FR2783097A1 - Vertically-polarized radio antenna with variable radiation angle, for CB or amateur radio, has ground plane construction with pivoting arrangement altering inclination of radials to whip section - Google Patents

Abstract

The ground plane antenna has an insulated base (4) for the whip section (2) and preferably eight radials (6), equally-spaced around the base part with a mechanism including a pivot (10), slide block (11), and an electric motor (14) to raise or lower them. In use, the angle of inclination of the radials is adjusted so as to change the radiation angle of the antenna to suit propagation conditions.

Description

POLARIZED RADIO WAVES TRANSCEIVING ANTENNA

VERTICAL.

  The invention relates to an antenna for transmitting and receiving radio waves with vertical polarization, with a vertical whip. The invention relates more particularly, but not exclusively, to such an antenna for the 27/28 MIz band, that is to say the 10/11 m band, for cibists, radio amateurs, radio amateurs. This example however

  is not limiting, the antenna being able to be suitable for any band of emission-reception.

  It is known that the transmission and reception conditions depend on the angle of departure of the emission waves or on the angle of arrival of the reception waves. The angle of departure or attack or fire or elevation is formed by the angle formed by the horizon line and the line of direction of the maximum emission lobe with respect to this horizon. A definition

  similar applies to the angle of arrival.

  It is therefore important to be able to tune the angle of departure, or arrival, of the electromagnetic waves in order to obtain the best gain in emission, or in reception, of a given station, and, according to the mode of transmission used, depending on the ionization state of the atmospheric layers concerned or the

  propagation in direct fire (optical range).

  We know, for this purpose, a vertical antenna mounted on a telescopic mast whose electric counterweight is made partially or only by the ground; varying the height of the antenna with respect to the ground varies the angle of departure of the waves. This system is however very expensive to make and is almost impossible to install on the roof of a house, which however corresponds to the majority of cases. The object of the invention is, above all, to provide an antenna for transmitting and receiving radio waves with vertical polarization which makes it possible to best match the angle of departure or arrival of electromagnetic waves in order to obtain the best gain in transmission and reception. It is desirable that the antenna remains of a simple and economic realization, while allowing, in particular, a

  installation on the roof of a dwelling.

  According to the invention, a transmitting antenna

  reception of vertically polarized radio waves with a vertical whip is characterized in that it comprises, in the lower part, at least one radian mounted to pivot so that the angle between this radian and the whip of the antenna is adjustable and that means for controlling the inclination of the radian is provided for

  allow to adjust this angle at will.

  Preferably, the antenna comprises, in the lower part, at least three radians mounted pivotally and a means for controlling the inclination of each radian to allow the angle of this radian to be adjusted with the whip

vertical of the antenna.

  The pivoting mounting of the radians is preferably provided to allow adjustment of the angle between the radian and the whip of the antenna over a range from

less than 15 to 1350.

  Advantageously, the antenna has eight radians,

regularly spaced.

  The angles of inclination between each radian and

  the antenna whip are preferably equal.

  The antenna advantageously comprises a control means capable of acting simultaneously and in the same way on the inclinations of all the radians of

the antenna relative to the whip.

  According to a preferred embodiment, each radian is pivotally mounted about a pivot axis orthogonal to the whip of the antenna and radially spaced therefrom, and the control means is provided for modifying the inclination of the radians by displacement vertical of a coaxial element to the whip of the antenna and connected to each radian, in particular connected to an extension of this radian radially inward relative to the pivot axis. The control means may comprise a motor driving an eccentric which actuates a main control rod acting on the element constituted by a vertical cylindrical slide, coaxial with the whip, to which are connected rods which transmit, by means of compensating elongation and shortening, movement to control rods

radians.

  Each radian can be constituted by a rod, in particular of aluminum, of round section fixed in a detachable manner on a control rod pivotally mounted around a pivot axis orthogonal to the whip of the antenna, this pivot axis being supported by the wall of a housing traversed substantially radially by the control rod, this housing being

  located at the bottom of the antenna whip.

  The invention consists, apart from the arrangements set out above, of a certain number of other arrangements which will be more explicitly discussed below in connection with an exemplary embodiment described with reference to the attached drawings, but who

is in no way limiting.

  Figure 1 of these drawings is a schematic vertical section, with external parts and parts removed, of a vertical polarized antenna

according to the invention.

  Figure 2 is a top view, with parts

  torn from the antenna of Figure 1.

  Figure 3 is a diagram partially illustrating the antenna, with parts broken away, for a

  first angular position of the radians.

  Figure 4, similarly shown in Figure 3,

  the antenna for another position of the radians.

  Figure 5 shows similarly to Figure 3

  the antenna with yet another radian position.

  Figures 6 to 11 illustrate the evolution of the radiation lobes for a conventional vertical antenna

  half-wave ground effect with no radians.

  Figures 12 to 14, finally, illustrate the evolution of the radiation lobes for a vertical half-wave antenna with radians, according to the invention, for different angles of the radians with the whip of the antenna, namely 90 for Figure 12 , 15 for the

  Figure 13, and 135 for Figure 14.

  Referring to the drawings, in particular to

  Figures 1 and 2, we can see a transmitting antenna 1

  reception of vertically polarized radio waves which includes a vertical whip 2 provided at its base with a shortening inductor 3. An insulating base 4 is provided for holding the whip 2 on an antenna support mast 5. The antenna 1 comprises in the lower part, that is to say just below the insulating base 4, and towards the top of the mast 5, radians 6 pivotally mounted so that the angle A between a radian and the whip 2 of the antenna (or its extension formed by the mast 5) is adjustable. A control means C is provided to enable this angle A to be adjusted. In the example considered, as visible in FIG. 2, eight radians 6 are provided, regularly distributed around the whip 2. The number of radians may be different. It is preferably greater than three and can be extended to twelve or eighteen. A good compromise between "emission-reception and wind resistance" is however achieved with the illustrated example of eight radians. A radian is considered, in radio transmission, as the radial part of the conductive artificial earth plane attached to the base of the antenna and always connected to the

  cold point, that is to say to the mass thereof.

  Whip 2 is the omnidirectional vertical radiating part, since with vertical polarization in

the case considered.

  Each radian 6 is constituted by a metal rod 7, in particular of aluminum, of round section by

  example of 10 mm in diameter and forming a strand of radian. This strand 7 is mounted, for example, by screwing onto the threaded end of an iron control rod 8, for example 10.

  Each rod 8 passes radially through the cylindrical wall of a housing 9 fixed to the top of the mast 5,

  below whip 2, coaxial to it.

  The outer diameter of the housing 9 can be of the order of 30 cm for a height of around 20 cm. The housing 9 is closed by an upper wall and a wall

  lower. The mast 5 has a diameter of the order of 40 mm.

  Each rod 8 is pivotally mounted about a pivot axis 10 orthogonal to the whip 2 and carried by

the cylindrical wall of the housing 9.

  The control means C of the inclination of each radian 6 comprises an element constituted by a slide 11 engaged on the mast 5 and passing through the bottom of the housing 9. The upper end of the slide 11 is connected to the inner radial end of each rod 8 by a link 12 and a metal circle 13 elastically deformable, for example 5 cm in diameter, serving as compensator for elongation and

shortening of movement.

  The vertical movements of the slide 11 are controlled by an electric motor 14, the frame of which is

  fixed by a bracket 15 under the bottom of the housing 9.

  The motor output shaft 14 is orthogonal to the mast 5 and drives an eccentric 16 which is connected by a connecting rod 17 to a lug 18 provided towards the lower end

  of the slide 11, outside the housing 9.

  The motor 14 is itself controlled from a

  console located at a distance, and not shown.

  The angles A between each radian 6 and the whip of the antenna 2 are equal and their variations are controlled simultaneously by the displacements of the slide 11, so that these angles remain equal

between them.

  The operation of the antenna results from

explanations above.

  By controlling the starting of the motor 14, a vertical displacement of the slide 11 is caused and therefore a modification of the angle A formed between the radians 6

  and the antenna whip 2, or its extension.

  This system makes it possible to change at will and according to the propagation conditions, the angle of departure of the emission waves and to obtain signals

  far superior to a fixed system.

  It is thus possible to make radio links which, until then, were difficult or impossible to achieve. The example described provides for motorized control of the radians 6. It is clear, however, that a control

  manual angle A is entirely possible.

  Figure 3 partially illustrates the antenna for

  an angle A between the radians 6 and the whip 2 equal to 15.

  Figure 4 corresponds to the case where the angle A is equal to 90. Figure 5 corresponds to the case where this angle A

is equal to 1350.

  An experiment was conducted. The antenna was installed 9m above the ground, in the study carried out in the frequency range of 27/28 Mh; the height of 9m corresponds to approximately 0.85X, X being the wavelength (10-11m in the example considered) of radio waves. This height is important because it represents the majority (of the order of 80%) of

  vertical antenna installations.

  To ensure that the operation of the variable firing angles is not disturbed, it is important to respect this distance because below and above appear

  unwanted radiation lobes as illustrated in Figures 6 to 14 which are graphs of the radiation lobes in a vertical plane, the geometric axis of the antenna being the vertical axis.

  Figures 6 to 11l correspond to a conventional vertical half-wave antenna, without radians, the height of which above the ground gradually increases from Figure 6 to Figure 11. The height of the base of the antenna above the ground is expressed in wavelength X corresponding to the operating frequency

from this antenna.

  Fig. 6 corresponds to a height of 0.25 X, Fig. 7 at a height of 0.37 X, Fig. 8 at a height of 0.5 y, Fig. 9 at a height of 0.75 X, Fig. 10 at a height of 0.85 X and Fig. 11 at a height of 1 X. For emission, the lobes having a vertical axis as in the case of Figures 7, 8, 10 and 11 are less favorable, since the energy radiated along the vertical axis is almost

lost.

  These Figures 6 to 11 illustrate the variations in the firing angle obtained, with a conventional antenna, by modifying the height of the base of this antenna.

relatively to the ground.

  Figures 12, 13 and 14 illustrate the radiation lobes with a half-wave antenna according to the invention in which the angle A of the radians with the axis of the whip is modified, while the height of the antenna au- above ground remains constant and equal to the

optimal value of 0.85 k.

  Fig. 12 corresponds to an angle A of the radians with the whip of 90; Fig. 13 at an angle A of 15 and FIG. 14

at an angle A of 1350.

  The cold point of the antenna, that is to say the ground, is connected directly to the earth with an electrical conductor of large section, for example 6 mm2, to ensure correct operation of the artificial earth plane constituted by the radians. This earthing also constitutes a surge protector protecting the interior installations of the dwelling and can be

equipped with a spark gap.

  The antenna of the example described was produced in 1/2 wave resonance. The installation of radians with variable pitch on vertical antennas of different type, in particular of the type / 8 or 7/8 of wave, is however possible. The system described can be transposed to any other

  vertical antenna with or without shortening inductor.

  The invention makes it possible to tune the starting angle of the electromagnetic waves in order to obtain the best gain in transmission from a given station and, depending on the transmission mode used, as a function of the ionization state of the atmospheric layers. concerned or propagation in direct fire (optical range). The differences in signals with equal power and identical propagation can in certain cases be greater than 24 dB, or 4 points per S-meter, compared to the same vertical antenna of the conventional fixed type of the prior art. The system remains compatible with any system

  existing, for a very low cost.

  The average radiation angle favorable to long distance links (DX), for the 11 meter band, that is to say the frequencies 27/28 Mhz is on average of degrees. This angle depends on the height at which the antenna is installed, the more or less perfect conductivity of the ground, the frequency used and the condition

  of the ionization of the layers E, F1, F2.

  The variations in the angle of departure or of firing are in direct connection with the maximum range of the antenna and of which here is the average diagram for the layer F2 (200 km to 420 km according to the hour) and F1 (approximately 100 km

depending on the time).

  Firing angle 0 5 10 15 20 30 35 40 F2 Range km 4200 3000 2500 1800 1500 1000 850 720 in 1 hop F1 Range km 1900 1360 1130 810 675 450 380 320 in 1 hop It is easy to see that if, at one time given, the link with a correspondent located at 1000 km

  is possible with obtaining a transmission signal-

  reception of 3 on the S-meter with a conventional antenna whose angle is fixed at 10 degrees, while the most favorable angle is around 30 degrees, it follows

a significant loss.

  The alignment of the radiation lobe of the variable angle antenna according to the invention solves this problem, even if the correspondent does not have the same type of aerial, the S-meter can then show an increase

  very sensitive by 7, that is to say 24 dB more.

  Likewise, the firing angle must be close to 0 for direct links, therefore local (from 1 to 100/150 km depending on the emission band used). The variation of this angle with the variable pitch radians system is

feasible.

  The antenna according to the invention, with variable pitch of firing angle, has an enormous advantage in covering the shadow areas whose firing angle is greater than 10 by raising the firing angle, and in range direct by

  a horizontal lowering of this shooting angle.

  The mounting of the radians 6 at a variable angle relative to the vertical whip 2 of transmission-reception, has a definite advantage as regards the optimization of the results of radiocommunications at medium distance (320 to 4000 km), and relates to excellent performance in very long distance, as well as in liaison

direct (1 to 150 km).

  There is a problem of impedance matching, but which in practical reality can be ignored because the Stationary Wave Report (ROS or TOS) does not exceed

  not 1.5 / 1.8, which can be considered normal for many, but perfectionists will adjust the ROS using a manual or automatic coupler at the transmitting station5.

Claims (9)

RESELL I CATIONS   1. Antenna for transmitting and receiving radio waves with vertical polarization, with a vertical whip (2), characterized in that it comprises, in the lower part, at least one radian (6) mounted so as to pivot so that the 'angle (A) between this radian and the whip (2) of the antenna is adjustable and that a control means (C) of the inclination of the radian is provided to allow adjust this angle (A) as desired.   2. Antenna according to claim 1, characterized in that it comprises, in the lower part, at least three radians (6) pivotally mounted and a control means (C) of the inclination of each radian to allow the adjustment of the 'angle of this radian with the vertical whip (2) of the antenna. 3. Antenna according to claim 1 or 2, characterized in that the pivoting mounting of the radian is provided to allow adjustment of the angle (A) between the radian and the whip (2) of the antenna over a range from at less than 15 to 1350.   4. Antenna according to claim 2 or 3, characterized in that it comprises eight radians (6), regularly spaced.   5. Antenna according to one of the preceding claims,   characterized in that the angles of inclination between each radian (6) and the whip (2) of the antenna are equal.   6. Antenna according to one of the preceding claims,   characterized by the fact that it comprises, a control means (C) capable of acting simultaneously and in the same way on the inclinations of all the radians (6) of   the antenna relative to the whip (2).   7. Antenna according to one of the preceding claims,   characterized in that each radian (6) is pivotally mounted around a pivot axis (10) orthogonal to the whip (2) of the antenna and radially spaced from it, and the control means (C) is intended to modify the inclination of the radians by vertical displacement of an element (11) coaxial with the whip (2) of the antenna and connected to each radian (6), in particular connected to an extension (8) of this radian radially inward relative to the pivot axis (10).   8. Antenna according to claim 7, characterized in that the control means (C) comprises a motor (14) driving an eccentric which actuates a main control rod (17) acting on the element constituted by a slide (11 ) vertical cylindrical, coaxial with the whip (2), to which are connected rods (12) which transmit, by means (13) compensators of elongation and shortening, the movement to control rods (8) for radians.   9. Antenna according to one of the preceding claims,   characterized in that each radian (6) consists of a rod (7), in particular of aluminum, of round section fixed in a removable manner on a control rod (8) pivotally mounted about a pivot axis ( 10) orthogonal to the whip of the antenna, this pivot axis (10) being supported by the wall of a housing (9) traversed substantially radially by the control rod (8), this housing (9) being located at the bottom of the antenna whip (2).