JPH0546087A - Display device for vehicle - Google Patents

Abstract

PURPOSE:To provide the vehicle display device which superimposes dynamic road information on traffic congestion, road constructions, traffic control, etc., within optimum ranges corresponding to the current travel state of the vehicle on a road map of the periphery of the current position of the vehicle. CONSTITUTION:This display device is equipped with a display range calculating means 106 which calculates the display range of the dynamic road information inputted from a dynamic road information input means 105 according to the current travel state of the vehicle including at least the travel direction of the vehicle detected by a travel direction detecting means, the travel speed detected by a travel speed detecting means, and the distance from the current position detected by a position detecting means to a destination set by a destination setting means, an information extracting means 107 which extracts the dynamic road information within the display range, and a display means 108 which reads static road information on the periphery of the current position of the vehicle detected by the position detecting means 100 out of a static road information storage means 104 and displays the dynamic road information extracted by the information extracting means 107 corresponding to the static road information; and the dynamic road information in the best range for the persons on the vehicle is displayed at all times.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle display device, and more particularly, to a method for displaying dynamic road information such as road congestion, construction, and regulations.

[0002]

2. Description of the Related Art Transmitting current position information of a vehicle to a ground station,
A vehicle display device is known that receives traffic information corresponding to the current position of a vehicle transmitted from a ground station, that is, dynamic road information such as road congestion, construction, and regulations, and displays it on a map around the current location. (For example, the actual exploitation Sho 61-12
8799).

[0003]

However, in the conventional vehicle display device, only the dynamic road information around the current position of the vehicle is displayed, and the occupant needs more, for example, the traveling direction, the traveling speed, and the current position. There is a lack of dynamic road information in the range according to the current driving situation of the vehicle such as the distance to the destination.

An object of the present invention is to display, on a road map around the present location of a vehicle, dynamic road information such as traffic congestion, road construction, traffic regulation, etc., in an optimum range according to the current driving situation of the vehicle. The present invention provides a display device for a vehicle.

[0005]

The present invention will be described with reference to FIG. 1, which is a claim correspondence diagram, and the present invention is directed to a position detecting means 100 for detecting the current position of a vehicle and a destination for setting a destination. Setting means 101, traveling direction detecting means 102 for detecting the traveling direction of the vehicle, traveling speed detecting means 103 for detecting the traveling speed of the vehicle, and static road information storage for storing static road information including at least a road map. Means 10
4 and dynamic road information input means 10 for inputting dynamic road information including at least traffic congestion, road construction and traffic regulation
5, the traveling direction of the vehicle detected by the traveling direction detecting means 102, the traveling speed detected by the traveling speed detecting means 103, and the current position detected by the position detecting means 100 are set by the destination setting means 101. Display range calculation means 106 for calculating the display range of the dynamic road information input by the dynamic road information input means 105 according to the current traveling condition of the vehicle including the distance to the destination, and the dynamic road information Information extracting means 107 for extracting dynamic road information within the display range calculated by the display range calculating means 106 from the dynamic road information input by the input means 105, and the vehicle detected by the position detecting means 100. The static road information around the current position is read from the static road information storage means 104, and the dynamic road information extracted by the information extracting means 107 is added to the static road information. And display means 108 for displaying in association response, thereby achieving the above object.

[0006]

The display range calculation means 106 determines at least the traveling direction of the vehicle detected by the traveling direction detecting means 102, the traveling speed detected by the traveling speed detecting means 103, and the current position detected by the position detecting means 100. The display range of the dynamic road information input by the dynamic road information input means 105 is calculated according to the current traveling state of the vehicle including the distance to the destination set by the ground setting means 101, and the information extracting means is calculated. 107 extracts dynamic road information within the display range calculated by the display range calculation means 106 from the dynamic road information input by the dynamic road information input means 105, and the display means 1
The static road information storage unit 1 stores static road information around the current position of the vehicle detected by the position detection unit 100.
04, and the information extracting means 1 is added to the static road information.
The dynamic road information extracted by 07 is displayed in association with each other.

[0007]

2 and 3 are block diagrams showing the construction of a vehicle display device according to an embodiment. As shown in the figure, this device is composed of a microcomputer centered on a CPU 1. The CPU 1 exchanges data with various devices via the system bus 2 to perform various arithmetic processes. A direction sensor 3 detects the traveling direction of the vehicle, and is connected to the system bus 2 via the amplifier 4, the A / D converter 5 and the I / O controller 6. Reference numeral 7 is a distance sensor that detects the traveling distance of the vehicle, and is connected to the system bus 2 via the I / O controller 6. 8 is
A key to input various commands and data to the device.
It is connected to the system bus 2 via the O controller 9. Reference numeral 10 is a voice output speaker, which is connected to the system bus 2 via the sound generator 11 and the I / O controller 9. 12 is a position detection system (Global Positioning) using a satellite.
System (hereinafter, referred to as GPS) receiver (hereinafter, referred to as GPS)
It is called a GPS receiver), and is connected to the system bus 2 via the expansion I / O controller 13. The current position of the vehicle is detected based on the current position information from the GPS receiver 12, the traveling direction information of the vehicle from the azimuth sensor 3, and the traveling distance information from the distance sensor 7. Further, 14 is a receiver, which receives dynamic road information and position information such as the above-mentioned traffic congestion, road construction, and traffic regulation through an antenna 15 from beacons installed at roads and intersections.

Further, in FIG. 3, reference numeral 16 is a CD-ROM storing map information, which is a SCSI interface.
It is connected to the system bus 2 via the controller 17. 18 is a VDT (Visual Display)
A CRT that functions as a terminal, is connected to the system bus 2 via the graphic controller 19, and overlays dynamic road information in the optimum range for the occupant, which is calculated by the procedure described below, on the road map around the current location of the vehicle. To display. Further, the system bus 2 includes a V-RAM 20 for image storage of the CRT 18, a ROM 21 for storing a control program described later, a D-RAM for temporarily storing data.
22, Kanji ROM 23, battery backup RAM 2 that stores information such as the current position when the ignition is off
4. The vehicle speedometer 25 is connected.

FIG. 4 is a flow chart showing an example of the display control program stored in the ROM 21, and the operation of the embodiment will be described with reference to this flow chart. Step S1
At, the occupant operates the key 8 to input the destination information, which is stored in the D-RAM 22. Continuing step S
At 2, as described above, the current position of the vehicle is detected based on the current position information from the GPS receiver 12, the traveling direction information of the vehicle from the azimuth sensor 3, and the traveling distance information from the distance sensor 7. Next, in step S3, the static road information such as road maps and buildings around the current position of the vehicle is set to C.
It is input from the D-ROM 16 and stored in the D-RAM 22. Further, in step S4, as described above, the dynamic road information such as road congestion information, construction information, and regulation information is received from the road beacon by the receiver 14, and the D-RAM is received.
Store in 22.

In step S5, information about the vehicle such as the traveling time per unit traveling distance of 100 m and the traveling direction of the vehicle per unit traveling distance of 100 m detected by the azimuth sensor 3 are input. In a succeeding step S6, a subroutine described later is executed to calculate the display content of the dynamic road information. Then, in step S7, the calculated dynamic road information is weighted and displayed on the static road information input in the above step.

5 and 6 are flowcharts showing a display content calculation subroutine of dynamic road information, FIG. 7 is a diagram for explaining a method of setting a display range of dynamic road information, and FIG. 8 is this dynamic road. It is a figure which shows the example of a display which superimposed the dynamic road information determined by the display content calculation of information on the static road information. The arithmetic processing of the display contents of the dynamic road information according to the present invention will be described with reference to these drawings. In step S11, the average vehicle speed is calculated by the following equation based on the travel time per unit travel distance of 100 m input in step S5 of FIG. Average vehicle speed = ΣV / N (1) Here, N is the number of measurements. Then in step S12,
The average azimuth is calculated by the following formula based on the traveling azimuth for each unit traveling distance of 100 m input in step S5 of FIG. Average azimuth = Σθ / N (2) Next, in step S13, the distance from the detected current position to the set destination is calculated by the following equation. Destination distance = {(destination X coordinate-current location X coordinate) ² + (destination Y coordinate --- current location Y coordinate) ² } ^1/2 (3)

In step S14, it is determined whether or not the dynamic road information display range fixing switch in the key 8 is on. If it is on, the process proceeds to step S15, and if not, the process proceeds to step S17. This dynamic road information display range fixing switch does not set the display range of the dynamic road information in advance according to the traveling state of the vehicle such as the traveling direction of the vehicle, the traveling speed, the distance from the current position to the destination, and the like. This is a switch for setting the display range of the dynamic road information within a determined range. In this embodiment, the display range of the dynamic road information is an ellipse as shown in FIG. 7, and one of the points of the ellipse is set as the current position of the vehicle. The display range of the dynamic road information is determined by the distance between the two elliptic points and the distances L1 and L2 from the respective points to the curve. If the dynamic road information display range fixing switch is on, step S15
Then, 0 is set to the distance between the gathering points, and in the subsequent step S16,
A predetermined coefficient, for example, 10 km is set to the range coefficient, that is, the sum L1 + L2 of the distances from the respective points of the ellipse to the curve. That is, in this case, the display range of the dynamic road information is a circle with a radius of 5 km.

If the dynamic road information display range fixing switch is off, the display range of the dynamic road information is calculated in steps S17 to S19. First, in step S17, the inter-collection point distance is calculated by the following equation based on the average vehicle speed calculated in the above step. Distance between points = {a × (average vehicle speed)} ^1/2 (4) Here, a is a constant, and is 0.5, for example. Next, in step S18, a range coefficient is calculated by the following equation based on the destination distance calculated in the above step. Range coefficient = L1 + L2 = b + {c × (destination distance)} ^1/2 (5) Here, b and c are constants, for example, b = 2, c =
Set to 2. Further, in step S19, the position of the focus point in the elliptical display range shown in FIG. 7 is calculated by the following equation based on the average azimuth calculated in the above step. Point position X coordinate = (current position X coordinate) + (distance between points) x cos (average direction) Point position Y coordinate = (current position Y coordinate) + (distance between points) x sin (average direction) (6) As a result, the display range of the dynamic road information is set such that the major axis direction of the ellipse shown in FIG. 7 matches the traveling direction of the vehicle.

In step S20 of FIG. 6, D-RA
It is determined whether or not there is dynamic road information such as traffic congestion, road construction, traffic regulation, etc. stored in M22. If there is dynamic road information, the process proceeds to step S21, otherwise returns to the program shown in FIG. To do. In step S21, the dynamic road information is read in order, and it is determined whether each information is within the display range of the dynamic road information set in the above step. This determination is performed as follows. Each piece of dynamic road information received from the road beacon has position coordinate information whose origin is at a predetermined location, and these position coordinates are displayed on the CRT.
After converting to a coordinate whose origin is a predetermined place on the map displayed on 18, it is determined whether the coordinate is within the set display range of the dynamic road information. That is, when the following expression is affirmed, the information is within the display range. (L1 ^* + L2 ^* ) ≦ range coefficient (L1 + L2) (7) where L1 ^* = {(information position X coordinate−collection point X coordinate) ² + (information position Y coordinate−collection point Y coordinate) ² } ^1/2 , L2 ^* = {(information position X coordinate-current position X coordinate) ² + (information position Y coordinate-current position Y coordinate) ² } ^1/2 If the result of this determination is within the display range, go to step S22. If not, return to step S20.

In step S22, it is determined whether or not the information of the same place as the information determined to be within the display range of the dynamic road information is present in the information at the time of the last reception of the road beacon, and the dynamic information of the previous time and this time is determined. If there is information on the same place when the road information is received, the process proceeds to step S23, and if not, step S2.
Go to 4. In step S23, the rate of change of the dynamic road information of the same place is calculated. This rate of change, for example, if it is information about traffic congestion, indicates how the traffic congestion has changed between the previous time and this time, and is calculated by the following formula. Change rate = (congestion distance of this time) / (congestion distance of previous time) -1 (8) On the other hand, in step S24, the change rate is set to 0 because the information is newly generated at the place this time. ..
In step S25, the dynamic road information within the display range set in the above step and its change rate, average vehicle speed, average direction,
Information such as the destination distance, the point-to-point distance and the range coefficient is stored in the D-RAM 22 and the backup RAM 24, and the process returns to step S20.

FIG. 8 shows a display example of the CRT 18 obtained by executing the control program. The CRT 18 includes static road information around the current position of the vehicle, that is, a road map,
Buildings and the like around the road are displayed with a black dot indicating the detected current position of the vehicle and an arrow indicating the calculated traveling direction of the vehicle. Furthermore, the CRT 18 has a direction of travel,
In the elliptical display range of the dynamic information calculated according to the current driving situation of the vehicle such as the vehicle speed and the distance from the current location to the destination, traffic congestion, road construction, obtained from the road beacon,
Dynamic road information such as traffic regulations is displayed over the static road information.

The method of displaying the rate of change indicates that, for example, in the case of traffic congestion, if the calculation result of equation (8) is positive, the traffic congestion will be severe. Therefore, for example, the congestion section is displayed in red and the calculation is performed. If the result is negative, it indicates that the traffic jam is resolved, so that the traffic jam section is displayed in blue, for example. Also, the rate of change may be displayed by a design. For example, when traffic congestion becomes severe, the traffic jam section is displayed with a symbol using the symbol +, and when the traffic jam is canceled, the traffic congestion section is displayed with a symbol using the symbol −. In any case, any display method may be used so that the temporal change of the dynamic road information can be recognized at a glance.

9 and 10 are flowcharts showing another example of the display contents calculation subroutine of the dynamic road information, and FIG.
FIG. 12 is a diagram for explaining another method of setting the display range of the dynamic road information, and FIG. 12 shows the dynamic road information determined by the display content calculation of these dynamic road information superimposed on the static road information. It is a figure which shows the example of a display displayed. Another calculation method of the display contents of the dynamic road information will be described with reference to these drawings. It should be noted that steps for performing the same processes as those in the subroutines shown in FIGS. 5 and 6 are denoted by the same step numbers, and different points will be mainly described. In this embodiment, the display range of the dynamic road information is set in the shape of a bow as shown in FIG. 11, and the current position of the vehicle is set at the center of the bow. The display range of the road-shaped dynamic road information is determined by the display distance and the display angle. In step S14 of FIG. 9, if the dynamic road information display range fixing switch is on, the process proceeds to step S15A, and if it is off, the process proceeds to step S17A. Step S15A
Then, the coefficient 1 is set to the display distance. Here, the coefficient 1 is, for example, 5 km. In a succeeding step S16A, a coefficient 2 is set to the display angle. Here, the coefficient 2 is, for example, 90 degrees. That is, the display range of the dynamic road information is set to a predetermined range regardless of the current traveling state of the vehicle such as the traveling direction of the vehicle, the vehicle speed, the distance from the current position to the destination, and the like.

On the other hand, when the dynamic road information display range fixing switch is off, the display range is calculated in steps S17A and S18A. First, in step S17A, the display distance is calculated by the following equation based on the destination distance calculated in the above step. Display distance = j1 + {j2 × (destination distance)} ^1/2 (9) where j1 and j2 are constants, for example, j1 = 2, j
Let 2 = 2. Next, in step S18A, the display angle is calculated by the following equation based on the vehicle speed calculated in the above step. Display angle = k1 + k2 / {k3 + (vehicle speed)} ^k4 (10) where k1 to ^k4 are constants. Next in step S19
At A, the direction of the display range of the oval shape shown in FIG. 11 is determined. This display direction is the average azimuth calculated in the above step.

In step S20 of FIG. 10, it is determined whether or not there is dynamic road information as in the above embodiment. If there is dynamic road information, the process proceeds to step S21A. Step S21A
Then, it is determined whether or not the dynamic road information is within the display range calculated in the above step. This determination is made based on whether or not the angle P between the current position of the vehicle and the position of the dynamic road information satisfies the following equation. {(Average azimuth)-(display angle) / 2} ≦ P ≦ {(average azimuth) + (display angle) / 2} (11) where the current position of the vehicle and the position of the dynamic road information Angle P
Is P = tan ⁻¹ {(information position Y coordinate−current position Y coordinate) / (information position X coordinate−current position X coordinate)} (12)

FIG. 12 shows a display example of the CRT 18 obtained by executing the control programs shown in FIGS. 4, 9 and 10. On the CRT 18, static road information around the current position of the vehicle, that is, a road map, buildings around the road, and the like are displayed together with a black dot indicating the detected current position of the vehicle and an arrow indicating the calculated traveling direction of the vehicle. To be done. Further CR
At T18, the traffic information obtained from the road beacon, the road congestion, and the road are displayed in the display area of the dynamic information calculated according to the traveling condition of the vehicle such as the traveling direction, the vehicle speed, and the distance from the current position to the destination. Dynamic road information such as construction and traffic regulations is displayed on top of the static road information. As described above, the traffic jam display may be displayed in different colors depending on the rate of change of the information, or may be displayed in different patterns.

Thus, the display of the dynamic road information such as traffic congestion, road construction, traffic regulation, etc., which has been input, according to the current traveling condition of the vehicle such as the traveling direction, the vehicle speed, the distance from the current position to the destination, etc. Since the range is calculated and the dynamic road information within the display range calculated on the road map around the current position of the vehicle is displayed in association with each other, the dynamic road information of the optimum range is always provided to the occupants. be able to.

In the above embodiment, the display range of the dynamic road information is calculated based on the traveling direction, the traveling speed, and the distance from the current position to the destination. However, the dynamic range is dynamically calculated based on the current driving condition of each vehicle. The display range of the road information may be calculated, or the display range may be calculated based on traveling conditions other than the above.

In the configuration of the above embodiment, the direction sensor 3, amplifier 4, A / D converter 5, distance sensor 7 and G
The PS receiver 12 is the position detecting means, the key 8 is the destination setting means, the azimuth sensor 3, the amplifier 4 and the A / D converter 5 are the traveling azimuth detecting means, the traveling speed meter 25 is the traveling speed detecting means, and the CD ROM 16 constitutes static road information storage means, receiver 14 and antenna 15 constitute dynamic road information input means, CPU 1 constitutes display range calculation means and information extraction means, and CRT 18 constitutes display means.

[0025]

As described above, according to the present invention, at least traffic congestion, road construction, and traffic depending on the current traveling condition of the vehicle including at least the traveling direction, the traveling speed, and the distance from the present location to the destination. The display range of dynamic road information including regulations is calculated, and the dynamic road information of the calculated display range is displayed in association with the static road information including at least the road map around the current position of the vehicle. , It is possible to always provide the occupant with the optimum range of dynamic road information.

[Brief description of drawings]

FIG. 1 is a diagram for responding to a complaint.

FIG. 2 is a block diagram showing the configuration of an embodiment.

FIG. 3 is a block diagram showing the configuration of an embodiment.

FIG. 4 is a flowchart showing an example of a display control program.

FIG. 5 is a flowchart showing a display content calculation subroutine of dynamic road information.

FIG. 6 is a flowchart showing a display content calculation subroutine of dynamic road information.

FIG. 7 is a diagram illustrating a method of setting a display range of dynamic road information.

FIG. 8 is a diagram showing a display example in which dynamic road information of display contents calculated by the subroutine shown in FIGS. 5 and 6 is superimposed and displayed on a road map around the current position of the vehicle.

FIG. 9 is a flowchart showing another example of a display content calculation subroutine of dynamic road information.

FIG. 10 is a flowchart showing another example of a display content calculation subroutine of dynamic road information.

FIG. 11 is a diagram illustrating another method of setting the display range of dynamic road information.

FIG. 12 is a diagram showing a display example in which dynamic road information of the display content calculated by the subroutine shown in FIGS. 9 and 10 is displayed in an overlapping manner on a road map around the current position of the vehicle.

[Explanation of symbols]

 1 CPU 2 System Bus 3 Direction Sensor 4 Amplifier 5 A / D Converter 6, 9 I / O Controller 7 Distance Sensor 8 Key 10 Speaker 11 Sound Generator 12 GPS Receiver 13 Extended I / O Controller 14 Receiver 15 Antenna 16 CD- ROM 17 SCSI controller 18 CRT 19 Graphic controller 20 V-RAM 21 ROM 22 D-ROM 23 Kanji ROM 24 Backup ROM 25 Travel speed meter 100 Position detection means 101 Destination setting means 102 Travel direction detection means 103 Travel speed detection means 104 Static Road information storage means 105 dynamic road information input means 106 display range calculation means 107 information extraction means 108 display means

Claims (1)

[Claims] 1. A position detecting means for detecting a current position of a vehicle, a destination setting means for setting a destination, a traveling direction detecting means for detecting a traveling direction of the vehicle, and a traveling speed of the vehicle. Driving speed detection means, static road information storage means for storing static road information including at least a road map, and dynamic road information input means for inputting dynamic road information including at least traffic congestion, road construction and traffic regulation And at least the traveling direction of the vehicle detected by the traveling direction detecting means, the traveling speed detected by the traveling speed detecting means, and the current position detected by the position detecting means by the destination setting means. The display range of the dynamic road information input by the dynamic road information input means is calculated according to the current traveling state of the vehicle including the set distance to the destination. Display range calculation means, and information extraction means for extracting dynamic road information within the display range calculated by the display range calculation means from the dynamic road information input by the dynamic road information input means. And static road information around the current position of the vehicle detected by the position detection means is read from the static road information storage means, and dynamic road information extracted by the information extraction means is added to the static road information. And a display unit that displays the information in association with each other.