Inversion Technique For Fracture Characterization In Highly Inclined Wells Using Multiaxial Induction Measurements

What is claimed is: 1 . A method for determining an orientation of formation fractures with respect to a wellbore axis, comprising: (a) accepting as input to a computer multiaxial electromagnetic measurements corresponding to measurements made along two mutually orthogonal axes perpendicular to and parallel to an axis of the wellbore, the measurements corresponding to at least one receiver spacing from a transmitter; (b) in the computer estimating an initial orientation of a fracture with respect to the axis of the wellbore and a distance from the fracture to a position from which the electromagnetic measurements are obtained using the multiaxial electromagnetic measurements; (c) in the computer generating an initial model of a subsurface formation using the estimated initial orientation and distance and data related to at least one formation resistivity adjacent to the fracture; (d) in the computer, generating an expected response of an electromagnetic well logging instrument to the initial model; (e) in the computer, comparing the expected response to measurements made by the electromagnetic well logging instrument; and (f) in the computer, adjusting at least one parameter of the initial model and repeating (d) and (e) until a difference between the expected response and the measurements either (i) falls below a selected threshold or (ii) exceeds a predetermined number of repetitions of (d) and (e) and; (g) in the computer either (i) displaying the model after (f)(i) or (ii) displaying an indication of non-convergence after (f)(ii). 2 . The method of claim 1 wherein the determining the initial orientation and the distance comprises: in the computer, calculating a first derivative with respect to wellbore depth of the multiaxial electromagnetic induction measurements; in the computer determining at least one peak and an amplitude thereof of the first derivatives; and in the computer using the peak and the amplitude to determine the location by displaying the first derivatives with respect to wellbore depth. 3 . The method of claim 1 wherein two mutually orthogonal axes are rotated such that one thereof is in a vertical direction. 4 . The method of claim 1 further comprising selecting a threshold value for amplitude and in the computer excluding from evaluation any peak in the first derivatives with respect to wellbore depth. 5 . The method of claim 1 further comprising accepting as input to the computer multiaxial electromagnetic measurements at at least one additional receiver spacing from the transmitter and repeating (b) through (g) for the at least one additional receiver spacing. 6 . The method of claim 1 further comprising in the computer displaying the input electromagnetic measurements in depth correspondence with first derivatives thereof as a quality control indication. 7 . The method of claim 1 wherein the electromagnetic measurements comprise electromagnetic induction measurements. 8 . The method of claim 1 wherein the electromagnetic measurements comprise electromagnetic propagation measurements. 9 . The method of claim 8 wherein the electromagnetic measurements are acquired while an electromagnetic propagation well logging instrument is rotated. 10 . A system for determining an orientation of formation fractures with respect to a wellbore axis, comprising: a processor and a display, the processor programmed to (a) accept as input multiaxial electromagnetic measurements corresponding to measurements made along two mutually orthogonal axes perpendicular to and parallel to an axis of the wellbore, the measurements corresponding to at least one receiver spacing from a transmitter; (b) estimate an initial orientation of a fracture with respect to the axis of the wellbore and a distance from the fracture to a position from which the electromagnetic measurements are obtained using the multiaxial electromagnetic measurements; (c) generate an initial model of a subsurface formation using the estimated initial orientation and distance and data related to at least one formation resistivity adjacent to the fracture; (d) generate an expected response of an electromagnetic well logging instrument to the initial model; (e) compare the expected response to measurements made by the electromagnetic well logging instrument; and (f) adjust at least one parameter of the initial model and repeat (d) and (e) until a difference between the expected response and the measurements either (i) falls below a selected threshold or (ii) exceeds a predetermined number of repetitions of (d) and (e) and; (g) either (i) display the model after (f)(i) or (ii) display an indication of non-convergence after (f)(ii). 11 . The system of claim 10 wherein the determining the initial orientation and the distance comprises: calculating a first derivative with respect to wellbore depth of the multiaxial electromagnetic induction measurements; in the computer determining at least one peak and an amplitude thereof of the first derivatives; and in the computer using the peak and the amplitude to determine the location by displaying the first derivatives with respect to wellbore depth. 12 . The system of claim 10 wherein two mutually orthogonal axes are rotated such that one thereof is in a vertical direction. 13 . The system of claim 10 wherein the processor is further programmed to select a threshold value for amplitude and to exclude from evaluation any peak in the first derivatives with respect to wellbore depth. 14 . The system of claim 10 wherein the processor is further programmed to accept as input to the multiaxial electromagnetic measurements at at least one additional receiver spacing from the transmitter and to repeat (b) through (g) for the at least one additional receiver spacing. 15 . The system of claim 10 wherein the processor is programmed to operate the display to display the input electromagnetic measurements in depth correspondence with first derivatives thereof as a quality control indication. 16 . The system of claim 10 wherein the electromagnetic measurements comprise electromagnetic induction measurements. 17 . The system of claim 10 wherein the electromagnetic measurements comprise electromagnetic propagation measurements. 18 . The system of claim 17 wherein the electromagnetic measurements are acquired while an electromagnetic propagation well logging instrument is rotated. 19 . A method for well logging, comprising: (a) moving a multiaxial electromagnetic well logging instrument along a wellbore through a formation intersected by at least one fracture; (b) accepting as input to a computer, multiaxial electromagnetic measurements corresponding to measurements made along two mutually orthogonal axes perpendicular to and parallel to an axis of the wellbore, the measurements corresponding to at least one receiver spacing from a transmitter; (c) in the computer, estimating an initial orientation of a fracture with respect to the axis of the wellbore and a distance from the fracture to a position from which the electromagnetic measurements are obtained using the multiaxial electromagnetic measurements; (d) in the computer, generating an initial model of a subsurface formation using the estimated initial orientation and distance and data related to at least one formation resistivity adjacent to the fracture; (e) in the computer, generating an expected response of an electromagnetic well logging instrument to the initial model; (f) in the computer, comparing the expected