BE425367A - - Google Patents

Description

       

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   BELL TELEPHONE MANUFACTURING COMPANY 4, rue Boudewyns ANTWERP.



   ANTENNA NETWORKS APPLICABLE IN PARTICULAR IN RADIO-GUIDANCE SYSTEMS
OF MOBILES "TELEPHONE EQUIPMENT".



   The present invention relates to antenna arrays applicable in particular in directional transmission systems.

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 or reception of radio waves. The invention provides, in particular, antenna arrays arranged for use in mobile radio-guidance systems as well as means for eliminating certain disturbances in the transmission of the waves used.



   In known systems, such as those used in blind landing installations, the directional beam is radiated and deviated usually by means of a system comprising an exciting antenna, one or more reflectors and one or more directors. Such an arrangement can in general be considered to include a longitudinal alignment giving one directional diagram and a transverse alignment giving another directional diagram, these two diagrams combining to form a directional diagram of desired characteristics.



   An automatic manipulator modifies the characteristics of the cross-section diagram by means of appropriate elements, according to a predetermined rhythm. It follows that the resulting diagram is deviated to the right or to the left of the axis to be marked out. According to known methods, the modification of the transverse diagram can be obtained by the operation of relays controlling the action of reflectors.



   According to the same known methods, any increase in the longitudinal directivity leads, for a given transverse directivity, to a decrease in the slope of the resulting diagram in the direction to be marked out, that is to say a reduction in the sharpness of the markup.



   One of the objects of the present invention is to provide means for increasing the sharpness of the marked axis.



   Another object of the invention is to provide means for increasing the longitudinal directivity of the antennas while maintaining a suitable sharpness of the marked axis.



   Another object of the invention is to provide means

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 to eliminate handling clicks without reducing the precision of the marked axis.



   According to one of the characteristics of the invention, each of the conductors of the transverse alignment is constantly traversou -ru by a current; depending on the handling period, it is arranged to operate either as a reflector or as a director and, consequently, its action does not present any dead time.



   According to another characteristic of the invention, means are provided for synchronizing the side reflectors of an antenna system, that is to say for suppressing harmful fields during part of the manipulation.



   According to another characteristic of the invention, means are provided for making the gain and the front / rear ratio of a directional diagram independent of the reflective elements of the system.



     These and other features will become apparent in more detail from the following description based on the accompanying drawings, in which:
FIG. 1 shows by way of example a possible arrangement of an array of directional antennas in which means are provided to ensure satisfactory sharpness of the marked axis;
Figure 2 shows a possible arrangement of a reflector capable of operating as a director during part of the manipulation;
Figures 3 and 4 show the directional, longitudinal and transverse diagrams of the antenna system shown in Figure 1, and Figure 7 shows the resulting directional diagram;
Figures 5 and 6 show vector diagrams used in the disclosure, in relation to the transverse directional diagram of Figure 4;

   and,
Figure 8 shows an arrangement of reflectors employing features of the invention, which eliminates

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 the clicks of manipulation.



   It is clear that the following description describes by way of example only a possible combination of exciter antenna, directors and reflectors, but that the invention can find applications in other combinations used in the field. convenient.



   FIG. 1 to which reference will now be made shows an array of antennas, which can be used in particular in blind landing or mobile radio guidance systems, comprising an exciting antenna A, a reflector Rl and two directors Dl and D2, which form the longitudinal alignment of the guidance station, and a reflector R2 and a director D3, the functions of which are swapped during handling, which together with the exciting antenna A, form a transverse alignment.



   Experience shows that during handling and because of the delays of the relays, the two side conductors operate simultaneously either as reflectors or as directors, during these periods, the field on the axis to be marked undergoes a sudden variation of value, which is reflected in the receiver by a so-called manipulation snap. The presence of such clicking is a cause of discomfort for the auditory observation of signals, and distorts the indications of a visual device.



   The conductor BB ′, shown in FIG. 2, and which can be used for the alternating reflector R2-director D3 system, comprises a choke coil L to the terminals of which is connected the usual handling relay R. This choke coil is of a value such that it detuns the reflector assembly by excess of inductance, at a time of manipulation. At this moment, the current has a value I and a phase angle f. The conductor BB ′ acts against the radiation from the exciter antenna A, that is to say plays the role of reflector.

   At another point in the manipulation, the relay R operates and short-circuits the choke L, thus reducing the electrical length of the conductor BB ', which is such that the value of the current remains I

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 but its phase becomes -. The conductor BB 'then acts by reinforcing the radiation of the antenna A, that is to say as a director.



   The relays interposed in the reflector R2 and the director D3 operating inversely with respect to each other, these elements will at all times have the inverse functions of each other, that is to say that at one time of the manipulation, there will be the reflector R2 and the director D3, and that at another time, there will be the director R2 and the reflector D3. These elements being located on either side of the exciting antenna A, it is obvious that their actions at a distance are added and produce more intense effects than those obtained with a single active conductor acting for example as a reflector following known methods.



   These intense effects make it possible, while maintaining sufficient sharpness of the axis, to use longitudinal alignments with high directivity giving a diagram such as that of FIG. 3. This directive diagram is that of the longitudinal alignment of the network, exciter antenna A, reflector R1 and director D1 and D2. The shape of this diagram is insignificant in itself, but it should present an advantageous ratio of forward OM and back ON radiation, as shown.



   The transverse alignment comprising the exciter antenna 11 and the reflector R2-director D3 assembly with inverting operation, gives a directional diagram shown in FIG. 4. The analysis of this diagram is facilitated by the examination of the lines. figures 5 and 6.



   In FIG. 5, the secondary electric field created by the antenna A at point A at the instant considered has been represented at AE0.



  The vector BE represents the field of the antenna A at the point B at the same instant. Be is behind by @ over A if the distance AB is
2 1/4 wave. At B is a conductor of the type shown in figure 2.



  Let us suppose that this conductor is arranged to act as a reflector at the considered instant. The vector BE, then represents its field. he

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 lags by an angle # 1, compared to the normal in B to BE. The resulting field in the direction AB is the result of BE and BE1, therefore weak compared to the inducing field BE. The conductor acts as a reflector.



   If, on the contrary, the inductor of the conductor is short-circuited, the phase of the current changes, the radiated field becomes BE2 ahead of # 2 on the normal to BE. This field resulting from the composition of BE and BE2 is greater than BE; the driver functions as a director.



   For the simplicity of the figures, we assume that the angles # 1 and # 2 are equal to a value r close to the optimum value which is #. .



   4
In this hypothesis, FIG. 6 represents: in AE0 the field of the exciter antenna, in BE2 the field of a directing element situated at 1/4 wave from the antenna, in CE 1 the field of a reflector element located 1/4 wave from the antenna.



   The fields BE2 and CE- can be broken down into their longitudinal components Be'2 and Ce'1 (in phase) and transverse components Be2 and Ce1 (in phase opposition).



   FIG. 4 represents: in OABC and ODEF the diagram of the components in phase opposition and in OGHI and OJKL the diagram of the components in phase.



   If, as shown in figure 6, the longitudinal and transverse components exist at the same time, the two elementary diagrams of figure 4 co-exist and the total effect of the transverse alignment is the result of these two basic diagrams. When combined with the longitudinal radiation (diagram in figure 3), it is easy to see that only the CABC-ODEF diagram of the components in phase opposition contributes to the scanning of the beam, that is to say to the definition of the axis to be marked.



   It is important that the diagrams of the components in opposition

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 phase present a zero field in the direction of the longitudinal axis, these components therefore have no effect on the intensity of the field on the axis to be marked. The gain and ratio of the front and rear radiations of the system are, therefore, independent of the presence of reflectors. And if these components disappear during the manipulation intervals, there will be no field variations on the axis, and therefore no clicks due to these components.



   The phased components, which alternately add and subtract in absolute value from the longitudinal field during manipulation, will produce noticeable manipulation clicks.



  In particular, during the transient handling periods mentioned above, the two lateral conductors tend to function simultaneously as reflectors (or directors). In this case only the components in phase remain according to the diagram OGHI - QJKL (figure 4) and have the effect of modifying the value of the field according to the direction to be marked. This variation in field is the cause of the manipulation clicks observed.



   According to certain characteristics of the invention, the conductors such as BB 'and CC' can be synchronized in their elec -triqu.e environment by means of an XY transmission line having a length equal to half a wavelength. Such an arrangement is shown diagrammatically in FIG. 8. In this figure, the conductor BB 'is shown operating in direction with its relay R short-circuiting the chokes L, L', and the 'conductor CC' is shown operating as a reflector with its relay R1 open and its choke coils serial.



   The impedance of the conductor DC 'seen from the Y end of the transmission line shows a characteristic inductance reactance, which seen at the other X end of the line has changed sign and has become a characteristic reactance of. capacity.



  That is, it is of suitable sign for the driver BB '

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 operating as a director with its short-circuited inductors whose impedance adapts this capacity. No current passes through the line and consequently the latter does not modify the normal operation of the conjugate reactance reflectors.



   Causing the dead time of the relays, the two conductors BB 'and CC' tend to function as reflectors. As the terminal reactances are no longer combined, a synchronization current arises in the XY line and tends to cancel these reactances and therefore to eliminate the effect of the conductors BB 'and CC'. The transverse field then no longer exists and the diagram of the system is such as that shown in FIG. 3. The manipulation clicks are thus eliminated.



   It is clear that the embodiment shown is given only by way of example and that other arrangements using characteristics of the invention can be established without departing from its scope.



   In the above detailed description, the phase of the longitudinal radiation was kept fixed and the phase of the transverse radiation was reversed symmetrically to produce the manipulated deformations of the resulting pattern. The phase of the transverse radiation can also be kept fixed by supplying the lateral conductors with suitable transmission lines. In this case, the phase of the longitudinal field is manipulated by providing the central antenna A or other conductors of the longitudinal alignment with means as shown in FIG. 2. The central antenna or the other conductors manipulated can d 'moreover be supplied by the same source as the transverse conductors, the phase shift then being symmetrically with respect to the common high frequency supply voltage.



   It is obvious that the devices described by way of example find a field of applications in all cases where it is desired to modify at will the radiation characteristics of a radiating system without mechanically moving one or more elements. ment.

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   In particular when a transmitting station serves several stations located in different geographical azimuths, the directional transmission or reception pattern can be rotated by a considerable angle without affecting its qualities or causing the appearance of radiation sheets. unwanted. this makes it possible, among other things, to reduce the number of directed antennas which is usually necessary. It is clear that directional reception antennas can also use these same methods. The directional diagram can also be rotated in time in order to obtain, for example, successive guides of different orientation by means of a single set of antennas.

   In the case where the number of directions to be served is high, it is obviously possible to have several lateral systems making it possible to carry out the desirable combinations of transverse fields without requiring the subsequent modification of the settings of the conductors themselves and to obtain different slopes and directivities at the by means of a system of mechanically fixed elements.



   CLAIMS.



   1 - Antenna arrays applicable in particular in directive systems for the transmission or reception of radio - electric waves, including: an exciter or receiver antenna; one or more drivers acting as directors; and one or more conductors functioning as reflectors to produce a directional diagram having the desired characteristics, characterized in that at least some of the conductors are each provided with a device which is such that when it acts, said conductor operates as a reflector, and when said device is inoperative, said conductor functions as a director.

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Claims (1)

2 - Antenna arrays applicable in particular in directional systems for the transmission or reception of electro-electric waves comprising: an antenna; one or more directors; one or more reflectors arranged to produce a diagram <Desc / Clms Page number 10> desired directive; a means by which the reflectors can function as directors and the directors as reflectors; and means by which a current flow in the conductors during a change in operation of the conductor is continuously maintained. 3 - Antenna arrays applicable in particular in directional systems for transmitting or receiving radio waves according to claim 2, characterized in that said means comprises a device which operates to oppose a change in the current in said driver. 4 - Antenna arrays applicable in particular in directional systems for transmitting or receiving radio waves according to claim 1 or 3, characterized in that said device comprises a coil having a large self-inductance, a switching device short circuiter being connected across the terminals of this coil, which is placed in the center of the length of the conductor. 5 - Antenna arrays applicable in particular in directional systems for the transmission or reception of radio waves for mobile radio guidance installations, comprising a network of directional antennas according to claims 1 or 2, or 3, or 4, and a mechanism whereby said selected conductor device can be made active or inactive alternately at a desired frequency of operation. 6 - Antenna arrays applicable in particular in directional systems for transmission or reception of radio waves according to claim 5, characterized in that the conductors are arranged in the shape of a cross with the antenna in the center, the devices of the conductors in alignment on one side of the antenna being made active, while the devices of conductors placed on the opposite side of the antenna are inactive. 7 - Antenna arrays applicable in particular in <Desc / Clms Page number 11> Directional systems for transmitting or receiving radio waves according to claim 5 or 6, characterized in that means are provided for synchronizing the conductors in the same alignment during the transition period when they change function. 8 - Antenna arrays applicable in particular in directional systems for transmission or reception of radioelectric waves according to claim 7, characterized in that the inductance coil included in a conductor is divided, the two free ends of the coil thus formed being connected by a transmission line to the corresponding ends of the inductance coils of the other conductors located at a distance equal to half a wavelength, a short-circuiting switch device being connected through the ends of each half of the inductor coil. 9 - Antenna arrays applicable in particular in directive systems for transmitting or receiving radio waves according to claim 4 or 8, characterized in that the short-circuiting switch comprises a relay contact, the relay being adapted to be periodically excited at a desired frequency by means of a manipulator. 10 - Antenna arrays applicable in particular in directional systems for the transmission or reception of radio waves comprising an antenna and one or more conductors provided with a contact switching device for bringing said conductor into condition. operating or in non-operating condition, characterized in that said contact switching device is shunted by a coil having a large self-inductance. II - Antenna arrays applicable in particular in directional systems for the transmission or reception of radio waves' as described above with reference to the accompanying drawings. <Desc / Clms Page number 12> ABSTRACT. The present invention relates to antenna arrays applicable in particular in directional systems for transmitting or receiving radio waves. According to certain characteristics of the invention, in directional antenna systems, such as, for example, systems used for the radio-guidance of mobiles, each of the conductors of the transverse alignment is constantly traversed by a current and is arranged to operate either as a reflector or as a director, for example by means of a relay short-circuiting an inductor which detuns the conductor by excess of inductance in its operation as a reflector; in this way, the action of this conductor does not present any dead time during the handling period. Such conductors are arranged symmetrically on each side of the exciter antenna, one operating as a director and the other as a reflector, these functions being changed during handling. In order to avoid handling clicks due to harmful fields which can occur during transient periods of handling, these two conductors are synchronized, for example by means of a transmission line. According to features of the invention, the phase of the longitudinal radiation of a directional antenna system is kept fixed and the phase of the transverse radiation is reversed to produce the manipulated deformations of the resulting pattern. The invention also provides for antenna systems in which the manipulation takes place on the phase of the longitudinal field, one or more conductors of the longitudinal alignment of the system then being arranged to be constantly traversed by a current and to operate alternately. as a reflector or as a director, the phase of the transverse radiation then being kept fixed. According to features of the invention, the diagram <Desc / Clms Page number 13> total directive of a transmitting or receiving station can be deformed so as to rotate its axis of maximum directivity in a desired azimuth without mechanically moving one or more elements of the antenna and conductor system.