Abstract: An implantation method to improve ESD robustness of thick-oxide grounded-gate NMOSFET's in deep-submicron CMOS technologies. Based on standard process flow in DGO, a thick gate-oxide ESD device is improved. Instead of using the standard I/O device, the ESD device uses the thin-oxide N-LDD implantation, and thus its ESD robustness is enhanced. This is performed by updating the logic Boolean operations of thick gate-oxide and thin gate-oxide N-LDD before fabricating the masks. In TGO, the intermediate-oxide ESD uses thin-oxide N-LDD implantation, and the thick-oxide ESD uses intermediate-oxide N-LDD implantation.

Abstract: Design and optimization of NMOS drivers using a self-ballasting ESD protection technique in a fully silicided CMOS process. Silicided NMOS fingers which include segmented drain diffusion. Specifically, the segmented drain diffusion provides self-ballasting resistors which improves the ESD performance. Preferably, the width of the each diffusion resistor is relatively small, as this can improve a non-uniform silicidation process. The resistance of the segmented diffusion resistors is determined by their width and length, and effectively increases the ballasting effect of parasitic n-p-n bipolar transistors.

Abstract: A technique to enhancing substrate bias of grounded-gate NMOS fingers (ggNMOSFET's) has been developed. By using this technique, lower triggering voltage of NMOS fingers can be achieved without degrading ESD protection in negative zapping. By introducing a simple gate-coupled effect and a PMOSFET triggering source with this technique, low-voltage triggered NMOS fingers have also been developed in power and I/O ESD protection, respectively. A semiconductor device which includes a P-well which is underneath NMOS fingers. The device includes an N-well ring which is configured so that the inner P-well underneath the NMOS fingers is separated from an outer P-well. The inner P-well and outer P-well are connected by a P-substrate resistance which is much higher than the resistance of the P-wells. A P+-diffusion ring surrounding the N-well ring is configured to connect to VSS, i.e., P-taps.

Abstract: A semiconductor device which includes a P-well which is underneath NMOS fingers. The device includes an N-well ring which is configured so that the inner P-well underneath the NMOS fingers is separated from an outer P-well. The inner P-well and outer P-well are connected by a P-substrate resistance which is much higher than the resistance of the P-wells. A P+-diffusion ring surrounding the N-well ring is configured to connect to VSS, i.e., P-taps.

Abstract: A semiconductor device which includes a P-well which is underneath NMOS fingers. The device includes an N-well ring which is configured so that the inner P-well underneath the NMOS fingers is separated from an outer P-well. The inner P-well and outer P-well are connected by a P-substrate resistance which is much higher than the resistance of the P-wells. A P+-diffusion ring surrounding the N-well ring is configured to connect to VSS, i.e., P-taps.

Abstract: Fabricated using a complementary metal oxide semiconductor process including the use of salicides, an input and power protection circuit for use in an integrated circuit protects voltage and signal terminals from both overvoltage and ESD pulses. A diode connected is connected between a first terminal and an inter-transistor node, a field effect transistor is connected between the inter-transistor node and a second terminal, and a lateral bipolar transistor, with a base connected to the inter-transistor node, is connected between the first and the second terminals. When an ESD pulse appears on the first terminal, the voltage at the inter-transistor node increases until a snapback trigger voltage of the field effect transistor is reached whereupon current flows from the first terminal, through the emitter-base junction of the lateral bipolar transistor, through the inter-transistor node, through the field effect transistor, and to the second terminal.