EP3509926A1 - Mobile radio device - Google Patents

Abstract

The invention relates, inter alia, to a mobile radio device (10) for a vehicle, in particular a rail vehicle (800), having at least a first and a second transceiver (100, 200) each having a transmitting module (SM) and a receiving module (EM). The invention provides for the mobile radio device (10) to have one or more transmitting antennas (120, 220, 320) for transmission and to have one or more receiving antennas for reception, wherein the receiving antenna(s) connected to the receiving modules (EM) of the first and second transceivers (100, 200) are separated from the transmitting modules (SM) of the first and second transceivers (100, 200), and wherein the transmitting antenna(s) (120, 220) connected to the transmitting modules (SM) of the first and second transceivers (100, 200) are separated from the receiving modules (EM) of the first and second transceivers (100, 200).

Description

description

The invention relates to a mobile radio device for a vehicle, in particular a rail vehicle, with at least one first and one second transceiver, each having a transmission module and a reception module. Rail vehicles (Euro ^¬ pean Train Control System) -Mobilfunksystem are equipped with a standardized ETCS and operated in accordance with ETCS Level 2 or 3, using it to communicate with the competent streckenseiti- gen headquarters and control center (fachsprachlich RBC - Radio block Center) the digital mobile network GSM-R (R - Railway). In order to ensure seamless train protection, the mobile radio devices - also referred to as OBUs (OBUs - on board unit) - are usually each equipped with three GSM-R transceivers (transmitting and receiving units). Two of the transceiver are used to allow during a transition from the respectively currently responsible centralized track control station to the next responsible centralized track control two parallel ^¬ mobile radio links, namely both to previous radio block center and a centralized track control station for subsequent. A third transceiver allows voice communication between the driver and the dispatcher.

The invention is based on the object, to admit a Mobilfunkein- device for a vehicle, in particular rail vehicle at ^¬ which enables a particularly secure and reliable transmission and reception operation.

This object is achieved by a mobile radio device with the features according to claim 1.

Advantageous embodiments of the mobile radio device according to the invention are specified in subclaims. According to the invention, it is provided according to the invention that the mobile radio device has one or more transmitting antennas for transmitting and one or more receiving antennas for receiving, wherein the receiving antenna or receiving antennas, which are in communication with the receiving modules of the first and second transceivers, are transmitted by the transmitting modules of the first and second transceivers second transceivers are separated, and wherein the transmission antenna or transmission antennas, which are in communication with the transmission modules of the first and second transceivers, are separated from the reception modules of the first and second transceivers.

A significant advantage of the mobile radio device according to the invention is the fact that the transmitting and ^{Empfangspfa ¬} de are each separated from each other in each of the transceivers, so that a feedback of own transmission signals in eige ^¬ ne reception paths is relatively low. Faults are thus avoided and it is a safe or reliable transmission and reception operation allows. In a preferred embodiment of the mobile radio device is provided that that a first transmission antenna, which eventually is ver ^¬ prevented from ^¬ to the transmission module of the first transceiver and a second transmit antenna, which is arranged spaced from the first transmitting antenna and exclusively to the transmission module of the second Transceivers is connected. In addition, the mobile radio device preferably comprises at least one shared Empfangsan ^¬ antenna, hereinafter referred to as community receiving antenna, which communicates with both the receiving module of the first transceiver and with the receiving module of the second transceiver. In this embodiment, the number of antennas despite maintaining the separation transmission and reception paths is advantageously low. The community receiving antenna is preferably connected via an antenna connection line to a signal input of a signal conditioning unit, the output side with the receiving modules of the first and second transceiver is in communication.

The signal conditioning unit preferably has an amplifier, in particular a linear amplifier. The amplifier is used for signal amplification, so that the occurring signal path attenuation - based on the strength of the receiving signal arriving at the receiving modules - can be reduced or even completely compensated.

The amplifier is - seen in the signal flow direction of the community receiving antenna in the direction of the transceiver - preferably a filter, in particular a bandpass filter or band-stop filter upstream. Such a filter can interference signals outside the frequency range of the useful signal dämp ^¬ fen and prevent clipping of the downstream amplifier.

It is also advantageous for the signal conditioning unit to have a filter downstream of the amplifier, as seen in the signal flow direction, in particular a bandpass filter or a bandstop filter. Such a subordinate filter can advantageously eliminate interference frequencies that are generated, for example, by non-linearities of the amplifier.

The amplifier upstream of the filter and the amplifier downstream of the filter are preferably identical or at least in terms of the frequency band whose frequencies pass or block the two band passes equal.

In addition, it is considered advantageous when a signal output of the signal processing unit is connected to a signal input of a distribution unit via a Zvi ^¬'s line on the output side via a first

Transceiver own or transceiver individually associated receive line with the receiving module of the first transceiver and a second transceiver own or Transceiver individually associated receive line is connected to the receiving module of the second transceiver.

The intermediate line is preferably longer than the

transceiver own receive lines and the antenna connection line. It is particularly advantageous if the intermediate line at least 5 times, particularly preferably Minim ^¬ least 10 times, as long as the first and second

transceiver own receive line and / or at least 5 times, more preferably at least 10 times, as long as the Antennenanschlusssleitung is.

The transmission module of the first transceiver is preferably finally called from ^¬ via a connecting cable, first below a connection cable, - ie in particular without intermediate ^¬ switched bandpass - attached Schlos ^¬ sen to the first transmitting antenna, so that the transmission signal of the first transceiver single ^¬ Lich of by the transmission characteristics first connection cable is affected.

In a corresponding manner, it is considered advantageous if the transmission module of the second transceiver is connected exclusively via a second connection cable to the second transmission antenna - ie in particular without zwischengeschalte- bandpass - and the transmission signal of the second transceiver is only influenced by the transmission characteristics of the second connection cable ,

With a view to use in the field of railway technology, it is considered advantageous if the mobile device has a third transmitting antenna, which is connected via a third connecting cable with a transmission module of a third Transcei ^¬ vers, and the community receiving antenna to ^¬ additional with a receiving module of the third Transceivers communicates.

The receiving module of the third transceiver is preferably via a third transceiver own or Transceiverindividually assigned line to a distributor ^¬ unit, in particular the above-mentioned distribution unit, on ^¬ closed. The intermediate pipe is preferably at least 5 times, particular ^¬ DERS preferably at least 10 times, as long as the third transceiver own line.

The transmission module of the third transceiver is preferably exclusively connected to the third transmission antenna via a connection cable, referred to below as the third connection ^cable , so that the transmission signal of the third transceiver is only influenced by the transmission characteristics of the third connection cable.

The distance between the third transmitting antenna and the first or second transmitting antenna is preferably at least 10 times as large as the distance between the first and second transmitting antennas.

The distance between each of the transmitting antennas and the common receiving antenna is preferably at least 10 times the distance between the first and second transmitting antennas.

The receiving module of the third transceiver is preferably switchable from a first operating mode to a second operating mode and vice versa, wherein the receiving module in the first operating mode is preferably connected to the distributor unit and thus to the common receiving antenna and receives received signals from the common receiving antenna and wherein the receiving module in the second operating mode preferred is connected to the third transmitting antenna and receiving signals from the third transmitting antenna.

The invention also relates to a vehicle, in particular ^¬ special rail vehicle. According to the invention, it is provided that the vehicle is equipped with a mobile radio device as described above.

The invention will be explained in more detail with reference to exemplary embodiments; thereby show by way of example

1 shows a first embodiment of an OF INVENTION ^¬ dung modern mobile radio device, which is received at a vehicle, especially rail vehicle may be, wherein the mobile device comprises according to figure 1, a single community reception ^¬ antenna, a second embodiment of an OF INVENTION ^¬ dung modern mobile radio device, wherein the Emp catch path has two community receiving antennas, a third embodiment of a erfin ^¬ tion contemporary mobile device in which a Emp pangsmodul one of the transceiver is switchable and is selectively connectable to a community receiving antenna for receiving received signals or with an individually assigned transmitting antenna for receiving received signals, a fourth exemplary embodiment of a dung oF INVENTION ^¬ modern mobile radio device, in which a signal conditioning unit with band-stop filter is provided instead of bandpass filters, and

Figure 5 shows an embodiment of a rail vehicle, which is equipped with the mobile radio device according to Figure 3.

For the sake of clarity, the same reference numbers are always used in the figures for identical or comparable components. FIG. 1 shows a mobile radio device 10 which is equipped with a first transceiver 100, a second transceiver 200 and a third transceiver 300. Each of the three transceivers 100, 200 and 300 has in each case a reception ^¬ module EM and a transmission module SM.

The first transceiver 100 is connected via a transceiver-own or transceiver-individually assigned connection cable 110, referred to below as the first connection cable 110, to a first transmission antenna 120, which is exclusively connected to the transmission module SM of the first transceiver 100. The transmission module SM of the second transceiver 200 is in ent ^¬ speaking manner via a transceivereigenes or

Transceiver individually associated second connecting cable 210 connected to a second transmitting antenna 220, which is ^¬ finally with the second transceiver 200 in combination.

The transmission module SM of the third transceiver 300 is connected to a third transmission antenna 320 via a third transceiver-own or transceiver- ^{individually assigned} connection cable 310.

The spacing of the three transmitter antennas 120, 220 and 320 may be re ^¬ tively small and for example less than 1 m Betra ^¬ gen.

The receiving modules EM of the three transceivers 100, 200 and 300 are connected to a distribution unit 400 via a first transceiver own receiving line 150, a second transceiver own receiving line 250 and a third transceiver own receiving line 350. A signal input 401 of the distribution unit 400 communicates with a common receiving antenna 500 via an intermediate line 700. In FIG. 1 it can be seen that a signal conditioning unit 600 is connected between the distributor unit 400 and the common receiver antenna 500. A signal input 601 of the signal conditioning unit 600 is connected via an antenna connection line 510 to the common ^reception antenna 500. A signal output 602 of the signal conditioning unit 600 is connected via the intermediate line 700 to the signal input 401 of the distributor unit 400. The signal conditioning unit 600 has on the input side a bandpass filter 610, which is arranged upstream of an amplifier 620. Downstream of the amplifier 620 is a bandpass filter 630 which is connected to the signal output 602 of the signal conditioning unit 600.

The band pass filter 610 upstream of the amplifier 620 is preferably dimensioned such that it allows only the frequency range of a received signal E to be received by the common receive antenna 500 to pass for the receive modules EM of the three

Transceiver 100, 200 and 300 is relevant or user data ent ^¬ holds. If the mobile radio device 10 is a device which is intended for use in the rail vehicle sector and should accordingly operate, for example, according to the GSM-R standard, it is considered advantageous if the bandpass filter 610 exclusively uses the frequency band of the GSM-R channel. Pass range and frequencies of adjacent frequency bands, in particular the adjacent frequency band E-GSM, the best possible attenuates or blocks.

By filtering the received signal E by the amplifier 620 arranged upstream of the bandpass filter 610 is sicherge ^¬ assumed that the amplifier 620 due to noise in other frequency bands, in particular an interference signal in the E-GSM area, is not overloaded.

The amplifier 620 is preferably a low-noise amplifier with high linearity. The function of the bandpass filter 630 arranged downstream of the amplifier 620 is to filter out any interference frequencies generated in the context of amplification by the amplifier 620, which can be caused by non-linearities of the amplifier, for example in the context of a frequency mixing, from the amplified received signal and output signals. side to output an amplified and filtered received signal Efv, which has the highest possible signal amplitude in the entire relevant Emp ^¬ catching frequency range by amplifying the amplifier 620 and is free of interference frequencies outside this receiving frequency range as possible.

With respect to the arrangement of the components, it is considered advantageous if the community receiving antenna is as far as possible from the transmit antennas 120, 220 and 320 ent ^¬ removed 500 to an irradiation of transmission signals of the transmitting modules SM of the three transceivers 100, 200 and 300 in the Be ^¬ rich the Community ^receiving antenna 500 to avoid.

With respect to the arrangement of the signal processing unit 600 and the distribution unit 400, it is advantageous angese ^¬ hen, when the signal processing unit 600 is arranged as close as possible to the community receiving antenna 500 and the distribution unit is as near as possible 400 in the area of three transceivers 100, 200 and 300th In other wor ^¬ th it is therefore considered to be advantageous if the length of the intermediate line 700 as long as possible and the length of the antenna terminal line 510 and the contrast is as short as possible the transceiver's receiving lines 150, 250 and 350th It is particularly advantageous, for example, if the antenna connection line 510 and the transceiver's own reception lines 150, 250 and 350 do not exceed a cable length of 1 m or at least not significantly; the intermediate line 700 serves to bridge the distance between the common ^reception antenna 500 or the signal ^{processing unit} 600 on the one hand and the three transceivers 100, 200 and 300 or the distributor unit 400 on the other hand. The mobile device 10 according to Figure 1 can be operated, for example, as follows: With the community receiving antenna 500 is a reception ^¬ signal E, which may be for example a GSM-R reception signal received. The received signal E is processed by the signal conditioning unit 600, in particular ^¬ filtered and amplified. The amplified and hardware filters shouldered Efv reception signal passes through the intermediate conduit 700 to the distribution unit 400, which divides the received signal ver ^¬ Efv to the receiving module EM of the three transceivers 100, 200, and 30th The receiving modules EM of the three transceivers 100, 200 and 300 can thus each evaluate the received signal Efv.

The transmitter module SM of the three transceivers 100, 200 and 300 sen ^¬ their transmission signals respectively via the transceiver individually assigned to transmit antennas 120, 220 and 320 from where the relatively large distance from the receiving antenna Community

500 a feedback on the receive path is largely verhin ^¬ changed.

The distance between the common receiving antenna 500 and the three transmitting antennas 120, 220 and 320 is preferably at least 5 m. The distance between the transmitting antennas 120, 220 and 320, on the other hand, can be relatively small, for example less than 1 m. FIG. 2 shows a further exemplary embodiment of a mobile radio device 10. In the exemplary embodiment according to FIG. 2, there are two common receiving antennas 500 and 501 which are each coupled to the signal input 601 of the signal conditioning unit 600. By providing two or more receiving antennas Community, it is possible to feed the received signal E with the largest possible signal ^¬ amplitude in the signal processing unit 600th Incidentally, the above statements in connection with the mobile radio device 10 according to Figure 1 apply accordingly.

3 shows a third embodiment of a mobile radio device 10. In the embodiment according to

3, the receiving module EM of the third transceiver 300 is connected to both the common receiving antenna 500 and the third transmitting antenna 320. The receiving module EM of the third transceiver 300 is, in the embodiment according to Figure 3 internally switched over so that the Emp ^¬ grabber module EM to receive the received signal E may optionally use the third transmit antenna 320, the community receiving antenna 500, or alternatively. Switching the Empfangsbe ^¬ drive from the community receiving antenna 500 to the third transmission antenna 320, the third transceiver 300 in ^{¬ make} example, if there is a disturbance of the signal ^{processing unit ¬} 600 or the distribution unit 400 and consequently no received signal E from the community receiving antenna 500 is to be received or another frequency band is to be received, which is blocked by the signal ^{processing unit ¬} 600.

It can also be seen in FIG. 3 that the third transmitting antenna 320 has as large a distance as possible from both the first transmitting antenna 120 and the second transmitting antenna 220 and from the common receiving antenna 500. Such a large spacing is therefore advantageous ^¬ way in particular, to avoid interference from transmission signals of the first transmission antenna 120 and the second transmit antenna 220 in the receiving module EM of the third transceiver 300 when the reception module of the third transceiver 300 as a receiving transformants ^¬ ne Transmitter antenna 320 uses.

FIG. 4 shows a fourth exemplary embodiment of a mobile radio device 10 according to the invention. In the exemplary embodiment according to FIG. 4, the signal conditioning unit 600 has an upstream of the amplifier 620 Band-stop filter 611 and a band-stop filter 631 downstream of the amplifier 620.

The two band-stop filters 611 and 631 are preferably dimensioned such that they suppress interference frequencies of known adjacent frequency bands. If the mobile radio device 10 is operated in the area of the GSM-R band, because it is to be used in the field of rail vehicle technology, then it is advantageous if, for example, the frequency band of the E-GSM mobile radio system by the two

Band-stop filter 611 and 631 is suppressed.

5 shows an exemplary embodiment of a rail vehicle ^¬ 800, which is equipped with the mobile radio device 10 in accordance with FIG. 3 It can be seen that the third transmission antenna 320 has as large a distance as possible from the first transmission antenna 120 and the second transmission antenna 220 as well as from the common ^reception antenna 500. For the rest, reference is made to the statements in connection with FIG.

Although the invention in detail by preferred execution ^¬ examples has been illustrated and described in detail, the invention is not limited by the disclosed examples and other variations can be derived therefrom by the skilled artisan without departing from the scope of the invention.

Reference sign list

10 mobile radio device

 100 transceivers

110 connection cable

 120 transmitting antenna

 150 receiving line

 200 transceivers

 210 connection cable

220 transmitting antenna

 250 receiving line

 300 transceivers

 310 connection cable

 320 transmitting antenna

350 receiving line

 400 distributor unit

 401 signal input

 500 communal antenna

501 Community antenna 510 Antenna connection cable

600 signal conditioning unit

601 signal input

 602 signal output

610 bandpass filter

611 band-stop filter

 620 amplifiers

 630 bandpass filter

 631 band-stop filter

700 intermediate line

800 rail vehicle

E received signal

 Efv received signal

 E-GSM frequency band

EM reception module

 SM transmitter module

Claims

claims

A mobile radio device (10) for a vehicle, in particular a rail vehicle (800), having at least a first and a second transceiver (100, 200) each having a transmission module (SM) and a reception module (EM),

d a d u r c h e c e n c i n e s that

 - the mobile radio device (10) for transmitting one or more transmitting antennas (120, 220, 320) and for receiving one or more receiving antennas,

 - The receiving antenna or receiving antennas, which are in communication with the receiving modules (EM) of the first and second transceiver (100, 200), from the transmission modules (SM) of the first and second transceivers (100, 200) are separated and

 - The transmit antenna or transmit antennas (120, 220), which are in communication with the transmission modules (SM) of the first and second transceivers (100, 200), separated from the receiving modules (EM) of the first and second transceivers (100, 200) are.

2. Mobile radio device (10) according to claim 1,

d a d u r c h e c e n c i n e s that

 - The mobile radio device (10) has a first transmitting antenna

(120), which is exclusively with the transmission module (SM) of the f th ^¬ transceiver (100), and a second Sen ^¬ dean antenna (220) of the first transmission antenna

is arranged spaced apart and exclusively with the Sen ^¬ demodul (SM) of the second transceiver (200) is connected, and

- The mobile radio device (10) at least one shared receiving antenna, hereinafter called community ^¬ receive receiving antenna (500, 501), comprising both the receiving module (EM) of the first transceiver (100) and with the receiving module (EM) of the second

Transceivers (200) communicates.

3. Mobile radio device (10) according to claim 2, characterized in that

the Community receiving antenna (500, 501) via a

Antenna Anschlußssleitung (510) to a signal input (601) of a signal conditioning unit (600) is connected, the output side with the receiving modules (EM) of the first and second transceivers (100, 200) is in communication.

4. Mobile radio device (10) according to claim 3,

d a d u r c h e c e n c i n e s that

the signal processing unit (600) comprises an amplifier, in particular ^¬ sondere a linear amplifier, and the amplifier - as viewed in the signal flow direction of the joint receiving antenna (500, 501) in the direction of the transceiver (100, 200) - is arranged upstream of the filter, particularly a band pass filter (610) or band-stop filter (611).

5. Mobile radio device (10) according to claim 4,

d a d u r c h e c e n c i n e s that

the signal conditioning unit (600) a the amplifier (620) - as seen in the signal flow direction - downstream filter, in particular a bandpass filter (630) or a

Band-stop filter (631).

6. Mobile radio device (10) according to claim 5,

d a d u r c h e c e n c i n e s that

that the amplifier (620) upstream filter and the Ver ^¬ stronger (620) downstream filter identical or at least in terms of the frequency band whose frequencies pass or block the two band passes are the same.

7. Mobile radio device (10) according to one of the preceding claims 3 to 6,

d a d u r c h e c e n c i n e s that

a signal output of the signal conditioning unit (600) via an intermediate line (700) to a signal input (401) of a distribution unit (400) is connected to the output side via a first transceiver own or transceiver individually associated receiving line (150) with the receiving module (EM) of the first transceiver (100) and via a second transceiver own or transceiver individually associated receiving line (250) to the receiving module (EM) of the second transceiver (200) is connected.

8. Mobile radio device (10) according to claim 7,

d a d u r c h e c e n c i n e s that

the intermediate line (700) longer than the transceiver own receiving lines (150, 250, 350) and the

Antenna connection line (510),

 - wherein the intermediate line (700) is preferably at least 5 times, more preferably at least 10 times as long as the first and the second transceiver own receiving line (150, 250) and / or

- wherein the intermediate line (700) is preferably at least 5 times, more preferably at least 10 times, as long as the Antennenanschlusssleitung (510).

9. Mobile radio device (10) according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

- the transmission module (SM) of the first transceiver (100) from finally ^¬ called via a connecting cable (110), first below connecting cable (110), - ie in particular without an intermediate band-pass - to the first transmitting antenna (210) is connected and the transmission signal of the ers ^¬ th transceiver (100) is influenced only by the Übertragungsei ^¬ properties of the first connecting cable (110) and

- The transmission module (SM) of the second transceiver (200) from ^¬ finally via a second connecting cable (210) to the second transmitting antenna (220) is connected - ie in particular ^¬ special without intermediate bandpass - and the Sen ^¬ designal of the second transceiver (200 ) is influenced only by the transmission characteristics of the second connection cable (210).

10. Mobile radio device (10) according to one of the preceding claims,

d a d u r c h e c e n c i n e s that

 - The mobile radio device (10) has a third transmitting antenna

 (320), which has a third connection cable

(310) is connected to a transmit module (SM) of a third transceiver (300), and

 - The community receiving antenna (500, 501) in addition to a receiving module (EM) of the third transceiver (300) is in communication.

11. Mobile radio device (10) according to claim 10,

d a d u r c h e c e n c i n e s that

the receiving module (EM) is connected to the third transceiver (300) via a third transceiver own or transceiver individually ^¬ parent line (350) to a distribution unit (400), into ^¬ particular, the distribution unit (400) according to claims 7 to 9. 12. Mobile radio device (10) according to claim 11,

d a d u r c h e c e n c i n e s that

(700) the intermediate line at least 5 times, especially before Trains t ^¬ at least 10 times, as long as the third

transceiver's own line (350).

13. Mobile radio device (10) according to one of the preceding claims 10 to 12,

d a d u r c h e c e n c i n e s that

- Removing the transmission module (SM) of the third transceiver (300) finally via a connecting cable (310), called third hereinafter connecting cable (310) is connected to the third Sen ^¬ dean antenna (320) and the transmission signal of the third transceiver (300) by merely to the delegation ^¬ transfer properties of the third connecting cable (310) is influ- enced and / or

- The distance between the third transmitting antenna (320) and the first or second transmitting antenna (120, 220) at least 10 times as large as the distance between the first and the second transmitting antenna (120, 220) is and / or

 the distance between each of the transmitting antennas (120, 220, 320) and the common receiving antenna (500, 501) is at least 10 times the distance between the first and second transmitting antennas (120, 220).

14. Mobile radio device (10) according to one of the preceding claims 10 to 13,

d a d u r c h e c e n c i n e s that

the receiving module (EM) of the third transceiver (100) from ei ^¬ nem first operating mode to a second mode of operation and vice versa is switchable,

- Wherein the receiving module (EM) in the first mode of operation to the distribution unit (400) and thus to the community ^¬ receiving antenna (500, 501) is connected and received by the Community receiving antenna (500, 501) receive signals (E) and

 - In the second operating mode, the receiving module (EM) is connected to the third transmitting antenna (320) and receiving signals (E) from the third transmitting antenna (320).

15. Vehicle, in particular rail vehicle (800),

d a d u r c h e c e n c i n e s that

the vehicle is equipped with a mobile radio device (10) according to any one of the preceding claims.