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.
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.
In one embodiment, 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.
In another embodiment, a grounding member is provided that holds the twin-ax wires in position for attachment to the conductors of a corresponding opposing backplane, or wafer connector. The grounding member includes a ground strip, or bar, that extends transversely to the wafer connector conductors. The grounding member preferably includes one or more cable clamps which extend out therefrom in a manner so as to provide a clamping nest that receives one of the twin-ax wires therein. The cable clamps include contact arms that are wrapped around the outer shielding of the twin-ax cable wires and which may be crimped therearound, or otherwise attached to the twin-ax outer shielding to ensure reliable electrical contact therebetween.
The ground strip preferably extends transversely to the twin-ax wires and the conductors of the wafer connectors. The ground strip is structured to support the cables in a predetermined spacing and this configuration may include depressions, or shoulders formed in the strip to provide a baseline, or datum for properly locating the twin-ax wire conductors. The free ends of the ground conductors may be offset in a selected plane beneath the centerlines of the twin-ax wire conductors. In this manner, the signal conductors of the twin-ax wires will be at or very close to the level of the wafer connector signal conductor mating surfaces. The ground strip is preferably welded to the wafer connector ground conductors, although other suitable manners of attachment in the art may be used.
The cable clamps may be crimped to the outer shielding members of each twin-ax cable and the cable clamps, the ground strip, free ends of the twin-ax cables and free ends of the connector terminals are disposed in a termination area of the wafer connector. This area is overmolded with a dielectric material that forms a solid mass that is joined to the connector frame. The ground strip commons the outer shielding members of the twin-ax wires together, as well as the ground terminals of the connector to provide a reliable ground path.
These and other objects, features and advantages of the Present Disclosure will be clearly understood through a consideration of the following detailed description.
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:
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.
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 wires can, in some instances, provide signal transmission lines from the chip/chip set to a connector location. In other instances, the cable wires may provide signal transmission lines between components on the circuit board, such as chips, processors, relays, amplifiers and the like, and even between nodes formed on or in the circuit board where different traces meet, and other connectors, such as backplane connectors.
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
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
The cable connector 62 of
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
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. (
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
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
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
In order to provide additional signal isolation, the wafers 80 may further includes one or more commoning members 104 (
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
The connector wafers 80 discussed above may also be used in a manner as illustrated in
A pair of such right angle connector wafers 130 are shown as part of the group of connector wafers illustrated in
In this embodiment, the one free ends of the terminals along the mounting sides 219 of the connectors 208 are formed as compliant pins 220, and they define mounting ends 222 of the terminals 212. These compliant pins 220 are received within vias located in the circuit board 202 (not shown). The other terminal free ends are structured as tail ends 224 with flat contact surfaces 225 that engage the free ends 213 of the signal conductors 205 of the twin-ax wires 204. The tail ends 224 of the first (signal) terminals 214 are contacted by the free ends 213 of the twin-ax wire signal conductors 205.
As illustrated in
One or more grounding nests, or cradles 230, are provided as part of the ground members 228 and these are spaced apart from the body portion 229 and connected thereto as illustrated. The nests 230 preferably have a plurality of elongated contact arms 231 that extend generally parallel to the body portion 229 and which are configured to permit them to be folded over the wires 204 during assembly such as by way of a crimping process to make electrical contact with the outer shielding member 209 of the twin-ax wires 204. The ground member 228 may further include contact legs, or tabs 232, that extend away from it at an angle, shown as extending perpendicularly in the Figures. The contact tabs 232 make contact with the tails of the ground terminals 216 of the wafer connector 208. These tabs 232 are connected to the ground terminal tails in a suitable manner, such as by welding, soldering, clamping or the like, with welding being the most useful manner of attachment.
The contact arms 231 of the ground member nests 230 are folded over onto the outer shielding members 209 of the corresponding twin-ax wires 204. The nests 230 are further preferably positioned with respect to the ground member 228 to position the signal conductor free ends 213 of the twin-ax wires 204 in a desired termination position where they contact the flat contact surfaces 225 of signal terminal tail ends 224, or very close thereto so as to require minimal bending of the signal conductors 205 into desired contact. These conductor free ends 213 may have flat portions formed thereon as shown in
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.
This Application is a continuation of U.S. application Ser. No. 15/641,777, filed Jul. 5, 2017, now U.S. Pat. No. TBD, which is a continuation of U.S. application Ser. No. 15/433,749, filed Feb. 15, 2017, now U.S. Pat. No. TBD, which in turn is a continuation of U.S. application Ser. No. 15/290,638, filed Oct. 11, 2016, now U.S. Pat. No. 9,608,348, which in turn is a continuation of U.S. application Ser. No. 15/162,264, filed May 23, 2016, now U.S. Pat. No. 9,490,558, which in turn is a continuation of U.S. application Ser. No. 14/973,095 filed Dec. 17, 2015, now U.S. Pat. No. 9,362,678, which is a continuation of U.S. application Ser. No. 14/829,319, filed Aug. 18, 2015, now U.S. Pat. No. 9,257,794, which is a continuation of and claims priority to U.S. application Ser. No. 14/486,838, filed Sep. 15, 2014, now U.S. Pat. No. 9,142,921, which is a Continuation-In-Part application of and claims priority to U.S. application Ser. No. 13/779,027, filed on Feb. 27, 2013, now U.S. Pat. No. 8,845,364, all of which are incorporated herein by reference in their entirety.
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