Non-contact egg identification system for determining egg viability using transmission spectroscopy, and associated method

That which is claimed: 1. An egg identification system for determining viability of an avian egg, comprising: a conveyor system configured to convey an egg flat containing a plurality of eggs; an emitter assembly configured to emit electromagnetic radiation toward one of the eggs conveyed in the egg flat; a non-contact detector assembly axially aligned with the emitter assembly, assembly, the emitter assembly and the non-contact detector assembly forming an emitter-detector pair, the non-contact detector assembly being configured to detect the electromagnetic radiation transmitted through the egg, the non-contact detector assembly being disposed in a non-contact position such that the egg positioned for identification is spaced-apart from the non-contact detector assembly during operation thereof; a processor configured to process an output signal of the non-contact detector assembly in a transmission spectroscopy mode for determining whether the egg is viable; and an opacity identification assembly configured to determine viability of the eggs based upon an opacity associated with a respective egg, the opacity identification assembly being disposed upstream of the emitter-detector pair, the opacity identification assembly being in communication with a controller configured to disable operation of the emitter-detector pairs when a non-viable egg, as identified by the opacity identification assembly, is conveyed thereto for viability determination. 2. An egg identification system according to claim 1 , wherein the non-contact detector assembly includes a spectrometer in communication with the processor, the processor being configured to generate a spectrum based on the output signal that represents light intensity at a selected wavelength, the processor being further configured to compare the generated spectrum with at least one spectrum associated with a known egg condition to identify a viability condition of the egg. 3. An egg identification system according to claim 1 , wherein the transmission spectroscopy mode is one of infrared absorption spectroscopy and fluorescence spectroscopy. 4. An egg identification system according to claim 1 , wherein the emitter assembly comprises a modulator configured to modulate the electromagnetic radiation emitted therefrom in the form of a modulated signal. 5. An egg identification system according to claim 1 , wherein there are a plurality of the emitter-detector pairs divided into subsets, and further wherein a first subset of the emitter-detector pairs is configured to operate in an infrared absorption spectroscopy mode and a second subset of the emitter-detector pairs is configured to operate in a fluorescence spectroscopy mode such that each egg contained within the egg flat is subjected to both infrared absorption spectroscopy analysis and fluorescence spectroscopy analysis for determining viability of the eggs transported in the egg flat by the conveyor system. 6. An egg identification system according to claim 1 , wherein the emitter assembly is configured to emit electromagnetic radiation at a wavelength different than that detected by the non-contact detector assembly. 7. An egg identification system according to claim 1 , further comprising a plurality of the emitter assemblies being divided into subsets, wherein a first subset of the emitter assemblies is configured to emit electromagnetic radiation at a first wavelength and a second subset of the emitter assemblies is configured to emit electromagnetic radiation at a second wavelength different than the first wavelength. 8. An egg identification system according to claim 1 , further comprising a plurality of the non-contact detector assemblies being divided into subsets, wherein a first subset of the non-contact detector assemblies is configured to detect electromagnetic radiation at a first optical bandwidth and a second subset of the non-contact detector assemblies is configured to detect electromagnetic radiation at a second optical bandwidth. 9. A method of determining viability of an egg, the method comprising: conveying an egg contained in an egg flat using a conveyor system; emitting electromagnetic radiation from an emitter assembly toward the egg; receiving electromagnetic radiation transmitted through the egg at a non-contact detector assembly axially aligned with the emitter assembly to form an emitter-detector pair, the non-contact detector assembly being spaced-apart from the egg; processing an output signal of the non-contact detector assembly in a transmission spectroscopy mode for determining whether the egg is viable; conveying the egg through an opacity identification assembly configured to determine viability of the eggs based upon an opacity associated with the egg, the opacity identification assembly being disposed upstream of the emitter-detector pair; and disabling operation of the emitter-detector pair when a non-viable egg, as identified by the opacity identification assembly, is conveyed thereto for viability determination. 10. A method according to claim 9 , wherein processing an output signal of the non-contact detector assembly in a transmission spectroscopy mode comprises generating a spectrum based on the output signal that represents light intensity at a selected wavelength, and comparing the generated spectrum with at least one spectrum associated with a known egg condition to identify a viability condition of the egg. 11. A method according to claim 9 , wherein processing an output signal of the non-contact detector assembly in a transmission spectroscopy mode comprises processing an output signal of the non-contact detector assembly in one of an infrared absorption spectroscopy mode and a transmission fluorescence spectroscopy mode. 12. A method according to claim 9 , wherein emitting electromagnetic radiation from an emitter assembly comprises modulating the electromagnetic radiation emitted from the emitter assembly in the form of a modulated signal. 13. A method according to claim 9 , further comprising providing a plurality of the emitter-detector pairs being divided into subsets, and wherein conveying the egg comprises conveying the egg past a first subset of the emitter-detector pairs implementing a transmission absorption spectroscopy mode and a second subset of the emitter-detector pairs implementing a transmission fluorescence spectroscopy mode such that the egg is subjected to both transmission absorption spectroscopy and transmission fluorescence spectroscopy for determining viability. 14. A method according to claim 9 , wherein emitting electromagnetic radiation from an emitter assembly further comprises emitting electromagnetic radiation at a wavelength different than that detected by the non-contact detector assembly. 15. A method according to claim 9 , further comprising providing a plurality of the emitter assemblies divided into subsets, and emitting electromagnetic radiation from a first subset of the emitter assemblies at a first wavelength and emitting electromagnetic radiation from a second subset of the emitter assemblies at a second wavelength different than the first wavelength. 16. A method according to claim 9 , further comprising providing a plurality of the non-contact detector assemblies divided into subsets, and detecting electromagnetic radiation from a first subset of the non-contact detector assemblies at a first optical bandwidth and detecting electromagnetic radiation from a second subset of the non-contact detector assemblies at a second optical bandwidth.