Non destructive evaluation scanning probe with self-contained multi-axis position encoder

What is claimed is: 1. A reflected penetrating waveform scanning probe for nondestructive evaluation of a non-living test sample, comprising: a housing having an underside for abutment against and multi-dimensional translation across a surface of a non-living test sample, and having directed outwardly toward the surface: a test sensor system for transmitting a penetrating waveform into the test sample, receiving a reflected waveform from the test sample at a multi-dimensional spatial location on the test sample surface and generating reflected waveform data corresponding to that location; and a probe position encoder system that correlates multi-dimensional probe underside translation and rotation motion across the test sample surface with the multi-dimensional spatial location on the test sample surface and that generates corresponding multi-dimensional spatial location data, said probe position encoder system having a pair of first and second orthogonal axes position encoders respectively generating first and second orthogonal axes position readings, with the respective corresponding orthogonal axes in mutual parallel alignment, said probe position encoder system compensating for probe rotation when the respective first and second orthogonal axes position readings differ, while generating said multi-dimensional spatial location data; and a scan data acquisition system, coupled to the test sensor and encoder systems, for receiving and correlating corresponding reflected waveform data at the location with its corresponding multi-dimensional spatial location data in a scan data set, and for sending the scan data set to a nondestructive evaluation analyzer. 2. The scanning probe of claim 1 , the first and second orthogonal axes position encoders comprising a pair of opto-mechanical mouse balls in contact with the test sample surface. 3. The scanning probe of claim 1 , the first and second orthogonal axes position encoders comprising a pair of opto-electronic mice sensors that project photonic beams on the test sample surface. 4. The scanning probe of claim 1 , the test sensor system comprising an ultrasound transmitter and receiver. 5. The scanning probe of claim 1 , the test sensor system comprising an eddy current transmitter and receiver. 6. The scanning probe of claim 1 , the reflected waveform data and the multi-dimensional spatial location data including time stamps when these data were generated; and the scan data acquisition system matching time stamps to correlate corresponding waveform and location data. 7. The scanning probe of claim 1 , the scan data acquisition system correlating respective waveform data and the multi-dimensional spatial location data by synchronizing their generation or capture. 8. A reflected penetrating waveform scanning system for nondestructive evaluation of a non-living test sample, comprising: a scanning probe having a housing with an underside for abutment against and multi-dimensional translation across a surface of a non-living test sample, and having directed outwardly toward the surface: a test sensor system for transmitting a penetrating waveform into the test sample, receiving a reflected waveform from the test sample at a multi-dimensional spatial location on the test sample surface and generating reflected waveform data corresponding to that location; and a probe position encoder system that correlates multi-dimensional probe underside translation and rotation motion across the test sample surface with the multi-dimensional spatial location on the test sample surface and that generates corresponding multi-dimensional spatial location data, said probe position encoder system having a pair of first and second orthogonal axes position encoders respectively generating first and second orthogonal axes position readings, with the respective corresponding orthogonal axes in mutual parallel alignment, said probe position encoder system compensating for probe rotation when the respective first and second orthogonal axes position readings differ, while generating said multi-dimensional spatial location data; a scan data acquisition system, coupled to the test sensor and encoder systems, for receiving and correlating corresponding reflected waveform data at the location with its corresponding multi-dimensional spatial location data in a scan data set, and for sending the scan data set to a nondestructive evaluation analyzer; and a nondestructive evaluation analyzer coupled to the scan data acquisition system, for receiving and transforming the scan data set into spatially mapped internal structural characterizations of the test object. 9. The scanning system of claim 8 , the first and second orthogonal axes position encoders comprising a pair of opto-mechanical mouse balls in contact with the test sample surface. 10. The scanning system of claim 8 , the first and second orthogonal axes position encoders comprising a pair of opto-electronic mice sensors that project photonic beams on the test sample surface. 11. The scanning system of claim 8 , the test sensor system comprising an ultrasound transmitter and receiver. 12. The scanning system of claim 8 , the test sensor system comprising an eddy current transmitter and receiver. 13. The scanning system of claim 8 , the scan data acquisition system correlating respective waveform data and the multi-dimensional spatial location data by: synchronizing their generation or capture; or time stamping and matching time stamps of the respective waveform data and the multi-dimensional spatial location data. 14. A method for nondestructive evaluation of a non-living test sample, comprising: providing a reflected penetrating waveform scanning system for nondestructive evaluation of a non-living test sample, having: a scanning probe having a housing with an underside for abutment against and multi-dimensional translation across a surface of a non-living test sample, and having directed outwardly toward the surface, said scanning probe including: a test sensor system for transmitting a penetrating waveform into the test sample, receiving a reflected waveform from the test sample at a multi-dimensional spatial location on the test sample surface and generating reflected waveform data corresponding to that location; and a probe position encoder system that correlates multi-dimensional probe underside translation and rotation motion across the test sample surface with the multi-dimensional spatial location on the test sample surface and that generates corresponding multi-dimensional spatial location data, said probe position encoder system having a pair of first and second orthogonal axes position encoders respectively generating first and second orthogonal axes position readings, with the respective corresponding orthogonal axes in mutual parallel alignment, said probe position encoder system compensating for probe rotation when the respective first and second orthogonal axes position readings differ, while generating said multi-dimensional spatial location data; a scan data acquisition system, coupled to the test sensor and encoder systems, for receiving and correlating corresponding reflected waveform data at the location with its corresponding multi-dimensional spatial location data in a scan data set; and a nondestructive evaluation analyzer coupled to the scan data acquisition system, for receiving and transforming the scan data set into spatially mapped internal structural characterizations of the test object; abutting the scanning probe underside against the test sample surface at a multi-dimensional spatial location and transmitting a penetrating waveform