Generally, the invention relates to the field of electrical connectors.
Specialized electrical connectors are used to connect different electrical components in order to allow electrical signal transmission between these components. It is known that cross talk between contacts of such an electrical connector influences the signal integrity of the signals transmitted by these electrical connectors.
Several approaches are known in the art for reducing the amount of cross talk between differential signaling contacts in the electrical connectors and, thus, to improve the signal integrity of these connectors.
In some differential signal connectors, a configuration of shielding plates and ground contacts is used to minimize cross talk between contacts of the connector. However, this approach results in connectors with lots of components and, consequently, expensive and heavy connectors.
In other differential signal connectors, shielding plates have been omitted. In these connectors, pairs of differential signal contacts are arranged in a staggered fashion in slots of a regular matrix and ground contacts are arranged between the staggered pairs of differential signal contacts in order to minimize cross talk between the differential signal contacts.
In still other differential signal connectors, an approach is taken wherein the housing of the electrical connector is modified in order to provide an irregular matrix of staggered slots. The differential signal contacts are received in the staggered slots. The thus achieved staggering of the differential signal contacts reduces the amount of cross talk between these differential signal contacts of the electrical connector.
It is an object of the invention to provide an electrical connector that is capable of providing a considerable reduction of cross talk between the contacts of the electrical connector.
To that end, an electrical connector is proposed that comprises an insulating connector housing containing a plurality of slots arranged in a matrix of rows and columns. A plurality of single ended contacts is received in the slots. In particular, the single ended contacts are arranged in pairs in said slots of said matrix, such that, in a first row, a first pair of said contacts accommodates slots in a first column and a second column of said matrix and, in a second row adjacent to said first row, a second pair of said contacts accommodates slots in said second column and a third column of said matrix, wherein the positions corresponding respectively to the first row and the third column, and to the first column and the second row are free of contact.
Furthermore, an electrical connector is proposed that comprises an insulating connector housing containing a plurality of slots arranged in a matrix of rows and columns. A plurality of single ended contacts is received in the slots. In particular, the single ended contacts are arranged in row wise pairs in said slots of said matrix, such that, in a first row, a first pair of said contacts accommodates slots in a first column and a second column of said matrix and, in a second row adjacent to said first row, a second pair of said contacts accommodates slots in said second column and a third column of said matrix. The matrix comprises contact-free slots in said rows of said matrix between said pairs of contacts.
Moreover, a tip and ring connector is proposed that comprises an insulating connector housing containing a plurality of slots arranged in a matrix of rows and columns. The insulating housing further accommodates a plurality of modules containing said slots. The connector is free of electromagnetic shielding plates between said modules. A plurality of single ended contacts is arranged in said slots. The single ended contacts are arranged in pairs in said slots of said matrix, such that, in a first row, a first pair of said contacts accommodates slots in a first column and a second column of said matrix and, in a second row adjacent to said first row, a second pair of said contacts accommodates slots in said second column and a third column of said matrix. The matrix comprises contact-free slots in said rows of said matrix between said pairs of contacts.
The prior art electrical connectors that employ staggered signal contacts to obtain an acceptable signal integrity behavior all relate to differential signal electrical connectors. The applicant has realized that the same behavior is sometimes desired for electrical connectors employing single ended contacts, such as connectors for xDSL applications. xDSL applications may involve HDSL, ADSL, VDSL and VDSL2 applications. In conventional electrical connectors with single ended contacts, such as the Metral® electrical connector of the applicant, the single ended signal contacts and ground contacts are located in slots of a housing, which slots arranged in rows and columns of a regular matrix. By removing the ground contacts from the slots of such a conventional connector, the single ended signal carrying contacts are left in the housing in an already staggered configuration as defined in claim 1. Surprisingly, the applicant has found that such a connector has an acceptable signal integrity behavior for xDSL applications, despite the fact that the electrical parameters (voltage, frequency) between single ended contact connectors and differential contact connectors differ considerably. It should be noted that the terms “row(s)” and “column(s)” can be interchanged in the claims.
The embodiment of the invention as defined in claim 2 provides the advantage that the housing of the electrical connector does not require modification.
The embodiments of the invention as defined in claims 5, 6, 9, 10 and 11 provide the advantage of improved manufacturability of the electrical connector.
The embodiment of the invention as defined in claim 8 provides the advantage of providing sufficient space between the board contacts for signal routing tracks while meeting criteria with respect to a minimum clearance and creepage distance.
Further advantageous embodiments are defined in the dependent claims.
It should be noted that the embodiments, or aspects thereof, may be combined.
The invention will be further illustrated with reference to the attached drawings, which schematically show preferred embodiments according to the invention. It will be understood that the invention is not in any way restricted to these embodiments.
In the drawings:
The values of some electrical parameters for single ended contact applications, such as xDSL applications, differ significantly from those for differential contact applications. As an example, for xDSL applications single ended contacts typically carry voltages of the order of volts (e.g. −48V) as opposed to voltages of the order of millivolts for differential signals, whereas signal frequencies for xDSL applications are of the order of megahertz (e.g. 20 MHz (VDSL) or 30 MHz (VDSL2)) as opposed to frequencies of the order of
GHz for differential signals.
In particular,
Preferably, the connector is free of signal ground contacts and free of electromagnetic shielding plates. A typical distance between the contacts 9 of pair 13 and pair 14 is 2 mm. It should be appreciated that a board connector 3 to be connected with a cable connector 2 having a staggered arrangements of staggered single ended contacts 9 as illustrated in
The table below provides measurement results for the near end cross talk (NEXT) and far end cross talk (FEXT) in decibels (dB) at different frequencies (VDSL, VDSL2). The measurements have been performed for a cable connector with four rows R and six columns C for a contact pair in the third row R3. The normal arrangement refers to a cable connector 2, wherein all slots 11 are filled with single ended contacts 9. Clearly, the cross talk results for staggered pairs single ended contacts 9 with empty slots 11 arranged in rows between these pairs show an improved cross talk behavior as compared with a normal arrangement of contacts in the housing. The cross talk performance of the connectors with staggered contacts is suitable for VDSL and VDSL 2 applications.
The housing 12 with the modules 16 is partly accommodated in a space defined by a die cast hood 20 and partly extends from this space. In the die cast hood, retention features provide for adequately retaining the cable 4. Wires (not shown) of the cable 4 are connected to the contacts 12 provided in the slots 11. Furthermore, the die cast hood 20 accommodates diametrically arranged fastening means, such as screws 21, for attaching the cable connector 2 to a panel behind which a board connector 3 is present. The hood 20 comprises two parts that are attached by means of screws to allow repair of the connector in the field.
As shown in
The housing 12 of the board connector 3 provides the mating side 8 containing slots 11 filled with single ended contacts 10 as a mirror image of
The housing 12 of the board connector 3 is supported by pegs 30 for attachment of the board connector 3 to the PCB 5. The housing 12 is constructed such that a cut out in the PCB 5 is not required. As clearly shown in
As is best illustrated in
As already briefly mentioned with reference to
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2007/052716 | 5/23/2007 | WO | 00 | 3/12/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/142489 | 11/27/2008 | WO | A |
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