Systems and method for controlling flow of coolant to components of a vehicle

What is claimed is: 1. A system for controlling flow of coolant to one or more components of a vehicle, the system comprising: a cooling system configured to provide coolant, via a coolant loop, to the one or more components of the vehicle; and a controller communicatively coupled to the cooling system, the controller configured to receive one or more current operating conditions of the one or more components of the one or more components of the vehicle, receive respective amounts of heat expected to be rejected by the one or more components of the vehicle in a steady state of operation at the one or more current operating conditions of the one or more components of the vehicle, wherein the controller receives the amounts of heat expected to be rejected by the one or more components of the vehicle by performing a look up in a pump map and at least one of an inverter heat rejection map and a motor generator heat rejection map, the pump map, inverter heat rejection map, and motor generator heat rejection map each comprising relationships between operating conditions of the one or more components and amounts of heat expected to be rejected by the one or more components of the vehicle in the steady state of operation of the one or more components at the one or more current operating conditions; and transmit a feedforward flow control signal based at least in part on i) the received amounts of heat expected to be rejected by the one or more components of the vehicle and ii) a target temperature for the one or more components of the vehicle, transmit a controller output signal based at least in part on the feedforward flow control signal, and provide the controller output signal to the cooling system to control flow of coolant to the one or more components of the vehicle from the cooling system in accordance with the received amounts of heat expected to be rejected by the one or more components of the vehicle. 2. The system of claim 1 , wherein the controller is configured to transmit the feedforward flow control signal further based on a current temperature of the coolant at an input to a system comprising the one or more components of the vehicle. 3. The system of claim 1 , wherein the controller is further configured to receive at least one feedback signal indicative of a current temperature of the one or more components of the vehicle, transmit a feedback flow control signal based on a difference between the target temperature and the current temperature of the one or more components of the vehicle, and transmit the controller output signal based on both i) the feedforward flow control signal and ii) the feedback flow control signal. 4. The system of claim 1 , wherein the vehicle is at least partially electric vehicle that comprises an electric motor, and the one or more components of the vehicle includes at least i) the electric motor and ii) an inverter configured to convert direct current (DC) energy from a battery to alternating current (AC) power for driving the electric motor. 5. The system of claim 4 , wherein the one or more current operating conditions of the one or more components of the vehicle include one or both of i) a current speed of the electric motor of the vehicle and ii) a current torque of the electric motor of the vehicle. 6. The system of claim 1 , wherein the cooling system includes a variable flow coolant pump configured to pump coolant to the one or more components of the vehicle, and the controller is configured to provide the controller output signal to a control input of the variable flow coolant pump to actuate the variable flow coolant pump in accordance with the received amounts of heat expected to be rejected by the one or more components of the vehicle. 7. The system of claim 6 , wherein the controller is further configured to sending, based on received amounts of heat expected to be rejected by the one or more components of the vehicle, a speed of at which to the variable flow coolant pump is to be operated, and transmit the feedforward flow control signal to control the variable flow coolant pump to operate at the sent speed. 8. The system of claim 1 , wherein the vehicle is a hybrid electric vehicle that includes a combustion engine and an electric motor, the one or more components of the vehicle include one or more electrical components, including the electric motor of the vehicle, and the coolant loop of the cooling system is coupled to a radiator configured to provide coolant to both the combustion engine and the electric motor of the vehicle. 9. The system of claim 1 , wherein the vehicle is a hybrid electric vehicle that includes a combustion engine and an electric motor, the one or more components include one or more electrical components of the vehicle, including the electric motor, and the coolant loop of the cooling system is a first coolant loop coupled to a first radiator configured to provide coolant to the one or more electrical components of the vehicle and a second radiator configured to provide coolant, via a second coolant loop separate from the first coolant loop, the combustion engine of the vehicle. 10. A controller, comprising: a processor; and a memory including instructions that, when executed by the processor, cause the controller to: receive one or more current operating conditions of one or more components of a vehicle, receive respective amounts of heat expected to be rejected by the one or more components of the vehicle in a steady state of operation at the one or more current operating conditions of the one or more components of the vehicle, wherein the controller receives the amounts of heat expected to be rejected by the one or more components of the vehicle by performing a look up in a pump map and at least one of an inverter heat rejection map and a motor generator heat rejection map, the pump map, inverter heat rejection map, and motor generator heat rejection map each storing relationships between operating conditions of the one or more components and amounts of heat expected to be rejected by the one or more components of the vehicle in the steady state of operation of the one or more components at the one or more current operating conditions; and transmit a feedforward flow control signal based at least in part on i) the received amounts of heat expected to be rejected by the one or more components of the vehicle and ii) a target temperature for the one or more components of the vehicle, transmit a controller output signal based at least in part on the feedforward flow control signal, and provide the controller output signal to a cooling system to control flow of coolant to the one or more components of the vehicle from the cooling system in accordance with the received amounts of heat expected to be rejected by the one or more components of the vehicle. 11. The controller of claim 10 , wherein the instructions, when executed by the processor, cause the controller to transmit the feedforward flow control signal further based on a current temperature of the coolant at an input to a system comprising the one or more components of the vehicle. 12. The controller of claim 10 , wherein the instructions, when executed by the processor, further cause the controller to: receive at least one feedback signal indicative of a current temperature of the one or more components of the vehicle, transmit a feedback flow control signal based on a difference between the target temperature and the current temperature of the one or more components of the vehicle, and transmit the controller output signal based on both i) the feedforward flow control signal and ii) the feedback flow