Abstract:
A map display apparatus includes a map data memory which stores map data necessary for plotting a map of a predetermined region; a map display which reads map data out of the map data memory and plots a bird&#39;s-eye view display by projecting the map data read out from the map data memory onto a projection plane which makes a projection angle with a plane of the map data read out from the map data memory, the projection angle being greater than 0° and less than 90°, the bird&#39;s-eye view display including identifying marks which identify items in the bird&#39;s-eye view display; and an identifying mark overlap preventer which prevents identifying marks from overlapping one another in the bird&#39;s-eye view display.

Description:
CROSS-REFERENCES TO RELATED APPLICATIONS 
     The present application is a continuation of application Ser. No. 09/932,951, filed Aug. 21, 2001, now U.S. Pat. No. 6,603,407, which is a continuation of application Ser. No. 09/320,556 filed on May 27, 1999, now U.S. Pat. No. 6,278,383, which is a divisional of application Ser. No. 08/636,767 filed on Apr. 19, 1996, now U.S. Pat. No. 5,917,436, the contents of which are incorporated herein by reference in their entirety. 
    
    
     BACKGROUND OF THE INVENTION 
     This invention relates to a map display apparatus for use in a navigation system for measuring the position of a mobile body and reporting the present position to a user, and more specifically to a bird&#39;s-eye view map display apparatus which provides a map in a more comprehensible way to the user. 
     A navigation apparatus mounted to a mobile body processes information from a variety of sensors to measure the position of the mobile body and reports the position to a user. This navigation apparatus comprises position measurement means for measuring the absolute position of a mobile body, memory means for storing map data constituted by two-dimensional vector data obtained by projecting points on the ground such as roads and buildings on a plane divided into meshes by universal transverse Mercator projection and character data accompanying the two-dimensional vector data, input means for receiving commands from the user, and display means for reading the necessary vector data from the map mesh stored in the memory means in accordance with the command inputted from the input means and conversion processing the data to display the map on a display. Here, data conversion processing includes movement conversion for changing the display position of the map, reduced scale conversion, such as enlargement and reduction, used for displaying the map in an arbitrary reduced scale and rotation conversion for changing the displaying direction of the map. By means of these processings, a plan view map depicting the ground surface directly overhead by normal projection is displayed on the display. 
     In navigation apparatuses, according to the prior art, plan view map display which depicts a map by normal projection directly overhead has been employed to display the map. When two points spaced apart from each other are simultaneously displayed, therefore, a reduced scale becomes unavoidably great and detailed information cannot be displayed. One of the means for solving this problem is a bird&#39;s-eye view display system which displays a map when points having a certain height from the ground surface are looked down obliquely from afar on a plane. In order to apply this bird&#39;s-eye view display to the navigation apparatuses, the following problems must be solved. 
     First, in the case of the bird&#39;s-eye view display which displays a broader range of regions than the plan view map, a reduced scale becomes great at points far from the start point, so that a greater quantity of information is displayed. According to the prior art systems, character strings of those regions in which the reduced scale becomes great are not displayed or the character strings in the proximity of a viewpoint are merely displayed at the upper part. For this reason, fall-off of characters and overlap of character strings are unavoidable, and recognizability of the characters by the user drops. 
     Secondly, background data and character data are constituted in the map database so that display quality attains the highest level when the plan view map is displayed. Therefore, in the bird&#39;s-eye view map display displaying a broader range of regions, the frequency of the occurrence that the same character strings are displayed at a plurality of positions becomes higher. Since no counter-measure has been taken in the past for the same character string, the same character string is unnecessarily displayed and this unnecessary character string hides the roads and other background data. In consequence, display quality gets deteriorated. 
     Thirdly, though a route to the destination is displayed in superposition with the map in a different color from those of the background roads, all the route data are displayed with the same line width in the past because the concept of the road width does not exist in the vector data expressing the routes. However, because the map is expressed three-dimensionally in the bird&#39;s-eye view display, the feel of three-dimensional depth will be lost if all the routes are displayed by the same line width. 
     In the fourth place, in the display of a driving orbit, it has been customary in the prior art to store the position information of driving in a certain distance interval and to display the points representing the driving orbit on the basis of the position information so stored. When the driving orbit is displayed by the method of the prior art system on the bird&#39;s-eye view map, however, the gap of the point strings representing the orbit is enlarged in the proximity of the viewpoint at which the reduced scale becomes small, and the user cannot easily recognize which route he has taken. The gap of the dot strings becomes unnecessarily narrow, on the contrary, at portions away from the viewpoint at which the reduced scale becomes great, and the roads and the character strings as the background information are hidden. Therefore, the user cannot easily recognize the map information, either. 
     In the fifth place, pattern information, e.g. solid lines and dash lines, used for displaying the vector information such as roads, railways, administrative districts, etc., and pattern information, e.g. check and checkered patterns, used for displaying polygons representing water systems, green zones, etc., are registered to the map data base. When the map containing these pattern information is displayed by bird&#39;s-eye view, the prior art systems execute not only perspective conversion of each apex coordinates constituting the lines and the polygons but also perspective conversion of the patterns for displaying the map. Therefore, the processing time becomes enormously long, and the time required for bird&#39;s-eye map display gets elongated. 
     In the sixth place, in order to prevent dispersion of the map data displayed near an infinite remote point called a “vanishing point” in the bird&#39;s-eye map display, the display region is limited to the foreground region by a predetermined distance from the vanishing point and artificial background information such as a virtual horizon and sky are displayed at the depth in the prior art system. However, these artificial background information in the prior art systems have fixed patterns or fixed colors and do not match the surrounding conditions. 
     In the seventh place, when the bird&#39;s-eye view map display and the plan view map display are switched, the user cannot easily discriminate which of them is actually displayed when the number of objects plotted is small. Moreover, the user can operate and change the position of the viewpoint in the bird&#39;s-eye view map display, and the map region actually displayed greatly changes depending on the position of the viewpoint and on the direction of the visual field. In the prior art systems, however, there is no means for providing the information of the position of the viewpoint, etc., even when the position of the viewpoint and the direction of the visual field are changed, and the systems are not easy to handle. 
     In the eighth place, when the bird&#39;s-eye view map is displayed, the map displaying direction is set in such a manner that the image display direction coincides with the driving direction, as described, for example, in JP-A-2-244188. When the destination is set, the driving direction and the direction of the destination are not always coincident, so that the destination disappears from the screen. Accordingly, there remains the problem that the user cannot recognize the map while always confirming the direction of the destination. 
     In the conventional bird&#39;s-eye view map display, in the ninth place, even when a map information density is low in a certain specific direction or when a specific direction comprises only information having specific attributes, the display position of the viewpoint, that is, the display position of the present position, does not change on the screen. In other words, there occurs the case where a large quantity of information, which are not much significant, are displayed on the display region having a limited area, and the information cannot be provided efficiently. 
     SUMMARY OF THE INVENTION 
     To solve the first problem, the present invention uses means for judging whether or not overlap occurs between character strings or symbols, and selecting and displaying character strings or symbols having predetermined attributes when overlap exists, or selecting and displaying character strings or symbols in the proximity of the viewpoint, or replacing the overlapping character strings or symbols by a font size smaller than the recommended font size. The character overlap judgment means uses means for judging that the character strings overlap by using rectangular region information circumscribed with the character strings when the mutual circumscribed rectangular regions overlap, or judges that the character strings overlap by using rectangular region information of rectangles positioned more inside by a predetermined distance from the rectangles circumscribed with the character strings when mutual rectangle regions overlap. 
     To solve the second problem, the present invention uses means for judging whether or not the same character strings or symbols exist inside the screen displaying a certain bird&#39;s-eye view map, and selecting and displaying character strings in the proximity of the viewpoint when the same character string or symbol exists. It is effective to display both the character strings or symbols if the mutual distance is great even when the same character strings or symbols exist. Accordingly, the present invention uses means for selecting and displaying character strings in the proximity of the viewpoint when the distance between the same character strings or symbols or the distance between them in the bird&#39;s-eye view map display is judged as existing within a predetermined range, and for displaying both of the character strings or the symbols when the distance is judged as existing outside the range. 
     To solve the third problem, the present invention uses means for displaying routes in the proximity of the viewpoint by thicker lines than routes apart from the viewpoint when the routes are displayed on the bird&#39;s-eye view map. Alternatively, the present invention uses means for dividing the bird&#39;s-eye view map into a plurality of regions and displaying routes by a line width inherent to each region when the routes to be displayed in superposition in these regions are displayed. 
     To solve the fourth problem, the present invention uses means for obtaining an orbit which supplements the stored orbit information for the driving routes in the proximity of the viewpoint, and displaying the orbit in superposition with the bird&#39;s-eye view map. As to driving orbits away from the viewpoint, on the other hand, the present invention uses means for thinning out the stored orbit information and displaying the orbits so thinned out in superposition on the bird&#39;s-eye view map. 
     To solve the fifth problem, the present invention uses means for executing perspective conversion the lines constituting the map data and each apex coordinates constituting polygons, and displaying the polygons or the lines by using the patterns used for plan view map display by using the coordinates values after perspective conversion. 
     To solve the sixth problem, the present invention uses means for limiting display of the map in the foreground regions by a predetermined distance from the vanishing point and changing the colors or patterns of the artificial background such as the horizon and the sky to be displayed at the depth. More concretely, the present invention uses means for changing the colors or the patterns of the artificial background information by a blue color representing the sky when lamps are not lit and by a black or grey color when the lamps are lit, by using signals representing the condition of the car, that is, light turn ON/OFF signal of the car. 
     To solve the seventh problem, the present invention uses means for causing a map display control portion to switch the bird&#39;s-eye view map and the plan view map in accordance with a user&#39;s request, and causing a menu display portion, which displays a mark in superposition with the map, to receive the change of the display state of the map and to display the mark representing the plan view map in superposition with the map when the map is switched from the bird&#39;s-eye view map to the plan view map. When the map is switched from the plan view map to the bird&#39;s-eye view map, the mark representing the bird&#39;s-eye view map is displayed in superposition with the map. When the user changes the position of the viewpoint during the display of the bird&#39;s-eye view map, the shape of the mark representing the present position is changed and is displayed in superposition with the map. 
     To solve the eighth problem, the present invention promotes the user to set the destination. After setting of the destination is completed, the direction of the viewpoint is brought into conformity with the direction of the destination from the position of the viewpoint, and the position/direction of the viewpoint and the projection angle are calculated so that the map of predetermined regions is displayed by the bird&#39;s-eye view map. Even when the present position is updated, the processing described above is always executed repeatedly to bring the position of the viewpoint into conformity with the present position and to display the bird&#39;s-eye view map. 
     To solve the ninth problem, a region inside the bird&#39;s-eye view map, which has a low map information density, and a region constituted by information having only specific attributes are retrieved. When these regions are retrieved, the position of the viewpoint is changed so that the region having a low map information density and the region comprising only the information of the specific attributes do not occupy a large area on the display screen. The bird&#39;s-eye view map is displayed by using the information of the position of the viewpoint and the projection angle so obtained. 
     When overlap exists between the character strings in the bird&#39;s-eye view map display, the first means displays one of them, or displays the overlapping character strings by changing their size to the smaller fonts. 
     When the same character strings or symbols exist in the bird&#39;s-eye view map display, the second means selects and displays the character strings closer to the viewpoint. 
     In the bird&#39;s-eye view map display, the third means so functions as to display the guiding route near the viewpoint by a greater line width than the guide routes existing away from the viewpoint. 
     In the bird&#39;s-eye view map display, the fourth means so functions as to display the dot strings representing the driving orbit with suitable gaps between the region near the viewpoint and the region far from the viewpoint. 
     In the bird&#39;s-eye view map display, the fifth means so functions as to speed up the display of pattern lines and polygons in which patterns exist. 
     In the bird&#39;s-eye view map display, the sixth means so functions as to display the artificial background in different colors or different patterns in accordance with the condition of the car. 
     In the bird&#39;s-eye view map display, when the bird&#39;s-eye view map and the plan view map are mutually switched, the seventh means so functions as to change the shape of the mark to be displayed in superposition with the map in the direction of the position of the viewpoint and the visual field. 
     In the bird&#39;s-eye view map display, the ninth means so functions as to reduce the occupying area of the regions having a low map information density or comprising only information of specific attributes. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1, shows a bird&#39;s-eye view map display according to an embodiment of the present invention; 
     FIG. 2 is an explanatory view showing a perspective conversion processing of a map; 
     FIGS. 3A,  3 B,  3 C and  3 D are explanatory views showing a perspective conversion process of a map; 
     FIG. 4 is a structural view of a navigation apparatus according to an embodiment of the present invention; 
     FIG. 5 is a hardware structural view of an arithmetic processing portion of the embodiment of the present invention; 
     FIG. 6 is an explanatory view showing appearance of a navigation apparatus according to an embodiment of the present invention; 
     FIG. 7 is a functional structural view of an arithmetic processing portion for accomplishing bird&#39;s-eye view map display; 
     FIG. 8 is a flowchart of map plotting means for accomplishing bird&#39;s-eye view map display; 
     FIG. 9 is a flowchart of coordinates conversion means for accomplishing bird&#39;s-eye view map display; 
     FIG. 10 is a flowchart of perspective conversion computation for accomplishing bird&#39;s-eye view map display; 
     FIG. 11 is a flowchart of display position computation for accomplishing bird&#39;s-eye view map display; 
     FIG. 12 is a flowchart of plotting judgment means for accomplishing bird&#39;s-eye view map display; 
     FIGS. 13A and 13B are flowcharts of polygonal and linear pattern displays in bird&#39;s-eye view map display; 
     FIG. 14 is a flowchart of character string display in bird&#39;s-eye view map display; 
     FIG. 15 is a flowchart of character plotting means; 
     FIGS. 16A,  16 B,  16 C and  16 D show an embodiment for character fringing display for representing one character by a plurality of characters; 
     FIGS. 17A and 17B show an embodiment for character clipping processing; 
     FIGS. 18A to  18 J show an embodiment for display means of a fringed character; 
     FIG. 19 is a flowchart of a route display in bird&#39;s-eye view map display; 
     FIG. 20 is a flowchart of orbit display in bird&#39;s-eye view map display; 
     FIG. 21 is a flowchart of artificial background display in bird&#39;s-eye view map display; 
     FIG. 22 is a flowchart of mark display in plan view map display and bird&#39;s-eye view map display; 
     FIGS. 23A,  23 B and  23 C are explanatory views useful for explaining a setting method of a viewpoint and a projection plane in bird&#39;s-eye view map display; 
     FIGS. 24A,  24 B, and  24 C are explanatory views useful for explaining a setting method of a viewpoint and a projection plane in bird&#39;s-eye view map display; 
     FIGS. 25A and 25B show an embodiment for optimization display of the present position in bird&#39;s-eye view, map display; 
     FIGS. 26A,  26 B,  27 A,  27 B,  28 A,  28 B,  29 A and  29 B show an embodiment for character string overlap judgment in bird&#39;s-eye view map display; 
     FIGS. 30A,  30 B,  31 A,  31 B,  32 A,  32 B;  33 A and  33 B show an embodiment for character string overlap judgment in bird&#39;s-eye view map display; 
     FIGS. 34A,  34 B,  35 A,  35 B,  36 A,  36 B,  37 A and  37 B show an embodiment for character string overlap judgment in bird&#39;s-eye view map display; 
     FIGS. 38A,  38 B and  38 C show an embodiment for avoiding character string overlap display in bird&#39;s-eye view map display; 
     FIGS. 39A and 39B show an embodiment for avoiding character string overlap display in bird&#39;s-eye view map display; 
     FIGS. 40A,  40 B,and  40 C show an embodiment for displaying the same character string in bird&#39;s-eye view map display; 
     FIGS. 41A,  41 B, and  41 C show an embodiment for polygonal and linear pattern display in bird&#39;s-eye view map display; 
     FIGS. 42A and 42B show an embodiment for route display in bird&#39;s-eye view map display; 
     FIGS. 43A and 43B show an embodiment for orbit display in bird&#39;s-eye view map display; 
     FIGS. 44A and 44B show an embodiment for artificial background display in bird&#39;s-eye view map display; 
     FIGS. 45A and 45B show an embodiment for mark display in plan view map display and bird&#39;s-eye view map display; and 
     FIGS. 46A and 46B show an embodiment for present position mark display in bird&#39;s-eye view map display. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1 shows an example of the bird&#39;s-eye view map displayed by a bird&#39;s-eye view map display device mounted to a navigation system according to an embodiment of the invention. The bird&#39;s-eye view map display device according to this embodiment generates a bird&#39;s-eye view  102  showing a bird&#39;s-eye view from a specific position as a projection chart of two-dimensional map data (indicated by reference numeral  101  in FIG.  1 ), and displays it on a display screen of a display  2 . Incidentally, in the bird&#39;s-eye view  102  shown in FIG. 1, a folded line  103  is provided with a thick line and is highlighted in order to represent a guiding route. An artificial background  104  represents the sky, a mark  105  represents the present position and an orbit mark  106  represents the orbit of a car so far driven. Further, arrows in FIG. 1 represent the relationship of projection from the two-dimensional map data  101  to the bird&#39;s-eye view  102 . 
     The outline of bird&#39;s-eye view map display as the characterizing feature of the present invention will be explained with reference to FIG.  2 . 
     In printed map charts or in the navigation systems according to the prior art, a map is represented by a plan map display obtained when a given area is viewed from an infinitely remote point above this area. Because this plan map display has the advantage that a reduced scale is constant irrespective of points inside the same display screen, the feel of distance is easy to grasp. When an area between certain two points is represented on the same screen, however, the operation for adjusting and optimizing the reduced scale of the map display becomes necessary, and if the distance between these two points is great, only limited information can be displayed because the quantity of information that can be displayed at one time is restricted by the size of the display used and the level of its precision. Bird&#39;s-eye view display is employed as means for solving this problem. When this bird&#39;s-eye view display is used, the information of those portions which are close to the viewpoint is enlarged while the information of those remote from the viewpoint is reduced, as is obvious from FIG.  2 . Therefore, when the area between certain two points is displayed on the same screen, the point for which more detailed information is required is situated close to the viewpoint with the other being remote from the viewpoint, and their mutual positional relationship is represented in an easily comprehensible form by displaying the two points on the same screen. Further, a greater quantity of information can be provided to the user on the information near the viewpoint. This bird&#39;s-eye view display can be accomplished by effecting perspective conversion which projects two or three-dimensional map information of a plane A to a plane B describing a certain angle θ with the plane A. Since two-dimensional map data can be used as the map information used, bird&#39;s-eye view display is feasible by adding the perspective conversion function to existing navigation systems without adding new map data, but various contrivances must be made when the bird&#39;s-eye view display is put into practical use. 
     FIG. 4 shows a structural example of a navigation apparatus for a mobile body to which the present invention is applied. 
     Hereinafter, each structural unit of this navigation apparatus will be explained. A processor unit  1  detects the present position on the basis of the information outputted from various sensors  6  to  9 , reads the map information necessary for display from a map memory unit  3  on the basis of the present position information so detected, graphically expands the map data, displays this data on a display  2  by superposing a present position mark, selects an optimum route connecting the destination indicated by the user to the present position and guides the user by using a speech input/output device  4  or the display  2 . In other words, it is a central unit for executing various processings. The display  2  is the unit which displays the graphic information generated by the processor unit  1 , and comprises a CRT (Cathode-Ray Tube) or a liquid crystal display. A signal S 1  between the processor unit  1  and the display  2  is generally constituted by RGB signals or NTSC (National Television System Committee) signals. The map memory device  3  comprises a large capacity memory medium such as a CD-ROM or an IC card and executes read/write processing of the required map data. S 2  is a signal between the processor unit  1  and the map memory device  3 . The speech input/output device  4  converts the message to the user generated by the processor unit  1  to the speech signals, outputs them, recognizes the user&#39;s voice and transfers it to the processor unit  1 . S 3  is a signal between the processor unit  1  and the speech input/output device  4 . An input device  5  is the unit that accepts the user&#39;s instruction, and comprises hard switches such as scroll keys  41 , reduced scale keys  42  and angle changing keys  43  shown in FIG. 6, for example, a joystick, touch panels bonded on the display  2 , or the like. S 4  is a signal between the processor unit  1  and the input device  5 . The sensors used for detecting the position in the navigation system for a mobile body comprise a wheel speed sensor  6  for measuring the distance from the product of the circumference of a wheel and the number of revolutions of the wheel and measuring a turning angle of the mobile body from the difference of the numbers of revolutions of the wheels forming a pair, a terrestrial magnetic sensor  7  for detecting the magnetic field of the earth and detecting the moving direction of the mobile body, a gyro sensor  8  for detecting the turning angle of the mobile body such as an optical fiber gyro or an oscillation gyro, and a GPS receiver  9  for receiving signals from a GPS satellite, measuring the distance between the mobile body and the GPS satellite and the change ratio of this distance for at least three satellites and thus measuring the present position of the mobile body, its traveling direction and its course. The input device further includes a traffic information receiver  10  for receiving signals from beacon transmitters and FM multiplex broadcasting that transmit weather information and traffic information such as road jamming information, closed-to-traffic information, parking lot information, etc., and outputting received information S 9  to the processor unit  1 . Furthermore, an internal LAN device  11  is provided so as to receive various information of the car such as door open/close information, the information on the kind and condition of lamps turned ON, the information of the engine condition, the information on the result of trouble-shooting, and so forth, and output car information S 10  to the processor unit  1 . 
     FIG. 5 is an explanatory view showing the hardware construction of the processor unit. 
     Hereinafter, each constituent element will be explained. The processor unit  1  employs the construction wherein devices are connected by a bus. The devices include a CPU  21  for executing computation of numerical values and controlling each device, a RAM  22  for storing the map and the operation data, a ROM  23  for storing the program and the data, a DMA (Direct Memory Access)  24  for executing data transfer at a high speed between the memory and the memory and between the memory and each device, a plotting controller  25  for executing at a high speed graphic plotting such as expansion of vector data to pixel information, etc., and for executing display control, a VRAM  26  for storing graphic image data, a color palette  27  for converting the image data to the RGB signals, an A/D converter  28  for converting analog signals to digital signals, an SCI  29  for converting serial signals to parallel signals in synchronism with the bus, a PIO  30  for establishing synchronism with the parallel signal and putting it on the bus, and a counter  31  for integrating pulse signals. 
     FIG. 7 is a explanatory view useful for explaining the functional construction of the processor unit  1 . 
     Hereinafter, each constituent element will be explained. Present position calculation means  66  integrates on the time axis the distance data and the angle data obtained by integrating the distance pulse data S 5  measured by the wheel speed sensor  6  and the angular velocity data S 7  measured by the gyro  8 , respectively, and calculates the position (X′, Y′) after driving of the mobile body from the initial position (X, Y). In order to bring the rotating angle of the mobile body into conformity with the azimuth of driving, the azimuth data S 6  obtained from the terrestrial magnetic sensor  7  and the angle data obtained by integrating the angular velocity data from the gyro  8  are mapped on the 1:1 basis, and the absolute azimuth of the driving direction of the mobile body is corrected. When the data obtained from the sensors described above are integrated on the time axis, the sensor errors accumulate. Therefore, a processing for canceling the errors so accumulated is executed in a certain time interval on the basis of the position data S 8  obtained from the GPS receiver  9 , and the present position information is outputted. Since the present position information acquired in this way contains the sensor errors, map-match processing means  67  executes map-match processing so as to further improve positional accuracy. This is the processing which collates the road data contained in the map in the proximity of the present position read by the data read processing means  68  with the driving orbit obtained from the present position calculation means  66 , and brings the present position to the road having the highest similarity of shape. When this map-match processing is executed, the present position coincides in most cases with the driving road, and the present position information can be accurately outputted. The present position information calculated in this way is stored in orbit memory means  69  whenever the mobile body drives a predetermined distance. The orbit data is used for plotting an orbit mark on the road on the corresponding map for the road through which the mobile body has run so far. 
     On the other hand, user operation analysis means  61  accepts the request from the user by the input device  5 , analyzes the content of the request and controls each unit so that a processing corresponding to the request can be executed. When the user requests to guide the route to the destination, for example, it requires the map plotting means  65  to execute processing for displaying the map for setting the destination and further requests route calculation means  62  to execute processing for calculating the route from the present position to the destination. The route calculation means  62  retrieves a node connecting between two designated points from the map data by a Dijkstra algorithm, etc., and stores the route so obtained in route memory means  63 . At this time, it is possible to determine the route in which the distance between the two points is the shortest, the route through which the destination can be reached within the shortest time or the route through which the driving cost is the lowest. Route guiding means  64  compares the link information of the guide route stored in the route memory means  63  with the present position information obtained by the present position calculation means  66  and the map match processing means  67  and notifies to the user whether or not to drive straight or whether or not to turn right or left before passing by a crossing, etc., by the speech input/output device  4 , displays the traveling direction on the map displayed on the display, and teaches the route to the user. Data read processing means  68  so operates as to prepare for reading the map data of the requested region from the map memory device  3 . Map plotting means  65  receives the map data around the point for which display is requested from the data read processing means  68  and transfers the command for plotting the designated object in the reduced scale, the plotting direction and the plotting system that are designated, respectively, to graphic plotting means  71 . On the other hand, menu plotting means  70  receives a command outputted from the user operation analysis means  61  and transfers a command for plotting various kinds of requested menus and marks to be displayed in overlap with the map to graphic processing means  71 . The graphic processing means  71  receives the plotting commands generated by the map plotting means  65  and the menu plotting means  70 , and expands the image on the VRAM  26 . 
     FIG. 8 is an explanatory view useful for explaining the functions of the map plotting means  65 . 
     Hereinafter, each constituent element will be explained. Display region judgment means  81  decides the display reduced scale of the map and decides also which region should be displayed with which point of the map data as the center. Initial data clip means  82  selects, by clip processing, the data necessary for display from the line data, the plan data and the character data representing objects such as roads, buildings, etc., necessary for subsequent processings from each mesh of the map data read out by the data read processing means  68  from the map memory device  3 , the line data comprising recommended routes and stored in the route memory means  63  and the point data comprising driving orbits and stored in the orbit memory means  69 , on the basis of the information set by the display region judgment means  81 . The clip processing algorithms hereby used include a Cohen-Sutherland line clip algorithm for the line and point data and a Sutherland-Hodgman polygon clip algorithm for the plan and character data (Foley et al., Computer Graphics, pp. 111-127, Addison-Wesley Publishing Company). This processing can reduce the data quantity which should be subsequently subjected to coordinates conversion and plotting processing and can improve a processing speed. 
     Coordinates conversion means  83  enlarges or reduces the map data obtained by the clip processing to the target size and when an object must be displayed by rotating it, this means  83  so functions as to effect affine conversion of each coordinates value of the map data. Plotting judgment means  84  so functions as to select those data which are practically necessary for plotting by using the map data obtained by the coordinates conversion means  83 . When the reduced scale is great, for example, the data quantity to be plotted substantially increases. Therefore, this means  84  so functions as to omit small roads and the names of places which may be omitted, and to eliminate character strings that are displayed in superposition with one another. Data clip means  85  so functions as to select the map data relating to the plotting area from the map data obtained from the plotting judgment means  84 , by clip processing. The clip processing algorithm hereby used may be the same algorithm used by the initial data clip means. Further, this processing may be omitted. Artificial background setting means  86  provides the function which is necessary for bird&#39;s-eye view map display and displays the artificial background such as the horizon, the sky, etc., in order to reduce the plotting data quantity and to improve the screen recognition property. Plotting command generation means  87  generates commands for plotting lines, polygons, characters, etc., so as to plot the resulting point, line and plane data as well as the character data by the designated colors and patterns, and the command for setting the colors and the patterns and outputs them to the graphic processing means  71 . 
     Next, the fundamental display system of the bird&#39;s-eye view map display will be explained with reference to FIGS. 3A,  3 B,  3 C,  3 D and FIG.  8 . 
     At first, the region for bird&#39;s-eye view display is decided by the display region judgment means  81  from the position of the viewpoint and the direction of the visual field and from the angle θ (projection angle) described between the plane A and the plane B in FIG. 2 (step  1  in FIG.  3 A). When a bird&#39;s-eye view is displayed on a rectangular display, map data of a narrow region is necessary for the area near the viewpoint and map data of a broad region is necessary for the area remote from the viewpoint. Therefore, the map data of a trapezoidal mesh region in the drawings is plotted finally. Next, the necessary map data is extracted by the initial data clip means  82  from the map mesh data inclusive of the region for bird&#39;s-eye view display by using the rectangular regions which are circumscribed with the trapezoidal region to be practically plotted (step  2  in FIG.  3 B). Next, the coordinates conversion means  83  enlarges or reduces the extracted data and then executes affine conversion so that the trapezoid stands upright. Further, perspective conversion is executed so as to convert each coordinates value of the map data to the data which is represented three-dimensionally (step  3  in FIG.  3 C). In this instance, perspective conversion is expressed by the following equations (1) and (2) where the position coordinates of the viewpoint are (Tx, Ty, Tz), the angle between the plane A and the plane B is θ, the map data coordinates values before conversion are (x, y) and the map data coordinates values after conversion are (x′, y′):                x   ′     =         T   x     +   x         T   z     +       y              ·   sin                   θ                 (   1   )                                              y   ′     =         T   y     +       y   ·   cos                   θ           T   z     +       y              ·   sin                   θ                 (   2   )                                 
     The trapezoid represented at the step  2  in FIG. 3B is subjected to coordinates conversion into the rectangular region represented at the step  3  in FIG. 3C whereas the rectangle circumscribed with the trapezoid represented at the step  2  in FIG. 3B is subjected to coordinates conversion into a deformed rectangle circumscribed with the rectangle represented at the step  3  in FIG. 3C, by perspective conversion, respectively. Because the portions other than the rectangular region need not be plotted, these portions other than the rectangular region are clipped by the data clip means  85  (step  4  in FIG.  3 D). The plotting command generation means  87  generates the plotting command by using the map data so obtained, and the graphic processing means  71  conducts plotting to the VRAM  26  so that the bird&#39;s-eye view map shown in FIG. 1 can be displayed. 
     Next, the perspective conversion parameters in bird&#39;s-eye view map display, that is, the angle  0  between the map and the projection plane (projection angle) and the coordinates (Tx, Ty, Tz) of the origin of the viewpoint coordinates system containing the projection plane, which is viewed from the object coordinates system containing in turn the map plane, or in other words, the method of calculating the position of the projection plane, will be explained with reference to FIGS. 23A,  23 B and  23 C. It is desired for the navigation apparatus to display in detail the point at which the user is now driving, that is, the region around the present position. Therefore, the explanation will be given on the case where the present position is displayed at the lower center portion of the screen as shown in FIG.  23 C. To accomplish bird&#39;s-eye view display, it is judged whether rotation of map is necessary at step  1002 , and in the event the rotation is considered necessary then the angle φ between the driving direction vector and the base of the map mesh is first determined at the step  1004  in FIG. 9, and affine conversion for rotating the map data to be plotted by the angle φ is executed for each data constituting the map (step  1005 ). Since bird&#39;s-eye view display is judged as being made at the step 1006, the flow proceeds to the processing for calculating the projection angle θ and the position of the viewpoint (steps  1008  and  1009 ). The projection angle θ is set to an angle near 0° when it is desired to make display so that the difference of the reduced scale becomes small between the portions near the viewpoint and the portions away from the viewpoint, and is set to near  900  when it is desired to make display so that the difference of the reduced scale becomes great between the portions near the viewpoint and the portions away from the viewpoint. Normally, the projection angle θ is set to the range of about 30° to about 45°. Since the user desires to arbitrarily set the map region to be displayed by bird&#39;s-eye view map display, the projection angle θ can be set by the projection angle change key  43  provided to the navigation apparatus shown in FIG.  6 . When this key  43  is so operated as to increase the projection angle θ, the projection angle θ increases, so that the map of remote regions is displayed. When the key  43  is so operated as to decrease the projection angle θ, the projection angle θ decreases, so that the map near the present position is displayed. 
     Next, as to the position (Tx, Ty, Tz) of the projection plane, calculation is executed at the step  1009  so that the difference (Ax, Ay, Az) obtained by subtracting the position (Tx, Ty, Tz) of the position of the projection plane from the present position (x, y, z) is always a constant value. As the absolute values, further, Δx is set to 0, Δz is set to a small value when display is made by a small reduced scale in match with the reduced scale of the map display and to a large reduced scale when display is made by a large reduced scale. Normally, Δz is decided preferably so that the reduced scale of the plane view is coincident with the reduced scale of a certain point near the center of bird&#39;s-eye view display. Since the reduced scale of the map is preferably changeable in accordance with the user&#39;s request, the step  1009  operates in such a manner as to set Δz to a small value when the user designates a small reduced scale by the reduced scale key  42  provided to the navigation apparatus shown in FIG.  6  and to a large value when a large reduced scale is designated. The Δy value may be either a positive value or a negative value but this embodiment uses the negative value and sets it so that the present position is displayed at a lower ⅓ position of the screen. Step  1010  executes perspective conversion of each coordinates value of the map data by using the projection angle θ and the position (Tx, Ty, Tz) of the projection plane that are obtained in the manner described above. 
     The detail of this perspective conversion operation will be explained with reference to FIG.  10 . First, whether or not the plane data constituted by polygons such as water systems, green zones, etc., exist is judged (step  1020 ). When the result proves YES, perspective conversion is executed for each node constituting the polygon (step  1021 ). This operation is executed for all the polygons (step  1022 ). Next, when the line data constituting the map such as the roads, the railways, the administrative districts, etc., and the optimum route from the present position to the destination are calculated, whether or not the line data representing the route exist is judged (step  1023 ). When the result proves YES, perspective conversion is executed for each node that constitutes the line (step  1024 ). Further, when the character data constituting the map such as the area names, symbols, etc., and the orbit are displayed, whether or not the point data representing the orbit exist is judged (step  1026 ). As to the character strings such as the area names, symbols, etc., it is advisable to handle one point representing a given character string such as the upper left end point of the character string as the point data. When these point data are judged as existing, perspective conversion is executed for each node constituting the point (step  1027 ) and is then executed for all the points (step  1028 ). The graphic processing means  71  executes plotting processing by using the map data so obtained. In consequence, in bird&#39;s-eye view map display shown in FIG. 23C, the driving direction is always displayed in the UP direction on the screen and the present position is always displayed at the same point on the screen. 
     Next, the explanation will be given on the display method of the bird&#39;s-eye view map, which can be easily recognized by the driver, when a certain destination is designated by the input device  5  from the map or the retrieved screen, will be explained with reference to FIG.  9  and FIGS. 24A,  24 B and  24 C. It is desired for the navigation apparatus to display in detail the point at which the user is driving at present, that is, the area near the present position. Therefore, the present position is displayed at the center lower portion of the screen, more concretely at the lower ⅓ region of the transverse center of the screen, as shown in FIG.  24 C. To accomplish bird&#39;s-eye view display shown in FIG. 24C, the angle o between the line perpendicular to the line connecting the present position to the destination shown in FIG.  24 A and the base of the map mesh is first determined at the step  1004  in FIG.  9  and affine conversion is executed by the angle φ for each coordinates value of the map data to be plotted (step  1005 ). Since this bird&#39;s-eye view display is judged as being made at the step  1006 , the flow then proceeds to the processings for calculating the projection angle θ and the position of the viewpoint (steps  1008  and  1009 ). The projection angle θ is set to an angle near 0° when it is desired to make display so that the difference of the reduced scale between small between the portions near the viewpoint and the portions away from the viewpoint, and is set to an angle near 90° when it is desired to make display so that the difference of the reduced scale becomes great between the portions near the viewpoint and the portions away from the viewpoint. Normally, the projection angle θ is set to the range of about 30° to about 45°. Since the user desires to arbitrarily set the map region to be displayed by bird&#39;s-eye view map display, the projection angle θ can be set by the projection angle change key  43  provided to the navigation apparatus shown in FIG.  6 . When this key  43  is so operated as to increase the projection angle θ, the projection angle e increases, so that the map of remote portions is displayed. When the key  43  is so operated as to decrease the projection angle θ, the projection angle θ decreases, so that the map near the present position is displayed. 
     Next, as to the position (Tx, Ty, Tz) of the projection plane, calculation is made at the step  1009  so that the difference (Δx, Δy, Δz) obtained by subtracting the position (Tx, Ty, Tz) of the projection plane from the present position (x, y, z) becomes always a constant value. As the absolute values, Δx is set to 0, and Δz is set to a small value when display is made by a small reduced scale in match with the reduced scale of the map displayed, and to a great value when display is made by a large reduced scale. Normally, Δz is preferably set so that the reduced scale of the plan view is coincident with the reduced scale of a certain point near the center of bird&#39;s-eye view display. Since the user desires to change the reduced scale of the map, the step  1009  so operates as to set a small value to Δz when the user designates a small reduced scale by the reduced scale key  42  provided to the navigation apparatus shown in FIG.  6  and to set a large value to Δz when the user designates a large reduced scale. The Δy value may be either a positive value or a negative value, but this embodiment uses the negative value and determines the value so that the present position can be displayed at the lower ⅓ position of the screen. The step  1010  executes perspective conversion of each coordinates value of the map data by using the projection angle θ and the position (Tx, Ty, Tz) of the projection plane so obtained, and the graphic processing means  71  executes the plotting processing by using the resulting map data. Consequently, in bird&#39;s-eye view display shown in FIG.  24 C, the destination is always displayed in the UP direction and the present position is always displayed at the same position on the screen. The navigation apparatus becomes easier to operate by switching the operation mode to the mode in which the destination and the present position are fixed always at certain two points on the screen when the car moves to the position where the destination can be displayed on the screen. 
     Incidentally, the polygon representing the Imperial Palace, the green zones and the water systems such as sea and lakes are not much useful as the information for the driver driving the car having the navigation apparatus, as shown in FIG.  25 A. Rather, a greater quantity of information which is directly necessary for driving, such as the road information, are displayed preferably on the limited screen. Means for solving this problem will be explained with reference to FIG.  11 . The information of the roads and the background are represented by the nodes, and the node density of the polygons representing the green zones and the water systems such as sea and lakes tends to be lower than the node density of the lines such as the roads. Therefore, the greatest quantity of information of the roads, etc., are displayed by optimizing the display region in the transverse direction of the screen, for the region displayed in the longitudinal direction, in accordance with the initial value. This processing is executed by the display position calculation routine at the step  1011  in FIG.  9 . First, whether the mode is for executing optimization of the display position is judged (step  1040 ). When optimization is judged as to be executed, the nodes that are practically displayed on the screen are extracted from the nodes constituting the lines and the polygons subjected to perspective conversion at the step  1041  by clip calculation (step  1041 ). Further, the difference Δx between the x coordinates arithmetic mean value x1 obtained at the step  1042  and the x-coordinates value x2 at the center of the screen is calculated (step  1043 ). At the next step  1044 , the difference Δx obtained by the step  1043  is added to the x-coordinates value of the nodes constituting the line and the polygon. The graphic processing means  71  executes the plotting processing by using the map data obtained in this manner. In consequence, bird&#39;s-eye view map display capable of displaying a greater quantity of those information which are directly necessary for driving, such as the roads, can be displayed on the screen as shown in FIG.  25 B. 
     Next, the method of the plotting processing of the objects constituting the bird&#39;s-eye view map will be explained more concretely. The plotting judgment means  84  shown in FIG. 12 operates in such a manner as to optimally display the plan data, the line data and the character data constituting the map, the route data calculated in accordance with the request from the user and the orbit data representing the route so far driven, respectively. 
     First, whether or not the plane data exists in the plotting data is judged (step  1060 ). When the plane data is judged as existing, the flow proceeds to the plane data plotting processing (step  1061 ) shown in FIG.  13 A. The plane data plotting processing judges whether the plane pattern exists inside the polygon to be practically plotted or whether the full plane should be smeared away (step  1080 ). When the plane pattern is not judged as existing, pattern setting is so effected as to smear away the entire portion inside the polygon and the processing is completed (step  1081 ). When the plane pattern is judged as existing, whether or not perspective conversion is to be executed for the plane pattern is judged (step  1082 ). When the plane pattern is subjected to perspective conversion and is displayed, the pattern has the feel of depth as depicted in FIG.  41 A and can be therefore displayed more three-dimensionally. However, the plotting time gets elongated because the processing quantity becomes greater. When the plane pattern used for plan view map display is displayed, on the other hand, the display becomes planar as depicted in FIG. 41B, but the processing can be made at a higher speed because the plane pattern can be handled two-dimensionally. Therefore, when a higher processing speed is required, perspective conversion of the pattern is judged as unnecessary at the step  1082  and the designated pattern itself is set as the pattern data (step  1083 ). When display quality has higher priority, on the other hand, perspective conversion of the pattern is judged as necessary at the step  1082 . Therefore, the pattern is subjected to perspective conversion and the conversion result is set as the pattern data (step  1084 ). The method shown in FIG. 41C may be employed as means for improving this processing speed. This method divides a polygon into a plurality of regions (four regions shown in the drawing) in the direction of depth and smearing away each region by using the mean pattern obtained by subjecting the plane pattern to perspective conversion in each of the region. Since the pattern becomes a two-dimensional pattern inside the region according to this method, the processing speed can be improved. 
     Next, whether or not the line data exists in the plotting data is judged (step  1062 ). When the line data is judged as existing, the processing shifts to the line data plotting processing (step  1063 ) in FIG.  13 B. In this line data plotting processing, whether the line pattern exists in the lines practically plotted or is smeared by solid lines is judged (step  1085 ). When the line pattern is not judged as existing, pattern setting is effected so as to draw the solid lines and the processing is completed (step  1087 ). When the line pattern is judged as existing, whether or not perspective conversion is to be effected for the line pattern is judged as step  1087 ). When the line pattern is subjected to perspective conversion and is displayed, the feel of depth develops as shown in FIG.  41 A and representation can be made more three-dimensionally. However, the plotting time gets elongated in this case because the processing quantity increases. When display is made by the line pattern used for plan view map display, display becomes planar as shown in FIG. 41B, but high speed processing can be made because the line pattern can be handled one-dimensionally. Therefore, when a higher processing speed is required, perspective conversion of the pattern is not judged as necessary at the step  1087  and the designated pattern itself is set as the pattern data (step  1088 ). On the other hand, when higher priority is put to display quality, perspective conversion of the pattern is judged as necessary at the step  1087 . Therefore, the pattern is subjected to perspective conversion and the converted result is set as the pattern data (step  1089 ). 
     Next, whether or not the character data exists in the plotting data is judged (step  1064 ). When the character data is judged as existing, the processing proceeds to the character data plotting processing (step  1065 ) in FIG.  14 . The character data plotting processing judges which attribute each character string in the map has, the attribute being one of a plurality of attributes such as names of places, names of buildings, map symbols, etc. (step  1100 ), selects character strings having predetermined attributes that must be displayed essentially, and hands over the processing to the step  1101 . Since the character string having the attributes that must be essentially displayed is selected, buffering is made so as to display this character string at the step  1101 . Next, overlap of one character string with another is judged (step  1102 ). There are a plurality of methods for judging overlap of the character strings. 
     The first method will be explained with reference to FIGS. 26A,  26 B,  27 A,  27 B,  28 A,  28 B,  29 A and  29 B. This method calculates the polygon encompassing the character string (the outer frame of the polygon shown in FIGS. 26A and 26B) and judges the overlap of the characters by using the polygonal region information (the hatched pattern region of the polygon shown in FIGS. 27A and 27B) constituted by a region positioned inward by a predetermined number of bits from the polygon. According to this method, the character strings are judged as overlapping when the overlap judgment regions (the hatched pattern regions of the polygons) overlap with one another as shown in FIGS. 28A and 28B. When the character overlap judgment regions do not overlap as shown in FIGS. 29A and 29B, the character strings are not judged as overlapping. Generally, the respective character strings can be discriminated even when the characters overlap to some extent, and this system operates in such a manner that overlap of the character strings to some extent are not judged as overlapping. Accordingly, the overlapping character strings are not omitted more than necessary, and the quantity of information to be transmitted to the driver increases. 
     Next, the second method will be explained with reference to FIGS. 30A,  30 B,  31 A,  31 B,  32 A,  32 B,  33 A and  33 B. This method calculates the rectangular regions circumscribed with the character string (the rectangles shown in FIGS. 30A and 30B) and judges overlap of the character strings by using the rectangular region information (the hatched rectangular regions shown in FIGS.  31 A and  31 B). According to this method, when the overlap judgment regions of the character strings (the hatched rectangular regions) overlap with one another as shown in FIGS. 32A and 32B, the character strings are judged as overlapping. When the character overlap judgment regions do not overlap with one another as shown in FIGS. 33A and 33B, the character strings are not judged as overlapping. Since this method can judge overlap of a plurality of character strings by a simple shape of the rectangle, the minimum and maximum values of the rectangle in the x- and y-axis directions may be merely compared between the overlapping character strings, and the operation time can be therefore shortened. 
     Finally, the third method will be explained with reference to FIGS. 34A,  34 B,  35 A,  35 B,  36 A,  36 B,  37 A and  37 B. This method calculates the rectangular region circumscribed with the character string (the rectangle of the outer frame shown in FIGS. 34A and 34B) and judges overlap of the character strings by using the rectangular region information (the hatched rectangular pattern region shown in FIGS. 35A and 35B) constituted by a region positioned inward by a predetermined number of dots from the rectangle. According to this method, the character strings are judged as overlapping when the overlap judgment regions of the character strings (the hatched rectangular pattern regions) overlap with one another as shown in FIGS. 36A and 36B. The character strings are not judged as overlapping when the overlap judgment regions do not overlap with one another as shown in FIGS. 37A and 37B. Generally, the respective character strings can be discriminated even when overlap of characters occurs to some extent, and this system operates in such a manner that the character strings are not judged as overlapping even when they overlap to some extent. Therefore, the overlapping character strings are not omitted more than necessary, and the quantity of the information to be transmitted to the driver increases. Further, because overlap of a plurality of character strings is judged by a simple shape of the rectangle, the minimum and maximum values in the x- and y-axis directions may be merely compared between a plurality of character strings, and the operation time can be shortened. 
     When overlap of the character strings is judged as existing after overlap is judged by any of the three kinds of character overlap judgment means described above, the attributes of the overlapping character strings are examined (step  1103 ). When the attributes of the overlapping character strings are judged as different, the character strings having the attributes which are decided as having higher priority for display are selected and are buffered (step  1104 ). Such an embodiment is shown in FIGS. 38A,  38 B and  38 C. It will be hereby assumed that the initial state has the screen structure such as shown in FIG. 38A, and comprises the symbol attributes constituted by symbols such as double circles and the post marks, and the character string attributes constituted by the character strings. If the symbol attributes are to be preferentially displayed when the processing of the step  1104  is executed, the symbol attributes are preferentially displayed when the character string and the symbol overlap with each other as shown in FIG.  38 B. In other words, the position at which “double circle” and the place name “Marunouchi” overlap with each other is displayed by the “double circle” and at the position at which the postal symbol “” overlaps with the place name “Kandabashi” is displayed by the symbol “”. Next, when the attributes of the character strings are judged as the same as a result of examination of the attributes of the overlapping character strings (step  1103 ), sorting is then effected in the depth-wise direction for the character string (step  1105 ). Further, the character string close to the present position is selected and is then buffered (step  1106 ). Such an embodiment is shown in FIG.  38 C. Here, if the character strings overlap with each other when the processing of the step  1106  is executed, the character string closer to the present position is displayed. In other words, when the name “Tokyo” and the name “Marunouchi 2” overlap, “Tokyo” is displayed, and when the name “Hitotsubashi” and “Ohtemachi” overlap, “Ohtemachi” is displayed. The explanation given above deals with the method of selecting and displaying the character strings when the character strings overlap, but there is still another method which replaces display of the overlapping character strings by small fonts and displays them as shown in FIGS. 39A and 39B. In other words, when overlap of the character strings is judged as existing at the step  1102  in FIG. 14, these character strings are displayed in the font size smaller than the designated font size. If the designated font size of characters is 24×24 pixels, for example, display is made in the font size of 16×16 pixels or 12×12 pixels. Since overlap of the character strings becomes smaller as shown in FIG. 39B in this case, recognition performance of the character strings can be improved. Next, whether or not the same character string, which expresses the same characters in the same sequence, exists in the character strings is judged (step  1107 ). When the same character string is judged as existing, the distance between the character strings is then calculated (step  1108 ). Here, the term “distance between the character strings” represents the difference of the position data of the characters put on the map data or the difference of the position data of the characters when the character strings are displayed on the bird&#39;s-eye view map. To calculate the distance, it is advisable to use one point representing the character string, that is, the upper left end point or the central point of the character string. Whether or not the distance between the character strings so calculated falls within a predetermined area is judged (step  1109 ) and when the result proves YES, the character strings in the proximity of the present position are buffered (step  1110 ). The operation example will be explained with reference to FIGS. 40A,  40 B and  40 C. Under the initial state shown in FIG. 40A, four character strings representing an interchange exist. The distances between these character strings are calculated as shown in FIG. 40B, and the character strings in the proximity of the present position, which has small distances, are selected, while both character strings are selected for those having large distances. In consequence, the character strings are displayed as shown in FIG.  40 C. As can be clearly understood from these drawings, the character strings which are not necessary as the information are omitted and only the character strings which are absolutely necessary are left. Therefore, the driver can more easily recognize them. 
     Next, the character plotting means  1185 , which can be inserted as a subroutine to the final step of the flowchart shown in FIG. 14, will be explained concretely with reference to FIG.  15 . 
     Here, whether or not decorated characters, or the like, are designated as a character style is first judged (step  1201 ). The decorated characters include bold-faced characters having a thick character line so as to highlight the characters and fringed characters having a background color or a frame of a designated specific color around the lines constituting a given character in order to have the character more comprehensible when it is displayed in superposition in a region where a large number of lines and planes are displayed as the background. Reference numeral  2181  in FIG. 18A represents an example of such a fringed character. This fringed character can be plotted in the following way. First, character plotting is effected for a character to be fringed at a position of one dot  2182  (FIG. 18B) from the upper left of the coordinates in which the object character is to be plotted, in the background color. Further, character plotting is effected eight times, in total, in the same way by using the background color at an upward position by one dot  2183  (FIG.  18 C), at a right upward position by one dot  2184  (FIG.  18 D), at a left position by one dot  2185  (FIG.  18 E), at a right position by one dot  2186  (FIG.  18 F), at a left downward position by one dot  2187  (FIG.  18 G), at a downward position by one dot  2188  (FIG. 18H) and at a right downward position by one dot  2189  (FIG.  181 ), respectively. Finally, the intended character is plotted at the designated coordinates position in the designated color ( 2191  in FIG.  18 J). As a modified example of the fringed characters, there is a method which displays the background color in the predetermined directions of the character, for example, to the right, down and right downward, or a frame having a designated specific color. 
     When the character is not judged as the decorated character in the character style judgment, the relation between the designated character and the clip region is judged by clip judgment (step  1207 ) so as to call the character plotting routine having, or not having, the clip in the pixel unit. The clip processing routine compares the character plotting start coordinates, for example, the left lower end point of the designated character, with the clip region and judges whether or not the left lower end point of this character is contained in the clip region  2162 , the plotting region  2161  or other regions, as shown in FIGS. 17A and 17B. By the way, when the character to be plotted is the standard character, the clip region is expanded to the left by the width of the character and in the down direction by the height of the character from the plotting region. Assuming that the height of the standard character and the half-size character is h, the width of the standard character is w, the width of the half-size character is w′, the left lower end point of the plotting region is (x 1 , y 1 ) and the right upper end point is (x 2 , y 2 ), for example, the left lower end point of the clip region in the standard character is (x 1 -w′, y 1 -h), its right upper end point is (x 2 , y 2 ), the left lower end point of the clip region in the half-size character is (x 1 -w′, y 1 -h) and its right upper end point is (x 2 , y 2 ). The left lower end points of the characters indicated by reference numerals  2163  and  2167  in FIGS. 17A and 17B exist outside the clip region. Therefore, the characters are clipped by clipping and nothing is plotted. The left lower end points indicated by reference numerals  2164  and  2168  in FIGS. 17A and 17B exist inside the clip region but are not contained in the plotting region. Therefore, the routine for executing the clip processing on the pixel unit is called, and character plotting is reliably executed, though the processing speed is not high (step  1209 ). The left lower end points of the characters indicated by reference numerals  2165  and  2169  in FIGS. 17A and 17B are contained in the plotting region. Therefore, the clip processing is omitted in the pixel unit, and character plotting is executed at a high processing speed (step  1208 ). Since the processing is executed in this way, high speed character plotting can be accomplished. Incidentally, the character plotting start coordinates are hereby set to the left lower end point of the character, but when the character plotting start coordinates are set to the position offset by a predetermined value from this left lower end point of the character, the offset distance may be added to the coordinates values of the plotting region and the clip region. 
     When the character is judged as having decoration in the character style judgment  1201 , whether or not the designated character constitutes one character by a plurality of characters is judged (step  1202 ). As an example of one character string constituted by a plurality of characters  2142 , there is a character  2141  of the shape having a size which exceeds the size that can be expressed by one character  2142  as shown in FIG.  16 A. When decoration is applied in a character unit to such a character string, a fringe  2143  is displayed at the boundary of a respective character  2142  in the case of a fringed character, for example, as shown in FIG. 16B, and display quality drops. Therefore, when a plurality of characters are judged as constituting one character string, the flow jumps to the routine which does not put decoration to the characters. Incidentally, there is a method which examines the character codes and judges that a plurality of characters constitute one character string when the codes are within a predetermined region, as a method of judging that a plurality of characters constitute one character string. Accordingly, in the case of the decorated characters such as the fringed characters, too, the fringe  2143  is not displayed at the boundary of each character  2142  and display quality can be improved. The operations after the clip judgment  1207  are the same as in the foregoing explanation. 
     Next, when a plurality of characters are not judged as constituting one character string at the step  1202 , whether or not the designated character is displayed in superposition with other characters is judged (step  1203 ). Here, whether or not the designated character overlaps with a plurality of characters that constitute one character is evaluated. The decorated characters such as the fringe characters intend to display more comprehensively those characters which overlap with the background information such as the lines and planes. When the decorated character such as the fringed character is displayed when overlapping characters exist as shown in FIG. 16C, the overlapped character string becomes difficult to discriminate. There is also the case where one symbol, or the like, is displayed by combining the character constituting one character by a plurality of characters with characters to be displayed in superposition with the former, and in such an application, the characters to be displayed in superposition need not be the decorated characters. Therefore, whether or not the designated character is displayed in superposition with other characters is examined at the step  1203 , and when it is, the flow jumps to the routine which does not put decoration to the character. In consequence, display such as shown in FIG. 16D is executed, and intended display can be accomplished. The operations after the clip judgment  1207  is the same as in the foregoing embodiment. 
     Next, when the designated character is not judged as being displayed in superposition with other characters at the step  1203 , plotting of the decorated characters is executed. The relation between the designated character and the clip region is judged by the clip judgment (step  1204 ) and the character plotting routine having, or not having, the clip in the pixel unit is called. The clip processing routine compares the plotting start coordinates of the character such as the left lower end point of the designated character with the clip region, and judges whether or not the left lower end point of the character is contained in the clip region  2162 , the plotting region  2161  or other regions in FIGS. 17A and 17B. When, for example, the height of the character is h, the width of the character is w, the left lower end point of the plotting region is (x 1 , y 1 ) and the right upper end point is (x 2 , y 2 ), the lower end point of the clip region is (x 1 -w, y 1 -h) and the right upper end point is (x 2 , y 2 ). When the left lower end point of the character exists outside the clip region, it is excluded by clipping and nothing is plotted. When the left lower end point of the character exists inside the clip region and is not contained in the plotting region, plotting of the decorated character is reliably executed by the clip processing in the pixel unit, though the processing speed is not high (step  1206 ). When the left lower end point of the character is contained in the plotting region, the clip processing in the pixel unit is omitted, and plotting of the decorated character is executed at a high processing speed (step  1205 ). When such a processing is executed, character plotting can be accomplished at a high speed. In this explanation, the plotting start coordinates of the character are set to the left lower end point of the character, but when the plotting start coordinates of the character are set to a point offset by a certain predetermined value from this left lower end point of the character, this offset may be added to the coordinates value of the boundary between the plotting region and the clip region. 
     Next, whether or not the route data exists in the plotting data is judged (step  1066 ). When the route data is judged as existing in the route memory means, the processing shifts to the route data plotting processing (step  1067 ). The route data plotting processing  1067  divides the region in which the map is practically displayed into a plurality of zones in the depth-wise direction, and applies necessary processing in each region. The explanation will be given hereby on the case where the region is divided into four zones. First, whether or not the route data exists in the foremost front side region  1  inclusive of the present position is judged (step  1120 ) and when the result proves YES, the line width for displaying the route is set to the greatest width (e.g. 9-dot width; step  1121 ). Next, whether or not the route data exists in the region  2  above the region  1  is judged (step  1122 ) and when the result proves YES, the line width representing the route is set to the width smaller than that of the step  1121  but greater than that of the step  1125  (e.g. 7-dot width: step  1123 ). Next, whether or not the route data exists in the region  3  above the region  2  is judged (step  1124 ), and when the result proves YES, the line width representing the route is set to the width smaller than that of the step  1123  but greater than that of the step  1127  (e.g. 5-dot width; step  1125 ). Finally, whether or not the route data exists in the deepest region  4  is judged (step  1126 ) and when the result proves YES, the line width representing the route is set to a width smaller than that of the step  1125  (e.g. 3-dot width; step  1127 ). When plotting is carried out in this manner, the forehand route can be displayed thinly and the depth route, thickly, as shown in FIG. 42B unlike the prior art system which does not have the feel of three-dimensional depth shown in FIG.  42 A. Accordingly, the driver can recognize very naturally the route data. Incidentally, the explanation is hereby given on the system which divides the region and changes the line width for each divided region. However, it is also possible to employ the method which displays the routes close to the present position by a thicker line and the routes away from the present position by a thinner line. 
     Next, whether or not the orbit data exists in the plotting data is judged (step  1068 ). When the orbit data is judged as existing, the processing shifts to the orbit data plotting processing (step  1069 ) shown in FIG.  20 . Incidentally, this orbit data is stored in the orbit memory means  69  storing therein the driving position in a predetermined distance interval. Generally, when the orbit data is displayed on the map by bird&#39;s-eye view map display, the gap of the points representing the orbit near the present position becomes great, whereas time gap of the points representing the orbit becomes small at the positions away from the present position. Therefore, there occurs the case from time to time where the points of the orbit overlap with one another. To solve this problem, in the orbit data plotting processing (step  1069 ), orbit thinning-out region judgment means (step  1140 ) for judging whether the region for which the orbit is to be plotted is away from the present position, switches the processing to the step  1141  if the orbit is the orbit of the position away from the present position. Thinning-out data quantity calculation means (step  1141 ) decides the thinning-out quantity of the orbit data displayed so that the gap of the points representing the orbit becomes easily comprehensible when bird&#39;s-eye view map display is executed (step  1141 ). The orbit thinning-out processing (step  1142 ) thins out the orbit data, which need not be displayed, from the data to be displayed in accordance with the thinning-out quantity of the orbit data determined by the step  1141 , and prevents the orbit data from being displayed for the positions away from the present position. Next, the orbit interpolation region judgment means (step  1143 ) for judging if the region for which the orbit is to be plotted is near the present position, judges whether or not the orbit to be displayed is near the present position, and when the orbit is judged as being near the present position, the processing shifts to the step  1144 . The interpolation data quantity calculation means (step  1144 ) decides the orbit data quantity to be interpolated afresh between the orbit and the orbit so that the gap of the points representing the orbit reaches the comprehensible data quantity when bird&#39;s-eye view map display is executed (step  1144 ). The orbit interpolation processing sets the orbit data to be afresh displayed between the orbit and the orbit and on the driving road in accordance with the interpolation quantity of the orbit data decided by the step  1144 , prevents the interval between the orbit data from becoming too great and displays comprehensibly the roads that have been taken in the proximity of the present position (step  1145 ). 
     Next, the orbit display examples are shown in FIGS. 43A and 43B. In the prior art system, the orbit data represented by the circles ◯ is displayed in such a manner as to broaden at portions in the proximity of the present position and to narrow at portions away from the present position as shown in FIG.  43 A. In the present system, on the other hand, the orbit data is displayed with equal gaps at the portions in the proximity of the present position and at the portion away from it as shown in FIG.  43 B. Accordingly, display quality can be improved and the roads containing the orbits can be more easily recognized. Therefore, the orbit recognition factor by the driver can be improved. 
     The explanation given above explains the plotting processing method of the objects constituting the bird&#39;s-eye view map. Next, the method of plotting the artificial background such as the sky and the horizon will be explained. One of the problems encountered in bird&#39;s-eye view map is that when the map of the far places from the present position is displayed as shown in FIG. 44A, its reduced scale becomes small, an extremely enormous quantity of map data are necessary in plotting, an elongated time is necessary for display and high speed response cannot be obtained. To solve this problem, the inventors of the present invention have proposed the method which limits the far region from the present position to be displayed in the map so as to reduce the map data quantity and displays instead artificial objects such as a horizon, a sky, and so forth. More concretely, the display region judgment means  81  shown in FIG. 8 decides the region to be displayed practically on the map. After the bird&#39;s-eye view map is displayed through the subsequent means  82  to  85 , the artificial background setting means  86  sets the data of the artificial background. The content of this processing will be explained with reference to FIG.  21 . First, an artificial background region calculation means (step  1161 ) reads out the region information whose map is decided to be displayed by the display region judgment means  81 , and decides the region for which the artificial background is displayed, from the difference between this region information and the screen size information. Next, artificial background color setting means (step  1162 ) and artificial background pattern setting means (step  1163 ) decide the colors of the background region and its pattern on the basis of various information such as the car information and the time information. The method of deciding the colors on the basis of the car information will be hereby explained by way of example. The car information S 10  is inputted to the processor portion through the car LAN  11 . When a side marker lamp of the car is lit at this time, it means that the surroundings are dark and the time can be judged as night. Therefore, the artificial background is displayed in black or grey. When the side marker lamp is not lit, the time can be judged as daytime. Therefore, the artificial background is displayed in blue. When the blue color cannot be displayed due to the color palette, it is advisable to conduct dither processing which sets the pattern so that the blue color and the white color are sequentially displayed. 
     Next, another embodiment which obtains the similar effect by a different means will be explained. In the navigation apparatus, the date and the time can be acquired by receiving and analyzing the signals from the GPS satellite. The artificial background can be displayed by using this information so that the blue color is displayed when the time is judged as daytime and the black or grey color is displayed when the time is judged as night. The artificial background may be displayed in red representing the morning or evening glow for the morning or the evening. Next, still another embodiment for obtaining the similar effect by a different means will be explained. This is the system which displays the artificial background in blue when the weather is fine and in grey when the weather is rainy or cloudy, by using the weather information contained in the information S 9  received by the traffic information receiver  10 . Since the artificial background is displayed to match with the surrounding conditions by these means, the driver can easily judge what is represented by the artificial background. 
     Next, display means for the additional information such as the means to be displayed in superposition with the bird&#39;s-eye view map will be explained. The navigation apparatus for displaying the bird&#39;s-eye view map improves the user, interface by displaying the information representing by which system the map presently displayed is plotted, in superposition with the map. Menu plotting means  70  for executing this processing will be explained with reference to FIG.  22 . The content of the user&#39;s operation is transmitted by the input device  5  to the user operation analysis means  61 , where the content is analyzed. When the necessity of display by the menu plotting means  70  is judged as existing, the content is transmitted to the menu plotting means  70  by using a message. Receiving this message, the menu plotting means starts its processing and judges whether or not the request of this message is the display request of the plan view map (step  1180 ). When the message is judged as the one requesting the display of the plan view map, a mark representing that the plan view map such as shown at the lower left of FIG. 45A is now being displayed is displayed (step  1181 ). Further, the mark representing the reduced scale of the map displayed at present is displayed (at the lower right of FIG. 45A; step  1182 ). When the message is not the one described above, whether or not the request of the message is the display request of the bird&#39;s-eye view map is judged (step  1183 ). When it is judged as the message requesting display of the bird&#39;s-eye view map, the mark representing that the bird&#39;s-eye view map is now being displayed, such as the one shown at the lower left of FIG. 45B, is displayed (step  1184 ). Further, the mark representing the reduced scale of the map presently displayed is turned off (step  1185 ). When the message is not the one described above (step  1186 ), whether or not the request of the message is the change request of the projection angle θ in the bird&#39;s-eye view map is judged (step  1186 ). When it is judged as the message requesting the change of the projection angle θ, the shape of the mark representing the present position shown in FIG. 45B is changed in accordance with the projection angle θ as shown in FIGS. 46A and 46B (step  1187 ). When the projection angle θ is close to 0, that is, when the bird&#39;s-eye view map is close to the plan view map, the shape of the present position mark is brought into conformity with the shape of the present position mark in the plan view map display, and as the projection angle θ approaches 90°, the shape of the present position mark is subjected to perspective conversion in accordance with the projection angle θ and a present position mark having the converted shape is used for display. As a result of the processing described above, the driver can easily judge the display mode of the map and the display region, so that recognition performance can be improved. 
     The foregoing embodiments can reduce overlap of the character strings in the bird&#39;s-eye view map display, eliminate the necessary for the user to estimate what is the character string displayed, from the relation between the preceding and subsequent character strings, and can make the character strings and the symbols more easily comprehensible. Because the bird&#39;s-eye view map is easily recognizable even while the driver is driving, safety can be further improved. 
     Since display of the same character string is eliminated in the bird&#39;s-eye view map display, the bird&#39;s-eye view map can be displayed more simply. In consequence, the bird&#39;s-eye view map can be recognized more easily even while the driver is driving, and safety can be further improved. 
     Because the route near the viewpoint is displayed more thickly than the routes away from the viewpoint in the bird&#39;s-eye view map display, the map can be expressed more three-dimensionally. Therefore, the user can easily acquire the feel of depth of the bird&#39;s-eye view map, and a more comprehensible map can be obtained. 
     Further, because the dot strings representing the driving orbit in the bird&#39;s-eye view map display are expressed with suitable gaps at both portions away from the viewpoint and portions near the viewpoint, the phenomenon in which the gaps of the dot strings representing the orbit becomes great, that occurs in the proximity of the viewpoint, as well as the phenomenon in which the gaps of the dot strings representing the orbit becomes narrower than necessary, that occurs at portions away from the viewpoint, can be avoided, and display quality of the bird&#39;s-eye view map and the driving orbit can be improved. 
     Display quality of the patterns contained in the lines and the planes in the bird&#39;s-eye view map display somewhat drops, but because the display time can be shortened, the time necessary for displaying the bird&#39;s-eye view map becomes shorter. Therefore, the redisplay cycle of the bird&#39;s-eye view map becomes shorter, and the bird&#39;s-eye view map can be displayed more really. 
     The artificial background representing the virtual sky and horizon are so displayed as to correspond to the surrounding condition in the bird&#39;s-eye view map display. Therefore, the user is not perplexed unnecessarily. 
     Further, the user can easily judge that the map presently displayed is the bird&#39;s-eye view map or the plan view map. Since the present condition is displayed in such a manner as to correspond to the change of the viewpoint, the navigation apparatus becomes easier to use and safety can be improved. 
     Since the destination is always displayed in a predetermined direction, the driver can drive the car while confirming always the direction of the destination. 
     Since the information desired by the driver is preferentially displayed, the necessity for the driver to conduct unnecessary operations decreases during driving, safety can be therefore improved further.