Source: https://patents.google.com/patent/GB2100100A/en
Timestamp: 2018-08-16 05:12:03
Document Index: 322853231

Matched Legal Cases: ['arts 29', 'arts 29', 'art 29', 'arts 29', 'arts 29', 'art 29']

GB2100100A - A computer generated imagery system - Google Patents
GB2100100A
GB2100100A GB8214845A GB8214845A GB2100100A GB 2100100 A GB2100100 A GB 2100100A GB 8214845 A GB8214845 A GB 8214845A GB 8214845 A GB8214845 A GB 8214845A GB 2100100 A GB2100100 A GB 2100100A
GB2100100B (en )
5 This invention relates to a computer generated imagery system having a data base containing descriptions of polygonal faces defining an object or scene to be depicted by an image. In such systems it is usually necessary to 10 provide some means for ensuring that, for a particular point of observation relative to the object or scene, faces which are hidden by other faces are not displayed. To deal with this problem it has previously been proposed 15 for each face to be allocated, in the data base, a code defining the direction in which is is directed. Faces directed away from the observer are not displayed. This technique is satisfactory for a simple object such as a cube or 20 sphere but does not work for more complex shapes where one face, directed towards the observer may obscure another also directed towards the observer. To deal with such situations it is necessary to allocate to each face, a 25 priority value, these priority values defining a hierarchy which determines which faces pointing generally towards rather than away from the observer are capable of obscuring other faces also pointing towards the observer. Thus 30 a face of priority 1 could be defined as being able to obscure any face of lower priority, e.g. of priority 2. etc., etc.
This simple allocation of priorities works in most situations but not for all situations. It 35 cannot, for example, satisfactorily handle an object or surface having a "saddleback"
shape, such as that shown at 3 in Fig. 1 (to be described later). For such a shape it is found impossible to allocate priorities as men-40 tioned above.This problem is explained in detail in a paper "A real-Time Three Dimensional Graphics Display" by A.H. Sale and A.G. Bromley in the Australian Computer Journal Vol. 7 No. 1 March 1975. This paper 45 illustrates the problem with reference to Fig.
In accordance with the invention each face is given more than one and preferably four priorities, one for each of different angles of 50 view.
One way in which the invention may be performed will now be described with reference to the accompanying drawings of a simulator constructed in accordance with the in-55 vention. In the drawings:
Figure 1 illustrates apparatus for preparing what will be termed the "data base" which is a digital recording of three dimensional information defining features to appear in simu-60 lated scenes;
Figure 2 illustrates, in the form of a sche-65 matic block diagram, apparatus for producing a display from the information in the data base, this apparatus including what will be termed a "scenario processor" for controlling the sequence of events to be portrayed by the 70 display, a "picture processor" for processing three dimensional information from the scenario processor into two dimensional information for display; a "display processor" for presenting information from the picture pro-75 cessor in a form suitable for reception by an optical projection system, and the optical projection itself;
Figures 3 and 4 illustrate the effect of mathematical projections from three dimen-80 sions to two dimensions performed in the picture processor;
Figure 5 is a schematic block diagram of the display processor shown as a single block on Fig. 2;
85 Figure 6 illustrates a raster spot of a cathode ray tube shown in Fig. 7;
Figure 7 is a schematic diagram of a cathode ray tube three of which are included in each of the two projecters shown in Fig. 2; 90 Figure 8 illustrates, again schematically, a display screen indicated generally in Fig. 2; and
It is desired to produce images on a display screen 1 (Fig. 2) visible by an observer who will normally be at position 2 (also Fig. 2) but 100 may move to other positions, e.g., 2A and 2B, in front of the screen 1. The images simulate a scene which would be visible by the observer when travelling in a vehicle over terrain divided into a number of square re-105 gions (called tiles). A contour map of one
"tile" is shown at 3 (Fig. 1). The same region or tile is also depicted by a map shown at 4 (Fig. 1) and is divided by lines of visual discontinuity 5, 6 and 7 into four areas which 110 are distinguishable by their colour, brightness or texture. Examples of such different areas might be areas of woodland, urban development, water, grass, crops, etc.
The data contained in the maps 3 and 4 115 needs to be stored in digital form and the process of doing this is called Data Base Preparation and will now be described with reference to Fig. 1. This can be done with the assistance of a suitable general purpose com-120 puter such as a CIG general purpose PDP VAX 1 1 /780 or a Marconi 920 Advanced Technology Computer to perform some of the tasks to be described below. The map 3 is first transposed into digital form and stored in 125 a memory 8 which is called the "height file". The height file is in the form of a table as shown, having height values associated with respective grid crossing points on the map 3. The transposition of the height information 130 from the map 3 into the height file 8 can be
GB 2 100 100A
done entirely manually by an operator who studies the map 3 and deduces from the contour lines, and from a process of interpolation a height value for each x-y address in the 5 height file. The height value for each such address can then be entered in the height file, e.g., using a keyboard. This operation, when performed entirely manually, can be time consuming and so an alternative method is pre-10 ferably used in which a digitiser is used. The digitiser is traced along the contour lines and automatically produces a signal representing the x and y values of its current position. The operator enters the height of the contour lines 1 5 currently being traced and this height is automatically entered in the height file at the x-y positions through which the digitiser passes. Preferably a mathematical interpolation method, e.g., using the aforementioned Mar-20 coni 920 Advanced Technology Computer previously mentioned is used to enter the appropriate height values in the height file x.y addresses therein through which addresses the digitiser has not passed.
25 The map 4 is also transposed by the operator into digital form and this is stored in a table 9 which is termed the "face description file"; a table 10 constituting the "points file" and a table 11 constituting the "edges file". 30 This operation can also be done entirely man-ualy by the operator who first divides each of the aforementioned four areas into polygonal faces, in this instance triangles, of a size chosen to fit very approximately to the discon-35 tinuity lines 5, 6 and 7. In the illustrated example the map 4 is divided as shown by the broken lines which the operator physically draws on the map. The points, e.g., points p, to p4, of the thus formed triangles are each 40 given an identity number which is entered in the first columm of the points file 10. The appropriate x and y co-ordinates of these points are then entered by the operator in the second and third columns of the points file 45 10. These x-y co-ordinates are also used by the operator to address the height file 8 and to produce a read out of the appropriate height value which the operator then enters in the fourth column of the points file 10. When 50 so entering information in the points file 10 the operator gives each point, e.g., p, an identity number which can conveniently be marked on the map 4 to serve as a reminder.
The operator now enters information defin-55 ing each triangular face into the face description file 9 whch is a table having eleven columns as shown. The first column contains a number identifying the face, e.g., face (i). The next three columns contain number iden-60 tifying the points or vertices of that face, e.g., points pl7 p2 and p3, taken in a predetermined direction, i.e. clockwise or anticlockwise. The fifth column contains a number, e.g., C1# identifying the colour of the face, e.g., green. 65 The colour is identified by a number according to a scale in which the lowest number represents a colour at one end of a spectrum of colours and the highest number represents a colour at the opposite end of the spectrum. 70 The sixth column contains another number identifying the brightness of the face, this also being chosen according to a scale in which the level of brightness is directly or inversely proportional to the size of the code number. 75 The next, seventh, column contains another code number defining the texture of the face. The eighth, ninth, tenth and eleventh columns contain priority numbers for observers looking in directions within four angles (a), (b), (c), 80 and (d) as indicated immediately below the map 4 on Fig. 1. The priority number given to a face denotes its capability of being obscured or of obscuring another face. Thus, a face having a priority 1 cannot be obscured by any 85 other face; a face of priority 2 can only be obscured by faces of priority 1; a face of priority 3 can only be obscured by faces of priority 1 or 2 and so on. In some cases for example in the case of faces (i) and (ii), 90 different priorities are applicable to different directions of view. Thus, in the illustrated example, face 1 has a priority of 1 for view directions a and d and a priority 2 for directions b and c.
95 The final eleventh column of the face description file contains a "direction vector"
code which defines a direction perpendicular tio the plane of the face. This is of important since, during subsequent processing of the 100 information, details of faces pointing away from the observer must not be displayed. This vector can be derived from the co-ordinates of the vertices of the face and this method is known (see for example "A review of some of 105 the more well known methods applicable to simulating" by W.G. Bennett published in SPIE Vol. 59 (1975) Simulators and Simulation. The direction vector code is calculated automatically by suitable programming of the 110 aforementioned computer, from the co-ordinates of the points defining the vertices of the face. The calculations and use of such direction vectors is known, and reference is made to a paper entitled "Computer Generated Gra-115 phics a Review of some of the more well-known methods applicable to simulation" by William S. Bennet published in SPIE Vol. 59 (1975) Simulators and Simulation.
The operator now uses information from the 120 map 4 to entern data in a table 11, which is called the "edges file" because it contains data defining the edges of the triangles. In the first column of the edges file the operator enters numbers identifying the edges, e.g., 125 edge L,. The second and third columns contain the identities (e.g., p, and p2) of the points at the beginning and end of the edge. The fifth and sixth columns contain the identities of the faces to the left and to the right of 130 the edge respectively. The left and right sides
GB 2100100A
are determined according to the clockwise or anticlockwise convention previously referred to.
As in the case of the height file 8, the 5 information in the files 9, 10 and 11 can be entered entirely manually by an operator who inspects the map 4 and works out from it the appropriate data which he enters by means of a keyboard; or, alternatively, this can be done 10 automatically. A similar digitiser to that previously described can be used for this purpose, the digitiser being traced along the lines of dincontinuity 5, 6 and 7 to provide a series of co-ordinate values spaced equally along those 15 lines, which co-ordinate values are entered into a store. The information in this store is then processed mathematically within the Marconi 920 Advanced Technology Computer by suitable programming of it to produce data 20 defining triangles like those shown at (i) to (xi) as shown on the map 4. All the information for the files 9, 10 and 11 is thus made available and entered automatically at the appropriate table positions: each of the points 25 p, to p4, etc., the faces (i) to (x), etc., and the edges L,, etc., being allocated identity numbers automatically.
It will be noted that the triangles into which the area shown on the map 4 is divided are 30 relatively large and that the information in the files 9, 10 and 11 is therefore only a rough approximation to the more detailed information available on the map 4. For this reason the files 9, 10 and 11 are marked on Fig. 1 35 as being "first level of detail." In order to provide a recording of the available information at a higher, second, level of detail the operator now divides each of the previous triangles into a number of smaller triangles as 40 shown in dotted lines at 12. Thus, the triangular face (i) is divided into smaller triangular faces (i)a, (i)b, (i)c and (i)d. Details of these traingles are entered in a second face description file 9', and second points file 10' and a 45 second edges file 11' in exactly the same way as before. However, the same height file 8 is used to obtain the z co-ordinate for entry in the points file 10'. In practice many further levels of detail are entered in further points 50 files, face description files and edges files,
buth the present description is confined to a system utilising two levels of detail for simplicity of description. It will be appreciated, however, that the larger the number of levels 55 of detail the greater is the advantage of using the common height file 8.
Particularly where very high levels of details are required it may be advantageous to use an interpolation method when reading from the 60 height file a height value corresponding to particular x-y co-ordinates. Such an interpolation can be carried out either by the judgement of the operator; or automatically using a mathematical process defined by suitable pro-65 gramming of the Marconi 920 Advanced
Technology Computer. The whole of the process of data base preparation is repeated for each "tile" of the terrain, additional face description files, points files and edges files 70 being provided for each tile.
When the various tables have been compiled the information on them is transferred into disc-stores 13 and 14 (Fig. 2), one disc store being used for each level of detail. The 75 disc stores are then loaded into the scenario processor 15 also shown in Fig. 2.
The Scenario Processor The scenario processor 1 5 comprises 80 another general purpose computer such as a DCS PDP Vaxll/780 and an ES PDP 11/34 or a Marconi Locus 16 Computer. This receives a code genrated by a control 16 which can be manipulated by the observer 3. This 85 code defines velocities of movement in three co-ordinates and angular velocities in two planes. The control 16 can be similar to that described and shown at 236 in U.S. Patent 3736564. The scenario processor 15 also 90 receives a code 17 which defines a starting position and is derived from a tape or disc programmed with rates defining the training exercise; and a clock signal on line 18 which is derived from a clock 18A and occurs for 95 each frame of a cathode ray tube display device to be described later. These codes are used by a position calculating circuit 19 to calculate the instantaneous position and direction of view. This information is presented in 100 the form of a signal 20 to a circuit 21. The circuit 21 also receives a signal 22 defining the angle of view u and a signal 23 defining the range of veiw which determines the visibility conditions which it is desired to simu-105 late. The signal 22 is pre-set according to the size of the screen 1. The signal 23 can also be pre-set or can be arranged to change according, for example, to the simulated height of the observer 2. From this received 110 information the circuit 21 calculates the "titles" currently in view. Each clock signal from 18A reads from the disc stores 1 3 and 14 information pertaining to those tiles; and this information is presented to a switch 11 5 shown schematically at 24, which selectively passes low definition information from disc 1 3 or higher definition information from disc 14 to a second processor 25 which is called the "picture processor" because it complies infor-120 mation for the production of a two dimensional picture from the three dimensional data presented to it.
A threshold detector 26 counts the number of faces per frame fed to the picture processor 125 25 and, if this is below a threshold (which is equal to the number of faces per frame which can be processed by a picture processor to be described later) causes the switch 24 to adopt its lower position so as to receive higher 130 definition data from the disc store 14. In this
way picture processor 25 is always used to its maximum capability.
Where more than two levels of detail are to be used then, of course, the switch 24 would 5 have several different postions. It will be understood that the three individual switches shown at 24 are linked so as to move in unison with each other.
10 Picture Processor
For each frame of information to be displayed the clock signals read the appropriate information from the store 13 or 14 via the switch 24 into the picture processor 25 15 formed by a further general purpose computer such as a Marconi Locus 16 Computer. This except for the information defining the edges of the triangular faces, this information being fed direct to a display processor to be de-20 scribed later. Information defining the points of the faces (from the points file) is fed to a 3D to 2D converter circuit 27 which receives information about the position of the observer in the simulated scene, this information being 25 obtained from the output of the circuit 1 9 in the scenario processor. The circuit 27 (which is a schematic representation of a suitably programmed part of the Locus 16 Computer) mathematically projects the three dimensional 30 co-ordinates of point one a two dimensional plane spaced from the point onto a two dimensional plane spaced from the point of observation by a distance equal to the distance between the position 2 and the screen 35 1. A schematic illustration of this mathematical projection process for the triangular face (i) is shown in Fig. 2. It is a well known process as described for example in the aforementioned paper by W.S. Bennet and is per-40 formed by suitable programming of the Locus 16 Computer previously referred to.
Referring to Fig. 3 the x, y and z coordinates are shown with an origin at 0 where the observer is assumed to be for the purpose 45 of simplifying this explanation. Of course in practice the observer will normally be required to appear to move and the co-ordinates of the observer as received from the circuit 19 will vary with time. The triangular face (i) has its 50 vertices at co-ordinates (x1,y1,z1), (x2,y2,z2) and (x3,y3,z3) and the programmed computer schematically shown as circuit 27 works out new co-ordinayes (x4,y = D,z4), (x5,y = D,z5) and (x6,y = D,z6) of an image of the face (i) 55 projected onto a plane where y = D and D is a positive value. D equals the distance between the observer and the screen 1.
The mathematical projection process can be performed in a relatively simply manner for 60 each point of a triangular face by deriving equations defining the lines joining the vertices of the triangle (i) to the onserver; and then calculating the points at which these equations are satisfied for the plane y = D. 65 Alternative perspective transformation equa-
sions, e.g., as set out in U.K. Patent Specification 2051525A can be used when it is desired to project onto the aforementioned plane a face having at least one vertex behind 70 the observer the normal projection procedure as described above will not work.
Such a triangular face is shown on Fig. 4, being defined by the vertices (x7,y7,z7), (x8, y8,z8) and (x9,y9,z9). A triangle like this is 75 detected in the circuit 27 by comparing the y co-ordinate of the observer with the y coordinate of the signal entering the mathematical projection system 27. When such a detection occurs the projected co-ordinates (x10, 80 y10 = D;,z10) of the point (xy,y7,z7) are used to calculate the co-ordinates (x1 3,y = D,z1 3) of the point where the extrapolated line L4 between points (x10,y = D,z10) and (x11, y = D,z11) meets at edge E of the plane of 85 projection; and where the extrapolated line L5 between points (x 10,y = D,z10) and (x1 2, y = D,z12) meets the edge E. The co-ordi-nates (x12,y = D,z12), (x11 ,y = D,z11) and (x13,y = d,z13) on the one hand and the co-90 ordinates (x12,y = D,z12), (x13,y = D,z1 3) and (x14,y = D,z14) on the other hand are then used to define two projected triangular faces (shown by different hatching on Fig. 4) and each is given the colour, brightness, 95 texture and priority of the original triangular face before projection.
The face description file 9 is fed to a colour change regulator 28 which prevents sudden changes in colour when the level of detail is 100 changed under the influence of the threshold detector. To understand this colour adjustment consider the situation when the level of detail is being increased by feeding a new frame of information to the picture processor 105 containing details of faces (i)a, (i)b, (i)c, (i)d and (i)e from the disc store 14 instead of face (i) from the disc store 13 as in the previous frame. In these circumstances, if no adjustment were effected, the face (i) would sud-110 denly change from its uniform colour C, to the multiple colours C3, C4, C5, C6 of faces (i)a, (i)b, (i)c and (i)d. Conversely, when the level of detail has been decreased so that a new frame of information fed to the picture proces-115 sor contains details of face (i) instead of individual faces (i)a, (i)b, (i)c, (i)d and (i)e, the varying colours C3, C4, C5, C6 would, if no means were provided to prevent this, suddenly become a uniform colour C.,. These 120 sudden transformations of colour would destroy the realism of the simulated scene. To avoid this the colour of each face is compared, in the circuit 28, with the arithmetical average colour of all faces having the same 125 prefix in the previous frame of information. If the new colour value is higher or lower than the aforesaid average it is modified so as to equal the average plus one or the average minus one respectively. In this way, the col-130 our of any given part of the scene can change
by only one colour value between frames this being sufficiently gradual as to be not noticeable by the observer. In cases where the level of detail is being increased so that, for exam-5 pie, the one original face (i) is replace by individual faces (i)a, (i)b, (i)c, (i)d, (i)e then the aforesaid "arithmetical average colour value" will simply be the colour value of the one original face (i).
10 It is similarly undesirable for sudden changes of brightness to occur when the level of detail is changed. Such changes of brightness are therefore controlled by a circuit 28A which operates on the brightness values in the 15 same way that the circuit 28 operates on the colour values. For each frame of information the face description, duly adjusted by the circuits 28 and 28A; and the projected points from the circuit 27 are passed to a third 20 processor 29 which is called the "display processor" because it processes the two dimensional information into a form acceptable by a display system indicated generally at 30.
25 The Display Processer
The display processor 29 (which can be another suitable programmed Marconi Locus Computer) is shown schematically in Fig. 5 and has four parts 29A, 29B, 29C and 29D 30 which respectively receive, from a scan signal generator 31 (Fig. 2) digital signals representing the x and y co-ordinates of positions respectively at the top, the bottom and two intermediate positions between the top and 35 bottom of the scanning spot of each of a number of cathode ray tubes included in projectors 30A and 30B (Fig. 2). The signals enter the display processor parts 29A, 29B, 29C and 29D at 29E, 29F, 29G and 29H 40 respectively as shown in Fig. 5. The display processor also receives, at 29! details of the edges currently in view derived from the edges file 11 of Fig. 1 via the disc store 13 or 14. The display processor further receives, at 45 29J, the projected co-ordinates of the points currently in view. The information received on lines 291 and 29J for each frame is used, in a computing device 29K forming part of the previously mentioned computer, to compute, 50 for each edge, an equation defining that edge. These edge-defining equations are stored in individual registers, e.g. as shown at 29L, 29M and 29N, forming part of the computer and the incoming co-ordinates entering at 29E 55 of the top of the scanning spot are tested against these equations. When an equation defining a particular edge is satisfied the face identity to the right of that edge (determined by the information entering at 291) is entered 60 in a "current face for display" register 290 (also forming part of the computer) and the face identity to the left of the edge is erased from this register. Thus the register 290 contains the identities of all faces projected by 65 the circuit 26 onto a point of the projected plane corresponding to the current top point of the raster spot, it will be appreciated that more than one such face will be projected onto the same spot where one face obscures 70 another.
The part 29Q of the display processor 29 receives at 29P, from the picture processor 25, a description of all the projected faces and these are arranged under the control of 75 the computer program in the table 29Q similar to that shown at 9 on Fig. 1. The contents of register 290, e.g., the identities of faces (i) and (ii), i.e., the faces projected onto the same position as the current position of the 80 top of the spot are used to read out from the register 29Q the colour, brightness, texture and the four priorities of each of the faces. This information is presented to a priority selector 29R which receives a signal 29S 85 from the scenario processor indicating within which angle (a), (b), (c) or (d) the observer is looking. The priority selector selects that face in register 29F having the highest priority for that particular angle (a), (b), (c) or (d) of view. 90 It also eliminates any faces whose direction vector is pointing away from the observer. The colour and brightness of the selected face are presented to inputs of respective adders 29T and 29U.
95 The adders 29T and 29(J also receive other colour and brightness inputs from the circuits 29B, 29C and 29D which operate in the same way as 29A but receive signals 29F, 29G and 29H representing the co-ordinates of 100 parts of the raster spot at other positions between the top and bottom thereof. The outputs of the adder 29T and 29U are divided by four at 29V and 29W to obtain the average colour and brightness values from the 105 parts 29A, 29B, 29C and 29D. This averaging process avoids edges which are neither horizontal nor vertical having a stepped appearance as would be the case if the colour and/or brightness were changed abruptly at 110 the instant when, say, the centre of the raster line crosses the edge concerned. Hitherto, proposals have been made, for example in US Patent Specification 4208719, resolving the problem of a "stepped edge" by smoothing 115 the stepped video signal so as to hide the steps. This procedure, however, (known as edge smoothing) requires some means for varying the degree of smoothing according to the slope of the edge: since no smoothing is 120 required for a vertical edge.
The display processor 29, shown in Fig. 5, does not use an edge smoothing technique in that it does not generate a video signal defining a stepped edge, which is subsequently 125 smoothed to remove the steps. Instead it avoids generating a stepped edge in the first place. The effect of the processor 29 is illustrated by Fig. 6 which shows the edge L, between faces (i) and (ii); and two adjacent 130 raster lines of finite width w intersecting this
edge L,. A raster spot is shown in four positions which is adopted at times T1( T2, T3 and T4 respectively as 31, 31 A, 31B and 31C. And it is the co-ordinates of points X,, X2 X3 5 and X4 of this spot which are represented by the four signals 29E to 29H entering respective display processor parts 29A to 29D. Thus the outputs of processor part 29A will change at time T1# the outputs of 29B will change at 1 0 T2, the outputs of 29C will change T3 and the outputs of 29D will change at T4. Hence the average outputs from 29V and 29W change colour and brightness in a series of four different jumps during the period when the 15 scanning spot is crossing the edge. The colour and brightness values of the raster spot therefore change gradually as the spot crosses a sloping edge between faces; thereby avoiding the stepped configuration previously referred 20 to. In the case of a vertical edge, all the points X, to X4 cross the edge simultaneously thereby producing the sudden colour changes required for a vertical edge. In the case of a horizontal edge bridged by the raster spot, the 25 latter automatically adopts an average colour of those faces above and below the edge. The brightness and colour signals from circuits 29V and 29W and th x,y deflection signals 29G are processed in a circuit 29X so as to 30 split them into two separate sets of signals for driving respective optical projectors 30A and 30B after being converted to analogue form at 29Y and 29Z.
35 Optical Projectors
Each of the optical projectors 30A and 30B projects half of the picture to be simulated on the screen 1 and consists of three cathode ray tubes which respectively handle red, blue and 40 green colours. One of the cathode ray tubes is shown in Fig. 7 and has the usual inputs for x and y deflection signals 30C and 30D and for the brightness signal 30E. The inside surface of a front face 30F of the cathode raye tube 45 bears a phospher layer 30G and its out surface is in contact with a body of water contained within a chamber 30H. The water chamber 30H is formed by a metal sleeve 30I and one end 30J of this sleeve passes around 50 the perimeter of the face 30F. The other end 30K projects in front of the face 30F. The sleeve 30I is secured to and sealed with respect to the glass wall of the cathode ray tube by adhesive 30L. The front end 30K of 55 the sleeve is rebated to receive a glass window 30M and a tubular lens holder SON. The latter has a flange 30P by which it is bolted to the sleeve 30!. The holder 30N receives a lens assembly shown schematically at 30Q 60 and incorporating a spherical and aspherical lens to provide the correct optical characteristics for projection of an image onto a convex rear surface of a screen to be described later. The lens assembly 30Q is spaced from the 65 window 30M by a step formed on the inner side of the holder 30N.
The water is circulated through the chamber 30H by a pump 30R and is maintained at a desired temperature by a thermostatically con-70 trolled cooler 30S. It has been found that, by using this technique, the tube can be operated at a very high brightness level without the glass face 30F cracking. The reasons for the success of the illustrated system is be-75 lieved to be connected with the high heat capacity of the water and its flow characteristics which allow it effectively to transfer heat from hot to relatively cool areas of the front face of the cathode ray tube. Also, because 80 the water flowing past the front face of the cathode ray tube is confined by the window to a region in close proximity with a cathode ray tube, water aquiring heat from hot parts thereof is likely to transfer this hear to the 85 cooler parts.
Fig. 8 shows the screen 1 onto which a picture to be displayed is projected by the 90 projectors 30A and 30B. The screen is part cylindrical in shape and has a layer 1A of translucent material on its side closest to the projectors. This layer 1A serves as a diffuser of light. The observer 2 is located at the 95 centre of curvature of the part cylindrical screen which has a radius D chosen to be sufficiently large to ensure that the projected image on the screen gives a sufficiently approximate illusion of being at infinity. This is 100 because most of the images to be displayed are intended to be of distant objects and features. It is important to note that no diffuser is perfect and that more light incident on it in a given direction continues travelling 105 close to that direction after diffusion than is diffused in any particular direction to the left or to the right. Thus, if one ignores the effect of the member 1B, to be described later, the observer 2 will receive a higher proportion of 110 the light diffused from points 1C and 1D than from points 1E and 1F. This is because light received by the observer from the points 1 E and 1F is diffused through a large angle whilst that from the points 1C and 1D is 115 diffused not at all. Thus, in the illustrated system, the picture would, but for the presence of the member 1 E, appear to an observer 2 to be brighter at positions near 1C and 1D than near positions 1 E and 1F. This in 120 itself is a disadvantage but a much greater problem arises if the observer moves towards positions 2A or 2B, i.e., to the left or to the right. When the observer is at the position 2A the point 1E is directly in line with the projec-125 tor 30B and so the point 1E appears relatively bright. However, light received by the observer at 2A from point 1E has been diffused through a large angle so point 1E appears relatively dim. The observer thus sees a verti-130 cal line down the centre of the screen dividing
relatively bright areas illuminated by projector 30B from relatively dim areas illuminated by projector 30A. The aforementioned explanation assumes that the desired brightness of 5 the simulated picture is constant over the whole screen. In practice this is, of course, not often the case but the effects described above often appear to a greater or lesser degree.
10 The problem described in the immediately preceding paragraph is mitigated by the use of the part cylindrical transparent sheet 1B. This is located immediately in front of the diffuser 1A. The sheet 1B, which is of uni-1 5 form thickness, is machined to form a series of vertical grooves. Each groove has a side 1G which is approximately in alignment with the observer 2 and a side 1 H which is inclined with respect to the rear surface 11 of the 20 acrylic sheet. The angle of inclination varies from groove to groove and is smallest near points 1C and 1 D in line with the projectors and the observer 2. The angle progressively increases with increasing distance from these 25 points 1C and 1D. The direction of inclination of any one face is away from the straight line between the observer 2 and the projector illuminating that face. Thus, each inclined face 1H defines, with the rear surface 11, a 30 prism which deflects light derived from one of the projectors towards the straight line between the projector and the observer 2. Each part of the sheet 1 B, illuminated by a given projector 30A or 30B, can be considered to 35 constitute a cylindrical lens which tends to focus (and would focus but for the diffusion effects of the screen 1 A) light from that projector onto the observer position 2.
Considering now the points 1 E and 1 F, as 40 observed from 2A, the maximum intensity of the diffused light is propagated in the directions of lines 1J and 1 K which are almost parallel. Thus, the observer at 2A is offset from these directions by approximately equal 45 angles; causing equal reductions in the brightness of the points 1 E and 1 F. The sharp dividing line previously mentioned is thus eliminated. Similar comments apply to the observer when he moves to or towards the 50 position 2B.
The grooves machined in the sheet 1 B may vary in depth and/or width. As an alternative to forming such grooves the rear surface of the member 1B may be continuously varying 55 in inclination with respect to the rear face or vice versa as shown in Figs. 9 and 10.
Another possiblity would be to form the grooves on the rear face. The diffuser 1A can be either to the rear or to the front of the 60 member 1B or could be dispensed with if the member 1 B were itself capable of diffusing the incident light. It could be surface treated for this purpose.
In some circumstances it may be desired to 65 have a screen which extends through a larger arc than that illustrated. In this case further projectors could be used and the screen would be formed of more than the two sections illustrated.
1. A computer generated imagery system having: a data base containing descriptions of polygonal faces defining an object or scene to
75 be depicted by an image, the description of each face including a code defining a priority value defining its capability of obscuring other faces; means for defining the position relative to said object or scene of an observation
80 point, and means for preventing display of a face having the lower priority value when two faces lie on a line of sight through the observation point: characterised in that the description of each face includes a plurality of codes
85 defining respective different priority values for different angles of view.
2. A computer generated imagery system according to claim 1 and substantially as described with reference to Figs. 1 and 2 of
90 the accompanying drawings.
GB2100100A true true GB2100100A (en) 1982-12-15
GB2100100B GB2100100B (en) 1985-08-21