FR2842949A1 - ECONOMIC METHOD AND DEVICE FOR EASILY ORIENTATING A SATELLITE OR TERRESTRIAL TELEVISION ANTENNA. - Google Patents

Abstract

Economic method and device making it possible to easily orient a satellite or terrestrial television antenna. The problem was to find an antenna pointing method which was precise, economical, not very constraining independent of the time and insensitive to atmospheric conditions. the invention uses the antenna (1) to capture and amplify the solar electromagnetic radiation received by a processing device (9) and signaling (5) allowing to recover an absolute reference of azimuth and elevation. We then use the electromagnetic radiation (12) of the targeted transmitter (13) to refine the setting of the antenna (1). The signaling device (5) makes it possible to have, near the place of installation of the antenna (1), any useful information (11) sent by the decoder (9) on the coaxial cable (6).

Description

The present invention relates to an economical method and device

  for easy orientation of an antenna

  satellite or terrestrial television.

  For the sake of simplification, the generic term "antenna" in the text below will denote both a dish and a VHF or UHF receiving antenna, and the term "transmitter"

  will designate a UHF or VHF satellite or terrestrial transmitter.

  The setting of an antenna on the desired transmitter is not

  easy thing without pointing aid device.

  Indeed, if the antenna is electrically connected to a decoder, itself connected to a television, which make it possible to "visualize" the received HF signal, and therefore to have an idea of the pointing level, these latter devices cannot generally not be installed, even temporarily, near said antenna, conventionally installed on a roof. And portable equipment to ensure that the correct transmitter is correctly pointed at the antenna is, by its price, reserved for professional installers: it must in fact include a demodulator, particularly expensive in technology

digital.

  Admittedly, there are inexpensive consumer devices for assisting with the precise pointing of a chosen satellite, which

  can be used on the dish itself and without assistance.

  We know for example the existence of devices capable of measuring the overall power at the output of the HF head. They plug into the Type F socket at the output of said HF head, also called LNB in English, and emit a signal depending on the

HF power level received.

  These devices are good for pointing a satellite, but not necessarily the right one: the possible "distance" in azimuth between

  two satellites can indeed be of the order of a degree.

  We also know patent application FR02 02993, from one of the present inventors, who teaches a pointing method using the reflection of the light rays of the sun on the plate of the -2 dish, towards the HF head. The underlying principles are that the sun passes at a very precise hour of the day vertically from the desired satellite, and that the geometry defects of the parabola (in particular in azimuth) produce the same aiming error with the light rays as 'with electromagnetic waves. This pointing process therefore allows very precise adjustment of said azimuth, without the risk of being mistaken for the satellite, or of being slightly offset, which could generate interference due to

to neighboring satellites.

  The less critical elevation setting (no other vertical satellites) simply uses the mechanism that

equips the antenna.

  The method has three weaknesses, however.

  First of all it requires seeing the sun sufficiently: it is therefore enough that it is hidden by a cloud at the fateful hour for the adjustment to be impossible, therefore postponed to a later day! A workaround provided for in the aforementioned patent is to point the sun at any time as soon as the sun appears, for example, and use the pointing as an azimuth reference; we then rotate the antenna by an angle

  given, to point to the target satellite.

  We then arrive at the second weakness of the process: Turning by hand a collar tightened to a vertical mast generates an uncontrollable error on the final azimuth, without being able to adjust the antenna subsequently. This problem would not be one if we had at this new azimuth a means of pointing control, which is unfortunately not provided for in the patent, and that would increase the

price of the final device.

  Third weakness, even if the weather is good, it may seem constraining to have to wait for a particular hour to adjust your dish, and if you want to adjust it to an hour

  different, we fall back into the previous problem.

  -3 Having said that, the pointing process taught in the patent

  FR0202993 is a good description of the current state of the art,

  concerning the easy pointing of satellites using the position of the sun at a given moment as a reference for azimuth and elevation. Knowledge of said process is useful for the correct

  understanding of the invention described in this text.

  The problem is therefore to develop an antenna pointing process that is precise, economical, not very restrictive, independent of the time and insensitive to conditions

weather.

  A solution to this multifaceted problem is the antenna pointing method according to the invention, as well as any specific device allowing the implementation of such a method. Concerning the problem of clouds hampering the implementation of the method described in the patent application FR02 02993 mentioned above, an analysis of solar radiation reveals that the latter also emits electromagnetic signals in the invisible domain, and this, even at frequencies also lower than the UHF or even VHF satellite or radio frequency bands or even lower. Admittedly, the powers involved are considerably lower than the available light power, and require good HF detection equipment, a priori more expensive than a simple light detector, but these electromagnetic waves are both attenuated and little diffracted by the clouds, therefore favor a localization of the sun which

  whatever the weather.

  A direct setting at a time fixed in advance using said HF signal detector will therefore be possible in any season,

in all latitudes.

  In the case of an indirect adjustment (pointing the sun at any time and posterior adjustment of the azimuth) the same HF signal detector can be used to precisely point the sun as a reference and then to refine the final relative position -4 of l antenna towards the target transmitter, after manual rotation. Still, an HF detector is more expensive than a light detector. As a decoder always contains a good quality tuner and demodulator, according to the method according to the invention, we can get around this last problem by using, as far as possible, the HF power detector that the tuner can constitute (possibly coupled to a demodulator capable of measuring the power at its input) and the qualitative HF signal analyzer that the demodulator can constitute (especially if it can demodulate both digital and analog modulations) Otherwise, still according to the invention, may choose to detect electromagnetic power at frequencies lower or higher than those for which the antenna is designed: the sun actually emits in a very wide frequency band. This method according to the invention makes it possible to produce an electronic device at low cost (particularly for lower frequencies); certainly it will probably be more subject to various electromagnetic disturbances, but these disturbances will be avoidable if the weather is clear or, at worst, allows you to see the horizon: we can then certainly seek the sun ... in the sky. In a particular embodiment of the device according to the invention, the latter could be directly integrated into the HF head of the parabola; this device would include an electromagnetic radiation detector operating at frequencies radiated by the sun but outside the usual bandwidth of satellites, and

  would therefore make it possible to discriminate the source of the radiation.

  By domestic decoder, in the present text, and

  including the claims, any digital satellite decoder or

  analog, any digital terrestrial television decoder, any internal or external computer peripheral capable of receiving satellite or terrestrial broadcasts or any television set (used not as a simple monitor, but also as a

decoder).

  -5 By decoder in the present text is meant any device for receiving television, radio or data stream signals, including, without limitation, any household decoder as defined above, as well as more generally any device comprising a tuner and a demodulator. It is noted that, according to the invention, the electromagnetic radiation from the sun, seen by certain satellite operators as an annoying source of noise, becomes a powerful means

  guidance not requiring any specific expensive material.

  In a particular mode of the method for pointing transmitters according to the invention, it is possible for example to use solar radiation in frequencies close to 10 GHz, which, concentrated by a satellite dish, generate at the input -and therefore at the output of the HF head a power level much higher than the noise of the latter; we can then, according to the method according to the invention, firstly point the sun at a given time - by measuring for example a maximum noise output from the HF head, around 2GHz - and therefore easily adjust the azimuth of a satellite antenna. The method according to the invention also provides that it is possible to directly measure the electromagnetic energy concentrated near the focus of said parabola, without necessarily using the HF head. In this particular way of pointing the sun, we can use a range

  much wider frequencies to point the sun.

  Obviously, it will be possible, still according to the method according to the invention, to use solar electromagnetic radiation at other frequencies to point any antenna (in the broad sense defined at the beginning of the text) towards the sun, in order to lock onto the azimuth and / or the elevation of the latter. According to the method according to the invention, the check-in time can be determined in advance, in order to directly recover the azimuth or the exact elevation of the target transmitter, or recorded at any time, in order to recover a precise reference of azimuth, elevation, or both. The user can in these cases there, still according to the method according to the invention, target the chosen transmitter by moving its antenna by a known angle in azimuth, in elevation or both; -6 it may possibly, still according to the invention, use the transmitters being "on the way" from the sun to the chosen transmitter to locate itself in its movement, when for example the elevation does not vary too much, counting the transmitters detected during the azimuth rotation of its antenna for example. Finally, still according to the method according to the invention, it will be able to use electromagnetic radiation, this time from the targeted transmitter, to calibrate with precision on the chosen transmitter. According to the invention, the pointing method may use any device, connected directly or indirectly to the antenna, physically located near or far from it, but sensitive to the electromagnetic radiation picked up by said antenna (before or after the HF head for a satellite antenna), and using for example, but not limited to, a GUNN diode, a PIN diode (HF signal rectification), a fast blocking sampler, a mixer (allowing to lower the working frequency), a true power detector (up to a few MHz), etc. Still according to the invention, it is possible to use a device according to the invention comprising a bandpass filter making it possible to retain only the frequencies not emitted by the targeted transmitters, the local transmitters, or even the sources of electromagnetic noise. This will easily discriminate the radiation caused by the sun from others. For example, but not limited to, the device according to the invention intended for adjusting a satellite dish could amplify a frequency band located at the top of the output satellite frequency band

  from the HF head (beyond 2150 MHz).

  According to the method according to the invention, it is also possible to use a decoder calibrated for example on one of the frequencies used by the chosen transmitter, which will endeavor to demodulate the received electromagnetic "signal" (which may if necessary be noise of 'solar origin): if said signal is reasonably strong, but incomprehensible, the demodulator can signal it, and the installer deduces that it is pointing at the sun, especially if it is trying to aim at it, and said receiver can -7

  demodulate both digital and analog modulations.

  The installer will then know how to reorient his antenna around the transmitter sought; since the decoder can then detect a signal and demodulate it, it can report this fact, and the installer will then know that it is pointing at the desired transmitter. This particular pointing method using a decoder is a possible implementation of the method according to the invention, particularly suitable for times when the sun is made invisible by adverse weather conditions. According to the invention, it will be possible to use the capacity of the decoder to clearly identify the transmitter (for example, according to the invention, without limitation, by extracting the program name from the DVB tables originating from the demodulated MPEG2 frame). The information sent to the installer will enable him to ensure

  the invention that its setting is definitely the right one.

  Still according to the method according to the invention, when the installer points to the sun, the tuner of the decoder can be set on a frequency where it is certain not to find a transmitter (in the direction of the sun), so as not to measure that the electromagnetic power of a solar "signal"; it is noted that if the power measurement is not directly accessible to the software integrated in the decoder, said software will be able to recover the state of the gain controller (AGC in English) which will give a good idea of said power received, especially if it is additionally coupled to a quadratic measurement of the amplitude of the input signals

  in the demodulator (common with digital demodulators).

  Once the sun has been spotted thanks to the tuner, we can, still according to the method according to the invention, set the tuner on the (or one of) the frequency (s) of the targeted transmitter, and move the antenna in the

  common sense until you find the transmitter.

  If necessary, according to the method according to the invention, the time constants of said AGCs will be reduced to the minimum (compatible with essential stability of the control loop) to allow rapid movement of the antenna; MCOs are not initially designed for this type of dynamic operation. In the case where several transmitters using the same frequency are "on the way", as seen previously, we will count them, still according to the invention, to be sure of pointing

in the end the good transmitter.

  We can also, to target the sun, still according to the method according to the invention, perform a statistical analysis of the electromagnetic signal received by the antenna, for example, but in a nonlimiting manner, by analyzing the spectral distribution, which will allow us to conclude whether a transmitter of human origin influences the signals received, or not, and therefore to conclude that the electromagnetic power received is respectively partly due to a human source or to the sun only. Any device implementing this method will be explicitly a device according to the invention. The method according to the invention provides that the user can have at the place of installation of the antenna

  audio, visual, or vibrating information.

  Said information may, according to the invention, be any information making it possible to correctly point the sun and / or the targeted transmitter, including, but not limited to, any information concerning the power or the quality of the received signal, the rate of 'error measured by the decoder, the result of a statistical analysis of the HF signals received, the presumed source of the detected radiation (sun or transmitter), even the name of the demodulated program package or better, the name of the satellite actually pointed. Said information can, according to the invention, be presented in the form of any variable power or frequency signals, all sound signals (by means of a sound generator), all visual signals (by means of a row LED or a flashing LED for example), all partial or full displays, alphanumeric or not (by means of a liquid crystal screen for example), all kinds of mechanical vibrations of intensity or frequency more or less

  strong (by means of an electromagnetic vibrator for example).

  -9 In particular embodiments of a specific device according to the invention making it possible to provide said information at the place of installation of the antenna, said device may include all or part of the measurement and / or qualification means. HF signals, necessary to implement a particular form of the method according to the invention, in particular, but not limited to, all the means seen previously usable for the implementation of the method according to the invention. In particular embodiments of a specific device according to the invention making it possible to provide said information at the place of installation of the antenna, said device which has become "peripheral" to the decoder, may include a mono or bidirectional communication means with the decoder (decoder towards device only or in both directions), allowing to recover the measurements made by the latter, or even to control it remotely so that it performs measurements useful for pointing, first of the sun, then of the target satellite; said means of communication may, according to the invention, and without limitation, use: - the coaxial cable existing between the antenna and the decoder (for example, and without limitation, by signals modulating 22 kHz), - a independent radio link, for example by means of and without limitation of a "PCMCIA" type transmission card inserted in the decoder, - an ultra-sonic link (for example, always without limitation, type signals RS232 modulated at kHz), - a simple video cable drawn between the decoder and said satellite, which could then be just a simple monitor

small television.

  Concretely, a decoder forming part of the device according to the invention will have the hardware and software means (residents - 10 or provided by a plug-in device of the PCMCIA type, smart card, memory card, the list not being exhaustive) to communicate to said audit peripheral (remote unit) all or part of the information allowing the antenna to be pointed towards a particular source of electromagnetic radiation: the measurements made concerning the power of the received signal, its ability to be demodulated, the error rate obtained, or even the satellite name

  actually targeted, the list not being exhaustive.

  In a particular embodiment of a specific device according to the invention, the housing of said device will be connected in series between the antenna and the decoder, along the coaxial cable, in a vampire on the cable (with or without contact, by electrical or electromagnetic connection for example). Where appropriate, all or part of the device according to the invention can be integrated with or in the HF head (also called LNB) in any form whatsoever (for example, in the form of components, of a card or of 'a sub-block, the list not being exhaustive). In the particular case where the antenna will be a parabola, the device according to the invention may, in different embodiments according to the invention, be provided to connect between the HF head and the decoder by suitable electrical plugs, or will have a means of directly recovering electromagnetic signals, allowing it to be placed simply in front of or in place of the HF head, it being understood that in these particular cases, an electrical connection to the coaxial cable will not be

  may not be necessary, according to the invention.

  In a particular embodiment of said device according to the invention, the latter will be supplied by the supply voltage, if any, present on the coaxial cable, coming from the decoder (for example 13V-18V supplying and

  commanding the LNBs present on the satellite dishes).

  In a particular implementation of the method according to the invention, the decoder according to the invention may also communicate acoustic information to the installer through the - 11 loudspeakers of the television. In the absence of a relay box located near the antenna, they will be adjusted for the occasion to a level strong enough to be heard from the top of the roof. According to the invention, certain signals could be spoken (for example, "you are perfectly on satellite X!"). A particular mode of the transmitter pointing method according to the invention, called indirect mode, is illustrated, by way of example

  nonlimiting, by the following description referring to

Figures 1 and 2.

  This mode makes it possible to point the sun (21) at any time of the day to make it the reference in Azimuth and in elevation and to move its antenna (1) towards the position of

  the transmitter (13) relative to the position of this reference.

  Step 1: becoming aware of the position values

  that will have the sun (21) at the time of decision decided.

  When the sun (21) is pointed at any time, it is preferable to know its azimuth and its elevation, at the reception point. Indeed, these data, relating to the North and the horizon, completely characterize the position of an object in

  space and then become the reference position.

  Step 2: effective pointing operation of the sun (21) at

said hour decided.

  Thanks to the calculation means contained in a particular embodiment of the device according to the invention (5), a real indication of the azimuth and elevation values of the sun, depending on the place, the date and the time, may allow the installer (23) to orient the antenna (1) approximately in the direction indicated in order to facilitate attachment of the correct position. Without this, in practice, it is very difficult to vary the two azimuth and elevation parameters simultaneously, especially in visual absence of the target: by time

  covered for example, the sun (21) is invisible to the naked eye.

  Step 3: signal indicating that the correct position has been locked.

  - 12 After processing the information coming from the electromagnetic radiation (22) of the sun (21), the device according to the invention (5) will indicate visually, audibly or by

  vibration the correct position of the antenna (1).

  Step 4: identification of the current position. The installer (23) can then mechanically locate the azimuth and the elevation of his antenna (1) in this reference position before moving it to the final position, in order to keep

  the initial reference position.

  In a particular mode of the process according to the invention, the installer (23) will stick an adhesive strip graduated in degrees (depending on the diameter of the mast), which can be supplied with the device according to the invention, on the mast. The graduation may not be in degrees but simply in millimeters, and the means of calculation used capable of converting according to

diameter of the mast.

  Step 5: reading of the relative position of the transmitter (13).

  The device according to the invention (5) in a particular embodiment, will indicate the deviation in azimuth and the deviation in elevation of the transmitter (13) from the current coordinates

antenna (1).

  Step 6: moving the antenna (1) to the final position. The installer (23) then unlocks the clamping devices located on the mast (8) and on the attachment system (7), and manually moves the antenna (1) by the angles indicated by the device according to the invention ( 5) above. We note that the

  the aforementioned graduated band will assist the azimuth approach.

  Step 7: signal indicating that the correct position has been locked

final.

  The final position is the targeted transmitter (13) which also produces electromagnetic radiation (12) which will be picked up and interpreted by the device according to the invention (5) in order to indicate - 13 visually, audibly or by vibration the correct position of

the transmitter (13).

  It should be noted that the closer the pointing time is to that where the sun (21) passes vertically over the target transmitter (13), the easier the adjustment will be, since the azimuth difference in particular will be small and will generate less error

  displacement relative to the reference.

  This is why another particular mode of the method for pointing transmitters according to the invention, known as direct mode, is proposed, again by way of nonlimiting example; it is described below. Said mode consists in pointing the sun (21) at the exact time

  of its passage vertically from the targeted transmitter (13).

  Stage 1: reading of the time of passage of the sun (21) in

azimuth of the transmitter (13).

  Using a means of determining the time of passage of the sun (21) in azimuth of the targeted transmitter (13), such as that described in patent FR0202993 of one of the present inventors, the installer ( 23) may, depending on its place and date, recover this information. This means can, in a particular implementation of the method according to the invention, and in a particular embodiment of the device according to the invention, be integrated into the decoder (9) in the form of a program

  IT, which can take the form of an "applet".

  Step 2: reading the position in azimuth and elevation,

  that the sun (21) will have at the time of arrival.

  This, again in order to allow the installer (23) to orient the antenna (1) approximately towards the direction

  indicated in case of visual absence of the target.

  Step 3: waiting for the time for the sun to pass (21) in

satellite azimuth (13).

  Step 4: at said precise time, pointing maneuver

number of sun (21).

  - 14 Step 5: signal indicating the correct position by hanging

from the sun (21).

  After processing the information coming from the electromagnetic radiation (22) from the sun (21), the device according to the invention (5) will indicate visually, audibly or by

  vibration the correct position of the antenna (1).

  Step 6: final locking of the azimuth.

  The installer (23) locks the clamping device located

on the mast (8).

  Step 7: mechanical identification of the elevation reference.

  The installer (23) can then mechanically locate the elevation of his antenna (1) in this reference position, before moving it to the final position, in order to keep

  the initial reference position.

  Step 8: reading the relative position of the transmitter (13)

in elevation.

  The device according to the invention (5), in a particular mode, will indicate the difference in elevation of the transmitter (13) relative to the current elevation of the antenna (1). If the antenna (1) does not make it possible to make a precise measurement of the elevation of the sun (21), for example sun too high, an absolute adjustment will be sufficient. Step 9: movement maneuver to the final position The installer (23) unlocks the clamping device of the fastening system (7), and if necessary manually moves the antenna (1) by the angle indicated by the device according to

the invention (5).

  Step 10: signal indicating that the correct position has been locked

on the transmitter (13).

  The final position is the targeted transmitter (13) which also produces electromagnetic radiation (12) which will be picked up and interpreted by the device according to the invention (5) in order to indicate - 15 visually, audibly or by vibration the correct position of

the transmitter (13).

  A particular environment of the transmitter pointing device according to the invention is illustrated, by way of example, without limitation, in the following description. A complete system for receiving audiovisual broadcasts by satellite, described in FIG. 1, comprises certain high frequency reception equipment, consisting of a plate (2) of parabolic shape, positioned then fixed on a mast (8), the all carrying an arm (3) with an HF head (4) at its end, at the focal point of the Parabola (1), for capturing and above all concentrating the weak electromagnetic waves (12) coming from a targeted geostationary satellite (13) . This sub-assembly is commonly called parabola (1) and its assembly is carried out outdoors in order to have

  sufficient clearance in the direction of the targeted transmitter (13).

  The reception system is completed by an analog or digital or mixed reception terminal, called a decoder (9), to which are connected on one side, the dish (1) via the coaxial cable (6), on the other the television set (10). This decoder (9) can transform the HF signals into image and sound signals (in this particular case, it would rather be a domestic decoder) and it is of course installed inside the house. It contains many on-board HF signal analysis systems but it is generally far from the place of installation of the antenna (1), often positioned on a roof, a chimney, a high wall, etc. ... This decoder (9) is generally not movable, especially since it necessarily requires the use of a television set (10),

  to which it is permanently electrically connected.

  In addition, this decoder (9), if equipped, is capable of sending and receiving information (11) using standard 22KHz signal modulation methods, initially intended to control the HF heads or the motorized antennas, via said coaxial cable (6). Said decoder (9) feeds the dish - 16 with a supply and control voltage of 13 or 18 Volts,

  dependent on the desired polarization.

  In a particular embodiment, part of the device according to the invention (5) is then placed between the HF head (4) and the cable (6) connecting the decoder (9), in order to exchange information ( 11) with the decoder (9) and recover the energy necessary for its operation. This part

  of said device then becomes a peripheral of the decoder (9).

  The second part of said device here consists of the decoder (9) provided that it integrates the material means and

  software for communicating with the aforementioned device.

  FIG. 3 describes a particular embodiment of an autonomous device according to the invention, which is provided with a unit for measuring solar radiation (35), with a unit for measuring satellite radiation (34), a power supply unit (39), a processing unit (37), an input unit (36) and an audible, visual or vibrating signaling unit (38). Said autonomous device can be placed, if necessary, directly on the HF head (4) in order to recover the waves reflected by the parabola (1) outside the bandwidth of the HF head (4), making it possible to easily discriminate the source of the electromagnetic power received (satellite or sun). The unit (35) may

  consist of a simple wire antenna, a bandpass filter followed by a simple amplitude detector with amplification.

  The signal from this unit will be deemed to be a measure of the electromagnetic radiation (22) from the sun (21). The unit (34), recovering the signals from the HF head (4) will be less economical (hence the advantage of deporting this function in the decoder (9) which is equipped with a tuner-demodulator which can fulfill the same function ) because it consists for example of an amplitude detector based on a PIN diode followed by a conventional amplification chain. The main function of the processing unit (37) is to direct the appropriate information collected towards the signaling unit (38) according to the

  commands from the input unit (36).

  - 17 Figure 4 describes a particular embodiment of a device (5) decoder (9), simple and very low cost, according to the invention. The decoder (9) being able for example to send bursts at 22Khz, all the more close together for example that the received signal is strong, and possibly a continuous signal at 22Khz when the signal is demodulated, said simple peripheral (5) could include a demodulator (42), composed for example, after high-pass filtering to eliminate the DC component, and amplification of the signal, of a simple rectifying circuit10 filtering, for example of a diode, a resistor and a capacitor in parallel. The signal controls a simple transistor activating a buzzer (41) supplied by the DC voltage present

on the coaxial cable (6).

  According to different embodiments of the method according to the invention: the electromagnetic radiation from the sun is used far from its visible spectrum, and in particular at wavelengths much greater than those of said spectrum; - Said receiving antenna is used to pick up and amplify said electromagnetic radiation of solar origin, including if necessary the frequency components of this radiation which are not within the expected operating ranges of said antenna; - We use the fact that said radiation will be better captured that said antenna will be oriented towards the sun, which will point very precisely said antenna on the sun; - one can use the electromagnetic radiation of said targeted transmitter to adjust the antenna setting; - you can use the tuner and, if necessary, the decoder demodulator to detect or measure the solar electromagnetic power picked up by the antenna; - the demodulator of the decoder, whether analog or digital or both, can be used to ensure that the - 18 signals received cannot be demodulated, and therefore probably come from the sun; - we can use the decoder to measure the power and the quality of the received signals (measurement of error rate), or even extract from said signals any information allowing to know which transmitter we are aiming at, which allows us to finally point very precisely the antenna on the right transmitter; - one can use, at the place where the antenna is installed, a means of viewing, hearing or feeling (by vibration) information making it possible to adjust the antenna, possibly

sent by the decoder.

  According to different embodiments of the device according to the invention, the latter can: - include visual and / or sound and / or vibrating means enabling it to provide, close to the place of installation of the antenna (1), any information helping to differentiate between solar electromagnetic radiation (22) and radiation from a satellite (12), it being understood for example, and in a nonlimiting manner, that a simple measurement of error rate originating from a demodulator, combined with a measurement of the received signal strength can help make this difference; - be directly integrated with or in the HF head (called LNB) in any form whatsoever (for example, in the form of components, a card or a sub-block); - be made up of a decoder (9) having electronic and software means (resident or provided by a plug-in device of the PCMCIA type, chip card, memory card, the list not being exhaustive) to remotely control a device ( 5) deported, equipped with means of sound, visual or vibrating information; - be a means of viewing, hearing or feeling (by vibration) the information enabling the antenna (1) to be adjusted, at the place where it is installed, and controlled by a decoder (9) according to the

claim 9.

- 19

Claims (8)

claims   1) A method making it possible to easily orient a satellite (13) or terrestrial television antenna (1), providing for first targeting the sun (21) at any time in order to have an absolute azimuth reference and / or elevation of said antenna (1), then change, if necessary, the azimuth and / or elevation of said antenna (1) in a relative manner, in order to finally point at the targeted transmitter (13), characterized in that that: - electromagnetic radiation (22) from the sun (21) is used far from its visible spectrum, and in particular at wavelengths much greater than those of said spectrum, - said receiving antenna (1) is used to capturing and amplifying said electromagnetic radiation (22) of solar origin, including if necessary the frequency components of this radiation which are not within the expected operating ranges of said antenna (1), - the fact that said radiation ( 22) will be all the better captured that said antenna (1) will be well oriented towards the sun (21), which will make it possible to very precisely point said antenna (1) on the sun (21).   2) Method according to claim 1, characterized in that one uses the electromagnetic radiation (12) of said targeted transmitter   (13) to adjust the antenna setting (1).   3) Method according to claim 1 or 2 characterized in that one uses the tuner and if necessary the demodulator of the decoder (9) to detect or measure the power   electromagnetic solar sensed by the antenna (1).   4) Method according to claim 1 or 2 or 3 characterized in that one uses the decoder demodulator (9), whether analog or digital or both, to ensure that the received signals can not be demodulated , and therefore come from probably from the sun (21). - 20   ) Method according to at least one of the preceding claims   characterized in that the decoder (9) is used to measure the power and the quality of the signals received (measurement of error rate), or even extract from said signals any information allowing to know which transmitter (13) we are currently to aim, which makes it possible to point the antenna very precisely in the end (1) on the correct transmitter (13).   6) Method according to any one of claims   previous, characterized in that one uses, at the place where the antenna is installed (1), a means of viewing, hearing or feeling (by vibration) information making it possible to adjust   the antenna (1), possibly sent by the decoder (9).   7) Device other than a household decoder, making it possible to   implement the method according to one of claims   above, characterized in that it includes visual and / or audible and / or vibrating means enabling it to provide, close to the place of installation of the antenna (1), any information helping to differentiate between the radiation electromagnetic solar (22) and the radiation from a satellite (12), it being understood for example, and in a nonlimiting manner, that a simple measurement of error rate originating from a demodulator, associated with a measurement of the power of the received signal can help make this difference, and therefore falls within the scope of this claim.   8) Device for implementing the method according to   at least one of claims 1 to 6, characterized in that it   is directly integrated with or in the HF (4) head (called LNB) in any form whatsoever (for example, in the form of   components, a card or a sub-block).   9) Device for implementing the method according to claim 6, and optionally using a device according to claim 7, characterized in that it consists of a decoder (9) having electronic and software means (resident or brought by a plug-in device of the PCMCIA type, smart card, memory card, the list not being -21 exhaustive) for remote control of a remote device (5),   equipped with means of sound, visual or vibrating information.   ) Device for implementing the method according to claim 6, characterized in that it is a means of viewing, hearing or feeling (by vibration) the information making it possible to adjust the antenna (1), at l 'place where it is installed, and controlled by a decoder (9) according to claim 9.