This application claims priority to foreign France patent application No. 0903422, filed on Jul. 10, 2009, the disclosure of which is hereby incorporated by reference in its entirety.
The field of the invention is that of optical devices for detecting the instantaneous position and orientation of the helmet worn by an aircraft pilot. In general, in the rest of the text the term “posture” refers to a particular position and a particular orientation of the helmet. For certain aeronautical applications, the helmets of pilots are provided with display devices for generating, in the pilot's field of view, information about the flight, the navigation or the reference system. These helmet visuals are generally coupled to systems for detecting the position and orientation of the helmet.
There are various systems for referencing the position of a helmet. In particular, systems based on the analysis of optical signals representative of the position of the helmet are used. These systems necessarily comprise one or more light emission sources and one or more light reception sources. The emission sources may, as shown in
Whatever the method chosen, the detected signal SD is disturbed by solar illumination, as indicated in
The object of the device according to the invention is to produce an optical position/orientation detection system that can be used in a wide range of illuminations, in daytime with illuminations of the order of 100 000 lux and at night with illuminations of the order of 0.01 lux. Under high illumination, the invention utilizes solar illumination instead of combating it, by employing passive markers on the helmet that do not reflect the solar illumination or that reflect the solar light along an axis different from that of the optical sensors. Under low illumination, additional light sources ensure, if need be, the visibility of the markers. These markers may be bordered with a phosphorescent film emitting visible light under excitation by the additional source in the ultraviolet range.
This solution has the main advantages, compared with the prior art, of not requiring a power supply for the markers on the pilot's helmet, of being particularly simple and robust, and of giving signal/noise ratios that are always high irrespective of the illumination. It is therefore perfectly suited to the environment of aircraft cockpits.
More precisely, the subject of the invention is an optical device for detecting the position/orientation of a helmet, said device comprising at least one stationary camera associated with an image processing system and a helmet, characterized in that the helmet has a scattering coating and includes at least one set of markers, each marker comprising at least a first optical element having a very low reflection coefficient, a very low scattering coefficient and a very high absorption coefficient in the visible range. Moreover, said device may include at least one additional stationary light source, the first optical element having a very low reflection coefficient, a very low scattering coefficient and a very high absorption coefficient in the emission range of said light source.
Advantageously, the first element is either a black body, i.e. a cavity having a hole, the dimensions of the hole being small compared with the dimensions of the cavity, or it comprises a nickel phosphide film, or else it consists of a carpet of carbon nanotubes.
Advantageously, in a second embodiment, the device includes at least one stationary camera associated with an image processing system and a helmet, characterized in that the helmet includes at least one set of markers, each marker comprising a first optical element having a very high retroreflection coefficient and a very low scattering coefficient in the visible range. As in the previous embodiment, the device may include at least one additional stationary light source.
In this case, the first optical element may be a catadioptric element.
Advantageously, the device includes optomechanical means for producing an image of the light source on the optical axis of the camera.
Advantageously, the marker comprises a second optical element, the second optical element having a high scattering or phosphorescence or fluorescence coefficient in the emission range of the light source, it being possible for the markers of each set of markers to be of different shape and for the second optical element to surround the first optical element.
Finally, the source may emit in the ultraviolet, the second element being phosphorescent or fluorescent in the emission range of said light source.
The invention will be better understood and other advantages will become apparent on reading the following description given by way of non-limiting example and thanks to the appended figures in which:
As first exemplary embodiment, a helmet posture detection device is depicted in
As shown in
The helmet 1 has a matt scattering coating, advantageously light in colour, and includes a set of markers 3. Each marker 3 is represented by a circle in
For operating at night or under a very low light level, the detection device may also include one or more additional stationary light sources 6 distributed around the cockpit. It is also possible, to avoid employing additional sources, to use cameras that can operate at a very low light level, such as cameras with light intensifiers. These sources are sufficiently numerous to illuminate the entire region 4 in which the helmet can move. In
The markers are detected by a set of cameras 2. For the sake of clarity, only one camera is shown in
If necessary, these markers have different geometric shapes so as to be able to be easily distinguished. They may be in the form of circles or lines. Their distribution on the helmet forms geometric figures, called “constellations”, which can be easily identified by the image processing system. Thus, in
Each marker 3 comprises a first optical element 31 as shown in the blown-up parts of
Each marker 3 may also include a second optical element 32 as shown in the blown-up parts of
The first element 31 is either a black body, i.e. a cavity 33 having a hole 34 as indicated in the sectional view shown in
As a second exemplary embodiment, which is a variant of the previous device, a second, helmet posture detection device is depicted in
This second device essential differs from the first embodiment by the operation of the markers. In the present case, each marker 3 comprises a first optical element 31 of the “catadioptric” type, having a very high retroreflection coefficient and a very low scattering coefficient in the visible range. Thus, the solar radiation is necessarily reflected in the sun's direction, as may be seen in
The term “catadioptric” refers to any optical reflector or retroreflector having the property reflecting a light beam in the same direction as its incident direction. To give an example, a “cube corner” reflector formed from three mutually orthogonal plane mirrors is a catadioptric reflector. Thus, a light beam emitted by the emitting part and illuminating the catadioptric reflector is re-emitted in the same direction towards the receiving part with an excellent efficiency. Likewise, any light beam which does not emanate from the source and which strikes the catadioptric reflector produces, in principle, virtually no illumination towards the receiving part.
A catadioptric reflector may constitute, as indicated in
a cube corner reflector, that is to say an assembly of three plane mirrors 35 that are mutually perpendicular;
a simple lens 36 and a reflecting mirror 37 placed on the focal surface of this lens;
a transparent sphere 38, with an optical index of 2, also called a “cat's eye”, the rear face 39 of said sphere being reflective.
It is also possible to use phase conjugate mirrors.
All these devices have the particular feature of reflecting any light ray in the same direction as its direction of incidence.
At night or under a very low light level, if the sensitivity of the cameras is no longer sufficient, it is possible to use additional light sources. In this case, there are two possible operating modes dependent on the position of the light source relative to the camera. In a first embodiment, the light source is not on the optical axis of the camera. In this case, the radiation from the source illuminating the catadioptric reflector is reflected back to the source, and the camera receives no illumination coming from the catadioptric reflector. The catadioptric reflector appears black on a light background. It is then advantageous for the marker to include a second optical element 32 having a high diffusion or phosphorescence coefficient in the emission range of the light source or for the coating on the helmet to be light in colour on the periphery of the catadioptric reflector.
In the second embodiment shown in
To improve the detection, it is possible to make a number of modifications to the general arrangements described above. Thus, the light source, when it is present, will be turned off when the sunshine conditions are sufficient; it may be modulated temporally; it may be a scanning light source; it may be controlled so as to illuminate particular areas of the helmet.
Number | Date | Country | Kind |
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09 03422 | Jul 2009 | FR | national |