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Network models and sensor layers to design adaptive learning using educational mapping

Published online by Cambridge University Press:  19 April 2021

Luwen Huang
Affiliation:
The Mapping Lab, Massachusetts Institute of Technology, Cambridge, MA02139, USA
Karen E. Willcox*
Affiliation:
Oden Institute for Computational Engineering and Sciences, UT Austin, Austin, TX78712, USA
*
Corresponding authorKaren E. Willcox [email protected]
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Abstract

A network modelling approach to educational mapping leads to a scalable computational model that supports adaptive learning, intelligent tutors, intelligent teaching assistants, and data-driven continuous improvement. Current educational mapping processes are generally applied at a level of resolution that is too coarse to support adaptive learning and learning analytics systems at scale. This paper proposes a network modelling approach to structure extremely fine-grained statements of learning ability called Micro-outcomes, and a method to design sensors for inferring a learner’s knowledge state. These sensors take the form of high-resolution assessments and trackers that collect digital analytics. The sensors are linked to Micro-outcomes as part of the network model, enabling inference and pathway analysis. One example demonstrates the modelling approach applied to two community college subjects in College Algebra and Introductory Accounting. Application examples showcase how this modelling approach provides the design foundation for an intelligent tutoring system and intelligent teaching assistant system deployed at Arapahoe Community College and Quinsigamond Community College. A second example demonstrates the modelling approach deployed in an undergraduate aerospace engineering subject at the Massachusetts Institute of Technology to support course planning and teaching improvement.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press

1. Introduction

Maps for education are numerous and diverse at many levels of scale. To give examples: there are degree maps that showcase paths through different majors (Aleven, McLaren, & Koedinger Reference Aleven, McLaren and Koedinger2010), curriculum maps that trace subject sequences through a programme’s offerings (Arafeh Reference Arafeh2016), concept maps that show related topics for learners (Fiorella & Mayer Reference Fiorella and Mayer2018), and outcomes maps that support accreditation (Willcox & Huang Reference Willcox and Huang2017) and learning path generation (Seering, Willcox, & Huang Reference Seering, Willcox and Huang2015; Miller, Willcox, & Huang Reference Miller, Willcox and Huang2016; Yang, Li, & Lau Reference Yang, Li and Lau2017). Scalable educational mapping via network modelling involves identifying entities and relationships amongst these entities, and representing them mathematically as a graph Willcox and Huang (Reference Willcox and Huang2017). In the computer science literature, this is referred to as a knowledge graph (Chen, Jia, & Xiang Reference Chen, Jia and Xiang2020). When educational maps are used for analytics and assessment, it is vital that their constituent entities and relationships are of sufficient resolution to pinpoint a learner’s status and to move the learner forward. It is also vital that these maps encompass notions of sensing (i.e., inferring a learner’s state) and feedback (i.e., influencing a learner’s future trajectory). This paper develops a modelling framework for architecting and designing such a fine-grained sensor-enabled educational map, and illustrates its potential use as a foundational model for an intelligent tutor and intelligent teacher assistant.

In contrast to a traditional table-based format, the network model explicitly represents relationships as first-class objects instead of as derived properties of other objects. This is important because relationships among elements of the model are essential to educational analytics (e.g., in pathway analyses, in understanding how content relates to learning objectives, etc.) and so the network model yields a flexible representation that enables visualisation and analysis of educational data at scale. Network modelling approaches are starting to see broader use across design science in other applications where relationships are key to inference, analysis and design. For example, a network mapping of technology constructed from patent data has been used to infer properties of technologies and of inventor behaviour (Alstott et al. Reference Alstott, Triulzi, Yan and Luo2017) and its effect on concept generation (Song, Srinivasan, & Luo Reference Song, Srinivasan and Luo2017). Use cases of the technology map include guiding technological change, exploration of design directions for inventors (Alstott et al. Reference Alstott, Triulzi, Yan and Luo2017), identifying design innovation directions in the technology space (Luo, Yan, & Wood Reference Luo, Yan and Wood2017) and visualising and analysing the expansion trajectories of the design knowledge base of a given technology domain (Song et al. Reference Song, Yan, Triulzi, Alstott and Luo2019). Another example is mapping of topics from multiple domains to discover creative sources of design inspiration (Ahmed & Fuge Reference Ahmed and Fuge2018).

In mapping an educational subject, entities can range from topical knowledge units to learning outcomes. Learning outcomes are statements of what a learner should be able to do; however, they are typically at a granularity level that is too coarse to support intelligent tutors that employ data-driven adaptive learning. Coarse-grained learning material may contain multiple subtopics, learning activities and learning objectives, which can lead to unclear meaning in connections between learning objectives (Pardos et al. Reference Pardos, Heffernan, Anderson and Heffernan2006; Ellis Reference Ellis2013; Thompson & Yonekura Reference Thompson and Yonekura2018). In contrast, adaptive learning systems and learning analytics require fine-grained learning objects (Battou et al. Reference Battou, Mezouary, Cherkaoui and Mammass2011), since in order for adaptive learning systems to correctly assess a learner’s state, the knowledge units used must be granular (Collins, Greer, & Huang Reference Collins, Greer and Huang2005; Reimann, Kickmeier-Rust, & Albert Reference Reimann, Kickmeier-Rust and Albert2006; Aleven, McLaren, & Koedinger Reference Aleven, McLaren and Koedinger2010; Essa Reference Essa2016). In this paper, we introduce the notion of fine-grained learning entities that we call Micro-outcomes. Table 1 shows an example of a typical subject-level learning outcome compared to our more granular Micro-outcomes. As Micro-outcomes are statements of a fine-grained skill a learner should be able to do, they will provide an effective way to infer and respond to a learner’s state. Amongst Micro-outcomes, there are prerequisite relationships, that is, certain skills build on others. The idea of analysing a knowledge domain into constituent skills and recognising that there are prerequisite skills has long been a key idea in the concept of mastery learning (Corbett & Anderson Reference Corbett and Anderson1994). Cavanagh et al. (Reference Cavanagh, Chen, Lahcen and Paradiso2020) similarly break one learning objective into multiple more granular pieces that they call ‘learning bits’ in order to design adaptive learning. Here, we use network models to structure the knowledge domain and represent the prerequisite and organisational relationships amongst Micro-outcomes.

Table 1. A typical learning outcome contrasted with high-granularity Micro-outcomes

A second challenge addressed in this paper is the need for sensors that provide observational data that support inference of a learner’s state. What is a sensor in the educational setting? Just as physical sensor provides (often indirect and noisy) information about a physical or natural system state, an educational sensor provides information about a learner’s state. Educational sensors may take the form of assessment questions or digital analytics that track a learner’s or instructor’s actions. Sensors may provide information at the level of an entire course, particularly when the sensor relates to a summative assessment (e.g., a final exam). Sensors may also be high resolution, providing information at a more fine-grained level, as is often the case for formative assessments (e.g., an in-class concept question poll). However, grain size is a known issue in assessment (Popham Reference Popham2006), and it is recognised that fine-grained statements of learning goals tied to assessments are essential to assessment design (Falkner, Vivian, & Falkner Reference Falkner, Vivian and Falkner2014; Yang, Li, & Lau Reference Yang, Li and Lau2017; Marion Reference Marion2018; Shepard, Penuel, & Pellegrino Reference Shepard, Penuel and Pellegrino2018). Especially for formative use cases, it is critical that assessments should be of high resolution, ideally matching the granularity of the Micro-outcome being tested, so that precise data analytics can be collected and accurate feedback can be generated for the learner (Reimann, Kickmeier-Rust, & Albert Reference Reimann, Kickmeier-Rust and Albert2006; Ellis Reference Ellis2013; Essa Reference Essa2016).

In this paper, we introduce a method to architect and design a network model using our high-granularity Micro-outcomes together with a sensor layer for inferring a learner’s state using high-granularity assessments and digital analytics. The next section presents the theoretical framework: we begin by motivating and architecting the network model, and explain how we design Micro-outcomes. We then introduce the approach of a high-granularity assessment and/or digital tracking analytics acting as a sensor, and show how these measurements link to the network model. We apply the process of designing Micro-outcomes and assessments to a specific instance of modelling Community College subjects in College Algebra and Introductory Accounting, and describe the implementation of the resulting network model and sensors applied to an intelligent tutoring system and intelligent teaching assistant system in community college classrooms. The paper presents a second example of the approach applied to develop a network model and digital analytics sensor layer for an aerospace engineering undergraduate subject at the Massachusetts Institute of Technology.

2. Educational mapping via a network model and sensor layer

This section first presents the network model that defines and connects fine-grained Micro-outcomes. We then describe how we architect and design a sensor layer on top of the base network model using high-resolution assessments and digital analytics.

2.1. The network model

A network model is a set of entities and relationships arranged in a graph structure in which entities are represented as vertices and relationships are represented as edges. Our previous work proposed an approach for mapping educational data with network models to obtain powerful analytical capabilities that come from making explicit the connections amongst entities in an educational system (Willcox & Huang Reference Willcox and Huang2017). Examples of entities include: an educational institution, a department, a subject, a learning module, a learning outcome, a concept, etc.

In the network model developed in this paper, we define the notion of a Micro-outcome entity. We name a Micro-outcome for its granularity – it is a statement describing an extremely fine-grained learning outcome. Learning outcomes may be familiar to readers in education as statements of competencies; however, in this case, it is important to emphasise that Micro-outcomes are unlike common learning outcomes in this respect – Micro-outcomes are much more fine-grained (as the example in Table 1 shows). The high granularity of a Micro-outcome in our model makes the model powerful enough to fuel many use cases, such as intelligent tutoring applications that pinpoint a user’s difficulties, recommendation engines that direct students to learning resources, or evaluation tools. For example, one may construct the Micro-outcomes as elemental knowledge points that are not further decomposable in the learning process, which paves the way to making a learner’s state more observable. We discuss this further in the next section, where we introduce the notion of a high-resolution sensor layer overlaying our fine-grained network.

The network model also represents the relationships between Micro-outcomes, as well as the relationships between Micro-outcomes and other entities. Between two Micro-outcomes there may be a has-prerequisite-of relationship that points from one Micro-outcome to the other. This relationship represents the notion that achieving one Micro-outcome is a prerequisite to achieving the next Micro-outcome. While the notion of prerequisites is commonly used with general competencies, explicitly highlighting prerequisite relationships amongst such granular Micro-outcomes is an enabler for designing sensing and adaptive feedback strategies. Between two Micro-outcomes there may instead be an undirected is-related-to relationship that indicates that the Micro-outcomes are related (e.g., they relate to similar skills), but not necessarily in a prerequisite manner.

The other entities in our model are Content, Module and Subject. A Module is a grouping of similar Micro-outcomes. This grouping is formally represented by a has-parent-of relationship pointing from a Micro-outcome to a Module. Similarly, a Subject is a grouping of Modules, and this grouping is also formally represented by a has-parent-of relationship pointing from a Module to the Subject entity. Content is related to the Micro-outcomes it addresses through addresses relationships. Figure 1 depicts the schematic of our network model with Subject, Module, Content and Micro-outcome entities, and the relationships amongst these entities.

Figure 1. Schematic showing nodes (entities) and edges (relationships) in base network model.

2.2. Architecture and design of the sensor layer

Drawing inspiration from networked systems, the sensor layer overlays the base network. The purpose of the sensor layer is to sense a learner’s status on each node in the network as the learner traverses through the network. The sensor layer can be composed of Assessments, where an Assessment is a question designed to infer the learner’s state relative to the Micro-outcomes targeted by that Assessment. The sensor layer can also include Trackers, which collect digital analytics about a learner’s or instructor’s actions (e.g., clickstream, page view counts, time on a particular screen, etc.). Figure 2 illustrates the notion of an Assessment or a Tracker serving as a sensor for a Micro-outcome.

Figure 2. Assessments (left) and Trackers (right) act as sensors for inferring learner state relative to a Micro-outcome.

Trackers are code implementations designed to collect interaction information on a learner’s actions, such as click interactions and time spent on a page. In the network model depicted in Figure 2, a Tracker measures actions executed on Content. Inferences about learner state leverage the underlying network model, using the addresses relationships that connect Content to Micro-outcomes.

Assessments can be multiple-choice or free-response, word-based or graphical, written or verbal. Because Assessments need to gather information on a learner’s achievement of a Micro-outcome, an Assessment must have the same level of (high) granularity as a Micro-outcome. When a learner responds to an Assessment, the learner’s response is collected as sensor data; the sensor data contains information on the learner’s capability of the targeted Micro-outcome, and crucially, why the learner provided his/her response. To assess the ‘why’ of the response, the base network model comes into play: recall that Micro-outcomes have prerequisite relationships to each other. Therefore, a gap of understanding in a prerequisite Micro-outcome is a possible reason why the learner answered incorrectly. The sensors must be designed using the base network model to enable inference of which prerequisite Micro-outcome underlies a learner’s gap. This takes the form, for example, of distractor questions that target a particular prerequisite gap. Given the sensor data (learner’s response), the inference of the learner’s state can be based on a manually hard-coded rule, for example, Response X always maps to (prerequisite) Micro-outcome A; it can be algorithmically-determined, for example, an artificial intelligence system can classify the response as belonging to one of the prerequisite Micro-outcomes; it can be binary, for example, belonging to Micro-outcome A or not; or it can be probabilistic, for example, belonging to Micro-outcome A with probability p. The existence of the base network model enables this determination. It also provides the model to determine the appropriate feedback to guide a learner through the network.

The sensor data collected provide input data to infer the learner’s state relative to each Micro-outcome targeted by the Assessments. Here, another inference can be made to evaluate the learner’s achievement of the Micro-outcome. The determination can be binary, that is, ‘Achieved or Not Achieved’; it can be categorical, for example, ‘Strongly Achieved, Moderately Achieved, Not Achieved’; it can be probabilistic, for example, ‘Achieved with probability p’; or it can be mixtures of the above. Furthermore, the inference can be made with a long-memory process, in which a student’s repeated attempts at a given Micro-outcome are tracked and remembered in the computation, or the inference can be made independently of previous historical data. Crucially, the base network layer joined with the sensor layer enables this inference of student state to be made at a high level of granularity. In the following sections, we demonstrate how this provides a foundation for an intelligent teacher assistant and for analytics that drive teaching improvements.

3. An intelligent teacher assistant for community college courses in College Algebra and Introductory Accounting

This section presents the development of two specific instances of the network model and sensor layer in the mapping of community college subjects. These mappings provide a foundation for an intelligent teacher assistant system used in the Fly-by-Wire project. Fly-by-Wire was deployed at two community colleges (Arapahoe Community College in Colorado and Quinsigamond Community College in Massachusetts) over a period of 3 years, involving 8 faculty members and 189 students across two subjects, College Algebra and Introductory Accounting. It is beyond the scope of this paper to detail the Fly-by-Wire project; here, we focus on the development of the network model and sensors, and how they form the basis of the intelligent feedback system.

3.1. Constructing the base network map

We map the subjects of College Algebra and Introductory Accounting as taught statewide in the Colorado Community College System. Our network model has three types of entities: Subject, Module and Micro-outcome. Micro-outcomes were extracted by working backwards from high-level outcomes standardised state-wide. For instance, the state of Colorado publishes state-wide outcomes in a syllabus format that specify what a community college graduate must be able to do for each learning module (Algebra, Geometry, etc.). For each high-level outcome, instructors and other subject matter experts worked backwards to arrive at prerequisite outcomes. Learning references such as student textbooks provided some guidance in this process and also provided some validation with respect to prerequisite order by listing more fine-grained outcomes at the beginning of each chapter. Figure 3 shows the College Algebra Module ‘Inverse Functions’ and some of its Micro-outcomes. After applying the mapping process, we obtain network models with the numbers of entities and relationships shown in Table 2. For this example, the graphs were constructed manually by a team of instructors and subject matter experts working together.

Figure 3. The ‘Inverse Functions’ Module and some of its Micro-outcomes in College Algebra. Highlighted outcome is again shown in Figure 5. Note: most has-parent-of relationships to ‘Inverse Functions’ have been omitted in the figure for clarity.

Table 2. Summary dimensions of the maps and sensor layers of College Algebra and Introductory Accounting

3.2. Architecting and designing the sensor layer

The next step is to design the Assessments constituting the sensor layer. To construct an Assessment, we use our network map: first, we choose a node of type Micro-outcome that is one of the most synthesising Micro-outcomes, that is, it draws from a long chain of prerequisites. Formally, this is done by computing the topological sort of the graph and identifying the nodes with the highest rank induced by outgoing edges of type has-prerequisite-of.

Starting with the most synthesising Micro-outcome (with highest rank), we create a multiple-choice question designed to evaluate the learner’s mastery of the Micro-outcome. We chose the multiple-choice format since students in the College Algebra course are accustomed to multiple-choice questions, but as described earlier, our framework generalises to other types of questions. A multiple-choice question is composed of the question wording itself and the set of answer choice options. Within the set of choice options, there is one correct answer, and at least one incorrect answer. Designing the incorrect answers is key; for this we use our base network map. Using the network map, we identify the prerequisite Micro-outcomes that lead to the targeted Micro-outcome. Formally, we follow the has-prerequisite-of relationships to one hop away from the starting node. Given a particular prerequisite, we construct an incorrect answer that might result if the learner has not met that prerequisite. We do this for all prerequisites. Recall that there can be many different methods of determining why an incorrect response was given. In this particular instance, we deterministically assign each incorrect option to a prerequisite Micro-outcome, however, our modelling approach is generalisable to other methods of determination. Figure 4 illustrates the schematic of a multiple-choice Assessment with incorrect options that link to prerequisite Micro-outcomes. A concrete example of one such Assessment is shown in Figure 5; the top half shows the Assessment with its incorrect options (b, c and d), and the bottom half displays the Micro-outcomes that are linked to each incorrect option.

Figure 4. Schematic showing how a multiple-choice Assessment with incorrect options is linked to prerequisite Micro-outcomes.

Figure 5. A screenshot from our technology of a multiple-choice Assessment for College Algebra with incorrect options (b, c and d) linked to their respective Micro-outcomes.

The above describes the construction of one Assessment. To construct the next Assessment, we look to the next Micro-outcome for which to write the Assessment by traversing the graph in a breadth-first search. This yields a collection of Assessments in which there is at least one Assessment for every Micro-outcome. In our implementation, teams of instructors and subject matter experts constructed the assignments. We referenced published and validated assessments, such as in student textbooks and assessments already used in our target classes, and altered the specifics of the question. (Due to copyright reasons, we could not use the assessments exactly as they were published.) Table 2 summarises the numbers of resulting Assessments for each Subject.

The base network map comprising all Micro-outcomes, Modules and their relationships, as well as the sensor layer comprising all Assessments and their linkages, can be freely accessed at the Open Ed Graph APIs website.Footnote 1

3.3. Deploying an intelligent tutor and teacher assistant

This network map and sensor layer form the foundations for the Fly-by-Wire Student App, an intelligent tutoring web and mobile application designed for formative assessment, and the Fly-by-Wire Instructor App, an intelligent tutoring and analytics system to help instructors identify and address areas of misunderstanding.

On the FbW Student App, students were assigned between five and seven synthesising Micro-outcomes per homework assignment. Recall from the previous section that a synthesising Micro-outcome is one with highest rank as computed using the base network model. For each Micro-outcome, the app displayed an Assessment targeting the given Micro-outcome. Figure 6 shows an assignment that targets the Micro-outcome ‘Determine the vertex of a parabola given its function and axis of symmetry’. This particular Micro-outcome synthesises six prerequisite Micro-outcomes. In the figure, the user is on the first Assessment, which corresponds to the targeted Micro-outcome.

Figure 6. The Fly-by-Wire Student App delivers multiple-choice questions designed as sensors to infer student state on the network of Micro-outcomes.

If the student answers an Assessment incorrectly, the app presents another Assessment that addresses the Micro-outcome that is linked to the incorrect response. In this way, the student is guided in a depth-first search through the network; this results in the student most quickly getting to the most fundamental Micro-outcomes (i.e., the ones with lowest rank) that are the cause of their initial incorrect response. Note that the depth-first search corresponds to the way in which we architect the multiple-choice assessments to have distractor questions corresponding to upstream prerequisite Micro-outcomes. Here, we see a concrete instance of how an Assessment functions as a sensor, in which high-resolution data are being collected as the student interacts – the incorrect response, the time spent on a given Assessment, and any other interaction or selections the student may have with a given answer option. These fine-grained sensor data are possible only because the Assessments and their linked Micro-outcomes have correspondingly high resolution.

The Fly-by-Wire Instructor App uses the sensor data generated during student interaction on the Student App. The Instructor App highlights Micro-outcomes with which students had difficulty, and offers guidance for how to address these areas of weakness by highlighting the directed acyclic graph (DAG) formed by these Micro-outcomes and their prerequisites. For instance, consider the example shown in Figure 7. The synthesising Micro-outcome that 11 of 22 students did not achieve was ‘Find all of the zeros of a polynomial function’. The graph shown is the full DAG of the Micro-outcome and its prerequisites, and the highlighted path shows the prerequisite Micro-outcomes with which most students had difficulty. Using this network map, the instructor can then address these specific Micro-outcomes using a variety of instructional methods.

Figure 7. The Fly-by-Wire Instructor App assimilates sensor data and highlights the directed acyclic graph of the Micro-outcomes with which most students had difficulty.

4. Fine-grained Micro-outcome map to support learning analytics in a sophomore engineering subject

This section presents the development of a network model and sensor layer for the sophomore class Signals and Systems as taught in the aerospace engineering undergraduate degree programme at the Massachusetts Institute of Technology in Fall 2017. In this example, digital analytics are the high-resolution sensors that track learning behavior and topical flow to assist in course planning and teaching improvement.

4.1. Constructing the base network map

The Signals and Systems subject has 36 measurable outcomes, defined by departmental curriculum planning. To construct a network model, we break these measurable outcomes into 195 Micro-outcomes. We group the Micro-outcomes in 25 Modules. Each Micro-outcome is addressed by a specific section (or sections) in the lecture notes; such a section is designated as an entity of type Content. The entities in our network model are thus Subject, Module, Micro-outcome, and Content. A grouping of Micro-outcomes in a Module is represented mathematically by a has-parent-of relationship. Similarly, the grouping of Modules to form the Subject is represented by a has-parent-of relationship. The relationship between Micro-outcomes is represented by an undirected is-related-to relationship. The relationship between Content and Micro-outcomes is represented by an addresses relationship. Table 3 shows the number of entities and relationships for the Massachusetts Institute of Technology (MIT) Signals and Systems subject. Figure 8 visualises the Signal and Systems map with Micro-outcomes grouped into 25 Modules.Footnote 2

Table 3. Properties of the network model for the subject Signals and Systems as taught in the aerospace engineering undergraduate degree programme at the Massachusetts Institute of Technology in Fall 2017

Figure 8. A visualisation of the map of the subject Signals and Systems as taught in the aerospace engineering undergraduate degree program at the Massachusetts Institute of Technology in Fall 2017.

4.2. Architecting and designing the sensor layer

The base network map in this application is implemented as a web application for student learning. Shown in Figure 9, the web application displays clickable Micro-outcomes arranged by Module; a click to a Micro-outcome takes the learner to a Content page that addresses the specific Micro-outcome. In addition to displaying as a ‘list view’ as shown in Figure 9, the network map is also displayed as a ‘map view’ as shown in Figure 10. This is made possible via architecting the data backend with separation of concerns against any frontend applications.

Figure 9. The map is used to create a web application that enables searching of Micro-outcomes, arranged by Module and linked to Content pages.

Figure 10. The network map can also be browsed in a ‘map view’ in which nodes are Micro-outcomes, are clickable, and bring the learner to a specific piece of Content.

The next step is to design the Trackers constituting the sensor layer in this application. Trackers are code implementations designed to collect interaction information on a learner, such that this information can be used downstream for learning analytics and decision-making. We attach a Tracker to every piece of Content as was shown in Figure 2, and collect the following pieces of information: the timestamp of when the learner visits the piece of Content, the location and device of the visit, the unique identifier of the learner, the time spent on page, click interactions on page, and the duration of time on page. Crucially, in addition to information collected on the current node, the Tracker also collects information on the next node, that is, the next Micro-outcome that the learner clicks to. This linked structure enables pathway analysis and inference across the entire graph. Figure 11 illustrates a single pathway undertaken by a learner in a single visiting session. Pathway analyses are valuable in helping to identify sources of student misunderstandings as well as foundational topics that relate to a large number of other Micro-outcomes. For example, in Figure 11, the Micro-outcome ‘Determine the Fourier series expansion of a periodic signal’ is one that relates to many other Micro-outcomes in the Signals and Systems subject.

Figure 11. Interaction pathway of a single student session. The student first visits the List View, clicks to two Micro-outcomes (#1 and #2), then visits Micro-outcome #3, and finally goes back to Micro-outcome #1.

While a formal assessment of the effectiveness of this deployment in the MIT Signals and Systems class was not conducted, students were specifically asked in the end-of-semester evaluations: What about the Signals & Systems micro-outcome tagging and online notes website did you find to be helpful or not helpful? Student responses were overwhelmingly positive with comments such as

I liked the modular format that allowed you to quickly find the topic you wanted to study.

It is so helpful!! I wish other classes had this as well. It is such an organized system to access information that I would otherwise probably google because it is faster than flipping through textbooks.

It broke down the material into sections, making it easy to go back and learn the material.

Micro-outcome tagging was a good way of figuring out where I was weak in specifically and address it.

The notes and structure of outcomes were very helpful, as I was able to separate out each subject in the class and learn it well.

These comments, while qualitative in nature, indicate that the students appreciated the structure brought by the network model and they used the lecture notes in anticipated ways (e.g., for exam review and self-identifying weaknesses). Site analytics also indicated a spike in usage around midterm and final exam times. Finally, discussions with students indicated that they used the site extensively as a reference during their follow-on junior-level controls class.

5. Discussion

The case studies presented here were chosen to highlight the flexibility and broad applicability of the proposed modelling approach, as well as the practical considerations of having access to instructors and instructional materials. For the community college subjects, the network model and sensor layer formed the foundations for an intelligent teacher assistant system to be used in real-time in the classroom setting. In contrast, the Signal and Systems example illustrated how the network model and sensor layer were used to underpin course planning and teaching improvement to be used over the course of a semester. In both cases, the combination of the network model and sensor layer enable dynamic data-driven feedback to the instructor. Rather than wait for the end-of-semester student evaluations, the instructors are able to dynamically assess student learning and the effectiveness of learning resources, and then adjust accordingly.

For the case studies presented here, the graphs were constructed manually using instructors’ first-hand knowledge of the subjects. The human process of creating such a large network graph is time-consuming and may be prone to errors and subjectivity. An alternative is to use an automatic generation process, as has been done in the knowledge graph literature. For example, Wang et al. (Reference Wang, Liang, Wu, Williams, Pursel, Brautigam, Saul, Williams, Bowen and Giles2015) extracts concepts hierarchies from the textbooks using an optimisation approach that considers both global and local features. Another example is the KnowEdu system, which uses a neural sequence labeling algorithm to automatically extract educational concepts and the relationships among them (Chen et al. Reference Chen, Lu, Zheng, Chen and Yang2018). Combining our mathematical modelling approach with automated knowledge graph extraction is an important and fruitful area of future work.

6. Conclusion

This paper has presented an approach for modelling fine-grained learning objectives (Micro-outcomes), their organisational entities, and organisational and prerequisite relationships in a network model, and then designing a sensor layer of high-resolution Assessments and Trackers on top of the base network map. The resulting map is a structured graph with high-resolution Assessments that provide high-fidelity sensing of a learner’s state on the map. The high-resolution nature of the model enables adaptive learning systems, intelligent tutoring systems, and other forms of learning analytics. The examples presented in this paper showcase only two applications possible with the base network map and accompanying sensors. Many other applications, particularly for adaptive learning systems and learning analytics, can leverage this scalable modelling approach.

An outstanding challenge is that articulating such fine-grained statements of learning outcomes and constructing valid assessments require domain expertise and much time. However, we note that if the resulting data is stored in a technology stack that is platform-independent and is accessible via APIs, the data are easily maintained and can be scaled to many other applications. Our APIsFootnote 3 are one example of such a technology stack.

Acknowledgements

This work was funded in part by the SUTD-MIT International Design Center and the U.S. Department of Education under the First in the World programme grant P116F150045. However, those contents do not necessarily represent the policy of the U.S. Department of Education, and you should not assume endorsement by the Federal Government.

References

Ahmed, F. & Fuge, M. 2018 Creative exploration using topic-based bisociative networks. Design Science 4, e12.CrossRefGoogle Scholar
Aleven, V., McLaren, B. M. & Koedinger, K. R. 2010 Automated, unobtrusive, action-by-action assessment of self-regulation during learning with an intelligent tutoring system. Educational Psychologist 45 (4), 224233.CrossRefGoogle Scholar
Alstott, J., Triulzi, G., Yan, B. & Luo, J. 2017 Inventors’ explorations across technology domains. Design Science 3, e20.CrossRefGoogle Scholar
Alstott, J., Triulzi, G., Yan, B. & Luo, J. 2017 Mapping technology space by normalizing patent networks. Scientometrics 110 (1), 443479.CrossRefGoogle Scholar
Arafeh, S. 2016 Curriculum mapping in higher education: A case study and proposed content scope and sequence mapping tool. Journal of Further and Higher Education 40 (5), 585611.CrossRefGoogle Scholar
Battou, A., Mezouary, C., Cherkaoui, C. & Mammass, D. 2011 Towards an adaptive learning system architecture based on a granular learning object framework. International Journal of Computer Applications 32 (5), 1827.Google Scholar
Cavanagh, T., Chen, B., Lahcen, R. A. M. & Paradiso, J. R. 2020 Constructing a design framework and pedagogical approach for adaptive learning in higher education: A practitioner’s perspective. The International Review of Research in Open and Distance Learning 21 (1), 173197.CrossRefGoogle Scholar
Chen, P., Lu, Y., Zheng, V. W., Chen, X. & Yang, B. 2018 Knowedu: A system to construct knowledge graph for education. IEEE Access 6, 3155331563.CrossRefGoogle Scholar
Chen, X., Jia, S. & Xiang, Y. 2020 A review: Knowledge reasoning over knowledge graph. Expert Systems with Applications 141, 112948.CrossRefGoogle Scholar
Collins, J., Greer, J. & Huang, S. 2005 Adaptive assessment using granularity hierarchies and Bayesian nets. In International Conference on Intelligent Tutoring Systems, pp. 569–577.Google Scholar
Corbett, A. & Anderson, J. R. 1994 Knowledge tracing: Modeling the acquisition of procedural knowledge. User Modeling and User-Adapted Interaction 4 (4), 253278.CrossRefGoogle Scholar
Ellis, C. 2013 Broadening the scope and increasing the usefulness of learning analytics: The case for assessment analytics. British Journal of Educational Technology 44 (4), 662664.CrossRefGoogle Scholar
Essa, A. 2016 A possible future for next generation adaptive learning systems. Smart Learning Environments 3, 16.CrossRefGoogle Scholar
Falkner, N., Vivian, R. & Falkner, K. 2014 Increasing the effectiveness of automated assessment by increasing marking granularity and feedback units. In SIGCSE’14 Proceedings of the 45th ACM Technical Symposium on Computer Science Education, pp. 9–14.Google Scholar
Fiorella, L. & Mayer, R. 2018 Eight ways to promote generative learning. Educational Measurement: Issues and Practice 28 (4), 717741.Google Scholar
Luo, J., Yan, B. & Wood, K. 2017 Innogps for data-driven exploration of design opportunities and directions: The case of google driverless car project. Journal of Mechanical Design 139 (11), 111416.CrossRefGoogle Scholar
Marion, S. 2018 The opportunities and challenges of a systems approach to assessment. Educational Measurement: Issues and Practice 37 (1), 4548.CrossRefGoogle Scholar
Miller, H., Willcox, K. & Huang, L. 2016 Crosslinks: Improving course connectivity using online open educational resources. The Bridge 46 (3), 3844.Google Scholar
Pardos, Z. A., Heffernan, N. T., Anderson, B. S. & Heffernan, C. L. 2006 Using fine-grained skill models to fit student performance with Bayesian networks. In Workshop in Educational Data Mining held at the Eight International Conference on Intelligent Tutoring Systems.Google Scholar
Popham, W. J. 2006 All about accountability / grain size: The unresolved riddle. Educational Leadership 64 (8), 8081.Google Scholar
Reimann, P., Kickmeier-Rust, M. & Albert, D. 2006 Problem solving learning environments and assessment: A knowledge space theory approach. Computers & Education 64, 183193.CrossRefGoogle Scholar
Seering, J., Willcox, K. & Huang, L. 2015 Mapping outcomes in an undergraduate aerospace engineering program. In Proceedings of the American Society for Engineering Education 12th Annual Conference & Exposition, Seattle, WA.Google Scholar
Shepard, L. A., Penuel, W. R. & Pellegrino, J. W. 2018 Using learning and motivation theories to coherently link formative assessment, grading practices, and large-scale assessment. Educational Measurement: Issues & Practice 37 (1), 2134.CrossRefGoogle Scholar
Song, B., Srinivasan, V. & Luo, J. 2017 Patent stimuli search and its influence on ideation outcomes. Design Science 3, e25.CrossRefGoogle Scholar
Song, B., Yan, B., Triulzi, G., Alstott, J. & Luo, J. 2019 Overlay technology space map for analyzing design knowledge base of a technology domain: The case of hybrid electric vehicles. Research in Engineering Design 30 (3), 405423.CrossRefGoogle Scholar
Thompson, K. & Yonekura, F. 2018 Practical guidelines for learning object granularity from one higher education setting. Interdisciplinary Journal of Knowledge and Learning Objects 37 (1), 2134.Google Scholar
Wang, S., Liang, C., Wu, Z., Williams, K., Pursel, B., Brautigam, B., Saul, S., Williams, H., Bowen, K. & Giles, C. L. 2015 Concept hierarchy extraction from textbooks. In Proceedings of the 2015 ACM Symposium on Document Engineering, pp. 147–156.Google Scholar
Willcox, K. E. & Huang, L. 2017 Network models for mapping educational data. Design Science 3, e18.CrossRefGoogle Scholar
Yang, F., Li, F. W. B. & Lau, R. 2017 A fine-grained outcome-based learning path model. IEEE Transactions on Systems, Man, and Cybernetics 44 (2), 235245.CrossRefGoogle Scholar
Figure 0

Table 1. A typical learning outcome contrasted with high-granularity Micro-outcomes

Figure 1

Figure 1. Schematic showing nodes (entities) and edges (relationships) in base network model.

Figure 2

Figure 2. Assessments (left) and Trackers (right) act as sensors for inferring learner state relative to a Micro-outcome.

Figure 3

Figure 3. The ‘Inverse Functions’ Module and some of its Micro-outcomes in College Algebra. Highlighted outcome is again shown in Figure 5. Note: most has-parent-of relationships to ‘Inverse Functions’ have been omitted in the figure for clarity.

Figure 4

Table 2. Summary dimensions of the maps and sensor layers of College Algebra and Introductory Accounting

Figure 5

Figure 4. Schematic showing how a multiple-choice Assessment with incorrect options is linked to prerequisite Micro-outcomes.

Figure 6

Figure 5. A screenshot from our technology of a multiple-choice Assessment for College Algebra with incorrect options (b, c and d) linked to their respective Micro-outcomes.

Figure 7

Figure 6. The Fly-by-Wire Student App delivers multiple-choice questions designed as sensors to infer student state on the network of Micro-outcomes.

Figure 8

Figure 7. The Fly-by-Wire Instructor App assimilates sensor data and highlights the directed acyclic graph of the Micro-outcomes with which most students had difficulty.

Figure 9

Table 3. Properties of the network model for the subject Signals and Systems as taught in the aerospace engineering undergraduate degree programme at the Massachusetts Institute of Technology in Fall 2017

Figure 10

Figure 8. A visualisation of the map of the subject Signals and Systems as taught in the aerospace engineering undergraduate degree program at the Massachusetts Institute of Technology in Fall 2017.

Figure 11

Figure 9. The map is used to create a web application that enables searching of Micro-outcomes, arranged by Module and linked to Content pages.

Figure 12

Figure 10. The network map can also be browsed in a ‘map view’ in which nodes are Micro-outcomes, are clickable, and bring the learner to a specific piece of Content.

Figure 13

Figure 11. Interaction pathway of a single student session. The student first visits the List View, clicks to two Micro-outcomes (#1 and #2), then visits Micro-outcome #3, and finally goes back to Micro-outcome #1.