Productivity and Impact Analysis of a Research and Technology
Development Center using Google Scholar Information
Eric Garcia-Cano
a
, Eugenio López-Ortega
b
and Luis Alvarez-Icaza
c
Instituto de Ingeniería, Universidad Nacional Autónoma de México, Ciudad Universitaria, Ciudad de México, Mexico
Keywords: Automated Bibliometric Analysis, Strategic Planning, Scientific Research Productivity Metric, Google
Scholar.
Abstract: This paper presents a project aimed at evaluating the scientific productivity and impact of a Mexican research
and technological development center. The proposed evaluation is based on an automated bibliometric
analysis system that exploits Google Scholar (GS) information. The import process of the evaluation is shown,
including different aspects such as information request times, data verification through a parallel query in
Crossref and homogenization of publication sources. As a result, 8,492 documents by 137 researchers
associated with the research center were identified. These documents have received 74,683 citations. GS
includes a great variety of published materials, such as journal papers, books, conference proceedings, white
papers, and technical reports. This diversity of documents allows for a broader evaluation that takes into
consideration other types of research products that are not usually considered for assessing scientific
productivity. From our work, we conclude that the information in GS can be used to conduct a formal analysis
of the productivity and impact of a research center.
1 INTRODUCTION
The Institute of Engineering (IIUNAM), belonging to
the National Autonomous University of Mexico is a
Mexican center for research and technological
development that serves various areas of Engineering.
A bibliometric analysis project aimed at detecting
strategic research topics for its development started in
2012. In its initial stages, a computer system was
developed to acquire data from Scopus, and to
generate reports related to the behavior of specific
research lines.
Google Scholar (GS) information coverage is
higher than other databases such as Scopus and Web
of Science (WoS) (Harzing, 2014, Harzing and
Alakangas, 2016, Harzing and Van Der Wal, 2009,
Mingers and Lipitakis, 2010). Several authors have
estimated that GS captures more than twice as many
citations as WoS and Scopus. Also, it considers
multiple types of publications, such as books,
congress proceedings, white papers, public reports
(norms, regulations), and doctoral theses (Halevi et
a
https://orcid.org/0000-0002-2723-075X
b
https://orcid.org/0000-0002-5687-8934
c
https://orcid.org/0000-0001-9516-3950
al., 2017, Meho and Yang, 2007, Meier and Conkling,
2008).
Some of the most cited works carried out by
IIUNAM researchers correspond to books and
congress proceedings. Thus, in 2017, the Board of
Directors of the Institute decided to analyze the
impact, productivity and characteristics of its research
based on the information contained in Google
Scholar.
This paper presents a review of the process for the
information retrieval from GS, as well as the main
results, obtained related to the scientific research
productivity and impact of the IIUNAM.
2 GOOGLE SCHOLAR
STRUCTURE
Information gathering is one of the hardest tasks in
data analysis. Unlike WoS and Scopus, GS does not
provide a public API to access its information
160
Garcia-Cano, E., López-Ortega, E. and Alvarez-Icaza, L.
Productivity and Impact Analysis of a Research and Technology Development Center using Google Scholar Information.
DOI: 10.5220/0007842601600167
In Proceedings of the 8th International Conference on Data Science, Technology and Applications (DATA 2019), pages 160-167
ISBN: 978-989-758-377-3
Copyright
c
2019 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
automatically. Therefore, we collected the data by
parsing the HTML code with a web scraper.
2.1 Site Map
In our analysis, we identified three levels of depth in
the way Google Scholar displays information in its
database.
2.1.1 First Level (L1): Profile Search Results
Pages
This first level corresponds to the results pages for
authors’ profiles search based on specific keywords
(in this case, the name of the institution). At this level,
GS identifies a list of all author profiles that meet the
search criteria.
As shown in Figure 1, this page displays the
primary data of the authors: (1) name and link to their
personal profile page, (2) photograph, (3) affiliation,
(4) email address domain, (5) their areas of interest (if
provided), and (6) the total count of citations he or she
has received.
Figure 1: GS profile search results page.
2.1.2 Second Level (L2): Author Profile
Pages
This level corresponds to the authors’ profile pages,
where all their works are listed. Any researcher can
create their account and select the works of their
authorship. In this way, GS seeks to deal with its lack
of rigor in indexing by relying on authors maintaining
and updating their works data, correcting errors and
combining duplicate records (Aguillo, 2012, Huang
and Yuan, 2012).
In this page (Figure 2), we identify four categories
of information:
1. Author Details: Basic information provided
by the authors, including name, affiliation,
fields of interest, email domain (verified by
Google), and personal homepage.
2. Citation Metrics: GS shows metrics for
authors estimated based on the citations
collected. Additionally, a bar graph helps to
visualize how an author's citations are
distributed each year.
3. Published Works: The list shows the essential
information for each work belonging to the
author. The information of each work listed
includes:
Document title and link to details
Citations count and link to the list of
citations
Year of publication
List of co-authors
Source information, such as title,
volume, and issue number
4. List of Co-authors: Authors can enter
manually the list of co-authors with whom they
frequently collaborate.
Figure 2: Author Profile Page.
2.1.3 Third Level (L3): Work Details View
This last level of depth shows information about each
published work. The information consists of a
detailed view (Figure 3) of the bibliographic data
containing the most comprehensive information GS
can provide about a work, such as (1) link to the full
text, (2) type of document, (3) editor, (4) abstract, (5)
a bar chart with the distribution of citations by year,
and (6) the list of versions and related articles.
However, it is common that some documents have
some missing information. Knowing the type of
document is particularly relevant, as in disciplines
such as engineering, many high-quality research
results are patented and reported in formats other than
a journal article or conference paper (Harzing and
Van der Wal, 2008, Huang and Yuan, 2012).
Also, if the document has citations reported by
WoS, GS shows its citation count as reported in WoS
(see Figure 4).
Productivity and Impact Analysis of a Research and Technology Development Center using Google Scholar Information
161
Figure 3: Work details view.
Figure 4: Work citations reported by Web of Science on GS.
The public academic information provided by
Google Scholar is vast. In our work, we selected the
following data for our analysis:
1. Authors:
Name
Profile page URL
Citations count
Citations distribution
2. Work:
Title
Authors list
Details view URL
Document type
Publication year
GS citations count and distribution
GS citations page URL
WoS citations count and URL
Source details
3 DATA COLLECTION
To automatize the process to download the
information from GS is not an easy task. If too many
requests are generated in short time, GS qualifies you
as malicious traffic.
We developed an adaptive request rate (ARR)
technique, which allows our scraper to collect
information at a moderate speed, without exceeding
the established limits per second, minute and hour.
Figure 5 is a diagram of the scraper architecture
and data flow in the download process. The main
feature of this application is ARR. It is composed of
three requests gauges, which act as traffic lights. Each
gauge comprises a timer and a request counter. They
record the number of queries sent to GS per unit of
time in seconds, minutes and hours and adjust the
requesting speed to stay within the average set for
each unit.
The speed setting is palliative, which means that
as many requests are made as possible in a time
interval. When the interval is met, it is checked
whether the respective limit has been exceeded.
When it is exceeded, it calculates the time that the
program must wait before it can continue performing
requests (compensation time). This time is calculated
based on the equation [1], where r
lu
are the requests
sent in the last unit of time and l
rr
is the limit average
request rate. Once the pause is over, the scraper
restarts the requesting.
1
(1)
3.1 Data Cross-checking
Every retrieved record from GS was cross-checked
with Crossref, which provides a public API to search
automatically by work title. This helped us to ensure
the reliability of the dataset.
It took an average of 2 to 5 seconds to get an
answer from Crossref servers. This active waiting
time was included in the pauses generated by the
ARR; this helped to slow down the speed of the
requests sent to GS.
The categorization of Crossref works is much
more detailed; it contains 27 different types. From the
types provided by both data sources, we created the
common work classification of Table 1.
4 RESULTS
In this work, we present indicators and metrics based
on descriptive and exploratory analyses of
information from GS. This allows us to measure the
impact of the productivity research in our institution.
Also, this could be of interest for Research and
Technological Development Centers, where the
results of their research are not always published as
articles in peer-reviewed journals.
DATA 2019 - 8th International Conference on Data Science, Technology and Applications
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Figure 5: Scraper architecture and download flow.
The "raw" dataset collected from GS is composed of
137 authors associated with our research center with
a total of 8,492 works, in 2,565 sources and 74,683
citations. The citations are reduced to 26,972 for the
1,552 works also found in WoS (see section 2.1.3).
Since it is common to have several authors in a
paper, it is expected that the document appears in
each co-author's profile. When the co-authors are
from the same institution, the work will repeatedly
appear in the raw dataset. By filter out duplicate
works, we retain 6,949 different works. Table 2
presents the metrics used in our analysis.
4.1 Works Analysis
From the data extracted from GS related to the
authors’ profile, a total of 5,680 (82%) of the works
have a GS type. Within these works 3,001 (43%) also
have a Crossref type.
From the types provided by both data sources, we
create a common classification that divides the works
into 7 classes (as seen in Table 1).
Our analysis agrees with other studies; GS has
greater work coverage than other databases. In this
particular case, less than half of the documents
indexed by GS were found in Crossref. From the
classified papers, only 1,268 are contained in a JCR
journal.
The pace of publication of our research center can
be understood by observing academic production and
productivity. Production means the number of papers
published by year while productivity indicates the
average number of documents published per author in
each year. Productivity is also used to measure the
efficiency of human resources.
Table 1: Common work classification based on Google
Scholar and Crossref types.
Common class
Google
Scholar Type
Crossref type
Book Book book-chapter
book-track
book-part
book
book-set
reference-book
book-series
edited-book
reference-entry
Journal article Journal journal-article
journal
journal-volume
journal-issue
Proceedings
article
Conference proceedings-
article
proceedings
Thesis Institution dissertation
Patent Patent Number N/A
Miscellaneous N/A monograph
report
report-series
component
standard
standard-series
posted-content
(preprints)
dataset
Unclassified Source other
Productivity and Impact Analysis of a Research and Technology Development Center using Google Scholar Information
163
Table 2: Metrics in the dataset.
Metric Count
Authors 137
Works 6,949
Sources 2,450
Citations 74,683
WoS citations 26,972
Citations per author 420
Works per author 20.22
Avg. citations per work 10.74
Avg. authors per work 4.47
Figure 6 shows the production of works by year.
Figure 7 shows the number of authors who have
published each year, along with the average number
of papers per author. According to the graph, it is
clear that not always more researchers publishing
means a higher average number of papers. In 2004,
with 68 authors, more works were produced than two
years later with 80 authors.
Table 3: Distribution of the works in the dataset.
Class Works
count
Citations
count
Average
citations
per class
Journal
article
4 513 60 774 13
Proceedings
article
888 4 400 4
Book 284 4 266 15
Thesis 61 398 6
Misc 9 2 839 326
Patent 9 118 13
Figure 6: Production of works of our institution by year.
4.2 Citations Analysis
Nowadays, the role of bibliometrics for analyzing
research impact has increased its relevance. In this
sense, citations received for a paper, especially those
that are not self-citations, are considered as one of the
most important quality indicators at present, since
they speak of peer recognition.
We also were interested in knowing how many of
the citations generated by the staff corresponded
directly to the research center. Usually, citations
reported in a paper are assigned to each author. Works
with many citations are not necessarily representative
of an individual when there are many co-authors in a
single work. Also, it is well known that the higher the
number of authors, the more self-citations tend to
increase; these situations are known as the co-
authorship effect (Batista et al., 2006, Hirsch, 2005).
To minimize the impact of this situation, in our
analysis we normalized the citations by work, which
means that for each work, the total number of
citations is divided by the number of co-authors.
From the normalized citations, we generated an
indicator called institutional citations. This indicator
is calculated as follows. If a paper has 264 citations
and 8 authors, and 2 of them are from our institution.
First, each author has 33 standard citations (264 / 8).
Since there are two authors from our institution, then
there are 66 institutional citations (33 × 2). Figure 8
shows the total citation versus institutional citations.
In average, the institutional citations represents 25%
of the total of citations.
Thus, the participation that a research center
generates in citations is directly related to the number
of institutional authors participating in the works.
Figure 7: Productivity of our institution.
Another quantitative point of view to study the
publication patterns in an institution is to know what
is published and where. 80% of the citations are
contained in 342 sources representing 34% of the
works. In JCR, there are 94 of those sources reporting
32,697 citations in GS.
Taking into account Table 3 and Table 4, it seems
evident that the most common work and source types
are those classified as Journal. It is a fact that its
citation and work counts are much higher than any
other classification.
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The average number of citations by classification
is obtained by dividing the total number of citations
of one class, by the number of works in the same
class, this normalized the data to make comparable all
work categories, putting them all on the same scale.
Figure 8: Citations count vs. institutional citations.
Because of the above, we observe that the work
class Misc, which includes reports of different
natures, is the most important within the dataset,
followed by the Book class, moving Journal to third
place. This is congruent with the results shown in
Table 4, with Misc and Book publications appearing
with a higher weight than Journal; also, the two most
cited works in the dataset are a report and a book.
Journal articles will continue to be the most
numerous type of publication, as citations in indexed
journals are the standard measure of the quality of
current research and have a direct impact on the
professional lives of researchers, such as in
recruitment, tenure, promotion or funding. In the case
of institutions, they are reflected in university
rankings (Martín-Martín et al., 2018a).
4.3 WoS Citations Comparison
Google Scholar displays the WoS citation count
within its indexed works for subscribers to that
database, and we get it as seen in section 2.1.3.
Table 4: Citation coverage by publication type.
Source class Works
count
Citations
count
Average
citations
per class
Journal 1 936 49 396 26
Conference 437 4 809 11
Book 21 912 43
Misc 1 57 57
Figure 9: A. Total citations reported by GS for all works. B.
Citations reported in Google Scholar for the works that are
also reported citations in WoS. C. Citations in WoS for the
works in B.
There are several comparative studies about the
citation coverage between GS and other databases. In
summary, they conclude that the citation count is
about three times higher in GS than in WoS and
Scopus (Halevi et al., 2017, Harzing, 2013, Mingers
and Meyer, 2017).
In the study made by (Martín-Martín et al.,
2018b), they performed an analysis of the citations
overlap, 2,515 highly cited documents were included
from the sources mentioned above. They found that,
overall, citations in all three databases matched
46.9% and that more than one-third of the total
citations were only found by GS. By disaggregating
the results by fields of knowledge, they discovered
that nearly all citations overlapped in the areas of
Engineering, Physics & Mathematics, Earth
Sciences, and Chemistry & Materials, with overlap
Table 5: Results obtained from the chi-square test for the distribution of WoS citations.
Paper rank in h
index
GS citations
count
WoS citations
count
Degrees of
freedom
X
2
P value
9 488 332 7 14.33 0.0456
31 194 34 17 29.14 0.0330
39 177 69 5 17.6 0.0035
43 91 46 15 29.89 0.0123
52 54 25 15 29.19 0.0152
56 121 81 17 45.71 0.0002
107 109 61 16 43.23 0.0003
All citations 12 890 7 239 18 90.85 0.0000
Productivity and Impact Analysis of a Research and Technology Development Center using Google Scholar Information
165
percentages ranging from 46.8% to 67.7%. These
results lead them to conclude that GS contains almost
all reported WoS citations (95%).
Figure 9 shows the results we obtained from our
dataset. Considering the institution as a whole, GS
identified three times more citations than WoS; it
found more documents associated with institutional
researchers. By comparing the works identified by
GS that are also in WoS, we found a citation overlap
of around 60%, which coincides with the range
mentioned above for the research areas of our interest.
GS only provides the citation count reported in
WoS, but not its distribution. It has been found that
there is a remarkably strong linear correlation at the
document level between GS, Scopus, and WoS
citation counts in the range of 0.8 to 0.9. This degree
of correlation suggests that the behavior of citations
is similar in all three data sources, regardless of the
volume of documents in each of them (Halevi et al.,
2017, Martín-Martín et al., 2018a).
Considering the findings reported for overlap and
correlation of citations previously mentioned, we
generated a theoretical distribution by year of the
citations count reported in WoS, based on the GS
distribution by year. For this analysis, we consider 73
documents of the institutional h-index that contain
citations in both databases, between 2000 and 2018.
We performed the Pearson chi-square test that
measures the discrepancy between an observed and a
theoretical distribution, using the actual distribution
of WoS citations with a statistical significance of
95%.
At the document level, we find that in only 9.5%
of cases, the theoretical and observed distributions are
adjusted with a minimal discrepancy. When
considering the citations of the 73 papers as a unit,
there is also a statistically significant difference
(Table 5). These results suggest that the proposed
distribution model should be applied only to
distribute citations at the institutional level (Figure
10).
4.4 Institutional Quality and Impact
Nowadays, the most accepted index to consider when
it comes to characterizing a researcher's work is the
h-index. (Hirsch, 2005) defines this index as the h
articles of a researcher with a number of citations
equal to or greater than h. The original research
focused only on physicists, but the index has proven
been useful for many disciplines.
Hirsch also mentioned several disadvantages of
single-number metrics that are commonly used to
evaluate scientific research, generally referring to the
Figure 10: Goodness of fit for the theoretical distribution of
WoS citations generated from the GS distribution.
counting of citations and works. His main criticisms
are based on the difficulty of the calculation, the low
relevance of the impact and the use of arbitrary
parameters. Hence, the calculation of the h-index is
necessary to understand the quality of the research
conducted at the institutional level.
Following the mechanism indicated by the index
creator, we consider all authors’ works, ordering them
according to their citations, until we find that 108
papers have at least 108 citations. Documents of h-
index are published in 59 sources (24 of them in JCR),
with the participation of 33% of the authors, adding a
total of 25,808 citations in GS and 8,033 in WoS. As
expected, Journal is the most extensive work class.
However, the ones with the most significant weight
are these classified as Misc and Book. We also
calculated a normalized h-index (106), similar to that
proposed by (Batista et al., 2006) considering
normalized citations, instead of total citations. The
purpose of this index is to determine the impact per
author. We also propose calculating an institutional
h-index (65) computed from institutional citations.
5 CONCLUSIONS
Today, bibliometric analysis has become a
fundamental tool for assessing the scientific research
quality, its impact and collaboration patterns, often
used in strategic planning and evaluation contexts.
Google Scholar is a valuable source of information
for these purposes, having clear advantages over WoS
and Scopus, in terms of citations coverage and types
of work generated in research and technological
development centers. In this study, we explore the
extent to which the data available in Google Scholar
can be used to conduct a formal analysis of an
institution's research, concluding:
GS can be used as a source of bibliometric data
for authors and institutions, whose research
DATA 2019 - 8th International Conference on Data Science, Technology and Applications
166
results are published in formats that are not
necessarily journal articles and that are in a
language other than English.
The grouping of authors through their
affiliation and the possibility of listing them by
that criterion in GS makes possible the
recovery and analysis of an institution’s
scientific production as a whole.
GS provides enough information to calculate
metrics commonly used to estimate the
scientific quality of research and to discover
publication patterns from a wide variety of
publications.
The recovery of the information from GS is a
challenging task since Google does not provide
an API to access its data.
Consistent with previous literature, we found
that GS coverage is greater than other scientific
databases.
As corroboration of our productivity metrics,
we observed a significant correlation in citation
counts for the publications of GS that
overlapped with those of WoS and Scopus.
Finally, our analyses were limited to the scientific
publications of authors of our institution. As a future
work, we will include other institutions with similar
lines of research to compare and evaluate the
performance of different research centers.
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