Abstract: An exercise intensity assessing system includes a physiological information sensor, a signal transmitter connected with the physiological information sensor, a central control host connected with the signal transmitter, and a cloud database connected with the central control host. The physiological information sensor senses physiological information of an exerciser before and after the exerciser exercises. The physiological information is transmitted by the signal transmitter to the central control host, and transmitted by the central control host to the cloud database for being diagnosed and analyzed by a fitness instructor. The cloud database obtains a forecasted watt value corresponding to the physiological information, and obtains a resistance level of different fitness apparatuses according to the forecasted watt value.

Abstract: An intelligent exercise intensity assessing system includes an exercise testing machine, a physiological information sensor, a signal transmitter connected with the physiological information sensor, a central control host connected with the signal transmitter, and a cloud database connected with the central control host. The physiological information sensor senses physiological information of an exerciser before and after the exerciser operates the exercise testing machine. The physiological information is transmitted by the signal transmitter to the central control host, and transmitted by the central control host to the cloud database. The cloud database analyzes the physiological information to obtain a corresponding forecasted watt value, and obtains a resistance level of different fitness apparatuses according to the forecasted watt value.

Abstract: A double &dgr;-doped In0.34 Al0.66As0.85 Sb0.15/InP heterostructure field-effect transistor has been successfully grown by metalorganic chemical vapor deposition for the first time. Electron mobilities can be enhanced without sacrificing the carrier densities. A turn-on voltage as high as 1 V along with an extremely low gate reverse leakage current of 111 &mgr;A/mm at Vgs=−40V is achieved. The three-terminal on-and off-state breakdown voltages are as high as 40.8V and 16.1V, respectively. The output conductance is as low as 1.8 mS/mm even when the drain-to-source voltage is 15V. The gds is significantly smaller than that of our previously reported InAlAsSb/InGaAs/InP HFET. These characteristics are attributed to the use of the coupled &dgr;-doped structure, InP channel, In0.34 Al0.66As0.85 Sb0.15 Schottky layer, and to the large conduction-band discontinuity (&Dgr;Ec) at the InAlAsSb/InP heterojunction.

Abstract: A double &dgr;-doped In0.34 Al0.66As0.85 Sb0.15/InP heterostructure field-effect transistor has been successfully grown by metalorganic chemical vapor deposition for the first time. Electron mobilities can be enhanced without sacrificing the carrier densities. A turn-on voltage as high as 1 V along with an extremely low gate reverse leakage current of 111 &mgr;A/mm at Vgs=−40V is achieved. The three-terminal on-and off-state breakdown voltages are as high as 40.8V and 16.1V,respectively. The output conductance is as low as 1.8 mS/mm even when the drain-to-source voltage is 15V. The gds is significantly smaller than that of our previously reported InAlAsSb/InGaAs/InP HFET. These characteristics are attributed to the use of the coupled &dgr;-doped structure, InP channel, In0.34 Al0.66As0.85 Sb0.15 Schottky layer'and to the large conduction-band discontinuity(&Dgr;Ec) at the InAlAsSb/InP heterojunction.