naidu


 

 
Australian Journal of  
Educational Technology 
 
Definitions of instructional control in learning 
environments 
 

Som Naidu, PhD 
University of Southern Queensland 

 
A fundamental question in the design of learning environments is 
determining the nature of instructional control which will facilitate optimal 
learning outcomes. The assumptions that increased control in the hands of 
learners will produce enhanced learning outcomes is untenable. This short 
paper reviews a select body of research with varying types and levels of 
control in learning environments and presents a summary of operational 
definitions of control applied in those studies. Analysis of these definitions 
revealed variations in the amount of control allowed which is most 
meaningful if represented on a continuum ranging from maximum 
program control on the one hand, to maximum learner control on the other. 
The impacts of control in learning environments is briefly discussed. 

 
Locus of instructional control in learning environments whether CAI 
(computer-assisted instruction) or CAVI (computer-assisted video 
instruction) may range from maximal program control on the one hand to 
maximal learner control on the other. Program control refers to a learning 
environment in which the selection and sequence of instructional stimuli 
are made without strategy inputs from the learner, while learner control 
refers to one where the learner is responsible for the learning strategy. The 
condition in which there is maximal or complete learner control of 
everything (ie., learner control) has been described by Snow (1980) as the 
'Adult Scholar Model'; and one where the learner has virtually no control 
(ie., program control) as 'Child Robot Model'. In the former the learner 
commands complete independence and self direction while in the latter 
he/she is subjected to fixed tasks, a fixed pace, and no remediation. 
 
 
 
 
 



Naidu 13 

As it is now clear that each learner and learning context is different and 
that learners will always differ in their preferences for self-control, and 
also to the extent that they may be able to exercise it effectively for their 
own benefit, the program/learner control dichotomy in the design and 
arrangement of learning environments is far from adequate. The 
assumption that all learners know what is best for themselves at any given 
moment in an instructional sequence, and that all are capable of acting on 
this knowledge is untenable, at least for many learners (Snow, 1980). The 
current feeling is that one can perhaps give control to all of the learners 
some of the time, and to some of the learners all of the time, but one 
should probably not give control to all of the learners all of the time. A 
fundamental instructional design question is to determine what kind of 
control should be given and when. 
 
Recent research has identified the existence of a whole range of 
possibilities in the arrangement of learning environments with varying 
degrees of learner and program control so much so that instructional 
control in learning environments is now represented more fully and 
appropriately as a continuum varying or ranging from maximum program 
control on the one hand to maximum learner control on the other. Between 
the two there is a range of variations, each recognisable by its placement 
on the continuum. 
 
The choice of the nature and degree of control in instruction is the net 
result of a variety of factors pertaining to the learner, the learning 
environment, and the subject matter being learned. As learners, learning 
environments, and subject matter become more complex, the design and 
arrangement of learning environments have become equally complex. The 
accompanying chart is a summary of recent research on instructional 
control in learning environments. It is intended to show: a) how various 
researchers and authors have defined locus of instructional control, and b) 
the nature of the overlap. 
 
Summary comment 
 
Two issues arising from the above chart are worth further comment. First, 
clearly there is general concurrence amongst those cited on the existence of 
degrees of instructional control in the arrangement of learning 
environments ranging from program controlled to learner controlled, and 
with variations in between. The terminology is not quite the same but the 
meaning is similar. 
 
 
 
 



14 Australian Journal of Educational Technology, 1995, 11(1) 

Source Definition 
 Program Control   Learner Control 
Holmes, 
Robson & 
Steward 
(1985) 

Frame displays 
and selections 
made by the 
computer 
program. 

  Students have 
pre-instructional 
advice on self-
estimation of 
comprehension 
and decision 
making process 
on selection of 
next frame. 

 Program Control Lecture Non-Adaptive Learner Control 
Ross & 
Rakow 
(1981) 

Examples 
adapted to 
subjects' pretest 
scores. Prescri-
ptions varied 
according to 
subjects' scores. 

Students could 
attend either one 
of two lecture 
presentations. 

Five examples 
selected per rule 
considered as 
optimum. 

Examples 
selected by 
subjects who 
could ask for 
more. 

 Program Control   Learner Control 
Gay (1986) Computer con-

trolled present-
ation of concepts 
in hierarchical 
form with 
remediation and 
review. Student 
controlled pace. 

  Student control 
of pace, 
sequence, depth, 
amount of 
practice, mode 
of presentation 
and type of 
content. 

  Forced Group: Yoked Control Learner Control 
Judd (1972)  Forced Group: 

directed through 
sequence dictat-
ed by task analy-
sis of subject 
matter. 

Members paired 
with learner 
control group. 

Determined 
their own 
sequence 
through the 
materials. 

 Program Control   Learner Control 
Judd (1972) Learners 

proceed through 
fix-ed, optimally 
ordered 
sequence. 

  Student control 
over sequence 
and selection of 
materials. 

 Program Control   Learner Control 
Judd (1972) Order of 

presentation 
fixed in an 
assumed 
optimal order 
for all 
treatments. 

  Instructional 
decisions based 
on learner's 
ability to do self-
evaluation. 



Naidu 15 

 Program Control  

Learner Control 
with Memory 
Support Learner Control 

Judd (1972) No access to 
memory sup-
port. (Control 
group 1). 

 Previous stimuli 
and their correct 
classifications 
displayed on 
request. 

Memory Supp-
ort always pre-
sented. (Control 
group 2). 

 Program Control   Student Control 
Laurillard 
(1984) 

Designer 
determined 
route; a subset of 
many possible 
routes. 

  Interface that 
allows students 
free access to 
materials at any 
time, in any 
sequence. 

 Yoked  Choice Control  
Fisher & 
Blackwell 
(1975) 

No choice of 
problem. Same 
amount of time 
allowed as in the 
choice group. 

 Selected their 
own problems 
from CAI. Time 
taken (within 
limits). 

 

 Program Control  Adaptive Control Learner Control 
Tennyson, 
Robert & 
Rothen 
(1979) 

Selection and 
sequence made 
without learner 
input. 

 Anon-line algor-
ithm adjusts the 
learning envir-
onment to indiv-
idual learners or 
on-task error 
patterns. 

Learners resp-
onsible for learn-
ing strategy. 
Learners made 
decisions about 
their own 
learning. 

  Adaptive Control Strategy  
Learner Control 
Strategy 

Tennyson, 
Tennyson, 
& 
Wolfgang 
(1980) 

 Regulated by 
MAIS: - selects 
number of inst-
ances presented 
to learners based 
on pre-task and 
on-task perform-
ance - learners 
not told how 
program opera-
ted: advised of 
posttest. 

 Learners decide 
whether or not 
to continue 
receiving 
instances or go 
to posttest. 

 Adaptive Control  
Learner-Adaptive 
Control Learner Control 

Tennyson 
(1980) 

No student 
control: 
examples 
presented in 
rational sets. 

 Student control 
of amount and 
sequence. Advis-
ement on diagn-
osis and 
prescription. 

Student control 
of amount and 
sequence: pres-
ented concepts 
presented 
separately. 



16 Australian Journal of Educational Technology, 1995, 11(1) 

 Adaptive Control  

Learner Control 
with or without 
advisement Learner Control 

Tennyson 
& Buttery 
(1980) 

Number of 
presentations 
based on pretask 
and on-task 
performance. 
Sequence 
determined by 
response 
pattern. Program 
directions given. 

 With: Advice on 
amount of 
examples 
necessary.  
Without: No 
advice on 
progress or 
diagnostic help. 

Students decide 
whether or not 
to continue gett-
ing examples or 
go to posttest 
informed of pro-
gram directions 
and had control 
of amount and 
sequence. 

 External Locus of Control   
Internal Locus of 
Control 

Hannafin 
(1984) 

Learners follow 
a predetermined 
path: no indivi-
dual judgement 
as to its approp-
riateness. 

  Individuals con-
trol path, pace 
and contingen-
cies of instruct-
ion by specifying 
choices from 
among a range 
of options 
presented by 
designer. 

 Linear Control  Adaptive Control 
Learner Control 
with advisement 

Goetzfried 
& 
Hannafin 
(1985) 

Sequence same 
as Learner 
Control with 
Advisement, but 
no advisement, 
no individual 
control to review 
of select 
examples. No 
externally 
imposed 
decisions based 
on response 
accuracies. 
Students 
controlled pace. 
Followed 
predetermined 
path. 

 Computer 
branched 
students for 
reteaching or 
more examples 
based on 
response 
accuracy. 
Students 
completed full 
lesson. No 
control over 
pacing or 
amount. Mastery 
learning 
principles used. 

Internally 
controlled CAI. 
Students 
continuously 
advised of 
progress and 
permitted to 
determine if 
reteaching or 
examples 
needed. 
Students free to 
move from 
lesson to lesson 
after each 
tutorial session. 

 
 
 
 

    



Naidu 17 

 Linear Control Designer Imposed  Learner Selected 
Hannafin 
& 
Colomaio 
(1987, 1988) 

Students follow 
a linear path 
through the 
lesson. Feedback 
given. No option 
for controlling 
sequence of 
lesson. No 
imposed 
decision for 
remediation 
provided. 

Students 
followed a 
predetermined 
path deemed 
best by experts. 
Given 
knowledge of 
response to 
question: 
branched if 
wrong after 
second incorrect 
attempt, correct 
answer given. 

 Students control-
led path through 
lesson. Given 
advice on reco-
mmended 
sequence, but 
sequence select-
ion was their 
own. Feedback 
provided, option 
to review. Perm-
itted to make 
decisions on des-
igner imposed 
design features. 

 
Program control/ External Locus of Control/ Designer Imposed/ Forced Group/ 
Lecture all referred to learning environments in which learners were 
permitted to exert only minimal influence on the learning exercise. 
Conversely, Learner Control/ Student Control/ Internal Locus of Control/ 
Learner Control with Advisement referred to learning environments in which 
learners were permitted to exercise a much greater influence on their 
learning experience. Adaptive Control refers to arrangements in between in 
which varying degrees of control were incorporated into the instructional 
process. Hannafin and associates (1987, 1988) are responsible for 
introducing yet another category, linear control which is different from 
designer control and refers to environments where the learning path is 
very fixed. Learners enter at one end and proceed through to the other 
with no options for controlling either sequence or remediation. 
 
The second point worth further comment has to do with the subtle 
variations in the definition of each categorisation by different researchers. 
While there is general consensus on the meaning of these, 'learner control' 
for example, is not seen in exactly the same vein by all. Tennyson and 
Buttery (1980) operationalised learner control, quite specifically, as when 
"students decided whether to continue getting examples, and which ones, 
or go on to the post test. Students were informed on program directions 
but had complete control of amount and sequence". On the other hand, for 
Hannafin and Colomaio (1988), learner control was also very specific: 
when "students controlled their sequence through the lesson ...students 
were permitted to make an individual control decision at each point at 
which a designer-imposed decision had been enforced. Students could 
choose the order of video segments. They were advised on recommended 
lesson sequence. They got advice before and after answering embedded 
questions and feedback on results." For her purposes, Gay (1986) defined 
learner control as when her "students had control of pace, sequence, depth, 
or amount of practice, mode of presentation (video, audio, graphics, or 



18 Australian Journal of Educational Technology, 1995, 11(1) 

text), and type of content (rules, key ideas, examples, or practice). Similar 
variations in definitions is true of program control and adaptive control. 
 
In the case of the latter point the variation is somewhat more noticeable. 
Tennyson and Rothen (1979) offer a nice review of various definitions of 
adaptive control. Their own definition of adaptive control, similar to the 
others, refers to "strategies which prescribed the optimal amount of 
instruction necessary to achieve a given objective" (Tennyson & Rothen, 
1977). This variation in the use of terminology is not being pointed out as a 
criticism but rather as a truism in the literature: a truism necessitated by 
the need to operationalise definitions for the purpose of measurement of 
effect. 
 
Existing research on instructional control is limited and critically so in the 
design of CAVI. We are aware that learners will always differ in the 
degree of control they would prefer, and on how well they might be able 
to exercise that control if allowed directly or indirectly. We are also aware 
that learners always exercise some degree of control over their overt and 
covert learning activities during instruction regardless of treatment. Snow 
(1980) has suggested that, bearing the above in mind, instructional 
treatment variables not ostensibly concerned with learner control contrasts 
often have different implications for learner control of these activities. 
Moreover, that the question of research on learner control is too simply 
put if it concerns only whether or not learners are allowed to choose their 
own amounts, sequences, contents, or methods of instruction. The 
arrangement of instructional control ought to be seen in relation to a 
measure of prior individual dispositions (aptitude treatment interaction) 
than only something worthwhile could be said about learning and 
achievement, and instruction. There is a basic research need for a measure 
of differences in prior individual dispositions of learners as this is invariably 
a critical factor in learning achievement (Gary, 1986; Snow, 1980). 
 
References 
 
Fisher, M. D., & Blackwell, L. R. (1975). The effects of student control and 

choice on engagement in a CAI Arithmetic task in low-income schools. 
Journal of Educational Psychology, 67(6), 776-783. 

Gay, G. (1986). Interaction of Learner Control and prior understanding in 
computer-assisted video instruction. Journal of Educational Psychology, 
78(3), 225-227. 

Goetzfried, L., & Hannafin, M. J. (1985). The effect of the locus of CAI 
control strategies on the learning of Mathematics rules. American 
Educational Research Journal, 22(2), 273-278. 

Hannafin, M. J. (1984). Guidelines for using locus of instructional control 
in the design of computer-assisted instruction. Journal of Instructional 
Development, 7(3), 6-9. 



Naidu 19 

Hannafin, M. J., & Colomaio, M. E. (1988). The effects of variations in 
lesson control and practice on learning from interactive video. 
Educational Communication and Technology Journal, 35(4), 203-212. 

Hannafin, M. J. & Colomaio, M. E. (1987). The effects of locus of 
instructional and practice on learning from interactive video. Paper 
presented at the Annual Meeting of the Association of Educational 
Communications and Technology, Atlanta, Georgia. 

Holmes, N., Robson, E. H. & Steward, A. P. (1985). Learner control in 
computer-assisted learning. Journal of Computer-Assisted Learning, 1, 99-
107. 

Judd, W. A. (1972). Learner controlled computer-assisted instruction. 
Paper presented at the International School on Computers in 
Education, Pugnochiusco, Italy. (ERIC Document Number: ED 072 
635). 

Laurillard, D. (1984). Interactive video and the control of learning. 
Educational Technology, 24(6), 7-144. 

Ross, S. M. & Rakow, E. A. (1981). Learner control versus program control 
as adaptive strategies for selection of instructional support on Math 
rules. Journal of Educational Psychology, 73(5), 745-753. 

Snow, R. E. (1980). Aptitude, learner control and adaptive instruction. 
Educational Psychologist, 15(3), 151-158. 

Tennyson, R. D., Robert, D. & Rothen, W. (1979). Management of 
computer-based instruction: design of an adaptive control strategy. 
Journal of Computer-Based Instruction, 5(3) 63-71. 

Tennyson, C. L., Tennyson, R. D. & Wolfgang, R. (1980). Content structure 
and instructional control strategies as design variables in concept 
acquisition. Journal of Educational Psychology, 72 (4), 499-505. 

Tennyson R. D. (1980). Instructional control strategies and content 
structure as design variables in concept acquisition using computer 
based instruction. Journal of Educational Psychology, 72 (4), 525-532. 

Tennyson, R. D. & Buttery, T. (1980). Advisement and management 
strategies as design variables in computer-assisted instruction. 
Educational Communication and Technology Journal, 28 (3), 169-176. 

 
Contributor: Dr Som Naidu lecturers in Instructional Science and 
Technology at the University of Southern Queensland. His research 
interests are in the areas of instructional systems design, human 
performance technology, instructional technology, and open and distance 
learning. Dr Naidu can be contacted at: University of Southern Queensland, 
Distance Education Centre, Queensland, 4350, Australia. Email: 
naidu@usq.edu.au 
 
Please cite as: Naidu, S. (1995). Definitions of instructional control in 
learning environments. Australian Journal of Educational Technology, 11(1), 12-
19. http://www.ascilite.org.au/ajet/ajet11/naidu.html