Awesome
VIO Benchmark
A collection of Python scripts for benchmarking Visual-Inertial Odometry (VIO) solutions.
These scripts are best used together with data collection apps which output the used JSONL data format, such as the following:
some of which use jsonl-recorder.
benchmark.py
Usage
benchmark.py
is a library for running multiple parallel benchmarks. It's not a stand alone script. See benchmark/example_benchmark.py
on how to use it.
Running benchmarks sets
To run benchmark sets, use the option -set name_of_the_set
. The benchmark sets are define in json files in current directory or in given -setDir <folder>
.
python benchmark/example_benchmark.py -set example
Following example benchmark set will run each dataset in "benchmarks" array once for every entry in "parameterSets", meaning you will get 6 x 2 = 12 benchmarks ran in total. You can use same dataset with different parameters as seen with the last 4 datasets. "parameterSets" is optional. All "params" flags are appended. If you run a benchmark with flags -set example -params "-something=true"
, the full arguments for dataset euroc-mh-01-vR-01 and first parameter set would be -something=true -customParam1=0.0 -customParam2=0.01
.
{
"benchmarks": [
{"folder": "advio-01"},
{"folder": "advio-02"},
{"folder": "euroc-mh-01-easy", "params": "-customParam1=0.01", "name": "euroc-mh-01-vR-01"},
{"folder": "euroc-mh-01-easy", "params": "-customParam1=0.05", "name": "euroc-mh-01-vR-05"},
{"folder": "euroc-mh-02-easy", "params": "-customParam1=0.01", "name": "euroc-mh-02-vR-01"},
{"folder": "euroc-mh-02-easy", "params": "-customParam1=0.05", "name": "euroc-mh-02-vR-05"}
],
"parameterSets": [
{"params": "-customParam2=0.0", "name": "filterOff"},
{"params": "-customParam2=0.1", "name": "filterOn"}
]
}
combine_jsonl.py
Script for combining JSONL data from multiple sources. Use add_time_offset.py
to synchronize them first.
If you store you data in following layout:
folder/containing/all/datasets
/arcore
/data.jsonl
/info.jsonl
/arkit
/data.jsonl
...
You can combine data into arcore-combined
output folder with:
python -m vio_benchmark.benchmark.combine_jsonl \
arcore \
-root folder/containing/all/datasets/ \
-output arcore-combined \
-arkit arkit \
-rtk rtkgps \
-realsense realsense \
-gps arkit
Benchmark data format
Each dataset, ie a single continuous recording of sensor data, is made out of a single folder with the following contents:
data.jsonl
in the format described below.data.mp4
(or other video file extension) for monocular camera.- (optional)
data2.mp4
second camera for stereo recordings. - (optional)
parameters.txt
see Parameters format below.
JSONL format
This section defines the JSONL-based data format that most scripts in this repository produce or consume. The format can include sensor data used as input and pose estimates produced by different VIO methods.
Timestamps
Each JSONL line that describes temporal data should have a time
field at the root using seconds as units. The whole JSONL file is preferably sorted by these timestamps in ascending order. The timestamps may begin from any value, including negative ones.
Inertial sensors (IMU)
IMU and other "N-axis" sensors define a sensor
field with sub-fields type
and values
. The units for values
are m/s^2 for accelerometer
, rad/s for gyroscope
, μT for magnetometer
, and K for imuTemperature
.
Camera frames
For each frame in data.mp4
, and a perfectly synchronized data2.mp4
in case of stereo, there is a single line with frames
in the root whose array value lists outputs for each camera. The number
field starts from 0 and increments by one per frame. cameraInd
0 refers to data.mp4
and 1 to data2.mp4
. cameraParameters
follow the same format as in Parameters format below, except that matrices given in [[],[],[],[]]
are read as row-major.
GNSS
Defines gps
in the root with the fields longitude
, latitude
, and altitude
(meters) in the Geographic coordinate system. The field accuracy
has no precise definition, but in most cases is a distance (meters) corresponding to a given confidence level.
Ground truth and VIO output
Defines groundTruth
or name of a VIO method in the root, with subfields position
(t
) and optionally orientation
(q
). Position is given in meters, with negative z-axis pointing along gravity. Orientation is given as a unit quaternion. Together these define a 4x4 matrix T = [R(q), t; 0, 1]
that transforms homogeneous device coordinates p_d
to world coordinates p_w
by left-multiplication p_w = T * p_d
.
Example data.jsonl
{"groundTruth":{"position":{"x":-0.007567568216472864,"y":0.022782884538173676,"z":0.00817866250872612},"orientation":{"w":0.53464,"x":-0.15299,"y":-0.826976,"z":-0.082863}},"time":1.444770263671875}
{"sensor":{"type":"accelerometer","values":[-0.03824593499302864,9.121655464172363,-2.983182907104492]},"time":1.43846240234375}
{"sensor":{"type":"gyroscope","values":[0.003195890923961997,-0.17364339530467987,0.015979453921318054]},"time":1.44976953125}
{"sensor":{"type":"imuTemperature","values":[292.8961]},"time":1.44976953125}
{"groundTruth":{"position":{"x":-0.007713410072028637,"y":0.022989293560385704,"z":0.008272084407508373},"orientation":{"w":0.53464,"x":-0.15299,"y":-0.826976,"z":-0.082863}},"time":1.449769287109375}
{"frames":[{"cameraInd":0,"cameraParameters":{"focalLengthX":284.929992675781,"focalLengthY":285.165496826172,"principalPointX":416.4547119140625,"principalPointY":395.77349853515625,"distortionModel":"KANNALA_BRANDT4","distortionCoefficients":[-0.004973,0.03975,-0.0374,0.006239]},"imuToCamera":[[0.01486,0.9995,-0.02577,0.06522],[-0.9998,0.01496,0.003756,-0.0207],[0.00414,0.02571,0.9996,-0.008054],[0,0,0,1]],"time":1.436207275390625},{"cameraInd":1,"cameraParameters":{"focalLengthX":284.559509277344,"focalLengthY":284.4418029785162,"principalPointX":410.81329345703125,"principalPointY":394.1506042480469,"distortionModel":"KANNALA_BRANDT4","distortionCoefficients":[-0.006496,0.04365,-0.04025,0.006813]},"imuToCamera":[[0.01255,0.9995,-0.02538,-0.0449],[-0.9997,0.01301,0.0179,-0.02056],[0.01822,0.02515,0.9995,-0.008638],[0,0,0,1]],"time":1.436207275390625}],"number":28,"time":1.436207275390625}
{"sensor":{"type":"gyroscope","values":[-0.025567127391695976,-0.16512103378772736,0.034089501947164536]},"time":1.4547685546875}
{"sensor":{"type":"imuTemperature","values":[292.8961]},"time":1.4547685546875}
{"groundTruth":{"position":{"x":-0.00783445406705141,"y":0.02315470017492771,"z":0.008362464606761932},"orientation":{"w":0.53464,"x":-0.15299,"y":-0.826976,"z":-0.082863}},"time":1.45476806640625}
{"sensor":{"type":"gyroscope","values":[-0.07137490063905716,-0.1523374617099762,0.04793836548924446]},"time":1.45976806640625}
{"sensor":{"type":"imuTemperature","values":[292.8961]},"time":1.45976806640625}
{"groundTruth":{"position":{"x":-0.007959198206663132,"y":0.023323576897382736,"z":0.008457313291728497},"orientation":{"w":0.53464,"x":-0.15299,"y":-0.826976,"z":-0.082863}},"time":1.459767333984375}
{"sensor":{"type":"accelerometer","values":[0.4015823304653168,9.446745872497559,-2.8301992416381836]},"time":1.4539404296875}
{"sensor":{"type":"gyroscope","values":[-0.12037855386734009,-0.12037855386734009,0.07457078248262405]},"time":1.46476708984375}
{"sensor":{"type":"imuTemperature","values":[292.8961]},"time":1.46476708984375}
{"groundTruth":{"position":{"x":-0.008127331733703613,"y":0.023527292534708977,"z":0.008570007979869843},"orientation":{"w":0.53464,"x":-0.15299,"y":-0.826976,"z":-0.082863}},"time":1.464766357421875}
{"frames":[{"cameraInd":0,"cameraParameters":{"focalLengthX":284.929992675781,"focalLengthY":285.165496826172,"principalPointX":416.4547119140625,"principalPointY":395.77349853515625,"distortionModel":"KANNALA_BRANDT4","distortionCoefficients":[-0.004973,0.03975,-0.0374,0.006239]},"imuToCamera":[[0.01486,0.9995,-0.02577,0.06522],[-0.9998,0.01496,0.003756,-0.0207],[0.00414,0.02571,0.9996,-0.008054],[0,0,0,1]],"time":1.46955859375},{"cameraInd":1,"cameraParameters":{"focalLengthX":284.559509277344,"focalLengthY":284.4418029785162,"principalPointX":410.81329345703125,"principalPointY":394.1506042480469,"distortionModel":"KANNALA_BRANDT4","distortionCoefficients":[-0.006496,0.04365,-0.04025,0.006813]},"imuToCamera":[[0.01255,0.9995,-0.02538,-0.0449],[-0.9997,0.01301,0.0179,-0.02056],[0.01822,0.02515,0.9995,-0.008638],[0,0,0,1]],"time":1.46955859375}],"number":29,"time":1.46955859375}
{"sensor":{"type":"gyroscope","values":[-0.15979453921318054,-0.08735434710979462,0.08841964602470398]},"time":1.4697841796875}
{"sensor":{"type":"imuTemperature","values":[292.8961]},"time":1.4697841796875}
{"groundTruth":{"position":{"x":-0.007131610997021198,"y":0.022098174318671227,"z":0.008283869363367558},"orientation":{"w":0.53464,"x":-0.15299,"y":-0.826976,"z":-0.082863}},"time":1.469782958984375}
{"sensor":{"type":"gyroscope","values":[-0.18323107063770294,-0.06178722158074379,0.09481143206357956]},"time":1.474782958984375}
{"gps": {"accuracy": 4.0, "altitude": 14.18831106834269, "latitude": 60.173783793064594, "longitude": 24.906486344581662}, "time":1.474782958984375}
Parameters format
Most of the conversion scripts additionally produce a parameters.txt
file that stores session-wide constants and other hints for using the data as input for a VIO method.
The parameter names are separated from the values by space and parameters are separated by ;
, which may be followed by whitespace including newlines.
The parameters are:
focalLengthX
: first camera horizontal focal length.focalLengthY
: first camera vertical focal length.principalPointX
: first camera horizontal principal point (pixels).principalPointY
: first camera vertical principal point (pixels).secondFocalLengthX
,secondFocalLengthY
,secondPrincipalPointX
,secondPrincipalPointY
: same but for the second camera.fisheyeCamera
(boolean): iftrue
distortionCoeffs
define the first four Kannala-Brandt model parameters, iffalse
they define OpenCV radial distortion model (only the k1, k2, k3 parameters).distortionCoeffs
: array of 3 or 4 values depending onfisheyeCamera
.secondDistortionCoeffs
: same but for the second camera.imuToCameraMatrix
: describing pose difference of the IMU and camera component, lists a column-major representation of 4x4 matrix that transforms homogeneous coordinates as:p_camera = T * p_imu
.secondImuToCameraMatrix
: same but for the second camera.matchStereoIntensities
: whentrue
, a hint that the stereo cameras are not visually synchronized, eg due to differing exposure timings.
Example parameters.txt
focalLengthX 458.654;focalLengthY 457.296;principalPointX 367.215;principalPointY 248.375;
distortionCoeffs -0.28340811,0.07395907,0.00019359;
secondFocalLengthX 457.587;secondFocalLengthY 456.134;
secondPrincipalPointX 379.999;secondPrincipalPointY 255.238;
secondDistortionCoeffs -0.28368365,0.07451284,-0.00010473;
imuToCameraMatrix 0.01486554298179427,-0.9998809296985752,0.004140296794224038,0.0,0.9995572490083462,0.01496721332471924,0.025715529947966016,0.0,-0.02577443669744028,0.0037561883579669726,0.9996607271779023,0.0,0.06522290953553112,-0.02070638549271943,-0.008054602460029517,1.0;
secondImuToCameraMatrix 0.012555267089102956,-0.9997550997231162,0.018223771455443325,0.0,0.999598781151433,0.013011905181503854,0.02515883631155237,0.0,-0.025389800891746528,0.01790058382525125,0.999517347077547,0.0,-0.04490198068250875,-0.020569771258915234,-0.008638135126028098,1.0;