Abstract
To achieve radio frequency (RF) power detection, gain control, and circuit protection, this paper presents n+ GaAs/AuGeNi-Au thermocouple-type RF microelectromechanical system (MEMS) power sensors based on dual thermal flow paths. The sensors utilize a conversion principle of RF power-heat-voltage, where a thermovoltage is obtained as the RF power changes. To improve the heat transfer efficiency and the sensitivity, structures of two heat conduction paths are designed: one in which a thermal slug of Au is placed between two load resistors and hot junctions of the thermocouples, and one in which a back cavity is fabricated by the MEMS technology to form a substrate membrane underneath the resistors and the hot junctions. The improved sensors were fabricated by a GaAs monolithic microwave integrated circuit (MMIC) process. Experiments show that these sensors have reflection losses of less than −17 dB up to 12 GHz. At 1, 5, and 10 GHz, measured sensitivities are about 63.45, 53.97, and 44.14 µV/mW for the sensor with the thermal slug, and about 111.03, 94.79, and 79.04 µV/mW for the sensor with the thermal slug and the back cavity, respectively.
Highlights
Radio frequency (RF) power measurement plays an important role in radar and communication systems
Thermocouple-type RF power sensors based on the Seebeck effect have become one of the most widely tools for RF power detection, gain control, and circuit protection [1]
Some thermocouple-type RF power sensors based on the microelectromechanical system (MEMS) technology have been developed [3,4,5,6,7,8]
Summary
Radio frequency (RF) power measurement plays an important role in radar and communication systems. The substrate membrane of the sensors is about 10 μm thick to obtain a low thermal loss of the substrate and a sufficiently robust. 22 of membrane of the sensors is about 10 μm thick to obtain a low thermal loss of the substrate and a sufficiently robust stiffness, with microwave the GaAs monolithic microwave integrated stiffness, compatible with the compatible. These sensors by canusing be packaged using the bonding orThe soldering methods sensors be packaged the bonding orby soldering methods [9].
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