Abstract: A power transistor chip and an application circuit thereof have a junction field effect transistor to act as a start-up circuit of an AC/DC voltage converter. The start-up circuit can be turned off after the PWM circuit of the AC/DC voltage converter operates normally to conserve the consumption of the power. Besides, the junction field effect transistor is built in the power transistor chip. Because the junction field effect transistor is fabricated with the same manufacturing process as the power transistor, it is capable of simplifying the entire process and lowering the production cost due to no additional mask and manufacturing process.

Abstract: A Schottky device and a semiconductor process of making the same are provided. The Schottky device comprises a substrate, a deep well, a Schottky contact, and an Ohmic contact. The substrate is doped with a first type of ions. The deep well is doped with a second type of ions, and formed in the substrate. The Schottky contact contacts a first electrode with the deep well. The Ohmic contact contacts a second electrode with a heavily doped region with the second type of ions in the deep well. Wherein the deep well has a geometry gap with a width formed under the Schottky contact, the first type of ions and the second type of ions are complementary, and the width of the gap adjusts the breakdown voltage.

Abstract: The present invention provides a self-driven LDMOS which utilizes a parasitic resistor between a drain terminal and an auxiliary region. The parasitic resistor is formed between two depletion boundaries in a quasi-linked deep N-type well. When the two depletion boundaries pinch off, a gate-voltage potential at a gate terminal is clipped at a drain-voltage potential at said drain terminal. Since the gate-voltage potential is designed to be equal to or higher than a start-threshold voltage, the LDMOS is turned on accordingly. Besides, no additional die space and masking process are needed to manufacture the parasitic resistor. Furthermore, the parasitic resistor of the present invention does not lower the breakdown voltage and the operating speed of the LDMOS. In addition, when the two depletion boundaries pinch off, the gate-voltage potential does not vary in response to an increment of the drain-voltage potential.

Abstract: The present invention discloses an integrated PMOS transistor and Schottky diode, comprising a PMOS transistor which includes a gate, a source, a drain and a channel region between the source and drain, wherein the source, drain and channel region are formed in a substrate, and a parasitic diode is formed between the drain and the channel region; and a Schottky diode formed in the substrate and connected in reverse series with the parasitic diode, the Schottky diode having one end connected with the parasitic diode and the other end connected with the source.

Abstract: The present invention discloses an integrated junction field effect transistor (JFET) and Schottky diode, comprising a depletion mode JFET which includes a source, a drain and a gate, wherein the drain is not provided with an ohmic contact such that it forms a Schottky diode.

Abstract: A MOSFET with an isolation structure is provided. An N-type MOSFET includes a first N-type buried layer and a P-type epitaxial layer disposed in a P-type substrate. A P-type FET includes a second N-type buried layer and the P-type epitaxial layer disposed in the P-type substrate. The first, second N-type buried layers and the P-type epitaxial layer provide isolation between FETs. In addition, a plurality of separated P-type regions disposed in the P-type epitaxial layer further provides an isolation effect. A first gap exists between a first thick field oxide layer and a first P-type region, for raising a breakdown voltage of the N-type FET. A second gap exists between a second thick field oxide layer and a second N-well, for raising a breakdown voltage of the P-type FET.

Abstract: A controller chip provides protection to a power converter by using a high-voltage start-up device in the controller chip, without additional pins or external elements of the controller chip. A JFET is used as the high-voltage start-up device connected between a high-voltage pin and a power input pin of the controller chip, to charge a power capacitor connected to the power input pin at power on. The controller chip monitors the voltage at the power input pin and turns off the JFET once the voltage at the power input pin increases to reach a threshold. Thereafter, the source voltage of the JFET will reflect the voltage at the high-voltage pin, and a protection circuit monitors the source voltage of the JFET to trigger a protection signal.

Abstract: The present invention discloses a bi-directional SCR ESD device, comprising: a substrate; a first well located in the substrate, which is floating and has a first conductivity type; a second well and a third well both located in the first well and both having a second conductivity type, the second well and the third well being separated from each other; a first high density doped region of the first conductivity type and a second high density doped region of the second conductivity type located in the second well; and a third high density doped region of the first conductivity type and a fourth high density doped region of the second conductivity type located in the third well.

Abstract: The present invention discloses an isolated SCR ESD device, comprising: a substrate; a first well located in the substrate, which is floating and has a first conductivity type; a first high density doped region located in the first well and having a second conductivity type; a second well nearby the first well and having the second conductivity type; a second high density doped region located in the second well and having the second conductivity type; and a third high density doped region located in the second well and having the first conductivity type, wherein the first high density doped region is for electrical connection with a pad, and wherein the first well is not provided with a high density doped region having the first conductivity type for connection with the pad.

Abstract: Voltage-controlled semiconductor structures, voltage-controlled resistors, and manufacturing processes are provided. The semiconductor structure comprises a substrate, a first doped well, and a second doped well. The substrate is doped with a first type of ions. The first doped well is with a second type of ions and is formed in the substrate. The second doped well is with the second type of ions and is formed in the substrate. The first type of ions and the second type of ions are complementary. A resistor is formed between the first doped well and the second doped well. A resistivity of the resistor is controlled by a differential voltage. A resistivity of the resistor relates to a first depth of the first doped well, a second depth of the second doped well, and a distance between the first doped well and the second doped well. The resistivity of the resistor is higher than that of a well resistor formed in a single doped well with the second type of ions.

Abstract: A method of manufacturing different-voltage devices mainly comprises forming at least one high-voltage well in high-voltage device regions, at least one N-well in low-voltage device regions, at least one P-well in low-voltage device regions, source/drain wells in high-voltage device regions, and isolation wells in isolation regions in a p-type substrate. The breakdown voltage is adjusted by modulating the ion doping profile. Furthermore, parameters of implanting conductive ions are adjusted for implanting conductive ions into both high-voltage device regions and low-voltage device regions. The isolation wells formed in isolation regions between devices are for separating device formed over high-voltage device regions and device formed over low-voltage device regions. The thickness of a HV gate oxide layer is thicker than the thickness of an LV gate oxide layer for modulating threshold voltages of high-voltage devices and low-voltage devices.

Abstract: A switch circuit to control a high voltage source is presented. It includes a JFET transistor, a resistive device, a first transistor and a second transistor. The JFET transistor is coupled to the high voltage source. The first transistor is connected in serial with the JFET transistor to output a voltage in response to the high voltage source. The second transistor is coupled to control the first transistor and the JFET transistor in response to a control signal. The resistive device is coupled to the JFET transistor and the first transistor to provide a bias voltage to turn on the JFET transistor and the first transistor when the second transistor is turned off. Once the second transistor is turned on, the first transistor is turned off and the JFET transistor is negative biased.

Abstract: A MOSFET device with an isolation structure for a monolithic integration is provided. A P-type MOSFET includes a first N-well disposed in a P-type substrate, a first P-type region disposed in the first N-well, a P+ drain region disposed in the first P-type region, a first source electrode formed with a P+ source region and an N+ contact region. The first N-well surrounds the P+ source region and the N+ contact region. An N-type MOSFET includes a second N-well disposed in a P-type substrate, a second P-type region disposed in the second N-well, an N+drain region disposed in the second N-well, a second source electrode formed with an N+ source region and a P+ contact region. The second P-type region surrounds the N+ source region and the P+ contact region. A plurality of separated P-type regions is disposed in the P-type substrate to provide isolation for transistors.

Abstract: The present invention discloses an integrated junction field effect transistor (JFET) and Schottky diode, comprising a depletion mode JFET which includes a source, a drain and a gate, wherein the drain is not provided with an ohmic contact such that it forms a Schottky diode.

Abstract: The present invention discloses an integrated PMOS transistor and Schottky diode, comprising a PMOS transistor which includes a gate, a source, a drain and a channel region between the source and drain, wherein the source, drain and channel region are formed in a substrate, and a parasitic diode is formed between the drain and the channel region; and a Schottky diode formed in the substrate and connected in reverse series with the parasitic diode, the Schottky diode having one end connected with the parasitic diode and the other end connected with the source.

Abstract: The present invention discloses an integrated PMOS transistor and Schottky diode, comprising a PMOS transistor which includes a gate, a source, a drain and a channel region between the source and drain, wherein the source, drain and channel region are formed in a substrate, and a parasitic diode is formed between the drain and the channel region; and a Schottky diode formed in the substrate and connected in reverse series with the parasitic diode, the Schottky diode having one end connected with the parasitic diode and the other end connected with the source.

Abstract: A semiconductor structure for protecting an internal integrated circuit comprises a substrate; a plurality of first doping regions formed in the substrate and disposed substantially within an N-well; a plurality of second doping regions, formed in the substrate and disposed within an P-well; a N+ section, formed in the substrate and enclosing the N-well and the P-well; a pad, formed above the substrate and electrically connected to at least one of the first doping regions; and a first ground and a second ground respectively disposed to positions corresponding to outside and inside of the N+ section. Also, the second doping regions are isolated from the first doping regions. The first and second doping regions located within the N+ section are isolated from the substrate by the N+ section. Furthermore, the second ground is electrically connected to at least one of the second doping regions.

Abstract: A semiconductor structure of a high side driver and method for manufacturing the same is disclosed. The semiconductor of a high side driver includes an ion-doped junction and an isolation layer formed on the ion-doped junction. The ion-doped junction has a number of ion-doped deep wells, and the ion-doped deep wells are separated but partially linked with each other.

Abstract: A power transistor chip with built-in enhancement mode metal oxide semiconductor field effect transistor and application circuit thereof provides an enhancement mode metal oxide semiconductor field effect transistor in association with two series connected resistors to act as a start-up circuit for the AC/DC voltage converter. The start-up circuit can be shut off after the pulse width modulation circuit of the AC/DC voltage converter circuit works normally and still capable of offering a function of brown out detection for the pulse width modulation circuit as well. Besides, the enhancement mode metal oxide semiconductor field effect transistor is built in the power transistor chip without additional masks and processes during the power transistor chip being fabricated such that the entire manufacturing process is simplified substantively with the economical production cost.

Abstract: A start up circuit of power converters is presented. It includes a first transistor, a resistive device, a second transistor, a third transistor and a diode. The first transistor is coupled to a voltage source. The third transistor is connected in serial with the first transistor to output a supply voltage to a control circuit of the power converter in response to the voltage source. The diode is connected from a transformer winding of the power converter to supply a further supply voltage to the control circuit of the power converter. The second transistor is coupled to control the first transistor and the third transistor in response to a control signal. The resistive device provides a bias voltage to turn on the first transistor and the third transistor when the second transistor is turned off. Once the second transistor is turned on, the third transistor is turned off and the first transistor is negative biased.