System, method, and apparatus for inspecting a surface

What is claimed is: 1. A system, comprising: an inspection robot having a plurality of inspection sensors, the plurality of inspection sensors distributed horizontally relative to an inspection surface and configured to provide inspection data of the inspection surface at selected horizontal positions; and a controller, comprising: a position definition circuit structured to determine an inspection robot position of the inspection robot on the inspection surface based on position information, and to create a plant position definition in real-time by interrogating the position information as the inspection robot traverses the inspection surface and mapping the position information aggregated over time; and a data positioning circuit structured to interpret the inspection data, to correlate the inspection data to the inspection robot position on the inspection surface, and to determine position informed inspection data in response to the correlating of the inspection data with the inspection robot position, wherein the position informed inspection data includes the inspection data correlated to at least one of the position information or the plant position definition. 2. An inspection apparatus, comprising: an inspection robot; a payload operationally coupled to the inspection robot; an inspection sled mount and an arm, the inspection sled mount structured to pivotally couple the arm to the payload; a sled pivotally mounted to the arm; and an inspection sensor coupled to the sled such that the inspection sensor is operationally couplable to an inspection surface, wherein the inspection sled mount comprises a biasing member structured to provide a biasing force on the arm, wherein the biasing force is directed toward the inspection surface and an amount of the biasing force is adjustable, and wherein the biasing member is active and is structured to adjust the amount of the biasing force based on a downforce command value. 3. The inspection apparatus of claim 2 , wherein the biasing member further includes a passive component including at least one of a torsion spring, a leaf spring, a cylindrical spring, or a passive permanent magnet. 4. The inspection apparatus of claim 2 , wherein the biasing member comprises an electronically controlled electromagnet, or an active spring. 5. The inspection apparatus of claim 2 , further comprising: a plurality of arms, each of the plurality of arms pivotally mounted to at least one payload; and a plurality of sleds, wherein each of the plurality of sleds is pivotally mounted to one of the plurality of arms. 6. The inspection apparatus of claim 5 , wherein the plurality of sleds is horizontally distributed on the inspection surface at selected horizontal positions, and wherein each of the plurality of arms is horizontally moveable relative to the at least one payload. 7. The inspection apparatus of claim 2 , further comprising: an actuator, operationally coupled to the payload, structured to provide a second biasing force on the payload, wherein the second biasing force is directed such that the sled is directed toward the inspection surface. 8. The inspection apparatus of claim 7 , further comprising a controller, the controller comprising: a data collection circuit structured to provide a surface inspection value based on data received from the inspection sensor; a sensor contact circuit structured to determine a sensor contact value based on the surface inspection value; and a downforce command circuit structured to provide the downforce command value based, at least in part, on the sensor contact value, wherein the actuator is responsive to the downforce command value. 9. The inspection apparatus of claim 7 , wherein the actuator is further structured to raise the payload away from the inspection surface. 10. The inspection apparatus of claim 7 , wherein the actuator comprises a motor, push-rod, or electromagnet. 11. The inspection apparatus of claim 2 , wherein the sled comprises a sensor biasing member structured to provide a sensor biasing force on the inspection sensor coupled to the sled, wherein the sensor biasing force is directed to ensure, at least in part, a coupling of the inspection sensor to the inspection surface. 12. The inspection apparatus of claim 11 , wherein ensuring, at least in part, the coupling of the inspection sensor to the inspection surface comprises proximity control or lateral stabilization. 13. The inspection apparatus of claim 11 , wherein the sensor biasing member is passive, and comprises an embedded magnet, a torsion spring, suction force, or a leaf spring. 14. The inspection apparatus of claim 11 , wherein the sensor biasing member is active, and comprises an active electromagnet. 15. The inspection apparatus of claim 14 , further comprising a controller, the controller comprising: a data collection circuit structured to provide a surface inspection value based on data received from the inspection sensor; a sensor contact circuit structured to determine a sensor contact value based on the surface inspection value; and a downforce command circuit structured to provide the downforce command value based, at least in part, on the sensor contact value, wherein the sensor biasing member is responsive to the downforce command value. 16. The inspection apparatus of claim 2 , further comprising a controller, the controller comprising: a data collection circuit structured to provide a surface inspection value based on data received from the inspection sensor; a sensor contact circuit structured to determine a sensor contact value based on the surface inspection value; and a downforce command circuit structured to provide the downforce command value based, at least in part, on the sensor contact value. 17. The inspection apparatus of claim 16 , wherein the biasing member is responsive to the downforce command value. 18. The inspection apparatus of claim 11 , wherein the sensor biasing member is active, and comprises an active electromagnet. 19. A method, the method comprising: placing an inspection robot on an inspection surface such that a sled is in contact with the inspection surface, wherein the inspection robot includes: a payload operationally coupled to the inspection robot; an inspection sled mount and an arm, the inspection sled mount structured to pivotally couple the arm to the payload, wherein the sled is pivotally mounted to the arm; an inspection sensor coupled to the sled such that the inspection sensor is operationally couplable to the inspection surface, wherein the inspection sled mount comprises a biasing member structured to provide a biasing force on the arm, and wherein the biasing force is directed toward the inspection surface; measuring, with the inspection sensor of the sled, the inspection surface; determining a sensor contact value based, at least in part, on the measurement of the inspection surface; providing a payload downforce command to an active payload biasing member in response to the sensor contact value; identifying an obstacle on the inspection surface; and in response to an identified obstacle, adjusting the payload downforce command. 20. The method of claim 19 , further comprising providing a sled downforce command to an active sled biasing member based, at least in part, on the measurement of the inspection surface. 21. The method of claim 20 , further comprising: in response to the identified obstacle, adjusting the sled downforce