brown


 

 
 
 
 

Special keyboards for special needs 
 

Ian C. Brown 
City of London Polytechnic 

United Kingdom 
 

This paper stresses the importance of good design at the child-computer 
interface. The Concept Keyboard is discussed as an example of a useful 
input device. It has a touch-sensitive surface overlaid by a rectangular sheet 
of paper. This "overlay" may be designed to meet the requirements of each 
individual program. Examples are given of various applications, including 
a project in which the Concept Keyboard has been used to develop the 
curriculum in environmental studies for children with moderate learning 
difficulties. Nature walks in various environments are simulated and the 
computer is integrated with other indoor and outdoor resources. 

 
The child-computer interface 
 
If a group of educational technologists were to start today and design from a 
scratch a microprocessor-based aid for very young or educationally 
handicapped children, it is most unlikely that they would employ the 
QWERTY keyboard. Yet in the second half of the 1980s this historic device 
remains the most common input medium for microcomputers in schools. 
 
A simplified analysis of the development of computing in general and of 
educational computing in particular, may identify three phases in which the 
main advances have been, in chronological order, in the fields of: 
 
• hardware, 
• software, 
• the user-interface. 
 
Whilst it is true that general progress in computing has been concerned with 
all three of these areas, the main concern of the first generation was to build 
machines of adequate computing power. The next phase was characterised by 
developing software to exploit this computing power. We are now entering 
the phase where the scope and extent of both hardware and software has 
increased tremendously and more attention is being focused on how the 
human user relates to such systems. In the present paper we are concerned 
with the design of the child-computer interface. 
 



68 Australian Journal of Educational Technology, 1987, 3(1) 

In some early applications using the QWERTY keyboard as input device, the 
task of finding and depressing the correct keys presented more problems to 
the handicapped user than the educational objective itself. This made life 
particularly difficult for children with certain types of special needs, such as 
those with poor motor control or slow learners. The QWERTY keyboard did 
not help or invite the child to use it. Instead it often initiated fear and required 
training or practice before it could be used efficiently. 
 
More recently alternative input devices have been developed such as the 
touch-sensitive screen, the mouse, the light pen and the Concept Keyboard 
(Brown, 1985a). 
 
The concept keyboard 
 
The Concept Keyboard is a particularly useful input device. It allows the user 
to select the keyboard layout best suited to the required application. It consists 
of a flat touch-sensitive polycarbonate surface (A2, A3 or A4 size) made up of 
128 or 256 cells set out in a rectangular array. Although the board is 
completely smooth, each one of the touch cells sends a unique signal to the 
computer via a connecting lead. Any or all of these outputs are available for 
use by a controlling program. The potential of the Concept Keyboard is 
generally better exploited, however, not by assigning each of the touch cells to 
give a separate response; instead groups of cells may be connected logically 
into response areas so that a touch anywhere within one area will give the same 
response. The response areas are identified on a sheet of paper or thin card 
which exactly fits over the board. The overlay might display pictures, words, 
colours, a map ... the list is endless. The program designer can select the most 
suitable format for the current application. Examples are shown in figures 1 
and 2. 
 

 
 

Figure 1: Overlay for simplified Logo 
 
Just as the computer's communication to the user is no longer restricted to text 
on the screen, but employs exciting and colourful graphics; so the Concept 
Keyboard user can reply not only by means of text but by touching overlays 
which might include such items as pictures of animals, musical notes, the 
words of a reading scheme, diagrams or coloured shapes. 
 
 



Brown 69 

 
 

Figure 2: Overlay for money program 
 
The traditional flow of information between a human and a microcomputer 
system was as shown in figure 3. The human user sent information via the 
keyboard to the central processing unit. After doing its work, the 
microprocessor sent information to the user via the screen. With the arrival of 
the Concept Keyboard an important new link is introduced into the chain. The 
Concept Keyboard conveys information to the user. Information about the 
program is supplied to the user by the overlays as well as the VDU screen 
(figure 4). 
 

 
 

Figure 3 
 

 
 

Figure 4 
 



70 Australian Journal of Educational Technology, 1987, 3(1) 

With light pens and touch-sensitive screens it is now possible to communicate 
with the microprocessor via the screen. The keyboard, whether Concept or 
conventional, can receive messages from the microprocessor (to cause red 
lights to shine or bleeps to be emitted). Thus the circle of two-way 
communication is complete (Figure 5). 
 

 
 

Figure 5 
 
It has been shown (Brown, 1985b) that the Concept Keyboard program 
designer should not only use the board as an input device, but also as a means 
of informing the user about the program. This will mean in practice that the 
child will not spend long periods of time staring at a screen. Instead messages 
from the screen will be related to information on the Concept Keyboard and 
vice-versa. 
 
From an ergonomic point of view it is undesirable for a child to sit still at a 
work station for extensive periods of time. The situation is considerably 
improved if the time spent looking at the screen is punctuated by the activity 
of receiving information from the Concept Keyboard and making a considered 
response back to it. The latter may be implemented by pressing a particular 
part of the board or by moving an object across it. Typically, the object may be 
a pawn, button or counter to mark the user's position, for example, on a 
simulated walk. 
 
Nevertheless, even by using Concept Keyboard in this way the child is still 
sedentary and his physical activity is confined to interaction with the 
computer and its peripheral devices. Experience has shown that it is 
educationally desirable for periods of activity at the computer to be 
interspersed with sessions handling natural everyday objects. Creativity is 
enhanced if the child is stimulated in a variety of ways. An example will now 
be given of a development in which the computer is integrated with other 
classroom resources in a learning package. 
 
The computer and environmental studies 
 
Environmental studies has been taken as a classic example of a subject area 
which, by definition, is characterised by outdoor activity. Nevertheless it has 
been shown that computer based packages can enhance the environmental 
studies curriculum. It cannot be over-emphasised that staring at a screen is 
directly counter to the spirit of environmental studies. Let the child go out into 
the field ... touch, handle, do, record. There is no substitute for experiencing 



Brown 71 

mud, getting drenched by rain and feeling blisters! What is the justification, 
then, for the use of a software package? 
 
Firstly, the computer can provide simulations of excursions into other 
environments. For most children it will not be part of every day experience to 
explore a wide range of environments. For schools in an inner city, visits to the 
sea will be the subject of occasional outings. For country children, visits to the 
town will be special occasions. Children with special needs may suffer 
particular restrictions upon their ability to enjoy a variety of environments. 
 
Secondly, the programs can provide preparatory or follow-up material to the 
actual outdoor activity. They are ancillary to, but no substitute for, the real 
thing! They should stimulate and motivate children by encouraging them to be 
more aware of the outdoor environment: to think about the subjects of their 
observations and be more informed about them. 
 
Thirdly, the package should not merely keep the child staring at a screen, but 
can offer a variety of stimulating activities within the classroom. 
 
Description of nature walks package 
 
The project produced three packages. Each simulates nature walk in one of 
three environments; the country, the town, the seaside. The target age group 
was six to eight year olds or older children with moderate learning difficulties. 
Each walk takes place on the Concept Keyboard; the child moves a small 
counter or button across the overlay which depicts an aerial view of one of the 
three environments (see Figures 6 to 8). The counter represents the child's 
position. For example he may be walking along a road, entering a park or 
climbing down onto a beach. He must walk one step at a time as in real life. 
The computer will notice if he cheats by jumping, say, from one side of a town 
to another. The screen will show what he has tried to do and from where he 
must continue. The child's task is to collect ten objects of interest. They cannot 
be seen on the overlay but are hidden in the places where one might expect to 
find them. For example, a crab may be under a rock, an apple may be under a 
tree. 
 

 
 

Figure 6: Overlay for seaside walk simulation 
 
While the walk progresses the screen provides a graphics display of a little 
man walking along. Left or right movements to the Concept Keyboard 
generate corresponding movements of this little man against a background 



72 Australian Journal of Educational Technology, 1987, 3(1) 

depicting the appropriate environment. This screen display represents the 
stage when a child is out walking happily without spotting anything very 
special. Then suddenly he finds something! The screen display changes to a 
picture of the object he has discovered. 
 

 
 

Figure 7: Overlay for country walk simulation 
 

 
 

Figure 8: Overlay for town walk simulation 
 
The child must now go to a box, quite separate from the computer, in which 
there are initially ten picture cards. Each card has a drawing which exactly 
matches the computer screen's representation of one of the ten objects. The 
child searches for the right one; he then picks up a special book which contains 
matching pictures of the ten objects. He finds the right one and then reads the 
passage beside the picture. (An example of a page layout is given in figure 9). 
He then returns to the computer and reads from the screen a simple multiple-
choice statement. Response is made via the Concept Keyboard. If the child gets 
it wrong he returns the card to the box and carries on walking. If he gets it 
right, he may put the card into a slot provided beside the picture in the book. 
These slots are in the form of bags appropriate for use in the current 
environment: beach bags for the seaside, hold-alls for the town and knapsacks 
for the country. 
 
The teacher may, by interrupting the program at any stage, check which 
objects should be in the bag-slots. The screen will display, for each object, 
whether it has been found, whether the question has been answered correctly 
and how many wrong attempts, if any, have been made. 
 



Brown 73 

The child is stimulated by the excitement of anticipating the next "find" and 
the desire to collect a complete set of ten cards. No two uses of the program 
are the same because the objects are hidden in certain places with a probability 
defined in the program. So no two walks, even over the same route, will 
produce all the same finds in the same places. 
 
When the walk is over and all objects have been collected, the child is 
encouraged to choose a follow-up activity relating to any of the objects. For 
this purpose a book of suggestions for teachers is supplied with each package. 
At this point the computer activity stimulates the child to go out of doors and 
collect real objects, classify and compare them, bring them into the classroom 
and carry out experiments, observations and do art work. For example, after 
finding the feather on the country walk the child may be encouraged to go out 
and collect real feathers, classify them by colour and size, relate the size of 
feathers to the size of the birds, their eggs, their nests, their wingspan. 
Activities include collecting pictures of birds and learning to recognise them, 
attracting birds to a feeding table outside the classroom. Artwork suggested 
by a feather includes making a quill pen, painting with a feather or designing 
an Indian headdress. 
 

 
 
The computer, then, should be seen not as an attraction in itself, holding a 
child indoors with its artificial simulations, however realistic they may be. 
Instead the computer should give encouragement and support to actual 
outdoor activities which enrich the child's awareness of the variety of living 
things and materials in the environment. Thus the child will come to 



74 Australian Journal of Educational Technology, 1987, 3(1) 

appreciate the structure and form of living things and their products. It should 
develop the child's ability to use books and other media further ideas and 
information. 
 
Special needs 
 
For the child with special needs who is physically prevented from exploring 
and enjoying the outdoor environment, a computer package with support 
materials is ideal for obvious reasons. Some of the thrills of walking over 
countryside or by the sea are brought to the desk top. 
 
Slow learners and other children with moderate learning difficulties find this 
multi-media approach helpful. Concentration levels are significantly increased 
when using packages like those described here. The continuous use of the 
screen can become tiring. However in the package described, the scene of the 
action changes repeatedly between the screen, the Concept Keyboard, the 
book, the box of picture cards and finally the follow-up activity. 
 
References 
 
Brown, I. C. (1985a). The Concept Keyboard user guide. London: AB Electronic 

Components Limited. 
Brown I. C. (1985b). The use of icons at the child-computer interface. In 

Children in an information age: tomorrow's problems today, Vol.1, Proceedings 
of the international conference and exhibition, Bulgaria: State Committee 
for Science and Technical Progress, pp. 99-124. 

 
Acknowledgments 
 
The project discussed in this paper was sponsored by the Council for 
Educational Technology, UK, through the British Government's 
Microelectronics Education Programme (Project No. 297). Thanks are 
expressed to their representative Mrs Audrey Milner, Curriculum 
Development Manager, Mr Tom Au, Programmer, City of London 
Polytechnic, and Mr Ralph Dunkley, also of City of London Polytechnic who 
was responsible for the artwork and the layout of the documentation. Thanks 
are also due to Mrs Marion Brown, Headmistress, Woodlea School, 
Woldingham, Surrey, who made many helpful suggestions and was 
responsible for the schools trials. 
 

Based on a paper presented at EdTech'86, International Educational 
Technology Conference and Exhibition, University of Western Australia, 
Perth, 2-5 December 1986. 
 
Please cite as: Brown, I. C. (1987). Special keyboards for special needs. 
Australian Journal of Educational Technology, 3(1), 67-74. 
http://www.ascilite.org.au/ajet/ajet3/brown.html