Co-orbiting laser communications relay satellite

The invention claimed is: 1. A relay satellite for relaying data from a client satellite to thereby reduce power and pointing accuracy requirements of the client satellite, said relay satellite comprising: a short-range communications link configured to receive data from the client satellite; and a long-range communications link configured to retransmit the received data to a ground station or another satellite, wherein the relay satellite is deployed in one of (a) a quasi-orbit with respect to the client satellite such that the relay satellite and the client satellite can be kept within a pre-determined distance or (b) the same orbit as the client satellite but with an in-track offset that keeps the relay satellite and the client satellite within a pre-determined distance; wherein the short-range communications link can be used to receive data from the client satellite when the client satellite is within a pre-determined distance of the relay satellite; wherein the relay satellite is deployable from the client satellite after the client satellite reaches orbit. 2. The relay satellite of claim 1 , wherein the relay satellite further comprises a docking mechanism configured to dock the relay satellite with the client satellite. 3. The relay satellite of claim 2 , wherein the docking mechanism comprises a fuel transfer mechanism configured to transfer propellant between the client satellite and the relay satellite. 4. A satellite network comprising a plurality of relay satellites, as described in claim 1 , wherein the plurality of relay satellites are each configured to receive data from the same client satellite and wherein the plurality of relay satellites are each in quasi-orbits phased as a function of time with respect to the client satellite. 5. A method of relaying data using a relay satellite to thereby reduce power and pointing accuracy requirements of the client satellite, comprising: deploying the relay satellite in one of (a) a quasi-orbit with respect to the client satellite such that the relay satellite and the client satellite can be kept within a pre-determined distance or (b) the same orbit as the client satellite but with an in-track offset that keeps the relay satellite and the client satellite within a pre-determined distance; the relay satellite receiving data from a client satellite via a radio communications link; and transmitting the received data from the relay satellite to a ground station or another satellite using an optical communication link; wherein the short-range communications link can be used to receive data from the client satellite when the client satellite is within a pre-determined distance of the relay satellite; wherein the relay satellite is one of a plurality of relay satellites, wherein the quasi-orbit of the relay satellite is one of a plurality of phased quasi-orbits, and wherein the other relay satellites of the plurality of relay satellites are in the other phased quasi-orbits of the plurality of phased quasi-orbits.