In the theoretical part of my thesis, I first present geometrical, wave and quantum models of light. I describe fluorescence, reflection, absorption, Rayleigh scattering of light and utilised light sources. I further describe the structure of the human eye, the photoreceptors inside, their spectral sensitivity and the correlation between the light spectrum and the observed colour. I expose the difference between the physical definition and everyday use of terms black, white and grey body. I describe two systems for quantitative analysis of colour and problems that appear in digital and physical colour reproduction at printing. I finish the theoretical part by describing the instruments that I use for measuring the temperature of tungsten filament and light spectra of light bulbs. In the experimental part of my thesis, I calibrate the spectrometer and measure the spectrum of incident light and light that has reflected off a coloured surface. By using the measured spectrum, I analyse the correlation between incident and reflected light and calculate the surface reflectance. For demonstration of practical use, I predict the colour of an object by knowing incident light and the applied pigment. I revive curriculum for primary and high school science and physics classes. Then I study incomplete perceptions and misconceptions about colour detection among high school students. I design an experiment in which different colours of light illuminate different coloured objects. I test the effectiveness of this experiment for improving understanding of colour detection in high school.