The present invention relates to connector systems. More specifically, the present invention relates to a connector system that allows cable connectors to be connected to a substrate in a stacked configuration.
Cable connector systems that can include differential signal pairs or optical cables that electrically or optically connect an application-specific integrated circuit (ASIC) and a panel are known. A problem with known cable connector systems is providing higher density and higher terabyte throughput between an ASIC and a front panel of a rack-mountable equipment enclosing the ASIC.
To overcome the problems described above, preferred embodiments of the present invention provide cable connector systems that allow cable connectors to be connected to a board connector in a stacked or nested configuration, while reducing the footprint and stack height required by the board connector. For example, embodiments of the present invention can be used in groups of connectors positioned on one or both opposed surfaces of a die package substrate or on one or both opposed sides of a second substrate that includes a die package and is attached to a host substrate. The embodiments of the present invention can be used to collectively transmit at least 50 terabytes of data with frequency domain crosstalk of −40 dB or better on a standard 70-mm-by-70-mm die package, a 75-mm-by-75-mm die package, an 85-mm-by-85-mm die package, a 120-mm-by-120-mm die package, a 150-mm-by-150-mm die package, or other sized die packages. Embodiments of the present invention can have a height, measured from a mounting surface of the substrate to a top surface of any one of the connectors described herein of about 1.5 mm to about 7 mm.
A board connector can include a housing. The housing can include a first board connector mating interface surface, a first slot defined by the first board connector mating interface surface, a second slot vertically stacked over the first slot, and a first housing wall that partially defines both the first slot and the second slot. A first leadframe assembly can be positioned in the first slot. The first leadframe assembly can include a first signal conductor that can define a first mating end and a second signal conductor that can define a second mating end. A second leadframe assembly can be positioned in the second slot. The second leadframe assembly can include a third signal conductor that defines a third mating end and a fourth signal conductor that defines a fourth mating end. The first mating end and the second mating end can each be positioned closer to the first board connector mating interface surface than the third mating end and the fourth mating end. A first housing wall can extend over the first mating end, the second mating end, the third mating end, and the fourth mating end.
The first slot can be partially defined by the first housing wall, a first wall, and an opposed third wall. The first wall and the opposed third wall can be evenly spaced from a longitudinal centerline that is positioned between the first wall and the opposed third wall. The longitudinal centerline can also be parallel to both the first wall and the opposed third wall.
The second slot can be partially defined by the first housing wall, the first wall, and the opposed third wall, and the first wall and the opposed third wall can each be unevenly spaced from the longitudinal centerline. Alternatively, the second slot can be partially defined by the first housing wall, the first wall, and the opposed third wall, and the first wall and the opposed third wall are evenly spaced from the longitudinal centerline.
The housing can include a third slot vertically stacked over the second slot, a second housing wall that partially defines both the second slot and the third slot, and a third leadframe assembly positioned in the third slot. The third leadframe assembly can include a fifth signal conductor with a fifth mating end and a sixth signal conductor with a sixth mating end. The fifth mating end and the sixth mating end can each be positioned farther from the first board connector mating interface surface than the first mating end, the second mating end, the third mating end, and the fourth mating end.
The third slot can be partially defined by the second housing wall, a first wall, and an opposed third wall, and the first wall and the opposed third wall are unevenly spaced from the longitudinal centerline. Alternatively, the second slot can be partially defined by the second housing wall, a first wall, and an opposed third wall, and the first wall and the opposed third wall can be evenly spaced from the longitudinal centerline.
The board connector housing can further include a fourth slot vertically stacked over the third slot, a third housing wall that partially defines both the third slot and the fourth slot, and a fourth leadframe assembly positioned in the fourth slot. A fourth leadframe assembly can include a seventh signal conductor with a seventh mating end and an eighth signal conductor with an eighth mating end. The seventh mating end and the eighth mating end can each be positioned farther from the first board connector mating interface surface than the first mating end, the second mating end, the third mating end, the fourth mating end, the fifth mating end, and the sixth mating end.
The fourth slot can be partially defined by the third housing wall, a first wall, and an opposed third wall, and the first wall and the opposed third wall can be unevenly spaced from the longitudinal centerline. Alternatively, the fourth slot can be partially defined by the third housing wall, a first wall, and an opposed third wall, and the first wall and the opposed third wall can be evenly spaced from the longitudinal centerline.
The first slot and the second slot can each have a same width. The first slot and the second slot can each have a same depth. The first slot and the second slot can each have different depths. The first slot and the second slot can each receive an identical cable connector. The first, second, third, and fourth signal conductors can each be receptacle conductors. The housing is configured to overhang an edge of a mounting substrate. The housing can have a height of approximately 1.7 mm to approximately 4 mm or approximately 4 mm to approximately 7 mm or approximately 5 mm to approximately 8 mm, or approximately 1.7 mm to approximately 7 mm. The first slot, the second slot, and the third slot can each have a same width. The second slot and the third slot can each have a same width. The first slot, the second slot, and the third slot can each have the same depth. The second slot and the third slot can each have the same depth. The first slot, the second slot, the third slot, and the fourth slot can each have the same width. The third slot and the fourth slot can each have the same width. The first slot, the second slot, the third slot, and the fourth slot can each have the same depth. The third slot and the fourth slot can each have the same depth.
A cable connector can include a cable connector shield. The cable connector shield can include a single sheet of electrically conductive material with a shield arm and a hole. The shield arm can bend back over itself and extend into the hole. The cable connector can mate with a mating connector. The shield arm can be configured to make electrical connection with a mating connector shield. The cable connector can include an insert that includes cable connector signal conductors. Cables can be connected to the cable connector signal conductors. The cable connector can be approximately 1 mm in height.
An electrical connector with differential signal pairs and a unitary connector shield can be provided. The connector shield can include a first connector shield surface, a second connector shield surface opposed to the first connector shield surface, a hole, and a shield arm. The shield arm can bend back over the first connector shield surface and pass through the hole, the first connector shield surface, and the second connector shield surface, such that the shield arm is configured to contact a mating connector shield of a mating connector when the electrical connector is mated with the mating connector. The electrical connector can be a cable connector.
A panel can be provided. The panel can define a 1RU area and at least two-hundred and fifty-seven 56-GHz differential signal pairs positioned in the 1RU area, or at least two-hundred and eighty-nine 56-GHz differential signal pairs can be positioned in the 1RU area, or at least three hundred 56-GHz differential signal pairs can be positioned in the 1RU area, or at least four hundred 56-GHz differential signal pairs can be positioned in the 1RU area, or at least five hundred 56-GHz differential signal pairs can be positioned in the 1RU area.
A tray can be provided. The tray can include a first airflow zone and a second airflow zone. The first airflow zone and the second airflow zone can each be positioned parallel to each other, can each be positioned immediately adjacent to each other, and can each be serviced by separate fans. Back-to-back, on-board transceivers can be positioned in the first airflow zone. A die can be positioned in the second airflow zone.
Mated electrical right-angle connectors can have a mated stack height greater than zero but less than approximately 5 mm.
A substrate can be provided. The substrate can include a first linear array of pads that can extend along a first pad centerline and can include first and second end pads at opposite ends of the first linear array of pads. A second linear array of pads can extend along a second pad centerline and can include third and fourth end pads at opposite ends of the second linear array of pads. A possible first weld tab land on the substrate can have a first weld tab centerline. A possible second weld tab land on the substrate can have a second weld tab centerline. A first pad centerline can be positioned parallel to the second pad centerline. The first linear array of pads can be offset from the second linear array of pads by more than a row pitch. The first end pad and the third end pad can each be on a same side of the substrate. The second end pad and the fourth end pad can each be on a same side of the substrate opposite to the first end pad and the third end pad. The first weld tab centerline and the second weld tab centerline can each be positioned parallel to each other and perpendicular to the first pad centerline and to the second pad centerline. A first pad distance from a center of the second end pad to the second weld tab centerline can be less than a second pad distance from a center of the third end pad to the first weld tab centerline. A third pad distance between the first end pad in the first linear array of pads to the first weld tab centerline can be greater than the first pad distance. The first pad centerline and the second pad centerline do not intersect the first weld tab land or the second weld tab land.
The above and other features, elements, characteristics, steps, and advantages of the present invention will become more apparent from the following detailed description of embodiments of the present invention with reference to the attached drawings.
The cable connector systems described herein are able to transport, i.e., transmit and/or receive, signals up to 56 GHz NRZ and/or 112 PAM4. The cable connector systems may be applied to die package substrates or extension cards attached to die substrates that are 70 mm by 70 mm, 75 mm by 75 mm, 80 mm by 80 mm, 85 mm by 85 mm, 90 mm by 90 mm, 95 mm by 95 mm, 100 mm by 100 mm, 105 mm by 105 mm, 110 mm by 110 mm, or any die package having N by N dimensions, where N is greater than or equal to 70 mm and N is less than or equal to 200 mm. The cable connector systems can also be applied to a substrate that includes a die package, a die substrate, or an extension card attached to a die package or die substrate.
If there are N number of cable connectors 14, then the corresponding board connectors 12 can include N number of leadframe assemblies 24a, 24b or wafers, one for each corresponding cable connector 14. If there are a total of P number of cables 22 in a corresponding cable connector 14, then the corresponding board connector 12 can include 2×P electrical conductors 26, 28, assuming each cable 22 is a twin axial cable with two center cable conductors 38. If the cables 22 only have a single center cable conductor 38, then the board connector 12 can include P electrical conductors, such as signal conductors 26 and optional ground conductors 28.
Two sets of immediately adjacent leadframe assemblies 24a, 24b are shown. Two immediately adjacent leadframe assemblies 24a, 24b can be offset with respect to each other in a horizontal direction D that is perpendicular to an insertion direction I of the cable connectors 14. As shown in
As shown in
The housing 16 or first housing 18 can define four slots 50, 50a, 50b, 50c. At least one or both of the first slot 50 and second slot 50a can each open at first board connector mating interface surfaces 52a of the housing 16 or first housing 18. At least one or both of the third slot 50b and fourth slot 50c can each open at second board connector mating interface surfaces 52b of the housing 16 or the first housing 18. The first board connector mating interface surface 52a can each lie in a first plane FP that is generally perpendicular to a mounting interface plane MIP that is parallel to a board connector mounting interface surface 44 of the housing 16. The second board connector mating interface surfaces 52b can each lie in a second plane SP that is generally perpendicular to the mounting interface plane MIP. The first plane FP and the second plane SP can be parallel to each other, and both generally perpendicular to the mounting interface plane MIP. The first board connector mating interface surfaces 52a and the second board connector mating interface surfaces 52b can be spaced apart from one another. The second board connector mating interface surfaces 52b can be positioned vertically above the first board connector mating interface surfaces 52a, and can be recessed away from the first board connector mating interface surfaces 52a in a direction toward the second housing 20.
Each of the four slots 50, 50a, 50b, 50c can receive a corresponding one of four cable connectors 14. A different number of slots 50-50c can be included if a corresponding different number of cable connectors 14 is used. The slots 50-50c can each be positioned parallel to one another. A first slot 50 may be positioned immediately adjacent to a mounting substrate, such as a printed circuit board (PCB) (shown, for example, in
A third slot 50b may be vertically stacked over the first slot 50 and the second slot 50a and can be positioned immediately adjacent to the second slot 50a in a vertical direction along a height H of the housing 16. The third slot 50b can be defined by a first wall 54b, a third housing wall 56b, a third wall 58b, and the second housing wall 56a of the second slot 50a. A fourth slot 50c may be vertically stacked over the first slot 50, the second slot 50a, and the third slot 50b and can be positioned immediately adjacent to the third slot 50b in a vertical direction along a height H of the housing 16. The fourth slot may be defined by four walls, such as a first wall 54c, a fourth housing wall 56c, a third wall 58c, and the third housing wall 56b of the third slot 50b.
Mating ends 62 of signal conductor pairs 26b, 26c and board connector shields 40b, 40c can protrude into the respective slots 50b, 50c. Similar to the first and second slots 50, 50a, the third slot 50b and the fourth slot 50c can be horizontally offset in a direction perpendicular to an insertion direction I of cable connectors 14, such that a signal conductor 26b pair positioned in third slot 50b can be offset from corresponding signal conductor pair 26c positioned in the fourth slot 50c by a partial row pitch, a full row pitch, or more than a row pitch.
A second slot 50a can be defined by at least four walls or only four walls, such as the first wall 54a, the opposed third wall 58a, the first housing wall 56 that can span the first wall 54a and the opposed third wall 58a, and the second housing wall 56a that can span the first wall 54a and the opposed third wall 58a. Second housing wall 56a can partially define both the second slot 50a and the third slot 50b and can define a second wall edge 64a.
A third slot 50b can be defined by at least four walls or only four walls, such as the first wall 54b, the opposed third wall 58b, the second housing wall 56a that can span the first wall 54b and the opposed third wall 58b, and the third housing wall 56b that can span the first wall 54b and the opposed third wall 58b. Third housing wall 56b can partially define both the third slot 50b and the fourth slot 50c and can define a third wall edge 64b.
A fourth slot 50c can be defined by at least four walls or only four walls, such as a first wall 54c, an opposed third wall 58c, a third housing wall 56b that can span the first wall 54c and the opposed third wall 58c, and a fourth housing wall 56c that can span the first wall 54c and the opposed third wall 58c. Third housing wall 56b can partially define both the third slot 50c and the fourth slot 50d. The fourth housing wall 56c and can define a fourth wall edge 64c. All of the slots 50-50c can have the same width, the same depth, different widths, or different depths.
The first wall edge 64, the second wall edge 64a, the third wall edge 64b, and the fourth wall edge 64c can each be vertically stair-stepped along a height H1 of the first housing 18. For example, the first wall edge 64 of the first housing wall 56 can be positioned farther away from a rear, vertical wall 66 of the first housing 18 than the second wall edge 64a, the third wall edge 64b, or the fourth wall edge 64c. As measured from the rear, the vertical wall 66 of the first housing 18, the second wall edge 64a can be positioned farther away from the rear, vertical wall 66 than the third wall edge 64b and the fourth wall edge 64c. Alternatively, the first wall edge 64 and the second wall edge 64a can each be spaced the same distance from the rear, vertical wall 66 of the first housing 18. As measured from the rear, vertical wall 66 of the first housing 18, the third wall edge 64b can be positioned farther away from the rear, vertical wall 66 of the first housing 18 than the fourth wall edge 64c of the fourth housing wall 56c. Alternatively, the third wall edge 64b and the fourth wall edge 64c can each be spaced the same distance from the rear, vertical wall 66 of the first housing 18. Grooves 68 can receive portions of a corresponding molded leadframe assembly 24a, 24b.
As shown in
As shown in
A first leadframe assembly 74 can include a second signal section 84 and a second board connector shield section 88. Second, third, and fourth leadframe assemblies 76, 78, 80 can each include a first signal section 82, a second signal section 84, a first board connector shield section 86, and a second board connector shield section 88. First signal sections 82 can be separately attached to the first board connector shield sections 86, and the second signal sections 84 can be separately attached to the second board connector shield sections 88. Alternatively, the second signal sections 84 and respective second board connector shield sections 88 can be molded together, and the first signal sections 82 and respective first board connector shield sections 86 can be molded together. The board connector 12 can be devoid of discrete ground conductors positioned between adjacent signal conductors 26 or between adjacent signal conductor pairs 26a, 26b.
A first signal section 82 and a corresponding second signal section 84 can define a right angle. A first signal section 82 of the third leadframe assembly 78 can be longer in length and taller in height than a first signal section 82 of the second leadframe assembly 76. A first signal section 82 of the fourth leadframe assembly 80 can be longer in length and taller in height than a first signal section 82 of the third leadframe assembly 78.
In the second, third, and fourth leadframe assemblies 76, 78, 80, respective first and second signal sections 82, 84 can be connected together in any suitable manner, including, for example, by soldering, welding, sonic welding, laser welding, etc. A first board connector shield section 86 and a respective second board connector shield section 88 of each board connector shield 40 can be connected together in any suitable manner, such as the methods discussed in this paragraph with respect to first and second signal sections 82, 84. In one embodiment, signal conductors 26 of the second signal section 84 are inserted into a corresponding one of holes defined by signal conductors 26 of the second signal section 84 and the first and second signal sections 82, 84 are soldered or welded. A first board connector shield section 86 and a second board connector shield section 88 can be similarly attached. Board connector shield tail 92 can extend from the board connector shield 40 and be in-line with tails of signal conductors 26 carried by a corresponding first signal section 82.
A first leadframe assembly 74 is shown in
In this embodiment, one of the electrical conductors, such as signal conductors 26a, positioned in the second slot 50a (or first slot 50) can be horizontally offset from a corresponding electrical conductor, such as signal conductor 26b positioned in the third slot 50b (or second slot 50a) in a horizontal direction by no row pitch RP1 (i.e., no offset), a partial row pitch RP1 that is less than a full row pitch RP1, a full row pitch RP1, more than a row pitch RP1, a full conductor pitch CP, at least two conductor pitches CP, at least three conductor pitches CP, more than two conductor pitches CP, or more than three conductor pitches CP, where a conductor pitch CP is a distance between centerlines of two adjacent electrical conductors or two adjacent signal conductors 26a or 26b. Corresponding electrical conductors or signal conductors 26a, 26b can have the same position numbers, left to right, such as the last signal conductor 26a positioned in the second slot 50a (or first slot 50) and, left to right, the last signal conductor 26b positioned in the third slot 50b (or second slot 50a).
One pair of signal conductors 26a positioned in second slot 50a (or first slot 50) can be offset from a corresponding pair of signal conductors 26b positioned in the third slot 50b (or second slot 50) in a horizontal direction by no conductor row pitch RP2 (i.e., no offset), a partial conductor row pitch RP2 that is less than a full conductor row pitch RP2, a full conductor row pitch RP2, more than a conductor row pitch RP2, a full conductor pitch CP, at least two conductor pitches CP, at least three conductor pitches CP, more than two conductor pitches CP, or more than three conductor pitches CP, where a conductor pitch CP is a distance between centerlines of two adjacent electrical conductors, such as two signal conductors 26a or 26b. Corresponding pairs of signal conductors 26a, 26b can have the same position numbers, left to right, such as the last two signal conductors 26a positioned in the second slot 50a (or first slot 50) and, left to right, the corresponding last two signal conductors 26b positioned in the third slot 50b (or second slot 50a).
As shown in
The shield arm 124 of the cable connector shield 42, as well as cable connector insert 118 that includes cable connector signal conductors 120, is further shown in
In this embodiment, one of the pads of the first linear array of pads 144, such as a pad 157 that receives a corresponding one of signal conductors 26, can be horizontally offset from a corresponding one of the pads of the second linear array of pads 146, such as pad 157a that receives a corresponding one of signal conductors 26a. The horizontal offset can be by no pad row pitch RP (i.e., no offset), a partial pad row pitch RP1 that is less than a full pad row pitch RP, a full pad row pitch RP, more than a pad row pitch RP, a full pad pitch PP, at least two pad pitches PP, at least three pad pitches PP, more than two pad pitches PP, or more than three pad pitches PP. A pad row pitch RP can be measured from a centerline of a pad in the first linear array of pads 144 and a corresponding pad in the second linear array of pads 146. A pad pitch PP can be a distance between centerlines of two adjacent pads in the respective first or second linear arrays 144, 146. For pad row pitch RP, corresponding pads can have the same position number, left to right, in each of the first and second linear arrays of pads 144, 146. For example, corresponding pads can each be the last or second to last pads 157, 157a, left to right, in each of the first and second linear arrays of pads 144, 146.
A first weld tab land 152 and a second weld tab land 154 can be positioned on the generic mounting substrate 160, adjacent to the second linear array of pads 146. The first weld tab land 152 can have a first weld tab centerline TCL1, and the second weld tab land 154 can have a second weld tab centerline TCL2. The first weld tab centerline TCL1 and the second weld tab centerline TCL2 can each be positioned parallel to each other and perpendicular to the first pad centerline PC1 and the second pad centerline PC2. A first pad distance PD1, measured from a center of end pad 156 in the first linear array of pads 144 to the second weld tab centerline TCL2, is less than a second pad distance PD2 measured from a center of the opposite end pad 158 in the second linear array of pads 146 to the first weld tab centerline TCL1. A third pad distance PD3, measured between the other end pad 162 in the first linear array of pads 144 and the first weld tab centerline TCL1, can be greater than the first pad distance PD1 or the second pad distance PD2. The first pad centerline PC1 and the second pad centerline PC2 do not intersect the first weld tab land 152 or the second weld tab land 154.
For a 1-by-4 board connector 12, 12A, as shown in
One of the pads of the first linear array of pads 144, such as a pad 157 that receives a corresponding one of signal conductors 26b, can be horizontally offset from a corresponding one of the pads of the second linear array of pads 146, such as pad 157a that receives a corresponding one of signal conductors 26a, by no pad row pitch RP (i.e., no offset), a partial pad row pitch RP that is less than a full row pitch RP, a full pad row pitch RP, more than a pad row pitch RP, a full pad pitch PP, at least two pad pitches PP, at least three pad pitches PP, more than two pad pitches PP, or more than three pad pitches PP. A pad row pitch RP can be the distance from a centerline of a pad in the first linear array of pads 144 and a corresponding pad in the second linear array of pads 146. A pad pitch PP can be the distance between centerlines of two adjacent pads in the respective first or second linear arrays 144, 146. For pad row pitch RP, corresponding pads can have the same position number, left to right, in each of the first and second linear arrays of pads 144, 146. For example, corresponding pads can each be the last or second to last pads 157, 157a, left to right, in each of the first and second linear arrays of pads 144, 146.
A first weld tab land 152 and a second weld tab land 154 can be positioned on the generic mounting substrate 160. The first weld tab land 152 can have a first weld tab centerline TCL1, and the second weld tab land 154 can have a second weld tab centerline TCL2. The first weld tab centerline TCL1 and the second weld tab centerline TCL2 can each be positioned parallel to each other and perpendicular to the first pad centerline PC1 and the second pad centerline PC2. A first pad distance PD1, measured from a center of end pad 156 in the first linear array of pads 144 to the second weld tab centerline TCL2, is less than a second pad distance PD2 measured from a center of the opposite end pad 158 in the second linear array of pads 146 to the first weld tab centerline TCL1. A third pad distance PD3, measured between the other end pad 162 in the first linear array of pads 144 to the first weld tab centerline TCL1, can be greater than the first pad distance PD1 or the second pad distance PD2. A third linear array of pads 164 can extend along a third pad centerline PC3 that extends parallel to the first pad centerline PC1. A fourth linear array of pads 166 can extend along a fourth pad centerline PC4 that extends parallel to the first pad centerline PC1. The first linear array of pads 144 can be positioned with no row pitch offset between the first linear array of pads 144 and the third linear array of pads 164. The second linear array of pads 146 can be positioned with no row pitch offset between the second linear array of pads 146 and the fourth linear array of pads 166. The first pad centerline PC1, the second pad centerline PC2, the third pad centerline PC3 and the fourth pad centerline PC4 do not intersect the first weld tab land 152 or the second weld tab land 154.
The die substrate 168 can be any suitable size, such as an approximate 85-mm-by-85-mm printed circuit board, measured along two intersecting first and second die edges 176, 178 of the die substrate 168. The die substrate 168 can be other sizes. The die package 174 is preferably square, but does not have to have sides of equal lengths and can have other shapes. The larger the area of the die substrate 168, the more connector systems 10, 10A, 10B, 10C can be added to the first die substrate surface 172.
As shown in
The board connectors 12 and the cable connectors 14 can each include one, two, three, or four rows of four differential signal pairs, or any other number of rows, contacts, or differential pairs. For example, each board connector 12 can include eight differential signal pair per slot, and each cable connector can include eight differential signal pairs, or a total of eight, sixteen, twenty-four, or thirty-two 56 GHz NRZ or 112 GHz PAM4 capable differential signal pairs per cable connector system 10, 10A, 10B, 10C. As shown on the 85-mm-by-85-mm die package 174, twelve two-row cable connector systems 10 (
Cables 22 attached to the cable connectors 14 can have a maximum diameter of 33, 34 or 35 or 36 gauge. The board connector 12 and the cable connector 14 can both be configured not to receive an edge card. A 2-by-1 board connector 12, 12A, 12B or cable connector 14 has modeled insertion loss between 0 dB and −1 dB through frequencies up to 25 GHz, modeled insertion loss between 0 dB and −1 dB through frequencies up to 30 GHz, and modeled insertion loss between 0 dB and −2 dB through frequencies up to 40 GHz. Differential return loss can be between −20 dB and −60 dB through frequencies up to 20 GHz and between −10 dB and −60 dB through frequencies up to 30 GHz. Differential far end crosstalk (FEXT) powersum is modeled between −30 dB and −100 dB through frequencies up 40 GHz and between −20 dB and −100 dB through frequencies up to 90 GHz. Modeled differential near end crosstalk (NEXT) is between −40 dB and −100 dB through frequencies up to 35 GHz and between −30 dB and −100 dB through frequencies up to 50 GHz.
A 4-by-1 board connector 12, 12A, 12B or cable connector 14 has modeled insertion loss between 0 dB and −2 dB through frequencies up to 15 GHz, between 0 dB and −3 dB through frequencies up to 20 GHz, and between 0 dB and −5 dB through frequencies up to 40 GHz. Differential return loss is between −20 dB and −60 dB through frequencies up to 10 GHz and between −10 dB and −60 dB through frequencies up to 50 GHz. Differential far end crosstalk (FEXT) powersum is modeled between −30 dB and −100 dB through frequencies up to 40 GHz and between −20 dB and −100 dB through frequencies up to 60 GHz. Modeled differential near end crosstalk (NEXT) is between −40 dB and −100 dB through frequencies up to 40 GHz and between −30 dB and −100 dB through frequencies up to 50 GHz. Date rata is approximately equal to two times the frequency, so a frequency of 20 GHz approximately equals a data rate of 40 Gbits/sec, a frequency of 30 GHz approximately equals a data rate of 60 Gbits/sec, a frequency of 40 GHz approximately equals a data rate of 80 Gbits/sec, etc.
Each cable connector 14 can be terminated with another connector, such as a panel I/O connector 184, board connector, etc. As shown in
A panel I/O connector 184 can include first, second, third, and fourth rows 188, 190, 192, 194 of electrical conductors, such as eight I/O differential signal pairs 196 and grounds 198 arranged in a S-S-G or S-S-G-G configuration. A S-S-G-G configuration can reduce signal density. The first row 188 and the second row 190 can be spaced apart by a first pitch P1 of about 2.2 mm, the second row 190 and the third row 192 can be spaced apart by a second pitch P2 of about 3 mm, and the third row 192 and the fourth row 194 can be spaced apart by a third pitch P3 of about 2.2 mm. Electrical conductors can be on a 0.635-mm pitch. Panel fasteners 200 can be used to affix the panel I/O connector 184 to a panel, such as the 1 RU panel 202 shown in
Embodiments of the present invention can pass or fit at least two-hundred and fifty-seven, at least two-hundred and eighty-nine, at least three hundred, at least four hundred, and at least five hundred 56 GHz NRZ or 112 GHz PAM4 differential signal pairs through a 1 RU panel area. In a 1-by-4 configuration, on a 85-mm-by-85-mm die package, with eight differential signal pairs per slot or row, only twelve board connectors 10, 10A, 10B, 10C and only twelve panel I/O connectors are needed on the panel to pass a minimum of three-hundred and eighty-four differential signals through the panel. If twelve more board connectors are positioned on a second die substrate surface of the die package, the total number of differential signal pairs can be doubled to 768 differential signal pairs that pass through less than a 1 RU panel area.
Any 1 RU panel area described herein is not limited to a single 1 RU panel. A 1 RU panel area can be distributed among two or more 1 RU panels. The 1 RU panel can define a plurality of panel through holes, like a screen, to permit airflow through the 1 RU panel.
As shown in
With reference to 34, on-board transceivers 204 can be received by corresponding low speed connectors 218 and high-speed connectors 220 that are each positioned on corresponding tray substrates 222. This configuration can yield thirty-two on-board transceivers 204, sixteen of which are not inverted and sixteen of which are inverted. Cables 22 are electrically attached to respective ones of the high-speed connectors 220 at one end, and corresponding cable connector 14 (
As shown in
It should be understood that the foregoing description is only illustrative of the present invention. Various alternatives and modifications can be devised by those skilled in the art without departing from the present invention. Accordingly, the present invention is intended to embrace all such alternatives, modifications, and variances that fall within the scope of the appended claims. Descriptions of embodiments described herein are not limited to the embodiment described, and can also apply to other embodiments disclosed herein.
This application claims the benefit of U.S. Patent Application No. 62/704,025, filed on Oct. 9, 2018; U.S. Patent Application No. 62/704,052, filed on Jan. 28, 2019; U.S. Patent Application No. 62/813,102, filed on Mar. 3, 2019; U.S. Patent Application No. 62/840,731, filed Apr. 30, 2019; and PCT Application No. PCT/US2019/041356, filed Jul. 11, 2019, all of which are incorporated by reference in their entirety for all purposes as if fully set forth herein.
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Official Communication issued in corresponding Taiwanese Patent Application No. 111109451, dated Feb. 3, 2023. |
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Number | Date | Country | |
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20230178917 A1 | Jun 2023 | US |
Number | Date | Country | |
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62840731 | Apr 2019 | US | |
62813102 | Mar 2019 | US | |
62704052 | Jan 2019 | US | |
62704025 | Oct 2018 | US |
Number | Date | Country | |
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Parent | 17266937 | US | |
Child | 18096605 | US |