Angled sensor bar for detecting plants

What is claimed is: 1. A detasseler system mountable to a mobile platform, the detasseling system comprising: a lift assembly connected to a mobile platform; and a detasseling assembly connected to the lift assembly, the lift assembly structured and operable to raise and lower the detasseling assembly, the detasseling assembly structured and operable to detassel the plants in a single row of plants in a test plot as the detasseler system is moved through the test plot, the test plot comprising at least one row of plants comprising a plurality of plants the detasseling assembly comprising: a head assembly comprising: a carrier bar connected to the lift assembly; a cutter head disposed at a first distal end of the carrier bar; and a puller head disposed at an opposing second distal end of the carrier bar; a sensor boom fixedly connected at a proximal end to the lift assembly; and an angled sensor bar assembly connected to sensor boom, the angled sensor bar assembly comprising: an sensor bar connected at a midsection thereof to the sensor boom at an angle such that a non-orthogonal angle is defined between the sensor bar and the sensor boom; and a sensor system connected to the angle sensor bar, the sensor system structured and operable to detect the presence of a plant within a sensing field of the sensor system, and to detect the top of a target plant within the sensing field when the presence of a plant is detected. 2. The system of claim 1 , wherein the sensor bar has a length and the non-orthognal angle between the sensor bar and the sensor boom is such that, as the detasseler system is moved through the test plot, a plurality of plants in the single row of plants are simultaneously within the sensing field of the sensor system. 3. The system of claim 2 , wherein the non-orthogonal angle between the sensor bar and the sensor boom is between 20° and 80°. 4. The system of claim 3 , wherein the sensor bar is pivotally connected at the midsection thereof to the sensor boom at a sensor bar axis of rotation such that the sensor bar assembly can be pivoted about the sensor bar axis of rotation to change the non-orthogonal angle between the sensor bar and the sensor boom. 5. The system of claim 1 , wherein the sensor system comprises: at least one transceiver connected at a first end of the angled sensor bar; and at least one reflector connected at a second end of the angled sensor bar, and the sensing field is a line-of-sight between the at least one transceiver and the reflector. 6. The system of claim 5 , wherein the length of the sensor bar and the non-orthogonal angle between the sensor bar and the sensor boom is such that, as the detasseler system is moved through the test plot, the at least one transceiver is disposed within a first lane on a first side of the single row of plants and the at least one reflector is disposed within a second lane on an opposing second side of the single row of plants, and a plurality of plants in the single row of plants are simultaneously within a line-of-sight between the at least one transceiver and the at least one reflector. 7. The system of claim 6 , wherein the sensor system comprises a pair of vertically oriented and vertically stacked transceivers each having an emitter and a receiver, wherein the emitter and receiver are disposed in a horizontal side-by-side relationship with each other. 8. The system of claim 1 , wherein the carrier bar is rotatably connected to the lift assembly at a carrier bar axis of rotation such that the head assembly can be alternated between a cutter active position and a puller active position by rotation of the head assembly about the carrier bar axis of rotation. 9. The system of claim 8 wherein the detasseling assembly further comprises a locking mechanism structured and operable to secure the head assembly in each of the cutter active and puller active positions. 10. A mobile system for detasseling plants in a test plot, said system comprising: a mobile platform structured and operable to move through the test plot, the test plot comprising at least one row of plants comprising a plurality of plants; a detasseler system mounted to the mobile platform, the detasseling system comprising: a lift assembly connected to the mobile platform; and a detasseling assembly connected to the lift assembly, the lift assembly structured and operable to raise and lower the detasseling assembly, the detasseling assembly structured and operable to detassel the plants in a single row of plants in the test plot as the mobile platform moves through the test plot, the detasseling assembly comprising: a head assembly comprising: a carrier bar connected to the lift assembly; a cutter head disposed at a first distal end of the carrier bar; and a puller head disposed at an opposing second distal end of the carrier bar; a sensor boom fixedly connected at a proximal end to the lift assembly; and an angled sensor bar assembly connected to sensor boom, the angled sensor bar assembly comprising: a sensor bar connected at a midsection thereof to the sensor boom at an angle such that a non-orthogonal angle is defined between the sensor bar and the sensor boom; and a sensor system connected to the angle sensor bar, the sensor system structured and operable to detect the presence of a plant within a sensing field of the sensor system, and to detect the top of a target plant within the sensing field when the presence of a plant is detected. 11. The system of claim 10 , wherein the sensor bar has a length and the non-orthognal angle between the sensor bar and the sensor boom is such that, as the mobile platform moves through the test plot, a plurality of plants in the single row of plants are simultaneously within the sensing field of the sensor system. 12. The system of claim 11 , wherein the non-orthogonal angle between the sensor bar and the sensor boom is between 20° and 80°. 13. The system of claim 12 , wherein the sensor bar is pivotally connected at the midsection thereof to the sensor boom at a sensor bar axis of rotation such that the sensor bar assembly can be pivoted about the sensor bar axis of rotation to change the non-orthogonal angle between the sensor bar and the sensor boom. 14. The system of claim 10 , wherein the sensor system comprises: at least one transceiver connected at a first end of the angled sensor bar; and at least one reflector connected at a second end of the angled sensor bar, and the sensing field is a line-of-sight between the at least one transceiver and the reflector. 15. The system of claim 14 , wherein the length of the sensor bar and the non-orthogonal angle between the sensor bar and the sensor boom is such that, as the mobile platform moves through the test plot, the at least one transceiver is disposed within a first lane on a first side of the single row of plants and the at least one reflector is disposed within a second lane on an opposing second side of the single row of plants, and a plurality of plants in the single row of plants are simultaneously within a line-of-sight between the at least one transceiver and the at least one reflector. 16. The system of claim 15 , wherein the sensor system comprises a pair of vertically oriented and vertically stacked transceivers each having an emitter and a receiver, wherein the emitter and receiver are disposed in a horizontal side-by-side relationship with each other. 17. The system of claim 10 , wherein the carrier bar is rotatably connected to the lift assembly at a carrier bar axis of rotation such that the head assem