Battery cell state-of-health estimation method

What is claimed is: 1. A method of determining the state of health of a first elementary cell of a battery, comprising the steps of: measuring, with a sensor of a management device of the battery, the voltage across the cell at a plurality of times in a phase of cell charge between first and second state-of-charge levels or a plurality of times in a phase of cell discharge between first and second state-of-charge levels; measuring, with a coulometer or a current integrator of the management device of the battery, variations of cell charge of the cell between said voltage measurements; detecting, with the management device of the battery, a crossing by said voltage of a predetermined specific value, corresponding to a predetermined specific physical charge value of the cell, said specific physical charge value and said specific voltage values corresponding to the coordinates of a crossing point of at least two curves representative of the variation of said voltage according to the charge contained in the cell, said at least two curves corresponding respectively to different states of health of the cell; calculating, with the management device, a variable representing: a slope of a curve representing the variation of said voltage according to the charge variation of the cell, at the crossing of said specific voltage value; or an average value of said voltage between first and second cell charge levels, said first and second cell charge levels both being higher than said specific charge value or lower than said specific charge value; and converting, with the management device, said variable into a state of health value. 2. The method of claim 1 , wherein said voltage is the voltage across the cell under a reference current. 3. The method of claim 2 , wherein said reference current is zero and wherein said steps of measuring the voltage across the first cell are implemented during periods of disconnection of the first cell by the management device for the generation of an AC voltage across the battery. 4. The method of claim 1 , further comprising storing the variations of the cell charge between said voltage measurements. 5. The method of claim 1 , wherein said specific charge value is in the range from 20% to 60% of the nominal full charge capacity of the cell. 6. The method of claim 1 , wherein said cell is a cell of lithium-ion type and wherein said specific charge value is in the range from 38% to 42% of the nominal full charge capacity of the cell. 7. The method of claim 6 , wherein said cell has a 2.2-Ah nominal capacity and a 4.2-V nominal full charge voltage, and wherein said specific voltage value is in the range from 3.5 V to 3.6 V. 8. The method of claim 1 , further comprising a previous characterization phase comprising acquiring, for a second elementary cell of the same type as the first cell, at least two characteristic curves representative of the variation of the voltage across the second cell according to the charge contained in the second cell, for at least two different states of health of the second cell. 9. The method of claim 8 , wherein the previous characterization phase further comprises a step of determining a crossing point of said at least two characteristic curves in the charge range from 20% to 60% of the nominal capacity of the cell. 10. A system comprising: a battery comprising a plurality of elementary cells; and a battery management device comprising a sensor and one of a coulometer and a current integrator; wherein the management device determines the state of health of an elementary cell by: measuring, with the sensor, the voltage across the cell at a plurality of times in a phase of cell charge between first and second state-of-charge levels or a plurality of times in a phase of cell discharge between first and second state-of-charge levels; measuring, with the coulometer or the current integrator, variations of cell charge of the cell between said voltage measurements; detecting a crossing by said voltage of a predetermined specific value, corresponding to a predetermined specific physical charge value of the cell, said specific physical charge value and said specific voltage value corresponding to the coordinates of a crossing point of at least two curves representative of the variation of said voltage according to the charge contained in the cell, said at least two curves corresponding respectively to different states of health of the cell; calculating a variable representing: a slope of a curve representing the variation of said voltage according to the charge variation of the cell, at the crossing of said specific voltage value; or an average value of said voltage between first and second cell charge levels, said first and second cell charge levels both being higher than said specific charge value or lower than said specific charge value; and converting said variable into a state of health value. 11. The system of claim 10 , wherein the battery is a battery with a dynamically reconfigurable architecture, and wherein the management device is capable of dynamically disconnecting and connecting back cells of the battery so that an AC voltage is provided across the battery. 12. The system of claim 11 , wherein said reference current is zero and wherein said steps of measuring the voltage across the first cell are implemented during periods of disconnection of the first cell by the management device for the generation of an AC voltage across the battery.