Abstract:
The invention relates to a controllable semiconductor circuit element consisting of a vertical thyristor comprised of four zones of alternating conductivity types and arranged in a semiconductor disk, with the two load current connections located on the top surface and on the bottom surface of the semiconductor disk respectively. According to the invention, the semiconductor disk comprises an additional controllable circuit element with a lateral zone structure on the top surface of the semiconductor disk. Zones of this additional circuit element are linked with zones of the vertical thyristor in such a way as to enable the vertical thyristor to be indirectly ignited by ignition of the lateral circuit element.

Description:
BACKGROUND OF THE INVENTION 
     Integrated semiconductor arrangements comprised of a semiconductor disk containing a thyristor and, in addition, an ignition or pilot thyristor in a monolythically integrated form are known. The actual vertical thyristor has a zone sequence npnp of pnpn, with the individual zones arranged sequentially in a vertical direction in the semiconductor disk. The pilot thyristor serving for the ignition likewise has a vertical zone sequence in the known arrangement (F. E. Gentry, J. Moyson: &#34;The Amplifying Gate Thyristor&#34;, International Electron Devices Meeting, Washington, D.C. 1968, Technical Digest page 110). 
     There are cases where the vertical zone sequence of the pilot thyristor is disadvantageous for the ignition of the vertical thyristor. This is, for instance, the case if the pilot thyristor is an optically controlled component where only a small part of the incident light can be used for the switching operation. In other cases, it is desirable to ignite a thyristor from the surface side located opposite the control base zone, which is only possible with the known arrangement if disadvantages are tolerated. 
     SUMMARY OF THE INVENTION 
     The object underlying the invention is therefore to provide a controllable semiconductor circuit element comprised of a vertical thyristor and an additional switching element, with which, also in such cases, low electrical or optical triggering outputs are obtainable. 
     This object is characterized in accordance with the invention in that the additional controllable circuit element has a lateral zone structure and is located at the top surface of the semiconductor disk, and in that zones of this additional circuit element are linked with zones of the vertical thyristor in such a way as to enable the vertical thyristor to be indirectly ignited by ignition of the lateral circuit element. 
     In a preferred embodiment of the invention, two vertically arranged anti-parallel thyristors each consisting of four zones of alternating conductance type are arranged in the semiconductor disk, with three zones being common to both thyristors, while the fourth outer zones acting as emitters are inserted opposite each other in the top surface and bottom surface of the semiconductor disk in the respective adjoining control base zone. The two load current connections are common to both vertical thyristors. With this arrangement, the vertical thyristor, whose control base zone is located on the surface side of the semiconductor disk facing away from the incident light, can be ignited with low triggering output indirectly by optical ignition of the lateral thyristor, which, in turn, actuates the subsequent ignition of the vertical thyristor. 
     Further advantageous features of the invention are likewise described. 
     Bidirectional thyristors designed as vertically switching anti-parallel thyristors and provided with an electric control connection, with both partial thyristors being switchable by trigger currents in this control connection, are already known. 
     With these switching elements, however, a relatively large electric trigger output is required, in particular, for the ignition of the partial thyristor whose n +  -emitter zone and control base zone are not located on the same surface as the control connection (German Auslegeschrift 1,764,821). 
     If such components are to be ignited by optical irradiation, the partial thyristor whose n +  -emitter zone is located on the surface side of the semiconductor body common to both partial thyristors opposite the irradiation direction, may only be ignited by means of relatively high light intensity, unless bad spurious ignition characteristics (du/dt load resistance) are tolerated. With the semiconductor circuit element according to the invention, on the other hand, in the case of optical ignition, at least one of the vertical thyristors is indirectly ignited by the optically controllable lateral thyristor. 
     Laterally acting thyristors for low triggering output where the spurious ignition resistance is improved by additional aids (German Auslegeschrift 1,464,984) are also known. 
     Since output components are soldered or glued at least on one side onto a good heat conducting carrier to improve heat dissipation, measures for improving the spurious ignition resistance may only be taken, in vertically arranged bidirectional thyristors, for the partial thyristor whose control base zone is located on the surface side of the semiconductor body which is not soldered to the heat conducting carrier. Such anti-parallel vertical thyristors therefore cannot be triggered by low electrical or optical control outputs. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention is described in greater detail with reference to embodiments shown schematically in the drawings. 
     FIG. 1 is a first embodiment of the invention comprised of two anti-parallel vertical thyristors and a lateral thyristor, with the latter being optically ignitable and thereby actuating the ignition of a vertical thyristor; 
     FIG. 2 is a further embodiment wherein additional measures are taken for the prevention of spurious ignitions. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1 is a schematic illustration of a semiconductor disk 1 comprising optically controllable, integrated, anti-parallel vertical thyristors 2 and 3 and a lateral thyristor 4. The top disk surface 5 on which the lateral thyristor is arranged carries one load current connection 6, and the opposite bottom disk surface 7 carries the other load current connection 8. To trigger the element, there are directed at the surface 5, as indicated by arrows, an optical irradiation 9 into the vertical thyristor 3 and an irradiation 10 into the lateral thyristor 4. 
     The vertical thyristors 2 and 3 have the p zone 11 on the surface side 5, the lower p zone 13 on the opposite surface side 7 of the semiconductor body, and the n conducting base zone 12 located between the p zones 11 and 13 in common. The n +  emitter zone 14 for the thyristor 2 is inserted in the p zone 11, and the n +  emitter zone 15 for the thyristor 3 in the p zone 13. Emitter zones 14 and 15 are linked by shunts 16 and 17 respectively to their respective adjacent p conducting control base zones 11 and 13. These shunts 16 and 17 consist of p conducting, local breakthroughs of the control base zones 11 and 13 respectively, which extend through the adjacent emitter zones 14 and 15 respectively as far as the respective surfaces 5 and 7. These shunts 16 and 17 reduce the spurious ignition sensitivity. 
     The p zone 13 extends from the bottom side 7 of the semi-conductor disk 1 through a separating diffusion zone 18 to the surface side 5 where it is insulated against the upper p zone 11 by the pn junctions 20, 21 covered by oxide layers or semi-insulating layers 19. 
     The lateral thyristor 4 on the surface side 5 consists of the n +  emitter zone 22, its surrounding, associated and p conducting control base zone 23, and n base area 24 reaching the surface 5, and the laterally adjacent p conducting zone area 11&#39; which forms the p emitter and is comprised of a section of the p conducting zone 11 of the vertical thyristors 2 and 3. The p conducting zone areas 11 and 11&#39; therefore extend into one another and the overlapping area constitutes a bulk resistance. The n +  emitter zone 22 is connected to the upwardly extending, p conducting separating diffusion zone 18 via an Ohmic link 25. Furthermore, the p control base zone 23 is connected to the separating diffusion zone 18 by a slightly p doped area 26, which constitutes the resistance determining the ignition and spurious ignition sensitivity of the lateral thyristor 4. 
     While the thyristor 2 is ignited in the known manner by optical irradiation 9 and the charge carrier generation caused thereby in the p zone 11 and the pn junction 20 constituted by zones 11 and 12, ignition of the thyristor 3 is effected indirectly by optical ignition of the lateral thyristor 4. Thyristor 3 is not ignited until the load current in the thyristor 4 causes a strong injection of holes from the p emitter zone 11&#39; into the n base area 24 and 12, respectively, as indicated by the electron flows 27 and the hole flows 28 in FIG. 1. The advantage gained by the invention consists in that the partial thyristor 3, whose optical ignition sensitivity is low, is indirectly triggered by the substantially more ignition sensitive element 4. Thus, the otherwise high ignition sensitivity required of the thyristor 3 with the disadvantageous correspondingly high spurious ignition sensitivity is avoided. 
     FIG. 2 shows an advantageous further development of the invention where a lateral thyristor 4&#39; is also associated with the vertical thyristor 2 for ignition purposes. The lateral thyristors 4 and 4&#39; also have additional circuit components for avoidance of spurious ignitions, i.e., a du/dt compensation. The design of the du/dt compensated lateral thyristors is identical. They consist of the n +  emitter zones 22, 22&#39;, the control base zones 23, 23&#39;, the control base leak resistors 29, 29&#39; which carry out a similar function to that of the p zone 26 in FIG. 1, the emitter preresistors 30, 30&#39; and the compensation zones 31, 31&#39;, and finally the n base areas 24, 24&#39;, and the p emitter areas 11&#39; and 18&#39;. The emitter preresistors 30, 30&#39; and the control base leak resistors 29, 29&#39; are dimensioned such that with du/dt loads--i.e. with steeply rising inverse voltage jumps--the capacitive spurious currents cause identically sized voltages at resistors 29, 30 and 29&#39; and 30&#39;, respectively, so that a current flow through the pn junctions between zones 22 and 23, and 22&#39; and 23&#39;, respectively, is avoided, thus safely preventing the occurrence of a spurious ignition. The capacitive currents through resistors 29, 29&#39; occur in the presence of voltage on account of the pn junctions between zones 23 and 12 and 23&#39; and 12&#39;, respectively; the capacitive currents through resistors 30, 30&#39; on account of the pn junctions between the zones 31, 12 and 31&#39;, 12&#39;, respectively. 
     The p zone areas 23, 23&#39; and, advantageously, also the base zone areas 24 and 24&#39; are subjected to irradiation to effect optical ignition. In this case, the voltage decrease caused by the photo-electric current at the control base leak resistor 29, 29&#39; initiates ignition. The compensation areas 31 and 31&#39; are protected from irradiation by covers. 
     This embodiment permits an increase in the optical triggering sensitivity without raising the spurious ignition sensitivity of the partial thyristors. 
     Base zone 11 is separated from base zone 13 by passivation trenches 32 so that greater stability may also be achieved in the case of larger inverse voltages. These, for instance, etched passivation trenches 32 are always located in the region of the base zone areas 24 and 24&#39; of the lateral thyristors. 
     Basically, the advantage of the invention is not limited to optical triggering. Also in the case of triggering by means of small control currents, the integration of a lateral thyristor 4 is of advantage; it will, however, in this event be designed accordingly as an electrically ignited thyristor. 
     Furthermore, an embodiment is possible where the entire circuit component is provided with interchanged conductivity dopings, i.e., where the p zones are replaced by n zones (and vice versa). The emitter zones and the control base zones are preferably produced by means of diffusion. 
     The arrangement shown in FIG. 2 has the advantage that the lateral thyristor 4 which is associated with the vertical thyristor 3 and ignites it may comprise integrated protective circuit components. Such a direct protective circuitry is hardly or only incompletely realizable for the vertical thyristor 3, since its large-surface cathode metallization in the form of the load current connection 8 is mounted on a good heat conducting carrier body, so that these bottom surfaces of the semiconductor disk 1 are practically not available for accommodation and contacting of further circuitry elements.