Understanding Linear-Mode Robustness in Low-Voltage Trench Power MOSFETs

The high-temperature electrothermal stability and linear-mode robustness of low-voltage discrete power trench MOSFETs are assessed. The linear-mode robustness is shown to be dependent on the positive temperature coefficient of the subthreshold diffusion current and the MOSFET gain factor. The datasheet threshold voltage temperature coefficient (V _GSTX TC) of a power MOSFET is important because it correlates with the linear-mode robustness and the zero-temperature-coefficient (ZTC) point of the device. The impact of the MOSFET active area and the cell pitch on the V _GSTX TC is experimentally assessed on fabricated devices. It is shown that the magnitude of the V _GSTX TC increases as the MOSFET active area increases, whereas it reduces as the cell pitch increases. The drain voltage at the onset of thermal runaway is shown to increase as the V _GSTX TC reduces for the same active area, thereby making the V _GSTX TC an indicator of linear-mode robustness. Although the gate voltage at the ZTC point and the magnitude of the V _GSTX TC increase with the MOSFET active area, the reduced thermal resistance improves the linear-mode robustness. The implication is that improved device performance in terms of lower specific on-state resistance ( R _SPEC in ohm-square millimeter) is at the expense of linear-mode robustness of the power MOSFET since lower R _SPEC devices have higher gain factors and higher currents are delivered at weaker inversion levels (and therefore contain higher proportions of subthreshold diffusion currents). In designing power MOSFETs, these parameters must be taken into consideration so as to minimize high-temperature instability and improve linear-mode robustness.