Mobile platform for materials transport

What is claimed is: 1. A mobile platform comprising: a chassis comprising a first end, a second end distal the first end, and opposite sides extending therebetween; a pair of suspension devices located on the opposite sides, each comprising: a respective rocker beam, pivotally connected to a respective side, and extending from about a centre of the chassis to about the first end, and being one of a pair of rocker beams; a respective central wheel connected to the rocker beam at about the centre, and being one of a pair of central wheels; and, a respective first end wheel connected to the rocker beam at about the first end, and being one of a pair of first end wheels; and, one or more second end wheels located at the second end, each of the pair of rocker beams configured to rotate between at least: a first position, the pair of central wheels extending outwards from a bottom portion of the chassis in the first position, such that the chassis rolls using at least the pair of central wheels; and, a second position, the pair of central wheels retracting towards the bottom portion in the second position, such that the chassis rolls using the pair of first end wheels, and the one or more second end wheels without the pair of central wheels; a drive system configured to drive the pair of central wheels; one or more sensors positioned to sense one or more of force, a strain, and a rotation of one or more of the pair of suspension devices; one or more load cells configured to sense a load on the chassis; and, a control device in communication with the one or more sensors and the one or more load cells, the control device configured to adjust operation of the drive system according to data received from the or more sensors and the one or more load cells. 2. The mobile platform of claim 1 , wherein, in the first position, the pair of central wheels, the pair of first end wheels, and the one or more second end wheels are all configured to contact ground, and in the second position, the pair of first end wheels, and the one or more second end wheels are configured to contact the ground, the pair of central wheels being retracted. 3. The mobile platform of claim 1 , further comprising a pair of actuation devices configured to rotate the pair of rocker beams between the first position and the second position. 4. The mobile platform of claim 3 , wherein each of the pair of actuation devices is located on a top side of the chassis, and between the pair of first end wheels and respective pivot points of the pair of rocker beams. 5. The mobile platform of claim 3 , wherein the pair of actuation devices comprises a pair of jackscrews positioned in respective complementary threaded apertures in the chassis and configured to urge the pair of rocker beams from the first position to the second position when the pair of jackscrews are actuated downward, and release the pair of rocker beams from the second position to the first position when the pair of jackscrews are actuated upward. 6. The mobile platform of claim 1 , wherein each of the pair of first end wheels and the one or more second end wheels comprises a respective caster wheel. 7. The mobile platform of claim 1 , further comprising a further suspension device extending between the opposite sides of the chassis at the second end, the one or more second end wheels attached to the further suspension device. 8. The mobile platform of claim 1 , wherein the one or more second end wheels comprises: a pair of second end wheels located at second end corners of the chassis. 9. The mobile platform of claim 1 , wherein each of the pair of rocker beams further comprises a respective pivot point located between the respective central wheel and the respective first end wheel. 10. The mobile platform of claim 1 , further comprising a drive system configured to drive the pair of central wheels. 11. The mobile platform of claim 10 , wherein the drive system connects the pair of central wheels, and the drive system is further configured to move together with the pair of central wheels when the pair of rocker beams rotate. 12. The mobile platform of claim 11 , wherein the chassis comprises a space into which the drive system can move when the pair of rocker beams rotate from the first position to the second position. 13. The mobile platform of claim 1 , wherein the control device is further configured to moderate speed of the drive system when the data received from the one or more sensors and the one or more load cells indicates one or more of: bumps encountered by the pair of central wheels; and load instability. 14. The mobile platform of claim 1 , further comprising one or more lift points. 15. The mobile platform of claim 1 , further comprising a fairing. 16. The mobile platform of claim 1 , further comprising one or more of: a remote controlled vehicle, a remote guided vehicle, a robot, and an autonomous vehicle. 17. The mobile platform of claim 1 , wherein the control device is operable to: detect a load instability event based on the data received from at least one of at least one sensor and at least one load cell; and adjust a speed of the drive system in response to detecting the load instability event. 18. The mobile platform of claim 17 , wherein the control device is operable to: determine a detected change at the at least one of the at least one sensor and the at least one load cell triggers the load instability event. 19. The mobile platform of claim 18 , wherein the control device is operable to: determine the detected change from a shift in load distribution detected by the at least one of the at least one sensor and the at least one load cell; and adjust the speed of the drive system to compensate for the shift in load distribution. 20. The mobile platform of claim 18 , wherein the control device is operable to: determine the detected change from a force differential detected by the at least one of the at least one sensor and the at least one load cell resulting from encountering rugged terrain; and adjust the speed of the drive system to compensate for the force differential.