Testing the Reliability and Validity of the XOS Motion Capture
System at Measuring Counter Movement Vertical Jump
Suzanne M. Konz and David Cottrill
Marshall University, Huntington WV, U.S.A.
Keywords: CMVJ, Measurement, Instrumentation, Reliability.
Abstract: The purpose of this study was to conduct simultaneous measurement of counter movement vertical jump
height using the XOS motion capture system and the Vertec system. Ten participants (body height: 170.17
cm ± 13.4, body weight: 79.76 kg ± 17.72) from the Marshall University student body comprised the testing
group. Participants were instructed on proper counter movement vertical jump technique. Five practice
jumps at 50% effort were conducted. Participants donned a compression suit with reflective markers. The
paired t-tests indicated that a difference existed in counter movement vertical jump height measured
between the Vertec and the XOS vertical jump was (p < 0.001), SEM of 1.4 with a .823 correlation and the
Vertec and the XOS center of gravity was also (p < 0.001), SEM of 1.42 with a correlation of .788. A
marked difference exists between the XOS SportMotion capture system’s methods of measuring counter
movement vertical jump height when compared to the Vertec measurement.
1 INTRODUCTION
Motion analysis systems are a widely used tool in
performance enhancement, biomechanical analysis,
and injury assessment. These systems provide users
with important information to guide the
improvement of function. The reliability and validity
of the information of these systems is vital.
Reliability is the degree to which an experiment,
test, or measuring procedure produces stable and
consistent results. Reliability for measurement
systems like these are concerned with concepts like
stability, reliability, and internal consistency
(Vincent, 2009). More importantly however, these
systems require validity to be able to be of value as
true measurement tool. The validity of a system tells
the user how well it measures what is supposedly
measures.
The XOS SportMotion system (Motion Reality,
Inc. Marietta, GA) is a relatively new technology
platform built upon the most modern advances in 3-
D Motion Capture and Analysis technology.
According to the company’s website, SportMotion is
the world's first 3-D motion capture system
specifically designed to help measure an athlete's
performance, aid in rehabilitation, assist in training
and become an effective teaching tool (Motion
Reality 2014). The technology of the XOS
SportMotion system is similar to that used to
produce movies and video games, but is customized
to specifically serve the functional and usability
needs for athletes. The system is marketed as a
convenient device to use to improve performance
within the strength and conditioning and team
specific areas. Several professional teams in the
MBL and NFL along with NCAA-I teams use this
system to improve athlete performance. It is not
used typically for quantitative research purposes.
A component of the XOS SportMotion system is
the measurement of counter movement vertical jump
height (CMVJH). This CMVJH data, normally
provided through physical measurement using a
Vertec (Vertec Sports Imports, Hilliard, OH)
measuring device, is typically generated through
tracking the subject’s center of mass (COM) (Isaacs,
1998). The difference between the resting height of
COM and the peak height during the jump is
presented as CMVJH. In addition to tracking COM
travel, certain systems, such as the XOS motion
capture system calculate CMVJH through
measurement of the time the subject is off the
ground. This method is employed by Jump Mat
systems, and has been found to be comparable to
Vertec and center of gravity (COG) tracking
methods (Isaacs 1998, Pond, Verducci et al. 2003,
Leard, Cirillo et al. 2007)
The Vertec CMVJ testing system is device
typically used by universities and high schools to
5
M. Konz S. and Cottrill D..
Testing the Reliability and Validity of the XOS Motion Capture System at Measuring Counter Movement Vertical Jump.
DOI: 10.5220/0005094500050010
In Proceedings of the 2nd International Congress on Sports Sciences Research and Technology Support (icSPORTS-2014), pages 5-10
ISBN: 978-989-758-057-4
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
test athlete vertical jump height. It is considered the
testing device of choice due to the low coast and
high reliability. The Vertec device requires an
athlete to maximally reach for the object while
jumping. The measuring device is widely used in
athletic testing due to its simplicity. The Vertec
(Vertec Sports Imports, Hilliard, OH) consists of a
series of colored plastic vanes that are placed 0.0127
m apart on a telescoping aluminum pole that can be
adjusted to the subject’s standing reach. The subject
performs a maximal jump and swats at the plastic
vanes at the peak of the jump. Vertical jump height
is measured as the vertical distance between the
standing reach and the highest vane displaced by the
subject’s hand at the peak of the jump. Jump height
assessed by the Vertec is determined by subtracting
the standing height or reach height by the maximum
jumping height or reach height using procedures
such as Sargent’s, Abalakov’s, and Starosta’s, jump
tests (Klavora, 2000; Starosta & Radzinska, 2001).
As such the reliability and validity of the XOS
SportMotion system is not known. To date, no
studies testing the reliability of the XOS system’s
measurement methods in comparison to the gold
standard Vertec measurement system exist
(
Hutchinson Issacs 1998, Petushek 2010, Pond 2003).
From a research perspective, the gold standard is
either 3-D motion analysis or force plate. The
question at hand is how reliable and valid is the
XOS SportMotion system. The purpose of this study
is to conduct simultaneous measurement of CMVJH
using the XOS motion capture system and the
Vertec system. The comparison of these results will
help determine the reliability and validity of the
XOS system in measuring jump height compared to
a verified measurement system.
2 METHODS
Prior to experimental testing, project approval was
obtained from the Marshall University Institutional
Review Board. Ten participants (body height:
170.17 cm ± 13.4, body mass: 79.76 kg ± 17.72)
from the Marshall University student body
comprised the testing group. Participants included
four male (body height: 177.80 cm ± 9.51, body
mass: 81.13 kg ± 8.45) and six females (body
height: 165.09 m ± 14.67, body mass: 78.85 kg ±
23.77). All subjects signed informed consent and
were able to withdraw at any time during the course
of the study.
Clothing/
Strap
#
of
M
arkers
Location
1 Shirt 12 2 markers top of shoulders
3 markers across top of back
2 markers in center of back
1 marker on sternum
2 markers on side of each upper arm
1 Belt 4 2 markers side of waist
2 markers back of waist
1 Cap 4 2 markers on top of head
2 markers in front
2 Wrist
Straps
2/wrist 1 marker on outside of wrist
1 marker on inside of wrist
2 Knee
Straps
2/knee 1 maker centered below knee on leg
1 marker on outside of shin
2 Shoe
Covers
4/foot 2 markers on top of shoe
1 maker at center of heel
1 maker centered on outside of foot
Figure 1: “Marker placement”.
The XOS Sport Motion system (Motion Reality,
Inc. Marietta, GA) is an infrared tracking system
that provides instant three-dimensional motion
feedback to assist in the training and performance
evaluation of athletes for all levels. The XOS
system housed in this laboratory utilizes 24 cameras.
Each XOS Sport Motion system contains three
options for specific data collection: golf, baseball,
and free play. The option selected determines the
size of the calibration space and the number of
cameras used. The golf option uses the smallest
space and only eight of the 24 cameras. The free
play option uses the largest space and all 24 camers.
The free play option allows the user to be creative
with the data collected. Items that can be tested
include vertical jump, broad jump, and tracking of
weight lifting technique. This study utilized the free
play option. Multiple requests for further
information on the process by which the system
processess and calculates were not met due to the
proprietary nature of this information.
The XOS Sport Motion system was calibrated
each testing day according to the systems required
means. This is a two phase process. The first phase
begins with placing the reflective wand on three
specific locations spaced 3 meters apart followed
byplacing the wand in locations around the oustide
of the free play area in a vertical direction. The
system notifies the user when all 24 of the cameras
have recognized the wand and the location
plaements. The second phase is the typical sweeping
of the inside of the calibrated space. The system then
combines these to actions to calibrate the space. The
system is ready for data collection with a successful
calibration.
icSPORTS2014-InternationalCongressonSportSciencesResearchandTechnologySupport
6
Users of the XOS Sport Motion don a compression
suit with 36 reflective markers located at specific
locations (See Figure 1). Four additional markers are
attached to the suit as part of the global reference
component. Two global markers are placed on the
anterior chest at the shoulder joint area. The other
two global markers are placed in the general
location of the hip, usually over the greater
trochanter. This makes a total of 40 reflective
markers associated with the compression suit. The
additional four markers are removed once an avatar
is generated. These markers allow the XOS system
to generate an avatar model that is displayed to
allow the athlete to view the skill for feedback. The
avatar comes in only two versions: a male and
female avatar. The avatar adjusts its look based upon
the distribution of the markers in the known pattern
for the individual
The 28 reflective markers used for data
collection are not placed on the joint axis as required
by most infrared tracking systems. Rather, the
markers are placed in unique placements to fit a
specific pattern (See Figure 1). The interesting
component here is that the locations per the user
guide manual are very generalized locations.
However, during training the representatives used
anatomical reference points for the location of
several of the markers.
Participants for this study donned the
compression suit. 36 permanent and 4 temporary
global markers were placed according to company
standards. Participants were instructed on proper
CMVJ (counter movement vertical jump) technique
and use of the Vertec (Vertec Sports Imports,
Hilliard, OH) during CMVJ testing. Reach height
for the Vertec was established using the following
body position: erect stance, both feet together and
flat on the ground, both arms fully extended
overhead, and the head and eyes level (Issacs 1998).
Instructions on the CMJ technique were then
provided. This technique required subjects to start in
an upright position with the feet parallel to each
other and hip to shoulder width apart. The subject
then performed a quick countermovement drop into
a quarter-squat position by flexing the hips and
knees into a semi-squat position while swinging
their arms back to prepare for the jump. After
reaching their preferred depth of descent, subjects
explosively extended at the knees and hips, and
plantar flexed at the ankles in an effort to attain a
maximal jump height. During the concentric and
flight phases of the jumps, subjects were required to
maintain a level head position (i. e., not looking
Figure 2: “T-position”.
upward at the Vertec vanes) while reaching upward
with both hands simultaneously (Issacs 1998).The
arms swing forward above their head as they jump
straight up into the air, landing on both feet at the
same time (Harman 1990). Arm swing has been
shown to influence vertical jump height (Lees 2004)
and performance biomechanics (Lees 2004).
Five practice jumps at 50% effort were
conducted to ensure understanding of appropriate
technique. A rest period of at least 60 seconds
between each jump occurred during familiarization
to provide feedback on improving the participant’s
technique along with recovery. After familiarization
was complete, participants left the room to allow for
a noise elimination procedure which is required by
the XOS system. This part of the avatar generation
process required by the system. Upon completion of
the noise elimination, the participants re-entered the
room and took their place within the calibrated
space. The system began the process of generating
an avatar model for each participant at this time.
This was accomplished by having the participant
stand within the calibrated space in a “t-position” as
the system went through the process of recognizing
the reflective marker pattern. The t-position finds the
subject standing in an erect posture with the feet
approximately shoulder width apart while the
shoulders are abducted to approximately ninety
degrees (See Figure 2). The participant’s avatar is
generated after the system recognizes the reflective
markers being in the correct configuration and
locations.
With the avatar generated, participants again
entered the calibrated space and conducted three
CMVJ trials separated by 60 seconds of rest. During
these trials, jump height was measured
TestingtheReliabilityandValidityoftheXOSMotionCaptureSystematMeasuringCounterMovementVerticalJump
7
simultaneously by the XOS system and the Vertec.
Vertec data was collected by the same researcher
who provided the instruction on CMVJ technique.
The XOS data measured the calculated center of
gravity travelled and vertical jump height through
proprietary software. Data was analyzed using SPSS
(IBM, Armonk, New York). Descriptive statistics,
paired t-tests, and intraclass correlation coefficients
(ICC 1,3 and ICC 2,3) analysis were completed.
Significance was set at the 0.05 level. ICC 1,3 was
run to investigate the reliability and validity for each
type of CMVJ test. An ICC 2,3 determined the
reliability of the XOS Sport Motion CMVJ testing
against the Vertec.
3 RESULTS
Descriptive statistics are presented in Table 1. The
paired t-tests indicated that a difference existed in
CMVJ height measured. The significance for the
comparison between CMVJ height measured
between the Vertec and the XOS VJ (XOS vertical
jump) was (p < 0.001), SEM(standard error of the
mean) of 1.4 with a .823 correlation The
significance for the comparison between CMVJ
height measured between the Vertec and the XOS
COG (XOS center of gravity) was also (p < 0.001),
SEM of 1.42 with a correlation of .788.
The vertical jump height measured with the
Vertec ranged from 31.75 cm to 82.55 cm. The
vertical jump height measured with the XOS VJ
ranged from 23.68 cm to 61.47 cm. The reliability
(ICC 1,3) of the Vertec measures was 0.97. The
SE
m
(Standard error of Measurement) for the Vertec
measures was 0.0004. A MCD (minimal clinical
difference) for the Vertec was 3.58. The reliability
(ICC 1,3) of XOS VJ measures was 0.936. The SE
m
for the XOS VJ measures was 0.016 with an MCD
of 2.69. The reliability (ICC 2,3) for the Vertec and
the XOS VJ was .871.
The vertical jump height measured with the XOS
COG ranged from 30.734 cm to 62.23 cm. The
reliability (ICC 1,3) of the Vertec measures again
was 0.97. Again, the SE
m
for the Vertec measures
was 0.0004. An MCD for the Vertec was 0.005. The
reliability (ICC 1,3) of XOS COG measures was
0.945. The SE
m
for the XOS COG measures was
2.46 cm. And, a MCD calculated at 3.54. The
reliability (ICC 2,3) for the Vertec and the XOS
COG was .833.
Table 1: Descriptive Statistics.
Device Group Mean ± Std. Dev. (cm)
Vertec
All 49.66 ± 12.56
M 59.16 ± 13.41
F 43.32 ± 6.82
XOS VJ
All 39.38 ± 13.46
M 53.41 ± 8.83
F 30.03 ± 5.53
XOS COG
All 43.46 ± 9.42
M 52.87 ± 5.65
F 37.24 ± 5.23
4 DISCUSSION
All three means of measurement demonstrated
adequate individual reliability. This means that the
each of the systems measured CMVJH consistently.
However, the validity of the XOS system’s
measurements did not prove as great as the Vertec.
An interesting situation was noted with two of our
subjects that demonstrated part of the problem with
the internal consistency with the XOS system. Two
subjects (subject 5 and 9) had Vertec measurements
of 82.55 cm for their CMVJ. XOS SportMotion
calculated the XOS VJ at 66.55 cm and 53.34 cm for
subject 5’s CMVJ heights. Subject 9’s CMVJ height
at 82.55 cm was calculated at 54.61 cm. These
differences show that there is a lack of consistency
within the calculation of XOS VJ height.
XOS SportMotion system has two definitions
attached to the label "COG". One is used to calculate
the COG path (actual and floor projected) and the
other is used for the calculation of the vertical and
horizontal jump functions. In the vertical jump
function, the 3D location designated as the COG is
actually approximated to the origin of the waist
body in the skeleton (See Figure 1). During the
scaling process, the system optimizes this location
based on the placement of the markers, for both
capture and scaling, identified during said scaling
process. The vertical distance measurement is the
difference between the take-off height and peak
height of this COG location; where the take-off
frame is calculated as the frame where both feet
have been deemed to have left the floor plane. The
feet are calculated to have left the floor when both
heels are more than 4 inches above the floor plane.
The heel is approximated as the points located 3
inches below each ankle. Landing occurs at the
frame where at least one of the heel locations is back
icSPORTS2014-InternationalCongressonSportSciencesResearchandTechnologySupport
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within 4 inches of the floor plane. This method of
calculation does not take in to account that most
individuals will land on the forefoot to provide a
triple absorption of force through ankles, knees, and
hips (Motion Reality 2014). With information
provided by Motion Reality, Inc, the XOS system
software appears to calculate jump height by using
total time the subject spends off the ground. These
XOS COG data seems to calculated with the
following equation:
∗
,
where t represents time off the ground and G the
gravitational constant to confirm or refute this
assumption (Isaacs 1998, Pond, Verducci et al.
2003, Leard, Cirillo et al. 2007). However, we could
not get this confirmed by the company.
The company’s marker placement may be a
source of error when it comes to the reliability and
validity of the XOS Sport Motion. The traditional
infrared 3-D motion analysis system requires the
placement of reflective markers at the joint centers
to assist in determining segment lengths, kinematics,
and kinetics. The XOS system is looking for specific
patterns and not locations to develop the avatar. The
company instructions on marker location are part of
the issue.
The shirt has 12 markers placed on it. Two
markers are placed on the top of shoulders, three
markers across top of back, two markers in center of
back, one marker on sternum, and two markers on
side of each upper arm. The instructions don’t give
clear expectations of this placement. The shoulder
makers are placed on the AC joint. The three
markers on the top of the back are equally
distributed across the back. The center markers on
the back again are distributed equal at the mid-back
level of the participant. The marker on the sternum
is located on the upper portion. And the two markers
on the side of the arm are placed at the elbow and at
a location that is 1/3 down the upper arm from the
shoulder marker. Unless you had knowledge of the
location from training by company representatives
you would not know the locations the system
expects in order to recognize and generate the
avatar.
The belt worn at the waist requires four markers:
two on the side and two on the posterior side. The
system expects these markers at the ASIS and L4-L5
location. The cap also has 4 markers. 2 are located at
the front and 2 on top. An issue occurs with
overweight individuals at the ASIS markers. The
markers on the belt rotate downward toward the
floor due to the material of the belt. The altered
positions make it difficult for the cameras to see the
markers. The cap has four markers as well. The
instructions list 2 at the front and 2 on the top of the
head. However, the system wants one marker at
either temple, one on top of the head, and one at the
back of the head. This posterior head marker
becomes an issue with females having long hair.
The wrist, knees, and feet straps the company
uses also present challenges for the system to
recognize. Each of the wrist and knee straps has two
markers for each of the extremities. The wrist strap
help the system understand pronation and supination
of the forearm. In order to accomplish this, the
system needs to see an offset of the markers at the
wrist. However, the instructions provided by the
company lists that one marker be attached on outside
of wrist and one marker on inside of wrist. The
system does have a hard time determining which
marker is on the outside and which is on the inside
of the wrist. As a result, the avatar does not always
generate a correct model or the model will have a
“twitch” in the hand and wrist area. The feet require
the subject to wear shoes and covers are placed over
the participant’s shoes. Each shoe cover has four
markers. The four markers are instructed to be
located at on top of shoe, at center of heel, and
centered on outside of foot. In reality, the two
markers need to be located on the great toe and 5
th
digit, one marker is located at the center of the heel,
and one marker is located on the 5
th
metatarsal. An
issue here is the size of the shoe covers does not
allow for the larger feet of many athletes. This
makes it difficult for appropriate marker locations to
be provided.
The system introduces error into the calculations
provided to users in a couple ways. The calculation
of the jump height provides much of the error.
Marker placement is also a source of error. Both of
these lend to decrease reliability and validity on the
XOS Sport Motion system.
5 CONCLUSIONS
Based on initial data analysis, there is a marked
difference between the XOS SportMotion capture
system’s methods of measuring CMVJ height when
compared to Vertec measurement. XOS
SportMotion does provide a reliable means of
measuring CMVJ; however, the measurements
provided are not at the same level of validity as the
Vertec system. Individuals using the XOS
TestingtheReliabilityandValidityoftheXOSMotionCaptureSystematMeasuringCounterMovementVerticalJump
9
SportMotion system need to keep this in mind when
using this particular component to evaluate athlete
performance. Interpretation of these results confines
generalization to recreationally active college-aged
students. Future studies should test other suitable
populations such as the athletes.
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