Methods and systems for coolant system

The invention claimed is: 1. A method for operating a vehicle air conditioning system, comprising: with a controller, executing instructions stored on non-transitory memory to: adjust, via a pump and a proportioning valve coupled to each of a charge air cooler and an air conditioner condenser, a flow of coolant through the condenser in which refrigerant different from the coolant flows, the adjusting in response to a charge air cooler coolant temperature and an actual head pressure of an air conditioner compressor. 2. The method of claim 1 , wherein adjusting, in response to a reference head pressure, includes adjusting in response to a difference between the actual head pressure and the reference head pressure, the flow of coolant through the condenser increased as the actual head pressure exceeds the reference head pressure. 3. The method of claim 2 , wherein the reference head pressure is modeled by the controller via a two-dimensional map, the map stored on the non-transitory memory as a function of the charge air cooler coolant temperature and a coolant flow rate. 4. The method of claim 1 , wherein the actual head pressure includes a pressure at a location downstream of the air conditioner compressor and upstream of each of an expansion valve and the air conditioner condenser in a refrigerant circuit coupled to the air conditioning system. 5. The method of claim 4 , wherein the pump and the proportioning valve are selectively coupled to a coolant circuit of the air conditioning system, each of the coolant circuit and the refrigerant circuit coupled to the air conditioner condenser. 6. The method of claim 5 , wherein the adjusting is further in response to a temperature of oil in a transmission cooler circuit, the transmission cooler circuit coupled to the coolant circuit at a transmission cooler, the transmission cooler located upstream of the proportioning valve and downstream of the pump, the transmission cooler further coupled to an engine coolant circuit distinct from the coolant circuit of the air conditioning system. 7. The method of claim 6 , wherein the adjusting includes, as the temperature of oil in the transmission cooler circuit increases, increasing an output of the pump to increase coolant flow to the air conditioner condenser through the transmission cooler, wherein the increase in oil temperature is responsive to increased torque converter slip. 8. The method of claim 1 , wherein the adjusting includes, for a given cabin cooling demand, maintaining or decreasing flow through the air conditioner condenser while increasing flow through the charge air cooler as the charge air cooler coolant temperature increases, and increasing flow through the air conditioner condenser while maintaining or decreasing flow through the charge air cooler as the actual head pressure exceeds a reference head pressure. 9. The method of claim 1 , wherein the adjusting includes, responsive to each of the actual head pressure and the charge cooler coolant air temperature exceeding respective thresholds, increasing an output of the pump to an upper limit while setting the proportioning valve to a position that provides a calibrated fixed ratio of coolant flow through the air conditioner condenser relative to the charge air cooler. 10. The method of claim 1 , wherein the adjusting includes feed-forward selecting a pump and proportioning valve setting that provides a coolant flow rate determined as a function of the charge air cooler coolant temperature, and feedback adjusting the pump and proportioning valve setting based on an error between the actual head pressure and a reference head pressure, the reference head pressure determined as another function of the charge air cooler coolant temperature. 11. A method for a vehicle, comprising: with a controller, executing instructions stored on non-transitory memory to: flow refrigerant through a refrigerant circuit including an air-conditioning condenser; flow coolant through a first branch of a coolant circuit including the air-conditioning condenser, and through a second branch of the coolant circuit including a charge air cooler, wherein coolant flow through the first branch relative to the second branch is adjusted based on an air-conditioning head pressure in the refrigerant circuit, a coolant temperature in the coolant circuit, and a charge air cooler cooling demand. 12. The method of claim 11 , wherein the first and second branches are located downstream of each of a coolant pump and a proportioning valve, and wherein the first and second branches are parallel to a transmission oil cooler. 13. The method of claim 12 , wherein coolant flow through the first branch relative to the second branch is adjusted via adjustments to a pump output and a position of the proportioning valve. 14. The method of claim 11 , wherein the refrigerant circuit includes an air-conditioning compressor, a thermal expansion valve, an air-conditioning clutch, the condenser, and an air-conditioning evaporator, and wherein the air-conditioning head pressure in the refrigerant circuit is based on a position of the air-conditioning clutch, a temperature of the air-conditioning condenser, a position of the thermal expansion valve, and a vehicle cabin cooling demand. 15. The method of claim 13 , wherein the coolant flow through the first branch relative to the second branch is further adjusted based on a transmission oil temperature of oil circulating through the transmission oil cooler. 16. The method of claim 13 , wherein the adjusting includes operating with an initial setting of the pump output and the proportional valve position based on the coolant temperature, and then transitioning from the initial setting to a final setting of the pump output and the proportional valve position based on the air-conditioning head pressure relative to a reference air-conditioning head pressure, the reference air-conditioning head pressure modeled as a two-dimensional function of coolant temperature, coolant flow rate, and change in charge air cooler cooling demand. 17. A vehicle system, comprising: a vehicle cabin; an air conditioning system including an evaporator and a condenser for cooling cabin air; a boosted engine system including an engine, and a turbocharger compressor coupled upstream of a charge air cooler; a refrigerant circuit circulating refrigerant through the condenser, the refrigerant circuit including a pressure sensor; a first coolant circuit circulating coolant through each of the condenser, the charge air cooler, and a transmission oil cooler, the first coolant circuit including an electric pump, a proportioning valve, and a temperature sensor; and a second coolant circuit circulating coolant through each of the engine, an exhaust manifold cooler, and the transmission oil cooler, the second coolant circuit including a mechanical pump. 18. The system of claim 17 , wherein the refrigerant circuit is coupled to the first coolant circuit at the condenser, wherein the first coolant circuit is coupled to the second coolant circuit at the transmission oil cooler, the transmission oil cooler receiving oil from a torque converter outlet, and wherein the condenser is coupled to a first branch of the first coolant circuit downstream of the proportioning valve, and the charge air cooler is coupled to a second branch of the first coolant circuit downstream of the proportioning valve, the first branch distinct from and parallel to the second branch. 19. The system of claim 18 , further comprising a controller with computer readable