Link maintenance in point-to-point wireless communication networks

We claim: 1. A wireless communication network, comprising: a transmitting node and a receiving node configured to transmit and receive packets between the transmitting node and the receiving node through one or more of a plurality of predetermined micro-routes, wherein each of the plurality of predetermined micro-routes is determined by a transmit beamforming direction and a receive beamforming direction, and wherein each of the plurality of predetermined micro-routes includes a single wireless hop link between the transmitting node and the receiving node with no intermediate nodes; wherein the transmitting node is configured to: retrieve a first micro-route of the plurality of predetermined micro-routes; transmit packets in a first transmit beamforming direction associated with the first micro-route between the transmitting node and the receiving node; transmit packets including one or more training signals in a second transmit beamforming direction associated with a second micro-route of the plurality of predetermined micro-routes that is different than the first transmit beamforming direction associated with the first micro-route; and receive feedback from the receiving node indicating that the second micro-route corresponding with a transmit/receive beamforming pair of the second transmit beamforming direction and a second receive beamforming direction provides a better communication link than a transmit/receive beamforming pair of the first transmit beamforming direction and a first receive beamforming direction of the first micro-route, wherein the receiving node decodes a header of a packet received from the transmitting node, and determines a number of training signals included within the packet, and a number of receive beamforming directions of the receiving node for the number of training signals. 2. The wireless communication network of claim 1 , wherein the transmitting node is further configured to change a transmit beamforming direction of the transmitting node to the second transmit beamforming direction associated with the second micro-route. 3. The wireless communication network of claim 1 , further comprising the transmitting node adaptively transmitting packets that include one or more training signals in different transmit beamforming directions based on at least one of a link quality between the transmitting node and the receiving node, a detected change in an environmental condition of the wireless communication network, a detected change in packet traffic of the wireless communication network, or a monitored condition of the wireless communication network. 4. The wireless communication network of claim 1 , wherein a transmit packet includes a plurality of training signals, and wherein the transmitting node is further configured to: retrieve two or more micro-routes of the plurality of predetermined micro-routes; transmit a first training signal of the plurality of training signals within the transmit packet in a first transmit beamforming direction associated with a first micro-route; transmit a second training signal of the plurality of training signals within the transmit packet in a second transmit beamforming direction associated with a second micro-route; receive feedback from the receiving node indicating a communication link quality corresponding with one or more of a transmit/receive beamforming pair of the first transmit beamforming direction and a first receive beamforming direction, a transmit/receive beamforming pair of the second transmit beamforming direction and a second receive beamforming direction. 5. The wireless communication network of claim 4 , wherein the transmitting node is further configured to: receive feedback from the receiving node indicating a communication link quality corresponding with one or more of a transmit/receive beamforming pair of the second transmit beamforming direction and the first receive beamforming direction, a transmit/receive beamforming pair of the second transmit beamforming direction and the second receive beamforming direction. 6. The wireless communication network of claim 1 , wherein the transmitting node is further configured to: transmit a training packet a plurality of times in a single transmit beamforming direction; receive feedback from the receiving node indicating detection of reception of the training packet in at least one of a plurality of receive beamforming directions. 7. The wireless communication network of claim 1 , wherein the transmitting node is further configured to: transmit a training packet in a plurality transmit beamforming direction; receive feedback from the receiving node indicating detection of reception of the training packet in a single receive beamforming direction for one or more of the plurality of transmit beamforming directions. 8. The wireless communication network of claim 1 , wherein the transmitting node is further configured to: transmit a first training signal of the plurality of training signals within the at least one transmit packet in a first fined-tuned direction of a transmit beamforming direction associated with a micro-route, wherein the first fine-tune direction deviates a direction of the transmit beamforming direction by a first threshold; transmit a second training signal of the plurality of training signals within the at least one transmit packet in a second fine-tuned direction of the transmit beamforming direction associated with the micro-route, wherein the second fine-tune direction deviates a direction of the transmit beamforming direction by a second threshold; receive feedback from the receiving node indicating a communication link quality corresponding with one or more of first fine-tuned direction of the transmit beamforming direction or the second fine-tuned direction of the transmit beamforming direction. 9. The wireless communication network of claim 1 , wherein at least one of a central controller or a controller of the transmitting node is operative to: determine the plurality of predetermined micro-routes comprising: characterizing a plurality of micro-routes between the transmitting node and the receiving node; and storing the characterized plurality of micro-routes. 10. The wireless communication network of claim 9 , wherein characterizing the plurality of micro-routes between the transmitting node and the receiving node, comprises the upstream controller operative to: direct a first beam formed by a plurality of antennas of the transmitting node to a plurality of directions; for each of the plurality of directions of the first beam, direct a second beam formed by a plurality of antennas of the receiving nodes to a plurality of directions; characterize a link quality between the transmitting node and the receiving node for each of the plurality of beam directions of the first beam and each of the plurality of beam directions of the second beam. 11. A method, comprising: transmitting, by a transmitting node, transmit packets, and receiving, by a receiving node, receive packets between the transmitting node and the receiving node through one or more of a plurality of predetermined micro-routes, wherein each the plurality of predetermined micro-routes is determined by a transmit beamforming direction and a receive beamforming direction, and wherein each of the plurality of predetermined micro-routes includes a single wireless hop link between the transmitting node and the receiving node with no intermediate nodes; retrieving, by the transmitting node, a first micro-route of the plurality of predetermined micro-routes; transmitting, by the transmitting node, packets in a first transmit beamforming direction associated with