Abstract: An electrostatic discharge (ESD) protection circuit is provided. A transistor is coupled between a node and a ground, and has a gate coupled to the ground. A diode chain is coupled between the node and a pad, and comprises a plurality of first diodes connected in series, wherein the first diode is coupled in a forward conduction direction from the pad to the node. A second diode is coupled between the node and the pad, and the second diode is coupled in a forward conduction direction from the node to the pad.

Abstract: ESD protection devices without current crowding effect at the finger's ends. It is applied under MM ESD stress in sub-quarter-micron CMOS technology. The ESD discharging current path in the MMOS or PMOS device structure is changed by the proposed new structures, therefore the MM ESD level of the NMOS and PMOS can be significantly improved. In this invention, 6 kinds of new structures are provided. The current crowding problem can be successfully solved, and have a higher MM ESD robustness. Moreover, these novel devices will not degrade the HBM ESD level and are widely used in ESD protection circuits.

Abstract: ESD protection devices without current crowding effect at the finger's ends. It is applied under MM ESD stress in sub-quarter-micron CMOS technology. The ESD discharging current path in the NMOS or PMOS device structure is changed by the proposed new structures, therefore the MM ESD level of the NMOS and PMOS can be significantly improved. In this invention, 6 kinds of new structures are provided. The current crowding problem can be successfully solved, and have a higher MM ESD robustness. Moreover, these novel devices will not degrade the HBM ESD level and are widely used in ESD protection circuits.

Abstract: ESD protection devices without current crowding effect at the finger's ends. It is applied under MM ESD stress in sub-quarter-micron CMOS technology. The ESD discharging current path in the NMOS or PMOS device structure is changed by the proposed new structures, therefore the MM ESD level of the NMOS and PMOS can be significantly improved. In this invention, 6 kinds of new structures are provided. The current crowding problem can be successfully solved, and have a higher MM ESD robustness. Moreover, these novel devices will not degrade the HBM ESD level and are widely used in ESD protection circuits.

Abstract: An ESD protection device. The ESD protection device has a substrate; a channel region, a source region, and a drain region. The channel region is formed on a predetermined area of a surface of the substrate, the channel region has a first side and a second side. The source region is formed adjacent to the first side. The drain region which has a heavily doped region and a lightly doped region formed below the heavily doped region is formed adjacent to the second side. The width along a longitudinal axis of the heavily doped region has variable length and thus the length between one side of the heavily doped region to the second side has variable length.

Abstract: A high voltage device. A high voltage MOS transistor is applied in the ESD protection device to the structure of which a doped region is added, generating a parasitic semiconductor controlled rectifier (SCR) having a shorter discharge path such that the SCR has faster response enhancing ESD protection.

Abstract: An ESD protection device. The ESD protection device is incorporated with a gap structure in a laterally diffused metal oxide semiconductor (LDMOS) field effect transistor, isolating a doped region and a field oxide region. When a parasitical semiconductor controlled rectifier (SCR) of LDMOS is turned off, ESD current is discharged distributively through several discharge paths, avoiding ESD current focus in a signal narrow discharge path and the danger therefrom.

Abstract: An ESD protection device. The ESD protection device has a substrate; a channel region, a source region, and a drain region. The channel region is formed on a predetermined area of a surface of the substrate, the channel region has a first side and a second side. The source region is formed adjacent to the first side. The drain region which has a heavily doped region and a lightly doped region formed below the heavily doped region is formed adjacent to the second side. The width along a longitudinal axis of the heavily doped region has variable length and thus the length between one side of the heavily doped region to the second side has variable length.

Abstract: A high voltage device. A high voltage MOS transistor is applied in the ESD protection device to the structure of which a doped region is added, generating a parasitic semiconductor controlled rectifier (SCR) having a shorter discharge path such that the SCR has faster response enhancing ESD protection.

Abstract: ESD protection devices without current crowding effect at the finger's ends. It is applied under MM ESD stress in sub-quarter-micron CMOS technology. The ESD discharging current path in the NMOS or PMOS device structure is changed by the proposed new structures, therefore the MM ESD level of the NMOS and PMOS can be significantly improved. In this invention, 6 kinds of new structures are provided. The current crowding problem can be successfully solved, and have a higher MM ESD robustness. Moreover, these novel devices will not degrade the HBM ESD level and are widely used in ESD protection circuits.

Abstract: The present invention proposes an ESD protection circuit and its related circuits, suitable in an integrated circuit (IC), and coupled between a first pad and a second pad. When a power supply is provided to the IC, a bias generator generates a bias voltage to close the protection component. When the power supply is not provided to the IC, the protection component is always on to release the ESD stress between the first pad and the second pad.

Abstract: A two-stage ESD protection circuit coupled between an I/O pad and a power rail is provided in the present invention. The two-stage ESD protection circuit has a primary ESD protection circuit and a secondary ESD circuit. The trigger-on rate of the secondary ESD protection circuit is sped up by employing an ESD detection circuit coupled to the I/O pad. It can be further sped up by employing a native NMOS in the secondary ESD protection. According to the invention, the trigger-on speed of the secondary ESD protection circuit can be effectively improved to obtain better ESD protection for the thinner gate oxides of internal circuits in sub-quarter-micron CMOS process.

Abstract: Hybrid diodes with excellent ESD protection capacity. Each hybrid diode has two diodes: one is a poly-bounded diode formed as a junction between a substrate and a diffusion region thereon, the other is a poly diode formed as a poly gate having two regions with different conductivity. The poly-bounded diode and the poly diode are connected in series or in parallel to form a hybrid diode. The parallel hybrid diode has smaller operation resistance and as a result better ESD robustness. The series hybrid diode has lower capacitance load and is especially suitable for the ESD protection in high-speed or radio frequency integrated circuit input/output design. The hybrid diode can also be applied in the ESD protection circuit in an input/output port, a power-rail ESD clamp circuit, and a whole-chip ESD protection system. The hybrid diodes can be also implemented in the silicon-on-insulator (SOI) CMOS process.

Abstract: An open drain driver circuit and a Vss to Vdd FET with a merged layout structure are formed to provide a short path for an ESD current from an associated pad and either Vss or Vdd. The short path reduces the IR drop in the path and thereby maintains a lower voltage at the pad during an ESD event. The driver and the Vss to Vdd FET are each formed of one or more cells that each comprise two source diffusions, two gates, and a common drain diffusion. A frame of the opposite conductivity type as the drain and source diffusions surrounds the components of each cell. The driver and Vss to Vdd FET cells are formed closely adjacent and share common parts of the frame. Several configurations with merged layout structures are disclosed that provide a short ESD current path.

Abstract: Hybrid diodes with excellent ESD protection capacity. Each hybrid diode has two diodes: one is a poly-bounded diode formed as a junction between a substrate and a diffusion region thereon, the other is a poly diode formed as a poly gate having two regions with different conductivity. The poly-bounded diode and the poly diode are connected in series or in parallel to form a hybrid diode. The parallel hybrid diode has smaller operation resistance and as a result better ESD robustness. The series hybrid diode has lower capacitance load and is especially suitable for the ESD protection in high-speed or radio frequency integrated circuit input/output design. The hybrid diode can also be applied in the ESD protection circuit in an input/output port, a power-rail ESD clamp circuit, and a whole-chip ESD protection system. The hybrid diodes can be also implemented in the silicon-on-insulator (SOI) CMOS process.

Abstract: A method for generating a semiconductor test program is disclosed. The method is practiced by first creating a test plan according to a test key database, then take out the related parameters from the other databases in light of the test item in the test plan and creating a semiconductor test program. The semiconductor test program is attached to the wafer acceptance test (WAT) main program as a sub-program. The method for generating the auto-testing program can promote the efficiency for writing a test program and is easy to expand and maintain according to the progress of semiconductor processes.

Abstract: A two-stage ESD protection circuit coupled between an I/O pad and a power rail is provided in the present invention. The two-stage ESD protection circuit has a primary ESD protection circuit and a secondary ESD circuit. The trigger-on rate of the secondary ESD protection circuit is sped up by employing an ESD detection circuit coupled to the I/O pad. It can be further sped up by employing a native NMOS in the secondary ESD protection. According to the invention, the trigger-on speed of the secondary ESD protection circuit can be effectively improved to obtain better ESD protection for the thinner gate oxides of internal circuits in sub-quarter-micron CMOS process.

Abstract: A novel low-voltage-triggered semiconductor controlled rectified (LVTSCR) as an ESD protection device is provided in this invention. The ESD protection device of the present invention has a lateral SCR (LSCR) structure with two electrodes and a MOS for triggering the LSCR. A dummy gate and a doped region are used to isolate the MOS from one of these two electrodes. The dummy gate is designed to block the formation of field-oxide layer formed in the device structure of the lateral SCR. Therefore, the proposed SCR device has a shorter current path in CMOS process, especially in the CMOS process with shallow trench isolation (STI) field-oxide layer. During an ESD, the current path in the ESD protection device is much shorter, and the turn-on speed and the ESD tolerance level are thereby enhanced.

Abstract: The present invention proposes an ESD protection circuit and its related circuits, suitable in an integrated circuit (IC), and coupled between a first pad and a second pad. When a power supply is provided to the IC, a bias generator generates a bias voltage to close the protection component. When the power supply is not provided to the IC, the protection component is always on to release the ESD stress between the first pad and the second pad.

Abstract: A low junction capacitance semiconductor structure and an I/O buffer are disclosed. The semiconductor structure includes a MOS transistor and a lightly doped region. The MOS transistor is formed in a semiconductor substrate and has a gate and source and drain region formed aside the gate. The lightly doped region has a conductivity the same as the source and drain regions, and is formed in the drain region and has a depth larger than the source and drain regions. Further, the lightly doped region can be achieved by CMOS-compatible processes, and the formed devices in the well can be isolated from the semiconductor substrate using deeply doped regions which are usually adopted in advanced technologies.