DE10043313A1 - Positive identification of transmitter location in network using GPS receivers, using method secure against fraud, employs concept of randomly-variable reference space characteristics - Google Patents

Abstract

Global space is divided into reference spaces. Provisions define reference space characteristics. Reference space(s) are varied in global space accordingly. Provision(s) are altered at random times. Each transmitter and receiver maintain provisional data information. A transmitter sending communication(s) determines its position with respect to the reference space. Included in the communication(s) is data concerning transmitter location relative to the reference space. The receiver of communication(s) or information determines its position relative to the reference space. It integrates information from the transmitter on transmitter location. Hence the receiver unambiguously identifies and locates the transmitter.

Description

The invention relates to a method for tamper-proof unique localization Identify and identify a sender that has one or more messages sent to one or more recipients via a transmission medium. A variety of communication tasks between a transmitter and one Recipients require the sender's unique identity. The conclusion on the unique identity of the broadcaster is, for example, with pay TV, pay audio or in the future also when renting video films from a virtual video thek on the Internet an imperative. Only with the knowledge of unique, tamper-proof identity of the sender and the recipient data communication possible without pretending an incorrect identity. The clear, forgery-proof identity is particularly important for Internet Banking.

Communication systems are subject to other threats. So be Data packets sent or down over a communication network charged, which can be infected with fours. In these cases it would be from The advantage of being able to clearly localize the origin of the attack. Also at Display and provide information relevant to criminal law in a communications network, it’s crucial for the judiciary to if there was a clear location of the transmitter.

Another use case where the localization of the unique identity would be particularly advantageous lies with the unauthorized and unnoticed Access to a computer or computer system.

From WO9953624 a GPS signal access system is known, the access nes authorized recipient on z. B. video data, audio data, boarding data or data signals from other computers. A characteristic of this Lö solution is that the customer signal access control can only access authorized, if it is located authoritatively, using a GPS receiver. The GPS signal access system uses the GPS position data for the autori in one place.  

The signal access system also has a central access control, the one GPS receiver is used and provides position data that is transmitted via a trans medium to be transferred to the customer. Position data of the customers Access control and central control are for the authorized Access to sent signals used.

The GPS signal access control enables the control center to locate one Customer access control and its authorization for access to the ge wish data sent out from a center. A disadvantage of this Lö solution is that not every recipient connected to a transmission medium is switched on, each transmitter that is on the same transmission medium switch is tamper-proof. Another disadvantage of the Lö solution is that the localization required for authorized access cannot be used for e-mail communication.

The invention is based on the problem of a forgery-proof and public ches method for locating the sender of a message from the recipient of the message. The advantages to be achieved with the invention are that the localization can be done from any recipient and is forgery-proof despite the known method.

Manipulation of the identity by the sender of the message and / or the Recipient of the message and / or a third party is impossible.

The problem is solved according to the invention by the method according to the Claims 1 and 2 solved.

The invention is explained in more detail below with reference to FIGS. 1 to 14. The drawings represent preferred exemplary embodiments of the invention.

Fig. 1 is a schematic representation of the arrangement according to the invention for implementing the method,

FIG. 2 is a global Ortraum and reference areas,

Fig. 3 shows the identity of a transmitter locations and their provision in a reference area at the location of the transmitter,

Fig. 4 shows the localization of the transmitter locations and their determination in the global Ortraum with respect to three reference areas on the location of the transmitter,

Fig. 5 shows the localization positions of the transmitter and the determination with respect to three reference areas in the global Ortraum from the location of the receiver,

Fig. 6 shows the localization of the transmitter locations and their determination in the global Ortraum with respect to five reference areas at the location of the transmitter,

Fig. 7 shows the localization positions of the transmitter and the determining the global Ortraum with respect to five reference areas on the location of the receiver,

Fig. 8 the spatial position of the identity of the transmitter to the point Identitätsbe zugsebenen at the location of the sender and the destination,

Fig. 9, the spatial position of the location point of the transmitter to the Lokalisati onsbezugsebenen at the location of the sender and the destination,

Fig. 10 shows the determination of the spatial position of the point identity of the transmitter by the receiver,

Fig. 11 shows the determination of the spatial position of the location point of the transmitter by the receiver,

Fig. 12 shows the determination of the localization and identity of the transmitter locations in the global Ortraum and identity space,

Fig. 13 is an embodiment of the determination of the spatial positions of the identity and localization point in a common spot and identity space,

Fig. 14 shows a further embodiment of the shape of the Ortraumes,

Fig. 15 shows the structure of a transmitter of the inventive arrangement,

Fig. 16 shows the structure of a receiver of the arrangement according to the invention and

Fig. 17 is an embodiment of the inventive arrangement.

In Fig. 1, the arrangement of the invention is shown for implementing the method. A GPS is required for safe, unambiguous localization. In Fig. 1, only one satellite 11 from the GPS is shown due to the clarity. Furthermore, a control center 13 , a satellite transmission system 12 , transmitters 141 , 142 , receivers 151 , 152 and a wired transmission path 16 are disclosed. The transmitter 141 with i = 1.2 and the receiver receive via the satellite transmission system 12 and their receiving devices according to claim 61 data from the control center 13 and the GPS 11 coordinates. A transmitter 14 i sends over the wired transmission path 16 to a receiver or multiple receivers 151 messages in the form of telegrams.

FIG. 2 shows a location 21 and three reference spaces 421 with i = 1, 2, 3 and three spatial points each, which serve to determine the reference spaces and / or as reference points.

FIGS. 3 and 4 show a first embodiment of the method for time t _i. Here is z. B. the IP address of the sender assigned a unique identity point in the identity reference areas and a unique localization point in a place.

In Fig. 3, an identity point IPdS and the identity locations of the transmitter ILdS are shown in a reference space 42 i. An identity point in the identity reference space 42 i is assigned to each transmitter. The location of the identity points in majority identity spaces is always identical. The transmitter determines the location, the reference rooms and the focal points of the reference rooms from the specifications of the headquarters. For each identity reference space, the transmitter 141 calculates the identity positions as spatial straight lines which each pass through a spatial point RP ki, the so-called identity reference point, and the identity point of the transmitter. From these spatial straight lines, the transmitter determines the associated unit space vectors as relative transmitter-side information about the identity positions.

In FIG. 4 the Ortraum 21, three reference areas 42 i with i = 1 2 3, are, each reference space a center of gravity and a point of identity, six documents localization of the transmitter LIS ij and the location point of the transmitter shown. In this embodiment, the reference spaces 42 i are at the same time identity and localization reference spaces. The transmitter 14 i determines the localization positions as spatial straight lines in the local space. Each localization location goes through the localization point and a focus or identity point. From the Raumgera the sender determines the associated unit room vectors as relative transmitter-side information about the localization. The transmitter sends this relative information dependent on the transmitter position via the transmission path 16 to the receiver or to the receivers 15 i.

FIG. 5 shows, from the point of view of the recipient at time t _{i + 1,} the location space 21 , the three reference spaces 42 i with i = 1, 2, 3, a focal point and an identity point for each reference space, and six localization locations. The reference space 423 is changed in its position with respect to the position in FIG. 4. The new location of the reference space is intended to represent a random change in a specification which was communicated by the control centers 13 to each transmitter and receiver shortly before the time t _{i + 1} . The recipient determines the location space, the reference spaces and the focal points of the reference spaces from the specifications of the headquarters. From the telegram transmitted by the transmitter via the transmission path 16 , the receiver selects the relative information dependent on the transmitter position. The unit space vectors which are assigned to the identity positions are converted by the receiver into straight lines which are entered in each reference space 42 i in the identity reference points RP ki. The intersection of the three straight lines represents the identity point of the transmitter in the identity reference space 42 i. The identity of the transmitter is established according to claim 12 with the majority of the identity points of all identity spaces. Furthermore, the receiver selects the localization locations LIS ij on the transmitter side, which, as shown in FIG. 5, it applies in the respective associated center of gravity or identity point. The intersection of the majority of localization locations corresponds to the localization point of the OPdS transmitter.

Fig. 6 shows a second embodiment of the invention at the location of the Sen at time t _i . The location 21 , the reference spaces 42 i, the localization locations LIS ij, the reference point for each reference space and the location of the transmitter in the location are shown in detail. All of these components were identified by the broadcaster. In this embodiment variant too, the reference spaces 42 i are both identity reference spaces and localization spaces. FIG. 7 presents the local space 21 , the reference spaces 42 i, the localization locations LIS ij from the point of view of the recipient at the time t _{i + 1} . As the comparison between FIGS . 6 and 7 shows, the positions of the reference spaces 424 and 425 are changed ver. As in the first embodiment variant, this change represents a random change in the specifications for the reference rooms 424 and 425. The random changes serve for tamper-proof identification and localization. As in the first variant, the transmitter determines the identity points and identity locations. The localization locations are determined analogously.

The only difference is that it is no longer the location locations of the focal points that are used, but two additional location locations of two additional reference rooms. As with the first embodiment, the sender determines its sender position-dependent information, which it then sends to the recipient along with the other messages via the transmission path 16 . The receiver selects the information dependent on the sender location, determines the identity locations from the unit space vectors and, as in the first embodiment, determines the identity points per identity reference space. The identity also results from a majority decision of the same identity points of all identity reference areas. For the localization of the localization point of the transmitter, the receiver generates the localization locations of the localization point and enters them in the identity points of all reference spaces. The intersection of the majority of straight lines characterizes the location of the transmitter.

In FIGS. 8 and 9, a third embodiment of the invention de monstriert. In detail, FIG. 8 shows a reference chamber 42 i, three spatial points RP ki, the identity of the sender point IPDS, two reference planes 61 and 62, the so-called identity reference planes determining relative sendeseiti ger information of identity documents. In this case, the identity positions represent solder vectors from the identity point to the identity levels. Starting from the identity point of the transmitter, the solder vector to the reference level 6 v with v = 1, 2 is precipitated for each reference level. The intersection of the solder vector with the identity reference plane is the identity reference point IBP j. The perpendicular distances between the identity point and the respective identity reference point IBP j form the first components of the information on the transmitting side about the identity positions. Furthermore, three additional plumb points are determined on the reference level. As can be seen from FIG. 8, the three spatial points RP ki serve as starting points. The distances r _ljki are determined by the transmitter and added as further components of the information _dependent on the transmitter position.

In Fig. 9 the location 21 is shown, the three reference spaces 421 , 422 and 423 , the localization reference levels 51 and 52 , the localization reference points LBP 1 and LBP 2 , the localization point of the transmitter OPdS and the localization locations. In this embodiment variant, the localization positions correspond to solder vectors of the localization point with respect to the localization planes. The transmitter determines the localization location and the intersection of the localization location with the localization level for each localization reference level 5 i. This intersection then forms the localization reference point LBP i. Further solder points are determined as shown in FIG. 9. The distances r _{Ljk of} the plumb points to the localization reference point LBP j on the localization reference planes form, on the one hand, the information provided by the transmitter, which are supplemented with the plumb distance of the localization point from the localization reference point. All distances with respect to the identity point and localization point are transmitted by the transmitter over the transmission path 16 together with other messages without being marked.

Fig. 10 provides information on the determination of the identity reference point IPDS or the identity reference points. Fig. 11 shows the determination of the point of localization LPdS in place 21 by the receiver 15 i. Specifically, an identity reference area 42 is in Fig. 10 displayed i the Identitätsbezugsebe nen 61, 62, three spatial points RP ki, the identity point IPDS, the Identitätsbe reference points IBP j as well as the determination of the identity reference and the identity point.

The receiver selects the distances from the telegrams, calculates the Location, the reference spaces and determines the reference planes, the plumb points of the plumb vectors of the spatial points on the identity reference levels, as well as the Plumb points on the localization reference levels. The recipient strikes with the Distances as radii three circles around the plumb points. The intersection represents the respective reference point. In this reference point for each reference level in one variant, the plumb line with the plumb spacing of the identity point or the solder is plotted with the solder spacing of the transmitter's localization point. The identity and location of the localization point are also derived from the won majority agreement.  

In another variant, the solder straight lines are established in the reference points tet. The intersection of the majority plumb line represents either the Identi point of action or the localization point of the transmitter unit is also caused by random changes in a reference space or one Reference plane or the spatial points guaranteed.

Fig. 12 are shown in detail a place 21 , an identity space 31 , reference spaces 42 i, the localization point of the transmitter, the identity point of the transmitter and reference points. Furthermore, the identity and location locations are drawn as straight lines. The transmitter 14 i determines the respective rooms, reference points and identity and localization locations. From this, he determines the sender-dependent information that he sends via the transmission path 16 to the receiver 15 j. The receiver 15 j calculates the respective rooms, reference points and identity and localization locations. From the telegrams received via the transmission path 16 , he selects the transmitter-side relative information about the identity and localization locations. After the application in the reference points, the majority of intersections of all localization locations or all identity locations are determined. With these intersections, the identity of the transmitter is known and the transmitter is localized. Several variants can be used to implement counterfeit protection. The first variant is characterized in that a reference space is changed in one time unit.

The second variant is characterized by at least three spatial arrangements of FIG. 12, two of these arrangements being identical in one time unit and one changing. After a further random time, one of the previously identical arrangements is transferred to the previously modified arrangement by specifying the control centers. The identity of a transmitter is thus determined from the majority agreement of the identity points and the location of the transmitter from the majority agreement of the localization points. FIG. 13 shows a further embodiment for determining the spatial positions of the identity and localization point. As can be seen from FIG. 13, the location space and identity space are identical. The determination of the identity and the localization of the transmitter is carried out according to claims 13 and following.

Fig. 14 is another layout of the space is Ortraumes and identity. According to the invention the method also comprises the combination of a plurality of spatial forms.

In Fig. 15, an embodiment of the transmitter of the arrangement according to the invention is shown, which builds up and works according to claims 48, 49 and 59. Fig. 16 shows an embodiment of the receiver of the inventive arrangement, which according to the claims 50, constructed and functions 51 and 57. Fig. 17 shows types of integrations of the inventive arrangements of the transmitter and receiver in a computer network.

Claims (63)

1. A method for tamper-proof, unambiguous localization and identification of a transmitter which sends one or more messages via a transmission medium to one or more receivers, using GPS receivers, is characterized in that

• - that there is more than one reference space in at least one global space,
• - that there are specifications for the reference spaces that contain properties about the reference space,
• - that at least one reference space in the global space is changed,
• - that the reference space is changed according to specifications,
• - that at least one specification is changed at random times,
• - that each sender and each recipient receive at least one piece of information regarding the requirements,
• that a transmitter which sends at least one message determines its position in relation to the reference spaces,
• that the sender transmits at least one piece of information, which is dependent on its position in relation to the reference spaces, to the recipient in at least one message of the entire shipment,
• - that the recipient of a message determines one or more pieces of information about his position in relation to the reference spaces,
• that the receiver determines the information integrated by the transmitter about the position of the transmitter in relation to the reference spaces,
• - That the receiver uniquely identifies and localizes the transmitter from its position information or its position information and from the information determined from the position of the transmitter or from the information determined from the position of the transmitter.

2. The method according to claim 1, characterized in

• that each transmitter is assigned at least one unique spatial point, the so-called localization point, in at least one location and at least one unique spatial point, the so-called identity point, in or to at least one identity space,
• - that the identity of a transmitter is determined on the basis of the identity point or the identity points and the transmitter is localized on the basis of its localization point or localization points,
• that each identity point has at least one reference point a defined location, the so-called identity location, and each localization point has at least one reference point a defined location, the so-called location location,
• that the transmitter sends information relating to the identity locations and location locations as information dependent on the transmitter location in at least one data packet via at least one transmission medium to at least one receiver,
• the receiver determines the identity point or the identity points of the transmitter from the information provided by the transmitter on the identity positions of the transmitter and from the reference point or reference points determined by the receiver,
• - That the receiver determines the localization point or the localization points of the transmitter from the transmitter-side information on the location of the transmitter and from the reference point or reference points determined by the receiver.

3. The method according to claim 2, characterized in that the reference point Center of gravity and / or an identity reference point and / or a localization reference point of a reference space or a reference plane. 4. The method according to claim 2, characterized in that the identity and / or  Localization locations are straight. The position of identity through the Identi and the identity reference point or focus of a reference space goes. The localization location through the localization point and the Localization reference point or center of gravity of a reference space.   5. The method according to claims 2 and 4, characterized in that the Transmitter as transmitter-side information the direction vectors of the identity and localization locations determined. 6. The method according to claims 4 and 5, characterized in that the Recipients send the identity and localization locations from the Rich tion vectors and the assigned reference points. 7. The method according to claim 6, characterized in that the recipient as Identity point of an identity space the intersection of majority identi situation and as the localization point the intersection of majority localis positions. 8. The method according to the above claims, characterized in that a global space and global identity space and at least three references There are spaces for identity and location localization. 9. The method according to claim 8, characterized in

• - that the identity of the sender is established with the determination of the intersection of majority identity positions,
• - That the localization point, the location of the transmitter in global locality, is localized with the determination of the intersection of majority localization locations.

10. The method according to claims 1 and 2, characterized in that only a global space as a global place and reference spaces as identity spaces available. 11. The method according to claim 10, characterized in that three identity spaces exist. 12. The method according to claim 11, characterized in

• - that an identity point is determined for each identity space,
• - That the identity of a broadcaster is established with a majority of the identity points of all identity spaces.

13. The method according to claim 2, characterized in that the identity layers and / or localization layers of solder vectors to at least one reference level are. The plumb point from the plumb vector of a localization layer corresponds to the loca Point of reference on the localization level. The solder point from the solder vector an identity position corresponds to the identity reference point on the identity label train level. 14. The method according to claim 13, characterized in that the transmitter as Transmitter information at least the distances between the ldenti point of reference and other plumbing points of the identity reference level, the Ab between the localization reference point and other plumbing points of the Localization reference level determined. 15. The method according to claim 14, characterized in that the transmitter as further transmitter-side information the solder vector lengths (solder spacing of the ident point of the identity reference plane, vertical distance of the localization point from the localization reference level). 16. The method according to claim 14, characterized in that the further solder points the intersection of the perpendicular lines at least three points of the Be train spaces with the reference plane. 17. The method according to claims 13-15, characterized in that the Receiver the further plumb points on the reference level or the reference levels determined. With these plumb points and the distances on the transmitter side the recipient determines the identity reference point or identity reference points and / or the localization reference point or the localization des traction points. 18. The method according to claim 17, characterized in that the identity traction point and / or localization reference point intersection of three circles  are at the respective reference level. The radii correspond to the distances between the other plumb points and the reference points. The centers of the circles are the intersections of the perpendicular lines of at least three points the reference spaces with the reference levels. 19. The method according to claims 16 and 17, characterized in that the Identity point of the sender by the one specified in the identity reference point NEN solder vector with the length of the transmitter-side solder spacing of the identity point and that the localization point of the transmitter by that in the position Lot vector plotted with the length of the Lotab on the transmitter side position of the localization point. 20. The method according to claim 19, characterized in that depending on the identity train level an identity point is determined that the identity of a Sen in the case of a majority agreement of the identity points of all Identity reference levels are established. 21. The method according to claims 17 and 18, characterized in that the The majority of recipients as the sender's identity point Plumb line chooses, each in the identity reference point of the Identitybe train level were built. 22. The method according to claims 17 and 18 characterized in that the The majority of the recipients as the transmitter's localization point cher selects straight lines, each in the localization reference point of the loca level were established. 23. The method according to claim 3, characterized in that the Identitybe traction points are spatial points that are both points of the identity space are also points of the space. 24. The method according to claim 23, characterized in that the spatial points Points of the outer surface of the identity space are.   25. The method according to claim 3, characterized in that the heavy point of an identity space and / or the focus of a reference room measured from the mean values of the coordinates of three spatial points of the global place. 26. The method according to claim 2, characterized in that the identity points in relation to the majority of all identity spaces or in relation to ides planes of reference and / or with respect to the reference points are the same. 27. The method according to claims 1 and 2, characterized in that the Specifications relate to the reference space, with at least three coordinates he are spatial points of the global place. 28. The method according to claim 1, characterized in that the default the properties of a reference space concerns the shape, with all Be train spaces of the same shape or the majority of all reference spaces of are of the same shape. 29. The method according to claim 1, characterized in that the requirements of Majority of the reference spaces are the same. 30. The method according to claim 1, characterized in that the change a specification of the location and / or orientation of a reference space in min changed a global space. 31. The method according to claims 1 and 2, characterized in that the requirements and orientation of at least three global spatial points the reference spaces in the global space or in the global spaces be averaged. 32. The method according to claim 3, characterized in that an identity is the focus of the identity space.   33. The method according to claim 3, characterized in that the localization Reference points and identity reference points are identical. 34. The method according to claim 3, characterized in that a localization is the focal point of the reference space. 35. The method according to claim 1, characterized in that a global cent rale sends the specifications to all senders and receivers. 36. The method according to claims 1, 2 and 35, characterized in that the Transmission from the headquarters to the receivers and transmitters and the Transmission between transmitters and receivers is not on the same Transmission path takes place. 37. The method according to claim 36, characterized in that the transfer path between control centers and the receivers and transmitters is a terrest path or a satellite-based path. 38. The method according to claim 36, characterized in that the transfer path between one transmitter and one receiver or more Recipients of the Internet. 39. The method according to claims 1 and 2, characterized in that the Location (location point) of a transmitter in the global location using a GPS receiver is determined. 40. The method according to claims 2, characterized in that the identi point of a sender is related to the IP address. 41. The method according to claims 1 and 2, characterized in that the Reference spaces are levels. 42. The method according to claims 1 and 8, characterized in that the globa len rooms are identical.   43. The method according to claims 1 and 8, characterized in that the global spaces take shape and / or location and / or orientation divorce. 44. The method according to claim 1, characterized in that the Sen send information and specifications sent to recipients are encrypted and / or broadcast at various non-public times become. 45. The method according to claims 8 and 10, characterized in that the Location and / or identity space has a clear location to the GPS space, so that between every location in the GPS space and every location in the A unique figure exists. 46. The method according to claims 8 and 10, characterized in that the Location and / or identity space is identical to the GPS space. 47. Arrangement for tamper-proof, unambiguous localization and identification of a transmitter, the transmitter sending one or more messages via a transmission medium to one or more receivers, the coordinates of a location being determined using GPS, characterized in that

• - That a center 13 simultaneously via a first transmission path 12 to all transmitters 14 i and receivers 15 j, which are connected to one another via a second transmission path 16 , random specifications about at least one location and / or at least one identity space and / or at least sends a reference space and / or at least one reference level at due times,
• that each transmitter is assigned at least one unique point, the so-called localization point, in at least one location and at least one unique point, the so-called identity point, in at least one identity space,
• that the transmitter determines the position of the rooms and levels relative to one another and / or in relation to the GPS coordinate space and / or the properties of the rooms and / or levels from the specifications of the control centers,
• - That the transmitter determines before sending a message via the second transmission path for at least one identity point assigned to it the identity positions with respect to at least one reference space and / or reference level and for at least one location point assigned to it the localization positions with respect to at least one reference space and / or reference plane determined,
• that the sender determines relative sender location-dependent information in relation to the identity locations and location locations, which he inserts in at least one message as additional unmarked data,
• - that the receiver determines the position of the rooms and levels relative to one another and / or in relation to the GPS coordinate space and / or the properties of the rooms and / or levels from the specifications of the control centers,
• that the recipient selects the relative information dependent on the transmitter position from the messages received via the second transmission path,
• - that the recipient determines the identity and localization from the relative information depending on the sender location and from the knowledge of the rooms and / or levels,
• - that the recipient determines the identity point or the identity points and the localization point or the localization points of the transmitter from the identity locations and localization algae,
• - That the receiver identifies the transmitter based on its determination of the unique identity point on the transmitter side and locates the location of the transmitter based on its determination of the unique localization point.

48. Arrangement according to claim 47, characterized in that the transmitter from at least

• - a GPS receiver module ( 14 i4),
• - a decryption module ( 14 i5),
• - a telegram receiving unit ( 14 i6),
• - a module for determining all rooms and levels ( 14 i7),
• - a module for determining at least one localization point ( 14 i8),
• - a module for determining at least one identity point ( 14 i9),
• - a module for determining at least one localization position ( 14 i10),
• - a module for determining at least one identity position ( 14 i11),
• - a module for determining the relative information about these dependent localization locations ( 14 i12),
• - a module for determining the relative information about these dependent identity situations ( 14 i13),
• - A module for integrating the relative information dependent on the transmitter position in a message ( 14 i14) and
• - a telegram transmitter ( 14 i15)
  consists.

49. Arrangement according to claim 48, characterized in

• - That the output of the GPS module ( 14 i4) is connected to a first input of the module ( 14 i7) and to a first input of the module ( 14 i8),
• - That a first output of the decryption module ( 14 i5) is connected to the second input of the module ( 14 i7) and a second output is connected to a first input of the module ( 14 i14),
• - That the input of the telegram receiving unit ( 14 i6) is connected to a data processing unit,
• - that a first output of the telegram receiving unit ( 14 i6) is connected to a first input of the module ( 14 i9) and the second output of ( 14 i6) is connected to a second input of the module ( 14 i14),
• - that a first output of the module ( 14 i7) is connected to the respective second inputs of the modules ( 14 i8) and ( 14 i9),
• - That the second output of the module ( 14 i7) is connected to a first input of the modules ( 14 i10), ( 14 i1), ( 14 i12) and ( 14 i13),
• - that the output of the module ( 14 i8) is connected to the second input of the module ( 14 i10) and its output is connected to the second input of the module ( 14 i12),
• the output of the module ( 14 i9) is connected to the second input of the module ( 14 i11) and its output is connected to the second input of the module ( 14 i13),
• - that the output of the module ( 14 i13) is connected to the third input of the module ( 14 i14) and the output of the module ( 14 i12) to the fourth input of the module ( 14 i14),
• - That the output of the module ( 14 i14) with the input of the telegram transmitter ( 14 i15) and its output is connected to the transmission medium 16 .

50. Arrangement according to claim 47, characterized in that the receiver consists of at least

• - a GPS receiver module ( 15 i4),
• - a decryption module ( 15 i5),
• - a telegram transmission unit ( 15 i6)
• - a module for determining all rooms and levels ( 15 i7),
• - a module for determining at least one localization point ( 15 i8),
• - a module for determining at least one identity point ( 15 i9),
• - a module for determining at least one localization position ( 15 i10),
• - a module for determining at least one identity position ( 15 i11),
• - a module for locating the transmitter ( 15 i12),
• - a module for identifying the transmitter ( 15 i13),
• - a module for the selection of the relative sender position-dependent information ( 15 i14),
• - a telegram receiver ( 15 i15),
• - a communication recorder ( 15 i16),
• - A module for determining an activation signal ( 15 i17) and
• - There is an identity memory 15 i18.

51. Arrangement according to claim 50, characterized in

• - That the output of the GPS module ( 15 i4) is connected to a first input of the module ( 15 i7),
• - That a first output of the decryption module ( 15 i5) is connected to the second input of the module ( 15 i7) and the second output is connected to a first input of the module ( 15 i14),
• - That the input of the telegram receiver ( 15 i15) is connected to the transmission medium 16 and the output is connected to the second input of the module ( 15 i14),
• - that a first output of the module ( 15 i7) is connected to a first input of the module ( 15 i10) and the second output is connected to a first input of the module ( 15 i11),
• - that a first output of the module ( 15 i14) is connected to the second input of the module ( 15 i10) and the second output is connected to the second input of the module ( 15 i11),
• - That the third output of the module ( 15 i7) is connected to the respective first inputs of the modules ( 15 i8) and ( 15 i9),
• - That the output of the module ( 15 i10) is connected to the second input of the module ( 15 i8) and the output of the module ( 15 i11) to the second input of the module ( 15 i9),
• - That the output of the module ( 15 i8) with the input of the module ( 15 i12), the output of which is connected to a first input of the communication recorder ( 15 i16) and the module ( 15 i17),
• - That the output of the module ( 15 i9) with the input of the module ( 15 i13), the first output with the second input of the communication recorder ( 15 i16) and the module ( 15 i17) and the second output with the input of the identity memory ( 15 i18) is interconnected,
• - that the output of ( 15 i18) is connected to the third input of the module ( 15 i17),
• - That the output of the module ( 15 i17) is connected to a first input of the telegram transmission unit ( 15 i6) and the third output of the module ( 15 i14) to the second input of the telegram transmission unit ( 15 i6),
• - That the output of the telegram transmission unit ( 15 i6) is connected to a data processing unit.

52. Arrangement according to claims 48 and 50, characterized in that the GPS reception modules ( 14 i4), ( 15 i4) and the decryption modules ( 14 i5), ( 15 i5) are identical. 53. Arrangement according to claim 50, characterized in that the communication tion recorder, the identity, the location of the sender, date and time not ma nipulatable stores. 54. Arrangement according to claim 50, characterized in that the module ( 15 i17) activates the activation signal when the identity and / or the location of the transmitter is established or the identity corresponds to an identity stored in the data unit ( 15 i18). 55. Arrangement according to claims 50 and 54, characterized in that the module ( 15 i6) sends the received message only when the activation signal is active at the output. 56. Arrangement according to claim 50, characterized in that the decryption module ( 15 i5) notifies the module ( 15 i14) of the locations and / or the type of the transmitter-dependent information in the received telegram. 57. Arrangement according to claim 50, characterized in

• - that the decryption module ( 15 i5) sends the module ( 15 i7) the specifications for all rooms and levels,
• - that the GPS module ( 15 i4) sends the GPS coordinates to the module ( 15 i7),
• - that the module ( 15 i7) determines all rooms and levels from the specifications and GPS coordinates,
• - that the module ( 15 i7) sends the determined location spaces, reference spaces and / or reference levels to the module ( 15 i10) and the determined identity spaces, reference spaces and / or reference levels to the module ( 15 i11),
• - That the module ( 15 i14) selects the sender location-dependent information from the receive telegram, determines the relative sender information on the identity locations and localization locations, the relative sen derseiten information on the identity locations of the module ( 15 i11) and the relative sender information on the location locations Module ( 15 i10) and the message of the received telegram to the telegram transmission unit ( 15 i6) transmitted,
• - That the module ( 15 i10) determines the localization positions and then sends them to the module ( 15 i8), which thus determines the localization point or the localization points,
• - that the module ( 15 i11) determines the identity positions and then sends them to the module ( 15 i9), which thus determines the identity point or the identity points,
• - that the module ( 15 i12) clearly locates the transmitter on the basis of the localization point or the localization points,
• - That the module ( 15 i13) clearly determines the identity of the transmitter on the basis of the identity point or the identity points, that the module ( 15 i12) the location of the transmitter and the module ( 15 i13) the identity of the transmitter to the communication recorder ( 15 i16) and sends to the module ( 15 i17),
• - That the module 15 i17 forms the release signal only if the identity of the transmitter is established and / or the transmitter is located and / or the identity corresponds to an identity stored in the data unit 15 i18.

58. Arrangement according to claim 48, characterized in that the decryption module ( 14 i5) informs the module ( 14 i14) of the locations for the transmission of the information dependent on the transmitter position in the transmission telegram. 59. Arrangement according to claim 48, characterized in that

• - that the decryption module ( 14 i5) sends the module ( 14 i7) the specifications for all rooms and levels,
• - that the GPS module ( 14 i4) sends the GPS coordinates to the modules ( 14 i7) and ( 14 i8),
• - That the module ( 14 i7) determines all rooms and levels from the transmission data of the modules ( 14 i4) and ( 14 i5) and the location spaces to the module ( 14 i8), the identity spaces to the module ( 14 i9), the reference spaces and / or reference levels to the modules ( 14 i10), ( 14 i11), ( 14 i12) and ( 14 i13),
• - that the module ( 14 i8) determines the localization point or the localization points, the module ( 14 i9) determines the identity point or the identity points,
• - that the module ( 14 i10) determines the localization reference point or the localization reference points and / or localization locations from the input information,
• - that the module ( 14 i11) determines the identity reference point or the identity reference points and / or identity positions from the input information,
• - that the module ( 14 i12) determines the relative information about the transmitter-dependent localization positions from the input information,
• - that the module ( 14 i13) determines the relative information about the transmitter-dependent identity positions from the input information,
• - That the module ( 14 i14) integrates the relative information about the localization and identity locations as sender location-dependent information in at least one message, with the locations of the program being specified in the transmission telegram via the decryption module by a central unit.

60. Arrangement according to claims 48 and 50, characterized in that the decryption modules ( 14 i5) and ( 15 i5) receive data from the control center. 61. Arrangement according to claim 60, characterized in that the data

• - decryption information and / or decryption tables and / or
• - Encrypted specifications about the rooms and / or levels and / or the locations of the information dependent on the transmitter position in the transmission telegrams and reception telegrams.

62. Arrangement according to claims 47, 48 and 50, characterized in that that the sender and / or receiver are separate devices that are between a computer and the transmission path are switched.   63. Arrangement according to claims 47, 48 and 50, characterized in that that the transmitter and receiver are modules for computers.