Electrical architecture for converting DC voltage into AC voltage, and vice versa

The invention claimed is: 1. An electrical architecture comprising: a DC/AC voltage converter for converting a DC voltage into an AC voltage and for converting an AC voltage into a DC voltage, comprising a plurality of arms assembled in parallel, each arm comprising two controllable switching cells, in series and separated by a midpoint, the arms being paired according to H-bridges; for each H-bridge, a dedicated control block, such that all the switching cells of said H-bridge can be controlled by the dedicated control block, each dedicated control block being configured to communicate with a same remote control unit through a potential barrier; and a DC/DC voltage converter comprising a high-voltage interface and a low-voltage interface, one of the high-voltage interface and the low-voltage interface being connected to the DC/AC voltage converter. 2. The architecture as claimed in claim 1 , each control block comprising a first source of electrical energy and a second source of electrical energy, separate from the first source of electrical energy. 3. The architecture as claimed in claim 1 , each control block including at least one selected from the group consisting of: a digital processing unit configured to communicate with the remote control unit, a device for measuring at least one electrical quantity in the H-bridge, and a device for measuring the temperature in the H-bridge. 4. The architecture as claimed in claim 3 , each control block comprising a digital processing unit configured to communicate with a digital processing unit of the remote control unit via a link common to the control blocks and passing through said potential barrier, one of the digital processing units of a control block being master for this communication. 5. The architecture as claimed in claim 1 , each control block being configured to communicate with the other control blocks. 6. The architecture as claimed in claim 1 , the DC/DC voltage converter comprising several interleaved branches, each branch comprising: an arm extending between two terminals defining the low-voltage interface and comprising two controllable switching cells, in series and separated by a midpoint, a coil having one end connected to the midpoint of the branch and the other end connected to the positive terminal of the high-voltage interface. 7. The architecture as claimed in claim 6 , the DC/DC voltage converter comprising an even number of branches, and the branches being paired, the coil of a branch of a pair being in magnetic coupling with the coil of the other branch of said pair. 8. The architecture as claimed in claim 7 , comprising for each pair of branches a control block suitable for driving all the switching cells of said pair of branches. 9. The architecture as claimed in claim 8 , each control block of a pair of branches of the DC/DC voltage converter comprising a first source of electrical energy and a second source of electrical energy that is separate from the first source of electrical energy. 10. The architecture as claimed in claim 9 , each control block of a pair of branches of the DC/DC voltage converter comprising at least one from among: a digital processing unit configured to communicate with the remote control unit, a device for measuring at least one electrical quantity in the pair of branches, and a device for measuring the temperature in the pair of branches. 11. The architecture as claimed in claim 10 , each control block of a pair of branches comprising a digital processing unit configured to communicate with the digital processing unit of the remote control unit via a link common to the control blocks of the switching cells of the H-bridges of the DC/AC voltage converter and common to the control blocks of the switching cells of a pair of branches of the DC/DC voltage converter, said link passing through said potential barrier, one of the digital processing units of a control block being master for this communication. 12. The architecture as claimed in claim 10 , the number of branches of the DC/DC voltage converter being equal to the number of arms of the DC/AC voltage converter and the architecture comprising as many control blocks driving the switching cells of the DC/AC voltage converter as control blocks driving the switching cells of the DC/DC voltage converter. 13. The architecture as claimed in claim 12 , the DC/AC voltage converter comprising six arms and the DC/DC voltage converter comprising six branches. 14. The architecture as claimed in claim 7 , the number of branches of the DC/DC voltage converter being equal to the number of arms of the DC/AC voltage converter, and each control block dedicated to an H-bridge being also suitable for driving all the switching cells of a pair of arms of the DC/DC voltage converter. 15. The architecture as claimed in claim 1 , additionally comprising: an electrical energy storage unit having a DC voltage across its terminals, and connected directly or not to the DC/AC voltage converter; an electrical stator winding, each electrical phase of the stator of being connected between two midpoints of an H-bridge; and the remote control unit. 16. The architecture as claimed in claim 15 , comprising only a single microcontroller forming part of the remote control unit, and three or six programmable logic circuits (FPGAs) forming the digital processing units of the control blocks of the H-bridges. 17. A control method for the architecture as claimed in claim 15 , comprising: detecting that at least one fault occurs in the architecture while a first control mode is applied to the switching cells; and generating a second control mode when the at least one fault is detected, this second control mode being then applied to all or some of the switching cells. 18. The method as claimed in claim 17 , in which the first control mode allows and corresponds to the power supply from the electrical energy storage unit for the electrical stator winding, the latter being polyphase, and the second control mode applied provides for and corresponds to the placing in short circuit of all or some of the electrical phases of said winding. 19. The method as claimed in claim 17 , in which the first control mode allows and corresponds to the power supply from the electrical energy storage unit for the electrical stator winding, the latter being polyphase, in which it is detected that the fault relates only to the control of one phase of the electrical stator winding, and in which the second control mode applied provides for and corresponds to the placing in short circuit of the other electrical phases of the electrical stator winding, or provides for temporarily suppressing, corresponding to the temporary suspension of the electrical phase in the control of which the fault occurs. 20. The method as claimed in claim 17 , in which the first control mode allows and corresponds to the charging of the electrical energy storage unit from an electrical network through, among other items, the electrical stator winding, and in which the second control mode applied provides for interrupting, and corresponds to the interruption of, said charging or provides for reducing the performance level thereof, or notably corresponds to the reduction of its performance level. 21. The architecture as claimed in claim 1 , further comprising: an electrical energy storage unit configured to receive a DC voltage, wherein the DC voltage is obtained by converting an AC voltage supplied by an electrical network, to