Phases of a Rowing Cycle

Rowing is a periodic movement that can be divided into cycles, i.e. strokes. Each rowing cycle starts at the catch, followed by the drive phase, the release, and the recovery phase before it restarts at the catch (Figure 2). At the catch, the oar blades are moved vertically into the water, ready to exert propulsive forces. In the following drive phase, the rower performs a coordinatively demanding sequential movement of legs, trunk, and arms. The rower uses the power generated by this sequential movement to pull the oars through water and propel the boat. At the end of the drive phase, i.e. the release, both blades are vertically pushed out of water. The subsequent recovery phase is characterized by the sequential movement of arms, trunk, and legs to bring the oars back to a minimal horizontal angle, where another stroke is started with a new catch [47]. In principle, there are two different types of rowing: sweep rowing and scull. During sweep rowing, each rower only holds one oar with both hands, thus, an even number of rowers is needed to propel the boat. In scull rowing, as investigated in this study, the rower can propel the boat by manipulating two oars simultaneously, holding one oar in each hand.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 2. The phases of the rowing cycle.

The rowing cycle is divided into two phases: the recovery phase, where the oar is in water and the drive phase, where the oar is pulled through water. The stars indicate the locations, where the phases are separated. These are the points, where the oar enters water (catch) and where the oar is lifted out of water (release).

https://doi.org/10.1371/journal.pone.0082145.g002

Scull Simulator

Setup.

For the current study, a single scull simulator was placed in a CAVE at the Sensory-Motor Systems Lab, ETH Zurich. In the center of this CAVE, one rower was seated inside a trimmed rowing skiff and held one trimmed oar in each hand. A sound wave field synthesis system (112 speakers and 4 subwoofers, Iosono GmbH, Erfurt, Germany) placed in a ring around the CAVE at the level of the rower's ears was used to render a realistic soundscape. Furthermore, 3 screens (4 m×3 m, projectors: Projection Design F3+, Norway) surrounded the rower (Figure 1). When the rower moved the oars, he/she could hear and see the oar-water interaction that propelled the virtual boat through a virtual scenario. In addition to the visual and auditory impressions, the oar-water interaction was rendered haptically so that the rower could feel the oar-water interaction. Therefore, two custom-made tendon-based parallel robots [41], [43], [49] were connected to the end-effectors, i.e. outer ends of the trimmed oars (Figure 1).

In this study, both tendon-based parallel robots were composed by five drive trains, i.e. five axes per robot. Each of these drive trains consisted of a rope ( “D-Pro Dyneema”, Rosenberger Tauwerk GmbH, Lichtenberg, Germany) that linked a motorized winch located outside the CAVE over deflection units and a force sensor (K100.2k, Transmetra GmbH, Neuhausen am Rheinfall, Germany) to one oar end (Figure 1). To render the haptic interactions between oars and water, all drive trains were controlled simultaneously through one Matlab/Simulink® model running at on an XPC-target. Data exchange with the sensors, drives, brakes, and safety devices of the robot was entirely handled using EtherCAT® -data across a Linux™ PC. One operator could control the entire scull simulator through a graphical user interface (GUI) written in C++ on a control PC. This GUI controlled the states of the Matlab/Simulink® model using control-data defined by the “XPCAPI.dll” included in the Matlab/Simulink® package. Furthermore, the soundscape was controlled by the GUI: UDP-data provided by the XPC-target was transformed to splash sounds of the oar-water interaction on the control PC and forwarded to the sound system via OSC-protocol. The graphical scenario was driven by the boat, rower and oar movements that were sent to each graphics PC in form of UDP-data from the XPC-target (Figure 3). The graphical scene was developed in a commercially available game engine (Unity Pro, Unity Technologies, San Francisco, USA). For the transfer study described in this paper, two different graphics scenarios were developed: a scenario with a diverse landscape to make the trainings visually attractive (Figure 4) and an ocean scenario for baseline and retention tests to avoid visual distraction (Figure 5). The update rate of both scenarios was set to at a resolution of ×. In the ocean scenario, the update rate could be kept constant, while in the more demanding training scenario, the update rate could decrease to a minimum of in dependence of the complexity of the rendered objects and scene depth. UDP-data for the graphics scenario was sent at . Maximal delays of the graphics data from measuring data at the robots' sensors until data arrived at the graphics PCs were .

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 3. Setup and implementation of data transfer for the scull simulator.

One human operator can control the entire scull simulator from the control PC. The core of the setup is the XPC-target that calculates the real-time rowing model and the haptic interaction forces. This XPC-target collects sensor data from the robot and sensors inside the CAVE, processes this data, and transfers it via different protocols to the other PCs that render sound and graphics. Safety of the simulator is constantly guaranteed by a watchdog, safety relays in the cabinet, error detection software in the XPC-target, and the human operator. Furthermore, the participant in the simulator has emergency cords around his wrists that stop the simulator as soon as the hands are too far away from the oar handles.

https://doi.org/10.1371/journal.pone.0082145.g003

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 4. The training scenario was only used in the simulator group.

This scenario provided some distraction for the participant during the four trainings, similar to a training environment on water. For rendering, a global coordinate system () and boat coordinate system () where defined. Two lines of buoys limited the rower's workspace within the scenario. In this way the rower was in a setting comparable to a rowing race and at the same time, the rower could not leave the virtual world.

https://doi.org/10.1371/journal.pone.0082145.g004

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 5. The ocean scenario was used in all participants during the baseline and retention tests.

This scenario was designed to prevent the participants from distractions and to focus on their rowing technique. For rendering, a global coordinate system () and boat coordinate system () where defined. Two lines of buoys limited the rower's workspace within the scenario. In this way the rower was in a setting comparable to a rowing race and at the same time, the rower could not leave the virtual world.

https://doi.org/10.1371/journal.pone.0082145.g005

To render the haptic interaction between the oars and the water, the oar movements induced by the rower have to be known. Therefore, the end-effector positions of both oars were determined by forward kinematics calculation [50]. The forward kinematics reached an accuracy of , which corresponded to an oar angle accuracy higher than . The direction from the oar lock to the corresponding end-effector position defined the orientations of the axis in both oar coordinate systems and (Figure 6). Consecutively, the horizontal oar angles and the vertical oar angles could be determined between the orientation of the initial oar coordinate systems and the moved oar coordinate systems . The third oar angle, the rotation of the oar around its longitudinal axis , was measured by two wire potentiometers wound around each oar in parallel. Angle was defined to be , when the oar blade was parallel to the water surface and , when the oar blade was vertical to the water surface. Both oars were fixed in oar locks that reduced the originally six degrees of freedom (DOFs) of each oar to three rotational DOFs. These three rotational DOFs were uniquely defined by the three oar angles , , and , where and were actuated by the robot, while remained unactuated. In the scull simulator, the following movement variables were recorded:

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 6. Definition of the boat's coordinate systems, the forces at the oars, the oar angles, the seat position, and centers of gravity.

https://doi.org/10.1371/journal.pone.0082145.g006

1. the two oar angles of both oars and (resolution resulting in an accuracy higher than ),
2. the turning of the oar around its longitudinal axis of both oars (accuracy higher than ),
3. the oar forces in three dimensional Cartesian space at the end-effectors of both oars (resolution of the force sensors at the end-effector in each drive train with a linearity of over a force range from ),
4. the seat position with a wire potentiometer measuring the distance between its mounting point on the boat hull and the back of the sliding seat (accuracy ),
5. and the distance correlated with the rower's upper-body movement due to a wire potentiometer measuring the distance between its mounting point on the boat hull and a clavicle orthosis worn by the rower (accuracy ).

The integral information on the movement variables was first transferred over EtherCAT® to a Linux™ PC and then via UDP to an XPC-target. A Matlab/Simulink model was used to control both robots simultaneously. In the robot control model, the recorded movement variables from the right robot and the left robot were processed by a rowing model. This rowing model determined the oar forces that should be rendered. A closed-loop force controller transformed these oar forces into desired motor torques for each robot [43]. The signals for the desired torques were sent back to the Linux™ PC, which further communicated with the drives in the cabinet and all other sensors of the robot via EtherCAT® protocol. To synchronize all modalities in the virtual environment, the rowing model simultaneously determined the desired oar forces while generating UDP-data to trigger sound and graphics (Figure 7).

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 7. Schematic description of the Matlab/Simulink® model.

This model is used to render sound and graphics as well as to control the two tendon-based parallel robots displaying haptic oar-water interactions.

https://doi.org/10.1371/journal.pone.0082145.g007

Rowing Model.

For this study on transfer in sculling, a planar rowing model was developed that provided three DOFs for the rowing boat. The three DOFs were the movement in longitudinal- and lateral direction of the boat , and the turning of the boat around its vertical axis in the center of gravity (COG).

To determine the desired oar forces due to the interaction of the oars with the virtual water, all three oar angles (, , and ) of both oars, the seat position , and the seat acceleration had to be included. These input data were provided by the measured signals from the right robot and the left robot . During each execution of the Matlab/Simulink® model (), a multibody dynamics system (velocity model), comprising rower, boat, and the oars, was solved. This velocity model provided the boat's pose and velocity , where denoted the boat's position, the boat's rotation, and were their derivatives with respect to time. The boat's pose and velocity were needed for visual and auditory rendering. Moreover, the boat movement was used to determine the desired oar forces for each oar individually (force models for the right and left oar). Consequently, the resulting desired oar forces were used for haptic rendering with both robots. Finally, the desired oar forces served as input for the velocity model in the following iteration (Figure 8). A more detailed description of the velocity and the force models composing the rowing model can be found in the appendix (Appendix S1).

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 8. Data flow between the velocity model and the force models which constitute the rowing model.

The rowing model gets the rower's movement as an input and drives the rendering of the acoustic, visual, and haptic scenario.

https://doi.org/10.1371/journal.pone.0082145.g008

Due to the design of the scull simulator and the chosen functionalities of the implemented rowing model, the scull simulator has the following a priori known limitations:

1. the rower can experience oar-water forces due to a planar boat movement, however, the boat itself is stationary and the virtual reality scenario is moved around the rower in the stationary boat,
2. the dynamic behavior of the rowing model is reduced to a three DOF boat movement (a planar boat movement), while the remaining three DOFs are kept constant,
3. the center of gravity (COG) of the system rower-boat-oars is assumed to remain constant in the initial position of the rower's seat, therefore, turning of the boat will not exactly match turning of a real boat,
4. the boat-fixed coordinate system is defined in the COG of the system rower-boat-oars at a predefined water level, therefore a changed rower mass does not have an effect on the boat drag, only on the inertia of the system rower-boat,
5. the boat only rotates around the axis in , which defines the yaw angle of the boat , therefore, the rower's movement on the roll seat does not have an influence on the rotation axis of the boat,
6. the matrix of inertia of the system rower-boat in is in principal axis form and, therefore, movements in one direction cannot transfer energy into movements in another direction without the help of oar interactions,
7. environmental influences such as waves, other boats, etc. were not simulated.

On-Water Measurements

To assess transfer of simulator training by measurements on water, a skiff was equipped with a measurement system ( BiorowTel® version 3.5 from BioRow Ltd., Slough, UK). The following variables were measured at on water, matching those on the simulator (Figure 9):

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 9. On-water measurement in a skiff for beginners.

The skiff (Stämpfli Racing Boat AG, Switzerland) was equipped with a measurement system ( BiorowTel® version 3.5). This measurement system allowed for measurement of biomechanical performance measures in a similar way as in the simulator. The person of the photograph has given written informed consent, as outlined in the PLOS consent form, to publication of his photograph.

https://doi.org/10.1371/journal.pone.0082145.g009

1. the horizontal oar angles together with the vertical oar angles on both oars by 2D oar angle sensors (resolution with a mean (standard deviation) in angular deviation of ),
2. the turning of both oars around their longitudinal axes by binary tilt angle sensors (, when the oar blade was parallel to the water surface and , when the oar blade was vertical to the water surface),
3. the oar forces on both oars for pressure forces by 1D force sensors integrated in the oarlocks (resolution with a mean (standard deviation) in force deviation of ),
4. the seat position by a wire potentiometer measuring the distance between its mounting point on the boat hull and the back of the sliding seat (resolution with a mean (standard deviation) in position deviation of ),
5. and the distance representing the rower's upper-body movement by a wire potentiometer measuring the distance between its mounting point on the boat hull and a clavicle orthosis worn by the rower (resolution with a mean (standard deviation) in position deviation of ).

For the measurements, a broad, full-carbon skiff for beginners provided by Stämpfli Racing Boat AG, Switzerland, was used. This boat provided increased stability against boat tilting, decreased the effect of waves. Thus, the intermediate rowers could focus on their coordination and oar handling technique.

Participants

We were looking for participants who could improve their rowing performance within a short period of training and could row alone in a beginner's skiff without falling into water. Thus, the inclusion criteria were as follows:

1. recreational rower without competition experience,
2. participation in an intermediate's rowing course,
3. participation in a post-care rowing course,
4. less than two hours training per week,
5. healthy (no physical impairments or discomforts),
6. normal hearing, normal (or corrected to normal) vision,
7. age between 18 and 50 years.

Eight participants, four men and four women (mean age 35 years, 28 to 45 years), were included. The current study was conducted according to the regulation of the ethics commission of ETH Zurich. The corresponding ethics consent was obtained from the ethics commission of ETH Zurich: EK_2010-N-53. Furthermore, all participants signed a written consent form prior to the study. In addition, all participants were informed verbally about the study procedure, the risks, and their possibility to quit any time without a reason and without consequences. Moreover, all participants confirmed not to perform any rowing additional to the study. The participants were randomly assigned to one of two training groups, i.e. four to the on-water training group (W) and four to the simulator training group (S), i.e. the control group. Each group consisted of two women and two men.

Experimental Protocol

The current study aimed at comparing the effectiveness of training in a realistic simulator to training on water. Consequently, the control group performed conventional rowing training on water (on-water group W) while the experimental group trained in the simulator (simulator group S). To keep the study close to real training conditions, a conventional training protocol for rowing was applied, i.e. a licensed human trainer guided the training sessions. The same licensed rowing trainer conducted the training sessions for all participants in order to eliminate the influence of different training methods. Furthermore, the rowing trainer did not prefer one training method to the other. In return, the human trainer's capacity, the scheduling and simultaneous availability of participants that fulfilled the criteria for the study, the availability of locations, boats, training-, and measurement equipment, as well as good environmental conditions e.g. little wind and good weather, limited the possible number of participants for the study to four participants per group.

After all participants had performed a baseline test on water and a baseline test in the simulator, all participants trained during four sessions in their respective group within a two week period. After the four training sessions, all participants were tested again under both conditions, i.e. on water and in the simulator (Figure 10). To evaluate the performance development of each participant, quantitative performance measures were derived from the variables recorded on water and on the simulator. In rowing, videos are commonly used to analyze the rowing technique. Therefore, also in this study, videos were taken of all participants during the baseline and retention tests on water. These videos were evaluated by a second, independent rowing trainer, who was blinded to the training conditions of the participants. Furthermore, the independent rowing trainer did not know if a video was taken during the baseline or during the retention test.

Download:

• PPT
  PowerPoint slide
• PNG
  larger image
• TIFF
  original image

Figure 10. Study design for the two participant groups.

Group 1 (on-water group = control group) trained on water (cyan) and group 2 (simulator group) in the simulator (orange). Before the training started, all participants underwent a baseline test under both conditions: in the simulator and on water. Then, both groups trained under their according condition for two weeks. During these two weeks, all participants trained four times under supervision of the same rowing trainer. Finally, both groups underwent a retention test similar to the baseline test.

https://doi.org/10.1371/journal.pone.0082145.g010

Biomechanical Performance Measures

To enable a quantitative comparison between the development in rowing performance on water and in the simulator, ten biomechanical performance measures () were defined together with the rowing trainers in accordance with literature [47], [51], [52]. Furthermore, these should cover the key measures that the rowing trainer, who performed the trainings, intended to use to instruct the participants. At the same time, the should also be the key measures that the independent rowing trainer, who performed the blinded video evaluation of the baseline and retention tests on water, would need to evaluate the individual development of each participant. The covered four categories: the two technical aspects, i.e. “oar handling skills” and “coordination of body segments” and two general categories, i.e. “oar angles” and “power”. “Oar handling skills”, were represented by the following sub aspects: (i) “catch slip”, (ii) “depth of the blade immersion”, and (iii) “striking out before catch”. “Coordination of body segments” could be subdivided into: (i) “temporal overlap in the movement of legs and trunk during drive phase” and (ii) “overlap in the movement of trunk and arms during drive phase”. The “oar angles” consisted of (i) the “catch angle”, (ii) the “release angle”, (iii) and the “stroke length”. The “power” was subdivided into (i) “maximal power at the oar handle” and (ii) “mean power at the oar handle”. All performance measures for the oars were derived from measurements on the left-hand oar, i.e. starboard oar in the simulator and on water. The data for the right oar was not used due to a deficiency of the measurement of the vertical oar angle in the right-hand oar (port side oar) during all retention tests on water. The turning of the oars around their longitudinal axis was not considered in the performance measures. A detailed description of all ten biomechanical performance measures can be found further down in this chapter.

Only one out of three runs from baseline tests (one from on-water and one from the simulator condition) and one out of three runs from retention tests (one from on-water and one from the simulator condition) were considered to evaluate a participant. The runs were chosen on their consistency in performance measures. These performance measures were: direct catch, depth of the blade immersion, striking out before catch, overlap of leg and trunk movement, overlap of trunk and arm movement, catch angle, release angle, and stroke length. Consistency of a run was evaluated by the sum of the coefficients of variation for these eight performance measures:(1)Where denotes the standard deviation of the performance measure with index , and is the mean of the absolute values of the -th performance measure. Hereby, high consistency was defined by low values in the . The most consistent runs were used to evaluate the individual development in performance from baseline to retention for each participant. To quantify the development, the difference between the performance measures during baseline and retention tests was set in relation to the pooled standard deviation :(2)The pooled standard deviation is commonly used to express the effect size of a variable. It considers the performance measure of standard deviations of baseline- and retention tests . Furthermore, the pooled standard considers the number of rowing cycles in baseline and retention that were used to calculate the standard deviations and :(3)Due to the relatively small group size, a change in a performance measure was considered as significant if the change was at least in the order of one pooled standard deviation.

Definition of the Ten Biomechanical Performance Measures

Video Assessment

In addition to the assessment by , videos of all on-water tests were taken. The performance of all participants was rated by a second, independent rowing trainer, who was blinded to the group assignment of the participants. Also, he did not know if a video showed a baseline or a retention test. Seven technical aspects were rated according to the degree of error occurrence. The rating scale ranged from 0 ( = no occurrence) to 4 ( = very strong occurrence). All seven technical aspects that were rated corresponded to one out of the biomechanical performance measures. The stroke length, the mean power, and the maximal power were difficult to rate by video assessment and were therefore not considered by the independent rowing trainer. A comparison between the and their corresponding video rating was performed to test the validity of the for quantitative assessment of rowing performance on water.

In addition to the technical aspects quantified by , the independent rowing trainer rated general aspects such as the rowing rhythm, dynamics of the technique, and provided a general impression. The general aspects were rated in a scale from 1 (very bad) to 6 (very good). These general aspects were intended to document the general development of each participant.

Questionnaire

All participants had to fill out a questionnaire including 21 questions (six categories). In the following, these six categories are explained through a typical question for each category:

1. “Involvement/control”: How deeply involved into the virtual environment did you feel? How well could you control the oar in the virtual world?
2. “Naturalism”: How natural did the boat movement in the simulator appear to you?
3. “Advantage simulator”: Was it helpful for you that you were able to fully concentrate on the rowing technique in the simulator without environmental disturbances?
4. “Interface quality”: How natural did the haptic interaction with the water feel?
5. “Engagement trainer”: How well did the rowing trainer supervise you during the trainings?
6. “Personal profit”: Could you personally profit from this rowing course?

The rating score ranged from 1 (worst rating) to 7 (best rating).

Questions on category three were only asked to participants in the simulator group. The questions of category 1 to 4 were adapted from [53]. In addition, participants were asked if they had performed extra rowing training beyond the study.

Movement Consistency

Consistency is known as an indicator for expert performance [55]. The results of this study support this indication: Participants “W2”/;“W1”, who showed the least/highest values in the sums of coefficients of variation also got the best/worst ratings in the assessment of general aspects. Generally, the ranking of the participants according to “overall impression in the development” was similar to the participants' ranking according to consistency (Table 4: row: “overall impression”, columns “D”; compared to Table 1: last row).

The participants' consistency during the baseline tests on water was by lower than on the simulator. During the retention tests on water, the participants' consistency was even lower than on the simulator (Table 1: last column). Probably, external factors such as waves, wind, and other boats, had an impact on the consistency of on-water rowing. Such environmental influences were absent in the simulator which might be supportive particularly in early learning phases.

Individual Development

All participants were selected upon rather strict criteria; nevertheless slight differences in initial skill-level between participants had to be expected. Furthermore, the participants were expected to show individual deficits in different with respect to the predefined training goals. Therefore, the rowing trainer was allowed to provide individual verbal feedback with respect to deficient . The that were explicitly trained in this way were indicated by italic font in Table 3. At a close look, only participants and got instructions concerning the same . All other participants trained other combinations of . This inconsistency originated from the trainer's intuition to satisfy the participants' need for individual training, e.g. to train the most prominent deficits first. The participants' need for individual training is especially supported by the fact that the participants exhibited large differences in their initial skill level (Table 4: “overall impression” in the baseline tests). These differences in initial skill level combined with individual training might explain to a large part why all participants developed differently in the (Table 3). Although learning is an individual process that depends on many factors, all participants could improve in at least one general aspect from baseline to retention on water according to the video assessment. The only exception was participant “S4”, who did not follow the training protocol and performed extra rowing trainings in different conditions besides this study (Table 4). This general gain in performance indicates that the applied training protocol from conventional rowing training with a human trainer was adequate for the current study.

Biomechanical Performance Measures Compared to Video Assessment

Considering the total sum of 17 improved and 6 worsened , the simulator group principally improved their skills on the simulator. Similarly, the on-water training group improved in and degraded in 5 on the simulator. Thus, the on-water group could transfer the learned skills trained on water to the simulator.

On water, the on-water group increased performance in 13 , whereas only 7 developments showed a degradation. This development was also confirmed by the video assessment that indicated an improvement of 12 , while only 3 developments degraded. The simulator group showed a total of 6 improvements in , while 14 parameters indicated a decrease in performance development. Thus, more were found to be degraded than improved. However, this development was not confirmed by the video assessment of the through the independent, blinded rowing trainer. The video assessment of the revealed a total of 7 improvements and 6 degradations (Table 3). In our experience, the following points could be discussed to explain the discrepancy between the and the video assessment for the development:

1. The evaluation of the was based on all strokes, i.e. also on irregular or externally disturbed strokes. Thus, characteristic behavior of the rower might be weakened by averaging over all cycles. In contrast, the independent human trainer, who evaluated the videos, might have focused on characteristic performance in the strokes he judged as regular. Furthermore, a human trainer is able to rate performance particularities in relation to an overall impression of an athlete. To improve the biomechanical analysis, machine learning techniques could be applied to train algorithms that can classify and rate data in relation to the overall impression of an athlete's performance. This has been tried already in rowing for one specific rowing error [56].
2. Due to the influence of weather and waves, the participants might have been forced to row in a different way in the baseline test than in the retention test. While the independent rowing trainer could take the influence of the environmental conditions into account, the did not adapt to changed conditions.
3. Although the were selected based on literature and in discussions with both trainers, the were not sufficient to capture the individual performance especially of more skilled participants. This conclusion is supported by the documented instructions given by the trainer indicating that he had to provide also instructions on different than those selected for this study, e.g. instructions on secondary rowing errors that only have an indirect impact on the rowing performance such as the shoulder posture.
4. The quality of the rowing model and the simulation might not have been high enough to provide the necessary key features that enable a transfer of the improved performance from the simulator to rowing on water. However, the matching of the participants' rankings based on the “mean power” on water and in the simulator suggested a realistic simulation of the interactions (Figure 14). Similarly, results of a previous study on sweep rowing allowed reasonable ranking of athletes according to their experience and preferred oar side (bow/stern) [44]. Furthermore, the “stroke length” and the “overlap of trunk and arms during drive phase” on the simulator were in a similar range as during rowing on water. Moreover, all participants confirmed the realism of the simulator in the questionnaire. Therefore, we believe that the simulator might not only be used to simulate on-water rowing, but also to assess athletes under constant conditions.
5. The choice of the most consistent of three runs for the evaluation of this study might have had an influence on the study results, since the participants could have learnt from one test condition to the next one. However, no learning effect was found in a more detailed analysis. Therefore, the choice of the most consistent runs for evaluation of the study still seems reasonable.
6. Evaluation of biomechanical performance measures was based only on one oar due to a deficiency of one oar sensor on water during retention. In contrary, the independent rowing trainer could analyze the handling and the coordination of both oars. However, significant influences on other aspects than on the oar coordination are not expected.

To summarize the influence of all the previously mentioned points on the expressiveness of the chosen , the differences between the ratings based on biomechanical data and the video evaluation were calculated: In most cases (29), one evaluation method revealed a significant increase or decrease in a technical aspect, while the other evaluation method indicated no change. For example, participant “W1” improved her catch angle on water according to the biomechanical performance measures, but the video evaluation did not reveal a performance change. A development in the same direction for both evaluation methods was found in 25 cases for the tests on water. Opposed ratings in the developments on water were only found in two cases. Accordingly, the rating methods did not contradict each other. In contrary, even a clear tendency for a correspondence between the evaluation methods of the based on data and video evaluation could be found. However, regardless of the way the were evaluated, the chosen seem to allow only a documentation of basic development in rowing performance. For a detailed insight into performance gains in skilled participants, especially in a setting that is significantly influenced by the environment, the chosen might be limited. Therefore, a thorough evaluation of skilled performance in a complex task in a variable environment still has to rely on conventional rating through a human trainer.

Transfer Evaluation based on Video Rating of General Aspects

The video rating based on general aspects drew a positive picture of learning and transfer. Regardless of the training group, all participants increased in at least one general aspect, with exception from participant “S4”. This finding confirms that the analysis of the could not explain all important factors in sculling that the trainer could assess. Moreover, the assessment of general aspects revealed that the initial skill level of the participants in the simulator group was on average one point higher than the initial skill level in the participants of the on-water group (Table 4: “overall impression” in the baseline tests). This initial advantage in performance left less space for improvement in the simulator group, especially within the short training period of two weeks. The fact that even participants with advanced skills could improve in the general aspects clearly confirms the effectiveness of simulator training and skill transfer. The basic skill gains measured in the current study are expected to be further increased when additional augmented feedback or modifications in physical parameters are applied, which was shown in previous studies [35], [37].

Positive Participant Ratings

Realism of the simulator was confirmed in the questionnaire: The average participants' rating of “involvement/control”, “naturalism”, “advantage simulator”, and “interface quality” of the simulator reached points out of (Figure 15). The participants agreed that the simulator offers a clear advantage over training on water in terms of dependence on good weather conditions and the influence of environmental conditions like wind, waves, and other boats. This reduction of external influences allowed participants of the simulator group to focus more on single technical aspects such as the correct coordination of legs trunk and arms without having to struggle with wind, waves or to worry about a collision with other boats. Moreover, the rowers could train to immerse the oars at the right depth simultaneously on both sides without having to estimate the influence of waves. Therefore, simulator training also indicated its acceptance and relevance for training of real-life tasks and can be seen as a good complement for training in the real environment. However, simulators may not be able to simulate all aspects that are important for a task, e.g. proper handling of rowing equipment or coping with variable environmental conditions must still be learnt under real conditions. In general, all participants were satisfied with the special rowing course (average of points out of 7 over all questions) and they could all benefit personally (6.5 points out of 7).

Expected Effects of Larger Group Size

A larger group size would have allowed the use of statistical methods which could reveal between and within group effects and correlations between the biomechanical data and video analysis. However, a larger group size is not expected to change the general results of the current study, i.e. the learning and transfer of skills from the simulator to rowing on water, and the acceptance and relevance of the scull simulator for training of technical aspects for rowing on water.