Missile system with navigation capability based on image processing

What is claimed is: 1. A missile system comprising: (a) a missile; (b) a seeker located at a nose portion of said missile, said seeker including an electro-optic imaging sensor; and (c) a control arrangement for steering the missile along a flight path to a target, said control arrangement comprising: (i) a tracking subsystem receiving images from said imaging sensor, said tracking system configured to track a target in said, images and to determine a tracked target direction, and (ii) a guidance subsystem operable to steer the missile towards the tracked target based on a guidance algorithm on the basis of said tracked target direction, characterized in that the missile system further comprises: (d) a navigation subsystem receiving images from said imaging sensor, said navigation subsystem being configured to: (i) co-process a plurality of said images from said imaging sensor to derive ego-motion of said missile relative to a region viewed by said imaging sensor; (ii) derive from said ego-motion a calculated target direction from said missile to a target. 2. The missile system of claim 1 , wherein said seeker further comprises a gimbal arrangement supporting said imaging sensor so as to be movable relative to a body of said missile. 3. The missile system of claim 1 , wherein said navigation subsystem is further configured to: (a) determine from said ego-motion an object-distance corresponding to a distance from the missile to an object appearing in an image from said imaging sensor along the direction-to-target; (b) determine a target-distance corresponding to a distance from a current position of the missile to the target; and (c) compare said object-distance with said target-distance to determine whether the target is obscured. 4. The missile system of claim 1 , further comprising a remote operator station including a display, an operator input device and components of a communication subsystem for communicating with components of a communication subsystem within said missile, said remote operator station receiving and displaying images from said imaging sensor, and receiving control inputs via said operator input device for modifying operation of said missile. 5. The missile system of claim 4 , wherein said navigation subsystem is configured to generate a visual prompt for display on said display, said visual prompt being derived from said calculated target direction, to facilitate identification of a target by the operator. 6. The missile system of claim 4 , wherein said navigation subsystem is further configured to generate a boundary of a region of uncertainty around a target location for display on said display. 7. The missile system of claim 1 , wherein said navigation subsystem further comprises a data storage device for storing, prior to launch of said missile, data corresponding to: (a) coordinates of a geographical location of the missile; (b) orientation angles of the missile; and (c) coordinates of a target location. 8. The missile system of claim 7 , wherein said data storage device further stores data corresponding to a range to a location corresponding to a pixel within an image sampled by said imaging sensor prior to launch. 9. The missile system of claim 1 , wherein said missile is configured to operate without an onboard inertial navigation system and without onboard satellite positioning signal sensors. 10. The missile system of claim 1 , further comprising components of a communications subsystem located in said missile and configured for transmitting images from said imaging sensor for display to a remote operator and receiving control inputs from the remote operator for modifying operation of said missile. 11. A method for operating a guided missile having a seeker including an electro-optic imaging sensor, the method comprising the steps of: (a) receiving a dataset defining a position of a target relative to the launching position and launching orientation of the missile, and data indicative of an ego-motion scaling factor; (b) from launch during flight of the missile, performing ego-motion processing on a plurality of image frames from the imaging sensor of the seeker so as to derive a position of the missile; (c) deriving a calculated target direction from a current position of the missile to the target, and (d) during at least part of the flight of the missile: (i) applying tracking algorithms to a sequence of images from the imaging sensor to track a target; and (ii) steering the missile towards the target tracked by said tracking algorithms. 12. The method of claim 11 , wherein the plurality of images are derived from a gimbaled imaging sensor. 13. The method of claim 11 , further comprising: (a) determining from said ego-motion processing an object-distance corresponding to a distance from the missile an object appearing in an image from said imaging sensor along the calculated target direction; (b) determining a target-distance corresponding to a distance from the position of the missile to the target; and (c) comparing said object-distance with said target-distance to determine whether the target is obscured. 14. The method of claim 11 , further comprising displaying images from said imaging sensor to a remote operator and receiving control inputs via an operator input device for modifying operation of said missile. 15. The method of claim 14 , further comprising generating a visual prompt for display to the remote operator, said visual prompt being derived from said calculated target direction, to facilitate identification of a target by the operator. 16. The method of claim 14 , further comprising generating a boundary of a region of uncertainty around a target location for display to a remote operator. 17. The method of claim 11 , wherein said dataset includes: (a) coordinates of a geographical location of the missile; (b) orientation angles of the missile; and (c) coordinates of a target location. 18. The method of claim 11 , wherein said data sufficient to determine an ego-motion scaling factor comprises a range to a location corresponding to a pixel within an image sampled by the imaging sensor prior to launch. 19. The of claim 11 , wherein the missile is configured to operate without an onboard inertial navigation system and without onboard satellite positioning signal sensors.