A device for automatically mounting a connector-housing with a contact-part attached to an electrical line includes a holder, a movable-gripper, an alignment-station, a camera, and a control-device. The holder fixes the connector-housing. The movable-gripper holds the contact-part and inserts the contact-part into a cavity of the connector-housing. The alignment-station includes an alignment-gripper that holds the contact-part and rotates the contact-part about a rotation-axis parallel to an insertion-direction. The camera determines an actual-rotational-position of the contact-part held by the alignment-gripper in relation to the rotation-axis. The control-device compares the actual-rotational-position with a predetermined-rotational-position based on the characteristics and arrangement of the connector-housing. The control-device further controls the alignment-gripper to perform a corrective rotational movement based on the result of the comparison.

There is described a method for testing equipment using a test box unit and a mate-in interface having a unique mate-in interface ID, the equipment comprising a plurality of contacts. The method comprises connecting a mate-in interface to the test box unit, connecting the mate-in interface to the contacts of the equipment; selecting a mate-in interface for testing using the unique mate-in interface ID; in the mate-in interface as selected, selecting any one of the contacts for testing; and testing the any one of the contacts of the selected mate-in interface to ground and against each other one of the contacts by inputting a signal and measuring the signal through the selected mate-in interface. There can then be automatically created a list of connections for the equipment making use of the detected or otherwise obtained unique mate-in interface ID.

A system and method are described for improved connector position assurance. A latch stop mechanism (10) on a first connector may be used to selectively limit movement of a latch (50) and attached latch lock (54) after the latch lock (54) has been engaged to secure the first connector to a second connector. The latch stop mechanism (10) may be attached to the connector housing (80) and have a series of hinges (12), (16) that allow a latch stop mechanism (10) to pivot into place, limiting movement of the latch (50) and latch lock (54). A terminal position assurance (TPA) (30) may be located on the bottom of the connector main body and when engaged, ensures proper positioning of the engaged wire terminal.

The present document describes an assembly for connecting a test unit to a wiring harness or equipment to be tested, and a method for testing using the assembly. The assembly may comprise a test box unit, a generic mate-in interface, and at least one specific mate-in interface. The generic mate-in interface is for connection to the test box unit on one end, and to the at least one specific mate-in interfaces at the other end. The mate-in interfaces are for testing different existing wiring harnesses or equipment. Each one of the generic and specific mate-in interfaces has a specific ID comprised in an ID support on the electrical path of the generic mate-in interface and the specific mate-in interface, for example, on any one of the end connectors of the interfaces or on their wiring. Information relating to the IDs of the connectors and the contact configuration of each mate-in interface is stored in a database of the test unit for identifying the appropriate test contacts that should be used for testing.

Methods and systems for providing crosstalk compensation in a jack are disclosed. According to one method, the crosstalk compensation is adapted to compensate for undesired crosstalk generated at a capacitive coupling located at a plug inserted within the jack. The method includes positioning a first capacitive coupling a first time delay away from the capacitive coupling of the plug, the first capacitive coupling having a greater magnitude and an opposite polarity as compared to the capacitive coupling of the plug. The method also includes positioning a second capacitive coupling at a second time delay from the first capacitive coupling, the second time delay corresponding to an average time delay that optimizes near end crosstalk. The second capacitive coupling has generally the same overall magnitude but an opposite polarity as compared to the first capacitive coupling, and includes two capacitive elements spaced at different time delays from the first capacitive coupling.

A compliant pin pre-screening, guiding and quality monitoring apparatus is provided. The compliant pin pre-screening, guiding and quality monitoring apparatus includes a fixed plate, a movable plate, a printed circuit board (PCB) and a press-fit connector. The fixed plate defines a through-hole and is disposable above a working table. The movable plate is disposable to be urged by a bias against a first surface of the fixed plate facing the working table and includes pin extendable through the through-hole. The PCB defines a via and is disposable on a second surface of the fixed plate opposite the first surface whereby the pin is extendable through the via with the via corresponding in position to the through-hole and the pin. The press-fit connector is disposable to be secured in position proximate to the PCB and to be inserted into the via with guidance provided by the pin against the bias.

A connector-soldering aid (1) for soldering single and/or cable wires to a connector comprises a connector mount (5) with a first stand (9) and a cable mount (7) with a second stand (31). The connector mount (5) has a base body (17), which is arranged on the first stand (9) and is rotatable relative to the latter about a fixed axis of rotation (19). The connector mount (5) further comprises a replaceable attachment (21) with a connector receiver and a centring device (23) for centring the attachment (21). The centring device (23) is arranged on the base body (17) and is further formed to centre the attachment (21) such that the connector receiver is positioned centrally in relation to the axis of rotation (19) of the base body (17).

A module installation assembly for installing a module into a socket of a land grid array includes a tool having a mounting bracket for connecting the tool to an adjacent fixture, an alignment member connected to the mounting bracket, and cavity defined at least partially by the alignment member. The cavity is substantially aligned with a socket of the land grid array such that the module is configured to pass through the cavity when being connected to the socket.

A connector support assembly is configured to securely retain an electrical connector during a manufacturing process. The connector support assembly may include a base, a first securing member, and a second securing member. The first and/or second securing members is movable, and is configured to be moved between an open position in which a mating connector of the electrical connector is positioned between the first and second securing members, and a clamped position in which the mating connector is securely clamped between the first and second securing members.

Methods and systems for providing crosstalk compensation in a jack are disclosed. According to one method, the crosstalk compensation is adapted to compensate for undesired crosstalk generated at a capacitive coupling located at a plug inserted within the jack. The method includes positioning a first capacitive coupling a first time delay away from the capacitive coupling of the plug, the first capacitive coupling having a greater magnitude and an opposite polarity as compared to the capacitive coupling of the plug. The method also includes positioning a second capacitive coupling at a second time delay from the first capacitive coupling, the second time delay corresponding to an average time delay that optimizes near end crosstalk. The second capacitive coupling has generally the same overall magnitude but an opposite polarity as compared to the first capacitive coupling, and includes two capacitive elements spaced at different time delays from the first capacitive coupling.