A bias current generator circuit includes a current path and a leakage control circuit. The current path is connected between a supply voltage and a ground level. The current path includes a transistor and a resistor. The transistor has a current channel connected in the current path. The resistor has an upper terminal and a lower terminal connected in the current path, and a well contact to allow a reverse leakage current of the resistor to flow through. The leakage control circuit is connected to the supply voltage. The leakage control circuit includes a driving transistor to provide a driving voltage to the well contact of the resistor, and to allow the reverse leakage current of the resistor to flow into the leakage control circuit.

A bias current generator circuit includes a current path and a leakage control circuit. The current path is connected between a supply voltage and a ground level. The current path includes a transistor and a resistor. The transistor has a current channel connected in the current path. The resistor has an upper terminal and a lower terminal connected in the current path, and a well contact to allow a reverse leakage current of the resistor to flow through. The leakage control circuit is connected to the supply voltage. The leakage control circuit includes a driving transistor to provide a driving voltage to the well contact of the resistor, and to allow the reverse leakage current of the resistor to flow into the leakage control circuit.

A resistor-transistor-logic circuit with GaN structures, including a 2DEG resistor having a drain connected with an operating voltage, and a logic FET having a gate connected to an input voltage, a source grounded and a drain connected with a source of the 2DEG resistor and connected collectively to an output voltage.

Structures and related techniques for control of two-dimensional electron gas (2DEG) charge density in gallium nitride (GaN) devices are disclosed. In one aspect, a GaN device includes a compound semiconductor substrate, a source region formed in the compound semiconductor substrate, a drain region formed in the compound semiconductor substrate and separated from the source region, a 2DEG layer formed in the compound semiconductor substrate and extending between the source region and the drain region, a gate region formed on the compound semiconductor substrate and positioned between the source region and the drain region, and a plurality of isolated charge control structures disposed between the gate region and the drain region.

Self-cooling semiconductor resistor and manufacturing method thereof are provided. The resistor comprises: multiple N-type and P-type wells in a semiconductor substrate, first polysilicon gates on each N-type well, second polysilicon gates on each P-type well, and metal interconnect layers. The multiple N-type and P-type wells are arranged alternately in row and column direction, respectively. N-type and P-type deep doped regions are formed on each N-type and P-type well, respectively. The first and second polysilicon gates are N-type and P-type deep doped respectively, and there is no gate oxide layer between the first and second polysilicon gates and the semiconductor substrate. The metal interconnect layers connect the multiple first and second polysilicon gates as an S-shaped structure. In the present application, the flow direction of heat is from the inside of the resistor to its surface, thereby realizing heat dissipation and cooling.

A resistor including a device isolation layer is described that includes a first active region and a second active region, a buried insulating layer, and an N well region. The N well region surrounds the first active region, the second active region, the device isolation layer and the buried insulating layer. A first doped region and a second doped region are disposed on the first active region and the second active region. The first doped region and the second doped region are in contact with the N well region and include n type impurities.

The present application provides a strain sensing film, a pressure sensor, and a hybrid strain sensing system. The strain sensing film includes a semiconductor thin-film, at least two resistors are disposed on the semiconductor thin-film, one resistor has a different response to a strain with respect to at least another resistor, thereby enhancing resistance to external environmental disturbances and improving the accuracy of pressure measurements.

An electronic device can include a drain terminal, a control terminal, and a source terminal, a first HEMT, and a second HEMT. The first HEMT can include a drain electrode coupled to the drain terminal, a gate electrode coupled to the first control terminal, and a source electrode coupled to the source terminal. The second HEMT can include a drain electrode, a gate electrode, and a source electrode. The drain electrode can be coupled to the drain terminal, and the source electrode can be coupled to the source terminal. In an embodiment, a resistor can be coupled between the gate and source electrodes of the second HEMT, and in another embodiment, the gate electrode of the second HEMT can electrically float. During or after a triggering event, the second HEMT can turn on temporarily to divert some of the charging from the triggering event into the second HEMT.

A resistor-transistor-logic (RTL) circuit with GaN structure, including a GaN layer, a AlGaN barrier layer on the GaN layer, multiple p-type doped GaN capping layers on the AlGaN barrier layer, wherein parts of the p-type doped GaN capping layers in a high-voltage region and in a low-voltage region convert the underlying GaN layer into gate depletion areas, the GaN layer not covered by the p-type doped GaN capping layers in a resistor region becomes a 2DEG resistor.

A resistor including a device isolation layer is described that includes a first active region and a second active region, a buried insulating layer, and an N well region. The N well region surrounds the first active region, the second active region, the device isolation layer and the buried insulating layer. A first doped region and a second doped region are disposed on the first active region and the second active region. The first doped region and the second doped region are in contact with the N well region and include n type impurities.