Difference between revisions of "Modal practical"

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==DATA IMPORT AND READING==
==DATA IMPORT AND READING==


 
===Data import===
For  this  demo,  use  the  data  file  `CANTILEVER  HAMMER  DATA.uff<nowiki>’</nowiki>  containing  the  Frequency Response Functions acquired with one impact hammer and 2 accelerometers.
For  this  demo,  use  the  data  file  `CANTILEVER  HAMMER  DATA.uff<nowiki>’</nowiki>  containing  the  Frequency Response Functions acquired with one impact hammer and 2 accelerometers.


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By  right  clicking  on  the  graph  and  selecting  `Showed  Series…<nowiki>’</nowiki>, you  can  display  several  FRFs on the same graph for comparison.
By  right  clicking  on  the  graph  and  selecting  `Showed  Series…<nowiki>’</nowiki>, you  can  display  several  FRFs on the same graph for comparison.


==MODAL IDENTIFICATION==
==MODAL IDENTIFICATION==

Revision as of 08:12, 17 July 2020

Create a new project

- Open the software
- Click on `File/New' and give a name to your project `Cantilever'.

GEOMETRY BUILDING

The goal of this part is to model the cantilever by the geometry below. The different steps of the procedure are described here.

Modal practical 13.png


  • Position in the XY plan by clicking on `Top view’ in the toolbar.
Modal practical 14.png


  • Line 1

Click on `add line’ Modal practical 15.pngin the geometry toolbar. A line is defined as follow:

Modal practical 07.png

For each line, the software associates a Cartesian coordinates system. The line is defined by the origin of this system, the direction of X axis, the length and the number of segments.


To create the line 1, enter the following parameters:

Modal practical 16.png

Note: for the local coordinate system parameters, enter parameters about origin point and Euler angles only.

Rename the point 6 in point 3 by opening `Config review’ and make the modification in the `nodes’ window.

Note: When the `config review’ is activated, click on `modeling interface’ button Modal practical 17.pngto display both `geometry’ and `config review’ windows.

  • Line 2

Click on `add line’ Modal practical 18.pngand enter the following parameters


Modal practical 19.png

Remove the line between point 18 and 19 by clicking on `select lines’ in the toolbar Select the line 18-19 and delete it.

Selectline.png

Rename the point 18 in point 1.

Create the lines 1-19 and 3-7 by clicking on`add lines’ in the toolbar and link the points directly on the geometry. (left click on the 2 points and right click to end the operation)


Modal practical 20.png
  • Line 3

Click on `add lines’ Modal practical 21.png and link point 1 and 3

Modal practical 08.png

To create point 2, click on `add nodes’ Modal practical 22.png, a grid is displayed to help you to position new points. Right click to fix a new point and rename it in point 2.

  • Line 4

Create the points 4, 5 and 6 with the grid and add lines to link them.

Line4.png
  • Experimental coordinates systems

Regarding the axis definition for the acquisition, 2 local coordinates systems should be added respectively on the nodes of line 1 and 2.

In the `config review’ select the nodes of lines 1. Right click and select `Assign Coord.’

Modal practical 02.jpg

To reproduce the experimental conditions, enter the following parameters

Modal practical 09.jpg

In the `Config review’ select the nodes of line 2. Right click and select `Assign Coord.’ Enter the following parameters

Config.png


Delete the coordinates systems 1 and 2 in `config review’ /coordinates


  • Results
Modal practical 03.png

DATA IMPORT AND READING

Data import

For this demo, use the data file `CANTILEVER HAMMER DATA.uff’ containing the Frequency Response Functions acquired with one impact hammer and 2 accelerometers.

In the File menu, click on Import/Data files (UFF). The following window is displayed.

Import modal.png


Select `acceleration’ for response type,

`Frequency domain’ for data type.

Click on the button

Modal practical 23.png

, select the file `CANTILEVER HAMMER DATA.uff’ and click on OK.


The following window shows all the results contained in the imported file with their characteristics. Information of nodes and directions can be modified if an error occurs.

Any filters are available to import a part of the data only.



Modal practical 24.jpg

Here all the data will be used, so click on OK. The FRFs are directly displayed in the software.


FRF modal.png

All the FRFs can be visualized.

DATA READING

By using the Control Panel (Series select), all the FRFs can be displayed. For each result, there is information about the DOFs (node, direction).

Several types of displayed are available by right clicking on the graph: magnitude/phase, real/imaginary, Nyquist.

By right clicking on the graph and selecting `Showed Series…’, you can display several FRFs on the same graph for comparison.

MODAL IDENTIFICATION

OPERATING DEFLECTION SHAPE

Modal practical 04.jpg

In the operation tree, double click on `ODS: Freq Domain The following interface is displayed.

On the left, the Modal Indication Function (MIF) shows the modes in the frequency band. Position the cursor on the peaks and visualize the corresponding mode shapes on the right.


What is the MIF?

MIF can be employed in not only EMA, but also OMA. In EMA case, the number of MIFs equals the number of excitations or references. In OMA case, the number of MIFs equals the minimum number of responses of each setup. The MIFs consist of the singular values of frequency response function matrix (FRF), output power spectral density matrix (OPSD), or half power spectral density matrix (HPSD). By the powerful singular value decomposition, the real signal space is separated from the noise space. Therefore, the MIFs exhibit the modes effectively. A peak in the MIFs plot usually indicate the existence of a structural mode, and two peaks at a same frequency point means the existence of two repeated modes. Moreover, the magnitude of the MIFs always implies the strength of a mode.

Two separated modes


Weak modes



Two pairs of repeated modes


Sometimes we should note the cross modes. For example, in the below figure, the peak in the second MIF curve doesn’t indicate a mode. It’s formed by the cross of two modes.

MODAL ANALYSIS USING EMA BROBAND

In the operation tree:

  1. select EMA Broband (A red icon appears near the method),
  2. the MIF is displayed,
  3. Select a large frequency band by positioning the cursors and double click to fix them (a black line between the 2 cursors appears),
  4. click on start identification
Modal practical 12.png

The follwoing windows is displayed:

Modal id.png


  1. Preliminary determination of the number of modes in the selected frequency band according to the MIF plot, and fill it in the edit box of "Preset Modes No." Then the BroBand software will calculate a default "minimum order" according to this number. The relationship between "Preset Modes No." and "Minimum Order" is: minimum order = (preset modes No)*Ni/2, where Ni means the number of input. Change the number of "Order Span" if necessary. The BroBand software will estimate the poles with a range of system order from "Minimum Order" to "Maximum Order", where Maximum order= Minimum order + Order Span-1. The default order span is 12.
  1. Modal identification

Press the button of "Start Modal ID" to obtain frequency stability diagram. This operation might take a little longer time to finish a complex structure with large number of modes and measurement coordinates. In the stability diagram, a shape symbol represents one pole. A pole in this diagram may represent a physical (i.e. structural) mode or a spurious (or noise) mode. It is normally not difficult to distinguish physical/structural) mode from spurious/noise mode by the distribution of poles. Generally speaking, a physical/structural mode can be identified in each proper number of order, while for a spurious/noise pole it usually is not the case. There are five kinds of symbols to indicate the poles:

Symbol Description
o The pole is not stable. (The poles obtained from the first order are always
considered as unstable.)
f The frequency of the pole does not change within the tolerance of 1%.
v The frequency of the pole does not change within the tolerance of 1%,
and the pole vector does not change within the tolerance of 10%
d The frequency of the pole does not change within the tolerance of 1%,
and the damping of the pole does not change within the tolerance of 10%.
s Both frequency, damping and vector are stable within the tolerances: the frequency of the pole does not change within the tolerance of 1%; the pole vector does not change within the tolerance of 10%;
and the damping of the pole does not change within the tolerance of 10%.

Modal practical 25.jpg
  1. Auto selection of structural modes

Press the button of "Auto Selection" or

Modal practical 26.png

, the OM2 selects the physical/structural modes automatically. While move the mouse cursor on a pole, the modal frequency and damping ratio corresponding to this pole will be shown. You can move the mouse on

different poles to check the stability via small change of the modal frequency and/or damping ratio.


Modal practical 27.jpg

==

Modal practical 11.png

Note: Manual selection of structural modes: a pole can also be manually selected by clicking it or deselected it by same operation. A selected pole will be marked with a shape symbol==

  1. Mode shapes calculation

Press the button of "Calc. Modeshape" to confirm the pole section and BroBand software start to estimate the mode shapes and to calculate the synthesized FRFs.

Modal practical 05.png

  1. Results visualization
Modal practical 10.jpg

To visualize the list of the modes, double click on `EMA: BroBand The list of results will be displayed. By right clicking on a mode and selecting `animate’, the corresponding mode shape will be showed.

Animate.png


MODAL VALIDATION

The first way to check the results is to look at the coherence between the experimental FRFs and the synthesized ones in the selected frequency band.

To go further, results from 2 different methods can be compared using the Modal Assurance Criterion (MAC).

Here, we have results from Broadband method. The repertory `Cantilever modal demo’ contains a file `MIMO1 results’ with the modal parameters obtained from MIMO1 method.

In the operation tree, double click on MAC
Modal practical 28.png

The following window is displayed


Modal practical 29.jpg

Click on Import Modes and select the file `MIMO1 results’ and OK

Modal practical 06.jpg
Mac.png




SAVE/EXPORT

The project can be saved in a workspace containing data, geometry, results… It’s also possible to save independently each part of a project.

    • The data (FRFs) are saved in uff 58
    • Create a file uff 15 containing the geometry by clicking on File/export/geometry,
    • Export the modal results by right clicking on the modes list and select `Export Modes…’
    • Create a file .avi with a mose shape by displaying a mode shape and click on
Modal practical 30.png

in the control panel.