User:Jouvencel

Control command based of quaternions

Files :

- stabilization_attitude_quat_int.c (.h)

- stabilization_attitude_ref_quat_int.c (.h)

- quat_setpoint_int.c (.h)

• Position in the autopilot structure

• Control structure

note : (${\displaystyle 2^{''N''}}$) number of decimals for integer calculus

• Comments

- "stab_att_sp_quat (15)" attitude to reach

- "stab_att_ref_accel(12)", "stab_att_ref_rate(16)","stab_att_ref_quat(15)" references défined by two order model

- stabilization_cmd[X] (X=ROLL, PITCH, YAW) commands défined by a feedforward part and feedback part, feedback part is based on PID

- quaternions define the orientation of rotorcraft,

- the error between the quat_sp and the quat_ref is computed by a quaternion product,

- the dot_quaternion is computed by the formula ${\displaystyle {\frac {1}{2}}M_{s}(p,q,r)Q}$

- The second order model :

-- Integrates accelerate to obtain "stab_att_ref_rate" by the Euler method

-- Integrates rate to obtain "stab_att_ref_quat" by the Euler method

-- The Euler method uses dt. Here dt is implicite and equal 1/512 or ${\displaystyle 2^{9}}$,

-- Determines the stab_att_ref_accel(12) by a second order ${\displaystyle {\frac {\Omega ^{2}}{s^{2}+2\mathrm {Z} \Omega s+\Omega ^{2}}}}$ with ${\displaystyle \Omega =200*\pi /180}$ and ${\displaystyle \mathrm {Z} =0.9}$.${\displaystyle \Omega }$ and ${\displaystyle \mathrm {Z} }$ are defined in airframe.xml.

• The second order

• Feedforward part

• Feedback part

• Comments

With the assumption of small variations so ${\displaystyle sin(\phi )=\phi }$ and so on for pitch and yaw, terms of second order are ignored :

- ${\displaystyle q_{e}=1}$

- ${\displaystyle q_{x}=\psi /2-\theta /2*\phi /2=\psi /2}$

- ${\displaystyle q_{y}=\theta /2-\psi /2*\phi /2=\theta /2}$

- ${\displaystyle q_{z}=\phi /2-\theta /2*\psi /2=\phi /2}$