Electric circuit for cutting off an electric power supply having transistors and fuses

The invention claimed is: 1. An electric circuit adapted to cut-off a power supply of an electrical equipment ( 2 ), said electric circuit receiving as input at least two discrete electrical signals (x 1 , x 2 ) which values determine the power supply of the electrical equipment ( 2 ), the discrete electrical signals having a high state (‘ 1 ’) if the electrical equipment is to be power supplied, the electric circuit comprising a voltage source (+Vpp); a first cut-off unit (Uc 1 ) connected between the electrical equipment ( 2 ) and the voltage source (+Vpp), the first cut-off unit (Uc 1 ) having an open or closed state based on discrete electrical signals (x 1 , x 2 ), a second cut-off unit (Uc 2 ) connected to the intersection of the electrical equipment and the first cut-off unit (Uc 1 ), and a ground line, the second cut-off unit (Uc 2 ) having a state complementary to the state of the first cut-off unit if the discrete electrical signals (x 1 , x 2 ) are in a same state, the second cut-off unit (Uc 2 ) comprising a parallel circuit of at least two switches (Q 2 L, Q 2 R), said parallel circuit being connected to the power source, wherein the state of each of the two switches is a function of athe discrete electrical signals (x 1 , x 2 ), the two switches are in the same state when the discrete electrical signals (x 1 , x 2 ) are in the same state, and in case of a discrepancy between the state of the discrete electrical signals, the first and second cut-off units generate a short-circuit by the at least two switches of the second cut-off unit having divergent states one from another. 2. The electric circuit according to claim 1 , wherein the second cut-off unit (Uc 2 ) comprises as many switches as discrete electrical signals. 3. The electric circuit according to claim 2 , wherein the switches of the parallel arrangement have an open or closed state depending on an electric control signal, the switches being in the open state if the electric control signal has a “high” state and in the closed state if the electric control signal has a “low” state. 4. The electric circuit according to claim 1 , wherein the first cut-off unit comprises a first switch (Q 1 ) having an open or closed state depending on an electric control signal based on discrete electrical signals, the first switch being in the open state if the electric control signal has a “low” state and is in the closed state if the electric control signal has a “high” state. 5. The electric circuit according to claim 4 , wherein the first switch is controlled by a logical function of the discrete electric signals of logic type ‘OR’. 6. The electric circuit according to claim 4 or claim 5 , wherein the first cut-off unit (Uc 1 ) comprises a second switch (Q 4 ), the second switch having an open or closed state depending on the electric control signal based on discrete electrical signals, the second switch being in the open state if the electric control signal has a “down” state and is in the closed state if the electric control signal has a “high” state, the said second switch (Q 4 ) being adapted to isolate the voltage source from the power supply if the discrete electrical signals are in the low state. 7. The electric circuit according to claim 6 , wherein the second switch (Q 4 ) is controlled by a logical function of discrete electrical signals of the type logic ‘AND’. 8. The electric circuit according to claim 1 , comprising at least one fuse (FUSE) for isolating, in case of short-circuit, the voltage source (+Vpp) of the elements of said electric circuit. 9. The electric circuit according to claim 1 , comprising a test unit (TEST) for detecting a failure of at least one component of the circuit and selectively controlling the first and second cut-off units to generate a short-circuit. 10. The electric circuit according to claim 9 , wherein the test unit is adapted to implement the steps of: isolating the electrical equipment of the electric circuit; controlling the second cut-off unit (Uc 2 ) so that the second cut-off unit is in the closed state; measuring a voltage between the first cut-off unit and the second cut-off unit to verify that the second cut-off unit is adapted to generate a short-circuit. 11. The electric circuit according to claim 9 or claim 10 , wherein the test unit (TEST) is adapted to implement the steps of: controlling the first cut-off unit (Uc 1 ) to be in the closed state; measuring a voltage at the terminals of the second cut-off unit (Uc 2 ), a voltage equal to the voltage supplied by the voltage source (+Vpp) indicating that the first cut-off unit is operating; controlling the first cut-off unit (Uc 1 ) to be in the open state; measuring a voltage at the terminals of the second cut-off unit (Uc 1 ), a zero voltage indicating that the first cut-off unit is operating. 12. The electric circuit according to claim 9 or claim 10 , wherein the test unit (TEST) is implemented using programmable logic components or using microcontrollers which can incorporate means of analog voltage measurements for enriching the circuit supervision level. 13. An avionic data acquisition, processing and communication system comprising a radio module ( 2 ) connected to an electric circuit according to claim 1 .