Estimate of formation mobility from Stoneley waveforms

What is claimed is: 1. A method comprising: generating, by a computer system, synthetic pressure values for a test mobility and a test intrinsic attenuation of a formation, based on a synthetic model of Stoneley wave propagation through the formation, the synthetic model including effects of permeability and intrinsic attenuation on modeled Stoneley pressure waves and associated reflections within the formation; acquiring, by the computer system from a downhole tool disposed in a borehole extending over a plurality of depths within the formation, Stoneley pressure values measured by each receiver in a receiver array of the downhole tool at each of the plurality of depths along a length of the borehole drilled within the formation; generating, by the computer system, an objective function that represents a misfit between the Stoneley pressure values measured by each receiver of the receiver array at each of the plurality of depths and the synthetic pressure values generated using the synthetic model; analytically minimizing, by the computer system, the objective function with respect to reflection coefficients for the test mobility and test intrinsic attenuation, wherein the test mobility and test intrinsic attenuation are repeatedly adjusted until a global minimum is obtained for the objective function; estimating, by the computer system, formation mobility and intrinsic attenuation from the minimized objective function; determining, by the computer system, a permeability profile of the formation as a function of depth, based on the estimated formation mobility and intrinsic attenuation; and providing, via a display of the computer system, the permeability profile for the borehole to be drilled over additional depths within the formation. 2. The method of claim 1 , wherein the receiver array of the downhole tool has a plurality of receivers at each of a plurality of planes along a length of the downhole tool. 3. The method of claim 2 , wherein generating synthetic pressure values includes synthetic modeling over all depth-receiver combinations of the plurality of receivers of the downhole tool such that data points in the objective function are stacked to include effects of reflections. 4. The method of claim 3 , wherein the stacked data points in the objective function reduce effects of noise when estimating the formation mobility. 5. The method of claim 2 , wherein the Stoneley pressure values are measured using receivers of the plurality of receivers having different transmitter to receiver gains. 6. The method of claim 1 , wherein estimating formation mobility and intrinsic attenuation includes estimating the formation mobility and intrinsic attenuation based on different frequency dependencies of the formation mobility and intrinsic attenuation. 7. The method of claim 1 , wherein generating the objective function includes generating an L2 norm of the misfit as a function of reflection coefficients. 8. The method of claim 7 , wherein generating the L2 norm includes generating the L2 norm as a function of frequency. 9. A machine-readable storage device having instructions stored thereon, which, when performed by a machine, cause the machine to perform operations, the operations comprising: generating synthetic pressure values for a test mobility and a test intrinsic attenuation of a formation, based on a synthetic model of Stoneley wave propagation through the formation, the synthetic model including effects of permeability and intrinsic attenuation on modeled Stoneley pressure waves and associated reflections within the formation; acquiring, from a downhole tool disposed in a borehole extending over a plurality of depths within the formation, Stoneley pressure values measured by each receiver in a receiver array of the downhole tool at each of the plurality of depths along a length of the borehole drilled within the formation; generating an objective function that represents a misfit between the Stoneley pressure values measured by each receiver of the receiver array at each of the plurality of depths and the synthetic pressure values generated using the synthetic model; analytically minimizing the objective function with respect to reflection coefficients for the test mobility and test intrinsic attenuation, wherein the test mobility and test intrinsic attenuation are repeatedly adjusted until a global minimum is obtained for the objective function; estimating formation mobility and intrinsic attenuation from minimizing the objective function; determining a permeability profile of the formation as a function of depth, based on the estimated formation mobility and intrinsic attenuation; and providing, via a display, the permeability profile for the borehole to be drilled over additional depths within the formation. 10. The machine-readable storage device of claim 9 , wherein the receiver array of the downhole tool has a plurality of receivers at each of a plurality of planes along a length of the downhole tool. 11. The machine-readable storage device of claim 10 , wherein generating synthetic pressure values includes synthetic modeling over all depth-receiver combinations of the plurality of receivers of the downhole tool such that data points in the objective function are stacked to include effects of reflections. 12. The machine-readable storage device of claim 11 , wherein the stacked data points in the objective function reduce effects of noise when estimating the formation mobility. 13. The machine-readable storage device of claim 10 , wherein the Stoneley pressure values are measured using receivers of the plurality of receivers having different transmitter to receiver gains. 14. The machine-readable storage device of claim 9 , wherein estimating formation mobility and intrinsic attenuation includes estimating the formation mobility and intrinsic attenuation based on different frequency dependencies of the formation mobility and intrinsic attenuation. 15. The machine-readable storage device of claim 9 , wherein generating the objective function includes generating an L2 norm of the misfit as a function of reflection coefficients. 16. The machine-readable storage device of claim 15 , wherein generating the L2 norm includes generating the L2 norm as a function of frequency. 17. A system comprising: an acoustic tool disposed in a borehole extending over a plurality of depths within a formation and having a transmitter and an array of receivers; a control unit operable to manage generation of acoustic signals from the transmitter and to manage collection of received signals at the receivers as the borehole is drilled; and a processing unit coupled to the acoustic tool and the control unit for performing a plurality of operations, including operations to: generate synthetic pressure values for a test mobility and a test intrinsic attenuation of the formation, based on a synthetic model of Stoneley wave propagation through the formation, the synthetic model including effects of permeability and intrinsic attenuation on modeled Stoneley pressure waves and associated reflections within the formation; acquire, from the acoustic tool, Stoneley pressure values measured by each of the receivers of the acoustic tool at each of the plurality of depths along a length of the borehole drilled within the formation; generate an objective function that represents a misfit between the Stoneley pressure values and the synthetic pressure values; analytically minimize the objective function with respect to reflection coefficients for the test mobility and test intrinsic attenuat