Abstract: A semiconductor device comprising a silicon body (1) with a surface (2) which is adjoined by insulation regions of a first type (3) and insulation regions of a second type (4). The insulation regions of the first type (3) enclose active regions (5) which each comprise a bipolar transistor (6), the insulation regions of the second type (4) enclose active regions (7) which each comprise a MOS transistor (8). The insulation regions of the first type (3) are etched grooves (14) which are filled with insulating material (15) through deposition. The insulation regions of the second type (4) are silicon oxide regions obtained through local oxidation of the silicon body.

Abstract: The invention relates to the manufacture of a so-called differential bipolar transistor comprising a base (1A), an emitter (2) and a collector (3), the base (1A) being formed by applying a doped semiconducting layer (1) which locally borders on a monocrystalline part (3) of the semiconductor body (10) where it forms the (monocrystalline) base (1A), and which semiconducting layer (1) borders, outside said monocrystalline part, on a non-monocrystalline part (4, 8) of the semiconductor body (10) where it forms a (non-monocrystalline) connecting region (1B) of the base (1A). The non-monocrystalline part (4, 8) of the semiconductor body (10) is obtained by covering the semiconductor body (10) with a mask (20) and replacing on either side thereof a part (8) of the semiconductor body (10) by an electrically insulating region (8) and by providing this, prior to the application of the semiconducting layer (1) with a polycrystalline semiconducting layer (4).

Abstract: The invention relates to a method of manufacturing a discrete or integrated bipolar transistor comprising a base (1A), an emitter (2) and a collector (3). The base (1A) and a connecting region (1B) of the base (1A) are formed by providing a semiconductor body (10) with a doped semiconducting layer (1) which locally borders on a monocrystalline part (3) of the semiconductor body which forms the collector (3). Outside said base, the layer (1) borders on a non-monocrystalline part (4) of the semiconductor body (10) and forms a non-monocrystalline connecting region (1B) of the base (1A). By means of a mask (5), the doping concentration of the layer (1) outside the mask (5) is selectively increased, resulting in a highly conducting connection region (1B) and a very fast transistor. In the known method, an ion implantation is used for this purpose.

Abstract: The continuing miniaturization of integrated circuits leads to a demand for ever higher resistance values. In conventional diffused resistors or poly resistors, an increase in the resistance value also means an increase in the surface area. Such resistors, moreover, are highly dependent on the doping concentration and sensitive to temperature changes. A resistor according to the invention comprises a resistor region 18 with a length and doping concentration which are chosen such that an electric field is applied at which velocity saturation of charge carriers takes place in the envisaged range of operation. The connection regions are connected to the resistor region via rectifying junctions 21, 22. In a specific embodiment, these junctions are formed by pn junctions, so that the resistor has, for example, an npn shape.