JP2010276613A - Navigation device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a navigation device for rationally displaying an image on navigation-related information, including the location of own ship position or other places. <P>SOLUTION: The navigation device includes a cursor display means for displaying a cursor movable in an image plane and passing through an optional point, in order to designate the optional point in the image plane for displaying each display state; and a large/small cursor display means for displaying a cursor by using a large cursor, including a horizontal line extending over the horizontal whole of the image plane and a vertical line extending over the vertical whole of the image plane during the move of the cursor; while the cursor is displayed, by using a small cursor for indicating only a portion of an optional point during the stoppage of the cursor. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a navigation apparatus that displays an image of a navigation position of a ship, a wake, a navigation target point, information on a planned route, and information associated therewith (referred to as navigation-related information in the present invention).

  As such a navigation apparatus, as shown in FIG. 13, the position of the ship's navigation position, that is, the position measurement part 10 for measuring the position of the ship, for example, GPS radio navigation, Loran C radio navigation, Decca radio navigation, etc. A configuration (hereinafter, referred to as a first conventional technique) in which a position measurement portion to be performed and a navigation related information display portion 20 that displays an image of navigation related information are separated is well known.

  Note that in each drawing described below, a portion denoted by the same reference numeral is a portion having the same function as a portion having the same reference numeral described in any of the drawings. The point or position is generally a point or position represented by a latitude and longitude value, but when using Loran radio navigation or Decca radio navigation, it may be a point or position represented by an LOP value in the navigation.

  In addition, a predetermined part of the position measurement part 10 in the first prior art, for example, a calculation part for obtaining data of own ship position 10a, own ship speed 10b, and current traveling direction 10c, and a navigation related information display part 20 are integrated. The configuration (hereinafter referred to as second prior art) is well known.

  The position measurement part 10 by radio navigation is generally called a radio navigation receiver, and the navigation related information display part 20 is generally called a wake recording device.

  Further, for example, when a radio navigation receiver using GPS radio navigation is used as the position measurement portion 10, a configuration capable of measuring not only the own ship position but also the own ship speed and the current traveling direction (hereinafter referred to as “No. 1”). 3 prior art) is well known. In addition, the radio navigation receiver using GPS radio navigation has a feature that the own ship speed and the current traveling direction can be measured from the Doppler shift amount of the frequency of the GPS radio wave.

  In FIG. 13, the position measurement portion 10, for example, a GPS radio navigation receiver, displays a navigation-related information display using a signal including data of the own ship position 10 a, own ship speed 10 b, and current traveling direction 10 c as a part of the navigation related information. Part 20 is given.

  The navigation related information display part 20 includes a navigation information processing part 70 having a control processing function (hereinafter referred to as CPU) 70A mainly composed of a microcomputer, for example, a control processing part mainly composed of a commercially available CPU, and a CPU 70A. A display processing portion 80 having a jointly operating CPU 80A, for example, a control processing portion mainly composed of a commercially available drawing processing IC.

  The data of the own ship position 10a, own ship speed 10b, and current traveling direction 10c is taken into the navigation information processing part 70 via the input / output port 71A, that is, the I / O part, and the data of the own ship position 10a. Is loaded at predetermined time intervals or at predetermined distance intervals based on the setting conditions given by operating the setting operation portion 60 described later, and stored in the wake data memory 74.

  The setting operation portion 60 is, for example, an operation panel on which operation portions such as operation keys for giving a required operation input to the navigation information processing portion 70 via the input / output port 71B, that is, the I / O portion are arranged. In the operation part for setting processing conditions for obtaining the required navigation-related information by the navigation information processing part 70 and display conditions for displaying the required navigation-related conditions on the display screen 81 of the display processing part 80. Yes, for example, setting or changing display scale, display / deletion of latitude / longitude line, movement / enlargement / reduction of display range, display / deletion of map, etc., in addition to the above-mentioned data acquisition conditions of ship position 10a Each operation key is provided.

  The navigation information processing section 70 includes a working memory 73 for storing setting data based on the setting signal 60a fetched from the input / output port 71B, data necessary for the control process, and the above-described track data memory 74. , A map data memory 75 for storing data for displaying a map, a clock circuit 76 for obtaining temporal data, and a processing memory for storing designation data for fixed figures and screen elements such as marks and menus 72, the navigation related information data obtained by carrying out the required processing by the control processing flow program stored in the processing memory 72 is stored in the work memory 73.

  The navigation-related information data stored in the work memory 73 includes the navigation-related information data stored in the track data memory 74 and the navigation-related information data stored in the map data memory 75 as necessary. At the same time, it is given to the display processing portion 80. In general, either one of the case of displaying a figure of only the coastline and the case of displaying a figure in which the land side portion of the coastline is filled with a predetermined color are used as the map.

  In the display processing portion 80, the CPU 80A controls the data of each navigation related information given from the information processing portion 70, the image element data for drawing stored in the image element memory 82, and the processing memory 83. By processing based on the processing flow program for processing, an image of target navigation-related information, for example, as shown in FIG.

  Own ship track CR1, planned route RT1, destination point JP1, map M1, latitudinal line LX / longitude line LY, figure of own ship position 10a, own ship speed 10b, current traveling direction 10c, destination point JP1, and progress Image data representing the character TT such as the numerical value of the difference angle θ1 between the direction 10c and the planned route RT1 is stored in the display screen memory 84 while being sequentially updated, and the stored contents of the display screen memory 84 are read out. Are displayed on the display screen 81.

  The processing memory 72, the processing memory 83, the map data memory 75, and the image element memory 82 are composed of a ROM, that is, a read-only memory, and a work memory 73, a track data memory 74, and a display screen. The memory 84 is composed of a RAM, that is, a rewritable and readable memory, and the stored contents of the wake data memory 74 are stored in the memory holding battery 77, for example By storing and holding a lithium battery that can be used over a period of time or a rechargeable battery such as a nickel cadmium battery, the display of past navigation-related information can be reproduced when the device is powered on again. It is configured.

  In FIG. 14, a display screen 81 is a display screen having a display surface by raster scanning, for example, a cathode ray tube display, a dot matrix type liquid crystal display, etc. Each figure of an image to be displayed is generated as follows. Is displayed.

  The image of the ship's wake CR1 is for drawing the image data stored in the image element memory 82 at the points of the past ship's position 10a and the current ship's position 10a stored in the wake data memory 74. The image elements are connected to each other and displayed as one wakeline figure. In addition, the own ship track CR2 at the time of the past voyage can be displayed by changing the type of line or by changing the color as described later.

  The image of the planned route RT1 is obtained by connecting a route to the destination point JP1 by connecting a plurality of direction change points P1 to P4 with image elements for drawing stored in the image element memory 82. The figure is displayed in the form of lines L1 to L5.

  Also, only the destination point JP1 is set without setting the direction change points P1 to P4, and a figure of only one straight line connecting the own ship position 10a and the destination point JP1 at the time when the setting is made. It can also be configured to display. The direction change points P1 to P4 are also referred to as turning points.

  The image of the map M1 is displayed as a series of coastline graphics, for example, by connecting the finely spaced points stored in the map data memory 75 with the drawing image elements stored in the image element memory 82. . In addition, since the map M1 becomes a nautical chart in the case of a ship, a graphic image of a contour line Ld connecting predetermined depths of the seabed, for example, every 100 m, is also displayed.

  Images of latitude line LX / longitude line LY are determined according to predetermined conditions or conditions set on the menu screen described later, for example, two latitude lines LX, three longitude lines LY, and an interval of latitude A horizontal line and a vertical line over the entire screen, for example, a horizontal line by a solid line, by a drawing image element stored in the image element memory 82 for the location of the point calculated in accordance with the condition that the longitude is “′” or “″”. Displays a figure with vertical lines.

  A movable cursor CLX / CLY for designating an arbitrary point CP on the display screen 81 is an image element for drawing the location of the designated point CP that moves on the display screen 81 by an operation input from the setting operation portion 60. With this, a horizontal line and a vertical line over the entire screen, for example, a graphic with a horizontal line and a vertical line as dotted lines are displayed.

  Specifically, in the setting operation portion 60, each operation key is constituted by, for example, a contact operation key that closes a contact only during operation, and input by the operated operation key is predetermined at the input / output port 71B. The signal is converted into a signal of the following code and given to a predetermined portion.

  In the case of color display in which each navigation-related information is displayed in different colors, for example, as shown in FIG. 15, a screen selection operation part 61, a destination setting operation part 62, a track setting operation part 63, It comprises a mark setting operation portion 64, a numerical value setting operation portion 65, a screen setting operation portion 66, a power supply operation portion 67, an arbitrary direction movement operation portion 68, and the like.

  In FIG. 15, a screen selection operation portion 61 is an operation portion for mainly selecting a display form of a display image of navigation-related information displayed on the display screen 81, and includes a “wake” key, a “steering” key, and a “monitor” key.・ "Menu" key is provided.

  The “wake” key is an operation key for selecting a display state mainly based on the ship's track, for example, the display state of FIG. 14. The “ship maneuvering” key is an operation key for selecting a display state mainly based on the ship maneuvering of the ship. The “monitor” key is an operation key for selecting a state in which navigation-related information is displayed and monitored only by characters, that is, a monitor state. The “menu” key is an operation key for selecting a display state for displaying a menu screen for setting each detail among the display conditions of the navigation related information.

  The destination setting operation part 62 is an operation part for mainly selecting a display form related to the destination in the navigation-related information displayed on the display screen 81, and includes a “destination” key, a “destination” key, A “route” key, an “alarm” key, etc. are provided.

  The “destination” key sets a destination point as an end point of navigation, for example, the destination point JP1 of FIG. 14 and registers the destination with a predetermined code, for example, a destination number. This is an operation key for displaying.

  The “destination” key is an operation key for setting a display state in which any one of destinations registered by an operation with the “destination” key is selected as a destination. The “route” key is an operation key for setting a display state for setting a planned route to a destination, for example, the planned route RT1 of FIG. 14, that is, a route.

  The “alarm” key is an operation key for setting a display condition for setting an alarm condition for generating an alarm such as arrival at a predetermined point, for example, a point at a predetermined distance from the destination point JP1 in FIG.

  The wake setting operation part 63 is an operation part for mainly selecting a display form related to a wake or the like in the navigation related information displayed on the display screen 81, and includes a “map” key, “color” key, and “erase” key. -A "connect / disconnect" key is provided.

  The “map” key is an operation key for selecting display / non-display of the map in the display state of the wake display. The “color” key is an operation key for selecting each display color for the figure of the wake, for example, the ship wake CR1 and the past wake CR2 in FIG.

  The display color is selected by operating the “color” key to display the screen of the “color” selection menu, and the numbers corresponding to the respective colors displayed in the “color” selection menu are displayed as “0” to “ “9” is selected with each numeric key.

  The “erase” key is an operation key for temporarily erasing an image of a route, for example, an image of own ship track CR1 and past track CR2 in FIG. The “connect / disconnect” key is used to select an interval value for capturing the data of the ship position 10a into the track data memory 74 in order to draw a track, and to select the interval value ON state, that is, the “contact” state. An operation key for switching to an OFF state, that is, a “OFF” state.

  In the “contact” state by the “contact / disconnect” key, the interval value of the interval at which the data of the ship position 10a is taken into the wake data memory 74 is determined by a predetermined time interval on the menu screen by the “menu” key. For example, it can be set to capture every “20 seconds”, or can be set to capture every predetermined distance interval, for example, every movement “100 m”.

  Here, the display state of the wake display refers to a display state in which the wake display can be performed, and includes a display state in which the image of the wake is erased as described above.

  The mark setting operation portion 64 is mainly used for each predetermined point associated with the navigation-related information, for example, the own ship position 10a, the destination point JP1 in FIG. This is the operation part that selects the figure and color of the mark that displays the attention points EV1, EV2, etc., and has the “color” key, “○” key, “△” key, “□” key, etc. .

  The “color” key is an operation key for performing an operation of selecting each display color for further distinguishing each mark figure into a plurality. Each display color is selected by selecting “color” in the wake setting operation portion 63. Select by the same operation. The “O” key, the “△” key, and the “□” key select one of these keys as a mark by operating one of these keys.

  These marks are always displayed at a constant size regardless of “enlargement” and “reduction” of the displayed image. Further, the mark for displaying the above-mentioned matters to be noted, for example, the points EV1 and EV2 where fishing is performed is referred to as an event mark.

  The numerical value setting operation part 65 is an operation part mainly for inputting a required numerical value or selecting a required item, for example, the type of “color” in the display state of the menu screen. Numeric keys of “0” to “9”, sign keys of “+” and “−” are provided.

  The screen setting operation portion 66 is an operation portion for mainly performing operations such as changing the scale of the screen and moving the screen in the display state of the wake display. The “center” key, “↑” key, “↓” key, “→” key, “←” key, “enlarge” key, “reduced” key, etc. are provided.

  The “center” key is an operation key for bringing the own ship position 10 a into a display state positioned at the center of the display screen 81. An “enlarge” key, that is, an operation key with four arrows pointing diagonally outward is an operation key for enlarging the displayed screen in a zoomed manner. The “reduction” key, that is, the operation keys with four arrows directed diagonally inward are operation keys for reducing the displayed screen in a zoomed manner.

  The “↑” key, “↓” key, “→” key, and “←” key indicate the intersection of the cursors CLX and CLY, that is, the designated point CP when the cursor is displayed by the “cursor” key described later. Acts as an operation key that moves in the up, down, left, or right direction corresponding to the arrow direction, and when the cursor is not displayed, the entire screen is in the up / down direction corresponding to the arrow direction・ Operates as an operation key that moves to the left or right.

  The power operation section 67 is an operation section for mainly turning on / off the power of the apparatus and adjusting the brightness of the display screen 81, and is provided with a “power” key, a “luminance” key, and the like.

  The “power” key 67A is an operation key for performing an operation of turning on / off the apparatus, that is, turning on or off the apparatus. The “luminance” key is an operation key for performing an operation for changing the luminance of the display screen. Then, as shown in FIG. 13, the part for turning on / off the power is supplied from the onboard power supply 50 to the internal power supply part 52 for applying a required voltage to each part of the apparatus via the self-holding circuit 55. It is.

  Each time the power key 67A of FIG. 15 is operated, the self-holding circuit 55 alternately switches and holds between the on-side and the off-side, and when the on-board power source 50 itself is shut off, the self-holding circuit 55 automatically The circuit is configured to be reset to, for example, a combination circuit of a JK flip-flop circuit and a relay. Therefore, when a rechargeable battery is used as the memory retention battery 77, the battery is in a charged state only while the power is on.

  The arbitrary direction movement operation portion 68 is an operation portion that performs an operation of moving the entire displayed screen or the cursor CLX / CLY in an arbitrary direction, and is configured by, for example, a trackball or a joystick.

  When the cursor is displayed by the “cursor” key described later, when the cursor operates as an operation key for moving the intersection point of the cursors CLX and CLY, that is, the designated point CP in an arbitrary direction, and the cursor is not displayed. Operates as an operation key for moving the entire screen in an arbitrary direction.

  The cursor setting operation portion 69 is an operation portion for mainly performing operations such as display / non-display of the cursor, orientation of the display screen, and determination or cancellation of the selected / input condition / numerical value. “Navigation switching” key, “OK” key, “Cancel” key, etc. are provided.

  The “cursor” key is an operation key for switching the cursor CLX / CLY between a display state and a non-display state every time a key operation is performed. The “navigation switching” key is displayed every time the key operation is performed, “north direction display” in which the display image 81 is displayed with the direction directly above the display screen 81 being “north direction”, ”Is an operation key for switching between“ heading direction display ”for displaying a display image as“ ”and“ destination direction display ”for displaying a display image with the direction directly above the display screen 81 as“ direction of destination point JP1 ”.

  The “decision” key is an operation key for “deciding” to operate according to a condition / numerical value selected or input by operating another operation key. The “Cancel” key is an operation key for canceling the above-mentioned conditions / numerical values.

  13 to 15, the external storage part 90 and its input / output port 91 are provided as necessary to store necessary data in the apparatus from the outside, or data in the apparatus. Is well known in the art (hereinafter referred to as “fourth conventional”) in which the information is stored in an external storage portion 90, for example, an IC card.

  In the case of the former configuration, for example, the map data memory 75 is removed, and the external storage portion 90 is configured as an IC card that stores map data in advance, and the IC card is stored in the input / output port 91. By providing a reading function, the map data is read from the external storage portion 90 and displayed.

  In the case of the latter configuration, for example, the external storage portion 90 is configured as an IC card that stores display data on the display screen 81 in the wake display state, and the IC card is stored in the input / output port 91. By providing the read function, the navigation related information in the past track display state is stored, and the past track display state is reproduced and displayed as necessary.

  In the configuration of FIG. 14 above, the ship maneuvering state of the ship with respect to the planned route RT1 is indicated by the course deviation θ1, but instead of displaying such a course deviation, the planned route RT1 is centered as shown in FIG. A predetermined distance width B1, for example, a portion with a width of 100 m on each of the left and right sides is set as a predetermined route range, and a distance width B1a where the ship position 10a exceeds the distance width B1 is displayed as a course deviation amount (hereinafter referred to as fifth Is known).

[Screen transition return display operation]
In the navigation device 100 as described above, after the scale is enlarged or reduced from the display state including the point of the ship position 10a on the display screen 81, the display screen 81 shifts to the display state including the destination point JP1, for example. Again, the operation for shifting to the display state including the own ship position 10a (hereinafter referred to as “screen transition return display operation”) is configured as follows (hereinafter referred to as “sixth prior art”).

  First, in the display state of FIG. 14, when the cursor is not displayed, the cursor CLX / CLY is displayed by operating the “cursor” key, and the “↑” key, “↓” key, “→” key, After operating the required operation key of the “←” key or the arbitrary direction moving operation portion 68 to match the intersection of the cursors CLX and CLY, that is, the designated point CP with the destination point JP1, the “center” When the key is operated, the scale of display remains the scale of FIG. 14, for example, the scale of 1/10000, and the display moves to the display state where the destination point JP1 is positioned at the center position of the display screen 81.

  Next, the desired operation key of the “enlarge” key or the “reduced” key, in this case, the “enlarge” key, is operated to enlarge to a desired scale, for example, a scale of 1/4000. For example, the display state shown in FIG. 17 is set.

  In the state of FIG. 17, an enlarged display state in which the vicinity of the destination point JP <b> 1 is enlarged is displayed, and thus navigation-related information in the area near the destination point JP <b> 1 can be determined in detail. Further, when the scale is changed and the “reduction” key is operated to display the reduced display state, the navigation-related information in a wide area centering on the destination point JP1 is roughly judged to navigate. Useful for planning.

  However, in the above enlarged display state, in most cases, the point of the own ship position 10a is not included, or the point of the own ship position 10a is positioned near the corner portion of the display screen 81. Since navigation-related information in the vicinity of the ship cannot be known, it is necessary to return to the display state including the point of the own ship position 10a again as shown in FIG. There is.

  Therefore, first, when the “center” key is operated, as shown in FIG. 18, the scale is kept at a scale of 1/4000 and the ship position 10 a is positioned at the center position of the display screen 81. By operating the “reduction” key, the display state is restored to the original scale, for example, the scale of 1/10000.

  In the reduced display state, the vicinity of the ship position 10a becomes too small and the navigation state cannot be clearly determined. Therefore, the “center” key is operated to display the ship position 10a on the display screen 81. After being positioned at the center position, the “magnify” key is operated to restore the display state based on the original scale.

  In addition, by operating to move the designated point CP of the cursor CLX / CLY to the outside of the display screen 81, an outside point not displayed on the display screen 81 is designated and the screen transition return display operation is performed. Can do. As the display scale, a distance value corresponding to the width in the horizontal direction or the vertical direction of the display screen 81, for example, a distance value represented by “浬” can be used instead of the scale.

[First issue]
In the configuration of the screen transition return display operation according to the sixth prior art described above, after operating the “center” key, the “reduction” key or the “enlargement” key is operated to return to the original scale. The operation is complicated and takes time.

[Second issue]
In the structure of mark display such as ○ mark, △ mark, and □ mark in the first to sixth prior arts described above, if the mark is made large and easy to see, the position of the point indicated by the mark becomes vague. Therefore, the position of the point to be pointed can be clearly determined by making the mark as small as possible, so it is difficult to see the target mark part, and if inadvertently, the mark part is missed is there.

[Third issue]
In the configuration of the storage portion in the first to sixth prior arts described above, the required storage portion of the working memory 73, the storage portion of the track data memory 74, etc. are stored and held by the storage holding battery 77. However, when the ship is anchored for a long period of time, the inboard power supply 50 is cut off during that time, and the amount of power stored in the memory retention battery 77 is reduced, resulting in the loss of stored contents.

  In order to solve such inconvenience, it is conceivable to change these storage parts to a storage part that is electrically rewritable and stores and holds electricity without electricity, for example, flash memory. Since it takes time to rewrite the contents, the processing operation of the navigation-related information is delayed, and there is a disadvantage that the intended display cannot be performed.

  Further, if a UPS (Uninterruptable Power Supply = uninterruptible power supply) is provided, the apparatus configuration becomes large, and there is a disadvantage that it cannot be provided in a simple and inexpensive configuration.

[Fourth issue]
In the configuration of the cursors CLX and CLY in the first to sixth prior arts, the horizontal line cursor CLX and the vertical line cursor CLY over the entire display screen 81 are provided. When matching the CP, there is an advantage that it can be easily matched by matching one of the cursor lines and then matching the other cursor line.

  However, since the cursor CLX / CLY is a line extending over the entire display screen, it becomes an obstacle to monitoring the images of each navigation-related information. Therefore, there is an inconvenience that it must be deleted after each use. is there.

  Furthermore, when it becomes necessary to designate another point immediately after designating one point, there is an inconvenience that the erased cursors CLX and CLY must be displayed again. .

  In order to solve such an inconvenience, a configuration in which the cursor CLX / CLY is changed to a cursor with a small cross-shaped figure is well known. However, such cursors cannot be operated to match one cursor line and then the other, like the horizontal line cursor CLX and the vertical line cursor CLY. Inconveniently, it takes a certain amount of time to make the cursor coincide with the point to perform.

[Fifth issue]
In the configuration of the storage portion in the first to sixth prior arts described above, the interval at which the data of the ship position 10a is taken into the wake data memory 74 is either a predetermined time interval or a predetermined distance interval. You can select and use it.

  However, when the time interval is selected and used, the ship position 10a is hardly changed, but a lot of data of the ship position 10a is taken into the wake data memory 74, and the wake data memory is used. The stored contents of 74 are wasted.

Further, when the distance interval is selected and used, the ship's position 10a data at many intermediate points is taken into the wake data memory 74 even though it is navigating in a substantially straight direction, and the wake data is used. There is a disadvantage that the contents stored in the memory 74 are wasted.
For this reason, there exists a subject that provision of the navigation apparatus without such an inconvenience is desired.

The present invention addresses the above-mentioned [first problem] from the first display state in which an image of navigation-related information including the point of the ship position as described above is displayed on a predetermined scale. In a navigation apparatus that can change and display an image of navigation-related information including other points away from the ship position in a second display state in which the scale is changed to another scale and displayed.

  By performing an operation of designating the other point and the scale to be changed, the point of the predetermined position in the image in the first display state and the predetermined scale are stored, and First display transition means for transitioning from the first display state to the second display state;

  A first configuration provided with second display transition means for reading the memory by a single operation and shifting from the second display state to the first display state;

In this first configuration:
The point at the predetermined position is a point at the center of the image in the first display state, an arbitrary point among the four corner points of the image in the first display state, or a point at the own ship position. A second configuration of any one or more of:

In the first configuration or the second configuration,
Each of the above scales is solved by a third configuration in which a distance value or a scale ratio corresponding to the horizontal or vertical width of the display screen for performing the above display is used.

For the above [second problem]
Display that displays the image of navigation-related information including the point of the ship's position on a predetermined scale, or the image of navigation-related information that includes other points far from the ship's position on the scale above In the navigation device that can be changed and displayed,

  A graphic surrounding each of the predetermined points for roughly identifying each predetermined point associated with each of the navigation related information is displayed, and the true of each of the predetermined points in the graphic is displayed. A fourth configuration providing point identification graphic display means for displaying a graphic for indicating a position;

In this fourth configuration:
The figure surrounding the above point is a first figure by a circle or a polygon, and the figure for indicating the true position is a second figure having a dot or cross shape smaller than the first figure. This is solved by the fifth configuration.

For the above [third problem]
In a navigation device similar to the navigation device in the fourth configuration,
As a storage portion for storing predetermined information of each of the above-mentioned related information, a volatile storage portion that can electrically rewrite and retain the above storage, and the above storage electrically A storage unit provided with a nonvolatile storage part capable of storing and holding electricity without electricity;

  A sixth memory identification processing means is provided that performs processing for making the corresponding storage contents of the nonvolatile storage portion and the volatile storage portion the same only when the operation power of the apparatus is turned on. Configuration,

In this sixth configuration,
This is achieved by a seventh configuration in which the volatile memory portion is constituted by a static RAM and a memory holding battery, and the nonvolatile memory portion is constituted by a flash memory.

For the [fourth problem] above,
In a navigation device similar to the navigation device in the fourth configuration,
Cursor display means for displaying a cursor that is movable in the screen and passes through the arbitrary point in order to specify an arbitrary point on the screen that displays each of the display states.

  While the cursor is moving, the cursor is displayed as a large cursor with a horizontal line extending across the horizontal direction of the screen and a vertical line extending across the vertical direction of the screen. An eighth configuration that includes a large and small cursor display means for displaying the cursor with a small cursor that indicates only the portion of the arbitrary point described above;

In this eighth configuration,
The above-mentioned large cursor is solved by the ninth configuration in which the horizontal line and the vertical line are displayed as dotted lines or solid lines, and the small cursor is displayed as a cross-shaped figure of about 1 cm in length and width. It is.

For the above [fifth problem]
In a navigation device similar to the navigation device in the fourth configuration,
Wake display means for displaying the wake of the ship based on the stored contents of the position value of the ship position,

  When the ship speed reaches a predetermined value, it is captured at a predetermined time interval and stored as described above, and when it is less than the predetermined value, it is acquired at a predetermined distance interval and stored as described above. A tenth configuration providing a storage unit;

In this tenth configuration,
The eleventh configuration using the own ship speed obtained by the position measuring portion that measures the own ship position as the own ship speed and the twelfth configuration that performs the determination of the predetermined value by a hysteresis operation are solved. Is.

  As described above, according to the present invention, first, by storing the predetermined position and scale in the image before movement, it is possible to return to the original display state by only a single operation, and secondly, By displaying a graphic designating the true position of the point in a graphic surrounding the point to be marked, the mark can be easily distinguished.

  Third, predetermined information of the navigation-related information is stored in a storage part that can be electrically rewritten and electrically stored and held, and a storage part that can be electrically rewritten and stored and held without electricity. At the same time, the stored contents can be maintained without providing a large-scale configuration such as an uninterruptible power supply by performing a rewriting operation for making the stored contents of both the same only when the apparatus is turned on.

  Furthermore, fourth, a large cursor can be displayed during movement, and a small cursor can be displayed during stoppage to make the image easy to see. Fifth, to display a wake When the ship's speed is greater than or equal to a predetermined value, the position acquisition is performed at time intervals, and when it is less than the predetermined value, it is possible to eliminate unnecessary position acquisition storage by using automatic intervals. There is an effect that it is possible to provide a navigation device having features such as.

  As an embodiment of the present invention, an embodiment in which the present invention is applied to the configurations of the first to sixth prior arts will be described.

[First embodiment]
The first embodiment will be described below with reference to FIGS. The locations where the configuration of the first embodiment differs from the configurations of the first to sixth prior arts are as follows.

  First, in FIG. 1 [block configuration] and FIG. 2, the position of the power switch 67B is changed to [block configuration] in FIG. 13 and the "power" key / input / output port 71B in FIG. This is a place that is changed to an independent simple on / off type switch, that is, an ON-OFF switch, without using a holding structure as described above.

  In general, the inboard power supply 50 is provided with a main power switch 51 for supplying power to a plurality of devices including the navigation device 100. Therefore, it is troublesome to operate individual power switches of the plurality of devices. The power switch in each device, for example, the power switch 67B is left in the on state, and the main power switch 51 is shut off so that the power supply to a plurality of devices is cut off at the same time. It is composed.

  Second, the setting operation portion 60 in FIG. 2 is configured by changing the setting operation portion 60 in FIG. 15 as follows. That is, only the “menu” key in the screen selection operation portion 61 in FIG. 15 is arranged in the destination setting operation portion 62X in FIG. 2, and the other key operations are selected on the menu screen by the “menu” key 62A. It has been changed to.

  Only the operation by the “destination” key in the destination setting operation part 62 in FIG. 15 is arranged in the destination setting operation part 62X in FIG. 2, and the operation by other keys is selected on the menu screen by the “menu” key 62A. The operation is changed so that all the operations in the numerical value setting operation portion 65 in FIG. 15 are selected on the menu screen by the “menu” key 62A.

  The screen setting operation portion 66 in FIG. 15 is removed from the movement operation by the “↑” key, “↓” key, “→” key, “←” in FIG. 15 as the screen setting operation portion 66X in FIG. In addition to the “enlarge” key 66D, the “center” key 66E, and the “reduced” key 66F as in FIG. 15, the “scale 1” key 66A, the “scale 2” key 66B, and the “scale 3” key 66C are newly added. It has been changed to provide.

  Note that the scales by the “scale 1” key 66A, the “scale 2” key 66B, and the “scale 3” key 66C can be set in advance on the menu screen by the “menu” key 62A.

  The wake setting operation part 63 in FIG. 15 is changed so that the operation by the “map” key in FIG. 15 is selected and operated on the menu screen by the “menu” key 62A like the wake setting operation part 63X in FIG. The selection by the “color” key and the menu screen is changed so that it can be directly selected by the “wake color” selector switch 63A of FIG.

  Further, in addition to the “connect / disconnect” key 63D and “delete track” key 63F of the wake similar to FIG. 15, the “memory” key 63B and “call” key 63C of FIG. The operation of adding and storing the operation and the operation of calling the stored wake are changed so that the menu can be displayed directly and by a simple operation.

  The mark setting operation portion 64 in FIG. 15 is arranged in the same manner as the mark setting operation portion 64X in FIG. 2 in addition to the “O” key 64B and “□” key 64C similar to those in FIG. Further, a “▽” key 64F in which the “△” key in FIG. 15 is an inverted triangular figure is arranged, and selection by the “color” key and the menu screen is directly performed by the “mark” changeover switch 64A in FIG. It is changed so that it can be selected, and further, a “mark erase” 64F is arranged so that the designated mark can be erased.

  The “×” key 64E has an advantage that the position of the intersection of the figure can be clearly displayed as the position where the mark is set, and the “▽” key 66F has a longer side on the figure, so In particular, since it gives a stronger impression than “Δ”, there is an advantage that it is easy to distinguish.

  Further, the “menu” key 62A, the “destination” key 62B, the “cursor” key 62H, and the “cancel” key 62D and “OK” similar to FIG. In addition to the "key 62F" and "navigation switching" key 62G, a "running" key 62C, a "return" key 62J, and a "cancel" key 62E are added.

  The “running anchor” key 62C stores the own ship position 10a at which the ship has lowered the dredger, and displays the distance and direction the ship has moved from that point due to waves and tides. The “Return” key 62J is used to move the screen displayed on the display screen 81 and move back to the original display state. The “Release” key 62E is used for the menu screen / purpose. Used to cancel the display / setting of the ground / running ground.

  The arbitrary direction moving operation portion 68 in FIG. 2 is configured by a joystick-type operating device, and the screen and cursor moving operation and the selection operation on the menu screen are all performed by the arbitrary direction moving operation portion 68. It has changed.

  Third, in FIG. 1 [block configuration] and FIG. 3, the configuration of each storage portion is changed as follows. That is, the work memory 73 in [Block Configuration] in FIG. 13 is made into two work memories (1) 73A and work memories (2) 73B.

  The work memory (1) 73A is configured by a memory that cannot be stored and held by the storage battery 77, for example, a dynamic RAM, and the work memory (2) 73B is used for storing and holding, similarly to the work memory 73. A memory that can be stored and held by the battery 77, that is, a volatile storage portion that is electrically rewritable and electrically stored and held, for example, a static RAM, is used.

  As shown in FIG. 3, the storage contents stored in the work memory (1) 73A are current position data, current speed data, current traveling direction data, that is, current own ship position 10a, own ship speed 10b, and current advance direction 10c. And other arithmetic processing related data, that is, data requiring temporary storage such as data temporarily stored in the process of arithmetic processing by the program of the control processing flow stored in the processing memory 72 is there.

  As shown in FIG. 3, the work memory (2) 73B has a display condition data storage area 73B1 for storing data related to various display conditions, and a mark for storing data related only to the display of the mark. It is divided into a related data storage area 73B2 and a track related data storage area 73B3 for storing data related only to the display of the track.

  In the display condition data storage area 73B1, for example, luminance data set by the “luminance” key 67C, “scale 1” key 66A, “scale 2” key 66B, “scale 3” 66C, “enlarge” key 66D, “ Scale data set by any of the “reduction” key 66E,

  Scale data of “Scale 1” key 66A, “Scale 2” key 66B and “Scale 3” 66C set by “Menu” key 62A, and position value of destination JP1 set by “Destination” key 62B And the position value data of the point where the kite set by the “running kit” key 62C is lowered,

  The cursor intersection displayed by the “cursor” key 62H, that is, the position value of the designated point CP, the “cursor graphic”, that is, the graphic data of the large cursor CLX / CLY and the small cursor CLZ described later, and the track Data indicating the track “contact” state set by operating the “contact / disconnect” key 63D or the track “disconnect” state;

  “Time interval” and “distance interval” data used when capturing position value data used to display the wake, data of position and scale to be returned when the “return” key 62J is operated, and others For example, data related to the display condition, for example, navigation type data set by the “navigation switching” key 62G is stored.

  In the mark related data storage area 73B2, for example, the “color” data selected by the “mark color” switch 64A in the mark setting operation portion 64X, the “◯” key 64B, the “□” key 64C, and the “▽” key 64D. The mark shape set by operating any of the “x” keys 64E and the data of the point are configured to store the mark number data sequentially in the set order. is there.

  In the wake related data storage area 73B3, the self captured by the “time interval” or “distance interval” when the “contact / disconnect” key 63D of the wake in the wake setting operation portion 63X is operated to enter the “contact” state. “Point” data of the ship position 10a, for example, latitude and longitude values,

  “Attribute” data that determines whether or not the point data corresponds to a continuation point of the wake, “color” data set by the “wake color” switch 63A of the wake setting operation portion 63X, and data of the “point” Are sequentially stored as wake data.

  Fourthly, in FIG. 1 [block configuration], a holding memory 70X is newly added, and the holding memory 70X can store the stored contents without supplying a power supply like the storage holding battery 77. A memory that can be held, that is, a memory portion that is electrically rewritable and stores and holds electricity without electricity, for example, a flash memory, is used.

  The holding memory 70X is provided with a display condition data storage area 70X1, a mark related data storage area 70X2, a wake related data storage area 70X3, and a map data storage area 70X4.

  In the display condition data storage area 70X1, the mark related data storage area 70X2, and the wake related data storage area 70X3, the display condition data storage area 73B1, the mark related data storage area 73B2, and the wake related information in the work memory (2) 73B of FIG. The storage contents of the data storage area 73B3 are stored, and map data is stored and stored in the map data storage area 70X4 instead of the map data memory 75 in [Block Configuration] of FIG.

  Fifth, the processing memory 72 stores the program according to the control processing flow of FIG. 4 or the control processing flow of FIG. [Problem] is solved.

  Hereinafter, the control processing flow of FIG. 4 will be described. The control processing flow of FIG. 4 is configured as a subroutine of a main control processing routine for performing main control processing in the navigation information processing portion 70. For example, the control processing flow shifts to the control processing flow of FIG. 4 every second. It is configured to come.

[Description of Control Processing Flow in FIG. 4]
In step SP1, it is determined whether or not a “move” operation has been performed. When the “move” operation is performed, the process proceeds to the next step SP2, and when not, the process returns to a predetermined step in the main control process routine.

  The determination here is whether or not there is input data obtained by performing a moving operation for moving the intersection point of the cursors CLX and CLY, that is, the designated point CP, or a moving operation for moving the screen by the arbitrary direction moving operation portion 68. Determine by It should be noted that a flag for facilitating the determination in step SP3 described later, for example, “F1” is stored as necessary.

  In step SP2, as the data used for “return”, the scale value of the image displayed on the display screen 81 immediately before the moving operation is performed, and the point at a predetermined position of the image, for example, the image of FIG. After the data with the position value of the central position P10 is taken in and stored as “return” data in the work memory (2) 73B, the process proceeds to step SP4. If the previous “return” data is stored, it is rewritten with new “return” data.

In step SP3, it is determined whether or not the moving operation described in step SP1 has been performed again. The determination here is performed in the same manner as in step SP1, but the presence or absence of the flag “F1” is determined as necessary.
In step SP4, after performing the movement process corresponding to the above movement operation, the process proceeds to the next step SP5.

  In step SP5, it is determined whether or not an “enlargement” operation or a “reduction” operation has been performed. When the “enlargement” operation or the “reduction” operation is performed, the process proceeds to the next step SP6, and when not, the process proceeds to step SP7.

In this case, the “scale 1” key 66A, “scale 2” key 66B, “scale 3” key 66C, “enlarge” key 66D, and “reduction” key 66F are used to enlarge or reduce the screen. The determination is made based on whether or not there is input data for which the “reduction” operation has been performed.
In step SP6, after performing the “enlargement” and “reduction” processing corresponding to the “enlargement” and “reduction” operations, the process proceeds to the next step SP7.

In step SP7, it is determined whether or not a “return” operation has been performed. When the “return” operation is performed, the process proceeds to the next step SP8, and when not, the process returns to step SP3.
This determination is made based on whether or not there is input data for which a “return” operation for returning the screen to the original display state is performed using the “return” key 62J.

In step SP8, after reading the “return” data stored in step SP2, the process proceeds to the next step SP9.
In step SP9, based on the “return” data, after performing the process of reproducing and displaying the screen before the moving operation in step SP1, the process returns to a predetermined step in the main control process routine.

  Note that the “point of the predetermined position of the image” immediately before the moving operation stored as the “return” data in step SP2 is the “point of the central position of the image”, for example, the central position P10 in FIG. And “any point among the four corner points of the image”, for example, any point among the four corner points P11 to P14 in FIG. 14 and “the point of the ship position”, for example, the own ship in FIG. If one or more of the points of the position 10a are stored, the original image state with the point as the display reference point or the original scale with the own ship position 10a in the center It is possible to return to the image state.

  Further, the “image scale” immediately before the moving operation stored as the “return” data in step SP2 corresponds to, for example, the “horizontal or vertical width BB or HB” of the display screen 81 in FIG. If the “distance value” or “scale ratio” is configured to be stored, the image state of the original scale can be restored by the “distance value” or “scale ratio”.

  Even when the “return” key 62J is operated without performing the “enlargement” and “reduction” processing in step SP6, the original image state is similarly restored by the stored “return” data. Is possible.

  Therefore, after performing the operation of returning to the original position, the original original image state or the original scale image state with the ship position 10a in the center without performing a complicated operation of returning to the original scale. Therefore, the above [first problem] can be solved.

  In the control processing flow of FIG. 4, the “return” key 62J is used. However, the “cursor” key 62H and the “center” key 66D are used together without providing the “return” key 62J. The “return” operation similar to the above can be performed.

  When the former “cursor” key 62H is used, the cursor CLX / CLY can be erased simultaneously with the “return” display process as shown in the control processing flow of FIG. In the case of using the “center” key, the same operation as in the case where the “point of the predetermined position of the image” stored as “the point of the center position of the image” is performed can be performed.

  Hereinafter, the control processing flow of FIG. 5 will be described. The control processing flow of FIG. 5 is configured as a subroutine associated with the “display” state of the cursor of the main control processing routine for performing main control processing in the navigation information processing portion 70, and the cursors CLX and CLY are displayed. In this state, for example, the control process flow of FIG. 5 is performed every second.

[Description of Control Processing Flow in FIG. 5]
The only difference between the control process flow of FIG. 5 and the control process flow of FIG. 4 is that of step SP1, step SP3, step SP7, and step SP10, and only these steps will be described here.

  ◆ Step SP1 is different from step SP1 in FIG. 4 in that the object to be determined is determined so as to determine whether or not a moving operation to move the intersection of the cursors CLX and CLY, that is, the designated point CP, has been performed. It is a place.

  4. Where the step SP3 is different from the step SP3 in FIG. 4, it is determined whether or not the moving operation for moving the intersection of the cursors CLX and CLY, that is, the designated point CP, is performed again. It is the place changed to.

  ◆ Where the step SP7 is different from the step SP7 in FIG. 4, it is determined whether or not the “cursor delete” operation for deleting the cursors CLX and CLY has been performed. It is the place which changed so that it may transfer to step SP8, and when that is not right, it returns to step SP3.

  This determination is made based on whether or not there is input data for which the “cursor deletion” operation for deleting the cursors CLX and CLY is performed by operating the “cursor” key 62H.

In this configuration, when the cursor CLX / CLY is displayed, the cursor CLX / CLY is erased when the “cursor” key 62H is operated, regardless of whether or not the cursor is moved. .
Therefore, the “cursor deletion” and the solution of the [first problem] can be performed simultaneously.

That is, the configuration of the first embodiment is generally as follows. First, an image of navigation-related information including the point of the ship position 10a as described above is displayed at a predetermined scale, for example, a scale of 1/10000. From the first display state to be displayed, for example, the display state as shown in FIG. 14, an image of navigation-related information including another point away from the ship position 10 a, for example, the destination point JP 1, is displayed on the scale 1 / In the navigation device 100 in which 10000 can be changed to another scale, for example, a second display state in which the display is changed to 1/400, for example, a display state as shown in FIG.

  By performing the operation of designating the other point, for example, the destination point JP1, and the scale to be changed, for example, 1/400, the image in the first display state, for example, as shown in FIG. A point of a predetermined position in an image in a proper display state, for example, the center of the center position of the image, and the predetermined scale, for example, 1/10000 are stored, and the first display state, for example, FIG. A first display transition means for transitioning from the display state as shown in FIG. 14 to the second display state as described above, for example, as shown in FIG.

  The memory is read out by simply operating any one of a single operation, for example, the “return” key 62J, the “cursor” key 62H, the “center” 66E, etc. The above first configuration provided with the second display transition means for shifting from the display state, for example, the display state as shown in FIG. 17 to the above-mentioned second display state, for example, the display state as shown in FIG. It is what constitutes.

Secondly, in the first configuration,
The point at the predetermined position is set to the first display state, for example, the point at the center position P10 of the image in the display state as shown in FIG. 14, and the first display state, for example, as shown in FIG. The above-described second configuration is configured such that any one or more of the four corner points P11 to P14 of the image in the display state and the point of the own ship position 10a is set. is there.

Further, thirdly, in the first configuration or the second configuration described above,
Each of the above scales is a display screen for performing the above display, for example, the above third configuration in which the distance value or the scale ratio corresponds to the horizontal or vertical width BB or HB of the display screen 81 of FIG. It is what you are doing.
And according to these 1st structure-3rd structure, as mentioned above, said [1st subject] is solved.

[Second Embodiment]
The second embodiment will be described below with reference to FIGS. 1 to 3, 6, and 7. The configuration of the second embodiment is a configuration in which the mark configurations of FIGS. 6 and 7 are provided in the configurations of FIGS. 1 to 3 in the first embodiment, and each of the positions positioned in each mark. By adding a graphic for indicating the true position of a predetermined point, the above [second problem] can be solved.

  In FIG. 6, the [circular mark], [square mark], and [triangle mark] figures are marked with predetermined marks, for example, own ship position 10a, destination point JP1, and attention point EV1 in FIG. In order to identify the attention point EV2 and the like, the schematic position graphic 64X and the true position graphic 64Y1 and 64Y2 are displayed.

  In order to roughly identify these points, the approximate position figure 64X is a figure such as a circle, a square, or an inverted triangle surrounding these points, and the true position figures 64Y1 and 64Y2 are approximate positions. In order to indicate the true position of these points in the figure 64X, the true position figure 64Y2 is a small dot-like figure smaller than the approximate position figure 64X, and the true position figure 64Y1 is a cross character smaller than the approximate position figure 64X. It is shaped like a shape. In the cross-shaped figure, the intersection of the cross characters is the true position.

  Further, the true position figures 64Y1 and 64Y2 only need to be located in the approximate position figure 64X at the location where the true position is indicated. The true position figures 64Y1 and 64Y2 may be positioned and displayed at eccentric positions in the position figure 64X. Note that the cross-shaped figure of the true position figure 64Y1 includes a case where the cross-shaped figure is slanted, that is, a "x" shape.

  Therefore, in order to make it easy to distinguish each mark, as shown in FIG. 7, even if the approximate position figure 64X is made larger than the size of the conventional mark, the true position figure 64Y1 or 64Y2 is used to indicate the true position of the mark. Therefore, the above [second problem] can be solved.

That is, the configuration of the second embodiment is generally as follows. First, an image of navigation-related information including the point of the ship position 10a as described above is displayed at a predetermined scale, for example, a scale of 1/10000. The display to be displayed, for example, the display as shown in FIG. 14 and the image of the navigation-related information including the other point away from the ship position 10a, for example, the destination point JP1, the above scale 1/10000 as another scale. For example, in the navigation device 100 that can perform display that is changed to 1/400, for example, display as shown in FIG.

  A figure surrounding each predetermined point for roughly identifying each predetermined point associated with each of the navigation related information, for example, own ship position 10a, destination point JP1, attention point EV1, attention point EV2, etc. For example, the approximate position figure 64X is displayed, and the predetermined positions in the figure are indicated, for example, the true position of the own ship position 10a, the destination point JP1, the attention point EV1, the attention point EV2, etc. For example, a point identification graphic display means for displaying true position figures 64Y1 and 64Y2 is provided.

Secondly, in the above fourth configuration,
For example, like the [circular mark], [quadrangle mark], and [triangle mark] in FIG. 7, a figure surrounding the above-mentioned point, for example, the approximate position figure 64X is set as a first figure by a circle or a polygon, and the above true A figure for indicating a position, for example, the above-described fifth configuration in which the true-position figures 64Y1 and 64Y2 are second dotted figures or cross-shaped second figures smaller than the first figure. It is.
And according to these 4th structure and 5th structure, as mentioned above, said [2nd subject] is solved.

[Third embodiment]
Hereinafter, a third embodiment will be described with reference to FIGS. 1 to 3, 8, and 9. The configuration of the third embodiment is the same as the configuration of FIGS. 1 to 3 in the first embodiment described above except that the storage and storage configurations of FIGS. 8 and 9 are provided and stored in the working memory (2) 73B. The above-mentioned [Third Problem] can be solved by making the stored contents of the storage area and the storage contents of the corresponding storage area portion of the storage memory 70X the same only when the apparatus is turned on. It is what I did.

  In FIG. 8, the storage content of the work memory (2) 73B is a simplified description of the storage content of the work memory (2) 73B of FIG. 3, and the storage content of the storage memory 70X is the work memory. (2) In addition to the display condition data storage area 70X1 and mark-related data storage area 70X2 corresponding to the storage area 73B, the wake-related data storage area (1) 70X3 in which the wake-related data storage area 70X3 is divided into two storage areas. (1) A track-related data storage area (2) 70X3 (2) and a map data storage area 70X4 are provided.

  The portion of the wake related data storage area (1) 70X3 (1) corresponds to the wake related data storage area 73B3 of the work memory (2) 73B, and the portion of the wake related data storage area (2) 70X3 (2). Is a memory for storing all the track point data and mark data included in the track with a specific storage item such as a track number by the menu screen by the operation of the “memory” key 63B in the track setting operation part 63X of FIG. Part of the region.

  When the past track CR2 in FIG. 14 is called by operating the “call” key 63C in the track setting operation portion 63X in FIG. 2, the stored contents of the portion of the track related data storage area (2) 70X3 (2) are read out. To display.

  In the map data storage area 70X4, map data is stored in advance, and if necessary, new map data is given from an appropriate input portion (not shown) to rewrite the stored contents. .

  The storage memory 70X is composed of a non-volatile memory that is electrically rewritable and does not require electricity, for example, a flash memory, and is not shown in the flash memory, but is rewritten for each rewrite block. A control circuit portion is provided, and by giving a code signal based on predetermined data, the stored contents of the designated rewrite block are first erased, and the stored contents to be rewritten based on the signal for which the erasure has been completed A function is provided that can provide data and store it in the rewrite block.

  The rewrite blocks rm1 to rmn are made to correspond to the stored contents of the work memory (2) 73B, the rewrite blocks rn1 to rnn are made to the track-related data storage area (2) 70X3 (2), and the rewrite blocks ro1 to ro1 ron is assigned to be the map data storage area 70X4.

  By the way, since the storage contents of the work memory (2) 73B are stored and held by the storage holding battery 77, the storage contents are disturbed due to a defective battery or the like, and the storage contents of the storage memory 70X are stored. The content may be partially lost due to some signal operation error.

  For this reason, the storage portions of the storage areas 73B1 to 73B3 of the work memory (2) 73B and the storage portions of the storage areas 70X1 to 70X3 (1) of the storage memory 70X corresponding to the storage portions include, for example, A specific part of the storage contents of each storage area, for example, a check bit part for confirming the storage contents is provided at the beginning part of each storage area, and a predetermined code, for example, , 01 to XX are stored, and when the storage state of this check bit, that is, the storage of 01 to XX is in a predetermined state, it is determined that the stored content is maintained. It is configured to do.

  Specifically, the check bits 01 to XX are, for example, 4 bytes at the beginning of each of the storage areas 73B1 to 73B3 and 70X1 to 70X3 (1), that is, the 32 bits. Bit numbers of binary numbers 01 to 08, that is, “0001” “0010” “0011” “0100” “0101” “0110” “0111” “1000” are stored.

  Then, when a partial disappearance of the stored contents occurs in the work memory (2) 73B or the storage memory 70X, as a control process for relieving the disappearance, the processing memory 72 is changed to FIG. This is the place where the above [third problem] is solved by storing the program according to the control processing flow and performing the storage control processing.

  Hereinafter, the control processing flow of FIG. 9 will be described. The control processing flow of FIG. 9 is configured as a subroutine of a main control processing routine for performing main control processing in the navigation information processing section 70, and as described above, by operating the power switch 67B or the main power switch 51. 9 is configured to shift to the control processing flow of FIG. 9 only immediately after the operation power of the apparatus is supplied.

[Description of Control Processing Flow in FIG. 9]
In step SP1, the storage contents of the check bit of the work memory (2) 73B and the check bit of the storage memory 70X are fetched, and the process proceeds to the next step SP2.

  In step SP2, the storage bits 01 to XX of the check bits in the work memory (2) 73B and the storage codes 01 to XX of the check bits in the storage memory 70X are confirmed and are all normal. Determine whether or not. If both are normal, the process proceeds to step SP6. Otherwise, the process proceeds to the next step SP3.

  In step SP3, it is determined whether or not the check bits storage codes 01 to XX of the work memory (2) 73B are normal. When normal, the process proceeds to step SP6, and when not, the process proceeds to the next step SP4.

  In step SP4, it is determined whether or not the storage codes 01 to XX of the check bits in the storage memory 70X are normal. When it is normal, the process proceeds to step SP7, and when not, the process proceeds to the next step SP5.

  In step SP5, an alarm indicating that both the work memory (2) 73B and the storage memory 70X are in an abnormal state, that is, “memory failure” is displayed on the display screen 81, and an appropriate warning sound part ( For example, after making a warning sound with a piezoelectric buzzer or the like, the routine proceeds to a predetermined step portion of the main control processing routine.

  In step SP6, all the stored contents stored in the work memory (2) 73B are stored in the corresponding storage locations of the storage memory 70X, that is, the rewrite blocks rm1 to rmn, and the stored contents are stored. After the same, the process proceeds to a predetermined step part of the main control processing routine.

  In step SP6, all the stored contents stored in the rewrite blocks rm1 to rmn are stored in the working memory (2) 73B among the stored contents of the storage memory 70X, that is, all the stored contents stored in the rewrite blocks rm1 to rmn. 2) After performing the rewriting operation stored in 73B to make the stored contents identical, the process proceeds to a predetermined step portion of the main control processing routine.

  The determination at the above steps SP2 to SP4 can be made based on, for example, whether or not the total number of binary numbers of the codes of the check bit storage codes 01 to XX is a predetermined value.

  According to the above control processing, even when the power is turned on / off by the main power switch 51, the contents stored in the work memory (2) 73B each time the power is turned on to the navigation device 100, The stored contents of the rewrite blocks rm1 to rmn of the storage memory 70X corresponding to the stored contents are made identical.

  When only the stored contents of both memories or the stored contents of the working memory (2) 73B are normal, the rewrite blocks rm1 to rmn of the storage memory 70X are always rewritten and stored with the new stored contents.

  Further, when only the stored contents of the rewrite blocks rm1 to rmn of the storage memory 70X are normal, the stored contents are re-stored in the work memory (2) 73B. Since the stored contents can be restored to the extent that there is no inconvenience, the above [third problem] has been solved.

That is, the configuration of the third embodiment is generally as follows. First, in the navigation device 100 similar to the navigation device 100 in the fourth configuration,
As the storage portion for storing predetermined information of each of the above related information, for example, display condition data, mark related data, and track related data information, the above memory can be electrically rewritten and electrically stored. Volatile storage part to be held, for example, a working memory (2) 73B for storing and holding a static RAM with a storage battery 77, and a non-volatile storage part for electrically storing and holding the above-mentioned storage without electricity For example, a storage unit provided with a storage memory 70X using a flash memory,

  For example, only when the operation power of the apparatus is turned on by the power switch 67B or the main power switch 51, the non-volatile storage portion, for example, the storage memory 70X and the volatile storage portion, for example, the work memory (2) Storage contents corresponding to 73B, for example, display condition data storage area 70X1, mark related data storage area 70X2, track related data storage area (1) storage contents of 70X3 (1) and display condition data storage area 73B1 The sixth configuration described above is provided with a process for making the mark-related data storage area 73B2 and the track-related data storage area 73B3 the same, for example, a storage identification processing means for performing the process according to the control process flow of FIG. It is what you are doing.

Second, in the sixth configuration,
The volatile storage part is composed of, for example, the static RAM of the working memory (2) 73B and the storage holding battery 77, and the nonvolatile storage part is composed of, for example, the flash memory of the storage memory 70X. This constitutes the seventh configuration described above.
And according to these 6th structure and 7th structure, as mentioned above, said [3rd subject] is solved.

[Fourth embodiment]
Hereinafter, the fourth embodiment will be described with reference to FIGS. 1 to 3, 7, and 10. The configuration of the fourth embodiment is such that two cursors as shown in FIGS. 7 and 10 are displayed in the configuration of FIGS. 1 to 3 in the first embodiment.

  In FIG. 7, the cursors CLX and CLY similar to those of the prior art are configured as “large cursors”, and the small cursor CLZ with a cross-shaped figure as shown in FIG. 7 is configured as “small cursor”. The intersection point is designated as a designated point CP. In addition, the cross-shaped figure has a size of about 1 cm in length and width to make it relatively easy to distinguish.

  The “large cursor” may be displayed by changing the cursor CLX / CLY to a solid line, and the cross-shaped figure of the small cursor CLZ includes an oblique cross-shaped character, that is, an “×” -shaped character. This includes the case where it is displayed on a figure.

  Then, the cursor graphic stored in the work memory (2) 73B is stored in the above two types of “large cursor” and “small cursor”, and when the cursor is moved, In order to display “large cursor” and “small cursor” when the cursor is stopped, the processing memory 72 stores the program according to the control processing flow of FIG. 10 and performs display control processing. Thus, the present invention is configured to solve the above [fourth problem].

  Hereinafter, the control processing flow of FIG. 10 will be described. The control processing flow of FIG. 10 is configured as a subroutine of a main control processing routine for performing main control processing in the navigation information processing portion 70. For example, the control processing flow shifts to the control processing flow of FIG. 10 every second. It is configured to come.

[Description of Control Processing Flow in FIG. 10]
In step SP1, it is determined whether or not an operation for displaying a “cursor” has been performed. When the operation of displaying the “cursor” is performed, the process proceeds to the next step SP2, and when not, the process returns to a predetermined step position of the main control processing routine.

This determination is made based on whether or not there is input data for performing an operation for displaying the cursor by the “cursor” key 62H in the destination setting operation portion 62X in FIG.
In step SP2, after the small cursor CLZ is displayed, the process proceeds to the next step SP3.

  In step SP3, it is determined whether or not an operation for moving the “cursor” has been performed. When an operation of moving the “cursor” is performed, the process proceeds to step SP6, and when not, the process proceeds to the next step SP4.

  The determination here is performed by operating the arbitrary direction movement operation portion 68 in any direction to determine whether or not there is input data for performing an operation of moving the “cursor”.

In step SP4, it is determined whether or not an operation for deleting the “cursor” has been performed. When an operation for deleting the “cursor” is performed, the process proceeds to the next step SP5, and when not, the process returns to step SP3.
This determination is made based on whether or not there is input data that has been operated to delete the cursor by the “cursor” key 62H.

In step SP5, after deleting the “cursor”, the process returns to a predetermined step of the main control processing routine.
In step SP6, after displaying the “large cursor”, that is, the cursor CLX / CLY, the process proceeds to the next step SP7.

  In step SP7, it is determined whether or not an operation for stopping the “cursor” has been performed. If an operation to stop the “cursor” is performed, the process returns to step SP2, and if not, this step SP7 is repeated.

  The determination here is made based on whether or not the arbitrary direction moving operation portion 68 is positioned at the stop position, for example, the neutral position of the joystick, and there is no input data for moving the “cursor”.

  Therefore, according to the configuration of the fourth embodiment, when the “cursor” is moved, the “large cursor”, that is, the cursor CLX / CLY is displayed. Can be easily matched to the intended location.

  In addition, when the “cursor” is stopped, the small cursor CLZ is displayed, so that other parts of the image can be seen without being obstructed by the large cursors CLX and CLY. 4) is solved.

  It should be noted that the designated point CP of the small cursor CLZ includes a configuration in which a “◎” mark similar to that illustrated in the designated point CP of the large cursor CLX / CLY is displayed as necessary.

That is, the configuration of the fourth embodiment is generally as follows. First, in the navigation device 100 similar to the navigation device 100 in the fourth configuration,
In order to designate an arbitrary point on the screen for displaying each of the above display states, for example, the display screen 81 as shown in FIG. 7, a cursor that can move in the above screen and passes through the above arbitrary point, for example, , Cursor display means for displaying "large cursor" or "small cursor",

  During the movement of the cursor, the cursor is moved to the above-mentioned screen, for example, a large cursor by the horizontal line extending over the entire horizontal direction BB of the display screen 81 and the vertical line extending over the entire vertical direction HB of the screen, for example, the cursor CLX. The above-mentioned second display is provided with a small cursor that displays the CLY and indicates the cursor only at the arbitrary point while the cursor is stopped, for example, a large / small cursor display means for displaying the small cursor CLZ. 8 is constituted.

Second, in the eighth configuration described above,
The large cursor, for example, the horizontal line and the vertical line of the cursor CLX / CLY are displayed by dotted lines or solid lines, and the small cursor, for example, the small cursor CLZ is a cross-shaped character having a height of about 1 cm. This forms the ninth configuration as a figure.
And according to these 8th structure and 9th structure, as mentioned above, said [4th subject] is solved.

[Fifth embodiment]
The fifth embodiment will be described below with reference to FIGS. 1 to 3, 11, and 12. The configuration of the fifth embodiment is a configuration in which an automatic take-in configuration of track point data as shown in FIGS. 11 and 12 is provided in the configuration of FIGS. 1 to 3 in the first embodiment.

  In FIG. 2, the “contact” state by the operation of the “contact / disconnection” key 63D of the wake in the wake setting operation portion 63X includes the “contact” state of “distance interval” and the “contact” state of “time interval”. Three “contact” states, “automatic interval” and “contact” states, are provided.

  In the “contact” state of the “distance interval”, the interval for acquiring the track data of the wake, that is, the interval for acquiring and storing the data of the ship position 10a is set at a predetermined distance interval, for example, every 100 m of moving distance. A state to be performed, for example, a state in which the distance interval capture storage DP in FIG. 12 is performed. In FIG. 12, a very small portion marked with a circle is not actually displayed, but is drawn to make it easy to understand the state of capture storage.

  In the “contact” state of “time interval”, a state in which the track point data capture interval is performed at a predetermined time interval, for example, every 10 seconds, for example, the time interval capture storage TP of FIG. 12 is performed. It becomes a state.

  In the “contact” state of “automatic interval”, that is, in the state of the above-described automatic take-up configuration, as shown in FIG. 12, when the own ship speed 10b is equal to or higher than a predetermined speed and 10bS2, for example, 3 knots or higher, automatic Therefore, when the “distance interval” is in the “contact” state, for example, the state in which the time interval capture and storage TP in FIG. 12 is performed and less than a predetermined speed of 10 bS1, for example, less than 3 knots, automatically The “distance interval” is in the “contact” state, for example, the distance interval capture storage DP state of FIG.

  Furthermore, when returning from the “contact” state of the “time interval” to the “contact” state of the “distance interval” in the “contact” state of the “automatic interval”, than the predetermined speed 10 bS, for example, 3 knots, “−α”, for example, an operation that does not return to the “contact” state of the “distance interval” until the speed is reduced by one knot, for example, 2 knots, that is, for example, [Hysteris The operation is performed.

  In this hysteretic operation, when the own ship speed 10b fluctuates in the vicinity of a predetermined speed 10bS, for example, around 3 knots, the distance interval capture memory DP and the time interval capture memory TP are frequently used. This operation is performed to prevent the control from being disrupted.

  Then, the data necessary for the above operation is stored in the display condition data storage area 73B1 of the work memory (2) 73B in FIG. 3, and the program according to the control processing flow in FIG. 11 is stored in the processing memory 72. By performing the display control process, the operation in the “contact” state of the “automatic interval” is performed to solve the [fifth problem].

  Hereinafter, the control processing flow of FIG. 11 will be described. The control processing flow of FIG. 11 is configured as a subroutine of a main control processing routine for performing main control processing in the navigation information processing section 70, and the “contact / disconnect” key 63D of the wake is set to the “contact” state. When the data is read, the process proceeds to the control processing flow of FIG.

[Description of Control Processing Flow in FIG. 11]
In step SP1, it is determined whether or not an operation for changing to the “contact” state of “automatic interval” has been performed. When an operation to set the “automatic interval” to the “contact” state is performed, the process proceeds to the next step SP2, and when not, the process returns to a predetermined step position of the main control processing routine.
This determination is made based on whether or not there is input data in which the “contact / disconnection” key 63D of the wake is operated to set the “automatic interval” to the “contact” state.

  In step SP2, it is determined whether or not the own ship speed 10b is less than the predetermined speed 10bS1, for example, less than 3 knots. When the speed is less than the predetermined speed 10bS1, the process proceeds to step SP10. Otherwise, the process proceeds to the next step SP3.

  In step SP3, after setting “−α”, for example, −1 knot for performing the hysteresis operation, the process proceeds to the next step SP4. If “−α” is already set, the process proceeds to the next step SP4.

  Here, the setting of “−α” is data that changes to a value less than the predetermined speed 10bS1 determined in step SP2, for example, a value less than 3 knots to “−α”, for example, less than 2 knots by −1 knot, For example, an operation of storing in the display condition data storage area 73B1 of the work memory (2) 73B is performed.

  In step SP4, after performing the above time interval capture storage TP only once, the process proceeds to the next step SP5. The capture storage here is stored in the point data in the track-related data storage area 73B3 of the work memory (2) 73B.

  When “−α” is set in step SP3, that is, when the time interval capture storage TP is the first time, the data of the ship position 10a is immediately captured and the clock circuit 76 It operates so as to determine the time for taking-in and storing after the next time by measuring the time for a predetermined time interval, for example, 10 seconds.

In step SP5, it is determined whether or not the track of that time is the first acquisition storage, that is, whether or not the track start point LS. If it is the wake start point LS, the process proceeds to step SP12, and if not, the process proceeds to the next step SP6.
The determination here is made by determining that no track data is stored in the track related data storage area 73B3 of the work memory (2) 73B.

In step SP6, the point of the previous time interval capture memory TP or the point of the previous distance interval capture memory DP and the point of the current time interval capture memory TP or the current distance interval capture memory After storing data for drawing a line connecting the DP, that is, the wake element line LE, the process proceeds to the next step SP7.
Here, the data is stored by setting the attribute data in the track-related data storage area 73B3 of the work memory (2) 73B as “continuation” data.

In step SP7, it is determined whether or not the “contact” state of “automatic interval” has been canceled. When the state is canceled, the process proceeds to the next step SP8, and when not, the process returns to step SP2.
This determination is made based on whether or not the data used for the determination in step SP2, that is, the input data in the “contact” state of “automatic interval” is lost.

In step SP8, it is determined whether or not the wake has been set to the “off” state. When the wake is set to the “OFF” state, the process proceeds to the next step SP9. Otherwise, a predetermined step position of the main control processing routine, that is, the “contact” state or the “time interval” of the “distance interval” described above. The process proceeds to the step of performing the “contact” state process of “”.
The determination here is made based on whether or not there is input data that has been set to the “disconnected” state by operating the “connect / disconnect” key 63D of the wake.

In step SP9, after the data of the “end point” of the wake is stored, the process proceeds to a predetermined step portion of the main control processing routine, that is, a step for performing the process of ending the wake display operation.
The storage of data here is the track end point CRE by not storing the data of “continuation” because the attribute of the track related data storage area 73B3 of the work memory (2) 73B is “non-continuation”.

  In step SP10, in order to perform a hysteresis operation, after canceling “−α” set in step SP3, the process proceeds to the next step SP11. If “−α” has already been released, the process proceeds to the next step SP4.

  The release of “−α” here returns the data “−α” stored in the display condition data storage area 73B1 of the work memory (2) 73B to the original predetermined speed of 3 knots in step SP3. Re-store the data.

  In step SP11, after the distance interval capture storage DP is performed only once, the process proceeds to step SP5. The capture storage here is stored in the wake-related data storage area 73B3 of the work memory (2) 73B.

  Note that when “−α” is canceled in step SP10, that is, when the distance interval capture storage TD is the first time, the data of the ship position 10a is immediately captured and the ship position 10a. The calculation for determining the change in the distance value due to the change in the distance is started, and operation is performed so as to store the next and subsequent times at a predetermined distance interval, for example, 100 m.

In step SP12, after storing the “start point” data of the wake, the process proceeds to step SP7.
The storage of data here is the track start point CRS by not storing the “continuation” data because the attribute of the track related data storage area 73B3 of the work memory (2) 73B is “non-continuation”.

  Therefore, according to the above control process, as shown in FIG. 12, in the navigation state range of less than the predetermined speed value 10bS1, the data of the own ship position 10a is stored by the distance interval capture storage DP, and is equal to or higher than the predetermined speed value 10bS2. In the range of the navigation state, the data of the ship position 10a is stored by the time interval capture storage TP.

  For this reason, in the time interval capture storage TP portion, the distance interval at which capture storage is performed is random, but it is possible to automatically prevent wasteful capture storage in the navigation state range of less than the predetermined speed value 10bS1. Therefore, the above [fifth problem] has been solved.

  In general, a ship travels at a lower speed when navigating a meandering route, and at a higher speed when navigating a straight route, the configuration of the fifth embodiment Automatically records the track of the ship 10a on the meandering route at relatively small distance intervals, and records the ship's position 10a on a straight route. Even if the memory is stored at a relatively rough time interval, the route is straight and can be recorded faithfully. Therefore, it is possible to eliminate the waste of the storage amount stored in the track-related data storage area 70X3.

  When the position measurement portion 10 uses a radio navigation receiver using Loran C radio navigation or Decca radio navigation, etc., if the calculation of the own ship speed 10b is not in time, it depends on the screw shaft of the ship or the rotational speed of the engine. The speed of the ship can be determined by using the speed as the ship speed.

That is, the configuration of the fifth embodiment is generally the same as the navigation device 100 similar to the navigation device 100 in the fourth configuration described above.
For example, the ship's track, for example, the ship's track CR1, is stored in the track-related data storage area 73B3 of the work memory (2) 73B based on the stored contents. Wake display means for displaying;

  When the own ship speed 10b reaches the predetermined value 10bS, that is, when the own speed is equal to or higher than the predetermined speed 10bS2, the above-mentioned memory is stored at a predetermined time interval, for example, 10 seconds, and the predetermined value 10bS is satisfied. When there is not, that is, when the speed is less than a predetermined speed of 10bS1, the above-mentioned tenth configuration is provided, which is provided with a capture storage means that captures the data every predetermined distance interval, for example, every 100 m. It is.

Second, in the tenth configuration described above,
As the above-mentioned own ship speed 10b, the above eleventh configuration using the own ship speed 10b obtained by the position measuring portion 10 for measuring the above ship position 10a, for example, a radio navigation receiver by GPS radio navigation is configured. It is what.

Thirdly, in the tenth configuration and the eleventh configuration described above,
The above-described twelfth configuration is configured in which the predetermined value 10bS is determined by a hysteresis operation, for example, the [hysteresis operation] in FIG.
And according to these 10th structure-12th structure, as mentioned above, said [5th subject] is solved.

[Modification]
The present invention includes the following modifications.

(1) The configuration according to FIGS. 4 and 5 of the first embodiment is applied to the configurations of FIGS. 13 and 15.
(2) The configuration of the second embodiment shown in FIG. 7 is applied to the configurations of FIGS.

  (3) The portion of the map data storage area 70X4 in the third embodiment is configured by changing to an independent map data memory 75 or external storage portion 90 as shown in FIGS.

  (4) The storage memory 70X in the third embodiment is an electrically rewritable and rewritable memory circuit having another configuration, for example, a rewritable voltage and rewritable storage data for each rewritable block. And the flash memory or the like that is rewritten for each rewrite block.

  (5) The storage memory 70X and the working memory (2) 73B in the third embodiment are configured for each storage area or for each of a plurality of storage areas, and modified so as to perform the same rewriting operation. .

  (6) The rewrite between the storage memory 70X and the work memory (2) 73B in the third embodiment is determined for each storage area by checking whether the check bits 01 to XX are good or not. Change and configure to rewrite the bad one.

  (7) The check bit portion in the third embodiment is not provided individually for each storage area, but is changed so as to be provided only at specific locations in the entire storage area.

  (8) The control process of FIG. 9 is applied to the configuration in which the storage area similar to the wake-related data storage area (2) 70X3 (2) is provided in the work memory (2) 73B in the fourth embodiment. Constitute.

(9) The configuration in the “contact” state of “automatic interval” in the fifth embodiment is applied to the configurations of FIGS.
(10) In the configuration of the fifth embodiment, the “part of contact” state of “distance interval” and the “contact” state of “time interval” are removed, and only the “contact” state of “automatic interval” is removed. Provide and configure.

(11) The configuration part that performs “change of scale” is removed from the configurations of the second to fifth embodiments.
(12) Display the character information TT in one or more columns below the display screen 81.
(13) Arbitrary plural of the configurations of the first to fifth embodiments and the configurations of (1) to (12) above are combined.

(14) The portion for displaying the course deviation in the constructions of the first to fifth embodiments and the constructions (1) to (13) is changed to the course deviation configuration of FIG.
(15) In the configurations of the first to fifth embodiments and the configurations of the above (1) to (14), the [hysteresis operation] in FIG. The configuration is changed so that the hysteresis operation is performed at a place where ΔS is increased or decreased.

  (16) To obtain the own ship position 10a, own ship speed 10b, and current traveling direction 10c in the position measurement portion 10 in the configurations of the first to fifth embodiments and the configurations of (1) to (15) above. All or part of the arithmetic processing is arranged in the navigation information processing part 70.

In the drawings, FIGS. 1 to 12 show an embodiment of the present invention, and FIGS. 13 to 18 show the prior art. The contents of each figure are as follows.
Overall block configuration / specific configuration perspective view Part specific configuration front view Main part memory configuration diagram Main part control processing configuration diagram Main part control processing configuration diagram Main part display diagram Main part display configuration diagram Main part memory storage configuration diagram Main part control processing configuration diagram Main part control processing configuration diagram Main part control processing configuration diagram Main part display configuration diagram Overall block configuration / specific configuration perspective view Main part display configuration diagram Part specific configuration front view Main part display configuration diagram Main part display configuration diagram Main part display configuration diagram

DESCRIPTION OF SYMBOLS 10 Position measurement part 10a Own ship position 10b Own ship speed 10bS Predetermined speed 10bS1 Less than predetermined speed 10bS2 Predetermined speed or more 10c Current traveling direction 20 Navigation related information display part 50 Inboard power supply 51 Core power switch 52 Internal power supply 55 Self-holding circuit 60 Setting operation Part 61 Screen selection operation part 62 Destination etc. setting operation part 62X Destination etc. setting operation part 62A "Menu" key 62B "Destination" key 62C "Strike" key 62D "Cancel" key 62E "Release" key 62F "Enter" ”Key 62G“ Navigation switch ”key 62H“ Cursor ”key 62J“ Return ”key 63 Track setting operation part 63X Track setting operation part 63A“ Track color ”switch 63B“ Memory ”key 63C“ Call ”key 63D“ Connect / Disconnect ” Key 63E “Track erase” key 64 mark Fixed operation part 64X Mark setting operation part 64A "Mark color" switch 64B "O" key 64C "□" key 64D "▽" key 64E "X" key 64F "Mark erase" key 64X Approximate position figure 64Y1 True position figure 64Y2 True Position figure 65 Numerical value setting operation part 66 Screen setting operation part 66X Screen setting operation part 66A "Scale 1" key 66B "Scale 2" key 66C "Scale 3" key 66D "Enlarge" key 66E "Center" key 66F "Reduce" Key 67 Operation part for power source 67A “Power” key 67B Power switch 67C “Luminance” key 68 Operation part for arbitrary direction movement 69 Setting operation part for cursor etc. 70 Navigation related information processing part 70X Storage memory 70X1 Display condition data storage area 70X2 Mark related Data storage area 70X3 Track related data Storage area 70X3 (1) track related data storage area (1)
70X3 (2) Track related data storage area (2)
70X4 Map data storage area 71A I / O port 71B I / O port 70A CPU
72 processing memory 73 working memory 73A working memory (1)
73B Work memory (2)
73B1 Display condition data storage area 73B2 Mark related data storage area 73B3 Track related data storage area 74 Track data memory 75 Map data memory 76 Clock circuit 77 Memory holding battery 80 Display processing part 80A CPU
81 Display screen 82 Image element memory 83 Processing memory 84 Display image memory 90 External storage part 100 Navigation device B1a Distance width BB Horizontal width CLX Cursor CLY Cursor CLZ Small cursor CP Specified point CR1 Own ship track CR2 Past track CRE Track End point CRS Track start point DP Distance interval capture memory E1 Point of interest E2 Point of interest HB Vertical width JP1 Destination point L1 to L5 Route line LE Track element line Ld Contour line LX Latitude line LY Longitude line M1 Map (Coastline)
P1 to P4 direction change point (change point)
P10 Center position P11 to P14 Four corner points RT1 Planned route (route)
rm1 to rmm Rewrite block rn1 to rnn Rewrite block ro1 to ron Rewrite block S Predetermined value TP Time interval capture storage TT Character information θ1 Course deviation

Claims (2)

A display that displays an image of navigation-related information including a point of the ship's position on a predetermined scale, or an image of navigation-related information that includes another point away from the ship's position is changed to another scale. A navigation device that can perform display for display,
Cursor display means for displaying a cursor that is movable in the screen and passes through the arbitrary point in order to specify an arbitrary point on the screen that displays each of the display states,
While the cursor is moving, the cursor is displayed as a large cursor with a horizontal line extending across the entire horizontal direction of the screen and a vertical line extending across the entire vertical direction of the screen, and while the cursor is stopped, the cursor is moved to the arbitrary point. And a large / small cursor display means for displaying with a small cursor that points only to the portion.   The navigation device according to claim 1, wherein the horizontal line and the vertical line of the large cursor are displayed as dotted lines or solid lines, and the small cursor is displayed as a cross-shaped figure of about 1 cm in length and width.