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#!/usr/bin/env python
# -*- coding: utf-8 -*-
'''
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###########################################################################
## TRACKING OF PERSON OF INTEREST ##
###########################################################################
Openpose detects all people in the field of view .
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- multi_person = false : Triangulates the most prominent person
- multi_person = true : Triangulates persons across views
Tracking them across time frames is done in the triangulation stage .
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If multi_person = false , this module tries all possible triangulations of a chosen
anatomical point , and chooses the person for whom the reprojection error is smallest .
If multi_person = true , it computes the distance between epipolar lines ( camera to
keypoint lines ) for all persons detected in all views , and selects the best correspondences .
The computation of the affinity matrix from the distance is inspired from the EasyMocap approach .
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INPUTS :
- a calibration file ( . toml extension )
- json files from each camera folders with several detected persons
- a Config . toml file
- a skeleton model
OUTPUTS :
- json files for each camera with only one person of interest
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'''
## INIT
import os
import glob
import fnmatch
import numpy as np
import json
import itertools as it
import toml
from tqdm import tqdm
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import cv2
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from anytree import RenderTree
from anytree . importer import DictImporter
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import logging
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from Pose2Sim . common import retrieve_calib_params , computeP , weighted_triangulation , \
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reprojection , euclidean_distance , sort_stringlist_by_last_number
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from Pose2Sim . skeletons import *
## AUTHORSHIP INFORMATION
__author__ = " David Pagnon "
__copyright__ = " Copyright 2021, Pose2Sim "
__credits__ = [ " David Pagnon " ]
__license__ = " BSD 3-Clause License "
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__version__ = " 0.8.2 "
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__maintainer__ = " David Pagnon "
__email__ = " contact@david-pagnon.com "
__status__ = " Development "
## FUNCTIONS
def persons_combinations ( json_files_framef ) :
'''
Find all possible combinations of detected persons ' ids.
Person ' s id when no person detected is set to -1.
INPUT :
- json_files_framef : list of strings
OUTPUT :
- personsIDs_comb : array , list of lists of int
'''
n_cams = len ( json_files_framef )
# amount of persons detected for each cam
nb_persons_per_cam = [ ]
for c in range ( n_cams ) :
with open ( json_files_framef [ c ] , ' r ' ) as js :
nb_persons_per_cam + = [ len ( json . load ( js ) [ ' people ' ] ) ]
# persons_combinations
id_no_detect = [ i for i , x in enumerate ( nb_persons_per_cam ) if x == 0 ] # ids of cameras that have not detected any person
nb_persons_per_cam = [ x if x != 0 else 1 for x in nb_persons_per_cam ] # temporarily replace persons count by 1 when no detection
range_persons_per_cam = [ range ( nb_persons_per_cam [ c ] ) for c in range ( n_cams ) ]
personsIDs_comb = np . array ( list ( it . product ( * range_persons_per_cam ) ) , float ) # all possible combinations of persons' ids
personsIDs_comb [ : , id_no_detect ] = np . nan # -1 = persons' ids when no person detected
return personsIDs_comb
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def triangulate_comb ( comb , coords , P_all , calib_params , config ) :
'''
Triangulate 2 D points and compute reprojection error for a combination of cameras .
INPUTS :
- comb : list of ints : combination of persons ' ids for each camera
- coords : array : x , y , likelihood for each camera
- P_all : list of arrays : projection matrices for each camera
- calib_params : dict : calibration parameters
- config : dictionary from Config . toml file
OUTPUTS :
- error_comb : float : reprojection error
- comb : list of ints : combination of persons ' ids for each camera
- Q_comb : array : 3 D coordinates of the triangulated point
'''
undistort_points = config . get ( ' triangulation ' ) . get ( ' undistort_points ' )
likelihood_threshold = config . get ( ' personAssociation ' ) . get ( ' likelihood_threshold_association ' )
# Replace likelihood by 0. if under likelihood_threshold
coords [ : , 2 ] [ coords [ : , 2 ] < likelihood_threshold ] = 0.
comb [ coords [ : , 2 ] == 0. ] = np . nan
# Filter coords and projection_matrices containing nans
coords_filt = [ coords [ i ] for i in range ( len ( comb ) ) if not np . isnan ( comb [ i ] ) ]
projection_matrices_filt = [ P_all [ i ] for i in range ( len ( comb ) ) if not np . isnan ( comb [ i ] ) ]
if undistort_points :
calib_params_R_filt = [ calib_params [ ' R ' ] [ i ] for i in range ( len ( comb ) ) if not np . isnan ( comb [ i ] ) ]
calib_params_T_filt = [ calib_params [ ' T ' ] [ i ] for i in range ( len ( comb ) ) if not np . isnan ( comb [ i ] ) ]
calib_params_K_filt = [ calib_params [ ' K ' ] [ i ] for i in range ( len ( comb ) ) if not np . isnan ( comb [ i ] ) ]
calib_params_dist_filt = [ calib_params [ ' dist ' ] [ i ] for i in range ( len ( comb ) ) if not np . isnan ( comb [ i ] ) ]
# Triangulate 2D points
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try :
x_files_filt , y_files_filt , likelihood_files_filt = np . array ( coords_filt ) . T
Q_comb = weighted_triangulation ( projection_matrices_filt , x_files_filt , y_files_filt , likelihood_files_filt )
except :
Q_comb = [ np . nan , np . nan , np . nan , 1. ]
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# Reprojection
if undistort_points :
coords_2D_kpt_calc_filt = [ cv2 . projectPoints ( np . array ( Q_comb [ : - 1 ] ) , calib_params_R_filt [ i ] , calib_params_T_filt [ i ] , calib_params_K_filt [ i ] , calib_params_dist_filt [ i ] ) [ 0 ] for i in range ( len ( Q_comb ) ) ]
x_calc = [ coords_2D_kpt_calc_filt [ i ] [ 0 , 0 , 0 ] for i in range ( len ( Q_comb ) ) ]
y_calc = [ coords_2D_kpt_calc_filt [ i ] [ 0 , 0 , 1 ] for i in range ( len ( Q_comb ) ) ]
else :
x_calc , y_calc = reprojection ( projection_matrices_filt , Q_comb )
# Reprojection error
error_comb_per_cam = [ ]
for cam in range ( len ( x_calc ) ) :
q_file = ( x_files_filt [ cam ] , y_files_filt [ cam ] )
q_calc = ( x_calc [ cam ] , y_calc [ cam ] )
error_comb_per_cam . append ( euclidean_distance ( q_file , q_calc ) )
error_comb = np . mean ( error_comb_per_cam )
return error_comb , comb , Q_comb
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def best_persons_and_cameras_combination ( config , json_files_framef , personsIDs_combinations , projection_matrices , tracked_keypoint_id , calib_params ) :
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'''
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Chooses the right person among the multiple ones found by
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OpenPose & excludes cameras with wrong 2 d - pose estimation .
1. triangulate the tracked keypoint for all possible combinations of people ,
2. compute difference between reprojection & original openpose detection ,
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3. take combination with smallest error OR all those below the error threshold
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If error is too big , take off one or several of the cameras until err is
lower than " max_err_px " .
INPUTS :
- a Config . toml file
- json_files_framef : list of strings
- personsIDs_combinations : array , list of lists of int
- projection_matrices : list of arrays
- tracked_keypoint_id : int
OUTPUTS :
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- errors_below_thresh : list of float
- comb_errors_below_thresh : list of arrays of ints
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'''
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error_threshold_tracking = config . get ( ' personAssociation ' ) . get ( ' single_person ' ) . get ( ' reproj_error_threshold_association ' )
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likelihood_threshold = config . get ( ' personAssociation ' ) . get ( ' likelihood_threshold_association ' )
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min_cameras_for_triangulation = config . get ( ' triangulation ' ) . get ( ' min_cameras_for_triangulation ' )
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undistort_points = config . get ( ' triangulation ' ) . get ( ' undistort_points ' )
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n_cams = len ( json_files_framef )
error_min = np . inf
nb_cams_off = 0 # cameras will be taken-off until the reprojection error is under threshold
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errors_below_thresh = [ ]
comb_errors_below_thresh = [ ]
Q_kpt = [ ]
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while error_min > error_threshold_tracking and n_cams - nb_cams_off > = min_cameras_for_triangulation :
# Try all persons combinations
for combination in personsIDs_combinations :
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# Get coords from files
coords = [ ]
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for index_cam , person_nb in enumerate ( combination ) :
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try :
js = read_json ( json_files_framef [ index_cam ] )
coords . append ( js [ int ( person_nb ) ] [ tracked_keypoint_id * 3 : tracked_keypoint_id * 3 + 3 ] )
except :
coords . append ( [ np . nan , np . nan , np . nan ] )
coords = np . array ( coords )
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# undistort points
if undistort_points :
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points = np . array ( coords ) [ : , None , : 2 ]
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undistorted_points = [ cv2 . undistortPoints ( points [ i ] , calib_params [ ' K ' ] [ i ] , calib_params [ ' dist ' ] [ i ] , None , calib_params [ ' optim_K ' ] [ i ] ) for i in range ( n_cams ) ]
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coords [ : , 0 ] = np . array ( [ [ u [ i ] [ 0 ] [ 0 ] for i in range ( len ( u ) ) ] for u in undistorted_points ] ) . squeeze ( )
coords [ : , 1 ] = np . array ( [ [ u [ i ] [ 0 ] [ 1 ] for i in range ( len ( u ) ) ] for u in undistorted_points ] ) . squeeze ( )
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# For each persons combination, create subsets with "nb_cams_off" cameras excluded
id_cams_off = list ( it . combinations ( range ( len ( combination ) ) , nb_cams_off ) )
combinations_with_cams_off = np . array ( [ combination . copy ( ) ] * len ( id_cams_off ) )
for i , id in enumerate ( id_cams_off ) :
combinations_with_cams_off [ i , id ] = np . nan
# Try all subsets
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error_comb_all , comb_all , Q_comb_all = [ ] , [ ] , [ ]
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for comb in combinations_with_cams_off :
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error_comb , comb , Q_comb = triangulate_comb ( comb , coords , projection_matrices , calib_params , config )
error_comb_all . append ( error_comb )
comb_all . append ( comb )
Q_comb_all . append ( Q_comb )
error_min = np . nanmin ( error_comb_all )
comb_error_min = [ comb_all [ np . argmin ( error_comb_all ) ] ]
Q_kpt = [ Q_comb_all [ np . argmin ( error_comb_all ) ] ]
if error_min < error_threshold_tracking :
break
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nb_cams_off + = 1
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return error_min , comb_error_min , Q_kpt
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def read_json ( js_file ) :
'''
Read OpenPose json file
'''
with open ( js_file , ' r ' ) as json_f :
js = json . load ( json_f )
json_data = [ ]
for people in range ( len ( js [ ' people ' ] ) ) :
if len ( js [ ' people ' ] [ people ] [ ' pose_keypoints_2d ' ] ) < 3 : continue
else :
json_data . append ( js [ ' people ' ] [ people ] [ ' pose_keypoints_2d ' ] )
return json_data
def compute_rays ( json_coord , calib_params , cam_id ) :
'''
Plucker coordinates of rays from camera to each joint of a person
Plucker coordinates : camera to keypoint line direction ( size 3 )
moment : origin ^ line ( size 3 )
additionally , confidence
INPUTS :
- json_coord : x , y , likelihood for a person seen from a camera ( list of 3 * joint_nb )
- calib_params : calibration parameters from retrieve_calib_params ( ' calib.toml ' )
- cam_id : camera id ( int )
OUTPUT :
- plucker : array . nb joints * ( 6 plucker coordinates + 1 likelihood )
'''
x = json_coord [ 0 : : 3 ]
y = json_coord [ 1 : : 3 ]
likelihood = json_coord [ 2 : : 3 ]
inv_K = calib_params [ ' inv_K ' ] [ cam_id ]
R_mat = calib_params [ ' R_mat ' ] [ cam_id ]
T = calib_params [ ' T ' ] [ cam_id ]
cam_center = - R_mat . T @ T
plucker = [ ]
for i in range ( len ( x ) ) :
q = np . array ( [ x [ i ] , y [ i ] , 1 ] )
norm_Q = R_mat . T @ ( inv_K @ q - T )
line = norm_Q - cam_center
norm_line = line / np . linalg . norm ( line )
moment = np . cross ( cam_center , norm_line )
plucker . append ( np . concatenate ( [ norm_line , moment , [ likelihood [ i ] ] ] ) )
return np . array ( plucker )
def broadcast_line_to_line_distance ( p0 , p1 ) :
'''
Compute the distance between two lines in 3 D space .
see : https : / / faculty . sites . iastate . edu / jia / files / inline - files / plucker - coordinates . pdf
p0 = ( l0 , m0 ) , p1 = ( l1 , m1 )
dist = | ( l0 , m0 ) * ( l1 , m1 ) | / | | l0 x l1 | |
( l0 , m0 ) * ( l1 , m1 ) = l0 @ m1 + m0 @ l1 ( reciprocal product )
No need to divide by the norm of the cross product of the directions , since we
don ' t need the actual distance but whether the lines are close to intersecting or not
= > dist = | ( l0 , m0 ) * ( l1 , m1 ) |
INPUTS :
- p0 : array ( nb_persons_detected * 1 * nb_joints * 7 coordinates )
- p1 : array ( 1 * nb_persons_detected * nb_joints * 7 coordinates )
OUTPUT :
- dist : distances between the two lines ( not normalized ) .
array ( nb_persons_0 * nb_persons_1 * nb_joints )
'''
product = np . sum ( p0 [ . . . , : 3 ] * p1 [ . . . , 3 : 6 ] , axis = - 1 ) + np . sum ( p1 [ . . . , : 3 ] * p0 [ . . . , 3 : 6 ] , axis = - 1 )
dist = np . abs ( product )
return dist
def compute_affinity ( all_json_data_f , calib_params , cum_persons_per_view , reconstruction_error_threshold = 0.1 ) :
'''
Compute the affinity between all the people in the different views .
The affinity is defined as 1 - distance / max_distance , with distance the
distance between epipolar lines in each view ( reciprocal product of Plucker
coordinates ) .
Another approach would be to project one epipolar line onto the other camera
plane and compute the line to point distance , but it is more computationally
intensive ( simple dot product vs . projection and distance calculation ) .
INPUTS :
- all_json_data_f : list of json data . For frame f , nb_views * nb_persons * ( x , y , likelihood ) * nb_joints
- calib_params : calibration parameters from retrieve_calib_params ( ' calib.toml ' )
- cum_persons_per_view : cumulative number of persons per view
- reconstruction_error_threshold : maximum distance between epipolar lines to consider a match
OUTPUT :
- affinity : affinity matrix between all the people in the different views .
( nb_views * nb_persons_per_view * nb_views * nb_persons_per_view )
'''
# Compute plucker coordinates for all keypoints for each person in each view
# pluckers_f: dims=(camera, person, joint, 7 coordinates)
pluckers_f = [ ]
for cam_id , json_cam in enumerate ( all_json_data_f ) :
pluckers = [ ]
for json_coord in json_cam :
plucker = compute_rays ( json_coord , calib_params , cam_id ) # LIMIT TO 15 JOINTS? json_coord[:15*3]
pluckers . append ( plucker )
pluckers = np . array ( pluckers )
pluckers_f . append ( pluckers )
# Compute affinity matrix
distance = np . zeros ( ( cum_persons_per_view [ - 1 ] , cum_persons_per_view [ - 1 ] ) ) + 2 * reconstruction_error_threshold
for compared_cam0 , compared_cam1 in it . combinations ( range ( len ( all_json_data_f ) ) , 2 ) :
# skip when no detection for a camera
if cum_persons_per_view [ compared_cam0 ] == cum_persons_per_view [ compared_cam0 + 1 ] \
or cum_persons_per_view [ compared_cam1 ] == cum_persons_per_view [ compared_cam1 + 1 ] :
continue
# compute distance
p0 = pluckers_f [ compared_cam0 ] [ : , None ] # add coordinate on second dimension
p1 = pluckers_f [ compared_cam1 ] [ None , : ] # add coordinate on first dimension
dist = broadcast_line_to_line_distance ( p0 , p1 )
likelihood = np . sqrt ( p0 [ . . . , - 1 ] * p1 [ . . . , - 1 ] )
mean_weighted_dist = np . sum ( dist * likelihood , axis = - 1 ) / ( 1e-5 + likelihood . sum ( axis = - 1 ) ) # array(nb_persons_0 * nb_persons_1)
# populate distance matrix
distance [ cum_persons_per_view [ compared_cam0 ] : cum_persons_per_view [ compared_cam0 + 1 ] , \
cum_persons_per_view [ compared_cam1 ] : cum_persons_per_view [ compared_cam1 + 1 ] ] \
= mean_weighted_dist
distance [ cum_persons_per_view [ compared_cam1 ] : cum_persons_per_view [ compared_cam1 + 1 ] , \
cum_persons_per_view [ compared_cam0 ] : cum_persons_per_view [ compared_cam0 + 1 ] ] \
= mean_weighted_dist . T
# compute affinity matrix and clamp it to zero when distance > reconstruction_error_threshold
distance [ distance > reconstruction_error_threshold ] = reconstruction_error_threshold
affinity = 1 - distance / reconstruction_error_threshold
return affinity
def circular_constraint ( cum_persons_per_view ) :
'''
A person can be matched only with themselves in the same view , and with any
person from other views
INPUT :
- cum_persons_per_view : cumulative number of persons per view
OUTPUT :
- circ_constraint : circular constraint matrix
'''
circ_constraint = np . identity ( cum_persons_per_view [ - 1 ] )
for i in range ( len ( cum_persons_per_view ) - 1 ) :
circ_constraint [ cum_persons_per_view [ i ] : cum_persons_per_view [ i + 1 ] , cum_persons_per_view [ i + 1 ] : cum_persons_per_view [ - 1 ] ] = 1
circ_constraint [ cum_persons_per_view [ i + 1 ] : cum_persons_per_view [ - 1 ] , cum_persons_per_view [ i ] : cum_persons_per_view [ i + 1 ] ] = 1
return circ_constraint
def SVT ( matrix , threshold ) :
'''
Find a low - rank approximation of the matrix using Singular Value Thresholding .
INPUTS :
- matrix : matrix to decompose
- threshold : threshold for singular values
OUTPUT :
- matrix_thresh : low - rank approximation of the matrix
'''
U , s , Vt = np . linalg . svd ( matrix ) # decompose matrix
s_thresh = np . maximum ( s - threshold , 0 ) # set smallest singular values to zero
matrix_thresh = U @ np . diag ( s_thresh ) @ Vt # recompose matrix
return matrix_thresh
def matchSVT ( affinity , cum_persons_per_view , circ_constraint , max_iter = 20 , w_rank = 50 , tol = 1e-4 , w_sparse = 0.1 ) :
'''
Find low - rank approximation of ' affinity ' while satisfying the circular constraint .
INPUTS :
- affinity : affinity matrix between all the people in the different views
- cum_persons_per_view : cumulative number of persons per view
- circ_constraint : circular constraint matrix
- max_iter : maximum number of iterations
- w_rank : threshold for singular values
- tol : tolerance for convergence
- w_sparse : regularization parameter
OUTPUT :
- new_aff : low - rank approximation of the affinity matrix
'''
new_aff = affinity . copy ( )
N = new_aff . shape [ 0 ]
index_diag = np . arange ( N )
new_aff [ index_diag , index_diag ] = 0.
# new_aff = (new_aff + new_aff.T)/2 # symmetric by construction
Y = np . zeros_like ( new_aff ) # Initial deviation matrix / residual ()
W = w_sparse - new_aff # Initial sparse matrix / regularization (prevent overfitting)
mu = 64 # initial step size
for iter in range ( max_iter ) :
new_aff0 = new_aff . copy ( )
Q = new_aff + Y * 1.0 / mu
Q = SVT ( Q , w_rank / mu )
new_aff = Q - ( W + Y ) / mu
# Project X onto dimGroups
for i in range ( len ( cum_persons_per_view ) - 1 ) :
ind1 , ind2 = cum_persons_per_view [ i ] , cum_persons_per_view [ i + 1 ]
new_aff [ ind1 : ind2 , ind1 : ind2 ] = 0
# Reset diagonal elements to one and ensure X is within valid range [0, 1]
new_aff [ index_diag , index_diag ] = 1.
new_aff [ new_aff < 0 ] = 0
new_aff [ new_aff > 1 ] = 1
# Enforce circular constraint
new_aff = new_aff * circ_constraint
new_aff = ( new_aff + new_aff . T ) / 2 # kept just in case X loses its symmetry during optimization
Y = Y + mu * ( new_aff - Q )
# Compute convergence criteria: break if new_aff is close enough to Q and no evolution anymore
pRes = np . linalg . norm ( new_aff - Q ) / N # primal residual (diff between new_aff and SVT result)
dRes = mu * np . linalg . norm ( new_aff - new_aff0 ) / N # dual residual (diff between new_aff and previous new_aff)
if pRes < tol and dRes < tol :
break
if pRes > 10 * dRes : mu = 2 * mu
elif dRes > 10 * pRes : mu = mu / 2
iter + = 1
return new_aff
def person_index_per_cam ( affinity , cum_persons_per_view , min_cameras_for_triangulation ) :
'''
For each detected person , gives their index for each camera
INPUTS :
- affinity : affinity matrix between all the people in the different views
- min_cameras_for_triangulation : exclude proposals if less than N cameras see them
OUTPUT :
- proposals : 2 D array : n_persons * n_cams
'''
# index of the max affinity for each group (-1 if no detection)
proposals = [ ]
for row in range ( affinity . shape [ 0 ] ) :
proposal_row = [ ]
for cam in range ( len ( cum_persons_per_view ) - 1 ) :
id_persons_per_view = affinity [ row , cum_persons_per_view [ cam ] : cum_persons_per_view [ cam + 1 ] ]
proposal_row + = [ np . argmax ( id_persons_per_view ) if ( len ( id_persons_per_view ) > 0 and max ( id_persons_per_view ) > 0 ) else - 1 ]
proposals . append ( proposal_row )
proposals = np . array ( proposals , dtype = float )
# remove duplicates and order
proposals , nb_detections = np . unique ( proposals , axis = 0 , return_counts = True )
proposals = proposals [ np . argsort ( nb_detections ) [ : : - 1 ] ]
# remove row if any value is the same in previous rows at same index (nan!=nan so nan ignored)
proposals [ proposals == - 1 ] = np . nan
mask = np . ones ( proposals . shape [ 0 ] , dtype = bool )
for i in range ( 1 , len ( proposals ) ) :
mask [ i ] = ~ np . any ( proposals [ i ] == proposals [ : i ] , axis = 0 ) . any ( )
proposals = proposals [ mask ]
# remove identifications if less than N cameras see them
nb_cams_per_person = [ np . count_nonzero ( ~ np . isnan ( p ) ) for p in proposals ]
proposals = np . array ( [ p for ( n , p ) in zip ( nb_cams_per_person , proposals ) if n > = min_cameras_for_triangulation ] )
return proposals
def rewrite_json_files ( json_tracked_files_f , json_files_f , proposals , n_cams ) :
'''
Write new json files with correct association of people across cameras .
INPUTS :
- json_tracked_files_f : list of strings : json files to write
- json_files_f : list of strings : json files to read
- proposals : 2 D array : n_persons * n_cams
- n_cams : int : number of cameras
OUTPUT :
- json files with correct association of people across cameras
'''
for cam in range ( n_cams ) :
with open ( json_tracked_files_f [ cam ] , ' w ' ) as json_tracked_f :
with open ( json_files_f [ cam ] , ' r ' ) as json_f :
js = json . load ( json_f )
js_new = js . copy ( )
js_new [ ' people ' ] = [ ]
for new_comb in proposals :
if not np . isnan ( new_comb [ cam ] ) :
js_new [ ' people ' ] + = [ js [ ' people ' ] [ int ( new_comb [ cam ] ) ] ]
else :
js_new [ ' people ' ] + = [ { } ]
json_tracked_f . write ( json . dumps ( js_new ) )
def recap_tracking ( config , error = 0 , nb_cams_excluded = 0 ) :
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'''
Print a message giving statistics on reprojection errors ( in pixel and in m )
as well as the number of cameras that had to be excluded to reach threshold
conditions . Also stored in User / logs . txt .
INPUT :
- a Config . toml file
- error : dataframe
- nb_cams_excluded : dataframe
OUTPUT :
- Message in console
'''
# Read config
project_dir = config . get ( ' project ' ) . get ( ' project_dir ' )
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# if batch
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session_dir = os . path . realpath ( os . path . join ( project_dir , ' .. ' , ' .. ' ) )
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# if single trial
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session_dir = session_dir if ' Config.toml ' in os . listdir ( session_dir ) else os . getcwd ( )
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multi_person = config . get ( ' project ' ) . get ( ' multi_person ' )
likelihood_threshold_association = config . get ( ' personAssociation ' ) . get ( ' likelihood_threshold_association ' )
tracked_keypoint = config . get ( ' personAssociation ' ) . get ( ' single_person ' ) . get ( ' tracked_keypoint ' )
error_threshold_tracking = config . get ( ' personAssociation ' ) . get ( ' single_person ' ) . get ( ' reproj_error_threshold_association ' )
reconstruction_error_threshold = config . get ( ' personAssociation ' ) . get ( ' multi_person ' ) . get ( ' reconstruction_error_threshold ' )
min_affinity = config . get ( ' personAssociation ' ) . get ( ' multi_person ' ) . get ( ' min_affinity ' )
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poseTracked_dir = os . path . join ( project_dir , ' pose-associated ' )
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calib_dir = [ os . path . join ( session_dir , c ) for c in os . listdir ( session_dir ) if ' calib ' in c . lower ( ) ] [ 0 ]
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calib_file = glob . glob ( os . path . join ( calib_dir , ' *.toml ' ) ) [ 0 ] # lastly created calibration file
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if not multi_person :
logging . info ( ' \n Single-person analysis selected. ' )
# Error
mean_error_px = np . around ( np . mean ( error ) , decimals = 1 )
calib = toml . load ( calib_file )
calib_cam1 = calib [ list ( calib . keys ( ) ) [ 0 ] ]
fm = calib_cam1 [ ' matrix ' ] [ 0 ] [ 0 ]
Dm = euclidean_distance ( calib_cam1 [ ' translation ' ] , [ 0 , 0 , 0 ] )
mean_error_mm = np . around ( mean_error_px * Dm / fm * 1000 , decimals = 1 )
# Excluded cameras
mean_cam_off_count = np . around ( np . mean ( nb_cams_excluded ) , decimals = 2 )
# Recap
logging . info ( f ' \n --> Mean reprojection error for { tracked_keypoint } point on all frames is { mean_error_px } px, which roughly corresponds to { mean_error_mm } mm. ' )
logging . info ( f ' --> In average, { mean_cam_off_count } cameras had to be excluded to reach the demanded { error_threshold_tracking } px error threshold after excluding points with likelihood below { likelihood_threshold_association } . ' )
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else :
logging . info ( ' \n Multi-person analysis selected. ' )
logging . info ( f ' \n --> A person was reconstructed if the lines from cameras to their keypoints intersected within { reconstruction_error_threshold } m and if the calculated affinity stayed below { min_affinity } after excluding points with likelihood below { likelihood_threshold_association } . ' )
logging . info ( f ' --> Beware that people were sorted across cameras, but not across frames. This will be done in the triangulation stage. ' )
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logging . info ( f ' \n Tracked json files are stored in { os . path . realpath ( poseTracked_dir ) } . ' )
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def track_2d_all ( config ) :
'''
For each frame ,
- Find all possible combinations of detected persons
- Triangulate ' tracked_keypoint ' for all combinations
- Reproject the point on all cameras
- Take combination with smallest reprojection error
- Write json file with only one detected person
Print recap message
INPUTS :
- a calibration file ( . toml extension )
- json files from each camera folders with several detected persons
- a Config . toml file
- a skeleton model
OUTPUTS :
- json files for each camera with only one person of interest
'''
# Read config
project_dir = config . get ( ' project ' ) . get ( ' project_dir ' )
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# if batch
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session_dir = os . path . realpath ( os . path . join ( project_dir , ' .. ' , ' .. ' ) )
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# if single trial
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session_dir = session_dir if ' Config.toml ' in os . listdir ( session_dir ) else os . getcwd ( )
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multi_person = config . get ( ' project ' ) . get ( ' multi_person ' )
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pose_model = config . get ( ' pose ' ) . get ( ' pose_model ' )
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tracked_keypoint = config . get ( ' personAssociation ' ) . get ( ' single_person ' ) . get ( ' tracked_keypoint ' )
likelihood_threshold = config . get ( ' personAssociation ' ) . get ( ' likelihood_threshold_association ' )
min_cameras_for_triangulation = config . get ( ' triangulation ' ) . get ( ' min_cameras_for_triangulation ' )
reconstruction_error_threshold = config . get ( ' personAssociation ' ) . get ( ' multi_person ' ) . get ( ' reconstruction_error_threshold ' )
min_affinity = config . get ( ' personAssociation ' ) . get ( ' multi_person ' ) . get ( ' min_affinity ' )
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frame_range = config . get ( ' project ' ) . get ( ' frame_range ' )
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undistort_points = config . get ( ' triangulation ' ) . get ( ' undistort_points ' )
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calib_dir = [ os . path . join ( session_dir , c ) for c in os . listdir ( session_dir ) if ' calib ' in c . lower ( ) ] [ 0 ]
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try :
calib_file = glob . glob ( os . path . join ( calib_dir , ' *.toml ' ) ) [ 0 ] # lastly created calibration file
except :
raise Exception ( f ' No .toml calibration file found in the { calib_dir } . ' )
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pose_dir = os . path . join ( project_dir , ' pose ' )
poseTracked_dir = os . path . join ( project_dir , ' pose-associated ' )
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# projection matrix from toml calibration file
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P_all = computeP ( calib_file , undistort = undistort_points )
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calib_params = retrieve_calib_params ( calib_file )
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# selection of tracked keypoint id
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try : # from skeletons.py
model = eval ( pose_model )
except :
try : # from Config.toml
model = DictImporter ( ) . import_ ( config . get ( ' pose ' ) . get ( pose_model ) )
if model . id == ' None ' :
model . id = None
except :
raise NameError ( ' Model not found in skeletons.py nor in Config.toml ' )
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tracked_keypoint_id = [ node . id for _ , _ , node in RenderTree ( model ) if node . name == tracked_keypoint ] [ 0 ]
# 2d-pose files selection
pose_listdirs_names = next ( os . walk ( pose_dir ) ) [ 1 ]
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pose_listdirs_names = sort_stringlist_by_last_number ( pose_listdirs_names )
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json_dirs_names = [ k for k in pose_listdirs_names if ' json ' in k ]
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json_files_names = [ fnmatch . filter ( os . listdir ( os . path . join ( pose_dir , js_dir ) ) , ' *.json ' ) for js_dir in json_dirs_names ]
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json_files_names = [ sort_stringlist_by_last_number ( j ) for j in json_files_names ]
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json_files = [ [ os . path . join ( pose_dir , j_dir , j_file ) for j_file in json_files_names [ j ] ] for j , j_dir in enumerate ( json_dirs_names ) ]
# 2d-pose-associated files creation
if not os . path . exists ( poseTracked_dir ) : os . mkdir ( poseTracked_dir )
try : [ os . mkdir ( os . path . join ( poseTracked_dir , k ) ) for k in json_dirs_names ]
except : pass
json_tracked_files = [ [ os . path . join ( poseTracked_dir , j_dir , j_file ) for j_file in json_files_names [ j ] ] for j , j_dir in enumerate ( json_dirs_names ) ]
f_range = [ [ min ( [ len ( j ) for j in json_files ] ) ] if frame_range == [ ] else frame_range ] [ 0 ]
n_cams = len ( json_dirs_names )
error_min_tot , cameras_off_tot = [ ] , [ ]
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# Check that camera number is consistent between calibration file and pose folders
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if n_cams != len ( P_all ) :
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raise Exception ( f ' Error: The number of cameras is not consistent: \
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Found { len ( P_all ) } cameras in the calibration file , \
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and { n_cams } cameras based on the number of pose folders . ' )
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Q_kpt = [ np . array ( [ 0. , 0. , 0. , 1. ] ) ]
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for f in tqdm ( range ( * f_range ) ) :
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# print(f'\nFrame {f}:')
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json_files_f = [ json_files [ c ] [ f ] for c in range ( n_cams ) ]
json_tracked_files_f = [ json_tracked_files [ c ] [ f ] for c in range ( n_cams ) ]
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Q_kpt_old = Q_kpt
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if not multi_person :
# all possible combinations of persons
personsIDs_comb = persons_combinations ( json_files_f )
# choose persons of interest and exclude cameras with bad pose estimation
error_proposals , proposals , Q_kpt = best_persons_and_cameras_combination ( config , json_files_f , personsIDs_comb , P_all , tracked_keypoint_id , calib_params )
error_min_tot . append ( np . mean ( error_proposals ) )
cameras_off_count = np . count_nonzero ( [ np . isnan ( comb ) for comb in proposals ] ) / len ( proposals )
cameras_off_tot . append ( cameras_off_count )
else :
# read data
all_json_data_f = [ ]
for js_file in json_files_f :
all_json_data_f . append ( read_json ( js_file ) )
#TODO: remove people with average likelihood < 0.3, no full torso, less than 12 joints... (cf filter2d in dataset/base.py L498)
# obtain proposals after computing affinity between all the people in the different views
persons_per_view = [ 0 ] + [ len ( j ) for j in all_json_data_f ]
cum_persons_per_view = np . cumsum ( persons_per_view )
affinity = compute_affinity ( all_json_data_f , calib_params , cum_persons_per_view , reconstruction_error_threshold = reconstruction_error_threshold )
circ_constraint = circular_constraint ( cum_persons_per_view )
affinity = affinity * circ_constraint
#TODO: affinity without hand, face, feet (cf ray.py L31)
affinity = matchSVT ( affinity , cum_persons_per_view , circ_constraint , max_iter = 20 , w_rank = 50 , tol = 1e-4 , w_sparse = 0.1 )
affinity [ affinity < min_affinity ] = 0
proposals = person_index_per_cam ( affinity , cum_persons_per_view , min_cameras_for_triangulation )
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# rewrite json files with a single or multiple persons of interest
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rewrite_json_files ( json_tracked_files_f , json_files_f , proposals , n_cams )
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# recap message
recap_tracking ( config , error_min_tot , cameras_off_tot )