부산대학교 도서관

Communications to and from a spacecraft undertaking launch-landing interstellar travel at near light speed faces significant challenges. Photon-based communication is significantly impacted by large photon propagation delay and relativistic time dilation. The timing of communications by photon transfer, as measured specifically by local clocks at origin and destination and aboard spacecraft, is analyzed and illustrated for concrete mission scenarios. These include a spacecraft experiencing indefinite constant self-acceleration, and a launch-landing mission, in which a spacecraft experiences constant acceleration for the first half of its cruise phase and a like deceleration for the second half. The origin and destination are assumed to be at rest within a common inertial frame with a wide range of fixed distances separating them. Several typical communication modes are considered, including one-way messaging, two-way message query with an expected response, and the one-way streaming of long program material such as a podcast or video. The local-clock relative timing experienced by the communicating entities including clock images (relation of transmit and receive clocks in one-way communication), the query-response latency (the elapsed time between a query message and reception of a message in response), and the time warping of a streaming program (nonlinear stretching or shrinking of the time axis) are included. In particular, large query-response latency, except for a short interval following launch or before landing, is a severe limit on remote control and social interaction. When photons must travel in the same direction as the spacecraft, communication blackouts strongly limit the periods of time during which communication is possible, and restrict the opportunities for both one-way and two-way communication.