Adaptive multi-view feature selection for human motion retrieval

Wang, Zhao; Feng, Yinfu; Tian, Qi; Yang, Xiaosong; Zhang, Jian Jun

doi:10.1016/j.sigpro.2014.11.015

Cited by 73 publications

(28 citation statements)

References 49 publications

(56 reference statements)

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“…Furthermore, the retrieval approach proposed by Zhu et al [51] highly relies on the manually designed geometric thresholds based on HDM05, which may lead to less robustness in other challenging dataset (e.g., Berkeley MHAD). Compared with Wang et al [40], our approach shows a more stable performance on all the motion types. The high-dimensional features considered in [40] claim to optimize more parameters with a longer retrieval time.…”

Section: Comparison With Other Retrieval Methodsmentioning

confidence: 66%

“…To validate our approach, we examine the deep learningbased motion image representation proposed by Du et al [8], the adaptive motion feature selection proposed by Wang et al [40], the temporal sparse representation-based motion retrieval proposed by Zhou et al [50], the topic modeling retrieval approach based on geometric motion features proposed by Zhu et al [51] and the benchmark retrieval algorithm based on semantic features proposed by Qi et al [30], and compare their performance with ours on the same evaluation datasets. All the methods are tested on equal terms of experimental protocol.…”

Section: Comparison With Other Retrieval Methodsmentioning

confidence: 99%

“…The temporal pyramid variation, JR with BPR descriptors generation and LDA with KLD (Kullback-Leibler divergence) are shared for both training and query processes joint classes, joint positions and temporal alignment. Wang et al [40] automatically select the most informative motion descriptors extracted from the well-defined trajectory-based [10] and pose-based features [6]. Hussein et al [12] utilize the covariance matrix as the spatial descriptor of joints to classify actions, and the covariance descriptor is later employed in [21] to construct adaptive graph kernels.…”

Section: Related Workmentioning

confidence: 99%

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Retrieval of spatial–temporal motion topics from 3D skeleton data

Men

Leung

2019

Vis Comput

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Retrieval of a specific human motion from 3D skeleton data is intractable because of its articulated complexity. We propose a context-based motion document formation method to reflect geometric variations by calculating covariance descriptors among skeletal joint locations and joint relative distances, and temporal variations by performing a coarse-to-fine segmentation on the motion sequence. The descriptors of query motion traverse all the motion categories to lock its motion words, which can be regarded as the basic units of a motion document. The discrete motion words of different spatiotemporal descriptors are also mapped to divergent index ranges to add prior knowledge of motion with temporal order to latent Dirichlet allocation (LDA). The similarity matching is based on motion-topic distributions from LDA with semantic meanings. The experiments on public datasets show the effectiveness and robustness of the proposed method over existing models.

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Section: Comparison With Other Retrieval Methodsmentioning

confidence: 66%

Section: Comparison With Other Retrieval Methodsmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

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Retrieval of spatial–temporal motion topics from 3D skeleton data

Men

Leung

2019

Vis Comput

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“…Most approaches on the 3D human motion retrieval have focused on developing hand crafted features to represent the skeleton sequences [11,15,20]. In this section, we broadly categorize them by the method in which they engineer their descriptors.…”

Section: Related Workmentioning

confidence: 99%

DeepHuMS: Deep Human Motion Signature for 3D Skeletal Sequences

Battan

Venkat

Sharma

2020

Lecture Notes in Computer Science

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3D Human Motion Indexing and Retrieval is an interesting problem due to the rise of several data-driven applications aimed at analyzing and/or re-utilizing 3D human 12 skeletal data, such as datadriven animation, analysis of sports bio-mechanics, human surveillance etc. Spatio-temporal articulations of humans, noisy/missing data, different speeds of the same motion etc. make it challenging and several of the existing state of the art methods use hand-craft features along with optimization based or histogram based comparison in order to perform retrieval. Further, they demonstrate it only for very small datasets and few classes. We make a case for using a learned representation that should recognize the motion as well as enforce a discriminative ranking. To that end, we propose, a 3D human motion descriptor learned using a deep network. Our learned embedding is generalizable and applicable to real-world data -addressing the aforementioned challenges and further enables sub-motion searching in its embedding space using another network. Our model exploits the inter-class similarity using trajectory cues, and performs far superior in a self-supervised setting. State of the art results on all these fronts is shown on two large scale 3D human motion datasets -NTU RGB+D and HDM05.

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“…Feature selection (see figure 2): Figure 2. Adaptive multi-view feature selection (AMFS) [11] Model Selection: Two-Step SVM Fusion: Combine tree-structured vector quantization and Multiple binary Support Vector Machine classifiers [3]. The proposed algorithms using the 5-fold cross validation procedure and obtained a correct classification rate of 99.6% [3].…”

Section: Segmentationmentioning

confidence: 99%

Motus: Marco de trabajo para la clasificación de Captura de Movimiento humano en ambientes no controlados

Rodríguez-González

Hernández-López

Siles

2020

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This work introduces a framework proposal based on various algorithms, processes, and methods to classify Motion Capture (MoCap) data. To provide a generalized model for MoCap data classification, the approach is defined step by step: data collecting, data cleansing, segmentation, data pre-processing, feature selection, model selection, and validation. For each step, we selected and evaluated algorithms, process and methods have shown good performance in previous studies, all of them were proved and validated in BVH databases, but in not freely moving environment. Palabras clavesMoCap; clasificación; segmentación; selección de características; limpieza. ResumenEste trabajo presenta la propuesta para un marco de trabajo (Motus) basado en varios algoritmos, procesos y métodos para la clasificación de archivos de captura de movimiento. El objetivo es proveer un modelo generalizado para la clasificación de movimiento, el enfoque es defino bajo los siguientes pasos: recolección y limpieza de datos, pre-procesamiento de la información, selección de características, segmentación y la selección del modelo y la validación. Para casa uno de los pasos, se selección y evaluó algoritmos que han demostrado un buen rendimiento, en ambientes controlados, en estudios previos, todos ellos han sido probados en archivos BVH, pero no en ambientes no controlados.

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Adaptive multi-view feature selection for human motion retrieval

Cited by 73 publications

References 49 publications

Retrieval of spatial–temporal motion topics from 3D skeleton data

Retrieval of spatial–temporal motion topics from 3D skeleton data

DeepHuMS: Deep Human Motion Signature for 3D Skeletal Sequences

Motus: Marco de trabajo para la clasificación de Captura de Movimiento humano en ambientes no controlados

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