EP0848390A2 - Contact-pairs assembly of double lines and of multi-conductor cable-lines for cross-talk reduction - Google Patents

Abstract

The invention relates to an arrangement of contact pairs of double lines (1,2; 3,4; 5,6; 7,8) and of lines of a multi-core cable to reduce crosstalk, in which the contact pairs of the double line (1,2; 3, 4; 5.6; 7.8) or the line pairs parallel to one another and not overlapping surfaces F _{1, 2} ; F _{3, 4} ; F _{5, 6} ; Open F _{7, 8} and the double lines (1,2; 3,4; 5,6; 7,8) or pairs of lines on electrical equipotential lines of their neighboring double lines (1,2; 3,4; 5,6; 7,8 ) are arranged.

Description

The invention relates to an arrangement of contact pairs of double lines and lines of a multi-core cable to reduce crosstalk.

Due to a magnetic and electrical coupling between two neighboring ones Contact pairs induce a contact pair in neighboring contact pairs a current or influences electrical charges so that it becomes a Crosstalk is coming.

In principle, there are several possible solutions for reducing crosstalk conceivable. For example, the individual contact pairs are shielded against each other will. The disadvantage of this solution is the increased manufacturing effort and the associated costs. Another possibility is the Arrange contact pairs at a large distance from each other and at the same time the To choose distances between the contacts of a couple very small, because the Amounts of field strengths decrease with increasing distance. Disadvantageous about such arrangements is that they are very voluminous and demands run counter to a compact design. It is also known that to compensate for existing crosstalk, which is very technical is complex and comes up against physical limits.

Another possibility is the arrangement of the contact pairs in such a way that crosstalk is reduced in the field conditions. It was proposed to arrange the contact pairs of double lines to each other, that the spanned by the contact pairs of a respective double line Areas are perpendicular to each other. There are certain symmetry conditions Considered by the field distribution, a pair of contacts on the electrical equipotential surfaces of its neighboring contact pair be arranged so that the contact pairs are electrically and magnetically decoupled are. The contact pairs can be arranged so that cut the surfaces spanned by the contact pairs. This leads to, that the lines are nested in the connection area to the transmissions are what causes additional crosstalk. Therefore Arrangements are preferred in which the spanned surfaces of the contact pairs do not cut. A disadvantage of the known arrangements not intersecting areas is the large space requirement and the changing Connection levels. In principle, similar problems occur through crosstalk even with multi-core cables.

The invention is therefore based on the problem of an arrangement of contact pairs of double lines and lines of a multi-core cable create that compact and easily accessible with minimal crosstalk are arranged.

The solution to the problem results from the features of the claims 1 and 4. By the arrangement of the contact pairs such that the spanned by them Surfaces are parallel and the contact pairs on electrical equipotential lines of their adjacent contact pairs is a compact, easily accessible arrangement of the contact pairs to each other possible, at which the neighboring contact pairs are electrically and magnetically decoupled, so that crosstalk is avoided. The same applies to the multi-core Cable in which the adjacent pairs of lines on an electrical Equipotential surface of a pair of lines are arranged. More beneficial Embodiments of the invention result from the subclaims.

By forming the contact pairs with the same distance a is one Simplified mechanical connection of the double lines to subsequent ones Cable possible. In a further preferred embodiment, all back and forth all return conductors arranged on one level.

Fig. 1

ein Feldbild einer Doppelleitung,

Fig. 2

eine Kontaktanordnung einer zweiten parallelen Doppelleitung im Feldbild der ersten Doppelleitung,

Fig. 3

eine Kontaktanordnung eines 4 x 2-Steckers und

Fig. 4

eine schematische Darstellung zur Berechnung des optimalen Winkels.

The invention is explained in more detail below with the aid of a preferred exemplary embodiment. The figures show:

Fig. 1

a field picture of a double line,

Fig. 2

a contact arrangement of a second parallel double line in the field pattern of the first double line,

Fig. 3

a contact arrangement of a 4 x 2 connector and

Fig. 4

a schematic representation for calculating the optimal angle.

1 shows the field image of a double line 1, 2 with the magnetic field lines H and the electrical field lines E. The magnetic crosstalk from the first double line 1, 2 to a second double line 3, 4 is directly proportional to the mutual inductance M of this arrangement. The mutual inductance results from the integration of the magnetic field strength H of the double line 1, 2 over the area F _{3, 4} , which is spanned by the line conductors of the double line 3, 4 M = µ O F 3.4 H 12th (x, y, z) dF , in this scalar vector product of the magnetic field strength H only the component perpendicular to the surface F _{3, 4} makes a contribution. The surface integral represents the magnetic flux that passes between the two conductors 3, 4. This is equal to zero if the two conductors 3, 4 lie on a common magnetic field line H. Due to the electric field E of the double line 1, 2, influence charges are generated on the conductors 3, 4, which can flow away via the load resistor and thus generate crosstalk. The electric field E of the double line 1, 2 generates a potential difference of between the two conductors 3, 4 V 4th - V 3rd = ladder 3rd ladder 4th E dr .

This is a line integral on an electrical field line E from conductor 3 to conductor 4, the potential difference being zero when the electrical field strength E strikes the surface F _{3, 4} spanned by the conductors 3, 4. The vectorial electric field E can also be described by the scalar potential, the potential lines being perpendicular to the electric field lines E. In the case of electrical decoupling, the two conductors 3, 4 must then be arranged on an equipotential surface of the electrical potential. Since the electrical and magnetic field lines E and H are perpendicular to one another, the course of the potential lines is identical to the course of the magnetic field lines H. This in turn means that with line conductors, an arrangement with magnetic decoupling also has electrical decoupling. Due to the finite extension of the lines, the electric field E is distorted near the line, since the surface represents an equipotential surface. However, these deviations are negligible for larger distances.

2, the magnetic field H of the double line 1, 2 is shown, the contact distance of the lines 1, 2 a. 2 shows possible arrangements of the second double line 3, 4, in which the contact distance is also a. There are therefore an infinite number of possible arrangements of the double lines 3, 4, in which the area F _{3, 4} spanned by the lines _{3, 4 is} parallel to the area F _{1, 2} and the distance between the contact pairs 1, 2 and 3, 4 is the same size in each case, since the double line 3, 4 is located on a magnetic field line H, the two double lines 1, 2 and 3, 4 are both electrically and magnetically decoupled.

3 shows a contact arrangement for a 4 x 2 connector. Of the Distance of the lines of each double line 1, 2 or 3, 4 or 5, 6 or 7, 8 is a. In addition, the outgoing conductors 1, 3, 5, 7 and the return conductors 2, 4, 6, 8 each in one plane, the distance between a return conductor 2, 4, 6 to the neighboring outgoing conductor 3, 5, 7 is also a. The resulting one Angle α can be calculated using a calculation with the aid of FIG. 4 calculate as follows:

The outgoing conductor 3 describes depending on the angle α = 90 ° + β a circle around the return conductor 2 with the radius 2 A = a and the center shift A. The circle equation for this circle K 1 is: (X - A) 2nd + Y 2nd = (2 A) 2nd .

For complete decoupling, the conductors 3, 4 must lie on a magnetic field line which is defined by a circle K 2 with the radius R 2nd = M 2nd - A 2nd and the center M is described: (X - M) 2nd + Y 2nd = M 2nd - A 2nd

The intersection of the two circles K 1, K 2 is obtained by solving the system of equations ( XA ) 2nd - ( XM ) 2nd = (2nd A ) 2nd - M 2nd + A 2nd ⇒ X = 2 A 2nd M - A

4 for the center point M = X + A , so that the following relationship results for the X coordinate of the conductor 3: x = √2 * A .

The angle β can be calculated from the X coordinate of the conductor 3:

This gives the angle you are looking for α = β + 90 ° to 101.95 ° . sinβ = X - A 2 A = √2-1 2nd ⇒β = 11.95 °

3, the double lines 5, 6 and 7, 8 are no longer exactly on a magnetic field line of the double line 1, 2, so that crosstalk is induced. This crosstalk is very small due to the large distance. 3, a multi-core cable can be constructed, for example, as a ribbon cable. in which the adjacent line pairs are arranged on an electrical equipotential line of a line pair.

Claims (4)

Arrangement of contact pairs of double lines to reduce crosstalk,
characterized in that
clamp the contact pairs of the double line (1,2; 3,4; 5,6; 7,8) parallel, non-overlapping surfaces (F _{1, 2} ; F _{3, 4} ; F _{5, 6} ; F _{7, 8} ) and the double lines (1,2; 3,4; 5,6; 7,8) are arranged on electrical equipotential lines of their adjacent double lines (1,2; 3,4; 5,6; 7,8). Arrangement according to claim 1, characterized in that the contact pairs the double lines (1,2; 3,4; 5,6; 7,8) each have the same distance a have. Arrangement according to claim 2, characterized in that all Outgoing conductors (1, 3, 5, 7) and all return conductors (2, 4, 6, 8) of the arrangement in each case are arranged in one plane. Multi-core cable with a multitude of lines,
characterized in that
the wire pairs span mutually parallel, non-overlapping surfaces and the wire pairs are arranged on electrical equipotential surfaces of their adjacent wire pairs.

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