Abstract: A vertical transistor structure in which a recessed field plate trench surrounds multiple adjacent gate electrodes. Thus the specific on-state conductance is increased, since the ratio of recessed field plate area to channel area is reduced. Various versions use two, three, or more distinct gate electrodes within the interior of a single RFP or RSFP trench's layout.

Abstract: Over a flexible substrate are deposited stacked pixel layers including a bottom layer of LEDs forming blue pixels, a middle layer of LEDs forming green pixels, and a top layer of LEDs forming red pixels. Each LED die comprises an LED portion and an integrated transistor portion. Applying a voltage to a control terminal of the transistor portion energizes the LED portion. The pixels are substantially transparent, due to the LEDs being microscopic and the pixel areas being much larger, to allow light from the underlying layers to pass through. The three layers of pixels are aligned so that a combination of a single top red pixel, a single underlying green pixel, and a single underlying blue pixel form a single multi-color pixel. The different layers have transparent column and row lines.

Abstract: A design technique is disclosed that divides up a cellular power switch into different size segments. Each segment is driven by a different driver circuit. The selection of the combination of segments is made to minimize the combined conduction and switching losses of the power switch. For example, for very light loads, switching losses dominate so only a small segment is activated for driving the load. For medium and high load currents, conduction losses become more significant, so additional segments are activated to minimize the total losses. In one embodiment, the number of cells in the segments is binary weighted, such as 1×, 2×, and 4×, so that there are seven different combinations of segments. The drivers may be configured to achieve the same or different slew rates of the segments, such as to reduce transients. The segments may all be in the same die or a plurality of dies.

Abstract: Trenches having a gate oxide layer are formed in the surface of a silicon wafer for vertical gates. Conductive doped polysilicon is then deposited in the trenches to form a relatively thin layer of doped polysilicon along the sidewalls. Thus, there is a central cavity surrounded by polysilicon. Next, the cavity is filled in with a much higher conductivity material, such as aluminum, copper, a metal silicide, or other conductor to greatly reduce the overall resistivity of the trenched gates. The thin polysilicon forms an excellent barrier to protect the gate oxide from diffusion from the inner conductor atoms. The inner conductor and the polysilicon conduct the gate voltage in parallel to lower the resistance of the gates, which increases the switching speed of the device. In another embodiment, a metal silicide is used as the first layer, and a metal fills the cavity.

Abstract: A power device is divided into an active area, an active area perimeter, and a termination region. An array of insulated gates formed in trenches form cells in a p-well body, where n+ source regions are formed in the top surface of the silicon wafer and surround the tops of the trenches. A top cathode electrode contacts the source regions, and an anode electrode is on the bottom of the die. A sufficiently high reverse voltage causes a breakdown current to flow between the anode and cathode electrodes. To ensure that a reverse breakdown voltage current occurs away from the gate oxide and/or the termination region, the active area and the active area perimeter of the p-well are additionally doped with p-type dopants to form deep p+ regions in selected areas that extend below the trenches. The deep p+ regions channel the breakdown current away from active cells and the termination region.

Abstract: In an insulated trench gate device, polysilicon in the trench is etched below the top surface of the trench, leaving a thin gate oxide layer exposed near the top of the trench. An angled implant is conducted that implants dopants through the exposed gate oxide and into the side of the trench. If the implanted dopants are n-type, this technique may be used to extend an n+ source region to be below the top of the polysilicon in the trench. If the implanted dopants are p-type, the dopants may be used to form a p-MOS device that turns on when the polysilicon is biased with a negative voltage. P-MOS and n-MOS devices can be formed in a single cell using this technique, where turning on the n-MOS device turns on a vertical power switch, and turning on the p-MOS device turns off the power switch.

Abstract: Over a flexible substrate are deposited stacked pixel layers including a bottom layer of LEDs forming blue pixels, a middle layer of LEDs forming green pixels, and a top layer of LEDs forming red pixels. Each LED die comprises an LED portion and an integrated transistor portion. Applying a voltage to a control terminal of the transistor portion energizes the LED portion. The pixels are substantially transparent, due to the LEDs being microscopic and the pixel areas being much larger, to allow light from the underlying layers to pass through. The three layers of pixels are aligned so that a combination of a single top red pixel, a single underlying green pixel, and a single underlying blue pixel form a single multi-color pixel. The different layers have transparent column and row lines.

Abstract: A high power vertical insulated-gate switch is described that includes a parallel cell array having inner cells and an edge cell. The cells have a vertical npnp structure with a trenched field effect device that turns the device on and off. The edge cell is prone to breaking down at high currents. Techniques used to cause the current in the edge cell to be lower than the current in the inner cells, to improve robustness, include: forming a top n-type source region to not extend completely across opposing trenches in areas of the edge cell; forming the edge cell to have a threshold voltage of its field effect device that is greater than the threshold voltage of the field effect devices in the inner cells; and providing a resistive layer between the edge cell and a top cathode electrode electrically contacting the inner cells and the edge cell.

Abstract: The present application teaches, among other innovations, power semiconductor devices in which breakdown initiation regions, on BOTH sides of a die, are located inside the emitter/collector regions, but laterally spaced away from insulated trenches which surround the emitter/collector regions. Preferably this is part of a symmetrically-bidirectional power device of the “B-TRAN” type. In one advantageous group of embodiments (but not all), the breakdown initiation regions are defined by dopant introduction through the bottom of trench portions which lie within the emitter/collector region. In one group of embodiments (but not all), these can advantageously be separated trench portions which are not continuous with the trench(es) surrounding the emitter/collector region(s).

Abstract: A lateral insulated gate turn-off device includes an n-drift layer, a p-well formed in the n? drift layer, a shallow n+ type region formed in the well, a shallow p+ type region formed in the well, a cathode electrode shorting the n+ type region to the p+ type region, a trenched first gate extending through the n+ type region and into the well, a p+ type anode region laterally spaced from the well, an anode electrode electrically contacting the p+ type anode region, and a trenched second gate extending from the p+ type anode region into the n-drift layer. For turning the device on, a positive voltage is applied to the first gate the reduce the base width of the npn transistor, and a negative voltage is applied to the second gate to effectively extend the p+ emitter of the pnp transistor further into the n-drift layer to improve performance.

Abstract: An insulated gate turn-off (IGTO) device, formed as a die, has a layered structure including a p+ layer (e.g., a substrate), an n? drift layer, a p-well, trenched insulated gates formed in the p-well, and n+ regions between at least some of the gates, so that vertical npn and pnp transistors are formed. A cathode electrode is on top, and an anode electrode is on the bottom of the substrate. The device is formed of a matrix of cells. To turn the device on, a positive voltage is applied to the gates, referenced to the cathode electrode. To direct high energy electrons away from a gate oxide layer on the sidewalls of the trenches, boron is implanted between the trenches so p+ regions are formed in the mesas of the less-doped p-well. The p+ regions break down during an over-voltage event before the p-well breaks down in the mesas.

Abstract: The present application teaches, among other innovations, power semiconductor devices in which breakdown initiation regions, on BOTH sides of a die, are located inside the emitter/collector regions, but laterally spaced away from insulated trenches which surround the emitter/collector regions. Preferably this is part of a symmetrically-bidirectional power device of the “B-TRAN” type. In one advantageous group of embodiments (but not all), the breakdown initiation regions are defined by dopant introduction through the bottom of trench portions which lie within the emitter/collector region. In one group of embodiments (but not all), these can advantageously be separated trench portions which are not continuous with the trench(es) surrounding the emitter/collector region(s).

Abstract: On a flexible substrate is printed LEDs and a driver circuit containing transistors. The LEDs and transistors are printed microscopic devices contained in an ink. The LEDs are printed in groups and connected in parallel, and the transistors are printed in groups and connected in parallel. Other components, such as resistors and an on/off switch, are also printed to form the driver. A battery and other circuit components may also be printed on the substrate. An overlay is provided over the LEDs to create a desired light pattern. The LEDs and driver may be generic, and the overlay customizes the light pattern for a particular application. The transistors in the driver may be interconnected with a trace pattern to drive the LEDs in a customized manner, such as for an insert in a product package for marketing to a consumer.

Abstract: Methods and systems for power semiconductor devices integrating multiple quasi-vertical transistors on a single chip. Multiple power transistors (or active regions) are paralleled, but one transistor has a lower threshold voltage. This reduces the voltage drop when the transistor is forward-biased. In an alternative embodiment, the power device with lower threshold voltage is simply connected as a depletion diode, to thereby shunt the body diodes of the active transistors, without affecting turn-on and ON-state behavior.

Abstract: On a flexible substrate is printed LEDs and a driver circuit containing transistors. The LEDs and transistors are printed microscopic devices contained in an ink. The LEDs are printed in groups and connected in parallel, and the transistors are printed in groups and connected in parallel. Other components, such as resistors and an on/off switch, are also printed to form the driver. A battery and other circuit components may also be printed on the substrate. An overlay is provided over the LEDs to create a desired light pattern. The LEDs and driver may be generic, and the overlay customizes the light pattern for a particular application. The transistors in the driver may be interconnected with a trace pattern to drive the LEDs in a customized manner, such as for an insert in a product package for marketing to a consumer.

Abstract: A vertical transistor structure in which a recessed field plate trench surrounds multiple adjacent gate electrodes. Thus the specific on-state conductance is increased, since the ratio of recessed field plate area to channel area is reduced. Various versions use two, three, or more distinct gate electrodes within the interior of a single RFP or RSFP trench's layout.

Abstract: Over a flexible substrate are deposited stacked pixel layers including a bottom layer of LEDs forming blue pixels, a middle layer of LEDs forming green pixels, and a top layer of LEDs forming red pixels. Each LED die comprises an LED portion and an integrated transistor portion. Applying a voltage to a control terminal of the transistor portion energizes the LED portion. The pixels are substantially transparent, due to the LEDs being microscopic and the pixel areas being much larger, to allow light from the underlying layers to pass through. The three layers of pixels are aligned so that a combination of a single top red pixel, a single underlying green pixel, and a single underlying blue pixel form a single multi-color pixel. The different layers have transparent column and row lines.

Abstract: An insulated gate turn-off (IGTO) device, formed as a die, has a layered structure including a p+ layer (e.g., a substrate), an n? epi layer, a p-well, trenched insulated gate regions formed in the p-well, and n+ regions between the gate regions, so that vertical NPN and PNP transistors are formed. The device may be formed of a matrix of cells or may be interdigitated. To turn the device on, a positive voltage is applied to the gate, referenced to the cathode. The cells further contain a vertical p-channel MOSFET, for rapidly turning the device off. The p-channel MOSFET may be made a depletion mode device by implanting boron ions at an angle into the trenches to create a p-channel. This allows the IGTO device to be turned off with a zero gate voltage while in a latch-up condition, when the device is acting like a thyristor.

Abstract: Over a flexible substrate are deposited stacked pixel layers including a bottom layer of LEDs forming blue pixels, a middle layer of LEDs forming green pixels, and a top layer of LEDs forming red pixels. Each LED die comprises an LED portion and an integrated transistor portion. Applying a voltage to a control terminal of the transistor portion energizes the LED portion. The pixels are substantially transparent, due to the LEDs being microscopic and the pixel areas being much larger, to allow light from the underlying layers to pass through. The three layers of pixels are aligned so that a combination of a single top red pixel, a single underlying green pixel, and a single underlying blue pixel form a single multi-color pixel. The different layers have transparent column and row lines.

Abstract: Dual-base two-sided bipolar power transistors which use an insulated field plate to separate the emitter/collector diffusions from the nearest base contact diffusion. This provides a surprising improvement in turn-off performance, and in breakdown voltage.