Controller for a motor vehicle cooling system and method

The invention claimed is: 1. A controller in combination with a motor vehicle cooling system thermostatic valve assembly, the assembly comprising: a radiator bypass coolant flow inlet; a radiator coolant flow inlet; a coolant outlet; a heater; and a thermal actuator including a wax pellet type thermostatic pressure relief valve comprising a wax medium, the thermostatic pressure relief valve comprising a first valve provided in a flowpath of coolant from the radiator bypass coolant flow inlet to the coolant outlet and a second valve provided in a flowpath of coolant from the radiator coolant flow inlet to the coolant outlet, wherein the assembly is configured to allow flow of coolant from the radiator bypass coolant flow inlet to the coolant outlet and from the radiator coolant flow inlet to the coolant outlet, wherein the second valve is configured to control a flow rate of coolant from the radiator coolant flow inlet to the coolant outlet, wherein as pressure of coolant at the radiator bypass coolant flow inlet increases, the first valve opens to accommodate the flow rate, wherein the wax medium is provided in thermal communication with coolant flowing into the assembly from the radiator bypass coolant flow inlet and coolant flowing into the assembly from the radiator coolant flow inlet, and wherein under substantially static coolant conditions a temperature of the wax medium is determined at least in part by a temperature of coolant at the radiator bypass coolant flow inlet and a temperature of coolant at the radiator coolant flow inlet, the controller being configured to receive an ambient temperature signal indicative of an ambient air temperature, the controller being configured to control the flow rate of coolant from the radiator coolant flow inlet to the coolant outlet in dependence at least in part on the ambient temperature signal, the flow rate being controlled by causing opening of the second valve by causing the heater to heat the wax medium. 2. The controller according to claim 1 , wherein the controller is configured to provide a predetermined amount of power to the heater in dependence at least in part on the ambient temperature signal. 3. The controller according to claim 2 , wherein the controller is configured to receive at least one further signal selected from among a knock signal indicative of an amount of knock suffered by an associated engine, a transmission oil temperature signal indicative of a temperature of a transmission oil and a mass flow rate signal indicative of a mass flow rate of engine intake air, the controller being configured to cause a predetermined amount of power to be supplied to the heater in dependence at least in part on the at least one further signal. 4. The controller according to claim 3 , wherein the controller is configured to receive the mass flow rate signal and an engine coolant temperature signal indicative of a temperature of coolant at an engine coolant outlet, the controller being configured to control the flow of coolant from the radiator coolant flow inlet to the coolant outlet of the assembly in order to attempt to maintain a predetermined relationship between the mass flow rate signal and the engine coolant temperature signal. 5. The controller according to claim 1 , wherein the controller is configured to cause heating of the heater by controlling a duty cycle of an electrical signal supplied to the heater. 6. A controller according to claim 1 , wherein under substantially static coolant conditions a relative contribution of coolant at the radiator coolant flow inlet to a temperature of the wax medium compared to a relative contribution of coolant at the radiator bypass coolant flow inlet is at least 10%. 7. A motor vehicle engine cooling system comprising a controller according to claim 1 . 8. A method of controlling a motor vehicle cooling system thermostatic valve assembly having: a radiator bypass coolant flow inlet; a radiator coolant flow inlet; a coolant outlet; a heater; and a thermal actuator including a wax pellet type thermostatic pressure relief valve comprising a wax medium, the thermostatic pressure relief valve comprising a first valve provided in a flowpath of coolant from the radiator bypass coolant flow inlet to the coolant outlet and a second valve provided in a flowpath of coolant from the radiator coolant flow inlet to the coolant outlet, the method comprising: allowing flow of coolant from the radiator bypass coolant flow inlet to the coolant outlet and controlling a flow rate of coolant from the radiator coolant flow inlet to the coolant outlet, wherein as pressure of coolant at the radiator bypass coolant flow inlet increases, the first valve opens to accommodate the flow rate; providing the wax medium in thermal communication with coolant flowing into the assembly from the radiator bypass coolant flow inlet and coolant flowing into the assembly from the radiator coolant flow inlet; determining a temperature of the wax medium under substantially static coolant conditions at least in part by a temperature of coolant at the radiator bypass coolant flow inlet and a temperature of coolant at the radiator coolant flow inlet; receiving an ambient temperature signal indicative of an ambient air temperature; and, controlling the flow rate of coolant from the radiator coolant flow inlet to the coolant outlet in dependence at least in part on the ambient temperature signal, the flow rate being controlled by causing opening of the second valve by causing the heater to heat the wax medium. 9. A method according to claim 8 , comprising providing a predetermined amount of power to the heater in dependence at least in part on the ambient temperature signal. 10. A method according to claim 9 , comprising receiving at least one further signal selected from among a knock signal indicative of an amount of knock suffered by an associated engine, a transmission oil temperature signal indicative of a temperature of a transmission oil and a mass flow rate signal indicative of a mass flow rate of engine intake air; and causing a predetermined amount of power to be supplied to the heater in dependence at least in part on the at least one further signal. 11. A method according to claim 10 , comprising receiving the mass flow rate signal and an engine coolant temperature signal indicative of a temperature of coolant at an engine coolant outlet; and controlling the flow of coolant from the radiator coolant flow inlet to the coolant outlet of the assembly in order to attempt to maintain a predetermined relationship between the mass flow rate signal and the engine coolant temperature signal. 12. A method according to claim 8 , comprising causing heating of the heater by controlling a duty cycle of an electrical signal supplied to the heater. 13. A non-transitory storage medium carrying computer readable code for controlling a vehicle to carry out the method of claim 8 . 14. A processor arranged to implement the method of claim 8 .