Patent application number | Description | Published |
20110194045 | ELECTRO-OPTIC DISPLAYS, AND COMPONENTS FOR USE THEREIN - An electro-optic display comprises a substrate ( | 08-11-2011 |
20130161663 | ELECTRO-OPTIC DISPLAYS, AND COMPONENTS FOR USE THEREIN - An electro-optic display comprises a substrate ( | 06-27-2013 |
20130277687 | HIGH VOLTAGE FIELD EFFECT TRANSITOR FINGER TERMINATIONS - A field effect transistor having at least one structure configured to redistribute and/or reduce an electric field from gate finger ends is disclosed. Embodiments of the field effect transistor include a substrate, an active region disposed on the substrate, at least one source finger in contact with the active region, at least one drain finger in contact with the active region, and at least one gate finger in rectifying contact with the active region. One embodiment has at least one end of the at least one gate finger extending outside of the active region. Another embodiment includes at least one source field plate integral with the at least one source finger. The at least one source field plate extends over the at least one gate finger that includes a portion outside of the active region. Either embodiment can also include a sloped gate foot to further improve high voltage operation. | 10-24-2013 |
20130280877 | METHODS FOR FABRICATING HIGH VOLTAGE FIELD EFFECT TRANSITOR FINGER TERMINATIONS - Methods for fabricating a field effect transistor having at least one structure configured to redistribute and/or reduce an electric field from gate finger ends are disclosed. The methods provide field effect transistors that each include a substrate, an active region disposed on the substrate, at least one source finger in contact with the active region, at least one drain finger in contact with the active region, and at least one gate finger in rectifying contact with the active region. One embodiment has at least one end of the at least one gate finger extending outside of the active region. At least one method includes etching at least one gate channel into the passivation layer with a predetermined slope that reduces electric fields at a gate edge. Other methods include steps for fabricating a sloped gate foot, a round end, and/or a chamfered end to further improve high voltage operation. | 10-24-2013 |
20140054585 | LATERAL SEMICONDUCTOR DEVICE WITH VERTICAL BREAKDOWN REGION - A lateral semiconductor device having a vertical region for providing a protective avalanche breakdown (PAB) is disclosed. The lateral semiconductor device has a lateral structure that includes a conductive substrate, semi-insulating layer(s) disposed on the conductive substrate, device layer(s) disposed on the semi-insulating layer(s), along with a source electrode and a drain electrode disposed on the device layer(s). The vertical region is separated from the source electrode by a lateral region wherein the vertical region has a relatively lower breakdown voltage level than a relatively higher breakdown voltage level of the lateral region for providing the PAB within the vertical region to prevent a potentially damaging breakdown of the lateral region. The vertical region is structured to be more rugged than the lateral region and thus will not be damaged by a PAB event. | 02-27-2014 |
20140054596 | SEMICONDUCTOR DEVICE WITH ELECTRICAL OVERSTRESS (EOS) PROTECTION - A semiconductor device with electrical overstress (EOS) protection is disclosed. The semiconductor device includes a semi-insulating layer, a first contact disposed onto the semi-insulating layer, and a second contact disposed onto the semi-insulating layer. A passivation layer is disposed onto the semi-insulating layer. The passivation layer has a dielectric strength that is greater than that of the semi-insulating layer to ensure that a voltage breakdown occurs within the semi-insulating layer within a semi-insulating region between the first contact and the second contact before a voltage breakdown can occur in the passivation layer. | 02-27-2014 |
20140054597 | POWER DEVICE AND PACKAGING THEREOF - The present disclosure provides a power device and power device packaging. Generally, the power device of the present disclosure includes a die backside and a die frontside. A semi-insulating substrate with epitaxial layers disposed thereon is sandwiched between the die backside and the die frontside. Pads on the die frontside are coupled to the die backside with patterned backmetals that are disposed within vias that pass through the semi-insulating substrate and epitaxial layers from the die backside to the die frontside. | 02-27-2014 |
20140054601 | GALLIUM NITRIDE (GAN) DEVICE WITH LEAKAGE CURRENT-BASED OVER-VOLTAGE PROTECTION - A gallium nitride (GaN) device with leakage current-based over-voltage protection is disclosed. The GaN device includes a drain and a source disposed on a semiconductor substrate. The GaN device also includes a first channel region within the semiconductor substrate and between the drain and the source. The GaN device further includes a second channel region within the semiconductor substrate and between the drain and the source. The second channel region has an enhanced drain induced barrier lowering (DIBL) that is greater than the DIBL of the first channel region. As a result, a drain voltage will be safely clamped below a destructive breakdown voltage once a substantial drain current begins to flow through the second channel region. | 02-27-2014 |
20140054604 | SEMICONDUCTOR DEVICE HAVING IMPROVED HEAT DISSIPATION - A semiconductor device having improved heat dissipation is disclosed. The semiconductor device includes a semi-insulating substrate and epitaxial layers disposed on the semi-insulating substrate wherein the epitaxial layers include a plurality of heat conductive vias that are disposed through the epitaxial layers with the plurality of heat conductive vias being spaced along a plurality of finger axes that are aligned generally parallel across a surface of the epitaxial layers. The semiconductor device further includes an electrode having a plurality of electrically conductive fingers that are disposed along the plurality of finger axes such that the electrically conductive fingers are in contact with the first plurality of heat conductive vias. | 02-27-2014 |
20140055192 | SATURATION CURRENT LIMITING CIRCUIT TOPOLOGY FOR POWER TRANSISTORS - A circuit topology for limiting saturation current in power transistors is disclosed. The circuit topology includes a normally-on transistor and a normally-off transistor coupled in series. A limiter circuit is coupled between a gate of the normally-on transistor and a source of the normally-off transistor for limiting the steady-state maximum gate-to-source voltage V | 02-27-2014 |
20140057372 | METHOD FOR ON-WAFER HIGH VOLTAGE TESTING OF SEMICONDUCTOR DEVICES - A method for wafer high voltage testing of semiconductor devices is disclosed. The method involves adding a patterning layer onto a passivation layer of the semiconductor devices and then etching vias through the passivation layer to expose conductive test points. Testing of the semiconductor devices begins with engaging the conductive test points with high voltage test probes of a testing apparatus and then applying a high voltage test sequence to the conductive test points via the high voltage test probes. The testing of the semiconductor devices concludes by disengaging the high voltage test probes from a last one of the semiconductor devices and then removing the patterning layer from the passivation layer of the semiconductor devices. | 02-27-2014 |
20150295053 | HIGH VOLTAGE FIELD EFFECT TRANSITOR FINGER TERMINATIONS - A field effect transistor having at least one structure configured to redistribute and/or reduce an electric field from gate finger ends is disclosed. Embodiments of the field effect transistor include a substrate, an active region disposed on the substrate, at least one source finger in contact with the active region, at least one drain finger in contact with the active region, and at least one gate finger in rectifying contact with the active region. One embodiment has at least one end of the at least one gate finger extending outside of the active region. Another embodiment includes at least one source field plate integral with the at least one source finger. The at least one source field plate extends over the at least one gate finger that includes a portion outside of the active region. Either embodiment can also include a sloped gate foot to further improve high voltage operation. | 10-15-2015 |
Patent application number | Description | Published |
20090029527 | PROCESSES FOR FORMING BACKPLANES FOR ELECTRO-OPTIC DISPLAYS - A non-linear element is formed on a flexible substrate by securing the substrate to a rigid carrier, forming the non-linear element, and then separating the flexible substrate from the carrier. The process allows flexible substrates to be processed in a conventional fab intended to process rigid substrates. In a second method, a transistor is formed on a insulating substrate by forming gate electrodes, depositing a dielectric layer, a semiconductor layer and a conductive layer, patterning the conductive layer to form source, drain and pixel electrodes, covering the channel region of the resultant transistor with an etch-resistant material and etching using the etch-resistant material and the conductive layer as a mask, the etching extending substantially through the semiconductor layer between adjacent transistors. The invention also provides a process for forming a diode on a substrate by depositing on the substrate a first conductive layer, and a second patterned conductive layer and a patterned dielectric layer over parts of the first conductive layer, and etching the first conductive layer using the second conductive layer and dielectric layer as an etch mask. Finally, the invention provides a process for driving an impulse-sensitive electro-optic display. | 01-29-2009 |
20090315044 | ELECTRO-OPTIC DISPLAYS, AND COMPONENTS FOR USE THEREIN - An electro-optic display comprises a substrate ( | 12-24-2009 |
20100265239 | PROCESSES FOR FORMING BACKPLANES FOR ELECTRO-OPTIC DISPLAYS - A non-linear element is formed on a flexible substrate by securing the substrate to a rigid carrier, forming the non-linear element, and then separating the flexible substrate from the carrier. The process allows flexible substrates to be processed in a conventional fab intended to process rigid substrates. In a second method, a transistor is formed on a insulating substrate by forming gate electrodes, depositing a dielectric layer, a semiconductor layer and a conductive layer, patterning the conductive layer to form source, drain and pixel electrodes, covering the channel region of the resultant transistor with an etch-resistant material and etching using the etch-resistant material and the conductive layer as a mask, the etching extending substantially through the semiconductor layer between adjacent transistors. The invention also provides a process for forming a diode on a substrate by depositing on the substrate a first conductive layer, and a second patterned conductive layer and a patterned dielectric layer over parts of the first conductive layer, and etching the first conductive layer using the second conductive layer and dielectric layer as an etch mask. Finally, the invention provides a process for driving an impulse-sensitive electro-optic display. | 10-21-2010 |