Abstract: When a high-voltage, such as from an ESD pulse, is placed across a silicon controlled rectifier, which includes an NPN transistor and a PNP transistor that is connected to the NPN transistor, the likelihood of punch through occurring between two regions of the rectifier is substantially reduced by forming the collector of the NPN transistor between the emitter and collector of the PNP transistor.

Abstract: A three-terminal snapback device is utilized with a control circuit to provide a low snapback voltage that is protected from non-ESD voltage spikes and ripples. In response to a fast edge, the control circuit lowers the snapback voltage, unless a status signal indicates that normal operating voltages are present, and raises the snapback voltage a predefined time later. If the fast edge represents an ESD pulse, SCR operation is initiated at the lowered snapback voltage. If the fast edge represents a power on sequence, the maximum voltage is less than the momentarily lowered snapback voltage and therefore insufficient to initiate SCR operation. Further, once normal operating voltages are present, the control circuit continuously maintains the raised snapback voltage so that a non-ESD voltage spike or ripple can not improperly turn on the snapback device.

Abstract: In a fuse-based programmable circuit block, the poly-fuse is burned out by making use of a snapback device connected in series with the poly-fuse.

Abstract: An electrical shield is provided in a non-volatile memory (NVM) cell structure to protect the cell's floating gate from any influence resulting from charge redistribution in the vicinity of the floating gate during a programming operation. The shield may be created from the second polysilicon layer or other conductive material covering the floating gate. The shield may be grounded. Alternately, it may be connected to the cell's control gate electrode resulting in better coupling between the floating gate and the control gate. It is not necessary that the shield cover the floating gate completely, the necessary protective effect is achieved if the coupling to the dielectric layers surrounding the floating gate is reduced.

Abstract: Feedback between the floating gate voltage and a high erase voltage is utilized in the erase operation of a non-volatile memory (NVM) cell. Erasing stops when the floating gate voltage reaches the threshold voltage of the controlling transistor, making the variability of the NVM cell's threshold voltage the same as a regular device in the integrated circuit structure, thereby reducing the significant threshold voltage variability in erased NVM cells.

Abstract: In some embodiments, a chip with a metal heat flow path extending between a terminal of a transistor thereof and bulk semiconductor material of the chip (e.g., from the terminal to a substrate over which the transistor is formed or to the body of a semiconductor device adjacent to the transistor) and methods for manufacturing such a chip. The chip can be implemented by a semiconductor on insulator (SOI) process and can include at least one bipolar or MOS transistor, an insulator underlying the transistor, a semiconductor substrate underlying the insulator, and a metal heat flow path extending between a terminal of the transistor through the insulator to the substrate. Preferably, the metal heat flow path is a metal interconnect formed by a process step (or steps) of the same type performed to produce other metal interconnects of the chip.

Abstract: A snapback ESD protection network coupled across first and second integrated circuit pads and including first and second snapback devices, such as SCR devices, with the second device having a turnoff current ITOFF which is greater than the turnoff current of the first device. Each of the snapback devices has an anode terminal and a cathode terminal, with the first device anode and cathode terminals being coupled to the respective first and second integrated circuit pads through a first effective series resistance and the second device being coupled to the respective first and second integrated circuit pads through a second effective series resistance, with the first effective series resistance being smaller than the second so as to cause the first and second snapback devices to tend to turn on at about the same time at the beginning of an ESD event. The differences in turnoff current cause the second snapback device to turn off prior to the first snapback device at the conclusion of an ESD event.

Abstract: In an EEPROM array the cells are pre-charged or pre-erased so that they will respond uniformly to the same read voltage level. By clearly defining the threshold voltage for the cells in their erased states and in their programmed states, it is possible to define more than one read voltage and thus provide cells that an store multiple values and even analog values.

Abstract: In a low voltage ESD protection device, an extra control electrode is created by not connecting the n+ drain and p+ emitter regions of the LVTSCR, and controlling the control electrode by means of a diode connected NMOS.

Abstract: In an NMOS device, the turn-on voltage or the triggering voltage is reduced by adding an NBL connected to an n-sinker and contacted through an n+ region, which is connected to a bias voltage. The bias voltage may be provided by the drain contact or by a separate bias voltage.

Abstract: A vertical MOS transistor has a source region, a channel region, and a drain region that are vertically stacked, and a trench that extends from the top surface of the drain region through the drain region, the channel region, and partially into the source region. The vertical MOS transistor also has an insulation layer that lines the trench, and a conductive gate region that contacts the insulation layer to fill up the trench.

Abstract: When a high-voltage, such as from an ESD pulse, is placed across a silicon controlled rectifier, which includes an NPN transistor and a PNP transistor that is connected to the NPN transistor, the likelihood of punch through occurring between two regions of the rectifier is substantially reduced by forming the emitter of one transistor adjacent to the tails of the sinker down region of the other transistor.

Abstract: A ballasting region is placed between the base region and the collector contact of a bipolar junction transistor to relocate a hot spot away from the collector contact of the transistor. Relocating the hot spot away from the collector contact prevents the collector contact from melting during an electrostatic discharge (ESD) pulse.

Abstract: The snapback characteristics of the parasitic NPN structure inside an NMOS device are used to write and store information in the device by periodically triggering the device from the high impedance state to the low impedance state using the self turn-on characteristics of the device under elevated voltage. To minimize power consumption, and thus overheating, in the “on” state, a pulsed mode operation is combined with dV/dt triggering powering the device at a constant Vdd pulse amplitude.

Abstract: A transistor array is self-protected from an electrostatic discharge (ESD) event which can cause localized ESD damage by integrating an ESD protection device into the transistor array. The ESD protection device operates as a transistor during normal operating conditions, and provides a low-resistance current path during an ESD event.

Abstract: The integration period of an imaging cell, or the time that an imaging cell is exposed to light energy, is substantially increased by utilizing a single-poly, electrically-programmable, read-only-memory (EPROM) structure to capture the light energy. Photogenerated electrons are formed in the channel region of the EPROM structure from the light energy. The photogenerated electrons are then accelerated into having ionizing collisions which, in turn, leads to electrons being injected onto the floating gate of the EPROM structure at a rate that is proportionate to the number of photons captured by the channel region.

Abstract: An integrated circuit is powered by exposing conductive regions, such as the p+ source regions of the PMOS transistors that are formed to receive a supply voltage, to light energy from a light source. The conductive regions function as photodiodes that produce voltages on the conductive regions via the photovoltaic effect.

Abstract: A MOSFET transistor structure is formed in a substrate of semiconductor material having a first conductivity type. The MOSFET transistor structure includes an active region that is surrounded by a perimeter isolation dielectric material formed in the substrate to define a continuous sidewall interface between the sidewall dielectric material and the active region. Spaced-apart source and drain regions are formed in the active region and are also spaced-apart from the sidewall interface. A conductive gate electrode that is separated from the substrate channel region by intervening gate dielectric material includes a first portion that extends over the substrate channel region and a second portion that extends continuously over the entire sidewall interface between the isolation dielectric material and the active region.

Abstract: In a high voltage ESD protection solution, a plurality of DIACs are connected together to define a cascaded structure with isolation regions provided to prevent n-well and p-well punch through. An p-ring surrounds the DIACs and provides a ground for the substrate in which the DIACs are formed.

Abstract: An implant is added at the interface between the source region of an MOS transistor and the well material to improve dynamic IR drop performance. The additional implant raises the underlying capacitance of the source region. This, in turn, provides for an increase in charge storage which, in turn, provides for an improved level of protection against dynamic IR drop.