Optical particle detector

The invention claimed is: 1. An optical detector for particles, comprising: a channel configured to receive a fluid comprising at least one particle and to receive at least one incident light ray; a detection system comprising a plurality of photodetectors, each photodetector being configured to receive light rays coming from the channel and diffused by the at least one particle; and an angular filtering system comprising a plurality of angular filtering devices each associated with a photodetector of the plurality of photodetectors, each angular filtering device being configured to angularly filter the light rays coming from the channel before reception thereof by the photodetector with which it is associated, and each angular filtering device comprises an optical entry having a numerical aperture smaller than a numerical aperture of the photodetector with which said each angular filtering device is associated. 2. The optical detector according to claim 1 , wherein the optical entry of said each angular filtering device is less than or equal to 0.3. 3. The optical detector according to claim 1 , wherein said each angular filtering device is configured to define a collection cone at a respective optical entry thereof, each collection cone having an aperture angle γ c of less than 35°, so as to collect diffused light rays having propagation directions having angles of incidence relative to an optical axis of the respective optical entry, of less than 17.5°. 4. The optical detector according to claim 3 , further comprising, for at least some of the angular filtering devices, an intermediate optical structure between the channel and the optical entry, the intermediate optical structure being configured so as to reduce divergence of the collection cone and/or to broaden a section of the collection cone of the optical entry, the intermediate optical structure being chosen from among a microlens and a microbead. 5. The optical detector according to claim 1 , wherein the channel is cylindrical and the optical entry of said each angular filtering device is distributed at least partly around the channel, along at least a portion of at least one circle. 6. The optical detector according to claim 5 , wherein said each photodetector is disposed along at least two concentric circles, in alternation. 7. The optical detector according to claim 5 , wherein the optical entry of said each angular filtering device is distributed along a semicircle. 8. The optical detector according to claim 5 , wherein the optical entry of said each angular filtering device has an optical axis matching with a radius of a cylinder forming the channel. 9. The optical detector according to claim 1 , wherein said each angular filtering device comprises, between an entry thereof and the respective photodetector that is associated therewith, an optical guidance structure from among an optical fibre, a waveguide, a lens, or a light trap. 10. The optical detector according to claim 1 , wherein the photodetectors comprise photodetection surfaces disposed in a plane transverse to a longitudinal axis of the channel, the optical detector further comprising an optical integration structure configured to transmit diffused light rays collected at a respective optical entry as far as the photodetection surface of the photodetector associated with the respective optical entry, the optical integration structure being an integrating sphere, an integrating washer, or a prism. 11. The optical detector according to claim 1 , wherein the channel is cylindrical and the optical entry of said each angular filtering device is distributed around the channel on axes in line with radii of the cylinder, two successive axes being separated by a distribution angle θ of between 15° and 45°. 12. The optical detector according to claim 11 , wherein the distribution angle θ varies around the channel. 13. The optical detector according to claim 11 , wherein a first part of the optical entry of said each angular filtering device is distributed over a first half of a circle and has a first distribution angle θ 1 of about 30°, and wherein a second part of the optical entry of said each angular filtering device is distributed over a second half of the circle and has a second distribution angle θ 2 different from θ 1 , of about 36°, so as to perform a non-redundant sampling of the diffused light rays. 14. The optical detector according to claim 1 , further comprising a light source configured to emit the at least one incident light ray through the channel. 15. The optical detector according to claim 14 , wherein the light source is isotropic and the optical detector further comprises a device configured to form an incident beam associated with the light source and having an optical exit, and to form, at the optical exit, a beam of incident light rays having an aperture angle of less than 30°. 16. The optical detector according claim 1 , having a principal extension dimension of less than 10 mm. 17. A system comprising: at least one optical detector according to claim 1 , wherein the system is chosen from among: a fire alarm system, a fire detection system, a system for analysing quality of a fluid such as air or water, a pollution alarm system, an explosive-powder detection system, and a microbiological-species detection system. 18. A method for manufacturing the optical detector according to claim 1 , the method comprising: providing a substrate; defining, on one face of the substrate, angular filtering devices surrounding the channel; forming the channel through the substrate to provide a passage for the fluid; forming the angular filtering devices on a face of the substrate; and associating each photodetector with each of the angular filtering devices. 19. The method according to claim 18 , wherein the angular filtering devices are light traps formed by etching of the substrate. 20. The method according to claim 18 , further comprising forming an optical integration structure configured to transmit light rays from a respective angular filtering device as far as a photodetection surface of the photodetector associated with the respective angular filtering device, the photodetection surface mainly extending on planes parallel to the face of the substrate, and the optical integration structure being an integrating washer etched from the face of the substrate. 21. The method according to claim 18 , wherein the photodetectors are disposed on a linear array, and the linear array of photodetectors is associated with a respective angular filtering device.