FR3058838A1 - RADIANT CABLE - Google Patents

Abstract

The invention relates to a radiating cable coaxially comprising, from inside the cable towards the outside of the cable (1), a central conductor (2), an electrically insulating casing (3) intermediate, and an outer conductor (4). ) having at least one opening (5), characterized in that each opening (5) is delimited by two non-parallel edges (41, 42) of the outer conductor (4), each edge (41, 42) forming a sinusoid along cable (1).

Description

(54) RADIANT CABLE.

©) The invention relates to a radiating cable comprising coaxially, from the inside of the cable to the outside of the cable (1), a central conductor (2), an electrically insulating envelope (3) intermediate, and an external conductor (4) comprising at least one opening (5), characterized in that each opening (5) is delimited by two edges (41,42) which are not parallel to the external conductor (4), each edge (41, 42) forming a sinusoid along the cable (1).

RADIANT CABLE

The present invention relates to a so-called radiating cable comprising an external conductor provided with openings.

Radiant cables are intended to be used as elements for the transmission of signals between a transmitter and a receiver under conditions where these signals transmitted from a point source are rapidly attenuated, in particular in radiocommunication systems comprising mobiles, in underground, buildings or tunnels.

Radiant cables transmit electromagnetic waves in the form of homogeneous transverse electromagnetic waves, distributed over their entire length.

The radiating cables provide a dual function of transmitting and receiving said electromagnetic waves and, for example, make the interior of a tunnel or of a building transparent to the outside.

A radiating cable is typically a coaxial cable as described for example in the document FR. 2,685,549.

Figure 1 shows an exploded perspective view of such a radiating cable.

The radiating cable 1 comprises, arranged coaxially from the inside to the outside:

- a central conductor 2 made of copper or aluminum,

an insulating envelope 3 made of a dielectric material, such as for example polyethylene or expanded polyethylene,

an external conductor 4, of copper or aluminum, having openings or slots 5, arranged in patterns repeated periodically along the cable 1, and

- a protective sheath 6 made of an insulating material.

There are two modes of electromagnetic waves. The first mode is the guided mode, in which the electromagnetic wave propagates along the cable.

Thanks to the slots 5, part of the power transmitted in the cable is coupled to the outside and constitutes the second mode, which is the radiated mode. Cable 1 then functions as a long antenna.

The distribution of the slots is an essential element in the radiating cables. It generally consists of the repetition of the patterns of slits. The cut-off frequency υ ₀ is defined by the relation:

in which c denotes the speed of light, d denotes the distance between two consecutive slot patterns, and s _r denotes the relative permittivity of the dielectric material of the insulating envelope.

Above the cutoff frequency, constructive interference leads to the appearance of radiated modes up to a second cutoff frequency defined by _ c ^f

From frequencies of the order of twice the cut-off frequency υ ₀ appear radiated modes of higher order. The interference of these higher modes disrupts the coupling of the radiating cable to an outdoor antenna, which limits the bandwidth of the transmission system.

To avoid this problem, the use of the cable is usually restricted to frequencies between υ ₀ and 2υ ₀ . To increase the width of this interval of frequencies, it is necessary to find a solution to suppress the higher radiated modes and to preserve only the fundamental mode.

A known solution, as described in document EP 0 375 840, consists in selectively eliminating some of the upper radiated modes by increasing the number of slots. However, this solution has the disadvantage that the increase in the number of slots leads to a partial superposition of slots, which can be difficult to manage. In addition, the discretization of the slots creates additional disturbances and does not lead to a complete extinction of the higher radiated modes.

The invention aims to remedy these drawbacks.

The invention thus relates to a radiating cable comprising coaxially, from the inside of the cable to the outside of the cable, a central conductor, an electrically insulating intermediate casing, and an external conductor comprising at least one opening.

In the cable according to the invention, each opening is delimited by two non-parallel edges of the outer conductor, each edge forming a sinusoid along the cable. Thus, the specific shape of the openings makes it possible to eliminate the higher radiated modes and to keep only the fundamental mode.

The sinusoids of the two borders can be of the same period.

The sinusoids of the two borders can also be of different period. The difference in period of the two borders makes it possible to extend the bandwidth of the cable.

The sinusoids may be in phase opposition, the lower vertices of one border facing longitudinally to the upper vertices of the other border.

The lower vertices of one border and the upper vertices of the other border can touch each other periodically, thus defining a plurality of openings.

The sinusoids of the two borders can be of the same amplitude.

The sinusoids of the two borders can also be of different amplitude.

The sinusoids of the two borders can be of the same period and of the same amplitude, and the ratio of the period to the amplitude is typically between 20 and 2000. The choice of the value of the period makes it possible to control the desired cutoff frequency. The choice of the amplitude value makes it possible to influence the radiated power. The amplitude also has an impact on the power transmitted by the guided mode. The greater the amplitude, the higher the transmission attenuation. A compromise must therefore be found between the radiated power and the transmitted power in order to find an optimal ratio of the period to the amplitude and thus to optimize the coupling to the antenna and the operating distance of the cable. It should be noted that the ratio of the period to the amplitude has a frequency dependence, i.e., a mode of higher frequency radiates more and has an attenuation of the guided mode higher than a mode of lower frequency which radiates less.

The outer conductor may further include slots arranged perpendicular to the axis of the cable and in patterns repeated periodically along the cable.

The cable may further comprise an outer protective sheath made of an electrically insulating material.

Other objects, characteristics and advantages of the invention will appear on reading the following description, given solely by way of nonlimiting example, and made with reference to the appended drawings, in which:

FIG. 1, already described, illustrates a radiating cable of the state of the art,

FIG. 2a illustrates an external conductor of a cable according to the invention, in accordance with a first embodiment, before its application to an insulating jacket made of dielectric material of the cable,

FIG. 2b is a top view of the external conductor, in accordance with the first embodiment,

FIG. 2c is a side view of the external conductor, according to the first embodiment,

FIG. 3 is a diagram showing the attenuation of the linear transmission along a cable according to an embodiment as a function of the frequency of the transmitted wave,

FIG. 4 illustrates external cable conductors according to the invention, in accordance with a second embodiment, and

- Figure 5 is a diagram showing the attenuation of the linear transmission along two cables, according to the second embodiment, as a function of the frequency of the transmitted wave.

As illustrated in Figure 2a, the outer conductor 4 of the radiating cable according to the invention comprises two edges 41, 42 which have a sinusoidal profile along the cable. A sinusoid is a periodic wavy curve representative of the trigonometric function called a sine.

In a first embodiment, illustrated in FIGS. 2a to 2c, the sinusoids of the two borders 41, 42 are identical, that is to say that the sinusoids of the two borders are of the same period (ie not the same) and of same amplitude. In addition, the sinusoids are in phase opposition, that is to say that the lower vertices A of a border 41 face longitudinally, along the axis X, to the upper vertices B of the other border 42 (ie the lower vertices A have the same abscissa as the upper vertices B on the longitudinal axis of the cable). Similarly, the upper vertices A 'of the border 41 face longitudinally, along the axis X, to the lower vertices B' of the other border 42 (ie the upper vertices A 'have the same abscissa as the lower vertices B 'on the longitudinal axis of the cable). The lower vertices A 'can coincide with the upper vertices B, thus defining a plurality of openings 5, or be at a distance therefrom, which defines a single opening.

FIG. 3 is a diagram illustrating the attenuation of the linear transmission along the cable as a function of the frequency of the transmitted wave, for a diameter of the cable (without the external conductor) of 23.5 mm, corresponding to 7 / 8, a period of the sinusoid of 2.20 m and an amplitude of the sinusoid (distance between a lower vertex A and an upper vertex A ') of 20 mm. Figure 3 shows that only the fundamental cut-off frequency υ ₀ is retained, there are no longer multiples of the frequency at which the fundamental mode is located. The bandwidth for the cable according to the first embodiment is therefore not limited to the high frequencies.

Other embodiments are possible. The two edges of the outer conductor 4 may in particular have sinusoids having different periods and / or amplitudes.

An outer conductor 40b of a cable according to a second embodiment of the invention is illustrated in FIG. 4B. Figure 4A shows an outer conductor 40a of a cable according to the prior art. The comparison between these two cables makes it possible to appreciate the effect of the external conductor according to the present invention. The external conductor 40a of the cable according to the prior art (FIG. 4A) comprises slots 50a or openings arranged in patterns repeated periodically all along the cable, the slots 50a being oriented perpendicular to the axis of the cable. The outer conductor 40b of the cable 40b according to the second embodiment (FIG. 4B) comprises two edges 41, 42 which have a sinusoidal profile along the cable as well as slots 50b or openings, arranged in patterns repeated periodically along the cable , the slots 50a being oriented perpendicular to the axis of the cable. Other arrangements of the sinusoidal edges 41, 42 and the slots 50b as well as different numbers of slots 50b than those shown in FIG. 4B are possible.

Figures 5 and 6 show measurement results for a cable according to the second embodiment, combining edges 41, 42 sinusoidal and slots 50b on its outer conductor 40b, and for a cable according to the prior art whose outer conductor 40a does not shows only slots 50a, examples of which are shown in Figures 4B and 4A, respectively. For these measurements, the sinusoids of the two edges 41, 42 are identical, that is to say that the sinusoids of the two edges 41, 42 are of the same period and of the same amplitude. In addition, the sinusoids are in phase opposition. The period is 2192 mm and the amplitude 5 mm. The groups 51a, 51b of slots 50a, 50b are spaced 130 mm (distance between the slots of the same order for a group) for the two cables. Each group 51a, 51b includes eight slots, the slots 50a, 50b being spaced from each other by 15 mm and having dimensions of 3 mm x 15 mm.

FIG. 5 illustrates, in comparison, the attenuation of the coupling as a function of the frequency of the transmitted wave, for the cable 40b according to the second embodiment and for the cable 40a according to the prior art 4B and 4A, respectively. The two cables each have a diameter of 25.4 mm, corresponding to 7/8. Curves 60 and 61 correspond to cable 40a having an outer conductor having only slots 50a, for the median attenuation (curve 60) and the attenuation below which 95% of the measured values are found (curve 61). Curves 62 and 63 correspond to cable 40b having an outer conductor having sinusoidal edges 41, 42 and slots 50b at the same time, for a value of the median attenuation (curve 62) and a value of the attenuation below which are 95% of the measured values (curve 63). FIG. 5 shows that the coupling attenuation for the cable 40b according to the invention is less; for example, the median attenuation at 900 MHz, is -64 dB for the cable 40b according to the invention (curve 62) and -73 for the cable 40a with the slots only (curve 60).

FIG. 6 is a diagram illustrating the attenuation of the linear transmission along the cable as a function of the frequency of the transmitted wave, for the cable 40b according to the second embodiment and for the cable 40a according to the prior art. The curve 70 corresponds to the cable according to the prior art having only slots, the curve 71 corresponds to the cable according to the invention having sinusoidal edges and slots. Figure 6 shows that the linear attenuation is only slightly impacted by the presence of the sinusoidal border.

It follows from the results shown in FIGS. 5 and 6 that on the one hand, the coupling of the radiation towards the outside is much improved thanks to the presence of the sinusoidal edges in the outside conductor of the cable according to the invention. On the other hand, the attenuation of the transmission of the guided mode is practically not altered by the presence of these sinusoidal borders. In addition, the combination of slots and sinusoidal edges according to the second embodiment of the invention makes it possible to widen the bandwidth of the cable because the different sizes of the openings in the external conductor, created by the slots and the sinusoidal edges, promote the coupling of radiation at different frequencies.

Claims (10)

1. Radiant cable coaxially comprising, from inside the cable towards the outside of the cable, a central conductor (2), an electrically insulating envelope (3) intermediate, and an external conductor (4) comprising at least one opening (5 ), characterized in that each opening (5) is delimited by two non-parallel edges (41, 42) of the external conductor (4), each edge (41, 42) forming a sinusoid along the cable (1). 2. Radiant cable according to claim 1, characterized in that the outer conductor (4, 40a, 40b) further comprises slots (50b) arranged perpendicular to the axis of the cable and in patterns repeated periodically along the cable. 3. Radiant cable according to claim 1 or 2, characterized in that the sinusoids of the two edges (41,42) are of the same period. 4. Radiant cable according to claim 1 or 2, characterized in that the sinusoids of the two edges (41,42) are of different period. 5. Radiant cable according to claim 3, characterized in that the sinusoids are in phase opposition, the lower vertices (A) of a border (41) facing longitudinally to the upper vertices (B) of the other border (42 ). 6. Radiant cable according to claim 3 or 5, characterized in that the lower vertices (A) of one edge (41) and the upper vertices (B) of the other border (42) touch periodically, thus defining a plurality of openings (5). 7. Radiant cable according to one of claims 1 to 5, characterized in that the sinusoids of the two edges (41, 42) are of the same amplitude. 8. Radiating cable according to one of claims 1 to 5, characterized in that the sinusoids of the two edges (41, 42) are of different amplitude. 9. Radiant cable according to claim 7, characterized in that the 5 sinusoids of the two borders (41, 42) are of the same period and of the same amplitude, and in that the ratio of the period to the amplitude is between 20 and 2000. 10. Radiant cable according to one of claims 1 to 9, characterized in that it further comprises an outer sheath (6) of protection in one 10 electrically insulating material. 1/3