Photoelectric sensor for seed dispensing system

What is claimed is: 1. A system for monitoring the dispensing of seeds, comprising: a photoelectric sensor comprising a light-emitting element and a light-responsive element for detecting changes in light flow through an optical path between the light-emitting element and the light-responsive element, and for outputting a signal conveying detected changes in the light flow; signal conditioning circuitry adapted to condition the output signal of the photoelectric sensor to generate a pulse signal waveform with a stable baseline in which pulses generated from the passage of a conveyor flight through the optical path of the photoelectric sensor are maintained with substantially uniform amplitude to serve as a signal reference for determination of signal characteristics of pulses generated from the passage of one or more seeds through the optical path of the photoelectric sensor; and a computing device adapted to receive and process pulse signal waveforms from the signal conditioning circuitry to measure one or more parameters of the pulse signal waveform, and to distinguish portions of the pulse signal waveform based on the one or more measured parameters of the pulse signal waveform, wherein the computing device is adapted to distinguish portions of the pulse signal waveform that are attributable to disturbances in the light flow based on the passage of one or more seeds through the optical path of the photoelectric sensor from portions of the signal waveform that are attributable to disturbances in the light flow based on the passage of a conveyor flight through the optical path of the photoelectric sensor. 2. The system according to claim 1 , wherein the computing device is adapted to measure, as the one or more parameters, at least one of: a pulse peak; a pulse period; a pulse width; and a pulse area. 3. The system according to claim 2 , wherein the signal conditioning circuitry comprises at least one of a proportional-integral control loop and a gain control loop for controlling an intensity of the light-emitting element of the photoelectric sensor for maintaining pulses generated from the passage of a conveyor flight within a first predetermined intensity range, and further comprises a peak detector control loop for maintaining a stable pulse baseline. 4. The system according to claim 3 , wherein the computing device is adapted to distinguish between pulses generated from the passage of a single seed through the optical path of the photoelectric sensor and pulses generated from the concurrent passage of multiple seeds through the optical path of the photoelectric sensor. 5. The system according to claim 4 , wherein the computing device is adapted to determine at least one of a pulse width and a pulse area of pulses in the pulse signal waveform, and to distinguish pulses generated from the passage of one or more seeds from pulses generated by the passage of a conveyor flight based on one or more predetermined threshold values for pulse width and/or pulse area. 6. The system according to claim 5 , wherein the computing device is adapted to determine a period of pulses in the pulse signal waveform, and to identify pulses having a period exceeding a predetermined period threshold as a compound pulse attributable to the concurrent passage of a conveyor flight and one or more seeds, and to then adjust one or more measured parameters of identified compound pulses to remove a bias error attributable to the conveyor flight. 7. The system according to claim 1 , wherein the signal conditioning circuitry comprises at least one of a proportional-integral control loop and a gain control loop for controlling an intensity of the light-emitting element of the photoelectric sensor for maintaining pulses generated from the passage of a conveyor flight within a first predetermined intensity range, and further comprises a peak detector control loop for maintaining a stable pulse baseline. 8. The system according to claim 7 , wherein the computing device is adapted to distinguish between pulses generated from the passage of a single seed through the optical path of the photoelectric sensor and pulses generated from the concurrent passage of multiple seeds through the optical path of the photoelectric sensor. 9. The system according to claim 8 , wherein the computing device is adapted to determine at least one of a pulse width and a pulse area of pulses in the pulse signal waveform, and to distinguish pulses generated from the passage of one or more seeds from pulses generated by the passage of a conveyor flight based on one or more predetermined threshold values for pulse width and/or pulse area. 10. The system according to claim 9 , wherein the computing device is adapted to determine a period of pulses in the pulse signal waveform, and to identify pulses having a period exceeding a predetermined period threshold as a compound pulse attributable to the concurrent passage of a conveyor flight and one or more seeds, and to then adjust one or more measured parameters of identified compound pulses to remove a bias error attributable to the conveyor flight. 11. The system according to claim 1 , wherein the computing device is adapted to distinguish between pulses generated from the passage of a single seed through the optical path of the photoelectric sensor and pulses generated from the concurrent passage of multiple seeds through the optical path of the photoelectric sensor. 12. A seed dispensing system comprising: a seed dispenser comprising a passage for the conveyance of seeds, and a conveyor comprising an endless belt having a plurality of flights therealong for capturing and conveying seeds through the passage; and a system for monitoring the dispensing of seeds according to claim 1 . 13. A system for monitoring the dispensing of seeds, comprising a photoelectric sensor comprising a light-emitting element and a light-responsive element for detecting changes in light flow through an optical path between the light-emitting element and the light-responsive element, and for outputting a signal conveying detected changes in the light flow; and a computing device adapted to receive and process signal waveforms based on the output signal of the photoelectric sensor to measure one or more parameters of the signal waveform, and to distinguish portions of the signal waveform based on the one or more measured parameters of the signal waveform, wherein the computing device is adapted to determine a period of pulses in the signal waveform, and to identify pulses having a period exceeding a predetermined period threshold as a compound pulse attributable to the concurrent passage of a conveyor flight and one or more seeds, and to then adjust one or more measured parameters of identified compound pulses to remove a bias error attributable to the conveyor flight. 14. The system according to claim 13 , wherein the computing device is adapted to distinguish pulses of the signal waveform that are attributable to disturbances in the light flow based on the passage of one or more seeds through the optical path of the photoelectric sensor from pulses of the signal waveform that are attributable to disturbances in the light flow based on the passage of a conveyor flight through the optical path of the photoelectric sensor. 15. The system according to claim 13 , wherein the computing device is adapted to determine at least one of a pulse width and a pulse area of pulses in the signal waveform, and to distinguish pulses generated from the passage of one or more seeds from pulses generated by the passage of a conveyor flight based on o