Skip to main content

Read and plot slow and fast data binary files from centrifuge experiments conducted at Center of Geotechnical Modeling at University of California Davis

Project description

DAQData

Usage

Read and plot slow and fast data binary files from centrifuge experiments conducted at Center of Geotechnical Modeling at University of California Davis

Features

  • Reads slow and fast data binary files.
  • List downs all the sensors,channels,configuration list, sampling rate...
  • Extract all data or a subset of a data within a time frame as a pandas DataFrame object
  • Plot data directly from the binary file.
  • supports reading and plotting large data files.

Installation

This package is availably via pypi:

pip install DAQData

Read meta data from the binary file

import DAQData as DQ;

# Centrifuge CGM (UC Davis) data file. Can be slow as well as fast data 
Data_File = "./Binary_Data_Files/07122019@121326@154548@64.4rpm.bin";

# By default the, 'Extract_Data' parameter is set to be True. If the files are
# very large and only meta data needs to be checked, the data extraction can be
# stooped by setting 'Extract_Data' parameter false. This would increase the
# execution speed but will not read any data 
Data_DAQ = DQ.DAQ(Data_File,Extract_Data=True);

# To print all the meta data 
print(Data_DAQ)


# Extracting meta data
FileName                      = Data_DAQ.FileName; # gets the filename
Sampling_Rate                 = Data_DAQ.Sampling_Rate; # gets Sampling_Rate
Number_of_Channels            = Data_DAQ.Number_of_Channels; # gets number of channels
Number_of_Hardware_Channels   = Data_DAQ.Number_of_Hardware_Channels; # gets number of hardware channels
Number_of_Sensors             = Data_DAQ.Number_of_Sensors # gets number of Xdcr_Serial Numbers (also referred as sensors)
Channel_List                  = Data_DAQ.Channel_List; # gets the channel list
Hardware_Channel_List         = Data_DAQ.Hardware_Channel_List; # get the hardware channel list
Sensor_List                   = Data_DAQ.Sensor_List; # gets the sensor list 
Number_of_Samples             = Data_DAQ.Number_of_Samples; # gets the total number of samples per sensor 
Data_Length                   = Data_DAQ.Data_Length; # gets the total data length in the binary file. Number_of_Samples*Number_of_sensors
Channel_Dictionary            = Data_DAQ.Channel_Dictionary; # returns a dictionary of channel name to the column number in the Channel List  
ExcelConfig                   = Data_DAQ.ExcelConfig; # return excel configuration file as a csv string 

Extract data on demand

import DAQData as DQ;

Data_File = "./Binary_Data_Files/07122019@121326@154548@64.4rpm.bin";
Data_DAQ  = DQ.DAQ(Data_File,Extract_Data=True);


# If the 'Extract_Data' parameter is True, the whole data is already read and extracted and can be easily retrieved as
Sensor_Data         = Data_DAQ.Sensor_Data;	# 2-D pandas DataFrame with column names (headers) as Channel Names 
print(Sensor_Data.head(2)); # shows first 2 rows of the data set
# print(Sensor_Data.shape); # gets the size of the dataset (rows,columns)
# print(Sensor_Data['ICP1-0']) # will retrieve the data for channel no  'ICP1-0'
# print(Sensor_Data.columns) # will show all the header names in the data. It is the same as the Channel List. 

# The column names can be renamed to sensor names or any other meaningful names as shown below
Sensor_Data.columns = ["TIME (s)","EAST (g)","WEST (g)","P1_ACC_H2 (g)","P2_ACC_H2 (g)","P1_G1 (lbf)","P1_G2 (lbf)","P1_G3 (lbf)","P1_G4 (lbf)","P1_G5 (lbf)","P1_G6 (lbf)","P1_G7 (lbf)","P1_G8 (lbf)","P2_ACC-V1 (g)","P2_ACC_H1 (g)","4th RING (g)","SOUTH (g)","P1_ACC_H1 (g)","P1_ACC_V1 (g)","NORTH (g)","P2_G1 (lbf)","P2_G2 (lbf)","P2_G3 (lbf)","P2_G4 (lbf)","P2_G5 (lbf)","P2_G6 (lbf)","P2_G7 (lbf)","P2_G8 (lbf)","P1_G9 (lbf)","P2_G9 (lbf)","dummy3","Dummy_2","PPT_5 (kPa)","PPT_3 (kPa)","PPT_9 (kPa)","PPT_1 (kPa)","PPT_8 (kPa)","PPT_6 (kPa)","PPT_2 (kPa)","PPT_7 (kPa)","PPT_5442","PPT_4 (kPa)","PPT_10 (kPa)","PPT_10_Proxy (kPa)","Dummy-127926","ACC_6 (g)","ACC_1 (g)","ACC_3 (g)","ACC_5 (g)","ACC_2 (g)","ACC_7 (g)","ACC_4 (g)","dummy21320","dummy-108849","PT 9F008","P2_LP (mm)","P2_MEM (g)","SM2 (mm)","P1_MEM (g)","P1_LP (mm)","SM1 (mm)","PPT_22 (kPa)","PPT_14 (kPa)","PPT_16 (kPa)","PPT_15 (kPa)","PPT_21 (kPa)","MS5407_115","PPT_18 (kPa)","PPT_20 (kPa)","PPT_19 (kPa)","PPT_12 (kPa)","PPT_1 (kPa)","PPT_11 (kPa)","PPT_17 (kPa)","CPT (lbf)","EXT (lbf)","PLT (lbf)","ACT (mm)"]; # here as an example the channel names 'ICP1-0' is renamed to 'EAST (g)'
print(Sensor_Data.head(2)); # shows first 2 columns of the data with new column names
# print(Sensor_Data['EAST (g)']) # will retrieve the data corresponding to column name  'EAST (g)'. Will give the same result (print(Sensor_Data['ICP1-0'])) has the headers or column names not renames 

# If the 'Extract_Data' parameter was initially set to False, the data can be extracted on demand by defining the start and end time
# ..... Time_Data, Sesnor_Data = Data_DAQ.Extract(Start_Time=0, End_Time=10)
# To extract the whole data, set the start time to be 0 and end time to be Number_of_Samples/Sampling_Rate

Data_DAQ  = DQ.DAQ(Data_File,Extract_Data=False);
Sensor_Data = Data_DAQ.Extract(Start_Time=0,End_Time=Number_of_Samples/Sampling_Rate);

# print(Sensor_Data.shape) # would return the same length of data as above 

Plot data

import DAQData as DQ;

Data_File = "./Binary_Data_Files/07122019@121326@154548@64.4rpm.bin";
Data_DAQ  = DQ.DAQ(Data_File,Extract_Data=True);

Sensor_Data = Data_DAQ.Sensor_Data;

# get the time data 
Time_Data   = Sensor_Data['TIME']; 
# if the headers were changed as in the previous above examples 
# it can be extracted as Time_Data   = Sensor_Data['TIME (s)']; 

# get the sensor data of interest
# extract the data from the Sensor_Data DataFrame
Input_Acceleration    = Sensor_Data['ICP1-0'];
# if the headers were changed as in the previous above examples 
# it can be extracted as Time_Data   = Sensor_Data['EAST (g)']; 

# extract the sensor name
Sensor_Name   = Data_DAQ.Sensor_List[Data_DAQ.get_Channel_Index(Channel_Name='ICP1-0')];

import matplotlib.pyplot as plt;

plt.figure(figsize=(8,3));
plt.plot(Time_Data,Input_Acceleration,'k',label=Sensor_Name);
plt.legend(loc='best')
plt.grid(axis='both', which='major', ls='-')
plt.grid(axis='both', which='minor', ls='--', alpha=0.4)
plt.minorticks_on()
plt.xlabel('Time [s]')
plt.ylabel('Acc [g]')
plt.ylim([-10,10])
plt.tight_layout();
plt.show();

example3


Send your comments, bugs, issues and features to add to Sumeet Kumar Sinha at sumeet.kumar507@gmail.com. Please feel free to create issues on https://github.com/SumeetSinha/DAQData/issues

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

DAQData-2.4.tar.gz (9.1 kB view hashes)

Uploaded Source

Built Distribution

DAQData-2.4-py3-none-any.whl (19.3 kB view hashes)

Uploaded Python 3

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page