Commercial and General Aircraft Avoidance using Multi-spectral wave detection

What is claimed is: 1 . A method, comprising: generating multispectral signals, by one or more multispectral sensors of an unmanned aerial vehicle (UAV), from a spectrum of electromagnetic waves reflected or emitted from a flying object; determining one or more characteristic features of the multispectral signals; identifying the flying object based at least in part on a comparison of the one or more characteristic features to a database of known signal features; associating performance parameters with the flying object using a look-up table that includes unique performance parameters for at least one of a plurality of flying objects or class of flying objects; determining an approximate location and an approximate airspeed of the flying object based at least in part on the multispectral signals; determining a trajectory envelope for the flying object based at least in part on the approximate location, the approximate airspeed and the associated performance parameters; and updating a flight plan for the UAV based at least in part on the trajectory envelope of the flying object. 2 . The method of claim 1 , wherein the multispectral signals are comprised of a defined band from within the spectrum. 3 . The method of claim 2 , wherein the defined band is determined at least in part on the likelihood of a particular object being present in the UAV's airspace, the particular object having a known spectral signature. 4 . The method of claim 1 , wherein the characteristic features include at least one of object composition, one or more object surface coatings, one or more object surface finishes, or a color characteristic. 5 . The method of claim 1 , further comprising processing the multispectral signals using a beamformer to create beamformed multispectral signals prior to determining the approximate location and the approximate airspeed of the flying object, and wherein the determining the approximate location and the approximate airspeed of the flying object is performed using the beamformed multispectral signals. 6 . An unmanned aerial vehicle (UAV), comprising: one or more processors; memory to store computer-readable instructions; one or more multispectral sensors coupled to the unmanned aerial vehicle (UAV), the one or more multispectral sensors to generate multispectral signals from electromagnetic energy reflected or emitted by an object within an airspace at least partially surrounding the UAV; and a flight management component stored within the memory that, when executed, causes the one or more processors to: detect, from the multispectral signals, an object in the airspace at least partially surrounding the UAV; determine, based at least in part on an analysis of the multispectral signals, one or more operating characteristics associated with the object; determine a trajectory envelope for the object based at least in part on the one or more operating characteristics. 7 . The UAV of claim 6 , further comprising an acoustic sensor to capture acoustic energy emitted or reflected by the object, the flight management component causing the one or more processors to: detect, from a signal representing the captured acoustic energy, the object in the airspace at least partially surrounding the UAV; and determine, from the signal representing the captured acoustic energy, one or more different operating characteristics associated with the object based at least in part on a fingerprint associated with the signals representing the captured, wherein the determining the trajectory envelope is further based at least in part on the one or more different operating characteristics. 8 . The UAV of claim 6 , wherein the fight management component, when executed, further causes the one or more processors to: determine the likelihood of interaction between the UAV and the trajectory envelope associated with the object; and update a UAV flight plan to avoid interaction between the UAV and the trajectory envelope. 9 . The UAV of claim 6 , further comprising an optical sensor to capture signals providing a visual representation of at least part of the airspace, and the flight management component causing the one or more processors to: detect, from the signals, an object present in the airspace; determine, from the images, one or more additional operating characteristic associated with the object; and wherein determining a trajectory envelope associated with the object is based at least in part on the one or more operating characteristics. 10 . The UAV of claim 6 , further comprising a communication component to create a peer-to-peer network with one or more nearby UAVs, the communication component configured to exchange at least one of the multispectral signals, the identity of the object, or the trajectory envelope of the object with the one or more nearby UAVs. 11 . The UAV of claim 10 , where the flight management component is further configured to determine an approximate location and approximate airspeed of the object based at least in part on information exchanged from at least one of the one or more nearby UAVs using triangulation. 12 . The UAV of claim 6 , wherein the performance parameters are stored in a database and include at least a rate of climb, a rate of decent, and a maneuverability parameter associated with each of various objects. 13 . The UAV of claim 6 , further comprising at least one of an acoustic sensor to produce one or more acoustic signals or an optical sensor to produce one or more image signals and wherein the identity of the object is determined from at least one of the multispectral signals, the acoustic signals, or the optical signals. 14 . The UAV of claim 6 , further comprising determining, based at least in part on an analysis of the multispectral signals, an identity of the object associated with the multispectral signals. 15 . An object detection and avoidance system comprising: one or more processors; and memory storing computer-executable instructions that, when executed, cause the one or more processors to perform acts comprising: identifying an object based upon multispectral signals captured from electromagnetic energy emitted from the object; determining performance parameters for the object based at least in part on the identifying of the object; and determining a trajectory envelope of the object based at least in part on the performance parameters. 16 . The object detection and avoidance system of claim 15 , wherein the acts further comprise updating a flight plan for a UAV based at least in part on a probability of interaction between the UAV and the trajectory envelope of the object. 17 . The object detection and avoidance system of claim 15 , wherein identifying the object includes matching the one or more characteristic features of the multispectral signals with signal features stored in a database that associates individual signal features with respective objects or groups of objects. 18 . The object detection and avoidance system of claim 15 , further comprising determining an approximate airspeed of the object based at least in part on changes in the multispectral signals over a predetermined period of time. 19 . The object detection and avoidance system of claim 18 , wherein the trajectory envelope is formed using a scalable volume that is scaled based in least in part on the approximate airspeed and performance parameters of the object. 20 . The object detection and avoidance system of claim 15 , further compri