1. Field of the Invention
The present invention relates to a broadband RF connector interconnect for multilayer electronic packages, and more particularly to impedance matching to provide improved broadband performance in ceramic multilayer packages requiring brazed connectors.
2. History of the Prior Art
It is known in the art to provide a coaxial transition arrangement including a broadband RF connector interconnect for multilayer electronic packages. Such arrangements are commonly used in, for example, radar systems having an electronic package with a transmit/receive module and antenna feed network for the transmitter.
In such arrangements, it is difficult to achieve broadband high frequency RF performance from a coaxial connector transition to a transmission line structure within a multilayer package. It is impossible to compensate the impedance mismatch within the connector by using impedance matching structures inside the package alone. Attempts to compensate connector transition by reducing the braze pad for the pin connection leads to high-risk manufacturing and connector reliability.
Various different arrangements have been tried in an attempt to provide impedance matching and thereby broadband performance in coaxial transition arrangements. Such an arrangement is shown in U.S. Pat. No. 3,745,488 of Rogers. This patent describes a disk 76 and a ring 78 which are moveable within a coaxial structure to achieve impedance matching. However, such structure is relatively complex and not readily adapted to coaxial transition arrangements which couple a coaxial cable to a multilayer package so that impedance matching is achieved with minimum modification. Similar comments apply to U.S. Pat. No. 6,028,497 of Allen in which the impedance of a coaxial transmission line is adjusted by adjusting the width and shape of a pin and the inner diameter of a washer-shaped end of a shroud.
The present invention provides impedance matching and improved broadband performance with a broadband RF connector interconnect for multilayer electronic packages in which only relatively minor modification of conventional structures is required. A coaxial transition arrangement comprises a transmission line structure inside a multilayer package, a coaxial cable and a coaxial connector coupling the multilayer package to the coaxial cable. The coaxial conductor includes a center conductor pin having a metal disk structure thereon. The metal disk structure provides impedance matching.
In accordance with the invention, the metal disk structure includes a plurality of metal disks of different size mounted in spaced-apart relation along the center conductor pin. The center conductor pin has a base coupled to the multilayer package, and the plurality of metal disks have decreasing diameters with increasing distance from the multilayer package. The coaxial connector includes a shroud brazed on the multilayer package, surrounding the center conductor pin and the metal disk structure thereon and receiving the coaxial cable therein.
In a preferred arrangement according to the invention, the multilayer package includes a stack of ceramic layers, inside which a coaxial via structure exists. The center conductor pin of the broadband RF connector has a braze pad at a base thereof which is brazed to the stack of the ceramic layers. Within the ceramic layers the center via of the coaxial structure is connected to the braze pad. The multilayer package may include a ring of ground vias for construction of coaxial via structure.
Impedance matching in accordance with the invention is achieved with only relatively minor modification of conventional coaxial structures. More specifically, a plurality of the thin metal disks are mounted on the center conductor pin adjacent the braze pad at the base of the pin. Additionally, the size and shape of a shroud which surrounds the center conductor pin is adjusted so as to accommodate the thin conductive disks.
In a preferred arrangement, three conductive disks are mounted on the center conductor pin in spaced-apart relation adjacent the braze pad of the pin. The diameter of each disk is different from the diameter of the other two disks, and the disks are mounted such that the diameters thereof decrease with increasing distance from the braze pad.
The center conductor pin 10 is of conventional design and has a generally cylindrical portion 22 which terminates in a tip 24. The center conductor pin 10 has a second cylindrical portion 26 of diameter which is larger than the diameter of the cylindrical portion 22. The second cylindrical portion 26 extends between the first cylindrical portion 22 and a base 28 of the center conductor pin on which a braze pad 30 is mounted.
As shown in the side view of
The center conductor pin 10 with the metal disk structure 14 thereon form a part of the coaxial connector 12 which is shown in
The shroud 32 has an opening 40 therein for receiving the coaxial cable 36 to couple the coaxial cable 36 to the multilayer package 34 by way of the coaxial connector 12.
The transmission line structure within the multilayer package 34 may comprise a coaxial via structure, as in the case of the present example, or it may comprise a slabline structure or a stripline structure.
As previously noted, the metal disk structure 14 consisting of the disks 16, 18 and 20 on the center conductor pin 10 provides impedance matching with the result that improved broadband performance is achieved. This is illustrated by the diagrammatic plots in
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Number | Date | Country | |
---|---|---|---|
20080200068 A1 | Aug 2008 | US |