Agile transport for background traffic in cellular networks

The invention claimed is: 1. A system comprising: a processor; and a memory that stores computer-executable instructions that, in response to execution by the processor, cause the processor to perform operations comprising: determining a capacity of a communication path that communicatively couples a user equipment to a radio access network cell site, assembling a plurality of probe burst packet sets from a background traffic flow, wherein the plurality of probe burst packet sets comprise a first probe burst packet set, a second probe burst packet set, and a third probe burst packet set, probing the communication path for spare capacity using the plurality of probe burst packet sets, wherein probing the communication path for spare capacity comprises delivering, via the communication path, the first probe burst packet set to the user equipment, determining that the communication path is not busy based on a lack of a packet inter-arrival discontinuity after delivery of the first probe burst packet set, in response to determining that the communication path is not busy, delivering, via the communication path, the second probe burst packet set to the user equipment, determining that the communication path remains not busy based on a lack of a packet inter-arrival discontinuity after delivery of the second probe burst packet set, in response to determining that the communication path remains not busy, delivering, via the communication path, the third probe burst packet set to the user equipment, and determining that the communication path continues to remain not busy based on a lack of a packet inter-arrival discontinuity after delivery of the third probe burst packet set, and delivering the background traffic flow to the user equipment using the spare capacity while the communication path is not busy. 2. The system of claim 1 , wherein delivery of the background traffic flow is limited such that a reserve capacity of the communication path is maintained. 3. The system of claim 1 , wherein the third probe burst packet set is larger in size than the second probe burst packet set, and wherein the second probe burst packet set is larger in size than the first probe burst packet set. 4. The system of claim 1 , wherein delivering the background traffic flow to the user equipment occurs in response to determining that the communication path continues to remain not busy. 5. The system of claim 1 , wherein the operations further comprise detecting that bursts of a foreground traffic flow are being sent concurrently along the communication path while the background traffic flow is being delivered. 6. The system of claim 5 , wherein the operations further comprise: in response to detecting that bursts of the foreground traffic flow are being sent, determining whether the communication path is busy; and in response to determining that the communication path is busy, yielding the capacity of the communication path to the foreground traffic flow. 7. The system of claim 5 , wherein the operations further comprise: in response to detecting that bursts of the foreground traffic flow are being sent, determining whether the communication path is busy; and in response to determining that the communication path is not busy, continuing to deliver the background traffic flow to the user equipment using the spare capacity. 8. A method comprising: determining, by a proxy server, a capacity of a communication path that communicatively couples a user equipment to a radio access network cell site; assembling, by the proxy server, a plurality of probe burst packet sets from a background traffic flow, wherein the plurality of probe burst packet sets comprises a first probe burst packet set, a second probe burst packet set, and a third probe burst packet set; probing, by the proxy server, the communication path for spare capacity using the plurality of probe burst packet sets, wherein probing the communication path for spare capacity comprises delivering, by the proxy server, via the communication path, the first probe burst packet set to the user equipment, determining, by the proxy server, that the communication path is not busy based on a lack of a packet inter-arrival discontinuity after delivery of the first probe burst packet set, in response to determining that the communication path is not busy, delivering, by the proxy server, via the communication path, the second probe burst packet set to the user equipment, determining, by the proxy server, that the communication path remains not busy based on a lack of the packet inter-arrival discontinuity after delivery of the second probe burst packet set, in response to determining that the communication path remains not busy, delivering, by the proxy server, via the communication path, the third probe burst packet set to the user equipment, and determining, by the proxy server, that the communication path continues to remain not busy based on a lack of the packet inter-arrival discontinuity after delivery of the third probe burst packet set; and delivering, by the proxy server, the background traffic flow to the user equipment using the spare capacity while the communication path is not busy. 9. The method of claim 8 , wherein delivery of the background traffic flow is limited such that a reserve capacity of the communication path is maintained. 10. The method of claim 8 , wherein the third probe burst packet set is larger in size than the second probe burst packet set, and wherein the second probe burst packet set is larger in size than the first probe burst packet set. 11. The method of claim 8 , wherein delivering the background traffic flow to the user equipment occurs in response to determining that the communication path continues to remain not busy. 12. The method of claim 8 , further comprising detecting, by the proxy server, that bursts of a foreground traffic flow are being sent concurrently along the communication path while the background traffic flow is being delivered. 13. The method of claim 12 , further comprising: in response to detecting that bursts of the foreground traffic flow are being sent, determining, by the proxy server, whether the communication path is busy; and in response to determining that the communication path is busy, yielding, by the proxy server, the capacity of the communication path to the foreground traffic flow. 14. The method of claim 12 , further comprising: in response to detecting that bursts of the foreground traffic flow are being sent, determining, by the proxy server, whether the communication path is busy; and in response to determining that the communication path is not busy, continuing to deliver, by the proxy server, the background traffic flow to the user equipment using the spare capacity. 15. A computer storage medium having computer-executable instructions stored thereon that, in response to execution by a processor, cause the processor to perform operations comprising: determining a capacity of a communication path that communicatively couples a user equipment to a radio access network cell site; assembling a plurality of probe burst packet sets from a background traffic flow, wherein the plurality of probe burst packet sets comprises a first probe burst packet set, a second probe burst packet set, and a third probe burst packet set; probing the communication path for spare capacity using the plurality of probe burst packet sets, wherein probing the communication path for spare capacity comprises delivering, via the communication path, the first probe burst packet set to the user equipment, determi