NL8501021A - TRANSMISSION DEVICE IN A TACTICAL RADIO SYSTEM. - Google Patents

Description

Transmission device in a tactical radio system.

The invention relates to a transmission device for transmitting a radio subscriber in a wire-bound dialing network, comprising a connecting device, radio means (VG) containing transmitters, frequency transmitters and / or receivers, the transmitters being connected to an antenna via a transmitter coupling network are connected, and of controllers for the radio means connected between the connecting device and the radio means, in which frequency addresses required for the frequency hopping method are stored in a frequency range, and in which the data flows between separate subscriber terminals of the connecting device and control the radio resources.

Transmission devices of this kind are of particular importance for practical radio systems. Practical radio systems build on cable and beam transmitter logistics. By means of the transfer device, also called radio concentrator or radio access point (RAP), mobile radio subscribers of an area encompassed by the transfer device are connected to a supraregional wired network. In addition to voice and text information, data (data) are also eligible for the transfer.

In addition to good transmission properties, tactical radio systems have high confidentiality and interference resistance requirements. For this reason, the so-called frequency hopping method is used in the transmission of the information. The frequency hopping method is described in detail in the book "Principle of Military Communication Systems" by Don J. Torrieri, 1981, Artech House.

Such a frequency hopping method is all the more resistant to interference the greater the available frequency range, that is, the greater the number of available carrier frequencies. Each transmitter of the radio means is capable of delivering one of the carrier frequencies located in this frequency range.

In transmission mode of the transmission device, a loss of the transmission power of three dB occurs in the connection network consisting of 3dB coupling members per coupling member. For example, if eight or more transmitters are linked via the connection network, half the transmission power and more in the connection network is lost.

The object of the invention is to indicate a transfer device in which this drawback is avoided.

In the case of a transmission device of the type mentioned in the preamble according to the invention, this is achieved in such a way that mutually delimited, non-overlapping frequency bands are added to the radio means and that a coupling field connected between the controls of the radio means and the radio means is provided, via which connections for the data flows between the controllers of the radio means and the radio means can be switched.

In an advantageous embodiment of the invention, further, i.e. first and second controls for the radio means are provided, so that only connections for the transmit-receive data are switched through the coupling field.

It is furthermore advantageous if the transmission coupling network has transmission switches and a 3dB coupling member, the transmitters of the radio means being coupled such that a frequency range is covered without intervals by the frequency bands assigned to the transmitters.

The invention will be further elucidated on the basis of an exemplary embodiment with reference to the drawings, in which:

Fig. 1 is a schematic view of a designed embodiment of a transfer device;

Fig. 2 shows the diagram of an embodiment of a transfer device according to the invention; Figures 3 and 4 show diagrams of two embodiments of a transmitter coupling network; and

Fig. 5 shows a diagram of a further embodiment of the transfer device.

Fig. 1 shows in block diagram a transmission device as already designed for a tactical radio system. The transfer device has a connecting device VE which forms the intersection with the supraregional wireline bound network. The connection device VE has, for example, four subscriber terminals TL1 to TL4. The subscriber terminals TL1 to TL4 are each connected to a radio resource controller FS1 to FS4. Transmit-receive data SED is transmitted between the subscriber terminals TL1 to TL4 and the radio control devices FS1 to FS4. The term transmit-receive data SED is understood to mean the digitized speech text information and data mentioned in the preamble.

The radio means controllers FS1 to FS4 each cooperate with one of the radio means FG1 to FG4. These each contain a transmitter S, a frequency transmitter F and a receiver E. Between the transmitters S resp. the receivers E of the radio means FG1 to FG4 and the associated controllers FS1 to FS4 of the radio means, transmission data SD and resp. reception data ED exchanged. The controls FS1 to FS4 of the radio means effect the setting of the transmitter resp. reception frequency of the transmitters S resp. receivers E of the associated radio means FG1 to FG4. The order of the output frequency addresses FA is determined in each case by a frequency key text stored in the radio control units FS1 to FS4. For synchronization, the radio resource controllers FS1 to FS4 are connected to a common clock generator TG.

The transmitters S of the radio means FG1 to FG4 are connected at the output side via a connection network equipped with three coupling stages KI to K3 to an antenna switch Axis of an antenna A. The coupling stages Kl to K3 are realized by so-called 3dB coupler channels . The transmitters S of the radio means FG1 and FG2 are on the two inputs of the coupling stage Kl, the transmitters S of the radio means FG3 and FG4 are on both inputs of the coupling stage K2, and the outputs of the coupling stages Kl and K2 are on the inputs of the coupling stage K3 are switched. The output of the coupling stage K3 is connected to the antenna switch AS, to which the antenna A is connected.

At more than the indicated radio means FG, the number of the coupling stages K, via which the transmitters S are coupled analogously to Fig. 1, increases. This also increases the power loss on the way from a transmitter S to the antenna A.

The antenna switch AS provides the selectable connection of the antenna A to the coupling stage K3 resp. with a receive distributor EV. A transceiver switching stage SE is provided for switching the antenna switch As, which is also clocked by the clock generator TG. Unspecified outputs of the receiver distributor EV are connected to the receiver E of the radio means VG1 to VG4.

In time-division multiplex operation, the antenna A is periodically connected alternately to the coupling stage K3 and the receiver distributor EV via the antenna switch AS. It is also conceivable to use a frequency change instead of the antenna switch AS in frequency multiplex operation. In frequency multiplex operation, the transmitters S and the receivers E of the radio means FG1 to FG4 are assigned separate, non-overlapping frequency ranges.

The operation of the transfer device shown in FIG. 1 is described below.

For example, if a connection is established between the subscriber terminal TS1 of the connecting device VE and an external radio subscriber, the message is transmitted in frequency hopping method. For this purpose, the radio resource controller FS1 successively issues frequency addresses FA to the frequency transmitter F of the radio resources FG1 on the basis of the predetermined frequency key text. The message resp. the data of the subscriber connection TL1 are thus modulated successively by the radio means FG1 at different carrier frequencies and radiated via the antenna A.

This applies analogously to the reverse direction of reception.

The frequency hopping method is more resistant to interference, the greater the available frequency range, that is, the greater the number of available carrier frequencies. Each transmitter S of the radio means FG1 to FG4 is capable of delivering one of the carrier frequencies located in this frequency range.

During transmission operation of the transmission device, a loss of transmission power of 3dB per coupling member occurs in the connection network consisting of 3dB coupling members. For example, if eight or more transmitters are linked via the connection network, half the transmission power and more in the connection network is lost.

This drawback is avoided in the exemplary embodiments described in the following figures.

The exemplary embodiment according to the invention shown in Fig. 2 of a transmission device with a size of the radio means according to Fig. 1 also has the connecting device VE with, for example, the four subscriber terminals TL1 to TL4, the clock transmitter TG, the antenna switch AS with the antenna A, the transmit-receive switching stage SE, the receive distributor EV, the radio means FG1 to FG4, and the radio means controllers FS1 to FS4.

In contrast to FIG. 1, the transmitters S and the radio means FG1 to FG4 are assigned mutually delimited, non-overlapping frequency bands.

Analogously to Fig. 1, transmit-receive data SED are also exchanged in the transmission device shown in Fig. 2 between the radio resource controllers FS1 to FS4 and the connecting device VE. According to the invention, however, the coupling field is connected between the radio means controllers FS1 to FS4 and the radio means FG1 to FG4. The coupling field KF is, for example, composed of building blocks 4066. The radio resource controllers FS1 to FS4 output transmitting data SD resp. receive data ED received from the terminals 11 to 41 resp. 13 to 43 of the coupling field KF. Furthermore, the radio resource controllers FS1 to FS4 output frequency addresses FA at terminals 12 to 42 and at first control inputs S11 to S14 of the coupling field KF. With a parallel transmission of the frequency addresses FA, the connections 12 to 42 are multipolar.

The transmitters S of the radio means FG1 to FG4 obtain transmission data SD from, respectively. their receivers E deliver receive data to terminals 14 to 44 and 44 respectively. 16 to 46 of the coupling field KF. The frequency transmitters F of the radio means FG1 to FG4 obtain frequency addresses FA of the terminals 15 to 45 of the coupling field KF. A control ST issues control addresses SA to second control inputs S21 to S24 of the coupling field KF.

The idea underlying the transfer device according to the invention is described below.

The frequency range required for the frequency hopping method is divided into delimited, non-overlapping frequency bands. A transmitter S of one of the radio means FG1 to FG4 is each added to the carrier frequencies of the frequency bands. The frequency range is divided into frequency bands according to the number of the radio means present, to which as many transmitters S are added. Gaps or intervals may exist between the frequency bands, but the frequency bands may also span the frequency range without intervals. By using these transmitters S, which are added to different frequency ranges, the number of the 3dB couplers can be reduced to a maximum of one, because low-frequency frequency changes can be made here for coupling the transmitters S instead of 3dB couplers.

The coupling field KF always establishes connections between the transmitter S resp. the receiver E as well as the frequency transmitter F of one of the radio means FG1 to FG4 and one of the radio means controllers FS1 to FS4 are established. This is accomplished by supplying a frequency address FA and one of the first control inputs S11 to S14 and a control address SA corresponding to this frequency address FA to one of the second control inputs S21 to S24. The control addresses SA ensure that only transmission data SD with an associated carrier frequency, which are present in the frequency band of these radio means FG, is forwarded to the associated radio means FG. The control addresses SA are fixed. A carrier frequency is determined by the frequency addresses FA issued by one of the radio resource controllers FS1 to FS4. This is, via the associated frequency transmitter F, emitted by the transmitter S from one of the radio means FG1 to FG4. The frequency addresses FA and the associated transmission data SD are forwarded through the coupling field KF to the corresponding radio means FG.

For example, the radio resource controller FS1 issues a frequency address FA, thereby determining a carrier frequency radiated by the transmitter S from the radio resource FG3. The connections 11 and 34 of the coupling field are connected on the basis of this frequency address FA and the fixed control address S.

For example, only the first two binary values of the frequency address FA are applied to one of the first control inputs S11 to S14. The coupling to the terminals is then established by the coupling field KF, to which the same binary values are applied as control address SA.

The receivers E of the radio means FG1 to FG4 are connected to the receiver divider EV as described in Fig. 1. The transmitters S of the radio means FG5 to FG8 are connected to a transmitter coupling network SK, which is connected to the antenna switch AS. The sending company has only been described above. The same applies to the receiving company.

In Fig. 3, a first transmitter coupling network SKI is indicated. It contains three transmission switches SW1 to SW3, via which the transmitters of the radio means FG5 to FG8 are known in a manner known per se and connected to the antenna switch AS. In this embodiment of the transmitter coupling network SK, the transmitters S of the radio means FG5 to FG8 cannot cover a frequency range without intervals, since the transmitter switches SW for separating two adjacent frequency bands require an unavoidable frequency separation for the filter transition.

The second transmitter coupling network SK2 shown in Fig. 4 comprises two transmitter switches SW4, SW5 and a coupling stage K4. The transmitters of the radio means FG5 and FG6 are coupled by the coupling stage K4 and connected to the antenna switch AS. In this embodiment of the transmitter coupling network SK, an interval-free coverage of the frequency range is possible if the transmitters are thus connected to the transmitter switches SW1 and SW2, respectively. in the case of more than four transmitters S, so be added to the two frequency exchange devices consisting of transmitter switches that different transmitters are assigned to transmitters S for adjacent frequency bands.

An advantageous variant compared to the exemplary embodiment of a transmission device according to Fig. 2 shows Fig. 5. Here radio means FG5 to FG8 are indicated, which are distinguished from the radio means FG1 to FG4 known from Fig. 2 by an additional fine frequency transmitter. FF. The transmission resp. reception frequency of the transmitters S resp. receivers E of the radio means FG5 to FG8 are set jointly by the frequency transmitter F and the fine frequency transmitter FF. The frequency address FA, i.e., the transmitter S, is addressed by the frequency address FA, and the carrier frequency in the frequency band is addressed by the fine frequency address FFA.

Analogous to the radio resource controllers FS1 to FS4 in FIG. 2, in FIG. 5, first radio resource controllers FS11 to FS14 are connected to the subscriber terminals TL1 to TL.4 of the connecting device VE.

The coupling field KF shown in Fig. 5 differs from the field shown in Fig. 2 by a smaller number of connectable connections. The frequency address FA is no longer forwarded to radio means FG1 to FG4.

Second radio means controllers FS21 to FS24 are provided on the opposite side of the coupling field KF, each of which receives transmission data SD from the coupling field KF and carries it on to the transmitters S of the radio means FG4 to FG8, respectively. receive receive data ED from the receivers of the radio means FG5 to FG8 and continue feeding them to the coupling field KF. The transmission data SD

terminals 14 to 44 can be taken off and receive data ED is applied to terminals 16 to 46. The second radio resource controllers FS21 to FS24 each supply frequency addresses FA to the second control inputs S21 to S24 of the coupling field KF> and to the frequency transmitter F of the radio resources FG5 to FG8. Furthermore, the second radio resource controllers FS21 to FS24 each deliver fine frequency addresses FFA to the fine frequency generator FF of the radio resources FG5 to FG8. The first and second radio control devices FS11 to FS14, FS21 to FS24 are synchronized by the clock generator TG). The frequency addresses FA resp. the fine frequency addresses FFA are obtained in the first and second radio resource controllers FS11 to FS14, FS21 to FS24 from the frequency key texts stored there.

The coupling field KF always establishes connections between one of the first radio resource controllers FS11 to FS14 and one of the second radio resource controllers FS21 to FS24. This is accomplished by the same frequency addresses FA supplied to the first and second control inputs S11 to S14, S21 to S24 of the coupling field.

1 Since four second radio resource controllers FS21 to FS24, i.e. four transmitters S of radio resources FG1 to FG4 can be controlled with four different frequency bands, the first radio resource controllers FS11 to FS14 can output four different frequency addresses FA.

For example, a connection is established between the first radio resource control FS12 and the second radio resource control FS24 when the same frequency address FA is applied to the first control input S12 and to the second control input S24 of the coupling field KF.

The receivers E of the radio means FG5 and FG8 are connected to the receiver divider EV as described in Fig. 1. The transmitters S of the radio means FG5 to FG8 are connected to a transmitter coupling network SK, which is connected to the antenna switch AS.

The transmitters S of the radio means FG5 to FG8 are fixedly set to predetermined frequency bands on the basis of the frequency addresses FA issued by the second radio means controllers FS21 to FS24 · The fine-frequency addresses FFA also issued by the second radio means controllers FS21 to FS24 enable within these frequency bands certain channels resp. carrier frequencies can be selected. If, for example, a connection has been built up between the subscriber connection TL1 of the connecting device VE and an external radio subscriber, the message is transmitted in frequency hopping method. For this purpose, the first radio resource controller FS11 successively outputs frequency addresses FA to the first control input S11 of the coupling field KF on the basis of the predetermined frequency key text. The subscriber connection TL1 is hereby connected successively to the transmitters S of the radio means FG5 to FG8, to the frequency transmitters F whose same frequency address FA is applied. The message resp. the data of the subscriber terminal TL are thus emitted one after the other by the radio means FG5 to FG8, in which they are modulated at different carrier frequencies, via the antenna A.

The connecting element between the antenna A and the radio means FG5 to FG8, the transmitter coupling network SK, respectively. SKI or SK2, in the transmission device according to the invention, is built up in the first line from low-loss coupling transmitter switches SW1 to SW5. This is possible because mutually delimited, non-overlapping frequency bands are added to the transmitters S of the radio means FG5 to FG8.

The number of the parallel radio links, i.e. of the radio means FG, is limited by the frequency occupancy, but not by the coupling field KF. The greater the number of the parallel radio links, the greater the transmission power gain of the transfer device (Figures 2-5) of the invention over the conventional transfer device (Figure 1).

Claims (5)

1. Transmission device for transmitting a radio subscriber In a corded dialing network, provided with a connecting device (VE), radio means (VG) containing transmitters (S), frequency transmitters (F) and / or receivers (E), the transmitters (S) are connected to an antenna (A) via a transmitter coupling network (SK), and radio resource controllers (FS) connected between the connecting device (VE) and the radio means (FG), which required the frequency hopping method, in a frequency addresses (FA), which control the data flows between separate subscriber terminals (TL) of the connecting device (VE) and the radio means (FG), characterized in that the radio means (FG) are mutually delimited non-overlapping frequency bands have been added that a coupling field (KF) connected between the radio resource controllers (FS) and the radio resource (FG) is provided, through which connections for the data streams between the radio resource controllers (FS) and the radio resource (FG) can be switched. Transmission device according to claim 1, characterized in that the coupling field (KF) has first and second control inputs (ST11 .·, ST21 ···) as well as connections for transmission data (SD) on the side of the radio means and of the radio means controls. ) and / or receive data (ED), whereby the terminals belonging to a first control input (ST11 ...) are connected to the terminals belonging to a second control input (ST21 ...), when the same frequency address ( FA). Transmission device according to claim 2, characterized in that further radio means controllers (FS21 ...) connected between the coupling field (KF) and the radio means (FG) are arranged, that the radio means (FG) have additional fine frequency transmitters (FF). ), where the frequency and fine frequency transducers (F, FF) together provide the transmit and / or receive frequencies, and the radio control devices (FFS11) have frequency addresses (FA) at the first control inputs (ST11 ·· ·), The further radio resource controllers (FS21) frequency addresses (FA) at the second control inputs (ST21 ...) of the coupling field (KF) and frequency addresses (FA) and fine frequency addresses (FFA) at the radio resources (FG). Transmission device according to any one of claims 1 to 3, characterized in that the transmitter coupling network (SK) has a frequency exchange device (SW) consisting of transmission switches (SW), the frequency bands required for the inevitable filter transitions being between the frequency bands added to the transmitters (S). intervals are provided. Transmission device according to any one of claims 1 to 3, characterized in that the transmitter coupling network (SK) has two frequency switch units (SW) consisting of transmitter switches (SW), which are connected to the antenna (A) at the output side via a 3dB coupling element. and that the transmitters (S) of the radio means (FG) for the interval-free coverage of the frequency range are distributed over the two frequency exchange devices such that different frequency exchange devices are added to transmitters (S) for adjacent frequency bands.