Identifying Gaps in Use of and Research on Adaptive Learning

Systems

Shuai Wang

1,* a

, Claire Christensen

1,*

, Elizabeth McBride

1,* b

, Hannah Kelly

, Wei Cui

Richard Tong

, Linda Shear

, Louise Yarnall

and Mingyu Feng

SRI Education, SRI International, 1100 Wilson Blvd., Suite 2800, Arlington, VA 22209, U.S.A.

Squirrel AI Learning by Yixue Education Group, 39 Hongcao Road, Shanghai, China

WestEd, 730 Harrison Street, San Francisco, California 94107, U.S.A.

{cuiwei, Richard}@songshuai.com, mfeng@wested.org

Keywords: Adaptive Learning, Algorithms, Artificial Intelligence, Efficacy Studies, Literature Review.

Abstract: Adaptive learning systems have become increasingly common across age groups and content areas. Many

adaptive learning systems personalize the learning experience based on students’ prior knowledge,

preferences, learner profile, system usage, learning style, and/or learning perceptions. In addition, various

learning algorithms have been developed over the years, such as item response theories, Markov modelling,

recurrent neural networks, and Bayesian knowledge tracing (BKT). Although western countries have

generated numerous efficacy studies, Chinese adaptive education is in its earliest stage, with few efficacy

studies conducted in this context, which is a gap in this field. This position paper describes one Chinese

adaptive learning system, Squirrel AI Learning, and invites further research on adaptive learning systems in

China and other Asian countries.

1 INTRODUCTION

Adaptive learning systems have become increasingly

more popular across age groups and content areas. As

adaptive learning system use has grown, so too has

research on their efficacy for learning. This paper

details gaps in the research and in the use of adaptive

learning systems. After discussing adaptive learning

systems in general, we address a case study on

Squirrel AI Learning in greater depth.

Adaptive learning systems use comprehensive

data analytics and machine-learning algorithms to

provide individualized, computer-based learning

experiences. Many adaptive learning systems

personalize the learning experience based on

students’ prior knowledge, preferences, learner

profile, system usage, learning style, and/or learning

perceptions (Nakic et al., 2015; Xie et al., 2019). As

students spend more time in the system, the system

may develop a more detailed understanding of

https://orcid.org/0000-0002-4983-9558

https://orcid.org/0000-0002-0168-5705

https://orcid.org/0000-0001-9635-1611

Sam Wang, Claire Christensen, and Elizabeth McBride contributed to the study equally.

students’ needs and preferences, resulting in greater

personalization (Hauger & Köck, 2007; Van Seters et

al., 2012). Aspects of the system that may be

personalized vary, but often include the learning

sequence, item difficulty, and learning supports

provided.

For many years, computer scientists and cognitive

scientists have developed adaptive learning systems

that use artificial intelligence to mimic the

interactions of one-on-one human tutoring (Merrill,

Reiser, Ranney, & Trafton, 1992). Developers have

created systems that present content, pose questions,

assign tasks, provide hints, answer questions, and

suggest improvements to learners based on their prior

behaviors (Ma, Adesope, Nesbit, & Liu, 2014).

Adaptive learning systems follow a similar “closed

loop” architecture that gathers data from the learner

and then uses that data to estimate the learner’s

progress, recommend activities, gives hints, or

provides tailored feedback. The adaptive system’s

algorithms typically make such decisions by referring

118

Wang, S., Christensen, C., McBride, E., Kelly, H., Cui, W., Tong, R., Shear, L., Yarnall, L. and Feng, M.

Identifying Gaps in Use of and Research on Adaptive Learning Systems.

DOI: 10.5220/0009590701180124

In Proceedings of the 12th International Conference on Computer Supported Education (CSEDU 2020) - Volume 1, pages 118-124

ISBN: 978-989-758-417-6

to a domain model of the knowledge to be learned, a

student model of learners’ background characteristics

(knowledge level, affect, and motivation), and a task

model that specifies features of the learning activities

(e.g., questions, tasks, quizzes, dynamic hints,

feedback, prompts, and recommendations) (Lee &

Park, 2008).

Adaptive learning systems utilize various

algorithms, such as item response theories, Markov

modelling, recurrent neural networks, Bayesian

knowledge tracing (BKT), natural language

processing, and other machine learning models to

personalize the learning sequence for each student.

This personalization is based on system-generated

student profiles, informed by a students’ performance

on an initial knowledge diagnostic and continuously

updated with student usage data and learning

behaviors. As students spend more time in the system,

their learning profiles become more accurate and

allow for greater personalization (Hauger & Köck,

2007; Van Seters et al., 2012).

Historically, adaptive learning systems utilize

different models for estimating a learner’s level of

domain knowledge. Some focus on how well learners

implement core steps in tasks (Koedinger, Anderson,

Hadley, & Mark, 1997); some examine learners’

problem-solving behaviors and compare them to

models of both correct and incorrect behaviors

(Aleven, McLaren, Sewall, & Koedinger, 2009);

others present specific problem-solving situations

and check for common errors (Mitrovic, 2012;

Ohlsson, 1992). Some use natural language

processing to measure how well learners articulate

common learning goals or misconceptions (Graesser,

VanLehn, Rose, Jordan, Harter, 2001), while still

others model a learners’ understanding at each point

of interaction (Piech et al, 2015; Yudelson,

Koedinger & Gordon, 2013).

Often, the content area being assessed is linked to

the requirements for the algorithm that is used. For

example, in content areas where knowledge

components can be clearly distinguished, as in

algebra, a model like Bayesian knowledge tracing

may work well for modelling student behaviour and

providing guidance for learning. However, in a

content area, like English, where writing a coherent

argument is important, natural language processing is

an important algorithm to include. Use of knowledge

components is also a common metric used to trace

student understanding in adaptive learning systems.

A knowledge component is a description of a mental

structure a student uses to accomplish steps in a

problem or task (Koedinger, Corbett, & Perfetti,

2012). A knowledge component relates features of a

question or task to a response given by a student.

2 EFFICACY RESEARCH

Efficacy studies from the past 6 years have shown

that the use of adaptive learning systems is associated

with greater gains in student learning. Across several

different types of studies, including a review of 37

adaptive learning efficacy studies, a comparative

study of 1,600 adaptive and 4,800 non-adaptive

courses, and a large-scale randomized control trial in

algebra classrooms, researchers report positive

findings when they compare students who use

adaptive learning systems in academic contexts to

those who do not. In two studies that involved the

implementation of adaptive learning systems in

mathematics instruction, students’ scores on

proficiency exams were 8 and 3 percentile points

higher, respectively, than the scores of their peers

who did not use the learning system (Bomash & Kish,

2015; Pane et al., 2014, 2017).

Despite these promising findings, we know

relatively little about for whom and in what contexts

adaptive learning systems are most effective. Below

we provide an overview of the relevant literature to

date and highlight areas for future research and

development.

2.1 Learner Characteristics

Adaptive learning systems have potential to promote

equity in education by responding to diverse learners’

needs in ways that may not be feasible for teachers in

traditional classroom instruction. We call for more

research on subgroup effects to evaluate whether and

how adaptive learning realizes this promise. Do

adaptive learning systems work equally well for all

learners? Or are they better suited for a particular

level of prior knowledge, socioeconomic status,

gender, or age range?

Researchers have begun to explore the differential

impacts of prior knowledge on students’ learning

from adaptive learning systems. Many adaptive

learning systems personalize the learning experience

based on prior knowledge (Nakic et al., 2015), as

students with different prior knowledge may benefit

from different instructional features (Ayres, 2006;

Flores et al., 2012). For example, to avoid cognitive

overload in learners with less prior knowledge,

adaptive learning systems may tailor worked

examples or the degree of learner autonomy (Lee et

al., 2008; McNeill et al., 2006; Salden et al., 2009;

Identifying Gaps in Use of and Research on Adaptive Learning Systems

119

Scheiter et al., 2007). Some evidence suggests that

such adaptations can be effective: some studies have

found that adaptive learning is able to help students

with less prior knowledge achieve similar outcomes

to students with more prior knowledge (Jones, 2018;

Wang et al., 2019). More research is needed to

demonstrate which adaptive learning algorithms and

features are best suited to addressing the needs of

learners with varying prior knowledge.

In addition to adapting to differences in prior

knowledge, adaptive learning may also have potential

to address equity gaps that affect historically

underserved populations, such as students from lower

socioeconomic-status (SES) families. These students

tend to report lower academic participation and

academic achievement on math and reading

assessments (Dahl & Lochner, 2012; Willms, 2003).

Initial research suggests that such students may

benefit from adaptive learning systems in academic

settings. A study by Yarnall and colleagues (2016)

assessed 2-year and 4-year college students’

impressions of adaptive learning systems in higher

education and found that 2-year college students, who

are more likely to be lower SES, rate adaptive

learning systems more favourably. More of these

students also reported positive learning gains than

their 4-year institution peers. In two cases reported in

this study, Pell grant students showed similar positive

learning outcomes associated with using adaptive

courseware to those reported for the general

population. More research is needed to explore

adaptive learning systems’ promise with lower SES

students, and to elucidate the most effective

adaptations for this population, such as those that

address prior knowledge gaps and learner motivation.

More research is needed on the efficacy of

adaptive learning systems for K–12 students. Most

adaptive learning efficacy studies are conducted with

higher education students. A systematic review of 70

articles on adaptive and personalized learning

published from 2007 to 2017 found that the largest

share, 46%, included higher education students. Less

than half that, 21% of studies, included elementary

students, and only 9% included middle and high

school students (Xie et al., 2019). While K–12

efficacy studies in adaptive learning are less common,

some suggest adaptive learning can be effective for

elementary students (Mettler et al., 2011) and middle

school students (Feng et al., 2018).

2.2 Content Areas and Features

A systematic review of 70 articles on personalized

and adaptive learning found that many studies are

conducted in certain content areas, while in others

there have been few studies. Xie (et al, 2019) report

that the most studies are conducted in engineering and

computer science, followed by languages,

mathematics, and science. Content areas like health

(medical/nursing), social science, art/design, and

business management have few or no efficacy studies

using adaptive learning systems. While there is a

larger proportion of research conducted on adaptive

learning systems in more traditional school content

areas (e.g., math and science), there is little research

done on adaptive learning systems in content areas

that are more commonly found in college courses or

professional training (e.g., health/medical/nursing).

This is consistent with prior studies (e.g. Alexander,

Rose, & Woodhead, 1992) that discussed the limited

domain knowledge of researchers who developed

adaptive learning products.

In addition, Xie (et al, 2019) report on the types of

learning supports provided by adaptive learning

systems. Personalized learning content is the most

common feature, followed by personalized learning

paths, personalized interfaces, personalized diagnosis

and suggestions, personalized recommendations, and

personalized prompts or feedback. While many of

these personalization features have been studied in

some way, a meta-analysis of their impact on student

learning has not been conducted. Since adaptive

learning systems rarely contain only one way of using

personalization, a meta-analysis of these features is

particularly necessary as it will provide insight into

design features for these systems. However, due to

the large range of learner populations, content areas,

and system features contained under the adaptive

learning systems umbrella, many more studies on

efficacy must be conducted.

2.3 Outcomes

As mentioned previously, adaptive learning has been

shown to have significant positive impacts on

learning outcomes. More research is needed to

explore how effects vary by outcome. For instance,

consistent with prior studies (Brookhart, 2020;

White, 1993), Xie (et al, 2019) have found that

positive effects of adaptive learning are more likely

to be reported on student affect than on student

cognition More research is needed to distinguish

which learning metrics are most sensitive to adaptive

learning-related change. While some studies measure

academic outcomes solely via in-system performance

(Bomash & Kish, 2015; Jones, 2018), others have

examined adaptive learning’s effects on external

metrics.

CSEDU 2020 - 12th International Conference on Computer Supported Education

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Test scores and assessments are some of the most

common external metrics that researchers use to

assess the efficacy of adaptive learning systems.

Studies that measure student outcomes on

assessments have shown mixed, though mostly

positive, effects (Fullerton & Hughes, 2016; Yarnall

et al., 2016). A review of six studies found that the

use of adaptive learning systems in various

environments (upper elementary through the

workplace) related to positive effects on students’

course test achievement (Durlach & Ray, 2011). An

important feature of the adaptive learning systems in

these studies that may have contributed to the positive

results is mastery-based progression, which requires

students to demonstrate their knowledge before

advancing. Another study review by Yarnall and

colleagues (2016) reported that while it positively

impacted students’ scores on course tests, the use of

adaptive courseware did not have significant effects

on course grades or completion rates.

3 GLOBAL SPREAD

Adaptive learning systems are increasingly common

in western culture, including the United States,

United Kingdom, and other regions. Some well-

known products already on the market for learners

and educators include Knewton (Wilson & Nichols,

2015), ASSISTments (Heffernan & Heffernan,

2014), ALEKS (Canfield, 2001), i-Ready,

Achieve3000, Carnegie Learning, Norton, Kidaptive,

and DreamBox Learning. Accordingly, many

efficacy studies of adaptive learning systems have

been only conducted in western countries (e.g., Griff

& Matter, 2013; Mettler et al., 2011; Sun et al., 2017).

Meanwhile, in mainland China, adaptive learning

systems are only just beginning to gain popularity,

even though 19% of all Chinese Internet users have

engaged in online education in recent years (China

Internet Network Information Center, 2017). While

adaptive learning is relatively new in mainland China,

it is a Chinese education policy priority (O’Meara,

2019).

3.1 Squirrel AI Learning

Squirrel AI Learning is considered the first

commercial adaptive learning system in mainland

China. Since its establishment in 2016, Squirrel AI

Learning has expanded to serve almost 2 million

registered accounts in over 700 cities. These 2 million

users are diverse in socioeconomic status, urbanicity,

and academic achievement. In addition to this user

base, Squirrel AI Learning has opened over 2,000

learning centers in less than 5 years. This rapid

expansion is indicative of the gap that adaptive

learning fills in the Chinese after-school tutoring

market.

In particular, during the coronavirus outbreak in

2020, Squirrel AI Learning is considered an

important supplement for student learning while

students are required to stay at home and schools are

closed in almost all provinces in China. Because of

their potential to reach so many students, research is

needed to ensure that such learning systems truly

support student learning in China and possibly in

other countries of Asia.

3.2 Squirrel AI Learning Features

Squirrel AI Learning provides instructions and

supports for K–12 students and has the following

features:

1. Nanoscale Knowledge Components.

Squirrel AI Learning breaks down

knowledge components into a fine-grained

knowledge map with knowledge

components organized hierarchically based

on the following: relationship to learning

progression; adaptive diagnostic pre-

assessment; automated differentiated

instruction; rich, high-quality learning

repository of various types of learning

content; immediate feedback and

explanations to students and in-class support

and intervention by teachers. For example,

in junior high school mathematics, 300

knowledge components are dissolved into

30,000 fine-grained knowledge

components, and each knowledge

component is matched with the learning

content. This content may include text items,

animation, slides, short instructional videos,

etc. A parent knowledge component can be

resolved into sub-knowledge components

that are more specific and targeted. See

figure 1 for an example of the Squirrel AI

Learning system, where students receive

popup explanations if their attempts are

incorrect; students can choose to view video

or text explanations.

2. Integration of Various Learning

Algorithms. Squirrel AI Learning uses

more than 10 learning algorithm

technologies, including Clustering

algorithm, such as k-means and expectation

maximization (EM), logistic regression,

Identifying Gaps in Use of and Research on Adaptive Learning Systems

121

Item Response Theory, graph theory,

probabilistic graph model, Bayesian

network, knowledge space theory,

information theory, source tracing model,

knowledge tracking theory, learning

analysis technology, and so on. The

algorithms help to identify students'

weaknesses in current knowledge by tracing

the pre-requisite knowledge components of

their current learning content. The

algorithms determine the recommendation

priority of each knowledge component from

three aspects: whether the pre-requisite

knowledge component is easy to learn,

whether its map position is relatively

backward, and its central degree. This

layered process of identifying student

weaknesses creates a solid foundation to

effectively promote the learning of current

and future knowledge components.

3. MCM Model (Methodology, Capacity,

and Mode of Thinking). Squirrel AI

Learning splits MCM into nanoscale just

like the knowledge components, and the

ambiguous and incomprehensible

capabilities are split into nanoscale

capabilities that can be clearly defined. In

this way, Squirrel AI Learning can measure

the level of a student's capabilities and

represent his capabilities quantitatively. At

the same time, Squirrel AI Learning ensures

that the capabilities can not only be clearly

explained by teachers but also understood

and digested by students. MCM are curated

and summarized; for example, in middle

school mathematics, 500 components

subdivide into 1,000 application scenarios to

make them completely definable,

measurable and teachable. Squirrel AI

Learning can identify and quantify the

capabilities that individuals possess and the

capabilities that they need to improve, such

as those of a lawyer who is excellent in

pattern exploration skills and summarization

skills yet lacks the skills needed for

analyzing 3D graphics, algorithm

construction, and realization. In contrast to

the lawyer, a scientist may be excellent at

data analysis but poor in linguistic

association skills. In Squirrel AI Learning,

the users’ behavior is taken automatically

into account by the algorithm parameters.

However, in the initial phase, some of the

parameters are set according to experts’

experience. For example, the item difficulty

is set according to experts’ experience if the

number of data samples is less than 25.

When the number of data samples is more

than 25, the item difficulty is computed by

machine learning algorithms.

Figure 1: Screenshot of Squirrel AI Learning system.

Note. The question is on the upper left of the white

window. The

choices are on the right side of the

white window. When students answer the question

incorrectly, the system gives explanations at the

bottom of the white window. The next question is

dependent on the correctness and difficulty level of

the current question.

3.3 Squirrel AI Learning Efficacy

Multiple efficacy studies have shown that the Squirrel

AI Learning platform:

 Improves learning efficiency and students’

perceptions of the learning experience, as

compared to other learning platforms (Li,

Cui, Xu, Zhu, & Feng, 2018)

 Is associated with greater improvements in

test scores compared with whole-classroom

instruction or small-group tutoring (Feng et

al. 2018; Wang, Christensen, Cui, Tong,

Yarnall, Shear, & Feng, submitted). This

builds upon a review finding that contrary to

popular belief, intelligent tutoring is nearly

as effective as human tutoring (VanLehn,

2011).

 Is associated with similar gain scores

regardless of students’ prior knowledge

(Wang, Feng, Bienkowski, Christensen, &

Cui, 2019).

However, the sample sizes for these studies were

not large, the topics covered in these studies were

limited, and the interventions of these programs were

short-term, e.g. in a couple of days. Future studies

CSEDU 2020 - 12th International Conference on Computer Supported Education

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examining Chinese adaptive learning efficacies in

different contexts are highly needed.

4 CONCLUSIONS

Adaptive learning systems have become more widely

used in the last 2 decades and are only becoming more

widely used with each passing year. The ubiquity of

adaptive learning systems demands wide-reaching

studies on their efficacy. Many current efficacy

studies apply adaptive learning systems in higher

education and in traditional academic subjects (math,

science, languages). Further efforts are still needed to

determine which outcome metrics are both useful and

aligned with the use of adaptive learning systems.

Further, more research is needed to address how these

adaptive learning systems might address issues of

equity or otherwise impact lower- SES students.

One additional gap in the research is in study

geography. Many efficacy studies using adaptive

learning systems take place in either the United States

or the United Kingdom. With the potential to impact

many students worldwide, efficacy studies must be

undertaken in a wider variety of contexts. We

discussed one such case, Squirrel AI Learning, a

commercial adaptive learning system in mainland

China. However, efficacy studies on Squirrel AI

Learning have included limited numbers of

participants and a limited range of subject areas.

Efficacy studies of different contexts need to be

conducted. More importantly, as new technological

and pedagogical approaches continue to evolve, more

efficacy studies are needed in Asia and worldwide in

the future, and we invite more scholars to continue

research in the adaptive learning systems field.

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