Key words
spring mass model - energy - kinetics - sport - biomechanics - physical performance
Introduction
Considering legs as springs has been introduced by Cavagna et al. [1] to explain the high efficiency of running. Indeed,
if potential and kinetic energy are in anti-phase during walking, allowing for
energy transfers, they are in phase during running [2]. The observed running efficiency therefore implies an internal mechanism
that absorb and restore mechanical energy. This mechanism has been used to describe
a stretch shortening cycle, where animals can store and return elastic energy in
muscles, tendons and ligaments while hopping, trotting or running [3]
[4]
[5]
[6]. Cavagna et al.
[4] observed a lower deformation of the lower limb
with the increase of the running speed and suggested a quicker and more rigid spring
at higher speed.
A spring mass model was then proposed by Blickhan [7]
considering the human body as a single point mass bouncing on a massless spring. The
limits of the model were clearly addressed, as it supposed similar take-off and
landing velocities and symmetrical acceleration and deceleration phases during
stance. Based on this model, Mc Mahon and Cheng [8]
and then Farley and Gonzalez [9] provided equations to
determine both vertical stiffness (Kvert) and leg stiffness (Kleg). They used
maximal vertical force value during stance (Fzmax), vertical displacement
of the center of mass (COM), running velocity (V) and foot contact time
(Tcontact). They assumed that the angles of the spring respectively
at foot initial contact and toe off were identical. Finally, Morin et al. [10] developed equations allowing to estimate the
maximal force using Tcontact and flight time Tflight. This
method has been widely used, due to its simplicity since only spatio-temporal
parameters are needed to calculate Kvert and Kleg. Globally, results based on the
spring mass model seems to show constant leg stiffness as running speed increased
[8]
[9]
[10]
[11].
Arampatzis et al. [12] developed another approach,
using both kinetic and kinematic data to determine Kvert and Kleg
(Eq.1–2).
A force platform was used to determine the maximal force, while COM vertical
displacement (ΔZ) and changes in leg length (ΔL) were calculated
using synchronized cameras and a 15 segments body model [13]
[14]. They observed a clear effect of
speed on Kleg, showing a discrepancy with the model-based method described
above.
In a review by Brughelli and Cronin [15], indirect
evidence of increased Kleg with speed was highlighted. These authors analysed 14
studies evaluating running stiffness and compared running speeds below vs higher
than 5 m·s-1. The average Kleg was 11.2 vs 17.0
kN·m-1 in the low vs high speed, respectively. As several
studies reported a constant leg stiffness with running speed increase [8]
[10]
[11] it is very interesting to gain more insight about
these discrepancies. One may therefore hypothesize that the leg stiffness is
dependent on the running speed, and that the calculation method per se
modifies the outcome.
In addition to the effect of speed, another important aspect is the applicability of
the spring-mass model for graded running. The model is indeed based on the
assumption that the oscillations are symmetrical, which is not respected on a slope
[16]. Nevertheless, using direct measurement of
the maximal force and COM displacement should still provide coherent results, while
the simplified equation developed by Morin et al. [10]
should induce different outcomes. It would therefore be of interest to compare the
different models for both Kvert and Kleg on different slopes. As Dewolf et al. [17] showed the progressive reduction of the rebound
mechanism when slope increase, (both in uphill and downhill), one may hypothesize
that both Kvert and Kleg would reach very important values on slopes.
Materials and Methods
Subjects
Twenty-nine healthy individuals (19 males, 10 females) volunteered in this study
(age: 34±10 [mean±SD] years; height:
1.74±0.09 m; body mass: 68.3±12.2 kg). They were
running between one and 5 times a week. Every participant was informed on the
benefits and risks of this investigation prior to giving their written informed
consent to participate in this study. The protocol was approved by the local
ethical committee and conducted according to the declaration of Helsinki.
Design
All participants visited the laboratory on four occasions to perform each of the
experimental tests. A level running incremental test was performed during the
first session, with the first stage beginning at
8 km·h-1 during 4 min and the running
speed then increased by 1 km·h-1 every minute. Then,
during the next three sessions participants had to perform six to eight running
bouts at different speeds (8, 10, 12 and 14 km·h-1)
and different treadmill slopes (−20, −10, −5, 0, 5, 10,
15 and 20%). For each condition, participants had to run for
4 min to allow reaching a steady state [18], following by two to five minutes of recovery between each trial.
The high demanding conditions (20% at 12 and
14 km·h-1and 15% at
14 km·h-1) were not performed, and the trials
were also interrupted when the participant was not able to reach a steady state.
The order of the speed and slope conditions was randomized for each participant
and each session was separated by at least one week of recovery.
Methodology
An instrumented treadmill (T-170-FMT, Arsalis, Belgium) sampling at
1000 Hz was used to record 3D reaction force, and a 3D cameras system
composed of eight infrared cameras (Vicon Motion System, Ltd., Oxford, UK) was
used to record kinematic data at 200 Hz. Before each test session,
participants were equipped with 39 retro-reflective markers (14 mm in
diameter) following the integrated plug-in Gait Model. Kinetics and kinematics
data were recorded during 30 s starting 45 s before the end of
the trial.
A specific procedure (Matlab version R2019a, MathWorks Inc., Natick, MA, USA) was
developed to process and analyze data [19]: To
reduce the noise inherent to the treadmill’s vibrations, we first
applied, on the vertical ground reaction force (GRF) signal, a 2nd-order
stop-band Butterworth filter with edge frequencies set to 25 and 65 Hz.
The filter configuration was chosen empirically to obtain a satisfactory
reduction of the oscillations observed during flight phases (i. e.,
subject not in contact with the treadmill) while minimizing its widening effect
during ground contact time.
The instants of initial contact (IC) and terminal contact (TC) were identified
using a threshold of 7% of bodyweight on the filtered vertical ground
reaction force signal, based on a previously published work [19]. The IC and TC of the left and right legs were
combined to determine the Tcontact (the time duration between IC and
TC of the same leg) and the Tflight (the time duration between the TC
of one leg and the IC of the other leg).
Depending on available instrument and possible application, three methods were
used and compared to estimate Kvert and Kleg (Eq. 1–2) from
Fzmax, ΔL and ΔZ:
Temporal method where only spatio-temporal parameters were provided using
Eq. 3–5 [10]. The leg length (Lmod) was
estimated as 0.53*height (in m) [20], m is
the mass of the participant, g the gravity constant.
Kinetic method in which a force platform is available to determine the
vertical force (Fz) and estimate the vertical speed (Vz) and vertical
displacement of the center of mass (h) (Eq. 6–10) [21].
Kinematic-Kinetic method, where kinematic data obtained from 3D motion capture
system was used to estimate ΔZ and ΔL with morphological
estimation models [13]
[14], (Eq. 11–13). The variables X, Y and Z are the 3D
coordinate of a given point in a global reference system, L represent the leg
length. The point of force application on the treadmill (subscript
PFA ) was obtained directly from the force plate [22]
[23] and the
subscript Hip is given for the Hip 3D position calculated by the
plug-in Gait Model.
Statistical analysis
Linear mixed models (LMM) were applied on the dependant variables Kvert, Kleg,
ΔZ, ΔL and Fzmax obtained with the three methods,
with a fixed effect on the method and on the slope as independent variables, and
a random intercept effect on subjects. The Bonferroni pairwise comparison
post-hoc test was then applied to identify differences between methods, slopes
and speeds. All the statistical comparisons were obtained using Jamovi Software
(Jamovi project 2020, Version 1.2, Sydney; Australia). The overall significance
level was set at p<0.05. The Cohen’s coefficients f2
were also presented to assess effect size. They were calculated based on the
marginal coefficient of determination R2 as proposed by Selya et al.
[24]. Values of 0.02 and over are considered
small, 0.15 medium and 0.35 large [25]. All data
are expressed as mean±standard deviation (SD).
Results
Effect of speed
For the determination of Kvert, the LMM showed a significant difference between
methods (p<0.001, f2=0.16) ([Fig. 1a]). The post-hoc indicated significant lower values in Kvert
with the Temporal and Kinetic methods than with the Kinematic-Kinetic method
(both p<0.001), but not between Temporal and Kinetic (p=0.44).
Each method showed a significant increase of Kvert with increase of speed
(p<0.001, f2=0.65).
Fig. 1
a. Vertical stiffness given as a function of speed, calculated
using a Temporal, Kinetic or Kinematic-Kinetic method. b. Leg
stiffness given as a function of speed, calculated with either the
Temporal, Kinetic or Kinematic-Kinetic method. *Significant
difference between methods (p<0.05).
The LMM highlighted significant differences between methods to assess Kleg
(p<0.001, f2=0.21) ([Fig
1b]). The post-hoc showed lower values with Kinematic-Kinetic than
with Kinetic as well as with Kinetic than Temporal (all p<0.001) ([Fig. 2]). With the increase of speed, the Kleg
significantly decreased, but with a small effect size (p<0.001,
f2=0.04).
Fig. 2
a. Vertical displacement of the center of mass (ΔZ) given
as a function of speed, calculated with either the Kinematic-Kinetic,
Temporal or Kinetic method. b. Leg length change (ΔL)
given as a function of speed, calculated with either a
Kinematic-Kinetic, Temporal or Kinetic method. c. Maximal
vertical force (Fzmax) given as a function of speed, calculated with
either the Kinematic-Kinetic, Temporal or Kinetic method.
*Significant difference between methods (p<0.05).
Looking at the intrinsic parameters allowing to determine Kleg and Kvert,
ΔZ values were significantly different between methods (p<0.001,
f2=0.10) ([Fig. 2a]). The
pairwise comparison indicated significant higher values of ΔZ with
Kinetic compared to Kinematic-Kinetic (p=0.008), and for Temporal
compared to both Kinetic and Kinematic-Kinetic (both p<0.001). The
effect of speed was also significant (p<0.001,
f2=0.17), with a decrease of ΔZ with running speed
increase. For ΔL, the LMM indicate a significant difference between
methods (p<0.001, f2=0.30) ([Fig. 2b]). The post-hoc comparison indicated significantly higher
ΔL values with Kinematic-Kinetic compared to Temporal and Kinetic, and
with Temporal than Kinetic (all p<0.001). The running speed also had
significant impact on ΔL (p<0.001, f2=0.44),
with a positive correlation. Finally, the Fzmax calculation using
either a force plate or a model based on temporal parameters didn’t show
significant differences (p=0.065) ([Fig.
2c]). The Fzmax significantly increased with the speed
(p<0.001, f
2=0.13)
Effect of slope
The determination of Kvert highlighted significant differences when using the
three different methods (p<0.001, f2=0.37) ([Fig. 3a]). Kvert with the Temporal method was
significantly lower than with Kinematic-Kinetic or Kinetic (both
p<0.001), and with Kinetic than with Kinematic-Kinetic (p=0.04).
The slope also significantly impacted the calculation of the Kvert
(p<0.001, f2=0.18). Both the Kinematic-Kinetic and
the Kinetic methods did not provide valid Kvert values on extreme slopes
(i. e.±20%) as Kvert reached infinite values on such
slopes.
Fig. 3
a. Vertical stiffness given as a function of slope, calculated
with either the Kinematic-Kinetic, Temporal or Kinetic method. b.
Leg stiffness given as a function of slope, calculated with either the
Kinematic-Kinetic, Temporal or Kinetic method. *Significant
difference between methods (p<0.05).
The Kleg was also significantly affected by the calculation method
(p<0.001, f2=0.42) ([Fig.
3b]), Pairwise comparison indicated higher Kleg values with the
Kinetic method than Kinematic-Kinetic and Temporal (both p<0.001) as
well as with Temporal than Kinematic-Kinetic (p<0.001). The slope also
had a significant impact on the Kleg calculation (p<0.001,
f2=0.17).
Looking at the intrinsic parameters allowing to determine Kleg and Kvert,
ΔZ values were significantly different between methods (p<0.001,
f 2=0.94) ([Fig. 4a]). The
pairwise comparison indicated significant higher ΔZ values with the
Temporal method compared to both Kinematic-Kinetic and Kinetic
(p<0.001), and higher ΔZ values with Kinematic-Kinetic compared
to Kinetic (p<0.001). The effect of slope was also significant
(p<0.001, f2=0.41).
Fig. 4
a. Vertical displacement of the center of mass (ΔZ) given
as a function of slope, calculated with either the Kinematic-Kinetic,
Temporal or Kinetic method. b. Leg length change (ΔL)
given as a function of slope, calculated using a Kinematic-Kinetic,
Temporal or Kinetic method. c. Maximal vertical force
(Fzmax) given as a function of slope, calculated with
either the Kinematic-Kinetic, Temporal or Kinetic method.
*Significant difference between methods (p<0.05).
The LMM indicate a significant difference between methods (p<0.001,
f2=0.43) ([Fig. 4b]). The
pairwise comparison indicated significantly higher ΔL values for
Kinematic-Kinetic compared to both Temporal and Kinetic, as well as with
Temporal than Kinetic (all p<0.001). The slope also had significant
impact on ΔL (p<0.001, f2=0.20). Finally, the
Fzmax calculation using either a force plate or a model based on
temporal parameters showed significant differences but with a very low effect
size (p<0.001, f2=0.01) ([Fig. 4c]). The Fzmax significantly decreased when the
slope increased, with a low effect size (p<0.001,
f2=0.06).
Discussion
The present study is the first to clearly report the boundaries in which the model
based on temporal parameters proposed by Morin et al. [10] can be applied. As expected, the model based on spatio-temporal
parameters is not valid on slopes, even at low inclines (5% uphill and
10% downhill). Interestingly, Snyder and Farley [26] found the same asymmetry in energy storage at slopes between
a+3 and -3 degrees. In downhill running, the same amount of elastic energy
was stored in the leg compared to level running, while significantly lower energy
was stored during uphill running. The Kinetic and Kinematic-Kinetic models showed
higher values in both Kvert and Kleg when slope increases (and decreases), whereas
the Temporal method provides results that are constant and independent of the slope.
The results obtained with the Kinetic and Kinematic-Kinetic models are consistent
with the results of Dewolf et al. [17], as the
stiffness increased on steeper slopes. Indeed, as the energy stored in a spring is
equal to half of the spring coefficient times the square of the displacement of the
spring, the stored value will reach zero when the displacement come close to zero.
Therefore, previous studies that used the Temporal method to determine Kvert and
Kleg on incline terrain are questionable [27]
[28].
The present study highlighted also a constant Kleg on a large speed range, and the
validity of the Temporal model for level running. The three methods used in our
study provided consistent outcomes, but the Kinematic-Kinetic method gave lower
values then the Temporal and the Kinetic methods. This is in line with previous
reports that compared different method and highlighted the good behavior of Temporal
method [22]
[29] for
different speeds. The Temporal and the Kinetic method provide similar values but
lower Kvert values and higher Kleg values than with the Kinematic-Kinetic method.
This difference is probably due to the calculation method of ΔZ and
ΔL. These results are consistent with previously published work using the
spring mass model [8]
[9]
[10]
[11],
but differs with the indirect evidence found by Brughelli and Cronin [15] and with the study of Arampatzis et al. [12], that used a method similar to our
Kinematic-Kinetic method. The difference seems to come from the calculation of the
ΔL, that is constant in Arampatzis et al. [12], but increases with speed in our work.
With the speed range used in this study, we can assume the symmetry of the
deceleration and acceleration phases. Nevertheless, the Kinematic-Kinetic method
should be adapted to estimate the compression and the decompression of the spring
with two different stiffness, as proposed by Clark and Weyand [30]. This method could probably provide more insights
on the mechanisms involved when sprinting and explain the higher Kleg obtained at
maximal speed [15].
Overall, this study confirms that errors may arise from different sources across
running speeds or slopes: the indirect estimation of ΔZ and ΔL and
the symmetry of acceleration and deceleration phases – known to be wrong
– have different weight on the inaccuracy when comparing different speeds or
different slopes. While we argue that the assumption of the symmetry of land and
take-off symmetry (known to be inexact) is an important source of inaccuracy, the
derivation of the kinematics which drive the estimation of ΔZ and ΔL
and consequently the differences in Kvert and Kleg is also an important limitation.
Moreover, none of the models take into account the medial-lateral displacement
estimated to be negligible [31].
Stiffness calculation and analysis is used both in research and by practitioners to
gather useful information of athletes’ physical state. It has been shown
that both Kvert and Kleg are affected during marathon running [32]
[33], providing
insight about the accumulated fatigue. It is therefore important for coaches and
researchers to understand the applicability and the limit of the calculation method,
to make sur that their interpretation of the output is valid. As a consequence, the
Temporal method [10] is perfectly adapted for level
running, but should not been used in Trail or on slopes.
Conclusion
Using mathematical models is helpful to describe complex concepts, but caution is
needed when applying these models. In this work, we analysed the range of
application and the limits of different stiffness calculation methods. This study
highlights that the assumption of symmetry between compression and decompression
phases or the estimation of ΔZ and ΔL are the major sources of
errors when comparing different speeds or different slopes.
