A Review of Force Myography Research and Development
Abstract
:1. Introduction
2. FMG Signal Acquisition
2.1. Resistive Polymer Thick Film Sensor (RPTF) for FMG Application
2.1.1. Element-Wise RPTF Sensor
2.1.2. High-Density Polymer Thick Film Sensor Array and Matrix
2.1.3. Sampling Rate
2.1.4. Sensor Placement and Applications
2.2. Example of FMG, MMG, and sEMG Signals from the Forearm for Squeezing Action
Other Force Sensors
3. FMG Processing Methods
3.1. FMG Signal Conditioning and Feature Extraction
3.2. Predict Limb Action Using Machine Learning Techniques
3.2.1. Classification
3.2.2. Regression
4. Discussion
4.1. Challenges in FMG Hardware Development
4.2. Challenges in FMG Software Development
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Appendix A
Reference | Title | Publication Type |
---|---|---|
Abboudi et al., 1999 [3] | A biomimetic controller for a multi-finger prosthesis | Journal |
Curcie et al., 2001 [6] | Biomimetic finger control by filtering of distributed forelimb pressures | Journal |
Craelius et al., 2002 [5] | The bionic man: restoring mobility | Journal |
Phillips et al., 2005 [4] | Residual kinetic imaging: a versatile interface for prosthetic control | Journal |
Amft et al., 2006 [8] | Sensing Muscle Activities with Body-Worn Sensors | Proceeding |
Lukowicz et al., 2006 [7] | Detecting and Interpreting Muscle Activity with Wearable Force Sensors | Proceeding |
Ogris et al., 2007 [9] | Using FSR-based muscule activity monitoring to recognize manipulative arm gestures | Proceeding |
Wininger et al., 2008 [1] | Pressure signature of forearm as predictor of grip force | Journal |
Wang et al., 2010 [37] | Biomechatronic approach to a multi-fingered hand prosthesis | Proceeding |
Yungher et al., 2011 [47] | Surface muscle pressure as a measure of active and passive behavior of muscles during gait | Journal |
Li et al., 2012 [13] | Combined Use of FSR Sensor Array and SVM Classifier for Finger Motion Recognition Based on Pressure Distribution Map | Journal |
Bin et al., 2012 [73] | Multi-sensor arm rehabilitation monitoring device | Proceeding |
Morganti et al., 2012 [24] | A Smart Watch with Embedded Sensors to Recognize Objects, Grasps and Forearm Gestures | Proceeding |
Yungher et al., 2012 [34] | Improving fine motor function after brain injury using gesture recognition biofeedback | Journal |
Castellini et al., 2012 [74] | Intention Gathering from Muscle Residual Activity for the Severely Disabled | Proceeding |
Dementyev et al., 2014 [30] | WristFlex | Proceeding |
Radmand et al., 2014 [12] | High-resolution muscle pressure mapping for upper-limb prosthetic control | Proceeding |
Castellini et al., 2013 [75] | Using a high spatial resolution tactile sensor for intention detection | Proceeding |
Xiao et al., 2014 [28] | Towards the development of a wearable feedback system for monitoring the activities of the upper-extremities | Journal |
Carbonaro et al., 2014 [76] | An Innovative Multisensor Controlled Prosthetic Hand | Proceeding |
Castellini et al., 2014 [10] | Proceedings of the first workshop on Peripheral Machine Interfaces: going beyond traditional surface electromyography | Journal |
Castellini et al., 2014 [68] | A wearable low-cost device based upon Force-Sensing Resistors to detect single-finger forces | Proceeding |
Ravindra et al., 2014 [35] | A Comparative Analysis of Three Non-Invasive Human-Machine Interfaces for the Disabled | Journal |
Rasouli et al., 2015 [55] | Stable force-myographic control of a prosthetic hand using incremental learning | Proceeding |
Sadarangani et al., 2015 [27] | A wearable sensor system for rehabilitation applications | Proceeding |
Koiva et al., 2015 [77] | Shape conformable high spatial resolution tactile bracelet for detecting hand and wrist activity | Proceeding |
Sanford et al., 2015 [78] | Surface EMG and intra-socket force measurement to control a prosthetic device | Proceeding |
Chengani et al., 2016 [79] | Pilot study on strategies in sensor placement for robust hand/wrist gesture classification based on movement related changes in forearm volume | Proceeding |
Cho et al., 2016 [41] | Force Myography to Control Robotic Upper Extremity Prostheses: A Feasibility Study | Journal |
Connan et al., 2016 [23] | Assessment of a Wearable Force- and Electromyography Device and Comparison of the Related Signals for Myocontrol | Journal |
Jiang et al., 2016 [50] | Ankle positions classification using force myography: An exploratory investigation | Proceeding |
Jiang et al., 2016 [32] | Exploration of Force Myography and surface Electro Myography in Hand Gesture classification | Journal |
Li et al., 2016 [56] | FMG-based body motion registration using piezoelectric sensors | Proceeding |
Radmand et al., 2016 [46] | High-density force myography: A possible alternative for upper-limb prosthetic control | Journal |
Yap et al., 2016 [38] | Design of a wearable FMG sensing system for user intent detection during hand rehabilitation with a soft robotic glove | Proceeding |
Kadkhodayan et al., 2016 [70] | Continuous Prediction of Finger Movements Using Force Myography | Journal |
Sakr et al., 2016 [69] | On the estimation of isometric wrist/forearm torque about three axes using Force Myography | Proceeding |
Ahmadizadeh et al., 2017 [31] | Toward Intuitive Prosthetic Control: Solving Common Issues Using Force Myography, Surface Electromyography, and Pattern Recognition in a Pilot Case Study | Journal |
Ferigo et al., 2017 [42] | A Case Study of a Force-myography Controlled Bionic Hand Mitigating Limb Position Effect | Journal |
Ghataurah et al., 2017 [43] | A Multi-sensor Approach for Biomimetic Control of a Robotic Prosthetic Hand | Proceeding |
Jaquier et al., 2017 [65] | Combining Electromyography and Tactile Myography to Improve Hand and Wrist Activity Detection in Prostheses | Journal |
Nowak et al., 2017 [66] | Multi-modal myocontrol: Testing combined force- and electromyography | Proceeding |
Sadarangani et al., 2017 [36] | Force Myography for Monitoring Grasping in Individuals with Stroke with Mild to Moderate Upper-Extremity Impairments: A Preliminary Investigation in a Controlled Environment | Journal |
Sanford et al., 2017 [80] | Concurrent surface electromyography and force myography classification during times of prosthetic socket shift and user fatigue | Journal |
Xiao et al., 2017 [45] | Performance of Forearm FMG and sEMG for Estimating Elbow, Forearm and Wrist Positions | Journal |
Xiao et al., 2017 [29] | Counting Grasping Action Using Force Myography: An Exploratory Study with Healthy Individuals | Journal |
Delva et al., 2017 [81] | FSR based Force Myography (FMG) Stability Throughout Non-Stationary Upper Extremity Tasks | Proceeding |
Booth et al., 2018 [82] | A Wrist-Worn Piezoelectric Sensor Array for Gesture Input | Journal |
Castellini et al., 2018 [14] | Tactile Myography: An Off-Line Assessment of Able-Bodied Subjects and One Upper-Limb Amputee | Journal |
Delva et al., 2018 [83] | Investigation into the Potential to Create a Force Myography-based Smart-home Controller for Aging Populations | Proceeding |
Ha et al., 2018 [57] | Force Myography Signal-Based Hand Gesture Classification for the Implementation of Real-Time Control System to a Prosthetic Hand | Proceeding |
Fang et al., 2018 [58] | Fabrication, structure characterization, and performance testing of piezoelectret-film sensors for recording body motion | Journal |
Fujiwara et al., 2018 [60] | Optical fiber force myography sensor for identification of hand postures | Journal |
Fujiwara et al., 2018 [84] | Optical fiber force myography sensor for applications in prosthetic hand control | Proceeding |
Godiyal et al., 2018 [26] | Force Myography Based Novel Strategy for Locomotion classification | Journal |
Jiang et al., 2018 [85] | Force Exertion Affects Grasp classification Using Force Myography | Journal |
Jiang et al., 2018 [51] | Exploration of Gait Parameters Affecting the Accuracy of Force Myography-Based Gait Phase Detection | Proceeding |
Jiang et al., 2018 [67] | Virtual grasps recognition using fusion of Leap Motion and force myography | Journal |
Truong et al., 2018 [59] | CapBand | Proceeding |
Zhang et al., 2018 [86] | A Pilot Study on Using Forcemyography to Record Upper-limb Movements for Human-machine Interactive Control | Proceeding |
Belyea et al., 2018 [48] | A Proportional Control Scheme for High Density Force Myography | Journal |
Sadeghi et al., 2018 [33] | Regressing grasping using force myography: An exploratory study | Journal |
Anvaripour et al., 2018 [62] | Hand gesture recognition using force myography of the forearm activities and optimized features | Proceeding |
Godiyal et al., 2018 [49] | A force myography-based system for gait event detection in overground and ramp walking | Journal |
Belbasis et al., 2018 [48] | Muscle performance investigated with a novel smart compression garment based on pressure sensor force myography and its validation against EMG | Journal |
Esposito et al., 2018 [22] | A piezoresistive sensor to measure muscle contraction and mechanomyography | Journal |
Sakr et al., 2018 [40] | Exploratory Evaluation of the Force Myography (FMG) Signals Usage for Admittance Control of a Linear Actuator | Proceeding |
Stefanou et al., 2018 [72] | Wearable Tactile Sensor Brace for Motion Intent Recognition in Upper-Limb Rehabilitation | Proceeding |
Ha et al., 2019 [87] | Performance of Forearm FMG for Estimating Hand Gestures and Prosthetic Hand Control | Journal |
Xiao et al., 2019 [61] | Does force myography recorded at the wrist correlate to resistance load levels during bicep curls? | Journal |
Xiao et al., 2019 [25] | An Investigation on the Sampling Frequency of the Upper-Limb Force Myographic Signals | Journal |
Xiao et al., 2019 [39] | Towards an FMG based augmented musical instrument interface | Proceeding |
Belyea et al., 2019 [71] | FMG vs EMG: A Comparison of Usability for Real-time Pattern Recognition Based Control | Journal |
Anvaripour et al., 2019 [88] | Controlling robot gripper force by transferring human forearm stiffness using force myography | Proceeding |
Herrera-Luna et al., 2019 [11] | Sensor Fusion Used in Applications for Hand Rehabilitation: a Systematic Review | Journal |
Prakash et al., 2019 [44] | Novel force myography sensor to measure muscle contractions for controlling hand prostheses | Journal |
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FSR (FSR402) [20] | Flexiforce® (FLX-A201-F) [21] | |
---|---|---|
Minimum actuation force (Newtons) | 0.1 | N/A |
Force sensitivity range (Newtons) | 0.1–10 | 0 to 4.4, 0 to 111, 0 to 445 |
Single part force repeatability | ±2% | ±2.5% |
Part to part force repeatability | +/−6% | ±40% |
Hysteresis | +10% | <4.5% |
Drift | <5% per log10 (time) | <5% per log10 (time) |
Response time (micro seconds) | <3 | <5 |
Linearity error | N/A | <±3% |
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Xiao, Z.G.; Menon, C. A Review of Force Myography Research and Development. Sensors 2019, 19, 4557. https://doi.org/10.3390/s19204557
Xiao ZG, Menon C. A Review of Force Myography Research and Development. Sensors. 2019; 19(20):4557. https://doi.org/10.3390/s19204557
Chicago/Turabian StyleXiao, Zhen Gang, and Carlo Menon. 2019. "A Review of Force Myography Research and Development" Sensors 19, no. 20: 4557. https://doi.org/10.3390/s19204557
APA StyleXiao, Z. G., & Menon, C. (2019). A Review of Force Myography Research and Development. Sensors, 19(20), 4557. https://doi.org/10.3390/s19204557