Abstract: A semiconductor device simplifies the manufacturing process. The device includes a protective chip which has a surface Zener diode to protect a light emitting chip with an LED formed therein from surge voltage. The protective chip is mounted over a wiring electrically coupled through a metal wire to an anode electrode coupled to a p-type semiconductor region whose conductivity type is the same as that of the semiconductor substrate of the chip. The anode electrode of the protective chip is electrically coupled to the back surface of the chip without PN junction, so even if the back surface is in contact with the wiring, no problem occurs with the electrical characteristics of the Zener diode. This eliminates the need to form an insulating film on the back surface of the chip to prevent contact between the back surface and the wiring, thus simplifying the manufacturing process.

Abstract: A semiconductor device simplifies the manufacturing process. The device includes a protective chip which has a surface Zener diode to protect a light emitting chip with an LED formed therein from surge voltage. The protective chip is mounted over a wiring electrically coupled through a metal wire to an anode electrode coupled to a p-type semiconductor region whose conductivity type is the same as that of the semiconductor substrate of the chip. The anode electrode of the protective chip is electrically coupled to the back surface of the chip without PN junction, so even if the back surface is in contact with the wiring, no problem occurs with the electrical characteristics of the Zener diode. This eliminates the need to form an insulating film on the back surface of the chip to prevent contact between the back surface and the wiring, thus simplifying the manufacturing process.

Abstract: A semiconductor device simplifies the manufacturing process. The device includes a protective chip which has a surface Zener diode to protect a light emitting chip with an LED formed therein from surge voltage. The protective chip is mounted over a wiring electrically coupled through a metal wire to an anode electrode coupled to a p-type semiconductor region whose conductivity type is the same as that of the semiconductor substrate of the chip. The anode electrode of the protective chip is electrically coupled to the back surface of the chip without PN junction, so even if the back surface is in contact with the wiring, no problem occurs with the electrical characteristics of the Zener diode. This eliminates the need to form an insulating film on the back surface of the chip to prevent contact between the back surface and the wiring, thus simplifying the manufacturing process.

Abstract: A semiconductor device simplifies the manufacturing process. The device includes a protective chip which has a surface Zener diode to protect a light emitting chip with an LED formed therein from surge voltage. The protective chip is mounted over a wiring electrically coupled through a metal wire to an anode electrode coupled to a p-type semiconductor region whose conductivity type is the same as that of the semiconductor substrate of the chip. The anode electrode of the protective chip is electrically coupled to the back surface of the chip without PN junction, so even if the back surface is in contact with the wiring, no problem occurs with the electrical characteristics of the Zener diode. This eliminates the need to form an insulating film on the back surface of the chip to prevent contact between the back surface and the wiring, thus simplifying the manufacturing process.

Abstract: To provide a technique that can decrease the leak current due to the photoelectric effect in a semiconductor device with a Zener diode. In a bidirectional Zener diode IZD having a trench structure in the invention, an upper electrode UE extends from an inside of an opening OP to cover a trench TR (isolation region). As shown in FIG. 8, in the bidirectional Zener diode IZD of the invention, the upper electrode UE is formed to cover the inner walls of the trenches TRs. Thus, even when light is applied to the bidirectional Zener diode IZD, the light can be prevented from entering the p-n junction formed at the boundary between the n-type semiconductor region NR and the p-type semiconductor region PR from the inner wall of the trench TR.

Abstract: An epitaxial layer is formed in a main surface of a semiconductor substrate of a first conductivity type. The epitaxial layer is partitioned into a first area and a second area by a device isolation area. A PN junction portion, which has a semiconductor layer of a second conductivity type and configures a variable capacitance element, is provided at the surface of the epitaxial layer of the first area. A PN junction portion, which has a semiconductor layer of the second conductivity type whose low portion is formed closer to the semiconductor substrate than the semiconductor layer of the second conductivity type configuring the above variable capacitive PN junction and which is configured as a fixed capacitance, is provided at the surface of the epitaxial layer of the second area.