Writing a CSV File
Several of the V-REP simulation scenes require a comma-separated values (CSV) file as input. A CSV file may represent the trajectory of a robot, where each row contains the configuration of the robot at an instant in time, with a fixed time between each row. If the robot has joints, then each row has numbers separated by commas. For example, five rows of a CSV file for a six-joint robot might look like this:
2.950000,-1.570000,0.000000,0.000000,0.000000,0.000000 2.987484,-1.540050,0.019967,0.019992,0.012495,0.009996 3.024875,-1.510399,0.039734,0.039933,0.024958,0.019967 3.062079,-1.481344,0.059104,0.059775,0.037360,0.029888 3.099002,-1.453174,0.077884,0.079468,0.049667,0.039734
Below are code snippets in Python, MATLAB, and Mathematica that you can modify to create your own CSV files.
This page contains information on getting started quickly with V-REP. This page contains a number of scenes that accept CSV file inputs for visualization of robot trajectories.
Python
import numpy as np
# Generate random 3x4 matrix of floats y, 3x1 vector of ints d
y = np.random.rand(3, 4)
d = np.random.randint(-100, 100, 3)
# Open a file for output
# Overwrite
f = open("output.csv", "w")
# Append
#f = open("output.csv", "a")
# For loop running 3 times to print each csv row
for i in range(len(d)):
output = " %10.6f, %10.6f, %10.6f, %10.6f, %d\n" % (y[i,0], y[i,1], y[i,2], y[i,3], d[i])
f.write(output)
# close file
f.close()
The code below is a somewhat simpler version.
import numpy as np
# Generate random 3x4 matrix of floats y, 3x1 vector of ints d
y = np.random.rand(3, 4)
d = np.random.randint(-100, 100, 3)
# Set number precision
y = np.round(y, 6)
# Overwrite csv file
np.savetxt("output.csv", np.asarray(np.c_[y, d]), delimiter = ",")
MATLAB
% Generate random 3x4 matrix of floats y, 3x1 vector of ints d
y = rand(3, 4);
d = randi([-100, 100], 3, 1);
% Open a file for output
% Overwrite
f = fopen('output.csv', 'w');
% Append
%f = fopen('output.csv', 'a');
% For loop running 3 times to print each csv row
for i = 1: length(d)
fprintf(f, ' %10.6f, %10.6f, %10.6f, %10.6f, %d\n', y(i, :), d(i));
end
% Close file
fclose(f);
The code below is a somewhat simpler version.
% Generate random 3x4 matrix of floats y, 3x1 vector of ints d
y = rand(3, 4);
d = randi([-100, 100], 3, 1);
% Set number precision
y = round(y, 6);
% Overwrite csv file
csvwrite('output.csv', [y, d]);
Mathematica
(* Generate random 3x4 matrix of floats y,3x1 vector of ints d *)
y = RandomReal[1, {3, 4}];
d = RandomInteger[{-100, 100}, {3, 1}];
(* Open a file for output *)
(* Overwrite *)
f = OpenWrite[FileNameJoin[{NotebookDirectory[], "output.csv"}]];
(* Append *)
(* \
f=OpenAppend[FileNameJoin[{NotebookDirectory[],"output.csv"}]]; *)
(* For loop running 3 times to print each csv row *)
Do[WriteString[f,
ExportString[{Flatten[{SetAccuracy[y[[i, ;;]], 6], d[[i]]}]},
"CSV"]], {i, Length[d]}];
(* Close file *)
Close[f];
The code below is a somewhat simpler version.
(* Generate random 3x4 matrix of floats y,3x1 vector of ints d *)
y = RandomReal[1, {3, 4}];
d = RandomInteger[{-100, 100}, {3, 1}];
(* Set number precision *)
y = SetAccuracy[y, 6];
(* Overwrite csv file *)
Export[FileNameJoin[{NotebookDirectory[], "output.csv"}],
ArrayFlatten[{{y, d}}], "CSV"];
