FR2570887A1 - Antenna - Google Patents

Abstract

The invention relates to wave transmission-reception techniques. The antenna forming the subject of the invention is of the type comprising a waveguide radiator 1 in the walls of which are made transmitter slots 4 and which is connected to a high-frequency channel 6, and is characterised in that the waveguide radiator 1 is formed of two waveguides 2, 3 with transmitter slots 4, these guides penetrating into one another so as together to form a cruciform cross-section, the entrance of the waveguide radiator 1 being connected by a supply connector 5 to the high-frequency channel 6. The invention can be used in particular in radio systems employed for steering the movements of agricultural machines.

Description

 The present invention relates to transceiver devices and in particular relates to an antenna.

 The invention can be used in particular in radio-electric systems used to orient the movements of agricultural machinery, in soil remediation works, in buildings, in quarries (or surface mines) for coal extraction. , that is to say where radio navigation systems are used to automate technological processes in open areas allowing the free propagation of radio waves. The special feature of the antenna is the significant flow of energy from the transmitter channel to the receiver channel (decoupling 20-30 dB), which does not limit its use for moving machines.

 The radio set installed on the machine operates with an active retransmitter. The energy then flowing from the transmitter channel to the receiver channel in the two stations, arranged, for example, one on the mobile agricultural machine, and the other, on the ground (re-transmitter), constitutes a signal d heterodyne, because the transmission frequencies of these stations differ from each other by a value corresponding to an intermediate frequency.

 We know an antenna (see the work of Y.N.

Feld, MS Benson, "Antenna devices and feeders" t.2 Moscow 1959, p.335 and "Manual of radio detection", editor M. Skolnik, t.2, ed. "SovetskoSe radio",
Moscow 1977, pp.30-32) comprising a slit radiator on an omnidirectional waveguide, connected by a feeder connection to the high frequency channel comprising a ferrite antenna switch.

 However, the feed connection of this antenna is of complicated design, because it must not only connect the output of the antenna switch, for example of rectangular section, to the slot radiator on circular waveguide, but also realize a complicated conversion of the main wave H01 from the rectangular waveguide to a symmetrical wave E01 (of the higher type) in the circular waveguide. In addition, the ferrite switch introduces additional losses in emitted (and captured) energy and reduces the economic efficiency of the antenna.

 An antenna is also known (see French patent application NO 2255715, cl. H01 Q 13/02, 1975) comprising a waveguide radiator on the walls of which emitting slots are provided and which is connected to the high frequency channel. The slots are made on the opposite narrow walls of the radiating waveguide, while in the middle of its wide walls are welded, externally, metal plates. Inside the radiating waveguide, in the middle of its wide wall, are mounted fins separated by intervals. This complicated antenna design is due to the need to form an omni-directional radiation pattern formed by the synthesis of two cardioid patterns formed by slotted radiators on the narrow walls in the plane of the orthogonal longitudinal axis of the guide d The insufficient level of intersection of the two cardioid diagrams for omnidirectional radiation required the installation of two metal plates on the outside, and for tuning, fins inside the radiating waveguide.

 In view of the above considerations, the invention relates to an antenna capable of ensuring the formation of a very directional radiation diagram in the plane of its longitudinal axis and the synthesis of an omnidirectional diagram in a plane orthogonal to a Sufficiently high level of intersection of the cardioid radiation patterns, requiring no additional complication in the design of the emitting slit waveguide.

 This object is achieved by the fact that in an antenna comprising a waveguide radiator in the walls of which are emitting slots and which is connected to a high frequency channel, according to the invention said waveguide radiator is formed by two waveguides with emitting slits penetrating one into the other so as to present together a cross section in cross, the input of said waveguide radiator being connected to the high frequency channel by means of a power connection.

 This embodiment of the waveguide radiator makes it possible to add four diagrams in the form of a cardiolde at a level ensuring the emission of a total omnidirectional signal.

 It is advantageous to provide the antenna of the high-frequency channel with an antenna switch produced in the form of a bridge connection, the outputs of which are connected to the inputs of the supply connection, and of which a first and a second input are connected to the outputs of the high frequency channel, which constitute the connection inputs of the transmitter and the receiver, respectively.

 The use of a slotted bridge simplifies the design of the antenna switch, reduces the losses of emitted (and captured) energy and improves its economic efficiency of use. On the other hand, the slot bridge is easily coupled, from the construction point of view, to the supply connection by its outputs, and can be connected by its inputs to the transmitter and to the receiver.

 It is reasonable, in the antenna according to the invention, to produce the switch in the form of a ferrite circulator connected by its output to the input of the supply connector. Such an embodiment of the antenna makes it possible to use an antenna switch in combination with a power supply function and a cross-section waveguide radiator. In some cases, the use of a ferrite circulator is necessary to reduce the reaction of the antenna on the transmitter, to ensure optimal characteristics of the high frequency channel during operation on transmission (radiation).

 It is preferable that the waveguides constituting the radiator are produced with emitting slots on their narrow and / or wide walls.

 The use of emitting slots in the waveguide radiator makes it possible to form radiation directed in a plane parallel to its longitudinal and omnidirectional (uniform) axis, as well as of shape adjustable in an orthogonal plane.

 It is advantageous that the antenna is provided with a phase shift element installed on the supply connection.

 The construction of the power connection as well as the antenna switch determines the phase ratio between the signals emitted by the emitting slit waveguides.

 To establish the desired phase ratio between the signals transmitted, and therefore, to ensure the synthesis of an omnidirectional diagram or of adjustable shape, the phase shift element is used.

The invention will be better understood and other objects, details and advantages thereof will appear better in the light of the explanatory description which will follow of different embodiments given solely by way of nonlimiting examples with reference to the drawings. nonlimiting annexed in which
- Figure 1 is a schematic view of the antenna according to the invention;
- Figures 2, 3, 4, 5 illustrate alternative embodiments of the waveguide radiator according to the invention;
- Figure 6 shows a high frequency channel with an antenna switch in the form of a ferrite circulator, according to the invention.

 The antenna according to the invention comprises a waveguide radiator 1 (FIG. 1) formed by two waveguides 2 and 3 penetrating one into the other so as to together form a cross section in cross. On the narrow walls of the waveguides 2 and 3 are provided emitting slots 4. It is also possible to provide slots on the wide walls of the waveguides 2 and 3. The intersection of the waveguides 3 and 2 is determined by the angle oCforme between the projections of the planes of symmetry parallel to the wide walls of each of the waveguides 2 and 3 in cross section.

The angle oG between the waveguides 2 and 3 can be either a right angle (Figures 2, 3), or an acute angle (Figures 4, 5). This angle OC is determined by the prescriptions concerning the shape of the overall directivity diagram of the waveguide radiator 1 (FIG. 1). In particular, to form the omnidirectional radiation pattern of the antenna, it is preferable that the angle OC between the waveguides 2 and 3 is equal to 900.

 The input of the waveguide radiator 1 is connected via a feeder 5 to a high frequency channel 6. The high frequency channel 6 comprises an antenna switch 7 with inputs 8 and 9 connected, respectively, to outputs 10, 11, to connect the transmitter 12 and the receiver 13. The outputs 14 and 15 of the antenna switch 7 are connected to the supply connector 5.

As an antenna switch 7 a bridge connection, of the slotted bridge type, can be used. The slotted bridge is a junction of two rectangular waveguides (not shown) with a slit on their common narrow wall. For this reason, the outputs 14 and 15 of the antenna switch 7, when it is in the form of a slotted bridge, are organically coupled to the input of the supply connection 5, consisting of two rectangular waveguides, touching by their narrow walls at their entry, and penetrating one into the other so as to form together a cross section at the outlet of the supply connector 5.

 In the supply connector 5 is mounted a phase shift element 16.

 According to a possible alternative embodiment of the antenna switch 7, this can be in the form of a ferrite circulator 17 (FIG. 6) connected by its outputs 10 and 11 to the transmitter 12 and to the receiver 13, respectively. The ferrite circulator 17 is connected to the supply connection 5 by a differentiator 18.

 The antenna works as follows. The antenna is mounted with a short-range radionavigation station on any mobile device to ensure the radio link with a repeater mounted at the navigation point.

 The operation of the antenna will be examined at the signal transmission and reception regimes.

 The transmitted signal, developed in the transmitter 12 (FIG. 1), attacks, through the output 10 of the high frequency channel 6, the input 8 of the antenna switch 7 realizes in the form of a slot bridge (at three decibels).

If the high frequency signal e1 at input 8 of the slit bridge from the transmitter 12 is present in the form

E being the amplitude of the field intensity,
the circular frequency of the signal,
t, the current time, at the outputs 14, 15 of the antenna switch 7 (d slot bridge) the signals emitted e2 and e3 will be in quadrature and of equal amplitude, that is to say that
e2 = Ej # t
e3 = E.ej (t - ## / 2)
It should be noted that at input 9 only a very small portion of the transmitted signal penetrates (decoupling is approximately 20 dB) and the signal at input is approximately agal to

Then, the signals e2 and e3 pass through the supply connection 5 and attack the inputs of the waveguides 2 and -3 of the waveguide radiator 1.

 The waveguides 2 and 3 provided with the emitting slots 4 form a radiation directed in the plane of the longitudinal axis of the waveguides 2 and 3, and from the emitting slots 4, on each of the four narrow walls of the guides waves 2 and 3, in a plane orthogonal to their longitudinal axis (the horizontal plane) are formed directivity diagrams in the form of a cardioid.

 Given that the level of intersection of the cardioldeal diagrams is sufficiently high, one obtains, if their phasing is correct, an omnidirectional total radiation diagram.

 The necessary phasing of the signals e2 and e3 emitted by the waveguides 2 and 3 is carried out by selecting the lengths of the waveguides constituting the supply connection 5 and is corrected if necessary using the phase shift element 16.

The shape of the directivity diagram resulting from the radiator with waveguides 1 in the horizontal plane can also be adjusted by modifying the angle oL between the waveguides 2 and 3.

 When the antenna operates in reception mode, the signals received by the emitting slots 4 of the waveguides 2 and 3 arrive through the supply connection 5 at the outputs 14 and 15 of the antenna switch 7, then at its exit 9; the signal then arrives at the output 11 of the high frequency channel 6, in the receiver 13.

 The formation of the omnidirectional total radiation pattern of the antenna mounted on the position of the short-range radio navigation system and installed on a mobile machine, is essential so that, for any direction of movement of the machine, the radio link with the re-emitter is not interrupted, i.e. so that the level of the signals received by the antenna and of the irradiated signal are independent of the coordinates of the navigation point chosen to install the re-emitter, as well as of the direction of movement of the mobile machine.

 In cases where the required antenna radiation is not omnidirectional in the horizontal plane, but has a determined antenna directivity, the shape of the antenna directivity diagram can be adjusted in the horizontal plane. .

 The proposed antenna is particularly usable for short-range radionavigation systems ensuring the orientation of the movement of mobile agricultural machinery with a determined distance between neighboring passes.

 In these systems, composed of a station mounted on a machine and a retransmitter installed on the ground, one must use antennas with high efficiency but of simple design, small footprint and reliable what, in the end, must to improve the efficiency of soil and plant treatment.

 This is all the more important as the specific efficiency of the antenna is very important in the sum of the technical and economic indices of the reception and emission devices, and in particular, of the short-range radionavigation systems.

Claims (5)

 1. Antenna comprising a waveguide radiator (1) in the walls of which are emitting slots (4) and which is connected to a high frequency channel (6), characterized in that the waveguide radiator (1) is formed by two waveguides (2, 3) with emitting slots (4), these guides penetrating one in the other so as to together form a cruciform cross section, the entry of the waveguide radiator (1) being connected by a supply connection (5) to the high frequency channel (6).  2. Antenna according to claim 1, characterized in that the high frequency channel (6) comprises an antenna switch (7) produced in the form of a bridge connection whose outputs (14, 15) are connected to the inputs of the supply connection (5), and the first and second inputs (8, 9) of which are connected to the outputs (10, 11) of the high-frequency channel (6) and constitute inputs for the connection of a transmitter (12) and receiver (13), respectively.  3. Antenna according to claim 1, characterized in that the antenna switch (7) is produced in the form of a ferrite circulator (17) whose output is coupled to the input of the supply connection (5) .  4. Antenna according to one of claims 1, 2 and 3, characterized in that the waveguides (2, 3) of the waveguide radiator (1) have emitting slots (4) on their narrow walls and / or wide.  5. Antenna according to one of claims 1, 2, 3 and 4, characterized in that it is provided with a phase shift element (16) disposed in the supply connector (5).