Technically, the indirect electrophotographic printing is a very complicated job. It implements 6 separate phases performed synchronically. They are charging, exposing, developing, the first transfer, the second transfer and cleaning. The influence of each phase on the quality of the multicolour reproduction has been researched in this work and the parameters which are not the standard ones for the production printing were used in it. The influence results of particular phases of electrophotographic printing process on the final reproduction have been presented in the gamut form (construction defined by ECI form of 378 patches) as well as the CIE LAB ΔE difference between calibration and the experimental print. In the starting phase, the influence of scorotron on the formation of the future free surfaces has been researched. The changes in gamut which appeared, were minimal ones (ΔVsimb=13,3, ΔVsplen=8,6 i ΔVarco= 4,1 space unit). The valid rule in this case is: the less scorotron voltage, the greater gamut volume. The change of the screen surfaces is greater in relation to the full tones. In investigating the influence of the laser head, it was noticed that the screen dot is subdued to great change. By increasing the laser strength, the screen elements become greater and darker. Full tones do not change considerably, and gamuts have the following changes: ΔVsimb=10,3, ΔVsple=13,2 i ΔVarco= 2,9 space unit. The developing process (developing drum and the squeegee rollers) influence the maximal change of the gamut inking (ΔVsimb= 301,5 ; ΔVsimb=210 space unit). By application of higher voltages, the greater application of the ink is achieved. The activity of the developing drum influences the greater change of the full tones, while in the case of the squeegee rollers greater change is achieved in screen. By the extreme increase of the voltage of the squeegee rollers, only smaller degradation of the gamut volume is achieved (ΔVsim=17,2, ΔVsple=22,3 i ΔVarc= 9,4 space unit) During the transferring process, two parameters varied: the temperature of the offset cylinder and the voltage of the offset cylinder. The increase of temperature causes the increase of the ink viscosity, which increases the gamut volume (ΔVsim=44,8, ΔVsple=49,3 i ΔVarc=31,9 space unit). The higher voltage of the offset cylinder ensures the better transfer. The change in voltage of 200V will cause the greatest gamut increase (ΔVsimb=37,7, ΔVsplen=14,3 i ΔVarco=11,5 space unit). At the end of the research the influence of the ink density on the final reproduction has been observed. The concentration increase of the pigment results in darker impression. During the colour variations, the gamuts ware not expected to be great (ΔVsimb=60,2, ΔVsplen=36,6 i ΔVarco=57,3 space unit). In investigation of the electrophotographic process, three different substrates were used: Simbol (glossy fine art paper for printing in classical offset), Splendogel (natural coated paper for digital printing) and Arcoprint (natural paper for classical offset printing). The surface properties of paper showed that they have decisive role in achieving the reproduction quality. Splendogel and Simbol papers with their coatings behave better in extreme conditions which is not the case in the application of the natural paper Arcoprint.