Method and apparatus for continuous wellbore curvature orientation and amplitude measurement using drill string bending

The invention claimed is: 1. A method for determining curvature of a wellbore, the curvature having a magnitude and an orientation, the method comprising: a) coupling a first strain gauge to a tubular member; b) positioning the tubular member in the wellbore such that the tubular member is placed under bending stress by a curvature or deviation in the wellbore; c) at least partially rotating the tubular member within the wellbore; d) using only the first strain gauge to measure mechanical strain on the tubular member as a function of time as the tubular member rotates so as to generate a time-based single-strain-gauge output; e) recording an amplitude of the output generated in step d); and f) determining one or more of the magnitude or orientation of the curvature of the wellbore based on the amplitude recorded in step e). 2. A method for determining curvature of a wellbore, the curvature having a magnitude and an orientation, the method comprising: coupling a first strain gauge to a tubular member; positioning the tubular member in the wellbore such that the tubular member is placed under bending stress by a curvature or deviation in the wellbore; rotating the tubular member within the wellbore; using only the first strain gauge to measure mechanical strain on the tubular member as a function of time as the tubular member rotates through a full rotation so as to generate a time-based single-strain-gauge output; determining the difference between a maximum and a minimum amplitude of the output of the time-based single-strain-gauge output over the course of the full rotation so as to define an amplitude differential; and calculating a degree of curvature of the wellbore from the amplitude differential. 3. The method of claim 2 , wherein the amplitude of the output of the first strain gauge is recorded in at least 3 angular orientations within a partial rotation of the tubular member; the method further comprises: interpolating a sinusoidal waveform from the 3 amplitude recordings; determining the difference between a maximum and a minimum amplitude of the sinusoidal waveform, defining an amplitude differential; and wherein the calculating operation utilizes the amplitude differential. 4. The method of claim 2 , further comprising: moving the tubular member through the wellbore while rotating continuously; and recording the position of the first strain gauge within the wellbore for each recording of the amplitude of the output of the first strain gauge. 5. The method of claim 4 , further comprising: determining the difference between a maximum and a minimum amplitude of the output of the strain gauge corresponding generally to a recorded position of the first strain gauge within the wellbore, the difference defining an amplitude differential; wherein the calculating operation utilizes the amplitude differential to determine the degree of curvature at the position within the wellbore. 6. The method of claim 5 , further comprising: recording the angular offset of the first strain gauge relative to a reference frame for each recording of the amplitude of the output of the strain gauge; determining the angular offset corresponding to the recording for the maximum or minimum amplitude of the output of the first strain gauge; and calculating the direction of the curvature of the wellbore at the location. 7. The method of claim 6 , further comprising: computing one or more of an azimuth of the path of the wellbore, an inclination of the path of the wellbore, or a model of the path of the wellbore between the first and the second locations. 8. The method of claim 1 , further comprising: recording the angular offset of the first strain gauge relative to a fixed reference frame for each recording of the amplitude of the output of the first strain gauge; and calculating a direction of curvature of the wellbore from the amplitude. 9. The method of claim 8 , wherein the tubular member is rotated a full rotation, and wherein the step of calculating a direction of curvature of the wellbore from the amplitude comprises: determining a maximum or minimum amplitude of the output of the first strain gauge over the course of the rotation; and determining the angular offset corresponding to the recording for the maximum or minimum amplitude of the output of the first strain gauge. 10. The method of claim 8 , wherein the amplitude of the output of the first strain gauge is recorded at least 3 angular orientations within a partial rotation of the tubular member; the method further comprises: interpolating a sinusoidal waveform from the 3 amplitude recordings; interpolating an interpolated angular offset for each of the 3 amplitude recordings from the recorded angular offsets; and wherein the step of calculating a direction of curvature of the wellbore from the amplitude comprises: determining a maximum or minimum amplitude of the sinusoidal waveform; and determining the angular offset corresponding to the recording for the maximum or minimum amplitude of the output of the first strain gauge. 11. The method of claim 8 , further comprising: moving the tubular member through the wellbore while rotating; and recording the position of the strain gauge within the wellbore for each recording of the amplitude of the output of the first strain gauge. 12. The method of claim 11 , further comprising: determining the difference between a maximum and a minimum amplitude of the output of the first strain gauge corresponding generally to a recorded position of the first strain gauge within the wellbore, the difference defining an amplitude differential; determining the angular offset corresponding to the maximum or minimum amplitude of the output of the strain gauge corresponding to the position of the first strain gauge within the wellbore; and calculating the direction and degree of curvature at the position within the wellbore using the amplitude differential and the determined angular offset. 13. The method of claim 1 , further comprising coupling a second strain gauge to the tubular member such that the second strain gauge is positioned opposite the first strain gauge. 14. The method of claim 2 , further comprising: moving the tubular member from a first location within the wellbore to a second location within the wellbore; and computing one or more of an azimuth of the wellbore, an inclination of the wellbore, or a model of the path of the wellbore between the first and the second locations. 15. The method of claim 14 , wherein the tubular member is moved from the first location to the second location in a sliding mode. 16. The method of claim 1 , further comprising: moving the tubular member from a first location within the wellbore to a second location within the wellbore; and computing one or more of an azimuth of the wellbore, an inclination of the wellbore, or a model of the path of the wellbore between the first and the second locations.