Thermally assisted writer protrusion determination and control

What is claimed is: 1. A method comprising: writing a data pattern to a rotating data recording surface using a transducer having a write element, a read element and a thermal assist energy source; determining a first protrusion distance for the read element induced by operation of the energy source responsive to first and second readback amplitudes obtained from the data pattern using different first and second power levels applied to the energy source; and determining a second protrusion distance for the write element induced by the energy source responsive to the first protrusion distance using a scaling factor to convert the first protrusion distance for the read element to the second protrusion distance for the write element without requiring a measurement that induces contact between the transducer and the data recording surface. 2. The method of claim 1 , wherein the first readback amplitude is obtained by positioning the read element adjacent a first portion of the data pattern, heat stressing the first portion of the data pattern by applying the first power level to the energy source, and then reading a second portion of the data pattern. 3. The method of claim 2 , wherein the second readback amplitude is obtained by positioning the read element adjacent the first portion, heat stressing the first portion by applying the second power level to the energy source, and reading the second portion. 4. The method of claim 1 , wherein the first protrusion distance is determined using the Wallace spacing loss equation based on the first and second readback amplitudes. 5. The method of claim 1 , wherein the second protrusion distance is determined by multiplying the first protrusion distance for the read element by the scaling factor to convert the first protrusion distance for the read element to the second protrusion distance for the write element. 6. The method of claim 1 , further comprising identifying a non-contacting target clearance value for the transducer for a write operation, identifying an input power level for the energy source during the write operation, and using the second protrusion distance to adjust a fly height adjustment (FHA) value applied to a FHA adjustment mechanism of the transducer responsive to the target clearance value and the input power level to maintain the identified non-contacting target clearance value. 7. The method of claim 1 , wherein the data pattern is written to a plurality of sectors on a selected track on the surface, wherein the first portion of the data pattern comprises a first subset of the plurality of sectors on the selected track, and wherein the second portion of the data pattern comprises a second subset of the plurality of sectors on the selected track. 8. The method of claim 1 , wherein the transducer further comprises a fly height adjustment (FHA) mechanism, wherein a baseline FHA value is supplied to the FHA mechanism during the obtaining of the first and second readback amplitudes, and wherein differences in the first and second readback amplitudes are established responsive to different first and second input power levels supplied to the energy source which induce different amounts of thermal expansion of the transducer. 9. The method of claim 1 , further comprising generating a transfer function that describes a change in protrusion distance of the write element in a direction toward the surface responsive to input power level applied to the energy source, and using the transfer function to select at least a selected one of the input power level to the energy source or an input control value to a fly height adjustment (FHA) mechanism of the transducer to establish the transducer at a target clearance during a write operation. 10. The method of claim 1 , wherein the first protrusion distance for the read element is determined by: placing the read element adjacent the data pattern; heat stressing a first portion of the data pattern by applying a first input power level to the energy source without supplying an input write signal to the write element; immediately reading a second portion of the data pattern to obtain the first readback amplitude; repeating the placing and heat stressing steps using a second input power level to the energy source without applying an input write signal to the write element to obtain the second readback amplitude; and determining the first protrusion distance responsive to A1/A2=e^[−2π(Δd)/λ] where A1 is the first readback amplitude, A2 is the second readback amplitude, Δd is a change in protrusion distance and λ is a write frequency at which the data pattern is written. 11. A method comprising: writing a data pattern to a rotating data recording surface using a transducer having a write element, a read element, a fly height adjustment (FHA) mechanism and a thermal assist energy source; heat stressing a first portion of the data pattern using a first power level applied to the energy source followed by reading a second portion of the data pattern using the read element to obtain a first readback amplitude; heat stressing the first portion of the data pattern using a second power level applied to the energy source followed by reading the second portion of the data pattern using the read element to obtain a second readback amplitude; determining a first protrusion distance for the read element induced by the energy source responsive to the first and second readback amplitudes; and determining a second protrusion distance for the write element induced by the energy source responsive to the first protrusion distance by multiplying the first protrusion distance for the read element by a scaling factor to generate the second protrusion distance for the write element, the second protrusion distance generated without requiring a measurement that induces contact between the transducer and the data recording surface. 12. The method of claim 11 , further comprising using the second protrusion distance to set an input power level for the energy source responsive to a target clearance value for the transducer during a write operation. 13. The method of claim 11 , further comprising applying a baseline input FHA value to the FHA mechanism to establish a baseline clearance distance for the transducer during the respective heat stressing steps, wherein differences between the first and second readback amplitudes are induced responsive to changes in thermal expansion of the transducer from the respective first and second power levels applied to the energy source. 14. The method of claim 13 , further comprising using the second protrusion distance to adjust an input FHA value to the FHA mechanism responsive to a target clearance value for the transducer and an input power level for the energy source during a write operation. 15. An apparatus comprising: a data transducer adjacent a data recording medium, the data transducer comprising a write element, a read element and a thermal assist energy source; and a protrusion analysis and control circuit configured to determine a first protrusion distance for the read element induced by operation of the energy source responsive to first and second readback amplitudes obtained from a data pattern written to the medium using different first and second power levels applied to the energy source, and to determine a second protrusion distance for the write element induced by the energy source responsive to the first protrusion distance by multiplying the first protrusion distance by a scaling factor to produce the second protrusion distance. 16. The apparatus of claim 15 , wherein the firs