Abstract: A radio frequency (RF) device is described. The RF device includes a switch field effect transistor (FET), having a source region, a drain region, a body region, and a gate region. The RF device also includes a dynamic bias control circuit. The dynamic bias control circuit includes a first transistor coupled to the gate region of the switch FET by a gate resistor. The dynamic bias control circuit also includes a second transistor coupled to the first transistor and coupled to the body region of the switch FET by a body resistor. The dynamic bias control circuit further includes a capacitor coupled to the body region of the switch FET by the body resistor, and the gate region of the switch FET, by the gate resistor.

Abstract: A radio frequency integrated circuit (RFIC) is described. The RFIC includes a switch field effect transistor (FET). The switch FET includes a source region, a drain region, a body region, and a gate region. The RFIC also includes a dynamic bias control circuit. The dynamic bias control circuit includes at least one transistor coupled between the body region and the gate region of the switch FET.

Abstract: Disclosed is a transistor of a device that has an asymmetric resistance or an asymmetric capacitive coupling or both. When used in a cascode configuration in an amplifier, low current performance of the amplifier is improved. Asymmetric resistance may be enabled through differentially doping source and drain structures of the transistor and/or through differentially manipulating geometries the source and drain structures. Asymmetric capacitive coupling may be enabled through providing dielectrics and differentially locating the dielectrics above a gate of the transistor. Further, a body of the transistor may be biased.

Abstract: A radio frequency (RF) switch includes switch transistors coupled in series. The RF switch includes a distributed gate bias network coupled to gate electrodes of the switch transistors. The RF switch also includes a distributed body bias network coupled to body electrodes of the switch transistors.

Abstract: A dual-sided MOS IC includes an isolation layer and a MOS transistor. The isolation layer separates the MOS IC into a MOS IC frontside and a MOS IC backside. The MOS transistor is on both the MOS IC frontside and the MOS IC backside. The MOS transistor includes MOS gates, a first source connection in a first subsection of the MOS IC frontside, and a second source connection in a second subsection of the MOS IC backside. The first and second source connections are electrically coupled together through a first front-to-backside connection extending through the isolation layer. The MOS transistor further includes a first drain connection in the first subsection of the MOS IC backside, and a second drain connection in the second subsection of the MOS IC frontside. The first and second drain connections are electrically coupled together through a second front-to-backside connection extending through the isolation layer.

Abstract: A radio frequency integrated circuit (RFIC) is described. The RFIC includes a field effect transistor (FET). The FET has a ferroelectric gate stack having a source region, a drain region, a body region, and a gate. The RFIC also includes a first resistor coupled between a first bias supply and the body region. The RFIC further includes a second resistor coupled between the gate and a second bias supply.

Abstract: An optically powered switch. An example optically powered switch generally includes a light source configured to output an optical signal. The example optically powered switch generally includes a photodiode configured to convert the optical signal to an electrical signal. The example optically powered switch generally includes a bias and control circuit configured to power at least one radio frequency (RF) switch using the electrical signal.

Abstract: A radio frequency (RF) switch includes switch transistors coupled in series. The RF switch includes a distributed gate bias network coupled to gate electrodes of the switch transistors. The RF switch also includes a distributed body bias network coupled to body electrodes of the switch transistors.

Abstract: Utilizing crystal orientation channeling through the semiconductor lattice structure of a silicon-on-insulator (SOI) wafer to create a thermally stable implanted amorphous layer beneath a buried oxide (BOX) layer in the SOI wafer is described. Utilizing channeling in this manner may involve tilting and/or twisting the SOI wafer to align axes of the crystal orientation channels with projections vectors from an implanter. One example method of fabricating a semiconductor device generally includes orienting an SOI substrate, the SOI substrate having a BOX layer and a device layer disposed above the BOX layer, such that directions of projection vectors from an implanter are substantially aligned with longitudinal axes of crystal orientation channels in a lattice structure of a semiconductor material of the device layer; and projecting, with the implanter, ions or particles into the crystal orientation channels of the oriented SOI substrate to create an implanted layer below the BOX layer.

Abstract: An integrated circuit (IC) is described. The IC includes a substrate and a plurality of back-end-of-line (BEOL) layers on the substrate. The IC also includes a trench having tapered sidewalls and a base in a BEOL layer of the plurality of BEOL layers on the substrate. The IC further includes a metal-insulator-metal (MIM) capacitor on the tapered sidewalls and the base of the trench in the BEOL layer. The MIM capacitor includes a first conductive layer to line the tapered sidewalls and the base of the trench. The MIM capacitor also includes a dielectric layer to line the first conductive layer on the tapered sidewalls and the base of the trench. The MIM capacitor further includes a second conductive layer on the dielectric layer and filling the trench in the BEOL layer.

Abstract: A method of constructing an integrated circuit (IC) includes fabricating a metal oxide semiconductor field effect transistor (MOSFET) on a first surface of an insulator layer of the integrated circuit. The insulator layer is supported by a sacrificial substrate. The MOSFET includes an extended drain region. The method deposits a front-side dielectric layer on the MOSFET, bonds a handle substrate to the front-side dielectric layer, and then removes the sacrificial substrate. The method also fabricates multiple back gates on a second surface of the insulator layer. The second surface is opposite the first surface.

Abstract: A dual sided contact switch has a first independent drain/source region of a multi-gate active device. The dual sided contact switch also has a first shared drain/source region of the multi-gate active device. The dual sided contact switch has a second independent drain/source region of the multi-gate active device, adjacent to the first shared drain/source region. The dual sided contact switch also has a second shared drain/source region of the multi-gate active device, adjacent to the first independent drain/source region. The dual sided contact switch has a gate region between the first independent drain/source region and the first shared drain/source region, and also between the second independent drain/source region and the second shared drain/source region.

Abstract: A dual sided contact switch has a first independent drain/source region of a multi-gate active device. The dual sided contact switch also has a first shared drain/source region of the multi-gate active device. The dual sided contact switch has a second independent drain/source region of the multi-gate active device, adjacent to the first shared drain/source region. The dual sided contact switch also has a second shared drain/source region of the multi-gate active device, adjacent to the first independent drain/source region. The dual sided contact switch has a gate region between the first independent drain/source region and the first shared drain/source region, and also between the second independent drain/source region and the second shared drain/source region.

Abstract: A method of constructing an integrated circuit (IC) includes fabricating a metal oxide semiconductor field effect transistor (MOSFET) on a first surface of an insulator layer of the integrated circuit. The insulator layer is supported by a sacrificial substrate. The MOSFET includes an extended drain region. The method deposits a front-side dielectric layer on the MOSFET, bonds a handle substrate to the front-side dielectric layer, and then removes the sacrificial substrate. The method also fabricates multiple back gates on a second surface of the insulator layer. The second surface is opposite the first surface.

Abstract: A radio frequency integrated circuit (RFIC) includes multi-finger transistors including discrete diffusion regions and interconnected within a reconfigured form factor as a single switch transistor. The RFIC also includes a source bus having a first plurality of source fingers coupled to each source region of the multi-finger transistors and a second plurality of source fingers orthogonally coupled to the first plurality of source fingers. The second plurality of source fingers couple the discrete diffusion regions in parallel. The RFIC also includes a drain bus having a first plurality of drain fingers coupled to each drain region of the multi-finger transistors and a second plurality of drain fingers orthogonally coupled to the first plurality of drain fingers. The second plurality of drain fingers electrically couple the discrete diffusion regions in parallel. The RFIC further includes a plurality of interconnected body contacts to bias a body of each of the multi-finger transistors.

Abstract: An integrated circuit is described. The integrated circuit includes a metal oxide semiconductor field effect transistor (MOSFET). The MOSFET is on a first surface of an insulator layer of the integrated circuit. The MOSFET including a source region, a drain region, and a front gate. The MOSFET also includes an extended drain region between the drain region and a well proximate the front gate. The integrated circuit also includes back gates on a second surface opposite the first surface of the insulator layer. The back gates are overlapped by the extended drain region.

Abstract: A semiconductor device includes a channel structure that includes a first oxide layer, a second oxide layer, and a channel region between the first oxide layer and the second oxide layer. The semiconductor device includes a first gate structure proximate to at least three sides of the channel structure. The semiconductor device includes a second gate structure proximate to at least a fourth side of the channel structure.

Abstract: An integrated circuit is described. The integrated circuit includes a metal oxide semiconductor field effect transistor (MOSFET). The MOSFET is on a first surface of an insulator layer of the integrated circuit. The MOSFET including a source region, a drain region, and a front gate. The MOSFET also includes an extended drain region between the drain region and a well proximate the front gate. The integrated circuit also includes back gates on a second surface opposite the first surface of the insulator layer. The back gates are overlapped by the extended drain region.

Abstract: A radio frequency integrated circuit switch includes a semiconductor die with a transistor having a gate on a first-side (e.g., front-side) of the semiconductor die. The semiconductor die may include a bulk semiconductor substrate or wafer (e.g., silicon substrate or wafer). The semiconductor die may also include a first deep trench isolation (DTI) region that extends from the front-side to a backside opposite the front-side of the semiconductor die. The radio frequency integrated circuit switch further includes a body contact layer on the backside of the semiconductor die. The body contact layer is coupled to a backside of a body of the transistor. The body of the transistor may have a first P-type region (e.g., a P+ region).

Abstract: A radio frequency (RF) integrated circuit (RFIC) switch multi-finger transistor includes a first dual gate transistor having a first gate with a first gate length on a first side of a substrate, and a second gate with a second gate length on a second side of the substrate. The RFIC also includes a second dual gate transistor having a third gate with a third gate length on the first side of the substrate, and a fourth gate with a fourth gate length on the second side of the substrate. The second gate length is different than the fourth gate length, and the second dual gate transistor is coupled in series with the first dual gate transistor in the RFIC switch multi-finger transistor.