nass-fem/index.org
2020-08-03 15:46:35 +02:00

60 KiB

Finite Element Model with Simscape

Amplified Piezoelectric Actuator - 3D elements

Introduction   ignore

The idea here is to:

  • export a FEM of an amplified piezoelectric actuator from Ansys to Matlab
  • import it into a Simscape model
  • compare the obtained dynamics
  • add 10kg mass on top of the actuator and identify the dynamics
  • compare with results from Ansys where 10kg are directly added to the FEM

Import Mass Matrix, Stiffness Matrix, and Interface Nodes Coordinates

We first extract the stiffness and mass matrices.

  K = extractMatrix('piezo_amplified_3d_K.txt');
  M = extractMatrix('piezo_amplified_3d_M.txt');

Then, we extract the coordinates of the interface nodes.

  [int_xyz, int_i, n_xyz, n_i, nodes] = extractNodes('piezo_amplified_3d.txt');
  save('./mat/piezo_amplified_3d.mat', 'int_xyz', 'int_i', 'n_xyz', 'n_i', 'nodes', 'M', 'K');

Output parameters

  load('./mat/piezo_amplified_3d.mat', 'int_xyz', 'int_i', 'n_xyz', 'n_i', 'nodes', 'M', 'K');
Total number of Nodes 168959
Number of interface Nodes 13
Number of Modes 30
Size of M and K matrices 108
/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/amplified_piezo_interface_nodes.png
Interface Nodes for the Amplified Piezo Actuator
Node i Node Number x [m] y [m] z [m]
1.0 168947.0 0.0 0.03 0.0
2.0 168949.0 0.0 -0.03 0.0
3.0 168950.0 -0.035 0.0 0.0
4.0 168951.0 -0.028 0.0 0.0
5.0 168952.0 -0.021 0.0 0.0
6.0 168953.0 -0.014 0.0 0.0
7.0 168954.0 -0.007 0.0 0.0
8.0 168955.0 0.0 0.0 0.0
9.0 168956.0 0.007 0.0 0.0
10.0 168957.0 0.014 0.0 0.0
11.0 168958.0 0.021 0.0 0.0
12.0 168959.0 0.035 0.0 0.0
13.0 168960.0 0.028 0.0 0.0
Coordinates of the interface nodes
300000000.0 -30000.0 8000.0 -200.0 -30.0 -60000.0 20000000.0 -4000.0 500.0 8
-30000.0 100000000.0 400.0 30.0 200.0 -1 4000.0 -8000000.0 800.0 7
8000.0 400.0 50000000.0 -800000.0 -300.0 -40.0 300.0 100.0 5000000.0 40000.0
-200.0 30.0 -800000.0 20000.0 5 1 -10.0 -2 -40000.0 -300.0
-30.0 200.0 -300.0 5 40000.0 0.3 -4 -10.0 40.0 0.4
-60000.0 -1 -40.0 1 0.3 3000.0 7000.0 0.8 -1 0.0003
20000000.0 4000.0 300.0 -10.0 -4 7000.0 300000000.0 20000.0 3000.0 80.0
-4000.0 -8000000.0 100.0 -2 -10.0 0.8 20000.0 100000000.0 -4000.0 -100.0
500.0 800.0 5000000.0 -40000.0 40.0 -1 3000.0 -4000.0 50000000.0 800000.0
8 7 40000.0 -300.0 0.4 0.0003 80.0 -100.0 800000.0 20000.0
First 10x10 elements of the Stiffness matrix
0.03 2e-06 -2e-07 1e-08 2e-08 0.0002 -0.001 2e-07 -8e-08 -9e-10
2e-06 0.02 -5e-07 7e-09 3e-08 2e-08 -3e-07 0.0003 -1e-08 1e-10
-2e-07 -5e-07 0.02 -9e-05 4e-09 -1e-08 2e-07 -2e-08 -0.0006 -5e-06
1e-08 7e-09 -9e-05 1e-06 6e-11 4e-10 -1e-09 3e-11 5e-06 3e-08
2e-08 3e-08 4e-09 6e-11 1e-06 2e-10 -2e-09 2e-10 -7e-09 -4e-11
0.0002 2e-08 -1e-08 4e-10 2e-10 2e-06 -2e-06 -1e-09 -7e-10 -9e-12
-0.001 -3e-07 2e-07 -1e-09 -2e-09 -2e-06 0.03 -2e-06 -1e-07 -5e-09
2e-07 0.0003 -2e-08 3e-11 2e-10 -1e-09 -2e-06 0.02 -8e-07 -1e-08
-8e-08 -1e-08 -0.0006 5e-06 -7e-09 -7e-10 -1e-07 -8e-07 0.02 9e-05
-9e-10 1e-10 -5e-06 3e-08 -4e-11 -9e-12 -5e-09 -1e-08 9e-05 1e-06
First 10x10 elements of the Mass matrix

Using K, M and int_xyz, we can use the Reduced Order Flexible Solid simscape block.

Piezoelectric parameters

Parameters for the APA95ML:

  d33 = 3e-10; % Strain constant [m/V]
  n = 80; % Number of layers per stack
  eT = 1.6e-7; % Permittivity under constant stress [F/m]
  sD = 2e-11; % Elastic compliance under constant electric displacement [m2/N]
  ka = 235e6; % Stack stiffness [N/m]
  C = 5e-6; % Stack capactiance [F]
  na = 2; % Number of stacks used as actuator
  ns = 1; % Number of stacks used as force sensor

The ratio of the developed force to applied voltage is $d_{33} n k_a$ in [N/V]. We denote this constant by $g_a$ and: \[ F_a = g_a V_a, \quad g_a = d_{33} n k_a \]

  d33*(na*n)*(ka/(na + ns)) % [N/V]
3.76

From cite:fleming14_desig_model_contr_nanop_system (page 123), the relation between relative displacement and generated voltage is: \[ V_s = \frac{d_{33}}{\epsilon^T s^D n} \Delta h \] where:

  • $V_s$: measured voltage [V]
  • $d_{33}$: strain constant [m/V]
  • $\epsilon^T$: permittivity under constant stress [F/m]
  • $s^D$: elastic compliance under constant electric displacement [m^2/N]
  • $n$: number of layers
  • $\Delta h$: relative displacement [m]
  1e-6*d33/(eT*sD*ns*n) % [V/um]
1.1719

Identification of the Dynamics

The flexible element is imported using the Reduced Order Flexible Solid simscape block.

To model the actuator, an Internal Force block is added between the nodes 3 and 12. A Relative Motion Sensor block is added between the nodes 1 and 2 to measure the displacement and the amplified piezo.

One mass is fixed at one end of the piezo-electric stack actuator, the other end is fixed to the world frame.

We first set the mass to be zero.

  m = 0.01;

The dynamics is identified from the applied force to the measured relative displacement.

  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/F'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/y'], 1, 'openoutput'); io_i = io_i + 1;

  Gh = -linearize(mdl, io);

Then, we add 10Kg of mass:

  m = 5;

And the dynamics is identified.

The two identified dynamics are compared in Figure fig:dynamics_act_disp_comp_mass.

  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/F'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/y'], 1, 'openoutput'); io_i = io_i + 1;

  Ghm = -linearize(mdl, io);

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/dynamics_act_disp_comp_mass.png

Dynamics from $F$ to $d$ without a payload and with a 10kg payload

Comparison with Ansys

Let's import the results from an Harmonic response analysis in Ansys.

  Gresp0 = readtable('FEA_HarmResponse_00kg.txt');
  Gresp10 = readtable('FEA_HarmResponse_10kg.txt');

The obtained dynamics from the Simscape model and from the Ansys analysis are compare in Figure fig:dynamics_force_disp_comp_anasys.

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/dynamics_force_disp_comp_anasys.png

Comparison of the obtained dynamics using Simscape with the harmonic response analysis using Ansys

Force Sensor

The dynamics is identified from internal forces applied between nodes 3 and 11 to the relative displacement of nodes 11 and 13.

The obtained dynamics is shown in Figure fig:dynamics_force_force_sensor_comp_mass.

  m = 0;
  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/Fa'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/Fs'], 1, 'openoutput'); io_i = io_i + 1;

  Gf = linearize(mdl, io);
  m = 10;
  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/Fa'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/Fs'], 1, 'openoutput'); io_i = io_i + 1;

  Gfm = linearize(mdl, io);

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/dynamics_force_force_sensor_comp_mass.png

Dynamics from $F$ to $F_m$ for $m=0$ and $m = 10kg$

Distributed Actuator

  m = 0;

The dynamics is identified from the applied force to the measured relative displacement.

  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d_distri';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/F'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/y'], 1, 'openoutput'); io_i = io_i + 1;

  Gd = linearize(mdl, io);

Then, we add 10Kg of mass:

  m = 10;

And the dynamics is identified.

  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d_distri';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/F'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/y'], 1, 'openoutput'); io_i = io_i + 1;

  Gdm = linearize(mdl, io);

Distributed Actuator and Force Sensor

  m = 0;
  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d_distri_act_sens';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/F'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/Fm'], 1, 'openoutput'); io_i = io_i + 1;

  Gfd = linearize(mdl, io);
  m = 10;
  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d_distri_act_sens';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/F'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/Fm'], 1, 'openoutput'); io_i = io_i + 1;

  Gfdm = linearize(mdl, io);

Dynamics from input voltage to displacement

  m = 5;

And the dynamics is identified.

The two identified dynamics are compared in Figure fig:dynamics_act_disp_comp_mass.

  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/V'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/y'], 1, 'openoutput'); io_i = io_i + 1;

  G = -linearize(mdl, io);
  save('../test-bench-apa/mat/fem_model_5kg.mat', 'G')

Dynamics from input voltage to output voltage

  m = 5;
  %% Name of the Simulink File
  mdl = 'piezo_amplified_3d';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/Va'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/Vs'], 1, 'openoutput'); io_i = io_i + 1;

  G = -linearize(mdl, io);

APA300ML

Introduction   ignore

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/apa300ml_ansys.jpg
Ansys FEM of the APA300ML

Import Mass Matrix, Stiffness Matrix, and Interface Nodes Coordinates

We first extract the stiffness and mass matrices.

  K = extractMatrix('mat_K-48modes-7MDoF.matrix');
  M = extractMatrix('mat_M-48modes-7MDoF.matrix');
  K = extractMatrix('mat_K-80modes-7MDoF.matrix');
  M = extractMatrix('mat_M-80modes-7MDoF.matrix');

Then, we extract the coordinates of the interface nodes.

  [int_xyz, int_i, n_xyz, n_i, nodes] = extractNodes('Nodes_MDoF_NLIST_MLIST.txt');
  save('./mat/APA300ML.mat', 'int_xyz', 'int_i', 'n_xyz', 'n_i', 'nodes', 'M', 'K');

Output parameters

  load('./mat/APA300ML.mat', 'int_xyz', 'int_i', 'n_xyz', 'n_i', 'nodes', 'M', 'K');
Total number of Nodes 7
Number of interface Nodes 7
Number of Modes 6
Size of M and K matrices 48
Node i Node Number x [m] y [m] z [m]
1.0 53917.0 0.0 -0.015 0.0
2.0 53918.0 0.0 0.015 0.0
3.0 53919.0 -0.0325 0.0 0.0
4.0 53920.0 -0.0125 0.0 0.0
5.0 53921.0 -0.0075 0.0 0.0
6.0 53922.0 0.0125 0.0 0.0
7.0 53923.0 0.0325 0.0 0.0
Coordinates of the interface nodes
200000000.0 30000.0 50000.0 200.0 -100.0 -300000.0 10000000.0 -6000.0 20000.0 -60.0
30000.0 7000000.0 10000.0 30.0 -30.0 -70.0 7000.0 -500000.0 3000.0 -10.0
50000.0 10000.0 30000000.0 200000.0 -200.0 -100.0 20000.0 -2000.0 2000000.0 -9000.0
200.0 30.0 200000.0 1000.0 -0.8 -0.4 50.0 -6 9000.0 -30.0
-100.0 -30.0 -200.0 -0.8 10000.0 0.2 -40.0 10.0 20.0 -0.05
-300000.0 -70.0 -100.0 -0.4 0.2 900.0 -30000.0 10.0 -40.0 0.1
10000000.0 7000.0 20000.0 50.0 -40.0 -30000.0 200000000.0 -50000.0 30000.0 -50.0
-6000.0 -500000.0 -2000.0 -6 10.0 10.0 -50000.0 7000000.0 -4000.0 8
20000.0 3000.0 2000000.0 9000.0 20.0 -40.0 30000.0 -4000.0 30000000.0 -200000.0
-60.0 -10.0 -9000.0 -30.0 -0.05 0.1 -50.0 8 -200000.0 1000.0
First 10x10 elements of the Stiffness matrix
0.01 7e-06 -5e-06 -6e-08 3e-09 -5e-05 -0.0005 -2e-07 -3e-06 1e-08
7e-06 0.009 4e-07 6e-09 -4e-09 -3e-08 -2e-07 6e-05 5e-07 -1e-09
-5e-06 4e-07 0.01 2e-05 2e-08 3e-08 -2e-06 -1e-07 -0.0002 9e-07
-6e-08 6e-09 2e-05 3e-07 1e-10 3e-10 -7e-09 2e-10 -9e-07 3e-09
3e-09 -4e-09 2e-08 1e-10 1e-07 -3e-12 6e-09 -2e-10 -3e-09 9e-12
-5e-05 -3e-08 3e-08 3e-10 -3e-12 6e-07 1e-06 -3e-09 2e-08 -7e-11
-0.0005 -2e-07 -2e-06 -7e-09 6e-09 1e-06 0.01 -8e-06 -2e-06 9e-09
-2e-07 6e-05 -1e-07 2e-10 -2e-10 -3e-09 -8e-06 0.009 1e-07 2e-09
-3e-06 5e-07 -0.0002 -9e-07 -3e-09 2e-08 -2e-06 1e-07 0.01 -2e-05
1e-08 -1e-09 9e-07 3e-09 9e-12 -7e-11 9e-09 2e-09 -2e-05 3e-07
First 10x10 elements of the Mass matrix

Using K, M and int_xyz, we can use the Reduced Order Flexible Solid simscape block.

Piezoelectric parameters

Parameters for the APA95ML:

  d33 = 3e-10; % Strain constant [m/V]
  n = 80; % Number of layers per stack
  eT = 1.6e-8; % Permittivity under constant stress [F/m]
  sD = 2e-11; % Elastic compliance under constant electric displacement [m2/N]
  ka = 235e6; % Stack stiffness [N/m]
  C = 5e-6; % Stack capactiance [F]
  na = 3; % Number of stacks used as actuator
  ns = 0; % Number of stacks used as force sensor

The ratio of the developed force to applied voltage is $d_{33} n k_a$ in [N/V]. We denote this constant by $g_a$ and: \[ F_a = g_a V_a, \quad g_a = d_{33} n k_a \]

  d33*(na*n)*(ka/(na + ns)) % [N/V]
1.88

From cite:fleming14_desig_model_contr_nanop_system (page 123), the relation between relative displacement and generated voltage is: \[ V_s = \frac{d_{33}}{\epsilon^T s^D n} \Delta h \] where:

  • $V_s$: measured voltage [V]
  • $d_{33}$: strain constant [m/V]
  • $\epsilon^T$: permittivity under constant stress [F/m]
  • $s^D$: elastic compliance under constant electric displacement [m^2/N]
  • $n$: number of layers
  • $\Delta h$: relative displacement [m]
  1e-6*d33/(eT*sD*ns*n) % [V/um]
5.8594

Identification of the APA Characteristics

Stiffness

The transfer function from vertical external force to the relative vertical displacement is identified.

The inverse of its DC gain is the axial stiffness of the APA:

  1e-6/dcgain(G) % [N/um]
1.8634

The specified stiffness in the datasheet is $k = 1.8\, [N/\mu m]$.

Resonance Frequency

The resonance frequency is specified to be between 650Hz and 840Hz. This is also the case for the FEM model (Figure fig:apa300ml_resonance).

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/apa300ml_resonance.png

First resonance is around 800Hz

Amplification factor

The amplification factor is the ratio of the axial displacement to the stack displacement.

The ratio of the two displacement is computed from the FEM model.

  -dcgain(G(1,1))./dcgain(G(2,1))
4.936

If we take the ratio of the piezo height and length (approximation of the amplification factor):

  75/15
5

Stroke

Estimation of the actuator stroke: \[ \Delta H = A n \Delta L \] with:

  • $\Delta H$ Axial Stroke of the APA
  • $A$ Amplification factor (5 for the APA300ML)
  • $n$ Number of stack used
  • $\Delta L$ Stroke of the stack (0.1% of its length)
  1e6 * 5 * 3 * 20e-3 * 0.1e-2
300

This is exactly the specified stroke in the data-sheet.

Identification of the Dynamics

The flexible element is imported using the Reduced Order Flexible Solid simscape block.

To model the actuator, an Internal Force block is added between the nodes 3 and 12. A Relative Motion Sensor block is added between the nodes 1 and 2 to measure the displacement and the amplified piezo.

One mass is fixed at one end of the piezo-electric stack actuator, the other end is fixed to the world frame.

We first set the mass to be zero.

The dynamics is identified from the applied force to the measured relative displacement.

The same dynamics is identified for a payload mass of 10Kg.

  m = 10;

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/apa300ml_plant_dynamics.png

Transfer function from forces applied by the stack to the axial displacement of the APA

IFF

Let's use 2 stacks as actuators and 1 stack as force sensor.

The transfer function from actuator to sensors is identified and shown in Figure fig:apa300ml_iff_plant.

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/apa300ml_iff_plant.png

Transfer function from actuator to force sensor

For root locus corresponding to IFF is shown in Figure fig:apa300ml_iff_root_locus.

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/apa300ml_iff_root_locus.png

Root Locus for IFF

DVF

Now the dynamics from the stack actuator to the relative motion sensor is identified and shown in Figure fig:apa300ml_dvf_plant.

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/apa300ml_dvf_plant.png

Transfer function from stack actuator to relative motion sensor

The root locus for DVF is shown in Figure fig:apa300ml_dvf_root_locus.

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/apa300ml_dvf_root_locus.png

Root Locus for Direct Velocity Feedback

Flexible Joint

Introduction   ignore

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/flexor_id16_screenshot.png
Flexor studied

Import Mass Matrix, Stiffness Matrix, and Interface Nodes Coordinates

We first extract the stiffness and mass matrices.

  K = extractMatrix('mat_K_6modes_2MDoF.matrix');
  M = extractMatrix('mat_M_6modes_2MDoF.matrix');

Then, we extract the coordinates of the interface nodes.

  [int_xyz, int_i, n_xyz, n_i, nodes] = extractNodes('out_nodes_3D.txt');
  save('./mat/flexor_ID16.mat', 'int_xyz', 'int_i', 'n_xyz', 'n_i', 'nodes', 'M', 'K');

Output parameters

  load('./mat/flexor_ID16.mat', 'int_xyz', 'int_i', 'n_xyz', 'n_i', 'nodes', 'M', 'K');
Total number of Nodes 2
Number of interface Nodes 2
Number of Modes 6
Size of M and K matrices 18
Node i Node Number x [m] y [m] z [m]
1.0 181278.0 0.0 0.0 0.0
2.0 181279.0 0.0 0.0 -0.0
Coordinates of the interface nodes
11200000.0 195.0 2220.0 -0.719 -265.0 1.59 -11200000.0 -213.0 -2220.0 0.147
195.0 11400000.0 1290.0 -148.0 -0.188 2.41 -212.0 -11400000.0 -1290.0 148.0
2220.0 1290.0 119000000.0 1.31 1.49 1.79 -2220.0 -1290.0 -119000000.0 -1.31
-0.719 -148.0 1.31 33.0 0.000488 -0.000977 0.141 148.0 -1.31 -33.0
-265.0 -0.188 1.49 0.000488 33.0 0.00293 266.0 0.154 -1.49 0.00026
1.59 2.41 1.79 -0.000977 0.00293 236.0 -1.32 -2.55 -1.79 0.000379
-11200000.0 -212.0 -2220.0 0.141 266.0 -1.32 11400000.0 24600.0 1640.0 120.0
-213.0 -11400000.0 -1290.0 148.0 0.154 -2.55 24600.0 11400000.0 1290.0 -72.0
-2220.0 -1290.0 -119000000.0 -1.31 -1.49 -1.79 1640.0 1290.0 119000000.0 1.32
0.147 148.0 -1.31 -33.0 0.00026 0.000379 120.0 -72.0 1.32 34.7
First 10x10 elements of the Stiffness matrix
0.02 1e-09 -4e-08 -1e-10 0.0002 -3e-11 0.004 5e-08 7e-08 1e-10
1e-09 0.02 -3e-07 -0.0002 -1e-10 -2e-09 2e-08 0.004 3e-07 1e-05
-4e-08 -3e-07 0.02 7e-10 -2e-09 1e-09 3e-07 7e-08 0.003 1e-09
-1e-10 -0.0002 7e-10 4e-06 -1e-12 -6e-13 2e-10 -7e-06 -8e-10 -1e-09
0.0002 -1e-10 -2e-09 -1e-12 3e-06 2e-13 9e-06 4e-11 2e-09 -3e-13
-3e-11 -2e-09 1e-09 -6e-13 2e-13 4e-07 8e-11 9e-10 -1e-09 2e-12
0.004 2e-08 3e-07 2e-10 9e-06 8e-11 0.02 -7e-08 -3e-07 -2e-10
5e-08 0.004 7e-08 -7e-06 4e-11 9e-10 -7e-08 0.01 -4e-08 0.0002
7e-08 3e-07 0.003 -8e-10 2e-09 -1e-09 -3e-07 -4e-08 0.02 -1e-09
1e-10 1e-05 1e-09 -1e-09 -3e-13 2e-12 -2e-10 0.0002 -1e-09 2e-06
First 10x10 elements of the Mass matrix

Using K, M and int_xyz, we can use the Reduced Order Flexible Solid simscape block.

Flexible Joint Characteristics

Caracteristic Value Estimation by Francois
Axial Stiffness [N/um] 119 60
Bending Stiffness [Nm/rad] 33 15
Bending Stiffness [Nm/rad] 33 15
Torsion Stiffness [Nm/rad] 236 20

Identification

  m = 10;

The dynamics is identified from the applied force to the measured relative displacement.

  %% Name of the Simulink File
  mdl = 'flexor_ID16';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/T'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/D'], 1, 'openoutput'); io_i = io_i + 1;

  G = linearize(mdl, io);
Caracteristic Value Identification
Axial Stiffness Dz [N/um] 119 119
Bending Stiffness Rx [Nm/rad] 33 34
Bending Stiffness Ry [Nm/rad] 33 126
Torsion Stiffness Rz [Nm/rad] 236 238

Integral Force Feedback with Amplified Piezo

Introduction   ignore

In this section, we try to replicate the results obtained in cite:souleille18_concep_activ_mount_space_applic.

Import Mass Matrix, Stiffness Matrix, and Interface Nodes Coordinates

We first extract the stiffness and mass matrices.

  K = extractMatrix('piezo_amplified_IFF_K.txt');
  M = extractMatrix('piezo_amplified_IFF_M.txt');

Then, we extract the coordinates of the interface nodes.

  [int_xyz, int_i, n_xyz, n_i, nodes] = extractNodes('piezo_amplified_IFF.txt');

IFF Plant

The transfer function from the force actuator to the force sensor is identified and shown in Figure fig:piezo_amplified_iff_plant.

  Kiff = tf(0);
  m = 0;
  %% Name of the Simulink File
  mdl = 'piezo_amplified_IFF';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/Kiff'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/G'],    1, 'openoutput'); io_i = io_i + 1;

  Gf = linearize(mdl, io);
  m = 10;
  Gfm = linearize(mdl, io);

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/piezo_amplified_iff_plant.png

IFF Plant

IFF controller

The controller is defined and the loop gain is shown in Figure fig:piezo_amplified_iff_loop_gain.

  Kiff = -1e12/s;

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/piezo_amplified_iff_loop_gain.png

IFF Loop Gain

Closed Loop System

  m = 10;
  Kiff = -1e12/s;
  %% Name of the Simulink File
  mdl = 'piezo_amplified_IFF';

  %% Input/Output definition
  clear io; io_i = 1;
  io(io_i) = linio([mdl, '/Dw'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/F'],  1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/Fd'], 1, 'openinput');  io_i = io_i + 1;
  io(io_i) = linio([mdl, '/d'],  1, 'openoutput'); io_i = io_i + 1;
  io(io_i) = linio([mdl, '/G'],  1, 'output'); io_i = io_i + 1;

  Giff = linearize(mdl, io);
  Giff.InputName  = {'w', 'f', 'F'};
  Giff.OutputName  = {'x1', 'Fs'};
  Kiff = tf(0);
  G = linearize(mdl, io);
  G.InputName  = {'w', 'f', 'F'};
  G.OutputName  = {'x1', 'Fs'};

/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/piezo_amplified_iff_comp.png

OL and CL transfer functions
/tdehaeze/nass-fem/media/commit/785ddf12db880a7115978eee75032878d6e4d143/figs/souleille18_results.png
Results obtained in cite:souleille18_concep_activ_mount_space_applic

Bibliography   ignore

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