Abstract:
A method and a circuit for protecting a transistor that controls the supply of an at least partially inductive load, including lowering the demagnetization voltage of the inductive load with respect to a demagnetization voltage set by a break-over component connected between a conduction terminal and the control terminal of the transistor.

Description:
BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to the protection against overcurrents in transistors carrying a load supply current and, for example, to the protection of transistors connected in parallel to control an at least partially inductive load, and more specifically the forming of individual circuits for protecting these transistors on demagnetization of the inductive load. 
   2. Description of the Related Art 
     FIG. 1  shows a conventional example of an assembly of several MOS power transistors M (M 1 , . . . Mn) connected in parallel between a terminal  1  of application of a supply voltage Vbat (for example, the voltage of a battery) and a terminal  2  of connection to a load Q to be powered, the other end of the load being for example connected to ground  3 . In the example of  FIG. 1 , only two transistors M 1  and Mn have been shown. In practice, the number n of parallel-connected transistors M depends on the power required by the load and on the current that each transistor can individually conduct. 
   All transistors M 1  to Mn are controlled from a same signal CTRL that they respectively receive via logic and level-adapting blocks B 1  to Bn (LOG) (for example, charge pump, set-up circuits, etc.) on their respective control terminals (gate) G (G 1  to Gn). The respective conduction terminals (drain and source) of transistors M are directly connected to terminals  1  and  2 . 
   Each transistor M is associated with a protection circuit formed of a zener diode DZ (DZ 1 , . . . DZn) in anti-series with a respective diode D (D 1 , . . . Dn) between terminal  1  and gate G of the concerned transistor. 
   When transistors M 1  to Mn are controlled to be turned on by signal CTRL, load Q is supplied with voltage Vbat. Diodes DZ 1  to DZn are reverse-biased. Diodes DZ have no function in the conduction phase since their threshold voltages are greater than the supply voltage, so that the voltage difference between control signal CTRL and voltage Vbat does not place them in avalanche when signal CTRL is active to turn on transistors M. 
   When transistors M 1  to Mn are controlled to be turned on by a state switching of signal CTRL, a problem of current distribution is traditionally posed in power transistors. This problem is particularly present in the case of an at least partially inductive load due to the demagnetization phenomenon. This demagnetization results in the voltage at terminal  2  becoming lower than the voltage at terminal  3  (the ground), which considerably increases the voltage difference between terminals  1  and  2 . To carry off the demagnetization current, transistors M 1  and Mn must be turned on until this current disappears. This is the function of diodes DZ 1  to DZn which set the demagnetization voltage, that is, the voltage across inductive load Q in the carrying off in the power supply of the demagnetization current. In fact, when the voltage of terminal  2  is lowered by the demagnetization to a value such that the voltage difference between terminals  1  and  2  exceeds the threshold voltage of diodes DZ, (neglecting gate-source voltage Vgs of transistors M and voltage drop VD in each forward-biased diode D), these diodes start an avalanche and impose a positive voltage between the gate and source of the corresponding transistors M to turn them on. 
   When control signal CTRL is inactive, demagnetization voltage Vdemag (the voltage across load Q) can be written, for each transistor M, as:
 
 V demag= V bat−( VDZ+VD+Vgs ),
 
where VDZ represents the threshold voltage of zener diode DZ.
 
   Forward voltage drops VD of diodes D are all fixed (on the order of 0.6 V), just as voltages Vgs of the different MOS transistors are approximately fixed, as well as battery voltage Vbat. Accordingly, in the above relation, it can be seen that the single parameter which conditions demagnetization voltage Vdemag of the load is the threshold voltage of zener diodes DZ. 
   Zener diodes DZ 1  to DZn are thus all selected to have the same nominal values, to set the same demagnetization voltage, for the entire assembly, and distribute the current in all branches. 
   A disadvantage of the circuit of  FIG. 1  is that manufacturing tolerances and technological dispersions make the respective threshold voltages of the different zener diodes DZ 1  to DZn of the protection circuits of transistors M 1  to Mn vary from one branch to another. This problem is particularly present in the case where each power transistor M is integrated with its protection circuit and its logic block in a circuit separate from the other transistors which are then associated in parallel in an assembly such as shown in  FIG. 1 . The presence of blocks B prevents a direct interconnection of all the gates of transistors M, which imposes providing one protection circuit (diodes DZ and D) per branch. 
   In fact, the zener diode DZ which has the smallest threshold voltage conducts first and thus imposes on its transistor a positive voltage Vgs to turn it on to carry off the demagnetization current. Since the other transistors M are not on yet because the protection zener diodes DZ associated therewith have greater thresholds, all the current flows through a single transistor M and said transistor is thus damaged since it is not designed to stand all of the current. 
   BRIEF SUMMARY OF THE INVENTION 
   The disclosed embodiments of the present invention maintain the balance between currents in the difference branches of a parallel association of several transistors in a demagnetization of an inductive load despite possible technological challenges and manufacturing tolerances of zener protection diodes. 
   In one embodiment of the present invention a circuit for protecting a transistor is provided. The circuit includes at least one break-over component in anti-series with a one-way conduction element coupled between a first conduction terminal and a control terminal. 
   These include a resistive element in series with the break-over component; and 
   a controllable current source between a terminal of the one-way conduction element opposite to said transistor and a second conduction terminal of the transistor. 
   According to an embodiment of the present invention, the current source is controlled according to the current in the transistor. 
   According to an embodiment of the present invention, the second conduction terminal of the transistor is intended to be connected to an at least partially inductive load, the current source belonging to a circuit for decreasing a demagnetization voltage set by the break-over component. 
   According to an embodiment of the present invention, the demagnetization voltage is lowered if the current in the transistor becomes greater than a threshold. 
   According to an embodiment of the present invention, the break-over component is a zener diode. 
   According to an embodiment of the present invention, the transistor is a MOS transistor. 
   The disclosed embodiments of the present invention also provide a circuit for supplying a load with several transistors coupled in parallel and connected between a first terminal of application of a supply voltage and a first terminal of the load, each transistor associated with a protection circuit. 
   According to an embodiment of the present invention, the load is at least partially inductive. 
   The present invention also provides a method for protecting a control transistor to supply an at least partially inductive load, the method including the step of lowering the demagnetization voltage of the load with respect to a demagnetization voltage set by a break-over component connected between a conduction terminal and the control terminal of the transistor. 
   In accordance with another embodiment of the invention, a circuit is provided that includes first and second parallel-coupled transistors, each transistor having a first terminal coupled to a supply terminal, a second terminal coupled to a load terminal, and a control terminal to receive a control signal; and a protection circuit, the protection circuit including a first diode coupled in series to a second diode between the first terminal of each transistor and the control terminal of each transistor, a first resistive element coupled in series with the first and second diodes, and a current source coupled between a first terminal of the resistive element and the load terminal. 
   In accordance with another aspect of the foregoing embodiment, the first diode comprises a zener diode with a cathode coupled to the supply terminal and the second diode has a cathode coupled to the control terminal of the respective transistor. Ideally, the first resistive element is coupled between the first and second diodes with the first terminal of the resistive element also coupled to an anode of the second diode. 
   In accordance with another aspect of the foregoing embodiment, a control circuit is coupled to the second terminal of each transistor and to a control terminal of the current source. 
   In accordance with another embodiment of the invention, a circuit is provided that includes a power transistor having a first terminal coupled to a supply terminal and a second terminal coupled to a load terminal, and a control terminal configured to receive a control signal; and a protection circuit that includes an auxiliary transistor having a first terminal coupled to the supply terminal and a second terminal coupled to the control terminal of the power transistor; a first diode having a cathode coupled to the supply terminal and an anode coupled to the first terminal of the auxiliary transistor; a second diode having an anode coupled to a control terminal of the auxiliary transistor and a cathode coupled to the anode of the first diode; a first resistor coupled to the anode of the first diode and to the control terminal of the auxiliary transistor; and a current source coupled between the control terminal of the auxiliary transistor and the load terminal, the current source including a line coupling a second terminal of the current source to an auxiliary terminal of the power transistor. 
   In accordance with another aspect of the foregoing embodiment, the current source includes a first transistor having a first terminal coupled to a control terminal of the auxiliary transistor, a second terminal coupled to the load terminal, and a control terminal, and further including a second transistor having a first terminal coupled to a current supply, a second terminal coupled to the load terminal, and a control terminal coupled to the control terminal of the first transistor in the current source, the second terminal of the second transistor including the third terminal of the current source that is coupled to the auxiliary terminal of the power transistor. 
   In accordance with yet a further aspect of the foregoing embodiment, the circuit includes a resistive element coupled between the second terminal of the second transistor and the load terminal. 
   In accordance with a further aspect of the foregoing embodiment, a threshold voltage of the second diode is smaller than a threshold voltage of the first diode. 
   In accordance with yet another embodiment of the invention, a protection circuit is provided for a power transistor having a first conduction terminal, a second conduction terminal, and a control terminal configured to receive a control signal and at least one other transistor coupled in parallel to the power transistor, the at least one other transistor having a first terminal coupled to the first conduction terminal and a second terminal coupled to the second conduction terminal and a control terminal. The protection circuit includes means for sensing current in each of the power transistor and the at least one other transistor; and means for diverting current from one of the power transistor and the at least one other transistor that is conducting a maximum current, the diverting means responsive to the sensing means, and the diverting means further configured to cause the other of the power transistor and the at least one other transistor to conduct current in response to the sensing means. 
   In accordance with another aspect of the foregoing embodiment, the sensing means includes a breakover component coupled between the first conduction terminal and the control terminal of the respective power transistor and the at least one other transistor, a one-way conduction element coupled between the breakover element and a control terminal of the power transistor and the respective at least one other transistor, and at least one resistive element coupled between the breakover component and the one-way conduction element. 
   In accordance with yet another aspect of the foregoing embodiment, the diverting means includes a current source having a first terminal coupled to a node formed by the coupling of the first resistive element and the one-way conduction element and a second terminal coupled to the second conduction terminal of the respective power transistor and the at least one other transistor, and a control circuit coupled to a control terminal of the current source and to the second conduction terminal of the respective power transistor and the at least one other transistor. 

   
     BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS 
     The foregoing and other features and advantages of the present invention will be discussed in detail in the following non-limiting description of specific embodiments in connection with the accompanying drawings, wherein: 
       FIG. 1 , previously described, is intended to show the state of the art; 
       FIG. 2  schematically shows in the form of blocks an embodiment of circuits for protecting power transistors according to the present invention; and 
       FIG. 3  shows a detailed embodiment of a power transistor and of its protection circuit according to the present invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   In the figures, the same elements have been designated with same reference numerals in the different drawings. For clarity, only those elements that are necessary to the understanding of the present invention have been shown and will be described hereafter. In particular, the structure of the load supplied by several parallel power transistors has not been shown, the present invention being compatible with the load conventionally controlled by transistors in parallel. Further, the generation of the control signals of these power transistors has not been shown and is compatible with conventional systems. 
   The disclosed features of the present invention will be described hereafter in relation with an example applied to MOS power transistors. It should however be noted that the implementation more generally applies whatever the nature of the transistor, for example, a bipolar transistor. 
     FIG. 2  schematically (and partially in the form of blocks) shows an embodiment of MOS power transistor protection circuits according to one embodiment of the present invention. 
   As previously described, several (n) MOS power transistors M 1  to Mn are connected in parallel between a terminal  1  of application of a supply voltage Vbat (for example, the D.C. voltage of a battery) and a terminal  2  intended to be connected to a first conduction terminal of a load Q having its other terminal connected, for example, to ground  3 . 
   According to the shown embodiment, the control electrode (gate) of each transistor M is connected to terminal  1  by a series association of a zener diode DZ (DZ 1  to DZn), of a resistor R (R 1  to Rn), and of a diode D (D 1  to Dn). The cathode of each diode DZ is directly connected to terminal  1  while the cathode of each diode D is directly connected to gate G (G 1  to Gn) of the transistor M with which it is associated. Each gate G receives a control signal CTRL via a conventional block B (B 1  to Bn). As an alternative, resistor R is interposed between the cathode of diode DZ and terminal  1 . 
   The resistor R is interposed between the respective anodes of diode DZ and of diode D. The function of resistor R is to effectively increase the threshold voltage of zener diode DZ to lower the source voltage of transistor M and thus the demagnetization voltage of the load. 
   The anode of diode D is further connected to terminal  2  by a controllable current source  10 . The source  10  of each stage is individually controlled by a circuit  11  associated with the concerned stage which, in the shown example, measures the current in the main branch (in the involved transistor M) by means of a resistor RS (RS 1  to RSn) connecting source S (S 1  to Sn) of each transistor to terminal  2 . 
   As in conventional embodiments, the different zener diodes used are provided to have a same nominal threshold voltage but may have different real threshold voltages from one diode to the other due to technological dispersions and/or manufacturing tolerances. 
   Here, however, when the first zener diode (that having the smallest real threshold voltage) starts an avalanche, and turns on the transistor M which is associated therewith, the current flow through this transistor starts the corresponding current source  10  via circuit  11 . In practice, circuit  11  triggers current source  10  with respect to a threshold for example selected according to the maximum current that transistor M withstand. The higher the current in transistor M (measured by resistor RS), the higher the current in source  10 . 
   The current diversion from the supply voltage to node  2  due to source  10  functionally decreases the level of the demagnetization voltage, that is, of the voltage of terminal  2 . Now, by decreasing the voltage of terminal  2 , the starting of the other branches having higher threshold voltages of their corresponding zener diodes is accelerated. Thus a single branch does not have to withstand the entire demagnetization current. 
   It can be seen that, in a first phase, the current in the transistor M that conducts first is maximum, that is, it absorbs the entire demagnetization current. During this phase, the current in zener diode DZ corresponds to the nominal current for which this diode is provided based on its threshold voltage. However, this first phase does not last. Due to the decrease in the voltage at node  2  by the action of the current diversion by source  10 , the other branches turn on, which places all branches in a second phase where the current in the zener diode corresponds to the nominal value and where the current is distributed in transistors M in balanced fashion. 
   As an alternative, the temperature of transistors M may be measured, rather than the currents that they conduct. 
     FIG. 3  shows a detailed example of an integrated circuit  20  containing a power transistor (here, a MOS transistor SM) and a protection circuit according to an embodiment of the present invention. For example, integrated circuit  20  is a tripole having a control terminal  23  connected to the input of block B intended to receive control signal CTRL and having two conduction terminals  21  and  22  intended to be respectively connected to terminals  1  and  2  of an assembly in parallel associating several circuits  20 . 
   In the example of  FIG. 3 , the function of diode D ( FIG. 2 ) is ensured by an auxiliary transistor M′ (for example, MOS) having a conduction terminal connected to the anode of diode DZ and having its other conduction terminal connected to gate G of transistor SM. Resistor R is in this example replaced with a resistor R′ between the anode of diode DZ and the gate of transistor M′ (and thus still in series with diode DZ) and is in parallel with an auxiliary zener diode ADZ which has the function of protecting transistor M′. The threshold voltage of diode ADZ is smaller than that of diode DZ. For example, for a diode DZ on the order of 30 volts, a diode ADZ on the order of a few volts will be sufficient. 
   In the embodiment of  FIG. 3 , to avoid the presence of the detection resistor in series with transistor M ( FIG. 2 ), a current measurement transistor SM (“sense FET”) having an auxiliary terminal  25  providing an image of the current flowing through said transistor SM will be used. Functionally, such a transistor amounts to connecting, between terminal  21  and the measurement input (terminal S) of a block  11  ( FIG. 2 ), an additional transistor (symbolized by auxiliary terminal  25 ) having its gate connected to that of the main transistor. 
   Terminal  25  is connected to a first terminal of a measurement resistor RS having its other terminal connected to main terminal  22 . The first terminal of resistor RS is further connected to a first transistor  26  (for example, MOS) of a current mirror having its other conduction terminal receiving a constant current  10 . This current originates from a conventional external current source which needs not be detailed. Transistor  26  has its control terminal (its gate) connected to that of another transistor  27  (for example, MOS) and to its conduction terminal receiving current  10 . The two conduction terminals of transistor  27  are respectively connected to the gate of transistor M′ and to terminal  22 . The function of the current mirror formed of transistor  26 ,  27  is to form a controllable current source adapting the current diverted by resistor R′ from the current measured by resistor RS. 
   In the case where the assembly has more than two branches in parallel, once the first branch is conductive, it is not compulsory for the other branches to simultaneously start conducting. Their respective conduction times will depend on the thresholds of their respective zener diodes. However, as long as a detection circuit of one of the branches detects in the main transistor of this branch a current greater than its allowed threshold (set by its circuit  11 ,  FIG. 2 , or by the structure of its current mirror  26 ,  27 ,  FIG. 3 ), it will attempt to lower the voltage of terminal  2  to start another branch. 
   An advantage of the present invention is that it compensates for the possible differences between the threshold voltages of the zener diodes of the protection circuits of the parallel-connected transistors. 
   Another advantage of the present invention is that the different circuits in parallel automatically adapt to the structures of the others. On this regard, it should be noted that each protection circuit associated with a power transistor is formed independently from the other branches. For example, the sizes of the transistors of the different branches may be different from one other, the respective starting thresholds of their protection circuits being then also different. However, the nominal threshold voltages of the zener diodes of the protection circuits are, preferably, selected to all have the same values. 
   Of course, the present invention is likely to have various alterations, modifications, and improvements which will readily occur to those skilled in the art. In particular, the dimensions to be given to the different components depend on the application and are within the abilities of those skilled in the art based on the functional indications given hereabove. Further, current sources other than those illustrated in  FIG. 3  are possible, since other circuits may perform the function of lowering the level of the demagnetization voltage down to the point where the zener diodes of the other branches are triggered. Further, it should be reminded that although the present invention has been described in relation with an application to MOS transistors, it more generally applies whatever the type of transistors (especially bipolar), the adaptations of the voltage controls to turn them into a current control (bipolar case) being with the abilities of those skilled in the art. 
   Such alterations, modifications, and improvements are intended to be part of this disclosure, and are intended to be within the spirit and the scope of the present invention. Accordingly, the foregoing description is by way of example only and is not intended to be limiting. The present invention is limited only as defined in the following claims and the equivalents thereto. 
   All of the above U.S. patents, U.S. patent application publications, U.S. patent applications, foreign patents, foreign patent applications and non-patent publications referred to in this specification and/or listed in the Application Data Sheet, are incorporated herein by reference, in their entirety.