Next Article in Journal
Learning Representative Features by Deep Attention Network for 3D Point Cloud Registration
Next Article in Special Issue
Spatial Calibration of Humanoid Robot Flexible Tactile Skin for Human–Robot Interaction
Previous Article in Journal
Pointing Error Correction for a Moving-Platform Electro-Optical Telescope Using an Optimized Parameter Model
Previous Article in Special Issue
Building a Low-Cost Wireless Biofeedback Solution: Applying Design Science Research Methodology
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

A Trade-Off between Complexity and Interaction Quality for Upper Limb Exoskeleton Interfaces

1
Université Paris-Saclay, CIAMS, 91405 Orsay, France
2
CIAMS, Université d’Orléans, 45100 Orléans, France
3
LURPA, ENS Paris-Saclay, Université Paris-Saclay, 91190 Gif-sur-Yvette, France
*
Author to whom correspondence should be addressed.
Sensors 2023, 23(8), 4122; https://doi.org/10.3390/s23084122
Submission received: 29 March 2023 / Revised: 14 April 2023 / Accepted: 18 April 2023 / Published: 20 April 2023

Abstract

:
Exoskeletons are among the most promising devices dedicated to assisting human movement during reeducation protocols and preventing musculoskeletal disorders at work. However, their potential is currently limited, partially because of a fundamental contradiction impacting their design. Indeed, increasing the interaction quality often requires the inclusion of passive degrees of freedom in the design of human-exoskeleton interfaces, which increases the exoskeleton’s inertia and complexity. Thus, its control also becomes more complex, and unwanted interaction efforts can become important. In the present paper, we investigate the influence of two passive rotations in the forearm interface on sagittal plane reaching movements while keeping the arm interface unchanged (i.e., without passive degrees of freedom). Such a proposal represents a possible compromise between conflicting design constraints. The in-depth investigations carried out here in terms of interaction efforts, kinematics, electromyographic signals, and subjective feedback of participants all underscored the benefits of such a design. Therefore, the proposed compromise appears to be suitable for rehabilitation sessions, specific tasks at work, and future investigations into human movement using exoskeletons.

1. Introduction

Active exoskeletons are considered to be potentially very beneficial for the future of rehabilitation protocols [1,2,3,4] and work-related musculoskeletal disorder (MSD) prevention [5,6,7,8]. A well-known limitation of such systems is the unavoidable joint misalignment (JM) between the human and the exoskeleton [9]. This leads to a kinematic incompatibility, also called hyperstaticity, as supported by both geometric models and the theory of mechanism-based models [10,11,12,13]. Such kinematic incompatibility can result in an increase in human-exoskeleton interaction efforts [12,14,15] and significant discomfort [15]. Hence, designing exoskeletons that reduce or compensate for this kinematic incompatibility is a key factor for their future widespread implementation.
Two main categories of solutions have been identified in the literature to solve these concerns [16]. In the first category, the solution consists of designing non-anthropomorphic exoskeletons. In the second category, the solution consists of compensating the JM using adjustable anthropomorphic exoskeletons and passive degrees of freedom at the human-exoskeleton interfaces level. On the one hand, non-anthropomorphic designs refer to exoskeletons that violate their most widespread definition [17]: “an exoskeleton is an external structural mechanism with joints and links corresponding to those of the human body”. For example, recent works based on a modular synthesis approach have led to the introduction of two four-bar mechanisms in series to design an upper limb exoskeleton [18,19]. Overall, numerous designs have been proposed for the main joints of both the upper [20,21,22] and lower [23,24,25,26,27] human limbs. On the other hand, anthropomorphic designs comply with the previous definition and must incorporate JM compensation methods. From that perspective, the first possibility is to design exoskeletons with adjustable limbs [28,29,30,31,32]. However, such features must be incorporated from the beginning of the design process because they determine the mechanical structure of the exoskeleton. A second possibility, which is the solution adopted in the present paper, is to design self-aligning human-exoskeleton interfaces. Such interfaces have been successfully added to upper-limb exoskeletons to improve the interaction quality [12,13,15]. The same positive results were obtained for lower-limb exoskeletons (see [33] for an example on the knee joint).
Importantly, all of these solutions are known to increase the exoskeleton’s mechanical complexity and inertia, which can result in unwanted interaction efforts and a complex controller design [9,14,16]. In the present paper, we thoroughly investigate the influence of two passive rotations included in the forearm interface of an upper-limb exoskeleton during shoulder and elbow reaching movements performed in a sagittal plane. Such a design has been shown to be highly beneficial during elbow movements performed in a sagittal plane with a transparent exoskeleton [15]. In such a framework, interaction efforts are minimized [34,35,36] to properly isolate the effects of the tested interfaces. In the case of 2-degrees of freedom reaching movements in a sagittal plane, this design constitutes a new trade-off between complexity and interaction quality. Indeed, the absence of passive joints in the arm interface allows for limiting the added inertia and complexity [37]. Furthermore, the passive rotations included in the forearm interface could have global and beneficial effects for both human effort and comfort, thereby limiting the alterations of natural human movements. Therefore, the aim of this study is to analyze the effects of two passive rotations included in the forearm interface of an upper-limb exoskeleton on the quality of the interaction during reaching movements performed in a sagittal plane.
The remainder of the present paper is organized as follows: in Section 2, the materials and measurements, the exoskeleton control, and the evaluation task implemented to test the effects of the different interfaces are described in detail. Furthermore, in Section 3, the evaluation results are described in terms of interaction efforts, kinematics, and EMG signals to provide an overview of the effects of the different interfaces. Finally, these results are discussed in Section 4.

2. Materials and Methods

2.1. Participants and Materials

2.1.1. Participants

A total of N = 19 right-handed, healthy young adults (7 females) were involved in the experiment. The anthropometric characteristics are the following: age 24 ± 2 years old, weight 66.7 ± 11   kg , and height 1.73 ± 0.07   m . All participants provided their written informed consent before performing the experiment, as required by the Helsinki Declaration.

2.1.2. Kinematic Recordings

Human movement kinematics were recorded by means of an optoelectronic system (10 Oqus 500 + cameras, sample rate 179 Hz ; Qualisys, Gothenburg, Sweden). Eight 10 mm reflective markers were placed on the participants to track their movements and provide a satisfying convergence of the labeling algorithm (Qualisys Track Manager, Qualisys, Gothenburg, Sweden): solar plexus, sternoclavicular joint, acromion, epicondyle, and epitrochlea of the elbow, middle of the forearm, styloid process of the radius (due to the human-exoskeleton configuration, the styloid process of the ulna was not accessible) and the base of the index finger. A 3 mm reflective marker was placed at the tip of the participant’s index. We used the recorded 3-dimensional positions of this last marker to describe the human movement kinematics.

2.1.3. EMG Recordings

The human muscle activity was quantified by means of surface EMG (Wave Plus wireless EMG system, sample rate 2 kHz , Cometa, Bareggio, Italy). Six muscles of the forearm, arm, and shoulder, involved in sagittal plane reaching movements, were recorded: brachioradialis (elbow flexor), biceps brachii (elbow and shoulder flexor), triceps brachii lateral head (elbow extensor), long head (elbow and shoulder extensor), anterior deltoid (shoulder flexor), and posterior deltoid (shoulder extensor). Before placing the electrodes, the participants were locally shaved and a hydroalcoholic solution was applied. The electrode positioning followed the SENIAM recommendations [38].

2.1.4. Ergonomic Feedback Questionnaire

The feedback of participants, with regard to the different conditions performed with the exoskeleton, was collected through the following semi-directed questionnaire, including negative and positive questions, inspired by previous studies [15,39,40]:
  • Comfort:
    -
    Did you feel any friction or irritation during the movement? (negative)
    -
    Did you experience any pressure points at the level of the interfaces? (negative)
    -
    Rate the general comfort of movement with the current interfaces. (positive)
  • Movement ability:
    -
    Rate the mobility with the current interfaces. (positive)
    -
    Did you feel any constraint on your motion range? (negative)
  • Accuracy:
    -
    Was it easy to reach the targets? (positive)
For each of these six items, participants gave a grade between 1 (if they completely agreed with a negative item or completely disagreed with a positive item) and 5 (if they completely agreed with a positive item or completely disagreed with a negative item). The grading scale proposed to participants was as follows: 1 and 5, completely agree or disagree; 2 and 4, agree or disagree; and 3, neither agree nor disagree.

2.1.5. ABLE Exoskeleton and Tested Interfaces

The present experiments were conducted using an ABLE active upper limb exoskeleton, known for its transmission system that provides high back-drivability and potential transparency [29,41,42]. This exoskeleton includes three active degrees of freedom reproducing the main rotations of the shoulder (i.e., internal/external, abduction/adduction, and flexion/extension), and one active degree of freedom reproducing the main rotation of the elbow (i.e., flexion/extension). The human was connected to the exoskeleton at the level of the forearm and the level of the arm (see Figure 1). The exoskeleton was modified to include two 6-axe force/torque (FT) sensors (1010 digital FT, ATI, sample rate 1   kHz ) placed at the level of the human-exoskeleton interfaces to quantify and minimize (through the exoskeleton control) the interaction efforts.
Previous works conducted on this exoskeleton have led to the inclusion of several passive degrees of freedom at the level of the forearm interface to improve the quality of the interaction during elbow flexion/extension in a sagittal plane [15]. In particular, a passive translation along the forearm of the exoskeleton (i.e., x FA , see Figure 1A) and two passive rotations preventing the apparition of flexion torques during elbow movements (i.e., around y FA and z FA , see Figure 1A) were included. Furthermore, two thermoformed orthoses were designed to increase the human-exoskeleton interaction area both at the forearm and arm levels, which has been suggested to improve the comfort reported by users [15]. The forearm orthosis was designed to block the human wrist rotations.
In the present paper, we tested the effect of these two passive rotations during reaching movements performed in the sagittal plane, where the degree of hyperstaticity was modified by the arm interface (which does not include passive degrees of freedom). The first two active rotations of the exoskeleton (i.e., shoulder internal/external rotation and abduction/adduction) were mechanically blocked using dedicated devices to ensure that movements were performed in a sagittal plane. Consequently, two conditions were tested in the current experiment: a condition without passive degrees of freedom at the forearm level (noRot) and a condition with these two degrees of freedom (Rot). The rotations were mechanically blocked using dedicated screws during the noRot condition.

2.2. Evaluation Task

The task was composed of reaching movements in a sagittal plane toward two semi-spherical 3 cm targets. Reaching tasks in a sagittal plane have been widely studied in the rehabilitation literature, and exoskeletons may be of potential help for this kind of application [43,44,45,46]. Before movement onset, participants were asked to remain static in a reference position, i.e., with the arm remaining vertical and the forearm horizontal. Then, one of the two targets was lit for 4 ± 0.5 s , which allowed the participant to perform the movement toward the target at a comfortable and self-selected pace without being able to anticipate. After this duration, the target was turned off and the participant was asked to return to the reference position. A total of 30 reaching movements were performed. Half of these movements were performed toward a target higher than the reference position (referred to as T t o p , aligned 30 ° above the reference position, as in Figure 1B) and the other half toward a target lower than the reference position (referred to as T b o t , aligned 30 ° below the reference position). This allowed assessing possible different constraints applied by the exoskeleton at the extremities of the large workspace. The sequence of reaching movements was pseudo-random.
Three blocks were performed: one with each of the two tested configurations of the forearm’s human-exoskeleton interface (i.e., noRot and Rot conditions) and one outside the exoskeleton (referred to as noExo), which served as the baseline for comparisons. To avoid potential wrist rotations and remain comparable between conditions in terms of kinematics, participants wore a light splint during the noExo block.
The exoskeleton was controlled in a transparent mode, which means that interaction efforts were minimized to minimize the possible alterations of human movements [34,35]. The controller was based on the identification of the exoskeleton’s dynamics, performed following previous procedures [36], coupled to a force feedback minimization [47]. More precisely, the controller was structured as detailed in Figure 2, which corresponds to the following equation,
τ r = K p L f e K i t 0 t L f e d t + τ ^ m
where τ r is a 2 × 1 vector representing the joint torques applied by the controller at the shoulder and elbow levels, respectively (the motor current is I r = K t τ r , where K t is the torque constant of the motors, which in the present case is a scalar because both motors are the same), K p and K i are 2 × 2 diagonal matrices corresponding to proportional and integral control gains, respectively, and L is a 2 × 2 diagonal matrix corresponding to the lever arms. The controlled forces are represented by f e = F z , A , F z , FA , which is the vector of normal forces applied to the human at the arm and forearm levels, respectively (see Figure 1A for the definition of the normal axes). Finally, the estimated motor torque τ ^ m , based on the identification of the exoskeleton dynamics [36], compensated for the gravity and friction torques of the exoskeleton.

2.3. Data Processing

2.3.1. Kinematics

The successive positions of the index reflective marker were low-pass filtered (Butterworth, fifth order, 5 Hz cut-off frequency) before numerical differentiation, which allowed for the computation of the velocity and acceleration profiles. Movement onset and end were defined with a threshold fixed at 5 % of the peak velocity [36,48,49,50]. The movement duration ( MD ) and amplitude were defined as the elapsed time and the traveled distance between these bounds, respectively. The average velocity ( aV ) was computed as the ratio between the amplitude and MD the mean acceleration during the acceleration phase was computed as the ratio between the peak velocity and the time elapsed between the movement onset and the peak velocity. Such early acceleration parameters have been shown to be impacted by additional inertia and unwanted interaction efforts at the interface level [15,51].

2.3.2. EMG

EMG data were band-pass filtered (Butterworth, fourth order, [ 20 ; 450 ] Hz cut-off frequencies) before being centered and rectified [52]. The root mean square (RMS) of the signal was then computed between the movement onset and end, based on the kinematics segmentation. This parameter allowed quantifying the average effort provided by a participant over the movement period. The computed RMS was averaged according to the functional muscle groups previously defined (i.e., shoulder or elbow flexors/extensors, see Section 2.1.3). The RMS of one muscle was computed as follows,
RMS = 1 N i = 1 N EMG i 2
where N is the number of samples and EMG i is the ith sample.

2.3.3. Interaction Efforts

Interaction efforts measured at the level of the human-exoskeleton interfaces were low-pass filtered (Butterworth, fifth order, 5 Hz cut-off frequency). The absolute maximum and absolute average values recorded for each component were used as descriptors of the interaction efforts. The maximum value provided information regarding the risk of inducing pain at the interface level [15,53,54,55], while the average value provided information regarding the long-term acceptability of the device [34,53].

2.4. Statistical Analysis

The possible main effects of the tested condition (i.e., noExo noRot and Rot) on the interaction were first assessed by one-way repeated measures ANOVA. Whenever a potential sphericity issue was detected (i.e., ϵ < 0.75 ) a Greenhouse–Geisser correction was applied. The significance level of the ANOVA was set at p < 0.05 . Whenever a significant difference was reported, the η 2 was provided to illustrate the effect size.
In the case of the main effect of the condition on a parameter, pairwise t-tests were performed between conditions for each target separately, which allowed assessing potential non-homogeneous effects across the workspace. The significance level of these comparisons was set at p < 0.05 . Whenever a significant difference was reported, Cohen’s D was provided to illustrate the effect size.
All statistical analyses were performed using custom Python 3.8 scripts and the Pingouin package [56].

3. Results

In this section, the effects of passive rotations included in the forearm human-exoskeleton interface are extensively assessed. First, the interaction efforts at the arm and forearm levels are described and compared between the noRot and Rot conditions (Section 3.1). Second, the impacts of both conditions on human kinematics are assessed by comparing these two conditions to each other and to natural human movements recorded in the noExo condition (Section 3.2). Third, the same types of comparisons are detailed on EMG signals to assess the level of human muscle solicitation (Section 3.3). Finally, the subjective reports of participants are detailed for both the noRot and Rot conditions (Section 3.4).

3.1. Effects on Interaction Efforts

The interaction efforts were assessed by computing the absolute maximum and absolute average values of each of the interaction forces and torque components. This analysis was performed for both the arm and forearm FT sensors and is summarized in Figure 3.
Effects of the tested condition: As reported in Figure 3A, the main effect of the condition was found for the z component of the arm interaction force. Despite the important effect size returned by the ANOVA ( η 2 > 0.2 ), pairwise comparisons were not significant. To summarize, there was a significant reduction in the Rot condition for the z component of the arm interaction force, but not for the other components. Furthermore, the Rot condition did not induce any significant change in the arm interaction torques (see Figure 3C).
As reported in Figure 3B, the main effects of the condition were found for both the maximum and average values of the y and z components of the interaction forces. The pairwise comparisons performed for the y and z components highlighted a reduction of the interaction forces with the Rot condition, when compared to the noRot condition, for both targets (in all cases: p < 0.011 , D > 0.87 ). The Rot condition induced overall lower interaction forces at the forearm level when compared to the noRot condition.
As reported in Figure 3D, the main effect of the condition was found on the y and z components of the interaction torques. The pairwise comparisons performed for the y and z components highlighted a reduction of the interaction torques with the Rot condition (when compared to the noRot condition) for both targets (in all cases: p < 3 . 10 4 , D > 1.32 ). To summarize, the y and z components of the interaction torques were clearly reduced in the Rot condition when compared to the noRot condition.
Effects of the aimed target: The ANOVAs performed on the arm interaction torques returned the main effects of the target in the y and z components. In particular, these components were significantly smaller for T b o t than for T t o p , both in terms of maximum and average values (in all cases: F 1 , 18 > 10.16 , p < 0.0051 , η 2 > 0.36 ), which was confirmed by pairwise comparisons (in all cases: p < 0.0055 , D > 0.65 ). To summarize, the arm interaction torques were higher when aiming at T t o p when compared to those reported when aiming at T b o t . Furthermore, there was no effect of the aimed target on the arm interaction force components.
The main effect of the target location was found in the x and y components of the forearm interaction forces, both in terms of maximum and average values (in all cases, i.e., F 1 , 18 > 20 , p < 3 . 10 4 , η 2 > 0.52 ). Subsequent pairwise comparisons showed that the x force component was higher for T b o t than for T t o p both in terms of average and maximum values (in both cases: p < 0.009 , D > 0.61 ). The target location modified the x component of the interaction force, with T b o t inducing higher efforts than T t o p in this component. Furthermore, the target location did not have any significant effect on the forearm interaction torques.

3.2. Effects on Human Movement Kinematics

Kinematics were qualitatively assessed by means of their temporal evolution, as summarized in Figure 4. Qualitatively, the average trajectories provided in Figure 4A mainly tended to be shorter for the T b o t target in the noRot condition when compared to the trajectories performed in the noExo and Rot conditions. Furthermore, the velocity profiles were, overall, bell-shaped for all conditions but the velocities tended to be lower in the noRot and Rot conditions when compared to the noExo condition (see Figure 4B), which was also true for the accelerations (see Figure 4C). Finally, the acceleration profiles reported in the noRot condition were noisy, particularly for movements toward T b o t .
To quantify human movement kinematics alterations, several descriptors were computed. They are summarized in Table 1.
Movement duration: ( MD ) The conducted pairwise comparisons exhibited an overall significantly higher MD in the noRot and Rot conditions than in the noExo condition (in both cases: p < 0.006 , D > 0.64 ). Target-based comparisons revealed a higher MD in the Rot condition than in the noExo condition for T t o p ( p = 0.04 , D = 0.69 ) and a higher MD in the noRot condition than in the noExo condition for T b o t ( p = 0.02 , D = 0.82 ). To summarize, both the noRot and Rot conditions induced higher MD than the noExo condition, the noRot condition was worse for T b o t and the Rot condition was slightly worse for T t o p .
Amplitude: The conducted pairwise comparisons highlighted that the movement amplitude was smaller in the noRot condition than in the noExo condition for T b o t ( p = 0.016 , D = 1.11 ), which was the only significant effect. To summarize, the noRot condition impacted movement amplitude significantly and non-homogeneously (with regard to the workspace) when compared to the noExo condition.
Average velocity ( aV ): The conducted pairwise comparisons exhibited an overall lower aV in the noRot and Rot conditions than in the noExo condition (in both cases: p < 0.003 , D > 0.7 ). Target-based comparisons revealed a lower aV in the noRot and Rot conditions than in the noExo condition for T b o t (in both cases: p < 0.016 , D > 0.81 ). To summarize, both conditions performed inside the exoskeleton tended to reduce aV ; the effect was more pronounced for T b o t than for T t o p . Finally, the noRot condition induced a higher impact on aV than the Rot condition for T b o t .
Mean acceleration ( mA ): The conducted pairwise comparisons exhibited an overall lower mA in the noRot and Rot conditions than in the noExo condition (in both cases: p < 0.003 , D > 0.69 ). Target-based comparisons revealed a lower mA in the noRot and Rot conditions than in the noExo condition for T b o t (in both cases: p < 0.04 , D > 0.68 ) and a lower mA in the Rot condition than in the noExo condition for T t o p ( p = 0.043 , D = 0.68 ). To summarize, both conditions performed inside the exoskeleton tended to reduce mA ; the effect was more pronounced for T b o t than for T t o p . Finally, the noRot condition induced a higher impact on mA than the Rot condition for T b o t , with the opposite for T t o p .

3.3. Effects on Human Muscle Activities

We quantified the average muscle effort of participants in each of the tested conditions by computing the average RMS of each of the functional muscle groups previously defined: shoulder flexors/extensors and elbow flexors/extensors (see Section 2.1.3 for details regarding the group composition). The results of these analyses are summarized in Figure 5.
Shoulder flexors: The conducted pairwise comparisons exhibited an overall higher RMS in the noRot condition than in the noExo and Rot conditions (in both cases: p < 2 . 10 4 , D > 0.99 ). Target-based comparisons revealed a higher RMS in the noRot condition than in the noExo and Rot conditions for T t o p (in both cases: p < 0.01 , D > 0.87 ). The noRot condition also induced a higher RMS of shoulder flexors than the noExo and Rot conditions for T b o t (in both cases: p < 0.002 , D > 1.12 ). To summarize, the noRot condition clearly induced higher levels of shoulder flexor activity when compared to the noExo and Rot conditions, as verified independently of the target. Furthermore, the Rot condition did not induce significantly higher levels of shoulder flexor activity than the noExo condition.
Shoulder extensors: No main effect of the tested condition was found on shoulder extensors.
Elbow flexors: The conducted pairwise comparisons exhibited an overall higher RMS in the noRot condition than in the noExo and Rot conditions (in both cases: p < 7 . 10 6 , D > 1.11 ). Target-based comparisons revealed a higher RMS in the noRot condition than in the noExo and Rot conditions for T t o p (in both cases: p < 4 . 10 3 , D > 1.01 ). The noRot condition also induced a higher RMS of elbow flexors than the noExo and Rot conditions for T b o t (in both cases: p < 7 . 10 4 , D > 1.2 ). To summarize, the noRot condition induced higher levels of elbow flexor activity when compared to the noExo and Rot conditions, which was verified for both targets. Furthermore, the Rot condition did not induce significantly higher levels of elbow flexor activity than the noExo condition.
Elbow extensors: The conducted pairwise comparisons exhibited an overall higher RMS in the noRot condition than in the noExo and Rot conditions (in both cases: p < 0.033 , D > 0.49 ). To summarize, the noRot condition induced higher levels of elbow extensor activity than the noExo and Rot conditions.

3.4. Ergonomic Feedback

The questionnaire submitted to participants was designed to evaluate the overall comfort, movement ability, and accuracy through six questions (see Section 2.1.4 for the detailed questions). The results of this evaluation are summarized in Figure 6.
Overall, the grades given by participants were higher for the Rot condition than for the noRot condition, which suggested a better acceptability of the device when including passive rotations. Pairwise comparisons were performed for each of the subjective criterion to confirm or infirm the observed trends. These pairwise comparisons confirmed that the Rot condition induced lower friction/irritation ( p = 0.01 , D = 0.94 ), lower pressure ( p = 0.043 , D = 0.72 ), higher overall comfort ( p = 0.004 , D = 1.06 ), higher mobility ( p = 10 5 , D = 1.8 ), and a higher motion range ( p = 2 . 10 6 , D = 1.99 ) when compared to the noRot condition. Finally, the participants did not report a significant difference regarding their subjective movement accuracy between the noRot and Rot conditions.

4. Discussion

In the present paper, we tested the influence of two passive rotations included at the forearm interface on the quality of human-exoskeleton interactions during reaching movements in a sagittal plane. Although the inclusion of passive degrees of freedom has been shown to be an important factor to improve such interactions [12,15], the design of human-exoskeleton physical interfaces has received less attention than other developments, such as control methods or transmission designs. However, it has been previously shown that including such passive degrees of freedom in the exoskeleton design increases its inertia and mechanical complexity [9]. Hence, the robot control becomes more complicated, and unwanted interaction forces, due to an incomplete compensation of the dynamics (in particular, of the inertia), can be more important. Here, we tested whether a forearm interface including several passive degrees of freedom could be an acceptable compromise between improving the interaction quality and providing a simple mechanical design with limited additional inertia (i.e., limited due to the absence of passive degrees of freedom in the arm interface). Following previous evaluation methodologies [15,34], the human-exoskeleton interaction was quantified through a set of objective (i.e., interaction forces, kinematics, and EMGs), and subjective (i.e., questionnaires) metrics.
First, an overall reduction of the interaction forces and torques was observed with the Rot condition, as in other works [12,15]. In particular, the inclusion of two passive rotations drastically decreased both the interaction forces and torques at the level of the forearm interface. Interestingly, this reduction of interaction forces, in particular along y FA , which is orthogonal to the movement plane (i.e., it cannot be a motive in this task), suggests a reduction in the mobility constraints applied to the participants. However, the corresponding reduction was small at the level of the arm interface, which does not include passive degrees of freedom. Finally, the last important observation was the non-homogeneous magnitude of interaction efforts across the tested workspace. Indeed, overall, the interaction torques were higher during movements aimed at T t o p when compared to those aimed at T b o t at the level of the arm interface, thereby exhibiting different constraints depending on the human pose. On the contrary, the interaction force along x FA , at the level of the forearm interface, was higher during movements aimed at the lower target T b o t than during those aimed at T t o p . This interaction force along x FA was not modified by the passive rotations, mainly due to the weight of the sliding FT sensor embedded in the interface and to the weight of the passive slider joint, which generate different interaction efforts depending on the arm and forearm positions.
Second, the natural human kinematics were overall less impacted when including the passive rotations at the forearm level. Interestingly, the substantial reduction of the interaction efforts, which one might have expected to be reflected in the kinematics, was not as evident in these metrics. Overall, the reduction in aV was lower than 30 % , which is a common value reported in previous studies using an open-loop compensation of the exoskeleton’s weight [29,34,51]. This was probably due to the closed-loop interaction minimization efforts. Furthermore, the main differences between the noRot and Rot conditions were for the lower target T b o t . Hence, as for interaction efforts, human kinematics are differently affected depending on the target location in the workspace. These observations are consistent with joint misalignment (JM) being essentially a geometric problem, as predicted by the theory of mechanisms [12,13] and more specific geometric models [10,11].
Third, the muscle activity levels during movement (described by the RMS of the EMG signals) were higher overall in the noRot condition than in the Rot and noExo conditions. Moreover, the muscle efforts were comparable between the Rot and noExo conditions. Primarily, this result is strongly in favor of the introduction of passive degrees of freedom at the forearm interface as an acceptable compromise because it does not increase substantially the level of muscle effort in the task, whether it be for the elbow or shoulder muscles. Furthermore, it is an interesting observation when coupled with the limited effects reported on kinematics because of their potential implications. Indeed, recent works have shown that humans are prone to expending large amounts of energy to save time [57], which was also shown while interacting with an exoskeleton [58]. Such an energetic expenditure was as predicted by the minimum time-effort theory in the field of human motor control [59,60], which is probably due to a temporal discounting of the reward (here, achieving the task) associated with the movement [61,62]. Hence, it is possible that in the present work, as previously suggested during the evaluation of the transparency of the ABLE exoskeleton [51], participants compensated for a part of the interaction efforts to save time and reproduce acceptable trajectories in the task space by expending energy. Interestingly, the level of comfort has been pointed out as a factor influencing humans’ preferred MD [63]. However, in the present study, it seems that the level of comfort was sufficient to allow participants to save time by expending more energy. Indeed, they could also have chosen to minimize their energetic expenditure by moving slower in the noRot condition than in the Rot condition, which was not clearly the case.
In the present experiment, participants reported an overall higher level of comfort and lower movement constraints with the Rot condition compared to the noRot condition. Interestingly, the average grades attributed to the noRot condition by the participants were around 3, which corresponds to “neither agree nor disagree”, in terms of general comfort and mobility. Such grades (and it is, thus, equally true for those attributed to the Rot condition) seem to be compatible with the application of higher levels of effort to save time. However, such a strategy might become detrimental to the skin at the level of the interface [55] and to the acceptability during long-term utilization of the device. Finally, it is worth mentioning that no effect of the condition was found on subjective accuracy, which was always well-graded. Consequently, the effects reported on movement vigor (i.e., self-selected velocity [60,64]) were probably not related to the effects of accuracy constraints or to a speed-accuracy trade-off, which are known to have impacts [65,66,67]. The main limit of the present work lies in the relatively high interaction efforts observed at the level of the arm interface. For extended applications, such interaction efforts could result in discomfort, skin issues and, eventually, rejection of the device by the user [55]. Furthermore, the effects of our interfaces would also need to be assessed during more complex movements to progress toward concrete applications. Nevertheless, it should be noted that shoulder and elbow sagittal plane movements are common types of movements in rehabilitation procedures [43,44,45,46], which are some of the main applications in active upper-limb exoskeletons.

5. Conclusions

Overall, it can be concluded that the proposed design, including passive rotations in the forearm interface, significantly improved the quality of the human-exoskeleton interaction when compared to common (i.e., fixed) human-exoskeleton interfaces. Such an interface design is a new compromise between the mechanical complexity and inertia of the device, as well as the interaction quality. Indeed, although this design did not allow for clearly reducing the interaction forces at the arm level, it implied limited additional inertia and was, overall, well-graded by the participants. Furthermore, it mainly introduces one large JM that can be efficiently identified following a simple procedure [50]. Finally, the proposed design seems to be suitable for clinical interventions or work tasks and for the burgeoning field of human movement studies involving exoskeletons [51,58,68]. In future works, the inclusion of passive degrees of freedom at the arm interface will be performed on the basis of the present study to further minimize unwanted interaction efforts while implementing a relatively simple design. The performances of this improved design will also need to be assessed with more complex controllers, for example, adaptive ones [69].

Author Contributions

Conceptualization, D.V., G.S., O.B., B.B. and N.V.; methodology, D.V., G.S. and N.V.; software, D.V.; validation, D.V.; formal analysis, D.V.; investigation, D.V. and G.S.; resources, O.B., B.B. and N.V.; data curation, D.V.; writing—original draft preparation, D.V.; writing—review and editing, D.V., O.B., B.B. and N.V.; visualization, D.V.; supervision, O.B., B.B. and N.V.; project administration, N.V.; funding acquisition, O.B., B.B. and N.V. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the French National Agency for Research (ANR), grant number ANR-19-CE33-0009. The APC was funded by the French National Agency for Research (ANR), grant number ANR-19-CE33-0009.

Institutional Review Board Statement

The study was conducted in accordance with the Declaration of Helsinki, and approved by the Ethics Committee of the Université Paris-Saclay (protocol code CER-Paris-Saclay-2021-048, 2021).

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

All data reported in this paper will be shared by the corresponding author upon request. Any additional information required to reanalyze the data reported in this paper is available from the corresponding author upon request. All data have been totally anonymized.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript; or in the decision to publish the results.

References

  1. Pons, J.L. Rehabilitation exoskeletal robotics. IEEE Eng. Med. Biol. Mag. 2010, 29, 57–63. [Google Scholar] [CrossRef] [PubMed]
  2. Jarrassé, N.; Proietti, T.; Crocher, V.; Robertson, J.; Sahbani, A.; Morel, G.; Roby-Brami, A. Robotic exoskeletons: A perspective for the rehabilitation of arm coordination in stroke patients. Front. Hum. Neurosci. 2014, 8, 947. [Google Scholar] [CrossRef] [PubMed]
  3. Proietti, T.; Crocher, V.; Roby-Brami, A.; Jarrasse, N. Upper-Limb Robotic Exoskeletons for Neurorehabilitation: A Review on Control Strategies. IEEE Rev. Biomed. Eng. 2016, 9, 4–14. [Google Scholar] [CrossRef] [PubMed]
  4. Mehrholz, J.; Pollock, A.; Pohl, M.; Kugler, J.; Elsner, B. Systematic review with network meta-analysis of randomized controlled trials of robotic-assisted arm training for improving activities of daily living and upper limb function after stroke. J. Neuroeng. Rehabil. 2020, 17, 83. [Google Scholar] [CrossRef]
  5. Muramatsu, Y.; Kobayashi, H.; Sato, Y.; Jiaou, H.; Hashimoto, T.; Kobayashi, H. Quantitative performance analysis of exoskeleton augmenting devices—Muscle suit—For manual worker. Int. J. Autom. Technol. 2011, 5, 559–567. [Google Scholar] [CrossRef]
  6. Ajoudani, A.; Zanchettin, A.M.; Ivaldi, S.; Albu-Schäffer, A.; Kosuge, K.; Khatib, O. Progress and prospects of the human-robot collaboration. Auton. Robot. 2018, 42, 957–975. [Google Scholar] [CrossRef]
  7. de Looze, M.P.; Bosch, T.; Krause, F.; Stadler, K.S.; O’Sullivan, L.W. Exoskeletons for industrial application and their potential effects on physical work load. Ergonomics 2016, 59, 671–681. [Google Scholar] [CrossRef]
  8. Nussbaum, M.A.; Lowe, B.D.; de Looze, M.; Harris-Adamson, C.; Smets, M. An introduction to the special issue on occupational exoskeletons. IISE Trans. Occup. Ergon. Hum. Factors 2019, 7, 153–162. [Google Scholar] [CrossRef]
  9. Mallat, R.; Khalil, M.; Venture, G.; Bonnet, V.; Mohammed, S. Human-exoskeleton joint misalignment: A systematic review. In Proceedings of the IEEE 2019 Fifth International Conference on Advances in Biomedical Engineering (ICABME), Tripoli, Lebanon, 17–19 October 2019. [Google Scholar] [CrossRef]
  10. Schiele, A. An explicit model to predict and interpret constraint force creation in pHRI with exoskeletons. In Proceedings of the 2008 IEEE International Conference on Robotics and Automation, Pasadena, CA, USA, 19–23 May 2008. [Google Scholar] [CrossRef]
  11. Schiele, A.; van der Helm, F.C.T. Influence of attachment pressure and kinematic configuration on pHRI with wearable robots. Appl. Bionics Biomech. 2009, 6, 157–173. [Google Scholar] [CrossRef]
  12. Jarrasse, N.; Morel, G. Connecting a Human Limb to an Exoskeleton. IEEE Trans. Robot. 2012, 28, 697–709. [Google Scholar] [CrossRef]
  13. Galinski, D.; Sapin, J.; Dehez, B. Optimal design of an alignment-free two-DOF rehabilitation robot for the shoulder complex. In Proceedings of the 2013 IEEE 13th International Conference on Rehabilitation Robotics (ICORR), Seattle, WA, USA, 24–26 June 2013. [Google Scholar] [CrossRef]
  14. Zanotto, D.; Akiyama, Y.; Stegall, P.; Agrawal, S.K. Knee joint misalignment in exoskeletons for the lower extremities: Effects on user’s gait. IEEE Trans. Robot. 2015, 31, 978–987. [Google Scholar] [CrossRef]
  15. Verdel, D.; Sahm, G.; Bastide, S.; Bruneau, O.; Berret, B.; Vignais, N. Influence of the physical interface on the quality of human–exoskeleton interaction. IEEE Trans. Hum.-Mach. Syst. 2022, 53, 44–53. [Google Scholar] [CrossRef]
  16. Näf, M.B.; Junius, K.; Rossini, M.; Rodriguez-Guerrero, C.; Vanderborght, B.; Lefeber, D. Misalignment compensation for full human-exoskeleton kinematic compatibility: State of the art and evaluation. Appl. Mech. Rev. 2018, 70, 5. [Google Scholar] [CrossRef]
  17. Perry, J.C.; Rosen, J.; Burns, S. Upper-limb powered exoskeleton design. IEEE/ASME Trans. Mechatronics 2007, 12, 408–417. [Google Scholar] [CrossRef]
  18. Gupta, S.; Agrawal, A.; Singla, E. Architectural design and development of an upper-limb rehabilitation device: A modular synthesis approach. Disabil. Rehabil. Assist. Technol. 2022, 1–15. [Google Scholar] [CrossRef] [PubMed]
  19. Gupta, S.; Agrawal, A.; Singla, E. Toward avoiding misalignment: Dimensional synthesis of task-oriented upper-limb hybrid exoskeleton. Robotics 2022, 11, 74. [Google Scholar] [CrossRef]
  20. Nef, T.; Guidali, M.; Riener, R. ARMin III – arm therapy exoskeleton with an ergonomic shoulder actuation. Appl. Bionics Biomech. 2009, 6, 127–142. [Google Scholar] [CrossRef]
  21. Stienen, A.H.A.; Hekman, E.E.G.; Prange, G.B.; Jannink, M.J.A.; Aalsma, A.M.M.; van der Helm, F.C.T.; van der Kooij, H. Dampace: Design of an exoskeleton for force-coordination training in upper-extremity rehabilitation. J. Med. Devices 2009, 3, 031003. [Google Scholar] [CrossRef]
  22. Stienen, A.H.A.; Hekman, E.E.G.; van der Helm, F.C.T.; van der Kooij, H. Self-aligning exoskeleton axes through decoupling of joint rotations and translations. IEEE Trans. Robot. 2009, 25, 628–633. [Google Scholar] [CrossRef]
  23. Sergi, F.; Accoto, D.; Tagliamonte, N.L.; Carpino, G.; Galzerano, S.; Guglielmelli, E. Kinematic synthesis, optimization and analysis of a non-anthropomorphic 2-DOFs wearable orthosis for gait assistance. In Proceedings of the 2012 IEEE/RSJ International Conference on Intelligent Robots and Systems, Vilamoura-Algarve, Portugal, 7–12 October 2012. [Google Scholar] [CrossRef]
  24. Accoto, D.; Sergi, F.; Tagliamonte, N.L.; Carpino, G.; Sudano, A.; Guglielmelli, E. Robomorphism: A nonanthropomorphic wearable robot. IEEE Robot. Autom. Mag. 2014, 21, 45–55. [Google Scholar] [CrossRef]
  25. Beil, J.; Marquardt, C.; Asfour, T. Self-aligning exoskeleton hip joint: Kinematic design with five revolute, three prismatic and one ball joint. In Proceedings of the 2017 International Conference on Rehabilitation Robotics (ICORR), London, UK, 17–20 July 2017. [Google Scholar] [CrossRef]
  26. Junius, K.; Lefeber, N.; Swinnen, E.; Vanderborght, B.; Lefeber, D. Metabolic effects induced by a kinematically compatible hip exoskeleton during STS. IEEE Trans. Biomed. Eng. 2018, 65, 1399–1409. [Google Scholar] [CrossRef] [PubMed]
  27. Chen, C.F.; Du, Z.J.; He, L.; Shi, Y.J.; Wang, J.Q.; Xu, G.Q.; Zhang, Y.; Wu, D.M.; Dong, W. Development and hybrid control of an electrically actuated lower limb exoskeleton for motion assistance. IEEE Access 2019, 7, 169107–169122. [Google Scholar] [CrossRef]
  28. Housman, S.J.; Le, V.; Rahman, T.; Sanchez, R.J.; Reinkensmeyer, D.J. Arm-training with T-WREX after chronic stroke: Preliminary results of a randomized controlled trial. In Proceedings of the 2007 IEEE 10th International Conference on Rehabilitation Robotics, Noordwijk, The Netherlands, 13–15 June 2007. [Google Scholar] [CrossRef]
  29. Jarrasse, N.; Robertson, J.; Garrec, P.; Paik, J.; Pasqui, V.; Perrot, Y.; Roby-Brami, A.; Wang, D.; Morel, G. Design and acceptability assessment of a new reversible orthosis. In Proceedings of the 2008 IEEE/RSJ International Conference on Intelligent Robots and Systems, Nice, France, 22–26 September 2008. [Google Scholar] [CrossRef]
  30. Ergin, M.A.; Patoglu, V. ASSISTON-SE: A self-aligning shoulder-elbow exoskeleton. In Proceedings of the 2012 IEEE International Conference on Robotics and Automation, St Paul, MN, USA, 14–18 May 2012. [Google Scholar] [CrossRef]
  31. Li, J.; Cao, Q.; Dong, M.; Zhang, C. Compatibility evaluation of a 4-DOF ergonomic exoskeleton for upper limb rehabilitation. Mech. Mach. Theory 2021, 156, 104146. [Google Scholar] [CrossRef]
  32. Ning, Y.; Wang, H.; Tian, J.; Zhu, P.; Yang, C.; Niu, J. Design, optimization, and analysis of a human-machine compatibility upper extremity exoskeleton rehabilitation robot. Proc. Inst. Mech. Eng. Part J. Mech. Eng. Sci. 2022, 095440622211399. [Google Scholar] [CrossRef]
  33. Sarkisian, S.V.; Ishmael, M.K.; Lenzi, T. Self-aligning mechanism improves comfort and performance with a powered knee exoskeleton. IEEE Trans. Neural Syst. Rehabil. Eng. 2021, 29, 629–640. [Google Scholar] [CrossRef]
  34. Jarrassé, N.; Tagliabue, M.; Robertson, J.V.G.; Maiza, A.; Crocher, V.; Roby-Brami, A.; Morel, G. A Methodology to Quantify Alterations in Human Upper Limb Movement During Co-Manipulation With an Exoskeleton. IEEE Trans. Neural Syst. Rehabil. Eng. 2010, 18, 389–397. [Google Scholar] [CrossRef]
  35. Pirondini, E.; Coscia, M.; Marcheschi, S.; Roas, G.; Salsedo, F.; Frisoli, A.; Bergamasco, M.; Micera, S. Evaluation of the effects of the Arm Light Exoskeleton on movement execution and muscle activities: A pilot study on healthy subjects. J. Neuroeng. Rehabil. 2016, 13, 9. [Google Scholar] [CrossRef]
  36. Verdel, D.; Bastide, S.; Vignais, N.; Bruneau, O.; Berret, B. An identification-based method improving the transparency of a robotic upper-limb exoskeleton. Robotica 2021, 39, 1711–1728. [Google Scholar] [CrossRef]
  37. Voilque, A.; Masood, J.; Fauroux, J.C.; Sabourin, L.; Guezet, O. Industrial exoskeleton technology: Classification, structural analysis, and structural complexity indicator. In Proceedings of the IEEE 2019 Wearable Robotics Association Conference (WearRAcon), Scottsdale, AZ, USA, 25–27 March 2019. [Google Scholar] [CrossRef]
  38. Hermens, H.J.; Research, R.; Development, B.V. (Eds.) European Recommendations for Surface ElectroMyoGraphy: Results of the SENIAM Project; Number 8 in SENIAM; Roessingh Research and Development: Enschede, The Netherlands, 1999. [Google Scholar]
  39. Hart, S.G.; Staveland, L.E. Development of NASA-TLX (task load index): Results of empirical and theoretical research. In Advances in Psychology; Elsevier: Amsterdam, The Netherlands, 1988; pp. 139–183. [Google Scholar] [CrossRef]
  40. Maurice, P.; Camernik, J.; Gorjan, D.; Schirrmeister, B.; Bornmann, J.; Tagliapietra, L.; Latella, C.; Pucci, D.; Fritzsche, L.; Ivaldi, S.; et al. Objective and subjective effects of a passive exoskeleton on overhead work. IEEE Trans. Neural Syst. Rehabil. Eng. 2020, 28, 152–164. [Google Scholar] [CrossRef]
  41. Garrec, P.; Friconneau, J.P.; Méasson, Y.; Perrot, Y. ABLE, an Innovative Transparent Exoskeleton for the Upper-Limb. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Nice, France, 22–26 September 2008; pp. 1483–1488. [Google Scholar] [CrossRef]
  42. Garrec, P. Screw and Cable Acutators (SCS) and Their Applications to Force Feedback Teleoperation, Exoskeleton and Anthropomorphic Robotics. In Robotics 2010 Current and Future Challenges; IntechOpen: London, UK, 2010; pp. 167–191. [Google Scholar] [CrossRef]
  43. Rosen, J.; Brand, M.; Fuchs, M.B.; Arcan, M. A myosignal-based powered exoskeleton system. IEEE Trans. Syst. Man Cybern.—Part A Syst. Hum. 2001, 31, 210–222. [Google Scholar] [CrossRef]
  44. Rosen, J.; Perry, J.C. Upper limb powered exoskeleton. Int. J. Humanoid Robot. 2007, 4, 529–548. [Google Scholar] [CrossRef]
  45. Eiichi, Y.; Daisuke, H.; Masaaki, K. Development of an upper limb power assist system using pneumatic actuators for farming lift-up motion. J. Syst. Des. Dyn. 2009, 3, 781–791. [Google Scholar] [CrossRef]
  46. Ragonesi, D.; Agrawal, S.; Sample, W.; Rahman, T. Series elastic actuator control of a powered exoskeleton. In Proceedings of the 2011 Annual International Conference of the IEEE Engineering in Medicine and Biology Society, Boston, MA, USA, 30 August–3 September 2011. [Google Scholar] [CrossRef]
  47. Verdel, D.; Bastide, S.; Bruneau, O.; Berret, B.; Vignais, N. Improving and quantifying the transparency of an upper-limb robotic exoskeleton with a force sensor and electromyographic measures. 46ème Congrès Société Biomécanique, Computer Methods in Biomechanics and Biomedical Engineering Comput. Methods Biomech. Biomed. Eng. 2021, 24 (Suppl. 1), S261–S263. [Google Scholar] [CrossRef]
  48. Gentili, R.; Cahouet, V.; Papaxanthis, C. Motor planning of arm movements is direction-dependent in the gravity field. Neuroscience 2007, 1, 20–32. [Google Scholar] [CrossRef] [PubMed]
  49. Papaxanthis, C.; Pozzo, T.; Schieppati, M. Trajectories of arm pointing movements on the sagittal plane vary with both direction and speed. Exp. Brain Res. 2003, 148, 498–503. [Google Scholar] [CrossRef]
  50. Verdel, D.; Bastide, S.; Vignais, N.; Bruneau, O.; Berret, B. Human weight compensation with a backdrivable upper-limb exoskeleton: Identification and control. Front. Bioeng. Biotechnol. 2022, 9, 796864. [Google Scholar] [CrossRef]
  51. Bastide, S.; Vignais, N.; Geffard, F.; Berret, B. Interacting with a “transparent” upper-limb exoskeleton: A human motor control approach. In Proceedings of the IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Madrid, Spain, 1–5 October 2018; pp. 4661–4666. [Google Scholar] [CrossRef]
  52. Potvin, J.R.; Brown, S.H.M. Less is more: High pass filtering, to remove up to 99% of the surface EMG signal power, improves EMG-based biceps brachii muscle force estimates. J. Electromyogr. Kinesiol. 2004, 14, 389–399. [Google Scholar] [CrossRef]
  53. Just, F.; Özhan, Ö.; Bösch, P.; Bobrovsky, H.; Klamroth-Marganska, V.; Riener, R.; Rauter, G. Exoskeleton transparency: Feed-forward compensation vs. disturbance observer. at-Automatisierungstechnik 2018, 66, 1014–1026. [Google Scholar] [CrossRef]
  54. Kermavnar, T.; Power, V.; de Eyto, A.; O’Sullivan, L.W. Computerized cuff pressure algometry as guidance for circumferential tissue compression for wearable soft robotic applications: A systematic review. Soft Robot. 2018, 5, 1–16. [Google Scholar] [CrossRef]
  55. Bessler, J.; Prange-Lasonder, G.B.; Schaake, L.; Saenz, J.F.; Bidard, C.; Fassi, I.; Valori, M.; Lassen, A.B.; Buurke, J.H. Safety assessment of rehabilitation robots: A review identifying safety skills and current knowledge gaps. Front. Robot. AI 2021, 8, 602878. [Google Scholar] [CrossRef]
  56. Vallat, R. Pingouin: Statistics in Python. J. Open Source Softw. 2018, 3, 1026. [Google Scholar] [CrossRef]
  57. Berret, B.; Baud-Bovy, G. Evidence for a cost of time in the invigoration of isometric reaching movements. J. Neurophysiol. 2022, 127, 689–701. [Google Scholar] [CrossRef] [PubMed]
  58. Verdel, D.; Bruneau, O.; Sahm, G.; Vignais, N.; Berret, B. The value of time in the invigoration of human movements when interacting with a robotic exoskeleton. bioRxiv 2023. [Google Scholar] [CrossRef]
  59. Berret, B.; Jean, F. Why Don’t We Move Slower? The Value of Time in the Neural Control of Action. J. Neurosci. 2016, 36, 1056–1070. [Google Scholar] [CrossRef] [PubMed]
  60. Berret, B.; Castanier, C.; Bastide, S.; Deroche, T. Vigour of self-paced reaching movement: Cost of time and individual traits. Sci. Rep. 2018, 8, 10655. [Google Scholar] [CrossRef] [PubMed]
  61. Shadmehr, R.; de Xivry, J.J.O.; Xu-Wilson, M.; Shih, T.Y. Temporal discounting of reward and the cost of time in motor control. J. Neurosci. 2010, 30, 10507–10516. [Google Scholar] [CrossRef]
  62. Shadmehr, R. Control of movements and temporal discounting of reward. Curr. Opin. Neurobiol. 2010, 20, 726–730. [Google Scholar] [CrossRef]
  63. Yandell, M.B.; Zelik, K.E. Preferred barefoot step frequency is influenced by factors beyond minimizing metabolic rate. Sci. Rep. 2016, 6, 23243. [Google Scholar] [CrossRef]
  64. Labaune, O.; Deroche, T.; Teulier, C.; Berret, B. Vigor of reaching, walking, and gazing movements: On the consistency of interindividual differences. J. Neurophysiol. 2020, 123, 234–242. [Google Scholar] [CrossRef]
  65. Fitts, R.H.; Riley, D.R.; Widrick, J.J. Functional and structural adaptations of skeletal muscle to microgravity. J. Exp. Biol. 2001, 204, 3201–3208. [Google Scholar] [CrossRef]
  66. Tanaka, H.; Krakauer, J.W.; Qian, N. An optimization principle for determining movement duration. J. Neurophysiol. 2006, 95, 3875–3886. [Google Scholar] [CrossRef] [PubMed]
  67. Berret, B.; Conessa, A.; Schweighofer, N.; Burdet, E. Stochastic optimal feedforward-feedback control determines timing and variability of arm movements with or without vision. PLoS Comput. Biol. 2021, 17, e1009047. [Google Scholar] [CrossRef] [PubMed]
  68. Verdel, D.; Bastide, S.; Geffard, F.; Bruneau, O.; Vignais, N.; Berret, B. Fast reoptimization of human motor patterns in non-Earth gravity fields locally induced by a robotic exoskeleton. bioRxiv 2022. [Google Scholar] [CrossRef]
  69. Li, Y.; Sena, A.; Wang, Z.; Xing, X.; Babič, J.; van Asseldonk, E.; Burdet, E. A review on interaction control for contact robots through intent detection. Prog. Biomed. Eng. 2022, 4, 032004. [Google Scholar] [CrossRef]
Figure 1. Illustration of the task. (A) Posture of a participant inside the exoskeleton. The axes ( x A and z A ) of the arm force sensor are highlighted in green. The last axis y A of the arm force sensor was defined by y A = z A × x A . The same definitions were adopted for the forearm force sensor, with axes represented in orange. The passive rotations and translation are illustrated in red in the zoomed picture. (B) Schematic representation of the task and the target location. The reference position is shaded.
Figure 1. Illustration of the task. (A) Posture of a participant inside the exoskeleton. The axes ( x A and z A ) of the arm force sensor are highlighted in green. The last axis y A of the arm force sensor was defined by y A = z A × x A . The same definitions were adopted for the forearm force sensor, with axes represented in orange. The passive rotations and translation are illustrated in red in the zoomed picture. (B) Schematic representation of the task and the target location. The reference position is shaded.
Sensors 23 04122 g001
Figure 2. Control structure of the exoskeleton (see the description of Equation (1) for the definition of the terms).
Figure 2. Control structure of the exoskeleton (see the description of Equation (1) for the definition of the terms).
Sensors 23 04122 g002
Figure 3. Maximum and averaged interaction effort components (i.e., i x , y , z ) at the level of the arm ( A ) and forearm ( FA ) for both the Rot and noRot conditions. T t o p movements are represented with positive values and T b o t movements are represented with negative values. Significant ANOVAs on the tested conditions are represented by “*” if p < 0.05 and by “ * * ” if p < 10 3 . (A) Components of the interaction force at the arm. (B) Components of the interaction force at the forearm. (C) Components of the interaction torque at the arm. (D) Components of the interaction torque at the forearm.
Figure 3. Maximum and averaged interaction effort components (i.e., i x , y , z ) at the level of the arm ( A ) and forearm ( FA ) for both the Rot and noRot conditions. T t o p movements are represented with positive values and T b o t movements are represented with negative values. Significant ANOVAs on the tested conditions are represented by “*” if p < 0.05 and by “ * * ” if p < 10 3 . (A) Components of the interaction force at the arm. (B) Components of the interaction force at the forearm. (C) Components of the interaction torque at the arm. (D) Components of the interaction torque at the forearm.
Sensors 23 04122 g003
Figure 4. Average trajectories recorded in the three tested conditions for each of the two targets, T t o p and T b o t . (A) Consecutive positions of the index in the sagittal plane ( x , y ) (see Figure 1B). (B) Velocity profiles normalized by MD . (C) Acceleration profiles normalized by MD .
Figure 4. Average trajectories recorded in the three tested conditions for each of the two targets, T t o p and T b o t . (A) Consecutive positions of the index in the sagittal plane ( x , y ) (see Figure 1B). (B) Velocity profiles normalized by MD . (C) Acceleration profiles normalized by MD .
Sensors 23 04122 g004
Figure 5. Average RMS of muscle groups for both targets and each condition. A main effect of the condition on the RMS is signaled by “*”. All significant ANOVAs returned p < 0.05 . (A) Shoulder flexors. (B) Shoulder extensors. (C) Elbow flexors. (D) Elbow extensors.
Figure 5. Average RMS of muscle groups for both targets and each condition. A main effect of the condition on the RMS is signaled by “*”. All significant ANOVAs returned p < 0.05 . (A) Shoulder flexors. (B) Shoulder extensors. (C) Elbow flexors. (D) Elbow extensors.
Sensors 23 04122 g005
Figure 6. Average answers of the participants to the ergonomic feedback questionnaire.
Figure 6. Average answers of the participants to the ergonomic feedback questionnaire.
Sensors 23 04122 g006
Table 1. Summary of the computed descriptors of the kinematics for each condition. The ANOVA significance level associated with each parameter is given in the last column.
Table 1. Summary of the computed descriptors of the kinematics for each condition. The ANOVA significance level associated with each parameter is given in the last column.
ParameterCondition T top T bot ANOVA
noExo 1.22 ± 0.34 1.16 ± 0.37
MD ( s )noRot 1.49 ± 0.52 1.54 ± 0.56 p = 3 . 10 5
Rot 1.51 ± 0.51 1.40 ± 0.45
noExo 0.64 ± 0.08 0.58 ± 0.08
Amp. ( m )noRot 0.63 ± 0.11 0.50 ± 0.07 p = 0.006
Rot 0.62 ± 0.08 0.54 ± 0.08
noExo 0.59 ± 0.20 0.57 ± 0.20
aV ( m . s 1 )noRot 0.49 ± 0.19 0.38 ± 0.15 p = 8 . 10 8
Rot 0.48 ± 0.18 0.43 ± 0.15
noExo 3.38 ± 1.98 3.42 ± 2.12
mA ( m . s 2 )noRot 2.51 ± 1.56 1.94 ± 1.48 p = 3 . 10 6
Rot 2.38 ± 1.40 2.22 ± 1.54
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Verdel, D.; Sahm, G.; Bruneau, O.; Berret, B.; Vignais, N. A Trade-Off between Complexity and Interaction Quality for Upper Limb Exoskeleton Interfaces. Sensors 2023, 23, 4122. https://doi.org/10.3390/s23084122

AMA Style

Verdel D, Sahm G, Bruneau O, Berret B, Vignais N. A Trade-Off between Complexity and Interaction Quality for Upper Limb Exoskeleton Interfaces. Sensors. 2023; 23(8):4122. https://doi.org/10.3390/s23084122

Chicago/Turabian Style

Verdel, Dorian, Guillaume Sahm, Olivier Bruneau, Bastien Berret, and Nicolas Vignais. 2023. "A Trade-Off between Complexity and Interaction Quality for Upper Limb Exoskeleton Interfaces" Sensors 23, no. 8: 4122. https://doi.org/10.3390/s23084122

APA Style

Verdel, D., Sahm, G., Bruneau, O., Berret, B., & Vignais, N. (2023). A Trade-Off between Complexity and Interaction Quality for Upper Limb Exoskeleton Interfaces. Sensors, 23(8), 4122. https://doi.org/10.3390/s23084122

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop