JP3952396B2 - GAME DEVICE AND INFORMATION PROCESSING DEVICE - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a game device and an information processing device, and more specifically to a game device and an information processing device that perform predetermined processing according to the direction and magnitude of an operation by a player.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is a game apparatus in which a player performs game processing by inputting an operation direction and magnitude. Here, as a means for the player to input the direction and size of the operation, in addition to using a general analog stick (see, for example, Patent Document 1), a method using a tilt sensor (for example, Patent Document 2). See). In particular, a game apparatus using an inclination sensor can perform a game operation according to the actual inclination of the game apparatus or the controller, for example, and thus provides an unprecedented operational feeling to the player.
[0003]
[Patent Document 1]
JP 2000-153062 A
[Patent Document 2]
JP 2001-170358 A
[0004]
[Problems to be solved by the invention]
The above-described conventional technology uses the direction and size of the operation mainly for the movement of the player character. That is, in the conventional game, the player operates an operation means such as an inclination sensor mainly for the purpose of moving the player character. However, such an operation method has already been adopted in many games and is not fresh for the player. The new operation feeling greatly affects the fun and novelty of the game, and there has been a demand for a proposal of an operation method capable of obtaining a new operation feeling.
[0005]
Therefore, an object of the present invention is to provide a game apparatus and an information processing apparatus that can give a new operation feeling to a player when inputting the direction and magnitude of an operation using an inclination sensor.
[0006]
Another object of the present invention is to provide a game device and an information processing device that can increase the variety of regions generated according to the direction and size of the operation and increase the strategy of the game. .
[0007]
Furthermore, the present invention provides a game device and an information processing device that can generate a region that matches or is surprising to the natural sense of the player when the region is generated according to the direction and size of the operation. To do other purposes.
[0008]
[Means for Solving the Problems and Effects of the Invention]
  In order to achieve the above object, the present invention is configured as follows.
  That is, the invention according to claim 1 is a game device for displaying a game image. This game apparatus includes a housing (for example, the housing 11 if a corresponding relationship with an embodiment described later is shown. Similarly, a corresponding relationship with the embodiment is shown in parentheses), and an inclination detecting means (acceleration sensor 154). )When,Object placement meansAnd the areaSettingMeans (S26, S55, S89 or S105. In the following, only the step number is shown.), Area expansion / contraction means (S24, S53 or S105), and area related processing means (S31, S33, S59, S65, S67, S83 to S91 or S109). The housing is gripped by the player. The tilt detection means detects the tilt direction and tilt amount of the housing.The object placement unit places a plurality of predetermined objects in the virtual space.regionSettingMeansA region object for selecting an object to be processed among a plurality of predetermined objects is set in the virtual space..Area setting meansFor example,To be described laterArea at the position touching the base pointobjectMay be displayed, or an area at a predetermined distance from the base pointobjectMay be displayed, or an area may be displayed at a position including the base point. The area expansion / contraction means isArea object, Tilt directionIn the direction determined according toDepending on the amount of tiltLengthStretchDisplay. The area-related processing means isFor each of the plurality of objects, it is determined whether the object exists inside or outside the area indicated by the area object, and whether to be a target of a predetermined process related to the game is determined according to the determination result. . The invention described in claim 2 further includes base point setting means for setting a base point for setting the region object in the virtual space. Note that it is sufficient for the base point setting means to set the position to be the base point, and it is not necessary to display an image representing the base point. The area setting means determines a position where the area object is arranged based on the position of the base point.
[0009]
According to the above, the area in the game image expands and contracts by the operation of the player tilting the housing. Furthermore, a predetermined process is performed according to the range covered by the area. As described above, according to the present invention, the player can obtain a new operation feeling that the area in the game image is operated by the inclination detecting means. Further, since the shape of the region changes according to the tilt direction and the tilt amount, the shape of the region is very diverse. Therefore, it is possible to increase the strategy of the predetermined process performed according to the range covered by the area, and consequently increase the strategy of the game. Further, since the area expands and contracts in the direction related to the tilt direction, the display form changes in relation to the player's operational feeling. Therefore, if the region is set to extend in the tilt direction, the player feels as if the object is expanding and contracting under the influence of gravity, and a region that changes to match the player's natural operation feeling is generated. can do. Conversely, if the area is set to extend in a direction opposite to the tilt direction (or in a direction having a predetermined angle with the tilt direction), an area where the player feels unexpected can be generated.
[0010]
  Claim3The invention described in claim 12A game device according to claim 1,Area setting meansIs the tilt direction as seen from the base pointIn the direction decided according toArea to be arrangedobjectofArrangementDetermine the position. According to this, not only the shape of the region but also the region display position changes according to the inclination of the housing. That is, in the invention according to claim 1, the shape of the region changes according to the inclination of the housing, whereas in the invention according to claim 2, the shape of the region and the display position depend on the inclination of the housing. Change. Accordingly, the display mode of the area has further diversity, and as a result, the strategy of the game increases.
[0011]
  Claim4The game device according to claim 1 is the game device according to claim 1, further comprising basic shape storage means (region object image data storage region 1522). Basic shape storage means is a regionobjectBasic shape (basic shape 31s)Image data showingRemember. At this time, the area expansion / contraction meansDirection decided according toaboutIndicated by the image dataDepending on the amount of inclination, the length of the basic shapeLengthChange. According to this, the area that expands and contracts according to the amount of tilt in the direction related to the tilt directionobjectCan be easily generated.
[0012]
  Claim5The invention according to claim 1 is the game device according to claim 1, wherein4As in the invention described in (1), a basic shape storage means is further provided. The area expansion / contraction means includes basic shape rotation means (S53a) and basic shape expansion / contraction means (S53b). The basic shape rotating means rotates the basic shape based on the tilt direction. In addition to rotating the basic shape, the basic shape rotating means may reverse the basic shape. Basic shape telescopic hand, tilt directionDirection decided according toaboutIndicated by the image dataBasic shapeRegion objectsDepending on the amount of inclinationLengthChange. According to this, the areaobjectIs the shadow of the characterObjectsEven in such a case, the area that expands and contracts according to the amount of tilt in the direction related to the tilt directionobjectCan be easily generated.
[0014]
  The invention according to claim 6 is the1The area-related processing means is the game device according to claim 1,Indicated by the region objectAll existing inside the areaPredeterminedA predetermined process is performed on the object. Or, the area-related processing means can be used for all the areas existing outside the area.PredeterminedA predetermined process is performed on one of the objects. According to this, a predetermined process is performed for all objects within (or outside) the area. Therefore, it is possible to enjoy the operation of operating the housing so that a desired object is included in the area and unnecessary objects are out of the area. Also, a predetermined process can be performed on a plurality of objects at once.
[0015]
  The invention according to claim 7 is the game device according to claim 5, wherein the area-related processing means is a predetermined process,PredeterminedProcessing to change the display mode of the object is performed. According to this, it is possible to change, for example, to another object, or to enlarge / reduce the object to be subjected to the predetermined processing. Furthermore, for example, a plurality of objects can be combined into one, or one object can be divided into a plurality of objects.
[0016]
  The invention according to claim 8 is the game device according to claim 5, wherein the area-related processing means is a predetermined process,PredeterminedProcess to change the attributes set for the object. According to this, for example, it is possible to perform an attack process on an object representing an enemy character (change in vitality that is an attribute value), or to change the effect of the item on an object representing an item.
[0017]
  The invention according to claim 9 is the game device according to claim 5, wherein the area-related processing means includes an object storage unit (S84), an objectArrangementPart (S91). The object storage unit stores the first time (when the A button is pressed, S82).Indicated by a region objectMemorize objects that exist inside the region. objectArrangementThe unit stores the object stored in the object storage unit at the second time point (when the A button is released, S90).Indicated by a region objectIn the areaArrangementTo do. According to this, so-called cut and paste processing can be executed on the objects in the region.
[0018]
  A tenth aspect of the present invention is the game device according to the ninth aspect of the present invention, in which the object storage unit is at the first time point.Indicated by a region objectThe object existing inside the area and the arrangement of the object in the area are stored. Also objectArrangementThe unit stores the object stored in the object storage unit at the second time point.Indicated by a region objectIn the area, according to the arrangement stored in the object storage unitArrangementTo do. According to this, it is possible to execute the cut and paste process without changing the arrangement of the objects at the first time point and the second time point.
[0019]
  The invention according to claim 11 is the game apparatus according to claim 1, wherein the area-related processing means includes area storage means (S67). The area storage means performs a predetermined process at a first time point (when the L button is pressed, S66).Area objectIs stored. At this time, the areaSettingThe means is a region based on the current output of the inclination detection means.objectTheArrangementAnd the area stored in the area storage meansobjectIs displayed further. According to this, the current areaobjectIn addition to the area generated in the past (first time)objectWill be displayed. According to this invention, the area generated in the pastobjectLeave the current areaobjectSince the game can be progressed in combination with the game, the game can be made more complex and highly strategic.
[0020]
A twelfth aspect of the present invention is the game apparatus according to the first aspect, further comprising first operating means (A button 13a or L button 13L). The first operation means is operated by the player. At this time, the area-related processing unit performs a predetermined process according to the operation of the first operation unit. According to this, the player can execute a predetermined process at a timing instructed by the player.
[0021]
A thirteenth aspect of the present invention is the game apparatus according to the first aspect of the present invention, further comprising an activated object display means (S50). The activated object display means displays an activated object (sound generating object 58), which is an object associated with a predetermined process, in the game image. At this time, the area-related processing means performs a predetermined process when the activation object is included in the area. According to this, since the predetermined process is automatically executed, the predetermined process is executed without an instruction from the player. In other words, the game can be made more dynamic and the fun of the game can be increased by performing predetermined processing only by including the activation object in the area.
[0022]
  The invention described in claim 14 is the claim.2The base point setting means moves the base point according to an operation by the player. According to this, the player can change not only the display mode of the area but also the displayed position. Therefore, as the player's operations become more diverse, the game can be made more complex and highly strategic.
[0023]
  A fifteenth aspect of the present invention is the game apparatus according to the first aspect of the present invention, further comprising base point candidate object display means (S50). The base point candidate object display means displays a base point candidate object (base point candidate object 54), which is an object for determining the base point, in the game image. At this time, the base point setting meansIndicated by the region objectIf the area contains a base point candidate object, the areaobjectThe position of the base point for determining the display position is changed to the position of the base point candidate object. According to this, the playerobjectBy operating the areaobjectIn addition to the display form, the displayed position can be changed. Therefore, as the player's operations become more diverse, the game can be made more complex and highly strategic.
[0024]
  A sixteenth aspect of the present invention is the game apparatus according to the first aspect, further comprising region shape changing means (B button 13b, S60, S61). The area shape changing means is in response to an operation by the player.Area objectChange the shape. According to this, in addition to the inclination detecting means, the area shape changing meansobjectThe shape of can be changed. Therefore, the generated areaobjectCan make the game more complex and more strategic.
[0025]
  The invention according to claim 17 is an information processing apparatus for displaying an image. The information processing apparatus includes a housing, an inclination detection unit,Object placement meansAnd the areaSettingMeans, area expansion / contraction means, and area-related processing means. The housing is gripped by the player. The tilt detection means detects the tilt direction and tilt amount of the housing.The object placement unit places a plurality of predetermined objects in the virtual space.regionSettingMeansA region object for selecting an object to be processed among a plurality of predetermined objects is set in the virtual space.. The area expansion / contraction means isArea object, Tilt directionIn the direction determined according toDepending on the amount of tiltLengthStretchDisplay. The area-related processing means isFor each of the plurality of objects, it is determined whether the object exists inside or outside the area indicated by the area object, and whether to be a target of a predetermined process related to the game is determined according to the determination result. .
[0026]
  According to an eighteenth aspect of the present invention, there is provided a computer of a game apparatus that includes a housing (housing 11) held by a player and an inclination detecting means (inclination sensor 154) for detecting the inclination of the housing and displays a game image. It is a game program (game program 1521) for functioning as a means. That is, the game program is stored on the computer of the game device, with inclination detecting means (S23, S52, S86, or S103),Object placement meansAnd the areaSettingTo execute the means (S26, S55, S89 or S105), the area expansion / contraction means (S24, S53 or S105), and the area related processing means (S31, S33, S59, S65, S67, S83 to S91 or S109). belongs to. The tilt detection means detects the tilt direction and tilt amount of the housing.The object placement unit places a plurality of predetermined objects in the virtual space.regionSettingMeansA region object for selecting an object to be processed among a plurality of predetermined objects is set in the virtual space.. The area expansion / contraction means isArea object, Tilt directionIn the direction determined according toDepending on the amount of tiltLengthStretchDisplay. The area-related processing means isFor each of the plurality of objects, it is determined whether the object exists inside or outside the area indicated by the area object, and whether to be a target of a predetermined process related to the game is determined according to the determination result. .
[0028]
  Claim19The invention described in (1) includes a housing (housing 11) gripped by the player and an inclination detecting means (inclination sensor 154) for detecting the inclination of the housing, and the following steps are performed on the computer of the information processing apparatus that displays an image. This is a computer program (game program 1521) for execution. That is, the computer program sends a tilt detection step to the computer of the information processing apparatus,Object placement stepWhen,An area stretching step,regionSettingSteps and region related processing steps are executed. In the tilt detection step, the tilt direction and the tilt amount of the housing are detected.The object placement step places a plurality of predetermined objects in the virtual space..In the region setting step, a region object for selecting an object to be processed among a plurality of predetermined objects is set in the virtual space.regionExpansion and contractionThe steps areRegion objectsTilt directionIn the direction determined according toDepending on the amount of tiltLengthExpansion and contractionDisplay. Region-related processing stepsFor each of the plurality of objects, it is determined whether the object exists inside or outside the area indicated by the area object, and whether to be a target of a predetermined process related to the game is determined according to the determination result. .
[0029]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 is an external view showing a game system 14 according to an embodiment of the present invention. The game system 14 includes a portable game device 10 and a game cartridge 15. The portable game device 10 includes a housing 11 for a user to hold. A liquid crystal display (hereinafter referred to as “LCD”) 12 is provided on one main surface (front surface) of the housing 11, and an operation switch is provided with the LCD 12 interposed therebetween. The operation switch (operation switch 13 shown in FIG. 2) is a switch (button) for the player to input an operation signal for game operation. Among the operation switches, a direction instruction button (cross key) 131, a start button 132, and a select button 133 are arranged on the left side of the LCD 12. Of the operation switches, an A button 13a and a B button 13b are arranged on the right side of the LCD 12. Further, an R button 13R and an L button 13L are arranged on the left and right of the upper side surface of the housing 11. The direction instruction button 131 is mainly used for instructing the moving direction of the player character. The A button 13a, the B button 13b, the R button 13R, and the L button 13L are mainly used for an instruction to execute a predetermined process (details will be described later) in addition to a movement instruction (jump, kick, throw, etc.) of the player character. Used. The start button 132 is used for instructing a game start. The select button 133 is used for selecting a menu displayed on the screen.
[0030]
Furthermore, a cartridge insertion hole (not shown) for detachably mounting a game cartridge (hereinafter referred to as “cartridge”) 15 is formed in the upper rear portion of the portable game apparatus 10. A connector (see connector 27 in FIG. 2) is provided in the vicinity of the cartridge insertion hole. The cartridge 15 incorporates a semiconductor memory or the like (ROM 152, RAM 153, acceleration sensor 154 shown in FIG. 2) in a housing 151.
[0031]
FIG. 2 is a block diagram of the game system 14. The portable game device 10 includes a control circuit (for example, a CPU chip) 20. The control circuit 20 includes a CPU core 21. An LCD controller 23, a work RAM 24, a video RAM (VRAM) 25, and a peripheral circuit 26 are connected to the CPU core 21 via a bus (address bus and data bus) 22. An operation switch 13, a connector 27 and a sound circuit 28 are connected to the control circuit 20. A speaker 29 is connected to the sound circuit 28. Prior to the start of the game, a desired cartridge 15 is attached to the connector 27. The player (user) can play desired game software by exchanging the cartridge 15.
[0032]
The CPU core 21 of the control circuit 20 reads the game program from the cartridge 15 connected to the connector 27. Further, the game process is executed based on the operation signal input by the operation switch 13 and the game program, and the data being processed is stored in the work RAM 24 and the image data is temporarily stored in the VRAM 25. The CPU core 21 gives the image data temporarily stored in the VRAM 25 to the LCD controller 23 in accordance with the display timing. The LCD controller 23 performs display control for causing the LCD 12 to display the image data supplied from the CPU core 21. The CPU core 21 generates sound data of game music or sound effects according to the progress of the game based on the game program, and provides the sound data to the sound circuit 28. The sound circuit 28 includes a DA conversion circuit and an amplifier circuit. The sound circuit 28 converts sound data into a sound signal (analog signal) and appropriately amplifies the sound data from the speaker 29.
[0033]
On the other hand, the cartridge 15 includes a ROM 152, a RAM 153, and an acceleration sensor 154. The ROM 152 stores a game program and various data used for the game program in a fixed manner. The RAM 153 stores game data obtained by executing the game program in a rewritable and nonvolatile manner. The game data stored in the RAM 153 includes, for example, backup data (e.g., acquired item, monster, life, number of advanced maps, etc.) indicating progress when the game is finished.
[0034]
The acceleration sensor 154 included in the cartridge 15 is a biaxial acceleration sensor that outputs the magnitude of inclination in two directions by detecting gravity. The acceleration sensor 154 has a horizontal direction (x-axis direction shown in FIG. 1, in other words, a rotational direction around the y-axis) and a vertical direction (y-axis direction shown in FIG. 1, in other words, x The cartridge 15 is disposed in the cartridge 15 so that the magnitude of the inclination of the cartridge 15 with respect to the rotation direction around the axis can be detected. Here, since the cartridge 15 is attached to the portable game apparatus 10, the acceleration sensor 154 can detect the inclination direction and the inclination amount of the portable game apparatus 10 (housing 11). Here, the tilt direction of the portable game apparatus 10 is the direction in which the portable game apparatus 10 is tilted, and the tilt amount of the portable game apparatus 10 is the magnitude of the tilt of the portable game apparatus 10. The player typically performs operations related to the game by holding the housing 11 and tilting the portable game apparatus 10.
[0035]
FIG. 3A is a diagram showing data stored in the ROM 152 of the cartridge 15. The ROM 152 includes a game program storage area 1521 that stores a game program, and areas (1522 to 1524) that store various data used for the game program. The area object image data storage area 1522 stores image data indicating an area operated by the player (hereinafter referred to as “operation area”, for example, an area indicated by the circular object 31 shown in FIG. 5). The base image data storage area 1523 stores image data indicating the base point (for example, image data of the base point object 32). The base point is a point for determining the position where the operation area is displayed. In the character object image data storage area 1524, image data indicating a character object is stored for each character object. The character object includes a player object indicating a player character operated by the player, an enemy object indicating an enemy character automatically controlled by the portable game device 10, an item object indicating an item appearing in the game, and the like. included. The other data storage area 1525 stores various other data (for example, terrain object data, audio data, etc.) used for the game program.
[0036]
FIG. 3B is a diagram showing an example of image data stored in the area object image data storage area 1522. The area object image data storage area 1522 stores image data of a basic shape 31s of a circular object as an example of an area object and a basic shape 34s of a shadow object as another example of an area object. Note that the basic shape is a shape before processing such as rotation, inversion, and change in length, which will be described later, is performed.
[0037]
FIG. 4 is a diagram showing data stored in the work RAM 24. The work RAM 24 stores temporary data generated in the game process. In the acceleration sensor output value storage area 241, the x-axis direction output value (x1) corresponding to the x-axis direction tilt amount (tilt angle) output from the acceleration sensor 154 and the y-axis direction tilt amount (tilt angle) are stored. The corresponding y-axis direction output value (y1) is stored.
[0038]
In the basic position data storage area 242, the output value of the acceleration sensor 154 corresponding to a basic position (a position where the inclination of the portable game apparatus 10 is treated as 0 °) determined prior to the start of the game is stored in the x-axis. Each of the direction value (x0) and the y-axis direction value (y0) is stored. The base position data storage area 243 stores position data indicating the position of the base point described above. The character object position data storage area 244 stores position data indicating the position of each character object. The position data of the base point and the position data of the character object are data indicating the position in the entire game space, but are data indicating the display position on the LCD 12 when the entire game world can be displayed on the LCD 12. May be. The area bitmap storage area 245 is bitmap data corresponding to each position in the game space, and the bit at the position where the operation area is generated is set to 1. The burn-in area bitmap storage area 246 is used for a burn-in process which will be described later with reference to FIG. 19, and is an area for storing an area when the player presses the operation switch (operation switch 13L). is there. Like the area bitmap, the burned area bitmap is bitmap data corresponding to each position in the game space, and the bit at the position where the burned area is generated is set to 1. The other game variable data storage area 247 stores other game variable data. For example, data indicating the attribute value of the character object (more specifically, vitality data of the player character) and data such as possessed items of the player character are stored.
[0039]
Next, before describing specific operation examples of the game system according to the present invention, outlines of various game examples performed in the game system will be described. In the game in this game system, the display form of the area (operation area) in the game image displayed on the LCD 12 changes according to the operation of tilting the portable game apparatus 10. Furthermore, predetermined processing relating to the game is performed according to the range covered by the operation area. The operation area varies depending on the tilt direction and tilt amount of the portable game apparatus 10 (housing 11). That is, the operation area expands and contracts in accordance with the tilt amount with respect to the tilt direction of the portable game apparatus 10. The operation area is moved by the player's operation. Hereinafter, the operation area will be described.
[0040]
FIG. 5 is a diagram illustrating an example of the relationship between the tilt of the portable game device 10 and the operation area. FIG. 5 shows a schematic diagram of the portable game device 10 when the portable game device 10 is tilted in four directions, up, down, left, and right on the paper surface, and a display example of the operation area for the two-step tilt amount. In FIGS. 5A to 5D, the left display example is a display example in which the inclination is smaller than that of the right display example. In the example of FIG. 5, the area object for expressing the operation area is generated using the basic shape 31s of the circular object of FIG. In addition, a base point object 32 representing a base point is displayed inside the circular object 31 to be displayed. FIG. 5A is a diagram showing a game image displayed on the LCD 12 when the portable game apparatus 10 is tilted downward on the plane of the paper (the negative direction of the y axis shown in FIG. 1). As shown in FIG. 5A, when the portable game apparatus 10 is tilted downward on the paper surface, the circular object 31 has a shape extending downward on the paper surface. In addition, the circular object 31 is arranged and displayed below the paper surface when viewed from the base point object 32. Further, as shown in the two display examples in FIG. 5A, as the tilt amount of the portable game apparatus 10 increases, the circular object 31 extends longer in the downward direction and becomes an elliptical shape.
[0041]
FIG. 5B is a diagram showing a game image displayed on the LCD 12 when the portable game apparatus 10 is tilted upward on the paper (the positive direction of the y-axis shown in FIG. 1). FIG. 5C is a diagram showing a game image displayed on the LCD 12 when the portable game apparatus 10 is tilted rightward on the paper surface (positive direction of the x axis shown in FIG. 1). ) Is a diagram showing a game image displayed on the LCD 12 when the portable game apparatus 10 is tilted leftward on the paper (a negative direction of the x axis shown in FIG. 1). In the cases of FIGS. 5B, 5C, and 5D, the length of the circular object 31 in the tilt direction of the portable game device 10 changes according to the tilt amount, as in the case of FIG. . That is, when the portable game device 10 is tilted upward on the paper surface, the circular object 31 is arranged and displayed above the paper surface when viewed from the base point object 32, and the shape extends and is displayed upward. Further, when the portable game device 10 is tilted to the right on the paper, the circular object 31 is arranged and displayed on the right of the paper as viewed from the base point object 32, and the shape is displayed to extend to the right. The When the portable game device 10 is tilted leftward on the paper surface, the circular object 31 is displayed on the left side of the paper surface as viewed from the base point object 32, and the shape is displayed extending leftward. Further, as the amount of tilt of the portable game apparatus 10 increases, the amount by which the circular object 31 extends in the tilt direction increases.
[0042]
As described above, the operation area expands and contracts in accordance with the tilt amount in the tilt direction of the portable game apparatus 10 (housing 11), and is displayed at a position based on the base point. As a method for generating the operation area for performing the display as described above, for example, there is the following method. That is, a basic shape (basic shape) is stored in advance in the area object image data storage area 1522 as image data of the area object. Then, the area object having the basic shape is rotated in accordance with the tilt direction of the portable game apparatus 10. Further, the length of the area object is changed according to the amount of inclination of the portable game apparatus 10. At this time, the direction in which the length is changed is determined as the tilt direction of the portable game apparatus 10. In the example in which the shadow of the character as described later with reference to FIGS. 6 to 8 is used, the basic shape needs to be rotated / inverted. In the example of FIG. 5, the basic shape is circular. Therefore, there is no need to rotate or reverse. That is, when the basic shape is circular, the operation region can be expanded and contracted in the tilt direction only by changing the length of the basic shape in the tilt direction. As described above, the shape of the operation region can be transformed into a shape corresponding to the tilt direction and the tilt amount.
[0043]
Furthermore, the display position of the area object generated as described above is determined based on the position of the base point. Specifically, the display position is determined so that the area object is arranged in the tilt direction as viewed from the base point. The region object may be arranged so that the base point is included therein, may be arranged so as to be in contact with the base point, or may be arranged at a position slightly away from the base point. By displaying the area object by the above processing, the operation area displayed on the screen can be changed according to the tilt of the portable game apparatus 10.
[0044]
In addition, the direction in which the operation area expands and contracts may be a direction related to the tilt direction of the portable game apparatus 10, and may be, for example, a direction opposite to the tilt direction or has a predetermined angle with the tilt direction. It may be a direction. When the direction in which the operation area expands and contracts is set to be the same as the tilt direction as in the present embodiment, an area that changes so as to match the natural operation feeling of the player can be generated. On the other hand, when the direction in which the operation area expands and contracts is set as a direction opposite to the tilt direction or a direction having a predetermined angle with the tilt direction, it is possible to generate an area where the player feels unexpected in the operation.
[0045]
Further, the display form of the operation area is shown as a circular example in FIG. 5, but any form may be used. For example, the operation area may be a shadow of a character. In this case, a region is generated using the basic shape 34s of the shadow object in FIG. Hereinafter, a case where the operation area is a shadow will be described with reference to FIGS.
[0046]
FIG. 6 is a diagram illustrating an example of a game image when the operation area is a shadow of a character. As shown in FIG. 6A, when the portable game apparatus 10 is tilted downward on the paper, the game image is as shown in FIG. 6B or 6C. FIG. 6B is a display example when the portable game device 10 is tilted downward on the paper surface, and FIG. 6C is a tilt of the portable game device 10 than the case shown in FIG. 6B. It is a display example when is large. In FIG. 6, the operation area is displayed as a shadow of the character. That is, the character object 33 and the shadow object 34 imitating the shadow of the character are displayed. Note that the base point of the shadow object 34 is not displayed, but the position of the character object 33 (the position of the foot) is processed as the position of the base point of the shadow object 34. Also, in the case where the operation area is a shadow, as in the case of the circular shape shown in FIG. 5, when the portable game apparatus 10 is tilted downward, the shadow object 34 is displayed at a lower position on the paper as viewed from the base point. The basic shape 34s is determined and displayed in an inverted form. Similarly to FIG. 5, the shadow object 34 displayed as a game image changes the length of the tilt direction (downward in FIG. 6) of the portable game device 10 according to the tilt amount of the portable game device 10. .
[0047]
FIG. 7 is a diagram illustrating another example of the game image when the operation area is a shadow of a character. As shown in FIG. 7A, when the portable game apparatus 10 is tilted rightward on the paper, the game image is as shown in FIG. 7B or 7C. FIG. 7B is a display example when the portable game apparatus 10 is tilted to the right on the paper surface, and FIG. 7C is a tilt of the portable game apparatus 10 as compared to the case shown in FIG. 7B. It is a display example when is large. In the case shown in FIG. 7, as in FIG. 6, the display position of the shadow object 34 is determined so as to be displayed on the right side of the paper from the base point (the position of the foot of the character object 33), and the basic shape is displayed. Is displayed in a reversed and rotated form. Further, the length of the portable game device 10 in the tilt direction (right direction in FIG. 7) changes according to the tilt amount of the portable game device 10.
[0048]
By setting the operation area as the shadow of the player character, the player can operate not only the player character but also the player character shadow at the same time. This makes it possible to give the player a new game sensation that has never existed before.
[0049]
8 and 9 are diagrams illustrating an example of the relationship between the tilt of the portable game device 10 and the area object displayed as a game image when the operation area is a shadow of a character. Here, when the portable game device 10 is tilted leftward on the paper surface as shown in FIG. 8A, the shape of the area object displayed as the game image is the shape shown in FIG. The area object having the shape shown in FIG. 8C can be obtained by rotating the basic shape 34s (FIG. 8B) prepared in advance.
[0050]
On the other hand, when the portable game apparatus 10 is tilted downward on the paper surface as shown in FIG. 9A, the shape of the area object displayed as the game image is the shape shown in FIG. 9C. Here, as is clear from FIGS. 9B and 9C, in the process of generating the area object having the shape shown in FIG. 9C from the basic shape (FIG. 9B), the basic shape is rotated. The region object cannot be obtained only by making it. This is because the shape of the area object is not symmetrical. Therefore, the portable game device 10 inverts the basic shape object in order to generate the region object having the shape shown in FIG. Even when the portable game apparatus 10 is tilted to the right on the paper, it is necessary to invert the basic shape object (and rotate the basic shape object) as in the case of FIG.
[0051]
As described above, when the shape of the operation area is not symmetric, it is necessary to invert the basic shape object depending on the tilt direction of the portable game apparatus 10. For example, when generating shadow objects that extend in the upward and left directions on the paper, if the basic shapes are not reversed, the basic shape is generated when generating shadow objects that extend in the opposite direction, that is, downward and rightward. Must be reversed.
[0052]
In addition, here, when the portable game device is in the basic position, the operation region has a basic shape, and the case where the basic shape expands (the length changes) according to the amount of inclination of the portable game device from the basic position has been described. . Here, in another embodiment, the operation region may have a shape obtained by shrinking the basic shape in the tilt direction. That is, in another embodiment, when the mobile game device has a predetermined inclination from the basic position, the operation area has a basic shape, and when the mobile game apparatus has an inclination smaller than the predetermined inclination, the operation area has the basic shape. The shape may be reduced.
[0053]
In the above, as a method of displaying the operation area, the method of rotating (reversing if necessary) the basic shape and changing the length in the tilt direction has been described. However, the character existing in the three-dimensional space is described. If the shadow is used as the operation area, a method of moving the light source may be used. That is, when the shadow display process of a character or the like is performed with a light source set at an arbitrary place in the game space, the position of the light source may be changed according to the tilt direction and the tilt amount of the portable game device 10. Thereby, the display of the shadow (operation area) can be changed according to the tilt direction and the tilt amount of the portable game apparatus 10. In this case, the position of the light source in the game space is moved in the direction opposite to the tilt direction. For example, when the portable game device is tilted downward on the paper surface as shown in FIG. 5A (that is, when the portable game device is rotated forward about the X axis), the position of the light source is on the back side about the X axis. Move to rotate. By doing so, the position of the light source moves to the back side, and the shadow extends downward. Similarly, when the portable game device is tilted rightward on the paper surface as shown in FIG. 5C (that is, when the portable game device is rotated to the right about the Y axis), the position of the light source is set to the left about the Y axis. Move to rotate. By doing so, the position of the light source moves to the left, and the shadow extends to the right. The same applies to the case where the portable game device is tilted upward on the paper or to the left.
[0054]
Next, the area related process will be described. The area-related process is a process related to the progress of the game, and is a process performed according to the range covered by the operation area. As the area-related process, for example, there are a process performed on an object included in the operation area and a process performed on the area object itself which is the operation area. Hereinafter, various specific examples of the region related processing will be described.
[0055]
First, object erasure processing and pasting processing will be described as region-related processing. FIG. 10 is a diagram illustrating an example of an object erasing process and a pasting process. The object erasing processing and pasting processing described in FIG. 10 is processing for performing so-called “cut and paste” on an object in a region. In FIG. 10, a case where the operation area is expressed by the circular object 31 shown in FIG. 5 will be described as an example. First, as shown in FIG. 10A, in a state where star-shaped character objects (star objects) 35 to 37 are included in the circular object 31, an operation for instructing execution of an erasing process (for example, In response to pressing of the A button 13a), an erasing process is performed. Here, the erasure process is a process of erasing the character object in the operation area. As a result of the erasure process, the game image is in the state shown in FIG. That is, as a result of the erasure process, the star objects 35 to 37 displayed in the circular object 31 are not displayed. There is no change in the star object that is not displayed in the circular object 31.
[0056]
Next, in the state of FIG. 10B, when the tilt operation of the portable game apparatus 10 is performed, the shape of the circular object 31 changes. FIG. 10C shows a state where the tilt of the portable game apparatus 10 is operated from the state of FIG. 10 (a) and 10 (b), the portable game device 10 is tilted in the upper right direction on the paper. In the state of FIG. 10C, the portable game device 10 is tilted in the lower right direction on the page. FIG. 10C shows a state where the rotational movement is performed around the base point as an example. Further, in the state of FIG. 10C, the pasting process is performed in response to an operation for instructing the pasting process to be performed (for example, the A button 13a pressed for performing the erasing process is released). Is done. Here, the pasting process refers to a process of displaying the character object erased by the erasing process. As a result of the pasting process, the game image is in the state shown in FIG. That is, as a result of the pasting process, the star objects 35 to 37 are displayed in the circular area. Note that the star objects 35 to 37 displayed by the pasting process are displayed while maintaining the positional relationship in the circular object 31 at the time of the erasing process. That is, the star objects 35 to 37 displayed by the pasting process are displayed at the same position as the erasing process point with respect to the circular object 31.
[0057]
Next, object movement processing will be described as region-related processing. FIG. 11 is a diagram illustrating an example of an object movement process. In FIG. 11, as in FIG. 10, a case where the operation area is the circular object 31 shown in FIG. 5 will be described as an example. Here, the moving process is a process of moving the character in the operation area according to a change in the display state of the operation area. At this time, the object to be moved is moved so as to maintain the positional relationship in the operation area, as in the case of the pasting process shown in FIG. In the state of FIG. 11A, the portable game device is tilted in the upper right direction of the page, in the state of FIG. 11B, tilted to the right side of the page, and in the state of FIG. Tilt.
[0058]
Specifically, first, as shown in FIG. 11A, in the state where the star objects 35 to 37 are included in the circular object 31, an operation (for example, an A button) 13a is pressed), the movement process is started. FIG. 11B shows a state in which the circular object 31 is rotated about the base object 32 after the start of the movement process. When the display state of the circular object 31 changes (in this case, it is rotationally moved) by the tilting operation of the portable game device 10 after the start of the moving process, the star objects 35 to 37 in the operation area are changed accordingly. Move accordingly. At this time, the star objects 35 to 37 are moved while maintaining the positional relationship in the circular object 31. Note that the position of the star object outside the operation area does not change. FIG. 11C shows a state where the circular object 31 is further rotated from the state of FIG. Also in FIG. 11C, as in FIG. 11B, the star objects 35 to 37 in the operation area are moved according to the rotational movement of the circular object 31. The movement process ends in response to an operation for ending the movement process (for example, the A button 13a pressed to start the movement process is released). After the movement process is completed, the star objects 35 to 37 do not move even if the display state of the circular object 31 changes.
[0059]
In addition to the above, a process for changing the display mode and attributes of the object is conceivable as the area-related process for the object in the operation area. FIG. 12 is a diagram illustrating an example of region-related processing for changing the display mode and attributes of an object. 12, as in FIG. 10, the case where the operation area is the circular object 31 shown in FIG. 5 will be described as an example. In FIG. 12, in the state where the star objects 35 to 37 are included in the circular object 31 as shown in FIG. 12A, an operation (for example, the A button 13a is pressed) is executed. When this is done, the region related processing is executed.
[0060]
FIG. 12B is a diagram illustrating an enlargement process for enlarging or reducing an object included in the operation area. In FIG. 12B, the display mode of the object is changed. That is, as a result of the enlargement process, the star objects 35 to 37 are enlarged or reduced (in the example shown in FIG. 12B, enlarged) and displayed.
[0061]
FIG. 12C is a diagram illustrating attribute change processing for changing the attribute of an object included in the operation area. In FIG. 12C, the attribute is changed in addition to the display mode of the object. Here, the attribute of the object refers to various parameters of the object such as the shape and color of the object. That is, as a result of the attribute change process, as shown in FIG. 12C, the character objects 35 to 37 that were star-shaped before the attribute change process are changed to a round shape and displayed. Further, the parameters set as the attributes of the character objects 35 to 37 are changed. Note that the attribute to be changed in the attribute changing process may be a parameter that does not appear on the display, in addition to the display form such as shape and color.
[0062]
FIG. 12D is a diagram showing a proportional enlargement process for enlarging or reducing an object included in the operation area in accordance with the enlargement or reduction of the operation area. In FIG. 12D, the display mode (including the display position) of the object is changed. Specifically, as illustrated in FIG. 12A, the execution of the area related process is started in a state where the star objects 35 to 37 are included in the circular object 31. After the area-related processing is started, proportional enlargement processing is performed in response to an operation for enlarging or reducing the circular object 31 (an operation for increasing or decreasing the inclination of the portable game apparatus 10). As a result of the proportional enlargement process, the star objects 35 to 37 are enlarged or reduced (in the example shown in FIG. 12B, reduced) and displayed. Further, as a result of the proportional enlargement process, the positions of the star objects 35 to 37 (not positions in the region but positions on the display screen) are changed while maintaining the relative positional relationship in the circular object 31.
[0063]
FIG. 12E is a diagram showing a composition process for composing a plurality of objects included in the operation area into one object. In FIG. 12E, the display mode and attributes of the object are changed. That is, as a result of the synthesis process, a new character object 38 is displayed instead of the star objects 35 to 37. In addition, the attributes of the character object 38 are newly set.
[0064]
Next, application examples in the case of using region-related processing in more specific game processing will be described with reference to FIGS. In FIGS. 13 to 19, as a more specific game process, a game in which a player operates a player character and battles with an enemy character is considered.
[0065]
First, a specific example of performing the area-related processing when displaying the menu screen executed before the game starts will be described with reference to FIGS. In the description of FIGS. 13 to 15, a case where the operation area is the circular object 31 illustrated in FIG. 5 will be described as an example. FIG. 13 is a diagram illustrating an example of a menu screen for selecting a player character. In FIG. 13, the position of the base object 32 is set in advance (here, it is set near the center of the screen). In addition, character icons 41 to 44 indicating player characters are displayed around the base object 32. The character icon 41 represents a swordsman character, the character icon 42 represents a hunter character, the character icon 43 represents a bandit character, and the character icon 44 represents a magician character. By operating the circular object 31, the player selects a player character to be operated in the game from among the player characters indicated by the four character icons 41 to 44. That is, the player changes the display of the circular object 31 by operating the tilt of the portable game apparatus 10. Then, the inclination of the portable game apparatus 10 is operated so that the desired character to be selected as the player character is included in the circular object 31. Further, in a state where the desired character is included in the circular object 31, the player operates in response to an operation for determining the player character (for example, an operation of pressing the A button 13a). A player character is determined (a swordsman character is selected in FIG. 13).
[0066]
FIG. 14 is a diagram illustrating an example of a menu screen for selecting a player character and an item to be equipped. In the menu screen shown in FIG. 14, in addition to the character icons 41 to 44, item icons indicating a plurality of items to be equipped to the player character are displayed. As described above, the player selects a player character to be operated in the game from among the player characters indicated by the character icons 41 to 44 by operating the circular object 31. Further, an item to be equipped to the player character is selected from items indicated by the plurality of item icons. That is, the player operates the tilt of the portable game apparatus 10 so that the circular object 31 includes the icon of the desired character that the player character wants to select and the icon of the desired item that the player character wants to equip. . Further, in a state where the icon of the desired character and the icon of the desired item are included in the circular object 31, an operation for determining the player character and the item (for example, an operation of pressing the A button 13a) is performed. Accordingly, the player character operated by the player and the item to be equipped to the player character are determined (a magician character equipped with a wand is selected in FIG. 14).
[0067]
In the menu screen shown in FIG. 14, when the base point object 32 is near the center of the screen, the combination of the player character and the item may not be a combination desired by the player. For example, when the base object 32 is in the vicinity of the center of the screen, a combination of the character icon 44 and the item icon 46 cannot be selected. Therefore, the player may be able to move the base object 32 on the menu screen shown in FIG. For example, the base object 32 may be moved by the player using the direction instruction button 131. Further, as will be described later, by tilting the portable game apparatus 10 while pressing a specific button (for example, the B button 13b), the base point may be moved in a tilted direction. FIG. 15 is a diagram showing a state in which the base point of the operation area is moved on the menu screen shown in FIG. As shown in FIG. 15, by moving the base point object 32, the player can select a combination of the character icon 44 and the item icon 46.
[0068]
Next, a game performed using the player character selected as described above will be described. Area related processing is also performed during game play. The area-related processing during play will be described with reference to FIGS. In the description of FIGS. 16 to 19, it is assumed that the operation area is the shadow of the player character, and the player operates the player character and its shadow. FIG. 16 is a diagram illustrating an example of attack processing that is an application example of region-related processing. There are enemy objects 51 to 54 representing enemy characters around the player object 50 representing the player character. The player can attack the enemy objects 51 to 54 included in the shadow object 34 by attack processing. Here, the attack processing for the enemy object is, for example, annihilating the enemy object, damaging the enemy object (decreasing the vitality value set as the attribute value of the enemy object), or moving the enemy object outside the operation area. The process of blowing away. Specifically, the player operates the shadow object 34 by operating the tilt of the portable game apparatus 10 as described above with reference to FIGS. Then, when an enemy object to be attacked enters the shadow object 34, an attack process is executed by performing an operation for executing the attack process (for example, an operation of pressing the A button 13a). For example, when the attack process is executed in the state shown in FIG. 16, the attack process is performed on the enemy objects 51 and 52 existing in the shadow object 34.
[0069]
FIG. 17 is a diagram illustrating an example of an item synthesis process that is an application example of the area-related process. Around the player object 50, there are item objects 55 and 56 representing items. The item composition process is a process for compositing items included in the shadow object 34. That is, when an item composition process is executed when there are a plurality of item objects in the shadow object 34, another item object different from the plurality of items is generated. Specifically, the player operates the shadow object 34 by operating the tilt of the portable game apparatus 10. Then, when the item object to be combined is included in the shadow object 34, the item combining process is executed by performing an operation for executing the item combining process (for example, an operation of pressing the A button 13a). For example, when the item composition process is executed in the state shown in FIG. 17, new item objects 57 different from the item objects 55 and 56 are generated as the item objects 55 and 56 existing in the shadow object 34, and the game image Is displayed.
[0070]
FIG. 18 is a diagram illustrating an example of sound generation processing that is an application example of region-related processing. The sound generation process is a process of outputting a predetermined sound (for example, a sound effect or the like) defined in advance from the speaker 29. A sound generation object 58 is displayed in the vicinity of the player object 50. The sound generation object 58 is an object for performing sound generation processing. In addition, the sound generation process is automatically executed when the sound generation object 58 is included in the shadow object 34. Therefore, the player can operate the sound generation process by operating the shadow object 34 so as to include the sound generation object 58. For example, as shown in FIG. 18, in response to the sound generation object 58 being included in the shadow object 34, a predetermined sound defined by the sound generation process is automatically output from the speaker 29 of the portable game device 10. Is done.
[0071]
In the example described with reference to FIG. 16 (attack process) and FIG. 17 (synthesis process), the area-related process is executed when the player operates the operation switch (A button 13a). In the example of processing, when the object 58 is included in the operation region, the region related processing is automatically executed. Here, an object that automatically performs a predetermined process when included in the operation area, such as the sound generation object 58, is referred to as an activation object. That is, when the activation object is included in the operation area, a predetermined process defined by the activation object is automatically executed. Examples of the activation object include a landmine object and an enemy object. A mine object is an object that has an effect of performing an explosion process when included in an operation area and blowing away a character existing around by the explosion process. Further, the enemy object may be an activation object. In this case, when an enemy object is included in the operation area, attack processing is automatically performed. That is, when the enemy object is an activation object, the attack process is automatically executed instead of being triggered by an operation by the player. As described above, the attack process may be started when an enemy object is included in the operation area, and the item composition process may be started when an item is included in the operation area. Further, the sound generation process may be executed in response to an operation for executing the sound generation process by the player.
[0072]
Note that the area-related processing described above is performed for objects existing inside the operation area. On the other hand, according to another embodiment, the region-related processing may be performed for an object existing outside the operation region. Furthermore, even if the area-related processing is to process all objects existing inside (or outside) the operation area, some of the objects existing inside the operation area are processed. It is also possible to perform processing. For example, the area-related process may be an attack process performed only on a predetermined type of enemy object.
[0073]
FIG. 19 is a diagram illustrating an example of a burning process which is an application example of the area-related process. FIG. 19A shows a state before the baking process is performed, and FIG. 19B shows a state after the baking process is performed. The burning process is a process for continuously displaying the area object at a certain time. Here, the attack process and the like described above are processes performed on the object in the operation area, but the burn process is a process performed on the area object itself. First, in the state shown in FIG. 19A, when an operation for executing the printing process (for example, an operation of pressing the L button 13L) is performed by the player, the printing process is executed. Thereby, the shadow object 34a at the time of the operation is burned. That is, the shadow object 34a at the time of the operation is continuously displayed in the display state at the time. Next, FIG. 19B shows a state where the position of the base point has been moved and the tilt of the portable game apparatus 10 has been manipulated after the burning process has been performed. As shown in FIG. 19B, after the burning process, the shadow object 34b whose tilt state changes according to the player's operation and whose display state changes accordingly is displayed. That is, the shadow object 34b is an area that is displayed according to the current tilt state. In addition, the burned shadow object 34a is displayed. Note that the region-related processing (attack processing against the enemy object in the example of FIG. 19) is executed for both the burned region 34a and the region 34b corresponding to the current tilt state. That is, attack processing is performed on enemy objects included in the areas 34a and 34b.
[0074]
In the present embodiment, the base point changing process is performed in addition to the area-related process. FIG. 20 is a diagram illustrating an example of the base point changing process. FIG. 20A shows a state before the base point changing process is performed, and FIG. 20B shows a state after the base point changing process is performed. The base point changing process is a process of changing the base point of the operation area to the position of the base point candidate object. The base point candidate object is an object that can be the base point of the operation area. First, in the state shown in FIG. 20A, the base point candidate object 54 is included in the shadow object 34. In this state, when an operation for executing the base point changing process (for example, an operation of pressing the R button 13R) is performed by the player, the base point changing process is executed. That is, the shadow object 34 based on the position of the player object 50 moves so as to use the position of the base point candidate object 54 as a base point (see FIG. 20B). After the base point changing process, the base point position of the shadow object 34 is processed as the base point candidate object 54 position. Therefore, the shadow object 34 moves as the base point candidate object 54 moves. Further, in the base point changing process, the shadow object indicating the shadow object 34 is converted into one suitable for the base point candidate object 54. Note that the player character operated by the player may be changed from the previous player object 50 to the base point candidate object 54.
[0075]
Next, the operation of the game system according to the present embodiment will be described. The flowcharts shown in FIGS. 21 to 24, 26 and 27 are flowcharts of programs executed by the control circuit 20 of the game system. This program is included in the game program stored in the ROM 152 of the cartridge 15. The operation of the game system is performed by executing the game program by the control circuit 20. Hereinafter, the operation of the game system will be described with reference to FIGS.
[0076]
FIG. 21 is a flowchart showing a main flow according to the first game example. In the first game example described below, the player operates the player character and its shadow (operation area), and performs various processes using the shadow on enemy characters and items appearing in the game.
[0077]
First, in S11, initialization processing is performed for various variables used in the subsequent processing. Next, in S12, the basic position is set. Specifically, the determination button (for example, A button 13a) is operated by the player while the player holds the portable game apparatus 10 at a desired position. Further, in response to the determination button being operated, the output values (x-axis direction value (x0) and y-axis direction value (y0)) of the acceleration sensor 154 at the time of the operation are stored in the basic position data storage area 242. Is done. In the subsequent game processing, a value obtained by subtracting this data from the output value of the acceleration sensor 154 is used. Thus, the player's desired position can be set to a neutral position (a position where the inclination is 0, that is, a position serving as a reference for the inclination).
[0078]
After S12, menu processing is performed in S13. Details of the menu processing will be described below. 22 and 23 are flowcharts showing details of the menu processing in S13 shown in FIG. The menu process is a process for selecting a player character or the like operated by the player in the game process as described above with reference to FIGS. First, in S20, the position of the base point (initial position) is set. Here, it is assumed that data indicating the initial position of the base point is stored in the ROM 152 of the cartridge 15, read as appropriate, and written in the base point position data storage area 243 of the work RAM 24. The initial position of the base point is set near the center of a menu screen described later. Next, in S21, a menu screen is displayed on the LCD 12 of the portable game apparatus 10 as a game image. Specifically, a base point object, a character icon, and an equipment icon as shown in FIG. 14 are displayed. The position where the base object is displayed is the position set in S20. The character icon is an icon indicating a character that can be selected as a player character operated by the player in the game process. Further, the equipment icon is an icon indicating an item for the player character to equip.
[0079]
Next, in S22, the input of the operation switch 13 is detected. The input detected here is an input for an operation related to the movement of the base point or an operation related to determination of the player character or the like. In subsequent S23, the input of the acceleration sensor 154 is detected. Specifically, acceleration sensor output values (x-axis direction output value (x1) and y-axis direction output value (y1)) output from the acceleration sensor 154 are stored in the acceleration sensor output value storage area 241.
[0080]
In S24, the basic shape image data of the area object (in this case, the circular object 31) is read from the area object image data storage area 1522 of the ROM 152, and the basic shape is deformed based on the inclination direction and the inclination amount. . Specifically, a process of deforming the area object is performed according to the acceleration sensor output value detected in S23. More specifically, first, the acceleration sensor output value (x1, y1) stored in the acceleration sensor output value storage area 241 and the basic position data (x0, y0) stored in the basic position data storage area 242. Based on the above, the tilt direction and the tilt amount are determined. More specifically, the tilt direction is obtained by subtracting the x-axis direction value (x0) from the x-axis direction output value (x1) and the y-axis direction value (y0) from the y-axis direction output value (y1). Determined in the direction of the vector (x1-x0, y1-y0) consisting of Further, the amount of inclination is determined by the magnitude of the vector. Further, the length of the area object in the direction of inclination (the direction in which the vector faces) is changed according to the amount of inclination (S24a). As described above, a deformed area object is generated.
[0081]
After S24, in S25 and S26, the operation area is displayed at a position based on the base point. The display form of the operation area displayed here is changed in S24. Specifically, after clearing the region bitmap in S25, the region bitmap is determined based on the region object deformed in the processing in S24 and the position of the base point stored in the base point position data storage region 243. Generated. More specifically, the area object deformed in S24 is arranged at a position in the tilt direction when viewed from the base point. Further, the value of the region bitmap is set to 1 for the position within the region. Since the area bitmap is cleared every time, only the latest area bitmap is stored in the area bitmap storage area 245. An example of the region bitmap is shown in FIG. The area bitmap indicates whether or not to display the operation area for all the areas of the game space (the horizontal position is indicated by an X coordinate value and the vertical position is indicated by a Y coordinate value). In the example of FIG. 25, the grid indicated by “1” displays the operation area, and the grid indicated by “0” does not display the operation area. That is, in FIG. 25, the part indicated by “1” is the part displayed as the operation area. Further, the area bitmap generated in S25 is stored in the area bitmap storage area 245 of the work RAM 24.
[0082]
Further, in S26, the operation area is displayed on the LCD 12 based on the area bitmap generated in S25. As described above, in S26, only the area bitmap stored in the area bitmap storage area 245 in the immediately preceding S25 is displayed on the LCD 12. Accordingly, the menu screen displayed on the LCD 12 at this time is, for example, a screen as shown in FIG.
[0083]
In the above description, the method using the region bitmap has been described as a method for expressing the portion where the operation region is displayed. In addition, the portion where the operation area is displayed may be expressed by a function. When expressed by a function, it is possible to perform arithmetic processing related to the operation area at a higher speed than when expressed by an area bitmap. For example, when a plurality of operation areas are displayed and a portion where the plurality of operation areas overlap is calculated, the function can perform processing faster than the area bitmap.
[0084]
Next to S26, in S27, it is determined whether or not an operation for selecting a character and equipment (here, an operation of pressing the A button 13a) has been performed by the player. This determination is made based on the input of the operation switch 13 detected in the immediately preceding S22. Specifically, when there is an input related to the A button 13a in S22 immediately before, it is determined that an operation for selecting a character and equipment has been performed. On the other hand, if there is no input regarding the A button 13a in the immediately preceding S22, it is determined that the operation for selecting the character and the equipment has not been performed.
[0085]
If it is determined in S27 that the operation for selecting the character and equipment has not been performed, the process of S28 is performed. That is, in S28, processing for moving the base point is performed. Here, the base point is moved by an operation of tilting the portable game apparatus 10 while pressing the B button 13b. Specifically, the acceleration sensor output value (x1, y1) stored in the acceleration sensor output value storage area 241 in the immediately preceding S23 and the basic position data (x0, y0) stored in the basic position data storage area 242. Based on the above, the tilt direction and the tilt amount are determined. The process of determining the tilt direction and tilt amount in S28 is the same as S24. The movement direction of the base point is determined according to the inclination direction determined as described above, and the movement amount is determined according to the inclination amount. Further, the position of the base point is moved and displayed on the LCD 12 according to the determined movement direction and amount of the base point. The above process is performed in S29, and then the process returns to S22. In S29, the base point moving operation is performed using the acceleration sensor 154, but the base point moving operation may be performed using the cross key 131.
[0086]
On the other hand, if it is determined in S27 that an operation for selecting a character and equipment has been performed, the process of S30 in FIG. 23 is performed. That is, in S30, it is determined whether or not only one character icon is included in the operation area. Here, whether or not a character icon is included in the operation area is determined according to an area determination process described below.
[0087]
FIG. 24 is a flowchart showing details of the area determination process. In the following description of the area determination process, a case will be described in which it is determined whether or not an object N (which is a concept including the character icon) that is an arbitrary character object is included in the operation area. First, in S41, the display position of the object N is detected. Specifically, the detected position of the object N is a position indicated by the position data of the object N stored in the character object position data storage area 244. Further, the position of the object N is expressed by the X coordinate value and the Y coordinate value used in the region bitmap shown in FIG.
[0088]
Next, in S42, it is determined whether or not the object N is included in the operation area. This determination is made based on the region bitmap generated in S25 and the display position of the object N detected in S41. Specifically, when the display position of the object N corresponds to a portion indicating the operation region in the region bitmap (portion “1” shown in FIG. 24), it is determined that the object N is included in the operation region. . On the other hand, when the display position of the object N corresponds to a portion other than the operation region in the region bitmap (“0” portion shown in FIG. 24), it is determined that the object N is not included in the operation region.
[0089]
In S30, an area determination process is performed for all the character icons displayed on the LCD 12. By performing the area determination process for all the character icons, it is determined whether or not only one character icon is included in the area. When a function is used instead of the area bitmap, the determination in S42 is performed based on the function indicating the operation area and the display position of the object N detected in S41.
[0090]
Returning to the description of FIG. 23, when the result of determination in S30 is that there is not one character icon included in the operation area, that is, when two or more character icons are included in the operation area, the process of S28 described above is performed. Proceed to processing. On the other hand, as a result of the determination in S30, if only one character icon is included in the operation area, the process proceeds to S31. That is, in S31, a player character operated by the player in a game process described later is determined. The determined player character is a character indicated by the character icon determined to be included in the operation area in S30.
[0091]
Next, in S32, it is determined whether or not an equipment icon is included in the operation area. Similar to the determination in S30, the determination in S32 is performed according to the area determination process shown in FIG. That is, it is determined whether or not an equipment icon is included in the operation area by performing an area determination process for all displayed equipment icons. When the equipment icon is not included in the operation area, the menu process is terminated. On the other hand, if an equipment icon is included in the operation area, the process of S33 is performed. That is, in S33, equipment is added to the player character determined in S31. The equipment to be added is an item indicated by the equipment icon determined to be included in the operation area in S32. By the process of S33, the game process performed thereafter is started in a state in which the item is equipped on the player character. After S33, the menu process is terminated. Above, description of the menu process of S13 shown in FIG. 21 is complete | finished.
[0092]
Returning to FIG. 21, the game process is performed in S14 after S13. Details of the game processing will be described below. 26 and 27 are flowcharts showing details of the game process in S14 shown in FIG. First, in S50, as a game screen displayed on the LCD 12, a player object indicating a player character appearing in the game, other character objects, a background image, and the like are displayed. Here, in this game example, the position of the base point of the operation area is assumed to move according to the position of the player character. Therefore, the position of the base point at the start of the game is set to the position of the player character displayed in S50. Specifically, the player character position data stored in the character object position data storage area 244 is written in the base position data storage area 243 as the position data of the base point.
[0093]
Next, the input of the operation switch 13 is detected in S51. The input detected here is an input for an operation related to the movement of the player character, an operation for performing region-related processing, or the like. In subsequent S52, the input of the acceleration sensor 154 is detected. Further, in S53, a process of deforming the area object is performed according to the acceleration sensor output value detected in S52. Specifically, the basic shape 34s is rotated, inverted, and the length of the tilt direction is changed. Here, it is assumed that the area object used in the game process is a shadow object imitating the shadow of the player character. Note that the processing of S51 to S53 is substantially the same as the processing of S22 to S24 of the menu processing shown in FIG. 22, but in S53, it is stored in the area object image data storage area 1522 in accordance with the tilt direction. After the basic shape is rotated (S53a), the length of the rotated area object in the tilt direction is changed according to the tilt amount (S53b).
[0094]
After S53, in S54 and S55, an operation area (shadow) is displayed on the LCD 12 based on the shadow object deformed in the process of S53 and the position of the base point. That is, after clearing the region bitmap in S54, a region bitmap is generated based on the region object deformed in S53 and the position of the base point. Since the area bitmap is cleared each time, a new area bitmap is generated, so that only the latest area bitmap is stored in the area bitmap storage area 245. In the game process, an area bitmap is generated for the ground surface of the entire area of the game space. Further, in S55, the data in the area bitmap storage area 245 generated in S54 and the data in the burned area bitmap storage area 246 are combined, and the operation area is displayed on the LCD 12. Note that at the start of the game or when the burning process (S67) has not yet been performed, since all data is set to 0 in the burned area bitmap storage area 246, only the area based on the area bitmap storage area 245 is displayed. Is displayed.
[0095]
After S55, in S56, it is determined whether or not an operation for moving the player character (here, an operation of pressing the cross key 131) has been performed by the player. This determination is made based on the input of the operation switch 13 detected in the immediately preceding S51. That is, when the cross key 131 is not pressed by the player, the process of S57 is skipped and the process proceeds to S58. On the other hand, when the cross key 131 is pressed by the player, the process proceeds to S58 after performing the process in S57. In S57, a player character movement process is performed. In the movement process of the player character, the player character is moved and displayed on the LCD 12 according to the direction of the pressed button of the up / down / left / right buttons of the cross key 131. At this time, as the player character moves, the base point of the operation area also moves, and the operation area (shadow) also moves accordingly. Specifically, with the movement of the player character, the position data of the player character stored in the character object position data storage area 244 is updated, the position data in the base position data storage area 243 is updated accordingly, and The region bitmap is updated.
[0096]
In S58, it is determined whether or not an operation for executing the region-related processing (here, an operation of pressing the A button 13a) has been performed by the player. This determination is made based on the input of the operation switch 13 detected in the immediately preceding S51. That is, when the A button 13a is not pressed by the player, the process of S59 is skipped and the process proceeds to S60. On the other hand, when the A button 13a is pressed by the player, the process proceeds to S60 after executing the process of S59. In S59, region related processing is performed.
[0097]
It is assumed that the area-related process performed in S59 is the above-described attack process or item composition process (see FIGS. 16 and 17). Whether the attack process or the item composition process is executed is a process selected in the effect menu process of S63 described later. Note that data indicating which process is selected at the time of S59 is stored in the work RAM 24 (see S63 described later). In addition, before the effect menu process is performed, it is assumed that one of the processes selected in advance by default among the attack process and the item composition process is stored in the work RAM 24.
[0098]
Specifically, the region-related processing is executed as follows. That is, in response to the A button 13a being pressed by the player, the above-described region determination process is performed for each character object (excluding the player object) displayed in the game screen. As a result of the area determination process, a predetermined effect process corresponding to the attack process or the item composition process is performed on the character object determined to be included in the operation area or the burn-in area. For example, as a predetermined effect process corresponding to the attack process, the vitality value (attribute value set for the enemy object) of the enemy object is decreased. In addition, as a predetermined effect process corresponding to the item composition process, an item associated with the item object determined to be included in the operation area is generated and displayed on the game screen. As described above, in S59, a predetermined process (attack process or item composition process) is performed in response to the operation of the A button 13a.
[0099]
In S60, it is determined whether or not an operation for changing the shape of the operation area (here, an operation of pressing the B button 13b) has been performed by the player. This determination is made based on the input of the operation switch 13 detected in the immediately preceding S51. That is, when the B button 13b is not pressed by the player, the process of S61 is skipped and the process proceeds to S62. On the other hand, when the B button 13b is pressed by the player, the process proceeds to S62 after performing the process of S61.
[0100]
In S61, the shape of the operation area is changed. For example, the shape of the shadow of the player character, which is the operation area, is changed from the shadow of the pose where the player character is holding the sword (shadow A) to the shadow of the pose where the sword is raised (shadow B). Specifically, the area object image data storage area 1522 stores area object data indicating the shadow A and area object data indicating the shadow B. Then, in response to the B button 13b being pressed by the player, the area object displayed on the game screen is converted from the area object indicating the shadow A to the area object indicating the shadow B. As a result, the shadow of the player character can be displayed as if it has changed. In S61, as the shadow shape is changed, the pose of the player character itself may be changed from a pose in which the player character is holding the sword to a pose in which the sword is raised.
[0101]
In S62, it is determined whether or not an operation for executing the effect menu processing (here, an operation of pressing the select button 133) has been performed by the player. Here, the effect menu process is a process for selecting which of the attack process and the item composition process is executed as the area-related process in S59 described above. The determination in S62 is made based on the input of the operation switch 13 detected in the immediately preceding S51. That is, when the select button 133 is not pressed by the player, the process of S63 is skipped and the process proceeds to S64. On the other hand, when the select button 133 is pressed by the player, the process proceeds to S64 after executing the process of S63.
[0102]
In the effect menu process of S63, either the attack process or the item composition process is selected by the player. Here, the display screen and selection method of the effect menu process may be any method. For example, the attack process and the item composition process may be interchanged in response to the selection button 133 being pressed. Data indicating the process (attack process or item composition process) selected in S63 is stored in the work RAM 24.
[0103]
Next, in S64, it is determined whether an activation object is included in the operation area. Specifically, the area determination process shown in FIG. 24 is performed for all activation objects displayed on the LCD 12, and based on the result, it is determined whether or not the activation object is included in the operation area. In other words, when there is an activated object determined to be included in the operation area by the area determination process, it is determined that the activated object is included in the operation area. On the other hand, when there is no activation object determined to be included in the operation area by the area determination process, it is determined that no activation object is included in the operation area. When the activation object is not included in the operation area, the process of S65 is skipped and the process proceeds to S66. On the other hand, if the activation object is included in the operation area, the process proceeds to S66 after executing the process of S65.
[0104]
In S65, a process corresponding to the activated object determined to be included in the operation area in the area determination process executed in S64 is performed. For example, when the activation object is the above-described sound generation object, a predetermined sound defined by the sound generation object is automatically output from the speaker 29 of the portable game apparatus 10 (without operation input by the player). Accordingly, in S64 and S65, a predetermined sound is output in response to the activation object being included in the operation area.
[0105]
Next, in S66 and S67, the above-described printing process (see FIG. 19) is executed. First, in S66, it is determined whether or not an operation for executing the printing process (here, an operation of pressing the L button 13L) has been performed by the player. The determination in S66 is made based on the input of the operation switch 13 detected in the immediately preceding S51. That is, when the L button 13L is not pressed by the player, the process of S67 is skipped and the process proceeds to S68. On the other hand, when the L button 13L is pressed by the player, the process proceeds to S68 after performing the process of S67.
[0106]
In S67, the area bitmap stored in the area bitmap storage area 245 is copied to the burned area bitmap storage area. Note that the burn-in area bitmap storage area is a storage area as shown in FIG. 25, similar to the area bitmap storage area. As described above, in S54, the data of the area bitmap storage area 245 and the data of the burned area bitmap storage area 246 are combined and the area is displayed, so the next loop after the processing of S67 is performed. In S54 executed in step S5, the burned area is also displayed.
[0107]
Next, in S68, it is determined whether or not an operation for executing the base point changing process (here, an operation of pressing the R button 13R) has been performed by the player. This determination is made based on the input of the operation switch 13 detected in the immediately preceding S51. That is, when the R button 13R is not pressed by the player, the process of S69 and S70 is skipped and the process proceeds to S71. On the other hand, when the R button 13R is pressed by the player, the process proceeds to S71 after executing the processes of S69 and S70.
[0108]
In S69, it is determined whether or not a base point candidate object is included in the operation area. The determination in S69 is performed according to the area determination process shown in FIG. 24, similar to the determinations in S30 and S32. That is, it is determined whether or not a base point candidate object is included in the operation region by performing region determination processing on all displayed base point candidate objects. When the base point candidate object is not included in the operation area, the process of S70 is skipped and the process proceeds to S71. On the other hand, when the base point candidate object is included in the operation area, the process proceeds to S71 after executing the process in S70.
[0109]
In S70, the base point is changed to the position of the base point candidate object. Here, the base point candidate object to which the position of the base point is changed is the base point candidate object that is determined to be included in the operation region in the region determination process performed in S69. Specifically, the position data stored in the base position data storage area 243 of the work RAM 24 is rewritten with the position data of the base point candidate object stored in the character object position data. As a result, the position of the base point of the operation area (shadow) displayed thereafter is changed to the position of the base point candidate object. For example, if the game screen before the process of S70 is shown in FIG. 20A, the game screen after the process of S70 is as shown in FIG. As described above, by changing the base point to the position of the base point candidate object, the player can obtain an unprecedented new operation feeling that the shadow of the character moves on the shadow of another character and moves. Can do.
[0110]
In the base point changing process in S70, the region object may be converted into a shape suitable for the base point candidate object. In the example of FIG. 20, the shape of the player object 50 is different from the shape of the base point candidate object 54. In such a case, if the shape of the shadow object that is a shadow image is left as it is, the shape of the character (base point candidate object 54) and the shape of the shadow (shadow object 34) are different, which is very unnatural. Therefore, the region object is changed according to the type (shape) of the base point candidate object by the following method. That is, the number of shadow objects corresponding to each base point candidate object is prepared in advance in the ROM 152 of the cartridge 15. Then, when the process of S70 is performed, the shadow object is changed to one corresponding to the change target base candidate object. Thereby, even when the base point is changed, the shape of the shadow is changed to a shape suitable for the shape of the character.
[0111]
Next, in S71, other game processing (for example, game score calculation processing, game sound output processing, etc.) is performed. In subsequent S72, processing for moving the enemy object is performed. The movement of the enemy object is controlled by the control circuit 20 based on the program. Finally, in S73, it is determined whether or not the game is over. For example, it is determined whether or not the vitality of the player character has become 0 or the time has expired. As a result of the determination in S73, if the game is not over, the process returns to S51 and repeats the processes in S51 to S72. On the other hand, if the result of determination in S73 is that the game is over, the game process is terminated. When the game process ends, the process of the first game example shown in FIG. 21 ends.
[0112]
In the game process described above with reference to FIGS. 26 and 27, the attribute change process (step S59 and step S65) and the burn process (step S67) are performed as the area-related processes. Here, in the game process, an erasing process, a pasting process, and a moving process may be performed instead of these processes. Hereinafter, as a modification of the game process, a case where the object pasting process shown in FIG. 10 is performed will be described.
[0113]
FIG. 28 is a flowchart showing details of the game process in the case of performing the object erasing process and the pasting process. First, in S80, a player object indicating a player character appearing in the game, other character objects, a background image, and the like are displayed. The process of S80 is the same as S50 shown in FIG. Accordingly, in the case of FIG. 28 as well, as in FIG. 26, the position of the base point at the start of the game is assumed to be the position of the player character displayed in S80.
[0114]
In S81, the same processing as S51 to S55 shown in FIG. 26 is performed. Next to S81, in S82, it is determined whether or not an operation for executing the object erasing process (here, an operation for pressing the A button 13a) has been performed by the player. Specifically, if there is an input related to the A button 13a in the immediately preceding S81, it is determined that an operation for executing the object erasing process has been performed. On the other hand, when there is no input regarding the A button 13a in the immediately preceding S81, it is determined that an operation for executing the object erasing process has not been performed. As a result of the determination in S81, if it is determined that an operation for executing the object erasing process has not been performed, the process proceeds to S92 without performing the processes in S83 to S91. On the other hand, as a result of the determination in S81, if it is determined that an operation for executing the object erasing process has been performed, the process proceeds to S83.
[0115]
In S83, the size and shape of the operation area are fixed. That is, in S83, the size and shape of the operation area are not changed in the subsequent object erasing process and pasting process. Specifically, the size and shape of the operation area when the A button 13a is pressed in S82 are stored in the work RAM 24.
[0116]
In S84, the object inside the operation area is stored. Specifically, for the object inside the operation area, the type of the object and the position in the operation area are stored in the work RAM 24. Here, the type of object is typically an identifier for identifying the object.
[0117]
In S85, the input of the operation switch 13 is detected. The input detected here is an input for an operation related to the object pasting process. In subsequent S86, the input of the acceleration sensor 154 is detected. Further, in S87, a process of rotating the area object is performed according to the acceleration sensor output value detected in S86. Here, the size and shape of the operation area are fixed in S83. Therefore, the tilt amount of the acceleration sensor 154 is ignored, and only the area object is rotated based on the tilt direction of the acceleration sensor 154 detected in S86. As described above, in the object erasing process and the pasting process shown in FIG. 28, the player can only perform the rotation operation of the operation area, and cannot change the size (and shape) of the operation area. .
[0118]
Following S87, after clearing the region bitmap in S88, a region bitmap is generated based on the region object rotated in the processing of S87 and the position of the base point. In S89, the operation area is displayed on the LCD 12 based on the area bitmap generated in S88. Here, in S89, only the operation area is displayed, and objects in the area are not displayed. Therefore, the object is not displayed until S91 is performed after S82. As a result, the erasure process is performed, that is, the object in the operation area is erased.
[0119]
Next to S89, in S90, it is determined whether or not an operation for executing the object pasting process (here, an operation of releasing the pressed A button 13a) has been performed by the player. Specifically, when there is an input related to the A button 13a in the immediately preceding S85, it is determined that an operation for executing the object pasting process has not been performed. On the other hand, if there is no input regarding the A button 13a in the immediately preceding S85, it is determined that an operation for executing the object pasting process has been performed. As a result of the determination in S90, when it is determined that the operation for executing the object pasting process has not been performed, the process returns to S85 and the processes in S85 to S89 are performed. On the other hand, as a result of the determination in S90, when it is determined that an operation for executing the object pasting process has been performed, the process proceeds to S91.
[0120]
In S91, in addition to the operation area displayed in S89, objects in the operation area are displayed. At this time, the object stored in the work RAM 24 in S84 is displayed as the object in the operation area. That is, it is displayed according to the type of the object stored in the work RAM 24 in S84 and the position in the operation area. As a result, the object is displayed while maintaining the positional relationship in the operation area at the time of the erasing process. In step S91, the object pasting process is completed, and then step S92 is performed.
[0121]
In S92, the same processing as S71 to S72 shown in FIG. 27 is performed. In subsequent S93, it is determined whether or not the game is over. The process of S93 is the same process as S73 shown in FIG. Therefore, if the result of the determination in S93 is that the game is not over, the process returns to S81 and repeats the processes in S81 to S92. On the other hand, if the result of determination in S73 is that the game is over, the game process shown in FIG. 28 is terminated.
[0122]
In the object erasing process and the pasting process described with reference to FIG. 28, the player can only execute the rotation of the operation area. Here, in another embodiment, the player may be able to change the size of the operation area. Further, at that time, the proportional enlargement process shown in FIG. In addition, the player may be able to move the base point during the object pasting process. For example, the base point can be moved by performing the processing of S68 to S70 shown in FIG. 27 between S89 and S90 shown in FIG.
[0123]
In S89 of FIG. 28, only the operation area is displayed on the game screen, and objects in the operation area are not displayed on the game screen. Here, in another embodiment, an object in the operation area may be displayed. Thereby, the movement process shown in FIG. 11 can be realized.
[0124]
Next, a second game example in this embodiment will be described. In the first game example, the player operates the player character and its shadow (operation area). On the other hand, in the second game example, the player operates the shadow (operation area) in accordance with the movement of the character that is automatically controlled by the portable game apparatus 10.
[0125]
FIG. 29 is a diagram showing an outline of the second game example. In the game shown in FIG. 29, the player operates shadow objects 65 to 68 that are shadows of the columnar column objects 61 to 64. That is, the operation area is a shadow of the column objects 61 to 64. The person object 69 is automatically controlled by the portable game device 10 and moves toward the goal point 70. The player operates the shadow objects 65 to 68 so that the person object 69 can reach the goal point 70 through the shadow objects 65 to 68. For example, when the person object 69 has moved to the position shown in FIG. 29B, the player must manipulate the tilt of the portable game device 10 so that the shadow objects 65 to 68 extend in the right direction on the paper surface. . Here, when the person object 69 is present at the same position as in FIG. 29B, the portable game device 10 is operated so that the shadow objects 65 to 68 extend downward on the page as shown in FIG. 29C. And the game is over.
[0126]
FIG. 30 is a flowchart showing the process of the second game example. The flowchart shown in FIG. 30 is a flowchart of a program to be executed by the control circuit 20 of the game system. First, in S100, an initialization process is performed. In subsequent S101, the basic position is set. The process of S100 is the same as S11 shown in FIG. 21, and the process of S101 is the same as S12 shown in FIG. Next, in S102, pillar objects 61 to 64, a person object 69, an object indicating the goal point 70, and the like are displayed. Here, the base point of the operation area is the position of each column object 61 to 64.
[0127]
Following S102, in S103, the input of the acceleration sensor 154 is detected. The process of S103 is the same as that of S23 and S52. In the subsequent S104, a person object moving process is performed. The movement of the person object is controlled by the portable game device 10. The portable game apparatus 10 may move the person object 69 according to a predetermined algorithm, or may move the person object irregularly using a random number, but the person object 69 finally reaches the goal point 70. To control.
[0128]
Next to S104, in S105, the shadows of the column objects 61 to 64, that is, the shadow objects 65 to 68 are displayed based on the acceleration sensor values detected in S103. Each shadow object 65-68 is displayed with the length of the portable game apparatus 10 in the tilt direction changing according to the tilt amount. Here, the generation method of the shadow object to be displayed is a method (the method of S53 to S55 in FIG. 26) in which the object prepared in advance is rotated and the length is changed as in the first game example. Alternatively, a method of moving the light source may be used.
[0129]
In S106, it is determined whether the person object 69 has reached the goal point 70 or not. Specifically, it is determined whether or not the position of the person object 68 moved in S104 immediately before matches the goal point 70. When the position of the person object 69 coincides with the goal point 70, it is determined that the person object 69 has reached the goal point 70, and the process of S107 is performed. On the other hand, when the position of the person object 69 does not coincide with the goal point 70, it is determined that the person object 69 has not reached the goal point 70, and the process of S108 is performed.
[0130]
In S107, the fact that the game was successful is displayed on the game screen, and the processing according to the second game example ends. On the other hand, in S108, it is determined whether or not the person object 69 is in the shadow. That is, if the position of the person object 69 moved in S104 is within at least one of the shadow objects 65 to 68 changed in S105, it is determined that the person object 69 is in the shadow. In this case, returning to the process of S103, the processes of S103 to S106 are performed again. On the other hand, if the position of the person object 69 moved in S104 is not in any of the shadow objects 65 to 68 changed in S105, it is determined that the person object 69 is not in the shadow. In this case, it is assumed that the person object has disappeared (game over), and in S109, the fact that the game has failed is displayed on the game screen. After S109, the process according to the second game example ends.
[0131]
As described above, as shown in the second game example, there may be a plurality of operation areas. When there are a plurality of operation areas, the direction in which each operation area expands and contracts with respect to the tilt direction of the portable game apparatus 10 may be different directions for each operation area. For example, it is possible to expand and contract each of the plurality of operation areas in different directions by separately operating the plurality of operation areas with one operation area operable at a time. Furthermore, a predetermined area-related process may be performed only when a plurality of operation areas overlap.
[0132]
According to the present embodiment, the operation area is a circular shape (circular object 31) indicating a simple area in the game image, or a shadow representing another character (shadow objects 34, 65 to 68). there were. Here, in other embodiments, the region is not limited to the above. For example, the operation area may represent a place where light is applied. That is, the player operates a place (operation area) where light is applied by operating the tilt of the portable game device. The portable game device causes characters and pictures to appear only in a portion that is exposed to light (inside the operation area). In the game as described above, the player can play the game as if holding a flashlight.
[0133]
Furthermore, according to the present embodiment, the operation region is planar, but may be three-dimensional in other embodiments. The operation area may represent, for example, a three-dimensional cloud, flame, or puddle. Specifically, a game in which a player operates a cloud flowing in a three-dimensional space using an inclination sensor can be considered. Specifically, the cloud expands and contracts according to the inclination of the game device, for example, a bird is flying around the cloud, and the player operates the cloud to catch the bird (catch the bird by putting it in the cloud) ). In addition, for example, a game in which the player operates a monster and the flame that the monster exhales can be considered. The player moves the monster using a button or the like and operates a flame for attacking the enemy character using the tilt sensor. Specifically, the flame extends in the direction in which the game device is tilted.
[0134]
In addition, according to the present embodiment, the base point for determining the display position of the operation area exists inside the operation area. Here, in another embodiment, the display position of the operation area does not need to be displayed so that the base point is inside the operation area. The base point may exist outside the operation area.
[0135]
According to the present embodiment, the game apparatus is a portable game apparatus in which a cartridge including a tilt sensor is inserted. Here, the present invention is not necessarily realized by a portable game device. The present invention can also be realized by a general stationary game device. That is, it can also be realized by a game device in which a controller including an inclination sensor is connected to a stationary game machine. In this case, the player operates by tilting only the controller.
[Brief description of the drawings]
FIG. 1 is an external view showing a game system 14 according to an embodiment of the present invention.
FIG. 2 is a block diagram of the game system 14;
3 is a diagram showing data stored in a ROM 152 of the cartridge 15. FIG.
4 is a view showing data stored in a work RAM 24. FIG.
FIG. 5 is a diagram illustrating an example of a relationship between the tilt of the portable game device 10 and an operation area.
FIG. 6 is a diagram showing an example of a game image when the operation area is a shadow of a character.
FIG. 7 is a diagram showing another example of a game image when the operation area is a shadow of a character.
FIG. 8 is a diagram illustrating an example of a relationship between the tilt of the portable game device and a region object displayed on the LCD when the operation region is a shadow of a character.
FIG. 9 is a diagram showing an example of the relationship between the tilt of the portable game device and the area object displayed on the LCD when the operation area is a shadow of a character.
FIG. 10 is a diagram illustrating an example of an object erasing process and a pasting process.
FIG. 11 is a diagram illustrating an example of object movement processing;
FIG. 12 is a diagram illustrating an example of region-related processing.
FIG. 13 is a diagram showing an example of a menu screen for selecting a player character.
FIG. 14 is a diagram showing an example of a menu screen for selecting a player character and an item to be equipped.
15 is a diagram showing a state in which the base point of the operation area is moved on the menu screen shown in FIG.
FIG. 16 is a diagram illustrating an example of attack processing that is an application example of region-related processing;
FIG. 17 is a diagram illustrating an example of item composition processing that is an application example of region-related processing;
FIG. 18 is a diagram illustrating an example of sound generation processing that is an application example of region-related processing;
FIG. 19 is a diagram illustrating an example of a printing process.
FIG. 20 is a diagram illustrating an example of a base point change process.
FIG. 21 is a flowchart showing a main flow according to a first game example.
FIG. 22 is a flowchart showing details of menu processing in S13 shown in FIG.
FIG. 23 is a flowchart showing details of menu processing in S13 shown in FIG. 21;
FIG. 24 is a flowchart showing details of region determination processing.
FIG. 25 is a diagram illustrating an example of a region bitmap.
FIG. 26 is a flowchart showing details of the game processing in S14 shown in FIG.
FIG. 27 is a flowchart showing details of the game processing in S14 shown in FIG.
FIG. 28 is a flowchart showing details of a game process in a case where an object erasing process and a pasting process are performed.
FIG. 29 is a diagram showing an outline of a second game example.
FIG. 30 is a flowchart showing processing of a second game example.
[Explanation of symbols]
10 ... portable game device
14 ... Game system
15 ... cartridge
154 ... Acceleration sensor
31 ... Circular object
32 ... Base point object
34 ... Shadow object

Claims (19)

A game device for displaying a game image,
A housing held by the player;
An inclination detecting means for detecting an inclination direction and an inclination amount of the housing;
Object placement means for placing a plurality of predetermined objects in a virtual space;
Area setting means for setting an area object in the virtual space for selecting an object to be processed among the plurality of predetermined objects;
The region object, in a direction determined according to the tilt direction, a region stretching means for displaying by stretching to a length corresponding to previous SL inclination amount,
It is determined whether each of the plurality of objects exists inside or outside the area indicated by the area object, and whether or not to be a target of a predetermined process related to the game is determined according to the determination result A game apparatus comprising: area-related processing means for determining . A base point setting means for setting a base point for setting the area object in the virtual space;
The game device according to claim 1, wherein the region setting means determines a position at which the region object is arranged based on the position of the base point. It said area setting means, and determines the position of the region object to be placed in a direction determined according to the tilt direction as viewed from the base point, the game apparatus according to claim 2. A basic shape storage means for storing image data indicating the basic shape of the region object ;
The area stretching means, with a direction that is determined according to the tilt direction, the length of the region object basic shape indicated by the image data is changed to a length corresponding to the tilt amount, according to claim 1 game apparatus. A basic shape storage means for storing image data indicating the basic shape of the region object ;
The region expansion / contraction means is
Basic shape rotating means for rotating the basic shape based on the tilt direction;
About direction is determined according to the slope way toward the, and a basic shape elastic means for varying the length of the region object basic shape indicated by the image data to a length corresponding to the amount of inclination, according to claim 1 Game device. It said region related processing means performs the predetermined processing with respect to any of all of the predetermined object present in all of the predetermined object or outside present inside the area indicated by the area object, wherein Item 4. A game device according to Item 1 . The game device according to claim 1 , wherein the area-related processing unit performs a process of changing a display mode of the predetermined object as the predetermined process. The game apparatus according to claim 1 , wherein the area-related processing unit performs a process of changing an attribute set for the predetermined object as the predetermined process. The region related processing means is
An object storage section for storing the predetermined object present inside the area indicated by the Contact Keru the region object to the first point in time,
The objects stored in the object storage unit, and a object arrangement unit be placed in the area indicated by the Contact Keru the region object to the second time point, the game apparatus according to claim 1. The object storage unit stores an object that exists inside the area indicated by the Contact Keru the region object to the first point, the arrangement in the region of the object,
The object arrangement unit, the object stored in the object storage unit, in the area indicated by the Contact Keru the region object to the second time point, be placed in accordance with the arrangement stored in the object storage unit, to claim 9 The game device described. The area-related processing means, as said predetermined process, comprises a region storing means for performing a process of storing your Keru the region object to the first point in time,
The game device according to claim 1, wherein the area setting unit arranges an area object based on the current output of the inclination detection unit and further arranges an area object stored in the area storage unit. A first operation means operated by the player;
The game apparatus according to claim 1, wherein the area-related processing unit performs the predetermined process when the first operation unit is operated. An activation object display means for displaying an activation object, which is an object associated with the predetermined process, in the game image;
The game device according to claim 1, wherein the area-related processing unit performs the predetermined process when the activation object is included in the area. The game device according to claim 2 , wherein the base point setting unit moves the base point according to an operation by a player. A base point candidate object display means for displaying a base point candidate object that is an object to be a base point candidate in the game image;
The base point setting means, when the base point candidate object is included in an area indicated by the area object, changes the position of the base point for determining the display position of the area object to the position of the base point candidate object. 2. The game device according to 2 . The game device according to claim 1, further comprising region shape changing means for changing a shape of the region object in accordance with an operation by a player. An information processing apparatus for displaying an image,
A housing held by the player;
An inclination detecting means for detecting an inclination direction and an inclination amount of the housing;
Object placement means for placing a plurality of predetermined objects in a virtual space;
Area setting means for setting an area object in the virtual space for selecting an object to be processed among the plurality of predetermined objects;
The region object, in a direction determined according to the tilt direction, a region stretching means for displaying by stretching to a length corresponding to previous SL inclination amount,
It is determined whether each of the plurality of objects exists inside or outside the area indicated by the area object, and whether or not to be a processing target of a predetermined process related to the game is determined according to the determination result An information processing apparatus comprising: a region-related processing unit for determining . A computer of a game apparatus that includes a housing held by a player and an inclination detection unit that detects an inclination of the housing and displays a game image.
A tilt detecting step for detecting a tilt direction and a tilt amount of the housing based on an output of the tilt detecting means;
An object placement step of placing a plurality of predetermined objects in a virtual space;
An area setting step for setting an area object in the virtual space for selecting an object to be processed among the plurality of predetermined objects;
The region object, in a direction determined according to the tilt direction, a region stretching step of displaying by stretching to a length corresponding to previous SL inclination amount,
It is determined whether each of the plurality of objects exists inside or outside the area indicated by the area object, and whether or not to be a target of a predetermined process related to the game is determined according to the determination result A game program for executing a region-related processing step to be determined . A computer of an information processing apparatus that includes a housing held by a player and an inclination detection unit that detects an inclination of the housing and displays an image.
A tilt detecting step for detecting a tilt direction and a tilt amount of the housing based on an output of the tilt detecting means;
An object placement step of placing a plurality of predetermined objects in a virtual space;
An area setting step for setting an area object in the virtual space for selecting an object to be processed among the plurality of predetermined objects;
The region object, in a direction determined according to the tilt direction, a region stretching step of displaying by stretching to a length corresponding to previous SL inclination amount,
It is determined whether each of the plurality of objects exists inside or outside the area indicated by the area object, and whether or not to be a target of a predetermined process related to the game is determined according to the determination result A computer program for executing a region-related processing step to be determined .

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