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An energy efficient MAC protocol for a sensor network that extends the battery life of remotely located wireless nodes by employing MAC operations involving transmission of a wake-up signal with more processing gain, dynamic adjustment of a transmission rate of synchronization messages for fast time

An energy efficient MAC protocol for a sensor network that extends the battery life of remotely located wireless nodes by employing MAC operations involving transmission of a wake-up signal with more processing gain, dynamic adjustment of a transmission rate of synchronization messages for fast time synchronization and an energy efficient neighboring node discovery technique.

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What is claimed is: 1. A method of waking up sensor nodes in a wireless mobile ad hoc sensor network, comprising: a. initiating formation of a wireless mobile ad hoc sensor network by wirelessly broadcasting a single wake-up signal one time by a first sensor node with at least one parameter that in

What is claimed is: 1. A method of waking up sensor nodes in a wireless mobile ad hoc sensor network, comprising: a. initiating formation of a wireless mobile ad hoc sensor network by wirelessly broadcasting a single wake-up signal one time by a first sensor node with at least one parameter that increases a processing gain of the wake-up signal to make it more likely to be received by other sensor nodes which prior to reception of the wake-up signal in an isolated state unaware of other sensors nodes or the existence of a network; b. receiving the wake-up signal from the first sensor node at at least a second sensor node, and in response thereto, the second node entering a wake-up state; and c. in response to the second node entering the wake-up state, said second sensor node rebroadcasting the wake-up signal to wake-up other isolated sensor nodes prior to the second sensor node switching to a higher power consumption receiver to receive a synchronization message from the first sensor node. 2. The method of claim 1, and further comprising delaying rebroadcasting of the wake-up signal by a period of time substantially equal to a sum of a transmission duration of the wake-up signal transmitted by the first node and random period of time. 3. The method of claim 2, wherein receiving comprises receiving the wake-up signal at a plurality of remote sensor nodes that are in an isolated state, each of which, in response thereto, enters a wake-up state, and rebroadcasts the wake-up signal to wake-up other remote sensor nodes that are in an isolated state. 4. The method of claim 1, wherein wirelessly broadcasting comprises transmitting the single wake-up signal with the at least one parameter that comprises one or more of a bit rate, chip rate and bandwidth, to increase the processing gain of the wake-up signal. 5. The method of claim 1, wherein wirelessly broadcasting comprises transmitting the single wake-up signal from the first node that is not power source limited. 6. The method of claim 1, wherein wirelessly broadcasting the single wake-up signal from the first sensor node comprises combining at least two pseudo-noise (PN) sequences into the single wake-up signal and transmitting the single wake-up signal at a frequency channel related to a first of the PN sequences. 7. A method for synchronizing nodes that have been placed in a wake-up state according to the method of claim 1, comprising transmitting synchronization messages from a synchronized sensor node to other sensor nodes that are not synchronized, wherein transmitting comprises transmitting the synchronization messages at a periodic transmission rate that is based on one or more factors including: and a number of node hops between a synchronized node and a certain node; a remaining available power level of the synchronized node; and a number of a synchronization message previously transmitted by the synchronized node in a current network synchronization sequence. 8. The method of claim 7, wherein a particular sensor node serves as an upstream sensor node through which data from other sensor nodes is transmitted for retransmission to master node based on the one or more factors associated with the particular sensor node. 9. The method of claim 8, wherein transmitting comprises transmitting the synchronization message from the particular sensor node at a faster periodic transmission rate than would be transmitted by other sensor nodes. 10. A method of discovering nodes in the wireless communication network that have been synchronized according to the method of claim 7, comprising: a. determining a level of remaining available power at a particular sensor node; b. selecting a transmission rate at which to transmit node discovery messages from the particular sensor node as a function of the level of remaining available power; and c. transmitting node discovery messages from the sensor node according to the selected transmission rate. 11. The method of claim 10, wherein transmitting node discovery messages comprises transmitting request-to-send (RTS) messages to other nodes in expectation of receiving an acknowledgment message from a node that receives it. 12. The method of claim 11, and further comprising receiving the node discovery messages at a particular sensor node and in response transmitting the acknowledgment message, wherein the particular sensor node that receives the node discovery message knows that the node that transmitted the node discovery message is a downstream node that wishes to join the wireless communication network. 13. The method of claim 12, and further comprising, in response to receiving the acknowledgment message, the node that transmitted the node discovery message joining the wireless communication network by transmitting a synchronization message to other nodes in the wireless communication network. 14. A moble ad hoc wireless sensor network comprising: a. a central node that wirelessly broadcasts a single wake-up signal one time with at least one parameter that increases the processing gain of the wake-up signal to make the single wake-up signal more likely to be detected by other sensor nodes when said central sensor node initiates formation of a moble ad hoc wireless sensor network; and b. a plurality of remote nodes that collect data and transmit the data to the central node, wherein when a remote node receives the wake-up signal from the central node it enters a wake-up state from an isolated state when it is unaware of other sensor nodes of the existence of a network and rebroadcasts the wake-up signal to wake-up other isolated sensor nodes prior to switching to a higher power consumption receiver to receive a synchronization message. 15. The wireless communication network of claim 14, wherein the centralsensor node transmits the single wake-up signal with one or more of a bit rate, bandwidth, chip rate that increases the processing gain of the wake-up signal. 16. The wireless communication network of claim 15, wherein the central node combines at least two pseudo-noise (PN) sequences into the single wake-up signal and transmits the single wake-up signal at a frequency channel related to a first of the PN sequences. 17. The wireless communication network of claim 14, wherein the remote nodes adaptively select a transmission rate at which synchronization messages are to be transmitted to other nodes, the transmission rate being selected as a function of one or more factors including: a number of node hops between the remote sensor node and the central sensor node; a remaining available power level of the remote node; and a number of synchronization message previously transmitted by the remote sensor node in a current network synchronization sequence. 18. The wireless communication network of claim 17, wherein a particular remote node serves as an upstream sensor node through which data from other remote nodes is transmitted for retransmission to the central sensor node based on the one or more factors associated with the particular remote node. 19. The wireless communication network of claim 14, wherein a remote node discovers other remote nodes in the wireless communication network by determining a level of its remaining available power; selecting a transmission rate at which to transmit node discovery messages as a function of the level of remaining available power; and transmitting node discovery messages according to the selected transmission rate.