Abstract: A transient voltage suppressor is provided, comprising a heavily doped substrate connected to a first node, a first doped layer formed on the heavily doped substrate, a second doped layer formed on the first doped layer, a first heavily doped region and a second heavily doped region formed in the second doped layer and coupled to a second node, and a plurality of trenches arranged in the heavily doped substrate, having a depth not less than that of the first doped layer for electrical isolation. The heavily doped substrate, the second doped layer, and the second heavily doped region belong to a first conductivity type. The first doped layer and the first heavily doped region belong to a second conductivity type. By employing the proposed present invention, pn junctions of the transient voltage suppressor can be controlled beneath the surface, thereby reducing the junction capacitance effectively.

Abstract: A vertical transient voltage suppression device includes a semiconductor substrate having a first conductivity type, a first doped well having a second conductivity type, a first heavily-doped area having the first conductivity type, a second heavily-doped area having the first conductivity type, and a diode. The first doped well is arranged in the semiconductor substrate and spaced from the bottom of the semiconductor substrate, and the first doped well is floating. The first heavily-doped area is arranged in the first doped well. The second heavily-doped area is arranged in the semiconductor substrate. The diode is arranged in the semiconductor substrate and electrically connected to the second heavily-doped area through a conductive trace.

Abstract: A lateral transient voltage suppressor device is provided, comprising a doped substrate, a lateral clamping structure disposed on the doped substrate, a buried doped layer disposed between the doped substrate and the lateral clamping structure for isolation, at least one diode module, and at least one trench arranged in the doped substrate, having a depth not less than that of the buried doped layer, and being disposed between the lateral clamping structure and the at least one diode module for electrical isolation. The doped substrate and the buried doped layer have opposite conductivity types such that the doped substrate is electrically floating. The buried doped layer can be further disposed to separate the diode module from the doped substrate. By employing the proposed invention, the lateral transient voltage suppressor device is advantageous of maintaining both a lower clamping voltage as well as a reduced dynamic resistance.

Abstract: A bus driver module with controlled circuit is connected to a controller area network bus for generating a high side output or a low side output, comprising a transition controlled circuit and an output driver. The transition controlled circuit comprises a first pathway controlled unit connected in parallel with a second pathway controlled unit for generating a side switching voltage. The output driver is connected in series with the transition controlled circuit and receives the side switching voltage so as to accordingly generate the output bus signal. Each of the first and second pathway controlled unit comprises a plurality of switches and can be activated depending on an input signal. By controlling the switches of the first or second pathway controlled unit to be sequentially turned on and off successively, the side switching voltage is characterized by a smooth phase transition, low common mode noise and better EMI performances.

Abstract: An on-chip multiple-stage electrical overstress (EOS) protection device is disclosed. The protection device includes a surge protector having a first clamping voltage and a first electrostatic discharge (ESD) protector having a second clamping voltage lower than the first clamping voltage. The surge protector is electrically connected to the first ESD protector in parallel. The surge protector and the first ESD protector are electrically connected between a receiving terminal and a voltage terminal, and the receiving terminal is electrically connected to an internal circuit. When an electrical overstress (EOS) signal including an electrostatic discharge (ESD) signal and a surge signal appears at the receiving terminal, the first ESD protector and the surge protector are triggered on in turn to clamp a voltage received by the internal circuit.

Abstract: An active surge protection structure is provided between a power line and a core circuit, comprising a surge-to-digital converter and a clamp circuit. The surge-to-digital converter comprises a plurality of surge detection circuit. Each surge detection circuit detects a surge event occurring on the power line and generates a digital signal. The clamp circuit is disposed adjacent to the core circuit and electrically connected with the surge-to-digital converter and the power line where the core circuit is connected for dissipating surge energy. The clamp circuit receives and is driven by the digital signals from the surge-to-digital converter such that its protection flexibility can be achieved according to the digital signals. By employing the present invention, it is extraordinarily advantageous of improving system stability and achieving comprehensive surge protection with configuration of driving capability dependent on surge levels.

Abstract: A silicon controlled rectifier includes a P-type substrate, an N-type doped well, a first P-type strip-shaped heavily-doped area arranged in the N-type doped well, a first N-type strip-shaped heavily-doped area arranged in the P-type substrate, and at least one N-type heavily-doped area arranged in the P-type substrate and the N-type doped well. The at least one N-type heavily-doped area is not arranged between the first P-type strip-shaped heavily-doped area and the first N-type strip-shaped heavily-doped area, thus the surface area of a semiconductor substrate can be reduced. The conductivity types of the abovementioned components are alternatively changed.

Abstract: A digital isolator module for high level common mode transient immunity is provided, comprising a transmitter circuit (TX), a receiver circuit (RX) and an isolation barrier which is connected there in between, wherein the transmitter circuit is electrically connected to a first ground voltage level and the receiver circuit is electrically connected to a second ground voltage level. The receiver circuit further comprises a resistance set, a high speed detector and a demodulator. By employing the proposed circuit diagram of the invention, interferences occurring at the common mode are suppressed and an RX output signal is synchronized with its input signal without having propagation delay.

Abstract: A transient voltage suppression device with improved electrostatic discharge (ESD) robustness includes a semiconductor substrate having a first conductivity type, a first doped well having a second conductivity type, a first heavily-doped area having the first conductivity type, a second doped well having the second conductivity type, a second heavily-doped area having the first conductivity type, and a first current blocking structure. The first doped well is arranged in the semiconductor substrate. The first heavily-doped area is arranged in the first doped well. The second doped well is arranged in the semiconductor substrate. The second heavily-doped area is arranged in the second doped well. The first current blocking structure is arranged in the semiconductor substrate, spaced from the bottom of the semiconductor substrate, and arranged between the first doped well and the second doped well.

Abstract: A bidirectional silicon-controlled rectifier includes a lightly-doped semiconductor structure, a first lightly-doped region, a second lightly-doped region, a first doped well, a second doped well, a first heavily-doped area, a second heavily-doped area, a third heavily-doped area, a fourth heavily-doped area. The lightly-doped semiconductor structure, the first heavily-doped area, and the third heavily-doped area have a first conductivity type. The first lightly-doped region, the second lightly-doped region, the first doped well, the second doped well, the fourth heavily-doped area, and the second heavily-doped area have a second conductivity type. A first part of the first lightly-doped region is arranged under the first doped well. A second part of the second lightly-doped region is arranged under the second doped well.

Abstract: An improved transient voltage suppression device includes a semiconductor substrate, a transient voltage suppressor, at least one first diode, at least one conductive pad, and at least one second diode. The transient voltage suppressor has an N-type heavily-doped clamping area. The first anode of the first diode is electrically connected to the N-type heavily-doped clamping area. The conductive pad is electrically connected to the first cathode of the first diode. The second anode of the second diode is electrically connected to the conductive pad and the second cathode of the second diode is electrically connected to the transient voltage suppressor. The first anode is closer to the N-type heavily-doped clamping area rather than the conductive pad. The conductive pad is closer to the N-type heavily-doped clamping area rather than the second anode.

Abstract: A heat-dissipating Zener diode includes a heavily-doped semiconductor substrate having a first conductivity type, a first epitaxial layer having the first conductivity type, a first heavily-doped area having a second conductivity type, a second epitaxial layer, and a second heavily-doped area having the second conductivity type or the first conductivity type. The first epitaxial layer is formed on the heavily-doped semiconductor substrate. The first heavily-doped area is formed in the first epitaxial layer and spaced from the heavily-doped semiconductor substrate. The second epitaxial layer is formed on the first epitaxial layer and penetrated with a first doped area, and the first doped area has the second conductivity type and contacts the first heavily-doped area. The second heavily-doped area is formed in the first doped area.

Abstract: In a test method for eliminating electrostatic charges, at least one test process is firstly performed by a test equipment comprising a tester and a platform, and electrostatic charges are generated on the test equipment in the test process. In the test process, the tester contacts and tests at least one tested integrated circuit (IC) on a test area of the platform, and then the tested IC is removed from the tester and the test area. Next, a conduction device which is grounded is moved to the test area, so that the tester contacts the conduction device to discharge the electrostatic charges to ground. Next, the conduction device is removed from the tester and the test area. Finally, the method returns to the test process to test the next tested IC.

Abstract: A self-balanced diode device includes a substrate, a doped well, at least one first conductivity type heavily doped fin and at least two second conductivity type heavily doped fins. The doped well is arranged in the substrate. The first conductivity type heavily doped fin is arranged in the doped well, arranged in a line along a first direction, and protruded up from a surface of the substrate. The second conductivity type heavily doped fins is arranged in the doped well, arranged in a line along a second direction intersecting the first direction, respectively arranged at two opposite sides of the first conductivity type heavily doped fin, and protruded up from the surface of the substrate. Each second conductivity type heavily doped fin and the first conductivity type heavily doped fin are spaced at a fixed interval.

Abstract: A self-balanced diode device includes a substrate, a doped well, at least one first conductivity type heavily doped fin and at least two second conductivity type heavily doped fins. The doped well is arranged in the substrate. The first conductivity type heavily doped fin is arranged in the doped well, arranged in a line along a first direction, and protruded up from a surface of the substrate. The second conductivity type heavily doped fins is arranged in the doped well, arranged in a line along a second direction intersecting the first direction, respectively arranged at two opposite sides of the first conductivity type heavily doped fin, and protruded up from the surface of the substrate. Each second conductivity type heavily doped fin and the first conductivity type heavily doped fin are spaced at a fixed interval.

Abstract: A self-balanced silicon-controlled rectification device includes a substrate, an N-type doped well, a P-type doped well, at least one heavily doped clamping fin, at least one first P-type heavily doped fin, and at least one first N-type heavily doped fin. The N-type doped well and the P-type doped well are arranged in the substrate. The heavily doped clamping fin is arranged in the N-type doped well and the P-type well and protruded up from a surface of the substrate. The first P-type heavily doped fin and the first N-type heavily doped fin are respectively arranged in the N-type doped well and the P-type doped well, and protruded up from the surface of the substrate. The abovementioned elements forms silicon-controlled rectifiers (SCRs) are forward biased to generate uniform electrostatic discharge (ESD) currents through the SCRs.

Abstract: A bipolar transistor device includes a substrate and at least one first transistor unit. The first transistor unit includes a first doped well of first conductivity type, at least one first fin-based structure and at least one second fin-based structure. The first fin-based structure includes a first gate strip and first doped fins arranged in the first doped well, and the first gate strip is floating. The second fin-based structure includes a second gate strip and second doped fins arranged in the first doped well, and the second gate strip is floating. The first doped fins, the second doped fins and the first doped well form first BJTs, and the first doped fins and the second doped fins are respectively coupled to high and low voltage terminals.

Abstract: A self-feedback control circuit is connected to a controller area network bus for controlling a high-level output and a low-level output, comprising a controller area network driving circuit and a replica circuit. The replica circuit is connected in parallel with the controller area network driving circuit and comprises an upper feedback path and a lower feedback path. The upper feedback path and the lower feedback path are connected jointly to a common mode, and the replica circuit provides a feedback signal from the common mode such that the feedback signal is able to be respectively transmitted to two individual transistors of the controller area network driving circuit through the upper feedback path and through the lower feedback path so as to control DC level stability of the high-level output and the low-level output.

Abstract: A slope control circuit is connected between a replica circuit and a controller area network bus. The replica circuit generates an upper and a lower feedback signal. The slope control circuit receives and is driven by the feedback signals for controlling a voltage slope of a high-level output and a low-level output. The slope control circuit comprises an upper and a lower driving circuit, individually connected between the replica circuit, the high-level output and the low-level output. The upper driving circuit and the lower driving circuit respectively include at least one charging and discharging circuit. By controlling the charging and discharging circuit, the present invention controls decreasing voltage slope of the high-level output to be symmetric to increasing voltage slope of the low-level output, and delay time of the circuit switching between different operating modes to be equivalent.

Abstract: A receiving circuit with an ultra-wide common-mode input voltage range applies to a controller area network (CAN) and comprises a resistor assembly electrically connected with a CANH and a CANL, a reference amplifier, a first input amplifier assembly, a second input amplifier assembly, and an analog adder. The receiving circuit receives voltages from the CANH and CANL. The resistor assembly bucks voltage, respectively generating CANH and CANL voltage divisions at first and second nodes and outputting the voltage divisions to the first and second input amplifier assemblies. The first and second input amplifier assemblies amplify the differential signal between the first and second nodes and convert the differential signal into single-end signals. The analog adder adds the single-end signals as the output signal. The receiving circuit can receive the signal ranging between the maximum and minimum common-mode voltages and reduce electromagnetic emission.