This invention relates to communications connectors, and more particularly, to communications connectors that are configured for low crosstalk.
In some communications systems, communications signals transmit video, audio and data signals over a pair of wires typically referred to as a “wirepair” or “differential pair” in which a voltage difference exists between wires to form the transmitted signal. Each wire in this wire pair typically picks up some electrical noise. If each wire in the pair picks up the same noise voltage, then differential recovery of the signal voltage cancels the common mode noise voltage. Typically, making both noise voltages the same requires closely spaced differential pairs of wires. Electrical noise is sometimes picked up from nearby wires or pairs of wires forming what is termed “crosstalk.” It is a common problem with many different modular plugs and other jacks and communications connectors.
Communications connectors have been designed with different configurations as an aid in reducing crosstalk while allowing high density signal communications, i.e., having a high signal throughput on many separate communication circuits all located within a small space. Some of these communications connectors are modular jacks that use cross-coupling configurations similar to twisted pair wires to generate crosstalk-canceling signals. Other connector configurations separate the input conductors to produce crosstalk cancellation by crossing input and output conductors. Other connector designs use additional conductors to cancel crosstalk or a pair of mating or crossover conductors to cancel crosstalk. It is also possible to add chip capacitors to cancel crosstalk, vary the distance between conductors, or incorporate extra grounds or shields to reduce crosstalk.
In one proposal, a communications connector has connective terminals configured in different planes with different separation distances from midpoints of first and second pairs of terminals. A third pair of terminals is aligned in another plane that could be perpendicular to first and second planes to reduce crosstalk.
Reducing crosstalk is especially desirable for customer satisfaction when the connectors are used in Customer Premises Equipment (CPE). For example, many residential and business customers use Asymmetric Digital Subscriber Line (ADSL) and Very High Bit Rate DSL (VDSL) communications systems that typically use twisted pairs of copper wires for carrying signals within different frequency channels termed “bins.” Achieving high data transmission rates with low error rates and latency requires that the cabling system adds minimal crosstalk. Low crosstalk must be maintained in all parts of the systems, including the connectors at the ends of the cable.
A communications connector includes an electrically non-conductive connector body having a terminal face. A plurality of connector terminals are positioned on the terminal face and arranged in a plurality of Tip/Ring terminal pairs, which are positioned substantially linearly with each other along the terminal face and arranged in alternating vertical and horizontal orientation of Tip/Ring terminal pairs and spaced to each other such that crosstalk among the Tip/Ring terminal pairs is cancelled.
Each Tip/Ring pair in one aspect comprises a pair of wire conductors that extend through the connector body and exit therefrom as connector pins for respective Tip/Ring terminal pairs. The connector pins are configured to enable wire wrapped connections to a printed circuit board. The connector body includes a rear face through which the Tip/Ring terminal pairs extend as connector pins. In one aspect, the connector pins extend from a rear face of the connector body and form a horizontal section followed by a riser section that extends downward from the horizontal section for engaging a circuit board to which the connector body is supported. In yet another aspect, the connector body supports at least three Tip/Ring terminal pairs along the terminal face. A female socket is formed within the terminal face at each location on the connector body at which a Tip/Ring terminal pair is located and into which a respective Tip/Ring terminal pair is positioned and into which a mating male plug can be inserted.
In yet another aspect, adjacent Tip/Ring terminal pairs are spaced such that the distance from a vertically oriented tip terminal connector on a first Tip/Ring terminal pair to a horizontally oriented tip terminal connector on a second adjacent Tip/Ring terminal pair and the distance between the ring terminal connector on the first Tip/Ring terminal pair and the tip terminal connector on the second Tip/Ring terminal pair are substantially the same distance d1. Also, the distance from the vertically oriented tip terminal connector on the first Tip/Ring terminal pair to the horizontally oriented ring terminal connector on the second Tip/Ring terminal pair and the distance between the ring terminal connector on the first Tip/Ring terminal pair and the ring terminal connector on the second Tip/Ring terminal pair are substantially the same distance d2. The distances d1 and d2 are such that crosstalk among Tip/Ring terminal pairs is cancelled.
In yet another aspect, the communications connector can be formed as a plurality of electrically non-conductive connector bodies each having a terminal face and positioned linearly and adjacent to each other. A pair of connector terminals are positioned on the terminal face of each electrically non-conductive connector body and arranged as a Tip/Ring terminal pair in one of a vertical or horizontal configuration on the terminal face. Each of the connector bodies are arranged adjacent to each other such that the Tip/Ring terminal pairs are arranged in alternating vertical and horizontal orientation and spaced to each other a distance such that the crosstalk among Tip/Ring terminal pairs is cancelled.
Other objects, features and advantages of the present invention will become apparent from the detailed description of the invention which follows, when considered in light of the accompanying drawings in which:
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout.
The communications connector, in accordance with one non-limiting aspect, has a symmetrical design configuration that uses an alternate horizontal and vertical orientation of the connector terminals forming the Tip/Ring terminal pair such as shown in
For the communications connector shown in
There now follows a basic description explaining crosstalk measurements with common mode and differential mode signals and measurements of various connector configurations such as shown in
To evaluate the crosstalk of a communications connector, both metallic (differential mode) and longitudinal (common mode) excitation and responses are considered. In order to reject noise, communications systems are typically configured to reject common mode noise while receiving differential signals. Furthermore, it is important to minimize the amount of differential signal from a first pair of communication wires that is conveyed by crosstalk to a second pair of communication wires. As will be explained later below, the chosen geometry used in the communications connector, in accordance with the non-limiting example shown in
It should be understood that there are different technical aspects of common mode and differential mode signals. For a pair of wires having conductors, for example “a” and “b,” it is possible to define the following quantities at any place along the length of wire:
A) Vab(dm)=Va−Vb, known as the differential mode or metallic voltage; and
B) Vab(cm)=(Va+Vb)/2, known as the common mode or longitudinal voltage.
To minimize crosstalk, communications systems typically generate and respond to differential mode signals. If the communications systems generate or respond to common mode signals, this is typically done only for low frequencies where crosstalk is less prevalent. This limits the bandwidth of the common mode portion of the channel.
To measure crosstalk in this example prior art communications connector, four connector terminal aspects are typically specified: (1) aggressor; (2) victim; (3) common mode excitation or reception; and (4) differential mode excitation or reception. The response of a victim to the aggressor depends upon both capacitive and inductive coupling. The strength of those responses is inversely proportional to distance, e.g., larger separations between aggressor and victim produce smaller responses in the victim than do smaller separations. There is typically some non-unity power involved in this relationship and the measurements as described assume a simple inverse relationship with distance to gain intuition about the crosstalk mechanisms.
If one unit of voltage is applied to a circuit, which includes the communications connector, this results in a current flow of one unit of current. The responses are linear with respect to the applied input. This allows use of superposition to facilitate the calculations. To gain intuition about the process, it is possible to note the decrease in crosstalk with increasing distance by a reciprocal relationship. The exact nature of the relationship is not critical, however. The geometry in the communications connector imposes a number of equal distances, which lead to equal and cancelling crosstalk signals.
By this inverse distance assumption, the excitation (Vin) and response (Vout) are related by:
To maintain the dimensionless nature on both sides, kd is applied a distance constant to the right side of the equation. Between ckt1 and ckt2 in the example of the communications connector of
Case 1—excite ckt1 with dm excitation, observe ckt2 dm response;
Case 2—excite ckt1 with dm excitation, observe ckt2 cm response;
Case 3—excite ckt1 with cm excitation, observe ckt2 dm response; and
Case 4—excite ckt1 with cm excitation, observe ckt2 cm response.
Case 1—excite ckt1 with differential mode (dm) excitation, observe ckt2 dm response:
Apply +Va/2 to T1 and −Va/2 to R1, for a differential mode voltage of Va. If each terminal in circuit 1 is separated by a distance d from its nearest neighbor, this results in a differential response Vout2_dm on ckt2. If in the communications connector of
Case 2—excite ckt1 with dm excitation, observe ckt2 cm response:
Case 3—excite ckt1 with cm excitation, observe ckt2 dm response. Apply +Va to T1 and Va to R1, for a common mode voltage of Va.
Case 4—excite ckt1 with cm excitation, observe ckt2 cm response:
Less crosstalk could be obtained by decreasing the distance between the connector terminals in each pair while simultaneously increasing the distance between respective pairs of connector terminals. This configuration change decreases the overall crosstalk. In addition, this configuration change makes the distances between a given aggressor and victim more nearly equal, which can lead to beneficial crosstalk cancellation. This technique, however, suffers potential limitations:
1) the conductors or connector terminals of a pair can only be so close while still allowing adequate insertion space for wire wrap connections and sufficient breakdown voltage; and
2) wider spacing between the respective pairs may decrease density in an undesirable fashion.
The changed configuration of the communications connector shown in
Referring now to
The connector body 52 is formed typically from a dielectric material to prevent arcing between connector terminals and provide mechanical stability. Each Tip/Ring terminal pair 60, 62, 64, 66 is supported by the connector body and a female socket 70 also termed a terminal socket for each Tip/Ring terminal pair is formed within the terminal face 54. The ends of a respective Tip/Ring terminal pair are positioned within a respective socket 70 and permit insertion of a mating male connector plug or similar cable or other connector into the respective connector terminal pair positioned within the terminal socket. As shown in the front plan view of
In this non-limiting example shown in
In one non-limiting example, the connector body for the four Tip/Ring terminal pairs as illustrated in
An analysis of crosstalk measurements is now given for the communications connector of the configuration shown in
Case 1—excite ckt1 with dm excitation and observe ckt2 dm response. Apply +Va/2 to T1 and —Va/2 to R1 in ckt1 for a differential mode voltage of Va. By the symmetry of the geometry of the communications connector 50 such as shown in
Case 2—excite ckt1 with dm excitation, observe ckt2 cm response:
Case 3—excite ckt1 with cm excitation, observe ckt2 dm response:
Case 4—excite ckt1 with cm excitation, observe ckt2 cm response:
Owing to the symmetry of this communications connector 50 design as illustrated and explained above, dm-dm crosstalk is substantially perfect. The data transmission signals are carried as dm (differential mode signals), and the power in the common mode signal is negligible by design. Case 2 indicates the common mode signal resulting from differential excitation is also zero. The reciprocity theorem informs one that the calculated results are valid if the source and the receiver are swapped. Thus, these results apply for aggressors on pair 2 and receivers on pair 1 corresponding to ckt1 and ckt2.
Terminal Pair 1 to terminal Pair 3 (corresponding to ckt1 and ckt2 as Tip/Ring terminal pairs) does not have the same symmetry as Terminal Pair 1 to Terminal Pair 2, and so does not exhibit perfect crosstalk cancellation. Still, when compared with prior art connectors as analyzed above such as shown in
The communications connector shown in
The communications connector 50 can be formed to have the alternate horizontal and vertical orientations of the PC board connector pins along with a symmetric placement to cancel differential-differential crosstalk in the riser section of the connector pin. This is clearly shown in the view from below the communications connector. The riser section is defined as that part of the connector pin that rises from the PC board towards the right angle transition at the horizontal section as shown in
The pattern as shown results in a slight asymmetry. The portion of the T1 conductor parallel to the plane of the board is slightly longer than the same portion of the R1 conductor as shown in
As noted before,
Measurements were made for the 100-ohm crosstalk for the following cases with Vertical-Horizontal (VH); Horizontal-Vertical (HV); Vertical-Vertical (VV); Horizontal-Horizontal (HH), and for Vertical-Horizontal such as from ckt1 to ckt4 in
VH (T1-R1 to T2-R2)
HV (T2-R2 to T3-R3)
VV (T1-R1 to T3-R3)
HH (T2-R4 to T4-R4)
VHfar (T1-R1 to T4-R4)
The graphs shown in
Many modifications and other embodiments of the invention will come to the mind of one skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is understood that the invention is not to be limited to the specific embodiments disclosed, and that modifications and embodiments are intended to be included within the scope of the appended claims.
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