Apparatus and method for monitoring autotroph cultivation

What is claimed is: 1. An apparatus comprising: at least one processing device configured to: receive a chlorophyll concentration measurement of an autotroph culture from a chlorophyll sensor; receive an optical density measurement of the autotroph culture from an optical density sensor; determine a chlorophyll concentration per optical density (CCpOD) value that is a function of the chlorophyll concentration measurement of the autotroph culture and the optical density measurement of the autotroph culture; identify a change in the autotroph culture using the CCpOD value; detect a contamination of the autotroph culture based on the identified change in the autotroph culture, the contamination including a presence of grazers or predators in the autotroph culture, the grazers comprising microorganisms that consume nutrients intended for the autotroph culture, the predators comprising microorganisms that consume the autotroph culture; and generate control signals to adjust at least one characteristic associated with the autotroph culture based on the identified change in the autotroph culture by automatically adjusting a supply component configured to provide at least one of gas, liquid, or nutrients to the autotroph culture. 2. The apparatus of claim 1 , wherein the at least one processing device is further configured to: calculate multiple CCpOD values; and generate an alarm if a specified number of the CCpOD values fall outside a range defined by upper and lower control limits. 3. The apparatus of claim 2 , wherein the at least one processing device is further configured to identify the upper and lower control limits using a specified number of previously-calculated CCpOD values. 4. The apparatus of claim 3 , wherein the previously-calculated CCpOD values are calculated when the autotroph culture is in a known healthy state. 5. The apparatus of claim 1 , further comprising: at least one interface configured to receive the chlorophyll concentration measurement from the chlorophyll sensor and the optical density measurement from the optical density sensor. 6. The apparatus of claim 1 , further comprising: the chlorophyll sensor configured to generate the chlorophyll concentration measurement. 7. The apparatus of claim 1 , further comprising: the optical density sensor configured to generate the optical density measurement. 8. The apparatus of claim 1 , further comprising: at least one memory device configured to store the CCpOD value and previously-calculated CCpOD values. 9. The apparatus of claim 1 , wherein the autotroph culture comprises algae. 10. The apparatus of claim 1 , wherein the change is a changed state of the culture compared to a known healthy state. 11. The apparatus of claim 1 , wherein the at least one processing device is configured to calculate the CCpOD value using multiple constants obtained by calibrating the chlorophyll sensor and a turbidity sensor to dry biomass using samples of a healthy autotroph culture. 12. A method comprising: identifying, by a monitoring device, a calculated chlorophyll concentration per optical density (CCpOD) value that is calculated as a function of a chlorophyll concentration measurement of an autotroph culture and an optical density measurement of the autotroph culture; identifying a change in the autotroph culture using the CCpOD value; detecting a contamination of the autotroph culture based on the identified change in the autotroph culture, the contamination including a presence of grazers or predators in the autotroph culture, the grazers comprising microorganisms that consume nutrients intended for the autotroph culture, the predators comprising microorganisms that consume the autotroph culture; and adjusting at least one characteristic associated with the autotroph culture based on the identified change in the autotroph culture by automatically adjusting a supply component configured to provide at least one of gas, liquid, or nutrients to the autotroph culture. 13. The method of claim 12 , wherein identifying the CCpOD value comprises: receiving the chlorophyll concentration measurement from a chlorophyll sensor; and receiving the optical density measurement from an optical density sensor. 14. The method of claim 12 , further comprising: calculating multiple CCpOD values; and generating an alarm if a specified number of the CCpOD values fall outside a range defined by upper and lower control limits. 15. The method of claim 12 , wherein the change is a changed state of the culture compared to a known healthy state. 16. A system comprising: a chlorophyll sensor configured to measure a chlorophyll concentration of an autotroph culture; an optical density sensor configured to measure an optical density of the autotroph culture; and a monitoring device configured to: receive a chlorophyll concentration measurement from the chlorophyll sensor; receive an optical density measurement from the optical density sensor; determine a chlorophyll concentration per optical density (CCpOD) value that is a function of the chlorophyll concentration measurement and the optical density measurement; identify a change in the autotroph culture using the CCpOD value; detect a contamination of the autotroph culture based on the identified change in the autotroph culture, the contamination including a presence of grazers or predators in the autotroph culture, the grazers comprising microorganisms that consume nutrients intended for the autotroph culture, the predators comprising microorganisms that consume the autotroph culture; and generate control signals to adjust at least one characteristic associated with the autotroph culture based on the identified change in the autotroph culture by automatically adjusting a supply component configured to provide at least one of gas, liquid, or nutrients to the autotroph culture. 17. The system of claim 16 , wherein the monitoring device is further configured to: identify upper and lower control limits using a specified number of previously-calculated CCpOD values; and determine whether the CCpOD value falls outside a range defined by the upper and lower control limits. 18. The system of claim 16 , wherein the monitoring device is further configured to: calculate multiple CCpOD values; and generate an alarm if a specified number of the CCpOD values fall outside a range defined by upper and lower control limits. 19. An apparatus comprising: at least one processing device configured to: receive a chlorophyll concentration measurement of an autotroph culture from a chlorophyll sensor; receive an optical density measurement of the autotroph culture from an optical density sensor; calculate a chlorophyll concentration per optical density (CCpOD) value that is a function of the chlorophyll concentration measurement of the autotroph culture and the optical density measurement of the autotroph culture; identify a change in the autotroph culture using the CCpOD value by determining whether the CCpOD value falls outside a range defined by upper and lower control limits; and when the change is identified, automatically adjust a supply component configured to provide at least one of gas, liquid, or nutrients to the autotroph culture; wherein the at least one processing device is configured to calculate the CCpOD value according to: (Cst 1 *chlorophyll concentration measurement−Cst 2 *turbidity)−Cst 3 wherein Cst 1 , Cst 2 , and Cst 3 are constants obtained by calibrating the chlorophyll sensor and a turb