Methods and systems for thermal management in a vehicle

The invention claimed is: 1. A method for controlling a heat exchanger in a vehicle, the method comprising: controlling a flow of coolant from each of a first coolant system and a second coolant system through the heat exchanger based on an estimated coolant temperature model and one or more dynamic conditions of the vehicle, wherein the first coolant system includes a battery coolant system including a battery of the vehicle and an inverter system controller (ISC) coolant system including an ISC, and wherein the second coolant system includes an engine coolant system including an engine of the vehicle; wherein the one or more dynamic conditions of the vehicle include a state of charge of the battery and/or a battery temperature. 2. The method of claim 1 , wherein the one or more dynamic conditions of the vehicle includes an engine temperature, and/or an ambient temperature of the vehicle and wherein the estimated coolant temperature model is based at least on information from an electronic horizon data source and/or vehicle sensors indicating expected driving conditions for a vehicle trip, the expected driving conditions indicating expected battery and/or engine usage. 3. The method of claim 1 , wherein the vehicle is a hybrid vehicle, the method further comprising operating in one of a plurality of vehicle operation modes including a first, battery-operated mode, where the vehicle is operated only via the battery, a second, engine-operated mode, where the vehicle is operated only via the engine, and/or a third, hybrid mode, where the vehicle is operated via the battery and the engine. 4. The method of claim 3 , wherein the estimated coolant temperature model indicates an estimated coolant temperature for the battery coolant system and/or the ISC coolant system and for the engine coolant system for each of the plurality of vehicle operation modes as a function of one or more trip parameters for a vehicle trip and the one or more dynamic conditions of the vehicle. 5. The method of claim 3 , wherein the vehicle is operated in the first, battery-operated mode and wherein, responsive to determining from the one or more dynamic conditions of the vehicle and/or information from an electronic horizon data source an indication of an upcoming activation of the engine while the engine is shut off in the first, battery-operated mode, coolant from the battery coolant system and/or the ISC coolant system is directed to the heat exchanger to heat coolant from the engine coolant system that is directed to the heat exchanger. 6. The method of claim 3 , wherein the vehicle is operated in the second, engine-operated mode and wherein, responsive to determining during the operation in the second, engine-operated mode from the one or more dynamic conditions of the vehicle and/or information from an electronic horizon data source that the vehicle is predicted to enter a geo-fenced area in which engine operation is prohibited, coolant from the engine coolant system is directed to the heat exchanger to heat coolant from the battery coolant system and/or the ISC coolant system that is directed to the heat exchanger. 7. The method of claim 3 , wherein the vehicle is operated in the third, hybrid mode and wherein during the third, hybrid mode, responsive to determining that the engine and the battery are each maintained within a threshold range of an operating temperature, the heat exchanger is deactivated and no coolant from the battery coolant system, the ISC coolant system, and the engine coolant system is directed to the heat exchanger. 8. The method of claim 3 , wherein controlling the flow of coolant through the heat exchanger comprises flowing coolant from the battery coolant system and/or the ISC coolant system to the engine coolant system to heat up a heater core for a cabin heating system of the vehicle. 9. A vehicle system comprising: a first coolant system comprising a battery coolant system including a battery of the vehicle and/or an inverter system controller (ISC) coolant system including an ISC; a second coolant system, wherein the second coolant system includes an engine coolant system including an engine of the vehicle; a heat exchanger coupled to each of the first coolant system and the second coolant system; and a controller with computer readable instructions stored on non-transitory memory that, when executed, cause the controller to: estimate coolant temperatures for an upcoming vehicle trip; schedule operation of the heat exchanger to exchange heat between coolant from the first coolant system and coolant from the second coolant system based on the estimated coolant temperatures; and during the vehicle trip, adjust operation of the heat exchanger based on dynamic vehicle data; wherein the battery coolant system further comprises a first low temperature radiator, the ISC coolant system further comprises a second low temperature radiator, and the engine coolant system further comprises a high temperature radiator, the heat exchanger being coupled to receive coolant from downstream of the ISC and upstream of the second low temperature radiator and/or to receive coolant from downstream of the engine and upstream of the high temperature radiator. 10. The vehicle system of claim 9 , wherein the controller comprises a hybrid powertrain control module that is communicatively coupled to one or more sensors of the first coolant system and the second coolant system and to an electronic horizon data source, the estimated coolant temperatures being estimated based on data received from the one or more sensors and/or the electronic horizon data source. 11. The vehicle system of claim 9 , wherein the ISC coolant system further comprises a DC/DC converter and a charger for charging the battery, and wherein the engine coolant system further comprises an exhaust gas recirculation (EGR) cooler and a heater core for a cabin heating system of the vehicle. 12. The vehicle system of claim 9 , wherein the heat exchanger is coupled to supply coolant to a first pump of the engine coolant system or to a second pump of the battery coolant system, the first pump being upstream of the engine and downstream of the high temperature radiator and the second pump being upstream of the battery and downstream of the first low temperature radiator. 13. The vehicle system of claim 12 , wherein scheduling operation of the heat exchanger includes selectively routing coolant from the ISC to the second pump via the heat exchanger, bypassing any other components of the ISC coolant system or the battery coolant system, and/or selectively routing coolant from the engine to the first pump via the heat exchanger, bypassing any other components of the engine coolant system. 14. A method for thermal management in a vehicle, the method comprising: determining a first set of vehicle parameters using measured data from one or more sensors of the vehicle, the first set of vehicle parameters indicating a vehicle status; determining a second set of vehicle parameters using information derived from one or more data sources including an electronic horizon, the second set of vehicle parameters indicating road load and drive event estimations for a vehicle trip; estimating coolant temperatures for a first coolant system and a second coolant system for the vehicle trip as a function of at least the second set of vehicle parameters; determining a heat exchanger control schedule for a heat exchanger coupled to the first coolant system and the second coolant system, the heat exchanger control schedule including instructions to operate the heat exchanger to maintain a respective coolant temperature in th