Abstract: A device comprising at least one power semiconductor die coated with a metallization and at least one light guide having two opposite ends. The first end is able to be connected at least to a light source and to a light receiver. The second end is permanently fixed facing to a surface of the metallization such that to form a light path towards said surface and a light path from said surface.

Abstract: The invention relates to an electrical power assembly (1), comprising: a power die (10), having at least two electrical contacts (11), an electrically insulating core (20), wherein the power die is embedded in the electrically insulating core, and two layers (30) of electrically conductive material on opposite main surfaces of the electrically insulating core, characterized in that the electrical power assembly comprises at least one open cavity (40) extending from an electrical contact (11) of the power die, through the electrically insulating core and the layer (30) of electrically conductive material located on the same side of the power die than the electrical contact, such that the open cavity has a bottom (41) formed by an area of the electrical contact of the power die.

Abstract: The present invention concerns a system comprising at least one power module comprising at least one power die that is cooled by a liquid cooled system, the liquid cooled system is arranged to provide at least one electric potential to each power dies of the power module, characterized in that the liquid cooled system is composed of a first and a second current-carrying bars connected together by an electrically non-conductive pipe, the first bar is placed on the top of the power module and provides a first electric potential to the power die and the second bar is placed on the bottom of the power module and provides a second electric potential to the power dies and the liquid coolant is electrically conductive and the channels surfaces are covered by an electrical insulation layer.

Abstract: A power module (1) is disclosed, comprising: first and second substrates (10), each substrate patterned layer of electrically conductive material (12), a plurality of pre-packed power cells (20), positioned between the substrates, each cell comprising: an electrically insulating core (21) embedding at least one power die (22), and two external layers (23) of electrically conductive material on opposite sides of the electrically insulating core (21), said external layers being respectively connected to each patterned layers of the substrates, wherein each external layer of a pre-packed power cell comprises a contact pad (230) connected to a respective contact (220) of the power die through connections arranged in the electrically insulating core (21), said contact pad having a surface area greater than the surface area of the power die electrical contact to which it is connected.

Abstract: The present invention concerns a method and a device (10) for monitoring a multi-die power module (15) comprising dies that are in a half-bridge switch configuration. The invention: •—sets the dies in a non conductive state, •—selects one die which is blocking a voltage, •—injects a current in a gate of the selected die in order to charge an input parasitic capacitance of the selected die, •—monitors a voltage that is representative of a voltage on the gate of the selected die, •—memorizes the value of the monitored voltage when the value of the monitored voltage is stabilized.

Abstract: A multi-die health monitoring device: sets, at a given current provided to the load by the group of dies, one of the dies in a non-conducting state (NCS), obtains, when the die is in the NCS, a signal that is representative of the temperature of the die and determines the temperature of the die, obtains, when the die is in the NCS, a signal that is representative of an on-state voltage (OSV) of the die and determines the OSV of the die, retrieves in a table stored in a memory of the multi-die health monitoring device, an OSV that corresponds to the given current and the determined temperature of the die, notifies that the multi-die power module has to be replaced, if the difference between the determined OSV of the die and the retrieved OSV is equal or upper than a predetermined value.

Abstract: The present invention concerns a method for controlling the temperature of a multi-die power module, comprising: determining and memorizing a first weighted arithmetic mean of junction temperatures of the dies of the multi-die power module, determining successively another weighted arithmetic mean of junction temperatures of the dies, checking if the difference between the other weighted arithmetic mean and the memorized weighted arithmetic mean is lower than a first predetermined value, enabling a modification of the duty cycle of an input signal to apply to at least one selected die of the multi-die power module if the difference is lower than a first predetermined value, disabling a modification of the duty cycle of the input signal to apply to the at least one die of the multi-die power module if the difference is not lower than the first predetermined value.

Abstract: The present invention concerns a system for allowing the restoration of an interconnection of a die of a power module, a first terminal of the interconnection being fixed on the die and a second terminal of the interconnection being connected to an electric circuit. The system comprises:—at least one material located in the vicinity of the first terminal of the interconnection, the material having a predetermined melting temperature,—means for controlling the temperature of the die at the predetermined melting temperature during a predetermined period of time. The present invention concerns also the method.

Abstract: The present invention concerns a system for allowing the restoration of a first interconnection of a die of a power module connecting the die to an electric circuit. The system comprises: at least one other interconnection of the power module, a periodic current source that is connected to the at least one other interconnection for generating a periodic current flow through the at least one other interconnection in order to reach, in at least a part of the first interconnection, a predetermined temperature during a predetermined time duration. The present invention concerns also the associated method.

Abstract: The present invention concerns a method for estimating a level of damage of an electric device. The method comprises the steps of: forming a histogram of operating cycles related to the electric device for which the level of damage estimation is performed, comparing the formed histogram to histograms of a collection of histograms or to combinations of histograms of the collection of histograms, each histogram of the collection of histogram being associated to a level of damage, in order to determine the histogram of the collection of histograms or the combination of histograms which is the closest from the formed histogram, determining an estimate of the level of damage of the electric device from the level of damage of the closest histogram or from the levels of damages of the histograms of the closest combination of histograms.

Abstract: The present invention concerns a method for controlling the temperature of a multi-die power module, a multi-die temperature control device. The multi-die temperature control: obtains a signal that is representative of the temperature of one die among the dies of the multi-die power module when the die is not conducting, obtains signals that are representative of a reference temperature that is dependent of the temperature of all the dies of the multi-die power module when the dies are not conducting, compares the signal that is representative of the temperature of one die to the signal that is representative of the reference temperature, reduces the duration of the conducting time of the die or reducing the duration of the conducting time of the other dies of the multi-die power module according to the comparison result.

Abstract: The present invention concerns a device for controlling the operation of a power module composed of switches, each switch being composed of a plurality of power dies connected in parallel, characterized in that the device comprises, for each power die of the power module: —a temperature sensor to sense the temperature of the power die, —a current sensor to sense the current going through the power die, —a gate interrupt circuit to interrupt the signal provided to the power die if the sensed current is higher than a predetermined current threshold, —a controller to reduce the conducting time of the die if the sensed temperature of the power die is higher than the average die temperature across the power dies of at least one switch.

Abstract: The present invention concerns a system comprising at least one power module comprising at least one power die that is cooled by a liquid cooled system, the liquid cooled system is arranged to provide at least one electric potential to each power dies of the power module, characterized in that the liquid cooled system is composed of a first and a second current-carrying bars connected together by an electrically non-conductive pipe, the first bar is placed on the top of the power module and provides a first electric potential to the power die and the second bar is placed on the bottom of the power module and provides a second electric potential to the power dies and the liquid coolant is electrically conductive and the channels surfaces are covered by an electrical insulation layer.

Abstract: A multi-die health monitoring device: sets, at a given current provided to the load by the group of dies, one of the dies in a non-conducting state (NCS), obtains, when the die is in the NCS, a signal that is representative of the temperature of the die and determines the temperature of the die, obtains, when the die is in the NCS, a signal that is representative of an on-state voltage (OSV) of the die and determines the OSV of the die, retrieves in a table stored in a memory of the multi-die health monitoring device, an OSV that corresponds to the given current and the determined temperature of the die, notifies that the multi-die power module has to be replaced, if the difference between the determined OSV of the die and the retrieved OSV is equal or upper than a predetermined value.

Abstract: The present invention concerns a method for controlling the temperature of a multi-die power module, comprising: determining and memorizing a first weighted arithmetic mean of junction temperatures of the dies of the multi-die power module, determining successively another weighted arithmetic mean of junction temperatures of the dies, checking if the difference between the other weighted arithmetic mean and the memorized weighted arithmetic mean is lower than a first predetermined value, enabling a modification of the duty cycle of an input signal to apply to at least one selected die of the multi-die power module if the difference is lower than a first predetermined value, disabling a modification of the duty cycle of the input signal to apply to the at least one die of the multi-die power module if the difference is not lower than the first predetermined value.

Abstract: The present invention concerns a system comprising a multi-die power module composed of dies and a controller receiving plural consecutive input patterns for activating the dies of the multi-die power module, wherein the dies are grouped into plural groups of at least one die and in that the controller comprises: —means for outputting one gate to source signal for each group of at least one die, the rising edges and/or falling edges of at least one gate to source signal being iteratively time shifted from the rising edge and/or a falling edge of the other gate to source signals for other groups of dies.

Abstract: The present invention concerns a method for controlling the operation of a multi-die power module composed of at least two dies connected in parallel. The method comprises the steps of: —obtaining the current flowing in the multi-die power module, —obtaining a loss profile that is related to the dies of the multi-die power module, —estimating from the measured current flowing in the multi-die power module, the losses of one die when no die is passivated, when the die is passivated, and when at least one other die is passivated, —determining if and which die has to be passivated from the estimated losses and from the loss profile—passivating the die which has to be passivated if a die has to be passivated.

Abstract: The present invention concerns a system comprising a multi-die power module composed of dies and a controller receiving plural consecutive input patterns for activating the dies of the multi-die power module. The dies are grouped into plural clusters of dies and the controller comprises means for outputting one gate to source signals for each cluster of dies, each outputted gate to source signal being different from the other gate to source signals and at least one first outputted gate to source signal reducing the activation of dies during at least one input pattern among the plural input patterns.

Abstract: The present invention concerns a power module comprising at least one power die, the at least one power die is embedded in a multilayer structure, the multilayer structure is an assembly of at least two sub-modules, each sub-module being formed of isolation and conductor layers and the power module further comprises at least one capacitor embedded in the multilayer structure for decoupling an electric power supply to the at least one power die embedded in the multilayer structure and at least one driving circuit of the at least one power die that is disposed on a surface of the multilayer structure or embedded completely or partially in the multilayer structure.

Abstract: The present invention concerns a method for controlling the operation of a multi-die power module composed of at least two dies connected in parallel. The method comprises the steps of: —obtaining the current flowing in the multi-die power module, —obtaining a loss profile that is related to the dies of the multi-die power module, —estimating from the measured current flowing in the multi-die power module, the losses of one die when no die is passivated, when the die is passivated, and when at least one other die is passivated, —determining if and which die has to be passivated from the estimated losses and from the loss profile—passivating the die which has to be passivated if a die has to be passivated.