Abstract: Various integrated circuits formed using gallium nitride and other materials are described. In one example, an integrated circuit includes a first integrated device formed over a first semiconductor structure in a first region of the integrated circuit, a second integrated device formed over a second semiconductor structure in a second region of the integrated circuit, and a passive component formed over a third region of the integrated circuit, between the first region and the second region. The third region comprises an insulating material, which can be glass in some cases. Further, the passive component can be formed over the glass in the third region. The integrated circuit is designed to avoid electromagnetic coupling between the passive component, during operation of the integrated circuit, and interfacial parasitic conductive layers existing in the first and second semiconductor structures, to improve performance.

Abstract: A number of integrated circuits and methods of manufacturing the integrated circuits are described. An integrated circuit can include different semiconductor devices formed from different semiconductor systems in different regions over the same substrate. The integrated circuit can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

Abstract: III-nitride materials are described herein, including material structures comprising III-nitride material regions (e.g., gallium nitride material regions). In certain cases, the material structures also comprise substrates having relatively high electrical conductivities. Certain embodiments include one or more features that reduce the degree to which thermal runaway occurs, which can enhance device performance including at elevated flange temperatures. Some embodiments include one or more features that reduce the degree of capacitive coupling exhibited during operation. For example, in some embodiments, relatively thick III-nitride material regions and/or relatively small ohmic contacts are employed.

Abstract: Extrinsic structure that is formed outside the active regions of active devices can influence aging characteristics and performance of the active devices. Extrinsic structure is described that can reduce gate leakage current in transistors by over four orders of magnitude.

Abstract: Apparatus and methods relating to heterolithic microwave integrated circuits HMICs are described. An HMIC can include different semiconductor devices formed from different semiconductor systems in different regions of a same substrate. An HMIC can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

Abstract: Apparatus and methods relating to heterolithic microwave integrated circuits HMICs are described. An HMIC can include different semiconductor devices formed from different semiconductor systems in different regions of a same substrate. An HMIC can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

Abstract: III-nitride materials are described herein, including material structures comprising III-nitride material regions (e.g., gallium nitride material regions). In certain cases, the material structures also comprise substrates having relatively high electrical conductivities. Certain embodiments include one or more features that reduce the degree to which thermal runaway occurs, which can enhance device performance including at elevated flange temperatures. Some embodiments include one or more features that reduce the degree of capacitive coupling exhibited during operation. For example, in some embodiments, relatively thick III-nitride material regions and/or relatively small ohmic contacts are employed.

Abstract: Structures and methods for isolating semiconductor devices and improving device reliability under harsh environmental conditions are described. An isolation region may be formed by ion implantation in a region of semiconductor surrounding a device. The implantation region may extend into streets of a wafer. A passivation layer may be deposited over the implantation region and extend further into the streets than the isolation region to protect the isolation region from environmental conditions that may adversely affect the isolation region.

Abstract: Apparatus and methods relating to heterolithic microwave integrated circuits HMICs are described. An HMIC can include different semiconductor devices formed from different semiconductor systems in different regions of a same substrate. An HMIC can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

Abstract: III-nitride materials are described herein, including material structures comprising III-nitride material regions (e.g., gallium nitride material regions). In certain cases, the material structures also comprise substrates having relatively high electrical conductivities. Certain embodiments include one or more features that reduce the degree to which thermal runaway occurs, which can enhance device performance including at elevated flange temperatures. Some embodiments include one or more features that reduce the degree of capacitive coupling exhibited during operation. For example, in some embodiments, relatively thick III-nitride material regions and/or relatively small ohmic contacts are employed.

Abstract: Apparatus and methods relating to heterolithic microwave integrated circuits HMICs are described. An HMIC can include different semiconductor devices formed from different semiconductor systems in different regions of a same substrate. An HMIC can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

Abstract: A method for making a semiconductor structure includes defining one or more device areas and one or more interconnect areas on a silicon substrate, forming trenches in the interconnect areas of the silicon substrate, oxidizing the silicon substrate in the trenches to form silicon dioxide regions, forming a III-nitride material layer on the surface of the silicon substrate, forming devices in the device areas of the gallium nitride layer, and forming interconnects in the interconnect areas. The silicon dioxide regions reduce parasitic capacitance between the interconnects and ground.

Abstract: Apparatus and methods relating to heterolithic microwave integrated circuits HMICs are described. An HMIC can include different semiconductor devices formed from different semiconductor systems in different regions of a same substrate. An HMIC can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

Abstract: Apparatus and methods relating to heterolithic microwave integrated circuits HMICs are described. An HMIC can include different semiconductor devices formed from different semiconductor systems in different regions of a same substrate. An HMIC can also include bulk regions of low-loss electrically-insulating material extending through the substrate and located between the different semiconductor regions. Passive RF circuit elements can be formed on the low-loss electrically-insulating material.

Abstract: Structures and methods for isolating semiconductor devices and improving device reliability under harsh environmental conditions are described. An isolation region may be formed by ion implantation in a region of semiconductor surrounding a device. The implantation region may extend into streets of a wafer. A passivation layer may be deposited over the implantation region and extend further into the streets than the isolation region to protect the isolation region from environmental conditions that may adversely affect the isolation region.

Abstract: A multiple layer inductor structure in which the difference in phase current between upper and lower spiral inductor segments is reduced so as to thereby obtain not only a significant reduction in area but also a substantial increase in self-resonance frequency and a concomitant increase in the operating frequency range. The structure incorporates upper and lower spiral inductor sections, the lower section being disposed on the surface of a semiconductor substrate and the upper section being disposed on the surface of a dielectric layer which separates the respective spiral inductor sections. A plurality of electrically conductive vias interconnect adjacent concentric loop segments of the spiral inductor sections, so that as current flows through the inductor element it passes from one of the upper and the lower inductor sections to the other of the upper and lower inductor sections, alternating between these levels a number of times (i.e., a number less than or equal to the number of concentric segments).

Abstract: A switched amplifying device for use in a wireless telecommunications receiver as an amplifier of an RF signal has an amplifying device electrically connected in parallel with a switch. The switched amplifying device has a bypass mode in which an electrical path of the RF signal bypasses the amplifying device and is connected to an RF output port. The switched amplifying device also has an amplification mode in which the electrical path of the RF signal flows through the amplifying device prior to presentation of the RF signal at the RF output. In the bypass mode, the amplification device is in an off state. Similarly, in the amplification mode, the bypass device is in an off state. Use of the switched amplifying device according to the teachings of the present invention in a receiver permits accommodation of a larger dynamic range in amplitude of received signal with less signal degradation and noise figure than in prior art amplification devices.

Abstract: A switched amplifying device for use in a wireless telecommunications receiver as an amplifier of an RF signal has an amplifying device electrically connected in parallel with a switch. The switched amplifying device has a bypass mode in which an electrical path of the RF signal bypasses the amplifying device and is connected to an RF output port. The switched amplifying device also has a amplification mode in which, the electrical path of the RF signal flows through the amplifying device prior to presentation of the RF signal at the RF output. In the bypass mode, the amplification device is in an off state. Similarly, in the amplification mode, the bypass device is in an off state. Use of the switched amplifying device according to the teachings of the present invention in a receiver permits accommodation of a larger dynamic range in amplitude of received signal with less signal degradation and noise figure than in prior art amplification devices.

Abstract: A control circuit is provided that can be used to compensate for pinch off voltage sensitive circuits. The control circuit comprises a control FET (26) having a gate (27), a drain (29), and a source (28). The control FET source (28) is connected to a tracking potential (23) through control FET source resistor (31) in series with a constant voltage drop element (32). A control voltage input (22) is applied to the control FET drain (29). A current flow through the control FET (26) results in a transfer function that is substantially linear for linear changes in control voltage input below a voltage pinch off value of the control FET (26). As the voltage control output (23) approaches the pinch off voltage value of the control FET (26), smaller changes in control voltage output (23) are realized for the same change in control voltage input (22).