[足式機器人]Part4 南科大高等機器人控制課 Ch05 Instantaneous Velocity of Moving Frames

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B站：CLEAR_LAB
筆者帶更新-運動學
課程主講教師：
Prof. Wei Zhang

南科大高等機器人控制課 Ch05 Instantaneous Velocity of Moving Frames

1.Instantanenous Velocity of Rotating Frames
2.Instantanenous Velocity of Moving Frames
3.Review/Summary of Rigid Body Velocity & Operation

Given Frame trajectory $\left[ T \right] \left( t \right) =\left( \left[ Q \right] \left( t \right) ,\vec{R}_p\left( t \right) \right)$ wrt $\left\{ O \right\}$
在這里插入圖片描述
Question : What is the velocity (twist/spatial velocity) of frame at time $t$
$\left[ T \right] \left( t \right) \in \mathbb{R} ^{4\times 4}$ : $4\times 4$ matrix $SE\left( 3 \right)$
$\log \left( \left[ T \right] \left( t \right) \right) \rightarrow \mathcal{S} \theta$ : is $\mathcal{S}$ (unit) the velocity of $\left[ T \right] \left( t \right)$ ? —— no

$\vec{R}_p\left( t \right)$ : position vector ; $\dot{\vec{R}}_p\left( t \right)$ velocity vector;
$\mathcal{S} \theta \leftrightarrow \left[ T \right] \left( t \right)$ : position coordination (what velocity?—— $\left[ \dot{T} \right] \left( t \right)$ ?)
$\left[ \dot{T} \right] \left( t \right) \in \mathbb{R} ^{4\times 4}\notin SE\left( 3 \right)$

1.Instantanenous Velocity of Rotating Frames

$\left\{ A \right\}$ frame is rotating with orientation $\left[ Q_A \right] \left( t \right)$ and velocity $\vec{\omega}_A\left( t \right)$ at time $t$ (Note: everything is wrt $\left\{ O \right\}$ frame)

Let $\hat{\omega}\theta =\log \left( \left[ Q_A \right] \left( t \right) \right)$ can be obtained from the reference frame (say $\left\{ O \right\}$ frame) by rotating about $\hat{\omega}$ by $\theta$ degree

$\hat{\omega}\theta$ only describes the current orientation of $\left\{ A \right\}$ relative to $\left\{ O \right\}$ , it does not contain info about how the frame is rotating at time $t$

What is the relation between $\vec{\omega}_A\left( t \right)$ and $\left[ Q_A \right] \left( t \right)$
$\frac{\mathrm{d}}{\mathrm{d}t}\left[ Q_A \right] \left( t \right) =\tilde{\vec{\omega}}_A\left( t \right) \left[ Q_A \right] \left( t \right) \Rightarrow \tilde{\vec{\omega}}_A\left( t \right) =\left[ \dot{Q}_A \right] \left( t \right) \left[ Q_A \right] ^{-1}\left( t \right) 1$

What is $\vec{\omega}_{\mathrm{A}}^{A}$ ?
$\vec{\omega}_{\mathrm{A}}^{A}=\left[ Q_{\mathrm{O}}^{A} \right] \vec{\omega}_{\mathrm{A}}^{O}$
velocity of $A$ relative to $\left\{ O \right\}$ , expressed in $\left\{ A \right\}$
$\tilde{\vec{\omega}}_{\mathrm{A}}^{A}=\widetilde{\left[ Q_{\mathrm{O}}^{A} \right] \vec{\omega}_{\mathrm{A}}^{O}}=\left[ Q_{\mathrm{O}}^{A} \right] \tilde{\vec{\omega}}_{\mathrm{A}}^{O}\left[ Q_{\mathrm{O}}^{A} \right] ^{\mathrm{T}}=\left[ Q_{\mathrm{O}}^{A} \right] \left[ \dot{Q}_{\mathrm{A}}^{O} \right] \left[ Q_{\mathrm{A}}^{O} \right] ^{-1}\left[ Q_{\mathrm{O}}^{A} \right] ^{\mathrm{T}}=\left[ Q_{\mathrm{O}}^{A} \right] \left[ \dot{Q}_{\mathrm{A}}^{O} \right] =\left[ Q_{\mathrm{A}}^{O} \right] ^{-1}\left[ \dot{Q}_{\mathrm{A}}^{O} \right]$

2.Instantanenous Velocity of Moving Frames

$\left\{ A \right\}$ moving frame with configuration $\left[ T_A \right] \left( t \right)$ at t ime $t$ undergoes a rigid body motion with velocity $\mathcal{V} _A\left( t \right) =\left( \vec{\omega},\vec{v} \right)$ (Note: everything is wrt $\left\{ O \right\}$ frame)

The exponential coordinate $\hat{\mathcal{S}}\left( t \right) \theta \left( t \right) =\log \left( \left[ T_A \right] \left( t \right) \right)$ only indicates the current configuration of $\left\{ A \right\}$ , and does not tell us about how the frame is moving at time $t$

What is the relation between $\mathcal{V} _A\left( t \right)$ and $\left[ T_A \right] \left( t \right)$ ?
$\frac{\mathrm{d}}{\mathrm{d}t}\left[ T_A \right] \left( t \right) =\left[ \mathcal{V} _A \right] \left( t \right) \left[ T_A \right] \left( t \right) \Rightarrow \left[ \mathcal{V} _A \right] \left( t \right) =\left[ \dot{T}_A \right] \left( t \right) \left[ T_A \right] ^{-1}\left( t \right)$

3.Review/Summary of Rigid Body Velocity & Operation

spatial velocity / twist $\mathcal{V} =\left[ \begin{array}{c} \vec{\omega}\\ \vec{v}_{\mathrm{O}}\\ \end{array} \right]$ , $\vec{v}_{\mathrm{O}}$ reference point $O$ may/may not move with the body
$\vec{\omega}$ : angular velocity
$\vec{v}_{\mathrm{O}}$ : velocity of the body-fixed partical currently coincides with $O$
Given $\mathcal{V} =\left[ \begin{array}{c} \vec{\omega}\\ \vec{v}_{\mathrm{O}}\\ \end{array} \right]$ , any body fixed point $P$ , its velocity is $\vec{v}_{\mathrm{P}}=\vec{v}_{\mathrm{O}}+\vec{\omega}\times \vec{R}_{\mathrm{OP}}$
Twist in frames : Given frame $\left\{ B \right\}$ , $\left\{ O \right\}$ with relation
$\mathcal{V} ^O=\left[ \begin{array}{c} \vec{\omega}^O\\ \vec{v}_{\mathrm{O}}^{O}\\ \end{array} \right] ,\mathcal{V} ^B=\left[ \begin{array}{c} \vec{\omega}^B\\ \vec{v}_{\mathrm{O}}^{B}\\ \end{array} \right]$ —— $\mathcal{V}$ is a twist of some rigid body
$\mathcal{V} ^O=\left[ X_{\mathrm{B}}^{O} \right] \mathcal{V} ^B$ —— change of coordinate for twist $\left[ X_{\mathrm{B}}^{O} \right] \in \mathbb{R} ^{6\times 6}$
$\left[ X_{\mathrm{B}}^{O} \right] \in \mathbb{R} ^{6\times 6}\left[ X_{\mathrm{B}}^{O} \right] =\left[ \begin{matrix} \left[ Q_{\mathrm{B}}^{O} \right]& 0\\ \tilde{\vec{R}}_{\mathrm{B}}^{O}\left[ Q_{\mathrm{B}}^{O} \right]& \left[ Q_{\mathrm{B}}^{O} \right]\\ \end{matrix} \right]$
For given $\left[ T \right] =\left( \left[ Q \right] ,\vec{R} \right) \Rightarrow \left[ X \right] =\left[ Ad_T \right] =\left[ \begin{matrix} \left[ Q \right]& 0\\ \tilde{\vec{R}}\left[ Q \right]& \left[ Q \right]\\ \end{matrix} \right]$
screw axis : $\mathcal{S} =\left( \hat{s},\vec{R}_{\mathrm{q}},h \right) \leftrightarrow \left[ \begin{array}{c} \vec{\omega}\\ \vec{v}\\ \end{array} \right] =\left[ \begin{array}{c} \hat{s}\\ h\hat{s}-\hat{s}\times \vec{R}_{\mathrm{q}}\\ \end{array} \right]$
Al rigid body motion can be "thought of " screw motion rotation & linear motion along the axis
we typically write $\mathcal{V} =\mathcal{S} \dot{\theta}$ ( $\mathcal{S}$ - ‘unit’ normalized twist)
rotation operation / Exp coordinate (wrt $\left\{ O \right\}$ )
OED for rotation : $\dot{\vec{R}}_{\mathrm{p}}=\vec{\omega}\times \vec{R}_{\mathrm{p}}=\tilde{\vec{\omega}}\vec{R}_{\mathrm{p}}\Rightarrow \vec{R}_{\mathrm{p}}\left( t \right) =e^{\tilde{\vec{\omega}}t}\vec{R}_{\mathrm{p}}\left( 0 \right) ,so\left( 3 \right) =\left\{ \tilde{\vec{\omega}}:\vec{\omega}\in \mathbb{R} ^3 \right\}$
if $\vec{\omega}=\hat{\omega}$ , unit vector , $t=\theta$ , $\hat{\omega}\theta \leftrightarrow \left[ Q \right] =e^{\tilde{\vec{\omega}}\theta}\in SO\left( 3 \right)$ , $\hat{\omega}\theta$ os calld exponention cooedinate of $\left[ Q \right]$ denoted $\log \left( \left[ Q \right] \right)$
$\vec{R}_{\mathrm{p}^{\prime}}=e^{\tilde{\vec{\omega}}\theta}\vec{R}_{\mathrm{p}}$
Given a frame $\left\{ A \right\}$ , $\left[ Q_A \right] =\left[ \hat{x}_A,\hat{y}_A,\hat{z}_A \right]$ then
$\left[ Q \right] \left[ Q_A \right] =e^{\tilde{\vec{\omega}}\theta}\left[ Q_A \right]$ : $\left[ Q \right]$ action operation , means rotate $\left[ Q_A \right]$ about $\hat{\omega}$ by $\theta$ degree
Experssion of rotation operator $\left[ Q \right]$ in $\left\{ O \right\}$ and $\left\{ B \right\}$ : $\left[ Q \right]$ in $\left\{ O \right\}$ ; $\left[ Q_{\mathrm{B}}^{O} \right] ^{-1}\left[ Q \right] \left[ Q_{\mathrm{B}}^{O} \right]$ same rotation operator in $\left\{ B \right\}$
Rigid body transformation and exp coordinate(wrt $\left\{ O \right\}$ )
ODE : $\dot{\vec{R}}_{\mathrm{p}}=\vec{v}+\vec{\omega}\times \vec{R}_{\mathrm{p}}\Rightarrow \left[ \begin{array}{c} \dot{\vec{R}}_{\mathrm{p}}\\ 0\\ \end{array} \right] =\left. \left[ \begin{matrix} \tilde{\vec{\omega}}& \vec{v}\\ 0& 0\\ \end{matrix} \right] \right|_{4\times 4}\left[ \begin{array}{c} \vec{R}_{\mathrm{p}}\\ 1\\ \end{array} \right] \Rightarrow \left[ \begin{array}{c} \dot{\vec{R}}_{\mathrm{p}}\\ 0\\ \end{array} \right] =e^{\left[ \mathcal{V} \right] t}\left[ \begin{array}{c} \vec{R}_{\mathrm{p}}\\ 1\\ \end{array} \right]$ $e^{\left[ \mathcal{V} \right] t}$ - matrix representation of $\mathcal{V}$ , $se\left( 3 \right) =\left\{ \left[ \mathcal{V} \right] ,\mathcal{V} \in \mathbb{R} ^6 \right\}$

$\hat{\mathcal{S}}\theta$ is the exp coordinate of $\left[ T \right]$
$\left[ \begin{array}{c} \vec{R}_{\mathrm{p}^{\prime}}\\ 1\\ \end{array} \right] =\left[ T \right] \left[ \begin{array}{c} \vec{R}_{\mathrm{p}}\\ 1\\ \end{array} \right]$
$\left[ T \right] \left[ T_A \right]$ : rotate frame $\left\{ A \right\}$ about screw axis $\hat{\mathcal{S}}$ by $\theta$ degree
rigid operation of screw axis
$\mathcal{S} ^{\prime}=\left[ Ad_T \right] \mathcal{S}$ means rotate about axis $\mathcal{S}$ along $\hat{\mathcal{S}}$ by $\theta$ degree
expression of $\left[ T \right]$ in $\left\{ B \right\}$ : $\left[ T_{\mathrm{B}} \right] ^{-1}\left[ T \right] \left[ T_{\mathrm{B}} \right]$
velocity of moving frame $\left[ T \right] \left( t \right)$ : $\left[ \mathcal{V} \right] =\left[ \dot{T} \right] \left[ T \right] ^{-1}$