Electric Assembly Including an Insulated Gate Bipolar Transistor Device and a Wide-Bandgap Transistor Device

What is claimed is: 1 . An electric assembly, comprising: an insulated gate bipolar transistor device; a wide-bandgap transistor device electrically connected in parallel with the bipolar transistor device; and a control circuit electrically coupled to a gate terminal of the bipolar transistor device and to a control terminal of the wide-bandgap transistor device, wherein the control circuit is configured to turn on the bipolar transistor device and to turn on the wide-bandgap transistor device at a predefined turn-on delay with respect to a turn-on of the bipolar transistor device. 2 . The electric assembly of claim 1 , wherein the control circuit is configured to turn off the bipolar transistor device and to turn off the wide-bandgap transistor device at a predefined turn-off delay with respect to a turn-off of the bipolar transistor device. 3 . The electric assembly of claim 1 , wherein the control circuit is configured to selectively turn on desaturation transistor cells of the bipolar transistor device under reverse bias of the bipolar transistor device. 4 . The electric assembly of claim 1 , wherein the control circuit is configured to turn on desaturation transistor cells of the bipolar transistor device and the wide-bandgap transistor device under reverse bias of the bipolar transistor device. 5 . The electric assembly of claim 1 , wherein a semiconductor portion of the wide-bandgap transistor device comprises a wide-bandgap semiconductor material with a bandgap of at least 2.0 eV. 6 . The electric assembly of claim 1 , wherein a semiconductor portion of the wide-bandgap transistor device comprises silicon carbide. 7 . The electric assembly of claim 1 , further comprising: an overcurrent detection circuit configured to detect an overload condition of the bipolar transistor device and to generate an overload detection signal indicating the overload condition, wherein the control circuit is configured to turn off the bipolar transistor device in response to the overload detection signal. 8 . The electric assembly of claim 1 , wherein a nominal turn-on current of the wide-bandgap transistor device is at least 10% of the nominal turn-on current of the bipolar transistor device. 9 . The electric assembly of claim 1 , wherein the control circuit is configured to generate a desaturation signal and to output the desaturation signal to the bipolar transistor device at a point in time preceding a change of a voltage bias across load terminals of the electric assembly from reverse to forward. 10 . The electric assembly of claim 1 , wherein the control circuit comprises a first output terminal electrically coupled to the gate terminal of the bipolar transistor device and a second output terminal electrically coupled to the control terminal of the wide-bandgap transistor device. 11 . The electric assembly of claim 1 , wherein the wide-bandgap transistor device comprises a plurality of field effect transistor cells electrically connected in parallel. 12 . The electric assembly of claim 11 , wherein the wide-bandgap transistor device comprises counter-doped portions forming pn junctions with a drift zone and one or more connection portions that directly adjoin the drift zone and a drain electrode. 13 . The electric assembly of claim 12 , wherein the one or more connection portions are arranged between the drift zone and the drain electrode, and wherein the counter-doped portions are configured to inject charge carriers into at least one of the drift zone and the one or more connection portions above a set-in voltage of at least 2V and at most 3.5V at 25° C. 14 . The electric assembly of claim 12 , wherein the counter-doped portions are arranged between the drift zone and a continuous connection portion and are configured to trigger impact ionization or Zener tunneling of charge carriers into the one or more connection portions. 15 . The electric assembly of claim 11 , wherein the wide-bandgap transistor device comprises a collector layer forming a backside pn junction with the drift zone. 16 . The electric assembly of claim 1 , wherein the control circuit is configured to output a second control signal for turning on the wide-bandgap transistor device and which changes from an off-level control voltage to an on-level control voltage not before 80% of an on-state period has passed, in which a first control signal output by the control circuit for turning on the bipolar transistor device has an on-level gate voltage. 17 . The electric assembly of claim 1 , wherein the control circuit is configured to output a second control signal for turning on the wide-bandgap transistor device and which rises to an on-level control voltage within less than 6 μs after a first control signal output by the control circuit for turning on the bipolar transistor device falls to an off-level gate voltage. 18 . An electric assembly, comprising: an insulated gate bipolar transistor device; a wide-bandgap transistor device electrically connected in parallel with the bipolar transistor device and comprising a plurality of field effect transistor cells electrically connected in parallel; and a backside construction directly adjoining a drain electrode and comprising one or more backside pn junctions. 19 . The electric assembly of claim 18 , wherein the wide-bandgap transistor device is configured to conduct, in an on-state, a unipolar current below a set-in voltage and a bipolar current above the set-in voltage, and wherein the set-in voltage is defined by parameters of the one or more backside pn junctions. 20 . The electric assembly of claim 18 , wherein the wide-bandgap transistor device comprises a drift zone and a plurality of counter-doped portions forming the backside pn junctions with at least one of the drift zone and with connection portions arranged between the drift zone and the drain electrode, and wherein the counter-doped portions are configured to inject charge carriers into at least one of the drift zone and the connection portions above a set-in voltage of at least 2V and at most 3.5V at 25° C. 21 . The electric assembly of claim 18 , wherein the wide-bandgap transistor device comprises a drift zone and a plurality of counter-doped portions forming the backside pn junctions with a continuous connection portion that is arranged between the counter-doped portions and the drain electrode, and wherein the counter-doped portions are configured to trigger at least one of impact ionization and Zener tunneling of charge carriers in the connection portion. 22 . The electric assembly of claim 18 , wherein the wide-bandgap transistor device comprises a collector layer directly adjoining the drain electrode and forming the backside pn junction with the drift zone. 23 . An electric assembly, comprising: a reverse conducting insulated gate bipolar transistor device comprising desaturation transistor cells; a wide-bandgap transistor device electrically connected in parallel with the bipolar transistor device; and a control circuit electrically coupled to a gate terminal of the bipolar transistor device and to a control terminal of the wide-bandgap transistor device, wherein the control circuit is configured to turn on the desaturation transistor cells under reverse bias of the bipolar transistor device and to turn on both the bipolar transistor device and the wide-bandgap transistor device under forward bias of the bipolar transistor device.