FR2660471A1 - Safety visual-display device, using a dot matrix screen and aircraft instrument panel including at least one such device - Google Patents

Abstract

In order to reduce the risk of loss of essential information, in the event of a partial breakdown in the display device, the wiring of the conductors which provides the display on the screen (6) is produced in such a way that the dots of the screen are divided into four separate groups controlled respectively by four distinct drive stages (1, 2, 3, 4): group of the points of odd lines to the left of the screen and to the right of the screen and groups of the points of even lines to the left of the screen and to the right of the screen. This allows quadruple redundancy of the information by repetition on the even lines of the information from the odd lines and by repetition on the right of the screen of the information given on the left of the screen. Application, in particular, to visual display devices for aircraft instrument panels.

Description

Safety viewing device using
a dot matrix and dashboard screen
aircraft comprising at least one such device.

 The present invention relates to visualization on dot matrix screens, such as, in particular, liquid crystal screens; the invention relates more particularly to the display of essential information for their user. This information being essential, must be saved even in the event of partial failure of the display device; this is the case, for example, for some of the information which appears on aircraft dashboard screens and which is essential for piloting.

 It is known to double the equipment, but this is a solution which is generally to be avoided more for reasons of space and weight than for price problems.

 The object of the present invention is to ensure good information display security while avoiding or at least reducing the drawbacks of existing equipment.

 This is achieved by a redundant display, designed specifically according to the structure of the dot matrix screens.

 According to the invention, a safety display device is proposed, using a dot matrix screen, that is to say comprising rows of a first and a second type, one of these types being made of horizontal rows or lines and the other of vertical rows or columns, and comprising in series information storage means, information transfer means and the screen, characterized in that the surface of the screen is subdivided into a first and a second half, in that the transfer means are four in number, are distinct from each other and are assigned to the transfer of information respectively intended for the odd rows of the first type of the first half of the screen, to odd rows of the first type of the second half of the screen, to even rows of the first type of the first half of the screen and to even rows of the first type of the second half of the screen.

The present invention will be better understood and other characteristics will appear from the following description and the figures relating thereto which represent
- Figure 1, the partial diagram of a device according to
The invention,
- Figures 2 to 4, three diagrams which supplement the diagram of Figure 1, respectively in three alternative embodiments of devices according to the invention.

 In the various diagrams, the precise synchronization devices, which are part of the current technique, have not been shown in order to make the drawings clearer and to simplify the description.

 FIG. 1 is the partial electrical diagram of a display device according to the invention with its time base circuit, H, which supplies the various synchronization signals necessary for the operation of this device.

The device comprises a dot matrix screen, 6, with its line counter 5 controlled by signals supplied by the circuit H; in the example described, this screen is a 480,480 dots liquid crystal screen. The wiring of the conductors, which make it possible to control the points of the screen matrix, is carried out so as to be able to control separately, from four pilot stages (drivers in the Anglo-Saxon literature), 1, 2, 3, 4 respectively the points of the odd lines located in the left half of the screen, the points of the odd lines located in the right half, the points of the even lines located in the left half of the screen and the points of the even lines located in the right half of the screen. The pilot stages, which are composed of a series-parallel register followed by a locking register (latch in Anglo-Saxon literature), include, given the screen used, 480 / 2 = 240 outputs and, for example, the 240 outputs of the pilot stage 3 are respectively connected to the first 240 points of the 2nd,> 238e and
Y of and 240 lines of
The screen 6, while the input of the pilot stage 3 receives video signals, Gp, relating to the points of the even lines located in the left part of the screen; similarly, the inputs of the pilot stages 1, 2 and 4 receive signals Gi, Di and Dp respectively. The input conductors of the pilot stages 1 to 4 bear the references 10, 20, 30, 40 respectively; above each of these conductors has been indicated that of the four signals Gi, Di, Gp, Dp which it conducts.

This way of controlling the display on the screen 6 makes it possible on the one hand to double the writing lines, that is to say to ensure redundancy in odd-even line, and on the other hand to ensure redundancy between the right part and the left part of the screen; this results in quadruple redundancy. As an example, the information concerning the altitude of an airplane can be given by the signals Gi,
Gp, in the form of a number on the left side of screen 6, with the same image shifted by one line; this same altitude information can be given on the right part of the screen 6, thanks to the signals Di, Dp, by two identical images offset by a line and these two images can be the same number as on the right part of the screen or may represent an altimeter dial with its needle, the needle being, of course, positioned on the value of the dial corresponding to the number displayed on the left side of the screen; thus in general it is possible to have two almost redundant but not identical images: numerical value given by a counter and tendency of variation of the value, given by a needle.

Figure 2 is a first embodiment of the part of the display device which provides the signals
Dp, Gp, Di, Gi which was discussed during the description of Figure 1. In a video memory 7, also called VRAM memory (initials of the English words VIDEO
RANDOM ACCUS S MEMORY) are stored the instructions corresponding to the plots of four redundant images. The signals delivered by the memory 7, at the rate of the time base circuit H of FIG. 1, correspond to the successive lines to be displayed on the screen 6 of figure 1. it is therefore necessary, to obtain the signals Dp, Gp, Di, Gi, to be able to distinguish between the signals relating to the even lines and to the odd lines and, among the signals of the same line, to be able to distinguish between those relative at the points on the right side of the line and those relating to the points on the left side of the line, that is to say, in the example described, between the first 240 points of a line and the 240 points For this, the signals delivered by the memory 7, at the rate of the time base circuit, H, of FIG. 1, are sent to the input of an electronic switch 8, represented diagrammatically in the form of a switch mechanical. The switch 8 is controlled by the output signals of a counting circuit 9, which is reset to zero by the start of frame signals, T, also supplied by the time base circuit H of FIG. 1. The circuit counting 9 comprises a modulo counter n / 2 = 240, where n is the number of points per line of the screen 6 and is equal to 480 in the example described; this modulo 240 counter, not shown in FIG. 2, counts the point writing signals, P, also provided by the time base
H of the display device. The counting circuit comprises on its output, a modulo 4 counter, not shown in FIG. 2, which advances by one at each zero crossing of the modulo 240 counter; thus the counting circuit 9 controls the switch 8 in synchronism with the reading of the memory 7 so that the information signals relating to the left parts, Gi, and right, Di, odd lines and to the left parts, Gp, and right , Dp, even lines are respectively routed on the four output conductors of the switch 8; these conductors identified 10, 20, 30, 40, correspond to the conductors which bear the same references in FIG. 1.

Figure 3 is a second embodiment of the part of the display device which provides the signals
Gi, Di, Gp, Dp used for display on the screen 6 of FIG. 1. In this embodiment, the information to be displayed is stored either in a so-called left video memory, 70, if it relates to the left part of the screen 6 of FIG. 1, either in a so-called right video memory, 71, if they relate to the right-hand part of the screen The information contained in memories 70 and 71 can be read simultaneously, and therefore, thanks to the assembly according to FIG. 1, the displays on the right and left parts of the screen 6 can be carried out simultaneously; that is to say that the signals Gi and Di on the one hand Gp and Dp on the other hand, can be supplied simultaneously to the assembly according to FIG. 1, so that, compared to what it was with the mounting according to Figure 2, the display speed is multiplied by two. In this embodiment, the read signals from the memories 70 and 71 are sent respectively to the inputs of two electronic switches with two positions, 80, 81, controlled by a counting circuit 90. The counting circuit 90 corresponds to the counting circuit 9 of FIG. 2 with the difference that, the signals Gi and Di being supplied simultaneously, as well as the signals Gp and Dp, this counting circuit comprises, after its modulo 240 counter, not a modulo 4 counter but a modulo 2 counter The output conductors of the electronic switches 80 and 81 are marked 10, 20, 30, 40 and correspond to the conductors bearing the same references in Figure 1.

The present invention is not limited to the examples described above, it is thus, in particular that a variant in Figures 2 and 3 consists, as shown in Figure 4, in an assembly with four video memories 72, 73, 74 , 75 respectively called left odd, right odd, left even, right even, which provide, on their output conductors 10, 20, 30, 40, respectively the signals Gi, Di,
Gp, Dp used in the assembly according to Figure 1; in this case these four signals can be supplied simultaneously to be displayed on the screen 6 according to FIG. 1 so that, compared to what it was with the assembly according to FIG. 2, the display speed is multiplied Similarly, with an assembly similar to that of FIG. 3 but where the two video memories serve respectively to store the information intended for the odd and even lines, it is possible, by a suitable command of the switches, to carry out with the assembly according to FIG. 1 a safety display with simultaneous display of an odd line and an even line.

 It should be noted that the invention also applies to a display device where the redundancy is a redundancy relating to the upper and lower halves of the screen and to the even and odd columns or a redundancy relating to the left halves and right of the screen and on the even and odd columns, or even a redundancy relating to the upper and lower halves of the screen and on the even and odd lines.

 The invention also relates to dashboards of aircraft equipped with such devices.

Claims (5)

 1. Safety display device, using a dot matrix screen, that is to say comprising rows of a first and a second type, one of these types being made of horizontal rows or lines and l other one of vertical rows or columns, and comprising in series information storage means, information transfer means and the screen, characterized in that the screen surface is subdivided into a first and a second half, into that the transfer means (1, 2, 3, 4) are four in number, are distinct from each other and are assigned to the transfer of information (Gi, Di, Gp, Dp) respectively intended for the odd rows of the first type of the first half of the screen, odd rows of the first type of the second half of the screen, even rows of the first type of the first half of the screen and even rows of the first type of the second half of the screen 'screen.  2. Display device according to FIG. 1, in which the storage means consist of a video memory (7), characterized in that a switching circuit (8) with four outputs couples the video memory to the four transfer means and in that the switching circuit is controlled by a counting circuit (9) which, according to signals supplied by a time base circuit (H) of the device, determines the instants of writing at the start and in the middle of the even and odd rows of the first type on the screen.  3. Display device according to FIG. 1, characterized in that the storage means consist of two video memories (70, 71), in that a first switching circuit (80) with two outputs couples one ( 70) of the two memories to two (1, 3) among the four transfer means, in that a second switching circuit (81) with two outputs couples the other (71) from the two memories to the other two (2, 4) among the four transfer means and in that the control of the switching circuits is effected by a counting circuit (90) which, as a function of signals supplied by a time base circuit (H) determines the instants of write at the beginning and in the middle of the even and odd rows of the first type of the screen.  4. Display device according to FIG. 1, characterized in that the storage means are constituted by four video memories (72, 73, 74, 75) respectively coupled to the transfer means (1, 2, 3, 4).  5. Aircraft dashboard, characterized in that it comprises at least one screen of a device according to any one of the preceding claims.