2.1. Errors in posture estimation using robot-mounted sensors

Wearable robots use various types of sensors to estimate the wearer’s posture as an input to their controllers. Here, we refer to a human’s posture as a set of limb segment angles (e.g., thigh or shank).

When a limb segment’s angle is estimated by a sensor mounted directly on that segment, the resultant measurement can be formulated as

(1) $$ {y}_{human}={y}_{segment}+{\varepsilon}_{measurement}, $$

where $ {y}_{human} $ is the measurement output from a sensor mounted directly on the human segment; $ {y}_{segment} $ is the true segment angle; $ {\varepsilon}_{measurement} $ is the estimation error due to the quality of the sensor’s readings and the algorithm used to estimate the angle (e.g., Kalman filter).

If the sensor is instead mounted on a structure, as is the case in wearable robots, and this structure is mounted on the limb segment, the sensor measurement output is affected by an additional source of error:

(2) $$ {y}_{robot}={y}_{segment}+{\varepsilon}_{measurement}+{\varepsilon}_{compliance}, $$

where $ {\varepsilon}_{compliance} $ is the estimation error due to the compliance of the human–robot interface.

Considering the two types of errors, we know that $ {\varepsilon}_{measurement} $ error is dependent on the type of the sensor being used, the environmental conditions in which that sensor is used, and on the algorithm for the estimation of the posture based on the sensor’s raw data. Because this is a common problem for many of motion-tracking systems and applications, much literature has been previously devoted to the problem of modeling the $ {\varepsilon}_{measurement} $ term.

For our work, we focused on quantifying the error due to the $ {\varepsilon}_{compliance} $ term. To isolate it from the $ {\varepsilon}_{measurement} $ term, we used a state-of-the-art camera-based motion capture system (Vicon, Oxford, UK) to simultaneously measure both the human’s limb segment angles (i.e., $ {y}_{human} $ ) and the corresponding robotic segment angle (i.e., $ {y}_{robot} $ ). We then derived the assumption that because both $ {y}_{human} $ and $ {y}_{robot} $ were measured simultaneously and by the same measurement system, their corresponding measurement errors could be canceled out to define the error due to compliance as

(3) $$ {\varepsilon}_{compliance}={y}_{human}-{y}_{robot}. $$

To capture the nonlinear behavior of the compliance effects, we have encoded the $ {y}_{robot} $ term as well as other robot-derived sensor signals in a matrix $ X $ (more details on the list of used signals can be found in Table 1) and have defined a mapping in the form

(4) $$ {\hat{y}}_{human}=f(X), $$

where $ {\hat{y}}_{human} $ is the estimated human-segment angle, corrected for the compliance effects, and $ f $ is a mapping function.

Table 1. List of features used for the algorithm

Note. The signal units reported in the table show the convention used as an input into the algorithm.

We modeled the $ f $ mapping function using machine learning to show that

(5) $$ {y}_{human}-{\hat{y}}_{human}<{y}_{human}-{y}_{robot}. $$

Throughout this project, we use the following naming convention:

1. 1. $ {y}_{human} $ – human segment angles: These angles were derived from a marker point cloud with a motion capture system and represent the target variable in our algorithm.

2. 2. $ {y}_{robot} $ – robot segment angles: These angles were derived from a marker point cloud with a motion capture system. The values imitate segment angle measurements of a robot. The values of $ {y}_{robot} $ were used as one of the features in our algorithm.

3. 3. $ {\hat{y}}_{human} $ – estimated human segment angles: These angles represent the estimation of the target variable by our algorithm using $ {y}_{robot} $ and robot-derived sensor measurements (see Table 1 for more details) as input features.

2.2. Participant recruitment

Eight unimpaired participants (4 female; height: 1.72 (1.62–1.95) m; mass: 63.77 (51–85) kg, mean (range)) were recruited for this study through word of mouth. The study protocol was reviewed and approved by the institutional board of ETH Zurich, Switzerland (reference number: EK 2019-N-119). All participants provided written informed consent for their participation in the experiment. Four out of the eight participants had previous experience wearing a wearable robot for the lower limbs. The previous experience had no impact on the results of this study as previous experience with a wearable robot does not affect the compliance of the robot-human interface.

2.3. Wearable robot

We used the Myosuit (MyoSwiss AG, Zurich, Switzerland) as an example of a wearable robot. The Myosuit was designed to support a person’s weight-bearing capacity during activities of daily life that include walking and standing (Haufe et al., Reference Haufe, Duroyon, Wolf, Riener and Xiloyannis2021). The full system weighs 5.5 kg. The device (Figure 1a) includes a backpack-like motor-driving unit that houses two motor-gearbox-pulley assemblies (one per leg), control electronics, and one Li-Ion battery pack. Two hard-shell plastic knee orthoses are placed on each leg to route an artificial tendon and anchor forces along the leg. Each leg is supported by an ultra-high-molecular-weight polyethylene cable routed posteriorly over the hip joint, laterally over the thigh, and anteriorly over the knee joint of the orthosis, anchoring at its distal shank component. Two passive polymer springs span the front of the hip joint. The springs were tensioned just enough to counteract potential downward slipping of the knee orthoses. The Myosuit includes five Inertial Measurement Units (IMUs); two on each thigh and shank segments and the fifth one in the motor-driving unit. A combination of the IMU signals is used to calculate the posture of the user’s five-segment body model at 100 Hz. The relative knee joint angle is used as an input for the instantaneous modulation of the assistance force (Figure 1b). The relative hip joint angle, as well as the raw IMU sensor signals, are used for the detection of key gait events.

Figure 1. Architecture and the operation principle of the Myosuit. (a) The Myosuit is a textile-based wearable robot to support the lower limbs. It is comprised of a textile harness that houses two motors, control electronics, and a battery. Two artificial tendons are routed from the motors posteriorly over the hip joint and anteriorly over the knee joint. Low-weight orthoses are placed on the user’s lower limbs to route and anchor the tendons. (b) The Myosuit supports the weight-bearing phase of walking. Here the mean and standard deviation of the forces measured during the experimental protocol and averaged across all participants and conditions are shown. The assisting forces are modulated based on the relative angle between the thigh and shank segments. The segment angles and walking events are estimated using a set of 9-axis IMUs mounted on the shank, thigh, and trunk segments of the user’s body.

When used for overground walking, the peak linear force of that can be applied through the tendons during the stance phase was 130 N. This force supports the extension of the knee and hip joints. The onset of the Myosuit’s support is right after detecting the user’s heel strike. The Myosuit provides no active assistance during the swing phase of the gait cycle. The switch between the stance and swing states happens at around 40–45% of the gait cycle–toward the end of the weight-bearing period of the stance phase (Figure 1b). The peak support force can be adjusted over 6 levels (0 to 5) between 0 N and 130 N (e.g., assistance level 3/5 means 60% of the peak 130 N force is available during the active support phase).

The Myosuit was donned on the participants according to its user manual. More details on the architecture of the device can be found in prior literature (Haufe et al., Reference Haufe, Schmidt, Duarte, Wolf, Riener and Xiloyannis2020).

2.4. Experimental protocol

Each participant completed three experimental blocks in a single session. For the experiment, participants walked on a split-belt treadmill (V-Gait Dual Belt, Motekforce Link, Netherlands) while wearing the Myosuit (see Figure 2). The session lasted approximately 90 min, including the time for donning and familiarization of the Myosuit.

Figure 2. Graphical representation of the study design. The participants were asked to walk at three levels of Myosuit assistance. For each of these levels, the participants walked in transparency mode at 0.8, and 1.3 m/s with Myosuit assistance turned on. In between each of these dynamic conditions, a static force ramping experiment was performed. For that, the participants were asked to stand still and a target force of 130 N was applied twice. The overall duration of the experiment was approximately 90 min, including the time for Myosuit donning and familiarization.

In each experimental condition, participants first walked for 3 min in a “zero-force” (i.e., transparent) condition. Here, the Myosuit was set to simply modulate the cable length such that the tissue compliance, limb configuration, and joint angular velocity were compensated for. After walking for 3 min, the participants were asked to stand still and a constant force of 130 N was applied by the Myosuit twice following a ramp input, for a total duration of 1 min. Participants then walked for 3 min at a speed of 0.8 m/s (constant speed controlled by the treadmill) with the Myosuit’s assistance turned on. Subsequently, the participants were asked to stand still and the constant force of 130 N was again applied twice for a total duration of 1 min. Finally, the participants walked for 3 min at a speed of 1.3 m/s (constant speed controlled by the treadmill) with the Myosuit’s assistance turned on. The assistance level was increased between the experimental blocks from levels 1 (maximum assistance 25 N) to 3 (maximum assistance 75 N) and 5 (maximum assistance 130 N).

2.5. Data acquisition

The kinematics of the right leg of the human limb segments and robot braces were measured using a camera-based motion capture system. For the human limb segments, two clouds of markers were placed directly on the soft tissue of the participants’ thigh (four markers) and shank (five markers). For the robot, two clouds of four markers were placed on the thigh and shank parts of the knee orthosis. Whenever possible, the markers were placed in an orthogonal configuration as suggested by Söderkvist and Wedin (Reference Söderkvist and Wedin1993). To minimize the risk of marker occlusion by the robot’s components, some markers were raised from their base using 3D-printed pillars. The markers were placed only on the right side because of the setup symmetry. We focus our analysis on the thigh and shank segments only because these are the main segments of interest for Myosuit’s control algorithm.

To assist in the post-processing, seven additional markers were tracked (four on the motor-driving unit, two on the left and right acromion, and one on the C7 vertebrae). The total marker set during the experiment consisted of 25 markers (see Figure 3a,b).

Figure 3. Marker placements from the front (a) and rear (b). Clouds of four and five markers were placed on the participant’s thigh and shank, respectively (highlighted in green). Clouds of four markers were placed on the thigh and shank components of the Myosuit (highlighted in orange). The choice of marker cloud sizes was driven by the initial sensitivity study where the chance of occlusion, marker loss, and marker stability were analysed. Additionally, markers were placed on the motor driving unit, left and right acromion, and the c7 vertebrae (highlighted in blue). (c) Angle convention for the shank and thigh segments in sagittal plane. The thigh angle (here $ {\gamma}_t $ ) is measured between the biological thigh and a vertical line passing through the knee joint’s centerline, with positive angles measured in the counter-clockwise direction. The shank angle (here $ {\gamma}_s $ ) is measured between the biological shank and the vertical line passing through the ankle joint’s centerline, with positive angles measured in the counter-clockwise direction. This angular convention was chosen as it matched the one used by the Myosuit controller.

The tension on the right tendon of the robot was measured with a load-cell (Miniature S-Beam FSH04416, Futek Advanced Sensor Technology, USA) placed proximally at the output of the motor-driving unit. For that, upon leaving the motor-gearbox-pulley assembly, the tendon was routed over a miniature pulley mounted on top of the S-Beam load-cell. The load-cell signals were used only in the data post-processing to confirm that the system was functioning appropriately (i.e., applying the forces as expected). Considering the limited scope of the load-cell’s purpose and the negligible friction between the tendon and the pulley mechanism, a uni-axial load-cell was used.

The position of the markers was recorded at 100 Hz using an array of 10 cameras (Bonita B10, VICON, UK). The sensor signals measured by the Myosuit were logged at 100 Hz. Table 1 lists all the signals logged by the Myosuit.

2.6. Data processing

The data from the motion capture and the Myosuit were synchronized using an external trigger signal. The data were then interpolated to the same time axis for alignment. The resultant time series were split into gait cycles based on the stance and swing detection algorithm of the Myosuit. The data of the motion capture markers were first processed through the Vicon Nexus software to label each marker and correct the gaps in the measured trajectories. For each experiment, the first 5 seconds (500 frames) of the static condition were averaged to calculate the reference marker cloud:

(6) $$ {\mathbf{p}}_{ref}=\frac{1}{500}\sum \limits_{n=1}^{500}{p}_n, $$

where $ p $ and $ {p}_{ref} $ are $ 3 xn $ matrices of n marker points.

The rigid best-fit transformations from the reference marker cloud to each recorded frame were then calculated following the approach described by Sorkine-Hornung and Rabinovich (Reference Sorkine-Hornung and Rabinovich2017) with identity weight matrix. For that, we first define the rotation and translation transformation problem in least-squares form as

(7) $$ \sum \limits_{i=1}^n{\left\Vert R{\mathbf{p}}_{ref_i}+\mathbf{t}-{\mathbf{q}}_i\right\Vert}^2, $$

where $ R $ is the $ 3x3 $ orthogonal matrix representing the cloud rotation, $ t $ is the cloud translation vector, and $ {q}_i $ represents the individual markers of a particular point cloud frame. The calculation of the rotation matrix can be decoupled from the calculation of the translation by assuming (temporarily) the latter to be zero. We can then define matrices $ A $ and $ B $ as $ A=\left[{p}_1-\overline{p}\dots {p}_n-\overline{p}\right] $ and $ B=\left[{q}_1-\overline{q}\dots {q}_n-\overline{q}\right] $ , where

(8) $$ \overline{\mathbf{p}}=\frac{1}{n}\sum \limits_{i=1}^n{\mathbf{p}}_i\hskip1em \mathrm{and}\hskip1em \overline{\mathbf{q}}=\frac{1}{n}\sum \limits_{i=1}^n{\mathbf{q}}_i $$

and their “covariance” matrix as

(9) $$ M={BA}^T. $$

The singular value decomposition of the M matrix is given by

(10) $$ SVD(M)=U\Sigma V. $$

Finally, the rotation matrix can be calculated as

(11) $$ R=U\left[\begin{array}{ccc}1& 0& 0\\ {}0& 1& 0\\ {}0& 0& \mathit{\det}\left({UV}^T\right)\end{array}\right]{V}^T $$

and substituted into (7) to find the translation as

(12) $$ \mathbf{t}=\overline{\mathbf{q}}-R\overline{\mathbf{p}}. $$

A local coordinate system was assigned to every reconstructed marker set. The vectors in this local coordinate system were used to calculate the angles of the segments in the sagittal plane relative to a vertical (see Figure 3c).

2.7. Pipeline for compliance error compensation

In this section we introduce the pipeline to create the model to compensate for compliance errors in segment angle estimation (see Figure 4) with the following steps:

1. 1. Combine the robot segment angles ( $ {y}_{robot} $ ) with the robot-derived data (see Table 1 for more details) to create a feature vector.

2. 2. Set the motion capture data of the human segment angles ( $ {y}_{human} $ ) as the target vector.

3. 3. Use a gradient boosting algorithm (XGBoost) to fit the regression model to the aforementioned data.

4. 4. Use the trained regression model, together with the new feature vector, to calculate the estimated human segment angles ( $ {\hat{y}}_{human} $ ).

Figure 4. Schematic representation of the implemented pipeline for compliance error compensation. Three main sources of data are used: motion capture of human segments (triangles, $ {y}_{human} $ ) and robot segments (circles, $ {y}_{robot} $ ) and robot-sensor derived data (rhombus). The latter and the $ {y}_{robot} $ are used to construct the feature vector for the gradient boosting algorithm. The $ {y}_{human} $ variable is used as the target variable. The data from the eight study participants are then arranged such that six participants are part of the training set, one is used for the validation set, and one for the model testing set. This splitting strategy was repeated eight times to show the model generalizability across the data of all of the study participants.

Ultimately, the aim of the model is to reconstruct $ {y}_{human} $ using only inputs from the robot. We limited the set of features fed to the algorithm to those that would be commonly available on a lower-limb wearable robot. We grouped these features into the following three categories: (1) robot performance data (e.g., applied motor torque or current), (2) state data (e.g., stance or swing state of the leg), and (3) human motion data (e.g., encoder counts or IMU data). We chose to not use windowing functions and only use the real-time signal data to ensure that no delay is introduced to the robot controllers when this model is used. The list of features, and their group assignments, that were used to train the regression model in this project are shown in Table 1.

We assessed the performance of the algorithm by looking at two key metrics: (1) root-mean-squared (RMS) compliance error and (2) peak angular compliance error, averaged over all gait cycles for a particular study participant.

To test the model’s generalizability, we split the data sets from the eight participants as follows:

• • data from six participants to train the model,

• • data from one participant to validate the model, and

• • data from one participant to test the model.

The aim of this configuration was to ensure that none of the data of the participants used in the testing phase were part of either the training or validation data sets. This splitting strategy was repeated eight times, always leaving one participant’s data for validation and another participant’s data for testing (Figure 4). The training of the algorithm was done using the XGBoost module in Python 3.8. Following the preliminary analysis and using the values derived by Molinaro et al. (Reference Molinaro, Kang, Camargo and Young2020), the following parameters were used as shown in Table 2.

Table 2. List of tuned XGBoost hyperparameters used in the segment estimation algorithm

We chose to train separate models for the thigh and shank segments since each segment was expected to experience different compliance effects. This is due to factors like (1) interface stiffness, (2) force application areas, and (3) transmitted forces and their losses, among others. Because the implemented pipeline matches exactly for both thigh and shank, we focused our efforts on the segment with the larger error between the robot and the human segment angles.

2.8. Influence of force and speed on compliance

We performed statistical analysis to assess the correlation between the average RMS error and the force and speed parameters. For that, the conditional mean of the mean RMS error was computed with a linear predictor model taking into account speed, force, and their interaction. A random intercept variable in the form of subject id was added to the model to decouple the subject dependency. The implementation of the model was performed using lmer (Linear Mixed-Effects Models) package for R programming language.