Estimating Exerted Hand Force via Force Myography to Interact with a Biaxial Stage in Real-Time by Learning Human Intentions: A Preliminary Investigation

Zakia, Umme; Menon, Carlo

doi:10.3390/s20072104

Cited by 11 publications

(15 citation statements)

References 42 publications

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“…Since FMG signals can read muscle contractions during such activities, it can be a viable tool for predicting worker's intended interactions or applied forces [14]. Therefore, a few studies were conducted to determine isometric hand forces, dynamic forces in motion via FMG signals [15], [16]. Although the study in [16] showed impressive results in recognizing applied forces in dynamic motion during HRI, it had a few shortcomings.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, a few studies were conducted to determine isometric hand forces, dynamic forces in motion via FMG signals [15], [16]. Although the study in [16] showed impressive results in recognizing applied forces in dynamic motion during HRI, it had a few shortcomings. First, a separate regression model was trained for predicting forces applied by each participant for one specific motion.…”

Section: Introductionmentioning

confidence: 99%

“…Performances of these LCFMG models were evaluated in RT and compared to each other. A few models were also trained with "new input sample data" only (no population data), as mentioned in [16]. These models were termed as "specialized trained models (STMs)" hereinafter and were compared with the proposed LCFMG models for performance evaluation.…”

Section: Introductionmentioning

confidence: 99%

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Toward Long-Term FMG Model-Based Estimation of Applied Hand Force in Dynamic Motion During Human–Robot Interactions

Zakia

Menon

2021

IEEE Trans. Human-Mach. Syst.

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Physical human-robot interaction (pHRI) is reliant on human actions and can be addressed by studying human upperlimb motions during interactions. Use of force myography (FMG) signals, which detect muscle contractions, can be useful in developing machine learning algorithms as controls. In this paper, a novel long-term calibrated FMG-based trained model is presented to estimate applied force in dynamic motion during real-time interactions between a human and a linear robot. The proposed FMG-based pHRI framework was investigated in new, unseen, real-time scenarios for the first time. Initially, a long-term reference dataset (multiple source distributions) of upper-limb FMG data was generated as five participants interacted with the robot applying force in five different dynamic motions. Ten other participants interacted with the robot in two intended motions to evaluate the out-of-distribution (OOD) target data (new, unlearned), which was different than the population data. Two practical scenarios were considered for assessment: i) a participant applied force in a new, unlearned motion (scenario 1), and ii) a new, unlearned participant applied force in an intended motion (scenario 2). In each scenario, few long-term FMG-based models were trained using a baseline dataset [reference dataset (scenario 1, 2) and/or a learnt participant dataset (scenario 1)] and a calibration dataset (collected during evaluation). Real-time evaluation showed that the proposed long-term calibrated FMG-based models (LCFMG) could achieve estimation accuracies of 80%-94% in all scenarios. These results are useful towards integrating and generalizing human activity data in a robot control scheme by avoiding extensive HRI training phase in regular applications.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Toward Long-Term FMG Model-Based Estimation of Applied Hand Force in Dynamic Motion During Human–Robot Interactions

Zakia

Menon

2021

IEEE Trans. Human-Mach. Syst.

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“…Estimating isometric or dynamic hand force/torque using FMG signals via FSRs were found favorable to FT sensors [ 28 , 29 , 30 ]. Recently, measuring force via FMG bio signals during physical human robot interactions (pHRI) between human participants and a linear robot was found effective for intra-session evaluation using traditional ML algorithms [ 31 ]. However, intra-session FMG-based pHRI required collecting adequate labelled training data, which was biased and impractical in real scenarios.…”

Section: Introductionmentioning

confidence: 99%

Force Myography-Based Human Robot Interactions via Deep Domain Adaptation and Generalization

Zakia

Menon

2021

Sensors

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Estimating applied force using force myography (FMG) technique can be effective in human-robot interactions (HRI) using data-driven models. A model predicts well when adequate training and evaluation are observed in same session, which is sometimes time consuming and impractical. In real scenarios, a pretrained transfer learning model predicting forces quickly once fine-tuned to target distribution would be a favorable choice and hence needs to be examined. Therefore, in this study a unified supervised FMG-based deep transfer learner (SFMG-DTL) model using CNN architecture was pretrained with multiple sessions FMG source data (Ds, Ts) and evaluated in estimating forces in separate target domains (Dt, Tt) via supervised domain adaptation (SDA) and supervised domain generalization (SDG). For SDA, case (i) intra-subject evaluation (Ds ≠ Dt-SDA, Ts ≈ Tt-SDA) was examined, while for SDG, case (ii) cross-subject evaluation (Ds ≠ Dt-SDG, Ts ≠ Tt-SDG) was examined. Fine tuning with few “target training data” calibrated the model effectively towards target adaptation. The proposed SFMG-DTL model performed better with higher estimation accuracies and lower errors (R2 ≥ 88%, NRMSE ≤ 0.6) in both cases. These results reveal that interactive force estimations via transfer learning will improve daily HRI experiences where “target training data” is limited, or faster adaptation is required.

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“…Force Myography (FMG) is a technique to quantify changes in the volume of a limb resulting from muscle contractions and relaxations (Xiao and Menon, 2014 ). This biosignal has been employed in a variety of applications including gesture recognition, control of exoskeletons, prostheses, and linear actuators, and estimation of user-applied forces to manipulate planar linear actuators (Xiao et al, 2014 ; Cho et al, 2016 ; Sakr and Menon, 2016a , b , 2017 , 2018 ; Jiang et al, 2017 ; Sadarangani and Menon, 2017 ; Zakia and Menon, 2020 ). Force myography from upper-limbs could be collected using lightweight, compact, and unobtrusive bands wrapped around wrist, forearm, and/or upper arm, which makes it an attractive technique for developing wearables.…”

Section: Introductionmentioning

confidence: 99%

FMG- and RNN-Based Estimation of Motor Intention of Upper-Limb Motion in Human-Robot Collaboration

et al. 2020

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Research on human-robot interactions has been driven by the increasing employment of robotic manipulators in manufacturing and production. Toward developing more effective human-robot collaboration during shared tasks, this paper proposes an interaction scheme by employing machine learning algorithms to interpret biosignals acquired from the human user and accordingly planning the robot reaction. More specifically, a force myography (FMG) band was wrapped around the user's forearm and was used to collect information about muscle contractions during a set of collaborative tasks between the user and an industrial robot. A recurrent neural network model was trained to estimate the user's hand movement pattern based on the collected FMG data to determine whether the performed motion was random or intended as part of the predefined collaborative tasks. Experimental evaluation during two practical collaboration scenarios demonstrated that the trained model could successfully estimate the category of hand motion, i.e., intended or random, such that the robot either assisted with performing the task or changed its course of action to avoid collision. Furthermore, proximity sensors were mounted on the robotic arm to investigate if monitoring the distance between the user and the robot had an effect on the outcome of the collaborative effort. While further investigation is required to rigorously establish the safety of the human worker, this study demonstrates the potential of FMG-based wearable technologies to enhance human-robot collaboration in industrial settings.

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Estimating Exerted Hand Force via Force Myography to Interact with a Biaxial Stage in Real-Time by Learning Human Intentions: A Preliminary Investigation

Cited by 11 publications

References 42 publications

Toward Long-Term FMG Model-Based Estimation of Applied Hand Force in Dynamic Motion During Human–Robot Interactions

Toward Long-Term FMG Model-Based Estimation of Applied Hand Force in Dynamic Motion During Human–Robot Interactions

Force Myography-Based Human Robot Interactions via Deep Domain Adaptation and Generalization

FMG- and RNN-Based Estimation of Motor Intention of Upper-Limb Motion in Human-Robot Collaboration

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