Paired beam transponder satellite communication

What is claimed is: 1. A satellite communications system comprising: a gateway terminal located in a loopback spot beam coverage area and having a flexible allocation of forward-channel and return-channel portions of uplink and downlink frequency bands; a plurality of user terminals located in the loopback spot beam coverage area and having the flexible allocation; and a satellite in communication with the gateway terminal and the plurality of user terminals, and having a loopback beam transponder comprising: an input subsystem comprising an uplink input port coupled with a loopback beam feed, and comprising an uplink output port to generate a combined input signal comprising forward-channel traffic received from the gateway terminal in the forward-channel portion of the uplink frequency band and return-channel traffic received from the user terminals in the return-channel portion of the uplink frequency band; and an output subsystem comprising a downlink input port to receive a combined output signal as a translation of the combined input signal to a downlink frequency band, and comprising a downlink output port coupled with the loopback beam feed to transmit, in the downlink frequency band, a downlink signal generated from the combined input signal to comprise the forward-channel traffic in the forward-channel portion of the downlink frequency band and the return-channel traffic in the return-channel portion of the downlink frequency band. 2. The satellite communications system of claim 1 , wherein the flexible allocation defines a first one or more sub-bands of the uplink frequency band and a first one or more sub-bands of the downlink frequency band to forward-channel communications, and defines a second one or more sub-bands of the uplink frequency band and a second one or more sub-bands of the downlink frequency band to return-channel communications. 3. The satellite communications system of claim 1 , wherein the flexible allocation is according to a spread-spectrum scheme. 4. The satellite communications system of claim 1 , wherein the satellite further comprises: a plurality of transponders comprising a paired-beam transponder and the loopback beam transponder. 5. The satellite communications system of claim 4 , wherein the gateway terminal includes an antenna supporting first and second communication polarities, and the first gateway terminal is configured to transmit to the paired-beam transponder using the first communication polarity and to transmit to the loopback transponder using the second communication polarity. 6. The satellite communications system of claim 1 , wherein the loopback beam transponder further comprises: a frequency translator coupled between the input subsystem and the output subsystem, the combined output signal generated by the frequency translator in response to receiving the combined input signal. 7. A satellite comprising: an antenna comprising a loopback beam feed to receive, in an uplink frequency band, a combined uplink signal having a ratio of forward-channel traffic to return-channel traffic according to a flexible allocation of forward-channel and return-channel portions of the uplink and downlink frequency bands; and a loopback beam transponder comprising: an input subsystem comprising an uplink input port adapted to couple with the loopback beam feed, and comprising an uplink output port to provide a combined input signal generated from the combined uplink signal; a frequency translator comprising a translator input coupled to the uplink output port to receive the combined input signal, and a translator output to provide a combined output signal corresponding to the combined input signal translated to a downlink frequency band; and an output subsystem comprising a downlink input port coupled to the translator output to receive the combined output signal, and a downlink output port to provide a combined downlink signal to the loopback beam feed of the antenna, the combined downlink signal generated from the combined output signal to comprise the ratio of forward-channel traffic to return-channel traffic according to the flexible allocation. 8. The satellite of claim 7 , wherein the flexible allocation defines a first one or more sub-bands of the uplink frequency band for forward-channel communications, a second one or more sub-bands of the uplink frequency band for return-channel communications, a first one or more sub-bands of the downlink frequency band for forward-channel communications, and a second one or more sub-bands of the downlink frequency band for return-channel communications. 9. The satellite of claim 7 , wherein the flexible allocation is according to a spread-spectrum scheme. 10. The satellite of claim 7 , wherein the forward-channel traffic is received from a gateway terminal in a loopback beam coverage area, and the return-channel traffic is received from a user terminal in the loopback beam coverage area. 11. The satellite of claim 7 , wherein the frequency translator comprises: a down converter coupled with the translator input port; and a channel filter coupled between the down converter and the translator output port. 12. The satellite of claim 7 , wherein: the input subsystem comprises a low-noise amplifier; and the output subsystem comprises a high-power amplifier. 13. The satellite of claim 7 , wherein: the input subsystem comprises an input utility selector switch having a normal mode and a utility mode; the output subsystem comprises an output utility selector switch having a normal mode and a utility mode; when the input utility selector switch and the output utility selector switch are in the respective normal modes, the input subsystem and the output subsystem are coupled with the loopback beam feed; and when the input utility selector switch and the output utility selector switch are in the respective utility modes: the input subsystem is coupled with a respective utility gateway beam feed and the loopback beam feed, and the output subsystem is coupled with the utility gateway beam feed and the loopback beam feed, such that the forward-channel traffic is received from a utility gateway terminal outside the loopback beam coverage area. 14. The satellite of claim 13 , wherein: the input utility selector switch and the output utility selector switch are adapted to be normally in the respective normal modes and to switch to the respective utility modes in response to detecting that the gateway terminal in the loopback beam coverage area is non-operational. 15. A satellite comprising: an antenna comprising a loopback beam feed to receive, in an uplink frequency band, a combined uplink signal having a ratio of forward-channel traffic to return-channel traffic according to a flexible allocation of forward-channel and return-channel portions of the uplink and downlink frequency bands; and a loopback beam transponder comprising: an input subsystem comprising an uplink input port adapted to couple with the loopback beam feed, an uplink output port to provide a combined input signal generated from the combined uplink signal, and an input utility selector switch having a normal mode and a utility mode; a frequency translator comprising a translator input coupled to the uplink output port to receive the combined input signal, and a translator output to provide a combined output signal corresponding to the combined input signal translated to a downlink frequency band; and an output subsystem comprising a downlink input port coupled to the translator output to receive the combined output signal, a downlink output port to provid