International Journal of Interactive Mobile Technologies (iJIM) – eISSN: 1865-7923 – Vol. 15, No. 19, 2021


Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

The Development of Video on Pickled Fruit 
Production for Flipped Classroom*

https://doi.org/10.3991/ijim.v15i19.22695

Andian Ari Anggraeni(*), Sumaryana, Wika Rinawati, Dewi Eka Murniati
Universitas Negeri Yogyakarta, Yogyakarta, Indonesia

andian_ari@uny.ac.id

Abstract—Undergraduate students are categorized as Generation Z. They 
prefer learning using video rather than the book. Demonstration videos are 
suitable for productive courses because they show step by step of product making. 
This study aimed to 1) develop a video of pickled fruit production for the Food 
Preservation Technology course, Universitas Negeri Yogyakarta (UNY), Indone-
sia and 2) determine the video’s feasibility. This study was a research and devel-
opment (R&D) performed by ten steps, namely information collecting, planning, 
developing initial products, preliminary field testing, main product revision, 
main field testing, operational product revision, operational field testing, final 
product revision, as well as dissemination and implementation. Data analysis 
was performed descriptively. The video feasibility analysis was conducted by 
one material expert, one media expert, two teachers, two peer reviewers, four 
students in one-on-one testing, and 36 students in classroom testing. Based on 
the feasibility test, the video was declared very feasible as learning media. Text, 
images, animations, and effects appeared in several parts of the video, making 
it easier for the students to understand the content. This video can be embedded 
in the learning management system (LMS) such as Google Classroom, Moodle, 
and others to facilitate mobile learning, and implemented in a flipped classroom 
design. Pre-test and post-test were then performed on 29 students in operational 
field testing. The post-test was significantly higher than the pre-test (p<0.05), so 
the video was able to improve the students’ cognitive skills.

Keywords—m-learning, multimedia learning, demonstration video, food 
science learning, food science education

1 Introduction

Generation Z grow up with increasingly cutting-edge information and communica-
tion technology (ICT). It makes them proficient in utilizing technology such as com-
puters, laptops, and various software applications, for their daily activities [1]. They 
can easily and quickly access any required information and prefer digital interaction 

* The authors hereby confirm that they have obtained the consent of the persons depicted in the photo-
graphs for publication.

118 http://www.i-jim.org

https://doi.org/10.3991/ijim.v15i19.22695
mailto:andian_ari@uny.ac.id


Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

through social media, for instance, YouTube, Instagram, Line, WhatsApp, Twitter, 
and others [1]. They can do all activities through the digital world anytime [2] and 
perform various activities simultaneously [1]. They enjoy technology-based learning 
because it supports mobile learning [1]. Common digital media for mobile learning are 
included, 1) text with pdf format, 2) audio such as podcast, 3) video namely podcast 
video, demonstration video, animation video, and others, and 4) combination of those 
media delivered in flipped book or online article [3]. Unlimited access to teaching and 
learning is the main characteristic of the education 4.0 era.

Education 4.0 offers innovation and promoting technology in the teaching and 
learning process [4]. The development of educational technology affects the variety 
of media used by teachers. Physical books were converted into electronic books or 
flipped books. Teacher explanation can be recorded and distributed using podcast 
audio or video. Abstract concept can be made easier to understand using animation 
videos. Besides, the expensive and/or dangerous environment can be emerged in 
virtual reality.

Video has gained its popularity for many years. It was started with television based 
learning and instruction in 1975 [5]. Since the last decade, video was used to support 
mobile learning. The video could be accessed individually, anytime and anywhere 
[1]. Video was used to support flipped classroom learning especially for undergradu-
ate students [6]. University students begin learning by doing self-directed asynchro-
nous meetings by observing various videos on LMS. The students then come to class 
to perform some student-centered activities. Although many positive results have 
been reported on developing and implementing video in flipped classroom in medical 
and health education [7], [8], none reported those in the field of food science and 
technology education.

The productive subjects require demonstration videos during the learning process 
because those videos show product-making steps [9]. Food Preservation Technology 
is a psychomotor-skill course in the Culinary Science study program, UNY, Indone-
sia. The course was delivered using flipped classroom. In the asynchronous meeting 
facilitated by LMS, the students could access text media, demonstration videos, and 
quiz [10]. The students’ activity to access the learning resources and take the quiz was 
expected to enhance students’ readiness in the laboratory meeting. Students receiving 
the minimum quiz grade of 70 were allowed to join the laboratory synchronous meeting 
to perform product making. The learning design in synchronous meetings was carried 
out using a team problem-based learning where the lecturers acted as facilitators.

Various videos for Food Preservation Technology course have been developed, 
including the making of soybean juice, vegetable noodles, fried nuts, garlic snack [11], 
purple sweet potato flour, shredded chicken [12], sorbet [13], and dry banana [14]. 
However, the demonstration videos for fruit processing are still limited. Fruit process-
ing topic contains processing and preserving fruit into various processed products, such 
as jams, dodol (sweet toffee-like confection), chips, syrup, juice, sorbet, pickled fruits, 
and others. The pickled fruits can be produced quickly, but attention should be paid 
to the critical points in selecting fruit raw materials, preventing enzymatic browning 
reactions, sugar concentrations, drying process, and packaging [15].

Many videos on pickled fruit making have been available on YouTube. Some of 
these videos have good visual quality, however they have monotonous backgrounds. 

iJIM ‒ Vol. 15, No. 19, 2021 119



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

Most videos are recorded at one location using limited camera angles. Mostly, those 
videos are demonstration videos that do not contain introductory material. Critical steps 
in the production process are also not discussed in those videos, so that those videos do 
not meet the criteria of good learning videos. Few findings reported the implementation 
of those videos to support flipped classrooms.

Therefore, the development of learning videos for making pickled fruit was nec-
essary. This article describes the development and the feasibility of a learning video 
to make pickled fruits for the Food Preservation Technology course. The video is a 
demonstration video, applying several styles, such as visually annotated and guided by 
voice recording in the demonstration scenes [16]. The video’s effectiveness was then 
measured by performing pre-test and post-test to evaluate students’ cognitive skills and 
readiness to perform the practical session in the laboratory.

2 Literature review

The characteristics of mobile learning are following the concept of education 4.0; 
namely, learning can be done individually and not limited by time and space. Mobile 
learning can be accessed using mobile gadgets such as laptops or cellphones, with 
the support of an internet connection [17]. Learning media for mobile learning should 
be designed with digital concepts, have good audio and visual quality. The video for 
mobile learning should be as shorter as 10-15 minutes [18], [19].

Video is an audio-visual media. Activating the sense of sight and hearing can 
enhance the learning process and improve the ability to retain information for a more 
extended period [20]. The use of video as a learning tool has proved to be very useful 
in influencing the learning process in mass, group, and individual settings. Videos can 
also be integrated into the LMS for blended learning, online learning [21], and flipped 
classroom [16]. The video used in online and blended learning has been previously 
reported in the field of medical and health science education [16], [21]–[23].

Learning videos have several characteristics, i.e., message clarity, independent 
aspect, user friendly, content representation, visualization with other media (text, graph-
ics, audio), and high-resolution quality [18]. However, videos are lack of interactivity 
and contain passive content [3]. Because of that, video usage should be complemented 
with other student-centre activities, such as problem-based [24] or project-based 
learning [25].

The short duration videos usually gain more views because long video will reduce 
student’s engagement [19]. When the learning videos are related to the test, the stu-
dents can watch the video repeatedly while completing the test. Several (3–10) simple 
questions in the quiz kept students’ attention in the video and not frustated them [25]. 
Thus, both strategies increase the student’s views. The highly viewed videos are also 
often guided by presenters who look smart and friendly, and also speak enthusiastically. 
Those videos usually look sophisticated, high-quality audio, professional, and visually 
attractive. Generally, those videos need to be supported by a well-established script and 
created by a qualified production team [26].

Videos cannot be easily modified once they are produced. Developing a ten-minutes 
video can take 5-20 hours depending on the script accuracy, b-rolls handling, and the 

120 http://www.i-jim.org



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

complexity of sound and visual effects. With the urgency of video as learning media, 
universities need to invest funds, time, and effort for video development [26].

Many articles have described the criteria of learning media that are favored by 
Generation Z, such as technologically advanced, visually attractive, individualized, 
quick accessed, and engaging [1], [2], [21]. This article describes the process of 
developing a learning video that is in line with the preference of Generation Z. Some 
reports have discussed the style of the demonstration videos, i.e., showing presenter in 
the narrative section [27] but avoiding presenter’s presence in the demonstration scene 
[16]. Those videos were visually annotated to ease student’s understanding [16], [21], 
guided by voice recording from a real female speaker [28], and used command form 
for action step [28].

Fig. 1. The research method based on Borg and Gal model [30]

3 Methods

3.1 Research type

This study could be categorized as Research and Development (R&D). This kind of 
research aimed at producing certain products and testing the effectiveness of the devel-
oped products [29]. The approach employed the Borg and Gal model [30]. It consisted 
of 10 stages, namely information collecting, planning, developing initial products, pre-
liminary field testing, main product revision, main field testing, operational product 

iJIM ‒ Vol. 15, No. 19, 2021 121



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

revision, operational field testing, final product revision, as well as dissemination and 
implementation [30]. Figure 1 shows the research procedure in each stage.

3.2 Data and instrument

The data were obtained from observation, feasibility tests, pre-test, and post-test. 
The observation was used during the information collecting stage. The feasibility test 
was in the form of a closed and open questionnaire. The closed questionnaire used 
a Likert scale of 1–4 (very unfeasible, unfeasible, feasible, and very feasible). The 
30-item questionnaire for material experts and teachers covered the aspects of learning, 
material, benefits, and usage. The questionnaire for media expert and peer reviewers 
contained 33 items covering the aspects of media, benefits, and usage. The question-
naire for students consisted of 30 questions to assess the elements of learning, media, 
material, benefits, and usage. The open questionnaire was used to express feedback 
and suggestions about the video. The feasibility test instrument can be accessed in the 
supplementary file.

The pre-test and post-test were distributed before and after they watch the video, 
respectively. The test consisted of 18 multiple-choice questions to measure students’ 
cognitive abilities and readiness in carrying out practical activities, as described by 
the previous study in health education [8]. Cognitive ability was measured from items 
about fruit theory, preservation techniques, processed fruit products, raw material selec-
tion, and packaging theory. The readiness of students to carry out practical activities 
was measured by items about equipment preparation, material preparation, manufac-
turing procedures, packaging procedures, and expired date evaluation procedures. The  
pre-test or post-test can be accessed in the supplementary file.

3.3 Data analysis technique

The feasibility data were analyzed descriptively. The feasibility percentage was 
calculated using (1).

 feasibilitypercentage
totalscore

totalof maximumscore
� �100%  (1)

The feasibility percentage was then interpreted qualitatively using data conversion 
from interval scale to ordinal scale, as shown in Table 1 [29]. The video could be used 
as the learning media if the video was categorized as very feasible.

Table 1. Interval scale data conversion to the ordinal scale

Feasibility Percentage Range (Interval Scale) Category (Ordinal scale)

0%–25% Very unfeasible

>25%–50% Unfeasible

>50%–75% Feasible

>75%–100% Very feasible

122 http://www.i-jim.org

https://drive.google.com/file/d/12C6Yhk2zdgZB9EgYmXxJHy7CM3vS6DFh/view?usp=sharing
https://drive.google.com/file/d/12C6Yhk2zdgZB9EgYmXxJHy7CM3vS6DFh/view?usp=sharing


Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

The pre-test and post-test were analyzed descriptively. The difference between 
pre-test and post-test was evaluated using t-test analysis.

4 Result and discussion

4.1 Information collecting

The observations and interviews to the students registered in Food Preservation 
Technology course were carried out by researchers. The lecturers had already used 
demonstration videos in their learning process. The videos were embedded in the 
Moodle LMS owned by UNY to support the flipped classroom. The teaching and learn-
ing in UNY was supported with Eduroam wifi connection, LCD projectors in all classes 
and laboratories, and a Moodle-based LMS that supports blended learning.

The students did not like reading, and they preferred digital audio-visual platforms 
[2]. The textbooks were less attractive and caused boredom to the students. Because of 
that, the video of pickled fruit making was necessary to provide the learning process 
preferred by the students. There were few videos on pickled fruit making. However, 
those videos did not contain introduction material and explanation on critical process 
steps, used background that interfered with audience’s focus (Figure 2 left), recorded 
with unsuitable camera angle (Figure 2 center), and used text annotation that interfered 
with the main image (Figure 2 right).

Fig. 2. The previously developed video on pickled fruit making

The video of pickled fruit making needs to be developed to support the learning 
process. The content of the video included wet pickled salak and dry pickled mango. 
These two fruits were selected due to their abundant sources. Salak and mango prices 
decreased during the harvest period. The large stocks at harvest time need to be 
processed into marketable products with longer shelf life.

4.2 Planning

The planning stage began with preparing video content by testing the wet pick-
led salak and dry pickled mango recipe to obtain high-quality picked products. Three 
types of treatments were carried out to prevent enzymatic browning in salak: 1) immer-
sion in saltwater, 2) immersion in sodium bisulfite solution [31], and 3) blanching for 
20 seconds [32] and followed by soaking in citric acid solution [33]. The first and 
second treatments resulted in brownish salak color. The third treatment was suc-
cessful in maintaining its original color. Two types of treatment were performed to 
obtain a chewy mango, namely: 1) soaking the mango in sugar solution overnight, and 

iJIM ‒ Vol. 15, No. 19, 2021 123



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

2) boiling. The first treatment resulted in created hard texture, and the second treatment 
resulted in a chewy texture.

The next step was the script preparation as the guidelines for making videos. The 
tabular video script consisted of scene number, take number, duration, visual source, 
visual insertion, narration, location, and description. The duration column was used to 
estimate the total video duration. The desired video duration ranged from 10–15 minutes, 
because the video duration was related to users’ ability to recall and focus [18]. The 
narration text was adopted from academic literature, such as journal articles and books. 
However, narrative writing must be carefully considered to change the writing language 
into standard verbal communication [7]. The difficulty in scriptwriting was that the 
vocabulary used should be understandable and straightforward. Moreover, the demon-
stration scenes must be performed sequentially to avoid flashback scenes.

The visual insertion column in the script would guide the video editing process. 
This column contained text, image, and animation insertion. Text and image were used 
to clarify the content delivered by the presenter. The text must be short of making the 
audience more comfortable to absorb the information [34] because long texts can inter-
rupt students’ focus. Meanwhile, animations were added through content visualization 
to improve student understanding.

The script was then analyzed by the material and media experts. The material experts 
evaluated the content accuracy, while the media experts reviewed the language styles, 
flashback sentences, and flashback scenes. The revision was carried out six times 
according to both experts’ suggestions until the script was declared feasible. The script 
was carefully written according to learning objectives to minimize mistakes in video 
recording and save energy, time, and fund.

The formation of the production team was based on the expertise, production skills, 
instructional design experience, and managerial skills on video projects [22]. The 
presenter selection was based on the ability to make eye contact with the camera and 
explain the content in-camera, facial expressions, and body language. The presenter’s 
articulation should not contain local dialects. The demonstrator was selected based on 
the ability to practice the process of making pickled fruits. Meanwhile, the dubber was 
selected by considering proper pronunciation, clear voice, and no local dialect.

4.3 Development of initial product

This stage was started with video shooting using a Sony NX100 camera of a single 
Exmor R sensor with a high-definition 1920 x 1080 resolution at 60p. The lighting 
used Kino Flo 6-bank LED lighting with uniform light distribution and lower power 
consumption compared to light output. Besides, the color temperature was stable 
when the light level changed, and the light was naturally soft color [35]. Lighting with 
maximum intensity and white/daylight was preferred so that the object’s shadow can be 
entirely avoided. Shadows in the foreground video can be identified as distinct colors 
due to the imperfect chroma key processing [36]. Tripod Pro NX100 was used through-
out the recording process to stabilize images. Boya BY WM8 clip-on microphones with 
voice-over techniques were used to record audio. The setting process of the camera and 
the supporting equipment spent 2 hours.

124 http://www.i-jim.org



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

The presenter’s shooting process was conducted for 2 hours at TV Studio UNY 
with a green screen backdrop. The use of the green screen was intended to simplify the 
editing process. The demonstration scene was recorded at the Chemistry Laboratory 
of the Faculty of Engineering UNY. The material preparation for the demonstration 
scene took 8 hours, including drying the mangoes. Meanwhile, the recording lasted 
for 4 hours.

Two cameras mounted in front and next to the presenter were used to capture the pre-
senter session. Two cameras also recorded the demonstration session. A camera was put 
in front of the production area, and another camera moved to capture b-roll. The camera 
layout determined the camera angle to avoid monotonous views [37]. The camera angle 
was essential to show the variation so that it included the eye-level angle and other 
angles. Eye-level referred to a method of taking pictures from the presenter’s front side 
with a parallel point of view [38]. Video delivery used a variety of shooting techniques 
such as long shoot (LS), medium shot (MS), close up (CU), high angle, and eye level.

The next stage was the video editing process using Adobe Premiere Pro CC 2017 
and Adobe After Effect. The video editing combined audio, visual source, animation, 
text, music, and transitions. High-quality media in screen presentation and design con-
sisted of text, picture, animation, and audio [39].

The video consisted of the opening, content, and closing sections. The presenter 
delivered the opening section, which explained the raw materials, products, preserva-
tion techniques, and packaging (Figure 3). The MS technique recorded this section. 
The presenter’s explanation included pictures, text, and 2D animation (Figure 3) to 
vary the scene layout to prevent boredom. The texts acted as keywords to ease under-
standing. 2D animation was used to illustrate the concept of preservation using a high 
concentration of sugar through reducing water activity (aw) of foodstuffs.

Fig. 3. The picture, text and animation insertion in the opening section

The content section covered the material and tool preparation, the production 
process, and expired date evaluation. The contents were performed by the demonstrator 
and guided by the dubber narration. The shooting was taken from chest to waist because 
facial expressions were not needed in this part. The presenter did not appear during 
the demonstration session to avoid focus distraction [34] because the audiences were 
expected to pay attention to the making process’s details. The presence of the presenter 
in the demonstration session will divide the user’s concentration [22].

Tool and material preparation (Figure 4) was taken using LS, CU, and high angle 
techniques. The LS technique was used to record the whole capture of equipment and 
materials. CU and high-angle techniques were used to show tools and materials one 
by one. Within this section, text annotations were used to explain the tool name, the 
material name, and the material size.

iJIM ‒ Vol. 15, No. 19, 2021 125



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

Fig. 4. Tool and material preparation

The production process (Figure 5) was recorded using MS, high angle, eye level, 
and CU techniques. The method of wet pickled fruits making included packaging 
steriliza-tion, stripping, reducing size, blanching, soaking in citric acid and sugar 
solution, as well as packaging. The process of dry pickled fruits making contained 
stripping, re-ducing size, soaking in a lime solution, washing, boiling with sugar, drain-
ing, mechani-cal drying with cabinet dryer or manual drying, sowing granulated sugar, 
and packag-ing. The production process part ended with the yield calculation.

Fig. 5. Wet and dry pickled fruit production

Figure 6 shows the expiration test. The demonstrator performed the organoleptic 
test to assess color, aroma, texture, and taste. This section was taken through the MS 
techniques by displaying half of the body from the stomach upward to show the face. 
The use of MS techniques in this section aimed at demonstrating the demonstrators’ 
activity when conducting the organoleptic tests involving observing, smelling, tasting, 
and trying the product. The product expiration time decision was based on the products’ 
organoleptic tests, which were stored for 1 to 2 weeks. The expiration time was based 
on the changes in the organoleptic nature of the product. This visualization of the expi-
ration time was assisted with the observation table (Figure 6).

126 http://www.i-jim.org



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

Fig. 6. Organoleptic testing and expired date evaluation

The last part of this video was the closing section delivered by the presenter, which 
explained the evaluation and conclusions (Figure 7). The conclusion section was taken 
with MS technique and equipped with text annotations written in round shapes. The 
total duration of the video was 16 minutes and 58 seconds.

Fig. 7. The closing section was equipped with text annotation

4.4 Preliminary field testing

Video feasibility assessment was carried out by the material expert and the media 
expert. Tables 2 and 3 show the video feasibility assessment from both experts. The 
material experts’ assessment result was 96.7%, and the media experts’ feasibility test 
was 93.2%. The video can be categorized as very feasible for both the quality of the 
material and the media. This video also obtained the highest score on the usage aspect 
because its operation was easy, simple, and practical.

Table 2. The result of the feasibility test based on material quality

Aspects
Material Experts Teachers

Feasibility, % Category Feasibility, % Category

Learning 96.4 Very Feasible 92.9 Very Feasible

Material 96.2 Very Feasible 89.4 Very Feasible

Benefit 95.0 Very Feasible 100.0 Very Feasible

Usage 100.0 Very Feasible 97.5 Very Feasible

Total 96.7 Very Feasible 93.3 Very Feasible

iJIM ‒ Vol. 15, No. 19, 2021 127



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

Table 3. The result of the feasibility test based on media quality

Aspects
Media Expert Peer Reviewers

Feasibility, % Category Feasibility, % Category

Media 92.7 Very Feasible 95.8 Very Feasible

Benefit 87.5 Very Feasible 87.5 Very Feasible

Usage 96.4 Very Feasible 96.4 Very Feasible

Total 93.2 Very Feasible 95.5 Very Feasible

4.5 Main product revision

Based on the material experts and media experts’ assessment, the video production 
team discussed several things that needed to be revised, as follows. The font and image 
sizes should be enlarged to attract the user’s attention. The sound recordings need to be 
edited to reduce noise in the video. The total duration of the video should be trimmed 
to reach a maximum length of 15 minutes. The changing between scenes should be 
smoothened by the addition of transition techniques [40]. Besides, there are several 
dissimilarities between the narrator’s voice and the script, so that the voice recording 
should be retaken in some scenes. Texts were also added to some presenter scenes to 
emphasize the clarity of the delivered message. After five times revisions, the duration 
of final video was 14 minutes 48 seconds, and the file extensions was mp4.

4.6 Main field testing

The video was then assessed its feasibility by two teachers and two peer reviewers. 
The teacher assessment used a material quality questionnaire. The results of the teach-
ers’ assessment can be seen in Table 2. The video obtained a total percentage of 93.3%, 
and it was categorized as very feasible.

Meanwhile, the peer reviewer assessments used the questionnaire based on media 
quality. The result indicated that the video was in the very feasible category with a 
total percentage of 95.5%, in which all aspects can be categorized as very feasible, as 
presented in Table 3. This implied that the video could be utilized as a supplementary 
material to improve the learning process, which was consistent with the purpose of this 
video-making [41]. Also, the video visualization was made with high-resolution digital 
technology that had met the video feasibility criteria [18].

The video was also assessed by four students in one-on-one testing and 36 students 
in classroom design (Table 4). The results were 92.3% for one-on-one testing and 
87.4% for classroom testing. Therefore, this video falls into a very feasible category.

This video’s results have similarities with the video of garlic snack making, which 
reported that the students’ assessment was lower than the material and media experts 
[11]. It is caused by a generation gap between the material and media experts and uni-
versity students [42]. The students belonging to Generation Z are more familiar with 
technology and virtual information, so they have high expectations for audio-visual 
standards.

128 http://www.i-jim.org



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

Table 4. Video assessment by students

Aspects
One-on-One Testing Classroom Testing

Feasibility, % Category Feasibility, % Category

Learning 91.3 Very Feasible 86.8 Very Feasible

Media 89.2 Very Feasible 87.0 Very Feasible

Material 98.4 Very Feasible 87.5 Very Feasible

Benefit 91.3 Very Feasible 87.1 Very Feasible

Usage 96.3 Very Feasible 89.0 Very Feasible

Total 92.3 Very Feasible 87.4 Very Feasible

4.7 Operational product revision

The peer reviewers did not give any suggestions, but the teachers provided feed-
backs for some revisions. One teacher suggested that the demonstrator use a mask and 
gloves to avoid contamination and personal protective equipment. All the demonstra-
tion scenes should be retaken to perform this suggestion. The retaking process was not 
possible because funds limited the production of this video. This suggestion would be 
follow up for other video production in Food Preservation Technology course.

This teacher also suggested weighing the dry pickled fruit since it was useful for 
labeling net-weight. This video has two contents, wet and dry pickled fruit. The weigh-
ing scene had been shown in the wet pickled fruit section. The weighing process was 
considered a simple and easy process, so that it was not necessary to be repeated in 
the dry pickled fruit section. The weighing scenes of dry pickled mangoes had been 
presented to show the yield calculation. Therefore, the weighing process was not 
repeated on the dry pickled fruit to maintain the video duration.

This teacher also suggested that 5 panelists carried out the organoleptic test. The 
organoleptic testing scene was shown to illustrate how to perform sensory evalua-
tion of the product, demonstrated by a panelist. The demonstration by a panelist was 
considered to be informative and educational. This scene has been able to elevate users’ 
understanding to carry out organoleptic tests appropriately. If this scene recorded five 
panelists, the students’ concentration would be distracted due to the repetition of similar 
scenes [23].

Another teacher suggested that the concept of preservation should be explained with 
the plasmolysis concept. The video content at the minute of 1:34 had already told the 
idea of preservation using high sugar content in the form of 2D animation (Figure 3). 
The animation explained that high sugar levels cause microorganism cells to lose the 
free water content beneficial for the growth of microorganisms. This learning video 
had already lasted 14 minutes 58 seconds and was limited to a maximum length of 
15 minutes [18]. Suppose the animation of the plasmolysis concept was included in 
this video. In that case, the video’s duration could be more than 15 minutes, and it did 
not meet the criteria of demonstration video feasibility. This video was a demonstration 
type whose purpose was to demonstrate to users about the tools, materials, and making 
processes [22]. Videos should focus on specific goals and topics.

iJIM ‒ Vol. 15, No. 19, 2021 129



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

Therefore, the production team decided not to revise by considering the video 
duration. Meanwhile, the feedback regarding personal protective equipment will be 
accommodated in the subsequent video development because it was challenging to 
retake all demonstration session scenes due to limited funds and time.

Students’ feedback in one-on-one testing and classroom testing was on the noise 
reduction and smoothing scene transition. For these reasons, the video was revised for 
both aspects.

4.8 Operational field testing

This stage was a video assessment of 29 students who took this course. Before 
watching the video in class, the students were asked to complete a pre-test. The 
students watched the video in the class through an LCD projector and a white screen. 
While watching, they were asked to fill out the feasibility test questionnaire and post-test.

The feasibility test total score was 83.6%. It consisted of learning 82.4%, media 
82.5%, material 86.4%, benefit 85.0%, and usage 83.4%. The results of the pre-test 
and post-test can be seen in Table 5. Meanwhile, the t-test analysis of the pre-test and 
post-test scores showed significant differences (p <0.05). Based on the course instruc-
tors’ observations, the independence of students while doing practice had increased 
after students used this demonstration video. Therefore, this video effectively enhanced 
students’ readiness to perform the practical session in the laboratory, related to tool and 
material preparation, production steps, and expiration testing in making pickled fruits.

Table 5. The paired t-test between pre-test and post-test

Pre-Test Post-Test

Mean 8.8621 16.8276

Variance 5.6232 1.2906

Observations 29 29

Hypothesized Mean Difference 0

df 28

t Stat –20.1442

P(T<=t) two-tail 3.3598. 10–18

t Critical two-tail 2.0484

The results of this study confirmed a finding from medical education. It stated 
that the use of demonstration videos in flipped classrooms for dermatology residents 
effectively improved procedural skills and self-confidence [16]. This article showed 
that demonstration videos could also be implemented in food technology flipped 
classrooms to prepare students’ readiness before doing a practical job in the laboratory. 
Those demonstration videos in medical education applied the same style as our devel-
oped video. They were annotated using animations, labels, and diagrams. Those videos 
also were explained using audio recording [16].

However, the pre-test and post-test in our findings did not include psychomotor 
skills. Future research must focus on measuring the students’ performance skill when 
they perform the practical session in flipped classroom design.

130 http://www.i-jim.org



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

4.9 Final product revision

During the operational field testing, the students did not provide any suggestions for 
revisions. Even when the video was ended in the classroom, almost all students clapped 
their hands. The students also wrote praise comments in their open questionnaire, such 
as “good,” “awesome,” or “keep your good work.” It indicated that this video did not 
require any further revision.

4.10 Dissemination and implementation

The learning video was then uploaded on the YouTube channel Boga UNY with 
the URL https://youtu.be/48y0hSyFvGk. YouTube was chosen because it provided the 
best video quality for video streaming and was suitable for multimedia applications in 
education [43]. The learning video on making pickled fruits have already received a 
copyright certificate. The video is embedded in the LMS to be used in the flipped class-
room learning in the Food Preservation Technology course.

Many findings reported the struggle to develop learning videos that were preferred 
by Generation Z. The time needed for material preparation to provide a learning video 
for flipped classroom design is more outrageous than conventional lectures. The educa-
tion institutions are recommended to support funds to develop such videos. Few reports 
described the development and implementation of demonstration videos in the field 
of food technology, so this video will guide teachers to develop videos preferred by 
Generation Z in this subject.

5 Conclusion

The study developed a learning video that explained the process of making pickled 
fruits. The video was in the form of a demonstration video which contained the open-
ing, content, and closing section. The presenter greeted the audience in the opening 
section. A demonstrator visualized the content section. The presenter did not present 
in the demonstration sessions to avoid the audience’s focus distraction. The content 
section consisted of tool and material preparation, production process, and expired 
date evaluation. This session also used voice-over techniques to support the demon-
stration process. The presenter delivered the closing section and explaining about the 
evaluation results and conclusions. The video was annotated with text, images, 2D 
animation, effects, and transitions to elevate users’ understanding. The students pre-
ferred these visual insertions. Nevertheless, the demonstrator did not use the equipment 
which supports personal hygiene. The demonstrator’s personal hygiene and uniform 
details should be considered more thoroughly in the video production. The demon-
stration video was useful to prepare students’ readiness before performing a practical 
session in the laboratory. Therefore, the demonstration videos are recommended to be 
implemented in a flipped classroom design. The videos are embedded in the LMS for 
self-directed asynchronous learning. The students then come to the laboratory to prac-
tice activities, as explained in the video. Further research is necessary to study whether 
demonstration videos can improve students’ psychomotor skills.

iJIM ‒ Vol. 15, No. 19, 2021 131



Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

6 Acknowledgment

This research was kindly funded by Research Grant Penelitian Unggulan Pergu-
ruan Tinggi from Universitas Negeri Yogyakarta in the 2019 budget year, with contract 
number 42/Penelitian/UPT/UN 34.21/2019.

7 References

 [1] B. Shatto and K. Erwin, “Teaching millennials and Generation Z: Bridging the 
generational divide,” Creat. Nurs., vol. 23, no. 1, pp. 24–28, 2017. https://doi.
org/10.1891/1078-4535.23.1.24

 [2] J. Chicca and T. Shellenbarger, “Connecting with Generation Z: Approaches in nursing 
education,” Teach. Learn. Nurs., vol. 13, no. 3, pp. 180–184, 2018. https://doi.org/10.1016/j.
teln.2018.03.008

 [3] I. Reychav and D. Wu, “Mobile collaborative learning: The role of individual learning in 
groups through text and video content delivery in tablets,” Comput. Human Behav., vol. 50, 
pp. 520–534, 2015. https://doi.org/10.1016/j.chb.2015.04.019

 [4] E. Gulicheva, E. Lisin, M. Osipova, and A. Khabdullin, “Leading factors in the formation of 
innovative education environment,” J. Int. Stud., vol. 10, no. 2, pp. 129–137, 2017. https://
doi.org/10.14254/2071-8330.2017/10-2/9

 [5] E. Nielsen and A. M. Sheppard, “Television as a patient education tool: A review 
of its effectiveness,” Patient Educ. Couns., vol. 11, pp. 3–16, 1988. https://doi.
org/10.1016/0738-3991(88)90072-9

 [6] G. Foster and S. Stagl, “Design, implementation , and evaluation of an inverted (flipped) 
classroom model economics for sustainable education course,” J. Clean. Prod., vol. 183, 
pp. 1323–1336, 2018. https://doi.org/10.1016/j.jclepro.2018.02.177

 [7] M. A. Corbally, “Considering video production? Lessons learned from the production of a 
blood pressure measurement video,” Nurse Educ. Pract., vol. 5, no. 6, pp. 375–379, 2005. 
https://doi.org/10.1016/j.nepr.2005.04.003

 [8] K. McKenny, “Using an online video to teach nursing skills,” Teach. Learn. Nurs., vol. 6, 
no. 4, pp. 172–175, 2011. https://doi.org/10.1016/j.teln.2011.04.003

 [9] E. J. Hibbert, T. Lambert, J. N. Carter, D. L. Learoyd, S. Twigg, and S. Clarke, “A random-
ized controlled pilot trial comparing the impact of access to clinical endocrinology video 
demonstrations with access to usual revision resources on medical student performance 
of clinical endocrinology skills,” BMC Med. Educ., vol. 13, no. 1, p. 1, 2013. https://doi.
org/10.1186/1472-6920-13-135

 [10] A. Pfennig, “Inverting the classroom in an introductory material science course,” 
Procedia - Soc. Behav. Sci., vol. 228, no. June, pp. 32–38, 2016. https://doi.org/10.1016/j.
sbspro.2016.07.005

 [11] A. A. Anggraeni, D. Nurtriyanti, W. Rinawati, and D. E. Murniati, “Developing 
video for agriculture product processing course in the subject of garlic snack produc-
tion,” Journal of Physics: Conference Series, vol. 1446, p. 012065, 2020. https://doi.
org/10.1088/1742-6596/1446/1/012065

 [12] W. Rinawati, P. M. Ghassani, and A. A. Anggraeni, “The development of an engaging 
demonstration video for making shredded chicken,” Journal of Physics: Conference Series, 
vol. 1810, p. 012043, 2021. https://doi.org/10.1088/1742-6596/1810/1/012043

132 http://www.i-jim.org

https://doi.org/10.1891/1078-4535.23.1.24
https://doi.org/10.1891/1078-4535.23.1.24
https://doi.org/10.1016/j.teln.2018.03.008
https://doi.org/10.1016/j.teln.2018.03.008
https://doi.org/10.1016/j.chb.2015.04.019
https://doi.org/10.14254/2071-8330.2017/10-2/9
https://doi.org/10.14254/2071-8330.2017/10-2/9
https://doi.org/10.1016/0738-3991(88)90072-9
https://doi.org/10.1016/0738-3991(88)90072-9
https://doi.org/10.1016/j.jclepro.2018.02.177
https://doi.org/10.1016/j.nepr.2005.04.003
https://doi.org/10.1016/j.teln.2011.04.003
https://doi.org/10.1186/1472-6920-13-135
https://doi.org/10.1186/1472-6920-13-135
https://doi.org/10.1016/j.sbspro.2016.07.005
https://doi.org/10.1016/j.sbspro.2016.07.005
https://doi.org/10.1088/1742-6596/1446/1/012065
https://doi.org/10.1088/1742-6596/1446/1/012065
https://doi.org/10.1088/1742-6596/1810/1/012043


Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

 [13] A. A. Anggraeni and W. A. A. Setiawan, “Developing learning video of making mango sorbet 
for agriculture product processing course,” IOP Conference Series: Materials Science and 
Engineering, vol. 1098, p. 022097, 2021. https://doi.org/10.1088/1757-899X/1098/2/022097

 [14] A. A. Anggraeni and R. A. Surya, “Developing a Demonstration Video on Making Dry 
Banana Preferred by Generation Z,” Journal of Physics: Conference Series, vol. 1737,  
p. 012037, 2021. https://doi.org/10.1088/1742-6596/1737/1/012037

 [15] D. Histifarina, “Studi penerapan hazard analysis critical control point (haccp) pada industri 
kecil manisan buah kering,” Bul. Has. Kaji. Balai Pengkaj. Teknol. Pertan. Jawa Barat, 
vol. 4, no. 4, pp. 21–28, 2014.

 [16] K. J. Liu et al., “A video-based, flipped classroom, simulation curriculum for dermatologic 
surgery: A prospective, multi-institution study,” J. Am. Acad. Dermatol., vol. 81, no. 6, 
pp. 1271–1276, 2019. https://doi.org/10.1016/j.jaad.2019.03.078

 [17] I. Lestari, A. Maksum, and C. Kustandi, “Mobile learning design models for State Univer-
sity of Jakarta, Indonesia,” Int. J. Interact. Mob. Technol., vol. 13, no. 9, pp. 152–171, 2019. 
https://doi.org/10.3991/ijim.v13i09.10987

 [18] C. Riyana, Pedoman Pengembangan Media Video. Jakarta: Program P3AI UPI, 2007.
 [19] T. Long, J. Logan, and M. Waugh, “Students’ perceptions of the value of using videos 

as a pre-class learning experience in the flipped classroom,” TechTrends, vol. 60, no. 3, 
pp. 245–252, 2016. https://doi.org/10.1007/s11528-016-0045-4

 [20] R. E. Mayer and R. Moreno, “Nine ways to reduce cognitive load in multimedia learning,” 
Educ. Psychol., vol. 38, no. 1, pp. 43–52, 2003. https://doi.org/10.1207/S15326985EP3801_6

 [21] M. N. Giannakos, K. Chorianopoulos, M. Ronchetti, P. Szegedi, and D. Stephanie, 
“Video-based learning and open online courses,” Int. J. Emerg. Technol. Learn., vol. 9, no. 
1, pp. 4–7, 2014. https://doi.org/10.3991/ijet.v9i1.3354

 [22] A. Hansch, L. Hillers, K. McConachie, C. Newman, T. Schildhauer, and P. Schmidt, “Video 
and online learning: critical reflections and findings from the field,” SSRN Electron. J., 2015. 
https://doi.org/10.2139/ssrn.2577882

 [23] C. J. Brame, “Effective educational videos: Principles and guidelines for maximizing student 
learning from video content,” CBE-Life Sci. Educ., pp. 1–6, 2016. https://doi.org/10.1187/
cbe.16-03-0125

 [24] A. K. Amin, I. N. S. Degeng, P. Setyosari, and E. T. Djatmika, “The effectiveness of mobile 
blended problem based learning on mathematical problem solving,” Int. J. Interact. Mob. 
Technol., vol. 15, no. 1, pp. 119–141, 2021. https://doi.org/10.3991/ijim.v15i01.17437

 [25] M. N. Giannakos, J. Krogstie, and T. Aalberg, “Video-based learning ecosystem to support 
active learning: application to an introductory computer science course,” Smart Learn. 
Environ., vol. 3, no. 11, pp. 1–13, 2016. https://doi.org/10.1186/s40561-016-0036-0

 [26] S. Korkut, R. Dornberger, P. Diwanji, B. P. Simon, and M. Märki, “Success factors of online 
learning videos,” Int. J. Interact. Mob. Technol., vol. 9, no. 4, pp. 17–22, 2015. https://doi.
org/10.3991/ijim.v9i4.4460

 [27] Z. Pi, K. Xu, C. Liu, and J. Yang, “Instructor presence in video lectures: Eye gaze matters, 
but not body orientation,” Comput. Educ., vol. 144, no. 152, 2020. https://doi.org/10.1016/j.
compedu.2019.103713

 [28] H. van der Meij, “Reviews in instructional video,” Comput. Educ., vol. 114, pp. 164–174, 
2017. https://doi.org/10.1016/j.compedu.2017.07.002

 [29] Sugiyono, Metode Penelitian Pendidikan Pendekatan Kualitatif, Kuantitatif, dan R&D. 
Bandung: Alfabeta, 2016.

 [30] M. D. Gall, J. P. Gall, and W. R. Borg, Educational Research: An Introduction, Seventh ed. 
Boston: Allyn & Bacon, 2003.

iJIM ‒ Vol. 15, No. 19, 2021 133

https://doi.org/10.1088/1757-899X/1098/2/022097
https://doi.org/10.1088/1742-6596/1737/1/012037
https://doi.org/10.1016/j.jaad.2019.03.078
https://doi.org/10.3991/ijim.v13i09.10987
https://doi.org/10.1007/s11528-016-0045-4
https://doi.org/10.1207/S15326985EP3801_6
https://doi.org/10.3991/ijet.v9i1.3354
https://doi.org/10.2139/ssrn.2577882
https://doi.org/10.1187/cbe.16-03-0125
https://doi.org/10.1187/cbe.16-03-0125
https://doi.org/10.3991/ijim.v15i01.17437
https://doi.org/10.1186/s40561-016-0036-0
https://doi.org/10.3991/ijim.v9i4.4460
https://doi.org/10.3991/ijim.v9i4.4460
https://doi.org/10.1016/j.compedu.2019.103713
https://doi.org/10.1016/j.compedu.2019.103713
https://doi.org/10.1016/j.compedu.2017.07.002


Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

 [31] C. Ruiz-Capillas and F. Jiménez-Colmenero, “Application of flow injection analysis for 
determining sulphites in food and beverages: A review,” Food Chem., vol. 112, no. 2, 
pp. 487–493, 2009. https://doi.org/10.1016/j.foodchem.2008.05.085

 [32] S. P. Ong and C. L. Law, “Microstructure and optical properties of salak fruit under different 
drying and pretreatment conditions,” Dry. Technol., vol. 29, no. 16, pp. 1954–1962, 2011. 
https://doi.org/10.1080/07373937.2011.606389

 [33] M. V. Martinez and J. R. Whitaker, “The biochemistry and control of enzymatic browning,” 
Trends Food Sci. Technol., vol. 6, no. 6, pp. 195–200, 1995. https://doi.org/10.1016/
S0924-2244(00)89054-8

 [34] R. Mayer, Ed., The Cambridge Handbook of Multimedia Learning. Cambridge: Cambridge 
University Press, 2014. https://doi.org/10.1017/CBO9781139547369

 [35] K. Malkiewicz and M. D. Mullen, Cinematography: Third Edition, 3rd edition. New York: 
Touchstone, 2005.

 [36] J. A. Okun and S. Zwerman, Eds., The VES Handbook of Visual Effects. Elsevier Inc. All 
rights reserved, 2010.

 [37] F. R. Pradhana, J. Karaman, and S. Andriyanto, “Optimalisasi penggunaan efek chroma 
key pada video dengan menggunakan metode dual layer greenscreen,” Semnasteknomedia 
Online, vol. 4, no. 5, pp. 6–7, 2016.

 [38] D. N. Bonafix, “Videografi: Kamera dan teknik pengambilan gambar,” Humaniora, vol. 2, 
no. 1, p. 845, 2011. https://doi.org/10.21512/humaniora.v2i1.4015

 [39] T. S. Chee and A. F. L. Wong, Teaching and Learning with Technology: An Asia-Pasific 
Perspective. Singapure: Pearson/Prentice Hall, 2003.

 [40] S. J. Tang, F. Hagenmüller, P. Sharma, H. Yamamoto, and J. Pohl, “Creating video 
manuscripts for the video journal & encyclopedia of GI endoscopy: Tips and comments 
from the editors,” Video J. Encycl. GI Endosc., vol. 2, no. 1, pp. 12–14, 2014. https://doi.
org/10.1016/j.vjgien.2013.01.001

 [41] M. Ljubojevic, V. Vaskovic, S. Stankovic, and J. Vaskovic, “Using supplementary 
video in multimedia instruction as a teaching tool to increase efficiency of learning and 
quality of experience,” Int. Rev. Res. Open Distance Learn., vol. 15, no. 3, pp. 275–291, 
2014. https://doi.org/10.19173/irrodl.v15i3.1825

 [42] D. Tapscott, Grown Up Digital: How the Net Generation is Changing Your World. New 
York: McGraw-Hill, 2009.

 [43] W. M. Jackman, “YouTube usage in the university classroom: An argument for its pedagog-
ical benefits,” Int. J. Emerg. Technol. Learn., vol. 14, no. 9, pp. 157–165, 2019. https://doi.
org/10.3991/ijet.v14i09.10475

8 Authors

Andian Ari Anggraeni is a a lecturer in Universitas Negeri Yogyakarta, Faculty of 
Engineering, Culinary Science study program in Yogyakarta, Indonesia. Her research 
interest includes pastry and bakery product science, functional food, and food science 
education. She is actively developing learning videos, virtual reality, and blended/
online learning courses in Food Science and Technology.

Sumaryana had been graduated from bachelor’s degree of Culinary Science 
study program, Universitas Negeri Yogyakarta, Yogyakarta, Indonesia (email: 
sumaryana.2016@student.uny.ac.id).

134 http://www.i-jim.org

https://doi.org/10.1016/j.foodchem.2008.05.085
https://doi.org/10.1080/07373937.2011.606389
https://doi.org/10.1016/S0924-2244(00)89054-8
https://doi.org/10.1016/S0924-2244(00)89054-8
https://doi.org/10.1017/CBO9781139547369
https://doi.org/10.21512/humaniora.v2i1.4015
https://doi.org/10.1016/j.vjgien.2013.01.001
https://doi.org/10.1016/j.vjgien.2013.01.001
https://doi.org/10.19173/irrodl.v15i3.1825
https://doi.org/10.3991/ijet.v14i09.10475
https://doi.org/10.3991/ijet.v14i09.10475
mailto:sumaryana.2016@student.uny.ac.id


Paper—The Development of Video on Pickled Fruit Production for Flipped Classroom

Wika Rinawati is a lecturer in the Universitas Negeri Yogyakarta, Faculty of 
Engineering, Culinary Science study program, Yogyakarta, Indonesia. Her research 
interest is learning media technology. She frequently engaged in video production in 
food production and food and beverage service (email: wika@uny.ac.id).

Dewi Eka Murniati is a lecturer in the Universitas Negeri Yogyakarta, Faculty of 
Engineering, Culinary Science study program, Yogyakarta, Indonesia. Her research 
interests are in hospitality and tourism management, digital marketing, and vocational 
education (email: dewi_ekamurniati@uny.ac.id).

Article submitted 2021-03-17. Resubmitted 2021-07-31. Final acceptance 2021-07-31. Final version 
published as submitted by the authors.

iJIM ‒ Vol. 15, No. 19, 2021 135

mailto:wika@uny.ac.id
mailto:dewi_ekamurniati@uny.ac.id