Methods and systems useful in connection with multipath

I claim: 1. A method of generating a model of a wireless multipath environment, the method intermittently modifying operation of a cellular telephone system during normal service, the cellular telephone system including first and second cellular telephone stations, each cellular telephone station including an antenna array comprising N radiators equi-angularly spaced around a vertical pole, the method comprising the acts: (a) during normal service of said cellular telephone system, temporarily changing a distribution of power among the N radiators of said first station from a normal state to a different state, wherein in the normal state all N of the radiators are equally-powered, and in the different state, one of said N radiators receives more or less power than the other radiators; (b) from a signal strength change between said normal and different states, of signals exchanged between the first cellular telephone station and a mobile terminal, determining an angular region extending from the vertical pole of the first cellular telephone station in which a multipath reflector is positioned; (c) during normal service of said cellular telephone system, temporarily changing a distribution of power among the N radiators of said second station from a normal state to a different state, wherein in the normal state all N of the radiators are equally-powered, and in the different state, one of said N radiators receives more or less power than the other radiators; (d) from a signal strength change between said normal and different states, of signals exchanged between the second cellular telephone station and said mobile terminal, determining an angular region extending from the vertical pole of the second cellular telephone station in which said multipath reflector is positioned; (e) localizing a position of the multipath reflector based on overlap of the angular regions extending from the vertical poles of the first and second cellular telephone stations, and entering resultant position data in a data structure; and repeating acts (a) through (e) multiple times during regular service of said cellular telephone system; wherein a dynamically-updated model of multipath reflectors is created and updated during regular service of the cellular telephone system. 2. The method of claim 1 that further includes: determining, from a time delay of a multipath component of a signal transferred between the first station and said mobile terminal, a first spatial ellipse on which said multipath reflector is positioned; determining, from a time delay of a multipath component of a signal transferred between the second station and said mobile terminal, a second spatial ellipse on which said multipath reflector is positioned; determining, from overlaps of said first and second spatial ellipses, two candidate points at which said multipath reflector may be positioned; from said signal strength change between said normal and different states, of signals exchanged between the first station and said mobile terminal, identifying one of said two candidate points as a resolved position of said multipath reflector; and entering data indicating said resolved position of the multipath reflector in said data structure. 3. The method of claim 2 that further includes: modeling distortion of an original signal sent from the first station, as received by the mobile terminal, taking into account superposition of a delayed component due to said multipath reflector; and at the mobile terminal, applying a filtering operation to counteract said modeled distortion. 4. The method of claim 2 that further includes: modeling distortion of an original signal sent from the mobile terminal, as received by the first station, taking into account superposition of a delayed component due to said multipath reflector; and at the first station, applying a filtering operation to counteract said modeled distortion. 5. The method of claim 1 that further includes a third cellular telephone station, including an antenna array comprising N radiators equi-angularly spaced around a vertical pole, the method further comprising: during normal service of said cellular telephone system, changing a distribution of power among the N radiators of the third cellular telephone station from a normal state to a different state, wherein in the normal state all N of the radiators are equally-powered, and in the different state, one of said N radiators receives more or less power than the other radiators; from a signal strength change between said normal and different states, of signals exchanged between the third station and said mobile terminal, determining an angular region extending from the vertical pole of the third station in which said multipath reflector is positioned; and localizing the position of the multipath reflector based on overlap of the angular regions extending from the vertical poles of the first, second and third cellular telephone stations, and entering resultant position data in the data structure. 6. The method of claim 5 that further includes: determining, from a time delay of a multipath component of a signal transferred between the first station and said mobile terminal, a first spatial ellipse on which said multipath reflector is positioned; determining, from a time delay of a multipath component of a signal transferred between the second station and said mobile terminal, a second spatial ellipse on which said multipath reflector is positioned; determining, from a time delay of a multipath component of a signal transferred between the third station and said mobile terminal, a third spatial ellipse on which said multipath reflector is positioned; determining, from overlaps of said first, second and third spatial ellipses, an unambiguous position of said multipath reflector; and entering data indicating said unambiguous position of the multipath reflector in said data structure. 7. The method of claim 1 that further includes a third cellular telephone station, including an antenna array comprising N radiators equi-angularly spaced around a vertical pole, the method further comprising: determining, from a time delay of a multipath component of a signal transferred between the first station and said mobile terminal, a first spatial ellipse on which said multipath reflector is positioned; determining, from a time delay of a multipath component of a signal transferred between the second station and said mobile terminal, a second spatial ellipse on which said multipath reflector is positioned; determining, from a time delay of a multipath component of a signal transferred between the third station and said mobile terminal, a third spatial ellipse on which said multipath reflector is positioned; determining, from overlaps of said first, second and third spatial ellipses, an unambiguous position of said multipath reflector; and entering data indicating said unambiguous position of the multipath reflector in said data structure. 8. The method of claim 7 that further includes: modeling distortion of an original signal sent from the first station, as received by the mobile terminal, taking into account superposition of a delayed component due to said multipath reflector; and at the mobile terminal, applying a filtering operation to counteract said modeled distortion. 9. The method of claim 7 that further includes: modeling distortion of an original signal sent from the mobile terminal, as received by the first station, taking into account superposition of a delayed component due to said multipath reflector; and at the first station, applying a filtering operation to counteract said modeled distortion.