Posyandu Application for Monitoring Children Under-Five: A 3-Year Data Quality Map in Indonesia

Rinawan, Fedri Ruluwedrata; Faza, Afina; Susanti, Ari Indra; Purnama, Wanda Gusdya; Indraswari, Noormarina; Didah,; Ferdian, Dani; Fatimah, Siti Nur; Purbasari, Ayi; Zulianto, Arief; Sari, Atriany Nilam; Yulita, Intan Nurma; Rabbi, Muhammad Fiqri Abdi; Ridwana, Riki

doi:10.3390/ijgi11070399

Open AccessArticle

Posyandu Application for Monitoring Children Under-Five: A 3-Year Data Quality Map in Indonesia

by

Fedri Ruluwedrata Rinawan

^1,2,3,*

,

Afina Faza

^4,5

,

Ari Indra Susanti

^1,2,

Wanda Gusdya Purnama

⁶,

Noormarina Indraswari

^1,2,

Didah

^1,2,

Dani Ferdian

^1,2,

Siti Nur Fatimah

¹,

Ayi Purbasari

⁶,

Arief Zulianto

⁷,

Atriany Nilam Sari

⁸

,

Intan Nurma Yulita

^9,10

,

Muhammad Fiqri Abdi Rabbi

^3,11 and

Riki Ridwana

^3,11

¹

Department of Public Health, Faculty of Medicine, Universitas Padjadjaran, Jalan Ir. Soekarno KM. 21, Jatinangor, Sumedang 45363, Indonesia

²

Center for Health System Study and Health Workforce Education Innovation, Faculty of Medicine, Universitas Padjadjaran, Jl. Eyckman No. 38, Bandung 40161, Indonesia

³

Indonesian Society for Remote Sensing Branch West Java, Gedung Labtek IX-C lt.3 Jalan Ganesha 10, Institut Teknologi Bandung, Bandung 40132, Indonesia

⁴

Master of Public Health Study Program, Faculty of Medicine, Universitas Padjadjaran, Jalan Eyckman No. 38 Gedung RSP Unpad Lantai 4, Bandung 40161, Indonesia

⁵

Biomedical Engineering Study Program, School of Electrical Engineering, Telkom University, Jl. Telekomunikasi No. 1, Terusan Buahbatu—Bojongsoang, Sukapura, Dayeuhkolot, Bandung 40257, Indonesia

⁶

Informatics Engineering Study Program, Faculty of Engineering, Universitas Pasundan, Jl. Dr. Setiabudi No. 193, Bandung 40153, Indonesia

⁷

Postgraduate Master Study Program of Informatics Engineering, Universitas Langlangbuana, Jl. Karapitan No. 116, Cikawao, Kec. Lengkong, Bandung 40261, Indonesia

⁸

Midwifery Study Program, Faculty of Medicine, Universitas Sebelas Maret, Jl. Ir. Sutami No. 36, Kentingan, Jebres, Surakarta 57126, Indonesia

⁹

Department of Computer Science, Faculty of Mathematics and Natural Sciences, Universitas Padjadjaran, Jalan Ir. Soekarno KM. 21, Jatinangor, Sumedang 45363, Indonesia

¹⁰

Research Center for Artificial Intelligence and Big Data, Universitas Padjadjaran, Jalan Ir. Soekarno KM. 21, Jatinangor, Sumedang 45363, Indonesia

¹¹

Geographic Information Science Study Program, Faculty of Social Sciences Education, Universitas Pendidikan Indonesia, Jalan Dr. Setiabudi No. 299, Bandung 40154, Indonesia

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ISPRS Int. J. Geo-Inf. 2022, 11(7), 399; https://0-doi-org.brum.beds.ac.uk/10.3390/ijgi11070399

Submission received: 3 May 2022 / Revised: 9 July 2022 / Accepted: 10 July 2022 / Published: 13 July 2022

(This article belongs to the Topic Advances in Sustainable Communities, Neighborhoods and 15-Minute Cities-Theory, Methods and Techniques)

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Abstract

:

Posyandu is an Indonesian mother-child health, community-based healthcare. The provision of the Posyandu data quality map is crucial for analyzing results but is limited. This research aimed to (a) demonstrate data quality analysis on its completeness, accuracy, and consistency and (b) map the data quality in Indonesia for evaluation and improvement. An observational study was conducted using the Posyandu application. We observed data in Indonesia from 2019 to 2021. Data completeness was identified using children’s visits/year. Data accuracy was analyzed using WHO anthropometry z-score and implausible z-score values analyzing the outliers. Cronbach’s α of variables was used to know data consistency. STATA 15.1 SE and QGIS 3.10 was used to analyze and map the quality. Data completeness and accuracy in three years show a good start for the pilot project area, continued with declines in pandemic time, while some other areas demonstrated a small start, then slightly increased. The overall consistency decreased through the study period. A good report on data completeness can occur initially in a pilot project area, followed by others. Data accuracy and consistency can decrease during the pandemic. The app can be promising when synchronized with the government health information system.

Keywords:

data quality; iPosyandu; map; mHealth

1. Introduction

Health informatics tools (HIT) using mobile health (mHealth) apps have been widely used because they can collect data from end-users and store them in a source database [1]. Using a healthcare setting results in electronic medical record documentation and database storage [2]. Such documentation is also needed in the community healthcare setting. For example, community health workers (CHWs) use mobile apps rather than laptops because they are easier to use. However, using it is another training issue because technology literacy about documentation and reporting needs much effort [3]. Moreover, access to adequate training in technology literacy during the pandemic is problematic [2,4]. It can cause poor data quality [4,5,6]. Data quality is a prerequisite for data analysis in medical research, preventing errors, and providing information for evidence-based intervention in health promotion [7,8]. Providing evidence-based policy depends on analysis that must use processed data quality from raw to ready-to-analyzed data. In general, public health data quality in an information system consists of many dimensions. Examples include completeness, accuracy, timeliness or up-datedness, validity, relevance, reliability, comparability, internal or external consistency, and data management [6]. The World Health Organization (WHO) reviewed four dimensions: (1) completeness and timeliness, (2) internal consistency, (3) external consistency, and (4) external comparison [9]. The accuracy analysis observed data with the WHO Child Growth standard formula to get the proportion of plausible values [10].

In Indonesia, a mother-child health (MCH) community healthcare setting has been established since the 1980s, named Posyandu, abbreviated from Pos Pelayanan Terpadu or Integrated service post [3,11,12]. Posyandu is located in every village, run by CHWs, and supervised by a village midwife in coordination with Pusat Kesehatan Masyarakat (Puskesmas) or the Public Health Center [3,13]. Regarding mHealth, midwives and CHWs have access to MCH’s data. Midwives can perform MCH screening, assessment, implementation, and evaluation of midwifery care based on the data [14]. Posyandu monthly activities start from registering mothers and their under-five children, measuring weight and height, giving nutritional education, and immunizations. In addition, vitamin A is given twice a year (in February and August) [12]. The CHWs record those activities in their notebook and then rewrite those data into the Posyandu information system (PIS) book and the mother-child health (MCH) book. Then, it is given to Puskesmas, the first layer of prehospital healthcare facilities for treating health problems. Afterward, data is received by healthcare workers (HCWs), such as midwives, nutrition staff, and nurses in Puskesmas, and reported using the national government application (app), such as a nutrition recording and reporting, called the ePPGBM app. However, documenting and reporting activities from Posyandu at the community to the national level is a long and time-consumed process.

To shorten the process, we built an independent mobile health application for Posyandu, the iPosyandu app, in 2017. Interoperability with the government’s health information system, such as ePPGBM, is the primary goal of building the iPosyandu app. The ePPGBM provides Excel forms that can be imported to it. iPosyandu can export similar Excel forms already filled in with the MCH data needed, then import the forms to the ePPBGM. The iPosyandu app was initiated, implemented, and evaluated in our pilot project area, Purwakarta Regency, West Java. Then the use widened to almost all provinces in Indonesia. However, the data quality needs improvement. Efforts to build capacity for CHWs and mothers of children under five using the app have been conducted since 2018. CHWs need more time to adapt to the app, from registering their identity (id) to the data collection [3] and being supervised by village midwives to obtain good data quality. Thus, the data can be used to improve the analysis results.

Previous research provided healthcare data with geographical information system (GIS) [15,16,17], and other research depicted environmental health analysis also using GIS [18]. According to International Organization for standardization, mapping geographical data quality comprises categories such as completeness, logical consistency, positional and thematical accuracy, and temporal quality [19]. Providing a community data quality map is crucial before analyzing results using GIS [20], but recent literature reviews stated that it is challenging [21,22], more importantly for our country, Indonesia. A data quality map in nutrition is most commonly derived from regional or national anthropometric data but lacks household data [23]. Our research provides more detail than household data. We analyzed data quality from individual data, i.e., relating to each child. The data quality map is critical and beneficial for further analysis to build a higher quality information system for social purposes, such as promoting health [24]. Furthermore, data quality is vital for machine learning, GIS, and social remote sensing (remote sensing complemented by social studies) to complete the health information system [25]. The problem that needs to be solved to gain good data quality relates to the person who performs the data entry [26]. A dedicated person for such a task is essential to an organization. However, data entry officers are often in limited numbers in healthcare settings because they focus on health services rather than data entry. In this context, we hypothesize that the data quality has improved over the last three years as CHWs learned how to use the app. Three indicators were analyzed to assess variations in data quality: the data completeness, the proportion of plausible values, and the consistency of collected variables. We also mapped these indicators over the years to see if they evolved similarly across Indonesia.

2. Materials and Methods

An observational study was conducted using the Posyandu application, named iPosyandu, registered in Google Play in December 2018, as a result of the project starting in Purwakarta regency, West Java/Jawa Barat province. Since then, its use has spread all over Indonesia until now. We observed the data quality for the last three years (2019–2021). We chose 3 of 4 dimensions from the WHO data quality review (DQR) framework: (1) completeness, (2) accuracy, and (3) internal consistency [9]. We did not use the fourth dimension, external consistency, because the iPosyandu back-end has not yet been connected with the government HIT. Thus, we have not had access to it. WHO stated that completeness refers to the percentage of monthly reports in a year. In the context of this research, we define accuracy as the proportion of plausible values in the data (i.e., not outliers, as defined by WHO). Consistency corroborates internal consistency between related data items at different times [3].

Before analysis, data duplications were tested using the identification number (id) of children under five and the date of the visit to Posyandu. We want to ensure no more than one data entry per child per month, reflecting one report to Posyandu monthly. The reason is that Posyandu activity per village is held monthly. Ideally, it is expected to be 12 visits in a year. WHO categorizes reporting data of 9–12 visits per year as the expected complete report of Posyandu [9]. Our data completeness was identified using one variable, which has the category of 1–4, 5–8, and 9–12 visits reported per year. The cell percentage of data completeness and accuracy of all provinces were presented in the table results. WHO stated that the timeliness of district reporting should be at least 75% of the monthly reports submitted on time, and received at the national level from the district. The WHO also suggests that the benchmark depends on each country. Our Ministry of Health mentioned 75% as 2022’s target [27].

In the context of our research, data accuracy was analyzed using WHO Child Growth Standards to get the proportion of outliers (implausible values) and accurate (plausible values). It has been standardized and widely used, and we use WHO anthropometry standards in the app’s back-end. The standard can be installed from the STATA package installer to run the data accuracy using four variables: age, weight, height, and gender. In Posyandu activities, these data are collected: age and gender are from registration, then weight and height are recorded in the mother-child health (MCH) book after measurement. The presence of outliers was analyzed by the WHO criteria of implausible z-score value: waz (weight per age) > 5 standard deviations (SD) and <−6 SD, haz (height per age) > 6 and <−6, whz (weight per height) > 5 and <−5 SD [10]. This implausible value is an alarm sign for reassessment whether it is an existing biological confounding or technical reason, such as a human error in data entry [10,28]. The remaining observations are considered plausible values. We did not delete the data duplication to see the data entry behaviors in analyzing the accuracy and consistency. Thus, it may result in a higher total number of data. The Chi-square test was used to analyze the difference in completeness and accuracy in 3 years. We hypothesize that there were differences in completeness and accuracy between years, and this information can support data quality measurement [6].

Data consistency was analyzed using Cronbach Alpha of 5 variables used in iPosyandu: ownership of mother-child health (MCH) book, anthropometry as the result of weight and height measurement, supplementary feeding as the service in Posyandu for baby and child, including those who suffer diarrhea, immunizations as the data that need to be recorded in MCH book, and vitamin A that routinely given twice a year. The WHO mentioned four metrics of internal consistency; in this research, we used the coherence between the related data items and at different time points because we do not have access to review of source documents in health facilities [9]. STATA version 15.1 Special Edition License (StataCorp LLC, College Station, Texas 77845, USA) was used for the analysis. QGIS 3.10 (open source) and shapefile of the 34 provinces in Indonesia were used to map the data quality. The community activities in Posyandu are participatory empowerment. Community participation can be mapped as social mapping. Social mapping represents a way to visualize the aspects of society in specific periods, such as participatory social patterns over time and the relationship between society and spatial factors. In social mapping, more classes are required to display visual information in each region. We used more classes in the completeness and accuracy maps. If a smaller number of classes is used, the information of each region will not be visible [29,30].

3. Results

Table 1 depicts total data completeness with a significant difference from 2019 to 2021, starting from 28.73%, where 11.23% completed their visits (9–12/year) to Posyandu. In 2020 (pandemic year 1), the total completeness was 19.31%, of which 11.74% still visited 1–4 times a year. In 2021, it increased to 51.96% (pandemic year 2), with most of the 1–4 and 5–8 visits/year. We checked duplication on the completeness, and we found 3583 (5.36%) duplications, resulting in 63,272 non-duplications (Table 1) from the total data of 66,855 (this total number is stated in Table 2).

Total data accuracy decreased at the beginning of the pandemic year (2020) and increased in the next year, in which the outliers continuously decreased in these three years. The difference between years is significant (<0.05). This information can be seen in Table 2.

The detail of data quality in every province in the three years is explained below. It is illustrated in Table 3 (the completeness), Table 4 (The accuracy and consistency), and Figure 1, Figure 2 and Figure 3.

3.1. Data Completeness

Table 3 shows data completeness per province from 2019 to 2021. We highlight some emerging results from the total data completeness. We found good reporting data on completeness (87.68%) in West Java (Jawa Barat) but low in Jakarta (3.8%), Central Sulawesi/Sulawesi Tengah (2.73%), Bali (2.18%), Lampung (1.15%), and the rest of the provinces. Generally, complete data in almost all provinces decreased within three years. West Java is the province with the most profound decreased gap between 2019 and the following pandemic years, whereas Central Sulawesi, which started low, slightly increased in the following years. The red highlight on the table refers to no data available because the CHWs in the province did not use the app. We used the other highlights to make the reader easier to locate the completeness of use. The maps in Figure 1a–c demonstrate the total completeness comprising the summary of the number of visits to Posyandu: 1–4, 5–8, and 9–12 visits/year. The spread of the app use completeness decreases in spatial distribution (Figure 1) but is higher in percentage than in the previous years (51.96%, p < 0.05 in Table 1). The community healthcare activities, including data entry, decreased during the pandemic, and some areas in the country concentrated on improving the number of Posyandu reports on mother and child visits, including after the pandemic.

3.2. Data Accuracy and Consistency

Table 4 illustrates data accuracy and consistency per province from 2019- to 2021. We found that West Java holds the highest accuracy percentage because this is the pilot project province. Other provinces that participated in using the app, such as Jakarta, Central Sulawesi, East Java, and Bali, were lower in accuracy percentages. We used the red, yellow, and green highlight colors with a similar function as in the data completeness section. Figure 2a–c shows the total data accuracy within the three years, generally similar to the completeness. The accuracy of areas like Jakarta, Central Sulawesi, and East Java is increasing, albeit the pandemic. Although the spatially higher spread area (white part, not accurate) through the years (Figure 2), data accuracy inclined on the existing colored provinces in 2021 (Table 4).

The overall consistency in each year was 0.56, 0.49, and 0.45, respectively. On the map (Figure 3a–c), we used classifications of high consistency (>0.7–1), medium (>0.5–0.7), low (0,3–0,5), not consistent (<0.3) [31,32]. We detailed the ‘not consistent’ listed on the map’s legend, so we do not lose the information. In Table 4, we can see that higher consistency can occur on a small number of data and the other way around. The not available data part (red on the data accuracy column or “no obs” on the consistency column) can be interpreted as people not using the app.

4. Discussion

Our data quality (completeness, accuracy, and consistency), which is still in the first three years, demonstrates good quality for the pilot project area but low in others. Data quality of health informatics tools may still be challenging for long-term use. Some applications need eight years to reach good quality. It is promising that consistent app development with training, e.g., using tutorial videos on the app, is vital [33]. Choosing one area is vital for a pilot project in development [34]. After registering in Google Play, when focusing on user-friendliness implemented in the regency, an app can endow easier usability for end-users in other areas in the same country. The main factors embedded in the end-users for data quality are digital literation, motivation, and characteristics (education level, age, profession) [33,35,36].

The criteria of the cadre can shift to younger productive ages because this chooses for longer working life in community healthcare [37]. Previous research stated that the younger aged person could coach the older aged person, creating higher capabilities for the older aged person to perform in digital health [38]. However, older cadres have more mature working experiences than younger ones [39]. In our pilot project area, we found that age was not related to their knowledge in running the mHealth because the learning process can occur at either younger or older [40]. The younger the age, the higher the digital literacy and the other way around. Nevertheless, regardless of age, training and motivation can increase the service and data entry [3,40,41]. The support factor from the midwife also plays an essential role in monitoring, supervising, and verifying the inputted data by the cadre using mHealth. This collaborative support can motivate the cadre to use mHealth [42]. Thus, inputting and reporting data from CHWs to midwives through mHealth can be faster and on time [43]. Both roles (of midwife and cadre) are interrelated for the satisfaction of the cadre in using the app. Collaboration of them is a cornerstone in running the consistency of Posyandu [3,11]. Determinant factors that affect the use of applications include perceived benefits, obstacles, and the appearance of easy applications [44]. User comfort is the main thing in achieving satisfaction. There are five dimensions in measuring application satisfaction: content dimensions [45], data accuracy dimensions [46,47], display dimensions [48], ease of use dimensions [49], and timeliness [50].

On the community level, the presence of a village midwife can coach and supervise the cadre when performing service, data documentation, and report. In the first level of the healthcare center in Indonesia, called, Puskesmas, data can be retrieved, checked, and verified by the healthcare workers (HCWs) before sending it to the regency health office and Ministry of Health. Regarding the transition from manual to digital, on the one hand, this transition can slow the cadre’s process of using the app for service, data recording, and reporting. However, the length of the process is around 2–3 years, enough for development and knowledge diffusion before going faster [3]. The local government can “push” the performance of healthcare workers and their motivation to support CHWs [37] by educating mothers, performing screening, e.g., weight and height, and record them, and referring suspected individuals to village midwives [3]. Governments support their work by giving material rewards, such as incentives [37]. More importantly, providing an internet quota is vital in supporting the gadget [51]. In addition, decentralization from the national government to the local government can make more flexible budget allocations depending on the local condition [52].

The Indonesian government has initiated a human development cadre (HDC) program in 2020/2021 focusing on social mapping through Posyandu, such as on nutritional (malnutrition, stunting, wasting) and environmental (lavatory availability) problems, service, and data recording, even though fewer cadres have been recruited [53]. From these nutritional and environmental factors in Posyandu, social mapping can be generated as a map with an administrative borderline to illustrate the information from each area, e.g., village, district, city, regency, and province boundaries [53,54]. In this case, the social mapping can be supported by a data quality map in our research. Through the iPosyandu application, cadres can directly input the data resulting from the Posyandu activities, whose data can be directly downloaded and verified on data quality. The government e-PPBGM (electronic Community-Based Nutrition Recording and Reporting) app provides front-end integration that the similar Excel file result can be uploaded into the app [55]. So far, the implementation of data input in the e-PPBGM application is still carried out by Puskesmas officers based on measurements made by the cadres at the Posyandu. Therefore, through the use of iPosyandu by the cadres, this problem can overcome the problem of delays in data input in the e-PPBGM application [3].

Performing data quality maps can be a basis for further analysis, such as machine learning, remote sensing, and geographical information systems (RS-GIS). The machine learning method uses data to build an intelligent system. Data quality is the main course of this method for creating a model [56]. However, raw data is not clean [57]. Not-clean data comprises inconsistency, incompleteness, duplication, inaccuracy, and irrelevance. Experts can preprocess and validate such data before implementing machine learning [58]. In the sense of RS-GIS, data quality maps can support further correlation analysis to environmental factors. Implementing remote sensing technology can determine the environmental factors such as land cover and vegetation associated with human aspects such as diseases. Geographical information systems can positively impact health-service quality and help stakeholders place an excellent policy [15]. Community-health data quality in a country is better created on a map to be more understandable spatially about the data distribution on which province has higher data quality and which one needs improvement. More importantly, if it is in the form of WebGIS that it can be more accessible [20].

5. Conclusions

Good quality data is essential for data analysis in providing information for evidence-based health policy for public health. We analyzed the data quality from iPosyandu for the last three years (2019–2021) using 3 dimensions: completeness, accuracy, and internal consistency. It shows a good report on data completeness initially in a pilot project area, followed widely in other areas in Indonesia. The pilot project area is essential for building and refining health informatics tools. Other areas can voluntarily follow it because the refining process makes it more user-friendly. However, several factors influence the data quality, such as a pandemic can decrease the Posyandu activities causing hindrances in data entry and reporting. It also severely affects data accuracy and consistency. The app can be promising when synchronized with the government health information system. The limitation of our study is that the identification (id) number of the cadre who input the data is not yet connected with their data input activities. The id number is vital for interpreting whether the data is duplicated by the same or different cadre, by which further improvement can be added in the app tutorial. Another limitation was that the cutoff of implausible values was not yet added to the app, which influenced our data quality. Further work on the app should improve these limitations.

6. Patents

The iPosyandu application copyright has been registered since 2018 with the number 000103655 in Indonesia’s Ministry of Law and Human Rights.

Author Contributions

Writing, methodology, draft preparation, Fedri Ruluwedrata Rinawan, Afina Faza; conceptualization, Fedri Ruluwedrata Rinawan, Ari Indra Susanti, Dani Ferdian; software; database, data preparation, Wanda Gusdya Purnama, Ayi Purbasari, Intan Nurma Yulita; investigation of app security and functionality, Arief Zulianto, Wanda Gusdya Purnama; data validation, analysis, Siti Nur Fatimah, Noormarina Indraswari; data curation, formal analysis, Wanda Gusdya Purnama, Fedri Ruluwedrata Rinawan, Afina Faza, Noormarina Indraswari; writing—original draft preparation, Fedri Ruluwedrata Rinawan, Afina Faza, Ari Indra Susanti, Noormarina Indraswari, Intan Nurma Yulita, Riki Ridwana, Didah, Dani Ferdian, Atriany Nilam Sari; visualization, Fedri Ruluwedrata Rinawan, Afina Faza, Muhammad Fiqri Abdi Rabbi, Riki Ridwana; data mapping, Muhammad Fiqri Abdi Rabbi, Riki Ridwana; project advocacy, Dani Ferdian, Ari Indra Susanti, Fedri Ruluwedrata Rinawan; project administration, funding acquisition, Ari Indra Susanti, Didah, Fedri Ruluwedrata Rinawan; capacity building of end-users, Ari Indra Susanti, Wanda Gusdya Purnama, Didah, Atriany Nilam Sari, Noormarina Indraswari, Fedri Ruluwedrata Rinawan; writing—review, editing, and supervision, Fedri Ruluwedrata Rinawan. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Lecturer Competence Internal Grant of Universitas Padjadjaran, Indonesia, grant number 2476 /UN6.C/LT/2018; PT. Astra International Tbk, grant number 087/LOA-ESR/VII/2019; the Indonesia Endowment Fund for Education abbreviated LPDP (Lembaga Pengelola Dana Pendidikan); the Ministry of Finance, grant number PRJ-70/LPDP/2019; and the Kreasi Insani Persada Foundation, grant number (-).

Institutional Review Board Statement

The study was conducted in accordance with the Declaration of Helsinki and approved continuously by the Research Ethics Committee Universitas Padjadjaran (protocol code 830/UN6.C10/PN/2017, 1456/UN6.KEP/EC/2019, 433/UN6.KEP/EC/2020, 640/UN6.KEP/EC/2021, and 160/UN6.KEP/EC/2022).

Informed Consent Statement

We used secondary data from the iPosyandu app database. The iPosyandu users must read the terms and conditions, including the informed consent, and then agree to involve in the study before using the app. The database is under the copyright protection of Law in the Republic of Indonesia.

Data Availability Statement

Not applicable.

Acknowledgments

The authors acknowledge the Purwakarta Regency Office for permission to conduct the app’s research and development, including integrating the iPosyandu app into the government health information system. We also acknowledge all Posyandu, community healthcare center/Puskesmas, and regency/city health offices in Indonesia that have used the app to support their work for supporting community health in Indonesia; and Izma Maulana Ahmad Lugina from the Geographic Information Science Study Program, Faculty of Social Sciences Education, Universitas Pendidikan Indonesia for contributing his help to the map creation.

Conflicts of Interest

The authors declare no conflict of interest, and the funders had no role in the design of the study, in the collection, analyses, or interpretation of data, in the writing of the manuscript, or in the decision to publish the results.

References

O’Neil, I. Digital Health Promotion: A Critical Introduction; Polity Press: Cambridge, UK; Medford, MA, USA, 2019. [Google Scholar]
Sujarwoto, S.; Augia, T.; Dahlan, H.; Sahputri, R.A.M.; Holipah, H.; Maharani, A. COVID-19 Mobile Health Apps: An Overview of Mobile Applications in Indonesia. Front. Public Health 2022, 10, 879695. [Google Scholar] [CrossRef] [PubMed]
Rinawan, F.R.; Susanti, A.I.; Amelia, I.; Ardisasmita, M.N.; Dewi, R.K.; Ferdian, D.; Purnama, W.G.; Purbasari, A. Understanding mobile application development and implementation for monitoring Posyandu data in Indonesia: A 3-year hybrid action study to build “a bridge” from the community to the national scale. BMC Public Health 2021, 21, 1024. [Google Scholar] [CrossRef] [PubMed]
Costa-Santos, C.; Neves, A.L.; Correia, R.; Santos, P.; Monteiro-Soares, M.; Freitas, A.; Ribeiro-Vaz, I.; Henriques, T.S.; Pereira Rodrigues, P.; Costa-Pereira, A.; et al. COVID-19 surveillance data quality issues: A national consecutive case series. BMJ Open 2021, 11, e047623. [Google Scholar] [CrossRef] [PubMed]
Glèlè Ahanhanzo, Y.; Ouedraogo, L.T.; Kpozèhouen, A.; Coppieters, Y.; Makoutodé, M.; Wilmet-Dramaix, M. Factors associated with data quality in the routine health information system of Benin. Arch. Public Health Arch. Belg. Sante Publique 2014, 72, 25. [Google Scholar] [CrossRef] [PubMed] [Green Version]
Chen, H.; Hailey, D.; Wang, N.; Yu, P. A review of data quality assessment methods for public health information systems. Int. J. Environ. Res. Public Health 2014, 11, 5170–5207. [Google Scholar] [CrossRef]
Cook, L.A.; Sachs, J.; Weiskopf, N.G. The quality of social determinants data in the electronic health record: A systematic review. J. Am. Med. Inform. Assoc. 2021, 29, 187–196. [Google Scholar] [CrossRef]
Daneshkohan, A.; Alimoradi, M.; Ahmadi, M.; Alipour, J. Data quality and data use in primary health care: A case study from Iran. Inform. Med. Unlocked 2022, 28, 100855. [Google Scholar] [CrossRef]
World Health Organization. Data Quality Review: Module 1: Framework and Metrics. 2017. Available online: http://apps.who.int/iris/bitstream/10665/259224/1/9789241512725-eng.pdf (accessed on 20 April 2022).
World Health Organization. Recommendations for Data Collection, Analysis and Reporting on Anthropometric Indicators in Children under 5 Years Old. 2019. Available online: https://apps.who.int/iris/bitstream/handle/10665/324791/9789241515559-eng.pdf (accessed on 28 April 2022).
Nazri, C.; Yamazaki, C.; Kameo, S.; Herawati, D.M.D.; Sekarwana, N.; Raksanagara, A.; Koyama, H. Factors influencing mother’s participation in Posyandu for improving nutritional status of children under-five in Aceh Utara district, Aceh province, Indonesia. BMC Public Health 2016, 16, 69. [Google Scholar] [CrossRef] [Green Version]
Ministry of Health. Pedoman Umum Pengelolaan Posyandu (General guideline of Posyandu Management), General Secretary Indonesia Ministry of Health, Jakarta, Indonesia. 2011. Available online: https://promkes.kemkes.go.id/pedoman-umum-pengelolaan-posyandu (accessed on 28 April 2022).
Suryanto; Plummer, V.; Boyle, M. Healthcare System in Indonesia. Hosp. Top. 2017, 95, 82–89. [Google Scholar] [CrossRef]
Eze, E.; Gleasure, R.; Heavin, C. Mobile health solutions in developing countries: A stakeholder perspective. Health Syst. 2020, 9, 179–201. [Google Scholar] [CrossRef]
Duarte, L.; Teodoro, A.C.; Lobo, M.; Viana, J.; Pinheiro, V.; Freitas, A. An Open Source GIS Application for Spatial Assessment of Health Care Quality Indicators. ISPRS Int. J. Geo-Inf. 2021, 10, 264. [Google Scholar] [CrossRef]
Murad, A.; Khashoggi, B.F. Using GIS for Disease Mapping and Clustering in Jeddah, Saudi Arabia. ISPRS Int. J. Geo-Inf. 2020, 9, 328. [Google Scholar] [CrossRef]
Rinawan, F.R.; Tateishi, R.; Raksanagara, A.S.; Agustian, D.; Alsaaideh, B.; Natalia, Y.A.; Raksanagara, A. Pitch and Flat Roof Factors’ Association with Spatiotemporal Patterns of Dengue Disease Analysed Using Pan-Sharpened Worldview 2 Imagery. ISPRS Int. J. Geo-Inf. 2015, 4, 2586–2603. [Google Scholar] [CrossRef] [Green Version]
Tariq, H.; Tahir, A.; Touati, F.; Al-Hitmi, M.A.E.; Crescini, D.; Ben Manouer, A. Geographical Area Network—Structural Health Monitoring Utility Computing Model. ISPRS Int. J. Geo-Inf. 2019, 8, 154. [Google Scholar] [CrossRef] [Green Version]
Yeboah, G.; Porto de Albuquerque, J.; Troilo, R.; Tregonning, G.; Perera, S.; Ahmed, S.A.K.S.; Ajisola, M.; Alam, O.; Aujla, N.; Azam, S.I.; et al. Analysis of OpenStreetMap Data Quality at Different Stages of a Participatory Mapping Process: Evidence from Slums in Africa and Asia. ISPRS Int. J. Geo-Inf. 2021, 10, 265. [Google Scholar] [CrossRef]
Khashoggi, B.F.; Murad, A. Issues of healthcare planning and GIS: A review. ISPRS Int. J. Geo-Inf. 2020, 9, 352. [Google Scholar] [CrossRef]
Senaratne, H.; Mobasheri, A.; Ali, A.L.; Capineri, C.; Haklay, M. A review of volunteered geographic information quality assessment methods. Int. J. Geogr. Inf. Sci. 2017, 31, 139–167. [Google Scholar] [CrossRef]
Alwan, A.A.; Ciupala, M.A.; Brimicombe, A.J.; Ghorashi, S.A.; Baravalle, A.; Falcarin, P. Data quality challenges in large-scale cyber-physical systems: A systematic review. Inf. Syst. 2022, 105, 101951. [Google Scholar] [CrossRef]
Marx, S.; Phalkey, R.; Aranda-Jan, C.B.; Profe, J.; Sauerborn, R.; Höfle, B. Geographic information analysis and web-based geoportals to explore malnutrition in Sub-Saharan Africa: A systematic review of approaches. BMC Public Health 2014, 14, 1189. [Google Scholar] [CrossRef] [Green Version]
Ibrahim, M.S.; Mohamed Yusoff, H.; Abu Bakar, Y.I.; Thwe Aung, M.M.; Abas, M.I.; Ramli, R.A. Digital health for quality healthcare: A systematic mapping of review studies. Digital Health 2022, 8, 1–20. [Google Scholar] [CrossRef]
Chen, Y.; Sanesi, G.; Li, X.; Chen, W.Y.; Lafortezza, R. Remote Sensing and Urban Green Infrastructure. In Urban Remote Sensing; John Wiley & Sons Ltd.: Oxford, UK, 2021; pp. 447–468. [Google Scholar]
Källander, K.; Tibenderana, K.J.; Akpogheneta, J.O.; Strachan, L.D.; Hill, Z.; ten Asbroek, A.A.H.; Conteh, L.; Kirkwood, R.B.; Meek, R.S. Mobile Health (mHealth) Approaches and lessons for increased performance and retention of community health workers in low- and middle-income countries: A review. J. Med. Internet Res. 2013, 15, e17. [Google Scholar] [CrossRef] [PubMed]
Ministry of Health. Indikator Program Kesehatan Masyarakat dalam RPJMN dan Renstra Kementerian Kesehatan 2020–2024 (Public Health Program Indicator in National Midterm Development Plan (NMDP) and Ministry of Health Strategic Plan 2020–2024). 2020. Available online: https://kesmas.kemkes.go.id/assets/uploads/contents/attachments/ef5bb48f4aaae60ebb724caf1c534a24.pdf (accessed on 28 April 2022).
Freedman, D.S.; Lawman, H.G.; Pan, L.; Skinner, A.C.; Allison, D.B.; McGuire, L.C.; Blanck, H.M. The prevalence and validity of high, biologically implausible values of weight, height, and BMI among 8.8 million children. Obesity 2016, 24, 1132–1139. [Google Scholar] [CrossRef] [PubMed] [Green Version]
De Vreese, R.; Leys, M.; Fontaine, C.M.; Dendoncker, N. Social mapping of perceived ecosystem services supply–The role of social landscape metrics and social hotspots for integrated ecosystem services assessment, landscape planning and management. Ecol. Indic. 2016, 66, 517–533. [Google Scholar] [CrossRef]
Vaughan, L. Mapping Society: The Spatial Dimensions of Social Cartography; UCL Press: London, UK, 2018. [Google Scholar]
Mukaka, M.M. Statistics corner: A guide to appropriate use of correlation coefficient in medical research. Malawi Med. J. 2012, 24, 69–71. [Google Scholar]
Pallant, J. SPSS Survival Guide Manual, 6th ed.; Open University Press, McGraw-Hill Education: Berkshire, UK, 2016. [Google Scholar]
Weatherburn, C.J. Data quality in primary care, Scotland. Scott. Med. J. 2021, 66, 66–72. [Google Scholar] [CrossRef]
Malmqvist, J.; Hellberg, K.; Möllås, G.; Rose, R.; Shevlin, M. Conducting the Pilot Study: A Neglected Part of the Research Process? Methodological Findings Supporting the Importance of Piloting in Qualitative Research Studies. Int. J. Qual. Methods 2019, 18, 1609406919878341. [Google Scholar] [CrossRef] [Green Version]
Nicol, E.; Bradshaw, D.; Phillips, T.; Dudley, L. Human factors affecting the quality of routinely collected data in South Africa. Stud. Health Technol. Inform. 2013, 192, 788–792. [Google Scholar]
Mondal, S.; Samaddar, K. Reinforcing the significance of human factor in achieving quality performance in data-driven supply chain management. TQM J. 2021. ahead-of-print. [Google Scholar] [CrossRef]
WHO. World Health Organization Guideline in Policy and System Support to Optimize Community Health Worker Programmes. 2018. Available online: http://apps.who.int/iris/bitstream/handle/10665/275474/9789241550369-eng.pdf (accessed on 28 April 2022).
Stara, V.; Santini, S.; Kropf, J.; D’Amen, B. Digital Health Coaching Programs Among Older Employees in Transition to Retirement: Systematic Literature Review. J. Med. Internet Res. 2020, 22, e17809. [Google Scholar] [CrossRef]
Rialike, B.; Reka Lagora, M.; Suryanti. Factors Related to the Performance of Cadre in the Implementation of Toddler Posyandu at the Working Area of Puskesmas Sulau in South Bengkulu Regency. In Proceedings of the 1st International Conference on Inter-professional Health Collaboration (ICIHC 2018), Bengkulu, Indonesia, 30 October–1 November 2018; 2019; pp. 256–259. [Google Scholar]
Rinawan, F.R.; Kusumastuti, P.; Mandiri, A.; Dewi, R.K. Association of Cadre’s Knowledge with Age, Duration of Work, Education, and Employment on the Use of iPosyandu Application in Pasawahan, Purwakarta. J. Ilmu Kesehat. Masy. 2020, 11, 150–159. [Google Scholar] [CrossRef]
Verbree, A.-R.; Toepoel, V.; Perada, D. The Effect of Seriousness and Device Use on Data Quality. Soc. Sci. Comput. Rev. 2020, 38, 720–738. [Google Scholar] [CrossRef]
Abejirinde, I.-O.O.; Ilozumba, O.; Marchal, B.; Zweekhorst, M.; Dieleman, M. Mobile health and the performance of maternal health care workers in low-and middle-income countries: A realist review. Int. J. Care Coord. 2018, 21, 73–86. [Google Scholar] [CrossRef] [Green Version]
Laar, A.; Bekyieriya, E.; Isang, S.; Baguune, B. Assessment of mobile health technology for maternal and child health services in rural Upper West Region of Ghana. Public Health 2019, 168, 1–8. [Google Scholar] [CrossRef] [PubMed]
Birkmeyer, S.; Wirtz, B.W.; Langer, P.F. Determinants of mHealth success: An empirical investigation of the user perspective. Int. J. Inf. Manag. 2021, 59, 102351. [Google Scholar] [CrossRef]
Kim, K.-H.; Kim, K.-J.; Lee, D.-H.; Kim, M.-G. Identification of critical quality dimensions for continuance intention in mHealth services: Case study of onecare service. Int. J. Inf. Manag. 2019, 46, 187–197. [Google Scholar] [CrossRef]
Benski, A.C.; Stancanelli, G.; Scaringella, S.; Herinainasolo, J.L.; Jinoro, J.; Vassilakos, P.; Petignat, P.; Schmidt, N.C. Usability and feasibility of a mobile health system to provide comprehensive antenatal care in low-income countries: PANDA mHealth pilot study in Madagascar. J. Telemed. Telecare 2017, 23, 536–543. [Google Scholar] [CrossRef] [PubMed]
Sari, A.N.; Susanti, A.I.; Rinawan, F.R. Survei Kepuasan Kader dalam Penggunaan Aplikasi iPosyandu dalam Pelayanan Kesehatan Ibu dan Anak di Indonesia. J. Bidan Cerdas 2021, 3, 72–80. [Google Scholar] [CrossRef]
Lazard, A.J.; Brennen, J.S.B.; Belina, S.P. App Designs and Interactive Features to Increase mHealth Adoption: User Expectation Survey and Experiment. JMIR Mhealth Uhealth 2021, 9, e29815. [Google Scholar] [CrossRef]
Wang, J.; Li, X.; Wang, P.; Liu, Q.; Deng, Z.; Wang, J. Research Trend of the Unified Theory of Acceptance and Use of Technology Theory: A Bibliometric Analysis. Sustainability 2021, 14, 10. [Google Scholar] [CrossRef]
Fadahunsi, K.P.; O’Connor, S.; Akinlua, J.T.; Wark, P.A.; Gallagher, J.; Carroll, C.; Car, J.; Majeed, A.; O’Donoghue, J. Information quality frameworks for digital health technologies: Systematic review. J. Med. Internet Res. 2021, 23, e23479. [Google Scholar] [CrossRef]
Kumar, S.; Tiwari, P.; Zymbler, M. Internet of Things is a revolutionary approach for future technology enhancement: A review. J. Big Data 2019, 6, 111. [Google Scholar] [CrossRef] [Green Version]
Shoesmith, D.; Franklin, N.; Hidayat, R. Decentralised Governance in Indonesia’s Disadvantaged Regions: A Critique of the Underperforming Model of Local Governance in Eastern Indonesia. J. Curr. Southeast Asian Aff. 2020, 39, 359–380. [Google Scholar] [CrossRef]
Ministry of Secretariat. Indonesian Ministry of Secretariat Pocket Book of Human Development Cadre (Buku Saku Kader Pembangunan Manusia). 2021. Available online: http://bppsdmk.kemkes.go.id/pusdiksdmk/wp-content/uploads/2018/09/Asuhan-Kebidanan-Komunitas_SC.pdf (accessed on 28 April 2022).
Nurwarsito, H.; Savitri, N. Development of Mobile Applications for Posyandu Administration Services Using Google Maps API Geolocation Tagging. In Proceedings of the 2018 International Conference on Sustainable Information Engineering and Technology (SIET), Malang, Indonesia, 10–12 November 2018; pp. 168–173. [Google Scholar]
Ministry of Health. Ministry of Health Guideline on Integrated Nutrition Information System. 2019. Available online: https://sigiziterpadu.kemkes.go.id/login_sisfo/assets/PANDUAN_SIGIZI_TERPADU.pdf (accessed on 3 May 2022).
Purbasari, A.; Rinawan, F.R.; Zulianto, A.; Susanti, A.I.; Komara, H. CRISP-DM for Data Quality Improvement to Support Machine Learning of Stunting Prediction in Infants and Toddlers. In Proceedings of the 2021 8th International Conference on Advanced Informatics: Concepts, Theory and Applications (ICAICTA), Bandung, Indonesia, 29–30 September 2021; pp. 1–6. [Google Scholar]
Bertossi, L.; Geerts, F. Data quality and explainable AI. J. Data Inf. Qual. 2020, 12, 1–9. [Google Scholar] [CrossRef]
Ahmad, T.; Aziz, M.N. Data preprocessing and feature selection for machine learning intrusion detection systems. ICIC Express Lett. 2019, 13, 93–101. [Google Scholar]

Table 1. Total data completeness analysis each year.

Data Completeness *	2019		2020		2021		Total		p
Data Completeness *	n	%	n	%	n	%	n	%	p
1–4	5951	9.41	7430	11.74	15,740	24.88	29,121	46.03	0.000 **
5–8	5120	8.09	2124	3.36	11,192	17.69	18,436	29.14
9–12	7106	11.23	2666	4.21	5943	9.39	15,715	24.84
Total	18,177	28.73	12,220	19.31	32,875	51.96	63,272	100.00

* (visits reported/year). ** Chi-square test.

Table 2. Total data accuracy analysis each year.

Data Accuracy	2019		2020		2021		Total		p
Data Accuracy	n	%	n	%	n	%	n	%
Outliers	5168	7.73	4332	6.48	1988	2.97	11,488	17.18	0.000 *
Accurate	13,664	20.43	8797	13.15	32,936	49.24	55,397	82.82
Total	18,832	28.16	13,129	19.63	34,924	52.51	66,855	100.00

* Chi-square test.

Table 3. Data completeness per province 2019–2021.

Province	Data Completeness 2019					Data Completeness 2020					Data Completeness 2021
Province	1–4	5–8	9–12	Total	%	1–4	5–8	9–12	Total	%	1–4	5–8	9–12	Total	%
Aceh						60	0	0	60	0.49	4	0	0	4	0.01
Bali	118	167	112	397	2.18	158	30	0	188	1.54	131	142	0	273	0.83
Banten	5	0	0	5	0.03	77	0	0	77	0.63	477	652	66	1195	3.63
Bengkulu	3	0	0	3	0.02	46	0	0	46	0.38
DI Yogyakarta	104	0	0	104	0.57	25	0	0	25	0.20	0	5	0	5	0.02
DKI Jakarta	693	0	0	693	3.81	1044	174	1285	2503	20.48	3644	2739	442	6825	20.76
Gorontalo						60	0	0	60	0.49
Jambi	41	89	0	130	0.72	26	0	0	26	0.21
Jawa Barat	4617	4595	6721	15,933	87.65	3852	1112	965	5929	48.52	8961	5381	4803	19,145	58.24
Jawa Tengah	7	5	0	12	0.07	334	0	0	334	2.73	1	0	0	1	0.00
Jawa Timur	7	0	0	7	0.04	99	0	0	99	0.81	1344	824	0	2168	6.59
Kalimantan Barat						34	0	0	34	0.28	50	33	0	83	0.25
Kalimantan Selatan	3	0	0	3	0.02	22	0	0	22	0.18	78	0	0	78	0.24
Kalimantan Tengah	8	0	0	8	0.04	277	88	10	375	3.07	93	0	0	93	0.28
Kalimantan Timur	21	16	57	94	0.52	55	43	0	98	0.80	72	0	0	72	0.22
Kalimantan Utara						33	0	0	33	0.27	7	0	0	7	0.02
Kepulauan Bangka Belitung	18	0	0	18	0.10	4	0	0	4	0.03
Kepulauan Riau						3	0	0	3	0.02	47	186	9	242	0.74
Lampung	195	14	0	209	1.15	275	314	66	655	5.36	258	50	0	308	0.94
Maluku						83	173	0	256	2.09
Maluku Utara											44	0	0	44	0.13
Nusa Tenggara Barat	28	0	0	28	0.15	233	80	318	631	5.16	135	440	0	575	1.75
Nusa Tenggara Timur						7	0	0	7	0.06
Papua	26	0	0	26	0.14
Papua Barat	1	0	0	1	0.01
Riau	1	0	0	1	0.01	66	0	0	66	0.54
Sulawesi Barat	1	0	0	1	0.01						18	128	0	146	0.44
Sulawesi Selatan						139	0	0	139	1.14
Sulawesi Tengah	48	234	216	498	2.74	343	110	22	475	3.89	167	491	605	1263	3.84
Sulawesi Tenggara	1	0	0	1	0.01	50	0	0	50	0.41	16	0	0	16	0.05
Sulawesi Utara						3	0	0	3	0.02	2	0	0	2	0.01
Sumatera Barat	4	0	0	4	0.02
Sumatera Selatan	1	0	0	1	0.01	20	0	0	20	0.16	191	121	18	330	1.00
Sumatera Utara						2	0	0	2	0.02
Total	5951	5120	7106	18,177	100.00	7430	2124	2666	12,220	100.00	15,740	11.92	5943	32,875	100.00

Red: Highlight for no data available.

Table 4. Data accuracy and consistency per province 2019–2021.

Province	Data Accuracy 2019						c. alpha *	Data Accuracy 2020						c. alpha *	Data Accuracy 2021						c. alpha *
Province	O **	%	A **	%	Total	%	c. alpha *	O **	%	A **	%	Total	%	c. alpha *	O **	%	A **	%	Total	%	c. alpha *
Aceh							no obs	3	0.02	57	0.43	60	0.46	0.5326	1	0.00	3	0.01	4	0.01	0.7273
Bali	94	0.50	306	1.62	400	2.12	0.0598	18	0.14	174	1.33	192	1.46	0.205	29	0.08	250	0.72	279	0.80	0.503
Banten	1	0.01	4	0.02	5	0.03	0.8824	32	0.24	51	0.39	83	0.63	0.4205	173	0.50	1217	3.48	1390	3.98	0.1952
Bengkulu	3	0.02	0	0.00	3	0.02	too few	54	0.41	0	0.00	54	0.41	too few							no obs
DI Yogyakarta	51	0.27	61	0.32	112	0.59	0.7353	3	0.02	23	0.18	26	0.20	0.8679	0	0.00	5	0.01	5	0.01	too few
DKI Jakarta	199	1.06	558	2.96	757	4.02	0.7356	275	2.09	2416	18.40	2691	20.50	0.6014	299	0.86	7060	20.22	7359	21.07	0.6565
Gorontalo							no obs	63	0.48	0	0.00	63	0.48	0.7441							no obs
Jambi	130	0.69	0	0.00	130	0.69	1	26	0.20	0	0.00	26	0.20	too few							no obs
Jawa Barat	4306	22.87	12,155	64.54	16,461	87.41	0.5462	2615	19.92	3828	29.16	6443	49.07	0.5101	1044	2.99	19,222	55.04	20,266	58.03	0.4122
Jawa Tengah	12	0.06	3	0.02	15	0.08	0.6074	18	0.14	334	2.54	352	2.68	0.7326	0	0.00	2	0.01	2	0.01	1
Jawa Timur	6	0.03	1	0.01	7	0.04	0.748	36	0.27	67	0.51	103	0.78	.***	117	0.34	2179	6.24	2296	6.57	.***
Kalimantan Barat							no obs	19	0.14	24	0.18	43	0.33	0.4244	15	0.04	72	0.21	87	0.25	0.2757
Kalimantan Selatan	0	0.00	3	0.02	3	0.02	not valid	5	0.04	18	0.14	23	0.18	0.6652	3	0.01	88	0.25	91	0.26	0.8374
Kalimantan Tengah	5	0.03	3	0.02	8	0.04	0.8019	128	0.97	264	2.01	392	2.99	0.3987	6	0.02	88	0.25	94	0.27	0.0673
Kalimantan Timur	33	0.18	87	0.46	120	0.64	0.5636	6	0.05	120	0.91	126	0.96	0.519	2	0.01	74	0.21	76	0.22	0.6064
Kalimantan Utara							no obs	4	0.03	29	0.22	33	0.25	0.4386	1	0.00	6	0.02	7	0.02	0.525
Kepulauan Bangka Belitung	10	0.05	9	0.05	19	0.10	0.7008	2	0.02	3	0.02	5	0.04	0.9701							no obs
Kepulauan Riau							no obs	2	0.02	1	0.01	3	0.02	0.9231	1	0.00	241	0.69	242	0.69	0.3328
Lampung	140	0.74	79	0.42	219	1.16	0.201	103	0.78	574	4.37	677	5.16	0.299	82	0.23	231	0.66	313	0.90	0.0934
Maluku							no obs	81	0.62	227	1.73	308	2.35	0.493							no obs
Maluku Utara							no obs							no obs	11	0.03	35	0.10	46	0.13	0.6502
Nusa Tenggara Barat	19	0.10	9	0.05	28	0.15	0.322	519	3.95	138	1.05	657	5.00	0.6449	115	0.33	467	1.34	582	1.67	0.3561
Nusa Tenggara Timur							no obs	2	0.02	5	0.04	7	0.05	0.7653							no obs
Papua	1	0.01	27	0.14	28	0.15	too few							no obs							no obs
Papua Barat	1	0.01	1	0.01	2	0.01	too few							no obs							no obs
Riau	0	0.00	1	0.01	1	0.01	not valid	68	0.52	0	0.00	68	0.52	1							no obs
Sulawesi Barat	0	0.00	1	0.01	1	0.01	not valid							no obs	10	0.03	150	0.43	160	0.46	0.137
Sulawesi Selatan							no obs	39	0.30	100	0.76	139	1.06	0.6474							no obs
Sulawesi Tengah	155	0.82	351	1.86	506	2.69	0.7022	189	1.44	290	2.21	479	3.65	0.2494	51	0.15	1218	3.49	1269	3.63	0.1985
Sulawesi Tenggara	2	0.01	0	0.00	2	0.01	not valid	18	0.14	33	0.25	51	0.39	0.4947	2	0.01	14	0.04	16	0.05	0.5813
Sulawesi Utara							no obs	0	0.00	3	0.02	3	0.02	too few	0	0.00	2	0.01	2	0.01	1
Sumatera Barat	0	0.00	4	0.02	4	0.02	too few							no obs							no obs
Sumatera Selatan	0	0.00	1	0.01	1	0.01	not valid	3	0.02	17	0.13	20	0.15	0.486	26	0.07	312	0.89	338	0.97	0.204
Sumatera Utara							no obs	1	0.01	1	0.01	2	0.02	1							no obs
Total	5168	27.44	13,664	72.56	18,832	100.00	0.56	4332	33	8797	67.00	13,129	100.00	0.49	1988	5.69	32,936	94.31	34,924	100.00	0.44

* c.alpha = Cronbach alpha coefficient; no obs= no observation; ** O = Outliers, A = Accurate Data *** = no result ouput in STATA, only (.). Red: Highlite for no data available; Yellow: Highlight for non-zero % Outliers; Green: Highlight for non-zero % Accurate data.

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Rinawan, F.R.; Faza, A.; Susanti, A.I.; Purnama, W.G.; Indraswari, N.; Didah; Ferdian, D.; Fatimah, S.N.; Purbasari, A.; Zulianto, A.; et al. Posyandu Application for Monitoring Children Under-Five: A 3-Year Data Quality Map in Indonesia. ISPRS Int. J. Geo-Inf. 2022, 11, 399. https://0-doi-org.brum.beds.ac.uk/10.3390/ijgi11070399

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Rinawan FR, Faza A, Susanti AI, Purnama WG, Indraswari N, Didah, Ferdian D, Fatimah SN, Purbasari A, Zulianto A, et al. Posyandu Application for Monitoring Children Under-Five: A 3-Year Data Quality Map in Indonesia. ISPRS International Journal of Geo-Information. 2022; 11(7):399. https://0-doi-org.brum.beds.ac.uk/10.3390/ijgi11070399

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Rinawan, Fedri Ruluwedrata, Afina Faza, Ari Indra Susanti, Wanda Gusdya Purnama, Noormarina Indraswari, Didah, Dani Ferdian, Siti Nur Fatimah, Ayi Purbasari, Arief Zulianto, and et al. 2022. "Posyandu Application for Monitoring Children Under-Five: A 3-Year Data Quality Map in Indonesia" ISPRS International Journal of Geo-Information 11, no. 7: 399. https://0-doi-org.brum.beds.ac.uk/10.3390/ijgi11070399

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Posyandu Application for Monitoring Children Under-Five: A 3-Year Data Quality Map in Indonesia

Abstract

1. Introduction

2. Materials and Methods

3. Results

3.1. Data Completeness

3.2. Data Accuracy and Consistency

4. Discussion

5. Conclusions

6. Patents

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

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