Solar tracking system using periodic scan patterns with a shielding tube

We claim: 1. A solar tracking system comprising: a tube for admitting solar radiation through an opening; at least one photodetector for generating a signal related to an intensity of said solar radiation incident on a distal end of said tube; a scan unit for periodically executing a predetermined scan pattern of said tube during a daily trajectory of the sun; a processing unit in communication with said at least one photodetector for determining an on-sun orientation of said tube based on said predetermined scan pattern; wherein the solar tracking system is configured to update an orientation of at least one solar surface based on the on-sun orientation to an updated position that overshoots the on-sun orientation along the trajectory of the sun and hold the updated position constant for an interval of time, wherein the solar tracking system is configured to repeat updating of the orientation of the at least one solar surface periodically during the daily trajectory of the sun so as to maintain a magnitude of incidence angle within a predetermined range. 2. The solar tracking system of claim 1 , wherein said solar surface is a photovoltaic solar surface for producing electricity from solar radiation incident on the surface. 3. The solar tracking system of claim 1 , wherein said solar surface is used to produce thermal energy from solar radiation incident on the surface. 4. The solar tracking system of claim 1 , wherein said tube is a shielding tube having an absorptive inner surface for absorbing said solar radiation incident on said inner surface. 5. The solar tracking system of claim 1 , wherein said tube is attached to said at least one solar surface such that a surface normal to said solar surface is parallel with a center axis of said tube. 6. A solar tracking system comprising: a tube for admitting solar radiation through an opening; at least one photodetector for generating a signal related to an intensity of said solar radiation incident on a distal end of said tube; a scan unit for periodically executing a predetermined scan pattern of said tube; and a processing unit in communication with said at least one photodetector for determining an on-sun orientation of said tube based on said predetermined scan pattern; wherein said on-sun orientation is deployed for updating the orientation of at least one solar surface, wherein said processing unit determines said on-sun orientation of said tube based on convolution of said signal obtained during said predetermined scan pattern with a trained convolution kernel. 7. The solar tracking system of claim 1 , wherein said scan unit executes said predetermined scan pattern in an elevation angle El and in an azimuth angle Az of said tube. 8. The solar tracking system of claim 7 , wherein said scan unit comprises an elevation drive for varying said elevation angle El and an azimuth drive for varying said azimuth angle Az. 9. The solar tracking system of claim 8 , wherein said solar tracking system further comprises a support structure for said at least one solar surface, and wherein said elevation drive and said azimuth drive are integrated with said support structure for updating the orientation of said at least one solar surface. 10. The solar tracking system of claim 1 , further comprising a light guide for guiding said solar radiation from said distal end to said at least one photodetector. 11. A solar tracking system comprising: a tube for admitting solar radiation through an opening; at least one photodetector for generating a signal related to an intensity of said solar radiation incident on a distal end of said tube; a scan unit for periodically executing a predetermined scan pattern of said tube; a processing unit in communication with said at least one photodetector for determining an on-sun orientation of said tube based on said predetermined scan pattern, wherein said on-sun orientation is deployed for updating the orientation of at least one solar surface; a light guide for guiding said solar radiation from said distal end to said at least one photodetector; and a mobile robot housing said at least one photodetector on-board and capable of establishing a temporary connection with said light guide. 12. The solar tracking system of claim 11 , wherein said mobile robot further houses said processing unit and a means of interfacing with said scan unit. 13. The solar tracking system of claim 10 , further comprising an optic at said distal end of said tube for coupling in said solar radiation into said light guide. 14. A solar tracking system comprising: a tube for admitting solar radiation through an opening; at least one photodetector for generating a signal related to an intensity of said solar radiation incident on a distal end of said tube; a scan unit for periodically executing a predetermined scan pattern of said tube; a processing unit in communication with said at least one photodetector for determining an on-sun orientation of said tube based on said predetermined scan pattern, wherein said on-sun orientation is deployed for updating the orientation of at least one solar surface; a light guide for guiding said solar radiation from said distal end to said at least one photodetector; a meter for obtaining a measure of ambient insolation conditions; and a communication link between said meter and said processing unit for supplying to said processing unit said measure; whereby said processing unit determines said on-sun orientation based on ambient insolation conditions. 15. A method for solar tracking comprising: providing a shielding tube for admitting solar radiation thereinto; providing an absorptive inner surface in said shielding tube for absorbing said solar radiation incident on said inner surface; generating a signal related to an intensity of said solar radiation at a distal end of said shielding tube; periodically executing a predetermined scan pattern of said shielding tube; determining an on-sun orientation of said shielding tube with a processing unit based on said predetermined scan pattern; updating the orientation of at least one solar surface based on said on-sun orientation to an updated position that overshoots the on-sun orientation along the trajectory of the sun and hold the updated position for an interval of time; and periodically repeat updating the orientation of the at least one solar surface periodically during the daily trajectory of the sun so as to maintain a magnitude of incidence angle within a predetermined range. 16. The method of claim 15 , wherein said step of periodically executing said predetermined scan pattern and updating the orientation of at least one solar surface is repeated at regular intervals of time being approximately 40 minutes or more. 17. The method of claim 15 , further comprising transporting said solar radiation from said distal end of said shielding tube to a remote photodetector using a light guide. 18. A method for solar tracking comprising: providing a shielding tube for admitting solar radiation thereinto; providing an absorptive inner surface in said shielding tube for absorbing said solar radiation incident on said inner surface; generating a signal related to an intensity of said solar radiation at a distal end of said shielding tube; periodically executing a predetermined scan pattern of said shielding tube; determining an on-sun orientation of said shielding tube with a processing unit based on said predetermined scan pattern; updating the orientation of at least one solar surface based