Impact of Auditory Listening on Emotional States in Self-paced
Outdoor Running
Klemens Weigl
1,2 a
, Sinja Becker
1 b
, Karolin Bosch
1 c
, Nhien Thai
1 d
and Andreas Riener
1 e
1
Human-Computer Interaction Group, Technische Hochschule Ingolstadt (THI), Esplanade 10, Ingolstadt, Germany
2
Department of Psychology, Catholic University Eichst
¨
att-Ingolstadt, Germany
Keywords:
Music, Audiobook, Emotional States, Portable Technologies, Self-paced Running, Outdoor.
Abstract:
Studies have shown that listening to music may evoke positive emotions when running. In recent years, the
growing trend of listening to audiobooks is also inevitably influencing running. However, to date, there has
been little research on the use of audiobooks in self-paced outdoor running. Therefore, our objective is to
investigate whether self-paced outdoor running with auditory stimuli such as music and audiobooks may elicit
different emotional states when compared to running with no-audio. Consequently, we adopted a repeated-
measures design with three different counter-balanced conditions: music, audiobook, and no-audio. Thereby,
thirty-two recreationally active female and male runners participated in a 10-minute running trial in each con-
dition. We assessed the impact of auditory stimuli and emotional states with the Sports Emotion Questionnaire
and the Brunel Music Rating Inventory-2. Our results of the self-report questionnaires indicate that running
with music is rated with substantially greater values when compared to the audiobook condition. Interestingly,
our findings uncover no meaningful difference among the self-rated emotional state dimensions anxiety, de-
jection, excitement, anger, and happiness across all three conditions, respectively. Hence, we conclude that
running with no-audio may evoke roughly the same emotional states as when compared to running with music
or audiobooks.
1 INTRODUCTION
With increasing digitization and the spread of new
technologies, the way we perceive and consume me-
dia is remarkably changing. Since several years,
portable devices such as MP3 players have gained
widespread popularity amongst runners around the
globe. Thereby, numerous recreationally active as
well as professional runners across age and gen-
der prefer listening to music when running outdoors.
Running has led manufacturers of music-enabled de-
vices to develop ever lighter and more ergonomic de-
vices (Karageorghis, 2016; Bigliassi et al., 2015).
Many runners prefer mobile listening to music by the
use of headphones which may create an acoustic en-
vironment that is set apart from the outside world and
dissociates themselves into a kind of cocoon (Bull,
2015). Beneficial effects of music in sports have espe-
a
https://orcid.org/0000-0003-2674-1061
b
https://orcid.org/0000-0002-2418-2756
c
https://orcid.org/0000-0003-4520-1749
d
https://orcid.org/0000-0003-3160-773X
e
https://orcid.org/0000-0002-9174-8895
cially been found in repetitive activities like running
(Karageorghis and Priest, 2012a; Terry and Kara-
georghis, 2011). In general, musical effects are ex-
plored in the field of exercise and sport in four areas
of research: (1) psychological, (2) psychophysical,
(3) ergogenic, and (4) psychophysiological effects of
music (Terry and Karageorghis, 2011; Karageorghis
et al., 2012; Karageorghis and Priest, 2012a; Kara-
georghis, 2016).
1.1 Audiobooks
Since the advent of mobile technology traditional
books can be provided as a digital audiobook which
is characterized by the small portable format that
creates new affordances and a multitude of possible
applications (Have and Pedersen, 2015). Conceptu-
ally, audiobooks are defined as a recording of a book
that is performed by a professional narrator or the
author (Have and Pedersen, 2015). Affordances can
be advantages such as their convenience, portability,
and supplementary status to other activities, meaning
audiobooks can easily be accessed whilst engaged
Weigl, K., Becker, S., Bosch, K., Thai, N. and Riener, A.
Impact of Auditory Listening on Emotional States in Self-paced Outdoor Running.
DOI: 10.5220/0009980201890196
In Proceedings of the 8th International Conference on Sport Sciences Research and Technology Support (icSPORTS 2020), pages 189-196
ISBN: 978-989-758-481-7
Copyright
c
2020 by SCITEPRESS Science and Technology Publications, Lda. All rights reserved
189
with another activity. Moreover, it was found that
81% of the surveyed audiobook listeners enjoy
audiobooks because they are also able to do other
things in the process of listening, whereby the top
three activities while listening to audiobooks are
driving, relaxing before going to sleep and doing
housework (Audio Publishers Association, 2018).
Consumer studies indicate that the use of smart-
phones for audiobooks accounted for 73% in 2018
and are expected to continue to grow (Audio Publish-
ers Association, 2018). In recent years, audiobooks
have rapidly gained popularity (Audio Publishers
Association, 2019) and listening to audiobooks has
become more accessible and user-friendly thanks to
mobile devices and access to digital downloading
and streaming services (Rubery, 2011; Have and
Pedersen, 2012; Have and Pedersen, 2015). For
instance, the music streaming service Spotify offers a
large library of more than 50 million music tracks, in-
cluding audiobooks, and podcasts. By using Spotify’s
free version with advertisement, users can access a
huge audio catalogue without any charge, while a
pay-per-month subscription allows users to synchro-
nise playlists for offline mobile usage (Spotify USA
Inc, 2020; Kreitz and Niemela, 2010). Moreover,
listening to audiobooks is saving time by enabling
users to simultaneously perform other tasks (Have
and Pedersen, 2015). This empowerment promotes
activity and at least dual-tasking which corresponds
to our modern, fast-paced society. Additionally, user
experience is positively influenced by the enjoyment
of the flexibility of listening to audiobooks wherever
the users are.
Music versus Audiobook
In a direct comparison of the two conditions treadmill
running with music versus treadmill running with an
audiobook, both, ratings of enjoyment were signifi-
cantly higher and ratings of perceived exertion were
substantially lower in the music condition compared
to the audiobook condition, respectively (Miller et al.,
2010). They concluded that the situational context
was more positively altered by music, than by the di-
alog condition audiobook. In a 12-min. cycling-bout,
music reduced ratings of perceived exertion when
compared to an audiobook and a control condition
(Bigliassi et al., 2017). Furthermore, based on mea-
surements with an electroencephalogram (EEG), in
the music condition the attentional focus of the par-
ticipants was reallocated toward auditory pathways,
while inhibiting alpha resynchronization at the Cz
electrode and reducing the spectral coherence val-
ues at Cz-C4 and Cz-Fz and a reduction of the fo-
cal awareness at light-to-moderate-intensities, which
resulted in a more autonomous control of cycle move-
ments in contrast to the two other conditions, re-
spectively. In another self-paced walking study, it
was identified that music induced more dissociative
thoughts by the up-regulation of beta waves as well as
arousal and perceived enjoyment in comparison with
a podcast, and a control condition (Bigliassi et al.,
2019). This reallocation of attention on external stim-
uli in ecologically valid settings elicited more positive
affective responses in the music condition in contrast
to podcast and control.
However, although ratings of perceived exertion
were similar across music, podcast, and no-audio
sprint interval training (SIT) conditions, researcher-
selected motivational music enhanced affective re-
sponses and enjoyment to a greater extend than in the
no-audio control condition, tentatively more than in
the podcast condition (Stork et al., 2019). Moreover,
a higher peak power output could be identified in the
music condition when compared to the podcast and
no-audio condition.
A dialogic condition such as an audibook has re-
ceived scant research attention though it possesses ex-
ternal validity in this exercise domain (Karageorghis
and Priest, 2012a).
1.2 The Present Study
To date, little is known if the increasingly popular
trend of listening to an audiobook may be perceived
as positive as listening to music in the externally valid
context of self-paced outdoor running. Moreover, yet
it is unclear, whether or not emotional states in self-
paced outdoor running are affected and reported sim-
ilarly for running with music, an audiobook, or no-
audio. Consequently, in the present study, we investi-
gated the following research questions (RQ) and hy-
potheses (H):
RQ1: Music versus Audiobook. Do runners prefer
listening to music or to an audiobook in self-paced
running?
H
1
: We hypothesize that runners assign substantially
more positive ratings to the music than to the audio-
book condition in self-paced running.
RQ2: Difference between Emotional States be-
tween Running Conditions. Do runners report
different emotional states when running self-paced
dependent on auditory input?
H
2.1
. We assume that runners assign significantly
more positive ratings to the positive emotional
state dimensions excitement and happiness in the
music condition compared to the audiobook and the
no-audio (baseline) condition in self-paced running.
icSPORTS 2020 - 8th International Conference on Sport Sciences Research and Technology Support
190
Thereby, we expect no meaningful difference be-
tween the audiobook and the no-audio condition.
H
2.2
. We hypothesize runners to assign noticeably
lower ratings to the negative emotional state dimen-
sions anxiety, dejection, and anger in the music
condition compared to the audiobook and the no-
audio (baseline) condition in self-paced running. At
the same time, we assume no considerable difference
between the audiobook and the no-audio condition.
RQ3: Associations of Emotional States and Audio
Ratings. Which associations can be found between
emotional states and audio ratings in self-paced run-
ning?
H
3
. We assume that, in self-paced running, the
self-report emotional state dimensions excitement and
happiness are positively associated with audio ratings,
whereas the self-report dimensions anxiety, dejection,
and anger are negatively associated with audio ratings
in both the music and the audiobook condition.
2 METHOD
2.1 Participants
Thirty-two recreationally active runners (11 female,
21 male) between 19 and 51 years (M = 25.34; SD
= 6.62) were recruited to participate in this study.
Recreationally active was defined as regularly engag-
ing in any strenuous physical activities such as aero-
bic, running, cycling or swimming at least once per
week. According to their own statements, the study
participants spent an average of 3.7 days per week
(SD = 1.89) on strenuous exercise or training and
run on average 6.48 km per unit. Subjects were vol-
unteers and participated without compensation. In
order to engage in the study, potential participants
were required to meet the following inclusion crite-
ria: regular participation in sports exercise for recre-
ational purposes, prior experience in recreational run-
ning, and no contradictions for performing 30 min-
utes at self-paced running. Anyone with orthopedic
limitations which may have prevented them from en-
gaging in 30 minutes of running was excluded. Fur-
thermore, all participants were fluent in [blanked] the
language in which the questionnaires were provided,
consumed no alcohol or drugs, and reported no diag-
nosis of a psychiatric or neurological disorder. Prior
to participating, they were required to provide writ-
ten informed consent. An institutional e-mail was dis-
tributed among members of the university and among
the members of a sports group in [blanked]. The study
information sheet was attached to this e-mail, explain-
ing the objectives and potential risks associated with
the study. The majority of the sample comprised of
students and lecturers.
2.2 Design
We adopted a repeated measures design (3 x 10-
minute of self-paced outdoor running) with three dif-
ferent conditions (independent variable): music (M),
audiobook (A), and control (C). The dependent vari-
ables (DVs) were the five dimensions of the Sports
Emotion Questionnaire and the single-factor of the
Brunel Music Rating Inventory-2 (further described
in 2.3). The study was conducted outdoors in an eco-
logically valid setting with an off-road and flat run-
ning course on the campus (cf. Figure 1) with no alti-
tude difference. The distance of one lap was roughly
450 m.
Figure 1: Flat and off-road running course.
2.3 Measures and Instruments
To assess the psychological impact of auditory
stimuli (M and A) on emotional states and feelings,
we applied the Sports Emotion Questionnaire (SEQ)
(Jones et al., 2005) in each condition (M, A, and C)
and a slightly adapted version of the Brunel Music
Rating Inventory-2 (BMRI-2) (Karageorghis et al.,
2006) in both auditory conditions (M and A).
Sports Emotion Questionnaire
Emotional states and feelings of participants were
measured after each condition using the sport-specific
Sports Emotion Questionnaire (SEQ). The SEQ com-
prises of a 5-factor structure assessing the self-report
emotional state dimensions anxiety, dejection, ex-
Impact of Auditory Listening on Emotional States in Self-paced Outdoor Running
191
citement, anger, and happiness. The questionnaire
inquired participants’ currently perceived emotional
states and feelings by 22 items, each consisting of
an adjective such as ”uneasy“, ”exhilarated“, or
”cheerful“. Participants responded to the items using
a 5-level likert-scale anchored at 0 (not at all) and 4
(extremely).
Brunel Music Rating Inventory-2
To determine participants’ perceived motivational
impact of the auditory conditions M and A, the
Brunel Music Rating Inventory-2 (BMRI-2) was
applied after each auditory listening condition. This
single-factor, six-item instrument, consists of dif-
ferent auditory components: rhythm, style, melody,
tempo, instrumentation, and beat. The response
options were limited to a 7-point Likert scale ranging
from 1 (strongly disagree) to 7 (strongly agree) for
each item, for example, ”The rhythm of the music
would motivate me during exercise” (Karageorghis
et al., 2006, p. 909). Hence, the summated total
score ranges from 6 to 42, which is deemed as a
measure for the motivational quotient of music that
may stimulate or inspire physical activity which is
described as high (36–42), moderate (24–35), and
oudeterous (< 24) (Karageorghis, 2008). Reliability
has been reported between .70 and .90, Cronbach’s
Alpha coefficient with .95, and references to criterion
validity have been stated (Karageorghis et al., 2006).
In the present study, we wanted to compare the
participants’ self-ratings of the motivational quality
of music with the motivational quality of audiobooks.
Henceforward, we applied a slightly modified version
of the BMRI-2 in the audiobook condition in order to
account for these specific motivational qualities (cf.
OSF link below).
Supplementary Materials: Open Science
We support the open science movement and supply
the data set, the music playlist, the modified items of
the BMRI-2, and a detailed description of the mu-
sic and audiobook selection for our study on OSF:
https://osf.io/urymp/.
2.4 Procedure
After a friendly welcome, each participant received
an introduction to the background and the main goal
of the study with all necessary information. Addition-
ally, everyone got a written summary about the study.
Then the information sheet on informed consent was
handed out, which all of them signed. Thereby, ev-
eryone was explicitly informed, that the participation
in this self-paced outdoor running study is voluntary.
In addition, everyone was instructed about the possi-
bility to stop at any time prior to the official end of the
study without receiving any consequences. However,
all of them completed the whole study without facing
any difficulties. After this introductory part, all par-
ticipants started with the initial 10-minute self-paced
running condition (C) with no-audio, which was com-
pleted only with the SEQ. In the next phase, the al-
location of all participants was randomly counterbal-
anced on either of the auditory listening conditions
(M and A). For example, the first participant started
the first 10-minute self-paced running condition with
music. After running, this auditory condition (M) was
rated with the BMRI-2 and the emotional states and
feelings were assessed with the SEQ. Then the par-
ticipant continued with 10-minute self-paced running
with the audiobook. After finishing (A), the BMRI-2
and the SEQ were completed. In contrast, the second
participant first received the A condition, followed by
the M condition, and so on.
Auditory Conditions
We prepared several different devices (MP3, iPod,
Smartphone) for the M (a compilation of tracks from
the most popular Spotify running playlist with a pace
ranging from 150 to 165 beat per minute (BPM)) and
A condition to reduce organizational effort and ease
the participation of the runners. Every participant
could adjust the volume when running. Each auditory
stimuli was played throughout the respective exercise
trial via the participants’ headphones. After 10 min-
utes in operation, the audio automatically stopped,
signaling each participant to come back to the start-
ing point. There the subsequent assessments with the
questionnaires awaited them with a duration of about
5 minutes.
Upon completion of all three conditions, a sheet
with a take-home-message about the study was
handed out, accompanied with the contact and affil-
iation details of the examiner, in case any questions
may arise later on. All data for this study were col-
lected anonymously. The entire participation dura-
tion lasted from approximately 45 to 60 minutes. The
study was carried out over a period of two days under
good weather conditions.
2.5 Statistical Analyses
The significance level has been set to α = .05, if not
stated otherwise (e.g., in case of Bonferroni correc-
tion). Hence, all results with p < α are reported as sta-
tistically significant. Since no negatively coded items
were included in the questionnaire, the total scores
icSPORTS 2020 - 8th International Conference on Sport Sciences Research and Technology Support
192
could be directly calculated for all five dimensions of
the SEQ and the single-factor of the BMRI-2. All
data were analyzed using IBM
R
SPSS
R
Statistics,
Version 25 (IBM Corp., 2017).
RQ1. Because of the rating scale response for-
mat of the BMRI-2, we focused on the single-factor
composite total score for which we could assume at
least pseudo-metric level data. Additionally, Shapiro
Wilk’s test revealed that the assumption of normality
of the BMRI-2 (DV) has been met for both conditions
M and A. Therefore, we applied a two samples depen-
dent t-test.
RQ2. Since the five emotional state dimensions of the
SEQ (DVs) are assessed with a Likert scale response
format yielding ordinal data, we applied the nonpara-
metric Friedman test for repeated measures with the
three conditions (i.e., M, A, and C) as within-subjects-
factor (IV). Moreover, normal distribution has not
been met for the negative emotional state dimensions
anxiety, dejection, and anger in either of the three con-
ditions.
RQ3. Given the ordinal data of the SEQ we applied
the nonparametric Spearman rank correlation.
Supplementary Analysis. In a supplementary and
exploratory statistical analysis, we performed a mul-
tiple linear regression analysis with the stepwise se-
lection method for the M and the A condition, respec-
tively.
3 RESULTS
We investigated the following three research ques-
tions (RQ1 to RQ3) with the accompanying two-sided
alternative hypotheses of interest (H
1
, H
2.1
, H
2.2
, and
H
3
). In addition, we performed supplementary statis-
tical analysis to identify any emotional states as pre-
dictors for music ratings.
RQ1: Music versus Audiobook.
In the beginning, we tested our first hypothesis H
1
,
that recreationally active runners assign substantially
greater positive ratings to the M than to the A condi-
tion on various musical components (rhythm, style,
melody, tempo, instrumentation, and beat) in self-
paced running. Thereby, we identified a large effect
(t(30) = 4.44; p = .000; Cohen’s d = .80; Power =
99%) in favor for the M condition (M = 27.84; SD =
7.01) compared to the A condition (M = 20.81; SD =
8.59). Therefore, we could assume that the M condi-
tion is substantially higher rated than the A condition,
what yielded to an acceptance of H
1
.
RQ2: Difference between Emotional States be-
tween the Running Conditions.
To investigate our second RQ, we thematically subdi-
vided our five self-report emotional state dimensions
into positive (i.e., excitement and happiness; cf. H
2.1
)
and negative (i.e., anxiety, dejection, and anger; cf.
H
2.2
) emotional state assessments. For each of the ve
emotional state dimensions a separate statistical anal-
ysis with the Friedman test was performed to compare
all three running conditions M, A, and C. Because
of multiple testing, we applied the Bonferroni proce-
dure to avoid alpha inflation and adjusted the nominal
alpha level to α
Bon f.corr.
= .01 for each condition to
maintain the overall alpha level of α = .05.
Positive Emotional States. We tested our second hy-
pothesis H
2.1
if runners assign significantly more pos-
itive ratings to the positive self-report emotional state
dimensions excitement and happiness in the M condi-
tion compared to the A and the C condition, while we
assumed no difference between A and C. Our results
indicate no difference between all three conditions for
excitement (χ
2
(2, N = 32) = 1.63, p = .443) and for
happiness (χ
2
(2, N = 32) = 4.5, p = .105), respec-
tively. Hence, we could not confirm our hypothesis
H
2.1
.
Negative Emotional States. Henceforward, we
tested our third hypothesis H
2.2
if runners assign sig-
nificantly more positive ratings to the negative self-
report emotional state dimensions anxiety, dejection,
and anger in the M condition compared to the A
and the C condition, whereby we expect no differ-
ence between A and C. Based on the necessary Bon-
ferroni correction to control for the family-wise er-
ror rate, we found no difference between all three
conditions for either of the emotional state dimen-
sions anxiety (χ
2
(2, N = 32) = 4.67, p = .097), de-
jection (χ
2
(2, N = 32) = 6.07, p = .048), and anger
(χ
2
(2, N = 32) = 3.89, p = .143). This finding did
not yield an assumption of our hypothesis H
2.2
.
RQ3: Associations of Emotional States and Au-
dio Ratings. Additionally, we analysed whether the
dimensions excitement and happiness are positively
associated with audio ratings of the BMRI-2, and if
the dimensions anxiety, dejection, and anger are neg-
atively associated with audio ratings in both auditory
condition M and A (H
3
). We found particularly strong
and positive correlations for the positive dimensions
excitement and happiness in both conditions M and
A (cf. Table 1). Moreover, we uncovered consis-
tently negative but weak correlations for the dimen-
sions anxiety, dejection, and anger for the M and A
condition, respectively. Thereby, only the dimension
anger in the M condition revealed a sufficiently large
effect, whereas the others showed no significant rela-
tionship (cf. Table 1). Therefore, the hypothesis H
3
can only be partly confirmed, but especially for the
positive dimensions excitement and happiness.
Impact of Auditory Listening on Emotional States in Self-paced Outdoor Running
193
Table 1: Spearman Correlations of Emotional State Dimensions (SEQ) and Audio Ratings (BMRI-2).
Emotional State Dimensions
Audio Ratings Anxiety Dejection Excitement Anger Happiness
Music Condition r -.21 -.31 .55* -.45* .51*
p .250 .082 .001 .009 .003
Audiobook Condition r -.22 -.27 .64* -.28 .70
p .233 .149 .000 .132 .000
Note. N = 32. *Significant at the Bonferroni-corrected level α = .01 (two-sided) for each condition.
Supplementary Statistical Analysis: Prediction of
BMRI-2. Based on the previous correlational find-
ings, we were interested whether any of the five emo-
tional state dimensions may positively or negatively
predict the auditory rating of the BMRI-2 (criterion
variable). We performed multiple linear regression
analyses with stepwise selection. We identified the
emotional state dimension happiness as a stable pre-
dictor for positive BMRI-2 ratings for the M (ex-
plained variation R
2
= .31) and the A condition (ex-
plained variation R
2
= .48; cf. Table 2).
4 DISCUSSION
The primary purpose of this study was to investigate
whether self-paced running with music or an audio-
book is perceived and rated more positive than the
other condition (RQ1.) In line with prior findings
in the literature (Miller et al., 2010; Bigliassi et al.,
2017; Bigliassi et al., 2019; Stork et al., 2019) we
could confirm, that in the M condition substantially
more positive audio ratings were assigned when com-
pared to the A condition. However, none of the
previous studies focused on self-paced running with
a researcher-selected audiobook with an overwhelm-
ingly rating as funny. As we expected, the potential
additional humorous induction of the funny audio-
book did not affect auditory ratings in terms of per-
ceived inspiration for self-paced running. In contrast,
the overall total score of the BMRI-2 of all runners
can be categorized as oudeterous (< 24, neither moti-
vating nor demotivating; cf. Karageorghis, 2008) for
the A condition (M = 20.81), and moderately inspir-
ing (range 24 to 35) for the M condition (M = 27.84).
Our secondary purpose of the present study was to
examine if different self-paced running conditions M,
A, and C may evolve more positive or more negative
emotional states (RQ2.) Several studies have found
smaller or larger effects of music of enhancing
the reallocation of attentional focus to distract and
dissociate from the sensation of boredom, pain, and
fatigue (Morgan and Pollock, 1977; Atkinson et al.,
2004; Edworthy and Waring, 2006; Karageorghis
and Priest, 2012b; Bigliassi et al., 2015; Bigliassi
et al., 2017; Bigliassi et al., 2019). However, our
investigation focused only on a potential perceived
and self-reported emotional state difference among
the three conditions M, A, and C, and not on the pos-
sible reallocation of attentional focus. Nevertheless,
our findings indicated no difference in self-reported
emotional state dimension in any of the three condi-
tions. Hence, we could not identify any substantial
benefits in favor for any auditory condition, neither
M, nor A, and we have to acknowledge that running
with no-audio may elicit roughly the same emotional
states in self-paced outdoor running.
Our third purpose was to assess any potential as-
sociations among self-reported emotional states such
as anxiety, dejection, excitement, anger, and happi-
ness in the M and A condition and the self ratings
for the preferences of the auditory conditions (RQ3).
Of course, we did not focus on any associations in
the C (baseline) condition with no-audio, because of
no auditory ratings in this condition. As expected,
more positive auditory ratings were associated with
more positive ratings of the positive emotional state
dimensions excitement and happiness. This finding
is very plausible, also because of the negative,
though weak and not significant correlations of the
auditory ratings (except anger in the M condition, cf.
Table 1) and the negatively deemed emotional state
dimensions anxiety, dejection, and anger (the later
only for the A condition). Hence, we may conclude
that negative emotions may have a slight but potential
impact on negative auditory ratings.
Based on the correlational findings (cf. RQ3),
we conducted additional supplementary statistical
analysis to possible identify any emotional state(s)
as predictor(s) for auditory ratings. Henceforward,
we performed a multiple linear regression analysis
with stepwise selection of any variable as potential
predictor of the criterion variable (BMRI-2). In both
auditory conditions M and A, the perceived and
self-reported emotional state happiness was iden-
tified as solid predictor (also in terms of explained
variations, cf. R
2
= .31 for the M and R
2
= .48 for
the A condition; cf. Table 2). Interestingly, though
the emotional state dimension excitement revealed
substantial positive associations with the auditory rat-
icSPORTS 2020 - 8th International Conference on Sport Sciences Research and Technology Support
194
Table 2: Multiple Linear Regression with Stepwise Selection: Prediction of Audio Ratings (BMRI-2).
Condition Variable
a
B SE t p 95% CI R
2
Music Happiness 4.84 1.33 3.64 .001* [2.13, 7.56] .31
Anxiety (excluded as predictor by stepwise selection)
Dejection (excluded as predictor by stepwise selection)
Excitement (excluded as predictor by stepwise selection)
Anger (excluded as predictor by stepwise selection)
Audiobook Happiness 5.49 1.06 5.17 .000* [3.32, 7.66] .48
Anxiety (excluded as predictor by stepwise selection)
Dejection (excluded as predictor by stepwise selection)
Excitement (excluded as predictor by stepwise selection)
Anger (excluded as predictor by stepwise selection)
Note. N = 32. Unstandardized regression coefficient B and standard error (SE);
CI = confidence interval;
a
Emotional state dimensions of SEQ.
*p < .05.
ings (cf. Table 1), in both linear regression analyses
it was excluded as predictor as well as the emotional
state dimensions anxiety, dejection, and anger.
Although several studies have been con-
ducted with researcher-selected (also referred to
as experimenter-selected) music-playlists (Atkinson
et al., 2004; Edworthy and Waring, 2006; Miller
et al., 2010; Stork et al., 2019), we cannot exclude
that personally selected songs may have elicited more
positive affective reactions. However, it was found
that in a direct comparison of experimenter-selected
versus self-selected music in sports, participants
assigned roughly the same ratings (Moss et al.,
2018). Conversely, this might prove difficult if the
sample size would be increased, and it would be
critical to create a seriously standardized M condition
what could negatively influence potential positive
findings. In this case, it should be ensured to select
only music with the same BPM of the same genre
with the same loudness (db).
Another potential limitation is that the audiobook
excerpt chosen for the experiment was no classic
novel narrative, but a live recording of a reading by
the author, including background noises and audience
laughter. Some test persons stated that they experi-
enced this laughter as irritating or odd for the context
of running. This aligns with qualitative responses
from participants who stated that the narrator’s voice
appeared monotonous, as they missed the usual
driving forces of rhythm and melody. Research has
identified that responsiveness to music in exercise
stems from musical qualities such as rhythm, melody
and harmony (Karageorghis, 2016). Nevertheless,
the majority of participants post-activity stated that
the audiobook was quite pleasant and humorous.
Some participants have expressed that the story was
so capitivating that they forgot about the time when
running. What should be noted in this regard is that
the majority of the participants reported no previous
use of audiobooks during running. Listening to an
audiobook may therefore have elicited a novelty
effect that would subsequently have been reduced
with repeated exposure.
Apart from this, in future studies, a single-item
liking scale, ranging from 1 (I do not like it at all)
to 10 (I like it very much), could be considered to
identify the degree to which participants preferred
the condition (Bigliassi et al., 2017).
5 CONCLUSION
For the last decades, running has made the use of
portable technologies such as listening to music for
individual training very popular. However, the newly
emerging trend of listening to audiobooks while run-
ning has only been scantly researched. So far there
has been no study focusing on emotional states and
listening to humorous audiobooks in recreational self-
paced outdoor running. Primarily, our results revealed
a clear preference in favor for auditory self-ratings
of self-paced outdoor running with music when com-
pared to audiobooks. Interestingly, we identified no
self-reported affective differences in the emotional
state dimensions such as anxiety, dejection, excite-
ment, anger, and happiness across all three conditions
when running with music, audiobooks, and no-audio
(baseline), respectively. Hence, we assume that self-
paced outdoor running with no auditory listening may
elicit the same emotional states as evoked by self-
paced outdoor running music or audiobooks.
In future research, it would be interesting to study
the music-emotion and the audiobook-emotion link
also under high physical exertion. Additionally, in
contrast to many studies, it would be important to in-
vestigate whether outdoor running with an audiobook
Impact of Auditory Listening on Emotional States in Self-paced Outdoor Running
195
may have a positive effect in running sessions with a
longer duration than 10 to 15 minutes. Furthermore,
different genres of audiobooks such as novels from
mystery, to thriller, and biographies should also be
considered.
Finally, we conclude that even simple self-paced
running in the nature with no-audio may elicit the
same emotional states as when compared to running
with portable auditory technologies such as music and
audiobooks.
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