Notwithstanding the complex advances in optical technologies, there are still no artificial light sources capable of adequately simulating the natural daylight. Reaching such a lighting standard will represent a reduction of the production costs, in view of the rework caused by not so reliable visual evaluations, and of the commercial conflicts related to products that have colour as one of their control characteristics, such as textile, graphics and merchandising articles. The present Master degree metrology research is related to the metrological evaluation of the lighting sources and light booths available in the market (commercially available), and to their conformity to the technical specifications standards, aiming to stimulate the introduction of technological innovation to new industrial developments eligible to enhance the performance of these apparatus. The research has also contributed to the development of a diagnosis of the collection of the existing technical standards applied to the standardisation of lighting systems; to the investigation of fluorescent lamps generally used as daylight simulators, and to the metrological evaluation of light booths available in the market (commercially available). Particularly, analyses were done with a highly precise spectroradiometric system that uses a double monochromator with capacity for beam dispersion of 2 nm/mm. Tests and analyses on repeatability and reproducibility made with the spectroradiometric measurement system let to quantify the variety associated with each manufactured set of daylight simulators, commercialised as fluorescent lamps available at the local market. Having the spectral distribution determined throughout the axis of the studied lighting sources (lamps) it was possible to develop an analysis of the impact caused at the lighting uniformity obtained for industrial light booths, and so, specifying a distinctive factor technically and commercially interesting. The research revealed that, when evaluated considering the international practices and standards, none of the daylight simulators tested achieved the minimum requirement indicated for the visual comparison of colours. In addition, measurements were done to verify the influence of the light booths building pieces at the power spectral distribution within the evaluation area. Based on 1578 measurements done at laboratorial conditions simulating industrial environment, the research proves that changes in the building characteristics of the light booths produce an impact at the result of the power spectral distribution classification, creating, thus, a smooth condition for the attendance of the standards specifications, even when using low-cost fluorescents lamps available in the market.