Method and device for detecting a short circuit in an H-bridge electronic circuit

The invention claimed is: 1. A method for detecting a short-circuit in an H-bridge electronic circuit that comprises: a high potential power supply terminal; a low potential power supply terminal; a first output terminal and a second output terminal intended to be connected to a load to be controlled; two high side branches, which each comprise a switch connected both to the high potential power supply terminal and also to one of the output terminals; two low side branches, which each comprise a switch connected both to the low potential power supply terminal and also to one of the output terminals; said method comprising: selecting one of said branches as a first test branch; activating a current source parallel to the switch of the first test branch, between the power supply terminal and the output terminal to which the first test branch is connected; taking a first potential measurement involving measuring the potential of one of the output terminals; selecting, if the potential resulting from this first potential measurement is substantially different from the potential of the power supply terminal to which the first test branch is connected, a second test branch that is diametrically opposite to the first test branch; activating a current source parallel to the switch of the second test branch, between the power supply terminal and the output terminal to which the second test branch is connected, and keeping the current source of the first test branch active; taking a second potential measurement involving measuring the potential of each output terminal; signalling the detection of a localized short-circuit in the output terminal having the potential resulting from the second potential measurement that is closest to the potential resulting from the first potential measurement. 2. The method as claimed in claim 1 , further comprising a step of indicating the resulting value of the detected short-circuit, with this resulting value of the detected short-circuit being equal to the potential measured during the first potential measurement. 3. The method as claimed in claim 2 , further comprising a step of determining the physical position of the detected short-circuit, on the basis of the identification of the output terminal in which the short-circuit is located and of said resulting value of the short-circuit. 4. The method as claimed in claim 1 , wherein the first potential measurement involves measuring the potential of the output terminal to which the switch of the first test branch is connected. 5. The method as claimed in claim 1 , wherein, after the step of taking the first potential measurement, if the potential resulting from this first potential measurement is substantially equal to the potential of the power supply terminal to which the first test branch is connected, the method comprises the following steps: selecting a third test branch that is adjacent to the first test branch and that is located on the side of the power supply terminal that is opposite to the power supply terminal of the first test branch; activating a current source parallel to the switch of the third test branch, between the power supply terminal and the output terminal to which the third test branch is connected; taking a third potential measurement involving measuring the potential of one of the output terminals; selecting, if the potential resulting from this third potential measurement is substantially equal to the potential of the power supply terminal to which the first test branch is connected, a fourth test branch that is diametrically opposite to the third test branch; activating a current source parallel to the switch of the fourth test branch, between the power supply the terminal and output terminal to which the fourth test branch is connected, and keeping the current source of the third test branch active; taking a fourth potential measurement involving measuring the potential of each output terminal; signalling the detection of a localized short-circuit in the output terminal having the potential resulting from the fourth potential measurement that is furthest from the potential resulting from the third potential measurement. 6. The method as claimed in claim 5 , wherein, after the step of taking the third potential measurement, if the potential resulting from this third potential measurement is substantially different from the potential of the power supply terminal to which the first test branch is connected, the method comprises a step of signalling the absence of a short-circuit. 7. The method as claimed in claim 5 , further comprising a step of indicating the resulting value of the detected short-circuit, with this resulting value of the detected short-circuit being equal to the potential measured during the third potential measurement. 8. The method as claimed in claim 7 , further comprising a step of determining the physical position of the detected short-circuit, on the basis of the identification of the output terminal in which the short-circuit is located and of said resulting value of the short-circuit. 9. The method as claimed in claim 5 , wherein the third potential measurement involves measuring the potential of the output terminal to which the switch of the third test branch is connected. 10. The method as claimed in claim 1 , wherein the current sources have identical bias voltages. 11. The method as claimed in claim 1 , wherein the current sources have different bias voltages. 12. An integrated circuit comprising an electronic H-bridge circuit and a module adapted for implementing the method according to claim 1 . 13. The method as claimed in claim 2 , wherein the first potential measurement involves measuring the potential of the output terminal to which the switch of the first test branch is connected. 14. The method as claimed in claim 3 , wherein the first potential measurement involves measuring the potential of the output terminal to which the switch of the first test branch is connected. 15. The method as claimed in claim 2 , wherein, after the step of taking the first potential measurement, if the potential resulting from this first potential measurement is substantially equal to the potential of the power supply terminal to which the first test branch is connected, the method comprises the following steps: selecting a third test branch that is adjacent to the first test branch and that is located on the side of the power supply terminal that is opposite to the power supply terminal of the first test branch; activating a current source parallel to the switch of the third test branch, between the power supply terminal and the output terminal to which the third test branch is connected; taking a third potential measurement involving measuring the potential of one of the output terminals; selecting, if the potential resulting from this third potential measurement is substantially equal to the potential of the power supply terminal to which the first test branch is connected, a fourth test branch that is diametrically opposite to the third test branch; activating a current source parallel to the switch of the fourth test branch, between the power supply terminal and the output terminal to which the fourth test branch is connected, and keeping the current source of the third test branch active; taking a fourth potential measurement involving measuring the potential of each output terminal; signalling the detection of a localized short-circuit in the output terminal having the potential resulting from the fourth potential measurement that is furthest from the potential