The prospects for testing the Einstein Equivalence Principle by measuring the gravitational time dilation effect using clocks in a distant retrograde orbit around the Moon are investigated. To obtain estimates of the accuracy that can be achieved in such an experiment, we constructed a model that accounts for the colored nature of the clock noise, as well as a possible clock frequency bias and drift. This model is applied to the case of a lunar distant retrograde orbit (a 2: 1 resonance) and three types of clocks characterized by qualitatively different stability and accuracy parameters: hydrogen masers (VCH-1010 and VCH-2021), a cesium fountain clock (PHARAO), and a strontium optical clock (I-SOC). Assuming 5 years of data accumulation, the following estimates for the achievable accuracy of the experiment were obtained: 6 10^-4 for VCH-1010, 1 10^-5 for VCH-2021, 2 10^-5 for PHARAO, and 3 10^-7 for I-SOC. These estimates show that an experiment with an optical clock would significantly improve upon both the current best result ( (2-3) 10^-5, GREAT project) and the anticipated results of experiments on the ISS and Tiangong orbital stations. A comparison of our results with previous studies that do not account for clock drift and frequency bias is provided.
Литвинов et al. (Wed,) studied this question.