The Ground Reaction Force of Standing Triple Long Jump
Chung-Yu Chen, Chung-Ming Chan, Chien-Kuo Wu, Ya-Ling Chi and Chi-Wen Chang
Graduate School of Physical Education, National Taiwan University of Sport, Taichung, Taiwan
Keywords: Standing Long Jump, Ground Reaction Force, Kinetics.
Abstract: The purpose of this study was to investigate the characteristics of ground reaction force (GRF) for standing
triple long jump with the quantitative analysis of force platform in biomechanics, and also to compare the
differences of GRF and impulse among jump movements and standing long jump. Thirteen high school
athletes participated for this study. Six Kistler force platforms (9260AA6, 1000 Hz) were used to record the
GRF data during the participant performed the movements of standing long jump and standing triple long
jump. The results showed that the every jump distance of standing triple long jump was only the 0.92-0.95
times as the maximal standing long jump. The performance of the 3rd jump was less consistent, because of
the continuous jump movement of task constraint and the larger impact force (4.49 ± 1.53 BW) during
landing.
1 OBJECTIVES
During walking or jogging, the person will perform
the movements in the appropriate or optimal stride
length to adapt the requirements of task or/and
environment. The characteristic of maximum
movement following a maximum movement is an
issue of this study. The movement pattern of
walking or running shows that the main extensors of
lower extremity will be lengthened to decrease the
downward trend during the initial stage of landing,
and the main extensors will shorten immediately to
accelerate the body upward to takeoff.
The standing triple long jump is one of event of
entrance examination of sport related department in
Taiwan. Unlike the submaximal movement of
supporting training, such as double-leg hop
progression, alternate leg bound, etc., the standing
triple long jump is asked to reach the maximal
displacement in two continuous horizontal jumps
following standing long jump. But will the
continuous long jumps following utmost standing
long jump be affected by the larger impact force or
the instable movement? The purpose of this study is
therefore to investigate the characteristics of ground
reaction force (GRF) for standing triple long jump
through the quantitative analysis of force platform,
and to compare the differences of GRF and impulse
among jump movements and standing long jump.
2 METHODS
Thirteen male high school athletes (17.3 ± 0.7 years,
1.71 ± 0.06 cm, 67.7 ± 11.5 kg, mean ± SD)
participated in this study. They were training
regularly without history of lower extremity injuries.
The testing procedures were explained to each
participant. All participants signed an informed
consent form approved by the Ethical Advisory
Committee of Tsaotun Psychiatric Center, Ministry
of Health and Welfare of Taiwan (IRB No: 104022)
before the start of testing.
Participants were instructed to perform standing
long jump and standing triple long jump. Two
successful trials were recorded at each movement.
GRFs were acquired at 1000 Hz using six Kistler
force platfroms (9260AA6) with 64 channels data
acquisition system (5695B) for every jump. The
detail of the set-up of force platforms are shown as
figure 1.
Figure 1: Schematic drawings of the set-up of six force
platforms.
Chen, C., Chan, C., Wu, C., Chi, Y. and Chang, C..
The Ground Reaction Force of Standing Triple Long Jump.
Copyright
c
2015 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
Table 1: Means, standard deviation, and analysis of variance (ANOVA) results for effects of standing triple long jump and
standing long jump (SLJ) on kinematical and GRF variables.
Variable 1st 2nd 3rd SLJ F(3, 36)
η
2
Tukey’s test
Distance (m) 2.61
(0.22)
2.62
(0.29)
2.71
(0.28)
2.85
(0.30)
3.26* .214
SLJ > 1st, 2nd
Takeoff V
x
(m/s) 3.28
(0.13)
3.54
(0.31)
3.81
(0.20)
3.36
(0.17)
23.52* .662
3rd > 2nd > 1st, SLJ
Takeoff V
y
(m/s) 1.75
(0.19)
2.18
(0.27)
2.04
(0.32)
1.83
(0.28)
10.25* .461
2nd > 1st, SLJ;
3rd > 1st
Angle of takeoff (deg) 28.08
(3.08)
31.68
(3.76)
28.01
(3.84)
28.53
(3.62)
5.08* .298
2nd > 1st, 3rd, SLJ
Peak active GRF
x
(N) 778.7
(140.3)
611.6
(130.5)
615.9
(91.7)
789.3
(146.7)
48.46* .802
1st, SLJ > 2nd, 3rd
Peak active GRF
y
(N) 1431.7
(301.2)
2159.3
(391.2)
2137.7
(556.1)
1427.5
(311.5)
49.41* .805
2nd, 3rd > 1st, SLJ
*p < .05. Note: x - horizontal, y – vertical
The first and the second landing positions of
standing triple long jump were estimated by the
center of pressure of force platforms. The total
distance of standing triple long jump was decided by
the center of pressure of force platform 1 plus the
distance from tape measure. The distance of
standing long jump was quantified from the distance
of the center of pressure of force platform 1 and the
center of pressure of force platform 2-3. The vertical
and horizontal center of mass velocities were
estimated using the impulse method.
Repeated measures one way ANOVA with
Tukey’s post-hoc test were applied to examine the
differences in the kinetics and kinematics data
between jumps and landings (α = .05).
3 RESULTS
The analysis of reliability across trials showed the
distances of the first jump, the second jump, the
third jump, and the standing long jump were ICC
= .766, .628, .373, and .876, respectively. The ICCs
across trials of peak active vertical GRFs for each
jump were .889-.991, but the ICCs of peak active
horizontal GRFs for the first jump, the second jump,
the third jump, and the standing long jump
were .970, .884, .726, and .991, respectively.
There were significant differences in the jump
distances, F(3, 36) = 3.26, p = .032, η
2
= .214. The
Tukey’s post-hoc test showed the SLJ was longer
than the first and second jump of standing triple long
jump (table 1). The results of takeoff velocity
showed that the angle of takeoff at the second jump
was the greatest, F(3, 36) = 5.08, p = .005, η
2
= .298.
The statistical results of biomechanical parameters
are showed as Table 1.
4 DISCUSSION
The analysis of reliability showed the distances of
two jump trials of SLJ and the first jump of standing
triple long jump were consistency highly. But the
jump distance of consistencies were reduced during
the second and the third jumps of standing triple
long jump. It indicated that the standing triple long
jump is asked the utmost jumping movement
following two feet landing. The performer had to
adapt the landing impact following the process of
quite long flight, and it increased the variability of
movement to perform the takeoff movement
continually.
The distance of each jump of standing triple long
jump was 92-95% of the maximal SLJ. Although the
statistical analysis showed that the first and second
jumps were less than SLJ, and the distances of three
jumps were no differences. These indicated that the
most performers did not jump longer than the
maximal SLJ during every jump of standing triple
long jump. The initial impact peak in vertical GRFs
were 3.47 BW and 4.49 BW at the second (the first
landing) and third (the second landing) jumps,
respectively. Such higher load of impact force could
inhibit the mechanism of pre-stretch for leg
extensors; as a result, it explained the cause that the
consistency was decreased during the second and
third jump of standing triple long jump.
In conclusion, the results showed that the every
jump distance of standing triple long jump was only
the 0.92-0.95 times as the maximal standing long
jump. The performance of the third jump was less
consistent, because the continuous jump movement
of task constraint and the larger impact force during
landing.
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