Caster wheel orientation sensor assembly

What is claimed is: 1. A caster wheel orientation sensor assembly, said assembly comprising: a wheel arm having first and second ends oppositely disposed; a wheel attached to said first end of said wheel arm, said wheel being rotatable about a first axis; a shaft fixedly attached to said second end of said wheel arm and oriented transversely to said first axis, a sensor target positioned on said shaft; a bearing defining a bore, said shaft being received within said bore, said shaft being rotatable about a second axis oriented coaxially with said bore; a sensor mounted on said bearing, said sensor adapted to sense a presence or absence of said sensor target upon rotation of said shaft and generate signals indicative of said presence or said absence of said sensor target. 2. The sensor assembly according to claim 1 , wherein said sensor target comprises a groove extending about a portion of a circumference of said shaft. 3. The sensor assembly according to claim 2 , wherein said groove subtends an angle of 285° about said shaft. 4. The sensor assembly according to claim 2 , wherein said groove has a uniform depth over its entire extent. 5. The sensor assembly according to claim 2 , wherein said groove has a non-uniform depth. 6. The sensor assembly according to claim 2 , wherein said groove is positioned within said bearing. 7. The sensor assembly according to claim 5 , wherein said groove comprises a first portion having a depth which increases with distance about said circumference, a second portion having a uniform depth, and a third portion having a depth which increases with distance about said circumference, said second portion being positioned between said first and third portions. 8. The sensor assembly according to claim 7 , wherein said depth of said first portion and said depth of said second portion increase linearly with said distance about said circumference. 9. The sensor assembly according to claim 6 , wherein said groove is positioned distal to said second end of said wheel arm. 10. The sensor assembly according to claim 2 , wherein said groove subtends an angle between 270° and 300° about said shaft. 11. The sensor assembly according to claim 1 , wherein said sensor comprises a proximity sensor. 12. The sensor assembly according to claim 11 , wherein said sensor is selected from the group consisting of Hall effect sensors, capacitive sensors, inductive sensors, optical sensors and ultrasonic sensors. 13. The sensor assembly according to claim 1 , wherein said sensor target comprises a recess in said shaft. 14. The sensor assembly according to claim 13 , wherein said recess comprises a flat surface. 15. The sensor assembly according to claim 14 , wherein said flat surface extends across a chord of a cross section of said shaft. 16. A harvester having a caster wheel orientation sensor system, said harvester comprising: a chassis; a first wheel arm having first and second ends oppositely disposed; a first wheel attached to said first end of said first wheel arm, said first wheel being rotatable about a first wheel axis; a first shaft fixedly attached to said second end of said first wheel arm and oriented transversely to said first wheel axis, a sensor target positioned on said shaft; a first bearing defining a first bore, said first shaft being received within said first bore, said first shaft being rotatable about a first shaft axis oriented coaxially with said first bore, said first bearing being mounted on said chassis; a sensor mounted on said first bearing, said sensor adapted to sense a presence or absence of said sensor target upon rotation of said first shaft and generate signals indicative of said presence or said absence of said groove; a controller mounted on said chassis, said controller adapted to receive said signals. 17. The harvester according to claim 16 , wherein said sensor target comprises a groove extending about a portion of a circumference of said shaft. 18. The harvester according to claim 17 , wherein said groove subtends an angle between 270° and 300° about said shaft. 19. The harvester according to claim 17 , wherein said groove subtends an angle of 285° about said shaft. 20. The harvester according to claim 17 , wherein said groove has a uniform depth over its entire extent. 21. The harvester according to claim 17 , wherein said groove has a non-uniform depth. 22. The harvester according to claim 21 , wherein said groove comprises a first portion having a depth which increases with distance about said circumference, a second portion having a uniform depth, and a third portion having a depth which increases with distance about said circumference, said second portion being positioned between said first and third portions. 23. The harvester according to claim 22 , wherein said depth of said first portion and said depth of said second portion increase linearly with said distance about said circumference. 24. The harvester according to claim 17 , wherein said groove is positioned within said first bearing. 25. The harvester according to claim 24 , wherein said groove is positioned distal to said second end of said wheel arm. 26. The harvester according to claim 16 , wherein said sensor comprises a proximity sensor. 27. The harvester according to claim 26 , wherein said sensor is selected from the group consisting of Hall effect sensors, capacitive sensors, inductive sensors, optical sensors and ultrasonic sensors. 28. The harvester according to claim 16 , further comprising: a second wheel arm having first and second ends oppositely disposed; a second wheel attached to said first end of said second wheel arm, said second wheel being rotatable about a second wheel axis; a second shaft fixedly attached to said second end of said second wheel arm and oriented transversely to said second wheel axis; a second bearing defining a second bore, said second shaft being received within said second bore, said second shaft being rotatable about a second shaft axis oriented coaxially with said second bore; an actuator acting between said chassis and one of said first and second shafts, said actuator being adapted to rotate said one of said first and second shafts for steering said harvester; wherein said controller is adapted to prevent said actuator from rotating said one of said first and second shafts upon receipt of said signals from said sensor indicative of said presence or said absence of said sensor target. 29. The harvester according to claim 16 , wherein said sensor target comprises a recess in said shaft. 30. The harvester according to claim 29 , wherein said recess comprises a flat surface. 31. The harvester according to claim 30 , wherein said flat surface extends across a chord of a cross section of said shaft.