#+TITLE: Robust and Optimal Sensor Fusion - Tikz Figures :DRAWER: #+HTML_LINK_HOME: ../index.html #+HTML_LINK_UP: ../index.html #+HTML_HEAD: #+HTML_HEAD: #+HTML_HEAD: #+HTML_HEAD: #+HTML_HEAD: #+HTML_HEAD: #+PROPERTY: header-args:latex :headers '("\\usepackage{tikz}" "\\usepackage{import}" "\\import{/home/thomas/MEGA/These/Papers/dehaeze19_desig_compl_filte/tikz/}{config.tex}") #+PROPERTY: header-args:latex+ :imagemagick t :fit yes #+PROPERTY: header-args:latex+ :iminoptions -scale 100% -density 150 #+PROPERTY: header-args:latex+ :imoutoptions -quality 100 #+PROPERTY: header-args:latex+ :results raw replace :buffer no #+PROPERTY: header-args:latex+ :eval no-export #+PROPERTY: header-args:latex+ :exports both #+PROPERTY: header-args:latex+ :mkdirp yes #+PROPERTY: header-args:latex+ :noweb yes #+PROPERTY: header-args:latex+ :output-dir figs #+PROPERTY: header-args:latex+ :post pdf2svg(file=*this*, ext="png") :END: Configuration file is accessible [[file:config.org][here]]. * Change some default #+NAME: tikz_default #+begin_src latex :eval no \tikzset{block/.default={0.8cm}{0.6cm}} \tikzset{addb/.append style={scale=0.7}} \tikzset{node distance=0.6} \def\cdist{0.7} \definecolor{T}{rgb}{0.230, 0.299, 0.754}% \definecolor{S}{rgb}{0.706, 0.016, 0.150}% #+end_src * H-Infinity - Complementary filters - Generalized plant #+begin_src latex :file sf_hinf_filters_plant_b.pdf :tangle figs/sf_hinf_filters_plant_b.tex <> \begin{tikzpicture} \node[block={4.0cm}{3.0cm}, dashed] (P) {}; \node[above] at (P.north) {$P$}; \coordinate[] (inputw) at ($(P.south west)!0.8!(P.north west) + (-\cdist, 0)$); \coordinate[] (inputu) at ($(P.south west)!0.4!(P.north west) + (-\cdist, 0)$); \coordinate[] (outputh) at ($(P.south east)!0.8!(P.north east) + ( \cdist, 0)$); \coordinate[] (outputl) at ($(P.south east)!0.4!(P.north east) + ( \cdist, 0)$); \coordinate[] (outputv) at ($(P.south east)!0.1!(P.north east) + ( \cdist, 0)$); \node[block, left=2*\cdist of outputl] (WL){$w_L$}; \node[block, left=2*\cdist of outputh] (WH){$w_H$}; \node[addb={+}{}{}{}{-}, left=of WH] (sub) {}; \draw[->] (inputw) node[above right]{$w$} -- (sub.west); \draw[->] (inputu) node[above right]{$u$} -- (WL.west); \draw[->] (inputu-|sub) node[branch]{} -- (sub.south); \draw[->] (sub.east) -- (WH.west); \draw[->] ($(inputw)+(2*\cdist, 0)$) node[branch]{} |- (outputv) node[above left]{$v$}; \draw[->] (WH.east) -- (outputh)node[above left]{$z_H$}; \draw[->] (WL.east) -- (outputl)node[above left]{$z_L$}; \end{tikzpicture} #+end_src #+name: fig:sf_hinf_filters_plant_b #+caption: H-Infinity - Complementary filters - Generalized plant ([[./figs/sf_hinf_filters_plant_b.png][png]], [[./figs/sf_hinf_filters_plant_b.pdf][pdf]], [[./figs/sf_hinf_filters_plant_b.tex][tex]]). #+RESULTS: [[file:figs/sf_hinf_filters_plant_b.png]] * H-Infinity - Complementary filters #+begin_src latex :file sf_hinf_filters_b.pdf :tangle figs/sf_hinf_filters_b.tex <> \begin{tikzpicture} \node[block={4.0cm}{3.0cm}, dashed] (P) {}; \node[above] at (P.north) {$P$}; \coordinate[] (inputw) at ($(P.south west)!0.8!(P.north west) + (-\cdist, 0)$); \coordinate[] (inputu) at ($(P.south west)!0.4!(P.north west) + (-\cdist, 0)$); \coordinate[] (outputh) at ($(P.south east)!0.8!(P.north east) + ( \cdist, 0)$); \coordinate[] (outputl) at ($(P.south east)!0.4!(P.north east) + ( \cdist, 0)$); \coordinate[] (outputv) at ($(P.south east)!0.1!(P.north east) + ( \cdist, 0)$); \node[block, left=2*\cdist of outputl] (WL){$w_L$}; \node[block, left=2*\cdist of outputh] (WH){$w_H$}; \node[addb={+}{}{}{}{-}, left=of WH] (sub) {}; \node[block, below=\cdist of P] (HL) {$H_L$}; \draw[->] (inputw) node[above right]{$w$} -- (sub.west); \draw[->] (HL.west) -| ($(inputu)+(0.5*\cdist, 0)$) -- (WL.west); \draw[->] (inputu-|sub) node[branch]{} -- (sub.south); \draw[->] (sub.east) -- (WH.west); \draw[->] ($(inputw)+(2*\cdist, 0)$) node[branch]{} |- ($(outputv)+(-0.5*\cdist, 0)$) |- (HL.east); \draw[->] (WH.east) -- (outputh)node[above left]{$z_H$}; \draw[->] (WL.east) -- (outputl)node[above left]{$z_L$}; \end{tikzpicture} #+end_src #+name: fig:sf_hinf_filters_b #+caption: H-Infinity - Complementary filters ([[./figs/sf_hinf_filters_b.png][png]], [[./figs/sf_hinf_filters_b.pdf][pdf]], [[./figs/sf_hinf_filters_b.tex][tex]]). #+RESULTS: [[file:figs/sf_hinf_filters_b.png]] * Generate Complementary Filters using Feedback Control Architecture #+begin_src latex :file complementary_filters_feedback_architecture.pdf :tangle figs/complementary_filters_feedback_architecture.tex :exports both \begin{tikzpicture} \node[addb={+}{}{}{}{-}] (addfb) at (0, 0){}; \node[block, right=1 of addfb] (L){$L$}; \node[addb={+}{}{}{}{}, right=1 of L] (adddy){}; \draw[<-] (addfb.west) -- ++(-1, 0) node[above right]{$y_1$}; \draw[->] (addfb.east) -- (L.west); \draw[->] (L.east) -- (adddy.west); \draw[->] (adddy.east) -- ++(1, 0) node[above left]{$y_s$}; \draw[->] ($(adddy.east) + (0.5, 0)$) node[branch]{} -- ++(0, -1) -| (addfb.south); \draw[<-] (adddy.north) -- ++(0, 1) node[below right]{$y_2$}; \end{tikzpicture} #+end_src #+name: fig:complementary_filters_feedback_architecture #+caption: Generation of Complementary Filters using the feedback architecture ([[./figs/complementary_filters_feedback_architecture.png][png]], [[./figs/complementary_filters_feedback_architecture.pdf][pdf]], [[./figs/complementary_filters_feedback_architecture.tex][tex]]). #+RESULTS: [[file:figs/complementary_filters_feedback_architecture.png]] * H-Infinity Synthesis for Robust Sensor Fusion #+begin_src latex :file h_infinity_robust_fusion_old.pdf :tangle figs/h_infinity_robust_fusion_old.tex :exports both <> \begin{tikzpicture} \node[block={4.0cm}{3.0cm}, dashed] (P) {}; \node[above] at (P.north) {$P$}; \coordinate[] (inputw) at ($(P.south west)!0.8!(P.north west) + (-\cdist, 0)$); \coordinate[] (inputu) at ($(P.south west)!0.4!(P.north west) + (-\cdist, 0)$); \coordinate[] (outputh) at ($(P.south east)!0.8!(P.north east) + ( \cdist, 0)$); \coordinate[] (outputl) at ($(P.south east)!0.4!(P.north east) + ( \cdist, 0)$); \coordinate[] (outputv) at ($(P.south east)!0.1!(P.north east) + ( \cdist, 0)$); \node[block, left=2*\cdist of outputl] (W1){$w_1$}; \node[block, left=2*\cdist of outputh] (W2){$w_2$}; \node[addb={+}{}{}{}{-}, left=of W2] (sub) {}; \node[block, below=\cdist of P] (H1) {$H_1$}; \draw[->] (inputw) node[above right]{$w$} -- (sub.west); \draw[->] (H1.west) -| ($(inputu)+(0.5*\cdist, 0)$) -- (W1.west); \draw[->] (inputu-|sub) node[branch]{} -- (sub.south); \draw[->] (sub.east) -- (W2.west); \draw[->] ($(inputw)+(2*\cdist, 0)$) node[branch]{} |- ($(outputv)+(-0.5*\cdist, 0)$) |- (H1.east); \draw[->] (W2.east) -- (outputh)node[above left]{$z_2$}; \draw[->] (W1.east) -- (outputl)node[above left]{$z_1$}; \end{tikzpicture} #+end_src #+name: fig:h_infinity_robust_fusion_old #+caption: H-Infinity Synthesis for Robust Sensor Fusion ([[./figs/h_infinity_robust_fusion_old.png][png]], [[./figs/h_infinity_robust_fusion_old.pdf][pdf]], [[./figs/h_infinity_robust_fusion_old.tex][tex]]). #+RESULTS: [[file:figs/h_infinity_robust_fusion_old.png]] * Fusion of two noisy sensors #+begin_src latex :file fusion_two_noisy_sensors.pdf :tangle figs/fusion_two_noisy_sensors.tex <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[block, above right=0.5 and 0.5 of x](G1){$G_1(s)$}; \node[block, below right=0.5 and 0.5 of x](G2){$G_2(s)$}; \node[addb, right=0.8 of G1](add1){}; \node[addb, right=0.8 of G2](add2){}; \node[block, right=0.8 of add1](H1){$H_1(s)$}; \node[block, right=0.8 of add2](H2){$H_2(s)$}; \node[addb, right=5 of x](add){}; \draw[] ($(x)+(-0.7, 0)$) node[above right]{$x$} -- (x.center); \draw[->] (x.center) |- (G1.west); \draw[->] (x.center) |- (G2.west); \draw[->] (G1.east) -- (add1.west); \draw[->] (G2.east) -- (add2.west); \draw[<-] (add1.north) -- ++(0, 0.8)node[below right](n1){$n_1$}; \draw[<-] (add2.north) -- ++(0, 0.8)node[below right](n2){$n_2$}; \draw[->] (add1.east) -- (H1.west); \draw[->] (add2.east) -- (H2.west); \draw[->] (H1) -| (add.north); \draw[->] (H2) -| (add.south); \draw[->] (add.east) -- ++(0.7, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(G2.south-|x)+(-0.2, -0.3)$) ($(n1.north east-|add.east)+(0.2, 0.3)$)}, fill=black!10!white, draw, dashed, inner sep=0pt] (supersensor) {}; \node[below left] at (supersensor.north east) {Super Sensor}; \node[fit={($(G1.south west)+(-0.3, -0.1)$) ($(n1.north east)+(0.0, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor1) {}; \node[below right] at (sensor1.north west) {Sensor 1}; \node[fit={($(G2.south west)+(-0.3, -0.1)$) ($(n2.north east)+(0.0, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor2) {}; \node[below right] at (sensor2.north west) {Sensor 2}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:fusion_two_noisy_sensors #+caption: Fusion of two noisy sensors ([[./figs/fusion_two_noisy_sensors.png][png]], [[./figs/fusion_two_noisy_sensors.pdf][pdf]], [[./figs/fusion_two_noisy_sensors.tex][tex]]). #+RESULTS: [[file:figs/fusion_two_noisy_sensors.png]] * Fusion of two noisy sensors with perfect dynamics #+begin_src latex :file sensor_fusion_noisy_perfect_dyn.pdf :tangle figs/sensor_fusion_noisy_perfect_dyn.tex <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[addb, above right=1.2 and 1.8 of x](addn1){}; \node[addb, below right=1.2 and 1.8 of x](addn2){}; \node[block, above=0.5 of addn1](N1) {$N_1(s)$}; \node[block, above=0.5 of addn2](N2) {$N_2(s)$}; \node[block, right=1.2 of addn1](H1){$H_1(s)$}; \node[block, right=1.2 of addn2](H2){$H_2(s)$}; \node[addb, right=4.5 of x](add){}; \draw[] ($(x)+(-0.7, 0)$) node[above right]{$x$} -- (x.center); \draw[->] (x.center) |- (addn1.west); \draw[->] (x.center) |- (addn2.west); \draw[->] (addn1.east) -- (H1.west)node[above left]{$\hat{x}_1$}; \draw[->] (addn2.east) -- (H2.west)node[above left]{$\hat{x}_2$}; \draw[->] ($(N1.north)+(0,0.7)$) node[below right](n1){$\tilde{n}_1$} -- (N1.north); \draw[->] ($(N2.north)+(0,0.7)$) node[below right](n2){$\tilde{n}_2$} -- (N2.north); \draw[->] (N1.south) -- (addn1.north)node[above right]{$n_1$}; \draw[->] (N2.south) -- (addn2.north)node[above right]{$n_2$}; \draw[->] (H1.east) -| (add.north); \draw[->] (H2.east) -| (add.south); \draw[->] (add.east) -- ++(0.7, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(addn2.south-|x)+(-0.2, -0.4)$) ($(n1.north-|add.east)+(0.2, 0.3)$)}, fill=black!10!white, draw, dashed, inner sep=0pt] (supersensor) {}; \node[below left] at (supersensor.north east) {Super Sensor}; \node[block, fit={($(x|-addn1.south)+(0.2, -0.2)$) ($(n1.north-|N1.east)+(0.2, 0.1)$)}, fill=black!20!white, dashed, inner sep=0pt] (sensor1) {}; \node[below right] at (sensor1.north west) {Sensor 1}; \node[block, fit={($(x|-addn2.south)+(0.2, -0.2)$) ($(n2.north-|N2.east)+(0.2, 0.1)$)}, fill=black!20!white, dashed, inner sep=0pt] (sensor2) {}; \node[below right] at (sensor2.north west) {Sensor 2}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:sensor_fusion_noisy_perfect_dyn #+caption: Sensor fusion architecture with sensor dynamics uncertainty ([[./figs/sensor_fusion_noisy_perfect_dyn.png][png]], [[./figs/sensor_fusion_noisy_perfect_dyn.pdf][pdf]], [[./figs/sensor_fusion_noisy_perfect_dyn.tex][tex]]). #+RESULTS: [[file:figs/sensor_fusion_noisy_perfect_dyn.png]] * Fusion of two noisy sensors with sensors weights #+begin_src latex :file fusion_two_noisy_sensors_weights.pdf :tangle figs/fusion_two_noisy_sensors_weights.tex <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[block, above right=1 and 0.5 of x](G1){$G_1(s)$}; \node[block, below right=1 and 0.5 of x](G2){$G_2(s)$}; \node[addb, right=0.8 of G1](add1){}; \node[addb, right=0.8 of G2](add2){}; \node[block, above=0.5 of add1](N1){$N_1(s)$}; \node[block, above=0.5 of add2](N2){$N_2(s)$}; \node[block, right=0.9 of add1](H1){$H_1(s)$}; \node[block, right=0.9 of add2](H2){$H_2(s)$}; \node[addb, right=5 of x](add){}; \draw[] ($(x)+(-0.7, 0)$) node[above right]{$x$} -- (x.center); \draw[->] (x.center) |- (G1.west); \draw[->] (x.center) |- (G2.west); \draw[->] (G1.east) -- (add1.west); \draw[->] (G2.east) -- (add2.west); \draw[<-] (N1.north) -- ++(0, 0.6)node[below right](n1){$\tilde{n}_1$}; \draw[<-] (N2.north) -- ++(0, 0.6)node[below right](n2){$\tilde{n}_2$}; \draw[->] (N1.south) -- (add1.north)node[above right]{$n_1$}; \draw[->] (N2.south) -- (add2.north)node[above right]{$n_2$}; \draw[->] (add1.east) -- (H1.west); \draw[->] (add2.east) -- (H2.west); \draw[->] (H1) -| (add.north); \draw[->] (H2) -| (add.south); \draw[->] (add.east) -- ++(0.7, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(G2.south-|x)+(-0.2, -0.3)$) ($(n1.north east-|add.east)+(0.2, 0.3)$)}, fill=black!10!white, draw, dashed, inner sep=0pt] (supersensor) {}; \node[below left] at (supersensor.north east) {Super Sensor}; \node[fit={($(G1.south west)+(-0.3, -0.1)$) ($(n1.north-|N1.east)+(0.2, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor1) {}; \node[below right] at (sensor1.north west) {Sensor 1}; \node[fit={($(G2.south west)+(-0.3, -0.1)$) ($(n2.north-|N1.east)+(0.2, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor2) {}; \node[below right] at (sensor2.north west) {Sensor 2}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:fusion_two_noisy_sensors_weights #+caption: Fusion of two noisy sensors ([[./figs/fusion_two_noisy_sensors_weights.png][png]], [[./figs/fusion_two_noisy_sensors_weights.pdf][pdf]], [[./figs/fusion_two_noisy_sensors_weights.tex][tex]]). #+RESULTS: [[file:figs/fusion_two_noisy_sensors_weights.png]] * Sensor fusion architecture with sensor dynamics uncertainty #+begin_src latex :file sensor_fusion_dynamic_uncertainty.pdf :tangle figs/sensor_fusion_dynamic_uncertainty.tex <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[addb, above right=0.8 and 3.7 of x](add1){}; \node[addb, below right=0.8 and 3.7 of x](add2){}; \node[block, above left=0.2 and 0.1 of add1](delta1){$\Delta_1(s)$}; \node[block, above left=0.2 and 0.1 of add2](delta2){$\Delta_2(s)$}; \node[block, left=0.5 of delta1](W1){$w_1(s)$}; \node[block, left=0.5 of delta2](W2){$w_2(s)$}; \node[block, right=0.5 of add1](H1){$H_1(s)$}; \node[block, right=0.5 of add2](H2){$H_2(s)$}; \node[addb, right=5.8 of x](add){}; \draw[] ($(x)+(-0.7, 0)$) node[above right]{$x$} -- (x.center); \draw[->] (x.center) |- (add1.west); \draw[->] (x.center) |- (add2.west); \draw[->] ($(add1-|W1.west)+(-0.5, 0)$)node[branch](S1){} |- (W1.west); \draw[->] ($(add2-|W2.west)+(-0.5, 0)$)node[branch](S1){} |- (W2.west); \draw[->] (W1.east) -- (delta1.west); \draw[->] (W2.east) -- (delta2.west); \draw[->] (delta1.east) -| (add1.north); \draw[->] (delta2.east) -| (add2.north); \draw[->] (add1.east) -- (H1.west); \draw[->] (add2.east) -- (H2.west); \draw[->] (H1.east) -| (add.north); \draw[->] (H2.east) -| (add.south); \draw[->] (add.east) -- ++(0.7, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(add2.south-|x)+(-0.2, -0.4)$) ($(delta1.north-|add.east)+(0.2, 0.4)$)}, fill=black!10!white, draw, dashed, inner sep=0pt] (supersensor) {}; \node[below left] at (supersensor.north east) {Super Sensor}; \node[block, fit={($(W1.north-|S1)+(-0.2, 0.2)$) ($(add1.south east)+(0.2, -0.3)$)}, fill=black!20!white, dashed, inner sep=0pt] (sensor1) {}; \node[above right] at (sensor1.south west) {Sensor 1}; \node[block, fit={($(W2.north-|S1)+(-0.2, 0.2)$) ($(add2.south east)+(0.2, -0.3)$)}, fill=black!20!white, dashed, inner sep=0pt] (sensor2) {}; \node[above right] at (sensor2.south west) {Sensor 2}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:sensor_fusion_dynamic_uncertainty #+caption: Sensor fusion architecture with sensor dynamics uncertainty ([[./figs/sensor_fusion_dynamic_uncertainty.png][png]], [[./figs/sensor_fusion_dynamic_uncertainty.pdf][pdf]], [[./figs/sensor_fusion_dynamic_uncertainty.tex][tex]]). #+RESULTS: [[file:figs/sensor_fusion_dynamic_uncertainty.png]] * Sensor fusion architecture with sensor dynamics uncertainty and noise #+begin_src latex :file sensor_fusion_full.pdf :tangle figs/sensor_fusion_full.tex <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[addb, above right=1.2 and 3.7 of x](add1){}; \node[addb, below right=1.2 and 3.7 of x](add2){}; \node[block, above left=0.2 and 0.1 of add1](delta1){$\Delta_1(s)$}; \node[block, above left=0.2 and 0.1 of add2](delta2){$\Delta_2(s)$}; \node[block, left=0.5 of delta1](W1){$w_1(s)$}; \node[block, left=0.5 of delta2](W2){$w_2(s)$}; \node[addb, right=0.5 of add1](addn1){}; \node[addb, right=0.5 of add2](addn2){}; \node[block, above=0.5 of addn1](N1) {$N_1(s)$}; \node[block, above=0.5 of addn2](N2) {$N_2(s)$}; \node[block, right=1.2 of addn1](H1){$H_1(s)$}; \node[block, right=1.2 of addn2](H2){$H_2(s)$}; \node[addb, right=7.5 of x](add){}; \draw[] ($(x)+(-0.7, 0)$) node[above right]{$x$} -- (x.center); \draw[->] (x.center) |- (add1.west); \draw[->] (x.center) |- (add2.west); \draw[->] ($(add1-|W1.west)+(-0.5, 0)$)node[branch](S1){} |- (W1.west); \draw[->] ($(add2-|W2.west)+(-0.5, 0)$)node[branch](S2){} |- (W2.west); \draw[->] (W1.east) -- (delta1.west); \draw[->] (W2.east) -- (delta2.west); \draw[->] (delta1.east) -| (add1.north); \draw[->] (delta2.east) -| (add2.north); \draw[->] (add1.east) -- (addn1.west); \draw[->] (add2.east) -- (addn2.west); \draw[->] (addn1.east) -- (H1.west)node[above left]{$\hat{x}_1$}; \draw[->] (addn2.east) -- (H2.west)node[above left]{$\hat{x}_2$}; \draw[->] ($(N1.north)+(0,0.7)$) node[below right](n1){$\tilde{n}_1$} -- (N1.north); \draw[->] ($(N2.north)+(0,0.7)$) node[below right](n2){$\tilde{n}_2$} -- (N2.north); \draw[->] (N1.south) -- (addn1.north)node[above right]{$n_1$}; \draw[->] (N2.south) -- (addn2.north)node[above right]{$n_2$}; \draw[->] (H1.east) -| (add.north); \draw[->] (H2.east) -| (add.south); \draw[->] (add.east) -- ++(0.7, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(add2.south-|x)+(-0.2, -0.4)$) ($(n1.north-|add.east)+(0.2, 0.3)$)}, fill=black!10!white, draw, dashed, inner sep=0pt] (supersensor) {}; \node[below left] at (supersensor.north east) {Super Sensor}; \node[block, fit={($(S1|-add1.south)+(-0.2, -0.2)$) ($(n1.north-|N1.east)+(0.2, 0.1)$)}, fill=black!20!white, dashed, inner sep=0pt] (sensor1) {}; \node[below right] at (sensor1.north west) {Sensor 1}; \node[block, fit={($(S2|-add2.south)+(-0.2, -0.2)$) ($(n2.north-|N2.east)+(0.2, 0.1)$)}, fill=black!20!white, dashed, inner sep=0pt] (sensor2) {}; \node[below right] at (sensor2.north west) {Sensor 2}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:sensor_fusion_full #+caption: Sensor fusion architecture with sensor dynamics uncertainty ([[./figs/sensor_fusion_full.png][png]], [[./figs/sensor_fusion_full.pdf][pdf]], [[./figs/sensor_fusion_full.tex][tex]]). #+RESULTS: [[file:figs/sensor_fusion_full.png]] * Equivalent super sensor #+begin_src latex :file sensor_fusion_equivalent.pdf :tangle figs/sensor_fusion_equivalent.tex <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[block, above right=0.6 and 0.4 of x](Wss){$w_{ss}(s)$}; \node[block, right=0.5 of Wss](delta){$\Delta(s)$}; \node[addb](add) at ($(delta.east|-x) + (0.5, 0)$){}; \node[addb, right=0.5 of add](addn){}; \node[block](Nss) at (delta-|addn) {$N_{ss}(s)$}; \draw[] ($(x)+(-0.7, 0)$) node[above right]{$x$} -- (add.west); \draw[->] (x.center) |- (Wss); \draw[->] (Wss.east) -- (delta.west); \draw[->] (delta.east) -| (add.north); \draw[->] (add.east) -- (addn.west); \draw[->] ($(Nss.north)+(0,0.7)$) node[below right](nss){$\hat{n}$} -- (Nss.north); \draw[->] (Nss.south) -- (addn.north) node[above right]{$n$}; \draw[->] (addn.east) -- ++(1.1, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(add.south-|x)+(-0.2, -0.2)$) ($(Nss.east|-nss.north)+(0.2, 0.2)$)}, fill=black!10!white, draw, dashed, inner sep=0pt] (supersensor) {}; \node[below right] at (supersensor.north west) {Super Sensor}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:sensor_fusion_equivalent #+caption: Sensor fusion architecture with sensor dynamics uncertainty ([[./figs/sensor_fusion_equivalent.png][png]], [[./figs/sensor_fusion_equivalent.pdf][pdf]], [[./figs/sensor_fusion_equivalent.tex][tex]]). #+RESULTS: [[file:figs/sensor_fusion_equivalent.png]] * One sensor with noise #+begin_src latex :file one_sensor_noise.pdf :tangle figs/huddle_test.tex :exports both <> \begin{tikzpicture} \node[block] (G) at (0, 0) {$G(s)$}; \node[addb, right=0.8 of G] (add) {}; \draw[->] ($(G.west) + (-0.8, 0)$)node[above right]{$x$} -- (G.west); \draw[->] (G.east) -- (add.west); \draw[->] ($(add.north) + (0, 0.8)$)node[below right](n){$n$} -- (add.north); \draw[->] (add.east) -- ++(0.8, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(G.south west)+(-0.3, -0.1)$) ($(n.north east)+(0.0, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor) {}; \node[below right] at (sensor.north west) {Sensor}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:one_sensor_noise #+caption: One sensor with Noise ([[./figs/one_sensor_noise.png][png]], [[./figs/one_sensor_noise.pdf][pdf]], [[./figs/one_sensor_noise.tex][tex]]). #+RESULTS: [[file:figs/one_sensor_noise.png]] * One sensor with normalized noise #+begin_src latex :file one_sensor_normalized_noise.pdf :tangle figs/huddle_test.tex :exports both <> \begin{tikzpicture} \node[block] (G) at (0, 0) {$G(s)$}; \node[addb, right=0.8 of G] (add) {}; \node[block, above=0.6 of add] (N) {$N(s)$}; \draw[->] ($(G.west) + (-0.8, 0)$)node[above right]{$x$} -- (G.west); \draw[->] (G.east) -- (add.west); \draw[->] ($(N.north) + (0, 0.8)$)node[below right](ntilde){$\tilde{n}$} -- (N.north); \draw[->] (N.south) -- (add.north)node[above right](n){$n$}; \draw[->] (add.east) -- ++(1.0, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(G.south west)+(-0.3, -0.2)$) ($(ntilde.north-|N.east)+(0.2, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor) {}; \node[below right] at (sensor.north west) {Sensor}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:one_sensor_normalized_noise #+caption: One sensor with normalized noise ([[./figs/one_sensor_normalized_noise.png][png]], [[./figs/one_sensor_normalized_noise.pdf][pdf]], [[./figs/one_sensor_normalized_noise.tex][tex]]). #+RESULTS: [[file:figs/one_sensor_normalized_noise.png]] * One sensor with dynamic uncertainty #+begin_src latex :file one_sensor_dyn_uncertainty.pdf :tangle figs/huddle_test.tex :exports both <> \begin{tikzpicture} \node[branch] (x) at (0, 0) {}; \node[block, above right=0.4 and 0.4 of x](W){$w(s)$}; \node[block, right=0.4 of W](delta){$\Delta(s)$}; \node[addb](add) at ($(delta.east|-x) + (0.4, 0)$) {}; \node[block, right=0.5 of add](G){$G(s)$}; \draw[->] ($(x.west) + (-0.8, 0)$)node[above right]{$x$} -- (add.west); \draw[->] (x.center) |- (W.west); \draw[->] (W.east) -- (delta.west); \draw[->] (delta.east) -| (add.north); \draw[->] (add.east) -- (G.west); \draw[->] (G.east) -- ++(0.8, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(x.west|-G.south)+(-0.2, -0.2)$) ($(delta.north-|G.east)+(0.2, 0.2)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor) {}; \node[below left] at (sensor.north east) {Sensor}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:one_sensor_dyn_uncertainty #+caption: One sensor with dynamic uncertainty ([[./figs/one_sensor_dyn_uncertainty.png][png]], [[./figs/one_sensor_dyn_uncertainty.pdf][pdf]], [[./figs/one_sensor_dyn_uncertainty.tex][tex]]). #+RESULTS: [[file:figs/one_sensor_dyn_uncertainty.png]] * One sensor with dynamic uncertainty and noise #+begin_src latex :file one_sensor_dyn_uncertainty_noise.pdf :tangle figs/huddle_test.tex :exports both <> \begin{tikzpicture} \node[branch] (x) at (0, 0) {}; \node[block, above right=0.4 and 0.4 of x](W){$w(s)$}; \node[block, right=0.4 of W](delta){$\Delta(s)$}; \node[addb](add) at ($(delta.east|-x) + (0.4, 0)$) {}; \node[block, right=0.5 of add](G){$G(s)$}; \node[addb, right=0.5 of G] (addn) {}; \draw[->] ($(x.west) + (-0.8, 0)$)node[above right]{$x$} -- (add.west); \draw[->] (x.center) |- (W.west); \draw[->] (W.east) -- (delta.west); \draw[->] (delta.east) -| (add.north); \draw[->] (add.east) -- (G.west); \draw[->] (G.east) -- (addn.west); \draw[->] ($(addn.north)+(0, 0.8)$) node[below right]{$n$} -- (addn.north); \draw[->] (addn.east) -- ++(0.8, 0) node[above left]{$\hat{x}$}; \begin{scope}[on background layer] \node[fit={($(x.west|-G.south)+(-0.2, -0.2)$) ($(delta.north-|addn.east)+(0.2, 0.2)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor) {}; \node[above right] at (sensor.south west) {Sensor}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:one_sensor_dyn_uncertainty_noise #+caption: One sensor with dynamic uncertainty ([[./figs/one_sensor_dyn_uncertainty_noise.png][png]], [[./figs/one_sensor_dyn_uncertainty_noise.pdf][pdf]], [[./figs/one_sensor_dyn_uncertainty_noise.tex][tex]]). #+RESULTS: [[file:figs/one_sensor_dyn_uncertainty_noise.png]] * Huddle Test #+begin_src latex :file huddle_test.pdf :tangle figs/huddle_test.tex :exports both <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[block, above right=0.5 and 0.5 of x](G1){$G_1(s)$}; \node[block, below right=0.5 and 0.5 of x](G2){$G_2(s)$}; \node[addb, right=0.8 of G1](add1){}; \node[addb, right=0.8 of G2](add2){}; \draw[] ($(x)+(-0.7, 0)$) node[above right]{$x$} -- (x.center); \draw[->] (x.center) |- (G1.west); \draw[->] (x.center) |- (G2.west); \draw[->] (G1.east) -- (add1.west); \draw[->] (G2.east) -- (add2.west); \draw[<-] (add1.north) -- ++(0, 0.8)node[below right](n1){$n_1$}; \draw[<-] (add2.north) -- ++(0, 0.8)node[below right](n2){$n_2$}; \draw[->] (add1.east) -- ++(1, 0)node[above left]{$\hat{x}_1$}; \draw[->] (add2.east) -- ++(1, 0)node[above left]{$\hat{x}_2$}; \begin{scope}[on background layer] % \node[fit={($(G2.south-|x)+(-0.2, -0.3)$) ($(n1.north east-|add.east)+(0.2, 0.3)$)}, fill=black!10!white, draw, dashed, inner sep=0pt] (supersensor) {}; % \node[below left] at (supersensor.north east) {Super Sensor}; \node[fit={($(G1.south west)+(-0.3, -0.1)$) ($(n1.north east)+(0.0, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor1) {}; \node[below right] at (sensor1.north west) {Sensor 1}; \node[fit={($(G2.south west)+(-0.3, -0.1)$) ($(n2.north east)+(0.0, 0.1)$)}, fill=black!20!white, draw, dashed, inner sep=0pt] (sensor2) {}; \node[below right] at (sensor2.north west) {Sensor 2}; \end{scope} \end{tikzpicture} #+end_src #+name: fig:huddle_test #+caption: Huddle Test ([[./figs/huddle_test.png][png]], [[./figs/huddle_test.pdf][pdf]], [[./figs/huddle_test.tex][tex]]). #+RESULTS: [[file:figs/huddle_test.png]] * Uncertainty to Phase and Gain variation #+begin_src latex :file uncertainty_gain_phase_variation.pdf :tangle figs/uncertainty_gain_phase_variation.tex :exports both \begin{tikzpicture} % Uncertainty Circle \node[circle, draw, fill=black!20!white] (c) at (4.5, 0)[minimum size=2cm]{}; % Real and Imaginary Axis \draw[->] (-0.5, 0) -- (6.2, 0) node[below left]{Re}; \draw[->] (0, -0.5) -- (0, 1) node[below left]{Im}; % X = 1 \node[branch] (1) at (4.5, 0){}; \node[below] at (1){$1$}; \draw[dashed] (0, 0)coordinate(A) -- (tangent cs:node=c,point={(0, 0)},solution=2)coordinate(B) -- node[midway, right]{$\epsilon$} (1); \draw[dashed] (2, 0) arc (0:23:1) node[midway, right]{$\Delta \phi$}; \end{tikzpicture} #+end_src #+name: fig:uncertainty_gain_phase_variation #+caption: Uncertainty to Phase and Gain variation ([[./figs/uncertainty_gain_phase_variation.png][png]], [[./figs/uncertainty_gain_phase_variation.pdf][pdf]], [[./figs/uncertainty_gain_phase_variation.tex][tex]]). #+RESULTS: [[file:figs/uncertainty_gain_phase_variation.png]] * Fusion of two noisy signals #+begin_src latex :file fusion_two_signals.pdf :tangle figs/fusion_two_signals.tex \begin{tikzpicture} \node[addb] (add) at (0, 0){}; \node[block, above left=0.5 and 0.8 of add] (H1) {$H_1$}; \node[block, below left=0.5 and 0.8 of add] (H2) {$H_2$}; \draw[->] ($(H1.west)+(-1.5, 0)$)node[above right]{$x + n_1$} -- (H1.west); \draw[->] ($(H2.west)+(-1.5, 0)$)node[above right]{$x + n_2$} -- (H2.west); \draw[->] (H1) -| (add.north); \draw[->] (H2) -| (add.south); \draw[->] (add.east) -- ++(1, 0) node[above left]{$\hat{x}$}; \end{tikzpicture} #+end_src #+name: fig:fusion_two_signals #+caption: Fusion of two noisy sensors ([[./figs/fusion_two_signals.png][png]], [[./figs/fusion_two_signals.pdf][pdf]], [[./figs/fusion_two_signals.tex][tex]]). #+RESULTS: [[file:figs/fusion_two_signals.png]] * Fusion of two noisy sensors with Dynamics #+begin_src latex :file fusion_two_noisy_sensors_with_dyn.pdf :tangle figs/fusion_two_noisy_sensors_with_dyn.tex \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[block, above right=1.5 and 0.5 of x](G1){$G_1$}; \node[block, below right=1.5 and 0.5 of x](G2){$G_2$}; \node[addb, right=1 of G1](add1){}; \node[addb, right=1 of G2](add2){}; \node[block, above=0.5 of add1](W1){$W_1$}; \node[block, above=0.5 of add2](W2){$W_2$}; \node[block, right=1 of add1](H1){$H_1$}; \node[block, right=1 of add2](H2){$H_2$}; \node[addb, right=6 of x](add){}; \draw[] ($(x)+(-1, 0)$) node[above right]{$x$} -- (x); \draw[->] (x) |- (G1.west); \draw[->] (x) |- (G2.west); \draw[->] (G1.east) -- (add1.west); \draw[->] (G2.east) -- (add2.west); \draw[->] (W1.south) -- (add1.north); \draw[->] (W2.south) -- (add2.north); \draw[<-] (W1.north) -- ++(0, 0.8)node[below right]{$n_1$}; \draw[<-] (W2.north) -- ++(0, 0.8)node[below right]{$n_2$}; \draw[->] (add1.east) -- (H1.west); \draw[->] (add2.east) -- (H2.west); \draw[->] (H1) -| (add.north); \draw[->] (H2) -| (add.south); \draw[->] (add.east) -- ++(1, 0) node[above left]{$\hat{x}$}; \end{tikzpicture} #+end_src #+name: fig:fusion_two_noisy_sensors_with_dyn #+caption: Fusion of two noisy sensors_with_dyn ([[./figs/fusion_two_noisy_sensors_with_dyn.png][png]], [[./figs/fusion_two_noisy_sensors_with_dyn.pdf][pdf]], [[./figs/fusion_two_noisy_sensors_with_dyn.tex][tex]]). #+RESULTS: [[file:figs/fusion_two_noisy_sensors_with_dyn.png]] * Fusion of two noisy sensors with Dynamics - Bis #+begin_src latex :file fusion_two_noisy_sensors_with_dyn_bis.pdf :tangle figs/fusion_two_noisy_sensors_with_dyn_bis.tex \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[block, above right=0.5 and 0.5 of x](G1){$G_1$}; \node[block, below right=0.5 and 0.5 of x](G2){$G_2$}; \node[addb, right=1 of G1](add1){}; \node[addb, right=1 of G2](add2){}; \node[block, right=1 of add1](H1){$H_1$}; \node[block, right=1 of add2](H2){$H_2$}; \node[addb, right=6 of x](add){}; \draw[] ($(x)+(-1, 0)$) node[above right]{$x$} -- (x); \draw[->] (x) |- (G1.west); \draw[->] (x) |- (G2.west); \draw[->] (G1.east) -- (add1.west); \draw[->] (G2.east) -- (add2.west); \draw[<-] (add1.north) -- ++(0, 0.8)node[below right]{$n_1$}; \draw[<-] (add2.north) -- ++(0, 0.8)node[below right]{$n_2$}; \draw[->] (add1.east) -- (H1.west); \draw[->] (add2.east) -- (H2.west); \draw[->] (H1) -| (add.north); \draw[->] (H2) -| (add.south); \draw[->] (add.east) -- ++(1, 0) node[above left]{$\hat{x}$}; \end{tikzpicture} #+end_src #+name: fig:fusion_two_noisy_sensors_with_dyn_bis #+caption: Fusion of two noisy sensors_with_dyn_bis ([[./figs/fusion_two_noisy_sensors_with_dyn_bis.png][png]], [[./figs/fusion_two_noisy_sensors_with_dyn_bis.pdf][pdf]], [[./figs/fusion_two_noisy_sensors_with_dyn_bis.tex][tex]]). #+RESULTS: [[file:figs/fusion_two_noisy_sensors_with_dyn_bis.png]] * Fusion of two sensors with mismatch dynamics #+begin_src latex :file fusion_gain_mismatch.pdf :tangle figs/fusion_gain_mismatch.tex <> \begin{tikzpicture} \node[branch] (x) at (0, 0); \node[addb, above right=1 and 3.5 of x](add1){}; \node[addb, below right=1 and 3.5 of x](add2){}; \node[block, above left= of add1](delta1){$\Delta_1$}; \node[block, above left= of add2](delta2){$\Delta_2$}; \node[block, left= of delta1](W1){$W_1$}; \node[block, left= of delta2](W2){$W_2$}; \node[block, right= of add1](H1){$H_1$}; \node[block, right= of add2](H2){$H_2$}; \node[addb, right=5.5 of x](add){}; \draw[] ($(x)+(-1, 0)$) node[above right]{$x$} -- (x); \draw[->] (x) |- (add1.west); \draw[->] (x) |- (add2.west); \draw[->] ($(add1-|W1.west)+(-0.5, 0)$)node[branch]{} |- (W1.west); \draw[->] ($(add2-|W2.west)+(-0.5, 0)$)node[branch]{} |- (W2.west); \draw[->] (W1.east) -- (delta1.west); \draw[->] (W2.east) -- (delta2.west); \draw[->] (delta1.east) -| (add1.north); \draw[->] (delta2.east) -| (add2.north); \draw[->] (add1.east) -- (H1.west); \draw[->] (add2.east) -- (H2.west); \draw[->] (H1.east) -| (add.north); \draw[->] (H2.east) -| (add.south); \draw[->] (add.east) -- ++(1, 0) node[above left]{$\hat{x}$}; \end{tikzpicture} #+end_src #+name: fig:fusion_gain_mismatch #+caption: Fusion of two noisy sensors_with_dyn ([[./figs/fusion_gain_mismatch.png][png]], [[./figs/fusion_gain_mismatch.pdf][pdf]], [[./figs/fusion_gain_mismatch.tex][tex]]). #+RESULTS: [[file:figs/fusion_gain_mismatch.png]] * Architecture used for $\mathcal{H}_\infty$ synthesis of complementary filters #+begin_src latex :file h_infinity_robust_fusion.pdf :tangle figs/h_infinity_robust_fusion.tex :exports both <> \begin{tikzpicture} \node[block={4.0cm}{2.5cm}, fill=black!20!white, dashed] (P) {}; \node[above] at (P.north) {$P(s)$}; \coordinate[] (inputw) at ($(P.south west)!0.75!(P.north west) + (-0.7, 0)$); \coordinate[] (inputu) at ($(P.south west)!0.35!(P.north west) + (-0.7, 0)$); \coordinate[] (output1) at ($(P.south east)!0.75!(P.north east) + ( 0.7, 0)$); \coordinate[] (output2) at ($(P.south east)!0.35!(P.north east) + ( 0.7, 0)$); \coordinate[] (outputv) at ($(P.south east)!0.1!(P.north east) + ( 0.7, 0)$); \node[block, left=1.4 of output1] (W1){$W_1(s)$}; \node[block, left=1.4 of output2] (W2){$W_2(s)$}; \node[addb={+}{}{}{}{-}, left=of W1] (sub) {}; \node[block, below=0.3 of P] (H2) {$H_2(s)$}; \draw[->] (inputw) node[above right]{$w$} -- (sub.west); \draw[->] (H2.west) -| ($(inputu)+(0.35, 0)$) node[above]{$u$} -- (W2.west); \draw[->] (inputu-|sub) node[branch]{} -- (sub.south); \draw[->] (sub.east) -- (W1.west); \draw[->] ($(sub.west)+(-0.6, 0)$) node[branch]{} |- ($(outputv)+(-0.35, 0)$) node[above]{$v$} |- (H2.east); \draw[->] (W1.east) -- (output1)node[above left]{$z_1$}; \draw[->] (W2.east) -- (output2)node[above left]{$z_2$}; \end{tikzpicture} #+end_src #+name: fig:h_infinity_robust_fusion #+caption: Architecture used for $\mathcal{H}_\infty$ synthesis of complementary filters ([[./figs/h_infinity_robust_fusion.png][png]], [[./figs/h_infinity_robust_fusion.pdf][pdf]], [[./figs/h_infinity_robust_fusion.tex][tex]]). #+RESULTS: [[file:figs/h_infinity_robust_fusion.png]] * H-Infinity - Optimal Complementary Filters #+begin_src latex :file h_infinity_optimal_comp_filters.pdf :tangle figs/h_infinity_optimal_comp_filters.tex <> \begin{tikzpicture} \node[block={5.0cm}{3.0cm}, fill=black!20!white, dashed] (P) {}; \node[above] at (P.north) {$P$}; \coordinate[] (inputn1) at ($(P.south west)!0.8!(P.north west) + (-\cdist, 0)$); \coordinate[] (inputn2) at ($(P.south west)!0.5!(P.north west) + (-\cdist, 0)$); \coordinate[] (inputu) at ($(P.south west)!0.2!(P.north west) + (-\cdist, 0)$); \coordinate[] (outputx) at ($(P.south east)!0.5!(P.north east) + ( \cdist, 0)$); \coordinate[] (outputv) at ($(P.south east)!0.1!(P.north east) + ( \cdist, 0)$); \node[block, right=1.5 of inputn1] (N1){$N_1$}; \node[block, right=1.5 of inputn2] (N2){$N_2$}; \node[addb={+}{}{}{}{-}, right=of N1] (sub) {}; \node[addb, right=2 of N2] (add) {}; \node[block, below=of P] (H1) {$H_1$}; \draw[->] (inputn1)node[above right]{$\tilde{n}_1$} -- (N1.west); \draw[->] (inputn2)node[above right]{$\tilde{n}_2$} -- (N2.west); \draw[->] (N1) -- (sub.west); \draw[->] (N2) -| (sub.south); \draw[->] (N2-|sub.south) node[branch]{} -- (add.west); \draw[->] (sub.east) -- ++(0.5, 0) |- ($(outputv) + (-0.3, 0)$) |- (H1.east); \draw[->] (H1.west) -| ($(inputu) + (0.3, 0)$) -| (add.south); \draw[->] (add.east) -- (outputx) node[above left]{$\hat{x}$}; \end{tikzpicture} #+end_src #+name: fig:h_infinity_optimal_comp_filters #+caption: H-Infinity - Optimal Complementary Filters ([[./figs/h_infinity_optimal_comp_filters.png][png]], [[./figs/h_infinity_optimal_comp_filters.pdf][pdf]], [[./figs/h_infinity_optimal_comp_filters.tex][tex]]). #+RESULTS: [[file:figs/h_infinity_optimal_comp_filters.png]] * H-Infinity - Optimal Complementary Filters - Alternative #+begin_src latex :file h_infinity_optimal_comp_filters_bis.pdf :tangle figs/h_infinity_optimal_comp_filters_bis.tex :exports both <> \begin{tikzpicture} \node[block={4.0cm}{2.5cm}, fill=black!20!white, dashed] (P) {}; \node[above] at (P.north) {$P(s)$}; \coordinate[] (inputw) at ($(P.south west)!0.75!(P.north west) + (-0.7, 0)$); \coordinate[] (inputu) at ($(P.south west)!0.35!(P.north west) + (-0.7, 0)$); \coordinate[] (output1) at ($(P.south east)!0.75!(P.north east) + ( 0.7, 0)$); \coordinate[] (output2) at ($(P.south east)!0.35!(P.north east) + ( 0.7, 0)$); \coordinate[] (outputv) at ($(P.south east)!0.1!(P.north east) + ( 0.7, 0)$); \node[block, left=1.4 of output1] (N1){$N_1(s)$}; \node[block, left=1.4 of output2] (N2){$N_2(s)$}; \node[addb={+}{}{}{}{-}, left=of N1] (sub) {}; \node[block, below=0.3 of P] (H2) {$H_2(s)$}; \draw[->] (inputw) node[above right]{$w$} -- (sub.west); \draw[->] (H2.west) -| ($(inputu)+(0.35, 0)$) node[above]{$u$} -- (N2.west); \draw[->] (inputu-|sub) node[branch]{} -- (sub.south); \draw[->] (sub.east) -- (N1.west); \draw[->] ($(sub.west)+(-0.6, 0)$) node[branch]{} |- ($(outputv)+(-0.35, 0)$) node[above]{$v$} |- (H2.east); \draw[->] (N1.east) -- (output1)node[above left]{$z_1$}; \draw[->] (N2.east) -- (output2)node[above left]{$z_2$}; \end{tikzpicture} #+end_src #+name: fig:h_infinity_optimal_comp_filters_bis #+caption: Architecture used for $\mathcal{H}_\infty$ synthesis of complementary filters ([[./figs/h_infinity_optimal_comp_filters_bis.png][png]], [[./figs/h_infinity_optimal_comp_filters_bis.pdf][pdf]], [[./figs/h_infinity_optimal_comp_filters_bis.tex][tex]]). #+RESULTS: [[file:figs/h_infinity_optimal_comp_filters_bis.png]] * Mixed H2/H-Infinity Synthesis #+begin_src latex :file mixed_h2_hinf_synthesis.pdf :tangle figs/mixed_h2_hinf_synthesis.tex :exports both \begin{tikzpicture} % Blocs \node[block={2.0cm}{2.0cm}] (P) {$P$}; \node[block={1.5cm}{1.2cm}, below=0.7 of P] (K) {$K$}; % Input and outputs coordinates \coordinate[] (inputw) at ($(P.north west)!0.25!(P.south west)$); \coordinate[] (inputu) at ($(P.north west)!0.75!(P.south west)$); \coordinate[] (outputzinf) at ($(P.north east)!0.1!(P.south east)$); \coordinate[] (outputz2) at ($(P.north east)!0.4!(P.south east)$); \coordinate[] (outputv) at ($(P.north east)!0.75!(P.south east)$); % Connections and labels \draw[<-] (inputw) -- ++(-1.0, 0) node[above left]{$w$}; \draw[<-] (inputu) -- ++(-0.8, 0) |- node[near start, left]{$u$} (K.west); \draw[->] (outputzinf) -- ++(1.0, 0) node[above right]{$z_\infty$}; \draw[->] (outputz2) -- ++(1.0, 0) node[above right]{$z_2$}; \draw[->] (outputv) -- ++(0.8, 0) |- node[near start, right]{$v$} (K.east); \end{tikzpicture} #+end_src #+name: fig:mixed_h2_hinf_synthesis #+caption: Mixed H2/H-Infinity Synthesis ([[./figs/mixed_h2_hinf_synthesis.png][png]], [[./figs/mixed_h2_hinf_synthesis.pdf][pdf]], [[./figs/mixed_h2_hinf_synthesis.tex][tex]]). #+RESULTS: [[file:figs/mixed_h2_hinf_synthesis.png]]