Method and apparatus for broadcast communication via guided waves

What is claimed is: 1. A broadcast communication system, comprising: a processing system that includes a processor; a guided wave transceiver that transmits and receives communications by electromagnetic waves at a physical interface of a transmission medium, wherein the electromagnetic waves are guided by the transmission medium and propagate without utilizing an electrical return path; a memory that stores executable instructions that, when executed by the processing system, facilitate performance of operations comprising: detecting a first power outage; generating a first plurality of the electromagnetic waves for transmission to a plurality of user devices of the broadcast communication system via the guided wave transceiver, wherein the first plurality of the electromagnetic waves includes an outage status signal generated in response to detecting the first power outage; predicting a second power outage by: determining a first power outage likelihood value; and comparing the first power outage likelihood value to a power outage likelihood threshold; and generating a second plurality of the electromagnetic waves for transmission to the plurality of user devices of the broadcast communication system via the guided wave transceiver, wherein the second plurality of the electromagnetic waves includes power outage warning data, and wherein the second plurality of the electromagnetic waves is generated in response to the first power outage likelihood value comparing unfavorably to the power outage likelihood threshold. 2. The broadcast communication system of claim 1 , wherein the broadcast communication system is physically attached to a first one of a plurality of power line phases of a power pole, and wherein the first power outage corresponds to a failure of a second one of the plurality of power line phases of the power pole. 3. The broadcast communication system of claim 2 , wherein the broadcast communication system further comprises a wireless transmitter and at least one of: a disturbance detection sensor, a loss of energy sensor, or a vibration sensor, wherein the second power outage corresponds to a failure of the first one of the plurality of power line phases, and wherein the second power outage is predicted based on a sensor input to the at least one of: the disturbance detection sensor, the loss of energy sensor, or the vibration sensor, and wherein the operations further comprise: generating a notification of the second power outage for transmission via the wireless transmitter. 4. The broadcast communication system of claim 1 , wherein the broadcast communication system further comprises a wireless transceiver, and wherein the operations further comprise: receiving a power outage notification via the wireless transceiver; wherein the first power outage is detected in response to receiving the power outage notification. 5. The broadcast communication system of claim 1 , wherein the broadcast communication system further comprises a wireless receiver, and wherein the operations further comprise: receiving at least one wireless transmission that includes utility status data from at least one utility provider via the wireless receiver; wherein the outage status signal is generated based on the utility status data. 6. The broadcast communication system of claim 5 , wherein the broadcast communication system further comprises a wireless transmitter, and wherein the operations further comprise: generating at least one status request for transmission via the wireless transmitter to the at least one utility provider in response to detecting the first power outage; wherein the at least one wireless transmission is received in response to the at least one status request. 7. The broadcast communication system of claim 1 , wherein the operations further comprise: receiving via the guided wave transceiver a third plurality of the electromagnetic waves that includes a power outage notification signal; wherein the first power outage is detected in response to receiving the power outage notification signal. 8. The broadcast communication system of claim 1 , wherein the operations further comprise: receiving at least one third plurality of the electromagnetic waves from at least one utility provider via the guided wave transceiver, wherein the at least one third plurality of electromagnetic waves includes utility status data, and wherein the outage status signal is generated based on the utility status data. 9. The broadcast communication system of claim 8 , wherein the operations further comprise: generating at least one fourth plurality of the electromagnetic waves that includes a status request signal for transmission via the guided wave transceiver to the at least one utility provider in response to detecting the first power outage; wherein the at least one third plurality of the electromagnetic waves is received in response to the status request signal. 10. The broadcast communication system of claim 1 , wherein the outage status signal includes message data for display by a subset of the plurality of user devices. 11. The broadcast communication system of claim 10 , wherein the message data corresponds to a message from a utility provider, wherein the operations further comprise: receiving a third plurality of the electromagnetic waves via the guided wave transceiver that includes a message response signal from one of the subset of the plurality of user devices corresponding to a user input to the one of the subset of the plurality of user devices; and transmitting the third plurality of the electromagnetic waves via the guided wave transceiver to the utility provider. 12. The broadcast communication system of claim 1 , wherein at least one of the plurality of user devices includes a home automation controller, and wherein the outage status signal includes at least one instruction for execution by the home automation controller. 13. The broadcast communication system of claim 1 , wherein the outage status signal includes at least one electric vehicle charging station location. 14. The broadcast communication system of claim 1 , wherein the operations further comprise: receiving a third plurality of the electromagnetic waves from a utility provider via the guided wave transceiver that includes planned maintenance data; and generating a fourth plurality of the electromagnetic waves for transmission to the plurality of user devices of the broadcast communication system via the guided wave transceiver, wherein the third plurality of the electromagnetic waves includes the planned maintenance data. 15. The broadcast communication system of claim 1 , wherein the broadcast communication system includes an environmental sensor, and wherein the first power outage likelihood value is based on a sensor input to the environmental sensor. 16. The broadcast communication system of claim 1 , wherein the first power outage likelihood value is determined at a first time; and wherein the operations further comprise: determining a second power outage likelihood value at a second time that is later than the first time; comparing the second power outage likelihood value to the power outage likelihood threshold; and generating a third plurality of the electromagnetic waves for transmission to the plurality of user devices of the broadcast communication system via the guided wave transceiver, wherein the third plurality of the electromagnetic waves indicates that a power outage warning has passed, and wherein the third plurality of the electromagnetic waves is generated in respons