Device for visually displaying alphanumeric characters, particularly in motor vehicles

A device for visually displaying alphanumeric characters by means of segments which are individually and selectively switchable between two operating states, one of which corresponds to visual perceptability of the segments themselves. The segments are arranged in identical, adjacent groups forming a repeating structure, wherein each group comprises first segments together defining a main configuration including two quadrilateral-shaped spaces arranged one above the other and open on their right-hand sides, second segments defining first and second subsidiary configurations disposed respectively at the lower left-hand corner, and the upper left-hand corner of the main configuration and each including a segment which extends substantially vertically from a respective corner of the main configuration itself, two third segments one of which occupies the upper left-hand portion of the lower quadrilateral-shaped space of the main configuration, and the other of which is located below the lower right-hand corner of the main configuration.

The present invention relates to devices for visually displaying 
alphanumeric characters and in particular relates to a device in which the 
visual display of the alphanumeric characters is achieved by means of 
segments which are individually and selectively switchable between two 
operating states, one of which corresponds to visual perceptability of the 
segments themselves. 
Numerous examples are known in the art of alphanumeric visual display 
devices suitable for use in vehicles, both on the ground and in the air. 
A first example of devices of the type indicated above is constituted by 
devices which use cathode ray tubes (CRT) and which are basically similar 
to those generally used in video terminals of electronic processors. In 
these devices, each character is reproduced by means of a matrix of 
luminous points which, when activated, define the overall form of the 
character. These devices suffer from the disadvantage of being rather 
expensive and, in addition, the display unit is delicate and vulnerable. 
These disadvantages are partially overcome by the use of visual display 
units employing light emitting diodes (LED) or, more recently, liquid 
crystals, these units being similar to those which are very widely used 
today in so-called digital watches and pocket calculators. 
The visual display units mentioned above are generally termed 
"seven-segment" units since they include seven segments which are either 
light emitting or can be made visually perceptable, and which define two 
spaces, usually quadrilateral in shape, located one above the other. These 
units allow the visual display of all the Arabic numbers as well as 
several letters of the alphabet (mostly capitals) with which alarm or 
error messages can be associated. 
These visual display devices are not really suitable for the generalised 
presentation of numbers and letters of the alphabet, particularly lower 
case alphabet letters. In order to provide this display versatility it is 
necessary to revert to the "point" system described previously which 
generally cannot be implemented in a small visual display unit because of 
the need to selectively activate a large number of points for each 
character. 
The object of the present invention is to provide a device of the type 
specified above which does not have the disadvantages described above and 
is simple and efficient to use particularly in motor vehicle applications. 
In order to achieve this object, the present invention provides a device of 
the type specified above characterised in that the said segments are 
arranged in identical, adjacent groups forming a repeating structure, each 
group comprising: 
first segments together defining a main configuration including two 
quadrilateral-shaped spaces arranged one above the other and open on their 
right-hand sides, 
second segments defining first and second subsidiary configurations 
disposed respectively at the lower left-hand corner, and the upper 
left-hand corner of the main configuration and each including a segment 
which extends substantially vertically from a respective corner of the 
main configuration itself; the second subsidiary configuration further 
including a horizontal segment which extends towards right as an extension 
of the substantially vertical segment and a corner segment occupying the 
corner position of the second configuration itself, 
two third segments one of which occupies the upper left-hand portion of the 
lower quadrilateralshaped space of the main configuration, and the other 
of which is located below the lower right-hand corner of the main 
configuration in a position substantially horizontally aligned with the 
lower end of the first subsidiary configuration, and 
means for selectively controlling the switching of each of the first, 
second and third segments into the state of visual perceptability. 
By virtue of this characteristic a device is provided which allows all the 
lower-case letters of the alphabet and several arithmetic signs to be 
displayed efficiently in addition to Arabic numerals. In addition to this, 
the presentation of the Arabic numerals is significantly improved, which 
makes their identification easier avoiding several of the errors which are 
frequently caused by the use of "seven-segment" units.

FIG. 1 shows generally a flat visual display screen 1 of a device according 
to the invention. 
On the surface of the screen 1 are a plurality of surface segments arranged 
in a repeating structure. 
Each surface segment is individually and selectively switchable between two 
operating states, one of which corresponds to visual perceptability of the 
segment itself. 
The switching of each segment to its state of visual perceptability is 
controlled by a supply source generally indicated 2. 
The screen 1 may be formed by any of the methods currently used for the 
manufacture of visual display units, such as, for example, light emitting 
diode technology (LED), vacuum fluorescent technology (VF) or liquid 
crystal technology (LCD=liquid crystal display). 
In all the cases mentioned the source 2 is constituted by an electrical 
source capable of producing a state of polarisation in each surface 
segment present on the screen 1. 
When the segments are formed by light emitting diode technology (LED) or 
vacuum fluorescent technology (VF), switching to the polarised state 
results in the whole surface of a segment becoming luminous and thus 
distinguishable from the extreme darkness of the screen. 
When liquid crystal technology is employed, switching to the polarised 
state produces a variation in the refractive index of the entire segment 
which takes on a uniformly light colour, clearly contrasting with the 
opacity and the generally dark colour of the screen or vice versa. 
The detailed specification of the characteristics of the supply source 2 
and of the criteria for connecting it to the surface segments of the 
screen 1 is a question of design which can be solved by an expert in this 
field. 
As indicated above, the surface segments present on the screen 1 are 
arranged in identical groups disposed very close to each other such as to 
form a continuous repeating structure extending in a horizontal direction 
on the surface of the screen 1. 
The basic structure of each of these groups is illustrated in FIG. 2. 
In this Figure first segments, progressively numbered from 10 to 14, 
together form a main configuration which defines two quadrilateral-shaped 
spaces located one above the other and open on their righthand sides. 
The first segments 10 to 14 basically correspond with five of the seven 
segments of the "seven-segment" displays at present in use for presenting 
Arabic numerals. Taking account of the fact that the surface segment 
present on the screen 1 are arranged in a repeating structure, the 
segments 10 to 14 allow the display of all of the Arabic numerals as is 
illustrated in FIG. 5 with reference to the numeral "1" in which, as in 
the other Figures, the activated segments are indicated by outlining. 
The group illustrated in FIG. 2 further includes a second collection of 
segments indicated by numerals 15 to 18, defining first and second 
subsidiary configurations. 
In the example described, the first subsidiary configuration includes a 
single segment indicated 15 which extends substantially vertically from 
the lower left-hand corner of the main configuration defined by the 
segments 10 to 14. 
The second subsidiary configuration, which is generally L-shaped, is 
disposed at the upper left-hand corner of the said main configuration. The 
second configuration includes a segment 16 which extends substantially 
vertically from the upper left-hand corner of the main configuration 
defined by the segments 10 to 14. A horizontal segment 17 projects towards 
right i.e. towards the vertical centre line of the main configuration as 
an extension of the segment 16. A corner segment 18 is interposed between 
the segment 16 and the segment 17. The segment 18 thus occupies the corner 
position of the second configuration itself. 
FIG. 6 illustrates the use of the segment 18 which is activated together 
with the segments 11 and 13 to achieve the presentation of the letter "i". 
References 19 and 20 indicate two further segments the first of which (19) 
is triangular and occupies the upper left-hand portion of the 
quadrilateral-shaped space defined by the segments 12, 13, 14, that is, 
the lower quadrilateral -shaped space of the main configuration defined by 
the segments 10 to 14. Preferably, the longer side of the segment 19 
extends along the longer diagonal of this quadrilateral-shaped space. The 
segment 20 is, in contrast, located below the segment 14, in a position 
substantially horizontally aligned with the lower end of the segment 15, 
in correspondence with the lower right-hand corner of the main 
configuration defined by the segments 10 to 14. 
The use of the segments 19 and 20, together with that of the other segments 
is shown, by way of example, in FIGS. 7 to 11. 
In particular, FIG. 7 shows the display of the character "k" the 
presentation of which is achieved by the simultaneous activation of the 
segments 11, 12, 13, 16, 18 and 19 of one of the groups forming the 
repeating structure, and the segments 11 and 13 of the adjacent group on 
the right. 
The display of the letters "q" and "g", illustrated in FIGS. 8 and 9 is 
achieved by the activation, in addition to the segments 10, 11, 13, 14 
(and in the case of the "g", 20) of one group, of the segments 11, 13, 15 
of the adjacent group on the right. 
FIGS. 10 and 11 illustrate the presentation of the characters "j" and "d". 
The presentation of the character "j" is achieved by the simultaneous 
activation of the segments 11, 13, 15, 16 and 18 of one group and the 
segment 20 of the adjacent group on the left. 
The presentation of the character "d" is, however, obtained by the 
simultaneous activation of the segments 10, 11, 13 and 14 of one group and 
the activation of the segments 13, 16 and 18 of the adjacent group on the 
right. 
The presentation of a single character may thus require the simultaneous 
activation of segments belonging to different groups. 
For this purpose, in order to allow the presentation of all the characters 
even in the end positions of the screen 1, the groups of segments 
occupying the left-hand and right-hand end positions of the repeating 
structure may be provided with auxiliary segments. 
The group occupying the left-hand end position, illustrated in FIG. 3, has 
an auxiliary segment indicated 20a which is located outside the group on 
the left-hand side thereof, in a position substantially in alignment with 
the lower end of the segment 15. 
The auxiliary segment 20a thus constitutes, so to speak, a sort of "left 
over" of an adjacent group to the left of the said end group. 
In a substantially similar manner, the group, illustrated in FIG. 4, which 
occupies the right-hand end position of the visual display structure of 
the screen 1, has further segments 11a, 13a, 15a, 16a, 18a aligned along 
the right-hand side of the group itself. These auxiliary segments are used 
for the representation of characters such as "d" or "i" in the right-hand 
end position of the screen 1. 
FIG. 12 illustrates the presentation of the character "m", which involves 
three groups of segments with the segments 10, 11 and 13 being activated 
in two adjacent groups and the segments 11 and 13 being activated in the 
group occupying the position to the right in the overall configuration. 
FIGS. 13 and 14 illustrate the presentation of groups of two letters, that 
is, the group "li" and the group "in". 
A more complete illustration of the manner of representation of Arabic 
numerals and lower-case alphabet letters by means of the device according 
to the invention is to be found in the drawings of Italian design 
application No. 52942-B/83 filed Feb. 14, 1983. 
FIG. 15 illustrates schematically the segments of the visual display screen 
1, together with the network of connecting lines terminating at the source 
2 which enables a state of polarisation to be selectively produced in each 
surface segment present on the screen 1. In the example illustrated, the 
surface segments on the screen 1 are arranged in a repeating structure 
comprising eleven groups of segments similar to that illusrated in FIG. 2 
and identical to each other. 
Successive references 21 to 26 indicate six connecting lines each of which 
connects together segments occupying corresponding positions in the eleven 
groups forming the said repeating structure. 
More particularly, line 21 connects with the segments 17 and 18 of all the 
groups of the structure, while lines 22 and 23 respectively connect with 
all the segments 10 and 16 and all the segments 11 and 12 on the screen 1. 
Similarly, the line 24 connects with all the segments 13 and 19 while the 
line 24 connects with all the segments 14 and 15. Finally the line 26 
connects all the segments 20. 
Successive references 27 to 37 indicate eleven pairs of connecting lines, 
each pair enabling the selective polarisation of the segments in one of 
the eleven identical groups forming the repeating structure. In 
particular, for each pair, the segments indicated 11, 13, 15, 16 and 18 
connect with one of the lines while the segments indicated 10, 12, 14, 17, 
19 and 20 connect with the other. 
The arrangement is such that each of the segments present on the screen 1 
is connected to only one of the lines 21 to 26 and to only one of the 
lines 27 to 37, in accordance with a matrix addressing scheme in which the 
polarisation of each segment is controlled by the source 2 through a 
signal applied to a unique pair of connecting lines. 
Thus for example, the polarisation and the visual perceptability of the 
segment 12 in the group furthest to the left in FIG. 15 can be achieved by 
the application of a polarisation signal between the line 23 and the line 
occupying the right-hand position of the pair indicated 27. 
The illustration provided by FIG. 15 is schematic since both the manner of 
formation of the lines 21 to 26, 27 to 37 (for example by metallisation on 
one or both faces of the screen 1) and the topological organisation of the 
lines themselves, vary in dependence on the technology (LED, LCD, vacuum 
fluorescent etc.) used for the manufacture of the screen 1. The adaption 
of the parameters of the connecting lines to a particular technology is a 
question of design which can be solved by an expert in this field. 
The connection configuration described facilitates the connection of the 
screen 1 to the supply source. In particular, in order to reduce the power 
used by the screen 1 it is possible (in known manner) to provide the 
source 2 with a multiplexer having the same number of outputs as the 
number of connecting lines (six, in the case of the lines 21 to 26) 
connecting corresponding segments in different groups of the repeating 
display structure. The purpose of the multiplexer is to cause the 
polarisation signals which are to be applied to the segments through these 
lines (21-26), to be applied to only one line at a time in a cyclic manner 
instead of being applied simultaneously to all the lines concerned. 
For example, in presenting a letter "i" (FIG. 6) by means of the segments 
11, 13 and 18 of any one group of the repeating structure, instead of 
supplying (together with the corresponding line selected from the lines 27 
to 37) the lines 21, 23 and 24 simultaneously with each other, the 
multiplexer cyclically supplies the line 21 alone, the line 23 alone, the 
line 24 alone, and then supplies the line 21 alone again and so on. 
The sequential supply of the lines 21 to 26 cannot be perceived by the 
observer since the period of the supply cycle is less than the average 
time of persistence of the images on the retina (typical value 1/16 
second). 
If a scheme for multiplexing the supply to the lines 27 to 37 is effected 
it is also possible (in known manner) to generate a "running" effect of 
the symbols and of the writing presented on the screen 1. 
Naturally, the effects of the present invention also extend to models which 
allow equal utility to be achieved by using the same innovative concept 
and in particular to models in which the segments 10-20 have a different 
form from the polygonal form illustrated in the drawings appended to the 
present specification.