The present invention relates to the field of connectors, more specifically to the field of connector suitable for high data rates.
Backplane connectors are often used to support high performance applications. While backplane connectors originally were mostly used in single-ended channels applications, most recent designs have migrated to providing differential signal pairs (as differential signal pairs inherently have greater resistance to spurious signals). Backplane connectors that are used to support systems that use high data rates thus tend to be configured to utilize a number of differential signal pairs. Because different applications require different numbers of data channels, backplane connectors often are provided in a configuration that includes a header (which is mounted on a first circuit board) and a daughter card connector (which is mounted on a second circuit board) that supports a number of wafers (which in turn provides some desired number of signal pairs). The number of signal pairs in the wafer can be adjusted, as well as the size of the housing of the header and the size of the housing of the daughter card connector. Thus, existing backplane connectors are able to offer substantial benefits to applications that can benefit from the performance capabilities.
As processing power and the desired rate of information transfer from one device to another increases, however, further improvements to the performance of backplane connectors will be helpful. In addition to performance improvements, extremely dense connectors (e.g., connectors with a large number of pins per area) are desirable. Thus, certain individuals would appreciate further improvements to connectors that are suitable to function as backplane connectors.
In an embodiment, a connector system is disclosed that includes a first and second connector. The first connector includes a housing that supports a channel terminal that is U-shaped and includes a mating edge. Two blade terminals can be positioned in the U-shaped region defined by the channel terminal. The second connector includes one or more wafers that support terminals arranged in an edge-coupled manner. Ground terminals in the one or more wafers are configured to engage the mating edge of the channel terminal. Each wafer can include a shield and the ground terminal, the channel terminal and the shield can be electrically connected in the mating interface.
In another embodiment, a connector is provided that includes a housing that supports a plurality of wafers. The wafers can include a shield and support a plurality of signal terminals, which are provided in pairs, and ground terminals positioned between the pairs of signal terminals. The shield can be electrically connected to the ground terminals. The ground terminals can have ground contact that have two beams, each beam having a contact surface facing in an opposite direction. If desired, the two beams can extend in different directions on opposite sides of a terminal centerline. The shield can include a groove that is aligned with a signal pair. If desired, the groove can be configured with fingers that are configured to be electrically connected to ground terminals that are positioned on opposite sides of the signal pair.
The present invention 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). The features of
Looking at
The connector 50 includes a housing 60 that can support an array of terminals 62 that includes channel terminals 65 and blade terminals 71, 72. The housing includes an alignment feature 80 that helps ensure the connector 50 can properly mate with a mating connector.
As can be appreciated, a first channel terminal 65a can be positioned adjacent a second channel terminal 65b. The number of channel terminals 65 supported by a particular connector 50 will depend on the application. The channel terminal 65 includes a base 66, and wings 67a, 67b that are positioned on opposite sides of the base 66. Each of the wings includes a mating surface 68. Thus, the edge of the stamped terminal can be used as a mating interface.
The channel terminal 65 includes two tails 69 that are aligned with the wings 67a, 67b. The blade terminals also each include a tail 79. As depicted, the tails of the blade terminals 71, 72 are orientated differently than the tails of the channel terminal 65. This allows the differential coupling between the edges 73, 74 of the blade terminals to be better maintained through the tails 79 as there is no need to change the orientation of the blade terminals through the housing 60. In addition, the orientation of the wings is also maintained to the tails 69, thus helping to ensure the coupling that takes place between one of the blade terminals and the channel terminal can be desirably managed through the interface. As can be appreciated, the supporting circuit board that the tails are mounted on includes vias that are circular in shape, thus the orientation of the tails does not get in the way of the desired circuit board layout.
Connector 100 includes a housing 110 that supports one or more wafers 120 and the wafers can be further supported with a retaining comb 130. The housing 110 includes ground apertures 112 that receive the channel terminals 65 and includes signal apertures 113 that receive the blade terminals 71, 72. To allow for consistent mating with an opposing connector, an alignment feature 115 is provided. As can be appreciated, the connector 100 includes a first edge 121a and a second edge 121b that allow the connector to be mounted and mated, respectively. As depicted, the edges are at a right angle to each other.
The wafer 120 includes a housing 130 that supports an optional shield 150. As can be appreciated, the shield 150 includes a front section 155 and rear section 156. The front section 155 is useful to help shield the contacts of terminals (e.g., the mating interface) in adjacent wafers from each other while the rear section 156 shields the body of the terminals. One advantage of maintaining the shield through the interface is that any coupling between the shield and the differential pair that exists can be maintained (thus potentially avoiding conversion of common mode energy to differential mode energy).
As depicted, the wafers 120 are provided in a repeating pattern of a first wafer 120a that supports a frame 130a and a second wafer 120b that supports a frame 130b. The wafers 120a, 120b in the depicted configuration are slightly offset from each other. However, the configuration could be shifted to a full offset (such that ground terminal in one wafer was directly across from the signal pair in an adjacent wafer) or to a configuration with no offset.
Each wafer 120 supports a first signal terminal 181a and a second signal terminal 182a that together form a signal pair 185a that is intended to be differentially edge-coupled. Unlike broadside coupled signal pairs (which tend to be easy to manage from a skew standpoint as both terminals are the same length), edge coupled terminals need to take into account skew management so that the differential signal arrives at both corresponding contacts at approximately the same time. This can be managed in a number of known ways and sometimes is done by controlling the dielectric constant associated with each terminal in the pair so that the electrical length is approximately the same. However, unlike broadside-coupled terminals, it has been determined that it can be easier to control the spacing between edge-coupled signal pairs (in broadside-coupled pairs the two terminals are often supported by two separate frames that must be positioned next to each other and any tolerances between the positioning of the two frames must be accounted for) in certain circumstances.
The depicted wafers provide multiple signal pairs and it should be noted that the number is expected to vary between about 2 and about 16 pairs, depending on the desired configuration of the corresponding application. Between each signal pair 185 a ground terminal 183 is provided. The ground terminal 183 is configured to be wider than one of the signal terminals that form the signal pair 185 and in an embodiment the ground terminal 183 may be configured so that a width W1 associated with a signal pair 185 is less than a width W2 associated with a ground terminal 183.
A signal terminal includes a contact 186a, a tail 186b and a body 186c that extends therebetween. Similarly, a ground terminal includes a ground contact 187a, a ground tail 187b and ground body 187c that extends therebetween. It should be noted that the depicted contacts 186a have a double arm contact system that reduces insertion force and improves reliability of the contact mating interface but such a contact system is not required.
As can be appreciated, regardless of the number of terminals, the terminals in each wafer 120 are aligned along a terminal centerline 132. It should be noted, however, that the terminal centerline 132 need not be exactly in the middle of the wafer 120, thus the terminal centerline 132 may or may not be aligned with a wafer centerline.
As noted above, positioned on a side 134 of the wafer 130 is a shield 150. The shield 150 can be configured so that it is aligned with the corresponding frame 130. Thus, shield 150a includes grooves 160a-160b that are aligned with the signal pairs 185a-185b of frame 130a while shield 150b includes grooves 170a-170b that are aligned with the signal pairs supported by frame 130b. In each case, the grooves can be formed by providing a wall 174 that includes a series of arms 176 and arms 177 that are formed so as to extend from the wall 174 toward the terminal centerline 132.
To improve electrical performance, the shield can further include a plurality of fingers 175 that are configured to engage apertures 184 in the ground terminal 183 (such as ground terminal 183d) so as to create electrical connections therebetween (rather than relying on capacitive coupling between the ground terminals and the shield). This allows the ground terminals to be commoned with the shield and helps prevent resonances at frequencies of interest that can otherwise occur when the electrical length of the ground terminals is increased due to the lack of commoning. In addition, as depicted, the groove extends between and commons two ground terminals 183 that are positioned on opposite sides of a signal pair 185. While the use of commoning elements is known, the depicted embodiment can provide improved performance by aligning the arms 176, 177 with the fingers 175 so that the groove can provide substantial shielding over 180 degrees (as is depicted in
As depicted, the frame 130 includes air recesses 135 that are aligned with signal pairs 185. For example, air recesses 135a-135c can be aligned with signal pairs 185a-185c, respectively. The use of the air recess 135 helps reduce the effective dielectric constant of corresponding signal pair (which can help reduce the electrical length). Naturally, it is less desirable from a manufacturing and structural standpoint to have a continuous air recess and therefore the air recesses have occasional webs of the frame intersecting them. To minimize impedance discontinuities, the terminals can be notched at the location of the webs.
One issue, as noted above, with existing connectors is that it has been difficult to provide a connector that can support high data rates such as 25 Gbps or greater using non-return to zero (NRZ) encoding while also providing a dense pin field. The depicted connector system provides features that help resolve this issue. As can be appreciated, the ground contact 187 includes a beam 188a that has a contact surface 187′ that engages the mating edge 68 of the channel terminal 65. Thus, unlike convention systems, the mating interface depicted herein has the ground contact mate to an edge of a corresponding terminal.
To provide additional performance enhancements, the ground contact may include a beam 188b that has a contact surface 187″ that faces the opposite direct of the contact surface 187′. In addition, as depicted in
As can be appreciated, the optional beam 188b (which allows the ground contact on one wafer to be electrically coupled to a shield of an adjacent wafer) provides further electrical benefits. And, as can be appreciated from
In an embodiment, as depicted in
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 is a continuation of U.S. Ser. No. 15/131,208, filed Apr. 18, 2016, now U.S. Pat. No. TBD, which is a continuation of U.S. Ser. No. 14/351,064, filed Apr. 10, 2014, now U.S. Pat. No. 9,331,407, which is incorporated herein by reference in its entirety and which is a national phase of PCT Application No. PCT/US2012/059975, filed Oct. 12, 2012, which in turn claims priority to U.S. Provisional Application No. 61/546,421, filed Oct. 12, 2011, which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61546421 | Oct 2011 | US |
Number | Date | Country | |
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Parent | 15131208 | Apr 2016 | US |
Child | 15606446 | US | |
Parent | 14351064 | Apr 2014 | US |
Child | 15131208 | US |