An Information and Communication Platform Supporting
Analytics for Elderly Care
Orhan Konak
1
, Harry Freitas Da Cruz
1
, Marvin Thiele
1
, David Golla
2
and Matthieu-P. Schapranow
1
1
Hasso Plattner Institute, Digital Health Center, Rudolf-Breitscheid-Str. 187, 14482 Potsdam, Germany
2
Data Experts GmbH, Allee der Kosmonauten 33G, 12681 Berlin, Germany
schapranow@hpi.de
Keywords:
Nursing Care, Software Architecture, Decision Support, In-Memory Database.
Abstract:
Germany faces an increase of its elderly population and along with it the number of people reliant on nursing
care is also rising. In this context, access to reliable information is key for all actors involved, be they family
members or political decision makers. Currently, the country lacks a centralized platform on which such actors
can access and exchange relevant information, e.g. as concerns finding a suitable facility or identifying trends
on the demand for care spots. Existing solutions are based on regional data silos, which render information
exchange time-consuming and error-prone. As a result, nursing care actors lack access to timely, reliable
information to support strategic decision-making. In this paper, we introduce a software platform built upon
an In-Memory database that meets the information and communication needs of the different user groups
involved. The platform establishes the necessary framework for real-time data collection and information
exchange, laying the foundation for deriving key performance indicators and enabling data exploration and
prognoses.
1 INTRODUCTION
The increase in life expectancy in Germany has co-
incided with a sharp rise in the number of elderly
people who are dependent on specialized care. In
fact, the average amount of pensioners with substan-
tial care needs has increased threefold between 1995
and 2017 (Bundesministerium f
¨
ur Gesundheit, 2018).
This phenomenon is not restricted to Germany. The
worldwide number of the elderly – those aged 60
years or over – is expected to more than double by
2050 and triple by 2100 (United Nations, 2017). Ag-
ing leads to a gradual decrease in physical and mental
capacity, a growing risk of disease, and further depen-
dence on nursing care (World Health Organization,
2018).
Today, acquiring information on nursing care ser-
vices in Germany is a laborious undertaking. Pa-
tients looking for a nursing care facility can com-
municate directly with it or consult with a nursing
care support center to obtain information on avail-
able care spots. Both alternatives are associated with
a significant time expenditure as important informa-
tion such as availability must be explicitly requested,
often by phone. At the policy level, social plan-
Column Store
Lightweight
Compression
Partitioning
Multi-Core
Parallelization
OLAP Cubes
Geo DataClaims Data
Governmental
Data
Facility Data
Behavioral
Data
Facilities Waiting list Prognoses
R
Application
Layer
Data
Layer
Family
members
Social
workers
Facility
managers
Social
planners
R R
R
Master Data Transactional Data
Information
Reporting
Visualization
Tool
RR
R
Incorporated
Data Sources
Figure 1: Software system architecture of the elderly care
information and communication platform depicted as a
FMC block diagram.
ners aim to improve a district’s nursing care offering
through demand forecasting and capacity planning.
This requires comprehensive up-to-date datasets com-
ing from different sources. Currently, these sources
are either scattered throughout different silos, thereby
presenting high heterogeneity, or are simply not avail-
able outside the respective institutions.
Konak, O., Freitas Da Cruz, H., Thiele, M., Golla, D. and Schapranow, M.
An Information and Communication Platform Supporting Analytics for Elderly Care.
DOI: 10.5220/0007717801970204
In Proceedings of the 5th International Conference on Information and Communication Technologies for Ageing Well and e-Health (ICT4AWE 2019), pages 197-204
ISBN: 978-989-758-368-1
Copyright
c
2019 by SCITEPRESS – Science and Technology Publications, Lda. All rights reser ved
197
A centralized software platform with reliable in-
formation on offer and demand for nursing care ser-
vices can help to close the gaps between silos. Such
an integrated platform can also be of interest for re-
lated actors, such as social workers and facility man-
agers. Fig. 1 shows the architecture of our software
solution in a Fundamental Modeling Concepts (FMC)
block diagram. The foundation is formed by data
coming from different sources, which are either pre-
defined (master data) or continuously updated (trans-
actional data). The master data is only updated peri-
odically, consisting of governmental data, geograph-
ical data, and insurance claims data. In contrast,
transactional data is continuously updated, originat-
ing from nursing care facilities and users’ search be-
havior. The different sources are integrated and har-
monized in an In-Memory Database (IMDB), which
has been demonstrated to support flexible and fast
analysis of extensive amounts of data (Plattner and
Schapranow, 2014). The application offers a wide
range of services such as a personalized waiting
list, recommendations for nursing services matching
given search criteria, fine-grained data exploration,
and prognosis on different key performance indica-
tors (KPIs). The requirements of our software were
elicited following principles from design thinking, a
user-centric approach. The platform standardizes in-
formation exchange across the nursing care spectrum,
making it possible for the first time to tap into exist-
ing data silos. It therefore establishes the basis upon
which to perform advanced analytics, ultimately en-
abling users to derive recommendations that inform
policy and to reduce the time needed to find appropri-
ate care services.
The remainder of this work is structured as fol-
lows: Sect. 2 places the work in the context of already
existing initiatives in the field. In Sect. 3 the software
architecture and the technical infrastructure are dis-
cussed. Our specific contributions are described in
Sect. 4, while they are critically analyzed in Sect. 5.
The paper concludes with an outlook on the next steps
in Sect. 6.
2 RELATED WORK
Decentralization of care delivery is currently gaining
more importance (Real et al., 2018). Information and
communication technologies in nursing care thus shift
towards decentralized networking. Honor (Honor,
2018) and careship (Careship, 2018) are two exam-
ples of this development. The idea is to bring together
people in need of care with suitable caregivers from
the neighborhood. This strengthens local care. Nev-
ertheless, compared to our platform, it does not cover
people who can no longer stay in their own home and
are dependent on a care facility.
Other platforms, such as AOK Pflege-
Navigator (AOK, 2018), Wohnen im Alter (Wohnen
im Alter, 2018) and Seniorplace (Seniorplace, 2018)
offer a complete overview of care facilities in the
search region and also provide additional information
on the facilities. Unfortunately, these platforms lack
information about capacity utilization. In contrast to
our solution, this information has to be requested.
The focus on a specific user group is another dis-
advantage of these approaches. In order to improve
the entire process of care, there is no holistic ap-
proach. All approaches concentrate only on one spe-
cific user group or the interaction of two user groups,
e.g. carers and people in need of care. On our plat-
form, on the other hand, the four actors care recipient,
nursing facility, social planner and social worker are
linked.
Linking the actors further leads to a homogeniza-
tion of data. This data collection and process stan-
dardization of information exchange in association
with the IMDB technology facilitates individual real-
time analysis, consistency, scalability and leads to
more transparency (Knawy, 2017). Current solutions
in this area, as in the case of Recom (RECOM, 2018),
only take place within a closed facility, such as a hos-
pital or a care facility.
The federal ministry of education and research in
Germany is promoting aging in place through the pri-
macy of outpatient rather than inpatient care (Bun-
desministerium f
¨
ur Bildung und Forschung, 2017).
Ambient assisted living and e-health are current
methods that intend to promote this (Cedillo et al.,
2018). Still, people reliant on care facility is in-
creasing (Destatis, 2015). In order to meet increased
demand, social planning derives prognosis based on
static and aggregated data at a district or state level.
Short-term changes due to new technologies and pop-
ulation migration are not absorbed by this approach
and thus make it cumbersome for changes. In com-
parison, our centralized approach provides analysis of
real-time data even at a municipality level.
3 METHODS
In the following, we share details about the utilized
research methodology. To get an overall picture of
the existing challenges in the field of nursing care
we used the design thinking approach. Based on its
guidelines, we elicited the software requirements via
subject-matter interviews with the identified stake-
ICT4AWE 2019 - 5th International Conference on Information and Communication Technologies for Ageing Well and e-Health
198
holders. To implement these requirements we made
use of selected IMDB building-blocks and web de-
velopment technologies.
3.1 Requirements Engineering
In order to understand the whole process of decision-
making in the nursing care field, we followed the
problem-solving method design thinking (Lockwood
and Papke, 2017). In interviews with subject-matter
experts, we were able to pinpoint problems and chal-
lenges, e.g. concerning how they are connected to
each other and how they communicate. This enabled
us to derive a concise representation of the stakehold-
ers in terms of personas and user stories. Personas are
a generic entity that represents a typical user of the
solution. In particular, four personas have been iden-
tified. The first is the family member who is looking
for an appropriate nursing care facility as soon and as
easily as possible. The second is the social planner,
responsible to carry out data analyses and draw up the
elderly care plan, which contains a number of recom-
mendations for policy making. The third is the social
worker in a nursing care support center, in charge of
counseling people on several topics related to nurs-
ing care. Finally, we identified the facility manager,
who needs to inform prospective patients on available
spots, submit key indicators to district administration
and ultimately optimize occupancy rates. A user story
helps to create a simplified description of a require-
ment (Cohn, 2004). A user story template often uses
the following format: ’As a Persona, I want feature
so that reason’. This led to a collection of user stories
that have guided the implementation of the platform.
They laid out the foundation for a set of functional and
non-functional requirements, which can be examined
as Supplementary Material
1
as per the ISO/IEC/IEEE
24765:2017 (International Organization for Standard-
ization, 2017).
3.2 IMDB Technology
Following the users’ non-functional requirements for
our software platform such as fast response times and
scalability, we decided to utilize the IMDB technol-
ogy. It uses the main memory for storage and enables
real-time data processing and analysis of the stored
data (Prassol, 2015). Increasing computing power and
recent advances in hardware allows real-time analysis
of massive amounts of data (Plattner and Schapranow,
2014). Our platform makes use of selected building-
blocks of the IMDB technology, which are described
in the following.
1
https://tinyurl.com/y4vt8b86
Column-oriented Data Layout. In classical rela-
tional databases data is stored in a row-oriented for-
mat (Halpin and Morgan, 2008). This characteris-
tic makes this approach particularly suitable for on-
line transactional processing (OLTP) systems. Row-
oriented data storage allows fast writing of data, while
retrieval takes longer. In contrast, column-oriented
databases are less able to cope with this frequent writ-
ing (Ordonez et al., 2018). However, the columnar
structure is often used in online analytical process-
ing (OLAP) systems. Since user queries are limited
to only a subset of the available attributes, for exam-
ple when a given district wants to access its KPIs, our
platform uses only columnar tables. Another advan-
tage of columnar format is that the data can be stored
in highly compressed form.
Lightweight Compression. Compression is tar-
geted at retaining the information content of a data
structure with a concomitant reduction of disk space
needed to represent it (Plattner, 2014). Column-wise
storage eases lightweight compression given that cer-
tain patterns in the data are often repeated (Svens-
son, 2008). As our platform shall cater to a wide
user base, acceptable performance must be ensured.
Performance gains can be enabled either by cache-
conscious algorithms (Rao and Ross, 1999) or by re-
ducing the amount of data transferred from and to
main memory, which can be achieved by data com-
pression approaches (Westmann et al., 2000).
Partitioning. Partitioning can be either vertical or
horizontal (Lightstone et al., 2007). Vertical parti-
tioning splits columns of database tables into multiple
column-wise subsets, which then can be distributed
on individual databases servers (Hellerstein et al.,
2007). In contrast, horizontal partitioning handles
large database tables by dividing them into smaller
pieces of row-wise data. This approach has the ad-
vantage that it enables parallel search operations and
improves scalability (Plattner, 2014).
Multi-Core Parallelization. Trends in multi-core
processing with multiple cores in each case can be
exploited by reducing the amount of sequential work
and developing parallized applications in order to
achieve highest processing speed. The IMDB system
used for our platform enables inter and intra operator
parallelism (Plattner, 2014). The IMDB handles par-
allelization autonomously so that we do not have to
explicitly manage it (Plattner and Leukert, 2015).
An Information and Communication Platform Supporting Analytics for Elderly Care
199
3.3 Web Technologies
For the development, we utilized the Model-View-
Controller (MVC) architecture. It is an architectural
pattern used to efficiently link the user interface to the
underlying data models (Goodrich and Lenz, 2016).
It separates the application into the components mod-
els, controllers and views. Separating our software
platform into these components leads to improved
scalability, ease of maintenance and reusability. In
particular, we used the Ruby on Rails framework
v3.2 along with the JQuery user interface library.
The geographical exploration of care services and the
overview of care utilization was developed with the
open-source JavaScript library Leaflet.js (Vladimir
Agafonkin, 2018).
3.4 User Experience Evaluation
For a first assessment of this platform, we conducted
a survey for users in the role of a family member. A
survey was carried out among people with different
socio-demographic characteristics. In order to eval-
uate how well family members are supported by the
platform, they were asked to find a nursing care facil-
ity matching pre-defined criteria. Subsequently, they
answered a survey on the usability of the platform.
A total of 42 subjects took part in the survey, out of
which 36 gave an answer. Questions were answered
using a Likert scale with grades from ”not applica-
ble” (1) to ”fully applicable” (5).
4 CONTRIBUTIONS
In the following, we detail the contributions we made
concerning software requirements, software architec-
ture, incorporated data sources, and process standard-
ization.
4.1 Software Requirements
As per Sect. 3.1, the interviews conducted with the
different stakeholders formed the basis for a set of
user stories, from which we derived functional and
non-functional requirements.
4.1.1 Functional Requirements
Our platform provides the needed foundation for dif-
ferent stakeholders to exchange information, with
each user group having different sets of needs, which
might overlap. In the following, we briefly outline
the identified functional requirements for each user
group.
Family Members. This user group is primarily
concerned with finding a suitable care spot which
meets specific criteria. Among others, geographi-
cal proximity is a key factor in the decision-making
process. Therefore, the platform shall enable fam-
ily members to define advanced search criteria and
explore the results with a geographical visualization
front-end. Since the desired facility is not always
available, family members shall be able to define
search agents which can trigger e-mail notifications
upon available spots matching the criteria defined.
Furthermore, the platform shall provide centralized
waiting lists across all facilities.
Social Planners. Tasked with providing informa-
tion for policy-makers in the field of nursing care
planning, social planners’ primary aim is access to up-
to-date KPIs on important developments in the field,
concerning, e.g., availability of nursing care offers,
personnel infrastructure, occupancy rates, and demo-
graphic trends, including prognoses. These KPIs are
currently generated by means of manual data collec-
tion, i.e. via questionnaires directed at care facili-
ties, a time-consuming and error-prone task. There-
fore, the platform shall provide the infrastructure for
continuous data collection to ensure actuality. In ad-
dition, the platform shall enable the social planner to
explore available KPIs in an explorative fashion, so as
to enable ad-hoc queries to be answered. An overview
of selected KPIs can be examined in Tab. 1.
Social Workers. These stakeholders help family
members and patients in all questions related to nurs-
ing care, particularly assistance in finding a suitable
nursing care offer. In addition to the same services
also provided to family members, the platform shall
provide social workers with detailed prognoses on the
availability of a given nursing care offer in a given
district.
Facility Managers. These stakeholders often need
to answer information requests from social planners,
regulatory agencies, governmental entities, and fam-
ily members. While answering a phone call for five
minutes may not seem like a significant amount of
time taken individually, collective they considerably
burden facility managers and employee who should
otherwise be engaged in patient care. To stream-
line this process, the platform shall enable facility
managers to report information required by the other
ICT4AWE 2019 - 5th International Conference on Information and Communication Technologies for Ageing Well and e-Health
200
stakeholders in a standardized fashion, e.g., regarding
service offering, available spots, personnel infrastruc-
ture, etc.
4.1.2 Non-functional Requirements
Non-functional requirements of the platform include
the same set characteristics which users expect from
modern web applications, concerning ease of use, fast
response time and device independence, i.e., ability to
use the software both from desktop and mobiles de-
vices. Additionally, the possibility to easily extend
the available KPIs shall be guaranteed by the plat-
form.
Table 1: Excerpt of KPIs. Abbreviations: SP=Social
Planner; FM=Family Member; FMa=Facility Manager;
SW=Social Worker.
Key Performance Indica-
tor
SP FM FMa SW
Care Utilization
x x x
Available Capacity
x x x x
Days of Capacity Over-
load
x x
Number of People in Care
Facility
x x
Covered Days
x x x
Number of Nursing Staff
x x
Nursing Staff Ratio
x x x
Nursing Staff Need
x x
Waiting Time per Care
Form
x x x x
Demand on Care Place
x x x
Care Migration
x x x
Forecast on KPIs
x x x
4.2 Software Architecture
The elicited requirements were mapped into soft-
ware components (application layer) within a web
platform built upon an IMDB database infrastructure
(data layer) which harmonizes the incorporated data
sources. The resulting software architecture is de-
picted in Fig. 1. In the following, we provide a de-
scription of each of the individual software layers in
top-down fashion.
Application Layer. The application components
were built using the MVC architectural pattern, en-
capsulating component responsibilities in ’Facility’,
’Waiting List’, ’Prognoses’, ’Information Reporting’
and ’Visualization Tool’. The ’Facility’ component
manages facility information, geographical explo-
ration, search capabilities, including search agent (F1-
F5). A core functionality of the platform resides
in the ’Waiting List’ component which manages re-
quests for nursing care offers in a centralized fash-
ion across different facilities (F6). The KPIs avail-
able on the platform can be forecast by means of the
’Prognoses’ component (F7). This component uti-
lizes analysis routines available in the IMDB, such as
time-series analysis. Facilities must provide differ-
ent stakeholders with information regarding available
spots, personnel availability, among others. This is
enabled by the ’Information Reporting’ component,
with which facilities can avoid having to answer in-
quiries by phone or e-mail manually (F8-F10). The
’Visualization Tool’ enables interactive exploration of
KPIs by means of an external software tool that is able
to consume OLAP cubes (F11-F13). Since the visual-
ization tool is directly embedded in the platform, it is
transparent for the user. Finally, security is provided
by means of an authentication and authorization role-
based access control components, implemented with
the Ruby gems ’devise’ and ’can-can’.
Application frontend was developed using
HTML5 and Javascript with JQuery using principles
of web usability in order to enable ease of use (NF1).
In particular, for the geographical exploration com-
ponent, we made applied caching strategies using the
user browser’s embedded off-line storage, allowing
to cache network requests and thereby avoiding
round trips to the web server, ensuring an interactive
web application (NF2). This is particularly relevant
with regards to shape data (GeoJSON) required to
display municipalities on a map. Furthermore, the
platform adapts to different devices flexibly, desktop
or mobile, providing device-independence (NF3).
Data Layer. For the data layer, we utilized the
IMDB building blocks column-oriented storage,
lightweight compression, partitioning, and multi-core
parallelization and OLAP cubes. In our platform,
we utilize column-based storage for the data entities.
This approach storage is beneficial both from a com-
pression perspective and for analytical purposes. Be-
sides, for database design, we strived to achieve the
third normal form for all entities, futher improving
disk utilization (Bernstein, 1976). This was imple-
mented, e.g., to keep track of available care spots
across all service types for a given facility. Further-
more, the partitioning and multi-core parallelization
capabilities of the IMDB enables data belonging to
different districts to distributed across different server
nodes, optimizing response times (NF2). To enable
data exploration, we developed virtual OLAP cubes
An Information and Communication Platform Supporting Analytics for Elderly Care
201
which meet the analysis needs of social planners. Fur-
thermore, virtual OLAP cubes provide the possibility
of extensibility by adding new measures or dimen-
sions without the need to recreate datamarts, as is
usual with traditional Business Intelligence systems,
ensuring ease of extensibility for KPIs (NF3).
Incorporated Data Sources. An important contri-
bution of our platform is integrating different data
sources within a central IMDB infrastructure. The in-
corporated data sources differ in the frequency with
which they are updated, termed either master data
(updated periodically) or transactional data (updated
daily). Belonging to the former category, are data
from health insurance claims, geographical data co-
ordinates for districts and municipalities (e.g. GeoJ-
SON), and statistical data, such as demographics for
a given region, which are typically available from
governmental sources. Transactional data sources
relate to data provided by the care facilities them-
selves, concerning real-time occupancy rates, i.e.,
how many spots are currently available for a given ser-
vice, and personnel infrastructure. Furthermore, the
platform can gather non-sensitive information about
users queries, e.g. geographical origin, services re-
quested, waiting times, etc. Regarding, the claims
data, we cooperated with a large German health in-
surance company which enabled us to obtain fine-
grained information on nursing care utilization (Fre-
itas da Cruz et al., 2018).
4.3 Process Standardization
The various user interviews helped us to identify the
gap in the communication channels between the ac-
tors involved in nursing care. All four identified users
are connected to each other directly or indirectly.
Hence, all actors interact with each other by infor-
mation exchange and are part of the decision-making
process of all individual actors.
Family
Member
Social
Planer
Facility
Manager
Social
Worker
Family
Member
Social
Planer
Facility
Manager
Social
Worker
Figure 2: Image depicts the intersection of the different user
groups: disjoint ellipses with dashed lines (left) vs. joint
ellipsis with solid lines (right). The platform joins the user
groups in order to save time and share common data rather
than manually built bilateral communication channels.
As shown in Fig. 2 on the left, the family mem-
ber e.g. is in direct contact with the care facility and
nursing care support center for information-gathering
about the facility. However, they are in indirect con-
tact with the social planner. The social planner is in-
terested in relevant KPIs on nursing care in order to
derive recommendations from them. The collected
KPIs depend not only on information coming from
the direct interface with the facilities. They also de-
pend on the search queries of the family members.
The flow of information between the facilities and
all other actors takes place on an individual level.
While family members’ search queries are always
answered by telephone or e-mail, queries coming
from the ministry via social planner about personnel
and care infrastructure are sent via non-standardized
channels and in individual consultation. The entire
data exchange between the individual actors does not
take place in a given format but after bilateral agree-
ment. With the help of our platform, as shown in
Fig. 2 on the right, the entire communication chan-
nel is standardized and all information exchange is
taking place at one single point. Standardization of
the process improves and promotes quality and saves
time (Knawy, 2017).
5 EVALUATION AND
DISCUSSION
Requirements imposed on the platform were met as
follows. From a functional perspective, the user is
provided with a geographical exploration tool of all
available care facilities in order to find the most suit-
able one in real-time without the need for additional
help (F1-F5). A centralized waiting list helps both the
care recipient and the nursing care facility to stream-
line the process of finding a suitable care spot (F6).
In the future, we will provide linear regression mod-
els to deliver forecasts on the expected waiting time
and fine-grained long-term forecasts on the demand
for nursing care spots (F7). Data harmonization and
process standardization are achieved by means of di-
rect communication channels and minimum informa-
tion reporting standards (F8-F10). Consistent infor-
mation reporting from care facilities results in ad-
ditional KPIs (F11-F13), which allow more precise
analyses and prognoses in social planning.
Our platform fulfilled non-functional require-
ments, such as ease of use, through the use of HTML5
and Javascript with JQuery (NF1). The incorporated
IMDB technology ensures fast response time (NF2)
and extensibility (NF4). Furthermore, the platform
can be accessed from different devices (NF3).
ICT4AWE 2019 - 5th International Conference on Information and Communication Technologies for Ageing Well and e-Health
202
In its current state, our platform has a number
of advantages over existing solutions. It supports
family members with additional information on nurs-
ing care facilities and thus helps them to save time.
In addition to the availability of real-time informa-
tion, the centralized collection and integration of var-
ious user groups and data sources, such as insurance
claims data, geo-information data, and statistical data
coming from governmental bodies, provides a suit-
able measuring instrument for KPIs. This data collec-
tion and process standardization paired with the used
IMDB technology facilitates the analysis and forecast
for social planning.
The survey presented in Tab. 2 suggested that the
platform is user-friendly and useful in finding care fa-
cilities and services. However, not all functionalities
needed were found by the users. For instance, the
possibility of entering a place name as a search cri-
terion was missing. Currently, the search function-
ality for finding a care spot is constrained to postal
code. A further question which we sought to answer
by the survey was if the platform provides better sup-
port than existing solutions from the users perspec-
tive. However, only one person stated to had experi-
ence with a similar solution, the response was consid-
ered as not sufficiently informative.
The approach chosen to evaluate the application
relied on a small sample size, thereby potentially pro-
viding biased the results. To address this limitation, a
more comprehensive user evaluation involving other
users and a wider sample is expected to be carried out
in the future when new features are implemented.
Table 2: Results of the survey of family members. Ques-
tions were answered using a Likert scale with grades from
”not applicable” (1) to ”fully applicable” (5). This can be
used to calculate a weighted mean.
Question
Weighted
Mean
I got along with the platform pretty well.
4.14
I got along with the map pretty well.
4.27
I was able to handle the filter settings.
4.14
I understood the icons on the map.
3.89
I have found all the functionality I need.
3.23
I like the information on the available ca-
pacity of the nursing care facility.
4.14
I felt supported by the platform.
4.14
I would like to use the platform when
searching for care places and offers.
4.11
6 CONCLUSION AND FUTURE
WORK
With the help of our software architecture, process
integration, and technology infrastructure, we devel-
oped a platform, that facilitates the searching process
for a care facility and helps to derive more detailed
analyses in order to improve the care offer of nursing
facilities. The data foundation is comprised of mas-
ter data by various institutions and transactional data
generated by the incorporated user groups. The soft-
ware architecture allows an easy extension for future
work, e.g. finding a kindergarten or school place.
Future work concerns deeper analysis of social
planning, incorporation of new user groups and new
proposals to try different methods. The following
ideas could be tested: 1) As we used linear regres-
sion models to forecast the waiting time and the de-
mand for nursing care offers, the application of more
sophisticated machine learning models could help to
improve the forecast quality. 2) It could be interesting
to include nursing care as a service. Offering help on
an outpatient basis leads to a larger data collection and
can thus further improve social planning. 3) Includ-
ing clinical data could also help to enhance demand
forecast accuracy.
ACKNOWLEDGEMENTS
Parts of this work were generously supported by a
grant of the German Federal Ministry of Economic
Affairs and Energy (01MD15005).
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