Method of controlling a hybrid powertrain of a motor vehicle

1 . A method of controlling a hybrid powertrain of a motor vehicle, said powertrain comprising a thermal drive chain and an electric drive chain, said electric drive chain comprising a traction battery, a voltage modulation device, an inverter, a first electrical machine and a second electrical machine, the voltage modulation device being adapted to modulate a supply voltage of an electric current which is output by the traction battery and which is supplied to the first electrical machine and to the second electrical machine of the motor vehicle, the method comprising: a step of analytically calculating an optimal supply voltage by means of a mathematical expression which corresponds to the resolution of an equation expressed in the form ∂ P bat ∂ U e = 0 ,  wherein U e is the supply voltage, wherein P bat is the electrical power supplied by the traction battery and wherein said electrical power supplied by the traction battery is expressed in the form of a quadratic function of said supply voltage, and a step of controlling the voltage modulation device so that the voltage modulation device supplies said optimal supply voltage. 2 . The control method according to claim 1 , wherein the mathematical expression of said optimal supply voltage is given by the formula - K 1 2 · K 2 if said optimal supply voltage is comprised between the voltage at the terminals of the traction battery and a predetermined maximum voltage threshold, wherein K 1 and K 2 are predetermined functions depending on a first speed of the first electrical machine, of a second speed of the second electrical machine, on the first electric torque developed by the first electrical machine and on the second electric torque developed by the second electrical machine. 3 . The control method according to claim 2 , wherein the mathematical expression of said optimal supply voltage is selected equal to the voltage at the terminals of the traction battery if the expression - K 1 2 · K 2 is lower than said voltage at the terminals of the traction battery. 4 . The control method according to claim 2 , wherein the mathematical expression of said optimal supply voltage is selected equal to the maximum voltage threshold if the expression - K 1 2 · K 2 is greater than said maximum voltage threshold. 5 . The control method according to claim 1 , wherein the power supplied by the traction battery is expressed according to the formula: P bat =K 2 U e 2 +K 1 U e +K 0 , where U e is the supply voltage and K 0 , K 1 and K 2 are predetermined functions depending on the first speed of the first electrical machine, on the second speed of the second electrical machine, on the first electric torque developed by the first electrical machine and on the second electric torque developed by the second electrical machine. 6 . The control method according to claim 1 , also comprising, before the step of analytically calculating the optimal supply voltage, a step of determining a first optimal electric torque that the first electrical machine must develop and a second optimal electric torque that the second electrical machine must develop, the first optimal electric torque and the second optimal electric torque being a function of a value of energy required to propel the motor vehicle and of an equivalence factor associated with the traction battery. 7 . The control method according to claim 6 , wherein said first optimal electric torque, said second optimal electric torque and said optimal electrical voltage minimize the electrical losses in an assembly comprising at least the voltage modulation device if a Hamiltonian, which is a function of a fuel consumption of an internal combustion engine of the motor vehicle and of an electric current consumption of said assembly, is minimized. 8 . A control method according to claim 1 , also comprising, before the step of analytically calculating the optimal supply voltage, a step of determining the electrical power supplied by the traction battery. 9 . The control method according to claim 1 , wherein the electrical losses in the voltage modulation device are expressed in the form of a linear function of said supply voltage. 10 . The control method according to claim 3 , wherein the mathematical expression of said optimal supply voltage is selected equal to the maximum voltage threshold if the expression - K 1 2 · K 2 is greater than said maximum voltage threshold. 11 . The control method according to claim 2 , wherein the power supplied by the traction battery is expressed according to the formula: P bat =K 2 U e +K 1 U e +K 0 , where U e is the supply voltage and K 0 , K 1 and K 2 are predetermined functions depending on the first speed of the first electrical machine, on the second speed of the second electrical machine, on the first electric torque developed by the first electrical machine and on the second electric torque developed by the second electrical machine. 12 . The control method according to claim 3 , wherein the power supplied by the traction battery is expressed according to the formula: P bat =K 2 U e +K 1 U e +K 0 , where U e is the supply voltage and K 0 , K 1 and K 2 are predetermined functions depending on the first speed of the first electrical machine, on the second speed of the second electrical machine, on the first electric torque developed by the first electrical machine and on the second electric torque developed by the second electrical machine. 13 . The control method according to claim 4 , wherein the power supplied by the traction battery is expressed according to the formula: P bat =K 2 U e +K 1 U e +K 0 , where U e is the supply voltage and K 0 , K 1 and K 2 are predetermined functions depe