Wireless communication systems for underground pipe inspection

What is claimed is: 1. Wireless communication system for underground pipeline inspection comprising: a plurality of sensor nodes moved by robots within the pipeline, each sensor node including a sensor node radio transceiver; a plurality of spaced apart, above ground relay nodes deployed along the pipeline, each relay node including a relay node radio transceiver having a communications range for communication with the sensor nodes wherein each relay node switches from a low duty cycle mode to an active state when a sensor node enters the communications range of said each relay node and then switches back to the low duty cycle mode when the sensor node moves out of the communications range of said each relay node; and a remote monitoring center in communication with the relay nodes, for receiving information of a leak detected by a sensor node. 2. The system of claim 1 wherein each sensor node further includes a microcontroller, an accelerometer and a timer. 3. The system of claim 1 wherein the remote monitoring center is in communication with the plurality of relay nodes through a mobile communications network. 4. The system of claim 1 wherein the mobile in-pipe sensor nodes detect the leak through acoustic or pressure effects, conduct on-board signal processing, and send the extracted leak detection information to the above ground relay nodes via a low-frequency radio transceiver, and wherein the selection of the radio frequency takes into account the data rate, the antenna size, and the signal attenuation in multiple transmission media, including the in-pipe water, plastic pipe body, soil, and air. 5. The system of claim 1 wherein the relay nodes send the received leak detection information from the sensor nodes to the remote monitoring center using the high-frequency radio transceiver via an aboveground mobile network. 6. The system of claim 1 wherein the aboveground mobile network can be a cellular network, a WiFi network, a WiMAX network, or a satellite network. 7. The system of claim 1 wherein the remote monitoring center sends control commands to the relay nodes via an above ground mobile network, and wherein the relay nodes forward the control commands to the sensor nodes via low-frequency radio transceivers. 8. The system of claim 1 wherein the sensor nodes can also perform onboard robot control without control commands from the remote monitoring center. 9. The system of claim 1 for a seamless handover between two neighboring relay nodes initiated by a current active relay node comprising: the current active relay node detecting that an RSSI value decreases to a threshold, and/or the current active relay node detecting that the distance between the relay node and the sensor node increases to a threshold; waking a neighboring relay node up and putting it into active status. 10. The system of claim 1 for a seamless handover between two neighboring relay nodes initiated by the mobile sensor node comprising: the sensor node detecting that a RSSI value decreases to a threshold, and the sensor node detecting that the distance between the sensor node and the relay node increases to a threshold; the sensor node sending the relay node a handover request; the relay node relaying the handover request and beginning the handover process. 11. The system of claim 1 in which the relay nodes deal with a sensor node moving at a high speed comprising; the current relay node waking its neighboring relay node up and putting it into active status after detecting that a mobile sensor node has established a communication link with the current relay node; the remote monitoring center sending an updated duty cycle configuration to the relay nodes based on the sensor node's moving speed; and the relay nodes performing onboard duty cycle configuration based on the sensor node's moving speed. 12. The system of claim 1 wherein an active relay node decides a sensor node's global position and movement direction comprising: the relay node telling its global position by an installed GPS receiver; the relay node determining the pipeline distance between the relay node and the sensor node by evaluating the received RSSI values from the sensor node; the relay node determining the moving direction of the sensor node by checking the received readings from an accelerometer installed in the sensor node; the relay node determining more accurate position of the sensor node by combining the RSSI values, the last handover record, and the outputs of the accelerometer and the timer from the sensor node; and the relay node calculating the sensor node's global position by combining the relay node's global position and the sensor node's location relative to the relay node. 13. The system of claim 1 wherein a sensor node decides its global position comprising: the relay node sending its global position from an installed GPS receiver to the sensor node; the sensor node determining the pipeline distance between the sensor node and the relay node by evaluating the received RSSI values from the relay node; the sensor node determining its more accurate position by combining the received RSSI values, and the outputs of the accelerometer and the timer installed in the sensor node; the sensor node calculating its global position by combining the received relay node's global position and the sensor node's location relative to the relay node. 14. The system of claim 1 for reliably and timely delivering the leak detection information from a sensor node to the remoter monitoring center comprising: a sensor node performing real-time onboard data processing and extracting useful information; the sensor node packetizing the information with error detection and correction fields, sending out the resulting packets, and waiting for ACKs from the relay nodes; the sensor node retransmitting the packet immediately if failing to receive the corresponding ACK; the sensor node buffering the leak detection information in its memory if no communication link with any relay node is available, and sending out the information immediately whenever a communication link is available. 15. The system of claim 1 for time synchronization between an in-pipe sensor node and a relay node comprising: a relay node retrieving a timestamp from the installed GPS receiver, and the relay node periodically transmitting a time beacon to inform an in-pipe sensor node of the timestamp.