DE102016008679A1 - Adapter and cable with adapter - Google Patents

Abstract

An adapter (1; 1 '; 1' '; 1' '', 1 '' '') for inner conductors of a cable in an RF connector has a first connection region (3) with two first pairs (51, 52) contact regions each having a first and a second contact region (611, 612, 621, 622) and a second connection region (4) having two second pairs (101, 102) of contact regions each having a third and fourth contact region (911, 912, 921, 922). The two first pairs (51, 52) of contact regions are arranged parallel to one another, while the two second pairs (101, 102) are arranged crossed over from one another by contact regions. The first and second contact regions (611, 621) of the one first pair (51) of contact regions and the first and second contact regions (612, 622) of the other first pair (52) of contact regions are each connected via a connecting line to the third or fourth contact region (911, 921) of the one second pair (101) of contact regions or with the third and fourth contact region (912, 922) of the other second pair (102) of contact regions electrically connected. Two connecting lines of the first, second, third and fourth connecting lines (7, 8, 11, 12; 7 ', 8', 11 ', 12', 7 '', 8 '', 11 '', 12 '', 7 ' '', 8 '' ', 11' '', 12 '' ', 7' '' ', 8' '' ', 11' '' ', 12' '' ') are each arranged parallel to each other. In the case of a cable (13) with attached adapter (1; 1 '; 1 ", 1"', 1 ""), instead of the first, second, third and fourth connecting lines, the inner conductors of the cable from the first connection area (3 ) led to the second connection area (4).

Description

The invention relates to an adapter and a cable having an adapter.

Data networks in automobiles today transmit data for different applications, such as sensor data, consumer electronics data, in a comparatively very high data rate over 1 GB / s. For this purpose, so-called HSD cables (high speed data, German: data in a high transmission rate) have been established. Such HSD cables have, for the parallel transmission of two differential signals, two pairs of data lines which are arranged in a so-called star quad array and are spirally stranded along the data line.

While the stranding of the star quad array results in a lower packing density, the star quad array allows for less crosstalk between the two pairs of data lines, at least in the lower to midrange frequency range. In the higher frequency range, the crosstalk between the individual pairs of data lines deteriorates significantly.

For the higher frequency range cables are therefore increasingly used, in each of which two shielded and parallel, d. H. non-crossed, pairs of data lines. The shielding of each individual pair of data lines improves crosstalk between the individual pairs.

Due to the much higher prevalence of cables with star quad array compared to cables with parallel and each shielded pairs of data lines exist in automotive many connectors with connection, for example, to a circuit board of RF electronics, which are aligned to a star-quad array of data lines are. The connection of prefabricated cables with parallel and respectively shielded pairs of data lines to existing printed circuit boards of RF electronics with a connector in star-quad array of data lines is therefore not possible and thus adversely affects the universal use of such cables.

The object of the invention is therefore to provide a device with the cable with parallel and shielded pairs of data lines to connectors in star quad array of data lines are coupled.

The object is achieved by an adapter according to the invention with the features of claim 1 and by a cable according to the invention, at the end of an adapter, with the features of claim 11. Advantageous technical extensions can be taken from the respective dependent claims.

The adapter according to the invention has a first connection region with two first pairs of contact regions, each having a first and a second contact region, and a second connection region having two second pairs of contact regions, each having a third and a fourth contact region. The two first pairs of contact regions in the first connection region are arranged parallel to one another, while the two second pairs of contact regions in the second connection region are arranged crossed over one another.

Thus, a cable with two parallel, preferably shielded, pairs of data lines can be connected to the first connection region of the adapter and the second connection region of the adapter can be connected to the data lines of a mating connector present in a star quad array. Consequently, in each case two differential signals can be transmitted via both connection areas.

The first contact region of the one first pair of contact regions is electrically connected via a first connection line to the third contact region of the one second pair of contact regions, while the second contact region of the one first pair of contact regions is connected via a second connection line to the fourth contact region of the one second pair Contact areas is electrically connected. The first contact region of the other first pair of contact regions is electrically connected via a third connection line to the third contact region of the second pair of contact regions, while the second contact region of the other first pair of contact regions via a fourth connection line to the fourth contact region of the second pair of contact regions connected is.

In this manner, the conversion from the two parallel first pairs of contact regions of the first connection region into the two second pairs of contact regions of the second connection region arranged in a star-quad arrangement takes place via the first, second, third and fourth connection lines.

According to the invention, two connecting lines of the first, second, third and fourth connecting line are each arranged parallel to one another between the first and second connecting region.

In this way, the number of crossover lines arranged between each other between the first and second connection region is minimized to two. Compared to the crossed connecting lines, which have a comparatively high inductive and capacitive overcoupling in the crossover region, the inductive and capacitive overcoupling between the parallel connecting lines is relatively lower due to the higher distance between the parallel connecting lines.

In addition to the solution according to the invention of an adapter which can be connected to the cable at its first connection region, the integration of an adapter according to the invention at the end of a cable is also expedient.

For this purpose, the two shielded pairs of inner conductors of the cable are not only guided to the two parallel first pairs of contact areas in the first connection area, but the first, second, third and fourth connection lines of the adapter according to the invention replaced by the inner conductor of the cable. These inner conductors of the cable are thus guided to the contact regions of the second connection region of the adapter. Thus, the first and second contact areas of the one pair of contact areas are electrically connected to the third and fourth contact areas of the one second pair of contact areas, respectively, via a different inner conductor of the one pair of inner conductors of the cable, while the first and second contact areas of the other one Pair of contact regions via a respective different inner conductor of the other pair of inner conductors with the third and fourth contact region of the second pair of contact regions are electrically connected.

Preferred technical extensions are realized both for the individual adapter and for the cable with integrated adapter:
In order to minimize the inductive over-coupling between the two crossing lines arranged crosswise to each other or between the two intersecting inner conductors in the region of the crossover, the crossover arranged interconnecting lines or crossed inner conductor are each oriented at an angle between 85 ° and 95 ° to each other , Preferably, the crossover arranged connecting lines or the crosswise arranged inner conductor are each oriented perpendicular to each other. For this purpose, the two interconnected interconnecting lines or the two interconnected inner conductors are preferably each in the region of the first connection area and the second connection area parallel to each other and parallel to the two parallel connection lines or parallel to the two parallel outgoing inner conductors out to in this way, to realize as orthogonal an orientation as possible of the two crossed connection lines or of the two crossed inner conductors arranged in the region of the crossing.

The capacitive overcoupling between the two crossover interconnected connecting lines or between the two intersecting arranged inner conductors in the region of the crossover is minimized by the distance between the two cross-over arranged connecting lines or between the two crossed to each other arranged inner conductors in the crossover area is maximized :
In a first variant for minimizing the capacitive overcoupling, the two interconnecting lines arranged in a cross-over to one another or the two cross-directionally arranged inner conductors are preferably convexly curved with respect to one another. Thus, in the middle between the first connection region and the second connection region, ie in the region of the crossover, they have their greatest distance from one another.

In the second variant, the minimization of the capacitive overcoupling between the two crossed connecting lines or between the two crossed inner conductors arranged is realized in that in each opposite regions of the two crossed interconnected connecting lines or the two crossed to each other arranged inner conductor in the area The crossover preferably material is removed in each case and thus the distance between the two crossed interconnected connecting lines or between the two crossed one another arranged inner conductors is increased.

In a third variant for minimizing the capacitive overcoupling, the two crossed interconnecting lines or the two crosswise arranged inner conductors are preferably each asymmetrically offset from the associated connecting line between the two contact areas of the first and second connecting area. The two interconnected connecting lines or the two crosswise arranged inner conductor then have their greatest possible distance in terms of minimized capacitive overcoupling, when the two asymmetrical dislocations are each phase-shifted by 180 ° to each other.

In addition, that connecting line of the two crossed over to each other arranged connecting lines or that inner conductor of the two intersecting arranged inner conductor in all three variants preferably has a different diameter than the respective other connection line of the two crossed connecting lines or as the other inner conductor of the two crossed to each other arranged inner conductor, the spatially closer to the peripheral surface of the cylindrical adapter and thus guided on the surrounding the adapter ground shield.

Preferably, that connecting line of the two crossed connecting lines or that inner conductor of the two crossed inner conductor arranged in all three variants preferably has a smaller diameter than the respective other connecting line of the two crossed interconnected connecting lines or as the other inner conductor of the two crossed to each other arranged inner conductor, which is guided spatially closer to the peripheral surface of the cylindrical adapter and thus on the surrounding the adapter ground shield.

The change, preferably the reduction, of the diameter of the connecting line guided closer to the ground shield of the two interconnected connecting lines or the inner conductor of the two inner conductors routed closer to the ground shield, advantageously effects an optimum value for the capacitive component of the impedance of the adapter between first and second connection area.

Since the two interconnected interconnecting lines or the two interconnected inner conductors have a greater length than the two mutually parallel connecting lines or the two mutually parallel inner conductors, the maturities of the RF signals in these interconnections or in these inner conductors each different. The signal components of a differential signal are no longer 180 ° out of phase after passing through the connecting lines or the inner conductor, but may have a different phase offset due to the different maturities in the two connecting lines or in the two inner conductors and therefore no longer represent an exact differential signal ,

A compensation of the different transit times in the differently arranged connecting lines or in the differently arranged inner conductors is effected by a different propagation speed of the signal components of the differential RF signal. For this purpose, the connecting lines arranged crosswise to one another or the inner conductors arranged crossed to one another are each surrounded by a material having a lower permittivity than the connecting lines arranged parallel to one another or the inner conductors arranged parallel to one another. The material with the lower permittivity causes a higher propagation speed, with which the greater length of the crossover interconnected interconnect lines or the crossover to each other arranged inner conductor is compensated. In this way, it is advantageously ensured that a differential RF signal with two signal components occurs at both connection regions of the adapter, each having a phase offset of 180 ° to one another.

In the following, the individual characteristics of the adapter according to the invention and of the cable according to the invention with connected adapter will be explained in detail with reference to the drawing. The figures of the drawing show:

1A . 1B . 1C a cross-sectional view in the longitudinal direction and in each case a cross-sectional view in the radial direction in the first and second connection region of a first embodiment of the adapter according to the invention,

2 a cross-sectional view in the longitudinal direction of a second embodiment of the adapter according to the invention,

3A . 3B . 3C a cross-sectional view in the longitudinal direction and in each case a cross-sectional view in the radial direction in the first and second connection region of a third embodiment of the adapter according to the invention,

4A . 4B . 4C a cross-sectional view in the longitudinal direction and in each case a cross-sectional view in the radial direction in the first and second connection region of a fourth embodiment of the adapter according to the invention,

5A . 5B . 5C a cross-sectional view in the longitudinal direction and in each case a cross-sectional view in the radial direction in the first and second connection region of a fifth embodiment of the adapter according to the invention and

6 a cross-sectional view in the longitudinal direction of a cable according to the invention with integrated adapter.

The following is a first embodiment of an adapter according to the invention 1 based on 1A . 1B and 1C explained in detail:
The adapter 1 has one with respect to a longitudinal axis 2 rotationally symmetrical basic body, which is preferably designed as a hollow cylinder. The preferred hollow cylindrical adapter 1 has in each case an end face in the area of its two end faces. The adapter 1 is preferably made as a plastic injection molded part, for example, polyethylene or polypropylene.

In the 1A right side face presents a first connection area 3 while the left end face shown a second connection area 4 forms. Both the first connection area 3 as well as the second connection area 4 each has a number of pairs of contact areas corresponding to the number of differential signals. Two pairs of contact areas corresponding to the number of differential signals transmitted in one HSD cable are preferably provided on both connection areas. The individual contact areas each cover the entire area of the associated, in 1A each illustrated holes or recesses in the first connection area 3 or in the second connection area 4 of the adapter 1 ,

According to 1C indicates the first connection area 3 two first couples 5 ₁ and 5 ₂ of contact areas, each with a first contact area 6 ₁₁ and 6 ₁₂ and a second contact area 6 ₂₁ and 6 ₂₂ on. The first two couples 5 ₁ and 5 ₂ of contact areas of the first connection area 3 are arranged parallel to each other.

In the first contact area 6 _{11 of} the first pair 5 ₁ of contact areas in the first connection area 3 is an inner conductor of the cable with a first connection line 7 For example, electrically connected via a soldering. In the second contact area 6 _{21 of} the first couple 5 ₁ of contact areas in the first connection area 3 is another inner conductor of the same pair of mutually shielded inner conductors of the cable with a second connecting line 8th electrically connected. The first connecting line electrically connected to the same pair of mutually shielded inner conductors of the cable 7 and second connection line 8th is characterized by a common hatching. The first connection line 7 is to a third contact area 9 _{11 of} a second pair 10 ₁ of contact areas in the second connection area 4 guided while the second connection line 8th to a fourth contact area 9 _{21 of the} same second pair 10 ₁ of contact areas in the second connection area 4 is guided.

In the first contact area 6 ₁₂ of another first pair 5 ₂ of contact areas in the first connection area 3 is an inner conductor of another shielded pair of inner conductors of the cable with a third connection line 11 electrically connected. In the second contact area 6 _{22 of} the other couple 5 ₂ of contact areas in the first connection area 3 is another inner conductor of this further shielded pair of inner conductors of the cable with a fourth connection line 12 electrically connected. The third connection line 11 and the fourth connection line 12 , which are electrically connected to the same pair of mutually shielded inner conductors of the cable, both are shown unshaded. The third connection line 11 is to a third contact area 9 ₁₂ of a further second pair 10 ₂ of contact areas in the second connection area 4 while the fourth connection line 12 to a fourth contact area 9 _{22 of the} same second pair 10 ₂ of contact areas in the second connection area 4 is guided.

As in the 1B and 1C is shown, represent the first, second, third and fourth connection line 7 . 8th . 11 and 12 each one bundle of conductive strands preferably made of copper with a sheath of a non-conductive plastic.

The first, second, third and fourth connection lines 7 . 8th . 11 and 12 are in the range of the first and second pairs 5 ₁ and 5 ₂ or 10 ₁ and 10 _{2 out} of contact areas either to the outer boundary or to the inner boundary of the respective contact area associated bore or recess. Alternatively, the first, second, third and fourth connection lines 7 . 8th . 11 and 12 also end within the respective contact area associated bore or recess.

Out 1A it can be seen that the second connecting line 8th and the fourth connection line 12 inside the adapter 1 each parallel to each other along the longitudinal axis 2 are arranged while the first connection line 7 and the third connection line 11 are each crossed over to each other.

The second and the fourth connection line 8th and 12 , which are each arranged parallel to each other, each have such a distance from one another and to a in 1A not shown, on the peripheral surface of the adapter 1 adjacent ground shielding, so that the inductive and capacitive overcoupling between the second and fourth connection line 8th and 12 total is minimized.

To minimize the inductive and capacitive overcoupling between the first and third connection line 7 and 11 , which are arranged crossed to each other, the following technical measures are preferably carried out:
In a second embodiment 1' an adapter according to the invention 2 this will be the first and third connection line 7 ' and 11 ' so crossed to each other that they are in the Cross-over area are oriented at an angle between 85 ° and 95 ° to each other or preferably orthogonal, ie at an angle of 90 °, are oriented to each other. In this way, an inductive over-coupling is largely avoided. For this purpose, the first and second connection line 7 ' and 11 ' in the region of the associated contact areas, ie in the area of the first contact area 6 ₁₁ and the first contact area 6 _{12 of} the first two pairs 5 ₁ and 5 ₂ of contact areas in the first connection area 3 and in the area of the first contact area 9 ₁₁ and the first contact area 9 _{12 of} the two second pairs 10 ₁ and 10 ₂ of contact areas in the second connection area 4 , guided parallel to each other over a longer distance.

A first variant for minimizing the capacitive overcoupling in the crossover region between the first and second connecting line, which are arranged crossed over one another, emerges from FIGS 3A . 3B and 3C out:
Like from the 3B and 3C is apparent, the representation is in 3A along the longitudinal axis 2 of the adapter by 90 ° compared to the illustration in the previous 1A and 2 turned.

It can be seen that the first and third connection line 7 '' and 11 '' , which are arranged crossed to each other, in the third embodiment 1'' of the adapter according to the invention are convexly curved towards one another and thus have an increased distance from one another in the region of the crossover. Due to the increased distance in the crossover area, the capacitive overcoupling between the first and third connection line 7 '' and 11 '' minimized.

The first connection line 7 '' closer to the peripheral surface of the substantially cylindrical adapter 1'' and thus closer to the in 3A is not shown, has, as shown 3A can be seen, a changed diameter, preferably a smaller diameter, than the third connecting line 11 '' on, farther away from the peripheral surface of the adapter 1'' and thus positioned by the ground shield. This preferably smaller diameter of the first connecting line 7 '' causes an optimum value for the capacitive component of the impedance between the first connection region 3 and second connection area 4 of the adapter 1'' ,

A second variant, with which the capacitive coupling in the crossing region between the first and second connecting line, which are arranged crossed to one another, can be minimized, is disclosed in US Pat 4A . 4B and 4C shown:
In the fourth embodiment 1''' the adapter according to the invention is an increased distance between the first and third connection line 7 ''' and 11 ''' , which are each arranged crossed to each other, realized in that they are each offset asymmetrically to a connecting line between the associated contact areas and offset by an angle of 180 ° to each other. The first connection line 7 ''' is thus in the range of the first contact area 6 _{11 of} a first pair 5 ₁ of contact areas in the first connection area 3 and in the area of the third contact area 9 _{11 of} a second pair 10 ₁ of contact areas in the second connection area 4 laid asymmetrically. The second connection line 11 ''' will be in the range of the second contact area 6 _{12 of} a first pair 5 ₂ of contact areas in the first connection area 3 and in the region of the second contact area 9 _{22 of} a second pair 10 ₂ of contact areas in the second connection area 4 laid asymmetrically.

The first connection line 7 ''' closer to the peripheral surface of the adapter 1''' and thus positioned closer to the ground shield, has a changed diameter, preferably a smaller diameter, than the third connection line 11 ''' on, farther away from the peripheral surface of the adapter 1''' and thus positioned further away from the ground shield. Thus, also in this case, the capacitive component of the impedance between the first terminal region 3 and second connection area 4 of the adapter 1''' reduced to the optimum value.

A third variant of the minimization of the capacitive overcoupling in the crossing region of the first and third connecting line, which are each arranged crossed over one another, is shown in FIGS 5A . 5B and 5C shown:
Here are the first and third connection line 7 '''' and 11 '''' the fifth embodiment 1''''' of the adapter according to the invention in each case in the crossover area a material removal 14 ₁ and 14 _3. In this way, the distance between the first and the third connection line 7 '''' and 11 '''' increases and the capacitive overcoupling between the first and the third connection line 7 '''' and 11 '''' reduced.

The closer to the peripheral surface of the adapter 1'''' and thus at the ground shield guided first connection line 7 '''' has a changed diameter, preferably a smaller diameter, than the farther from the peripheral surface of the adapter 1'''' guided third connection line 11 '''' on to the capacitive component of the impedance between the first terminal area 3 and the second connection area 4 of the adapter 1'''' to reduce to the optimum value.

Since the first and third connection lines, which are respectively arranged crossed over one another, have a greater length than the second and fourth connection lines, which are respectively arranged parallel to one another, there occurs between the signal components of the differential signal in the first and second connection line as well as between the two Signal components of the differential signal in the third and fourth connection line to a delay difference and thus to a phase shift. This phase shift between the signal components of the individual differential signals causes the signal components of the individual differential signals to no longer have the phase difference of 180 ° required for a differential signal after passing through the connecting lines.

To compensate for this phase shift, the propagation speed of the signal components of the differential RF signal in the respectively crossing connecting lines is increased relative to the propagation speed of the signal components of the differential RF signals in the respectively parallel connecting lines.

For this purpose, the connecting lines, which cross each other, surrounded by a material having a lower permittivity than the connecting lines, each extending in parallel. In this case, on the one hand, the sheathing of the electrical conductor of the connecting line or the material surrounding the sheathing of the electrical conductor of the connecting line can already be selected with regard to suitable permittivity.

In 6 is a cable according to the invention 13 represented, at the end of an adapter 1 is attached. The cable 13 includes two parallel, shielded pairs of inner conductors. These two pairs of inner conductors are connected to the first two pairs 5 ₁ and 5 ₂ of contact areas in the first connection area 3 brought to the adapter, which are each realized as holes or recesses, and passed through these holes or recesses.

Equivalent to the first, second, third and fourth connection line 7 . 8th . 11 and 12 in the first embodiment of the adapter according to the invention 1 according to the 1A . 1B and 1C become the inner conductors 8th ^v and 12 ^{v of} the two pairs of inner conductors of the individual second contact regions of the first connection region 3 to the directly opposite second contact region of the second connection region 4 guided while the inner conductor 7 ^v and 11 ^{v of} the two pairs of inner conductors of the individual first contact areas of the first connection area 3 to the on the longitudinal axis 2 mirrored first contact areas of the second connection area 4 be guided.

The in the 2 . 3A . 4A and 5A respectively illustrated second, third, fourth and fifth embodiment of the adapter according to the invention can be equivalent in the at the end of the cable according to the invention 13 be realized attached adapter.

The invention is not limited to the disclosed embodiments and variants of the adapter according to the invention and the cable according to the invention with integrated adapter.

Of the invention, in particular all combinations of the claims claimed in the individual claims, the characteristics respectively disclosed in the description and the features respectively shown in the figures of the drawing are covered, as far as they are technically feasible.

Claims (20)

Adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) for inner conductors in an RF connector with a first connection region ( 3 ) with two first pairs ( 5 ₁ , 5 ₂ ) of contact areas each having a first and a second contact area ( 6 ₁₁ , 6 ₁₂ , 6 ₂₁ , 6 ₂₂ ) and a second connection area ( 4 ) with two second pairs ( 10 ₁ , 10 ₂ ) of contact areas, each having a third and fourth contact area ( 9 ₁₁ , 9 ₁₂ , 9 ₂₁ , 9 ₂₂ ), the first two pairs ( 5 ₁ , 5 ₂ ) of contact areas are arranged parallel to each other, wherein the two second pairs ( 10 ₁ , 10 ₂ ) are arranged crossed by contact areas to each other, wherein the first contact area ( 6 ₁₁ ) of the first pair ( 5 ₁ ) of contact areas via a first connecting line ( 7 ; 7 '; 7 ''; 7 ''' . 7 '''' ) with the third contact area ( 9 ₁₁ ) of the one second pair ( 10 ₁ ) of contact areas, the second contact area ( 6 ₂₁ ) of the first pair ( 5 ₁ ) of contact areas via a second connecting line ( 8th ; 8th'; 8th''; 8th''' . 8th'''' ) with the fourth contact area ( 9 ₂₁ ) of the one second pair ( 10 ₁ ) of contact areas, the first contact area ( 6 ₁₂ ) of the other first pair ( 5 ₂ ) of contact areas via a third connecting line ( 11 ; 11 '; 11 ''; 11 ''' . 11 '''' ) with the third contact area ( 9 ₁₂ ) of the other second pair ( 10 ₂ ) of contact areas and the second contact area ( 6 ₂₂ ) of the other first pair ( 5 ₂ ) of contact areas via a fourth connecting line ( 11 ; 11 '; 12 ''; 12 ''' . 12 '''' ) with the fourth contact area ( 9 ₂₂ ) of the other second pair ( 10 ₂ ) are electrically connected by contact areas, characterized in that two Connecting lines of the first, second, third and fourth connecting line ( 7 . 8th . 11 . 12 ; 7 ' . 8th' . 11 ' . 12 '; 7 '' . 8th'' . 11 '' . 12 ''; 7 ''' . 8th''' . 11 ''' . 12 '''; 7 '''' . 8th'''' . 11 '''' . 12 '''' ) are each arranged parallel to each other. Adapter according to claim 1, characterized in that only two connecting lines of the first, second, third and fourth connecting line ( 7 . 8th . 11 . 12 ; 7 ' . 8th' . 11 ' . 12 '; 7 '' . 8th'' . 11 '' . 12 ''; 7 ''' . 8th''' . 11 ''' . 12 '''; 7 '''' . 8th'''' . 11 '''' . 12 '''' ) are each crossed over to each other. Adapter according to claim 1 or 2, characterized in that in the second pairs ( 10 ₁ , 10 ₂ ) of contact areas two pairs of signal lines leading in each case to a differential signal can be connected in a star-quad array. Adapter according to one of the claims 1 to 3, characterized in that in the first pairs ( 5 ₁ , 5 ₂ ) of contact areas in each case a pair of a differential signal leading inner conductors of a cable can be connected. Adapter according to one of claims 1 to 4, characterized in that the crossed to each other arranged first and third connecting lines ( 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ) are surrounded by a material having a lower permittivity than the two second and fourth connecting lines ( 8th . 12 ; 8th' . 12 '; 8th'' . 12 ''; 8th''' . 12 '''; 8th'''' . 12 '''' ), which are arranged parallel to each other. Adapter according to one of the claims 1 to 5, characterized in that the first and third connecting lines (FIG. 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ) are oriented in the crossing region at an angle between 85 ° and 95 ° to each other. Adapter according to one of the claims 1 to 6, characterized in that the distance between the first and third connecting lines (FIG. 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ) by removal of material ( 14 ₁ , 14 ₃ ) of the first and third connecting lines ( 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ) is increased in the region of the crossover. Adapter according to one of the claims 1 to 7, characterized in that the first and third connecting lines ( 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ) are guided to each other convexly curved. Adapter according to one of claims 1 to 8, characterized in that the crossed to each other arranged first and third connecting lines ( 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ) each asymmetrically offset to a connecting line between the associated contact areas ( 6 ₁₁ , 6 ₁₂ , 9 ₁₁ , 9 ₁₂ ) of the first and second connection areas ( 3 . 4 ) are guided. Adapter according to claim 8 or 9, characterized in that the connecting line ( 7 ; 7 '; 7 ''; 7 '''; 7 '''' ) of the two crossed first and third connecting lines ( 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ), which are closer to the peripheral surface of the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ), a modified diameter, preferably a smaller diameter, than that connecting line ( 11 ; 11 '; 11 ''; 11 ''' . 11 '''' ) of the two crossed first and third connecting lines ( 7 . 11 ; 7 ' . 11 '; 7 '' . 11 ''; 7 ''' . 11 '''; 7 '''' . 11 '''' ) further from the peripheral surface of the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) is positioned remotely. Electric wire ( 13 ) with two shielded and one differential signal leading pairs of inner conductors ( 7 ^v , 8th ^v , 11 ^v , 12 ^v ), at the end of which an adapter ( 1 ; 1'; 1''; 1''' . 1'''' ), the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) a first connection area ( 3 ) with two first pairs ( 5 ₁ , 5 ₂ ) of contact areas each having a first and a second contact area ( 6 ₁₁ , 6 ₁₂ , 6 ₂₁ , 6 ₂₂ ) and a second connection area ( 4 ) with two second pairs of contact areas ( 10 ₁ , 10 ₂ ) each having a third and fourth contact region ( 9 ₁₁ , 9 ₁₂ 9 ₂₁ , 9 ₂₂ ), wherein the two first pairs ( 5 ₁ , 5 ₂ ) of contact areas are arranged parallel to one another, wherein the two second pairs ( 10 ₁ , 10 ₂ ) are arranged crossed by contact areas to each other, wherein the first and second contact areas ( 6 ₁₁ , 6 ₂₁ ) of the first pair ( 5 ₁ ) of contact areas via a respective different inner conductor of the one pair ( 7 ^v , 8th ^v ) of inner conductors of the cable ( 13 ) with the third and fourth contact area ( 9 ₁₁ , 9 ₂₁ ) of the one second pair ( 10 ₁ ) of contact areas and the first and second contact area ( 6 ₁₂ 6 ₂₂ ) of the other first pair ( 52 ) of contact areas via a respective different inner conductor of the other pair ( 11 ^v , 12 ^v ) of inner conductors with the third or fourth contact region ( 9 ₁₂ , 9 ₂₂ ) of the other second pair ( 10 ₂ ) are electrically connected by contact areas, characterized in that two inner conductors ( 8th ^v , 12 ^v ) within the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) are each arranged parallel to each other. Electric wire ( 13 ) according to claim 11, characterized in that only two inner conductors ( 7 ^v , 11 ^v ) within the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) are each crossed over to each other. Electric wire ( 13 ) according to claim 11 or 12, characterized in that in the second pairs ( 10 ₁ , 10 ₂ ) of contact areas, the inner conductors ( 7 ^v , 8th ^v , 11 ^v , 12 ^v ) are arranged in a star-quad arrangement. Electric wire ( 13 ) according to one of the claims 11 to 13, characterized in that in the first pairs ( 5 ₁ , 5 ₂ ) of contact areas in parallel to each other the pairs of inner conductors ( 7 ^v , 8th ^v , 11 ^v , 12 ^v ) of the cable ( 13 ) are performed. Electric wire ( 13 ) according to one of the claims 11 to 14, characterized in that inside the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) the intersecting arranged inner conductor ( 7 ^v , 11 ^v ) are surrounded by a material having a lower permittivity than the two inner conductors ( 8th ^v , 12 ^v ), which are arranged parallel to each other. Electric wire ( 13 ) according to one of the claims 11 to 15, characterized in that inside the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) the intersecting arranged inner conductor ( 7 ^v , 11 ^v ) are oriented in the crossing region at an angle between 85 ° and 95 ° to each other. Electric wire ( 13 ) according to one of the claims 11 to 16, characterized in that inside the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) the distance of the inner conductors crossed over one another (FIG. 7 ^v , 11 ^v ) by material removal ( 14 ₁ , 14 ₃ ) the inner conductor ( 7 ^v , 11 ^v ) is increased in the region of the crossover. Electric wire ( 13 ) according to one of the claims 11 to 17, characterized in that inside the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) the intersecting arranged inner conductor ( 7 ^v , 11 ^v ) are guided to each other convexly curved. Electric wire ( 13 ) according to one of the claims 11 to 18, characterized in that inside the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) the intersecting arranged inner conductor ( 7 ^v , 11 ^v ) each asymmetrically offset to a connecting line between the associated contact areas ( 6 ₁₁ , 6 ₁₂ , 9 ₁₁ , 9 ₁₂ ) of the first and second connection areas ( 3 . 4 ) are guided. Electric wire ( 13 ) according to claim 18 or 19, characterized in that inside the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) that inner conductor ( 7 ^v ) of the two crossed inner conductors ( 7 ^v , 11 ^v ) closer to the peripheral surface of the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ), a modified diameter, preferably a smaller diameter, than the inner conductor ( 11 ^v ) of the two crossed inner conductors ( 7 ^v , 11 ^v ) further from the peripheral surface of the adapter ( 1 ; 1'; 1''; 1''' . 1'''' ) is positioned remotely.

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