DE202008002209U1 - Electrical connector - Google Patents

Abstract

An electrical connector, namely a data jack for contactingly receiving at least one data connector, comprising a housing and a connector positioned within the housing, the connector comprising at least eight substantially parallel electrical conductors forming an electrical conductive path between the input and output terminals of the connector, and the two middle adjacent adjacent electrical conductors forming a second pair of leads with one leading and one returning conductor, and the two outer adjacent electrical conductors forming a third and a fourth pair of leads with a trailing and a return conductor, respectively, for minimizing near-end crosstalk are crossed between the electrical conductors without electrical contact between the same, whereas the between the two crossed middle adjacent electrical Leit ern and the two crossed outer adjacent electrical conductors extending electrical conductors, which form a first pair of cables with a leading and a returning conductor are cross over free, characterized in that
a) between the first line pair (11) and the second line pair ...

Description

The The invention relates to an electrical connector according to the preamble of claim 1.

From the EP 0 558 225 B2 is an electrical connector with a housing and a housing positioned in the connector means known, wherein the connecting means comprises a plurality of substantially parallel electrical conductors forming an electrical conduction path between the input terminals and output terminals of the connecting means.

To minimize near-end crosstalk between the electrical conductors, it is out of the EP 0 558 225 B2 already known, at least to cross some adjacent electrical conductors without electrical contact between them. This can to a certain extent already minimize near-end crosstalk. However, especially when the electrical path provided by the electrical conductors between the input terminals and the output terminals of the connection means is short and / or when data signals having high transmission frequencies of more than 500 MHz are to be transmitted, the minimization of the near-end crosstalk achievable thereby is not sufficient.

Of the The present invention is based on the problem of a the achievable minimization of near-end crosstalk improved electrical To create connectors.

This Problem is solved by an electrical connector according to claim 1 solved. According to the invention electrical connector characterized in that a) between the first line pair and the second line pair have near-end crosstalk compensation is constructed such that at least before the crossing of the head of the second Line pairs in the range of free ends of the same one hand between the leading conductor of the first pair of wires and the returning conductor of the second pair of lines a capacity and on the other hand between the returning one Head of the first line pair and the leading conductor of the a second line pair is connected a capacitance; b) between the first line pair and the third line pair have near-end crosstalk compensation is constructed such that at least before the crossing of the head of the third pair of wires between the leading conductors of the first Line pair and the leading conductor of the third line pair in the range of free ends of the same one capacity and after the crossover the conductor of the third pair of wires between the incoming conductors of the first pair of wires and the returning conductor of the third Line pairs a capacity is switched; c) between the first pair of wires and the fourth Pair of lines a Nahnebensprechkompensation is constructed such that at least before the crossover the conductor of the fourth pair of wires between the incoming conductors of the first pair of wires and the returning conductor of the fourth Line pairs in the range of free ends of the same one capacity and after the crossover the head of the fourth pair of wires between the returning ones Head of the first pair of wires and the return conductor of the fourth pair of wires a capacity is switched.

With Such an electrical connector can in particular then, when the electrical conduction path between the input terminals and the output connections is short and / or when transmitting data signals with high transmission frequencies to achieve a good minimization of near-end crosstalk become.

preferred Further developments of the invention will become apparent from the dependent claims and the following description. Embodiments of the invention without being limited to this to be closer to the drawing explained. In the drawing shows:

1 an equivalent circuit diagram of an electrical connector according to the invention according to a first embodiment of the invention;

2 an equivalent circuit diagram of an electrical connector according to the invention according to a second embodiment of the invention;

3 an equivalent circuit diagram of an electrical connector according to the invention according to a third embodiment of the invention;

4 : An equivalent circuit diagram of an electrical connector according to the invention according to a fourth embodiment of the invention.

The present invention relates to an electrical connector, namely a data socket for contact receiving at least one data connector. The basic structure of such an electrical connector is known from the prior art, in particular EP 0 558 225 B2 , known. Thus, such an electrical connector comprises a housing and a connecting device positioned in the housing, wherein the connecting device has a plurality of substantially parallel to each other, electrical conductors.

1 schematically shows a replacement switch Image of an electrical connector according to the invention according to a first embodiment of the invention in the region of substantially parallel to each other, electrical conductors of the positioning means positioned in the housing, wherein according to 1 the connecting device a total of eight electrical conductors 1 . 2 . 3 . 4 . 5 . 6 . 7 and 8th includes. The electrical conductors 1 to 8th form an electrical conduction path between input terminals 9 and output terminals 10 the connection device.

The ladder 1 to 8th the connector of the 1 form a total of four pairs of lines, namely a first pair of wires 11 , a second pair of wires 12 , a third pair of wires 13 and a fourth line pair 14 , The first line pair 11 is from the ladders 3 and 6 formed, it is the head 3 around the running ladder and the ladder 6 is about the returning conductor. The second line pair includes the conductors 4 and 5 , where it is the leader 4 around the running ladder and the ladder 5 is the returning conductor of the second line pair. The third line pair 13 includes the ladder 1 and 2 and the fourth line pair 14 the ladder 7 and 8th , where it is the ladders 2 and 8th each around the leading ladder and the ladders 1 and 7 in each case around the returning conductors of the corresponding cable pairs 13 . 14 is.

The running ladder 2 . 3 . 4 . 8th are each with (+) and the returning ladder 1 . 5 . 6 . 7 each marked with (-).

According to 1 are some neighboring conductors 1 and 2 . 4 and 5 such as 7 and 8th that is, the conductors of the second line pair 12 , the third line pair 13 and the fourth pair of wires 14 , crossed to minimize near-end crosstalk between the electrical conductors without electrical contact therebetween, the crossover of the conductors 4 . 5 of the second line pair 12 by the reference number 15 , the crossover of the electrical conductors 1 . 2 of the third line pair 13 by the reference number 16 and the crossover of the ladder 7 . 8th of the fourth pair of wires 14 by the reference number 17 Marked are. By this crossing of the adjacent electrical conductors 1 and 2 . 4 and 5 such as 7 and 8th Already to some extent, near-end crosstalk compensation can be realized.

The ladder 3 . 6 of the first line pair 11 are not crossed.

In the electrical connector according to the invention is according to 1 between the first pair of wires 11 and the second line pair 12 An adjacent crosstalk compensation is constructed such that before crossover 15 the leader 4 and 5 of the second line pair 12 in the region of free ends of the conductors 3 . 4 . 5 and 6 on the one hand between the running ladder 3 of the first line pair 11 and the returning conductor 5 of the second line pair 12 a capacitor C35 and on the other hand between the returning conductors 6 of the first pair of wires and the leading conductor 4 of the second line pair 12 a capacity C46 is switched.

Furthermore, according to the electrical connector according to the invention 1 between the first pair of wires 11 and the third line pair 13 An adjacent crosstalk compensation is constructed such that before crossover 16 the leader 1 . 2 of the third line pair 13 between the running ladder 3 of the first line pair 11 and the walking ladder 2 of the third line pair 13 in the area of the free ends of the same a capacity C23 and after the crossover 16 the leader 1 . 2 of the third line pair 13 between the running ladder 3 of the first line pair 11 and the returning conductor 1 of the third line pair 13 a capacitor C13 is connected.

Furthermore, in the electrical connector according to the invention between the first line pair and the fourth line pair 14 An adjacent crosstalk compensation is constructed such that before crossover 17 the leader 7 . 8th of the fourth pair of wires 14 between the running ladder 3 of the first line pair 11 and the returning conductor 7 of the fourth pair of wires 14 in the area of free ends of the same a capacity C37 and after the crossover 17 the leader 7 . 8th of the fourth pair of wires 14 between the returning conductors 6 of the first line pair 11 and the returning conductor 7 of the fourth pair of wires 14 a capacity C67 is switched.

In the embodiment of 1 is therefore between the first pair of wires 11 and the third line pair 13 and between the first pair of wires 11 and the fourth pair of wires 14 built a multi-level compensation for near-end crosstalk. The capacitors C23, C13, C37 and C67 used for this purpose are preferably plate capacitors.

Likewise, the capacitances C35 and C46 are between the conductors 3 and 5 respectively. 4 and 6 from the first pair of wires 11 and second line pair 12 are switched, each preferably by plate capacitors.

Capacities C13 and C67 following the crossovers 16 . 17 and therefore in the area of the output terminals 10 are each positioned over a stub 18 to the appropriate ladder 1 and 3 respectively. 6 and 7 connected. The Connect the capacitors C13 and C67 via the spur lines 18 to the corresponding electrical conductors serves the further reduction of near-end crosstalk.

2 shows an advantageous development of the electrical connector of 1 Therefore, the same reference numerals are used to avoid unnecessary repetition for the same components below and in connection with 2 only the details will be described by which the embodiment of the 2 from the embodiment of 1 different.

Thus, in the embodiment of 2 the near-end crosstalk compensation between the first pair of lines 11 and the second line pair 12 further developed by the fact that after the crossover 15 the electrical conductor 4 and 5 of the second line pair 12 and thus in the area of the output connections 13 between the running ladder 3 of the first pair of wires and the leading conductor 4 of the second line pair, another capacitor, namely the capacitor CF34, is connected.

Likewise, between the returning ladder 6 of the first line pair 11 and the returning conductor 5 of the second line pair 12 after the crossover 15 the leader 4 and 5 of the second line pair 12 and thus in the area of the output connections 10 between the same another capacity, namely the capacity CF56, switched. The two capacitors CF34 and CF56 are in each case coupling interdigital capacitors or so-called finger capacitors. These capacities CF34 and CF56 are also each via a spur line 18 to the corresponding electrical conductors 3 and 5 such as 4 and 6 from the first pair of wires 11 and second pair of wires 12 connected.

A further advantageous embodiment of the embodiment of 1 shows 3 , wherein also for the embodiment of 3 for identical components same reference numerals are used and only those details are described by which the embodiment of the 3 from the embodiment of 1 different.

So is the embodiment of the 3 the near-end crosstalk compensation between the first pair of lines 11 and the fourth pair of wires 14 so developed that after the crossover 17 the leader 7 . 8th of the fourth pair of wires 14 and thus in the area of the output connections 10 between the running ladder 8th of the fourth pair of wires 14 and the returning conductor 6 of the first line pair 11 a capacitor C68 is connected, which is designed as a plate capacitor and a stub line 18 to the ladder 6 . 8th connected. Furthermore, in the embodiment of the 3 for near-end crosstalk compensation between the second pair of wires 12 and the third line pair 13 after the crossover points 15 and 16 the leader 3 . 4 of the second line pair 12 and the leader 1 . 2 of the third line pair 13 between the running ladder 2 of the third line pair 13 and the returning conductor 5 of the second line pair 12 a capacitor C25 connected, which in turn is designed as a plate capacitor and a stub line 18 to the ladder 2 . 5 connected.

The further embodiment of the 4 is a combination of the embodiments 2 and 3 Accordingly, it comprises both the capacitances CF34 and CF56 and the capacitances C25 and C68, in each case in the region of the output terminals 10 ,

With all embodiments of the 1 to 4 the electrical connector according to the invention, a good electrical performance for the compensation of the near-end crosstalk between all four pairs of lines can be achieved in each case.

By the small number of needed capacities can be a reliable one and reproducible electrical connector with stable electrical Performance be provided. By the simple close crosstalk compensation can be a cost effective electrical connector can be provided.

The inventive principle An electrical connector can be used for any geometry Contact springs forming part of the electrical conduction path of the electrical conductors are used.

1

ladder

2

ladder

3

ladder

4

ladder

5

ladder

6

ladder

7

ladder

8th

ladder

9

input port

10

output port

11

first line pair

12

second line pair

13

third line pair

14

fourth line pair

15

crossing

16

crossing

17

crossing

18

stub

Claims (5)

An electrical connector, namely a data jack for contactingly receiving at least one data connector, comprising a housing and a connector positioned within the housing, the connector comprising at least eight substantially parallel electrical conductors forming an electrical conductive path between the input and output terminals of the connector, and the two middle adjacent adjacent electrical conductors forming a second pair of leads with one leading and one returning conductor, and the two outer adjacent electrical conductors forming a third and a fourth pair of leads with a trailing and a return conductor, respectively, for minimizing near-end crosstalk are crossed between the electrical conductors without electrical contact between the same, whereas the between the two crossed middle adjacent electrical Leit ners and the two crossed outer adjacent electrical conductors extending electrical conductors which form a first pair of cables with a leading and a returning conductor are crossover-free, characterized in that: a) between the first pair of wires ( 11 ) and the second line pair ( 12 ) a near-end crosstalk compensation is constructed in such a way that at least before the crossover ( 15 ) the ladder ( 4 . 5 ) of the second line pair ( 12 ) in the region of free ends of the same on the one hand between the running ladder ( 3 ) of the first pair of lines ( 11 ) and the returning conductor ( 5 ) of the second line pair ( 12 ) one capacitance (C35) and, on the other hand, between the returning conductors ( 6 ) of the first pair of lines ( 11 ) and the leading conductor ( 4 ) of the second line pair ( 12 ) a capacitance (C46) is connected; b) between the first pair of wires ( 11 ) and the third line pair ( 13 ) a near-end crosstalk compensation is constructed in such a way that at least before the crossover ( 16 ) the ladder ( 1 . 2 ) of the third pair of lines ( 13 ) between the running ladder ( 3 ) of the first pair of lines ( 11 ) and the leading conductor ( 2 ) of the third pair of lines ( 13 ) in the region of free ends of the same a capacity (C23) and after the crossover ( 16 ) the ladder ( 1 . 2 ) of the third pair of lines ( 13 ) between the running ladder ( 3 ) of the first pair of lines ( 11 ) and the returning conductor ( 1 ) of the third pair of lines ( 13 ) a capacitor (C13) is connected; c) between the first pair of wires ( 11 ) and the fourth line pair ( 14 ) a near-end crosstalk compensation is constructed in such a way that at least before the crossover ( 17 ) the ladder ( 7 . 8th ) of the fourth pair of lines ( 14 ) between the running ladder ( 3 ) of the first pair of lines ( 11 ) and the returning conductor ( 7 ) of the fourth pair of lines ( 14 ) in the area of free ends of the same one capacity (C37) and after the crossover ( 17 ) the ladder ( 7 . 8th ) of the fourth pair of lines ( 14 ) between the returning conductors ( 6 ) of the first pair of lines ( 11 ) and the returning conductor ( 7 ) of the fourth pair of lines ( 14 ) a capacity (C67) is switched. Connector according to claim 1, characterized in that the near-end crosstalk compensation between the first pair of lines ( 11 ) and the second line pair ( 12 ) is developed such that after the crossover ( 15 ) the ladder ( 4 . 5 ) of the second line pair ( 12 ) between the running ladder ( 3 ) of the first pair of lines ( 11 ) and the leading conductor ( 4 ) of the second line pair ( 12 ) one capacity (CF34) and between the returning conductors ( 6 ) of the first pair of lines ( 11 ) and the returning conductor ( 5 ) of the second line pair ( 12 ) a capacity (CF56) is switched. Connector according to claim 1 or 2, characterized in that the near-end crosstalk compensation between the first pair of lines ( 11 ) and the fourth line pair ( 14 ) is developed such that after the crossover ( 17 ) the ladder ( 7 . 8th ) of the fourth pair of lines ( 14 ) between the running ladder ( 8th ) of the fourth pair of lines ( 14 ) and the returning conductor ( 6 ) of the first pair of lines ( 11 ) a capacity (C68) is switched; for near-end crosstalk compensation between the second line pair ( 12 ) and the third line pair ( 13 ) after the crossovers ( 15 . 16 ) the ladder ( 3 . 4 ) of the second line pair ( 12 ) and the leader ( 1 . 2 ) of the third pair of lines ( 13 ) between the running ladder ( 2 ) of the third pair of lines ( 13 ) and the returning conductor ( 5 ) of the second line pair ( 12 ) a capacity (C25) is connected. Connector according to one of claims 1 to 3, characterized in that after the crossovers ( 15 . 16 . 17 ) between conductors switched capacitances (C13, C67, C25, C68, CF34, CF56) to form stubs ( 18 ) are connected to the respective conductors. Connector according to one of claims 1 to 4, characterized in that first capacitances (C23, C35, C46, C37, C13, C67, C25, C68) as plate capacitors and second capacitors (CF34, CF56) are designed as coupling interdigital capacitors.