Wireless communication methods, systems, and computer program products

We claim: 1. A method of conveying data on a multi-hop communications network, the method comprising: receiving, with a first communications interface of a first communications device, a first node-state signal from a second communications device, wherein receiving, with the first communications interface of the first communications device, the first node-state signal from the second communications device further comprises: entering a lower-power mode of operating the first communications device for a first duration of time; entering a higher-power mode of operating the first communications device for a second duration of time that corresponds to a node-state signal interval of the first node-state signal; and entering the lower-power mode of operating the first communications device for a third duration of time; ascertaining, with the first communications device, in response to the first node-state signal, that the first communications device will make itself available as a relay for other communications devices in the multi-hop communications network via the second communications device; in response to ascertaining that the first communications device will make itself available as a relay for other communications devices in the multi-hop communications network via the second communications device, transmitting, from a second communications interface of the first communications device, a second node-state signal indicating the availability of the first communications device as a relay for other communications devices in the multi-hop communications network; and receiving, at the first communications device: uplink data from a third communications device and transmitting the uplink data to the second communications device; or downlink data from the second communications device and transmitting the downlink data to a third communications device. 2. The method of claim 1 , wherein: entering the lower-power mode of operating the first communications device comprises turning off a receiver of the first communications interface; and entering the higher-power mode of operating the first communications device comprises turning on the receiver of the first communications interface. 3. The method of claim 1 , wherein transmitting, from the second communications interface of the first communications device, the second node-state signal further comprises: entering a lower-power mode of operating the first communications device for a fourth duration of time; entering a higher-power mode of operating the first communications device for a fifth duration of time that corresponds to a node-state signal interval of the second node-state signal; and entering the lower-power mode of operating the first communications device for a sixth duration of time. 4. The method of claim 3 , wherein: entering the lower-power mode of operating the first communications device comprises turning off the receiver of the second communications interface; and entering the higher-power mode of operating the first communications device comprises turning on the receiver of the second communications interface. 5. The method of claim 1 , wherein at least one of the following is broadcast periodically as a beacon frame: the first node-state signal; and the second node-state signal. 6. The method of claim 1 , wherein the first communications interface and the second communications interface are the same. 7. The method of claim 1 , wherein transmitting or receiving comprises transmitting or receiving in accordance with IEEE 802.15.4. 8. The method of claim 1 , wherein transmitting or receiving comprises transmitting or receiving in accordance with at least one of the following protocols: IEEE 802.11, Bluetooth, Zigbee, and FlashlinQ. 9. The method of claim 1 , wherein ascertaining, with the first communications device, in response to the first node-state signal, that the first communications device will make itself available as a relay for other communications devices in the multi-hop communications network via the second communications device further comprises the first communications device determining to make itself available as a relay based on at least three of the following: a value indicative of a cellular signal strength of cellular signals from a base-station at the first communications device; a value indicative of a cellular signal quality of cellular signals from the base-station at the first communications device; node-state signals received from other communications devices in the multi-hop communications network at the first communications device; a value indicative of a non-cellular signal strength of non-cellular signals from the second communications device at the first communications device; a value indicative of a non-cellular signal quality of non-cellular signals from the second communications device at the first communications device; a value indicative of a price for cellular service paid by a user associated with the first communications device; a value indicative of an amount of energy stored by the first communications device; a type of power source of the first communications device; a number of antennas coupled to a cellular-interface of the first communications device; a value indicative of movement of the first communications device; a value indicative of the time of day; a value indicative of a number of hops between the second communications device and the first communications device; and a value indicative of an amount of available bandwidth for communication via the second communications device from the first communications device. 10. The method of claim 1 wherein the first node-state signal comprises data indicative of at least two of the following: the availability of the second communications device as a sink; a signal strength of cellular signals from a base-station at the second communications device; a signal quality of cellular signals from the base-station at the second communications device; an identity of a cellular network carrier operating the base-station; a number of antennas coupled to a cellular-interface of the second communications device; a number of hops; an amount of available bandwidth for communication via the second communications device; movement of the second communications device; a type of power source of the second communications device; and a non-cellular transmit power of the second communications device. 11. The method of claim 1 , wherein the second node-state signal comprises data indicative of at least two of the following: the availability of the first communications device as a relay; a signal strength of cellular signals from a base-station at the second communications device; a signal quality of cellular signals from the base-station at the second communications device; an identity of a cellular network carrier operating the base-station; a number of antennas coupled to a third communications interface of the second communications device; a number of hops between the second communications device and the first communications device; an amount of available bandwidth for communication via the second communications device from the first communications device; movement of the first communications device; a type of power source of the first communications device; and a non-cellular transmit power of the first communications device. 12. The method of claim 1 , wherein the first communication device comprises: a processor; memory; a display screen; an operating system; and a cellular radio configured with access to a cellular network. 13. The meth