Illumination device simulating the natural illumination and including an infrared light source

The invention claimed is: 1. An illumination device for an environment, the illumination device configured to simulate an open window and comprising: a first visible optical source configured to emit a visible optical beam; a diffuse light generator including an optical structure delimited by an inlet surface and by an outlet surface, the inlet surface being configured to receive the visible optical beam, said diffuse light generator being configured to emit from the outlet surface diffuse visible light and direct visible light, said direct visible light being formed by a portion of visible optical beam which is transmitted by the optical structure; an infrared optical source, different from the first visible optical source and configured to emit an infrared optical beam so that it impinges on the inlet surface, said optical structure being configured to transmit at least one first portion of the infrared optical beam; and a ventilation system in fluid communication with the environment and configured to introduce air masses into the environment in pulsed mode. 2. The illumination device according to claim 1 , wherein the ventilation system is configured to alternate periods of on and periods of off such that, in one hour, the total duration τ ON of the on periods and the total duration τ OFF of the off periods are such that τ ON /τ OFF ≤0.3. 3. The illumination device according to claim 1 , wherein the environment has a volume V; and wherein the ventilation system is configured to introduce into the environment a volume of air I per second; and wherein I/V≥5*10 −3 s −1 . 4. The illumination device according to claim 3 , wherein the ventilation system is configured to introduce said air masses into the environment through an intake opening having a section with area equal to ε*V 2/3 , with in the interval [0.03-1]. 5. The illumination device according to claim 1 , wherein the ventilation system is configured to introduce air masses having a temperature different from that of the environment. 6. The illumination device according to claim 1 , wherein the ventilation system comprises: a temperature sensor configured to detect the temperature of a portion of the environment; and a conditioner configured so as to introduce said air masses with a temperature differing from the temperature detected by the temperature sensor by at least one predefined thermal differential. 7. The illumination device according to claim 6 , wherein the ventilation system is configured to withdraw said air masses from a portion of space outside the environment; and wherein, if the air masses withdrawn have a temperature which differs from the temperature detected by the temperature sensor by less than said thermal differential, the conditioner thermally conditions the air masses withdrawn and subsequently introduces the conditioned air masses into the environment. 8. An illumination device for illuminating an environment, the illumination device comprising: a first visible optical source configured to emit a visible optical beam; a diffuse light generator including an optical structure delimited by an inlet surface and an outlet surface, the inlet surface being configured to receive the visible optical beam, said diffuse light generator being configured to emit from the outlet surface diffuse visible light and direct visible light, said direct visible light being formed by a portion of visible optical beam which is transmitted by the optical structure; an infrared optical source, different from the first visible optical source and configured to emit an infrared optical beam so that it impinges on the inlet surface, said optical structure being configured to transmit at least one first portion of the infrared optical beam; and a heating module arranged so as to receive said first portion of the infrared optical beam; wherein said heating module comprises a cavity optically accessible to said first portion of the infrared optical beam and further accessible to a fluid configured to absorb at least part of the first portion of the infrared optical beam, said cavity being in fluid communication with a hydraulic circuit. 9. The illumination device according to claim 8 , wherein the heating module further comprises: an upper region, which delimits the cavity; and a lower region arranged so that, in use, the fluid is arranged between said lower region and the upper region, said lower region being designed to backward diffuse in the visible spectrum. 10. An illumination device for illuminating an environment, the illumination device comprising: a first visible optical source configured to emit a visible optical beam; a diffuse light generator including an optical structure delimited by an inlet surface and by an outlet surface, the inlet surface being configured to receive the visible optical beam, said diffuse light generator being configured to emit from the outlet surface diffuse visible light and direct visible light, said direct visible light being formed of a portion of visible optical beam which is transmitted from the optical structure; an infrared optical source, different from the first visible optical source and configured to emit an infrared optical beam so that it impinges on the inlet surface, said optical structure being configured to transmit at least one first portion of the infrared optical beam; and an ultraviolet optical source configured to emit an ultraviolet optical beam, so that it impinges on the inlet surface and is subsequently emitted from the outlet surface. 11. The illumination device according to claim 1 , wherein the first visible optical source, the infrared optical source and the optical structure are configured so that, in use, the direct visible light and the first portion of the infrared optical beam are at least partially overlapped, in a volume of space arranged downstream of the outlet surface. 12. The illumination device according to claim 11 , wherein, for each point of at least one portion of said volume of space, the direction of maximum radiance of the direct visible light is no more than 30° from the direction of maximum radiance of the first portion of the infrared optical beam. 13. The illumination device according to claim 10 , wherein, within said portion of said volume of space, the width of the angular radiance peak of the direct visible light is below 15°, and the width of the angular radiance peak of the first portion of the infrared optical beam is below 30°. 14. The illumination device according to claim 1 , wherein the first visible optical source is different from a Planckian radiator. 15. The illumination device according to claim 14 , wherein the infrared source has no wavelength converters of the all-optical type. 16. The illumination device according to claim 1 , wherein the ratio between the integral in the visible spectrum of the radiant flux per unit of wavelength emitted by the first visible optical source and the integral in the infrared spectrum of the radiant flux per unit of wavelength emitted by the infrared source is below 0.1. 17. The illumination device according to claim 1 , further comprising a dichroic element arranged upstream of the optical structure and configured to optically couple the visible optical beam and the infrared optical beam, so that they are at least partly overlapping on the inlet surface. 18. The illumination device according to claim 1 , further comprising a reflecting optical system configured to convey the visible optical beam and the infrared optical beam onto the inlet surface.