Your search keyword '"Tony Luczak"' showing total 8 results

1. Closing the Wearable Gap—Part V: Development of a Pressure-Sensitive Sock Utilizing Soft Sensors

Author

Tony Luczak, Reuben F. Burch V, Brian K. Smith, Daniel W. Carruth, John Lamberth, Harish Chander, Adam Knight, J.E. Ball, and R.K. Prabhu

Subjects

wearables, pressure, soft robotic sensors, ground reaction force, root mean square error, Chemical technology, TP1-1185

Abstract

The purpose of this study was to evaluate the use of compressible soft robotic sensors (C-SRS) in determining plantar pressure to infer vertical and shear forces in wearable technology: A ground reaction pressure sock (GRPS). To assess pressure relationships between C-SRS, pressure cells on a BodiTrakTM Vector Plate, and KistlerTM Force Plates, thirteen volunteers performed three repetitions of three different movements: squats, shifting center-of-pressure right to left foot, and shifting toes to heels with C-SRS in both anterior−posterior (A/P) and medial−lateral (M/L) sensor orientations. Pearson correlation coefficient of C-SRS to BodiTrakTM Vector Plate resulted in an average R-value greater than 0.70 in 618/780 (79%) of sensor to cell comparisons. An average R-value greater than 0.90 was seen in C-SRS comparison to KistlerTM Force Plates during shifting right to left. An autoregressive integrated moving average (ARIMA) was conducted to identify and estimate future C-SRS data. No significant differences were seen in sensor orientation. Sensors in the A/P orientation reported a mean R2 value of 0.952 and 0.945 in the M/L sensor orientation, reducing the effectiveness to infer shear forces. Given the high R values, the use of C-SRSs to infer normal pressures appears to make the development of the GRPS feasible.

Published

2019

2. Closing the Wearable Gap—Part II: Sensor Orientation and Placement for Foot and Ankle Joint Kinematic Measurements

Author

David Saucier, Tony Luczak, Phuoc Nguyen, Samaneh Davarzani, Preston Peranich, John E. Ball, Reuben F. Burch, Brian K. Smith, Harish Chander, Adam Knight, and R. K. Prabhu

Subjects

soft robotic sensors, wearables, athletic training, ankle complex, plantar flexion, dorsiflexion, inversion, eversion, sensor placement, kinematic, Chemical technology, TP1-1185

Abstract

The linearity of soft robotic sensors (SRS) was recently validated for movement angle assessment using a rigid body structure that accurately depicted critical movements of the foot−ankle complex. The purpose of this study was to continue the validation of SRS for joint angle movement capture on 10 participants (five male and five female) performing ankle movements in a non-weight bearing, high-seated, sitting position. The four basic ankle movements—plantar flexion (PF), dorsiflexion (DF), inversion (INV), and eversion (EVR)—were assessed individually in order to select good placement and orientation configurations (POCs) for four SRS positioned to capture each movement type. PF, INV, and EVR each had three POCs identified based on bony landmarks of the foot and ankle while the DF location was only tested for one POC. Each participant wore a specialized compression sock where the SRS could be consistently tested from all POCs for each participant. The movement data collected from each sensor was then compared against 3D motion capture data. R-squared and root-mean-squared error averages were used to assess relative and absolute measures of fit to motion capture output. Participant robustness, opposing movements, and gender were also used to identify good SRS POC placement for foot−ankle movement capture.

Published

2019

3. Virtual Reality Induced Symptoms and Effects: Concerns, Causes, Assessment & Mitigation

Author

Nathan O. Conner, Hannah R. Freeman, J. Adam Jones, Tony Luczak, Daniel Carruth, Adam C. Knight, and Harish Chander

Abstract

The utilization of commercially available virtual reality (VR) environments has increased over the last decade. Motion sickness that is commonly reported while using VR devices is still prevalent and reported at a higher than acceptable rate. The virtual reality induced symptoms and effects (VRISE) are considered the largest barrier to widespread usage. Current measurement methods have uniform use across studies but are subjective and are not designed for VR. VRISE and other motion sickness symptom profiles are similar but not exactly the same. Common objective physiological and biomechanical as well as subjective perception measures correlated with VRISE should be used instead. Many physiological biomechanical and subjective changes evoked by VRISE have been identified. There is a great difficulty in claiming that these changes are directly caused by VRISE due to numerous other factors that are known to alter these variables resting states. Several theories exist regarding the causation of VRISE. Among these is the sensory conflict theory resulting from differences in expected and actual sensory input. Reducing these conflicts has been shown to decrease VRISE. User characteristics contributing to VRISE severity have shown inconsistent results. Guidelines of field of view (FOV), resolution, and frame rate have been developed to prevent VRISE. Motion-to-photons latency movement also contributes to these symptoms and effects. Intensity of content is positively correlated to VRISE, as is the speed of navigation and oscillatory displays. Duration of immersion shows greater VRISE, though adaptation has been shown to occur from multiple immersions. The duration of post immersion VRISE is related to user history of motion sickness and speed of onset. Cognitive changes from VRISE include decreased reaction time and eye hand coordination. Methods to lower VRISE have shown some success. Postural control presents a potential objective variable for predicting and monitoring VRISE intensity. Further research is needed to lower the rate of VRISE symptom occurrence as a limitation of use.

Published

2022

4. Closing the Wearable Gap-Part VII: A Retrospective of Stretch Sensor Tool Kit Development for Benchmark Testing

Author

David Saucier, Karen Persons, Purva Talegaonkar, John E. Ball, Will Carroll, Alana J. Turner, Raj Prabhu, Erin Parker, Tony Luczak, Samaneh Davarzani, Carver Middleton, Preston Peranich, Brian K. Smith, Harish Chander, Adam C. Knight, Reuben F. Burch, and Landon Casey

Subjects

stretch sensors, Computer Networks and Communications, Computer science, sports performance, Soft robotics, Wearable computer, lcsh:TK7800-8360, Kinematics, computer.software_genre, ankle joint complex, 01 natural sciences, 03 medical and health sciences, 0302 clinical medicine, Electrical and Electronic Engineering, Closing (morphology), wearable sensors, motion analysis, 010401 analytical chemistry, lcsh:Electronics, 030229 sport sciences, 0104 chemical sciences, Hardware and Architecture, Control and Systems Engineering, Gait analysis, Signal Processing, Data mining, athlete, computer

Abstract

This paper presents a retrospective of the benchmark testing methodologies developed and accumulated into the stretch sensor tool kit (SSTK) by the research team during the Closing the Wearable Gap series of studies. The techniques developed to validate stretchable soft robotic sensors (SRS) as a means for collecting human kinetic and kinematic data at the foot-ankle complex and at the wrist are reviewed. Lessons learned from past experiments are addressed, as well as what comprises the current SSTK based on what the researchers learned over the course of multiple studies. Three core components of the SSTK are featured: (a) material testing tools, (b) data analysis software, and (c) data collection devices. Results collected indicate that the stretch sensors are a viable means for predicting kinematic data based on the most recent gait analysis study conducted by the researchers (average root mean squared error or RMSE = 3.63°). With the aid of SSTK defined in this study summary and shared with the academic community on GitHub, researchers will be able to undergo more rigorous validation methodologies of SRS validation. A summary of the current state of the SSTK is detailed and includes insight into upcoming experiments that will utilize more sophisticated techniques for fatigue testing and gait analysis, utilizing SRS as the data collection solution.

Published

2020

5. Closing the Wearable Gap—Part VI: Human Gait Recognition Using Deep Learning Methodologies

Author

David Saucier, Raj Prabhu, Preston Peranich, Brian K. Smith, Harish Chander, Tony Luczak, Samaneh Davarzani, Carver Middleton, Reuben F. Burch, Will Carroll, Alana J. Turner, Phuoc Nguyen, Erin Parker, Preston Robertson, John E. Ball, and Adam C. Knight

Subjects

Computer Networks and Communications, Computer science, Soft robotics, lcsh:TK7800-8360, 02 engineering and technology, Kinematics, soft robotic sensors, RNN, Motion capture, 3D motion capture, 03 medical and health sciences, 0302 clinical medicine, Gait (human), 0202 electrical engineering, electronic engineering, information engineering, medicine, Electrical and Electronic Engineering, Artificial neural network, business.industry, Deep learning, wearable sensors, lcsh:Electronics, 020206 networking & telecommunications, Pattern recognition, 030229 sport sciences, Gait, Sagittal plane, medicine.anatomical_structure, Hardware and Architecture, Control and Systems Engineering, Signal Processing, Artificial intelligence, LSTM, business, human gait, ANN, multivariable linear model

Abstract

A novel wearable solution using soft robotic sensors (SRS) has been investigated to model foot-ankle kinematics during gait cycles. The capacitance of SRS related to foot-ankle basic movements was quantified during the gait movements of 20 participants on a flat surface as well as a cross-sloped surface. In order to evaluate the power of SRS in modeling foot-ankle kinematics, three-dimensional (3D) motion capture data was also collected for analyzing gait movement. Three different approaches were employed to quantify the relationship between the SRS and the 3D motion capture system, including multivariable linear regression, an artificial neural network (ANN), and a time-series long short-term memory (LSTM) network. Models were compared based on the root mean squared error (RMSE) of the prediction of the joint angle of the foot in the sagittal and frontal plane, collected from the motion capture system. There was not a significant difference between the error rates of the three different models. The ANN resulted in an average RMSE of 3.63, being slightly more successful in comparison to the average RMSE values of 3.94 and 3.98 resulting from multivariable linear regression and LSTM, respectively. The low error rate of the models revealed the high performance of SRS in capturing foot-ankle kinematics during the human gait cycle.

Published

2020

6. Closing the Wearable Gap—Part V: Development of a Pressure-Sensitive Sock Utilizing Soft Sensors

Author

John E. Ball, Tony Luczak, Daniel W. Carruth, Brian K. Smith, John Lamberth, Raj Prabhu, Adam C. Knight, Harish Chander, and Reuben F. Burch

Subjects

Mean squared error, Acoustics, Shear force, 02 engineering and technology, soft robotic sensors, lcsh:Chemical technology, Biochemistry, Article, Analytical Chemistry, 03 medical and health sciences, symbols.namesake, pressure, 0302 clinical medicine, Orientation (geometry), parasitic diseases, Force platform, lcsh:TP1-1185, Autoregressive integrated moving average, Electrical and Electronic Engineering, Ground reaction force, Instrumentation, Mathematics, 030229 sport sciences, 021001 nanoscience & nanotechnology, Atomic and Molecular Physics, and Optics, Pearson product-moment correlation coefficient, body regions, wearables, Compressibility, symbols, root mean square error, ground reaction force, 0210 nano-technology

Abstract

The purpose of this study was to evaluate the use of compressible soft robotic sensors (C-SRS) in determining plantar pressure to infer vertical and shear forces in wearable technology: A ground reaction pressure sock (GRPS). To assess pressure relationships between C-SRS, pressure cells on a BodiTrakTM Vector Plate, and KistlerTM Force Plates, thirteen volunteers performed three repetitions of three different movements: squats, shifting center-of-pressure right to left foot, and shifting toes to heels with C-SRS in both anterior&ndash, posterior (A/P) and medial&ndash, lateral (M/L) sensor orientations. Pearson correlation coefficient of C-SRS to BodiTrakTM Vector Plate resulted in an average R-value greater than 0.70 in 618/780 (79%) of sensor to cell comparisons. An average R-value greater than 0.90 was seen in C-SRS comparison to KistlerTM Force Plates during shifting right to left. An autoregressive integrated moving average (ARIMA) was conducted to identify and estimate future C-SRS data. No significant differences were seen in sensor orientation. Sensors in the A/P orientation reported a mean R2 value of 0.952 and 0.945 in the M/L sensor orientation, reducing the effectiveness to infer shear forces. Given the high R values, the use of C-SRSs to infer normal pressures appears to make the development of the GRPS feasible.

Published

2019

7. Closing the Wearable Gap: Mobile Systems for Kinematic Signal Monitoring of the Foot and Ankle

Author

David Saucier, Adam C. Knight, Tashfin Iftekhar, John E. Ball, Reuben F. Burch, Tony Luczak, Harish Chander, and Pan Wei

Subjects

medicine.medical_specialty, human ankle model, Computer Networks and Communications, Computer science, industrial_manufacturing_engineering, 0206 medical engineering, Wearable computer, lcsh:TK7800-8360, 02 engineering and technology, Kinematics, athletic training, Plantar flexion, resistance-based sensors, Athletic training, 03 medical and health sciences, Physical medicine and rehabilitation, 0302 clinical medicine, Inertial measurement unit, ComputerApplications_MISCELLANEOUS, medicine, Metre, Liquid Wire, Electrical and Electronic Engineering, Closing (morphology), Simulation, plantar flexion, ankle complex, sensor substrate, lcsh:Electronics, 030229 sport sciences, 020601 biomedical engineering, medicine.anatomical_structure, wearables, Hardware and Architecture, Control and Systems Engineering, Signal Processing, liquid metal sensors, Ankle, Signal monitoring, Foot (unit)

Abstract

Interviews from strength and conditioning coaches across all levels of athletic competition identified their two biggest concerns with the current state of wearable technology: (a) the lack of solutions that accurately capture data &ldquo, from the ground up&rdquo, and (b) the lack of trust due to inconsistent measurements. The purpose of this research is to investigate the use of liquid metal sensors, specifically Liquid Wire sensors, as a potential solution for accurately capturing ankle complex movements such as plantar flexion, dorsiflexion, inversion, and eversion. Sensor stretch linearity was validated using a Micro-Ohm Meter and a Wheatstone bridge circuit. Sensors made from different substrates were also tested and discovered to be linear at multiple temperatures. An ankle complex model and computing unit for measuring resistance values were developed to determine sensor output based on simulated plantar flexion movement. The sensors were found to have a significant relationship between the positional change and the resistance values for plantar flexion movement. The results of the study ultimately confirm the researchers&rsquo, hypothesis that liquid metal sensors, and Liquid Wire sensors specifically, can serve as a mitigating substitute for inertial measurement unit (IMU) based solutions that attempt to capture specific joint angles and movements.

Published

2018

8. Closing the Wearable Gap—Part IV: 3D Motion Capture Cameras Versus Soft Robotic Sensors Comparison of Gait Movement Assessment

Author

Brian K. Smith, Tony Luczak, Raj Prabhu, Will Carroll, Alana J. Turner, David Saucier, Phuoc Nguyen, Adam C. Knight, Harish Chander, John E. Ball, Samaneh Davarzani, and Reuben F. Burch

Subjects

Computer Networks and Communications, Computer science, Soft robotics, lcsh:TK7800-8360, Wearable computer, soft robotic sensors, 02 engineering and technology, gait, Movement assessment, Motion capture, 03 medical and health sciences, foot-ankle complex, 0302 clinical medicine, 0202 electrical engineering, electronic engineering, information engineering, Computer vision, Electrical and Electronic Engineering, Walking gait, adjusted r2, data coupling, business.industry, lcsh:Electronics, 020206 networking & telecommunications, 030229 sport sciences, mean absolute error, 3d motion capture, Gait, wearables, multivariate linear model, Hardware and Architecture, Control and Systems Engineering, Signal Processing, root mean square error, Artificial intelligence, business

Abstract

The purpose of this study was to use 3D motion capture and stretchable soft robotic sensors (SRS) to collect foot-ankle movement on participants performing walking gait cycles on flat and sloped surfaces. The primary aim was to assess differences between 3D motion capture and a new SRS-based wearable solution. Given the complex nature of using a linear solution to accurately quantify the movement of triaxial joints during a dynamic gait movement, 20 participants performing multiple walking trials were measured. The participant gait data was then upscaled (for the SRS), time-aligned (based on right heel strikes), and smoothed using filtering methods. A multivariate linear model was developed to assess goodness-of-fit based on mean absolute error (MAE, 1.54), root mean square error (RMSE, 1.96), and absolute R2 (R2, 0.854). Two and three SRS combinations were evaluated to determine if similar fit scores could be achieved using fewer sensors. Inversion (based on MAE and RMSE) and plantar flexion (based on R2) sensor removal provided second-best fit scores. Given that the scores indicate a high level of fit, with further development, an SRS-based wearable solution has the potential to measure motion during gait- based tasks with the accuracy of a 3D motion capture system.

Published

2019