This disclosure relates to field of connectors suitable for use in high data rate applications.
Backplane connectors, which are not limited to use in backplane applications, are generally designed to provide certain mechanical features. Common features include high numbers of pins per linear inch, mechanical robustness, and the ability to support high data rates. While there are a number of applications where older connectors are suitable, new connectors designed for backplane applications now are expected to support at least 25 Gbps data rates and certain applications are looking to extend to data rates as high as 56 Gbps.
A backplane connector, while possible to be provided in a variety of different configurations, often will be provided in either a mezzanine configuration (supporting two parallel circuit boards) or an orthogonal configuration (supporting two circuit boards that are orthogonal to each other). The orthogonal configuration is more common because it allows for a bottom main circuit board and a number of secondary circuit boards (often referred to as daughter cards) that are positioned parallel to each other but orthogonal to the main circuit board. Each daughter card can support one or more integrated circuits (IC) that provides the desired processing functionality.
One issue with orthogonal configurations is that there is a need to translate from a first right angle connector to a second right angle connector that is rotated 90 degrees from the first right angle connector. This has typically been accomplished by using an adaptor piece between two right angle connectors. One common configuration has been to have the adaptor piece consist of a circuit board with two header connectors mounted on both sides of the circuit board. The header connectors each provide a 45-degree rotation and collectively provide the desired 90-degree rotation. Due to the issues related to signal integrity (which becomes more problematic as data rates increase), the use of a circuit board in an adaptor is less desirable. Consequentially, improved adaptors have been developed that offer improved performance. However, it turns out that each mating interface provides the potential for signal reflections and further signal loss and therefore further improvements would be appreciated.
A connector system can be configured so that it provides desirable signal integrity. The connector system includes a first connector that can provide a 90-degree right angle configuration and includes a second connector that includes a right-angle configuration with a 90-degrees twist at a mating interface. When mated together, the first and second connectors provide an orthogonal arrangement that offers performance and cost improvements while allowing signal pairs to communicate from one board to another with a single interface junction. As can be appreciated, a U-shaped ground shield can be provided for each signal terminal pair. A shield can further be provided on each wafer to improve electrical performance. The depicted configuration allows for high data rates in a dense package while minimizing the number of components and providing for desirable signal integrity.
The present disclosure is illustrated by way of example and not limited in the accompanying figures in which like reference numerals indicate similar elements and in which:
The detailed description that follows describes exemplary embodiments and is not intended to be limited to the expressly disclosed combination(s). Therefore, unless otherwise noted, features disclosed herein may be combined together to form additional combinations that were not otherwise shown for purposes of brevity.
The depicted configurations illustrate features that can be used to provide a connector system that can be used in a backplane configuration with a first connector and a second connector. The first connector can be a right-angle connector. The second connector can be a right-angle connector with a 90-degree twist. As can be appreciated, the twist is possible due to the fact that the second connector includes signal terminals that have a contact that is blanked and formed. As can be further appreciated, the ground shield is provided in a U-shaped shielding arrangement that at least partially encloses a pair of signal terminals to help provide shielding. In the depicted embodiment the U-shaped shielding configuration is provided substantially along an entire length of the terminals path from the first circuit board to a mating interface and from the mating interface to a second circuit board and there is also shielding in the mating interface between the signal terminals of the first connector and signal terminals of the second connector, thus allowing for shielding on three sides of a particular terminal pair. Thus, the depicted configuration provides a potentially high performing and suitably dense configuration.
Turning to the FIGS., an embodiment of a connector system 10 includes a connection between a first circuit board 6 and a second circuit board 8 that are positioned orthogonally to each other. Specifically, a connector 100 is mounted on the circuit board 8 and is configured to mate with a connector 200 mounted on the circuit board 6. The connector 100 includes a shroud 110 that helps support a wafer set 140 that includes a plurality of wafers 150, which each include a frame 155, formed of an insulative material, that supports terminals as will be discussed below. To help provide additional stability and performance, the connector 100 includes an insert 120 that supports a plurality of U-shields 125. The insert 120 includes a first face 121a and a second face 121b. A tail aligner 130, which can be plated plastic and have electrical commoning features between ground shields, can be provided to help support the tails while a plurality of combs 112 can be used to help hold the wafer set 140 in a desired alignment and orientation.
As can be appreciated, the shroud 110 can be configured to be connected to the supporting circuit board and may be fastened to the circuit board if desired. The structure of the shroud 110, in combination with the use of the combs 112, allows for the elimination of an additional housing to support the wafer set 140.
In should be noted that the insert 120 is depicted as a separate component mounted in the shroud 110. The insert 120 can be formed of an insulative material and includes a conductive path (which can be formed in a desired manner via separate terminals or plating) that allows the insert 120 to electrically connect the U-shields 125 to a ground shield 160, as discussed below. Due to manufacturing limitations associated with preferred high-volume construction methods, it is expected that the insert 120 will be a separate piece from the shroud 110, but such a construction is not required and thus the insert 120 can also be formed integrally with the shroud 110 if desired. Thus, the shroud 110 can include a conductive path that electrically connects the U-shield to the ground shield.
The U-shield 125 includes a top wall 125a, two opposing side walls 125b, and a mating end 127, with the side walls 125b having edges 125c. As depicted, the mating end 127 is configured to engage the insert 120 through aperture 124, which is on the second face 121b, and can be configured differently than the aperture 122 on the first face 121a. Specifically, the aperture 124 can include pockets 126 that receive the mating ends 127.
The connector 200 can be constructed in a manner similar to connector 100 and includes a shroud 210 that helps support a wafer set 240. The connector 200 further includes a tail aligner 230, which can be plated plastic and have commoning features, that helps hold the plurality of wafers 250 in the wafer set 240 together while a plurality of combs 212 can be used to hold the wafer set 240 in a desired alignment and configuration. Each wafer 250 includes an insulative frame 255 for supporting terminals, as will be discussed below.
As both the connectors 100, 200 are both right angled connectors, the connectors allow for a connection between circuit boards 6 and 8 via the wafers 150, 250. It can be appreciated that circuit boards 6 and 8 are aligned in an orthogonal manner. Typically, two right angle connectors that are configured to join two orthogonally orientated circuit boards would require some sort of intermediary connector that 0 would map the alignment of the contacts in one right angle connector to the contacts of the other right angle connector. The depicted system works without such an intermediary connector.
As can be appreciated, the signal terminals 172a, 172b form a terminal pair 170 that is supported by the insulative frame 155. The signal terminals each include a contact 174a, a tail 174b, and a body 174c that extends therebetween. The bodies 174c of the signal terminals 172a, 172b are coupled together to form a differential pair and as depicted, are arranged to provide a vertical edge-coupled configuration. Each signal terminal 172a, 172b includes a folded section 175 that provides the transition from vertical to horizontal orientation that is still edge-coupled. Each insulative frame 155 will typically be configured to support a plurality of terminal pairs 170 (typically four or more such pairs, it being understood that an upper limit will be reached as manufacturing tolerances and issues with warpage are expected to prevent excessively high numbers of pairs such as 15 or 20 terminal pairs). As noted above, each terminal pair 170 has the body 174c of the two terminals aligned in an edge-to-edge configuration so that spacing of the terminals can be carefully controlled when the terminals are insert-molded into the wafer 150. Naturally, in a right-angle connector, the top terminal pair will tend to be longer than a bottom terminal pair but such arrangements are well known in the art.
The terminals pairs 170 are configured to mate with terminals pairs 270 that are provided by signal terminals 272a and 272b. Specifically, the terminal pairs 170 extend through apertures 122 in the insert 120 so that they can connect with the terminal pairs 270. Each of the signal terminals 272a, 272b include a contact 274a, a tail 274b, and a body 274c extended therebetween. The terminal pairs 270 thus provide a differential pair of the signal terminals 272a, 272b where the bodies 274a of these signal terminals are edge coupled.
In a typical edge-to-edge coupled terminal configuration suitable for higher performance (above 15 Gbps and more preferably above 20 Gbps using non-return to zero (NRZ) encoding), each adjacent terminal pair in a wafer will be separated by a ground terminal. The ground terminal acts as a shield between adjacent pairs of terminals in a wafer and can also provide a return path, thus the use of a ground terminal is generally accepted as being highly desirable at higher date rates (rates above 15 Gbps) as it helps prevent crosstalk between those adjacent pairs. While such a configuration is effective, it takes up additional space as both the ground terminals and the signal terminals need to be connected to the mating connector (otherwise unmated terminals would provide highly undesirable electrical performance). This turns out to be limiting when attempting to increase the density of the mating interface.
The depicted embodiment avoids the use of ground terminals between adjacent terminals pairs in a wafer while still supporting high data rates of at least 20 Gbps using NRZ encoding. Instead, a ground shield 160, 260 is mounted to the frame 155, 255 and the ground shield 160, 260 provides a U-channel 162, 262 around the terminal pairs 170, 270 (respectively). As can be appreciated, the ground shields 160, 260 provide broad-side coupling to the terminal pairs 170, 270 and provide a return path while also helping to shield the terminal pairs 170, 270 from adjacent terminal pairs in the same wafer and in an adjacent wafer.
The ground shield 160 includes an end 163 that is inserted into the insert 120 and a connection frame 161 that provides an electrical connection between adjacent U-channels 162. The ground shield 260 also includes connection frames 261 to provide similar electrical connections between adjacent U-channels 262. Thus, the U-channels 162, 262 can be commoned together at one or more locations to reduce the electrical length between points of commoning. Such a feature tends to reduce shift any resonances that can form between commoned locations to a high frequency, which in turn causes resonances to shift out of the frequency range of interest. Depending on the intended frequency of signaling, additional connector frame locations can be provided.
As can be appreciated, therefore, the U-channel 162 and U-shield provide a three-sided shield for a terminal pair 170 from the tail to the contact in a substantially continuous manner.
As depicted, the mating interface includes a double deflecting contact so that the signal terminals of the first connector 100 and second connector 200 both have a stub 173, 273 (as can be appreciated from
As noted above, the U-channel 162 uses the end 163 to connect the U-shield 125 via a conductive element 123 provided in the insert 120 (or shroud 110). The conductive element 123 can be a separate terminal supported by the insert 120 (in an embodiment it can be insert molded into the insert 120) or it can be a conductive plating formed on the insert 120 using additive manufacturing techniques. Thus, any desirable method of forming the conductive element 123 is suitable. The conductive element 123 can directly contact the U-shield 125 and thus electrical continuity between the ground shield 160 and the U-shield 125 is ensured.
The ground shield 260 is configured to make electrical contact with the U-shield 125. Fingers 266 are provided to engage the U-shield 125, for instance, on opposing sides walls 125b of the U-shield 125 so that a reliable electrical connection can be formed. If desired, multiple contact points on each side wall 125b can be provided. The ground shield 260 can also include a cutout 264 to provide space for the stubs 273. To provide improved electrical performance, the U-channel 262 can have an end 269 that extends past a front edge 125a of the ground shield 125 so that there is a partial overlap between the U-shield 125 and the U-channel 262.
As can be appreciated from
Specifically, a wafer 350 (which can replace wafer 250) can include a frame 355 that supports terminal pairs 370 formed of signal terminal 372a and signal terminal 372b. The signal terminals will each include a contact 374a, a tail 374b, and a body 374a extending therebetween. The wafer 350 includes a ground shield 360 that has U-channels 362 that are commoned with the use of connection frames 361.
It turns out that a secondary shield 390 can be added to the wafer 350 to provide an improvement in crosstalk and can be press directly against the ground shield 360. While the use of the secondary shield 390 does not provide significant improvements in shielding as the ground shield 160 already provides excellent shielding, it has been determined that the secondary shield 390 can reduce resonances that might otherwise exist. In addition, the secondary shield 390 can be readily fastened to the frame 355 of the wafer with a projection 359 that can be formed by a staking operation in securing apertures 391, thus providing desirable stiffening to the wafer. The secondary shield 390 can be connected to the ground shield 360 with conventional techniques such as, but not limited to, soldering, welding and conductive adhesives, and can cover a majority of the ground shield 360.
The ground shield 360 can extend from tails 367 on the mounting face of the connector to contacts on the mating face of the connector. The tails 367 of the ground shield 360 can be arranged in a substantially linear manner with the tails 274b that for a corresponding terminal pair 270 and can positioned on two sides of a terminal pair 270 but with the ground tails 367 can be arranged at about a 45-degree angle compared to the signal tails to help provide improved electrical performance in the footprint while allowing for desirable routing of signal traces in the corresponding circuit board. A plated plastic frame 330 can help common the various ground shields 360 (which also act as reference grounds for the edge-coupled differential pairs of signal terminals).
As can be appreciated, the ground shield 360 has a plurality of fingers 366a, 366b, 366c that preferably extend in directions so that the fingers 366 are configured to mate with surfaces that that are opposite and/or in orthogonal directions to each other. Naturally, the angles may not be perfectly opposite or orthogonal depending on the corresponding U-shield configuration. In an embodiment as depicted in
Because of the offset stagger in the terminal pairs 370, every other signal wafer has some extra space at a top side of the connector (such as connector 100). In an embodiment the space may be filled with a single-ended terminal 410. The single-ended terminal 410 has a contact 415 and can use the ground shield 360 of an adjacent wafer as a reference ground and thus the depicted connector system provides a way to offer desirable electrical performance with the terminal pairs (which are intended to support up to 56 Gbps using NRZ encoding) and still provide single-ended terminals useful for low-speed signaling. One interesting feature of the depicted design, as can be appreciated by
As can be appreciated from
The wafers 850 supports terminals pairs 870 that mate with terminal pairs 770. As discussed above, U-shields 125 are provided to shield the mating interface and provide a return path. The primary difference is that the ground shield 760, which includes tails 767, U-channels 762 and connection frames 761 as discussed above, includes fingers 766a and 766b. The fingers 766a are configured to engage the side walls 125b of the U-shield 125 surrounding terminal pair the while the fingers 766b are configured to engage top walls 125a of adjacent U-shields 125. As noted above, this allows for commoning of the U-shields in the mating interface and helps improve the performance of the system.
As can be appreciated from
It should be noted that the depicted embodiments illustrate an orthogonal configuration. If a simple right-angle to right-angle configuration is desired then the 90-degree rotation could be omitted. The same basic construction could also be used for vertical to vertical (e.g., mezzanine style) connectors. Thus, the depicted embodiments provide a technical solution that can be used for a wide range of connector configurations.
The disclosure provided herein describes features in terms of preferred and exemplary embodiments thereof. Numerous other embodiments, modifications and variations within the scope and spirit of the appended claims will occur to persons of ordinary skill in the art from a review of this disclosure.
This application claims priority to continuing U.S. application Ser. No. 17/327,817, filed May 24, 2021 which in turn claims priority to Ser. No. 16/866,158, filed May 4, 2020, now U.S. Pat. No. 11,018,454, which in turn claims priority to U.S. application Ser. No. 15/778,176, filed May 22, 2018, now U.S. Pat. No. 10,644,453, which is a national phase of PCT Application No. PCT/US2016/066522, filed Dec. 14, 2016, which in turn claims priority to U.S. Provisional Application No. 62/305,968, filed Mar. 9, 2016 and U.S. Provisional Application No. 62/266,924, filed Dec. 14, 2015, all of which are incorporated herein by reference in their entirety.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | 17327817 | May 2021 | US |
Child | 18304381 | US | |
Parent | 16866158 | May 2020 | US |
Child | 17327817 | US | |
Parent | 15778176 | US | |
Child | 16866158 | US |