Estimation of fast shear azimuth, methods and apparatus

What is claimed is: 1. An apparatus comprising: a tool having a longitudinal axis; a transmitter ring attached to the tool, the transmitter ring having orthogonal dipole transmitters; a number of receiver rings, each receiver ring disposed along a length of the longitudinal axis at a different distance from the other receiver rings along the length, each receiver ring having a plurality of acoustic dipole receivers azimuthally disposed around the tool; recording logic to record a plurality of acoustic waveforms corresponding to acoustic waves received at the acoustic dipole receivers when the tool is operated in a geological formation, the acoustic waves being generated by the orthogonal dipole transmitters; and a signal processor to generate an objective function, based on ordered sets of the plurality of acoustic waveforms received at each receiver ring, with respect to an azimuth angle, wherein the azimuth angle corresponds to an orientation of the orthogonal dipole transmitters and the acoustic dipole receivers relative to fast and slow principal flexural wave axes, with the signal processor structured to estimate a global minimum of the objective function with respect to the azimuth angle and to determine an anisotropy angle of the geological formation based on the global minimum. 2. The apparatus of claim 1 , wherein the signal processor is structured to generate the objective function with respect to the azimuth angle and a set of auxiliary parameters. 3. The apparatus of claim 1 , wherein the auxiliary parameters include fast and slow slowness values. 4. The apparatus of claim 1 , wherein a receiver ring of the number of receiver rings has N dipole receivers and is operable to provide N(N−1)/2 independent 2×2 waveforms, N being an integer greater than two. 5. The apparatus of claim 1 , wherein the signal processor is structured to diagonalize independent 2×2 waveforms, each independent 2×2 waveform being in-line and cross-line components according to two azimuth indices, the two azimuth indices not equal to each other, each azimuth index correlated to a different one of the acoustic dipole receivers of one of the receiver rings. 6. The apparatus of claim 1 , wherein the signal processor is structured to remove existing ambiguities associated with the fast and slow principal flexural wave axes and/or objective function minima and maxima. 7. The apparatus of claim 1 , wherein the tool comprises one of a wireline tool or a measurement while drilling tool. 8. A processor-implemented method of estimating an azimuth angle, executed by one or more processors that perform the method, the method comprising: recording a plurality of acoustic waveforms corresponding to acoustic waves received at a number of receiver rings, each receiver ring disposed along a length of a longitudinal axis of a tool at a different distance from the other receiver rings along the length of the longitudinal axis, the tool surrounded by a geological formation, each receiver ring having a plurality of acoustic dipole receivers azimuthally disposed around the tool and receiving acoustic waves, the acoustic waves being generated by orthogonal dipole transmitters in a transmitter ring attached to the tool; generating an objective function, based on ordered sets of the plurality of acoustic waveforms received at each receiver ring, with respect to an azimuth angle, wherein the azimuth angle corresponds to an orientation of the orthogonal dipole transmitters and the acoustic dipole receivers relative to fast and slow principal flexural wave axes; estimating a global minimum of the objective function with respect to the azimuth angle; and determining an anisotropy angle of the geological formation based on the global minimum. 9. The processor-implemented method of claim 8 , wherein the method includes forming the ordered sets of the plurality of acoustic waveforms from a receiver ring of the number of receiver rings having N dipole receivers providing N(N−1)/2 independent 2×2 waveforms, N being an integer greater than two. 10. The processor-implemented method of claim 8 , wherein the method includes diagonalizing independent 2×2 waveforms, each independent 2×2 waveform being in-line and cross-line components according to two azimuth indices, the two azimuth indices not equal to each other, each azimuth index correlated to a different one of the acoustic dipole receivers of one of the receiver rings. 11. The processor-implemented method of claim 8 , wherein generating the objective function includes extending a first objective function to include generalized waveforms correlated to the plurality of acoustic dipole receivers azimuthally disposed around the tool in each ring, the first objective function generated with respect to in-line and cross-line waveforms from transmitter rings to receiver rings, each transmitter ring having only two dipole transmitters orthogonal to each other and each receiver ring having only two dipole receivers orthogonal to each other. 12. The processor-implemented method of claim 8 , wherein estimating a global minimum of the objective function is accomplished analytically or by using a numerical search algorithm. 13. The processor-implemented method of claim 8 , wherein determining the anisotropy angle of the geological formation includes implementing the generating, the estimating, and the determining for a data point space defined over multiple frequency bands having different starting frequencies or by multiple different time periods having different starting times. 14. The processor-implemented method of claim 8 , wherein the method includes removing existing ambiguities associated with the fast and slow principal flexural wave axes and/or objective function minima and maxima. 15. The processor-implemented method of claim 14 , wherein removing existing objective function minimum/maximum ambiguity includes substituting the azimuth angle into the objective function and substituting an ambiguous angle into the objective function, and selecting an angle that minimizes the objective function. 16. The processor-implemented method of claim 14 , wherein removing existing fast slow principal axis ambiguity includes either constraining auxiliary parameters a priori to eliminate the ambiguity before minimizing the objective function; or eigenvalue alignment a priori to eliminate the ambiguity before minimizing the objective function; or rotating cross-dipole waveforms of the ordered sets of the plurality of acoustic waveforms by min/max ambiguity resolved azimuth angle into the fast and slow waveforms and comparing slowness of the cross-dipole waveforms using either a time semblance algorithm or frequency semblance algorithm. 17. A non-transitory machine-readable storage device having instructions stored thereon, which, when performed by a machine, cause the machine to perform operations, the operations comprising: recording a plurality of acoustic waveforms corresponding to acoustic waves received at a number of receiver rings, each receiver ring disposed along a length of a longitudinal axis of a tool at a different distance from the other receiver rings along the length of the longitudinal axis, the tool surrounded by a geological formation, each receiver ring having a plurality of acoustic dipole receivers azimuthally disposed around the tool and receiving acoustic waves, the acoustic waves being generated by orthogonal dipole transmitters in a transmitter ring attached to the tool; generating an objective function, based on ordered sets of the plurality of acoustic waveforms receive