Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01Q—ANTENNAS, i.e. RADIO AERIALS
  • H01Q21/00—Antenna arrays or systems
  • H01Q21/06—Arrays of individually energised antenna units similarly polarised and spaced apart
  • H01Q21/22—Antenna units of the array energised non-uniformly in amplitude or phase, e.g. tapered array or binomial array
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01P—WAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
  • H01P1/00—Auxiliary devices
  • H01P1/18—Phase-shifters
  • H01P1/182—Waveguide phase-shifters
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01P—WAVEGUIDES; RESONATORS, LINES, OR OTHER DEVICES OF THE WAVEGUIDE TYPE
  • H01P3/00—Waveguides; Transmission lines of the waveguide type
  • H01P3/12—Hollow waveguides
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01Q—ANTENNAS, i.e. RADIO AERIALS
  • H01Q21/00—Antenna arrays or systems
  • H01Q21/0087—Apparatus or processes specially adapted for manufacturing antenna arrays
• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01Q—ANTENNAS, i.e. RADIO AERIALS
  • H01Q21/00—Antenna arrays or systems
  • H01Q21/06—Arrays of individually energised antenna units similarly polarised and spaced apart
  • H01Q21/061—Two dimensional planar arrays
  • H01Q21/064—Two dimensional planar arrays using horn or slot aerials

Definitions

• Radio frequency module comprising an array of isophase waveguides
• the present invention relates to a radio frequency (RF) module comprising an array of several non-identical waveguides.
• the waveguides can in this case be of different lengths.
• the radiofrequency module and/or the waveguides it contains make it possible to deliver an isophase signal despite the differences of the waveguides.
• the present invention aims in particular to control the phase shift between the waveguides or to minimize or eliminate it.
• US201212112963 discloses a butler array having a plurality of hybrids and waveguides such that "the output of a butler array has the same amplitude and a constant phase difference with respect to a signal of entrance.
• the transmission lines connecting the hybrids must be designed to have the same transmission length, or the amplitude and phase must be adjusted according to the resulting change.
• a curved waveguide can increase the complexity of paths.
• JP2003185858 discloses a wavelength demultiplexer having an input channel optical waveguide 1, a plurality of output channel optical waveguides 5 and an array waveguide 8 interposed between the input waveguide 1 and the output waveguide 5.
• WO20201 94270 describes a radiofrequency module comprising waveguides provided with ridges making it possible to increase the single-mode bandwidth.
• DRA antenna arrays are also known which combine several phase-shifted radiating elements (elementary antennas) in order to improve the gain and the directivity.
• the signals received on the various radiating elements, or emitted by these elements, are amplified with variable gains and out of phase with each other in order to control the shape of the reception and transmission lobes of the network.
• the various radiating elements are each connected to a waveguide which transmits the signal received in the direction of the radio frequency electronic modules, respectively which supplies this radiating element with a radio frequency signal to emit.
• the signals transmitted or received by each radiating element can also be separated according to their polarization by means of a polarizer.
• the assembly consisting of radiating elements (elementary antennas) in a network, associated waveguides, any filters and polarizers is referred to in this text as a passive radiofrequency module.
• the waveguides and associated polarizers are referred to as the feed network.
• the assembly is intended to constitute the passive part of a direct radiation network DRA.
• Arrays of radiating elements for high frequencies, in particular for microwave frequencies, are difficult to design.
• This reduction in the pitch between the various radiating elements of the network is however incompatible on the one hand with the minimum size required by the polarizers, and on the other hand with the size of the electronic amplification and phase-shifting circuits upstream of the polarizers.
• the size of the polarizers and the electronics most often determines the minimum pitch between the different radiating elements of an array.
• WO2019229515 describes a set of non-rectilinear waveguides, of varying length and shape, making it possible to reduce or increase the pitch between the radiating elements and thus to modulate the secondary lobes.
• the phase shift resulting from their difference in length is compensated by adapting the section of the different waveguides.
• An object of the present invention is therefore to provide a passive radiofrequency module, intended to form the passive part of a direct radiation network DRA, which is free from or minimizes the limitations of known devices.
• This radio frequency module comprises in particular a first layer comprising an array of radiating elements, each radiating element having a section making it possible to support at least one mode of wave propagation.
• It may also comprise a second layer forming a network of waveguides.
• It may also comprise a fourth layer forming a network of ports.
• the second layer can be interposed between the first layer and the fourth layer.
• Each waveguide can be intended to transmit in one direction or the other a radiofrequency signal between a port of the fourth layer and a radiating element.
• the surface of the first layer may be different from the surface of the fourth layer.
• the waveguides can be of different length and shape, but preferably have the same section.
• One or more of the waveguides includes at least one phase adjustment element.
• the waveguides thus have several cumulative functions; they make it possible on the one hand to transmit the signals between the ports of the fourth layer and the radiating elements of the first layer, and on the other hand to choose independently the pitch of the radiating elements and the pitch of the fourth layer ports. They also make it possible to correct or eliminate any phase shifts inherent in the structure of the module. They also allow a more compact arrangement, which could be impossible or more difficult by existing means.
• This arrangement makes it possible, among other things, to reduce the pitch between the radiating elements of the first layer, in order to reduce the amplitude of the undesirable secondary lobes (“grating lobes”).
• the pitch (p1) between two radiating elements of the first layer is preferably less than /A2, X being the wavelength at the maximum operating frequency.
• the convergent arrangement of the waveguides from the fourth layer to the radiating elements also makes it possible to space out the ports of the fourth layer.
• the large pitch between the ports makes it possible, for example, to arrange the electronic amplification and phase-shifting circuit supplying each port in the immediate vicinity of each port, by reducing the constraints on the dimensions of this circuit.
• This significant step also makes it possible to have, if necessary, polarizers of sufficient size close to each port, to perform an effective separation of the signals according to their polarization.
• the area of the first layer is larger than the area of the fourth layer.
• the waveguides then move away from each other between the fourth layer and the first layer.
• the arrangement of the radiating elements of the first layer may be different from the arrangement of the ports of the fourth layer.
• the radiating elements of the first layer can be arranged in a rectangular MxN matrix while the ports of the fourth layer are arranged according to a rectangular matrix KxL, M being different from K and N being different from L.
• This different arrangement can also involve different shapes, for example a rectangular arrangement on one of the layers and a circle, oval, cross, rectangle hollow, polygon, etc on the other layer.
• the radiofrequency module may comprise a third layer interposed between the second layer and the fourth layer.
• the elements of the third layer can perform signal transformation.
• the third layer may also comprise an array of elements performing a section match between the section of the output of the ports of the fourth layer and the section of different shape of the waveguides.
• a third layer of this type can in particular be provided when only the ports or only the waveguides are ribbed.
• the third layer interposed between the second layer and the fourth layer can also comprise an array of polarizers as elements.
• the radio frequency module may include external polarizers just after the radiating elements in the air.
• the third layer interposed between the second layer and the fourth layer may include a filter.
• Each radiating element of the first layer can be provided with at least one ridge parallel to the direction of propagation of the signal.
• the radiating elements of the first layer can also be unstriated and consist of open waveguides or square, circular, pyramidal horns, in the form of splines.
• the radiant elements can have a square, rectangular, or preferably hexagonal, circular or oval outer section.
• the pitch (p 1 ) between two radiating elements can be variable within the module.
• Each waveguide of the second layer is preferably designed to transmit either only a fundamental mode or a fundamental mode and a single degenerate mode.
• the length of the different waveguides of the second layer can be variable.
• the waveguides are, however, rendered isophase at the wavelength considered, in particular thanks to the presence of at least one phase adjustment element.
• the channel of different waveguides can be non-rectilinear.
• the second layer waveguides can be curved.
• the curvature of the different waveguides of the second layer can be variable.
• edge waveguides can be more curved than center waveguides.
• the ports of the fourth layer can constitute the inputs of a polarizer.
• a first end of all the waveguides may be in a first plane, while a second end of all the waveguides is in a second plane.
• the module is advantageously a module made by additive manufacturing.
• Additive manufacturing makes it possible in particular to produce waveguides of complex shape, in particular curved waveguides converging into a funnel between the layer of radiating elements and the layer of polarizers.
• additive manufacturing means any process for manufacturing parts by adding material, according to computer data stored on a computer medium and defining a model of the part.
• the expression also refers to other manufacturing methods by hardening or coagulation of liquid or powder in particular, including without limitation methods based on ink jets (binder jetting), DED (Direct Energy Deposition), EBFF (Electron beam freeform fabrication), FDM (fused deposition modeling), PFF (plastic freeforming), aerosol, BPM (ballistic particle manufacturing), powder bed, SLS (Selective Laser Sintering), ALM ( additive Layer Manufacturing), polyjet, EBM (electron beam melting), light curing, etc. Manufacturing by stereolithography or by selective laser melting is however preferred because it makes it possible to obtain parts with relatively clean surface states, with low roughness.
• the module is preferably monolithic.
• a monolithic manufacture of the module makes it possible to reduce costs, by eliminating the need for assembly. It also makes it possible to guarantee precise relative positioning of the various components.
• the invention also relates to a module comprising the above elements as well as an electronic circuit with amplifiers and/or phase shifters linked to each port.
• the invention further relates to any object comprising such a module, in particular a communication object.
• a communication object can be specifically dedicated to the aeronautical field or aerospace. It may for example be a communication satellite.
• the invention further relates to a method for designing and producing the module that is the subject of the present description.
• FIG. 1 Schematic side view of the different layers of a module according to the invention.
• FIG. 2 Two examples of embodiments of the third layer, in which each element of this layer comprises either one or two inputs on the side of the fourth layer.
• FIG. 3A Schematic representations of the second and third layer of an example of a module according to the prior art.
• FIG. 4 Schematic representation of a waveguide according to an embodiment of the present description.
• FIG. 5A and FIG. 5B Schematic representation of a waveguide according to another embodiment of the present description.
• FIG. 6A Schematic representation of a waveguide according to other embodiments of the present description.
• FIG. 7A and FIG. 7B Schematic representation of a waveguide according to other embodiments of the present description.
• Figure 1 illustrates a passive radiofrequency module 1 according to a first embodiment of the invention, intended to form the passive part of a direct radiation network DRA.
• the radiofrequency module 1 of this example comprises four layers 3, 4, 5, 6.
• the first layer 3 comprises a two-dimensional network of N radiating elements 30 (antennas) for transmitting electromagnetic signals into the ether, respectively for receiving the signals received.
• the second layer 4 comprises a network of waveguides 40.
• the third layer 5 is optional; it can also be integrated into the second layer 4.
• the third layer 5 includes a network of elements 50, for example polarizers or section adapters.
• the fourth layer 6 comprises a two-dimensional network, for example a rectangular matrix, with N ports 60 of waveguide 40.
• Each port 60 constitutes an interface with an active element of the DRA such as an amplifier and/or a phase shifter, part of a beamforming network (also known as spatial filtering or beam forming or channel forming).
• a port thus connects a waveguide to an electronic circuit, in order to inject a signal in the waveguides or in the opposite direction to receive the electromagnetic signals in the waveguides.
• This module 1 is intended to be used in a multibeam environment.
• the radiating elements 30 are preferably close to each other so that the pitch p1 between two adjacent radiating elements is smaller than the wavelength at the nominal frequency at which the module 1 is intended to be used. The amplitude of the secondary transmission and reception lobes is thus reduced.
• FIGS. 3A to 3C illustrate different views of an example of a module according to the prior art, without the third and the fourth layer.
• the waveguides 40 and the radiating elements 30 have in this example a square section provided with four grooves arranged symmetrically on the internal flanks.
• the waveguides are convergent in the direction of the first layer 3.
• the radiating elements 30 are constituted by waveguides whose internal cavity is provided with grooves or edges 300, for example two, three or four edges 300, for example distributed at equal angular distances.
• the present invention is characterized by the presence of one or more phase adjustment elements 500, arranged in protrusion on the internal surface of the waveguides 40.
• the phase adjustment elements 500 can be arranged in replacing or in addition to the ridges or ridges 300 known from the prior art.
• the phase adjustment elements 500 make it possible in this case to eliminate the phase difference inherent in the variations in length and/or geometry of the waveguides 40 of the same assembly. They also make it possible to limit or eliminate the variations in shape and dimensions of the waveguides 40 within the same assembly.
• phase adjustment elements 500 make it possible to produce a signal without any phase shift.
• the phase adjustment elements 500 can however make it possible to control the phase shift, for example to better control the secondary lobes.
• a specific phase shift can be induced thanks to the phase adjustment elements 500, limited for example to certain waveguides 40, according to their position in the matrix of waveguides or other factors.
• phase adjustment elements which differ from one waveguide to another.
• the section of these elements, their length, their height and/or their number can vary from one waveguide to another so as to cause different phase shifts and for example to thus compensate for differences in length between different waveguides.
• the waveguides 40 can thus have a cross-section of constant or practically constant shape and dimension.
• the cross-sectional shape essentially designates the outer contour of a given waveguide 40. According to one aspect, it excludes the shape and section of the inner surface of the waveguide. According to another aspect, it excludes any geometry or internal element of the waveguide other than the internal contours whose shape corresponds to the external contours.
• the shape of the cross section refers not only to the geometric shape of the cross section but also to its dimensions.
• the cross-sectional shape of a given waveguide 40 is preferably constant or substantially constant over the entire length of the waveguide 40.
• the cross-sectional shape of all waveguides 40 d a given set is identical, even in the case where the waveguides 40 have different lengths.
• the variations in length between the waveguides 40 are liable to generate phase shifts which must be rectified or compensated, at least partially.
• Other parameters such as the variation of the longitudinal shapes of the waveguides, even if they have the same length, can generate phase shifts.
• variations in the radii of curvature, or in the number of curvatures of the waveguides 40 can produce such phase shifts.
• Other parameters such as any variations in roughness or combinations of materials used in the manufacture of the waveguides are also likely to influence the phase shift.
• phase adjustment elements 500 make it possible to eliminate the phase shift or in any case to control it.
• the waveguides of a given set, some or all of which include one or more of the phase adjustment elements 500 are isophase.
• the phase adjustment elements 500 alternatively make it possible to control the phase shifts. This means in particular that the differences in phase shift between waveguides, inherent in the structure of the waveguides of the module, can be reduced or made similar, or even identical. This further means that phase shifts can be produced in a controlled manner. This may be required, for example, to limit or eliminate secondary lobes or interference between radiating elements.
• Phase adjustment elements 500 can be used to correct phase shifts initially expected to result from the structure of the waveguides but ultimately diverge from the expected values.
• phase adjustment elements make it possible to rectify any structural or manufacturing faults to obtain the phase shift value required for each waveguide of the module.
• a phase adjustment element 500 can for example take the form of a variation in the internal diameter of the waveguide 40.
• FIG. 4 shows such an example of a waveguide 40, having an internal surface SI forming a maximum diameter dmax and a minimum diameter dmin, and an outer surface SE, of section and of constant shape over its length L.
• the waveguide 40 is shown rectilinear, it may not be rectilinear. It can also have all the shapes of cross sections already mentioned in the present description.
• the section of the waveguide can be hexagonal or polygonal, square, rectangular, round or oval, or of any other suitable geometry.
• the phase adjustment element 500 can gradually reduce the internal diameter of a waveguide 40 between a maximum diameter dmax and a minimum diameter dmin, over its entire length L or over only part of its length L. In this last case, it is a local reduction of the internal diameter being able for example to compensate for the effects of a curvature of the waveguide.
• Such an arrangement can be located in one or more central portions of the waveguide 40 or else at one or more of its ends.
• the values of the maximum diameter dmax and minimum dmin can be determined as a function of the length L of the waveguide 40 or of its difference in length with the adjacent waveguides.
• the slope of the variation in diameter between the values dmax and dmin, or else the length of the adjustment element 500 can be determined as a function of the length L of the waveguide 40 or of its difference in length with adjacent waveguides.
• the value of the maximum diameter dmax can correspond to the diameter of the internal surface SI, or else to a fraction of the order of 70% or 80% or approximately 90%, or approximately 95% of the diameter of the inner surface SI.
• the minimum diameter dmin can meanwhile correspond to a value of the order of 60% or approximately 50%, or even 40% of the diameter of the internal surface SI.
• phase adjustment elements 500 can each have an eigenvalue of the maximum diameter dmax and of the minimum diameter dmin.
• the diameter is understood here as the dimension of the internal space of the waveguide 40, independently of the geometry of its section. It therefore applies equally well to round or oval cross-sectional shapes as to polygonal shapes.
• the phase adjustment element can cover the entirety of the internal surface SI.
• the phase adjustment element 500 can be arranged on a part of the cross section of the waveguide 40.
• FIGS. 5A and 5B show an example of a waveguide 40 of round section comprising an element of phase adjustment 500 covering part of the section of the waveguide 40.
• FIG. 5A shows the corresponding transverse section and FIG. 5B a longitudinal section.
• the proportion of the cross section comprising a phase adjustment element 500 can be for example of the order of or greater than 10%, or of the order of or greater than 20% or of the order of or greater than 30% of the internal surface SI corresponding to this cross-section. It can be up to 100% of the internal surface SI for a given cross section. From one end of the phase adjustment element 500 to the other, the proportion of the internal surface SI occupied by the phase adjustment element 500 can vary, for example, from approximately 10% to approximately 90% or from 20% to about 80%, or from 30% to about 70% of the inner surface SI. In other words, the area occupied by a phase adjustment element 500 varies from a minimum area value Smin to a maximum area value Smax along the waveguide 40.
• the thickness of a phase adjustment element 500 on a given cross section of a waveguide may not be identical over the entire surface occupied by the phase adjustment element.
• a phase adjustment element 500 when it covers only a fraction of the surface of a cross section, can be oriented parallel to the longitudinal axis of the waveguide 40.
• an element phase adjuster 500 may deviate from the longitudinal axis of waveguide 40 and assume a helical configuration along the inner surface S1 of waveguide 40.
• the surface of the phase adjustment element 500 facing the inside of the waveguide 40 can be rounded and concave in shape, as shown in FIG. 5A. Alternatively, it can be rounded and convex, as shown in Figure 6A. Other shapes can be determined, in particular angular shapes such as triangular or rectangular shapes, as represented in FIGS. 7A and 7B.
• phase adjustment elements 500 are arranged in a waveguide, they can be arranged on the same sections of the waveguide 40, that is to say facing each other. - screw each other.
• FIG. 6A represents a waveguide section 40 comprising two phase adjustment elements 500 placed opposite one another.
• FIG. 6B represents a longitudinal section of a waveguide 40 comprising several adjustment elements 500a, 500b, 500c, 500d offset from each other along the waveguide.
• FIG. 6C represents another cross-sectional view where the phase adjustment elements 500a, 500b, 500c are arranged in an offset manner and oriented along an axis different from the longitudinal axis of the waveguide 40. In particular, they form a angle with respect to the longitudinal axis of the order of 10° to around 40°.
• Figures 7A and 7B show other example of waveguide 40 of rectangular section and comprising several elements phase adjustment 500a, 500b, 500c of different shapes. It is understood that each of the shapes represented can be chosen independently of the others, and that the same shape can be replicated in the same waveguide 40.
• the shape of the section of a phase adjustment element 500 can particular be selected from a rounded concave shape, a rounded convex shape, a polygonal shape, or a combination of these shapes.
• the phase adjustment elements 500 discussed in the present description can be arranged in addition to other elements already present in the waveguide 40 and not involved in the suppression or the controlled modulation.
• phase shift such as grooves or edges or points.
• radiating elements comprising ridges 300 allow dimensions smaller than the wavelength of the signal to be transmitted or received.
• the diameter of the waveguides can be smaller than the wavelength of the signal.
• such elements are not necessarily isophase and require phase shift correction.
• the phase adjustment elements 500 therefore make it possible to maintain the small dimensions of the waveguides 40 made possible thanks to the presence of ridges while making it possible to eliminate the phase shift or to control it.
• Examples of waveguides comprising such longitudinal elements such as grooves or ridges have also been given, which make it possible to increase the single-mode passband of each waveguide device.
• WO2020194270 gives one such example. A suppression or a modulation of the phase shift may nevertheless remain necessary. What the phase adjustment elements of the present description allow.
• the structures added to the waveguides 40 for particular reasons can also cause a phase shift which should be corrected.
• the phase adjustment elements 500 are arranged in waveguides 40 that do not include any of the other elements mentioned above. According to a provision particular, they can be arranged to replace the elements already present in the waveguide 40 and having different functions of modulation or phase shift suppression. In this case, the phase adjustment elements 500 make it possible to ensure the role of the elements that they replace while allowing the modulation or the elimination of the phase shift.
• the phase adjustment elements 500 can be arranged in a waveguide 40 replacing one or more of the ridges 300 that it comprises. The adapted geometry of the phase adjustment elements 500 thus make it possible to maintain small dimensions while controlling the phase shift.
• phase adjustment elements 500 are arranged as a replacement or in addition to other elements already present in the waveguide 40, they make it possible in all cases to avoid or limit the variations in section of the waveguides normally needed to remove or correct phase shift.
• the greater homogeneity in the diameters of the waveguides promotes greater compactness of the device.
• the diameter and/or the surface occupied by phase adjustment elements 500, replacing or complementing other elements not being involved in the correction or modulation of the phase shift are constant.
• the values of maximum diameter dmax and of minimum diameter dmin, or else the surface occupied for a given section of the waveguide 40 are equal for a given phase adjustment element 500 .
• the phase adjustment elements 500 can be symmetrical and/or be arranged in the waveguide 40 in a symmetrical or regular manner. Alternatively, the phase adjustment elements 500 do not have any particular symmetry, they can therefore be non-symmetrical. They can be arranged in the waveguide in a non-regular manner, that is to say at non-identical intervals. In this case they can be locally concentrated at the places of shape variation of the waveguides 40, for example at the level of the curvatures or close to the curvatures.
• each of the waveguides 40 can have a specific influence on the phase shift of the signal with respect to the signal relating to the other waveguides 40 of the set. This specific influence may result from a difference in length or other factors.
• the phase adjustment elements 500 are adapted to correct the impact of the different waveguides on the phase shift of the signal in a specific way. In other words, the number, shape, dimensions and arrangement of the phase adjustment elements 500 can vary from one waveguide 40 to another.
• some waveguides may be devoid of phase adjustment elements 500 and other waveguides 40 may be provided with such adjustment elements. phase adjustment.
• some or all of the waveguides of a set can include one or more phase adjustment elements 500, which are identical or different.
• all of the waveguides preferably have the same cross-section, both in shape and in size. In this way, their phase shift is not compensated by a variation in the shape or the dimensions of their section.
• a set of waveguides may nevertheless include waveguides whose shape and cross-sectional dimensions differ from one another without these cross-sectional differences allowing suppression, modulation or correction. of the desired phase shift.
• the waveguides 40 can be separated from each other. Alternatively, they can be linked to each other, so as to maintain their relative positioning. They can form a monolithic whole.
• the link between the waveguides can be established for example by the first layer 3, by the third layer 5 and/or by the fourth layer 6. It is also possible to make holding elements in the form of bridges between different waveguides.
• the waveguides can be in direct contact with each other over their entire length or over a portion of their length.
• a network of radiating elements 30 in the first layer 3 comprises N radiating elements 30.
• the radiating elements 30 can be arranged in a rectangular or square matrix or any other geometry suited to requirements.
• the radiant elements can form rows having a variable number of radiant elements according to the rows, the general shape of the layer forming an octagon.
• the radiating elements 30 may be phase shifted on the successive rows, the value of the phase shift possibly being less than the pitch p1 between two adjacent elements 30 on the same row.
• a first layer 3 of any polygonal or substantially circular shape can also be produced.
• the radiating elements 30 can also be arranged in a triangle, a rectangle, or a diamond, with lines aligned or out of phase.
• each radiating element of the first layer 3 makes it possible to obtain high insulation between the different beams.
• Sub-wavelength radiating elements reduce the impact of side lobes in the region covered.
• Any shape of radiating elements supporting at least one mode of propagation can be implemented, including rectangular, circular or rounded shapes, striated or not.
• the radiating elements 30 can be single-polarization or double-polarization.
• the polarization can be linear, inclined or circular.
• the pitch p1 between two radiating elements 30 of the first layer 3 is preferably less than or equal to ⁇ /2, X being the wavelength at the maximum frequency for which the module is provided.
• the radiating elements may include polarizers, not shown, for example at the junction with the second layer 4. In another embodiment, not shown, polarizers are provided just after the portion of free air in which the signal emitted is struck off. As will be seen later, polarizers can also be provided in the third layer 5.
• the second layer 4 comprises N waveguides 40.
• Each waveguide 40 transmits a signal from a port 60 and/or an element of the third layer 5 to a corresponding radiating element 30 in transmission, and vice versa. paid in reception.
• the waveguides 40 further perform a conversion between the arrangement of the elements 60 on the third layer 5 and fourth layer 6 and the different arrangement of the first layer of radiating elements 3.
• the waveguides 40 can be curved so as to make the transition between the surface of the third or fourth layer 6 and the different surface of the first layer 3 of radiating elements.
• the waveguides thus form a funnel-shaped volume.
• the second layer 4 can make it possible to adapt the pitch between adjacent elements. In one embodiment, it can also be made so as to make a transition between the arrangement of the radiating elements 30 of the first layer 3 and a different arrangement of the ports 60 of the fourth layer 6.
• the second layer 4 can perform a transition between an array of elements or ports arranged in a rectangular matrix and an array of elements or ports arranged in a different matrix, or in a polygon, or in a circle.
• At least some waveguides 40 can be curved.
• at least some waveguides are curved in two planes perpendicular to each other and parallel to the longitudinal axis of the module. These waveguides 40 are thus curved in an S in two planes orthogonal to each other and parallel to the main signal transmission direction.
• the connection plane between the waveguides 40 and the radiating elements 30 on one side, and the connection plane between the waveguides 40 and the elements 50 on the other side, are preferably parallel between them and perpendicular to the main direction of signal transmission.
• the waveguides 40 at the periphery of the second layer 4 can be more curved than those near the center, and longer.
• the waveguides 40 close to the center can be rectilinear.
• the phase adjustment elements 500 therefore differ between the waveguides 40 of the periphery and those of the center.
• the dimensions of the internal channel through the waveguides 40 and those of the input 41, as well as their shapes, are determined according to the operational frequency of the module, that is to say the frequency of the electromagnetic signal for which the module 1 is manufactured and for which a stable mode of transmission and optionally with a minimum of attenuation is obtained.
• the different waveguides 40 in the second layer 4 can have different lengths and curvatures, which influence their frequency response curve. These differences can be compensated by the electronics supplying each port 60 or processing the received signals. Preferably, however, these differences are at least partially compensated by adapting one or more of the shape, number, dimensions, geometry of the phase adjustment elements 500 of the present description. According to an advantageous arrangement, the presence of the phase adjustment elements makes it possible to dispense with the electronic elements dedicated to the correction of the phase shift.
• All the waveguides have the same shape and the same sectional dimensions.
• some waveguides may comprise one or more phase adjustment elements 500 intended to locally control the phase shift of the signal.
• phase adjustment elements 500 intended to locally control the phase shift of the signal.
• the phase adjustment elements 500 described here make it possible to obtain a set of isophase waveguides at the wavelength considered.
• the waveguides of such a set of isophase waveguides each make it possible to produce a signal without phase shift with respect to the signal of the other waveguides of the set despite the differences in length or curvature or shape of the waveguides.
• the different waveguides comprise one or more phase adjustment elements adapted to compensate for the phase variation resulting from the differences in length or shape of the different waveguides.
• waveguides of different length, and/or producing different phase shifts although provided with the phase adjustment elements described here, and to exploit or compensate for these phase shifts with the network of active electronic phase shift circuits, in order to control the relative phase shift between radiating elements, and for example to control the beamforming.
• the second layer 4 can also, according to the embodiments, include other waveguide elements such as filters, polarization converters or phase adapters.
• Each waveguide 40 may be intended to transmit a single-polarization or double-polarization signal.
• the third layer 5 is optional and comprises elements 50.
• the elements 50 make it possible to make a transition between the cross section of the ports 60 of the fourth layer 6 and the cross section which may be different from the 40 waveguides the second layer 4, generally corresponding to the cross section of the radiating elements of the first layer 3.
• the waveguides of the third layer 5 ensure for example a transition between the square or rectangular section of the output of the ports 60 and the section waveguides 40 and radiating elements 30 which can be provided with ridges 300.
• the elements 50 of the third layer 5 can also, according to the embodiments, carry out a transformation of the signal, for example using other waveguide elements such as filters, polarization converters , polarizers, phase adapters, etc.
• the cross-sectional area of the third layer 5 is preferably equal to the cross-sectional area of the fourth layer 6.
• Figure 2 illustrates an example of element 50 of the third layer 5.
• this element 50 comprises an input 51 linked to a port 60 and an input 53 linked to the input 41 of a waveguide 40.
• this element 50 comprises two inputs 52A, 52B, each being linked to a port 60A respectively 60B of the fourth layer, and an input 53 linked to the input 41 of a waveguide 40.
• element 60 preferably includes a polarizer for combining respectively separating two polarities on ports 60A, 60B, from/to a combined signal on waveguide 40.
• phase adjustment elements in the channel of the waveguide can cause filtering of the radiofrequency signal in the waveguide (comb filter). This filtering can be controlled so as to attenuate undesirable frequency bands or propagation modes. Filtering can also be an undesirable consequence of the presence of phase adjustment elements in the waveguide channel. In this case, the phase adjustment elements will be positioned and dimensioned in such a way as to attenuate only frequencies far from the nominal frequency of the waveguide.
• the present invention also covers a method of manufacturing a module which is the subject of the present description.
• the entire module 1 is preferably made monolithically, by additive manufacturing. It is also possible to make the entire module 1 in several blocks assembled together, each block comprising the four layers 3, 4, 5, 6, or at least the first layer 3, second layer 4 and fourth layer 6. A manufacturing by subtractive machining or by assembly is also possible, as well as a combination of additive manufacturing and subtractive machining steps.
• the phase adjustment elements 500 are preferably produced by an additive manufacturing method.
• the module is made entirely of metal, for example aluminum, by additive manufacturing.
• the module 1 comprises a core made of polymer, PEEK, metal or ceramic, and a conductive envelope deposited on the faces of this core.
• the core of the module 1 can be formed from a polymer material, ceramic, a metal or an alloy, for example aluminum, titanium or steel.
• the phase adjustment elements 500 can be integrated into the core and formed from the same material as the core.
• the conductive envelope may cover the phase adjustment elements 500.
• the core of the module 1 can be made by stereolithography or by selective laser melting (selective laser melting).
• the core may comprise various assembled parts, for example glued or welded together.
• the phase adjustment elements 500 can be added to the core and associated with the core by means of gluing or welding.
• the metallic layer forming the casing may comprise a metal selected from Cu, Au, Ag, Ni, Al, stainless steel, brass or a combination of these metals.
• One or more of the inner and outer surfaces of the core, including the phase adjustment elements 500, may be covered with a conductive metallic layer, for example copper, silver, gold, nickel etc, plated by chemical deposition without electric current.
• a conductive metallic layer for example copper, silver, gold, nickel etc, plated by chemical deposition without electric current.
• the thickness of this layer is for example between 1 and 20 micrometers, for example between 4 and 10 micrometers.
• this conductive coating must be sufficient for the surface to be electrically conductive at the selected radio frequency. This is typically obtained using a conductive layer whose thickness is greater than the skin depth S.
• This thickness is preferably substantially constant on all the internal surfaces in order to obtain a finished part with precise dimensional tolerances.
• the deposition of conductive metal on the internal and possibly external faces can be done by immersing the core in a series of successive baths, typically 1 to 15 baths. Each bath involves a fluid with one or more reactants. The deposition does not require applying a current to the core to be coated. Regular stirring and deposition are obtained by stirring the fluid, for example by pumping the fluid in the transmission channel and/or around the module 1 or by vibrating the core and/or the fluid container, for example with a device ultrasonic vibrator to create ultrasonic waves.
• the metallic conductive envelope can cover all the faces of the core in an uninterrupted manner.
• the module 1 comprises side walls with external and internal surfaces, the internal surfaces delimiting a channel, said envelope conductor covering said inner surface but not the entire outer surface.
• the module 1 may comprise a smoothing layer intended to at least partially smooth the irregularities of the surface of the core.
• the conductive envelope is deposited over the smoothing layer.
• the module 1 may comprise a bonding (or priming) layer deposited on the core so as to cover it in an uninterrupted manner.
• the tie layer can be made of conductive or non-conductive material.
• the tie layer makes it possible to improve the adhesion of the conductive layer to the core. Its thickness is preferably lower than the roughness Ra of the core, and lower than the resolution of the additive manufacturing process of the core.
• the module 1 successively comprises a non-conductive core produced by additive manufacturing, including one or more phase adjustment elements 500, a bonding layer, a smoothing layer and a conductive layer.
• the tie layer and the smoothing layer make it possible to reduce the roughness of the surface of the waveguide channel.
• the tie layer makes it possible to improve the adhesion of the core, conductive or non-conductive, with the smoothing layer and the conductive layer.
• the shape of the module 1 can be determined by a computer file stored in a computer data medium and making it possible to control an additive manufacturing device.
• the shape, number, location, dimensions as well as any useful parameter relating to the phase adjustment elements 500 can be determined by a computer file stored in a medium. of computer data and making it possible to control an additive manufacturing device.
• the shape, number, location, dimensions as well as any useful parameter relating to the phase adjustment elements 500 can be determined in whole or in part by means of a modeling program.
• a modeling program makes it possible, for example, to determine at least part of the characteristics of the phase adjustment elements 500 necessary to carry out the suppression or the modulation of the phase shift as a function of the characteristics of the waveguides used.
• Such a modeling program can for example take into account the length of the waveguide considered, its longitudinal shape, including the curvatures, the shape of its section, and any other useful parameter, as well as the wavelength of the signal. Modeling may include the application of an algorithm to determine the phase shift of a waveguide based on its characteristics.
• the characteristics of the phase adjustment elements 500 include one or more of their dimensions, their shapes, their number, and their arrangement in the waveguide, including their orientation and their location.
• An artificial intelligence and/or deep learning module can be used to determine the effect of the phase adjustment elements 500 on the phase shift and the transfer function of the waveguides. When the characteristics of the phase adjustment elements are determined, they can be transferred to an additive manufacturing device in order to produce them.
• the module can be linked to an electronic circuit, for example in the form of a printed circuit mounted behind the third layer 5 of ports or behind the fourth layer 6, with amplifiers and/or phase shifters linked to each port.

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• Engineering & Computer Science (AREA)
• Manufacturing & Machinery (AREA)
• Variable-Direction Aerials And Aerial Arrays (AREA)
• Optical Integrated Circuits (AREA)
• Aerials With Secondary Devices (AREA)
• Control Of Motors That Do Not Use Commutators (AREA)

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• 2021
  • 2021-10-27 FR FR2111441A patent/FR3128590B1/fr active Active
• 2022
  • 2022-10-26 WO PCT/IB2022/060264 patent/WO2023073567A1/fr not_active Ceased
  • 2022-10-26 CN CN202280072274.4A patent/CN118160160A/zh active Pending
  • 2022-10-26 KR KR1020247017195A patent/KR20240090858A/ko active Pending
  • 2022-10-26 JP JP2024525112A patent/JP2024540033A/ja active Pending
  • 2022-10-26 IL IL312034A patent/IL312034A/en unknown
  • 2022-10-26 CA CA3234143A patent/CA3234143A1/en active Pending
  • 2022-10-26 US US18/704,661 patent/US20240421501A1/en active Pending
  • 2022-10-26 EP EP22797889.7A patent/EP4423860A1/de active Pending

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