Human–Robot Collaboration in 3D via Force Myography Based Interactive Force Estimations Using Cross-Domain Generalization

Zakia, Umme; Menon, Carlo

doi:10.1109/access.2022.3164103

Cited by 5 publications

(11 citation statements)

References 24 publications

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“…For compliant collaboration during training and testing, motion trajectories were not fixed between a start and end point; rather, it was bounded by 6-axis rectangular areas in the 1D, 2D, and 3D workspaces [ 51 ]. This allowed flexible dynamic motions within certain ranges, instead of restricted movements.…”

Section: Discussionmentioning

confidence: 99%

“…This control mechanism could be implemented to control and monitor large industrial assembly line robots that do not have any joint torque sensors to recognize the external environment. Further description of this pHRI platform can be found in [ 51 ].…”

Section: Methodsmentioning

confidence: 99%

“…Common industrial tasks such as object transportation or handover may require the worker to apply hand forces during interactions with the robot. Estimating the applied hand force to interact with a robot in dynamic motions using FMG signals was found favorable in physical interactions [ 48 , 49 , 50 , 51 , 52 , 53 ]. These studies implemented compliant collaboration, where a robot’s trajectory was dictated by the applied hand force of a human worker.…”

Section: Introductionmentioning

confidence: 99%

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Detecting Safety Anomalies in pHRI Activities via Force Myography

Zakia

Menon

2023

Bioengineering

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The potential application of using a wearable force myography (FMG) band for monitoring the occupational safety of a human participant working in collaboration with an industrial robot was studied. Regular physical human–robot interactions were considered as activities of daily life in pHRI (pHRI-ADL) to recognize human-intended motions during such interactions. The force myography technique was used to read volumetric changes in muscle movements while a human participant interacted with a robot. Data-driven models were used to observe human activities for useful insights. Using three unsupervised learning algorithms, isolation forest, one-class SVM, and Mahalanobis distance, models were trained to determine pHRI-ADL/regular, preset activities by learning the latent features’ distributions. The trained models were evaluated separately to recognize any unwanted interactions that differed from the normal activities, i.e., anomalies that were novel, inliers, or outliers to the normal distributions. The models were able to detect unusual, novel movements during a certain scenario that was considered an unsafe interaction. Once a safety hazard was detected, the control system generated a warning signal within seconds of the event. Hence, this study showed the viability of using FMG biofeedback to indicate risky interactions to prevent injuries, improve occupational health, and monitor safety in workplaces that require human participation.

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Detecting Safety Anomalies in pHRI Activities via Force Myography

Zakia

Menon

2023

Bioengineering

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“…In the literature, CNN based GAN models are more dominant and have shown good performances in image classifications and pattern recognition. In our previous studies, we found that the model could effectively learn discriminative features of time-series interactive data [16], [17]. In this study, window size of the FMG-DCGAN model was set to 10ms evaluate the smallest time-series input (every single row) in the system.…”

Section: Discussionmentioning

confidence: 99%

“…The study showed that intrasession models could estimate applied forces well (accuracies of 94%>R 2 >82%) where training and evaluation were carried out in the same session, had similar feature distributions, and were labeled properly. Recently, adapting domain adaptation, domain generalization and cross-domain generalization techniques enabled an SVR, and a convolutional neural network (CNN) model trained with labeled FMG data from multiple pHRI source domains to recognize applied hand forces in unknown pHRI target scenarios that the model had never seen before [15]- [17]. Finetuning allowed required periodic calibrations to recognize any unseen, instantaneous signals.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised, Semi-Supervised Interactive Force Estimations During pHRI via Generated Synthetic Force Myography Signals

et al. 2022

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Recognizing applied hand forces using force myography (FMG) biosignals requires adequate training data to facilitate physical human-robot interactions (pHRI). But in practice, data is often scarce, and labels are usually unavailable or time consuming to generate. Synthesizing FMG biosignals can be a viable solution. Therefore, in this paper, we propose for the first time a dual-phased algorithm based on semisupervised adversarial learning utilizing fewer labeled real FMG data with generated unlabeled synthetic FMG data. We conducted a pilot study to test this algorithm in estimating applied forces during interactions with a Kuka robot in 1D-X, Y, Z directions. Initially, an unsupervised FMG-based deep convolutional generative adversarial network (FMG-DCGAN) model was employed to generate real-like synthetic FMG data. A variety of transformation functions were used to observe domain randomization for increasing data variability and for representing authentic physiological, environmental changes. Cosine similarity score and generated-to-input-data ratio were used as decision criteria minimizing the reality gap between real and synthetic data and helped avoid risks associated with wrong predictions. Finally, the FMG-DCGAN model was pretrained to generate pseudo-labels for unlabeled real and synthetic data, further retrained using all labeled and pseudo-labeled data and was termed as the self-trained FMG-DCGAN model. Lastly, this model was evaluated on unseen real test data and achieved accuracies of 85%>R 2 >77% in force estimation compared to the corresponding supervised baseline model (89%>R 2 >78%). Therefore, the proposed method can be more practical for use in FMG-based HRI, rehabilitation, and prosthetic control for daily, repetitive usage even with few labeled data.

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Dataset on Force Myography for Human–Robot Interactions

Zakia

Menon

2022

Data

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Force myography (FMG) is a contemporary, non-invasive, wearable technology that can read the underlying muscle volumetric changes during muscle contractions and expansions. The FMG technique can be used in recognizing human applied hand forces during physical human robot interactions (pHRI) via data-driven models. Several FMG-based pHRI studies were conducted in 1D, 2D and 3D during dynamic interactions between a human participant and a robot to realize human applied forces in intended directions during certain tasks. Raw FMG signals were collected via 16-channel (forearm) and 32-channel (forearm and upper arm) FMG bands while interacting with a biaxial stage (linear robot) and a serial manipulator (Kuka robot). In this paper, we present the datasets and their structures, the pHRI environments, and the collaborative tasks performed during the studies. We believe these datasets can be useful in future studies on FMG biosignal-based pHRI control design.

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Human–Robot Collaboration in 3D via Force Myography Based Interactive Force Estimations Using Cross-Domain Generalization

Cited by 5 publications

References 24 publications

Detecting Safety Anomalies in pHRI Activities via Force Myography

Detecting Safety Anomalies in pHRI Activities via Force Myography

Unsupervised, Semi-Supervised Interactive Force Estimations During pHRI via Generated Synthetic Force Myography Signals

Dataset on Force Myography for Human–Robot Interactions

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