Method for measuring semiconductor gas sensor based on virtual alternating current impedance

The invention claimed is: 1. A method for measuring a semiconductor gas sensor based on virtual alternating current impedance, comprising the following steps: first step, measuring a resistance value of a semiconductor gas sensor exposed to a series of to-be-measured gases with known concentrations, second step, connecting the resistance value with virtual capacitance C in parallel and calculating corresponding virtual impedance characteristic quantities by the following alternating current impedance formulas: Z 1 = R 1 + ( 2 ⁢ π ⁢ fCR ) 2 , Z 2 = - R 2 ⁢ C ⁢ 2 ⁢ π ⁢ f 1 + ( 2 ⁢ π ⁢ fCR ) 2 , Z = Z 1 2 + Z 2 2 , phase = arctan ⁡ ( Z 2 Z 1 ) , P = 1 phase , Y = 1 Z , Y 1 = 1 Z 1 , Y 2 = 1 Z 2 , G = Z 1 Z 1 2 + Z 2 2 ,  wherein f represents a virtual alternating current measurement frequency, R represents the measured resistance value, and the meaning of the virtual impedance characteristic quantities is as follows: Y: calculated virtual admittance modulus, G: calculated real component modulus of the virtual admittance, Z: calculated virtual impedance modulus, Z 1 ; calculated real component modulus of the virtual impedance, Z 2 : calculated imaginary component modulus of the virtual impedance, Y 1 : reciprocal of the calculated real component modulus of the virtual impedance, Y 2 : reciprocal of the imaginary component modulus of the virtual impedance, phase: calculated virtual phase, and P: reciprocal of the calculated virtual phase; combining measurement parameters of virtual frequencies in a first predetermined range and virtual parallel capacitance values in a second predetermined range, and measuring a certain type of gas with known concentration at each virtual impedance characteristic quantity among the above nine virtual impedance characteristic quantities in the case of each combination; obtaining a characteristic value corresponding to the known concentration at a certain virtual impedance characteristic quantity among the currently selected nine virtual impedance characteristic quantities at the end of each time of measurement; obtaining multiple characteristic values corresponding to the same gas concentration at each virtual impedance characteristic quantity after traversing all parameter combinations and all nine virtual impedance characteristic quantities; when considering the linearity and the signal-to-noise ratio between each characteristic value at all virtual impedance characteristic quantities and the known concentration, and making the linearity greater than or equal to a first threshold and the signal-to-noise ratio greater than or equal to a second threshold: selecting a frequency range composed of corresponding virtual frequency values as a third range of measurement frequencies, wherein the lower limit of the third range is the minimum frequency among the corresponding virtual frequency values, and the upper limit of the third range is the maximum frequency among the corresponding virtual frequency values, and selecting a capacitance range composed of corresponding virtual parallel capacitance values as a fourth range of parallel capacitance values, wherein the lower limit of the fourth range is the minimum capacitance value among the corresponding virtual parallel capacitance values, and the upper limit of the fourth range is the maximum capacitance value among the corresponding virtual parallel capacitance values, selecting one or several corresponding virtual impedance characteristic quantities, and taking the selected virtual measurement frequencies in the third range, the selected virtual parallel capacitance values in the fourth range and the selected one or several corresponding virtual impedance characteristic quantities as the finally selected measurement parameters for measuring the unknown gas concentration; and third step, measuring the type of gas with unknown concentration based on the m