Classifications

• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01C—MEASURING DISTANCES, LEVELS OR BEARINGS; SURVEYING; NAVIGATION; GYROSCOPIC INSTRUMENTS; PHOTOGRAMMETRY OR VIDEOGRAMMETRY
  • G01C21/00—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00
  • G01C21/26—Navigation; Navigational instruments not provided for in groups G01C1/00 - G01C19/00 specially adapted for navigation in a road network
  • G01C21/34—Route searching; Route guidance
  • G01C21/36—Input/output arrangements for on-board computers
  • G01C21/3605—Destination input or retrieval
  • G01C21/3611—Destination input or retrieval using character input or menus, e.g. menus of POIs

Definitions

• the invention relates to a car compass comprising a satellite receiver which on the basis of received satellite signals generates coordinates of an actual position of the car compass, input means whereby a user can input information about a desired destination, a control unit to which the coordinates of the actual position and the information about the desired destination are fed and which processes these coordinates and information in combination for obtaining information about a driving direction to be followed in order to reach the desired destination, and a display on which this driving direction to be followed is represented.
• Such a car compass is known per se and is inter alia marketed under the names of Telepath 100 and Carin.
• These types of systems further comprise a magnetic-field probe for determining the direction of the car compass or the driving direction of the car, sensors for determining the number of revolutions of the front wheels of the car, and a car atlas in CD-version for, inter alia, obtaining coordinates of a desired destination.
• the processing in combination of information coming from four different sources of information - namely satellite receiver, magnetic probe, front wheel sensors and the car atlas in CD-version - involves a fairly substantial susceptibility to interference.
• a route to be followed is typically represented on the display by means of text and maps. This is often difficult to read for a user, as a result of which a user runs the risk of slackening his attention to the traffic.
• control unit comprises a first digital file wherein at least postcodes and position coordinates related thereto and associated with those postcodes are stored, whilst the control unit, in use: - addresses, on the basis of a postcode associated with the inputted information about the desired destination, the first digital file to obtain the position coordinates of the desired destination;
• the postcodes are used, a system of a high accuracy is obtained. Determining the position of a desired destination can be carried out very accurately by means of the postcodes, due to the fact that for instance in the Netherlands, the postcodes have an average distance which is less than 300 m. If the accuracy of the satellite receiver is for instance 100 m, this means that, starting from an area of a 100 m radius around the position wherein the car compass is located and a 150 m radius for the postcode area, the accuracy of the distance measurement between the actual and the desired position is about 180 m. In urban areas this is still better, because in these areas the postcode density is greater than mentioned above.
• a particular embodiment of the car compass has as a characteristic that the control unit, in use:
• the direction of the direction arrow represents, relative to a vertical axis of the display, the driving direction to be followed relative to the actual direction of movement.
• the direction arrow forms a needle of a 'compass' pointing in the direction of the desired destination.
• the extremity of the direction arrow lies on an elliptic curve whose long axis is directed vertically and whose short axis is directed horizontally on the display. If a motorist has approached the desired destination very close, the final meters to the address can as a rule be travelled on the basis of street and house numbers.
• Fig. 1 shows a possible embodiment of a car compass according to the invention
• Fig. 2 shows a vector diagram to illustrate the operation of the control unit of the car compass according to Fig. 1;
• Fig. 3 shows a first possible representation on the display of the car compass;
• Fig. 4 shows a second possible representation on the display of the car compass
• Fig. 5 shows a third possible representation on the display of the car compass
• Fig. 6 shows a schematic view of the first and the second digital file of the car compass according to Fig. 1
• Fig. 7 shows a fourth possible representation on the display of the car compass.
• the car compass 1 comprises a satellite receiver 2, known per se.
• the satellite receiver 2 comprises an antenna 4 for receiving and further processing satellite signals.
• the satellite receiver 2 is suitable for receiving signals transmitted by GPS-satellites.
• 24 GPS- satellites are located at an altitude of 20,000 km above the earth. These satellites have a travelling time of 12 hours. They are evenly distributed over six orbit planes, so that, depending on the location on the earth, in each case at least four and maximally twelve satellites can be observed.
• the operation of the satellite receiver 2 is known per se and will presently not be further explained.
• the satellite receiver 2 determines coordinates of an actual position P at the point of time t of the car compass on the earth's surface.
• This actual position p t is fed to a control unit 8 of the car compass 1 by means of line 6.
• the actual position P t is expressed in coordinates P ⁇ (t) and P ⁇ (t) of the coordinate system GS84 (World Geodetic System 1984) , known per se.
• the WGS84 coordinates are generally expressed in P ⁇ and P ⁇ on the WGS84 ellipsoid.
• the satellite receiver 2 can also provide a coordinate H indicating the altitude above the ellipsoid. In this connection, however, this coordination is less interesting.
• the car compass further comprises input means 10 by means of which a user can input information about an address of a desired destination.
• the car compass comprises a display 12 for at least displaying information about a desired driving direction to be able to reach the desired destination.
• the input means 10 comprise four buttons 11 for the control of a cursor displayed on the display 12 and a button 13 for confirming an option on the display 12 indicated by means of the cursor buttons 11.
• the input means 10 and the display 12 are connected to the control unit 8 by means of line 14 and line 16 respectively.
• the control unit 8 is composed of a microprocessor 18, a working memory 20, a map reader 22 wherein a smartcard and/or PC-card (PCMIA-card) 24 is included, and an interface 26.
• PCMIA-card PC-card
• the microprocessor 18, the working memory 20, the map reader 22 and the interface 26 can communicate with one another in a manner known per se by means of a communication bus 28. Via line 14 and line 16, the interface 26 is further connected to the input means 10 and the display 12 to enable a communication between the input means 10 and the display 12 on the one hand and the microprocessor 18 on the other.
• the smartcard 24 comprises a first digital file, wherein at least postcodes and position coordinates related thereto and associated with those postcodes are stored; see also Fig. 6.
• a postcode consists of four digits and two letters.
• a postcode can be represented by CCCCLL, wherein C indicates a digit and indicates a letter.
• the first file comprises for all postcodes CCCCLL two associated coordinates G- ⁇ and Gy represented by the position G of the relevant postcode in the RD-system known per se.
• the smartcard 24 further comprises a second digital file (Fig. 6) with interrelated addresses and postcodes.
• the control unit 8 further comprises a ROM-memory 30 which is also connected to the bus 28.
• Stored in the ROM-memory 30 is software which, in use, determines the operation of the control unit and, accordingly, the operation of the car compass 1.
• a number of place names from the second digital file are displayed in alphabetic order on the display 12, under the control of the microprocessor 18.
• Fig. 3 shows an example of a possible representation on the display 12. By means of the cursor control keys 11, the alphabetic list of place names can be gone through in a known manner.
• a cursor 32 can for instance by placed on the arrow 33 by means of the cursor keys 11, whereupon, by pressing the button 13, the list of place names is gone through in rising alphabetic order. Likewise, the list can be gone through in opposite direction by operating an arrow 34 in a similar manner. If the place name of a desired destination has been found, in this example Apeldoorn, the cursor 32 can be placed on the place name Apeldoorn, again by means of the cursor keys ll. A definitive choice is made by subsequently energizing the button 13. After the choice has been made, the cursor 32 can be placed in a box with the text "to screen 3", whereupon the confirmation button 13 should be energized. The control unit 8 is thus brought into a second operating mode.
• Fig. 4 Displayed are a number of street names with corresponding house numbers and postcodes, associated with the selected place of Apeldoorn. As described in relation to Fig. 3, the list of street names can be gone through in alphabetic order, again by means of the cursor control keys 11.
• the microprocessor is controlled by the input means for selectively displaying a number of street names with, optionally, the associated house numbers and postcodes from the second digital file.
• the cursor control key 11 When, by means of the cursor control key 11, the street name and the associated house number of the desired destination has been found, the cursor control key 11 can be placed on the desired destination. In this example, this is the 'Wapenrustweg' .
• the Wapenrustweg is selected for the house numbers 100 to 134. in this example, the associated postcode is also displayed, as a check.
• the relevant information about the desired destination has been inputted.
• the postcode associated with that destination has been obtained.
• the microprocessor On the basis of the obtained postcode associated with the inputted information about the desired destination, the microprocessor will now address the first digital file to obtain the position coordinates G and G y of the desired destination G.
• the coordinates Gx, Gy of the desired destination G are known, as are the coordinates P ⁇ (t) and Py (t) of the actual position P t .
• the control unit 8 transforms the coordinates P ⁇ (t) and P ⁇ (t) into coordinates P x (t) and P y (t) , with the coordinates P x (t) and Py(t) representing the position of the car compass in the RD- system.
• the driving direction D to be followed can be determined.
• the point P t represents an example of an actual position of the car compass at the point of time t.
• Point G represents the desired destination.
• the vector D connects the point P t to the point G and, accordingly, represents the driving direction to be followed.
• the control unit 8 determines the coordinates D ⁇ (t-) and D y (t) of the driving direction to be followed at the point of time t as follows:
• Dy(t) Gy - Py(t)
• D x (t) and D y (t) are again defined in the RD-system.
• the vector D can be displayed on the display 12 as it is shown in Fig. 2.
• the displayed vector D thereby forms the above-mentioned direction arrow.
• the x-axis and y-axis of the RD-system could also be displayed on the display 12.
• the driving direction to be followed relative to the actual direction of movement of the car compass is represented on the display by means of a direction arrow.
• the control unit 8 determines, on the basis of coordinates, successively received by the satellite receiver, of at least two different consecutive actual positions P t - ⁇ t and P t of the car compass, the actual direction of movement of the car compass at the point of time t.
• the point p t - ⁇ t represents the actual position of the car compass at the point of time t- ⁇ t.
• the point P t represents the actual position of the car compass at the point of time t.
• the vector R interconnecting the point Pt- ⁇ t an ⁇ 3 the point P t is considered to represent the actual direction of movement of the car compass at the point of time t.
• the driving direction to be followed relative to the actual driving direction can be determined.
• This driving direction can then be represented on the display 12 by means of a direction arrow again (see Fig. 5) .
• the image according to Fig. 5 can for instance be obtained by moving the cursor into the frame with the text; "to screen 1" and then pressing the button 13 (see Fig. 4) .
• Fig. 5 can for instance be obtained by moving the cursor into the frame with the text; "to screen 1" and then pressing the button 13 (see Fig. 4) .
• the direction of the direction arrow V on the display corresponds to the driving direction to be followed relative to the actual direction of movement of the car compass.
• the vertical axis of the display gives the actual direction of movement (vector R) of the car compass.
• the length of the direction arrow V is chosen so that it lies on an elliptic curve whose long axis is directed horizontally and whose short axis is directed vertically on the display. This elliptic curve is also shown, in dotted lines, in Fig. 5. It is thus suggested that the direction arrow moves in the plane of the road.
• the control unit 8 also determines the length of the vector D as it is shown in Fig. 2.
• the length of the vector D corresponds to the distance in a straight line between the desired destination G and the actual position P t .
• the outcome of this calculation, in this example 12.4 km, is also represented on the display.
• the above-outlined operation of the control unit can be specified as follows.
• the control unit determines coordinates R x (t) and Ry(t) of the vector R in the RD-system as follows:
• R x (t) P x (t)-P x (t- ⁇ t)
• R y (t) P y (t) -Py(t- ⁇ t) .
• the inputting of information about the desired destination can also be carried out by putting in directly a postcode associated with the desired destination. Inputting by means of a keyboard is also possible.
• This postcode could for instance be selected by displaying lists of postcodes from the first digital file on the display 12.
• the inputting of an address of a desired destination need not necessarily concern a place of residence, street name and street number.
• the second digital file can be extended to include addresses or names of restaurants, petrol stations, banks, auxiliary services, tourist attractions on the one hand, and the associated postcodes on the other.
• the postcode areas are usually smaller, as a result of which the accuracy of the indications increases. However, in rural areas, the postcode areas are larger than the above- described 300 m section.
• a switch-over could be made for these areas from postcode coordinates to PAP-data (PAP: premises, address and place coordinates) . In that case, for particular addresses the postcode is replaced by PAP-data.
• PAP-data can then be related again to position coordinates of the desired destination.
• the first digital file is for this purpose provided with PAP-data related to the position coordinates associated with those PAP-data, while on the basis of PAP-data associated with the inputted desired destination, the control unit, in use, can address the first digital file to obtain the position coordinates of the desired destination. If a particular postcode is not known in the first digital file, the control unit can for instance select a postcode which numerically and alphabetically is closest to a selected postcode of the desired destination. The more positions in the postcode correspond, the closer they will be in each other's vicinity.
• the control unit can further comprise a digital road-network file, known per se, with numbered roads for displaying on the display, by means of a map, the main route to be followed to the desired destination (Fig. 7).
• the control unit displays the main route in this known manner in particular if the car compass is located outside a densely built-up area, or if the distance in a straight line between the actual position of the car compass and the desired destination is greater than a predetermined value.
• the direction arrow is displayed.
• the direction arrow is displayed with a background that does not comprise any cartographic information (see Fig. 5) .
• the background then comprises, for instance, a neutral blue field, while the direction arrow is white. In that case, the direction arrow only indicates the direction relative to the actual direction of movement.
• the map with the main route to be followed Fig. 7
• the direction arrow Fig.
• the car compass further comprises means for informing a user of the desired driving direction through sound.
• the first and second digital files can readily be replaced by new versions, simply by replacing the card 24 by a new smartcard. This is particularly convenient in view of the fact that new postcodes are regularly introduced for new housing estates. In this manner, the car compass 1 can always be kept up to date.

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• Engineering & Computer Science (AREA)
• Radar, Positioning & Navigation (AREA)
• Remote Sensing (AREA)
• Human Computer Interaction (AREA)
• Automation & Control Theory (AREA)
• Physics & Mathematics (AREA)
• General Physics & Mathematics (AREA)
• Navigation (AREA)

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ID=19761271

Family Applications (1)

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Cited By (6)

Citations (3)

• 1995
  • 1995-07-05 NL NL1000733A patent/NL1000733C2/nl not_active IP Right Cessation
• 1996
  • 1996-07-05 AU AU63201/96A patent/AU6320196A/en not_active Abandoned
  • 1996-07-05 WO PCT/NL1996/000277 patent/WO1997002469A1/en active Application Filing

Patent Citations (3)

Non-Patent Citations (2)

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