{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
*;`R05A_Before`
*: Interface "A" before any testing (mint-condition)
*;`R05B_Before`
*: Interface "B" before any testing (mint-condition)
*;`R05A_After`
*: Interface "A" after the first round of 8hr testing
*;`R05B_After`
*: Interface "B" after the first round of (8hr) testing
*;`R05A_After2`
*: Interface "A" after the second round of (4hr) testing
*;`R05B_After2`
*: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

* 3 sets of shaker test data are provided,
** `FirstRound_16Dec2020` : The first round. Includes
***;`RandFRF_Before`, `RandFRF_After`
***: Random FRF Test
***;`StepSine_Before`, `StepSine_After`
***: Step Sine Tests
***;`SingFreqTest` : Single Frequency Test
** `SecondRound_17Dec2020` : The second round. Includes
***;`RandFRF_After`
***: Random FRF Test
***;`StepSine_After`
***: Step Sine Test
***;`SingFreqTest`
***: Single Frequency Test
** `ThirdRound_18Dec2020` : The final round. Includes
***;`RandFRF_Before`, `RandFRF_After`
***: Random FRF Test
***;`StepSine_Before`, `StepSine_After`
***: Step Sine Tests
***;`SingFreqTest`
***: Single Frequency Test
* All the shaker data are collected in the time domain so the postprocessing scripts provided below also do the time-to frequency domain conversion

== Single Frequency Tests ==

* Three sets corresponding to the three 4 hour tests are provided,
** `FirstRound`
** `SecondRound`
** `ThirdRound`
* The data are provided as CSV files with names following the convention: `<prefix>_V<vlevel>_singfreq<index>.csv`
* For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the data from the `FirstRun`, undergoing an excitation of `1.2 V` at the stated frequency (172 Hz everywhere).
** The index 100 implies that this is the 100th file recorded for this case.
** Each file is a block recorded once every \~140seconds (the exact value can be obtained from `(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the code).
** The file with `<index>` 0 corresponds to test conducted with zero inputs (this can be used to estimate noise)
* The rows are organized as follows:
** Row 1: Name of channel
** Row 2: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
** Rows 3-: The data corresponding to each channel
* The MATLAB Script `singfreq_a_postproc.m` shows how these are postprocessed and written into .mat files
* The MATLAB Script `singfreq_b_makeplots.m` shows how to load the .mat files produced by the first script to make plots

[[File:SingFreq_AF_FirstRun_F1A1.png|500px|center|Sample force-acceleration data]]

== Random FRF Test ==

* Five sets of random FRF data are provided,
*;`FirstRound/RandFRF_Before`
*: The tests done
*;`FirstRound/RandFRF_After`
*: Done after 4hrs of monotone tests
*;`SecondRound/RandFRF_After`
*: Done after 8 hrs of monotone tests
*;`ThirdRound/RandFRF_Before`
*: Done after reassembly
*;`ThirdRound/RandFRF_After`
*: Done finally

* The data files are provided as csv files with naming convention:
<prefix>_V<level>_randfrf<index>.csv
where `<prefix>` & `<level>` mean the same as before, but `<index>` implies the realization of the random excitation test.
* For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it was the 9th repeat collected as part of the `FirstRun`, with an RMS input voltage of `1.0 V`
* The data are provided as csv files with rows organized similar to above, as
*;Row 1
*: Name of channel
*;Row 2
*: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
*;Rows 3-
*: The data corresponding to each channel

* The script `randfrf_a_postprof.m` provides MATLAB code to load and postprocess the data appropriately
* The script `randfrf_b_plots.m` shows how to load the data from the above to plot the FRF
[[File:FirstR_randfrf_5.png|500px|center|A sample of the random FRF data]]

== Step Sine Tests ==

* "Open-loop" Step-sine tests were conducted by imposing different voltage amplitudes and stepping through a set of frequencies
* Similar to before, five sets of step sine test data are provided.
*;`FirstRound/StepSine_Before`
*: First set of step sine
*;`FirstRound/StepSine_After`
*: Done after 4hrs of testing
*;`SecondRound/StepSine_After`
*: Done after 8hrs of testing
*;`ThirdRound/StepSine_Before`
*: Done after reassembly
*;`ThirdRound/StepSine_After`
*: Done after final 4hrs of testing

* The time-domain data are provided in csv files named with the convention:
<prefix>_V<level>_stepsine<index>.csv
where `<index>` corresponds to different frequency points along the step sine curve.

* The rows of the data files are
*;Row 1
*: Channel name
*;Row 2
*: Channel sampling time Δ t (s)
*;Row 3
*: Excitation frequency (Hz)
*;Rows 4-
*: Recorded data for each channel

* The script `stepsine_a_postproc.m` shows a sample of the postprocessing done in MATLAB
* The script `stepsine_b_makeplots` shows how to make plots using the data.

[[File:StepSine_SecondRun.png|500px|center|Sample of the step sine data]]

File:StepSine SecondRun.png

2023-12-18T13:05:56Z

Nidish9644:

Brb lterm multiscale21

2023-12-18T13:04:08Z

Nidish9644: /* Random FRF Test */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
*;`R05A_Before`
*: Interface "A" before any testing (mint-condition)
*;`R05B_Before`
*: Interface "B" before any testing (mint-condition)
*;`R05A_After`
*: Interface "A" after the first round of 8hr testing
*;`R05B_After`
*: Interface "B" after the first round of (8hr) testing
*;`R05A_After2`
*: Interface "A" after the second round of (4hr) testing
*;`R05B_After2`
*: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

* 3 sets of shaker test data are provided,
** `FirstRound_16Dec2020` : The first round. Includes
***;`RandFRF_Before`, `RandFRF_After`
***: Random FRF Test
***;`StepSine_Before`, `StepSine_After`
***: Step Sine Tests
***;`SingFreqTest` : Single Frequency Test
** `SecondRound_17Dec2020` : The second round. Includes
***;`RandFRF_After`
***: Random FRF Test
***;`StepSine_After`
***: Step Sine Test
***;`SingFreqTest`
***: Single Frequency Test
** `ThirdRound_18Dec2020` : The final round. Includes
***;`RandFRF_Before`, `RandFRF_After`
***: Random FRF Test
***;`StepSine_Before`, `StepSine_After`
***: Step Sine Tests
***;`SingFreqTest`
***: Single Frequency Test
* All the shaker data are collected in the time domain so the postprocessing scripts provided below also do the time-to frequency domain conversion

== Single Frequency Tests ==

* Three sets corresponding to the three 4 hour tests are provided,
** `FirstRound`
** `SecondRound`
** `ThirdRound`
* The data are provided as CSV files with names following the convention: `<prefix>_V<vlevel>_singfreq<index>.csv`
* For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the data from the `FirstRun`, undergoing an excitation of `1.2 V` at the stated frequency (172 Hz everywhere).
** The index 100 implies that this is the 100th file recorded for this case.
** Each file is a block recorded once every \~140seconds (the exact value can be obtained from `(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the code).
** The file with `<index>` 0 corresponds to test conducted with zero inputs (this can be used to estimate noise)
* The rows are organized as follows:
** Row 1: Name of channel
** Row 2: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
** Rows 3-: The data corresponding to each channel
* The MATLAB Script `singfreq_a_postproc.m` shows how these are postprocessed and written into .mat files
* The MATLAB Script `singfreq_b_makeplots.m` shows how to load the .mat files produced by the first script to make plots

[[File:SingFreq_AF_FirstRun_F1A1.png|500px|center|Sample force-acceleration data]]

== Random FRF Test ==

* Five sets of random FRF data are provided,
*;`FirstRound/RandFRF_Before`
*: The tests done
*;`FirstRound/RandFRF_After`
*: Done after 4hrs of monotone tests
*;`SecondRound/RandFRF_After`
*: Done after 8 hrs of monotone tests
*;`ThirdRound/RandFRF_Before`
*: Done after reassembly
*;`ThirdRound/RandFRF_After`
*: Done finally

* The data files are provided as csv files with naming convention:
<prefix>_V<level>_randfrf<index>.csv
where `<prefix>` & `<level>` mean the same as before, but `<index>` implies the realization of the random excitation test.
* For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it was the 9th repeat collected as part of the `FirstRun`, with an RMS input voltage of `1.0 V`
* The data are provided as csv files with rows organized similar to above, as
*;Row 1
*: Name of channel
*;Row 2
*: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
*;Rows 3-
*: The data corresponding to each channel

* The script `randfrf_a_postprof.m` provides MATLAB code to load and postprocess the data appropriately
* The script `randfrf_b_plots.m` shows how to load the data from the above to plot the FRF
[[File:FirstR_randfrf_5.png|500px|center|A sample of the random FRF data]]

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

File:FirstR randfrf 5.png

2023-12-18T13:03:46Z

Nidish9644:

Brb lterm multiscale21

2023-12-18T13:00:05Z

Nidish9644: /* Shaker Test Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
*;`R05A_Before`
*: Interface "A" before any testing (mint-condition)
*;`R05B_Before`
*: Interface "B" before any testing (mint-condition)
*;`R05A_After`
*: Interface "A" after the first round of 8hr testing
*;`R05B_After`
*: Interface "B" after the first round of (8hr) testing
*;`R05A_After2`
*: Interface "A" after the second round of (4hr) testing
*;`R05B_After2`
*: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

* 3 sets of shaker test data are provided,
** `FirstRound_16Dec2020` : The first round. Includes
***;`RandFRF_Before`, `RandFRF_After`
***: Random FRF Test
***;`StepSine_Before`, `StepSine_After`
***: Step Sine Tests
***;`SingFreqTest` : Single Frequency Test
** `SecondRound_17Dec2020` : The second round. Includes
***;`RandFRF_After`
***: Random FRF Test
***;`StepSine_After`
***: Step Sine Test
***;`SingFreqTest`
***: Single Frequency Test
** `ThirdRound_18Dec2020` : The final round. Includes
***;`RandFRF_Before`, `RandFRF_After`
***: Random FRF Test
***;`StepSine_Before`, `StepSine_After`
***: Step Sine Tests
***;`SingFreqTest`
***: Single Frequency Test
* All the shaker data are collected in the time domain so the postprocessing scripts provided below also do the time-to frequency domain conversion

== Single Frequency Tests ==

* Three sets corresponding to the three 4 hour tests are provided,
** `FirstRound`
** `SecondRound`
** `ThirdRound`
* The data are provided as CSV files with names following the convention: `<prefix>_V<vlevel>_singfreq<index>.csv`
* For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the data from the `FirstRun`, undergoing an excitation of `1.2 V` at the stated frequency (172 Hz everywhere).
** The index 100 implies that this is the 100th file recorded for this case.
** Each file is a block recorded once every \~140seconds (the exact value can be obtained from `(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the code).
** The file with `<index>` 0 corresponds to test conducted with zero inputs (this can be used to estimate noise)
* The rows are organized as follows:
** Row 1: Name of channel
** Row 2: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
** Rows 3-: The data corresponding to each channel
* The MATLAB Script `singfreq_a_postproc.m` shows how these are postprocessed and written into .mat files
* The MATLAB Script `singfreq_b_makeplots.m` shows how to load the .mat files produced by the first script to make plots

[[File:SingFreq_AF_FirstRun_F1A1.png|500px|center|Sample force-acceleration data]]

== Random FRF Test ==

* Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

Brb lterm multiscale21

2023-12-18T12:59:03Z

Nidish9644: /* Interfacial Scan Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
*;`R05A_Before`
*: Interface "A" before any testing (mint-condition)
*;`R05B_Before`
*: Interface "B" before any testing (mint-condition)
*;`R05A_After`
*: Interface "A" after the first round of 8hr testing
*;`R05B_After`
*: Interface "B" after the first round of (8hr) testing
*;`R05A_After2`
*: Interface "A" after the second round of (4hr) testing
*;`R05B_After2`
*: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

* 3 sets of shaker test data are provided,
** `FirstRound_16Dec2020` : The first round. Includes
*** `RandFRF_Before`, `RandFRF_After` : Random FRF Test
***`StepSine_Before`, `StepSine_After` : Step Sine Tests
***`SingFreqTest` : Single Frequency Test
** `SecondRound_17Dec2020` : The second round. Includes
***`RandFRF_After` : Random FRF Test
***`StepSine_After` : Step Sine Test
***`SingFreqTest` : Single Frequency Test
** `ThirdRound_18Dec2020` : The final round. Includes
***`RandFRF_Before`, `RandFRF_After` : Random FRF Test
***`StepSine_Before`, `StepSine_After` : Step Sine Tests
***`SingFreqTest` : Single Frequency Test
* All the shaker data are collected in the time domain so the postprocessing scripts provided below also do the time-to frequency domain conversion

== Single Frequency Tests ==

* Three sets corresponding to the three 4 hour tests are provided,
** `FirstRound`
** `SecondRound`
** `ThirdRound`
* The data are provided as CSV files with names following the convention: `<prefix>_V<vlevel>_singfreq<index>.csv`
* For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the data from the `FirstRun`, undergoing an excitation of `1.2 V` at the stated frequency (172 Hz everywhere).
** The index 100 implies that this is the 100th file recorded for this case.
** Each file is a block recorded once every \~140seconds (the exact value can be obtained from `(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the code).
** The file with `<index>` 0 corresponds to test conducted with zero inputs (this can be used to estimate noise)
* The rows are organized as follows:
** Row 1: Name of channel
** Row 2: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
** Rows 3-: The data corresponding to each channel
* The MATLAB Script `singfreq_a_postproc.m` shows how these are postprocessed and written into .mat files
* The MATLAB Script `singfreq_b_makeplots.m` shows how to load the .mat files produced by the first script to make plots

[[File:SingFreq_AF_FirstRun_F1A1.png|500px|center|Sample force-acceleration data]]

== Random FRF Test ==

* Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

Brb lterm multiscale21

2023-12-18T12:57:43Z

Nidish9644: /* Single Frequency Tests */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
;`R05A_Before`
: Interface "A" before any testing (mint-condition)
;`R05B_Before`
: Interface "B" before any testing (mint-condition)
;`R05A_After`
: Interface "A" after the first round of 8hr testing
;`R05B_After`
: Interface "B" after the first round of (8hr) testing
;`R05A_After2`
: Interface "A" after the second round of (4hr) testing
;`R05B_After2`
: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

* 3 sets of shaker test data are provided,
** `FirstRound_16Dec2020` : The first round. Includes
*** `RandFRF_Before`, `RandFRF_After` : Random FRF Test
***`StepSine_Before`, `StepSine_After` : Step Sine Tests
***`SingFreqTest` : Single Frequency Test
** `SecondRound_17Dec2020` : The second round. Includes
***`RandFRF_After` : Random FRF Test
***`StepSine_After` : Step Sine Test
***`SingFreqTest` : Single Frequency Test
** `ThirdRound_18Dec2020` : The final round. Includes
***`RandFRF_Before`, `RandFRF_After` : Random FRF Test
***`StepSine_Before`, `StepSine_After` : Step Sine Tests
***`SingFreqTest` : Single Frequency Test
* All the shaker data are collected in the time domain so the postprocessing scripts provided below also do the time-to frequency domain conversion

== Single Frequency Tests ==

* Three sets corresponding to the three 4 hour tests are provided,
** `FirstRound`
** `SecondRound`
** `ThirdRound`
* The data are provided as CSV files with names following the convention: `<prefix>_V<vlevel>_singfreq<index>.csv`
* For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the data from the `FirstRun`, undergoing an excitation of `1.2 V` at the stated frequency (172 Hz everywhere).
** The index 100 implies that this is the 100th file recorded for this case.
** Each file is a block recorded once every \~140seconds (the exact value can be obtained from `(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the code).
** The file with `<index>` 0 corresponds to test conducted with zero inputs (this can be used to estimate noise)
* The rows are organized as follows:
** Row 1: Name of channel
** Row 2: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
** Rows 3-: The data corresponding to each channel
* The MATLAB Script `singfreq_a_postproc.m` shows how these are postprocessed and written into .mat files
* The MATLAB Script `singfreq_b_makeplots.m` shows how to load the .mat files produced by the first script to make plots

[[File:SingFreq_AF_FirstRun_F1A1.png|500px|center|Sample force-acceleration data]]

== Random FRF Test ==

* Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

File:SingFreq AF FirstRun F1A1.png

2023-12-18T12:57:21Z

Nidish9644:

Brb lterm multiscale21

2023-12-18T12:56:44Z

Nidish9644: /* Shaker Test Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
;`R05A_Before`
: Interface "A" before any testing (mint-condition)
;`R05B_Before`
: Interface "B" before any testing (mint-condition)
;`R05A_After`
: Interface "A" after the first round of 8hr testing
;`R05B_After`
: Interface "B" after the first round of (8hr) testing
;`R05A_After2`
: Interface "A" after the second round of (4hr) testing
;`R05B_After2`
: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

* 3 sets of shaker test data are provided,
** `FirstRound_16Dec2020` : The first round. Includes
*** `RandFRF_Before`, `RandFRF_After` : Random FRF Test
***`StepSine_Before`, `StepSine_After` : Step Sine Tests
***`SingFreqTest` : Single Frequency Test
** `SecondRound_17Dec2020` : The second round. Includes
***`RandFRF_After` : Random FRF Test
***`StepSine_After` : Step Sine Test
***`SingFreqTest` : Single Frequency Test
** `ThirdRound_18Dec2020` : The final round. Includes
***`RandFRF_Before`, `RandFRF_After` : Random FRF Test
***`StepSine_Before`, `StepSine_After` : Step Sine Tests
***`SingFreqTest` : Single Frequency Test
* All the shaker data are collected in the time domain so the postprocessing scripts provided below also do the time-to frequency domain conversion

== Single Frequency Tests ==

* Three sets corresponding to the three 4 hour tests are provided,

** `FirstRound`
** `SecondRound`
** `ThirdRound`

* The data are provided as CSV files with names following the convention: `<prefix>_V<vlevel>_singfreq<index>.csv`

* For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the data from the `FirstRun`, undergoing an excitation of `1.2 V` at the stated frequency (172 Hz everywhere).

** The index 100 implies that this is the 100th file recorded for this case.
** Each file is a block recorded once every \~140seconds (the exact value can be obtained from `(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the code).
** The file with `<index>` 0 corresponds to test conducted with zero inputs (this can be used to estimate noise)

* The rows are organized as follows:

** Row 1: Name of channel
** Row 2: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
** Rows 3-: The data corresponding to each channel

* The MATLAB Script `singfreq_a_postproc.m` shows how these are postprocessed and written into .mat files

* The MATLAB Script `singfreq_b_makeplots.m` shows how to load the .mat files produced by the first script to make plots

![](FIGS/SingFreq_AF_FirstRun_F1A1.png)

== Random FRF Test ==

* Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

Brb lterm multiscale21

2023-12-18T12:55:40Z

Nidish9644: /* Shaker Test Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
;`R05A_Before`
: Interface "A" before any testing (mint-condition)
;`R05B_Before`
: Interface "B" before any testing (mint-condition)
;`R05A_After`
: Interface "A" after the first round of 8hr testing
;`R05B_After`
: Interface "B" after the first round of (8hr) testing
;`R05A_After2`
: Interface "A" after the second round of (4hr) testing
;`R05B_After2`
: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

* 3 sets of shaker test data are provided,
** `FirstRound_16Dec2020` : The first round. Includes
;`RandFRF_Before`, `RandFRF_After`
: Random FRF Test
;`StepSine_Before`, `StepSine_After`
: Step Sine Tests
;`SingFreqTest`
: Single Frequency Test
** `SecondRound_17Dec2020` : The second round. Includes
;`RandFRF_After`
: Random FRF Test
;`StepSine_After`
: Step Sine Test
;`SingFreqTest`
: Single Frequency Test
** `ThirdRound_18Dec2020` : The final round. Includes
;`RandFRF_Before`, `RandFRF_After`
: Random FRF Test
;`StepSine_Before`, `StepSine_After`
: Step Sine Tests
;`SingFreqTest`
: Single Frequency Test
* All the shaker data are collected in the time domain so the postprocessing scripts provided below also do the time-to frequency domain conversion

== Single Frequency Tests ==

* Three sets corresponding to the three 4 hour tests are provided,

** `FirstRound`
** `SecondRound`
** `ThirdRound`

* The data are provided as CSV files with names following the convention: `<prefix>_V<vlevel>_singfreq<index>.csv`

* For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the data from the `FirstRun`, undergoing an excitation of `1.2 V` at the stated frequency (172 Hz everywhere).

** The index 100 implies that this is the 100th file recorded for this case.
** Each file is a block recorded once every \~140seconds (the exact value can be obtained from `(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the code).
** The file with `<index>` 0 corresponds to test conducted with zero inputs (this can be used to estimate noise)

* The rows are organized as follows:

** Row 1: Name of channel
** Row 2: Sampling time Δ t (s) of channel (each channel can be sampled differently based on the type of sensore: ICP, strain gauge, thermocouple, etc.)
** Rows 3-: The data corresponding to each channel

* The MATLAB Script `singfreq_a_postproc.m` shows how these are postprocessed and written into .mat files

* The MATLAB Script `singfreq_b_makeplots.m` shows how to load the .mat files produced by the first script to make plots

![](FIGS/SingFreq_AF_FirstRun_F1A1.png)

== Random FRF Test ==

* Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

Brb lterm multiscale21

2023-12-18T12:50:43Z

Nidish9644: /* Hammer Impact Test Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
;`R05A_Before`
: Interface "A" before any testing (mint-condition)
;`R05B_Before`
: Interface "B" before any testing (mint-condition)
;`R05A_After`
: Interface "A" after the first round of 8hr testing
;`R05B_After`
: Interface "B" after the first round of (8hr) testing
;`R05A_After2`
: Interface "A" after the second round of (4hr) testing
;`R05B_After2`
: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

* Two sets of impact test data are provided, labeled "Initial" and "Final"
* The "Initial" data corresponds to the impact tests conducted right after assembling the beams for the first time
* The "Final data corresponds to the impact tests conducted after the 12 hour experimental campaign concluded
* The data can be found in the `DATA/IMPACT_DATA/` folder
* A MATLAB script `impact_a_loadshow.m` shows how to load and plot the data
[[File:IMPACT_4.png|500px|center|Sample output from the impact data script]]
* The first channel in `Signal_1` is the acceleration along the direction of input

= Shaker Test Data =

- 3 sets of shaker test data are provided,
- `FirstRound_16Dec2020` : The first round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- `SecondRound_17Dec2020` : The second round. Includes
- `RandFRF_After` : Random FRF Test
- `StepSine_After` : Step Sine Test
- `SingFreqTest` : Single Frequency Test
- `ThirdRound_18Dec2020` : The final round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- All the shaker data are collected in the time domain so the
postprocessing scripts provided below also do the time-to frequency
domain conversion

== Single Frequency Tests ==

- Three sets corresponding to the three 4 hour tests are provided,

- `FirstRound`
- `SecondRound`
- `ThirdRound`

- The data are provided as CSV files with names following the
convention: `<prefix>_V<vlevel>_singfreq<index>.csv`

- For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the
data from the `FirstRun`, undergoing an excitation of `1.2 V` at the
stated frequency (172 Hz everywhere).

- The index 100 implies that this is the 100th file recorded for
this case.
- Each file is a block recorded once every \~140seconds (the exact
value can be obtained from
`(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the
code).
- The file with `<index>` 0 corresponds to test conducted with
zero inputs (this can be used to estimate noise)

- The rows are organized as follows:

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The MATLAB Script `singfreq_a_postproc.m` shows how these are
postprocessed and written into .mat files

- The MATLAB Script `singfreq_b_makeplots.m` shows how to load the
.mat files produced by the first script to make plots

![](FIGS/SingFreq_AF_FirstRun_F1A1.png)

== Random FRF Test ==

- Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

File:IMPACT 4.png

2023-12-18T12:50:04Z

Nidish9644:

Brb lterm multiscale21

2023-12-18T12:49:03Z

Nidish9644: /* Interfacial Scan Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
;`R05A_Before`
: Interface "A" before any testing (mint-condition)
;`R05B_Before`
: Interface "B" before any testing (mint-condition)
;`R05A_After`
: Interface "A" after the first round of 8hr testing
;`R05B_After`
: Interface "B" after the first round of (8hr) testing
;`R05A_After2`
: Interface "A" after the second round of (4hr) testing
;`R05B_After2`
: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

<nowiki>*</nowiki> Two sets of impact test data are provided, labeled "Initial" and "Final"

<nowiki>*</nowiki> The "Initial" data corresponds to the impact tests conducted right
after assembling the beams for the first time

- The "Final data corresponds to the impact tests conducted after the
12 hour experimental campaign concluded

- The data can be found in the `DATA/IMPACT_DATA/` folder

- A MATLAB script `impact_a_loadshow.m` shows how to load and plot the
data

![](FIGS/IMPACT_4.png)

- The first channel in `Signal_1` is the acceleration along the
direction of input

= Shaker Test Data =

- 3 sets of shaker test data are provided,
- `FirstRound_16Dec2020` : The first round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- `SecondRound_17Dec2020` : The second round. Includes
- `RandFRF_After` : Random FRF Test
- `StepSine_After` : Step Sine Test
- `SingFreqTest` : Single Frequency Test
- `ThirdRound_18Dec2020` : The final round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- All the shaker data are collected in the time domain so the
postprocessing scripts provided below also do the time-to frequency
domain conversion

== Single Frequency Tests ==

- Three sets corresponding to the three 4 hour tests are provided,

- `FirstRound`
- `SecondRound`
- `ThirdRound`

- The data are provided as CSV files with names following the
convention: `<prefix>_V<vlevel>_singfreq<index>.csv`

- For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the
data from the `FirstRun`, undergoing an excitation of `1.2 V` at the
stated frequency (172 Hz everywhere).

- The index 100 implies that this is the 100th file recorded for
this case.
- Each file is a block recorded once every \~140seconds (the exact
value can be obtained from
`(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the
code).
- The file with `<index>` 0 corresponds to test conducted with
zero inputs (this can be used to estimate noise)

- The rows are organized as follows:

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The MATLAB Script `singfreq_a_postproc.m` shows how these are
postprocessed and written into .mat files

- The MATLAB Script `singfreq_b_makeplots.m` shows how to load the
.mat files produced by the first script to make plots

![](FIGS/SingFreq_AF_FirstRun_F1A1.png)

== Random FRF Test ==

- Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

Brb lterm multiscale21

2023-12-18T12:48:15Z

Nidish9644: /* Interfacial Scan Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
;`R05A_Before`
: Interface "A" before any testing (mint-condition)
;`R05B_Before`
: Interface "B" before any testing (mint-condition)
;`R05A_After`
: Interface "A" after the first round of 8hr testing
;`R05B_After`
: Interface "B" after the first round of (8hr) testing
;`R05A_After2`
: Interface "A" after the second round of (4hr) testing
;`R05B_After2`
: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

[[File:ASPSTAT_3.png|500px|center|A sample of the statistics of the asperities in an element]]

= Hammer Impact Test Data =

- Two sets of impact test data are provided, labeled "Initial" and
"Final".

- The "Initial" data corresponds to the impact tests conducted right
after assembling the beams for the first time

- The "Final data corresponds to the impact tests conducted after the
12 hour experimental campaign concluded

- The data can be found in the `DATA/IMPACT_DATA/` folder

- A MATLAB script `impact_a_loadshow.m` shows how to load and plot the
data

![](FIGS/IMPACT_4.png)

- The first channel in `Signal_1` is the acceleration along the
direction of input

= Shaker Test Data =

- 3 sets of shaker test data are provided,
- `FirstRound_16Dec2020` : The first round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- `SecondRound_17Dec2020` : The second round. Includes
- `RandFRF_After` : Random FRF Test
- `StepSine_After` : Step Sine Test
- `SingFreqTest` : Single Frequency Test
- `ThirdRound_18Dec2020` : The final round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- All the shaker data are collected in the time domain so the
postprocessing scripts provided below also do the time-to frequency
domain conversion

== Single Frequency Tests ==

- Three sets corresponding to the three 4 hour tests are provided,

- `FirstRound`
- `SecondRound`
- `ThirdRound`

- The data are provided as CSV files with names following the
convention: `<prefix>_V<vlevel>_singfreq<index>.csv`

- For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the
data from the `FirstRun`, undergoing an excitation of `1.2 V` at the
stated frequency (172 Hz everywhere).

- The index 100 implies that this is the 100th file recorded for
this case.
- Each file is a block recorded once every \~140seconds (the exact
value can be obtained from
`(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the
code).
- The file with `<index>` 0 corresponds to test conducted with
zero inputs (this can be used to estimate noise)

- The rows are organized as follows:

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The MATLAB Script `singfreq_a_postproc.m` shows how these are
postprocessed and written into .mat files

- The MATLAB Script `singfreq_b_makeplots.m` shows how to load the
.mat files produced by the first script to make plots

![](FIGS/SingFreq_AF_FirstRun_F1A1.png)

== Random FRF Test ==

- Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

File:ASPSTAT 3.png

2023-12-18T12:47:49Z

Nidish9644:

Brb lterm multiscale21

2023-12-18T12:47:38Z

Nidish9644: /* Interfacial Scan Data */

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

# Interface scan data captured using a Keyence VR-5100 white light interferometer,
# Hammer Impact Tests
# Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

# Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
# "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

# Interfaces were scanned initially
# Beams were assembled and impact tests were conducted
# Step sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for 4 hrs
# Step Sine and Random tests were conducted with the shaker
# A single sine excitation was provided to the assembly at 172Hz for another 4 hrs
# Step Sine and Random tests were conducted with the shaker
# The beams were **disassembled** and the interfaces were scanned after cleaning
# The beams were assembled again and step sine and random tests were conducted
# A single sine excitation was provided to the assembly at 172Hz for a final 4 hrs
# Step sine and Random tests were conducted with the shaker
# Hammer impact tests were conducted
# The beams were **disassembled** and the interfaces were scanned after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

# Excitation Force (N)
# Strain Gauge 1 (eps)
# Straing Gauge 2 (eps)
# Straing Gauge 3 (eps)
# Acceleration at Excitation Point (g)
# X Accel, left end in figure (g)
# Y Accel, left end in figure (g)
# Z Accel, left end in figure (g)
# X Accel, right end in figure (g)
# Y Accel, right end in figure (g)
# Z Accel, right end in figure (g)
# Thermocouple 1 (deg C)
# Thermocouple 2 (deg C)
# Thermocouple 3 (deg C)

[[File:FULLSETUP_BGBLUR.png|500px|center|A picture of the experimental setup]]

= Interfacial Scan Data =

* Six datasets are provided:
;`R05A_Before`
: Interface "A" before any testing (mint-condition)
;`R05B_Before`
: Interface "B" before any testing (mint-condition)
;`R05A_After`
: Interface "A" after the first round of 8hr testing
;`R05B_After`
: Interface "B" after the first round of (8hr) testing
;`R05A_After2`
: Interface "A" after the second round of (4hr) testing
;`R05B_After2`
: Interface "B" after the second round of (4hr) testing

* For each dataset, the height data are provided in a csv file named as: `<date>_<beam_identifier>_S<index>_<misc>.csv`
** Here, the `S<index>` portion indicates the "Segment Index" going from 1 through 12, since the whole interface
* The relevant scripts are,
** `scan_a_rawdat2meshsort.m`
** `scan_b_visdata.m`
** `scan_c_elemaspID.m`
* The first script, `scan_a_rawdat2meshsort.m`,
** Loads the raw data
** Loads a finite element mesh
** Processes the raw data (outlier rejection, patch-joining, etc.)
** Sorts the data into different elements, and
** saves it into a mat-file.
* The second script, `scan_b_visdata.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Makes basic plots, demonstrating the use of the data
* The third script, `scan_c_elemaspID.m`,
** Loads the processed data from the first script (you have to run the first script first)
** Shows how to extract statistical properties of the asperities
* Here are samples of the data through the processing steps:

[[File:IMPROCDEMO_1.png|500px|center|Optical Views of the data along with the references used for the sorting]]

[[File:AADEMO_2.png|500px|center|A view of one of the datasets after being sorted]]

<figure>
<img src="FIGS/ASPSTAT_3.png" width="500"
alt="A sample of the statistics of the asperities in an element" />
<figcaption aria-hidden="true">A sample of the statistics of the
asperities in an element</figcaption>
</figure>

= Hammer Impact Test Data =

- Two sets of impact test data are provided, labeled "Initial" and
"Final".

- The "Initial" data corresponds to the impact tests conducted right
after assembling the beams for the first time

- The "Final data corresponds to the impact tests conducted after the
12 hour experimental campaign concluded

- The data can be found in the `DATA/IMPACT_DATA/` folder

- A MATLAB script `impact_a_loadshow.m` shows how to load and plot the
data

![](FIGS/IMPACT_4.png)

- The first channel in `Signal_1` is the acceleration along the
direction of input

= Shaker Test Data =

- 3 sets of shaker test data are provided,
- `FirstRound_16Dec2020` : The first round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- `SecondRound_17Dec2020` : The second round. Includes
- `RandFRF_After` : Random FRF Test
- `StepSine_After` : Step Sine Test
- `SingFreqTest` : Single Frequency Test
- `ThirdRound_18Dec2020` : The final round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- All the shaker data are collected in the time domain so the
postprocessing scripts provided below also do the time-to frequency
domain conversion

== Single Frequency Tests ==

- Three sets corresponding to the three 4 hour tests are provided,

- `FirstRound`
- `SecondRound`
- `ThirdRound`

- The data are provided as CSV files with names following the
convention: `<prefix>_V<vlevel>_singfreq<index>.csv`

- For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the
data from the `FirstRun`, undergoing an excitation of `1.2 V` at the
stated frequency (172 Hz everywhere).

- The index 100 implies that this is the 100th file recorded for
this case.
- Each file is a block recorded once every \~140seconds (the exact
value can be obtained from
`(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the
code).
- The file with `<index>` 0 corresponds to test conducted with
zero inputs (this can be used to estimate noise)

- The rows are organized as follows:

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The MATLAB Script `singfreq_a_postproc.m` shows how these are
postprocessed and written into .mat files

- The MATLAB Script `singfreq_b_makeplots.m` shows how to load the
.mat files produced by the first script to make plots

![](FIGS/SingFreq_AF_FirstRun_F1A1.png)

== Random FRF Test ==

- Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>

File:AADEMO 2.png

2023-12-18T12:47:08Z

Nidish9644:

2023-12-18T12:08:50Z

Nidish9644:

{{DISPLAYTITLE:Multi-Scale Data from Long Term Vibration Tests Conducted on The Brake-Reuss Beam (2020-21) }}

This data repository holds the data for the Brake-Reuss Beam (BRB)
measured in Dec, 2021. The repository contains:

1. Interface scan data captured using a Keyence VR-5100 white light interferometer,

2. Hammer Impact Tests

3. Shaker tests (random and sine forcing) with an array of sensors

The first section provides some details about the experiments, but more
details on the data can be found in the following publications:

1. Balaji, Nidish. "Dissipative dynamics of bolted joints." PhD diss., Rice University, 2021. ([https://repository.rice.edu/items/49627bb2-a183-40fd-afdb-022f6006be2e])
2. "Influence of Wear on the Nonlinear Dynamics of a Lap Joint Structure: Observations from Long-Term Experimentation", Balaji, N. N., Smith, S. A., and Brake, M. R. W. (Under Preparation)

= Experimental Details =

== Overview ==

The data were collected over a 12 hour experimental campaign conducted in this sequence:

1. Interfaces were [scanned](color:red) initially
2. Beams were assembled and [impact tests](color:blue) were conducted
3. [Step sine and Random tests](color:magenta) were conducted with the
shaker
4. A [single sine excitation](color:green) was provided to the assembly
at 172Hz for 4 hrs
5. [Step Sine and Random tests](color:magenta) were conducted with the
shaker
6. A [single sine excitation](color:green) was provided to the assembly
at 172Hz for another 4 hrs
7. [Step Sine and Random tests](color:magenta) were conducted with the
shaker
8. The beams were **disassembled** and the interfaces were
[scanned](color:red) after cleaning
9. The beams were assembled again and [step sine and random
tests](color:magenta) were conducted
10. A [single sine excitation](color:green) was provided to the assembly
at 172Hz for a final 4 hrs
11. [Step sine and Random tests](color:magenta) were conducted with the
shaker
12. Hammer [impact tests](color:blue) were conducted
13. The beams were **disassembled** and the interfaces were
[scanned](color:red) after cleaning

[[File:Campaign_new.png|500px|center|A Graphical Overview of the experimental campaign]]

== Sensor Configuration ==

For all the shaker tests, the following 15 channels can be found

1. Excitation Force (N)
2. Strain Gauge 1 (eps)
3. Straing Gauge 2 (eps)
4. Straing Gauge 3 (eps)
5. Acceleration at Excitation Point (g)
6. X Accel, left end in figure (g)
7. Y Accel, left end in figure (g)
8. Z Accel, left end in figure (g)
9. X Accel, right end in figure (g)
10. Y Accel, right end in figure (g)
11. Z Accel, right end in figure (g)
12. Thermocouple 1 (deg C)
13. Thermocouple 2 (deg C)
14. Thermocouple 3 (deg C)

<figure>
<img src="FIGS/FULLSETUP_BGBLUR.png" width="500"
alt="A picture of the experimental setup" />
<figcaption aria-hidden="true">A picture of the experimental
setup</figcaption>
</figure>

= Interfacial Scan Data =

- Six datasets are provided:

- `R05A_Before` : Interface "A" before any testing
(mint-condition)
- `R05B_Before` : Interface "B" before any testing
(mint-condition)
- `R05A_After` : Interface "A" after the first round of 8hr
testing
- `R05B_After` : Interface "B" after the first round of (8hr)
testing
- `R05A_After2` : Interface "A" after the second round of (4hr)
testing
- `R05B_After2` : Interface "B" after the second round of (4hr)
testing

- For each dataset, the height data are provided in a csv file named
as: `<date>_<beam_identifier>_S<index>_<misc>.csv`

- Here, the `S<index>` portion indicates the "Segment Index" going
from 1 through 12, since the whole interface

- The relevant scripts are,

- `scan_a_rawdat2meshsort.m`
- `scan_b_visdata.m`
- `scan_c_elemaspID.m`

- The first script, `scan_a_rawdat2meshsort.m`,

- Loads the raw data
- Loads a finite element mesh
- Processes the raw data (outlier rejection, patch-joining, etc.)
- Sorts the data into different elements, and
- saves it into a mat-file.

- The second script, `scan_b_visdata.m`,

- Loads the processed data from the first script (you have to run
the first script first)
- Makes basic plots, demonstrating the use of the data

- The third script, `scan_c_elemaspID.m`,

- Loads the processed data from the first script (you have to run
the first script first)
- Shows how to extract statistical properties of the asperities

- Here are samples of the data through the processing steps:

<figure>
<img src="FIGS/IMPROCDEMO_1.png" width="500"
alt="Optical Views of the data along with the references used for the sorting" />
<figcaption aria-hidden="true">Optical Views of the data along with the
references used for the sorting</figcaption>
</figure>

<figure>
<img src="FIGS/AADEMO_2.png" width="500"
alt="A view of one of the datasets after being sorted" />
<figcaption aria-hidden="true">A view of one of the datasets after being
sorted</figcaption>
</figure>

<figure>
<img src="FIGS/ASPSTAT_3.png" width="500"
alt="A sample of the statistics of the asperities in an element" />
<figcaption aria-hidden="true">A sample of the statistics of the
asperities in an element</figcaption>
</figure>

= Hammer Impact Test Data =

- Two sets of impact test data are provided, labeled "Initial" and
"Final".

- The "Initial" data corresponds to the impact tests conducted right
after assembling the beams for the first time

- The "Final data corresponds to the impact tests conducted after the
12 hour experimental campaign concluded

- The data can be found in the `DATA/IMPACT_DATA/` folder

- A MATLAB script `impact_a_loadshow.m` shows how to load and plot the
data

![](FIGS/IMPACT_4.png)

- The first channel in `Signal_1` is the acceleration along the
direction of input

= Shaker Test Data =

- 3 sets of shaker test data are provided,
- `FirstRound_16Dec2020` : The first round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- `SecondRound_17Dec2020` : The second round. Includes
- `RandFRF_After` : Random FRF Test
- `StepSine_After` : Step Sine Test
- `SingFreqTest` : Single Frequency Test
- `ThirdRound_18Dec2020` : The final round. Includes
- `RandFRF_Before`, `RandFRF_After` : Random FRF Test
- `StepSine_Before`, `StepSine_After` : Step Sine Tests
- `SingFreqTest` : Single Frequency Test
- All the shaker data are collected in the time domain so the
postprocessing scripts provided below also do the time-to frequency
domain conversion

== Single Frequency Tests ==

- Three sets corresponding to the three 4 hour tests are provided,

- `FirstRound`
- `SecondRound`
- `ThirdRound`

- The data are provided as CSV files with names following the
convention: `<prefix>_V<vlevel>_singfreq<index>.csv`

- For example, the file `FirstRun_V1.2_singfreq100.csv` specifies the
data from the `FirstRun`, undergoing an excitation of `1.2 V` at the
stated frequency (172 Hz everywhere).

- The index 100 implies that this is the 100th file recorded for
this case.
- Each file is a block recorded once every \~140seconds (the exact
value can be obtained from
`(Testinfo.SaveBlocks+Testinfo.IntervalBlocks)*Tblock` in the
code).
- The file with `<index>` 0 corresponds to test conducted with
zero inputs (this can be used to estimate noise)

- The rows are organized as follows:

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The MATLAB Script `singfreq_a_postproc.m` shows how these are
postprocessed and written into .mat files

- The MATLAB Script `singfreq_b_makeplots.m` shows how to load the
.mat files produced by the first script to make plots

![](FIGS/SingFreq_AF_FirstRun_F1A1.png)

== Random FRF Test ==

- Five sets of random FRF data are provided,

- `FirstRound/RandFRF_Before` : The tests done
- `FirstRound/RandFRF_After` : Done after 4hrs of monotone tests
- `SecondRound/RandFRF_After` : Done after 8 hrs of monotone tests
- `ThirdRound/RandFRF_Before` : Done after reassembly
- `ThirdRound/RandFRF_After` : Done finally

- The data files are provided as csv files with naming convention:
`<prefix>_V<level>_randfrf<index>.csv` where `<prefix>` & `<level>`
mean the same as before, but `<index>` implies the realization of
the random excitation test.

- For example, the file `FirstRun_V1.0_randfrf9.csv` implies that it
was the 9th repeat collected as part of the `FirstRun`, with an RMS
input voltage of `1.0 V`

- The data are provided as csv files with rows organized similar to
above, as

- Row 1: Name of channel
- Row 2: Sampling time Δ t (s) of channel (each channel can be
sampled differently based on the type of sensore: ICP, strain
gauge, thermocouple, etc.)
- Rows 3-: The data corresponding to each channel

- The script `randfrf_a_postprof.m` provides MATLAB code to load and
postprocess the data appropriately

- The script `randfrf_b_plots.m` shows how to load the data from the
above to plot the FRF

<figure>
<img src="FIGS/FirstR_randfrf_5.png" width="500"
alt="A sample of the random FRF data" />
<figcaption aria-hidden="true">A sample of the random FRF
data</figcaption>
</figure>

== Step Sine Tests ==

- "Open-loop" Step-sine tests were conducted by imposing different
voltage amplitudes and stepping through a set of frequencies

- Similar to before, five sets of step sine test data are provided.

- `FirstRound/StepSine_Before` : First set of step sine
- `FirstRound/StepSine_After` : Done after 4hrs of testing
- `SecondRound/StepSine_After` : Done after 8hrs of testing
- `ThirdRound/StepSine_Before` : Done after reassembly
- `ThirdRound/StepSine_After` : Done after final 4hrs of testing

- The time-domain data are provided in csv files named with the
convention: `<prefix>_V<level>_stepsine<index>.csv` where `<index>`
corresponds to different frequency points along the step sine curve.

- The rows of the data files are

- Row 1: Channel name
- Row 2: Channel sampling time Δ t (s)
- Row 3: Excitation frequency (Hz)
- Rows 4-: Recorded data for each channel

- The script `stepsine_a_postproc.m` shows a sample of the
postprocessing done in MATLAB

- The script `stepsine_b_makeplots` shows how to make plots using the
data.

<figure>
<img src="FIGS/StepSine_SecondRun.png" width="500"
alt="Sample of the step sine data" />
<figcaption aria-hidden="true">Sample of the step sine data</figcaption>
</figure>