High speed bypass cable for use with backplanes

Abstract

A cable bypass assembly is disclosed for use in providing a high speed transmission line for connecting a chip, or processor mounted on a circuit board to a backplane. The bypass cable assembly has a structure that maintains the geometry of the cable in place from the chip to the connector and then through the connector. The connector includes a plurality of conductive terminals and shield members arranged within an insulative support frame in a manner that approximates the structure of the cable so that the impedance and other electrical characteristics of the cable may be maintained as best is possible through the cable termination and the connector.

Description

BACKGROUND OF THE PRESENT DISCLOSURE

The Present Disclosure relates, generally, to cable interconnection systems, and, more particularly, to bypass cable interconnection systems for transmitting high speed signals at low losses from chips or processors to backplanes.

Conventional cable interconnection systems are found in electronic devices such as routers, servers and the like, and are used to form signal transmission lines between a primary chip member mounted on a printed circuit board of the device, such as an ASIC, and a connector mounted to the circuit board. The transmission line typically takes the form of a plurality of conductive traces that are etched, or otherwise formed, on or as part of the printed circuit board. These traces extend between the chip member and a connector that provides a connection between one or more external plug connectors and the chip member. Circuit boards are usually formed from a material known as FR-4, which is inexpensive. However, FR-4 is known to promote losses in high speed signal transmission lines, and these losses make it undesirable to utilize FR-4 material for high speed applications of about 10 Gbps and greater. This drop off begins at 6 GBps and increases as the data rate increases. Custom materials for circuit boards are available that reduce such losses, but the prices of these materials severely increase the cost of the circuit board and, consequently, the electronic devices in which they are used. Additionally, when traces are used to form the signal transmission line, the overall length of the transmission line typically may well exceed 10 inches in length. These long lengths require that the signals traveling through the transmission line be amplified and repeated, thereby increasing the cost of the circuit board, and complicating the design inasmuch as additional board space is needed to accommodate these amplifiers and repeaters. In addition, the routing of the traces of such a transmission line in the FR-4 material may require multiple turns. These turns and the transitions that occur at terminations affect the integrity of the signals transmitted thereby. It then becomes difficult to route transmission line traces in a manner to achieve a consistent impedance and a low signal loss therethough.

It therefore becomes difficult to adequately design signal transmission lines in circuit boards, or backplanes, to meet the crosstalk and loss requirements needed for high speed applications. It is desirable to use economical board materials such as FR4, but the performance of FR4 falls off dramatically as the data rate approaches 10 Gbps, driving designers to use more expensive board materials and increasing the overall cost of the device in which the circuit board is used. Accordingly, the Present Disclosure is therefore directed to a high speed, bypass cable assembly that defines a transmission line for transmitting high speed signals, at 10 GBps and greater which removes the transmission line from the body of the circuit board or backplane, and which has low loss characteristics.

SUMMARY OF THE PRESENT DISCLOSURE

Accordingly, there is provided an improved high speed bypass cable assembly that defines a signal transmission line useful for high speed applications at 10 GBps or above and with low loss characteristics.

In accordance with an embodiment described in the Present Disclosure, an electrical cable assembly can be used to define a high speed transmission line extending between an electronic component, such as a chip, or chip set, and a predetermined location on a backplane. Inasmuch as the chip is typically located a long length from the aforesaid location, the cable assembly acts a signal transmission line that that avoids, or bypasses, the landscape of the circuit board construction and which provides an independent signal path line that has a consistent geometry and structure that resists signal loss and maintains its impedance at a consistent level without great discontinuity.

In accordance with the Present Disclosure, the cable may include one or more cables which contain dedicated signal transmission lines in the form of pairs of wires that are enclosed within an outer, insulative covering and which are known in the art as “twin-ax” wires. The spacing and orientation of the wires that make up each such twin-ax pair can be easily controlled in a manner such that the cable assembly provides a transmission line separate and apart from the circuit board, and which extends between a chip or chip set and a connector location on the circuit board. Preferably, a backplane style connector is provided, such as a pin header or the like, which defines a transition that does not inhibit the signal transmission. The cable twin-ax wires are terminated directly to the termination tails of a mating connector so that crosstalk and other deleterious factors are kept to a minimum at the connector location.

The signal wires of the bypass cable are terminated to terminal tails of the connector which are arranged in a like spacing so as to emulate the ordered geometry of the cable. The cable connector includes connector wafers that include ground terminals that encompass the signal terminals so that the ground shield(s) of the cable may be terminated to the connector and define a surrounding conductive enclosure to provide both shielding and reduction of cross talk. The termination of the wires of the bypass cable assembly is done in such a manner that to the extent possible, the geometry of the signal and ground conductors in the bypass cable is maintained through the termination of the cable to the board connector. The cable wires are preferably terminated to blade-style terminals in each connector wafer, which mate with opposing blade portions of corresponding terminals of a pin header. The pin header penetrates through the intervening circuit board and the pins of the header likewise mate with like cable connectors on the other side of the circuit board. In this manner, multiple bypass cable assemblies may be used as signal transmission paths. This structure eliminates the need for through-hole or compliant pin connectors as well as avoids the need for long and possibly complex routing paths in the circuit board. As such, a designer may use inexpensive FR4 material for the circuit board construction, but still obtain high speed performance without degrading losses.

The signal conductors of the twin-ax cables are terminated to corresponding signal terminal tail portions of their respective corresponding connector wafers. The grounding shield of each twin-ax pair of wires is terminated to two corresponding ground terminal tail portions which flank the pair of signal terminals. In this manner, each pair of signal terminals is flanked by two ground terminals therewithin. The connector wafers have a structure that permits them to support the terminals thereof in a G-S-S-G pattern within each wafer. Pairs of wafers are mated together to form a cable connector and, when mated together, the signal terminals of one wafer are flanked by ground terminals of an adjacent wafer. In this manner, the cable twin-ax wires are transitioned reliably to connector terminals in a fashion suitable for engaging a backplane connector, while shielding the cable wire signal pairs so that any impedance discontinuities are reduced.

Grounding cradles are provided for each twin-ax wire pair so that the grounding shield for each twin-ax wire may be terminated to the two corresponding grounding terminals that flank the pair of the interior signal terminals. In this manner, the geometry and spacing of the cable signal wires is maintained to the extent possible through the connector termination area. The connector terminals are configured to minimize the impedance discontinuity occurring through the connector so that designed impedance tolerances may be maintained through the connector system.

These and other objects, features and advantages of the Present Disclosure will be clearly understood through a consideration of the following detailed description.

BRIEF DESCRIPTION OF THE FIGURES

The organization and manner of the structure and operation of the Present Disclosure, together with further objects and advantages thereof, may best be understood by reference to the following Detailed Description, taken in connection with the accompanying Figures, wherein like reference numerals identify like elements, and in which:

FIG. 1 is a plan view of a typical backplane system with a chipset being interconnected to a series of backplane connectors;

FIG. 2 is a plan view of a backplane system utilizing bypass cable assemblies constructed in accordance with the Present Disclosure;

FIG. 2A is a perspective sectional view of a multi-wire cable used in conjunction with cable bypass assemblies of the Present Disclosure;

FIG. 3 is a perspective view, partially exploded, of a pin header utilized in the backplane system of FIG. 2, with a cable connector engaged therewith and a mating backplane connector disengaged and spaced apart therefrom;

FIG. 4 is an enlarged view of the backplane cable connector of FIG. 2;

FIG. 5 is a perspective view of a backplane connector and a cable connector of the Present Disclosure;

FIG. 6 is the same view as FIG. 5, but with the two connectors mated together;

FIG. 7 is an exploded view of the cable connector of FIG. 5, with the two frame members separated from each other and with the overmolding removed to illustrate the cable wire termination area of the connector;

FIG. 7A is an enlarged detail view of the rightmost connector frame member of FIG. 7, illustrating the alignment of the connector terminal tails and the arrangement of the cable wire signal conductor free ends;

FIG. 7B is an enlarged detail view of the leftmost connector frame member of FIG. 7, illustrating the use of a ground shield cradle that permits termination of the cable wire grounding shield to two ground terminal tail portions flanking a pair of signal terminal tail portions of the connector;

FIG. 7C is the same view as FIG. 7, but with the commoning members in place on the leftmost connector frame member;

FIG. 7D is the same view as FIG. 7, but with the connector frame members joined together;

FIG. 8 is the same view as FIG. 7, but with the termination area of the connector frame members filled in with a plastic or other suitable material;

FIG. 8A is the same view as FIG. 7, but with the connector frame members joined together, the commoning members inserted and with the termination areas overmolded;

FIG. 9 is a perspective view of the two connector frame members of FIG. 7, brought together as a single connector and with the top portion thereof removed to illustrate the engagement of the commoning member with the two types of ground terminals and illustrating how the terminals are spaced apart from each other within the connector;

FIG. 9A is a top plan view of the single connector of FIG. 9;

FIG. 10 is a perspective view of the two terminal sets utilized in the connector of FIG. 8A, with the connector frame member removed for clarity;

FIG. 10A is a top plan view of the terminal sets of FIG. 10;

FIG. 10B is a side elevational view of the terminal sets of FIG. 8A;

FIG. 10C is a side elevational view of the leftmost terminal set of FIG. 10;

FIG. 10D is the same view as FIG. 10, but with the rightmost terminal set removed for clarity;

FIG. 11 is a partial sectional view of the rightmost connector frame member of FIG. 7C, taken along the level of the terminal tail and mating blade portions thereof, with the termination area filled with an overmolding material;

FIG. 12 is a partial sectional view of the rightmost connector frame member of FIG. 7C, taken from the far side thereof and taken along the level of the terminal body portions; and

FIG. 13 is a view illustrating, in detail, area “A” of FIG. 3, which illustrates an angled cable connector constructed in accordance with the principles of the Present Disclosure mated with a backplane connector of the pin header style.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

While the Present Disclosure may be susceptible to embodiment in different forms, there is shown in the Figures, and will be described herein in detail, specific embodiments, with the understanding that the Present Disclosure is to be considered an exemplification of the principles of the Present Disclosure, and is not intended to limit the Present Disclosure to that as illustrated.

As such, references to a feature or aspect are intended to describe a feature or aspect of an example of the Present Disclosure, not to imply that every embodiment thereof must have the described feature or aspect. Furthermore, it should be noted that the description illustrates a number of features. While certain features have been combined together to illustrate potential system designs, those features may also be used in other combinations not expressly disclosed. Thus, the depicted combinations are not intended to be limiting, unless otherwise noted.

In the embodiments illustrated in the Figures, representations of directions such as up, down, left, right, front and rear, used for explaining the structure and movement of the various elements of the Present Disclosure, are not absolute, but relative. These representations are appropriate when the elements are in the position shown in the Figures. If the description of the position of the elements changes, however, these representations are to be changed accordingly.

FIG. 1 is a plan view of a conventional circuit board, or backplane assembly 49 that has a primary circuit board 50 that is connected to another, secondary circuit board 52 by way of an intervening circuit board, or backplane 54. The primary circuit board 50 has an array of electronic components disposed on it, including a chip set 56 that may include a base processor 58 or the like as well as a plurality of ancillary chips or processors 60. The chips 58, 60 may take the form of a PHY Chip, or any other surface-mounted, physical layer device, known in the art, from which a high speed signal is generated, such as an ASIC or the like. The primary circuit board 50 is provided with a plurality of circuit paths that are arranged in various layers of the board and which are formed from conductive traces 61. These conductive traces 61 sometimes follow long and torturous paths as they traverse the circuit board 50 from the chipset 56 to another location of the circuit board 50, such as a termination area near the edge of the circuit board 50 where a series of connectors 62 are mounted. The connectors 62 mate with corresponding mating connectors 63, mounted on the backplane 54 and these connectors 63 may commonly be of the pin header style, having an insulative body 66 and a plurality of conductive pins, or blades 67, that extend outward therefrom and which are contacted by opposing terminals of the connectors 62. The pins 67 of the connector 63 extend through the intervening circuit board 54 where they may mate with other connectors 65 disposed on the opposite side and on the secondary circuit board 52.

The board connectors 62, 65 typically utilize compliant mounting pins (not shown) for connecting to the circuit boards 50, 52. With compliant mounting pins, not only does the circuit board 50, 52 need to have mounting holes drilled into it and plated vias formed therein, but the risk exists that the plated vias may retain stub portions that act as unterminated transmission lines which can degrade the transmitted signals and contribute impedance discontinuities and crosstalk. In order to eliminate stubs and their deleterious effects on high speed signal transmission, vias need to be back-drilled, but this modification to the circuit board adds cost to the overall system. Long conductive traces 61 in circuit board material, such as FR4, become lossy at high speeds, which adds another negative aspect to high speed signal transmission on low cost circuit boards. High data speeds are those beginning at about 5 Ghz and extending to between about 10 and about 15 Ghz as well as speeds in excess thereof. There are ways to compensate for these losses such as utilizing chip clock data recovery systems, amplifiers or repeaters, but the use of these systems/components adds complexity and cost to the system.

In order to eliminate the inherent losses that occur in FR4 and other inexpensive, similar circuit board materials, we have developed a bypass cable system in which we utilize multi-wire cables for high speed, differential signal transmission. The cable wire provide signal transmission lines from the chip/chip set to a connector location. These cables take the transmission line off of the circuit boards 50, 52 and utilize wires, primarily wires of the twin-ax construction to route a transmission line from the chipset to another location on the circuit board 50, 52. In this application, the cable terminus is a backplane-style connector 62, 65. As shown best schematically in FIG. 2, a series of bypass cable assemblies 66, each including a plurality of twin-ax wires 69, are provided and they are connected at one end thereof to the chips 58, 60 and to backplane connectors 62, 65 at their opposite ends. These connectors 62, 65 mate with the pin header connectors 63 on the intervening circuit board 54 and provide a passage through that circuit board 54 between the primary and secondary circuit boards 50, 52.

The bypass cable assemblies 66 include a flexible circuit member, shown in the Figures as a multiple wire cable 68. The cable 68, as shown in FIG. 2A, may include an outer covering that contains a plurality of signal transmission wires 69, each of which contains two signal conductors 70a, 70b that are arranged in a spaced-apart fashion that is enclosed by an insulative portion 71. The insulative portion 71 of each such twin-ax wire 69 typically includes a conductive outer shield 72 that encloses the insulative portion 71 and its signal conductors 70a-b. The multiple cable wires 69 may be enclosed as a group by an outer insulative covering, which is shown in phantom in the Figures, or it may include only a plurality of the twin-ax wires. The signal conductors 70a-b, as is known in the art, are separated by a predetermined spacing and are used to transmit differential signals, i.e., signals of the same magnitude, but different polarity, such as +0.5 v and −0.5 v. The structure of the twin-ax wires lends itself to uniformity throughout its length so that a consistent impedance profile is attained for the entire length of the wires 69, or cables 68. The cable assemblies 66 of this Present Disclosure may include as few as one or two twin-ax wires, or they may include greater numbers as shown in the Figures.

FIGS. 5-12, depict one embodiment of a cable assembly and cable connector of the Present Disclosure, particularly suitable for mating the cable connector to a backplane style connector. It can be seen that the cable wires 69 are terminated to the cable connectors 62, and the cable connectors 62 are preferably formed from two halves, in the form of connector wafers 80, two of which are mated together in a suitable manner to form a connector. The wafers 80 are configured to mate in pairs with an opposing connector 63, such as the pin header 81 illustrated in FIG. 3, or a right angle connector 89 also be formed from two wafers 89a-b that support a plurality of conductive signal and ground terminals 89c. The terminals 89c terminate in mating ends that may take the form of cantilevered beams (not shown) that are held within an exterior shroud 89d, which contains a plurality of passages 89e. Each passage 89e is configured to receive one of the mating portions 90, 93 of the signal terminals 86a-b and the ground terminals 87a-b as shown in FIGS. 5-6. Such a connector arrangement shown in these Figures will be suitable for mating circuits on a primary circuit board 50 to those on a secondary circuit board 52. FIGS. 3-4 illustrate a connector arrangement that is suitable for use for connecting circuits through an intervening circuit board 54.

The cable connector 62 of FIG. 5 may be used to mate with a right angle connector 89 as shown in FIG. 5 or may be used, with some modification, to mate directly with the pin header connector 81 of FIGS. 3-4. Turning to FIG. 7, each wafer 80 can seen to have a frame member 84, preferably molded from an insulative material that provides a skeletal frame that supports both the cable wires 69 and the terminals of the cable connector 62. Each connector wafer 80 is preferably provided with distinct signal terminals 86 and ground terminals 87 that are arranged in a row upon the connector wafer 80. The signal terminals 86 in each row are themselves arranged in pairs of terminals 86a-b which are respectively connected to the cable wire signal conductors 70a-b. In order to maintain appropriate signal isolation and to further mirror the geometry of the cable wires 68, the pairs of signal terminals 86a, 86b are preferably flanked by one or more of the ground terminals 87, within each row of each connector wafer 80. The frame member 84, as illustrated, also may have a plurality of openings 97 formed therein that expose portions of the signal and ground terminals 86a-b & 87a-b to air for coupling between terminals of connected wafers 80 and for impedance control purposes. These openings 97 are elongated and extend vertically along the interior faces of the connector wafers 80 (FIG. 8), and are separated into discrete openings by portions of the frame 84 along the exterior faces of the connector wafers 80. They provide an intervening space filled with an air dielectric between terminals within a connector wafer pair as well as between adjacent connector wafer pairs.

The arrangement of the terminals of the wafers 80 is similar to that maintained in the cable wires 69. The signal terminals 86a-b are set at a desired spacing and each such pair of signal terminals, as noted above, has a ground terminal 87 flanking it. To the extent possible, it is preferred that the spacing between adjacent signal terminals 86a-b is equal to about the same spacing as occurs between the signal conductors 70a-b of the cable wires 69 and no greater than about two to about two and one-half times such spacing. That is, if the spacing between the signal conductors 70a-b is L, then the spacing between the pairs of the connector signal terminals 86a,b (shown vertically in the Figures) should be chosen from the range of about L to about 2.5 L This is to provide tail portions that may accommodate the signal conductors of each wire 69 in the spacing L found in the wire. Turning to FIG. 10C, it can be seen that each signal terminal 86a,b has a mating portion 90, a tail portion 91 and a body portion 92 that interconnects the two portions 90, 91 together. Likewise, each ground terminal includes a mating portion 93, a tail portion 94 and a body portion 95 interconnecting the mating and tail portions 93, 94 together.

The terminals within each connector wafer 80 are arranged, as illustrated, in a pattern of G-S-S-G-S-S-G-S-S-G, where “S” refers to a signal terminal 86a, 86b and “G” refers to a ground terminal 87a, 87b. This is a pattern shown in the Figures for a wafer 80 that accommodates three pairs of twin-ax wires in a single row. This pattern will be consistent among wafers 80 with a greater or lesser number of twin-ax wire pairs. In order to achieve better signal isolation, each pair of signal terminals 86a, 86b are separated from adjacent signal terminal pairs other by intervening ground terminals 87a, 87b. Within the vertical rows of each connector wafer 80, the ground terminals 87a-b are arranged to flank each pair of signal terminals 86a-b. The ground terminals 87a-b also are arranged transversely to oppose a pair of signal terminals 86a-b in an adjacent connector wafer 80 (FIG. 7C).

The ground terminals 87a, 87b of each wafer 80 may be of two distinct types. The first such ground terminal 87a, is found at the end of an array, shown at the top of the terminal row of FIG. 10C and may be referred to herein as “outer” or “exterior” ground terminal as it are disposed in the connector wafer 80 at the end(s) of a vertical terminal row. These terminals 87a alternate being located at the top and bottom of the terminal arrays in adjacent connector wafers 80 as the terminal rows are offset from each other as between adjacent connector wafers. The second type of ground terminal 87b is found between pairs of signal terminals, and not at the ends of the terminal arrays, and hence are referred to herein as “inner” or “interior” ground terminals 87b. In this regard, the difference between the two ground terminals 87a, 87b is that the “inner” ground terminals 87b have wider tail, body and mating portions. Specifically, it is preferred that the body portions of the inner ground terminals 87b be wider than the body portions of the outer ground terminals 87a and substantially wider (or larger) than the body portions 92 of the corresponding pair of signal terminals 86a-b which the inner ground terminals 87b oppose, i.e., those in a signal terminal pair in an adjacent wafer. The terminals in the rows of each connector wafer 80 differ among connector wafers so that when two connector wafers are assembled together as in FIG. 5, the wide ground terminals 87b in one connector wafer row of terminals flank, or oppose, a pair of signal terminals 86a-b. This structure provides good signal isolation of the signal terminals in each signal terminal pair. If one were to view a stack of connector wafers from their collective mating end, one would readily see this isolation. This reduces crosstalk between the signal terminals of one pair and other signal terminal pairs.

The second ground terminals 87b preferably include openings, or windows 98, 99 disposed in their body portions 95 that serve to facilitate the anchoring of the terminals to the connector frame body portion 85b. The openings 98, 99 permit the flow of plastic through and around the ground terminals 87a-b during the insert molding of the connectors. Similarly, a plurality of notches 100, 102 are provided in the edges of the signal terminal body portions 92 and the body portions 95 of ground terminals opposing them. These notches 100, 102 are arranged in pairs so that they cooperatively form openings between adjacent terminals 86a, 86b that are larger than the terminal spacing. These openings 100, 102 similar to the openings 98, 99, permit the flow of plastic during insert molding around and through the terminals so that the outer ground terminals 87b and signal terminals 86a,b are anchored in place within the connector wafer 80. The openings 98, 99 and notches 100, 102 are aligned with each other vertically as shown in FIG. 10C.

In order to provide additional signal isolation, the wafers 80 may further includes one or more commoning members 104 (FIGS. 7-9) that take the form or bars, or combs 105, with each such member having an elongated backbone portions 106 and a plurality of tines, or contact arms, 107 that extend outwardly therefrom at an angle thereto. The combs 105 are received within channels 110 that are formed in the wafers 80, and preferably along a vertical extent thereof. The tines 107 are received in passages 112 that extend transversely through the connector wafers so that they may contact the ground terminals 87a-b. As shown in FIG. 10D, the tines 107 extend through the two mated connector wafers 80 and contact both of the ground terminals on the left and right sides of the pair of connector wafers 80, which further increases the isolation of the signal terminals 86a-b (FIG. 9).

In furtherance of maintaining the geometry of the cable wires 68, the outer insulation 71 and grounding shield 72 covering each twin-ax wire 69 are cut off and peeled back, to expose free ends 114 of the signal conductors 70a-b. These conductor free ends 114 are attached to the flat surfaces of the signal terminal tail portions 91. The grounding shield 72 of each twin-ax wire 69 is connected to the ground terminals 87a-b by means of a grounding cradle 120. The cradle 120 has what may be considered a cup, or nest, portion, 121 that is formed in a configuration generally complementary to the exterior configuration of the cable wire 69, and it is provided with a pair of contact arms 122a-b which extend outwardly and which are configured for contacting opposing, associated ground terminal tail portions 94 of the connector wafers 80.

The two contact arms 122a-b are formed along the outer edges of the cup portion 121 so that contact surfaces 124 formed on the contact arms 122a-b are preferably aligned with each other along a common plane so that they will easily engage opposing surfaces of the ground terminal tail portions for attachment by welding or the like. The grounding cradles 120 may also be formed as a ganged unit, where a certain number of cradles 120 are provided and they are all interconnected along the contact arms 122a-b thereof. The cup portions 121 are generally U-shaped and the U is aligned with the pair of signal terminal tail portions so that the signal terminal tail portions would be contained within the U if the cup portion 121 were extended or vice-versa. In this manner, the geometry of the twin-ax wires is substantially maintained through the termination of the cable wires 69 with minimal disruption leading to lessened impedance discontinuities. Thus, the high speed signals of the chip set 56 are removed from passage directly on the circuit boards 50, 52, and the use of vias for the board connectors is eliminated. This not only leads to a reduction in cost of formation and manufacture of the circuit board, but also provides substantially complete shielding at the connection with the cable connector without any excessive impedance discontinuity.

As shown in FIG. 10A, the spacing between the connector wafer terminal tail portions of adjacent connector wafers is first at a predetermined spacing, then the spacing lessens where the terminal body portions are held in the connector frame and then the spacing increases at the terminal mating portions to a spacing that is greater than the predetermined spacing. The reduction in spacing along the terminal body portions takes into account the effect of the wider body portions of the ground terminals 87b and thus the spacing between the connector wafers in a pair of connector wafers varies in order to lessen any impedance discontinuities that arise. FIG. 10B illustrates how the wider ground terminal 87b in one vertical array are vertically offset from the other ground terminal 87a in the other, adjacent terminal array. This offset arrangement can also be determined from the order of the terminal-receiving passages 89e of the opposing mating connector 89 of FIG. 5. The connector wafer termination area 85c is preferably overmolded with a plastic 116 so as to cover the welds or solder used to attach the cable wire free ends 114 to their respective terminal tail portions and seal the termination area. Additional windows 117 may be formed in this overmolded portion to provide an air-filled passage between the signal terminal tail portions and the wire conductors 70a-b of each cable wire pair.

The connector wafers 80 discussed above may also be used in a manner as illustrated in FIGS. 3-4, where the terminal mating portions extend through the body of a backplane connector such as the pin header shown and into a channel defined between two sidewalls on the other side of an intervening circuit board 54. An opposing, mating right angle connector 89 similar to that shown in FIG. 5 is provided to fit into the space between the connector sidewalls 82 in order to effect an connection at a right angle to the intervening circuit board 54. In this embodiment, the terminal mating portions 90, 93 may take the form of flat mating blades or pins. The cable wires 69 associated with some of the connector wafers are in line with the terminal mating portions, but there may be instances where it is desired to have the cable wires 69 attached to the connector wafers in an angled fashion.

A pair of such right angle connector wafers 130 are shown as part of the group of connector wafers illustrated in FIGS. 3-4. The use of a right angle exit point from the connector wafer frees up some space at the rear ends of the group of connector wafers. FIG. 13 illustrates a partial sectional view of such a connector wafer 130. The terminals of the connector are formed with bends 132 in them so that the signal terminal tail portions 91 and ground terminal tail portions 94 are aligned with the entry point of the twin-ax wires 69 into the connector wafer frame 84. Ground cradles such as those described above are used to make contact with the outer conductive shielding 72 of the wires and utilize contact arms to attach to the ground terminal tail portions 94. In such an arrangement, the ground cradles are better being used in a ganged fashion.

While a preferred embodiment of the Present Disclosure is shown and described, it is envisioned that those skilled in the art may devise various modifications without departing from the spirit and scope of the foregoing Description and the appended Claims.

Claims

1. An improved bypass cable assembly for connecting a chip to a backplane, comprising: a cable, the cable including multiple wires, each wire having an insulative body portion with a pair of signal conductors extending lengthwise through the insulative body portion, the pair of signal conductors being separated by a first spacing, and a conductive shielding member surrounding the insulative body portion, each wire having opposing first and second free ends; anda connector, the connector including an insulative frame member that supports a plurality of conductive first and second terminals in at least one row, each of the first and second terminals including contact and tail portions disposed at opposite ends thereof, the contact and tail portions being interconnected by respective terminal body portions, the wire conductors being attached to corresponding ones of the first terminal tail portions and the shielding member being attached to the corresponding ones of the second terminal tail portions, the first and second terminals being further arranged in a pattern, whereby pairs of the first terminals in the row are separated from other pairs of the first terminals by at least one intervening second terminal, the first terminal tail portions being spaced apart from each other in a spacing intended to maintain an approximate spacing of the cable wire free ends terminated thereto.

2. The bypass cable assembly of claim 1, wherein the connector includes first and second connector wafers, each connector wafer respectively supporting one row of the first and second terminals.

3. The bypass cable assembly of claim 2, wherein the row of terminals supported by the first connector wafer is offset from the row of terminal supported by the second connector wafer.

4. The bypass cable assembly of claim 2, wherein the first and second terminals are arranged in the rows of the first and second connector wafers such that for any pair of first terminals on one of the first and second connector wafers, a second terminal is disposed on the other of the first and second connector wafers in opposition to the pair of first terminals.

5. The bypass cable assembly of claim 1, wherein the connector is formed from two connector wafers, the first and second terminals being supported by the first and second connector wafers so that first terminals supported by the first connector wafer oppose second terminals supported by the second connector wafer, and the first terminals supported by the second connector wafer oppose second terminals supported by the first connector wafer.

6. The bypass cable assembly of claim 1, wherein the connector further includes a plurality of conductive grounding cradles, each grounding cradle being configured to contact a wire conductive shield member at the cable first end, each grounding cradle including at least two spaced apart mounting feet spaced apart from each other for engaging tail portions of the second terminals.

7. The bypass cable assembly of claim 6, wherein the grounding cradles include generally U-shaped nest portions.

8. The bypass cable assembly of claim 6, wherein two of the grounding cable mounting feet and the cable wire signal conductor free ends are aligned with each other within a termination area of the connector frame member.

9. The bypass cable assembly of claim 6, wherein the grounding cradles are interconnected along the mounting feet.

10. The bypass cable assembly of claim 1, wherein the first terminal mating portions have a first width and the second terminal mating portions interposed between two first terminal mating portions have a second width, the second width being greater than the first terminal width.

11. The bypass cable assembly of claim 1, wherein the second terminals have a width that varies along their length from the tail portions thereof to the contact portions thereof.

12. The bypass cable assembly of claim 1, wherein the connector frame member includes a plurality of openings formed therein that expose portions of the first and second terminals to air.

13. The bypass cable assembly of claim 1, wherein the connector frame defines a termination area that receives free ends of the cable wires and a mating area for engaging an opposing connector, the termination area being filled with a dielectric material enclosing the cable wire free ends and the first and second terminal tail portions.

14. The bypass cable assembly of claim 1, wherein the first and second terminal tail portions extend at an angle to their respective corresponding first and second terminal body portions.

15. The bypass cable assembly of claim 1, wherein the cable wire signal conductors are spaced apart from each other in a first spacing, and the cable shielding member is spaced apart from the signal conductors by a second spacing; and pairs of the first terminal tail portions are separated from each other by the first spacing, and the second terminal tail portions are spaced apart from adjacent signal terminal tail portions by the second spacing.

16. The bypass cable assembly of claim 2, wherein the connector further includes a commoning member supported by one of the connector wafers and the commoning member has a plurality of tines that extend transversely through the first and second connector wafers.

17. The bypass cable assembly of claim 1, wherein the tines contact the second terminals in each row of terminals in the first and second connectors.

18. A connector for connecting a plurality of wires to an opposing connector, each wire including a pair of signal conductors extending lengthwise therethrough in an insulative body, the pair of signal conductors being spaced apart from each other in a first spacing, and a grounding shield extending over an exterior surface of the wire insulative body and being spaced a second spacing from said wire signal conductors, the connector comprising: an insulative connector body defining a connector mating area, body area and termination area; anda plurality of conductive terminals, each terminal including a mating portion disposed in the mating area of the connector body, a body portion disposed in the body area of the connector body and a tail portion disposed in the termination area of the connector body, the terminals including first terminals for transmission of signals from the wire signal conductors and second terminals for grounding the wire grounding shield, the terminals being supported the connector in separate rows of terminals and being arranged in each row in pairs of signal terminals and at least one ground terminal interposed between each pair of signal terminals.

19. The wire connector of claim 18, wherein the connector includes first and second connector wafers assembled together such that the first connector wafer supports a first row of terminals and the second connector wafer supports a second row of terminals, the second terminals in each of the first and second terminal rows facing a pair of signal terminals in an adjacent row.

20. The wire connector of claim 19, wherein the connector further includes a commoning member that extends generally parallel to said terminal rows, the commoning member including a plurality of contact arms that extend transversely through the connector body and into contact with the second terminals.