stewart-simscape/simscape-model.org
2019-10-09 11:08:42 +02:00

14 KiB

Stewart Platform - Simscape Model

Introduction   ignore

Stewart platforms are generated in multiple steps.

First, geometrical parameters are defined:

  • ${}^Aa_i$ - Position of the joints fixed to the fixed base w.r.t $\{A\}$
  • ${}^Ab_i$ - Position of the joints fixed to the mobile platform w.r.t $\{A\}$
  • ${}^Bb_i$ - Position of the joints fixed to the mobile platform w.r.t $\{B\}$
  • $H$ - Total height of the mobile platform

These parameter are enough to determine all the kinematic properties of the platform like the Jacobian, stroke, stiffness, … These geometrical parameters can be generated using different functions: initializeCubicConfiguration for cubic configuration or initializeGeneralConfiguration for more general configuration.

A function computeGeometricalProperties is then used to compute:

  • $J_f$ - Jacobian matrix for the force location
  • $J_d$ - Jacobian matrix for displacement estimation
  • $R_m$ - Rotation matrices to position the leg vectors

Then, geometrical parameters are computed for all the mechanical elements with the function initializeMechanicalElements:

  • Shape of the platforms

    • External Radius
    • Internal Radius
    • Density
    • Thickness
  • Shape of the Legs

    • Radius
    • Size of ball joint
    • Density

Other Parameters are defined for the Simscape simulation:

  • Sample mass, volume and position (initializeSample function)
  • Location of the inertial sensor
  • Location of the point for the differential measurements
  • Location of the Jacobian point for velocity/displacement computation

initializeGeneralConfiguration

Function description

The initializeGeneralConfiguration function takes one structure that contains configurations for the hexapod and returns one structure representing the Hexapod.

  function [stewart] = initializeGeneralConfiguration(opts_param)

Optional Parameters

Default values for opts.

  opts = struct(...
      'H_tot',   90, ... % Height of the platform [mm]
      'H_joint', 15, ... % Height of the joints [mm]
      'H_plate', 10, ... % Thickness of the fixed and mobile platforms [mm]
      'R_bot',  100, ... % Radius where the legs articulations are positionned [mm]
      'R_top',  80,  ... % Radius where the legs articulations are positionned [mm]
      'a_bot',  10,  ... % Angle Offset [deg]
      'a_top',  40,  ... % Angle Offset [deg]
      'da_top', 0    ... % Angle Offset from 0 position [deg]
      );

Populate opts with input parameters

  if exist('opts_param','var')
      for opt = fieldnames(opts_param)'
          opts.(opt{1}) = opts_param.(opt{1});
      end
  end

Geometry Description

/tdehaeze/stewart-simscape/media/commit/7855abed3befad7b6ff5dcd9760fdb6aa2c20e68/figs/stewart_bottom_plate.png
Schematic of the bottom plates with all the parameters

Compute Aa and Ab

We compute $[a_1, a_2, a_3, a_4, a_5, a_6]^T$ and $[b_1, b_2, b_3, b_4, b_5, b_6]^T$.

  Aa = zeros(6, 3); % [mm]
  Ab = zeros(6, 3); % [mm]
  Bb = zeros(6, 3); % [mm]
  for i = 1:3
      Aa(2*i-1,:) = [opts.R_bot*cos( pi/180*(120*(i-1) - opts.a_bot) ), ...
                     opts.R_bot*sin( pi/180*(120*(i-1) - opts.a_bot) ), ...
                     opts.H_plate+opts.H_joint];
      Aa(2*i,:)   = [opts.R_bot*cos( pi/180*(120*(i-1) + opts.a_bot) ), ...
                     opts.R_bot*sin( pi/180*(120*(i-1) + opts.a_bot) ), ...
                     opts.H_plate+opts.H_joint];

      Ab(2*i-1,:) = [opts.R_top*cos( pi/180*(120*(i-1) + opts.da_top - opts.a_top) ), ...
                     opts.R_top*sin( pi/180*(120*(i-1) + opts.da_top - opts.a_top) ), ...
                     opts.H_tot - opts.H_plate - opts.H_joint];
      Ab(2*i,:)   = [opts.R_top*cos( pi/180*(120*(i-1) + opts.da_top + opts.a_top) ), ...
                     opts.R_top*sin( pi/180*(120*(i-1) + opts.da_top + opts.a_top) ), ...
                     opts.H_tot - opts.H_plate - opts.H_joint];
  end

  Bb = Ab - opts.H_tot*[0,0,1];

Returns Stewart Structure

  stewart = struct();
  stewart.Aa = Aa;
  stewart.Ab = Ab;
  stewart.Bb = Bb;
  stewart.H_tot = opts.H_tot;
end

computeGeometricalProperties

Function description

  function [stewart] = computeGeometricalProperties(stewart, opts_param)

Optional Parameters

Default values for opts.

  opts = struct(...
      'Jd_pos', [0, 0, 30], ... % Position of the Jacobian for displacement estimation from the top of the mobile platform [mm]
      'Jf_pos', [0, 0, 30]  ... % Position of the Jacobian for force location from the top of the mobile platform [mm]
      );

Populate opts with input parameters

  if exist('opts_param','var')
      for opt = fieldnames(opts_param)'
          opts.(opt{1}) = opts_param.(opt{1});
      end
  end

Rotation matrices

We initialize $l_i$ and $\hat{s}_i$

  leg_length = zeros(6, 1); % [mm]
  leg_vectors = zeros(6, 3);

We compute $b_i - a_i$, and then:

\begin{align*} l_i &= \left|b_i - a_i\right| \\ \hat{s}_i &= \frac{b_i - a_i}{l_i} \end{align*}
  legs = stewart.Ab - stewart.Aa;

  for i = 1:6
      leg_length(i) = norm(legs(i,:));
      leg_vectors(i,:) = legs(i,:) / leg_length(i);
  end

We compute rotation matrices to have the orientation of the legs. The rotation matrix transforms the $z$ axis to the axis of the leg. The other axis are not important here.

  stewart.Rm = struct('R', eye(3));

  for i = 1:6
    sx = cross(leg_vectors(i,:), [1 0 0]);
    sx = sx/norm(sx);

    sy = -cross(sx, leg_vectors(i,:));
    sy = sy/norm(sy);

    sz = leg_vectors(i,:);
    sz = sz/norm(sz);

    stewart.Rm(i).R = [sx', sy', sz'];
  end

Jacobian matrices

Compute Jacobian Matrix

  Jd = zeros(6);

  for i = 1:6
    Jd(i, 1:3) = leg_vectors(i, :);
    Jd(i, 4:6) = cross(0.001*(stewart.Bb(i, :) - opts.Jd_pos), leg_vectors(i, :));
  end

  stewart.Jd = Jd;
  stewart.Jd_inv = inv(Jd);
  Jf = zeros(6);

  for i = 1:6
    Jf(i, 1:3) = leg_vectors(i, :);
    Jf(i, 4:6) = cross(0.001*(stewart.Bb(i, :) - opts.Jf_pos), leg_vectors(i, :));
  end

  stewart.Jf = Jf;
  stewart.Jf_inv = inv(Jf);
  end

initializeMechanicalElements

Function description

  function [stewart] = initializeMechanicalElements(stewart, opts_param)

Optional Parameters

Default values for opts.

  opts = struct(...
      'thickness', 10, ... % Thickness of the base and platform [mm]
      'density',   1000, ... % Density of the material used for the hexapod [kg/m3]
      'k_ax',      1e8, ... % Stiffness of each actuator [N/m]
      'c_ax',      1000, ... % Damping of each actuator [N/(m/s)]
      'stroke',    50e-6  ... % Maximum stroke of each actuator [m]
      );

Populate opts with input parameters

  if exist('opts_param','var')
      for opt = fieldnames(opts_param)'
          opts.(opt{1}) = opts_param.(opt{1});
      end
  end

Bottom Plate

/tdehaeze/stewart-simscape/media/commit/7855abed3befad7b6ff5dcd9760fdb6aa2c20e68/figs/stewart_bottom_plate.png
Schematic of the bottom plates with all the parameters

The bottom plate structure is initialized.

  BP = struct();

We defined its internal radius (if there is a hole in the bottom plate) and its outer radius.

  BP.Rint = 0;   % Internal Radius [mm]
  BP.Rext = 150; % External Radius [mm]

We define its thickness.

  BP.H = opts.thickness; % Thickness of the Bottom Plate [mm]

We defined the density of the material of the bottom plate.

  BP.density = opts.density; % Density of the material [kg/m3]

And its color.

  BP.color = [0.7 0.7 0.7]; % Color [RGB]

Then the profile of the bottom plate is computed and will be used by Simscape

  BP.shape = [BP.Rint BP.H; BP.Rint 0; BP.Rext 0; BP.Rext BP.H]; % [mm]

The structure is added to the stewart structure

  stewart.BP = BP;

Top Plate

The top plate structure is initialized.

  TP = struct();

We defined the internal and external radius of the top plate.

  TP.Rint = 0;   % [mm]
  TP.Rext = 100; % [mm]

The thickness of the top plate.

  TP.H = 10; % [mm]

The density of its material.

  TP.density = opts.density; % Density of the material [kg/m3]

Its color.

  TP.color = [0.7 0.7 0.7]; % Color [RGB]

Then the shape of the top plate is computed

  TP.shape = [TP.Rint TP.H; TP.Rint 0; TP.Rext 0; TP.Rext TP.H];

The structure is added to the stewart structure

  stewart.TP  = TP;

Legs

/tdehaeze/stewart-simscape/media/commit/7855abed3befad7b6ff5dcd9760fdb6aa2c20e68/figs/stewart_legs.png
Schematic for the legs of the Stewart platform

The leg structure is initialized.

  Leg = struct();

The maximum Stroke of each leg is defined.

  Leg.stroke = opts.stroke; % [m]

The stiffness and damping of each leg are defined

  Leg.k_ax = opts.k_ax; % Stiffness of each leg [N/m]
  Leg.c_ax = opts.c_ax; % Damping of each leg [N/(m/s)]

The radius of the legs are defined

  Leg.Rtop = 10; % Radius of the cylinder of the top part of the leg[mm]
  Leg.Rbot = 12; % Radius of the cylinder of the bottom part of the leg [mm]

The density of its material.

  Leg.density = opts.density; % Density of the material used for the legs [kg/m3]

Its color.

  Leg.color = [0.5 0.5 0.5]; % Color of the top part of the leg [RGB]

The radius of spheres representing the ball joints are defined.

  Leg.R = 1.3*Leg.Rbot; % Size of the sphere at the extremity of the leg [mm]

We estimate the length of the legs.

  legs = stewart.Ab - stewart.Aa;
  Leg.lenght = norm(legs(1,:))/1.5;

Then the shape of the bottom leg is estimated

  Leg.shape.bot = ...
      [0        0; ...
       Leg.Rbot 0; ...
       Leg.Rbot Leg.lenght; ...
       Leg.Rtop Leg.lenght; ...
       Leg.Rtop 0.2*Leg.lenght; ...
       0        0.2*Leg.lenght];

The structure is added to the stewart structure

  stewart.Leg = Leg;

Ball Joints

/tdehaeze/stewart-simscape/media/commit/7855abed3befad7b6ff5dcd9760fdb6aa2c20e68/figs/stewart_ball_joints.png
Schematic of the support for the ball joints

SP is the structure representing the support for the ball joints at the extremity of each leg.

The SP structure is initialized.

  SP = struct();

We can define its rotational stiffness and damping. For now, we use perfect joints.

  SP.k = 0; % [N*m/deg]
  SP.c = 0; % [N*m/deg]

Its height is defined

  SP.H = stewart.Aa(1, 3) - BP.H; % [mm]

Its radius is based on the radius on the sphere at the end of the legs.

  SP.R = Leg.R; % [mm]
  SP.section = [0    SP.H-SP.R;
                0    0;
                SP.R 0;
                SP.R SP.H];

The density of its material is defined.

  SP.density = opts.density; % [kg/m^3]

Its color is defined.

  SP.color = [0.7 0.7 0.7]; % [RGB]

The structure is added to the Hexapod structure

  stewart.SP  = SP;

initializeSample

Function description

  function [] = initializeSample(opts_param)

Optional Parameters

Default values for opts.

  sample = struct( ...
      'radius',     100, ... % radius of the cylinder [mm]
      'height',     100, ... % height of the cylinder [mm]
      'mass',       10,  ... % mass of the cylinder [kg]
      'measheight', 50, ... % measurement point z-offset [mm]
      'offset',     [0, 0, 0],   ... % offset position of the sample [mm]
      'color',      [0.9 0.1 0.1] ...
      );

Populate opts with input parameters

  if exist('opts_param','var')
      for opt = fieldnames(opts_param)'
          sample.(opt{1}) = opts_param.(opt{1});
      end
  end

Save the Sample structure

  save('./mat/sample.mat', 'sample');
  end