Systems and methods for fuel injector control

What is claimed is: 1. A multi-fuel injector assembly comprising: a first fuel injector assembly configured to deliver a first type of fuel to a cylinder of an engine, the first fuel injector assembly comprising a first nozzle, a first needle, and a first actuator, the first nozzle comprising a first cavity that houses the first needle; a second fuel delivery system configured to deliver a second type of fuel to the cylinder, the second fuel delivery system comprising a second nozzle, a second needle, and a second actuator, the second nozzle comprising a second cavity that houses the second needle; and one or more processors operably connected to the first fuel injector assembly and the second fuel delivery system and configured to control the first fuel injector assembly and the second fuel delivery system to provide a first target fuel composition to the cylinder during a first time period of engine operational and to provide a second target fuel composition to the cylinder during a second time period of engine operation, the first target fuel composition being different from the second target fuel composition, wherein, to achieve the first target fuel composition, the one or more processors control the first actuator to position the first needle at a first fuel delivery position within the first cavity to deliver a first, non-zero amount of the first type of fuel to the cylinder, and control the second actuator to position the second needle at a first position within the second cavity, and to achieve the second target fuel composition, the one or more processors control the first actuator to move the first needle within the first cavity to a second fuel delivery position to deliver a second, non-zero amount of the first type of fuel to the cylinder, and control the second actuator to move the second needle within the second cavity from the first position to a second position to deliver a non-zero amount of the second type of fuel to the cylinder, such that the second target fuel composition includes both the first and second types of fuel. 2. The multi-fuel injector assembly of claim 1 , wherein the first fuel injector assembly is configured to inject the first type of fuel directly into the cylinder, and the second fuel delivery system is configured to provide the second type of fuel into an intake assembly that is operably connected to the cylinder. 3. The multi-fuel injector assembly of claim 1 , wherein the first type of fuel is diesel fuel. 4. The multi-fuel injector assembly of claim 3 , wherein the second type of fuel comprises at least one of hydrogen, ethanol, methanol, gasoline, ammonia, natural gas, or methane. 5. The multi-fuel injector assembly of claim 4 , wherein the first fuel injector assembly is configured to inject the diesel fuel directly into the cylinder, and the second fuel delivery system is configured to emit the at least one of hydrogen, ethanol, methanol, gasoline, ammonia, natural gas, or methane into an intake assembly that is fluidly connected to the cylinder. 6. The multi-fuel injector assembly of claim 1 , wherein the first position of the second needle within the second cavity is a closed position of the second fuel delivery system such that the first type of fuel represents 100 percent of the first target fuel composition. 7. The multi-fuel injector assembly of claim 1 , wherein the first actuator includes at least a first coil and a second coil disposed around the first needle, the one or more processors configured to activate the first coil to place the first needle in the first fuel delivery position, the one or more processors configured to activate the second coil along with or instead of the first coil to place the first needle in the second fuel delivery position. 8. The multi-fuel injector assembly of claim 1 , wherein the first nozzle comprises a first set of nozzle openings and a second set of nozzle openings, wherein, in the first fuel delivery position, the first needle permits flow of the first type of fuel from the first cavity through the first set of nozzle openings but not the second set of nozzle openings, and, in the second fuel delivery position, the first needle permits flow of the first type of fuel from the first cavity through both the first and second sets of nozzle openings. 9. The multi-fuel injector assembly of claim 1 , wherein the first needle is an outer needle, and the first fuel injector assembly comprises an inner needle movably disposed in the outer needle. 10. The multi-fuel injector assembly of claim 1 , wherein the first time period of engine operation corresponds to an initial warm up period and the second time period of engine operation is after the initial warm up period. 11. The multi-fuel injector assembly of claim 1 , wherein the one or more processors are configured to control the second actuator of the second fuel delivery system to position the second needle at the first position within the second cavity to deliver a second non-zero amount of the second type of fuel to the cylinder, such that both the first type of fuel and the second type of fuel are present in each of the first target fuel composition and the second target fuel composition. 12. An engine assembly comprising: a cylinder of an engine; an intake assembly operably coupled to the cylinder; a first fuel injector assembly configured to deliver a first type of fuel directly to the cylinder, the first fuel injector assembly comprising: a nozzle comprising a cavity in fluid communication with nozzle openings, each of the nozzle openings extending through a wall of the nozzle from the cavity to an exterior surface of the nozzle that is within the cylinder, the nozzle openings comprising a first set of the nozzle openings and a second set of the nozzle openings; a needle movably disposed within the cavity, the needle preventing flow of the first type of fuel from the cavity through any of the nozzle openings in a closed position of the first fuel injector assembly; and an actuator that moves the needle within the cavity between the closed position, a first fuel delivery position within the cavity, and a second fuel delivery position within the cavity, wherein the actuator moves the needle from the closed position to the first fuel delivery position to emit a first, non-zero amount of the first type of fuel from the cavity through the first set of nozzle openings while blocking the second set of nozzle openings, and the actuator moves the needle to the second fuel delivery position to emit a second, non-zero amount of the first type of fuel from the cavity through both the first and second sets of nozzle openings; and a second fuel delivery system configured to deliver a second type of fuel to the intake assembly. 13. The engine assembly of claim 12 , wherein the first type of fuel is diesel fuel. 14. The engine assembly of claim 13 , wherein the second type of fuel comprises at least one of hydrogen, ethanol, methanol, gasoline, ammonia, natural gas, or methane. 15. The engine assembly of claim 12 , further comprising one or more processors communicatively connected to the second fuel delivery system and configured to control the second fuel delivery system to only deliver the second type of fuel to the intake assembly when the needle of the first fuel injector assembly is in the first fuel delivery position. 16. A method comprising: controlling, via one or more processors, a first fuel injector assembly and a second fuel delivery system to provide a first target fuel composition to a cylinder of an engine during a first time period of engine operation; and c