Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04B—TRANSMISSION
  • H04B7/00—Radio transmission systems, i.e. using radiation field
  • H04B7/02—Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W16/00—Network planning, e.g. coverage or traffic planning tools; Network deployment, e.g. resource partitioning or cells structures
  • H04W16/18—Network planning tools

Definitions

• the present invention relates to the broadcasting of synchronized radio waves in a frequency band covering a predetermined territory by means of a network of adaptive transmit antennas.
• a new transmission antenna technology is needed for the partial or total coverage of a predetermined territory such as a country using a single frequency or a single group of frequencies per radio broadcasting service in a given frequency band.
• a method for transmitting radio waves synchronized in at least one frequency band by several antennas respectively to coverage areas in which receivers measure characteristics of the transmitted waves comprises the steps following: transmit the measured characteristics from the receivers to a central processing device, analyze the received characteristics in the central processing device according to prediction models on the diffusion of the waves in the coverage areas to determine adjustment parameters for the antennas, transmit the setting parameters determined from the central server to the antennas, and control the antennas according to the setting parameters. Broadcasting of radio waves is provided by transmission antennas connected to a central processing device which transmits to them control parameters such as variable quantities of radiation pattern so as to guarantee an optimal radio coverage over a predetermined territory gathering the areas of coverage.
• the transmitting antennas according to the invention are ground-wave antennas and / or ionospheric-firing antennas and / or space-wave antennas and are adaptable in real time in order to favor wave propagation modes. transmitted in different frequency bands and / or disadvantage other propagation modes of waves emitted in different frequency bands.
• the synchronized wave diffusion in a frequency band according to the invention provides for an advantageous reorganization of the radio spectrum by optimizing the frequency resource available in the different frequency bands.
• the wave diffusion according to the invention allows an advantageous deployment of transmitting antennas according to which low power antennas are installed near agglomerations more easily respecting the electromagnetic compatibility constraints.
• the adjustment parameters are determined in order to minimize the impact of interference by external signals on the coverage areas and to minimize interference by the waves emitted by the antennas to areas other than the areas of coverage, particularly in border areas of coverage areas.
• adjustment parameters can be related to directivity and transmission power of the antennas and / or a change of mode of propagation of the transmitted waves.
• the emission of radio waves according to the invention respects interference levels outside the predetermined territory and makes it possible to use forbidden frequencies reserved for other countries.
• the emission is provided by ground antennas during the day and supplemented by ionospheric antennas during the night.
• the invention also relates to an antenna system for transmitting synchronized radio waves in at least one frequency band respectively to coverage areas in which receivers measure characteristics of the transmitted waves.
• the system is characterized by comprising a central processing device for analyzing the measured characteristics transmitted from the receivers according to wave diffusion prediction models to determine tuning parameters for the antennas, and for transmitting the Setting parameters determined by the antennas, in order to control the antennas according to the received settings.
• the invention relates to a computer program adapted to be implemented in a central processing device to an antenna system for transmitting synchronized radio waves in at least one frequency band respectively to coverage areas.
• receivers measure characteristics of the waves emitted.
• the program is characterized in that it includes instructions which, when the program is loaded and executed on said processing device, perform the steps of: analyzing the measured characteristics transmitted from the receivers according to prediction models on the broadcast of the waves in the coverage areas to determine setting parameters for the antennas, and transmit the determined setting parameters to the antennas in order to control the antennas according to the setting parameters.
• FIG. 1 is a schematic vertical front view of a ground wave transmission antenna
• FIG. 2 is a diagrammatic vertical front view of a ground wave directive transmission antenna of the "hot guy” type
• FIG. 3 is a schematic vertical front view of a ground wave emission antenna of the "anti-fading" type
• FIG. 4 is a schematic vertical front view of an emission antenna of the "horizontal doublet" type close to the ground with ionospheric firing;
• FIG. 5 is a schematic vertical front view of a vertical and variable ionospheric vertical doublet emission antenna
• FIG. 6 is a schematic vertical front view of a vertical helical type "helix" emission antenna
• FIG. 7 is a diagrammatic vertical front view of an antenna of emission type "pylon" on the ground or elevated with omnidirectional variable ionospheric firing;
• FIG. 8 is a diagrammatic vertical front view of a set of transmitting antennas of the "pylon" type on the ground or elevated with switchable directed ionospheric firing;
• FIG. 9 is a schematic vertical front view of a transmission antenna of the "long horizontal wire” type close to the ground, also called “beverage”, with directed ionospheric firing;
• FIG. 10 is a diagram of medium wave propagation in ionospheric layers
• FIG. 11 is a schematic block diagram of a broadcasting system comprising a network of adaptive transmission antennas according to the invention.
• FIG. 12 is an algorithm of a transmission method according to the invention.
• Radio wave transmitting antennas have a particular architecture for transmitting radio waves in a preferred propagation mode and have specific adjustment parameters to be modified for adaptation to the propagation conditions of the transmitted waves.
• each transmitting antenna is considered to be associated with a transmitter and a control unit in particular for interpreting adjustment parameters.
• the following terminology is used in the following description.
• An emission antenna radiates so-called “short” waves when the antenna radiates with a useful wavelength ⁇ substantially decametric.
• An emission antenna radiates so-called “average” waves when the antenna radiates with a useful wavelength ⁇ substantially hectometric.
• An emission antenna radiates so-called “long” waves when the antenna radiates with a useful wavelength ⁇ substantially Telec.
• the wavelength ⁇ corresponds to the central frequency of the frequency band in which waves are to be transmitted by the antenna.
• a ground wave transmission antenna AS1 radiates medium or long waves and essentially comprises a substantially horizontal metal mass plane near and under the ground surface, an open metal excitation loop or closed substantially horizontal, and a metallic connecting element, substantially vertical, connecting the excitation loop to the ground plane.
• the excitation loop extends substantially horizontally above the ground surface.
• the ASl antenna emits essentially omnidirectional ground waves and few ionospheric waves.
• the antenna AS1 is preferably used to radiate low power medium waves at the agglomeration periphery, because of its discretion in the landscape and its compliance with electromagnetic compatibility problems.
• the setting parameter to be modified is preferably the transmission power.
• an AS2 ground wave directive transmission antenna called a "hot guy” radiates medium or long waves and essentially comprises a vertical pylon associated with an active stay, connected to a substantially wired metallic ground plane. Horizon.
• the transmitting antenna AS2 emits essentially ground waves with an adjustable directivity.
• the wired metal ground plane is composed of copper wires arranged on approximately 30 to 120 radii around the antenna, of a length close to one quarter wave. Copper wires are buried in the soil at a depth of about 30 cm to about 60 cm from the soil surface.
• the value of a reactance, self or capacity, at the foot of the active stay and the position of attachment of the stay to the ground, or in other words the angle formed between the stay and the tower, determine the axis of emission of the radiation pattern and directivity of the ground wave. For example, the change in the value of the reactance makes it possible to switch from an omnidirectional diffusion during the night to a diffusion with a forward / backward ratio of 25 dB during the day.
• an AS3 ground wave transmission antenna radiates medium or long waves and essentially comprises a vertical pylon connected to a substantially horizontal wire mass plane.
• the AS3 antenna radiates only ground waves omnidirectionally.
• the wired metal ground plane is composed of copper wires arranged on 30 to 120 radii around the antenna, with a length close to one-quarter wave. Copper wires are buried in the soil at a depth between 30 and 60 cm from the soil surface.
• This antenna has a radiation pattern pinched to the ground and diffuses no waves to the sensitive ionospheric layers.
• the anti-fading AS3 antenna is used to radiate high-power ground waves with a far-reaching range, without fading during the night.
• Figures 4 to 9 illustrate ionospheric emission transmit antennas which radiate short, medium or long waves, that is to say with a useful wavelength ⁇ substantially decametric, hectometric or kilometer.
• An angle of fire from the horizontal determines the range, which varies from 100 km to 2000 km. For example, for an angle of fire greater than 60 °, the range does not exceed 150 km, and for a firing angle at 40 °, the range is about 250 km.
• Ionospheric firing antennas emit little or no ground waves and the area covered takes an annular or elliptical shape which is wider as the firing angle is small.
• a polarization-switchable ionospheric emission antenna ATI1 essentially comprises a substantially horizontal metallic mass plane, a substantially horizontal metallic luster with switchable central reactance represented by a black rectangle, and a metal monopole, substantially vertical, connecting the metal doublet to the ground plane.
• the ATIl antenna radiates waves to the ionosphere with vertical directivity and little ground waves.
• the metal doublet extends substantially horizontally above the ground surface at an adjustable height equal to about one-tenth of the wavelength ⁇ relative to the ground plane, in order to promote vertical incidence emission according to a wide lobe and thus modify the coverage area provided by the antenna ATIl.
• the metal monopoly provides wide vertical incidence ionospheric emission and radiates near ground waves. The coverage area is then bi-localized.
• an ionospheric emission antenna ATI2 essentially comprises a substantially horizontal metal mass plane, a substantially horizontal metallic lobe with switchable central reactance represented by a black rectangle, and two substantially vertical metal pylons supporting the metal doublet above the ground plane.
• the ATI2 antenna radiates only waves to the ionosphere with adjustable directivity.
• an ionospheric emission antenna ATI3 essentially comprises a metal helix extending substantially vertically and positioned above a substantially horizontal metal mass plane.
• the antenna ATI3 radiates circularly polarized waves towards the ionosphere with a substantially vertical directivity.
• the radiation pattern of the antenna depends on the height of the helix. For example, when the height of the helix is small, the radiation pattern has a broad lobe directivity similar to the ionospheric ATI1 antenna with the metal doublet according to FIG. helix is large, the lobe characterizing the directivity of the antenna is narrow.
• the antenna ATI3 serves a local coverage area of annular and narrow form.
• an ionospheric emission antenna ATI4 essentially comprises a vertical pylon positioned above a substantially horizontal metal ground plane.
• the ATI4 antenna radiates waves to the ionosphere with adjustable directivity and few ground waves.
• the vertical pylon contains a reactance, represented by a black rectangle, the variable value of which directs the radiation pattern of the antenna according to an omnidirectional emission directed at confined oblique incidence. No wave emission with vertical incidence is possible.
• the radiation pattern of the antenna ATI4 may have several distinct lobes according to different incidences, in order to serve different ring-shaped coverage areas.
• ATI4 ionospheric emission antennas are arranged sufficiently close to one another to modify a phase and / or power distribution in order to favor an oblique incidence directed wave emission.
• the antenna array ATI4 has a directionally adaptive radiation pattern to serve a particular coverage area with high gain, especially at the inner edge of a predetermined territory. .
• an ATI5 ionospheric firing antenna called “beverage” radiates short, medium or long waves with a useful wavelength ⁇ that is substantially metric, hectometric or kilometer and essentially comprises a substantially horizontal metallic ground plane. in the ground, a long wire extending substantially horizontally and close to the ground, a generator connecting one end of the wire to the ground plane and a load connecting the other end of the wire to the ground plane.
• the ATI5 antenna radiates progressive waves to the ionosphere with adjustable directivity and few short waves of ground.
• the ATI5 antenna has a radiation pattern with a narrow lobe at oblique incidence.
• the wire extends substantially horizontally above the ground surface at a height of about 3 or 4 meters for shortwave emission, generally with a length between 3x ⁇ and 8x ⁇ .
• the variation of the length of the wire modifies the emission range of the antenna.
• the ATI5 antenna serves remote coverage areas and corresponding to precise and specific locations such as islands or cities.
• ground antennas and the ionospheric firing antennas are designated indifferently by AS and ATI respectively.
• Space wave transmission antennas AE are used for the diffusion of short waves to agglomerations for example. Wave propagation is done in a "point-to-point" mode, in line of sight with the area to be served.
• a space wave antenna is generally disposed on an eminence and directed to the area to be served.
• the modulation of the directivity of space wave antennas is for example mechanical using a rotor or electric phase shift.
• the directivity is inclined to reduce the emission of parasitic waves by these antennas in the ionosphere.
• a space wave antenna is for example composed of several aerials such as a log-periodic antenna, a Yagi antenna or a panel antenna, arranged to emit in different directions.
• the space wave antenna may also emit omnidirectionally in a discoidal area centered on the antenna.
• Figure 10 is a schematic view of the propagation of medium waves in layers of the ionosphere.
• solar radiation especially ultraviolet radiation, ionizes gas particles that release electrons into the ionosphere.
• the density of free electrons increases with the altitude in the ionosphere which breaks down into three main layers D, E and F.
• Altitudes given below by way of example, vary considerably according to the day and the night, the season and the activity of the sun generating particular sunspots variables.
• the D layer is the lowest and reaches altitudes of between 50 and 70 km approximately.
• Layer D occurs during the day, but contains air whose density is high enough that ions and free electrons recombine and absorb the mid-waves. From the beginning of the night, the D layer has a concentration of free electrons rapidly decreasing and disappears, passing the average waves towards the layers E and F.
• the E layer reaches altitudes of between 70 and 150 km approximately. During the night, the concentration of the free electrons drops rapidly as for the layer D, but the layer E does not disappear completely.
• the layer F reaches altitudes of between 150 and 300 km approximately. Since the density of air at these altitudes is very low, free ions and electrons recombine only partially and the F layer remains ionized overnight.
• the radio waves that are emitted to the ionosphere undergo attenuation in the D-layer, which varies with the inverse of the square of the radio wave frequency.
• the low frequency radio waves reach the E and F layers only during the night when the D layer disappears.
• Waves radio frequencies are increasingly refracted as a function of altitude in the E and F layers of the ionosphere, where the density of free electrons increases with altitude.
• the refraction becomes sufficient to influence the trajectory of the propagation of radio waves towards the ground; therefore, layers E and F backscatter the radio waves.
• Radio waves are reflected in the ionosphere as a function of the angle of incidence and the frequency band in which the radio waves are emitted.
• radio waves which are transmitted in a high frequency band with a low angle of incidence relative to the horizontal, are reflected at high altitude from the layer F to reach a coverage area, so-called night zone, far from the emission point EM of the radio wave.
• the distance separating the reception point R from the emission point EM of the radio wave varies between 500 and 1500 km approximately.
• Soil waves emitted by a ground antenna have a trajectory that follows the curvature of the Earth, since induced currents on the ground surface cause an inclination of the wavefront of the radio waves.
• the ground wave generated by a ground antenna is guided by a strip of earth as a result of multiple reflections on the separation surface between the dielectric formed by the earth and the external environment constituted by the air and on a buried metal surface constituted by the ground plane of the antenna.
• a An antenna radiating ground waves serves a coverage area, called diurnal zone, about 150 km wide, for example.
• the layer D disappears and the radio waves emitted towards the ionosphere reach a coverage area at least 500 km away, for example from the emission point EM of the radio waves.
• the ground antennas have a limited range, equal to 150 km for example.
• the silence zone is for example between 150 km and 500 km.
• radio waves emitted by ionospheric antennas can reach a coverage area served by a ground antenna transmitting the same radio waves. This results in a fading zone, where waves of the same frequency are received with a phase shift resulting in destructive interference which degrades the reception quality of the radio waves.
• the broadcasting system comprises a central server SC, a database BD in connection with the central server SC, at least one ground antenna AS, at least one ionospheric firing antenna ATI at least one AE wave antenna, RQ quality receivers and RB interference receivers.
• the central server SC communicates with the antennas and the receivers via a telecommunications network RT of the internet type, or variant by specialized telecommunication lines.
• the central server provides a central processing device to the antenna system for analyzing data, such as measured wave characteristics CO, and determining antenna tuning parameters, as will be discussed hereinafter.
• the database BD is linked to the central server SC, that is to say it is either integrated in the central server SC, or incorporated in a database management server and connected to the central server by a local link or remote.
• the database BD notably includes adjustment parameters relating to propagation modes for each transmission site, that is to say relating to each transmitting antenna, and coefficients specific to each site according to different dates.
• the adjustment parameters and coefficients are defined according to the propagation modes so as to substantially maintain predetermined local or global coverage areas.
• the antennas serve respective coverage areas whose meeting serves a global coverage area corresponding, for example, to a predetermined territory TP, while minimizing the silence zones where few radio waves are received.
• receivers of quality RQ are arranged to evaluate the reception quality of the radio waves emitted by the different transmit antennas AS, ATI, AE.
• RB interference receivers to check whether radio broadcasting services specific to other territories, such as countries, adjacent to the TP territory are scrambled by the radio waves emitted by the different antennas AS, ATI, AE.
• RB receivers are used only when starting a radio broadcast service or when detecting interference.
• the receivers RQ and RB measure CO wave characteristics relating to the reception of the waves emitted by the antennas AS, ATI, AE and representative of the quality of the waves received, such as powers, impulse responses and signal-to-noise ratios. .
• the received wave characteristics CO are transmitted to the central server SC via the telecommunications network RT.
• Each receiver RQ, RB comprises, in addition to a receiving antenna and reception stages, software and hardware means for measuring the CO characteristics and transmitting them to the SC server.
• these software and hardware means are in the form of an IP (Internet Protocol) server transmitting data, including the measured characteristics CO in the form of IP packets according to the Transport Control Protocol (TCP).
• IP Internet Protocol
• broadcasters In order to broadcast programs throughout the predetermined territory TP, broadcasters emit short and / or medium and / or long waves in respective frequency bands. Moreover, the waves are emitted according to different modes of propagation relative to the different antennas AS, ATI, AE.
• a single omni-directional central antenna AS generates average ground waves in order to cover a circular zone partially or totally encompassing the predetermined territory TP during the day.
• the average ground waves generated by the central antenna AS have their power decreasing, and cover a narrower circular zone; several AS directive antennas located on the periphery of the predetermined territory TP are then activated in a synchronized manner to cover areas not served by the central antenna.
• the central antenna AS is of the "anti-fading" type and the peripheral antennas AS comprise a metal ground plane, like that represented in FIG. 1.
• the central antenna can be a microwave antenna. ATI ionospheric shot generating short waves.
• AS and / or ATI directional antennas situated on the periphery of the predetermined territory TP generate medium or long waves of ground synchronously in order to cover the predetermined territory TP.
• the antennas AS are of the type of the antenna "hot guy" AS2.
• AS directional antennas located on the periphery of the predetermined territory TP and generating medium or long waves are synchronously activated in order to cover the predetermined territory TP.
• the antennas AS are of the type of the "hot guy” antenna AS2 and are arranged on islands or platforms. maritime forms in order to benefit from the good conditions of propagation on the sea.
• directional or omnidirectional antennas AE generate short space waves and are regularly distributed over the predetermined territory TP to serve respective local coverage areas distinct from each other. These antennas are activated synchronously to cover the predetermined territory TP.
• AE antennas are of "cosecant" type without emission of waves above the horizon in order to limit interference phenomena due to waves emitted above the horizon and reflected by the ionosphere.
• the reception of waves transmitted in a given frequency band relating to a radio program may be scrambled by the reception of other waves transmitted in the same frequency band but relating to at least another radio program.
• These interference phenomena occur mainly during the night due to the propagation of interference waves in the ionosphere, said interference waves being scattered far from their emission sites and received in areas where other waves are also received and interfere with said scrambling waves. Consequently, the electromagnetic field relating to waves is locally reinforced in certain zones by the propagation of ionospheric, ground or space waves emitted by other antennas of the network of the invention in order to minimize in the interference the contribution ionospheric waves emitted from other countries, for example.
• a large number of transmission antennas making up the network provide a propagation diversity and a medium reception level in order to limit disturbances related to large variations in the behavior of the ionosphere and in particular the interference phenomena caused by the propagation of ionospheric waves.
• the transmission method comprises steps E1 to E8 executed automatically in the broadcasting system.
• Adjustment parameters relating to propagation modes for each transmitting antenna are stored in the database BD.
• the adjustment parameters concern, in particular, directivity, transmission power, polarization and antenna gain, and are to be estimated regularly to serve predetermined coverage areas.
• the database BD also contains data such as geographical, geological and topographical information relating to the predetermined territory TP and information on the implantation of agglomerations. Other data concern weather forecasts and forecasts on the behavior of the ionosphere which depend in particular on the solar activity according to the season, the time of day and the geographical place for example. According to the different information previously mentioned, time stamp data define coefficients specific to each transmission site according to different dates and make it possible to establish local or global coverage areas according to the propagation modes.
• the setting parameters and the timestamping data are associated with antenna switching scenarios intended to respect interference levels outside the predetermined territory TP and to guarantee a quality of reception of the radio broadcast services broadcast in the predetermined territory TP.
• the scenarios are progressively modified according to measured characteristics of waves received in order to establish prediction models on the diffusion of the waves in the predetermined territory according to the modes of propagation.
• the central server SC selects a frequency band comprising all the frequencies associated with respective radio broadcast services transmitted on waves having substantially equal useful wavelengths.
• a frequency band comprising all the frequencies associated with respective radio broadcast services transmitted on waves having substantially equal useful wavelengths.
• three frequency bands are provided, including the short waveband, the medium waveband and the long waveband respectively corresponding to frequencies associated with short waves, medium waves and long waves.
• the central server SC selects a propagation mode compatible with the selected frequency band in order to perform tests on the quality of a signal received in and out of the predetermined territory TP, the received signal being relative to the selected propagation mode.
• a single frequency associated with a radio broadcast service is selected to perform tests on the quality of a signal carried by waves transmitted at that frequency.
• different modes of propagation and modulation (coding) are selected in order to perform the quality tests simultaneously.
• the central server SC selects RQ quality receivers arranged in the predetermined territory TP and RB interference receivers disposed outside the predetermined territory TP, according to the selected propagation mode.
• the selected receivers are activated, for example automatically by the SC server via the network RT, and are able to pick up waves emitted by antennas specific to the selected propagation mode.
• the receivers measure CO characteristics of the transmitted waves.
• the characteristics are received powers, impulse responses and signal-to-noise ratios.
• receivers of quality RQ compare received powers relating to the waves emitted by the antennas AS, ATI, AE of the broadcasting system to predetermined power thresholds in the coverage areas in order to control whether a received power relative to a radio broadcasting service specific to the predetermined territory is sufficient according to reception quality criteria. For example, during the night in particular, the quality of reception of a radio broadcasting service is reduced by the jamming caused by the propagation of ionospheric waves emitted from other countries and the received power relating to the radio broadcast service must be sufficiently high to counter the interference.
• RQ quality receivers also perform direction finding measurements and evaluate bit error rates for received digital signals.
• interference receivers RB compare received powers relating to the waves transmitted by the antennas AS, ATI, AE of the broadcasting system to received powers relating to other waves transmitted from different territories adjacent to the coverage areas, to check whether radio broadcasting services specific to adjacent territories are interfered with by the radio waves emitted by one or more of the different antennas AS, ATI, AE.
• the RB interference receivers can identify the antennas causing external interference and also perform direction finding measurements.
• the receivers RQ and RB transmit the measured characteristics CO to the central server SC.
• the characteristics are transmitted in the form of IP packets via the network RT, or by email or by fax, and are interpreted for example by technicians attached to the central server SC.
• the characteristics can be transmitted at predetermined times, in particular corresponding to sunrise and sunset times, for example.
• the central server SC then stores the received characteristics CO in the database BD in order to enrich a detailed history of the characteristics of the waves received by the antennas AS, ATI, AE.
• the history is necessary for the establishment of wave propagation prediction models.
• all the receivers RQ, RB are activated simultaneously in order to carry out measurements without discontinuity and to constantly enrich the database BD.
• all the characteristics received are sorted according to the receivers and the propagation modes.
• step E5 the central server SC analyzes the received wave characteristics CO as a function of the information included in the database BD, in particular according to the prediction models on the wave diffusion.
• the central server analyzes in particular the received powers and the comparison results between the received powers and the predetermined power thresholds.
• the central server SC performs the various comparisons relating to the powers of the waves emitted by the antennas of the broadcasting system after reception of the CO characteristics transmitted by the receivers.
• the central server compares received powers relating to the waves emitted by the antennas of the broadcasting system to predetermined power thresholds in the coverage areas and to received powers relating to other waves emitted from different bordering border territories. outside the predetermined territory.
• the central server SC identifies tunable antennas associated with propagation modes, when quality criteria are not respected. For example, when the global reception of a signal in the predetermined territory TP is too weak during the day or is scrambled during the night, the central antenna AS type "hot guy" according to the so-called "central" propagation mode is identified.
• the central server compares the received characteristics CO with characteristics estimated by the wave diffusion prediction models in order to evaluate antenna tuning parameters complying with quality criteria and possibly modify antenna switching scenarios.
• the central server SC determines antenna tuning parameters PR to be transmitted to the antennas based on the analyzes of the received characteristics CO.
• the setting parameters PR are specific to each antenna according to the associated propagation mode. At least one setting parameter among the following is to be transmitted to each of the identified antennas: the power, the frequency and the polarization of the waves emitted, the position, the orientation and the height of the antenna, and the inclination and the switching of the directivity of the antenna.
• the analyzes of the characteristics received CO can lead to a change of mode of propagation and thus to a change of the setting parameters so as to deactivate certain antennas and to adjust other antennas again.
• the adjustment parameters PR of the antennas are determined in particular to adapt the selected propagation mode to the distribution of the different coverage areas in order to optimize the reception quality of a signal and the overall coverage of the predetermined territory TP.
• the PR setting parameters must satisfy the desired reception conditions in the coverage areas and in the outer areas possibly scrambled, that is to say minimize interference both in the predetermined territory TP and in neighboring countries or any area other than the coverage areas of the predetermined territory TP.
• the central server modifies the directivity and increases the transmission power for the central antenna AS to ensure reception quality in the predetermined territory TP.
• the central server reduces the transmission power for the central antenna AS and activates several directional antennas AS on the periphery. of the predetermined territory TP and directed towards it, or activates several short-range space-wave AE omnidirectional antennas located on the periphery of the predetermined territory TP.
• AS ground antennas When the reception of ground waves emitted by AS ground antennas is interfered with in an agglomeration during the night, other directional or omnidirectional AS ground antennas may be activated locally to counter interference.
• short space waves are scattered within an agglomeration and average waves of ground or space are scattered outside the agglomeration. Outside the agglomeration, the power of the short space waves becomes too weak to satisfy the quality of reception and the medium waves are unsuitable for the implantation of the agglomeration.
• the central server SC determines a peripheral zone of the agglomeration from which the average waves of soil or space must be emitted.
• digital receivers can switch quickly and automatically from the short waveband to the medium waveband, or vice versa, to receive the same radio broadcast service on the best available frequency.
• the central server SC analyzes the history of the previously transmitted setting parameters. If the reception of medium and / or long waves in a part of the predetermined territory TP remains scrambled despite an increase in transmission power of the medium and / or long waves, space wave antennas AE may be activated to transmit short wave whose reception is not scrambled in said part of the predetermined territory.
• step E7 the central server SC transmits the determined adjustment parameters PR to the previously identified antennas.
• setting parameters PR determined for a transmitting antenna are included in IP packets transmitted via the network RT and are automatically interpreted by a control unit connected to the transmitting antenna and acting as a client for the transmission antenna. SC server for remote control of the antenna.
• the adjustment parameters PR are transmitted by email or by fax and are interpreted by technicians controlling the transmission sites attached to the antennas.
• step E8 emission characteristics of the antennas are controlled mechanically and / or electronically by their control units as a function of the transmitted control parameters PR.
• transmission characteristics the transmission power and / or the modulation (coding) relating to one of the transmission antennas AS, ATI, AE are automatically adjusted by the control unit connected to the antenna, and the radiation pattern of another transmitting antenna is set manually by a technician according to transmitted control parameters such as a phase shift and a variation of the orientation of the antenna.
• Steps E1 through E8 are performed periodically to update the database BD of the central server SC and improve the prediction models on the broadcast of the waves.
• the regular update of the database allows a combination of the different propagation modes used in the transmission antenna system in order to constantly offer an optimal reception quality over the predetermined territory and a lack of interference outside the predetermined territory.
• the invention described herein relates to a method and an SC server for transmitting synchronized radio waves in at least one frequency band respectively to coverage areas.
• the steps of the method of the invention are determined by the instructions of a computer program incorporated into a computing device such as the central server SC.
• the program includes program instructions which, when said program is loaded and executed in the device whose operation is then controlled by the execution of the program, carry out the steps of the method according to the invention.
• the invention also applies to a computer program, including a computer program on or in an information carrier, adapted to implement the invention.

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