is twisted pair  4 . As a result, a small “coupled” portion of the differential signal originating on twisted pair  3  appears as two opposite common, or “even,” mode signals on the two-wire composites of twisted pair  2  and twisted pair  4 . 
     Thus, where the two-wire composites of twisted pair  2  and twisted pair  4  are treated equally, the signal transmitted on twisted pair  3  may impart opposite voltages and/or currents onto twisted pair  2  and twisted pair  4 , respectively, which causes differential voltages between the composite of the two wires of twisted pair  2  and the composite of the two wires of twisted pair  4 . This is the coupling, and thus a “launch,” of an undesired cable mode conversion that may increase undesired alien crosstalk elsewhere along the transmission path comprised of the plug, the jack and their respective cables. 
     This transmission path of the plug, the jack and their respective cables can thus be viewed as comprised of a plug in which some of the conductors are located in close proximity to one another and others are spaced farther apart, the interface between a portion of the plug and a portion of the jack and typically the site of origin of undesired mode conversion coupling, and the jack wherein conductors are located in close proximity to one another. This conventional arrangement of the transmission path may cause a “modal launch” that extends from the communication connector into the communication cable connected to the plug and/or the destination connected to the jack. 
     Within the communication jack, the modal launch effectively treats the jack tine pair  2  (i.e., jack tines J-T 1  and J-T 2 ) as a single two-stranded “paired” conductor PC-J 1  that is distantly juxtaposed with the jack tine pair  4  (i.e., jack tines J-T 7  and J-T 8 ) as its opposite single two-stranded “paired” conductor PC-J 2 . In other words, the jack tines J-T 1  and J-T 2  of the jack tine pair  2  combine to form the first single “paired” conductor PC-J 1  and the jack tines J-T 7  and J-T 8  connected to the jack tine pair  4  combine to form the second single “paired” conductor PC-J 2 . As a result, a “composite” differential pair is created inside the communication jack by the wider spaced apart first and second ‘paired’ conductors PC-J 1  and PC-J 2 . The wider spacing of first and second ‘paired’ conductors PC-J 1  and PC-J 2  will unfortunately enhance vulnerability and sourcing of unwanted crosstalk among other cables situated in the vicinity, such as in a same cable tray, conduit, etc. 
     As noted, within the communication plug, the modal launch effectively treats the twisted pair  2  as a single two-stranded “paired” conductor PC-P 1  that is distantly juxtaposed with the twisted pair  4  as its opposite single two-stranded “paired” conductor PC-P 2 . Again, the wires of the twisted pair  2  combine to form the first single “paired” conductor PC-P 1  and the wires of the twisted pair  4  combine to form the second single “paired” conductor PC-P 2 . As a result, a “composite” differential pair is created in a communication cable by the wider spaced apart first and second ‘paired’ conductors PC-P 1  and PC-P 2 . The wider spacing of the first and second ‘paired’ conductors PC-P 1  and PC-P 2  will unfortunately enhance vulnerability and sourcing of unwanted crosstalk among other cables situated in the vicinity, such as in a same cable tray, conduit, etc. 
     Within the plug-jack interface, the typical site of origin of undesired mode conversion coupling, of the communication connector, where the conductors (e.g., the wires of the twisted pair  3 , the plug contacts P-T 3  and P-T 6 , and the jack tines J-T 3  and J-T 6 ) are spaced apart from one another, the spaced apart conductors may couple (capacitively and/or inductively) with the other conductors of the communication connector. For example, within this plug-jack interface portion of the communication jack, the jack tine J-T 3  is adjacent the first paired conductor PC-J 1  and the jack tine J-T 6  is adjacent the second paired conductor PC-J 2 . In the plug-jack interface portion of the communication jack, the jack tine J-T 3  is capacitively coupled to the first paired conductor PC-J 1  and the jack tine J-T 6  is capacitively coupled to the second paired conductor PC-J 2 . A magnetic field forms between the split jack tines J-T 3  and J-T 6  that induces inductive coupling between split tines and the first and second paired conductors PC-J 1  and PC-J 2 . Within the plug-jack interface portion of the communication plug, a similar result occurs. 
     A conventional approach to addressing this capacitive and inductive coupling is to cross the split conductors in the plug-jack interface, ideally at a location near a midpoint of the plug-jack interface from which mode conversion coupling occurs. For example, the split conductors may be crossed within the communication jack, the communication plug, or both. 
     If the split conductors are crossed inside the communication jack, a first portion of the jack tine J-T 3  is adjacent the first paired conductor PC-J 1  and a second portion of the jack tine J-T 3  is adjacent the second paired conductor PC-J 2 . Likewise, a first portion of the jack tine J-T 6  is adjacent the second paired conductor PC-J 2  and a second portion of the jack tine J-T 6  is adjacent the first paired conductor PC-J 1 . In other words, any charge in the jack tines J-T 3  and J-T 6  is adjacent to a portion of each of the first and second paired conductors PC-J 1  and PC-J 2 , thereby substantially negating the effect of the capacitive coupling between the split jack tines and the first and second paired conductors PC-J 1  and PC-J 2 . 
     Further, by crossing the jack tines J-T 3  and J-T 6 , the direction of the magnetic field formed between the first portions of the jack tines is opposite that of the magnetic field formed between the second portions, which substantially negates the inductive coupling between the split jack tines and the first and second paired conductors PC-J 1  and PC-J 2 . In other words, mode conversion coupling is reduced by removing or subtracting away an equal amount of adverse coupling from each of the first and second paired conductors PC-J 1  and PC-J 2 . A similar result may be obtained by crossing the jack tines J-T 3  and J-T 6  within the plug-jack interface portion of the communication plug. 
     Thus, a need exists for communication plugs and communication jacks configured to reduce cross-talk. A further need exists for a communication connector configured to reduce cross-talk caused by unwanted inter-modal coupling between the conducting elements of the connector. The present application provides these and other advantages as will be apparent from the following detailed description and accompanying figures. 
    
    
     
       BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S) 
         FIG. 1  is a perspective view of an embodiment of a telecommunications connector. 
         FIG. 2  is a perspective view of a communication plug of the telecommunications connector of  FIG. 1 . 
         FIG. 3  is a schematic of a first wire layout for use with the communication plug of  FIG. 2  depicting portions of four twisted pairs connected with the communication plug and extending therefrom. 
         FIG. 4  is a perspective view of portions of the four twisted pairs as connected to the communication plug corresponding to the first wire layout of  FIG. 3 . 
         FIG. 5  is a perspective view of a communication jack of the telecommunications connector of  FIG. 1 . 
         FIG. 6  is a perspective view of representative internal components of the communication jack of  FIG. 5 . 
         FIG. 7  is an enlarged fragmentary perspective view of the internal components of the communication jack of  FIG. 6 . 
         FIG. 8  is a schematic circuit diagram of internal components of the communication jack of  FIG. 5 . 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     Referring to  FIG. 1 , aspects of the present invention relate to a telecommunications connector  10 . The connector  10  includes a communication plug  100  connected to one end  102  of a communication cable  104  and a communication jack  200  connected to communication cabling (not shown) via a plurality of wire termination contacts (e.g., insulation displacement connectors IDC 1 -IDC 8  shown in  FIG. 5 ). While the wire termination contacts have been illustrated as insulation displacement connectors IDC 1 -IDC 8 , any other means of electrically coupling jack tines to electrically conductive elements in cable may be used. In addition to transmitting communication signals across the telecommunications connector  10 , power may be transmitted across the telecommunications connector  10 . 
     Communication Plug  100   
     Referring to  FIG. 2 , the communication plug  100  includes multiple conductors arranged in twisted pairs to lessen the potential for alien crosstalk from differential voltages that would otherwise exist. In implementations, the twisted pairs  2  and  4  exchange lateral positions with one another near to where they are physically connected to their respective conductors of the communication plug  100  to thereby create a positional exchange or macro-level twist between the twisted pair  2  and the twisted pair  4  about split pair  3  to negate any even mode signals that otherwise would appear on them and cause alien crosstalk elsewhere due to their wide separation in the cable. 
     Referring to  FIG. 2 , the communication plug  100  is depicted connected to the communication cable  104 , which in the depicted implementation of the communication cable includes four twisted pairs. The communication plug  100  includes a plug body  106  with a row of eight plug contacts P-T 1  to P-T 8 , as conductors, shown in  FIG. 2  for exemplary purposes as demarcated in a left to right order for engagement with corresponding tines of the communication jack  200  (see  FIG. 1 ). The communication plug  100  is further depicted as having an engagement latch  108  to secure the communication plug with the communication jack  200 . 
       FIGS. 3 and 4  illustrate a first embodiment of a routing pattern used to route the four twisted pairs of the communication cable  104  from the cable to the plug contacts P-T 1  to P-T 8 . For illustrative purposes, the routing pattern will be described with respect to three regions, a first region P-R 1 , a second region P-R 2 , and a third region or crosstalk coupling zone P-R 3 , as shown in  FIG. 3 . The crosstalk coupling zone P-R 3  is closest to and includes the plug contacts P-T 1  to P-T 8  of the plug body  106 , and extends within the communication plug  100 . The second region P-R 2  is directly adjacent to the crosstalk coupling zone P-R 3  and extends within the communication plug  100  for a relatively short distance away therefrom. The first region P-R 1  is directly adjacent to the second region P-R 2  and typically extends therefrom for a majority of the length of the communication cable  104 . 
     As depicted, the communication cable  104  includes four twisted pairs: a first plug pair  1  having a first wire  110   a  and a second wire  110   b , a second plug pair  2  having a first wire  112   a  and a second wire  112   b , a third plug pair  3  having a first wire  114   a  and a second wire  114   b , and a fourth plug pair  4  having a first wire  116   a  and a second wire  116   b . In other implementations, the communication cable  104  may include a different number of twisted pairs. The first wire  110   a  and the second wire  110   b  form a first differential signaling pair  110 . The first wire  112   a  and the second wire  112   b  form a second differential signaling pair  112 . The first wire  114   a  and the second wire  114   b  form a third differential signaling pair  114 . The first wire  116   a  and the second wire  116   b  form a fourth differential signaling pair  116 . 
     The communication plug  100  and the communication cable  104  are further demarcated as having a first side  118 , which is closest to the plug contacts P-T 1  and P-T 2  in the crosstalk coupling zone P-R 3 , and a second side  120 , which is closest to the plug contacts P-T 7  and P-T 8  in the crosstalk coupling zone P-R 3 . Some implementations of the communication cable  104  can have a round or otherwise curvilinear cross-section so that the first side  118  and the second side  120  will not physically be flat, but will still be positioned relative to the plug contacts P-T 7 /P-T 8  and P-T 1 /P-T 2  as shown. 
     In the first and second regions P-R 1  and P-R 2 , the four twisted pairs run longitudinally with the first side  118  and the second side  120  of the communication cable  104  and are located therebetween without any cross-over. In the first and second regions P-R 1  and P-R 2 , the fourth plug pair  4  is positioned closest to the first side  118  and the second plug pair  2  is positioned closest to the second side  120 . The third plug pair  3  is shown in  FIG. 3  as positioned between the fourth plug pair  4  and the first plug pair  1 , whereas the first plug pair  1  is shown to be positioned between the third plug pair  3  and the second plug pair  2 . 
     In the crosstalk coupling zone P-R 3  within the communication plug  100 , engagement of the wires of the twisted pairs with the contacts P-T 1  to P-T 8  of the communication plug occurs. As shown in  FIG. 3 , the first wire  110   a  and the second wire  110   b  of the first plug pair  1  are connected to contacts P-T 4  and P-T 5 , respectively. The first wire  112   a  and the second wire  112   b  of the second plug pair  2  are connected to contacts P-T 1  and P-T 2 , respectively. The first wire  114   a  and the second wire  114   b  of the third plug pair  3  are connected to contacts P-T 3  and P-T 6 , respectively, on either side of the first plug pair  1 . The first wire  116   a  and the second wire  116   b  of the fourth plug pair  4  are connected to contacts P-T 7  and P-T 8 , respectively. 
     As shown in  FIG. 3 , in a portion of the third region P-R 3  within the communication plug  100 , the first wire  114   a  and the second wire  114   b  of the third plug pair  3  are no longer twisted together, but rather are separated apart from their twisted pair arrangement to straddle either side of the first plug pair  1 . In the third region P-R 3 , the second plug pair  2  crosses the first plug pair  1  and the third plug pair  3  to transition from being closest to the first side  118  to being closest to the second side  120  as found in the first and second regions P-R 1  and P-R 2 . In the third region P-R 3 , the fourth plug pair  4  crosses the first plug pair  1  and the third plug pair  3  to transition from being closest to the second side  120  to being closest to the first side  118  as found in the first and second regions P-R 1  and P-R 2 . As shown, the second plug pair  2  and the fourth plug pair  4  transition in the third region P-R 3  so that they cross each other. This crossing or reversing of the second plug pair  2  and the fourth plug pair  4  with respect to one another is understood to consequently help negate possible undesirable coupling between the second plug pair  2  and the fourth plug pair  4  due to differential voltage between the second plug pair  2  and the fourth plug pair  4  being imparted by the third plug pair  3  straddling the first plug pair  1 . 
     As explained in the Background Section, in a conventional prior art communication plug, within the crosstalk coupling zone, the wires coupled to the second plug pair combine to form the first paired conductor PC-P 1  and the wires coupled to the fourth plug pair combine to form the second paired conductor PC-P 2 . To reduce crosstalk, the first wire of the split third plug pair (which starts out near the second plug pair) is crossed over the second wire of the split third plug pair (and the wires of the first plug pair) to place the first wire in close proximity with the fourth plug pair. Additionally, the second wire of the split third plug pair (which starts out near the fourth plug pair) is crossed over the first wire of the split third plug pair (and the wires of the first plug pair) to place the second wire in close proximity with the second plug pair. The first and second paired conductors PC-P 1  and PC-P 2  are not crossed with any of the wires of any of the other plug pairs. 
     As explained above, in a conventional communication plug, crossing the first and second wires of the split third plug pair relative to the first and second paired conductors PC-P 1  and PC-P 2  negates both capacitive and inductive coupling between the first and second wires of the split third plug pair and the first and second paired conductors PC-P 1  and PC-P 2 . 
     In contrast, in crosstalk coupling zone P-R 3  of the communication plug  100 , capacitive and/or inductive coupling between the first and second wires  114   a  and  114   b  of the split third plug pair  3  and the second and fourth differential signaling pairs  112  and  116  is avoided by crossing the second differential signaling pair  112  and the fourth differential signaling pair  116  instead of the first and second wires  114   a  and  114   b . In this arrangement, any charge present in the first wire  114   a  may possibly couple with a first portion of the second differential signaling pair  112  and any charge present in the second wire  114   b  may possibly couple with a first portion of the fourth differential signaling pair  116 . The first portion of the second differential signaling pair  112  is spaced apart from and juxtaposed with the first portion of the fourth differential signaling pair  116 . Further, any charge present in the first wire  114   a  may possibly couple with a second portion of the fourth differential signaling pair  116  and any charge present in the second wire  114   b  may possibly couple with a second portion of the second differential signaling pair  112 . The second portion of the second differential signaling pair  112  is spaced apart from, and juxtaposed with, the second portion of the fourth differential signaling pair  116 . 
     The first portion of the second differential signaling pair  112  and the second portion of the fourth differential signaling pair  116  are both adjacent to different sections of the first wire  114   a , which negates or cancels any capacitive coupling between the first wire  114   a  and the second and fourth differential signaling pairs  112  and  116 . Similarly, the second portion of the second differential signaling pair  112  and the first portion of the fourth differential signaling pair  116  are both adjacent to different sections of the second wire  114   b , which negates or cancels any capacitive coupling between the second wire  114   b  and the second and fourth differential signaling pairs  112  and  116 . Further, the direction of the magnetic field formed between the first portions of the differential signaling pairs  112  and  116  is opposite that of the magnetic field formed between the second portions of the differential signaling pairs  112  and  116 , which negates or cancels the inductive coupling between the first and second wires  114   a  and  114   b  and the second and fourth differential signaling pairs  112  and  116 . In other words, in the communication plug  100 , mode conversion coupling is reduced by removing or subtracting away an equal amount of adverse coupling from each of the second and fourth differential signaling pairs  112  and  116 . 
     Communication Jack  200   
     Referring to  FIG. 5 , like the communication plug  100 , the communication jack  200  includes eight contacts or tines J-T 1  to J-T 8  arranged into four tine pairs. A first pair of jack tines includes tines J-T 4  and J-T 5 . A second pair of jack tines includes tines J-T 1  and J-T 2 . A third pair of jack tines includes tines J-T 3  and J-T 6 . A fourth pair of jack tines includes tines J-T 7  and J-T 8 . 
     Also like the communication plug  100 , the communication jack  200  includes tine arrangements to lessen potential for crosstalk due to unintended mode conversion coupling along wire pairs connected to both the second pair of jack tines J-T 1  and J-T 2  and the fourth pair of jack tines J-T 7  and J-T 8 . Cross-members and insulators are used to laterally exchange longitudinal routing of the second pair of jack tines J-T 1  and J-T 2  with the fourth pair of jack tines J-T 7  and J-T 8  for those portions extending away from, but not including, the plug engagement area of the communication jack  200 . In particular, the longitudinal routing between the jack tine J-T 1  and the jack tine J-T 8  are laterally exchanged and longitudinal routing between the jack tine J-T 2  and the jack tine J-T 7  are laterally exchanged. 
     As illustrated schematically in  FIG. 8 , and as will be described in greater detail below, the jack tine J-T 1  extends along and near to a first longitudinal side of the communication jack  200  in the plug engagement area and then, via a lateral transition by a cross-member, extends along and near to a second longitudinal side of the communication jack opposite the first longitudinal side as it extends farther away from the engagement area. The jack tine J-T 8  extends along and near to the second longitudinal side of the communication jack in the engagement area and then, via a lateral transition by a cross-member, extends along and near to the first longitudinal side of the communication jack as it extends farther away from the engagement area. 
     The jack tine J-T 2  extends along and near to the first longitudinal side of the communication jack  200  in the engagement area and then, via a lateral transition by a cross-member, extends along and near to the second longitudinal side of the communication jack as it extends farther away from the engagement area. The jack tine J-T 7  extends along and near to the second longitudinal side of the communication jack in the engagement area and then, via a lateral transition by a cross-member, extends along and near to the first longitudinal side of the communication jack as it extends farther away from the engagement area. In other words, the jack tine J-T 1  and the jack tine J-T 8  remain on the outward most lateral positions after their lateral exchanges and the jack tine J-T 2 , and the jack tine J-T 7  remain in inward lateral positions relative to the jack tine J-T 1  and the jack tine J-T 8 , respectively, to properly counter coupling related to their nearness to the third pair of jack tines J-T 3  and J-T 6 . By swapping the locations of the second pair of jack tines J-T 1  and J-T 2  with the fourth pair of jack tines J-T 7  and J-T 8 , both capacitive and inductive couplings for the second pair of jack tines and the fourth pair of jack tines are brought near to being equalized. 
       FIG. 5  depicts the communication jack  200  as having a jack frame  202  connected to a main housing  204  and further connected to a terminal housing  206 . The jack frame  202  includes an aperture  208  to provide access to the jack tines J-T 1  to J-T 8  for engagement with the plug contacts P-T 1  to P-T 8 , respectively, of the communication plug  100  (see  FIGS. 1 and 2 ) upon insertion of the communication plug into the aperture. The terminal housing  206  includes a plurality of insulation displacement connectors IDC 1 -IDC 8  for connecting the jack tines J-T 1  to J-T 8  with communication cabling (not shown). 
     The jack tines J-T 1  to J-T 8  are shown in simplified form for illustration purposes in  FIG. 6  and in circuit form in  FIG. 8  to include a first region J-R 1 , a second region J-R 2 , and a third region J-R 3 . The first region J-R 1 , is generally where engagement of the jack tines J-T 1  to J-T 8  occurs with the contacts of a connected communication plug (e.g., the plug contacts P-T 1  to P-T 8  of the communication plug  100 ). The second region J-R 2 , includes cross-member tine portions involved with lateral exchange of longitudinal routing of the second pair of jack tines J-T 1  and J-T 2  and the fourth pair of jack tines J-T 7  and J-T 8  as described further below. The third region J-R 3  includes the second pair of jack tines J-T 1  and J-T 2  and the fourth pair of jack tines J-T 7  and J-T 8  with their locations laterally exchanged with one another in the second region J-R 2 , relative to their orientation in the first region J-R 1 . 
     Within the first region J-R 1  and the third region J-R 3 , the jack tines J-T 1  to J-T 8  are substantially parallel with one another along an axis illustrated by a double-headed arrow “A.” Within the second region J-R 2 , only the jack tines J-T 6  and J-T 3  are substantially parallel with one another along the axis illustrated by the double-headed arrow “A” as depicted in  FIG. 6 . The jack tines J-T 1 , J-T 2 , J-T 4 , J-T 5 , J-T 7  and J-T 8  each cross over at least one other jack tine in the second region J-R 2 . Thus, each of the jack tines J-T 1 , J-T 2 , J-T 4 , J-T 5 , J-T 7  and J-T 8  has a portion that extends laterally above or below at least one other jack tine, and crosses the at least one other jack tine, without electrically contacting it relative to the axis illustrated by the double-headed arrow “A.” 
     The jack tines J-T 1  to J-T 8  extend from the second region J-R 2 , into the third region J-R 3 , where they engage with a substrate  230  (see  FIG. 8 ), such as a printed circuit board, a “boardless” lead frame, or other support structure that has a first side  230   a  opposite a second side  230   b . The substrate  230  connects the jack tines J-T 1  to J-T 8  with the insulated displacement connectors IDC 1 -IDC 8 , respectively, as shown in  FIG. 8 . 
     Included in the second region J-R 2 , further shown in  FIG. 6 , is a first insulative member  210  with a first aperture  210   a , a second aperture  210   b , a third aperture  210   c , and a fourth aperture  210   d ; a second insulative member  212  with a first aperture  212   a , a second aperture  212   b , a third aperture  212   c , and a fourth aperture  212   d ; a third insulative member  214  with a first aperture  214   a , a second aperture  214   b , a third aperture  214   c , and a fourth aperture  214   d ; and a fourth insulative member  216  with a first aperture  216   a , a second aperture  216   b , a third aperture  216   c , and a fourth aperture  216   d . Each of the insulative members  210 ,  212 ,  214 , and  216  is configured to support two of the jack tines J-T 1 , J-T 2 , J-T 4 , J-T 5 , J-T 7  and J-T 8  and direct the tine across at least one of the jack tines J-T 1  to J-T 8 . 
     In  FIG. 7 , for illustrative purposes, jack tines J-T 3 , J-T 4 , J-T 5 , and J-T 6  have been removed. In the second region J-R 2 , the jack tine J-T 1  includes a first cross-member  218  with a first portion  218   a , a second portion  218   b , and a third portion  218   c . The first aperture  210   a  of the first insulative member  210  is configured to receive the jack tine J-T 1  from the first region J-R 1 . The first insulative member  210  directs the first portion  218   a  of the jack tine J-T 1  out the second aperture  210   b . A portion  218   d  of the jack tine J-T 1  inside the first insulative member  210  is bent to position the second portion  218   b  above the jack tines J-T 2 , J-T 3 , J-T 4 , J-T 5 , J-T 6 , and J-T 7  for the purposes of crossing thereover. The bent portion  218   d  may define an inside obtuse angle. Alternatively, the bent portion  218   d  may define an inside acute or right angle. It should be understood that the bent portion  218   d  of the jack tine J-T 1  could be best to position the first portion  218   b  below the jack tines J-T 2 , J-T 3 , J-T 4 , J-T 5 , J-T 6 , and J-T 7 . 
     The first portion  218   a  is connected to or integrally formed with the second portion  218   b  that crosses over the jack tines J-T 2 , J-T 3 , J-T 4 , J-T 5 , J-T 6 , and J-T 7 . The second portion  218   b  is connected to or integrally formed with the third portion  218   c  that is received inside the third aperture  216   c  of the fourth insulative member  216 . A portion  218   e  of the jack tine J-T 1  inside the fourth insulative member  216  is bent to position the jack tine J-T 1  to exit the fourth insulative member  216  through the fourth aperture  216   d  in an orientation that renders the jack tine J-T 1  substantially parallel to the other jack tines J-T 2  to J-T 8  in the third region J-R 3 . The bent portion  218   e  may define an inside acute or right angle. Alternatively, the bent portion  218   e  may define an inside obtuse or right angle. 
     Thus, from the first region J-R 1 , the jack tine J-T 1  enters the first insulative member  210  through the first aperture  210   a , passes through the second aperture  210   b , laterally crosses over jack tines J-T 2  to J-T 7  from a position nearer the first side  230   a  to a position nearer the second side  230   b  as the second portion  218   b  of the first cross member, goes through the third aperture  216   c  of the fourth insulative member  216  and goes into the third region J-R 3  from the fourth aperture  216   d  of the fourth insulative support. 
     In the second region J-R 2 , the jack tine J-T 2  includes a second cross-member  220  with a first portion  220   a , a second portion  220   b , and a third portion  220   c . The first aperture  212   a  of the second insulative member  212  is configured to receive the jack tine J-T 2  from the first region J-R 1 . The second insulative member  212  directs the first portion  220   a  of the jack tine J-T 2  out the second aperture  212   b . A bent portion  220   d  of the jack tine J-T 2  inside the second insulative member  212  is bent to position the second portion  220   b  above the jack tines J-T 3 , J-T 4 , J-T 5 , and J-T 6  for the purposes of crossing thereover. The bent portion  220   d  may define an inside obtuse angle. Alternatively, the bent portion  220   d  may define an inside acute or right angle. It should be noted that the bent portion  220   d  of the jack tine J-T 2  could be bent to position the second portion  220   b  below the jack tines J-T 3 , J-T 4 , J-T 5 , and J-T 6 . 
     The first portion  220   a  is connected to or integrally formed with the second portion  220   b  that crosses over the jack tines J-T 3 , J-T 4 , J-T 5 , and J-T 6 . The second portion  220   b  is connected to or integrally formed with the third portion  220   c  that is received inside the third aperture  214   c  of the third insulative member  214 . A bent portion  220   e  of the jack tine J-T 2  inside the third insulative member  214  is bent to position the jack tine J-T 2  to exit the third insulative member  214  through the fourth aperture  214   d  in an orientation that renders the jack tine J-T 2  substantially parallel to the other jack tines J-T 1  and J-T 3  to J-T 8  in the third region J-R 3 . The bent portion  220   e  may define an inside acute or right angle. Alternatively, the bent portion  220   e  may define an inside obtuse or right angle. 
     Thus, from the first region J-R 1 , the jack tine J-T 2  enters the second insulative member  212  through the first aperture  212   a , passes through the second aperture  212   b , laterally crosses over jack tines J-T 3  to J-T 6  from a position nearer the first side  230   a  to a position nearer the second side  230   b  as the second portion  220   b  of the second cross member, goes through the third aperture  214   c  of the third insulative member  214  and goes into the third region J-R 3  from the fourth aperture  214   d  of the third insulative support. 
     In the second region J-R 2 , the jack tine J-T 7  includes a third cross-member  222  with a first portion  222   a , a second portion  222   b , and a third portion  222   c . The first aperture  214   a  of the third insulative member  214  is configured to receive the jack tine J-T 7  from the first region J-R 1 . The third insulative member  214  directs the first portion  222   a  of the jack tine J-T 7  out the second aperture  214   b . A bent portion  222   d  of the jack tine J-T 7  inside the third insulative member  214  is bent to position the second portion  222   b  below the jack tines J-T 3 , J-T 4 , J-T 5 , and J-T 6  for the purposes of crossing thereunder. The bent portion  222   d  may define an inside obtuse angle. Alternatively, the bent portion  222   d  may define an inside acute or right angle. It should be understood that the bent portion  222   d  of the jack tine J-T 7  could be bent to position the second portion  222   b  above the jack tines J-T 3 , J-T 4 , J-T 5 , and J-T 6 . 
     The first portion  222   a  is connected to or integrally formed with the second portion  222   b  that crosses under the jack tines J-T 3 , J-T 4 , J-T 5 , and J-T 6 . The second portion  222   b  is connected to or integrally formed with the third portion  222   c  that is received inside the third aperture  212   c  of the second insulative member  212 . A bent portion  222   e  of the jack tine J-T 7  inside the second insulative member  212  is bent to position the jack tine J-T 7  to exit the second insulative member  212  through the fourth aperture  212   d  in an orientation that renders the jack tine J-T 7  substantially parallel to the other jack tines J-T 1  to J-T 6  and J-T 8  in the third region J-R 3 . The bent portion  222   e  may define an inside acute or right angle. Alternatively, the bent portion  222   e  may define an inside obtuse or right angle. 
     Thus, from the first region J-R 1 , the jack tine J-T 7  enters the third insulative member  214  through the first aperture  214   a , passes through the second aperture  214   b , laterally crosses under jack tines J-T 3  to J-T 6  from a position nearer the second side  230   b  to a position nearer the first side  230   a  as the second portion  222   b  of the third cross member, goes through the third aperture  212   c  of the second insulative member  212  and goes into the third region J-R 3  from the fourth aperture  212   d  of the second insulative support. 
     In the second region J-R 2 , the jack tine J-T 8  includes a fourth cross-member  224  with a first portion  224   a , a second portion  224   b , and a third portion  224   c . The first aperture  216   a  of the fourth insulative member  216  is configured to receive the jack tine J-T 8  from the first region J-R 1 . The fourth insulative member  216  directs the first portion  224   a  of the jack tine J-T 8  out the second aperture  216   b . A bent portion  224   d  of the jack tine J-T 8  inside the fourth insulative member  216  is bent to position the second portion  224   b  below the jack tines J-T 2 , J-T 3 , J-T 4 , J-T 5 , J-T 6 , and J-T 7  for the purposes of crossing thereunder. The bent portion  224   d  may define an inside obtuse angle. Alternatively, the bent portion  224   d  may define an inside acute or right angle. It should be understood that the bent portion  224   d  of the jack tine J-T 8  could be bent to position the second portion  224   b  above the jack tines J-T 2 , J-T 3 , J-T 4 , J-T 5 , J-T 6 , and J-T 7 . 
     The first portion  224   a  is connected to or integrally formed with the second portion  224   b  that crosses under the jack tines J-T 2 , J-T 3 , J-T 4 , J-T 5 , J-T 6 , and J-T 7 . The second portion  224   b  is connected to or integrally formed with the third portion  224   c  that is received inside the third aperture  210   c  of the first insulative member  210 . A bent portion  224   e  of the jack tine J-T 8  inside first insulative member  210  is bent to position the jack tine J-T 8  to exit the first insulative member  210  through the fourth aperture  210   d  in an orientation that renders the jack tine J-T 8  substantially parallel to the other jack tines J-T 1  to J-T 7  in the third region J-R 3 . The bent portion  224   e  may define an inside acute or right angle. Alternatively, the bent portion  224   e  may define an inside obtuse or right angle. 
     Thus, from the first region J-R 1 , the jack tine J-T 8  enters the fourth insulative member  216  through the first aperture  216   a , passes through the second aperture  216   b , laterally crosses under jack tines J-T 2  to J-T 7  from a position nearer the second side  230   b  to a position nearer the first side  230   a  as the second portion  224   b  of the fourth cross member, goes through the third aperture  210   c  of the first insulative member  210  and goes into the third region J-R 3  from the fourth aperture  210   d  of the first insulative support. 
     Returning to  FIG. 6 , the jack tine J-T 4  has a cross-over portion  226  and the jack tine J-T 5  has a cross-over portion  228 . The cross-over portion  226  of the jack tine J-T 4  crosses under the cross-over portion  228  of the jack tine J-T 5 . In the embodiment illustrated, the cross-over portions  226  and  228  are located approximately between the second portions  218   b  and  220   b  of the jack tines J-T 1  and J-T 2 , and the second portions  222   b  and  224   b  of the jack tines J-T 7  and J-T 8 . 
     In a communication jack (such as the communication jack  200 ), the crosstalk coupling zone may extend along the length of the jack tines J-T 1  to J-T 8  (i.e., across regions J-R 1 , J-R 2 , and J-R 3 ). As mentioned above in the Background Section, in a conventional communication jack, crosstalk may be reduced by crossing the jack tines J-T 3  and J-T 6  (or conductors connected thereto) of the split third jack tine pair relative to the first and second paired conductors PC-P 1  and PC-P 2 . 
     In contrast, in the communication jack  200 , capacitive and/or inductive coupling between the jack tines J-T 3  and J-T 6  of the split third jack tine pair  3  and the second and fourth jack tine pairs  2  and  4  is avoided by crossing the jack tine pair  2  and the fourth jack tine pair  4  (instead of the jack tines J-T 3  and J-T 6  or conductors connected thereto). In this arrangement, any charge present in the jack tine J-T 3  may possibly couple with a first portion of the jack tine pair  2  in the first region J-R 1  and any charge present in the jack tine J-T 6  may possibly couple with a first portion of the fourth jack tine pair  4  in the first region J-R 1 . The first portion of the second jack tine pair  2  is spaced apart from, and juxtaposed with, the first portion of the fourth jack tine pair  4  in the first region J-R 1 . Further, any charge present in the jack tine J-T 3  may possibly couple with a second portion of the fourth jack tine pair  4  in the third region J-R 3  and any charge present in the jack tine J-T 6  may possibly couple with a second portion of the second jack tine pair  2  in the third region J-R 3 . The second portion of the second jack tine pair  2  is spaced apart from and juxtaposed with the second portion of the fourth jack tine pair  4  in the third region J-R 3 . 
     The first portion of the second jack tine pair  2  and the second portion of the fourth jack tine pair  4  are both adjacent to different sections of the jack tine J-T 3 , which negates or cancels any capacitive coupling between the jack tine J-T 3  and the second and fourth jack tine pairs  2  and  4 . Similarly, the second portion of the second jack tine pair  2  and the first portion of the fourth jack tine pair  4  are both adjacent to different sections of the jack tine J-T 6 , which negates or cancels any capacitive coupling between the jack tine J-T 6  and the second and fourth jack tine pairs  2  and  4 . Further, the direction of the magnetic field formed between the first portions of the second and fourth jack tine pairs  2  and  4  is the opposite that of the magnetic field formed between the second portions of the second and fourth jack tine pairs  2  and  4 , which negates or cancels the inductive coupling between the jack tines J-T 3  and J-T 6  and the second and fourth jack tine pairs  2  and  4 . In other words, in the communication jack  200 , mode conversion coupling is reduced by removing or subtracting away an equal amount of adverse coupling from each of the second and fourth jack tine pairs  2  and  4 . 
     Mode conversion coupling may also be reduced by crossing the jack tines J-T 4  and J-T 5 , both of which are located between the second and fourth jack tine pairs  2  and  4  and could potentially couple therewith if the jack tines J-T 4  and J-T 5  are not crossed. Crossing the jack tines J-T 4  and J-T 5  could also help prevent coupling between the jack tines J-T 4  and J-T 5  and the jack tines J-T 3  and J-T 6 , respectively. 
     As is apparent to those of ordinary skill in the art, mode conversion coupling may be reduced or eliminated in a communication connector formed by connecting the communication plug  100  with the communication jack  200 , any communication jack known in the art including the conventional communication jack described in the Background Section, and the like. Further, mode conversion coupling may be reduced or eliminated in a communication connector formed by connecting the communication plug  100  with a communication jack in which none of the wires are crossed for the purposes of reducing or eliminating mode conversion coupling. 
     Further, mode conversion coupling may be reduced or eliminated in a communication connector formed by connecting the communication jack  200  with the communication plug  100 , any communication plug known in the art including the conventional communication plug described in the Background Section, and the like. Further, mode conversion coupling may be reduced or eliminated in a communication connector formed by connecting the communication jack  200  with a communication plug in which none of the wires are crossed for the purposes of reducing or eliminating mode conversion coupling. 
     As is appreciated by those of ordinary skill in the art, it may be desirable to preserve a proper amount of pair-to-pair (internal) differential crosstalk inside the plug that would otherwise occur without the inclusion of the modal cancellation/compensation described above. Thus, in some implementations, adjustment of wire position details may be necessary to maintain all six combinations of differential crosstalk in the 4-pair example of the plug. Further, as is appreciated by those of ordinary skill in the art, many techniques are known for reducing crosstalk within a communication connector. Through application of ordinary skill in the art to the present teachings, communication jacks, plugs, and connectors may be constructed that include implementations of such techniques and such devices are within the scope of the present teachings. 
     The foregoing described embodiments depict different components contained within, or connected with, different other components. It is to be understood that such depicted architectures are merely exemplary, and that in fact many other architectures can be implemented which achieve the same functionality. In a conceptual sense, any arrangement of components to achieve the same functionality is effectively “associated” such that the desired functionality is achieved. Hence, any two components herein combined to achieve a particular functionality can be seen as “associated with” each other such that the desired functionality is achieved, irrespective of architectures or intermedial components. Likewise, any two components so associated can also be viewed as being “operably connected,” or “operably coupled,” to each other to achieve the desired functionality. 
     While particular embodiments of the present invention have been shown and described, it will be obvious to those skilled in the art that, based upon the teachings herein, changes and modifications may be made without departing from this invention and its broader aspects and, therefore, the appended claims are to encompass within their scope all such changes and modifications as are within the true spirit and scope of this invention. Furthermore, it is to be understood that the invention is solely defined by the appended claims. It will be understood by those within the art that, in general, terms used herein, and especially in the appended claims (e.g., bodies of the appended claims) are generally intended as “open” terms (e.g., the term “including” should be interpreted as “including but not limited to,” the term “having” should be interpreted as “having at least,” the term “includes” should be interpreted as “includes but is not limited to,” etc.). It will be further understood by those within the art that if a specific number of an introduced claim recitation is intended, such an intent will be explicitly recited in the claim, and in the absence of such recitation no such intent is present. For example, as an aid to understanding, the following appended claims may contain usage of the introductory phrases “at least one” and “one or more” to introduce claim recitations. However, the use of such phrases should not be construed to imply that the introduction of a claim recitation by the indefinite articles “a” or “an” limits any particular claim containing such introduced claim recitation to inventions containing only one such recitation, even when the same claim includes the introductory phrases “one or more” or “at least one” and indefinite articles such as “a” or “an” (e.g., “a” and/or “an” should typically be interpreted to mean “at least one” or “one or more”); the same holds true for the use of definite articles used to introduce claim recitations. In addition, even if a specific number of an introduced claim recitation is explicitly recited, those skilled in the art will recognize that such recitation should typically be interpreted to mean at least the recited number (e.g., the bare recitation of “two recitations,” without other modifiers, typically means at least two recitations, or two or more recitations). 
     Accordingly, the invention is not limited except as by the appended claims.