Internal Consistency of Physiological Responses during Exposure to

Emotional Stimuli using Biosensors

Eun-Hye Jang

, Ah-Young Kim

, Sang-Hyeob Kim

, Han-Young Yu

and Jin-Hun Sohn

Bio-Medical IT Convergence Research Department, Electronics and Telecommunications Research Institute,

Gajeongno, Yuseong-gu, Daejeon, Republic of Korea

Department of Psychology, Brain Research Institute, Chungnam National University,

Daehak-ro, Yuseong-gu, Daejeon, Republic of Korea

Keywords: Consistency, Biosensor, Physiological Response, Emotion.

Abstract: In biomedical engineering application, mental/physical health monitoring using biosensors has been lately

noticed because bio-signal acquisition by non-invasive sensors is relatively simple as well as bio-signal is

less sensitive to social/cultural difference. In particular, although it is known that they are significantly

correlated with human emotional state, whether the signals by various emotions are stable remains unknown.

In this study, we examined the consistency of physiological responses induced by six basic emotions,

happiness, sadness, anger, fear, disgust and surprise using an experiment that was repeated 10 times. Twelve

college subjects participated in this experiment. For emotion induction, sixty different emotional stimuli

were selected in a pilot experiment. Heart Rate (HR), Skin Conductance Level (SCL), mean of Skin

Temperature (meanSKT), and mean of Photoplethysmograph (meanPPG) were measured before the

presentation of stimuli as a baseline and during the presentation of the stimuli as emotional state. The results

showed that physiological responses during emotional states for the 10 times the experiment was repeated

were stable and consistent compared to the baseline. In particular, we could identify that physiological

features such as SCL, HR, and PPG are very reliable. Our results suggest that bio-signals by six emotions

are consistent over time regardless of various stimuli. This means that physiological responses are reliable

and biosensors are useful tool for emotion recognition.

1 INTRODUCTION

In biomedical engineering application, recent studies

have noted to improve health and wellbeing with the

help of Information and Communication Technology

(ICT) and in particular, mental/physical health

monitoring using biosensors has mainly done

because signal acquisition by non-invasive sensors is

relatively simple as well as biosignal is less sensitive

to social/cultural difference. Also, it is known that

several biosignals are significantly correlated with

human emotional state (Drummond and Quah, 2001;

Tefas, Kotropoulos, and Pitas, 2001). To provide

more effective wellbeing service, it is considered to

understand and recognize the emotions of humans.

However, a stability or reliability of physiological

responses related to emotional state using biosensors

remains unsolved (Hinz, Hueber, Schreinicke and

Seibt, 2002). To overcome this limitation, there were

many works which examine the temporal stability of

physiological responses using biosensors (Lacey and

Lacey, 1962; Fredrikson et al., 1985; Robinson,

Whitsett, and Kaplan, 1987; Waters, Williamson,

Bernard, Blouin and Faulstich, 1987; Arena,

Goldberg, Saul and Hobbs, 1989; Marwitz and

Stemmler, 1998). Some studies focused on proving

the stability and consistency of the physiological

response by introducing different time interval (e.g.,

2 weeks or 4 weeks) or using different kinds of

biomarkers (e.g., blinking responses, RSA, heart

period, and salivary cortisol, startle response)

(Manber, Allen, Burton and Kaszniak, 2000; Larson,

Ruffalo, Nietert and Davidson, 2000; Bradley,

Gianaros and Lang, 1995; Doussard-Roosevelt,

Montgomery and Porges, 2003). However, they

didn’t verify the consistency of physiological

responses over a relatively long period of time and

the stimuli with different contexts because the

physiological measures with the identical stimuli are

only twice within a relatively shorter period of

110

Jang, E-H., Kim, A-Y., Kim, S-H., Yu, H-Y. and Sohn, J-H.

Internal Consistency of Physiological Responses during Exposure to Emotional Stimuli using Biosensors.

DOI: 10.5220/0005998701100115

In Proceedings of the 6th International Joint Conference on Pervasive and Embedded Computing and Communication Systems (PECCS 2016), pages 110-115

ISBN: 978-989-758-195-3

interval. Twice repeated measures with identical

stimuli may have possibly resulted in potential effect

of adaptation to stimuli, learning effect. To examine

the consistency of physiological responses over a

relatively long period of time, we identified the

stability of physiological responses induced by six

specific emotions (happiness, sadness, anger, fear,

disgust, and surprise) using sixty different emotional

stimuli in an experiment repeated 10 times. We

expect our study to exclude a possible of adaptation

and learning effect (e.g., habituation) that occurred

in the previous studies using the same stimuli. We

conducted experiments consisted often sessions

across ten weeks under the same experimental

conditions by using different emotional stimuli per

session to induce each basic emotion.

2 EXPERIMENTAL METHODS

2.1 Participants

Twelve college students (6 male and 6 females,

mean 21.0 years ± 1.98) who attend Chungnam

National University participated in the study. None

of them reported any history of medical illness or

experiences of taking psychotropic medication and

any medication that would affect the cardiovascular,

respiratory, or central nervous system. A written

consent was obtained at the beginning of the study

when they were introduced to the experimental

procedures, and they were also paid $200 USD to

compensate for their participation.

2.2 Emotional Stimuli

To successfully provoke target emotions, we have

used audio-visual film clips as emotional stimuli

because film clip includes dynamic information to

evoke effective emotional responses than those of

still pictures (Lazarus, Speisman, Mordkoff and

Davidson, 1962; Davis, Hull, Young and Warren,

1987; Palomba et al., 2000). Ten of each film clips

to induce six emotions were excerpted from a

variety of movies and TV shows such as

documentary and drama. Each clip lasted 2- to 4-

minute long. They were counter-balanced to

minimize the order effect. Table 1 describes the

content of the stimuli to induce 6 emotions. The

emotional stimuli had 91.3% appropriateness and

8.9 point effectiveness on average for the 10 times

across the different emotional conditions (Park, Jang,

Chung and Kim, 2013).

Table 1: Summary of emotional stimuli.

Emotion Context of Stimuli

HAP

joyful scenes consisted of

victorious, wedding, laughing

contents, etc.

SAD

frustration or grief scenes

consisted of the longing for

parents, a failure in love, etc.

ANG

deliberate harmful or unfair

behaviours such as massacre,

beating, or attack, etc.

FEA

scary scenes consisted of

ghost or haunted house etc.

DIS

disgusting scenes consisted of

mutilation, butchery, or dirty

restroom, etc.

SUR

sudden or unexpected

screaming scenes occurred by

startling accident etc.

2.3 Experimental Settings

Prior to the experiment, participants were allowed to

take time to feel comfortable in the laboratory

setting and provided with instruction to experiment.

Then, electrodes for acquisition of physiological

signals were placed on their wrists, fingers, and

ankle. They had 60 seconds before the stimulus

presentation as a baseline condition during which

their physiological responses were measured without

any emotional stimulus. Then, they were presented

the emotion provoking stimuli for 2~4 minutes. At

the end of stimulus presentation, participants were

asked to rate the specific emotions they had

experienced during exposure to emotional stimuli on

Likert scale (Likert, 1932). After the ratings, they

were given 2 minutes to get debriefed and recovered

from the emotional condition. The stimulus order

was randomized for each participant and the

experiment took roughly about an hour and a half,

including a short break. This procedure was

conducted on each of the two emotions for 10 weeks

on a weekly basis.

2.4 Physiological Measures and Data

Analysis

MP100WS of Biopac Systems Inc. (California,

USA) was used to measure bio-signals and

AcqKnowledge (version 3.7.1) were used to and

analyse them, respectively. The sampling rate was

fixed at 200 Hz for all channels, and appropriate

Internal Consistency of Physiological Responses during Exposure to Emotional Stimuli using Biosensors

111

amplification and band-pass filtering were

performed. EDA signal was measured with the use

of 8 mm AgCl electrodes placed on the volar surface

of the distal phalanges of the index and middle

fingers of the non-dominant hand. The electrodes

were filled with a 0.05 molar isotonic NaCl paste to

provide a continuous connection between the

electrodes and the skin. The skin conductance

channel was analysed as mean level (skin

conductance level, SCL, in uS) after movement and

electrode contact artifacts had been edited out. ECG

electrodes were placed on both wrists and the left

ankle using two kinds of electrodes, sputtered and

AgCl. The electrode on left ankle was used as a

reference. Heart rate (HR, in beats per minute) was

analysed by a program that detects R-waves in the

ECG and calculates consecutive R–R intervals. PPG

sensor was attached to the first joint of the non-

dominant thumb and SKT signals were acquired by

an SKT electrode attached to the first joint of the

non-dominant ring finger. meanPPG and meanSKT

were calculated by averaging raw PPG and SKT

amplitude values during 30-seconds, respectively.

To analyse the physiological data, we chose the

most stable 30-seconds section from the baseline and

the most emotional 30-seconds section from each

emotional states. The emotional conditions were

determined based on the results of the participant’s

self-reporting, in which an emotion was most

strongly expressed during the presentation of a

stimulus. A t-test was conducted to examine any

statistically significant (alpha level at .05)

differences between two conditions which is before

(baseline) and during the presentation of emotional

stimulus (emotional condition). Cronbach’s alpha

(Cronbach, 1951), which means internal consistency

was also used to examine the reliability of

physiological responses observed during the 10

sessions. Cronbach's alpha is a useful coefficient for

assessing internal consistency. The formula is:

α=



−1

(1 −

∑













)

(1)

where k is the number of items (session), s

the variance of the ith item (session) and s

is the

variance of the total score formed by summing all

the items (sessions).

3 RESULTS

3.1 Validity of Emotion Induction

The results of appropriateness and effectiveness by

Table 2: Participants’ mean ratings of intensity for each

intended emotion condition.

Emotion

HAP SAD ANG FEA DIS SUR

100

(8.4)

(9.5)

(9.7)

(10)

(10.2)

(9.3)

(9.5)

100

(8.9)

100

(9.1)

(9.9)

100

(9.9)

(10.8)

(9.7)

(9.6)

100

(8.8)

100

(8.7)

(9.7)

(9.8)

(9.9)

100

(9.7)

(9.3)

100

(9.6)

100

(9.7)

(9.5)

(9.6)

100

(10.4)

100

(9.9)

(9.7)

100

(9.6)

100

(9.3)

(9.8)

(9.7)

(9.6)

100

(9.3)

100

(9.3)

(9.4)

(9.7)

100

(10.3)

(9.6)

(9.5)

100

(9.3)

(8.9)

(9.6)

100

(9.3)

100

(9.5)

(9.3)

(8.0)

100

(9.0)

(9.2)

100

(9.3)

(10.2)

(9.4)

(9.2)

100

(9.7)

100

(9.2)

(9.5)

100

(9.3)

100

(10.1)

(8.6)

(9.4)

(8.8)

100

(9.3)

(9.7)

(8.7)

100

(10.1)

(10.3)

(9.5)

(9.1)

(9.2)

(9.5)

(9.6)

(10.1)

(9.5)

93.3

(9.4)

Abbreviations of each emotion are as follows. HAP

happiness, SAD sadness, ANG anger, FEA fear, DIS:

disgust, SUR: surprise

the participants’ ratings mean their psychological

responses to emotional stimuli. Results on

psychological responses of each session showed that

the emotional stimuli have the appropriateness of

93.3% and an effectiveness of 9.4 points on average

for 10 times. Also, the results showed that the

appropriateness ranges from 75% to 100 % and the

effectiveness ranges from 8.7 points up to 10.8

points on emotions (Table 2). These results show

that our stimuli appropriately and effectively

provoked both emotions.

3.2 Reliability of Bio-Signals Induced

by Emotional Stimuli

To examine the reliability of the physiological data

obtained during the 10 sessions, Cronbach’s alpha was

used as the reliability coefficients. Table 3 to table 8

show the descriptive statistics (mean and standard

deviation) and Cronbach’s alpha to physiological

parameters from 12 participants during each emotion

over 10 sessions. The results showed that Cronbach’s

alpha of emotional conditions had the range from .42

to .96 and they were greater than that of baseline

ranging from .10 to 71. Figure 1 shows Cronbach’s

alpha of physiological parameters during six baselines

SPCS 2016 - International Conference on Signal Processing and Communication Systems

112

and emotions. In all parameters, coefficients during

emotional states are higher than baseline.

Table 3: Cronbach’s alpha of physiological features during

happiness.

Time

SCL HR meanSKT meanPPG

BAS EMO BAS EMO BAS EMO BAS EMO

5.13

(3.07)

5.14

(4.74)

72.21

(10.34)

72.75

(11.07)

90.31

(0.03)

90.31

(0.01)

-8.38

(0.84)

-8.36

(0.86)

3.46

(3.27)

3.76

(3.11)

72.87

(11.25)

70.93

(10.10)

90.33

(0.04)

90.30

(0.04)

-8.39

(0.61)

-8.26

(0.70)

4.71

(2.69)

4.48

(2.91)

71.62

(8.84)

70.24

(9.36)

90.31

(0.02)

90.28

(0.03)

-8.17

(0.81)

-8.21

(0.66)

3.64

(2.01)

4.16

(2.57)

74.96

(9.08)

73.08

(9.38)

90.31

(0.03)

90.29

(0.02)

-8.69

(0.93)

-8.68

(0.98)

3.97

(2.99)

4.31

(2.81)

72.36

(10.68)

73.08

(11.77)

94.22

(1.96)

94.52

(1.31)

-8.82

(0.61)

-8.72

(0.66)

4.42

(2.97)

4.10

(3.61)

76.04

(9.58)

76.80

(12.22)

94.26

(1.72)

94.49

(1.53)

-8.20

(0.63)

-8.21

(0.57)

4.38

(2.78)

3.14

(2.68)

76.41

(10.36)

75.72

(9.01)

94.65

(1.44)

93.46

(2.79)

-8.27

(0.61)

-8.21

(0.67)

4.69

(3.13)

3.91

(3.88)

74.38

(10.51)

72.67

(11.89)

94.09

(1.90)

94.08

(2.52)

-8.10

(0.71)

-8.62

(0.74)

4.05

(2.85)

2.96

(2.02)

79.06

(11.78)

76.52

(16.09)

94.54

(1.62)

94.71

(2.83)

-8.21

(0.64)

-8.50

(0.67)

4.35

(2.81)

3.29

(3.73)

80.00

(14.37)

78.60

(13.24)

94.50

(1.53)

95.07

(1.84)

-8.35

(0.59)

-8.85

(0.65)

4.28

(2.86)

3.93

(3.21)

74.99

(10.68)

74.09

(11.72)

92.8

(1.03)

92.75

(1.29)

-8.35

(0.70)

-8.46

(0.72)

α .61 .95 .44 .92 .10 .76 .63 .95

Table 4: Cronbach’s alpha of physiological features during

sadness.

Time

SCL HR meanSKT meanPPG

BAS EMO BAS EMO BAS EMO BAS EMO

4.99

(2.87)

5.48

(4.42)

70.54

(10.15)

70.79

(10.20)

90.31

(0.02)

90.31

(0.02)

-8.48

(0.91)

-8.38

(0.92)

3.90

(2.48)

3.33

(2.50)

69.19

(8.57)

68.05

(8.32)

90.30

(0.02)

90.31

(0.04)

-8.11

(0.85)

-8.14

(0.80)

4.65

(2.62)

3.84

(2.42)

69.42

(7.78)

68.98

(8.74)

90.30

(0.04)

90.29

(0.01)

-8.07

(0.80)

-8.12

(0.84)

4.13

(2.03)

3.60

(2.15)

73.27

(9.84)

74.49

(11.83)

90.32

(0.03)

90.28

(0.04)

-8.52

(0.87)

-8.48

(0.85)

4.54

(2.46)

4.23

(2.89)

72.90

(10.07)

71.66

(11.61)

93.44

(3.39)

93.86

(3.45)

-8.63

(0.91)

-8.60

(0.98)

4.36

(3.21)

4.44

(2.68)

73.11

(9.56)

73.33

(10.57)

93.17

(2.86)

94.84

(1.78)

-8.19

(0.76)

-8.25

(0.70)

4.32

(2.55)

4.27

(3.20)

75.17

(9.57)

71.05

(10.07)

93.99

(1.84)

92.57

(4.74)

-7.93

(0.75)

-8.10

(0.87)

4.18

(2.89)

4.21

(2.97)

74.56

(10.31)

70.01

(9.98)

92.78

(4.93)

93.36

(3.75)

-8.29

(0.75)

-8.47

(0.94)

4.49

(2.56)

3.70

(2.05)

75.14

(10.77)

71.72

(11.32)

93.99

(2.51)

95.27

(1.25)

-8.02

(0.73)

-8.25

(0.91)

3.94

(3.41)

3.83

(2.84)

76.96

(12.14)

75.54

(11.15)

92.66

(4.40)

94.60

(2.52)

-8.21

(0.89)

-8.58

(0.99)

4.35

(2.71)

4.09

(2.79)

73.03

(10.18)

71.56

(10.88)

92.13

(2.00)

92.57

(1.76)

-8.25

(0.83)

-8.34

(0.88)

α .63 .95 .48 .96 .22 .53 .57 .96

Table 5: Cronbach’s alpha of physiological features during

anger.

Time

SCL HR meanSKT meanPPG

BAS EMO BAS EMO BAS EMO BAS EMO

5.22

(3.36)

4.92

(3.00)

71.50

(9.45)

70.99

(11.13)

90.32

(0.04)

90.29

(0.03)

-8.42

(0.91)

-8.37

(0.90)

4.05

(2.42)

3.56

(2.33)

71.35

(9.31)

68.57

(10.47)

90.32

(0.05)

90.30

(0.03)

-8.14

(0.78)

-8.18

(0.71)

4.64

(2.63)

4.29

(3.11)

71.01

(8.91)

68.12

(9.99)

90.30

(0.05)

90.30

(0.05)

-8.07

(0.79)

-8.27

(0.78)

3.91

(2.21)

3.77

(2.69)

73.07

(9.62)

71.82

(10.33)

90.31

(0.05)

90.32

(0.03)

-8.55

(0.94)

-8.62

(0.95)

4.25

(2.39)

4.45

(3.15)

70.80

(11.11)

68.60

(9.93)

94.36

(1.64)

94.40

(2.03)

-8.64

(0.92)

-8.58

(0.95)

4.17

(3.43)

3.93

(2.73)

74.33

(9.06)

74.67

(11.42)

93.13

(3.74)

94.23

(2.05)

-8.64

(0.92)

-8.22

(0.60)

4.56

(3.39)

4.11

(3.12)

74.12

(10.23)

71.28

(8.94)

92.15

(4.16)

93.86

(2.10)

-8.34

(0.81)

-8.11

(0.86)

3.56

(2.54)

4.80

(3.19)

73.08

(11.06)

70.92

(10.43)

93.55

(4.23)

94.08

(2.22)

-8.26

(0.80)

-8.46

(0.90)

3.72

(3.03)

3.31

(2.18)

75.50

(11.79)

73.45

(12.18)

91.80

(4.52)

94.84

(1.98)

-8.29

(0.81)

-8.26

(0.79)

4.22

(2.68)

4.23

(3.31)

78.15

(14.77)

75.29

(13.70)

92.56

(3.21)

95.26

(1.27)

-8.27

(0.72)

-8.59

(0.87)

4.23

(2.81)

4.14

(2.88)

73.29

(10.53)

71.37

(11.05)

91.88

(2.17)

92.79

(1.13)

-8.31

(0.84)

-8.37

(0.83)

α .47 .96 .26 .96 .43 .57 .41 .96

Table 6: Cronbach’s alpha of physiological signal during

fear emotion.

Time

SCL HR meanSKT meanPPG

BAS EMO BAS EMO BAS EMO BAS EMO

5.07

(3.11)

5.56

(4.06)

72.77

(10.09)

70.80

(12.05)

90.32

(0.02)

90.29

(0.02)

-8.40

(0.90)

-8.33

(0.90)

3.93

(2.75)

4.80

(3.66)

70.49

(7.86)

69.27

(9.55)

90.33

(0.02)

90.27

(0.04)

-8.32

(0.77)

-8.20

(0.74)

4.61

(2.86)

4.82

(3.07)

71.60

(7.52)

71.59

(8.77)

90.31

(0.02)

90.29

(0.03)

-8.17

(0.64)

-8.21

(0.64)

3.97

(2.00)

4.63

(2.37)

73.84

(10.17)

71.99

(10.39)

90.30

(0.03)

90.29

(0.04)

-8.59

(0.87)

-8.47

(0.85)

4.53

(2.27)

5.10

(2.74)

71.77

(10.65)

67.23

(11.02)

94.01

(1.87)

93.86

(1.75)

-8.64

(0.86)

-8.60

(0.90)

3.68

(2.59)

5.35

(3.12)

75.30

(11.05)

73.51

(9.46)

94.27

(2.62)

94.35

(1.85)

-8.47

(0.89)

-8.18

(0.69)

3.43

(2.19)

4.74

(3.13)

75.99

(10.11)

73.98

(9.19)

92.81

(4.88)

92.44

(3.98)

-8.35

(0.64)

-8.30

(0.85)

3.92

(2.64)

5.83

(3.43)

73.33

(10.27)

68.99

(9.98)

94.82

(1.15)

93.63

(2.48)

-8.55

(0.81)

-8.50

(0.82)

4.07

(2.51)

4.21

(2.25)

78.05

(6.74)

75.27

(12.91)

94.37

(1.89)

94.90

(1.23)

-8.34

(0.94)

-8.17

(0.87)

3.83

(2.83)

4.09

(2.04)

77.58

(12.94)

73.59

(12.04)

95.10

(1.23)

95.14

(1.77)

-8.37

(0.94)

-8.59

(0.93)

4.10

(2.58)

4.91

(2.99)

74.07

(9.74)

71.62

(10.54)

92.66

(1.37)

92.55

(1.32)

-8.42

(0.84)

-8.35

(0.82)

α .57 .94 .46 .96 .37 .71 .71 .96

Internal Consistency of Physiological Responses during Exposure to Emotional Stimuli using Biosensors

113

Table 7: Cronbach’s alpha of physiological signal during

disgust emotion.

Time

SCL HR meanSKT meanPPG

BAS EMO BAS EMO BAS EMO BAS EMO

5.07

(3.11)

5.56

(4.06)

72.77

(10.09)

70.80

(12.05)

90.32

(0.02)

90.29

(0.02)

-8.40

(0.90)

-8.33

(0.90)

3.93

(2.75)

4.80

(3.66)

70.49

(7.86)

69.27

(9.55)

90.33

(0.02)

90.27

(0.04)

-8.32

(0.77)

-8.20

(0.74)

4.61

(2.86)

4.82

(3.07)

71.60

(7.52)

71.59

(8.77)

90.31

(0.02)

90.29

(0.03)

-8.17

(0.64)

-8.21

(0.64)

3.97

(2.00)

4.63

(2.37)

73.84

(10.17)

71.99

(10.39)

90.30

(0.03)

90.29

(0.04)

-8.59

(0.87)

-8.47

(0.85)

4.53

(2.27)

5.10

(2.74)

71.77

(10.65)

67.23

(11.02)

94.01

(1.87)

93.86

(1.75)

-8.64

(0.86)

-8.60

(0.90)

3.68

(2.59)

5.35

(3.12)

75.30

(11.05)

73.51

(9.46)

94.27

(2.62)

94.35

(1.85)

-8.47

(0.89)

-8.18

(0.69)

3.43

(2.19)

4.74

(3.13)

75.99

(10.11)

73.98

(9.19)

92.81

(4.88)

92.44

(3.98)

-8.35

(0.64)

-8.30

(0.85)

3.92

(2.64)

5.83

(3.43)

73.33

(10.27)

68.99

(9.98)

94.82

(1.15)

93.63

(2.48)

-8.55

(0.81)

-8.50

(0.82)

4.07

(2.51)

4.21

(2.25)

78.05

(6.74)

75.27

(12.91)

94.37

(1.89)

94.90

(1.23)

-8.34

(0.94)

-8.17

(0.87)

3.83

(2.83)

4.09

(2.04)

77.58

(12.94)

73.59

(12.04)

95.10

(1.23)

95.14

(1.77)

-8.37

(0.94)

-8.59

(0.93)

4.10

(2.58)

4.91

(2.99)

74.07

(9.74)

71.62

(10.54)

92.66

(1.37)

92.55

(1.32)

-8.42

(0.84)

-8.35

(0.82)

α .57 .94 .46 .96 .37 .71 .71 .96

Table 8: Cronbach’s alpha of physiological signal during

surprise emotion.

Time

SCL HR meanSKT meanPPG

BAS EMO BAS EMO BAS EMO BAS EMO

5.06

(3.45)

6.52

(3.11)

71.08

(11.06)

70.46

(10.52)

90.32

(0.03)

90.30

(0.03)

-8.33

(0.86)

-8.33

(0.95)

4.03

(2.85)

4.62

(2.26)

72.96

(9.13)

69.71

(8.49)

90.32

(0.04)

90.30

(0.03)

-8.29

(0.83)

-8.22

(0.74)

3.85

(3.39)

3.68

(3.11)

72.04

(7.19)

69.85

(8.17)

90.29

(0.04)

90.30

(0.02)

-8.29

(0.71)

-8.40

(0.59)

3.95

(3.03)

4.82

(1.98)

73.75

(8.71)

73.83

(10.51)

90.30

(0.03)

90.31

(0.04)

-8.70

(0.86)

-8.57

(0.87)

4.09

(2.21)

4.11

(2.35)

72.44

(13.69)

68.19

(10.48)

93.96

(1.97)

93.87

(2.01)

-8.71

(0.81)

-8.65

(0.87)

4.16

(2.90)

5.84

(3.01)

74.75

(10.90)

72.36

(10.94)

94.57

(2.24)

94.38

(1.90)

-8.49

(0.86)

-8.17

(0.71)

3.66

(1.55)

4.63

(3.09)

75.60

(11.40)

74.20

(10.11)

94.37

(1.52)

92.40

(4.28)

-8.62

(0.93)

-8.12

(0.75)

3.96

(2.38)

5.89

(3.02)

75.94

(11.75)

71.06

(12.19)

93.93

(3.24)

93.02

(4.38)

-8.37

(0.98)

-8.51

(1.00)

4.50

(3.14)

4.73

(2.52)

73.68

(10.91)

72.51

(10.93)

94.97

(1.65)

94.71

(1.08)

-8.52

(0.94)

-8.28

(0.98)

3.91

(2.50)

4.74

(2.45)

77.85

(11.84)

75.41

(14.23)

94.59

(1.33)

94.89

(2.34)

-8.36

(0.89)

-8.58

(0.96)

4.12

(2.74)

4.96

(2.89)

74.01

(10.66)

71.76

(10.66)

92.76

(1.21)

92.45

(1.61)

-8.47

(0.88)

-8.38

(0.84)

α .79 .92 .54 .96 .10 .54 .71 .96

Figure 1: Cronbach’s alpha of physiological signal during

all emotions.

4 CONCLUSIONS

We have attempted to investigate the consistency on

changes of bio-signals induced by emotional stimuli.

The used emotional stimuli have been proved to be

appropriate and effective in inducing targeted

emotions regardless of variety of stimulus (Table 2).

They were not only designed to produce active and

vivid images, even more effective than those of

static emotional stimuli (e.g., facial expressions,

slides, and imagery), but also considered particularly

advantageous for the clips have already been

standardized for conditioning purposes, require little

or no deception, and possess a high degree of

ecological validity in so far as to effectively evoke

emotions via dynamic auditory and visual situations

external (Gross and Levenson, 1995; Christie and

Friedman, 2004).

In physiological results, despite a small sample

size (n=12), Cronbach’s alpha, coefficient of internal

consistency had range from .10 to .71 in responses

during baseline. The lower consistency during

baseline may reflect the inter-individual differences

of physiological responses. Nevertheless, except for

meanSKT, the coefficients of SCL, HR, and

meanPPG during each emotional condition were

very high, having the range from .91 to .96. The

value of alpha greater than .9 means that internal

consistency is excellent and alpha value from .7 to .9

is good (George and Mallery, 2003; Kline, 2000).

Our result means that physiological responses during

emotional conditions are very stable and consistent

regardless of variety of emotional stimuli over time.

In conclusion, we have identified the reliability

of physiological responses induced by emotional

stimuli regardless of various stimuli and time. Our

results suggest that physiological responses such as

SCL and HR induced by emotional stimuli are very

stable and consistent. They can be useful in emotion

recognition, developing an emotion theory, or

profiling emotion-specific physiological responses,

SPCS 2016 - International Conference on Signal Processing and Communication Systems

114

as well as establishing the basis for an emotion

recognition system in human-computer interaction.

ACKNOWLEDGEMENTS

This work was supported by Institute for

Information & communications Technology

Promotion (IITP) grant funded by the Korea

government (MSIP) (No. B0132-15-1003).

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