Self-calibrating ultrasonic removal of ectoparasites from fish

What is claimed is: 1. A computer-implemented method, comprising: generating, by ultrasonic transducers distributed in a sea lice treatment station, a first set of ultrasonic signals; detecting, by the ultrasonic transducers, a second set of ultrasonic signals in response to propagation of the first set of ultrasonic signals through water in the sea lice treatment station; determining propagation parameters of the sea lice treatment station based on the second set of ultrasonic signals that were detected; storing the propagation parameters for later treatment of sea lice; and using the stored propagation parameters to generate a set of ultrasonic signals that focus energy at a sea louse. 2. The method of claim 1 , wherein detecting, by the ultrasonic transducers, a second set of ultrasonic signals in response to propagation of the first set of ultrasonic signals through water in the sea lice treatment station comprises: detecting, by a first ultrasonic transducer, ultrasonic signals in response to propagation of a first ultrasonic signal that was generated by a second ultrasonic transducer; and detecting, by the first ultrasonic transducer, ultrasonic signals in response to propagation of a second ultrasonic signal that was generated by a third ultrasonic transducer after the first ultrasonic signal was generated. 3. The method of claim 1 wherein determining propagation parameters of the sea lice treatment station based on the second set of ultrasonic signals that were detected comprises: determining at least one of: pulse or spectral width of ultrasonic signals of the second set of ultrasonic signals, time offsets between detections of the second set of ultrasonic signals and generation of the first set of ultrasonic signals, or reflections of the first set of ultrasonic signals. 4. The method of claim 1 wherein determining propagation parameters of the sea lice treatment station based on the second set of ultrasonic signals that were detected comprises: determining time delays of pulsed ultrasonic signals in the set of ultrasonic signals. 5. The method of claim 1 , comprising obtaining sensor data from at least one of a water temperature sensor, a water pressure sensor, or a water salinity sensor, wherein determining propagation parameters of the sea lice treatment station is based on the sensor data and the second set of ultrasonic signals that were detected. 6. The method of claim 1 , wherein storing the propagation parameters for later treatment of sea lice comprises: storing propagation parameters for each of the ultrasonic transducers. 7. A computer-implemented method, comprising: obtaining an image of a sea louse on a fish in a sea lice treatment station; determining, from the image, a location of the sea louse in the sea lice treatment station; accessing propagation parameters of the sea lice treatment station from storage of the sea lice treatment station; and generating, by ultrasonic transducers of the sea lice treatment station and based on the propagation parameters and the location of the sea louse in the sea lice treatment station, a third set of ultrasonic signals that focuses energy at the sea louse. 8. The method of claim 7 , wherein generating a third set of ultrasonic signals that focuses energy at the sea louse comprises: determining, from the image, that a portion of the fish is not between a particular ultrasonic transducer and the sea louse; and based on determining, from the image, that the portion of the fish is not between the particular ultrasonic transducer and the sea louse, generating an ultrasonic signal of the third set of ultrasonic signals with the particular ultrasonic transducer. 9. The method of claim 7 , wherein generating a third set of ultrasonic signals that focuses energy at the sea louse comprises: determining, from the image, that a portion of the fish is between a particular ultrasonic transducer and the sea louse; and based on determining, from the image, that the portion of the fish is between the particular ultrasonic transducer and the sea louse, determining not to generate an ultrasonic signal with the particular ultrasonic transducer. 10. A non-transitory computer storage medium encoded with instructions that, when executed by one or more computers, cause the one or more computers to perform operations comprising: generating, by ultrasonic transducers distributed in a sea lice treatment station, a first set of ultrasonic signals; detecting, by the ultrasonic transducers, a second set of ultrasonic signals in response to propagation of the first set of ultrasonic signals through water in the sea lice treatment station; determining propagation parameters of the sea lice treatment station based on the second set of ultrasonic signals that were detected; storing the propagation parameters for later treatment of sea lice; and using the stored propagation parameters to generate a set of ultrasonic signals that focus energy at a sea louse. 11. The computer storage medium of claim 10 , wherein detecting, by the ultrasonic transducers, a second set of ultrasonic signals in response to propagation of the first set of ultrasonic signals through water in the sea lice treatment station comprises: detecting, by a first ultrasonic transducer, ultrasonic signals in response to propagation of a first ultrasonic signal that was generated by a second ultrasonic transducer; and detecting, by the first ultrasonic transducer, ultrasonic signals in response to propagation of a second ultrasonic signal that was generated by a third ultrasonic transducer after the first ultrasonic signal was generated. 12. The computer storage medium of claim 10 wherein determining propagation parameters of the sea lice treatment station based on the second set of ultrasonic signals that were detected comprises: determining at least one of: pulse or spectral width of ultrasonic signals of the second set of ultrasonic signals, time offsets between detections of the second set of ultrasonic signals and generation of the first set of ultrasonic signals, or reflections of the first set of ultrasonic signals. 13. The computer storage medium of claim 10 wherein determining propagation parameters of the sea lice treatment station based on the second set of ultrasonic signals that were detected comprises: determining time delays of pulsed ultrasonic signals in the set of ultrasonic signals. 14. The computer storage medium of claim 10 , comprising obtaining sensor data from at least one of a water temperature sensor, a water pressure sensor, or a water salinity sensor, wherein determining propagation parameters of the sea lice treatment station is based on the sensor data and the second set of ultrasonic signals that were detected. 15. The computer storage medium of claim 10 , wherein storing the propagation parameters for later treatment of sea lice comprises: storing propagation parameters for each of the ultrasonic transducers. 16. A non-transitory computer storage medium encoded with instructions that, when executed by one or more computers, cause the one or more computers to perform operations comprising: obtaining an image of a sea louse on a fish in a sea lice treatment station; determining, from the image, a location of the sea louse in the sea lice treatment station; accessing propagation parameters of the sea lice treatment station from storage of the sea lice treatment station; and generating, by ultrasonic transducers of the sea lice treatment station and based on the propagation parameters and the location