Engine cooling system and method for an engine

What is claimed is: 1. A thermal management system, comprising: a first cooling circuit including an air-to-coolant radiator system; a second cooling circuit including an engine coolant jacket, the engine coolant jacket surrounding a plurality of cylinders of an engine; a coolant pump configured to provide coolant to the first cooling circuit and the second cooling circuit in parallel, wherein the air-to-coolant radiator system of the first cooling circuit is configured to cool coolant from the coolant pump; a fan operable to provide air flow to the air-to-coolant radiator system; a cooling shutter, positioned on another side of the air-to-coolant radiator system and remote from the fan, and being adjustable to control the air flow through the air-to-coolant radiator system, where coolant is pumped from the coolant pump through the first coolant circuit without first passing through one or more elements of the second cooling circuit; and a passive orifice flow restrictor, positioned between an outlet of the coolant pump and an inlet of the air-to-coolant radiator system, to control a flow of coolant to the air-to-coolant radiator system. 2. The thermal management system of claim 1 , wherein coolant is pumped from the coolant pump through the second cooling circuit without first passing through one or more elements of the first cooling circuit, and wherein the air-to-coolant radiator system includes a first sub-cooler, a second sub-cooler, and a radiator positioned within an air flow path of the air flow provided by the fan when the fan is operable, the air flow path passing through the second sub-cooler to the first sub-cooler and through the first sub-cooler to the radiator. 3. The thermal management system of claim 2 , further comprising a split passageway attached to an outlet of the radiator and configured to split coolant exiting the radiator into a first portion of coolant provided to the coolant pump and a second portion of coolant provided to the first sub-cooler. 4. A thermal management system comprising: a first cooling circuit including an air-to-coolant radiator system; a second cooling circuit including an engine coolant jacket, the engine coolant jacket surrounding a plurality of cylinders of an engine; a coolant pump configured to provide coolant to the first cooling circuit and the second cooling circuit in parallel, wherein the air-to-coolant radiator system of the first cooling circuit is configured to cool coolant from the coolant pump; a fan operable to provide air flow to the air-to-coolant radiator system; a cooling shutter, positioned on another side of the air-to-coolant radiator system and remote from the fan, and being adjustable to control the air flow through the air-to-coolant radiator system, where coolant is pumped from the coolant pump through the first coolant circuit without first passing through one or more elements of the second cooling circuit, wherein coolant is pumped from the coolant pump through the second cooling circuit without first passing through one or more elements of the first cooling circuit, and wherein the air-to-coolant radiator system includes a first sub-cooler, a second sub-cooler, and a radiator positioned within an air flow path of the air flow provided by the fan when the fan is operable, the air flow path passing through the second sub-cooler to the first sub-cooler and through the first sub-cooler to the radiator; a split passageway attached to an outlet of the radiator and configured to split coolant exiting the radiator into a first portion of coolant provided to the coolant pump and a second portion of coolant provided to the first sub-cooler; and further comprising a first passive orifice flow restrictor, positioned between the outlet of the radiator and an inlet of the coolant pump, and a second passive orifice flow restrictor, positioned between an outlet of the engine coolant jacket and the inlet of the coolant pump, to control a flow of coolant to the coolant pump. 5. The thermal management system of claim 3 , wherein an output of the second sub-cooler is connected to a water-based intercooler of the engine, for coolant exiting the second sub-cooler to be directed to the water-based intercooler. 6. The thermal management system of claim 5 , further comprising a first vent line positioned between the engine and an expansion tank, a second vent line positioned between the water-based intercooler and the expansion tank, and a third vent line positioned between the air-to-coolant radiator system and the expansion tank, the first vent line having a larger diameter than a diameter of the second vent line and having a larger diameter than a diameter of the third vent line. 7. The thermal management system of claim 5 , wherein an output of the water-based intercooler of the engine is connected to an oil cooler and an output of the oil cooler is connected to an inlet of the coolant pump, the thermal management system being configured for coolant exiting the water-based intercooler of the engine to be directed to the oil cooler and coolant exiting the oil cooler to be directed to the inlet of the coolant pump. 8. The thermal management system of claim 7 , wherein an output of the engine coolant jacket, an output of the oil cooler, and an output of the radiator are each connected to the inlet of the coolant pump, the thermal management system being configured for coolant exiting the engine coolant jacket, coolant exiting the oil cooler, and coolant exiting the radiator to be mixed before entering the inlet of the coolant pump. 9. The thermal management system of claim 1 , wherein a diverter section is connected to an output of the coolant pump, the thermal management system being configured for an equal amount of coolant directed through the diverter section to be directed to the first cooling circuit and to the second cooling circuit. 10. The thermal management system of claim 1 , further comprising a controller configured to control the shutter based at least in part on one or more sensed ambient conditions in response to a sensed coolant temperature relative to a minimum temperature threshold value. 11. The thermal management system of claim 1 , further comprising a controller configured to control the cooling shutter and the fan in response to a sensed intake manifold air temperature. 12. A thermal management method comprising: pumping coolant from a coolant pump of an engine to two or more cooling circuits in parallel, one of the cooling circuits including an air-to-coolant radiator system and another of the cooling circuits including an engine coolant jacket surrounding a plurality of cylinders of the engine, the coolant pumped from the coolant pump to the air-to-coolant radiator system controlled via a passive orifice flow restrictor, positioned between an outlet of the coolant pump and an inlet of the air-to-coolant radiator system, and without passing through the engine coolant jacket; detecting one or more operating parameters of the engine; adjusting a fan to adjust air flow provided by the fan to the air-to-coolant radiator system, the air flow being adjusted based on one or more detected operating parameters; and adjusting a cooling shutter to adjust air flow provided to the air-to-coolant radiator system based on one or more detected operating parameters. 13. The thermal management method of claim 12 , wherein detecting one or more operating parameters of the engine further comprises detecting an engine coolant temperature. 14. The thermal management method of claim 12 , wherein detecting one or more operating parameters further comprises detecting an intake man