Neural state machine for character-scene interactions

Starke, Sebastian; Zhang, He; Komura, Taku; Saito, Jun

doi:10.1145/3355089.3356505

Cited by 201 publications

(169 citation statements)

References 33 publications

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“…For task-specific computer animation, supervised learning of (direct-predictive) parametric motion models have seen much recent interest. Autoregressive DNN models can produce high-quality human variable-terrain locomotion , quadruped variable-terrain locomotion [Zhang et al 2018], and environment aware human locomotion [Starke et al 2019]. Similarly, a mix of data augmentation and flexible objective annotation ] can be used to learn an effective task-specific RNN model for human motion, as demonstrated on locomotion, basketball, and tennis.…”

Section: Kinematic Motion Synthesismentioning

confidence: 99%

Character controllers using motion VAEs

et al. 2020

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Fig. 1. Given example data, we learn an autoregressive conditional variational autoencoder (VAE) that predicts the next pose one frame at a time. A variety of task-specific control policies can then be learned on top of this model.A fundamental problem in computer animation is that of realizing purposeful and realistic human movement given a sufficiently-rich set of motion capture clips. We learn data-driven generative models of human movement using autoregressive conditional variational autoencoders, or Motion VAEs. The latent variables of the learned autoencoder define the action space for the movement and thereby govern its evolution over time. Planning or control algorithms can then use this action space to generate desired motions. In particular, we use deep reinforcement learning to learn controllers that achieve goal-directed movements. We demonstrate the effectiveness of the approach on multiple tasks. We further evaluate system-design choices and describe the current limitations of Motion VAEs.

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Section: Kinematic Motion Synthesismentioning

confidence: 99%

Character controllers using motion VAEs

et al. 2020

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“…Thanks to its nature, such models can be used for real-time character control, which is our target application. Human motion has been modelled with various time series models, such as conditional Restricted Bolzmann Machine (cRBM) [Taylor et al 2007], Gaussian processes (GP) [Wang et al 2008], recurrent neural networks [Fragkiadaki et al 2015;Harvey and Pal 2018;Li et al 2017;Villegas et al 2018], Phase Functioned Neural Networks (PFNN) [Holden et al 2017] and mixture-of-experts models [Starke et al 2019;Xia et al 2015;.…”

Section: Related Workmentioning

confidence: 99%

Local motion phases for learning multi-contact character movements

et al. 2020

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Training a bipedal character to play basketball and interact with objects, or a quadruped character to move in various locomotion modes, are difficult tasks due to the fast and complex contacts happening during the motion. In this paper, we propose a novel framework to learn fast and dynamic character interactions that involve multiple contacts between the body and an object, another character and the environment, from a rich, unstructured motion capture database. We use one-on-one basketball play and character interactions with the environment as examples. To achieve this task, we propose a novel feature called local motion phase, that can help neural networks to learn asynchronous movements of each bone and its interaction with external objects such as a ball or an environment. We also propose a novel generative scheme to reproduce a wide variation of movements from abstract control signals given by a gamepad, which can be useful for changing the style of the motion under the same context. Our scheme is useful for animating contact-rich, complex interactions for real-time applications such as computer games.

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“…Mixture‐of‐Experts Approaches : Another strategy exploited in [SZKS19, SZKZ20, LZCVDP20] to address the problem of mean collapse in multi‐modal motion data is to use a Mixture‐of‐Experts (MoE) network where each expert is responsible for one mode in the training data. Though effective at mitigating mean collapse, the number of parameters in these networks increases with the number of experts.…”

Section: Related Workmentioning

confidence: 99%

Probabilistic Character Motion Synthesis using a Hierarchical Deep Latent Variable Model

Ghorbani

Wloka

Etemad

et al. 2020

Computer Graphics Forum

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We present a probabilistic framework to generate character animations based on weak control signals, such that the synthesized motions are realistic while retaining the stochastic nature of human movement. The proposed architecture, which is designed as a hierarchical recurrent model, maps each sub‐sequence of motions into a stochastic latent code using a variational autoencoder extended over the temporal domain. We also propose an objective function which respects the impact of each joint on the pose and compares the joint angles based on angular distance. We use two novel quantitative protocols and human qualitative assessment to demonstrate the ability of our model to generate convincing and diverse periodic and non‐periodic motion sequences without the need for strong control signals.

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Neural state machine for character-scene interactions

Cited by 201 publications

References 33 publications

Character controllers using motion VAEs

Character controllers using motion VAEs

Local motion phases for learning multi-contact character movements

Probabilistic Character Motion Synthesis using a Hierarchical Deep Latent Variable Model

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