The OpenRepGrid.ic
R
package
is a browser-based software to perform Interpretive Clustering (IC)
for repertory grid data. The repertory
grid (often abbreviated
as grid or repgrid) is a person-centered data collection method. It
is primarily used in clinical psychology and generates a mix of
qualitative and quantitative data. IC is a method for clustering the
attributes (so called constructs) resulting from a repertory grid
interview by finding relational patterns between them. The IC method is
described in more detail in our publication Burr, King, and Heckmann
(2020). An introduction
to the software is also available on
YouTube. The package is part of the
OpenRepgrid project, which contains several
software packages for the analysis of repertory grid data. In the
following, we will briefly explain, why the software was developed,
describe the repertory grid technique and provide a short example of how
a grid dataset can be analyzed and interpreted using our
OpenRepGrid.ic
software.
Currently, the IC method is not implemented in any other existing repertory grid software. While IC can also be conducted by hand, this is very time consuming, error-prone and only feasible for small-sized grids. Hence, a software solution to support the IC procedure is needed. Without proper software support that facilitates the IC steps, the method is too laborious and is thus likely to become a methodological contribution which will rarely be used in research due to above mentioned reasons.
The repertory grid technique (RGT) is a method which originated from Personal Construct Theory (PCT) (Kelly 1955). It was originally designed as an instrument for clinical psychology but quickly spread to other disciplines like marketing, political, organizational, and educational research in the decades after its inauguration (Fransella, Bell, and Bannister 2004). The RGT is a person-centered method which focuses on understanding how an individual sees, or in constructivist terms construes, the world. The data collected by the RGT is both, qualitative and quantitative. The qualitative part of the data consists of a list of bipolar attributes (e.g. light-hearted vs. depressed), which are elicited during the repertory grid interview. These attributes are called constructs in PCT terminology. Each construct consists of two poles, e.g. light-hearted and depressed, with the poles usually being opposites. In PCT, the constructs constitute the templates a person uses to construe a set of objects under consideration. These objects are called elements in PCT terminology and are, for example, persons, brands, countries, companies etc. In our example in Figure 1, the elements are a set of persons relevant to the grid interviewee, for example, father, mother, self, or ideal self. The quantitative part of a grid is generated by letting the interviewee assign a score (e.g. 0/1, or 1 to 6) to each element on each of his/her bipolar constructs. The result of the RGT is usually displayed as a constructs x elements matrix with the cells containing the ratings of each element on each construct. Figure 1 shows a grid matrix where binary ratings (0/1) were used to assess the elements. For example, the element father received a score of 1 on the isolated = 0 vs. sociable = 1 construct, indicating that the father is construed as sociable. The mother, in contrast, received a score of 0 and is thus construed as isolated. The grid matrix is the central result of the RGT and yields a) a set of bipolar constructs which are relevant to the person and b) an assessment of each element (persons in Figure 1) on these dimensions. The white/red color coding in Figure 1 additionally indicates which construct poles (white = left, red = right) apply and facilitates to identify similarities between elements. In its original form (Kelly 1955) and in our example, grid ratings are binary (0/1), i.e., each element is assigned to one construct pole. Nowadays, also scales with more grades (e.g. 1 to 6) are common. A general and more comprehensive introduction to the RGT can be found in Fransella, Bell, and Bannister (2004).
Figure 1: Example of a binary repertory grid dataset. The data is a binarized version of a grid from Böker (1996)IC is an idiographic method of interpretation which makes use of both, the qualitative and the quantitative grid data. In contrast to thematic analysis or content analysis, which could be used to identify themes in person’s elicited constructs (see Braun and Clarke 2006), IC identifies the relation between the constructs via quantitative assessment. By assessing the quantitative construct relations, implications which constructs hold for each other are identified. IC essentially identifies clusters of constructs which hold implications for each other. These clusters (or cliques) of constructs form the basis for a subsequent qualitative interpretation. We will provide a brief interpretation example below. The example builds on the analysis results the software generates as shown next. However, for a more thorough introduction to the IC method and comprehensive illustrations of interpretations, the reader is referred to our publication Burr, King, and Heckmann (2020). Please note that the IC method only allows for binary grid ratings.
The package can be downloaded from the CRAN repository via the R command
install.packages("OpenRepGrid.ic")
. The software is then started as
follows.
library(OpenRepGrid.ic)
ic()
Also, we provide a docker image under https://hub.docker.com/repository/docker/markheckmann/openrepgrid.ic with a short instruction on how to run it locally. A video of the software is displayed in Figure 2. It shows the various tabs and processes a grid dataset from an interview with Sylvia which is also contained in the package.
The results of the IC analysis are not displayed interactively but are included in an MS Excel file that can be generated and downloaded. Also the results of the intermediate IC steps as described in Burr, King, and Heckmann (2020) are contained. The main purpose of the software is to automate the cluster identification step of the IC procedure, which is a cumbersome and error-prone task if performed manually. In Figure 3, an extract of the analysis results for Sylvia’s grid and corresponding analysis settings as shown in Figure 2 are displayed and subsequently discussed.
Figure 3: Results of IC method for Sylvia.Psychologically relevant information can be obtained from the interpretation of the network graphs. What follows is a shortened example. More comprehensive examples are outlined in our publication.
In the resulting diagram for Sylvia’s grid in Figure 3, a construct is indicated by a circle, with (+) denoting the preferred and (-) the non-preferred pole. The diagram shows three clusters (also called cliques), indicated by the colored hulls around several constructs. In Sylvia’s case, the three clusters are highly overlapping. Two of these are of particular interest, sharing a ‘core’ of three constructs – ‘(+) Wild, free vs (-) controlled, contained’, ‘(+) Massive sense of space, expansive vs (-) railed-off, small world’ and ‘(+) Freedom, wildness vs (-) conventional’, with (+) indicating the preferred and (-) the non-preferred pole. In one cluster, these three constructs are strongly associated with ‘(+) Verdant vs (-) dead, nothing thriving’; the association between her preferred poles suggests that she is drawn to places that are thriving and green, wild and expansive, as opposed to those which lack life, are small-scale, controlled and conventional. However, these three constructs share another cluster with the construct ‘(+) Cosy vs (-) Chaotic’, where ‘cosy’ is her preferred pole. In this cluster, however, her desires for the wild, free and expansive appear to be in tension with her desire for the ‘cosy’, as they are aligned with her non-preferred pole ‘chaotic’. The attraction of wild, free spaces for Sylvia is therefore not straightforward.
The third cluster includes the ‘(+) Verdant vs (-) dead, nothing thriving’ construct, which is here associated with ‘(+) Exciting, a lot going on vs (-) flat, unvarying, depressed, unenergetic’, ‘(+) Dramatic vs (-) unvarying, goes on and on’ and ‘(+) Variable vs (-) doesn’t change’. This suggests that to Sylvia ‘verdant’ spaces are also full of excitement, drama and variability- they are full of life in these ways. However, the fact that these three constructs do not cluster with the wild/expansive/freedom constructs indicates that they constitute a somewhat separate idea for her. A ‘wild’ space for her need not be ‘exciting’, for example, although a ‘verdant’ space is likely to be both exciting and wild. Interpretive clustering therefore gives us insight into some of the complexity of Sylvia’s construing.
In order to maximize the package’s usefulness for the research
community, we welcome participation in the package’s development.
Experienced R programmers are asked to make pull requests to the
OpenRepGrid.ic
GitHub
repository, report
issues, or
commit code snippets. Non-technical oriented researchers are invited to
send us feature requests or suggestions for improvement.
Böker, Heinz. 1996. “The Reconstruction of the Self in the Psychotherapy of Chronic Schizophrenia: A Case Study with the Repertory Grid Technique.” In Empirical Constructivism in Europe: The Personal Construct Approach, edited by Jörn W. Scheer and Ana Catina, 160–67. Giessen: Psychosozial-Verlag.
Braun, Virginia, and Victoria Clarke. 2006. “Using Thematic Analysis in Psychology.” Qualitative Research in Psychology 3 (2): 77–101. https://doi.org/10.1191/1478088706qp063oa.
Burr, Viv, Nigel King, and Mark Heckmann. 2020. “The Qualitative Analysis of Repertory Grid Data: Interpretive Clustering.” Qualitative Research in Psychology 0 (0): 1–25. https://doi.org/10.1080/14780887.2020.1794088.
Fransella, Fay, Richard C. Bell, and Donald Bannister. 2004. A Manual for Repertory Grid Technique. 2nd ed. Chichester: John Wiley & Sons.
Kelly, George Alexander. 1955. The Psychology of Personal Constructs. New York: Norton.