Journal of Jilin University(Engineering and Technology Edition) ›› 2022, Vol. 52 ›› Issue (12): 2954-2963.doi: 10.13229/j.cnki.jdxbgxb20210481

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Cross⁃modality person re⁃identification based on semantic coupling and identity⁃consistence constraint

Chun-ping HOU(),Qing-yuan YANG,Mei-yan HUANG,Zhi-peng WANG   

  1. School of Electrical and Information Engineering,Tianjin University,Tianjin 300072,China
  • Received:2021-05-31 Online:2022-12-01 Published:2022-12-08

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Abstract:

To solve the problem of the large inter-modality discrepancy and the intra-class variations in cross modality person re-Identification (CM-Reid), a novel CM-Reid framework based on semantic coupling and identity-consistence constraint was proposed. In the semantic level, the semantic representations bi-directionally and fuse the semantic information between different modalities were coupled to alleviate the inter-modality discrepancy. In the identity level, the cross-modality triplet loss and identity loss to maintain the identity consistence were optimized to alleviate the intra-class variations. The experimental results show that the proposed method can effectively improve the performance of CM-Reid. Compared with the baseline method, the accuracy of Top-1 and mAP indicators is improved by more than 10%.

Key words: computer application, cross-modality person re-identification, deep learning, semantic coupling, identity-consistence constrain

CLC Number: 

  • TP391

Fig.1

Framework of the proposed method"

Fig.2

Semantic coupling module"

Table 1

Effectiveness comparison of SCM"

序号方法All SearchIndoor Search
Top-1mAPTop-1mAP
1Baseline45.8144.8547.0646.13
2Baseline+SCM_block146.0145.1547.9846.05
3Baseline+SCM_block248.9748.0050.1049.25
4Baseline+SCM_block354.1052.6155.8352.96
5Baseline+SCM_block457.8555.3358.1556.19

Table 2

Cross-modality triplet loss validity verification"

方法All SearchIndoor Search
Top-1mAPTop-1mAP
155.9254.2056.8554.92
257.8555.3358.1556.19

Table 3

Comparision experiment on SYSY-MM01 dataset"

方法All SearchIndoor Search
Top-1Top-10Top-20mAPTop-1Top-10Top-20mAP
One-stream712.0449.6866.7413.6716.9463.5582.1022.95
Two-stream711.6547.9965.5012.8515.6061.1881.0221.49
Zero-Padding714.8054.1271.3315.9520.5868.3885.7926.92
SDL1628.1270.2383.6729.0132.5680.4590.6739.56
MSR1737.3583.4093.3438.1139.6489.2997.6650.88
MACE1851.6487.2594.4450.1157.3593.0297.4764.79
HSM920.6832.7477.9523.21----
BDTR1927.3266.9681.0727.3231.9277.1889.2841.86
eBDTR1927.8267.3481.3428.4232.4677.4289.6242.46
expAT2038.5776.6486.3938.6144.7169.8277.8732.20
CMSP2143.5686.25-44.9848.6289.50-57.50
cmGAN2226.9767.5180.5631.4931.6377.2389.1842.19
D2RL1128.9070.6082.4029.20----
JSIA2338.1080.7089.9036.9043.8086.2094.2052.90
AliGAN1042.4085.0093.7040.7045.9087.6094.4054.30
本文57.8589.2594.4555.3358.1590.0295.6356.19

Table 4

Comparision experiment on RegDB dataset"

方法RGB→ThermalThermal→RGB
Top-1Top-10Top-20mAPTop-1Top-10Top-20mAP
Zero-Padding717.7534.2144.3518.9016.6334.6844.2517.82
SDL1626.4751.3461.2223.5825.7450.2359.6622.89
MSR1748.4370.3279.9548.67----
MACE1872.3788.4093.5969.0972.1288.0793.0768.57
BDTR1933.5658.6167.4332.7632.9258.4668.4331.96
eBDTR1934.6258.9668.7233.4634.2158.7468.6432.49
HSME950.8573.3681.6647.0050.1572.4081.0746.16
expAT2067.45--66.5166.48--67.31
CMSP2165.0783.71-64.50----
D2RL1143.4066.1076.3044.10----
JSIA2348.50--48.90----
AliGAN1057.90--53.6056.30--53.40
本文75.1290.5696.0974.5174.9691.0295.7676.10

Fig.3

Retrieval result of RGB image to thermal images"

Fig.4

Retrieval result of thermal image to RGB images"

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