FR3139258A1 - OPTICAL TERMINAL FOR COMMUNICATION BY LASER SIGNALS - Google Patents

Abstract

An optical terminal (1) for communication by laser signals is adapted to emit, in addition to a useful laser beam (FU) which carries data to be transmitted, a jamming light beam (FB), so that the two beams are superimposed in a reception plane (PR). The optical terminal enables a recipient receiver (2) to receive the data with a signal-to-noise ratio value that is sufficiently high, while simultaneously producing another signal-to-noise ratio value that is effective for a receiver spy (3), and which is sufficiently low to prevent reception of data by said spy receiver. Abstract figure: Figure 1

Description

OPTICAL TERMINAL FOR COMMUNICATION BY LASER SIGNALS

The present description relates to a terminal, a system and a method for optical communication by laser signals. It relates more particularly to such terminals, systems and methods which make it possible to transmit useful signals to a recipient in a manner which is secure in relation to undesired reception by a third party.

The need to communicate securely concerns all modes of communication, including signal transmissions which are carried out by modulation of a laser beam. Indeed, the mode of communication by laser signals which propagate in a free field (“free space” in English) is intended to be used more and more, in particular between a satellite which is in orbit around the Earth and a receiver which is located on Earth. But other configurations of use are also possible. Communication by laser signals is particularly advantageous with regard to security compared to detection by an eavesdropper of the signals which are transmitted between a transmitter and a recipient receiver, because a main part of the laser beam which is modulated to transmit the signals is concentrated in a limited cross section. Thus, the illumination produced by the beam decreases rapidly outside the direction of emission. However, this illumination is not completely zero outside the direction of transmission, and a spy receiver which is close to the free field propagation path which connects the transmitter to the recipient receiver could perhaps succeed in detecting successfully transmitted signals. Usually, the terminal transmitting the signals is called Alice, the receiver receiving these signals is called Bob, and the spy who is likely to detect the signals transmitted by Alice to Bob is called Eve.

Such a need to communicate securely applies to usual communications by laser beam, to transmit unencrypted data, but it also applies to the transmission of encryption keys, in particular continuous variable quantum encryption keys. or discrete variable. The key generation rate requirements are determined by the level of security that is required by the cryptographic protocol used, and by the length of each useful content that is to be transmitted in an encrypted manner. The highest security is provided by an OTP type protocol, for “One time pad” in English, but lower levels of security are provided by other protocols, such as the AES3 protocol.

Technical problem

For such applications, but also for others, an aim of the present invention is to improve the level of security of communications by laser signals.

More particularly, the invention aims to reduce the risk that a spy receiver which is located near the propagation path of the laser signals, or outside an exclusion volume, can successfully detect the transmitted signals.

An additional aim of the invention is to make it possible to increase the key generation rate for a mode of communication by laser beam.

To achieve at least one of these goals or another, a first aspect of the invention proposes an optical terminal for communication by laser signals, adapted to emit a laser beam, called a useful laser beam, which is modulated so as to transmit useful signals to an optical receiver external to the optical terminal, called a destination receiver. For this, the useful laser beam has at least one wavelength and forms at least one illumination spot inside a plane, called the reception plane, which is perpendicular to a direction of propagation of the useful laser beam. and which is located at the recipient receiver.

According to the invention, the optical terminal is adapted to further emit a jamming light beam, so that the useful laser beam and the jamming light beam satisfy the following properties:
- the useful laser beam and the jamming light beam are emitted simultaneously;
- a direction of emission of the jamming light beam is such that this jamming light beam forms, in the reception plane, a superposition with the useful laser beam;
- the jamming light beam has a non-zero spectral power value for the wavelength of the useful laser beam, such that at this wavelength and in the reception plane, the jamming light beam constitutes a contribution noise compared to useful signals; And
- respective intensities of the useful laser beam and the jamming light beam are such that at the wavelength of the useful laser beam and in the reception plane, there exists a zone, called the destination zone, inside which the superposition of the two beams presents values of a signal-to-noise ratio, for the useful signals, at any point in the destination zone which are all greater than a limit value, and this signal-to-noise ratio -noise simultaneously has values which are all less than the limit value at any other point in the reception plane outside the destination area.

The invention therefore establishes security by additional physical layer, for the transmission of useful signals in the case of a mode of communication which uses laser beam propagation in a free field. In the context of this description, useful signals are understood to mean signals which result from the modulation of the useful laser beam in order to transcribe data into a format which allows transmission to the recipient receiver. The optical terminal for communication by laser signals which is the subject of the first aspect of the invention is Alice according to the conventional name in the technical field of quantum encryption, and the recipient receiver is Bob. The invention therefore adds the jamming light beam to the useful laser beam, during communication from Alice to Bob, to reduce the possibility that a spy, that is to say Eve, manages to detect the useful signals by placing a spy receiver near Bob. Thanks to the adjustment of the intensity of the jamming light beam in relation to that of the useful laser beam, as proposed by the invention, the detection of useful signals by Eve by placing a spy receiver outside the destination zone is made more difficult, if not impossible. This confidentiality is obtained by the invention without significantly degrading the quality of the transmission between Alice and Bob.

Preferably, the optical terminal can be adapted so that at any point inside the destination zone, the useful laser beam produces an illuminance value which is greater than an illuminance value of the light beam of interference at the wavelength of the useful laser beam, and so that at any other point on the reception plane outside the destination zone, the useful laser beam simultaneously produces an illuminance value which is less than an illumination value of the jamming light beam also at the wavelength of the useful laser beam. When the jamming light beam constitutes the main source of noise, compared to other contributions to the noise which may otherwise exist and which would be much weaker, the limiting value of the signal-to-noise ratio is then approximately equal to one to the border of the destination area. However, it is not essential that the limit value of the signal-to-noise ratio which is produced according to the invention at the border of the destination zone is equal to one.

Generally for the invention, the optical terminal can be adapted so that the jamming light beam is modulated randomly or pseudo-randomly. The noise which is thus produced by the jamming light beam can have any spectral characteristic. In particular, it may be a spectral characteristic of white noise, spontaneous emission noise, thermal noise, etc.

In various embodiments of the invention, the optical terminal can be adapted so that each of the useful laser beam and the jamming light beam is modulated in the form of successive pulses. However, the invention is compatible with other modulation modes, such as polarization modulation, frequency modulation or phase modulation, for example.

Preferably but without being essential, the jamming light beam can be another laser beam, which then has a wavelength identical to that of the useful laser beam.

Still generally for the invention, the optical terminal can comprise a noise source which is arranged to modulate the jamming light beam.

In first possible embodiments of the invention, the optical terminal can comprise an output optic, in particular of the telescope type, which is arranged to simultaneously transmit the useful laser beam and the jamming light beam in superposition one with the 'other in this perspective of exit. Such first embodiments for the optical terminal reduce its mass and its bulk, which is particularly advantageous for an optical terminal which is on board a satellite.

In second embodiments, alternative to the first, the optical terminal may comprise two output optics which are separate, each output optic may in particular be of the telescope type, one of them being arranged to transmit the useful laser beam and the other to transmit the jamming light beam.

Still generally for the invention, the optical terminal can further comprise at least one detector, called intrusion detector, which is adapted to reveal another optical receiver external to the optical terminal, called spy receiver and corresponding to Eve, if this spy receiver is located in a zone of the reception plane, called exclusion zone, which contains the destination zone while being larger than the latter. The security or confidentiality of communication by laser signals can thus be improved to an additional extent. Such an intrusion detector may include at least one of a radar system, an infrared detection system, and a LIDAR system. In a case where the intrusion detector comprises a LIDAR system and a scanning system which is arranged to produce a scan of the exclusion zone by the radiation emitted by the LIDAR system, the optical terminal and the LIDAR system can share a output optics through which the useful laser beam and the radiation from the LIDAR system are transmitted, and possibly also the jamming light beam, and through which part of the radiation emitted by the LIDAR system is collected which has been retroreflected or backscattered by the receiver spy. Shared output optics means output optics from the terminal in which the beam(s) and the radiation of the LIDAR system are superimposed.

A second aspect of the invention proposes a carrier vehicle such as a satellite, a land vehicle, a ship, an aircraft, a drone, or a high-altitude platform station, commonly designated by HAPS for “High-Altitude Platform Station » in English, this carrier comprising an optical terminal which conforms to the first aspect of the invention, including its improvements, and which is on board the carrier. The invention then makes it possible to improve the level of security of so-called downlink communications in the case of transmissions from the satellite to the land vehicle, ship, aircraft, drone, or the high altitude platform station, or so-called uplink communications in the case of transmissions from the land vehicle, ship, aircraft, drone, or the high altitude platform station to the satellite.

A third aspect of the invention proposes a transmission station, in particular such a station which is fixed on the surface of the Earth, this transmission station comprising an optical terminal which conforms to the first aspect of the invention, including its improvements . In this case, the invention makes it possible to improve the level of security of uplink communications, from the transmission station to a satellite.

A fourth aspect of the invention proposes a laser signal communication system comprising an optical terminal which conforms to the first aspect of the invention, a recipient receiver which is external to the optical terminal, and means for revealing a spy receiver, which is external to the optical terminal and to the recipient receiver, if this spy receiver is located in the exclusion zone. Instead of or in addition to the means for revealing the spy receiver, the system may include means for preventing any spy receiver from being in the exclusion zone. Then, the superposition of the useful laser beam and the jamming light beam presents values of the signal-to-noise ratio, for the useful signals, at any point of the reception plane outside the exclusion zone , which are all lower than an additional limit value, this additional limit value being lower than the limit value relating to the destination zone.

Finally, a fifth aspect of the invention proposes a method of transmitting useful signals between an optical terminal which conforms to the first aspect of the invention, and which is the transmitter of the useful signals, and a recipient receiver which is external to the optical terminal, and to which the useful signals are intended. According to this process:
- the useful laser beam is emitted in the direction of the destination receiver so that this destination receiver is inside the destination zone; And
- the jamming light beam is emitted by the optical terminal so that the useful laser beam is superimposed on the jamming light beam.

Preferably, the jamming light beam can be activated before the transmission of useful signals begins, then maintained until after an interruption of this transmission.

In possible downlink applications of the method, the optical terminal may be on board a satellite that is in orbit around the Earth, and the recipient receiver may be part of a fixed terrestrial receiving station, or may be on board a vehicle or vessel that is on the surface of the Earth, or on board an aircraft, drone or high-altitude platform station, or may be a part of a portable equipment for a user who is on the surface of the Earth.

In other possible uplink applications of the method, the optical terminal may be a part of a fixed terrestrial transmission station, or may be on board a vehicle or vessel which is on the surface of the Earth, or on board an aircraft, drone or high-altitude platform station, or may be part of portable equipment for a user who is on the surface of the Earth. The recipient receiver can then be embarked on board a satellite which is in orbit around the Earth.

The method can be combined with the use of at least one intrusion detector to reveal a spy receiver which is external to the optical terminal and to the recipient receiver, if this spy receiver is located in the exclusion zone as defined more high. The intrusion detector may in particular be of one of the types mentioned above. It can be preferably located at the optical terminal which transmits the useful signals, or at the destination receiver. In the first case, the intrusion detector can be incorporated at least partly into the optical terminal emitting useful signals.

Brief description of the figures

illustrates a possible implementation of the invention from a satellite;

illustrates a first possible embodiment for an optical terminal which conforms to the invention;

illustrates a second possible embodiment for an optical terminal which conforms to the invention; And

is a diagram which shows illumination distributions used to implement the invention.

Detailed description of the invention

For reasons of clarity, the dimensions of the elements which are represented in these figures correspond neither to real dimensions nor to real dimensional ratios. Furthermore, some of these elements are only represented symbolically, and identical references which are indicated in different figures designate identical elements or which have identical functions.

illustrates a use of the invention for transmitting data from a satellite 10, for example a low-altitude orbiting satellite, to a terrestrial receiving station 20, commonly called a ground station. In the example shown, the ground station 20 is fixed, but it can also be mobile, the communication receiver then being on board a carrier vehicle, whatever the land, nautical or air type of this carrier vehicle. . The mode of communication is the transmission of laser signals in a free field, which is well known to those skilled in the art. For example, the data to be transmitted are coded in the form of intensity modulations of a laser beam which is emitted from the satellite 10 towards the ground station 20, called the useful laser beam and designated by FU, thus constituting the laser signals which are transmitted. For this, the satellite 10 is equipped with an optical terminal for communication by laser signals 1, and the ground station 20 is equipped with a recipient receiver 2. The constitutions and operations of the terminal 1 and the receiver 2 are known, if although the following description is limited to the modifications which are made according to the invention to the terminal 1 and to the receiver 2. As an example, the wavelength of the useful laser beam FU can be approximately 1.5 µm (micrometer). The invention can be applied to the transmission of any type of data from terminal 1 to receiver 2, including image data, quantum encryption keys, keys of other types of encryption, etc.

The central direction of propagation of the useful laser beam FU is denoted A-A. In known manner, the useful laser beam FU has a small section at satellite 10, corresponding to the exit pupil of terminal 1, and has a larger section at ground station 20. Thus, the beam useful laser FU produces a spot of illumination in a reception plane PR which is tangent to the surface of the Earth at the location of the ground station 20. For the laser signals to be successfully detected by the recipient receiver 2, it is necessary that the useful laser beam FU has a sufficient value of a signal-to-noise ratio at the location of the recipient receiver 2. The part of the illumination spot in which the signal-to-noise ratio is greater at a limit value which allows the successful detection of laser signals is called destination zone, and denoted ZD. Terminal 1 must then be controlled to point the useful laser beam FU so that the destination receiver 2 is within the destination zone ZD at all times during data transmission.

However, inside the reception plane PR, the destination zone ZD is larger than the space which is occupied by the destination receiver 2. For this reason, a spy receiver 3 which would also be located in the destination zone ZD , although being separated from the recipient receiver 2, could detect simultaneously with the latter and successfully the useful laser signals transmitted by the terminal 1. But because the useful laser beam FU in fact has a transverse extension which extends beyond the destination zone ZD, even if the spy receiver 3 is outside this destination zone ZD, it could still detect part of the useful laser signals, although with an error rate which increases depending on the distance of the spy receiver 3 relative to the central direction of propagation A-A. The aim of the invention is then to reduce the possibility for the spy receiver 3, commonly called Eve, to successfully receive the data which are transmitted by the terminal 1, called Alice, to the recipient receiver 2, called Bob. The following description is provided assuming that the spy receiver 3 is in the reception plan PR, because this plan corresponds in practice to the maximum risk of intrusion by Eve, but those skilled in the art will be able to transpose this description to any level along the central propagation direction A-A at which spy receiver 3 might be located.

According to the invention, the terminal 1 emits, at the same time as the useful laser beam FU, a jamming light beam FB so that the two beams FU and FB are superimposed in the reception plane PR. In practice, the two beams FU and FB have respective central directions of propagation which are almost identical, due to the distance of the terminal 1 from the destination receiver 2. The jamming light beam FB has the function of producing values of the signal-to-noise ratio outside the destination zone ZD, which are greater than the limit value which makes it possible to successfully detect the useful laser signals transmitted by the terminal 1. So that the jamming light beam FB produces a noise which cannot be filtered optically, it has an optical wavelength which is identical to that of the useful laser beam FU. Preferably, the jamming light beam FB is also a laser beam. In this case, its wavelength is identical to that of the useful laser beam FU, and the spectral power of the jamming light beam FB is then equivalent to the output power of the light source which produces it, also commonly called the intensity of the FB jamming light beam. However, embodiments of the invention are also possible, for which the jamming light beam FB is produced by optical sources of other types, such as based on one or more light-emitting diodes, or LEDs, by example. So that the jamming light beam FB constitutes noise compared to the useful laser beam FU, the two beams FU and FB also have the same type of modulation. For example, the two beams are modulated in intensity to transmit their respective radiation in the form of successive pulses. The modulation of the useful laser beam FU is produced to transfer the data to the destination receiver 2, and the modulation of the jamming light beam FB is produced independently of that of the useful laser beam FU, in order to produce jamming noise for the signals useful laser. For this, the modulations of the jamming light beam FB can be random or pseudo-random.

symbolically shows a first possible design for the terminal 1, according to which the two beams FU and FB are transmitted to the outside by a common output optic 11. For example, this output optic 11 can be a telescope. Two object focal planes PF _U and PF _B are associated with this output optics 11 using a beam splitter 12 to superimpose the beams FU and FB in the direction of the output optics 11. The beam splitter 12 can be a biprism with intensity division. A source of the useful laser beam FU, designated by the reference 13a, is arranged to deliver this useful laser beam FU with a divergence from a first focus which is located in the focal plane PF _U. The system 12a controls the modulation of the useful laser beam FU so that this beam carries the data to be transmitted. Due to the position of the first focus in the focal plane PF _U , the useful laser beam FU is collimated downstream of the output optics 11, towards the destination receiver 2. A source of the jamming light beam FB, designated by the reference 13b, is also arranged to deliver this jamming light beam FB with a divergence from a second focus which is located in front of the focal plane PF _B , in the direction of the beam splitter 12. d designates the distance of defocus which is created between the second focus and the focal plane PF _B , being adjustable. Thus, although the two beams FU and FB are transmitted through the same output optics 11 and have the same central direction of propagation AA, the jamming light beam FB can have a divergence downstream of the output optics 11 which is adjustable, controlling the defocus distance d. The jamming light beam FB then produces in the reception plane PR an illumination spot which is larger than that of the useful laser beam FU, while being co-centered with the latter. Reference 12b designates a system for controlling the modulation of the jamming light beam FB, so that this beam FB carries a jamming signal, deliberately according to the invention. Different sources of random or pseudo-random noise can be used alternatively in system 12b depending on the spectral characteristics that are desired for this noise. Such noise sources are known to those skilled in the art, as are their implementations.

shows in modular form a second possible design for terminal 1, according to which the two beams FU and FB are transmitted to the outside by two output optics which are separated and juxtaposed, designated by 11a and 11b. These two output optics can each be a telescope. Terminal 1 then comprises two transmission channels: transmission channel 1a to transmit the useful laser beam FU, and transmission channel 1b to transmit the jamming light beam FB. The two transmission channels 1a and 1b are supported by the chassis of satellite 10.

The emission route 1a may have a usual structure known to those skilled in the art, as briefly recalled now. The optical source 13a transmits the useful laser beam FU, modulated by the control system 12a in accordance with the data to be transmitted, to a point-ahead module, which is designated by the reference 14a. The beam FU as it emerges from the forward pointing module 14a is transmitted to the output optics 11a through relay optics 15a and a main pointing system 16a. In addition, the relay optics 15a and the main pointing system 16a are included in a control loop to ensure that the useful laser beam FU continuously reaches the receiver 2. This control loop includes a tracking detector 18a, or “tracking detector” in English, and a vibration compensator 19a, commonly called “jitter controller” in English. The tracking detector 18a, in combination with the vibration compensator 19a, controls the orientation of the main pointing system 16a. The vibration compensator 19a is itself supplied as input with detection signals which are delivered by an inertial sensor 20a, and which are representative of vibrations and changes in orientation which affect the chassis of the satellite 10. In this way, the destination zone ZD remains precisely and continuously on the destination receiver 2 despite the vibrations of the satellite 10. Optionally, an optical communication receiver 17a can be arranged from an additional optical output of the relay optics 15a, to detect and processing optical communication signals which are transmitted by the receiver 2.

The transmission channel 1b, which is dedicated to the jamming light beam FB, can have a simplified structure by being coupled to the transmission channel 1a. The optical source 13b produces the jamming light beam FB, modulated by the control system 12b to produce the noise in accordance with the invention. The transmission channel 1b includes a forward pointing module 14b, relay optics 15b, a main pointing system 16b, a vibration compensator 19b and inertial sensor 20b. Unlike the transmission channel 1a, the transmission channel 1b does not have a dedicated tracking detector, and the vibration compensator 19b receives as input the detection signals from the recipient receiver which are delivered by the tracking detector 18a , in addition to the detection signals which are delivered by the inertial sensor 20b. Thus, the jamming light beam FB is transmitted by the output optics 11b according to the central direction of propagation A-A, so that the two beams FU and FB are co-centered in the reception plane PR due to the distance very large of this PR reception plan compared to terminal 1.

The diagram of shows spatial variations of illumination E at a point M of the reception plane PR, as a function of the radial distance r of this point M relative to the central direction of propagation AA (see r and M indicated in ). This lighting, denoted E generically, has the following three contributions:
- an atmospheric noise contribution, designated by ATM, which is substantially independent of the radial distance r;
- the contribution of the useful laser beam FU, which can have a Gaussian or substantially Gaussian radial profile; And
- the contribution of the jamming light beam FB, which can also have a Gaussian or substantially Gaussian radial profile.

In principle, so that data communication is possible between the terminal 1 and the recipient receiver 2 with a very low error rate, the useful laser beam FU is emitted by the terminal 1 with an intensity which ensures that the illumination of this useful laser beam FU in the illumination spot is much greater than the illumination of the ATM atmospheric noise. With regard to the useful laser signals which are transmitted by terminal 1, and when the invention is used, the noise is therefore mainly produced by the jamming light beam FB. For this reason, ATM atmospheric noise is no longer mentioned in the following.

The destination zone ZD can be defined by a minimum signal-to-noise ratio value for a receiver which is located inside it. For example, this minimum value of the signal-to-noise ratio may correspond to a minimum acceptable reception error rate for a receiver which is located anywhere within this destination zone ZD. Due to the symmetry around the central direction of propagation AA, the destination zone ZD is a disk or more generally a portion of surface which is limited by an ellipse, inside the reception plane PR. As a non-limiting example, the destination zone ZD can be defined by a minimum value of the signal-to-noise ratio which is equal to 1.0. Taking into account the previous realistic hypotheses, the circle or ellipse which then constitutes the peripheral border of the destination zone ZD corresponds to the points of the reception plane PR where the two beams FU and FB have the same illuminance value, as indicated in . For reasons of clarity, but without inducing limitation, the description is continued assuming that the destination zone ZD is a disk, it being understood that those skilled in the art will know how to transpose the elements and characteristics described to the case of a zone of destination ZD of elliptical shape.

The improvement which is now described aims to ensure that the spy receiver 3 cannot access the data transmitted by the terminal 1 to the destination receiver 2, with an additional security measure. For this, an exclusion zone ZE is provided in the reception plane PR, which is larger than the destination zone ZD, and outside of which the signal-to-noise ratio is further reduced compared to its value at the border of the destination zone ZD. Thus, the limiting value of the signal-to-noise ratio which is produced on the border of the destination zone ZD guarantees that the destination receiver 2 can detect the transmitted signals with a sufficiently low error rate. This limit value is denoted SNR _D. The signal-to-noise ratio is therefore greater than this SNR limit value _D at any point inside the destination zone ZD. Simultaneously, the signal-to-noise ratio is less than an additional limit value, denoted SNR _E , at any point of the reception plane PR which is outside the exclusion zone ZE. The additional limit value SNR _E is therefore produced on the peripheral limit of the exclusion zone ZE. Thus, the limit value SNR _D is greater than the additional limit value SNR _E , and the difference between the two constitutes the additional security which is provided for the confidentiality of the transmitted data.

To create the exclusion zone ZE, the transmission system between the terminal 1 and the receiver 2 can be provided with means of preventing entry of the spy receiver 3 into this exclusion zone. Such prevention means can have any form, such as isolation barriers for example. Alternatively or in combination, the transmission system between the terminal 1 and the receiver 2 can be provided with at least one intrusion detector 30 which is capable of revealing the spy receiver 3 as soon as the latter is located in the detection zone. ZE exclusion. The ZE exclusion zone is indicated in And .

The intrusion detector 30 can be of any type effective in revealing the presence of a spy receiver inside the exclusion zone ZE. It can be located near the destination receiver 2, or on board the satellite 10 as shown in , possibly being at least partly incorporated into the terminal 1. Alternatively, the intrusion detector 30 can be located at a distance from the receiver 2 and the terminal 1, for example by being on board an aircraft and pointed towards the area ZE exclusion. Such an intrusion detector 30 may consist of one or more radar system(s), one or more infrared detection system(s), or even one or more LIDAR system(s), for “LIght Detection And Ranging” in English, or light detection and ranging system(s). Such a LIDAR system emits radiation in the direction of the exclusion zone ZE, and part of this radiation which has been retroreflected or backscattered by the spy receiver 3, if the latter is inside the exclusion zone ZE , is detected and analyzed, in particular to obtain information on the distance at which the spy receiver 3 is located. The operation of such a LIDAR system is assumed to be known, so that it is not necessary to repeat it here. Advantageously, this LIDAR system can be associated with a scanning system, so that the search and intrusion detection which are produced by the LIDAR operation allow surveillance of the entire exclusion zone ZE.

It may be particularly advantageous for such a LIDAR system used as an intrusion detector 30 to be on board the satellite 10, in addition to the terminal 1, as shown in . Indeed, the satellite 10 may have the mission of transmitting confidential data successively to several recipient receivers 2 which are located at different locations on the Earth. In this case, the same LIDAR system can be used for all these receivers, successively while the data concerned is transmitted to each recipient receiver 2.

shows a combination in which the LIDAR system of the intrusion detector 30 is integrated into the terminal 1. The radiation which is emitted by the LIDAR system is designated by R in this figure. According to a further improvement, the radiation which is emitted towards the outside by the LIDAR system can be transmitted by the output optics 11 or 11a. For this, the LIDAR system can be coupled to the pointing of the useful laser beam FU, in a manner similar to that which was described above for the emission channel 1b in . Possibly, a scanning system can also be placed within terminal 1, on a portion of the transmission channel which is dedicated exclusively to the LIDAR system, in order to produce a scan of the exclusion zone ZE by the radiation of the system LIDAR.

Using the well-known approximation of Gaussian beams, the illumination distribution of the useful laser beam FU in the reception plane PR is: , where E _U (r) designates this illuminance of the beam FU at the distance r measured from the central direction of propagation AA, E _U0 is the value of this illuminance for r=0, w _U is the radius of the useful laser beam FU in the reception plane PR, and exp() denotes the exponential function. The value E _U0 can be adjusted either at the laser source 13a which produces the useful laser beam FU, by selecting an output power value for this laser source, corresponding to the intensity of the beam FU, or by using an attenuator optics which is located between the output of the laser source 13a and the output optics 11 or 11a of the terminal 1 which is used to transmit the useful laser beam FU to the outside.

Similarly, the illumination distribution of the jamming light beam FB in the reception plane PR is: , where E _B (r) designates this illuminance of the beam FB at the distance r measured from the central direction of propagation AA, E _{B 0} is the value of this illuminance for r=0 in the hypothesis where the two beams FU and FB have the same central direction of propagation, and w _B is the radius of the jamming light beam FB in the reception plane PR. The value E _{B 0} can be adjusted either at the level of the light source 13b which produces the jamming light beam FB, by selecting an output power value for this light source, corresponding to the intensity of the beam FB, or by using another optical attenuator which is located between the output of the light source 13b and the output optics 11 or 11b of the terminal 1 which is used to transmit the jamming light beam FB to the outside.

The four parameters E _U0 , w _U , E _B0 and w _B can be adjusted to produce the SNR limit value _D of the signal-to-noise ratio on the peripheral boundary of the destination zone ZD, and simultaneously the additional limit value SNR _E on the peripheral border of the ZE exclusion zone. For this, the value of E _U0 is much greater than the value of E _{B 0} , and the value of w _U is less than the value of w _B. Several methods of selecting suitable values can be used, which those skilled in the art will be able to implement without difficulty. The following simplified selection mode is given as an example. We can assume that the pointing of terminal 1 for the two beams FU and FB is sufficiently precise so that the destination receiver 2 is constantly at r=0. In this case, the signal-to-noise ratio as perceived by the recipient receiver 2 is directly the quotient E _U0 /E _B0 , and can be taken for the limit value SNR _D. The value of the signal-to-noise ratio at the peripheral border of the exclusion zone ZE, that is to say the additional limit value SNR _E , is then E _U (r _E )/E _B (r _E ) , where r _E is the radius of the peripheral border of the exclusion zone ZE. It then comes: . In other words, the radius r _E of the exclusion zone ZE is selected first, in particular according to the spatial coverage of the intrusion detection means 30, or according to the prevention measures which are used to avoid the entry of the spy receiver 3 inside the exclusion zone ZE. The limit value SNR _D so that the recipient receiver 2 detects the useful laser signals with an acceptable error rate, the additional limit value SNR _E to guarantee a sufficiently high error rate at the peripheral border of the exclusion zone ZE , and the radius w _U of the useful laser beam FU in the reception plane PR, in particular as a function of the precision of the pointing of the terminal 1, are also selected as inputs to the parameterization. Then, the value to adopt for the radius of the jamming light beam FB is: , where ln() denotes the natural logarithm function, or “natural log function” in English. This value for the radius w _B of the jamming light beam FB can in particular be produced by adjusting the defocusing distance d of the light source 13b in the embodiment of . For the embodiment of , the value of the radius w _B can be achieved by adjusting a defocus of the relay optics 15b.

It is understood that the invention can be reproduced by modifying secondary aspects thereof in relation to the detailed description which has just been provided above. Such modifications may depend on the application considered and its specific characteristics. In particular, by way of example, the radius of the destination zone ZD or that w _U of the useful laser beam FU in the reception plane PR can be chosen as much larger as the destination receiver 2 is mobile with a high speed . In addition, electronic or optical components can be used to replace the components mentioned, when they have functions equivalent to those of the latter, or whose combination of functions reproduces the operation described.

Claims (19)

Optical terminal (1) for communication by laser signals, adapted to emit a laser beam, called useful laser beam (FU), which is modulated so as to transmit useful signals to an optical receiver external to the optical terminal, called receiver recipient (2), the useful laser beam having at least one wavelength and forming at least one illumination spot inside a plane which is perpendicular to a direction of propagation of said useful laser beam and located at the level of the destination receiver, called reception plane (PR),
the optical terminal (1) being characterized in that it is adapted to further emit a jamming light beam (FB), so that the useful laser beam (FU) and the jamming light beam satisfy the following properties:
- the useful laser beam (FU) and the jamming light beam (FB) are emitted simultaneously;
- a direction of emission of the jamming light beam (FB) is such that said jamming light beam forms, in the reception plane (PR), a superposition with the useful laser beam (FU);
- the jamming light beam (FB) has a non-zero spectral power value for the wavelength of the useful laser beam (FU), such as at said wavelength and in the reception plane (PR) , the jamming light beam constitutes a noise contribution compared to the useful signals; And
- respective intensities of the useful laser beam (FU) and the jamming light beam (FB) are such that at the wavelength of the useful laser beam and in the reception plane (PR), there exists a zone, called destination zone (ZD), inside which the superposition of said useful laser beam and said jamming light beam presents values of a signal-to-noise ratio, for the useful signals, at any point of said destination area which are all greater than a limiting value, and said signal-to-noise ratio simultaneously has values which are all less than the limiting value at any other point of the reception plane outside said destination area. Optical terminal (1) according to claim 1, adapted so that at any point inside the destination zone (ZD), the useful laser beam (FU) produces an illuminance value which is greater than an illumination value of the jamming light beam (FB) at the wavelength of said useful laser beam,
and so that at any other point of the reception plane (PR) outside the destination zone (ZD), the useful laser beam (FU) simultaneously produces an illuminance value which is less than one illumination value of the jamming light beam also at the wavelength of said useful laser beam. Optical terminal (1) according to claim 1 or 2, adapted so that the jamming light beam (FB) is modulated randomly or pseudo-randomly. Optical terminal (1) according to any one of the preceding claims, adapted so that each of the useful laser beam (FU) and the jamming light beam (FB) is modulated in the form of successive pulses. Optical terminal (1) according to any one of the preceding claims, in which the jamming light beam (FB) is another laser beam, said other laser beam having a wavelength identical to the wavelength of the laser beam useful (FU). Optical terminal (1) according to any one of the preceding claims, comprising a noise source which is arranged to modulate the jamming light beam (FB). Optical terminal (1) according to any one of claims 1 to 6, comprising output optics (11), in particular of the telescope type, which is arranged to simultaneously transmit the useful laser beam (FU) and the jamming light beam ( FB) in superposition with one another in said output optics. Optical terminal (1) according to any one of claims 1 to 6, comprising two separate output optics (11a, 11b), in particular each of the telescope type, one of said output optics being arranged to transmit the useful laser beam ( FU) and the other of said output optics being arranged to transmit the jamming light beam (FB). Optical terminal (1) according to any one of the preceding claims, further comprising at least one detector, called intrusion detector (30), which is adapted to reveal another optical receiver external to the optical terminal, called spy receiver (3). ), if said spy receiver is located in a zone of the reception plane (PR), called exclusion zone (ZE), which contains the destination zone (ZD) being larger than said destination zone. Optical terminal (1) according to claim 9, wherein the intrusion detector (30) comprises at least one of a radar system, an infrared detection system, and a LIDAR system. Optical terminal (1) according to claim 9, in which the intrusion detector (30) comprises a LIDAR system and a scanning system arranged to produce a scan of the exclusion zone (ZE) by radiation emitted by the system LIDAR, said optical terminal and said LIDAR system having shared output optics through which the useful laser beam (FU) and the radiation from the LIDAR system, and possibly also the jamming light beam (FB), are transmitted, and through which is collected part of the radiation emitted by the LIDAR system which has been retroreflected or backscattered by the spy receiver (3). Carrier vehicle selected from a satellite (10), a land vehicle, a ship, an aircraft, a drone, or a high altitude platform station, comprising an optical terminal (1) which conforms to any one of claims 1 at 11, and who is embarked on board said carrier vehicle. Transmission station, comprising an optical terminal (1) which conforms to any one of claims 1 to 11. Laser signal communication system comprising an optical terminal (1) and an optical receiver, called recipient receiver (2), which is external to said optical terminal,
the optical terminal (1) being adapted to emit a laser beam, called useful laser beam (FU), which is modulated so as to transmit useful signals to the destination receiver (2), said useful laser beam having at least one length wave and forming at least one spot of illumination inside a plane which is perpendicular to a direction of propagation of said useful laser beam and located at the level of the recipient receiver, called reception plane (PR),
the system being characterized in that the optical terminal (1) is adapted to further emit a jamming light beam (FB), so that the useful laser beam (FU) and the jamming light beam satisfy the following properties:
- the useful laser beam (FU) and the jamming light beam (FB) are emitted simultaneously;
- a direction of emission of the jamming light beam (FB) is such that said jamming light beam forms, in the reception plane (PR), a superposition with the useful laser beam (FU);
- the jamming light beam (FB) has a non-zero spectral power value for the wavelength of the useful laser beam (FU), such as at said wavelength and in the reception plane (PR) , the jamming light beam constitutes a noise contribution compared to the useful signals; And
- respective intensities of the useful laser beam (FU) and the jamming light beam (FB) are such that at the wavelength of the useful laser beam and in the reception plane (PR), there exists a zone, called destination zone (ZD), inside which the superposition of said useful laser beam and said jamming light beam presents values of a signal-to-noise ratio, for the useful signals, at any point of said destination area which are all greater than a limiting value, and said signal-to-noise ratio simultaneously has values which are all less than the limiting value at any other point of the reception plane outside said destination area,
the system further comprising means for revealing another optical receiver, called spy receiver (3), external to the optical terminal (1) and to the recipient receiver (2), if said spy receiver is located in a zone of the reception plane, called exclusion zone (ZE), which contains the destination zone (ZD) being larger than said destination zone, or means for preventing any spy receiver from being in the exclusion zone, the superposition of the useful laser beam and the jamming light beam having signal-to-noise ratio values, for the useful signals, at any point on the reception plane outside the exclusion zone, all of which are lower than an additional limit value, said additional limit value being lower than the limit value relating to the destination zone. Method for transmitting useful signals between an optical terminal (1) which conforms to any one of claims 1 to 11, transmitter of said useful signals, and a recipient receiver (2) which is external to the optical terminal, according to which:
- the useful laser beam (FU) is emitted towards the destination receiver (2) so that said destination receiver is inside the destination zone (ZD); And
- the jamming light beam (FB) is emitted by the optical terminal (1) so that the useful laser beam (FU) is superimposed on said jamming light beam. Method according to claim 15, according to which the jamming light beam (FB) is activated before a start of the transmission of the useful signals, then maintained until after an interruption of said transmission of the useful signals. Method according to claim 15 or 16, according to which the optical terminal (1) is on board a satellite (10) which is in orbit around the Earth, and the destination receiver (2) is part of a station fixed terrestrial receiving station (20), or is on board a vehicle or ship which is on the surface of the Earth, or on board an aircraft, a drone or a platform station at high altitude, or is a part of portable equipment for a user who is on the surface of the Earth,
or the optical terminal (1) is a part of a fixed terrestrial transmission station, or may be on board a vehicle or ship which is on the surface of the Earth, or on board an aircraft , a drone or a high-altitude platform station, or is a part of portable equipment for a user who is on the surface of the Earth, and the recipient receiver (2) is carried on board a satellite that orbits the Earth. Method according to any one of claims 15 to 17, according to which the optical terminal (1) conforms to any one of claims 1 to 8, and according to which at least one intrusion detector (30) is used to reveal another optical receiver which is external to the optical terminal and to the recipient receiver (2), called spy receiver (3), if said spy receiver is located in a zone of the reception plane (PR), called exclusion zone (ZE) , which contains the destination zone (ZD) being larger than said destination zone. Method according to claim 18, according to which the intrusion detector (30) is located at the optical terminal (1) which emits the useful signals, the optical terminal preferably being able to conform to any one of claims 9 to 11 , or the optical terminal is located at the destination receiver (2).