Add documentation in rst for PID
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@ -26,6 +26,48 @@ reflow oven's solid state relais output is saturated by software to a limit of 0
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In addition to the above features, the derivate term contains an additional first order low pass filter in order to prevent coupling of high frequency noise amplified by the derivate term.
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In addition to the above features, the derivate term contains an additional first order low pass filter in order to prevent coupling of high frequency noise amplified by the derivate term.
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The low pass filter is charcterized by its time constant :math:`k_{d\tau}`.
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The low pass filter is charcterized by its time constant :math:`k_{d\tau}`.
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Time Continuous Transfer Function
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The time continous transfer function of the PID controller is
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.. math:: H_c(s) = \frac{Y_c(s)}{X_c(s)} = k_p + \frac{k_i}{s} + \frac{k_ds}{1+sk_{d\tau}}
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Time Discrete Transfer Function
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The time descrete transfer function which is implemented in the code is derived by converting the time continuous transfer function
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with the bilinear transformation:
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.. math:: s = \frac{2}{T_s}\cdot \frac{z-1}{z+1}
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The frequency warping of the bilinear transform can be considered negligible because the PID controller is targetted for low frequency temperature signal data with a maximum far below the nyquist freqency.
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In this area, the mapping of the continuous frequencies to the time descrete can be considered linear.
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The time discrete transfer function after inserting the bilinear transform is:
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.. math:: H_d(z) = H_c(s)\bigg|_{s=\frac{2}{T_s}\cdot \frac{z-1}{z+1}} = k_p + \frac{k_i T_s (z+1)}{2(z-1)} + \frac{\frac{2}{T_s}k_d(z-1)}{\left(1+\frac{2k_{d\tau}}{T_s}\right)z+\left(1-\frac{2k_{d\tau}}{T_s}\right)}.
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Converted to an implementable form:
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.. math:: H_d(z) = k_p + \frac{k_iT_s(1+ z^{-1})}{2(1-z^{-1})} + \frac{\frac{2}{T_s}k_d(1-z^{-1})}{(1+2k_{d\tau}T_s^{-1})+(1-2k_{d\tau}T_s^{-1})z^{-1}}
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This function can be splitted in the three individual parts of the PID controller:
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.. math:: H_{d1}(z) = k_p
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.. math:: H_{d2}(z) = \frac{k_iT_s(1+ z^{-1})}{2(1-z^{-1})}
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.. math:: H_{d3}(z) = \frac{\frac{2}{T_s}k_d(1-z^{-1})}{(1+2k_{d\tau}T_s^{-1})+(1-2k_{d\tau}T_s^{-1})z^{-1}}
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The individual time domain difference equations :math:`y_i[n] = \mathcal{Z}^{-1}\left\lbrace H_{di} * X(z)\right\rbrace` that are implemented in software are:
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.. math:: y_1[n] = k_p x[n]
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.. math:: y_2[n] = \underbrace{\frac{k_iT_s}{2}}_{k_{i_t}} \left( x[n] + x[n-1]\right) + y_2[n-1]
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.. math:: y_3[n] = \underbrace{\frac{2k_{d}}{2k_{d\tau} + T_s}}_{k_{d_t}}\left( x[n] - x[n-1] \right) + \underbrace{\frac{2k_{d\tau} - T_s}{2k_{d\tau} + T_s}}_{\overline{k_{d_t}}} y_3[n-1]
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The final output value is the sum of all three terms:
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.. math:: y[n] = \sum_{i=1}^{3} y_i[n]
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.. _pid_code_api:
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.. _pid_code_api:
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