Method, apparatus for temperature detection and wearable device

The invention claimed is: 1 . A method for determining a temperature of a physical environment around a wearable device, comprising: obtaining a sensed temperature from a sensor indicating an internal temperature inside the wearable device, the sensor being in a mounted mode on a constant temperature object wearing the wearable device where the sensor is thermally radiated by the physical environment and the constant temperature object wearing the wearable device; determining, based on the sensed temperature from the sensor, a temperature change rate of the sensor and at least one affecting factor that affects temperature sensing of the sensor, wherein the at least one affecting factor comprises a first affecting factor A, a second affecting factor B and a third affecting factor C, the affecting factors A, B and C being constants; and determining the temperature of the physical environment based on the sensed temperature, the temperature change rate and the affecting factors A, B and C, wherein the temperature of the physical environment is determined by T e ⁢ n ⁢ v = A · d ⁢ T N ⁢ T ⁢ C d ⁢ t + B · T N ⁢ T ⁢ C + C wherein T env denotes the environmental temperature, T NTC is the sensed temperature of the sensor, A denotes the first affecting factor that affects the temperature change rate, B denotes the second affecting factor that affects the sensed temperature, and C denotes the third affecting factor determined based on a temperature of the constant temperature object that affects an intermediate temperature determined based on the sensed temperature and the temperature change rate. 2 . The method of claim 1 , wherein determining the at least one affecting factor comprises: determining the first affecting factor based on a power generated by an active component on a printed circuit board (PCB) where the sensor is mounted, and a first equivalent thermal conductivity around the sensor, wherein the first equivalent thermal conductivity is associated with an equivalent thermal conductivity (λ env ) from the physical environment to the sensor and an equivalent thermal conductivity (λ pcb1 ) from the PCB to the physical environment. 3 . The method of claim 1 , wherein determining the at least one affecting factor comprises: determining the second affecting factor based on a power generated by an active component on a printed circuit board (PCB) where the sensor is mounted, and a second equivalent thermal conductivity around the sensor, wherein the second equivalent thermal conductivity is associated with an equivalent thermal conductivity (λ env ) from the physical environment to the sensor, an equivalent thermal conductivity (λ pcb1 ) from the PCB to the physical environment, an equivalent thermal conductivity (λ face ) from the constant temperature object to the sensor, and an equivalent thermal conductivity (λ pcb2 ) from the PCB to the constant temperature object. 4 . The method of claim 1 , wherein determining the at least one affecting factor comprises: determining the third affecting factor based on a temperature of the constant temperature object, a power generated by an active component on a printed circuit board (PCB) where the sensor is mounted, and a third equivalent thermal conductivity around the sensor, wherein a second equivalent thermal conductivity is associated with an equivalent thermal conductivity (λ env ) from the physical environment to the sensor, an equivalent thermal conductivity (λ pcb1 ) from the PCB to the physical environment, an equivalent thermal conductivity (λ face ) from the constant temperature object to the sensor, and an equivalent thermal conductivity (λ pcb2 ) from the PCB to the constant temperature object. 5 . The method of claim 1 , wherein determining the temperature change rate comprises: obtaining a plurality of historical temperatures sensed by the sensor over a period of time; and determining the change rate based on the plurality of historical temperatures and the period of time.