Embodiments of the present disclosure provide systems, apparatuses and methods for a facility, such as a feedlot, barn, greenhouse, hospital, school or production facility, with synchronous communication and control of LED lights in lighting arrays for the emission of photon pulses to induce the stimulation of desired biological responses. Further provided herein are mobile real time location units to assist the LED lighting arrays to identify the location or status of an organism and to adjust their photon pulse emissions based on the needs of the organism.

The invention provides a light generating system (1000) comprising (a) first light generating device (110) and (b) a control system (300), wherein: the first light generating device (110) is configured to generate first device light (111), wherein the first device light (111) comprises light having one or more wavelengths in a first wavelength range of 280-320 nm, wherein the first wavelength range comprises a lower subrange from 11 to 12 and a higher subrange from 21 to 22, wherein 280 nm11<1221<22320 nm, and wherein 12 and 21 are selected from the wavelength range of 290-315 nm, wherein a wavelength dependent radiant flux of the first device light (111) is controllable: the light generating system (1000) is configured to generate system light (1001) comprising at least part of the first device light (111); the control system (300) is configured to control the wavelength dependent radiant flux of the first device light (111) as a function of time, wherein the light gen-crating system (1000) is configured to provide the first device light (111) at a first time t1, at a second time t2, and at a third time t3; wherein the second time t2 is temporally arranged after the first time t1, and the third time t3 is temporally arranged after the second time t2; and wherein the first time t1, the second time t2, and the third time t3 are temporally arranged in a single day; wherein relative to a total radiant flux in the first wavelength range the radiant flux of the first device light (111) in the lower subrange is relatively lower at the first time t1 than at the second time t2, and wherein relative to the total radiant flux in the first wavelength range the radiant flux of the first device light (111) in the higher subrange is relatively higher at the first time t1 than at the second time t2; and/or wherein relative to the total radiant flux in the first wavelength range the radiant flux of the first device light (111) in the lower subrange is relatively higher at the second time t2 than at the third time t3, and wherein relative to the total radiant flux in the first wavelength range the radiant flux of the first device light (111) in the higher subrange is relatively lower at the second time t2 than at the third time t3.

A surface treatment system can include a reconfigurable frame structure at least partially defining a treatment area. The frame structure can include panels configured for repeated assembly and disassembly in any of a plurality of configurations and far-UVC light sources configured to emit far-UVC light directed into the treatment area. The surface treatment system also can include sensors configured to acquire presence data corresponding to a presence of an object in the treatment area and a control unit configured to operate the plurality of far-UVC light sources to treat surfaces of the object located in the treatment area using the presence data.

The present invention integrates infrared (IR) and near-infrared (NIR) light therapy with cold water immersion, providing combined therapeutic benefits for skin health, stress reduction, and enhanced healing. This variation utilizes the water's scattering and heat-conductive properties to optimize the distribution and safety of infrared light while maintaining the cooling benefits of the device.