Three dimensional laser measuring system and method

The invention claimed is: 1. A laser receiver comprising: at least one reflective surface attached thereto; a photo detection unit for receiving a plurality of modulated laser beams, the plurality of modulated laser beams being transmitted by a laser transmitter having at least one reflective surface attached thereto, and each laser beam of the plurality of laser beams being modulated with at least azimuthal angle information; and a processor for estimating an azimuthal position, associated with the laser receiver, using particular ones of the plurality of modulated laser beams, and estimating a distance between the laser receiver and the laser transmitter using at least one reflected modulated laser beam that has been reflected between the at least one reflective surface of the laser receiver and the at least one reflective surface of the laser transmitter. 2. The laser receiver of claim 1 wherein the at least one reflective surface of the laser receiver is a flat surface of a retro reflector. 3. The laser receiver of claim 2 wherein the azimuthal angle information is associated with the laser transmitter, and the azimuthal position is an azimuthal angle associated with the laser receiver. 4. The laser receiver of claim 3 wherein the processor estimates a vertical position, associated with the laser receiver, using particular ones of the plurality of modulated laser beams. 5. The laser receiver of claim 4 wherein the processor estimates a 3D position of the laser receiver using the vertical position, the azimuthal angle and the distance. 6. The laser receiver of claim 3 wherein the distance is estimated by comparing a signal difference between a first modulated laser beam received by the laser receiver and a second modulated laser beam, the second modulated laser beam being the at least one reflected modulated laser beam that has been reflected between the at least one reflective surface of the laser receiver and the at least one reflective surface of the laser transmitter. 7. The laser receiver of claim 2 wherein the at least one reflective surface of the laser receiver is a corner reflector having a plurality of mirror edges configured around a photo diode window, and the at least one reflective surface of the laser transmitter is a corner reflector having a plurality of mirror edges configured around a laser diode window. 8. The laser receiver of claim 1 wherein the plurality of modulated laser beams are modulated using a frequency modulation. 9. The laser receiver of claim 1 wherein the plurality of modulated laser beams are modulated using a phase modulation. 10. The laser receiver of claim 1 wherein each laser beam of the plurality of modulated laser beams is an N-shaped beam. 11. A position measuring method for a laser receiver, the method comprising: receiving a plurality of modulated laser beams, each laser beam of the plurality of laser beams being modulated with at least azimuthal angle information; reflecting one of the modulated laser beams received off a reflective surface attached to the laser receiver to produce a first reflected modulated beam signal; receiving the first reflected modulated laser beam signal by a reflective surface attached to a laser transmitter which transmits the plurality of modulated laser beams; reflecting the first reflected modulated laser beam received off the reflective surface attached to the laser transmitter to produce a second reflected modulated beam signal; receiving the second reflected modulated laser beam signal at the laser receiver; estimating a distance between the laser receiver and the laser transmitter using the one of the modulated laser beams received and the second reflected modulated laser beam signal; and estimating an azimuthal position, associated with the laser receiver, using the plurality of modulated laser beams. 12. The method of claim 11 wherein the reflective surface of the laser receiver is a flat surface of a retro reflector. 13. The method of claim 12 wherein the azimuthal angle information is associated with the laser transmitter, and the azimuthal position is an azimuthal angle associated with the laser receiver. 14. The method of claim 13 further comprising: estimating a vertical position, associated with the laser receiver, using particular ones of the plurality of modulated laser beams. 15. The method of claim 14 further comprising: estimating a three dimensional position of the laser receiver using the vertical position, the azimuthal angle and the distance. 16. The method of claim 12 wherein the first reflected modulated beam signal and the second reflected modulated beam signal are reflected between a corner mirror of a plurality of corner mirrors configured around a photo diode window in the laser receiver and a corner mirror a plurality of corner mirrors configured around a laser diode window of the laser transmitter. 17. The method of claim 12 wherein the distance is estimated by comparing a phase difference between the first reflected modulated laser beam signal and the second reflected modulated laser beam signal. 18. The method claim 11 wherein the plurality of modulated laser beams are modulated using a frequency modulation. 19. The method of claim 11 wherein the plurality of modulated laser beams are modulated using a phase modulation. 20. The method of claim 11 wherein each laser beam of the plurality of modulated laser beams is an N-shaped beam. 21. A non-transitory computer-readable medium storing computer program instructions for position measuring by a laser receiver, the computer program instructions, when executed on a processor, cause the processor to perform operations comprising: receiving a plurality of modulated laser beams, each laser beam of the plurality of modulated laser beams being modulated with at least azimuthal angle information of a laser transmitter that transmitted the plurality of modulated laser beams; estimating an azimuthal position of the laser receiver using the plurality of modulated laser beams; and estimating a distance between the laser receiver and the laser transmitter using at least one modulated laser beam which has been reflected between the laser receiver and a laser transmitter that transmitted the plurality of modulated laser beams, wherein the at least one modulated laser beam has been reflected by: reflecting one of the modulated laser beams received off a reflective surface attached to the laser receiver to produce a first reflected modulated beam signal; receiving the first reflected modulated laser beam signal by a reflective surface attached to a laser transmitter which transmits the plurality of modulated laser beams; reflecting the first reflected modulated laser beam received off the reflective surface attached to the laser transmitter to produce a second reflected modulated beam signal; and receiving the second reflected modulated laser beam signal at the laser receiver. 22. The non-transitory computer-readable medium of claim 21 wherein the operations further comprise: estimating a vertical position, associated with the laser receiver, using particular ones of the plurality of modulated laser beams; and estimating a three dimensional position of the laser receiver using the vertical position, the azimuthal position and the distance. 23. The non-transitory computer-readable medium of claim 21 wherein the reflective surface of the laser receiver is a corner reflector ha