Roll-biased skid-to-turn terminal guidance with rudder integrator feedback

What is claimed is: 1. An aircraft autopilot guidance control system for guiding an aircraft having a body, the system comprising: a processor configured to determine if a yaw angle difference and a pitch angle difference meet corresponding angle thresholds; a skid-to-turn module configured to generate a skid-to-turn signal if the corresponding angle thresholds are met; a bank-to-turn module configured to generate a bank-to-turn signal having a lower bandwidth than the generated skid-to-turn signal; a rudder integrator module configured to add a rudder integrator feedback signal to the bank-to-turn signal, wherein the rudder integrator feedback signal is proportional to a rudder integrator; and a filter module configured to filter the generated bank-to-turn signal, wherein the filter module comprises a low-pass filter configured by a set of gains to pass the bank-to-turn signal if a side force on the body meets a side force threshold. 2. The system of claim 1 , wherein the processor is further configured to: receive a body to target line of sight signal, receive a line of sight rate signal, and determine the yaw angle difference and the pitch angle difference based on the body to target line of sight signal and the line of sight rate signal. 3. The system of claim 2 , wherein: the skid-to-turn module further comprises a loop for implementing the skid-to-turn signal; the rudder integrator module further comprises a rudder integrator feedback gain configured to receive an output from the loop for implementing the skid-to-turn signal; and the bank-to-turn module further comprises a loop for implementing the bank-to-turn signal configured to receive an output from the rudder integrator feedback gain. 4. The system of claim 3 , wherein the loop for implementing the skid-to-turn signal further comprises: a body side specific force command module; a skid-to-turn steady state gain configured to receive a signal from the body side specific force command module; a skid-to-turn acceleration error summing junction configured to receive a signal from the skid-to-turn steady state gain; a skid-to-turn acceleration error gain configured to receive a signal from the skid-to-turn acceleration error summing junction; a skid-to-turn rate error command summing junction configured to receive a signal from the skid-to-turn acceleration error gain; a skid-to-turn rate error integrator gain configured to receive a signal from the skid-to-turn rate error command summing junction; a rudder integrator module configured to receive a signal from the skid-to-turn rate error integrator gain; a skid-to-turn rate error summing block configured to receive a signal from the rudder integrator module; a skid-to-turn rudder command control gain configured to receive a signal from the skid-to-turn rate error summing block; and a skid-to-turn rudder command dynamic pressure scaling gain configured to receive a signal from the skid-to-turn rudder command control gain. 5. The system of claim 4 , wherein the rudder integrator feedback gain is configured to receive the signal from the rudder integrator module, and wherein the rudder integrator feedback gain is configured to generate a rudder integrator signal. 6. The system of claim 5 , wherein the loop for implementing the bank-to-turn signal further comprises: a roll angle command module; an augmented bank-to-turn signal generated based on a signal from the roll angle command module and the generated rudder integrator signal; a main filter module configured to receive the augmented bank-to-turn signal; a roll angle error summing junction configured to receive a signal from the main filter module; a roll angle error proportional gain configured to receive a signal from the roll angle error summing junction; a roll rate command proportional and integral summing junction configured to receive a signal from the roll angle error proportional gain; a roll angle error integral gain configured to receive a signal from the roll angle error summing junction; a roll angle error integrator configured to receive a signal from the roll angle error integral gain; a roll rate error summing junction configured to receive a signal from the roll angle error integrator, a signal from the roll rate command proportional and integral summing junction, and a signal from a roll rate feedback gain; and a roll aileron command dynamic pressure scaling gain configured to receive a signal from the roll rate error summing junction. 7. The system of claim 6 , wherein the roll angle command module further comprises the low-pass filter. 8. The system of claim 6 , wherein the roll angle command module is configured to set to a non-zero value for generating the bank-to-turn signal with a lower bandwidth than the skid-to-turn signal generated by the body side specific force command module. 9. The system of claim 6 , wherein the main filter module is configured to decouple the loop for implementing the bank-to-turn signal and the loop for implementing the skid-to-turn signal. 10. The system of claim 6 , wherein a low-pass filter of the main filter module is configured to ensure that the bank-to-turn signal has lower bandwidth than the skid-to-turn signal. 11. The system of claim 6 , wherein the processor is further configured to: generate one or more actuator commands; and output the one or more actuator commands to vehicle plant dynamics. 12. The system of claim 11 , wherein the vehicle plant dynamics comprise: a skid-to-turn rudder actuator transfer function model configured to receive a signal from the skid-to-turn rudder command dynamic pressure scaling gain; a roll aileron actuator transfer function model configured to receive a signal from the roll aileron command dynamic pressure scaling gain; and a vehicle lateral dynamics state-space model configured to receive a signal from the skid-to-turn rudder actuator transfer function model and a signal from the roll aileron actuator transfer function model. 13. The system of claim 12 , wherein the system further comprises: one or more optical sensors, wherein the one or more optical sensors are configured to generate the body to target line of sight. 14. The system of claim 13 , wherein the system further comprises: one or more differentiators, wherein the one or more differentiators are configured to generate the line of sight rate. 15. The system of claim 14 , wherein the generated line of sight rate comprises differentiation of a line-of-sight vector expressed in an inertial frame. 16. The system of claim 15 , wherein the system further comprises: one or more side force optimizers, wherein the one or more side force optimizers are configured to provide the side force threshold to the processor. 17. The system of claim 16 , wherein the side force threshold is selected through optimization and set prior to a flight. 18. The system of claim 17 , wherein the system further comprises: one or angle threshold optimizers, wherein the one or angle threshold optimizers are configured to provide the angle thresholds to the processor. 19. The system of claim 17 , wherein the angle thresholds are selected through optimization and set prior to the flight.