System and method for navigation and targeting in GPS-challenged environments using factor graph optimization

We claim: 1. A method for aircraft-based targeting in global positioning system (GPS)-challenged airspaces, the method comprising: navigating at least one trajectory, via an aircraft, through a GPS-challenged airspace; sensing, via the aircraft, one or more observable signals corresponding to at least one target, wherein the one or more observable signals are associated with targeting information including at least one of: GPS-challenged targeting information associated with sensing while the aircraft is within the GPS-challenged airspace; or subsequent targeting information associated with sensing subsequent to exiting the GPS-challenged airspace, each subsequent targeting information associated with an absolute position of the aircraft; determining, via an inertial reference system (IRS) of the aircraft, one or more state vectors of the aircraft associated with each sensing, the one or more state vectors including at least one of: a GPS-challenged state vector associated with sensing while the aircraft is within the GPS-challenged airspace; or a subsequent state vector associated with sensing subsequent to exiting the GPS-challenged airspace, each subsequent state vector relative to an absolute position of the aircraft; storing, via a memory of the aircraft, the one or more state vectors and the targeting information associated with each sensing; and determining, via a navigation and targeting system of the aircraft, at least one targeting solution corresponding to a location of the at least one target via factor graph optimization of the targeting information and the one or more state vectors based on the plurality of subsequent absolute positions. 2. The method of claim 1 , wherein determining, via an inertial reference system (IRS) of the aircraft, one or more state vectors of the aircraft associated with each sensing includes determining one or more of: a relative position of the aircraft, the relative position relative to at least one of 1) a prior absolute position of the aircraft or 2) a prior relative position of the aircraft; an orientation of the aircraft, the orientation including one or more of a pitch angle, a roll angle, or a heading angle; or an altitude of the aircraft. 3. The method of claim 2 , determining, via an inertial reference system (IRS) of the aircraft, one or more state vectors of the aircraft associated with each sensing includes determining at least one rate of change associated with one or more of the relative position or the orientation. 4. The method of claim 1 , wherein sensing, via the aircraft, one or more observable signals corresponding to at least one target includes: sensing one or more of a received radio frequency (RF) signal, an observed RF emission, or an observed electro-optical infrared (EO/IR) emission via one or more passive sensors of the aircraft. 5. The method of claim 1 , wherein sensing, via the aircraft, one or more observable signals corresponding to at least one target includes: transmitting, via the aircraft, one or more of a signal or a beam; wherein the one or more observable signals are associated with a reflection by the target of the transmitted signal or beam. 6. The method of claim 1 , further comprising: transmitting, via the aircraft, at least one ranging signal; receiving, via the aircraft, a response to the at least one ranging signal from at least one ground station corresponding to a known location; determining, via the targeting system, at least one of a distance or a direction between the aircraft and the at least one ground station via two-way timing and ranging (TWTR); wherein determining, via the targeting system, at least one targeting solution includes determining the at least one targeting solution via factor graph optimization based on the at least one distance or direction. 7. The method of claim 1 , wherein the aircraft is a first aircraft, the one or more state vectors are first state vectors, the targeting information is first targeting information, and the plurality of subsequent absolute positions is a first plurality of subsequent absolute positions, further comprising: receiving, subsequent to exiting the GPS-challenged airspace, one or more second state vectors from at least one second aircraft, the one or more second state vectors including GPS-challenged state vectors and subsequent state vectors corresponding to the at least one second aircraft; receiving, subsequent to exiting the GPS-challenged airspace, second targeting information from the at least one second aircraft, the second targeting information including GPS-challenged targeting information and subsequent targeting information corresponding to the at least one second aircraft; receiving, subsequent to exiting the GPS-challenged airspace, one or more second subsequent absolute positions from the at least one second aircraft; and determining at least one vector between the first aircraft and the at least one second aircraft via two-way timing and ranging (TWTR), the at least one vector associated with one or more of a direction or a distance; wherein determining, via the targeting system, at least one targeting solution corresponding to a location of the at least one target via factor graph optimization of the targeting information and the one or more state vectors based on the plurality of subsequent absolute positions includes: determining the at least one targeting solution via factor graph optimization of the first and second target information and the one or more first and second state vectors based on the plurality of first and second subsequent absolute positions and the at least one vector. 8. The method of claim 7 , wherein the at least one second aircraft comprises two or more second aircraft, wherein the target is a non-stationary target associated with more than one target location, and wherein: receiving the one or more second state vectors from the at least one second aircraft includes determining at least one relative position of the target based on a first GPS-challenged first state vector and the associated one or more second GPS-challenged second state vectors; and determining, via the targeting system, at least one targeting solution corresponding to the target location includes determining vector information corresponding to a trajectory of the target. 9. The method of claim 1 , wherein: the at least one trajectory is associated with a sequence of GPS-challenged positions associated with each sensing within GPS-challenged airspace; and determining, via the targeting system, at least one targeting solution corresponding to a location of the at least one target via factor graph optimization of the targeting information and the one or more state vectors based on the plurality of subsequent absolute positions includes: determining, via the targeting system, at least one precision navigation solution corresponding to the aircraft by refining position information corresponding to one or more GPS-challenged positions. 10. An aircraft configured for entering and exiting at least one GPS-challenged airspace, comprising: at least one sensor configured to sense one or more observable signals corresponding to at least one target, the one or more observable signals are associated with targeting information including at least one of: GPS-challenged targeting information associated with at least one GPS-challenged sensing while the aircraft is navigating at least one trajectory through a GPS-challenged airspace; or subsequent targeting information associated with at least one sensing subsequent to the aircraft exiting the GPS-challenged airspace, each subsequent targeting information associated with a