Bolometer having frequency detection

The invention claimed is: 1. A bolometer comprising: a substrate; at least one electromechanical microsystem or nanosystem, the microsystem or nanosystem comprising a support and a mobile mass hung above the support by at least two beams anchored to the substrate, the mobile mass forming an absorber of optical flux; actuators disposed on the substrate and configured to cause the mobile mass to vibrate at a resonance frequency thereof in accordance with a deformation mode of the mobile mass in a median plane thereof, the median plane being substantially parallel to the substrate; and detectors disposed on the substrate and configured to detect variation in vibration frequency of the mobile mass, a thickness of the beams being at least ten times smaller than a thickness of the mobile mass. 2. The bolometer according to claim 1 , wherein the mobile mass is in plate form, the median plane of the mobile mass being the plane of the plate. 3. The bolometer according to claim 1 , wherein the actuators are of electrostatic type and include at least one actuation electrode on the support arranged laterally relative to the mobile mass. 4. The bolometer according to claim 1 , wherein the detectors are of capacitive type and include at least one detection electrode on the support arranged laterally relative to the mobile mass. 5. The bolometer according to claim 1 , wherein the at least two beams arranged along vibration nodes of the mobile mass. 6. The bolometer according to claim 1 , further comprising anti-reflective layers on a first surface of the mobile mass configured to receive the optical flux. 7. The bolometer according to claim 1 , further comprising a layer of a material having a different coefficient of expansion to that of the mobile mass, the layer being disposed on a first surface of the mobile mass and being configured to receive the optical flux. 8. The bolometer according to claim 7 , further comprising anti-reflective layer on the first surface of the mobile mass configured to receive the optical flux, and wherein the anti-reflective layer forms the layer of material having a different coefficient of expansion to that of the mobile mass. 9. The bolometer according to claim 1 , further comprising an optical reflector on a second surface of the mobile mass opposite a first surface thereof and configured to receive the optical flux, the mobile mass forming an optical resonant cavity. 10. The bolometer according to claim 1 , further comprising an optical reflector on the support facing a second surface of the mobile mass opposite a first surface thereof and configured to receive the optical flux, so as to form an optical resonant cavity between the optical reflector and the second surface of the mobile mass. 11. The bolometer according to claim 10 , wherein the optical reflector is separated from the mobile mass by a distance of an order of λ/4, λ being the wavelength of the optical flux to be measured. 12. The bolometer according to claim 1 , wherein the mobile mass and the at least two beams are formed of a crystalline semiconductor in silicon or SiGe. 13. The bolometer according to claim 1 , wherein the material of the at least two beams is different from that of the mobile mass. 14. An assembly of bolometers according to claim 1 , arranged in an array. 15. A temperature measuring assembly comprising one bolometer according to claim 1 and an electronic control circuit coupled to the bolometer and configured to cause the bolometer to be powered, to control the actuators to cause the mobile mass to vibrate, and to measure a variation in vibration frequency of the mobile mass via the detectors. 16. The measuring assembly according to claim 15 , wherein the electronic control circuit sets the mobile mass or an assembly of mobile masses in vibration in accordance with volume modes, or an extensional wine-glass mode, or Lamé mode. 17. The measuring assembly according to claim 15 , further comprising an optical focusing device arranged above the bolometer and configured to be inserted between the optical flux and a first surface of the mobile mass. 18. The measuring assembly according to claim 15 , wherein the electronic control circuit is assembled with the bolometer, the control circuit and the bolometer being superimposed. 19. The measuring assembly according to claim 15 , further comprising at least one actuation wire to send from the electronic control circuit actuation signals of different frequencies to one bolometer simultaneously, and at least one detection wire to collect detection signals of different frequencies from one bolometer and provide the detection signals to the electronic control circuit.