FR2882138A1 - Geographical point position designating method for e.g. car navigation, involves transmitting position as bar code, obtained by helicoid method, to navigator via electronic message or by presenting code to code reader coupled to navigator - Google Patents

Abstract

The method involves transmitting a geographical position of a point on the globe to a navigator as a bar code via a short electronic message or by presenting the code to a bar code reader coupled to the navigator. The code is obtained by a `helicoid method`, which involves regularly graduating a helicoid curve based on a pole, turning regularly around a north-south axis and choosing as codes the graduation nearest to the place.

Description

- 1 -

  The present invention introduces the use of a simple code to accurately represent the geographical position of a point on the surface of the globe. Such a representation of a geographical position facilitates its entry into an electronic system for assisting the navigation of vehicles: automobiles, boats, etc. The simple code can take the form, and this as an example and of without limitation, a group of characters or numbers or a barcode.

  Traditionally, the position of the place to be joined is given to a car navigation system by its postal address: country, city, lane and number in the lane. Such a datum is natural because it corresponds to the usual way of designating a place, but its input is tedious and in particular on limited keyboards like those of cars. It should also be noted that the destination can not be entered on a navigation system that does not know the route and that this deprives the driver of the minimum assistance which would be to indicate the direction of the point to be reached.

  Traditionally, another method is to designate the place by a couple of numbers as part of a defined coordinate system. There are several coordinate systems, the best known of which involves two angles called longitude and latitude.

  The longitude of a point corresponds to the angle formed by the vertical of this point with the plane of the reference meridian. Longitude can take values from 0 to 180 west or east of the reference meridian that marks longitude 0. The longitude therefore takes values over an interval of 360.

  The latitude of a point corresponds to the angle formed by the vertical of this point with the plane of the equator. The latitude can take values from 0 to 90 north or south of the equator which marks latitude 0. The latitude therefore takes values over an interval of 180.

  The expression of a position by the datum of longitude and latitude is complex for a person unfamiliar with the angular coordinates. It is then necessary to give two angles with for each one, a direction, north or south for the latitude and west or is for the longitude, and the data of the value of the angle in degree, minute, second ...

  The present invention aims to overcome these major drawbacks and proposes a way to give the position of a point that is easy to transmit. Such a position is given and this against all established uses, by a simple code in the form of a single number, which will be called later position index.

  Several definitions and methods of calculating position indexes can be considered. We will expose below, and this without limitation, several methods to define it.

  To provide a definition and method for calculating the position index, the invention introduces the combination method of angles that combines longitude and latitude into a number.

  To obtain a good precision, longitude and latitude are divided into fine angular gradations. Since an angle of longitude corresponds to a greater distance when the latitude is small, if we want to limit the distance between graduations to 10 meters, we must divide the 360 which make 40000000 meters to the equator in graduation of 10 meters. The longitude can therefore be expressed rather accurately by a longitude scale, an integer between 0 and 4000000. As far as the latitude is concerned, it would be necessary to divide the 180 or 20000000 meters in a 10-meter scale. The latitude can therefore be expressed by a latitude graduation, an integer between 0 and 2000000. It is then possible to group the two numbers into one, called the position index, so that the operation is invertible, that is, we can find both numbers from the position index.

  The position index is equal to: longitude graduation + latitude graduation x number of graduations of longitude. The latter is worth 4000000. From the position index it is possible to find the number of longitude and the number of latitude by the Euclidean division of the position index by the maximum number of longitude. In this example, the position index is therefore between 0 and 8000000000000, ie thirteen digits to designate a point. To make the most of the thirteen digits with the same method, you can take a graduation of 9 meters. The longitude is then designated by an integer between 0 and 4444444, 40000000 meters divided by 9 meters. The latitude is then designated by an integer between 0 and 2222222, 20000000 meters divided by 9 meters.

  To provide another definition and method of calculating the position index, the invention introduces the helical method. It uses another coordinate system, which we will call helical coordinate. This coordinate system is remarkable in that it provides a distance of 7 meters between graduations while using only thirteen digits. In the helical coordinate system, the graduation na has the following coordinates: Longitude (expressed in radians) = 4 x 10000000/7 x arcsin (n / 5000000000000 - 1) Latitude (expressed in radians) = arcsin (n / 5000000000000 - 1) The graduation n can take values from 0 to 9999999999999. The arcsin () function is the inverse trigonometric function of the sin () function called sine and these functions are well known in mathematics. The expression of longitude and latitude can be obtained in degrees, (2 x n) radians being equivalent to 360. The position index of a geographical point is equal to n if n corresponds to the graduation nearest the point.

  The advantage of the helical coordinate system is that it distributes more evenly over the Earth the graduation points corresponding to the values of the position index than the longitude-latitude system. In particular, this coordinate system does not have the disadvantage of tightening the graduation points towards the poles, which leads to a waste of position index - 4 - towards the poles, forcing in return to space the graduations elsewhere.

  The definition of a position index and its method of calculation allows the present invention to remedy the heaviness of the designation of a point by its postal address and the complexity of its designation by the usual longitude-latitude form allowing a navigation system user to designate a point by a number of thirteen digits. The idea of the invention can lead to the creation of the new habit of giving the position of places in a short and simple form and this against all established uses of geographical information.

  Thanks to the simple representation of a geographical position by its position index as defined by the invention, the invention provides for its transmission to the navigation aid system in several ways and for example, and without limitation, by typing the position index number on a keyboard, by transmitting this code to the navigation system by a short electronic message or by presenting to a barcode reader coupled to the navigation system the barcode inscribed on a support and representing this number. Bar code systems usually use a thirteen digit code. The point of the Earth to be designated can thus be given as well.

  Thus, the idea of the invention is to facilitate the designation of a geographical point and this against all established uses, by an operation as simple as the presentation of a bar code in front of a reader or, failing that, by entering a number.

  One embodiment of the invention can facilitate the operations that drivers must do by providing the navigation system of their car with the ability to take into account the position index and the ability to read this index in the form of a barcode thanks to a suitable reader. When we want to go to a store with his car, it will be sufficient - 5 - to present the bar code on the promotional leaflet of said store to the code reader integrated into the navigation aid system to record his goal. It should be noted that the presence of the code on a support encourages to keep the support, which is an asset for the impact of an advertising document. Objects that usually have a mailing address will also carry their position index with their barcode representation. For example, materials promoting a store, restaurant, resort, or other prominent place will carry the bar code of the position index. These materials may be advertising leaflets, plastic bags or bags, packaging, directories, guides or books etc. Business cards and personal business cards may also carry the bar code.

  One embodiment of the invention can facilitate the operations that drivers must do by providing the navigation system of their car with the ability to take into account the position index and the ability to read this index in the form of a device for receiving short messages such as can send them mobile terminals or personal electronic assistants. The driver can have the index of position of his relations on his personal assistant or he can receive this index on his mobile terminal that would be sent by the organizers of the evening or by an automatic server system interrogated beforehand by the driver.

  A basic embodiment of the invention can facilitate the operations that drivers must do by providing the navigation system of their car, boat or other vehicle with the ability to take into account the position index and a keyboard to type this. index.

  To complete the realization of the invention, it is necessary to make it easy to know the position index of a place. One embodiment of the invention includes software for calculators and intended to calculate the position index from longitude and latitude or from a postal address if the calculator has information. precise on the tracks. These software can be sold for installation on personal computers or for online use on the network. It should be noted that in order to function, a navigation aid system determines its longitude and latitude at any time. Supplemented with appropriate software, the navigation system could display the position index of the place where it is located, allowing, for example, the driver of a vehicle thus equipped to know the position index of his home. In a general manner, all the systems enabling their users to locate themselves can be extended as defined by the invention with calculation functions to calculate the position index corresponding to the current location and to display it.

  Remarkably, the implementation of the invention makes use of several technologies available on the market: calculator, printing and barcode reading, transmission of short electronic messages, navigation aid system. Thus the inventive step was not only to pose the technical and ergonomic problem to be solved but to provide an effective solution, elegant and easy to implement.

  The following description with reference to the accompanying drawings, all given by way of non-limiting example, will make it clear how the invention can be implemented.

  FIG. 1 provides an exemplary structure representing an extended navigation aid system to take advantage of the invention. In Figure 1, the navigation system is referenced NAVIGATOR, the barcode reader is referenced READER, the object bearing the barcode is referenced DOC, the light sent by the reader is referenced LASER, the light that is reflected by the object carrying the barcode is referenced IMAGE, the read position index is referenced INDEX. - 7 -

Claims (7)

  1) Method for programming a navigation aid system with the position of a geographical point, characterized in that this position is given to it in the form of a simple identifier.   2) Method according to claim 1, characterized in that the identifier to be given to the navigation aid system is an integer.   3) Method according to claim 2, the identifier to be given is obtained combination of angles consisting of converting longitude and latitude characterized in that by the method of at first to positive integers by division and numbering of their intervals of variation in equal parts and in a second time to combine these integers by adding the integer representing the longitude and the product of the integer representing the latitude by the number of integers encoding the longitude, the coding can also be done by inverting the roles of longitude and latitude.   4) Method according to claim 2, characterized in that the identifier to be given is obtained by the helical method which consists of regularly graduating a helical curve starting from a pole and rotating regularly around north-south axis while going towards the other pole and to choose as code the nearest graduation of the place.   5) Method according to claim 2, characterized in that the identifier is given in the form of bar code presented to the bar code reader of a navigation system equipped with such a device. - 8 -   6) Method according to claim 5, characterized in that the marking of the bar code is applied, and this without limitation, on media referring to a store, a restaurant, a tourist place, a company, a home or another remarkable place, these supports can be, for example and without limitation, advertising flyers, bags, plastic bags, packaging, directories or guides, business cards or personal business cards.   7) Method according to claim 2, characterized in that the identifier to be given is transmitted by an electronic message using for example and non-exclusively, a radio or optical link, to the message receiver of a navigation system specifically equipped with such a device.