Abstract:
An image processing apparatus is disclosed. The image processing apparatus includes a unit that determines whether a distance between a view point and a two-dimensional object belongs to any of first through fourth areas which are classified in the order from a shortest distance to a longest distance, a unit that sets an image drawing size of the object on the display to be a maximum value when the distance is in the first area, a unit that sets the image drawing size of the object on the display to be a value which continuously changes from the maximum value to a minimum value corresponding to the distance when the distance is in the second area, a unit that sets the image drawing size of the object on the display to be a minimum value when the distance is in the third area, a unit that sets not to display the object on the display when the distance is in the fourth area, and a unit that two-dimensionally displays the object whose image drawing size is set on the display.

Description:
BACKGROUND OF THE INVENTION  
       [0001]     1. Field of the Invention  
         [0002]     The present invention generally relates to an image processing apparatus, a mark drawing method and a recording medium storing a mark drawing program which can be applied to an apparatus such as a car navigation apparatus.  
         [0003]     2. Description of the Related Art  
         [0004]     A car navigation apparatus which displays the position and the moving direction of a car and so forth on a map on a display in the car has been widely used, and as the map on the display, a three-dimensional (3D) map which meets recent high technology standards is in demand. In the 3D map, 3D buildings are also displayed on the display while 3D roads are displayed.  
         [0005]     On the display of the car navigation apparatus, in addition to the roads and the buildings, icons of many objects such as stores like gas stations, a destination, and a name and letters of the destination are displayed. When the objects are displayed on the 3D map, the following two methods are generally used.  
         [0006]     (1): a space coordinate showing the position of an object is displayed on a displaying screen and a mark such as an icon having a fixed size of the object is displayed as a 2D image on the space coordinate.  
         [0007]     (2): an object is displayed as a 3D image on a space coordinate showing the position of the object (refer to Patent Document 1).  
         [0008]     [Patent Document 1] Japanese Laid-Open Patent Application No. 9-319302  
         [0009]     However, in the above method (1), since many icons, names, and letters are overlapped on a displaying screen, an object is hardly distinguished. In addition, since each icon has a fixed size, depth perception of the object is hardly obtained.  
         [0010]     In addition, in the above method (2), since the object is in the 3D space, depth perception is obtained; however, when the object is a long distance from a view point, the object becomes too small and cannot be noticed. On the contrary, in a case where an object is a long distance from a car and the size of the object is made to be large enough so as to be noticeable, when the car comes near the object, the object becomes too large in the displaying screen and obstructs the total view. Therefore, the method (2) is effective when the displaying area is small and is not suitable when the displaying area is large.  
       SUMMARY OF THE INVENTION  
       [0011]     Accordingly, the present invention may provide an image processing apparatus, a mark drawing method, and a recording medium storing a mark drawing program in which notice-ability of objects on a 3D map can be improved by controlling the two-dimensional sizes of the objects and controlling the number of objects to be displayed by utilizing distance difference from a view point while depth perception of the 3D space is maintained.  
         [0012]     Features and advantages of the present invention are set forth in the description which follows, and in part will become apparent from the description and the accompanying drawings, or may be learned by practice of the invention according to the teachings provided in the description. Features and advantages of the present invention may be realized and attained by an image processing apparatus, a mark drawing method, and a recording. medium storing a mark drawing program particularly pointed out in the specification in such full, clear, concise, and exact terms as to enable a person having ordinary skill in the art to practice the invention.  
         [0013]     According to one aspect of the present invention, there is provided an image processing apparatus which displays a 3D (three-dimensional) map including a road and a building on a display. The image processing apparatus includes a determining unit that determines whether a distance between a view point which determines a visual field on a display and a 2D (two-dimensional) object to be displayed belongs to any of first through fourth areas which are classified in the order from a shortest distance to a longest distance; a first setting unit that sets an image drawing size of the 2D object on the display to be a maximum value when the distance between the view point and the 2D object is in the first area; a second setting unit that sets the image drawing size of the 2D object on the display to be a value which continuously changes from the maximum value to a minimum value corresponding to the distance when the distance between the view point and the 2D object is in the second area; a third setting unit that sets the image drawing size of the 2D object on the display to be the minimum value when the distance between the view point and the 2D object is in the third area; a fourth setting unit that sets not to display the 2D object on the display when the distance between the view point and the 2D object is in the fourth area; and an image drawing unit that two-dimensionally displays the 2D object whose image drawing size is set on the display.  
         [0014]     According to another aspect of the present invention, the image processing apparatus further includes a leg indicator drawing unit that draws a leg indicator which has a length corrected from a maximum length determined in each of the kinds of 2D objects based on the depression angle from the view point to the 2D object, and has an inverse triangular shape whose upper end contacts the 2D object and whose lower end indicates the point where the 2D object exists.  
         [0015]     According to another aspect of the present invention, the 2D object which is set not to display by the fourth setting unit is displayed at a position corresponding to the existence of the 2D object on the horizon with the minimum image drawing size on the display when the 2D object is a specific spot which is registered by a user.  
         [0016]     According to another aspect of the present invention, there is provided an image processing apparatus which displays a 3D map including a road and a building on a display. The image processing apparatus includes a determining unit that determines whether a distance between a view point which determines a visual field on a display and a 3D object to be displayed belongs to any of first through fourth areas which are classified in the order from a shortest distance to a longest distance; a first setting unit that sets an image drawing scale of the 3D object on a 3D space to be a minimum value when the distance between the view point and the 3D object is in the first area; a second setting unit that sets the image drawing scale of the 3D object on the 3D space to be a value which continuously changes from a maximum value to the minimum value corresponding to the distance when the distance between the view point and the 3D object is in the second area; a third setting unit that sets the image drawing scale of the 3D object on the 3D space to be the maximum value when the distance between the view point and the 3D object is in the third area; a fourth setting unit that sets not to display the 3D object on the 3D space when the distance between the view point and the 3D object is in the fourth area; and an image drawing unit that three-dimensionally displays the 3D object whose image drawing scale is set on the display.  
         [0017]     According to another aspect of the present invention, a mark drawing method in an image processing apparatus which displays a 3D map including a road and a building on a display can be realized.  
         [0018]     According to another aspect of the present invention, a recording medium storing a mark drawing program in an image processing apparatus which displays a 3D map including a road and a building on a display can be realized.  
         [0019]     According to an embodiment of the present invention, in an image processing apparatus, a mark drawing method, and a recording medium storing a mark drawing program, notice-ability of objects on a 3D map can be improved by controlling the two-dimensional sizes of the objects and controlling the number of objects to be displayed by utilizing distance difference from a view point while depth perception of the 3D space is maintained.  
         [0020]     Features and advantages of the present invention will become apparent from the following detailed description when read in conjunction with the accompanying drawings. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0021]      FIG. 1  is a block diagram showing a car navigation apparatus according to an embodiment of the present invention;  
         [0022]      FIG. 2  is a diagram showing a relationship between the displaying position of a 2D (two-dimensional) object to be displayed and an image drawing size of the object according to the embodiment of the present invention;  
         [0023]      FIG. 3  is a diagram showing a relationship between the displaying positions of the 2D objects and the lengths of leg indicators of the 2D objects shown in  FIG. 2 ;  
         [0024]      FIG. 4  is a flowchart showing processes for drawing an image of the 2D object to be displayed such as the icon shown in  FIG. 2 ;  
         [0025]      FIG. 5  is a diagram showing a relationship between the displaying position of a 3D object to be displayed such as a destination object and an image drawing scale of the 3D object according to the embodiment of the present invention;  
         [0026]      FIG. 6  is a diagram showing a change of the image drawing scale caused by the displaying position of a 3D object to be displayed such as a destination object shown in  FIG. 5 ;  
         [0027]      FIG. 7  is a flowchart showing processes for drawing an image of a 3D object to be displayed such as the destination object shown in  FIG. 5 ;  
         [0028]      FIG. 8  is an image drawing example of stores of 2D objects to be displayed according to the embodiment of the present invention;  
         [0029]      FIG. 9  is an image drawing example of 2D objects which are memory spots input by a user as specific spots according to the embodiment of the present invention;  
         [0030]      FIG. 10  is an image drawing example of a mark stipulated by the VICS (vehicle information and communication system) according to the embodiment of the present invention;  
         [0031]      FIG. 11  is an image drawing example of a name display according to the embodiment of the present invention;  
         [0032]      FIG. 12  is an image drawing example of traffic signal (sign) icons as 2D objects to be displayed according to the embodiment of the present invention;  
         [0033]      FIG. 13  is an image drawing example of a traffic sign as a 2D object to be displayed according to the embodiment of the present invention; and  
         [0034]      FIG. 14  is an image drawing example of a destination object as a 3D object to be displayed according to the embodiment of the present invention. 
     
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT  
       [0035]     In the following, a preferred embodiment of the present invention is described with reference to the accompanying drawings.  
         [0036]     In the embodiment, a case where the present invention is applied to a car navigation apparatus is described.  
         [0037]      FIG. 1  is a block diagram showing the car navigation apparatus according to the embodiment of the present invention. As shown in  FIG. 1 , a car navigation apparatus  100  includes a HD (hard disk)  101  which stores 3D map information including information of two-dimensional (2D) icons showing objects to be displayed, a disk reading device  102  which reads the 3D map information from the HD  101 , a data buffer  103  which temporarily stores the 3D map information read from the HD  101  by the disk reading device  102 , and a map reading controller  104  which controls the disk reading device  102  to read the 3D map information. In this, as an information storing device, in addition to the HD  101 , or instead of the HD  101 , a DVD (digital versatile disk), or a CD (compact disk) can be used. The car navigation apparatus  100  further includes a GPS (global positioning system) receiver  105  which obtains position information of a car in which the car navigation apparatus  100  is installed, a self-contained navigation sensor  106  which detects the moving direction, acceleration, speed, moved distance, and so on of the car, and a car position calculating section  107  which calculates the car position from information from the GPS receiver  105  and the self-contained navigation sensor  106 . Information of the calculated car position is sent to the map reading controller  104 , and the map reading controller  104  controls the disk reading device  102  to read map information in a range where the car is located.  
         [0038]     In addition, the car navigation apparatus  100  includes a distant view drawing section  108 , a map drawing section  109 , a mark image drawing section  111 , an operating screen drawing section  112 , a route search processing section  113 , a navigating route drawing section  114 , and a VRAM (video random access memory)  115 . The distant view drawing section  108  draws a distant view image in the VRAM  115  based on the 3D map information obtained from the data buffer  103  and the car position information obtained from the car position calculating section  107 . The map drawing section  109  draws a map image of roads and 3D buildings in the VRAM  115  based on the 3D map information obtained from the data buffer  103 . The mark image drawing section  111  draws images of objects to be displayed such as icons in the VRAM  115  based on the 3D map information obtained from the data buffer  103 . The operating screen drawing section  112  draws an operating screen image in the VRAM  115  based on the 3D map information obtained from the data buffer  103 . The route search processing section  113  searches for a most suitable route to a destination received from a user based on the 3D map information obtained from the data buffer  103  and the car position information obtained from the car position calculating section  107 . The navigating route drawing section  114  draws a navigating route image in the VRAM  115  based on the search result from the route search processing section  113 . In addition, the car navigation apparatus  100  includes an image outputting section  116  which outputs the distant view image, the map image, the object image, the operating screen image, and the navigating route image; and a display  117  which displays a composite image of the above images.  
         [0039]      FIG. 2  is a diagram showing a relationship between the displaying position of a 2D (two-dimensional) object to be displayed and an image drawing size of the 2D object. In the displaying screen  1 , areas A 1 , A 2 , A 3 , and A 4 , which are classified by distances L 1 , L 2 , and L 3  from a view point (camera) to an object to be displayed, are determined. Then, the image drawing size of an object to be displayed is determined based on which area the object exists in. In the displaying screen  1 , A 4  is an area where a distant view (an image such as sky, distant mountains, and distant houses) is displayed.  
         [0040]     In  FIG. 2 , signs are defined as follows. In some cases, hereinafter an object to be displayed is simply referred to as an object.  
         [0041]     X is a distance between a view point coordinate (camera) and a space coordinate (two-dimensional coordinate) of an object to be displayed.  
         [0042]     L 1  is a distance within which the image drawing size of the object to be displayed does not become larger even if the view point approaches the object.  
         [0043]     L 2  is a distance beyond which the image drawing size of the object to be displayed does not become smaller even if the view point leaves from the object.  
         [0044]     L 3  is a distance beyond which no object is displayed. That is, there is the following relationship; X≧0, 0&lt;L 1 &lt;L 2 &lt;L 3 .  
         [0045]     Further, in  FIG. 2 , other signs are defined as follows.  
         [0046]     S is the image drawing size of an object to be displayed.  
         [0047]     S min  is the minimum image drawing size of the object which is noticeable on the displaying screen  1 .  
         [0048]     S max  is the maximum image drawing size of the object which does not obstruct the view of the whole screen.  
         [0049]     Next, the areas A 1  through A 4  are described. 
 
Area  A   1 ( X&lt;L   1 ) 
 
         [0050]     A 1  is an area where an object is displayed with the maximum image drawing size. The maximum image drawing size of the object is maintained on the displaying screen  1  and the maximum image drawing size does not obstruct the whole screen. The maximum image drawing size is S max  as described above. 
 
Area  A   2 ( L   1   &lt;X&lt;L   2 ) 
 
         [0051]     A 2  is an area where the image drawing size of the object is enlarged or reduced. The depth perception is obtained by changing the image drawing size corresponding to the distance X. The changing range of the image drawing size is S max &lt;S&lt;S min . 
 
Area  A   3 ( L   2   &lt;X&lt;L   3 ) 
 
         [0052]     A 3  is an area where the object is displayed with the minimum image drawing size. The minimum image drawing size of the object is maintained on the displaying screen  1  and the minimum image drawing size is S min  and is a noticeable size. 
 
Area  A   4 ( X≧L   3 ) 
 
         [0053]     A 4  is an area no object is displayed and the furthest area on the displaying screen  1 . Further, A 4  is an area that prevents many objects from being displayed  
         [0054]     In  FIG. 2 , as an example, an object  2   a  in the area A 3 , an object  2   b  in the area A 2 , and an object  2   c  in the area A 1  are shown. The object  2   a  in the area A 3  is two-dimensionally displayed on the displaying screen  1  with the image drawing size S=S min , the object  2   b  in the area A 2  is two-dimensionally displayed on the displaying screen  1  with the image drawing size S which changes in the range between S min  and S max  corresponding to the distance X, and the object  2   c  in the area A 1  is two-dimensionally displayed on the displaying screen  1  with the image drawing size S=S max . Each of the objects  2   a  through  2   c  has a leg indicator (leg effect) having an inverse triangular shape. That is, a leg indicator  3   a  is attached to the object  2   a  so that the upper end contacts the object  2   a  and the lower end indicates the point where the object  2   a  exists and the object  2   a  is in a floating state from the surface of the earth, a leg indicator  3   b  is attached to the object  2   b  so that the upper end contacts the object  2   b  and the lower end indicates the point where the object  2   b  exists and the object  2   b  is in a floating state from the surface of the earth, and a leg indicator  3   c  is attached to the object  2   c  so that the upper end contacts the object  2   c  and the lower end indicates the point where the object  2   c  exists and the object  2   c  is in a floating state from the surface of the earth. The length of each of the leg indicators  3   a  through  3   c  is suitably adjusted corresponding to the image drawing size of each of the objects  2   a  through  2   c . The leg indicators  3   a  through  3   c  are displayed on the displaying screen  1  with the objects  2   a  through  2   c . In the embodiment of the present invention, as described above, the inverse triangular shape indicator is defined as the leg indicator. In  FIG. 2 , the objects  2   a  through  2   c  are displayed as icons.  
         [0055]      FIG. 3  is a diagram showing a relationship between the displaying positions of 2D objects and the lengths of the leg indicators of the 2D objects. In  FIG. 3 , each size of the objects is conceptually shown to become an image drawing size when the object is displayed on the displaying screen  1 .  
         [0056]     In  FIG. 3 , signs are defined as follows.  
         [0057]     “θ” is the depression angle of the view point (camera).  
         [0058]     “h” is the length of the leg indicator which is changed by the depression angle θ.  
         [0059]     Each object always faces the view point and the maximum length of the leg indicator is h max , and when the depression angle θbecomes large, the length “h” becomes small. In this, the maximum length h max  of the leg indicator is determined by the kinds of objects. Specifically, the length “h” of the leg indicator is determined by multiplying the maximum length h max  by cos θ, and corresponds to a length when a 2D object is viewed by the depression angle θ. In  FIG. 3 , the length ha of the leg indicator  3   a  of the object  2   a  becomes close to the maximum length h max . The length “h” becomes smaller in the order from the length hb of the leg indicator  3   b  of the object  2   b  to the length hc of the leg indicator  3   c  of the object  2   c.    
         [0060]      FIG. 4  is a flowchart showing processes for drawing an image of a 2D object to be displayed such as an icon. The processes are performed by software (a computer program) in the mark image drawing section  111  shown in  FIG. 1 .  
         [0061]     First, displaying data of an object to be displayed are read from the data buffer  103  (step S 1 ), and the displaying coordinate (displaying position) of the object is detected (step S 2 ). The distance X between the displaying coordinate and the view point position is calculated (step S 3 ). Next, it is determined whether L 2 ≦X&lt;L 3  is satisfied, that is, whether the object is in the area A 3  (step S 4 ). When the object is in the area A 3  (YES in step S 4 ), the image drawing size of the object is set to be S min  (step S 5 ). When the object is not in the area A 3  (NO in step S 4 ), it is determined whether X&lt;L 1  is satisfied, that is, whether the object is in the area A 1  (step S 6 ). When the object is in the area A 1  (YES in step S 6 ), the image drawing size of the object is set to be S max  (step S 7 ). When the object is not in the area A 1  (NO in step S 6 ), it is determined whether L 1 ≦X&lt;L 2  is satisfied, that is, whether the object is in the area A 2  (step S 8 ). When the object is in the area A 2  (YES in step S 8 ), the image drawing size of the object is set to be a value which continuously changes from the maximum value S max  to the minimum value S min , corresponding to the distance X (step S 9 ). When the object is not in the area A 2  (NO in step S 8 ), the image drawing of the object is not performed by considering X≧L 3  (step S 10 ), and the process returns to step S 1 . By the setting in steps S 5 , S 7 , and S 9 , the image drawing size S is determined (step S 111 ).  
         [0062]     Next, the maximum length h max  of the leg indicator of each object to be displayed is detected (step S 12 ), and the length “h” of the leg indicator is calculated by using the depression angle θfrom the view point (step S 13 ). Next, it is determined whether the length “h” of the leg indicator is larger than the-maximum length h max  (step S 14 ). When the length “h” of the leg indicator is larger than the maximum length h max  (YES in step S 14 ), the maximum length h max  is set to be the length “h” (step S 15 ) and the length “h” is determined (step S 16 ). When the length “h” of the leg indicator is not larger than the maximum length h max  (NO in step S 14 ), the length “h” is determined as it is by using the depression angle θ(step S 16 ). Then, the object to be displayed and the leg indicator are two-dimensionally displayed on the displaying screen  1  based on the determined image drawing size S and the length “h” of the leg indicator (step S 17 ).  
         [0063]     As described above, since a 2D object such as an icon, which is positioned near the view point, is drawn by a maximum image drawing size which is a fixed size, even if a car approaches the object, the icon does not become too large and does not obstruct the whole screen. In addition, when the car is a long distance from an object, the object is displayed with a noticeable minimum image drawing size; therefore, a case where a user of the car cannot recognize the object due to a too-small size of the object does not occur. In addition, when the object is in a middle distance from the car, since the image drawing size is changed corresponding to the distance between the object and the car, depth perception can be obtained. Further, if the object is far from a predetermined distance, the object is not displayed; therefore, displaying too many objects can be avoided. In addition, when the object is displayed with the leg indicator, the length of the leg indicator is changed by the depression angle from the view point; therefore, a visual effect similar to a 3D effect can be obtained and the displaying position (indicating position) of the object can be easily recognized. Further, since the length of the leg indicator is different from among the kinds of objects to be displayed, the kind of object can be easily recognized by the floating height above the surface of the earth.  
         [0064]     Next, a 3D object to be displayed is described.  FIG. 5  is a diagram showing a relationship between the displaying position of a 3D object to be displayed such as a destination object and an image drawing scale of the 3D object. In the displaying screen  1 , areas A 1 ′, A 2 ′, A 3 ′, and A 4 ′, which are classified by distances L 1 ′, L 2 ′, and L 3 ′ from a view point (camera) that determines a visual field on a display, are determined. Then, the image drawing scale of an object to be displayed is determined based on which area the object exists in. The 3D object such as the destination object is different from the 2D object which is displayed by an icon and the 3D object is displayed as a 3D object on the displaying screen  1 . In addition, the image drawing scale is different from the image drawing size of the 2D object described above on the displaying screen  1 , and the image drawing scale is a scaling factor (reducing and enlarging factor) to apply to the 3D object on the displaying screen  1 . Generally, the object becomes large when the car approaches the object and becomes small when the car leaves the object. In addition to the above, when the image drawing scale is applied, the size of the object is changed based on the image drawing scale on the displaying screen  1 .  
         [0065]     In  FIG. 5 , signs are defined as follows.  
         [0066]     X is a distance between a view point coordinate (camera) and a space coordinate (two-dimensional coordinate) of an object to be displayed.  
         [0067]     L 1 ′ is a distance within which the image drawing scale of the object is not decreased even if the view point approaches the object.  
         [0068]     L 2 ′ is a distance beyond which the image drawing scale of the object is not increased even if the view point leaves the object.  
         [0069]     L 3 ′ is a distance beyond which no object is displayed. That is, there is the following relationship; X≧0,  0 &lt;L 1 ′&lt;L 2 ′&lt;L 3 ′.  
         [0070]     Further, in  FIG. 5 , other signs are defined as follows.  
         [0071]     SC is an image drawing scale of an object to be displayed.  
         [0072]     SC min  is the optimal minimum image drawing scale of the object on the displaying screen  1 .  
         [0073]     SC max  is the optimal maximum image drawing scale of the object on the displaying screen  1 .  
         [0074]     Next, the areas A 1 ′ through A 4 ′ are described. 
 
Area  A   1 ′( X&lt;L   1 ′) 
 
         [0075]     A 1 ′ is an area where the image drawing scale of an object to be displayed is set to be an optimal minimum scale and maintains the optimal minimum image drawing scale even when a car approaches the object. That is, in the area A 1 ′, the image drawing size of the object is maintained not to become too large. At this time, the image drawing scale is SC min . Since the image drawing scale is not changed, when the car approaches the object, the object gradually becomes large and also the height of the object gradually becomes large under the optimal minimum image drawing scale. That is, depth perception can be obtained. 
 
Area  A   2 ′( L   1   ′≦X&lt;L   2 ′) 
 
         [0076]     A 2 ′is an area where the image drawing scale of the object is changed corresponding to the displaying position of the object. That is, the image drawing scale of the object is changed corresponding to the distance X of the object; then, the size of the object is noticeable as almost the same size as in the area. The changing range of the image drawing scale is SC min &lt;SC&lt;SC max . When the car approaches the object, the image drawing scale is changed together with the distance; therefore, the size of the object is maintained as almost the same size in the displaying screen  1 . 
 
Area  A   3 ′( L   2   ′≦X&lt;L   3 ′) 
 
         [0077]     A 3 ′ is an area where the image drawing scale is set to be an optimal maximum scale and maintains the optimal maximum image drawing scale even when a car leaves the object. The object is displayed on the 3D map with an extremely large size; therefore, the object is noticeable even if the object is a long distance from the car. At this time, the image drawing scale is S max . Since the optimal maximum image drawing scale is used, when the car approaches the object, the object gradually becomes large and also the height of the object of the object gradually becomes high. Therefore, depth perception can be obtained. 
 
Area A 4 ′(X≧L 3 ′) 
 
         [0078]     A 4 ′ is an area where no object is. displayed. The destination object should be displayed even if the object is a great distance from the car; however, there is actually an upper limit in the displaying distance. Therefore, in this case, the upper limit is provided.  
         [0079]     In  FIG. 5 , as an example, an object  4   a  in the area A 3 ′, an object  4   b  in the area A 2 ′, and an object  4   c  in the area A 1 ′ are shown. The object  4   a  in the area A 3 ′ is three-dimensionally displayed on the displaying screen  1  with the image drawing scale SC=SC max  corresponding to the distance X from the view point, the object  4   b  in the area A 2 ′ is three-dimensionally displayed on the displaying screen  1  with the image drawing scale SC which is set in the range between S min  and S max  corresponding to the distance X from the view point, and the object  4   c  in the area A 1 ′ is three-dimensionally displayed on the displaying screen  1  with the image drawing scale SC =SC min  corresponding to the distance X from the view point.  
         [0080]      FIG. 6  is a diagram showing a change of the image drawing scale caused by the displaying position of a 3D object to be displayed such as a destination object. As shown in  FIG. 6 , the image drawing scale SC of the object to be displayed  4   c , whose distance X from the view point (camera) is X&lt;L 1 ′ is SC min , the image drawing scale SC of the object to be displayed  4   b , whose distance X from the view point (camera) is L 1 ′≦X&lt;L 2 ′ is the range between SC min  and SC max , and the image drawing scale SC of the object to be displayed  4   a , whose distance X from the view point (camera) is L 2 ′≦X&lt;L 3 ′ is SC max . That is, when the object is a long distance from the view point, the scaling factor of the image drawing scale becomes large, and when the object is near the view point, the scaling factor of the image drawing scale becomes small.  
         [0081]      FIG. 7  is a flowchart showing processes for drawing an image of a 3D object to be displayed such as a destination object. The processes are performed by software (a computer program) in the mark image drawing section  111  shown in  FIG. 1 .  
         [0082]     First, displaying data of an object to be displayed are read from the data buffer  103  (step S 21 ), and the displaying coordinate (displaying position) of the object is detected (step S 22 ). The distance X between the displaying coordinate and the view point position is calculated (step S 23 ). Next, it is determined whether L 2 ′≦X&lt;L 3 ′ is satisfied, that is, whether the object is in the area A 3 ′(step S 24 ). When the object is in the area A 3 ′(YES in step S 24 ), the image drawing scale of the object is set to be SC max  (step S 25 ). When the object is not in the area A 3 ′(NO in step S 24 ), it is determined whether X&lt;L 1 ′ is satisfied, that is, whether the object is in the area A 1 ′(step S 26 ) . When the object is in the area A 1 ′(YES in step S 26 ), the image drawing scale of the object is set to be SC min  (step S 27 ). When the object is not in the area A 1 ′(NO in step S 26 ), it is determined whether L 1 ′≦X&lt;L 2 ′ is satisfied, that is, whether the object is in the area A 2 ′(step S 28 ). When the object is in the area A 2 ′(YES in step S 28 ), the image drawing scale of the object is set to be a factor which continuously changes from the maximum value SC max  to the minimum value SC min  corresponding to the distance X (step S 29 ). When the object is not in the area A 2 ′(NO in step S 28 ), the drawing image of the object is not performed by considering X≧L 3 ′(step S 30 ), and the process returns to step S 21 . By the settings in steps S 25 , S 27 , and S 29 , the image drawing scale SC is determined (step S 31 ). Based on the determined image drawing scale SC, the object is three-dimensionally displayed on the displaying screen  1  (on the map) (step S 32 ).  
         [0083]     As described above, in the 3D object to be displayed such as the destination object, when the object is a long distance from the view point, the image drawing scale is set to be the maximum image drawing scale. With this, the destination object is displayed relatively larger than other objects and can be easily noticed. In addition, when the object is near the view point, the image drawing scale is set to be the minimum image drawing scale. With this, the destination object is prevented from being displayed with a too large size. Further, in the middle of the distance, the image drawing scale is changed corresponding to the distance; therefore, the image drawing size can be maintained with almost the same size.  
         [0084]     Next, examples of image drawing of a mark such an icon are described.  
         [0085]      FIG. 8  is an image drawing example of stores of 2D objects to be displayed. In this, the stores are displayed as icons. As shown in  FIG. 8 , store marks  21   a ,  21   b , and  21   c  are displayed with leg indicators  22   a ,  22   b , and  22   c . In  FIG. 8 , gas stations are shown as the stores.  
         [0086]      FIG. 9  is an image drawing example of 2D objects which are memory spots input by a user as specific spots. The memory spots are registered by a user. In  FIG. 9 , memory spots  23   a  and  23   b  are displayed with leg indicators  24   a  and  24   b . Generally, a 2D object which is a long distance from the view point is not displayed. However, the memory spot is different from a general 2D object to be displayed, and even if the memory spot is a long distance from the view point, as shown in  FIG. 9 , the memory spot  23   b  having the leg indicator  24   b  is displayed with the minimum image drawing size at a position on the horizon H. In addition to the above memory spot, a spot which is given by the navigation apparatus and a spot which is given from the outside via a communication network can be the memory spot.  
         [0087]      FIG. 10  is an image drawing example of a mark stipulated by the VICS (vehicle information and communication system). As shown in  FIG. 10 , marks  25   a  and  25   b  stipulated by the VICS are displayed. The marks stipulated by the VICS are displayed without leg indicators. In  FIG. 10 , marks under construction  25   a  and  25   b  are displayed.  
         [0088]      FIG. 11  is an image drawing example of a name display. As shown in  FIG. 11 ( a ), names  26   a  through  26   e  are displayed. The name is an intersection name, a route name, a place name, and so on. As shown in  FIG. 11 ( b ), the height from the surface of the earth is different among the kinds of names.  
         [0089]      FIG. 12  is an image drawing example of traffic signal (sign) icons as 2D objects to be displayed. As shown in  FIG. 12 ( a ), traffic signals  27   a  through  27   e  are displayed with the name of the place (route and intersection). As shown in  FIG. 12 ( b ), only the traffic signals which are near the car and in the car moving direction are displayed. With this, it is avoided to display too many traffic signals. In addition, as shown in  FIG. 12 ( c ), the displaying height is different among the kinds of signs.  
         [0090]      FIG. 13  is an image drawing example of a traffic sign as a 2D object to be displayed. As shown in  FIG. 13 , one-way traffic sign icons  28   a  and  28   b  are displayed.  
         [0091]     Next, an example of image drawing of a destination object as a 3D object to be displayed is described.  
         [0092]      FIG. 14  is an image drawing example of a destination object as a 3D object to be displayed. As shown in  FIG. 14 , a destination object  41  is displayed ahead on a route  61  extending from a car icon  51 .  
         [0093]     In the embodiment, the present invention is applied to a car navigation apparatus. However, the present invention can be applied to a portable navigation apparatus, a simulator, a game, and so on.  
         [0094]     Further, the present invention is not limited to the embodiment, but variations and modifications may be made without departing from the scope of the present invention.  
         [0095]     The present invention is based on Japanese Priority Patent Application No. 2005-208756, filed on Jul. 19, 2005, with the Japanese Patent Office, the entire contents of which are hereby incorporated by reference.