EP0897201A1 - Cylindrical reflector with sliding radiating elements - Google Patents

Abstract

The aerial elements may be moved along major axis of support parallel to reflector axis in order to accommodate different angles of incidence. The aerial comprises a cylindrical reflector (2) and a bar of radiating elements (S1 - SN) positioned parallel to the generatrix of the cylinder. These elements each include a dephaser/delay (O1 - ON), and the aerial includes an electronic scanning control (3) to act on the dephasers in order to obtain a deviation (θ ) of the aerial beam between two limits of alignment (θ M, θ -M). The aerial also includes provision to shift the position of the radiating elements along the major axis of the bar, when the deflection exceeds a given threshold.

Description

The invention relates to antennas in which a reflector cylindrical interacts with a line of radiating elements.

Such an antenna is usually used for transmission and / or reception of electromagnetic signals, such as in telecommunication systems with a satellite artificial. It also applies to speed cameras.

• des antennes constituées d'un élément rayonnant unitaire (ou source) interagissant avec un réflecteur, souvent parabolique.
• des antennes comportant des éléments rayonnants unitaires agencés suivant un réseau plan. Pour orienter (ou "dépointer") le faisceau d'antenne vers une direction donnée, chaque élément rayonnant peut être équipé d'un organe déphaseur/retardateur. Habituellement, une commande de balayage électronique agit sur ces organes en fonction du dépointage souhaité. Tout en conservant des caractéristiques de rayonnement équivalentes à une antenne selon le principe précédent, ce procédé nécessite un plus grand nombre d'éléments rayonnants.
• des antennes combinant les deux techniques précédentes, et comportant des éléments rayonnants agencés suivant un réseau linéaire. Ces éléments sont destinés à interagir en principe avec un réflecteur cylindrique, et une commande de balayage électronique permet généralement de pointer le faisceau vers une direction prédéterminée.

The antenna gain is a major parameter for such applications. Different methods make it possible to obtain an antenna having a narrow beam, and consequently a high gain. There are for example:

• antennas made up of a unitary radiating element (or source) interacting with a reflector, often parabolic.
• antennas comprising unitary radiating elements arranged in a plane array. To direct (or "point") the antenna beam towards a given direction, each radiating element can be equipped with a phase-shifting / retarding member. Usually, an electronic scanning command acts on these organs according to the desired depointing. While retaining radiation characteristics equivalent to an antenna according to the preceding principle, this method requires a greater number of radiating elements.
• antennas combining the two previous techniques, and comprising radiating elements arranged in a linear array. These elements are intended to interact in principle with a cylindrical reflector, and an electronic scanning control generally makes it possible to point the beam towards a predetermined direction.

The invention applies in particular to an antenna of this last type.

It then comprises a reflector of general shape substantially cylindrical, cooperating with a source formed of elements radiant arranged substantially in line. Each element radiating is associated with a delay organ, as well as with a respective excitation path comprising both a bond electromagnetic and a delay control input. The delays thus applied to excited radiating elements can then be chosen to obtain an antenna beam susceptible, by electronic scanning, to be diverted between two deflection limits.

The part of the reflector which, from a deflection limit to the other, is in interaction with the radiating elements, is generally much longer than the line itself. A antenna of this type therefore requires a cylindrical reflector of sufficient length to cooperate with the radiating elements of the network. Indeed, the length of the reflector must, in principle, be greater than the defined beam width by the distance between the two radiating elements occupying extreme positions of the line, at which add a length, seen on the reflector, corresponding to the total amplitude of depointing between the two limits.

However, such a reflector has an often incompatible volume with the desired arrangement for certain antennas. In in particular, a reduction in the size of the antennas on board civil or military aircraft or ships, is generally desired.

The object of the invention is in particular to overcome the drawback aforementioned by reducing the size of the reflectors of the technique anterior while obtaining characteristics similar radiant.

To this end, it offers an electromagnetic antenna of the type described above, but the source of which contains means for sliding the position of the radiating elements excited along said line, depending on the deviation defined by the electronic scan control.

According to the invention, these means cause the position of the radiant elements excited along the line and on the side opposite to the deflection of the beam seen on the reflector, this which reduces the size of the characteristic reflector radiantly constant.

Preferably, the source also includes an input for the electronic scanning control so as to control the deflection of the antenna beam.

Advantageously, said means and the scanning control electronics can then cooperate together to establish a correspondence between the position of the radiating elements excited and the beam deflection.

In principle, these means are capable of sliding the position of the radiating elements excited at least from a deviation threshold.

In practice, they drag the position of the elements radiant excited over a distance from the line substantially proportional to the tangent of the deviation.

According to a characteristic of the invention, the position of the excited radiant elements can slide on a beach excursion substantially equivalent to half the amplitude of depointing between the two limits.

The reflector is then of substantially chosen length equivalent to the width of the antenna beam increased by said excursion beach. Thus, the overall size of the antenna generally defined by the length of the reflector is, according to the invention, substantially equivalent to this length.

According to one aspect of the invention, the source comprises radiant elements movable in translation along the line, with their associated excitation path. She understands also mechanical means for controlling the translation of these radiant elements.

According to another aspect of the invention, the source comprises switching means for defining a sliding subset of active radiating elements, among all the elements radiant, while the correspondence between the tracks excitation and the radiant elements is changeable for accompany said sliding subset of radiating elements assets.

• les figures 1a et 1b, respectivement, représentent schématiquement un ensemble réseau-réflecteur de la technique antérieure, pour les deux limites de dépointage _M et -_M,
• les figures 2a et 2b, respectivement, représentent schématiquement un ensemble réseau-réflecteur pour les limites de dépointage _M et -_M, selon un premier aspect de l'invention mettant en ouvre des moyens mécaniques pour déplacer les éléments rayonnants, et
• les figures 3a et 3b, respectivement, représentent schématiquement un ensemble réseau-réflecteur pour les limites de dépointage _M et -_M, selon un autre aspect de l'invention mettant en ouvre des moyens électroniques et/ou électromécaniques pour faire glisser la position des éléments actifs.

Other advantages and characteristics of the invention will appear on examining the detailed description below and the attached drawings in which:

• FIGS. 1a and 1b, respectively, schematically represent a network-reflector assembly of the prior art, for the two deflection limits  _M and - _M ,
• FIGS. 2a and 2b, respectively, schematically represent an array-reflector assembly for the deflection limits  _M and - _M , according to a first aspect of the invention using mechanical means for moving the radiating elements, and
• FIGS. 3a and 3b, respectively, schematically represent a network-reflector assembly for the deflection limits  _M and - _M , according to another aspect of the invention implementing electronic and / or electromechanical means for sliding the position active elements.

The drawings mainly contain elements of certain character. They will therefore not only be used to make the description better understood, but also contribute the definition of the invention, if applicable.

The configuration of the antenna according to the invention is that of a cylindrical reflector antenna combining the first two techniques described in the introduction. As shown in FIG. 1A which is a top view in section of an antenna of this type, it comprises a cylindrical reflector 2 of parabolic section in the example described, and a linear array (or strip) 1 of N unitary elements adjacent S ₁ , S ₂ , ..., S _N. These N elements can, for example, be produced in the form of waveguide openings for the transmission and / or reception of radioelectric signals. They interact with the reflector 2 either by emitting a beam of electromagnetic waves towards the reflector, or by receiving a beam from the reflector.

The cylindro-parabolic reflector has a focal line, in principle a straight line D, formed by the focal points of the parabolas. The elements of network 1 are arranged substantially on this focal axis D. So the interaction beam is practically parallel; the antenna operates "in the far field", that is to say that the image (in emission) is formed at infinity, or the object (in reception) is located at infinity.

For example in transmission, network 1 in principle radiates a cylindrical wave. Because network 1 substantially coincides with the focal axis D, this wave is collimated by the reflector 2 in a practically plane wave. The section parabolic reflector 2 allows to "pinch" the beam reflected around a plane P perpendicular to the wave front and containing the line D. The arrangement of the elements radiant in a linear network still makes it possible to concentrate the beam in this plane P. The right generator of the cylinder then acts as a flat mirror. Obtaining a beam narrow, therefore of a high gain, is thus linked to the height of the parabolic profile section on the one hand and to the length from network 1 on the other hand.

To create a deflection of the beam in the P plane, by an angle  around the normal incidence, an electronic scanning system 3 is usually implemented. This involves installing N phase shifters O ₁ , O ₂ , ..., O _N behind the unit radiating elements S ₁ , S ₂ , ..., S _N in order to induce a variable delay on the signal emitted or received by each element of the network 1. The variation of this phase shift as a function of the respective positions of the elements S ₁ , S ₂ , ..., S _N on the network 1, is in principle linear to inflect the wave front and create a beam deflection. Phase shifters of this type are known in particular by "Radiation characteristics of the EISCAT VHF parabolic reflector antenna" from PS. Kildal in IEEE Transactions on Antennas & Propagation (June 1984, p. 541-552). We can consider for example phase shifts along lines of programmable length, according to a frequency sweep, etc.

• le réflecteur est mécaniquement plus simple à réaliser qu'un paraboloïde de révolution, le principe s'apparentant à une torsion uniforme d'un élément plan à l'origine, le long d'un axe,
• l'ensemble est moins complexe à réaliser qu'une antenne réseau plane à deux dimensions, puisque dans le cas présent le réseau est simplement linéaire.

The capacity and the electronic scanning characteristics of the linear array 1 are reproduced in full after reflection of the beam on the reflector 2. This technique makes it possible to obtain particularly high scanning speeds. Furthermore, such a method has a number of advantages:

• the reflector is mechanically simpler to produce than a paraboloid of revolution, the principle being akin to a uniform torsion of a plane element at the origin, along an axis,
• the assembly is less complex to produce than a flat two-dimensional array antenna, since in the present case the array is simply linear.

In principle, the dimensions of the antenna are chosen so as to obtain a certain level of gain. The maximum directivity of the antenna is a first approximation defined by the formula D ≈ 4 π L 1 . H / λ 2 , where L ₁ is the length of the network interacting with the reflector and H the height of the reflector. The gain of the antenna corresponds to a fraction of this directivity value, taking into account for example the interaction weighting of the linear array, the concentration in the focusing plane P, etc.

The shape of the parabola, substantially constant along the generatrix of the reflector, depends on the focal distance F chosen between the linear array 1 and the reflector 2. In the case of a cylindrical-parabolic reflector antenna 2 interacting with an array linear 1 of length L ₁ , the longitudinal dimension L ₂ of the reflector 2 is determined as a first approximation by the angular range of deflection (or incidence) of the beam, so that the field focused on the grating 1 positioned on the focal line D intercepts reflector 2.

In general, the length of the reflector L ₂ is chosen according to the expression L 2 = L 1 + 2F.tan ( M ) where  _M is the maximum deflection angle of the beam, counted from the normal axis, and F the focal length.

An object of the invention is to reduce the length of the reflector L ₂ . It obviously appears that for a given maximum depointing  _M and a given gain partly linked to L ₁ , only the focal distance F can be reduced. But the reduction of the focal length can lead to a degradation of the radiation diagram (deformation, loss of gain, parasitic depointing). Thus, the length L ₂ of the reflector is usually much greater than the length L ₁ of the network.

The principle of the invention is then to create a shift in the positions of the radiating elements S ₁ , S ₂ , ..., S _N of the network 1 in order to reduce the length L ₂ of the reflector. This offset is made along the focal line D of the reflector 2.

According to a first aspect of the invention, an adjustment mechanical presented in a simplified form in the figures 2A and 2B, is proposed. Then an electrical adjustment is described more precisely according to another aspect of the invention, shown in Figures 3A and 3B.

Let N be the number of active radiating elements necessary to obtain the desired radioelectric characteristics (beam opening, gain, deflection range, etc.). Typically, for a network of length L ₁ , N is at least equal to L _1. (1 + sin) ¦ _M ¦) / λ, where  _M is the maximum beam depointing angle and λ the length of working wave.

According to the first embodiment of the invention, mechanical means make it possible to physically move the network of N active elements along the focal line D. This movement takes place on the side opposite to the beam pointing direction, by a distance d. It appears then that the necessary dimension of the reflector to intercept the reflected beam of an angle maximum _M maximum is no more than F.tan ( M ) - d beyond the central zone of length L ₁ , instead of the initial F.tan ( _M ). It is the same, symmetrically on the reflector, when the beam is depointed by - _M and the grating is moved mechanically in the other direction.

Thus, from a displacement of the network of length L ₁ on ± d along the line D, the dimension of the reflector can be reduced to L ₂ = L ₁ + 2F.tan ( _M ) - 2d.

A minimum overall size of the antenna is found when, for a deflection of the beam over an angular range ±  _M , the linear array of length L ₁ can be moved over ± 1/2 F.tan ( M )

The overall size L ₃ of the moving linear network is then equal to the useful length L ₂ of the reflector, that is: L 2 = L 3 = L 1 + F.tan ( M )

In the latter case, a cylindro-parabolic reflector of length L ₂ = L ₁ + F.tan ( _M ) can interact with a linear network of length L ₁ made up of N active radiating elements. This network is then moved around its central position, along the focal line, on ± 1/2 F.tan ( _M ), for example from a mechanism implementing a rack 5 of axis coincident with the straight line D. This rack 5 is, in the example described, geared to a pinion 6 whose rotation is managed by a control module 4 as a function of the value of the deflection angle , as shown in FIGS. 2a and 2b.

However, as the invention applies to an antenna with electronic scanning, the mechanical movement along the focal line can be advantageously replaced by the use of K additional elements S _{N + 1} , ..., S _{N + K} , fixed for the linear network.

Thus, using the principle developed above, the total length L ₃ of the linear network can be chosen so that it is substantially equal to: L 3 = L 1 + F.tan ( M )

The network then includes a larger number of elements N + K than in the previous case using a mechanical solution, with approximately K = NL ₂ / L ₁

In such a network, to obtain behavior similar to the outgoing antenna, N contiguous active radiating elements chosen from the N + K are used for a depointing of given beam, depending on the area to be intercepted on the reflector.

For a deflected beam at - _M , the active radiating elements chosen are the N upper elements S ₁ , ..., S _N positioned on the side opposite to the deflected beam, as shown in FIG. 3A. For a beam deflected at +  _M , the active elements are the N lower elements S _{K + 1} , ..., S _{N + K} located on the other side, as shown in FIG. 3B.

• un mode de décalage "discontinu" dans lequel les éléments actifs sont choisis selon l'une ou l'autre des deux configurations précédentes, en fonction du signe de l'angle de dépointage, et
• un mode de décalage "continu" dans lequel les éléments actifs occupent des positions intermédiaires variables en fonction de l'angle d'incidence . Ainsi, pour le faisceau non dépointé ( = 0), les éléments actifs seront par exemple N éléments centraux.

For intermediate deflections of the beam, two modes of offset can be envisaged:

• a “discontinuous” shift mode in which the active elements are chosen according to one or the other of the two previous configurations, as a function of the sign of the depointing angle, and
• a “continuous” shift mode in which the active elements occupy variable intermediate positions as a function of the angle of incidence . Thus, for the non-depointed beam ( = 0), the active elements will for example be N central elements.

In the preferred configuration of a continuous shift, the choice of the active elements is made from passive switching systems (electronic and / or electromechanical switches) C ₁ , C ₂ , ..., C _{N + K.} This switching can advantageously be managed by the electronic scanning control 3, at the same time as the phase shift between the elements.

• i vaut sensiblement la partie entière du terme K/2 - (K/2 - 1) [tan(-) / tan(-M)]
• j vaut sensiblement la partie entière de i + N

When the beam is deviated by an angle - from normal incidence, the switching system makes active elements S _i , S _{i + 1} , .., S _j of the upper part of the network, the indices i and j being non-zero natural integers with i <j, and fixed by the following conditions:

• i is substantially worth the whole part of the term K / 2 - (K / 2 - 1) [tan (-) / tan (- M )]
• j is substantially equal to the whole part of i + N

At the same time, the switching system makes the elements S _{i + N} , S _{i + N + 1} , ..., S _{N + K} of the lower part of the network inactive.

Furthermore, to bend the wavefront by an angle -, a phase shifting element O _u induces a delay on the signal transmitted or received by an active element S _u of the network (with i <u <i + N-1 ), substantially equivalent to τ _u = [(ui) / (N-1)] [sin () L ₁ / c] where c is the propagation speed of the electromagnetic wave.

• p vaut sensiblement la partie entière du terme K/2 [tan() / tan(M)] + N + K/2
• m vaut sensiblement la partie entière de p - N

When the beam is deviated by an angle +  from normal incidence, the switching system activates the elements S _m , S _{m + 1} ..., S _p of the lower part of the network, the indices m and p being non-zero natural integers with m <p, and fixed by the following conditions:

• p is substantially equal to the whole part of the term K / 2 [tan () / tan ( M )] + N + K / 2
• m is substantially equal to the integer part of p - N

At the same time, the switching system makes the elements S ₁ , S ₂ , ..., S _pN of the upper part of the network inactive.

Furthermore, to inflect the wavefront by an angle + , a phase shifting element O _v induces a delay on the signal transmitted or received by an active element S _v of the network (with p-N + 1 <v <p ), substantially equivalent to τ _v = [(v-p + N-1) / (N-1)] [sin () L ₁ / c]

It appears that variations in phase shifts and positions active elements are substantially linear in function respectively of the sine and the tangent of the angle . The electronic scan control 3 can then establish a correspondence between positions and phase shifts respective of the N active radiating elements of the network, from the beam deflection .

Conversely, we can attribute to each radiating element an active or inactive state depending on the phase shifts applied. This principle makes it possible to establish a direct correspondence between the position of the active elements and the phase shifts associates, without having to consider the value of the deviation .

Other switching systems to make active useful and inactive elements unnecessary elements, could be considered. For example, switching ON / OFF of amplifier power supplies can be used for this effect, in the case of active antennas where each element radiant has its own amplifier.

We could also consider a combination of the two types of shifting means, mechanical and switching, for modify the position of the active radiating elements of the network.

We have described above an antenna whose reflector is parabolic profile. However, the invention could be applied to a sectional cylindrical reflector antenna elliptical or hyperbolic depending on the needs of the application. It could, for example, apply to an antenna with Cassegrain reflector.

The scope of the invention is also not limited to a cylindrical reflector of constant section. Indeed, the reflector could be, for example, globally shaped conical. In this case, the offset of the position of the elements active takes place along a focal line which is no longer parallel to a generator of the cylinder.

One could also provide a parabolic reflector of substantially toroidal shape. In this case, the active elements can occupy variable positions, according to the invention, according to the deflection of the beam, and arranged on a arc.

The invention described above could be applied by example to telecommunication satellites, radars, but also to any other transmitting and / or receiving device electromagnetic signals.

Of course, the present invention is not limited to the mode of embodiment described, but extends to any variant included in the context of the claims below.

Claims (17)

1. An electromagnetic antenna of the type comprising a reflector (2) of generally substantially cylindrical shape, cooperating with a source (1) formed of radiating elements (S ₁ , S ₂ , ..., S _N ) arranged substantially in line (D ), each radiating element (Si) being associated with a delay member (O _i ), as well as with a respective excitation channel comprising both an electromagnetic link and a delay control input, so that the delays (τ ₁ , ..., τ _N ) thus applied to the excited radiating elements can be chosen to obtain an antenna beam capable, by electronic scanning (3), of being deflected between two deflection limits ( _M , -  _M ),
characterized in that said source (1) comprises means for sliding the position of the excited radiating elements along said line (D), as a function of the deviation () defined by the electronic scanning control (3). 2. Antenna according to claim 1, characterized in that said means are capable of sliding the position of the excited radiating elements along said line (D), on the side opposite to the deflection () of the beam, seen on the reflector (2). 3. Antenna according to one of claims 1 and 2, characterized in that the source (1) further comprises an input for the electronic scanning control (3) so as to control the deflection () of the antenna beam . 4 . Antenna according to claim 3, characterized in that said means and the electronic scanning control (3) are able to cooperate together to establish a correspondence between the position of the radiating elements excited along said line (D) and the deflection of the beam (). 5. Antenna according to one of the preceding claims, characterized in that said means are capable of sliding the position of the radiating elements excited at least from a deviation threshold (). 6. Antenna according to one of the preceding claims, characterized in that said means are capable of sliding the position of the excited radiating elements (S ₁ , S ₂ , ..., S _N ) over a distance from the line (D ) substantially proportional to the tangent of the deviation (). 7. Antenna according to claim 6, characterized in that said means are capable of sliding the excited radiating elements (S ₁ , S ₂ , ..., S _N ) over a range of excursion (F.tan) substantially equivalent to half the amplitude of depointing between the two limits ( _M , - _M ). 8. Antenna according to claim 9, characterized in that the reflector is of length (L ₂ ) substantially equivalent to the width (L ₁ ) of the antenna beam increased by said range (F.tan). 10. Antenna according to one of the preceding claims, characterized in that the line (D) substantially coincides with a focal line of the reflector (2). 11. Antenna according to one of the preceding claims, characterized in that the base of the cylindrical reflector (2) is substantially a parabola. 12. Antenna according to one of the preceding claims, characterized in that the line (D) is substantially straight. 13. Antenna according to one of the preceding claims, characterized in that the line (D) is substantially parallel to the generator of the cylindrical reflector (2). 14. Antenna according to one of the preceding claims, characterized in that the source (1) comprises radiating elements (S ₁ , S ₂ , ..., S _N ) movable in translation along the line (D), with their access routes, and mechanical means (4,5,6) for controlling the translation of these radiating elements (S ₁ , S ₂ , ..., S _N ). 15. Antenna according to claim 10, characterized in that the mechanical means comprise a rack (5) integral with a bar (1) carrying the radiating elements, a pinion (6) meshed with the rack (5) and a module control (4) suitable for controlling a rotational movement of the pinion (6) as a function of the deflection () of the beam. 16. Antenna according to one of the preceding claims, characterized in that the source (1) comprises switching means (C ₁ , C ₂ , ..., C _{N + K} ) to define a sliding subset of active radiating elements (S _{i + 1} , ..., S _{i + N} ), among all the radiating elements (S ₁ , ..., S _{N + K} ), while the correspondence between the excitation channels and the radiating elements (S ₁ , ..., S _{N + K} ) can be modified to accompany said sliding subset of active radiating elements (S _{i + 1} , ..., S _{i + N} ). 17. Antenna according to claim 16, characterized in that said switching means comprise at least two electronic and / or electromechanical switches (C ₁ , ..., C _{N + K} ) for connecting or disconnecting according to the deflection of the beam (), at least part of the radiating elements (S ₁ , ..., S _N , S _{K + 1} , ..., S _{K + N} ) to their associated electromagnetic link. 18. Antenna according to one of claims 16 and 17, characterized in that the switching means comprise a set of switches (C1, ..., C _{N + K} ) each associated with the electromagnetic link of a channel excitation, to continuously slide the respective positions of the active radiating elements (S _{i + 1} , ..., S _{i + N} ) as a function of the beam deflection ().

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