1. Field of the Invention
The present invention relates to a method for forming optimal characteristic curves of a solar cell and the system thereof in an automatic manner.
2. Description of the Related Art
With the gradual exhaustion of oil reserves and other non-renewable energy resources and more concern toward environmental protection, the development of alternative energy resources draws more and more attention from many governments. Among the alternatives for future energy sources, the development of solar cells is one of the most attractive solutions. Many countries are applying extensive effort toward developing this technology so as to reduce their heavy reliance on oil or other non-renewable resources.
Using a solar cell to transform solar energy into electricity is the primary basis of collecting solar energy. The principle activity of a solar cell is to use semiconductor photoelectrical transformation to generate electrical power. The transformation efficiency will directly affect the output power and, therefore, the selling price of the solar cell. Generally, solar cells are classified into different classes based on their efficiency testing. It is expected that higher transformation efficiency in a solar cell corresponds to a higher price. Therefore, an accurate, objective and rapid measuring method or system is an important tool for solar cell manufacturers.
U.S. Pat. No. 4,528,503 discloses a method and apparatus for measuring current and voltage of a solar cell. This method measures characteristic curves of the solar cells while in the states of open and closed circuits, respectively, and the voltage and current of the maximal output power are deduced from the measured data.
Other methods of determining the maximal output power utilize mostly human operations to read operation data and then manually select a linear or fixed square root equation to find voltage and current curves. However, such method is so subjective that the analysis result is not reliable.
The proposed method for forming an optimal characteristic curve of a solar cell comprises the steps of: providing a first allowable error; then, determining a current-voltage polynomial regression equation in accordance with measured data of the solar cell, wherein the curve-fitting error of the current-voltage polynomial regression equation is smaller than the first allowable error.
The proposed method for forming an optimal characteristic curve of a solar cell comprises the steps of: providing a first allowable error; determining a current-voltage polynomial regression equation with a minimal curve-fitting error from all current-voltage polynomial regression equations with curve-fitting errors smaller than the first allowable error; calculating characteristic parameters including open voltage and short current; estimating a power-voltage polynomial regression equation; and estimating maximal power voltage, maximal power and maximal power current.
The proposed system for forming an optimal characteristic curve of a solar cell comprises a current-voltage polynomial regression module, a characteristic parameter calculation module, a temperature coefficient calculation module, an internal in-series resistance calculation module and a characteristic parameter transformation module. The current-voltage polynomial regression module is configured to determine polynomial regression equations with errors smaller than an allowable error in accordance with measured data of the solar cell. The characteristic parameter calculation module is configured to calculate characteristic parameters including open voltage and short current in accordance with the current-voltage polynomial regression equations. The temperature coefficient calculation module is configured to calculate temperature coefficients on the basis of the relationship of dimensionless characteristic parameters and temperature as well as illumination, wherein the dimensionless characteristic parameters are determined by conducting a dimensionless analysis on the measured data of the solar cell in accordance with the characteristic parameters. The internal in-series resistance calculation module is configured to calculate internal in-series resistance in accordance with the short current and voltage corresponding to the short current at different illumination conditions. The characteristic parameter transformation module is configured to transform the measured data and/or characteristic parameters of the solar cell into a standard test condition.
The invention will be described according to the appended drawings in which:
The method of the present invention takes advantage of regression equations and the optimization method thereof to achieve the purpose of automatic calculations, and utilizes the generated curve to calculate related characteristic parameters of the solar cells. The present invention exhibits such high levels of objectivity, automation and accuracy that many of the prior art's problems in measuring solar cells can be avoided. The measuring system using the algorithm of the present invention can achieve the objectives of standard test retroaction and can increase the measuring speed.
In Step S208, the coefficients of the I-V polynomial regression equation is obtained based on the I-V data. The regression analysis is done by performing a least square approximation, and the I-V polynomial regression equation may be the following:
f(V)=a0+a1V+a2V2+ . . . +anVn (1)
wherein a0,a1,a2 . . . an are coefficients of the I-V polynomial regression equation, while n is the power of the I-V polynomial regression equation. The I-V data and the equation (1) can infer to the following matrix equation:
R=X·A+E (2)
wherein I1, . . . Im and V1, . . . Vm are I-V measured data; the element ek of the matrix E is residual between Ik and f(Vk).
After completing the calculation of least square approximation, the coefficients of the polynomial regression equation are resolved as the following:
A=(XtX)−1·Xt·R (7)
wherein Xt is a transpose matrix of X, and (XtX)−1 is an inverse matrix of (XtX).
In Step S210, it is determined whether an I-V polynomial regression equation which satisfies the condition of an allowable error is found. The curve-fitting error of the I-V polynomial regression equation is calculated based on the following:
If ε is smaller than an allowable error, the I-V data is represented by the calculated I-V polynomial regression equation. If ε is greater than the allowable error, it means that the calculated I-V polynomial regression equation is still unqualified to represent the I-V data, and then a new I-V polynomial regression equation with one more power is used to perform the next curve fitting of the I-V data as shown in Step 211.
In Step S212, it is determined whether the power of the I-V polynomial regression equation is greater than 20. This step is used to limit the amount of calculation. When the power is greater than 20, an I-V polynomial regression equation will not be used to conduct a curve fitting any more, but instead, one I-V polynomial regression equation with minimal curve-fitting error is chosen from the previously calculated I-V polynomial regression equations with powers between 2 and 20 to represent the I-V data as shown in Step S213.
Due to the limitation of errors, the I-V polynomial regression equation obtained by using the above optimal characteristic curve selection algorithm has more accurate characteristic parameters, and the whole procedure is deduced automatically so as to ensure a consistent and accurate manner.
The transformation between I-V
data and characteristic parameters with different temperature and/or illumination are conducted as the following:
wherein I1 and V1 are obtained in the conditions of temperature T1 and illumination E1, I2 and V2 are I-V data after I1 and V1 are transformed based on temperature coefficients α, β, δ and internal in-series RS under temperature T2 and illumination E2. In Step S406, the temperature coefficients α, β, δ and RS are calculated based on equations (9) and (10). The temperature coefficient α is the slope of the regression equation related to Isc under 1000 W/m2 at different temperature; that is, ΔIsc/ΔT. The temperature coefficient β is obtained by first calculating the slope of Voc to temperature T in every illumination, that is ΔVoc/ΔT, standardizing by Voc and then by a linear regression equation based on ΔVoc/ΔT and illumination E. The temperature coefficient δ is obtained by first calculating the slope of Voc to ln(E) in every illumination, that is ΔVoc/Δln(E), standardizing by Voc and then by a linear regression equation based on ΔVoc/Δln(E) and temperature T.
The temperature coefficients α, β, δ and RS can be used to transform I-V data and characteristic parameters under any condition into a standard test condition.
The above-described embodiments of the present invention are intended to be illustrative only. Numerous alternative embodiments may be devised by persons skilled in the art without departing from the scope of the following claims.
Number | Date | Country | Kind |
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097108625 | Mar 2008 | TW | national |