Patent Document

TECHNICAL FIELD 
     The present invention relates to an insulated gate bipolar transistor (IGBT) device. In particular, the present invention relates to a hybrid form of semiconductor devices combining a field effect transistor with a bipolar transistor. 
     BACKGROUND OF THE INVENTION 
     Over the recent years a growing interest has been seen in the area of highly integrated semiconductor device that can be used for power management and signal amplification. 
     U.S. Pat. No. 5,126,806 describes a lateral insulated gate bipolar transistor (IGBT), Ref. 1, which is particularly well suited for high power switching applications. Disclosed is an enhancement-IGFET device having its source and drain electrodes connected to the base and emitter, respectively, of a lateral bipolar transistor. When an appropriate gate input voltage, here in the form of a positive charge, is applied to the IGFET, the channel conducts, thus biasing the bipolar transistor into conduction. The applied charge on the gate electrode can be used to control a large current through the bipolar device, which is of particular interest in power applications. Safe switching operation at high voltages however requires a very wide base and a low gain in the bipolar transistor. Various forms of said devices have been integrated in modern CMOS processes as described by Bakeroot et. al. in IEEE EDL-28, pp. 416-418, 2007, Ref. 2. Relevant in this context is also a report by E. Kho Ching Tee entitled “A review of techniques used in Lateral Insulated Gate Bipolar Transistor (LIGBT)” in Journal of Electrical and Electronics Engineering, vol. 3, pp. 35-52, 2012, Ref. 3. While this type of device is potentially quite useful for various forms of power switching, with its requirements of high voltage capability and low internal gain, it is disadvantageous for a device incorporated in a low voltage highly integrated circuit intended for power management and signal amplification. 
       FIG. 1A  shows one example of prior art in the form of a lateral insulated gate bipolar transistor device (LIGBT) such as described in U.S. Pat. No. 5,126,806 by Sakurai et. al. mentioned above. The integrated device  30  is constructed in a low-doped n-type layer  35  containing a p-type doped layer  50  with a higher impurity concentration than that of the n-type layer and a p+ layer  70  with an impurity concentration exceeding that of the p-type doped layer  50 . In the p-doped layer  50  is provided an n+-layer  60  with an impurity concentration that is higher than that of the p-type layer  50 . The p-doped layer  50  and the n+-layer  60  are electrically short-circuited by an emitter electrode  55 . A collector electrode  65  forms an ohmic contact to the p+-layer  70 . An insulating film serves as gate dielectric  40  and separates the gate electrode  45  from the substrate. 
     When a positive potential is applied to the gate electrode  45 , the conductivity of a surface portion of the p-layer  50  under the gate dielectric  40  is inverted to form an n-type channel. Electrons from the n+-layer  60  can then pass through the channel from the n-layer  35  to the p+-layer  70  from which positive holes are injected. Thereby the n-layer  35 , having a high resistivity, is conductivity-modulated to provide a low resistance path between the anode (C) and cathode (E) in  FIG. 1A . A low on-resistance and excellent forward blocking characteristic can thus be realized, which is quite useful for various forms of power switching. 
     Numerous modifications of the above described embodiment, with emphasis on improved switching performance, exist, some of which are covered in a report entitled “A review of techniques used in Lateral Insulated Gate Bipolar Transistor (LIGBT)” by E. Kho Ching Tee published in Journal of Electrical and Electronics Engineering, vol. 3, pp. 35-52, 2012. 
       FIG. 1B , is an equivalent electrical circuit diagram for the device in  FIG. 1A . Shown are the three terminals, C, E and G. The device also utilizes an external back-side substrate electrode. The n-type IGFET has its source and body terminals strapped together at (E) and these are, in turn, connected to the collector layer (C) of the lateral bipolar pnp-transistor over the body resistance, R 1 . Shown is also how the base terminal of the lateral pnp-transistor is connected to the drain of the IGFET over a variable resistance, R 2 , the latter mirroring the conductivity modulation. 
     A vertical parasitic npn-transistor that has its base connected to the collector of the lateral pnp-transistor is included in  FIG. 1B  to illustrate that the LIGBT contains a thyristor-like structure. Once this thyristor causes latch-up, the LIGBT device can no longer be controlled by the gate potential. The condition for latch-up is: α npn +α pnp ≧1, where α npn  and α pnp  are the common-base current gains of the parasitic npn transistor and pnp transistor, respectively. To reduce the risk for latch-up it is essential to lower the current gain α in both transistors. Since the pnp transistor carries the on-state voltage drop, the gain of the npn-transistor has to be suppressed by, e.g., increasing the base doping below the emitter layer (lowering the base resistance). 
     SUMMARY OF THE INVENTION 
     Obviously prior art hybrid semiconductor devices need to be improved, particularly with regards to the latch-up, in order to be commercially attractive as amplifying circuits. 
     The object of the present invention is to provide an IGBT device that overcomes the drawback of the prior art devices. This is achieved by the device as defined in claim  1 . 
     A lateral IGBT transistor is provided comprising a bipolar transistor and an IGFET having a low resistive connection between the drain of the IGFET and the base of the bipolar transistor and an isolating layer arranged between the IGFET and the bipolar transistor, thereby providing latch immunity. 
     According to one embodiment of the invention the lateral IGBT transistor is a lateral n-channel IGBT transistor comprising a bipolar pnp transistor and a n-channel IGFET. The lateral n-channel IGBT transistor comprises a semiconductor substrate, and an insulating layer buried in the semiconductor substrate and at least covering the bipolar pnp transistor. The bipolar pnp transistor comprises:
         a p-type collector layer arranged on top of a portion of insulating layer and extending to the upper surface of the semiconductor substrate, forming the collector of the bipolar pnp transistor;   an n-type base layer arranged within the p-type collector layer and extending to the upper surface of the semiconductor substrate, forming the base of the bipolar pnp transistor; and,   a p-type emitter layer arranged within n-type base layer and extending to the upper surface of the semiconductor substrate, forming the emitter of the bipolar pnp transistor.       

     The n-channel IGFET comprises:
         a p-well extending from the upper surface of the semiconductor substrate into the semiconductor substrate;   a channel layer in vicinity of the upper surface of the semiconductor substrate and arranged under a gate structure;   an n-type source layer forming the source of the n-channel IGFET; and   an n-type drain layer forming the drain of the n-channel IGFET.       

     According to the embodiment the lateral n-channel IGBT transistor is provided with:
         an n-well layer adjacent to the p-well of the n-channel IGFET and to the collector layer of the bipolar pnp transistor. The n-type base layer is enclosed by the collector layer. The n-well layer surrounds the collector layer and is in contact with insulating layer, providing device isolation of the bipolar pnp transistor,   a low resistive interconnect layer extending from the drain layer to the base layer forming low resistive interconnect and simultaneously providing an ohmic contact to the base layer. The low resistive interconnect layer is arranged at least partly over the p-well and at least partly over the collector layer and at least partly over the n-well layer.       

     According to another embodiment of the invention the lateral IGBT transistor is a lateral p-channel IGBT transistor comprising a bipolar npn transistor and a p-channel IGFET. 
     The lateral p-channel IGBT transistor comprises a semiconductor substrate and a buried n-layer arranged in the semiconductor substrate at least covering the bipolar npn transistor and at least portion of a drain layer of the IGFET. 
     The bipolar npn transistor comprises:
         an n-type collector layer arranged on top of a portion of the buried n-layer and a portion extending to the upper surface of the semiconductor substrate, forming the collector of the bipolar npn transistor;   a p-type base layer arranged within the n-type collector layer and extending to the upper surface of the semiconductor substrate, forming the base of the bipolar npn transistor; and   an n-type emitter layer arranged within base layer and extending to the upper semiconductor substrate, forming the emitter of the bipolar npn transistor.       

     The p-channel IGFET comprises:
         an n-well extending from the upper surface of the semiconductor substrate into the semiconductor substrate;   a channel layer in vicinity of the upper surface of the semiconductor substrate and arranged under a gate structure;   a p-type source layer is forming the source of the p-channel IGFET; and   a p-type drain layer forming the drain of the p-channel IGFET.       

     According to the embodiment the lateral p-channel IGBT transistor is provided with:
         a p-well layer adjacent to the p-well of the p-channel IGFET and to the collector layer of the bipolar npn transistor. The p-type base layer is enclosed by the collector layer and the p-well layer surrounds the collector layer and is in contact with the buried n-layer providing device isolation between the IGFET and the npn bipolar transistor;   a low resistive interconnect layer extending from the drain layer to the base layer forming low resistive interconnect and simultaneously providing an ohmic contact to the base layer.       

     The low resistive interconnect layer is arranged at least partly over the n-well, at least partly over the collector layer and at least partly over the p-well layer. 
     According to a further embodiment the semiconductor substrate of the lateral IGBT transistor comprises a buried oxide layer and the insulating layer is formed by the oxide layer that extends over the complete substrate. 
     According to a further embodiment the interconnect layer of the lateral IGBT transistor is provided with openings to allow contact to the collector layer. 
     According to yet a further embodiment the interconnect layer  136   c  is shunted by a silicide layer of low resistivity. 
     According to yet a possible further embodiment the interconnect layer is replaced by a metal bridge spanning from drain layer of the IGFET to base layer of the bipolar transistor. 
     If the interconnect layer is replaced by a metal bridge layer  130  in  FIG. 2  it may be connected to the highest potential which is the potential at the emitter layer  145  instead of following the varying base potential with a lot of capacitance variations. Further layer  125   a  can be withdrawn from layer  120 . 
     For the p-channel device in  FIG. 3  layer  220  can be withdrawn from layer  230   a  so that layer  225  will be in contact with the substrate  115  and normally be at ground potential. 
     According to yet a further embodiment the lateral IGBT transistor is provided with oxide isolation layers surrounding the emitter and the collector contact layers. 
     Latch-up immunity is a key performance advantage and is related to the killed gain of the lateral pnp-transistor in e.g.  FIG. 2  where layer  145  is the emitter layer,  136   c  is the base layer and  125  is the collector layer. The low resistance of the base layer will effectively kill the gain of the transistor and related collector current will be zero. 
     This will also prevent layer  135  from being forward biased against layer  125   a  which is the first step to latch-up. This will also drastically reduce substrate current which is another key performance advantage. 
     The latch-up immunity will allow the gain of the bipolar transistor  102  to be optimized for very high gain typically 100-500. 
     The bipolar transistor  102  can further optionally drive the base of an npn-transistor like  202  in a Darlington connection where the gains are multiplied to be well over 10000. 
     With this internal amplification the device can be used for power management and signal amplification and many other types of electronic circuits as near field communication, opto electronics and charge detection in sensor applications. 
     Further the n-channel device in  FIG. 2  can easily be combined on the same chip with the p-channel device in  FIG. 3 . 
     To further improve voltage capability for e.g. power management the IGFET could be of the extended drain type. 
     In the preferred embodiment the device can be realised in a standard low-voltage CMOS process as provided by foundries. 
     And can therefore easily be combined with standard CMOS logic and analogue functions. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       While the novel features of the invention are set forth with particularity in the appended claims, the invention, both as to organization and content, will be better understood and appreciated from the following detailed description and drawings, in which: 
         FIG. 1A  is a sectional side view depicting a representative prior art lateral insulated gate bipolar transistor (LIGBT), and 
         FIG. 1B  is the equivalent circuit of the prior-art device in  FIG. 1A . 
         FIG. 2  illustrates schematically the structure of a first embodiment of the IGBT according to the present invention. 
         FIG. 3  illustrates schematically the structure of a second embodiment of the IGBT according to the present invention. 
         FIG. 4  illustrates schematically the structure of a third embodiment of the IGBT according to the present invention. 
         FIG. 5  illustrates schematically the structure of a fourth embodiment of the IGBT according to the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     The present invention will now be explained with the help of the accompanying drawings which show embodiments thereof. 
     In  FIG. 2  is shown a preferred embodiment of a lateral N-channel IGBT transistor  100  which easily can be combined with state of the art CMOS technology. Said IGBT consists of an IGFET transistor  101  that is electrically connected to the base of a bipolar pnp transistor  102  as described below. 
     The substrate  115  consists of a silicon wafer with or without an epi layer on top. Said substrate  115  is preferably of ( 100 )-orientation. Substrate  115  can also, in an embodiment of the invention, be a Silicon-On-Insulator (SOI) substrate. In case an SOI substrate is used layer  120  is omitted. 
     Within a part of the substrate a buried n-type layer  120  with a typical thickness in the order of 1 μm and a typical doping concentration in the range of 1.10 17  to 1.10 19  cm −3  is formed. On top of a part of layer  120 , a p-type layer  125   b  is formed that reach the surface. Said layer  125   b  has a thickness around 0.6 μm and a doping concentration around 1.10 18  cm −3 . The layer  125   b  will form the collector of the bipolar pnp transistor. 
     Within layer  125   b  an n-type layer  127   b  is formed that reach the surface and forms the base of the bipolar pnp transistor. The n-type base layer  127   b  has a doping concentration in the range of 5.10 17  to 5.10 18  cm −3  and the base-collector junction is approximately 0.3 μm below surface. Said n-type base layer  127   b  is enclosed by the collector layer  125   b . Within layer  127   b  a p+-layer  145  which reach the surface is formed. The junction depth of said p+ layer is approximately 0.2 μm and the layer has a typical surface doping concentration of 5.10 19  cm −3 . Said layer, which is enclosed by the base layer  127   b , forms the emitter of the bipolar pnp transistor. 
     The n-type IGFET transistor is located in the p-well  125   a  with its channel layer  126  in vicinity of the semiconductor surface, right under the gate structure  156 . The n+-layer  135  is forming the source of the IGFET and the n+-layer  136   a  the drain of the IGFET. The junction depths of said n+-layers are approximately 0.2 μm and the layers have typical surface concentrations in the range of 5.10 19  to 1.10 2C  cm −3 . A p+-layer  140  with a typical junction depth of 0.2 μm and a typical surface doping concentration of 5.10 19  cm −3  will serve as substrate contact. 
     The n-type IGFET is separated from the Bipolar transistor by an n-type layer  130  that is placed on top of, and makes contact to, layer  120 . Said layer reaches the surface and vertically surrounds the p-type layer  125   b  that forms the collector of the pnp transistor. The thickness of said layer is approximately 0.4 μm and the doping concentration is around 1.10 18  cm −3 . On top of layer  130  is a low resistive interconnect layer  136   c  arranged that extends into layers  125   a  and  125   b  to interconnect layers  136   a  and  136   b , forming respective drain and base contact layers of the devices. 
     The layer  130  will isolate the bipolar pnp transistor from the substrate together with layer  120 . The highly doped drain layer  136   a  forms an ohmic contact to the IGFET and the highly doped layer  136   b  forms an ohmic contact to the base layer  127   b  of the pnp-transistor, where layer  145  is the emitter and layer  125   b  is the collector. The n+-layer  136   c  contain openings before reaching layer  125   b  leaving space for contacting the collector layer with a p+-layer,  142 . The surface of said interconnect layer is preferably shunted by a silicide layer (e.g. TiSi 2 , CoSi 2 , NiSi) of low resistivity. As indicated in  FIG. 2 , the p-layer  125   a , the contact p+-layer  140 , the n+-source  135 , the gate electrode  156  and drain layer  136   a  can be mirrored in the vertical plane  122  through the emitter. For about the preferred embodiment of the device in  FIG. 2  a gain more than 100 has been verified with a base-width of around 0.4 μm which means there is a lot of room for improvements. In  FIG. 3  is shown a preferred embodiment of a lateral P-channel IGBT transistor  200  which easily can be combined with state of the art CMOS technology. Said IGBT consists of a p-type IGFET transistor  201  that is electrically connected to the base of a bipolar npn transistor  202  as described below. 
     The device comprises a p-type silicon substrate  115  as described above. Within a part of the substrate a buried n-type layer  220  with a typical thickness in the order of 1 μm and a typical doping concentration in the range of 1·10 17  to 1·10 19  cm −3  is formed. On top of a part of layer  220 , an n-type layer  230   b  is formed that reaches the surface. Said layer  230   b  has a thickness around 0.4 μm and a doping concentration around 1.10 18  cm −3 . The layer  230   b  will form the collector of the bipolar npn transistor. 
     Within layer  230   b  a p-type layer  227   b  is formed that reaches the surface and forms the base of the bipolar npn transistor. The p-type base layer  227   b  has a doping concentration in the range of 5.10 17  to 5.10 18  cm −3  and the base-collector junction is approximately 0.4 μm below surface. Said p-type base layer  227   b  is enclosed by the collector layer  230   b.    
     Within layer  227   b  an n+-layer  245  which reaches the surface is formed. The junction depth of said n+ layer is approximately 0.2 μm and the layer has a typical surface doping concentration of 1.10 20  cm −3 . Said layer, which is enclosed by the base layer  227   b , forms the emitter of the bipolar npn transistor. 
     The p-type IGFET transistor is located in the n-well  230   a  with its channel layer  226  in vicinity of the semiconductor surface, right under the gate structure  256 . The p+-layer  240  is forming the source of the IGFET and the p+-layer  241   a  the drain of the IGFET. The junction depths of said p+-layers are approximately 0.2 μm and the layers have typical surface concentrations in the range of 1.10 19  to 5.10 19  cm −3 . An n+-layer  235  with a typical junction depth of 0.2 μm and a typical surface doping concentration of 1.10 2C  cm −3  will serve as body contact to the p-type IGFET transistor and as contact to the n-layer  230   a . Said n-layer  230   a , which reaches the surface, has an approximate depth of 0.4 μm and an approximate doping concentration of 1.10 18  cm −3 . Said layer makes contact to layer  220  and leaves space for a p-well  225 , on top of layer  220 , between layers  230   a  and  230   b.    
     On top of layer  225  is a highly conductive layer  241   c  arranged that interconnect layers  241   a  and  241   b  that forms respective drain and base contacts of the devices. The highly conductive layer  241   c  arranged on top of layer  225  extends into layers  230   a  and  230   b  to interconnect layers  241   a  and  241   b , forming respective drain and base contact layers of the devices. 
     The highly doped drain layer  241   a  forms an ohmic contact to the IGFET and the highly doped layer  241   b  forms an ohmic contact to the base layer  227   b  of the npn-transistor, where layer  245  is the emitter and layer  230   b  is the collector. The p+-layer  241   c  contain openings before reaching layer  230   b  leaving space for contacting the collector layer with an n+-layer,  242 . The surface of said interconnect layer is preferably shunted by a silicide layer (e.g. TiSi 2 , CoSi 2 , NiSi) of low resistivity. As indicated in  FIG. 3 , the n-layer  230   a , the contact n+-layer  235 , the p+-source  240 , the gate electrode  256  and drain layer  241   a  can be mirrored in the vertical plane  222  through the emitter. 
     In  FIG. 4  is shown an alternative preferred embodiment of a lateral N-channel IGBT transistor which use STI (Shallow Trench Isolation) layers  310 , for oxide isolation. These layers are about 0.3 μm deep and improve isolation between n+- and p+-layers this step can easily be combined with state of the art CMOS technology. Just the bipolar side of the device is shown. In  FIG. 4  the reference numerals designate same parts as those already shown in  FIG. 2 . 
     The substrate  115  consists of a silicon wafer with or without an epi layer on top. Said substrate  115  is preferably of ( 100 )-orientation. Substrate  115  can also, in an embodiment of the invention, be a Silicon-On-Insulator (SOI) substrate. 
     Within a part of the substrate a buried n-type layer  120  with a typical thickness in the order of 1 μm and a typical doping concentration in the range of 1.10 17  to 1.10 19  cm −3  is formed. On top of a part of layer  120 , a p-type layer  125   b  is formed that reaches the surface. Said layer  125   b  has a thickness around 0.4 μm and a doping concentration around 1.10 18  cm −3 . The layer  125   b  will form the collector of the bipolar pnp transistor. 
     Partly within layer  125   b  an n-type layer  127   b  is formed that reach the surface and forms the base of the bipolar pnp transistor. The n-type base layer  127   b  has a doping concentration in the range of 5.10 17  to 5.10 18  cm −3  and the base-collector junction is approximately 0.4 μm below surface. Said n-type base layer  127   b  is not fully enclosed by the collector layer  125   b . Within layer  127   b  a p+-layer  145  which reaches the surface is formed. The junction depth of said p+ layer is approximately 0.2 μm and the layer has a typical surface doping concentration of 5.10 19  cm −3 . Said layer, which is enclosed by the base layer  127   b , forms the emitter of the bipolar pnp transistor. 
     The n-type IGFET, not shown, is separated from the Bipolar transistor by an n-type layer  130  that is placed on top of, and makes contact to, layer  120 . Said layer reaches the surface and vertically surrounds the p-type layer  125   b  that forms the collector of the pnp transistor. The thickness of said layer is approximately 0.4 μm and the doping concentration is around 1.10 18  cm −3 . This layer will isolate the bipolar pnp transistor from the substrate together with layer  120 . The somewhat longer highly doped drain layer  136   a  will form an ohmic contact to the n-layer  130  and thus to the base layer  127   b  of the pnp-transistor, where layer  145  is the emitter and layer  125   b  is the collector. The surface of said interconnect layer  136   a  is preferably shunted by a silicide layer (e.g. TiSi 2 , CoSi 2 , NiSi) of low resistivity. 
     In  FIG. 5  is shown an alternative preferred embodiment of a lateral P-channel IGBT transistor which use STI (shallow Trench Isolation) layers  310 , for oxide isolation. These layers are about 0.3 μm deep and improve isolation between n+- and p+-layers, see  FIG. 5  layers  310 . This step can easily be combined with state of the art CMOS technology. In  FIG. 5  the reference numerals designate same parts as those already shown in  FIG. 2 . 
     The device comprises a p-type silicon substrate  115  as described above. Within a part of the substrate a buried n-type layer  220  with a typical thickness in the order of 1 μm and a typical doping concentration in the range of 1·10 17  to 1·10 19  cm −3  is formed. On top of a part of layer  220 , an n-type layer  230   b  is formed that reach the surface. Said layer  230   b  has a thickness around 0.4 μm and a doping concentration around 1.10 18  cm −3 . The layer  230   b  will form the collector of the bipolar npn transistor. 
     Within layer  230   b  a p-type layer  227   b  is formed that reaches the surface and forms the base of the bipolar npn transistor. The p-type base layer  227   b  has a doping concentration in the range of 5.10 17  to 5.10 18  cm −3  and the base-collector junction is approximately 0.4 μm below the surface. Said p-type base layer  227   b  is not fully enclosed by the collector layer  230   b.    
     Within layer  227   b  an n+-layer  245  which reaches the surface is formed. The junction depth of said n+-layer is approximately 0.2 μm and the layer has a typical surface doping concentration of 1.10 2C  cm −3 . Said layer, which is enclosed by the base layer  227   b , forms the emitter of the bipolar npn transistor. 
     The p-type IGFET transistor is located in the n-well  230   a  with its channel layer  236  in vicinity of the semiconductor surface, right under the gate structure  256 . The p+-layer  240  is forming the source of the IGFET and the p+-layer  241   a  the drain of the IGFET. The junction depths of said p+ layers are approximately 0.2 μm and the layers have typical surface concentrations in the range of 1.10 19  to 5.10 19  cm −3 . An n+-layer  235  with a typical junction depth of 0.2 μm and a typical surface doping concentration of 1·10 2C  cm −3  will serve as body contact to the p-type IGFET transistor and as contact to the n-layer  230   a . Said n-layer  230   a , which reaches the surface, has an approximate depth of 0.4 μm and an approximate doping concentration of 1.10 18  cm −3 . Said layer makes contact to layer  220  and leaves space for a p-well  225 , on top of layer  220 , between layers  230   a  and  230   b.    
     The somewhat longer highly doped drain layer  241   a , that extends into layer  225  will form an ohmic contact  241   b  to the base layer  227   b  of the npn-transistor, where layer  245  is the emitter and layer  230   b  is the collector. The surface of said interconnect layer is preferably shunted by a silicide layer (e.g. TiSi 2 , CoSi 2 , NiSi) of low resistivity. 
     The described devices and functions that have been detailed above as part of the invention are very different from the prior art device of  FIG. 1A , in that the drift layer  20  has in our embodiments been replaced by a somewhat extended drain diffusion having a very low resistivity, typically 20 ohm/square, as compared to the high resistivity, typically 10 kohm, of the prior art drift layer. Conductivity modulation, being an essential function of prior-art devices, will therefore not occur. Furthermore, in contrast to the prior art devices, the transistor structures implemented in the invention are all of standard type and do not require special processing and layout steps and modifications. The use of a vertical bipolar transistor in combination with a lateral IGFET and the elimination of any lateral pnp- and/or npn-transistor(s), the latter being an essential part of prior art devices, reduce the risk of latch-up problems and distinguishes our invention from prior art. 
     REFERENCES 
     
         
           1 N. Sakurai, M. Mori, T. Tanaka, “U.S. Pat. No. 5,126,806” 
           2 B. Bakeroot, J. Doutreloigne, P. Vanmeerbeek, P. Moens, “A New Lateral-IGBT Structure with a Wider Safe Operating Area”, IEEE Electron Device Letters 28, 416-418 (2007). 
           3 E. K. C. Tee, A. Holke, S. J. Pilkington, D. K. Pal, N. L. Yew, so W. A. W. Z. Abidin, “A Review of techniques used in Lateral Insulated Gate Bipolar Transistors (LIGBT)”.

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