NL8104607A - INFORMATION TRANSMISSION SYSTEM CONSISTING OF NETWORKS, WHICH OPERATE A NUMBER OF CHANNELS THROUGH FREQUENCY JUMPING. - Google Patents

Description

Short designation: Information transmission system consisting of networks which exploit a number of channels by means of frequency hopping.

The invention relates to an information transmission system formed by networks which exploit a set of channels by means of frequency jumps.

The networks in question here are formed by a number of reception / broadcasting stations, which can communicate with each other. Each network exploits, one by one, the channels of the system according to a pseudo-random frequency offset rule. The offset rule of a net must remain unknown to other nets. The operating rules of the different grids must be orthogonal, i.e. a channel can only be influenced by one grid at any given time.

Such a system finds an important application in the field of military radio communications, where it is required to have certain connections that are insensitive to interference from the enemy. As an efficient means of defending against enemy interference, it has been considered to use one channel from a very large number of channels for the shortest possible time.

As an explanation of the problems encountered, a station of a particular network which is in the listening position for receiving a broadcast of a near station which apparently forms part of this particular network is considered. When an unexpected frequency jump occurs, the particular grid will exploit a new channel. This new channel is not permitted to be used as a transmit channel for a further station which is part of another just before the said frequency jump since the propagation time of the wave transmitted by this removed station may reach the listening position and interfere between the long broadcast and the broadcast from the nearby station.

The object of the invention is to eliminate these drawbacks and to that end provide such a system, characterized in that the system is divided into separate sub-systems and that each of these sub-systems is operated at every jump.

The invention is elucidated with reference to the drawing.

Fig. 1 schematically shows the geographical locations of some transmission / reception stations of a system according to the invention; Fig. 2 schematically shows the operation of used frequency channels; Fig. 5 schematically shows the time division of the power used to transmit information in a given channel; Figure 4 shows efficiency curves of a system for which the invention has not been applied; Fig. 5 shows a possible exploitation of the available channels according to the invention; Fig. 6 shows efficiency curves of a system according to the invention; FIG. 7 shows an implementation diagram of a transmit / receive station of a system according to the invention for operating the channels shown in FIG. 5; Fig. 8 shows a first example for the operation of channels grouped in subchannels; FIG. 9 is a flow chart of a transmit / receive station for operating the channels shown in FIG. 8; Fig. 10 shows a second example for the operation of channels grouped in subchannels; Fig. 11 shows a realization diagram of a transmit / receive station for operating the channels shown in Fig. 10.

Fig. 1 shows very schematically the geographical location of some stations which form part of a system according to the invention. Such a system is formed by nets R0, R1, R2, R3, R4, R5 · ..., which are formed by groups of posts. In Fig. 1, for example, the posts P1 (R0), P2 (R0), P3 (R0) and P4 (HO) belong to the network R0, which is indicated with the brackets in the figure. The figure also contains the items P1 (R2), P2 (R2), P1 (R3). Each grid uses a channel for a time At and after that time a frequency jump occurs and another channel is used for a time At. As shown in Fig. 2 for the times t1 and for a duration & tt, the stations of the network RO can only communicate with each other via the channel CH7, the stations of the network R4 via the channel CH6 and those of the network R1 via the channel CH5; then, at time t2 and during At, the stations of the network RO can communicate with each other via the channel CH5. The channels CK7 and CH0 are used during this time At only for the nets R2 bar. R5. It should be noted that for the considered area of application, this time At must be as small as possible so that little information can be used by the enemy, so that the exchange rule of the channels cannot be traced.

For a proper understanding of the invention, it will be further considered what happens when the channels change; this takes, for example, the moment t2 and the channel GH7 is considered. This moment t2 is occupied by the post P2 (R2). Bit moment is known with an accuracy of St which is determined by the clock synchronization errors of the posts. At this time t2, the stations of the network R2 thus use the channel GHJ and the stations of the network RO transition to the channel GHJ. However, due to the fact that station P1 (RO) is at a distance "d", if no action is taken, its broadcast will still be received by station P2 (R2) for a period t equal to the propagation time involved .Po is propagation of the wave from station P1 (RO) to station P2 (R2). This infringement of the use of the same channel by two networks is partly avoided by means of the waiting time T_ s present between each channel change at the level of the transmitter (see fig. 3) · When T ^ indicates the time that elapses between the transmission with maximum transmitting power P ^^ of the transmitter until the cessation of transmitting, and also for the time for regaining its power, the following relationship applies: (1) TM + Tc t + 2 6t

For a maximum range d * 375 km, we have t ί 1.25 ms, which is greater than the value T ^ + Tg «0.75 ms permitted by the technology. Thus, one is forced to increase Tg to satisfy equation (1). One can define an efficiency P which represents the percentage of time available for sending information. By specifying T ^ the length of time during which the information is effectively sent, P can be written as

It appears that this efficiency is getting worse for increasing propagation times: to compensate for this very disadvantageous time, it is also possible to discuss the accuracy gt of the clocks, however, which increases the material costs.

Fig. 4 shows the decrease in the efficiency Pais function of the errors £ t for different values T, where the curves are

P are drawn for TM + t 1.5 ms. .M pg

In order to avoid this significant reduction, it is proposed according to the invention that the set of channels be subdivided into non-coincident N subsets, using one of these subsets for each jump.

Fig. 5 shows a set of channels designated CHO through CH63, the channels forming a set of BCH. According to the invention, this system is divided, for example, into N »2 inconsistencies; SECHA and SECHB. The SECHA subset includes the channels with an even reference number, CHO, CH2 .... CH62, and the SECHB subset, those with an odd reference number, CH1, CH3, ...... CH63. For the sake of clarity, the exploitation of these channels is examined by a single network, namely the HO network. The channel CH58 forming part of the subset SECHA is then used between moments tt1 and tt2; between the moments tt2 and tt3, the channel CH27 of the subset SECHB is used and between the moments tt3 and tt4 one of the channels of the subset SECHB, the channel CH40, is used.

Next, the improvement in efficiency as a result of the measure according to the invention can now be evaluated.

In case of N, the inequality (1) is replaced by (5) TM + Ts + (H-1) (ïp + 2Tm ♦ Tg) ITK + 2 Kt

While Pte writing is like;

and by elimination of Tp, the combination of equations (3) and (4) gives i

Different efficiency curves are shown in FIG. To the right of the vertical axis, different values for Tp are indicated, where equation (4) gives the relationship between Pen Tp. These curves are drawn for t '1.25 ma T ^ »0.25 ms Tg = 0.5 me.

It is clear that p and St can be large for small values of T and N. Comparison with Fig. 4 shows the improvement of P for a given St.

Fig. 7 shows the diagram of a station of the system according to the invention. This station comprises a transceiver 1 which allows transmission over the different channels CHO to CH63 * the selection of the channel takes place by the frequency of a frequency synthesizer 2 which is controlled by a switching unit 3} this switching unit 3 is provided with input terminals FO, F1, F2, F3, F4> F5 with which a correspondence can be made between the 64 channels and the binary code fed to the input terminals and which the respective binary elements f0, f1, f2 , f3, f4 * f5, where said match in Table 1 is data

Table 1.f 5_ £ 4_ £ 2_ £ 2_ £ 1_ £ 0_Channel

0 0 0 0 0 0 CHO 0 0 0 0 0 1 CH1 0 0 0 0 1 0 CH2 0 0 0 0 1 1 CH3 1 11 110 CH62 1 11 111 CH63

Terminals F1, F2, F3 »F4» F5 are respectively connected to the outputs FS1, FS2, FS3, FS4 »FS5 of a device 10 which provides different numerical codes for the terminals £ 0, B1, B2, B3, B4 conducted different identification codes; such a device is described in detail in the French patent application 80157 of July 16, 1980 in the name of the applicant.

The identification codes are used to identify the various networks of the system. The different binary elements B0, B1, B2, B3, S4 allow the determination of 32 networks in the manner indicated in table 2 »rfabel 2, b4_bj_b2_bl_bO_net

O O O O O HO O O O O 1 R1 O O O 1 O R2 0 O O 1 1 R3 1 1 1 1 O R30 1 1 1 1 1 R-31

The device 1Q is formed by a scrambling system BRO with output terminals FS1 to FS5 and with inputs G1, G2, G3, G4 »G5 · This device can be formed by the device as described in French patent application 8015506 of 11 July 1980 in the name of the applicant. This device provides a binary word on its outputs which is the result of a permutation of any order of the binary elements fed to its inputs. For the sake of clarity, one can consider the case where the device BRO performs a permutation of the order 0, ie everything passing through the inputs G1, G2, G3, G4 and G5 is directly forwarded to the outputs FS1, FS2, FS3t, IS4 and FS5 This device 10 also comprises a number of "modular 2" adders A1, A2, A3> A4 * A5, the outputs of which are connected to the inputs G1, G2, G3, G4, G5, the first inputs of these adders A1, A2, Δ3, A4 and A5 are connected to terminals B4, B3> B2, B1, BO, respectively.

These second inputs from these adders receive arrays of pseudo random binary elements generated by a pseudo random array generator GEK; the second input of the adder A1 receives a series denoted by SQ1, the second input of the adder A2 receives a series S ^ 2, etc. The different series depend on a key selected from a large number of keys. For example, the series SQ1 depends on a key C1, the series SQ2 on a key G2, the series SQ, 3 on a key C3 * the series SQ4 on a key C4 and SQ5 on C5 · However, in order to ensure that the codes on the inputs G1, G2, G3, G4 and G5 must be orthogonal, certain keys must be common to several networks; thus the key C2 is common to the network whose binary element b4 is the same. This key C3 will be common to the network whose binary elements b4, b3 are the same; rdefze ^ key is noted as C3 (b4, b3); other keys are C4 (b2, b3, b4) and C5 (b1, b2, b3, b4). The different codes are applied to the terminals FS1 to FS5 of the device 10 in the rhythm 1/41 of a clock 20. For example, a circuit 25 formed by a simple flip circuit provides a row of binary elements with an alternating value of 0, 1, 0, 1, 0, .... in such a way that for each Δt one is on either the even channels ( CH0, CII2, ... CH62) or on the odd channels (CH1, CH3, ... CH63).

In the system according to the invention, the transmitting / receiving stations associated with different networks may be present in a limited vicinity. It should therefore not be possible for these posts to disrupt each other; for this it is necessary to provide a high-frequency decoupling of these posts. To obtain this decoupling, the channels used by these networks are separated by a frequency having a value at least equal to a certain value. This determined value is obtained by dividing the 64 channels into 8 sub-channels SGO, SG1, .... SG7 · The sub-channel SGO is formed by the channels CHO, CH1,.,. CH7, the sub-channel SG1 by the channels GH8 , ... GH15, etc. So only the 4 subchannels SG1, SG3, SG5 and SG7 are used (see fig. 8), so that between each of these subchannels there is one unused subchannel whose value corresponds to a certain value. . According to the invention, alternatively, an even channel or odd channel can be used in each sub-channel used for each jump; the channels suitable for use are shown in bold in Fig. 8. Thus, the odd channels of the subchannels SG1, SG3, SG5 and SG7 can be used between moments tt1 and tt2, while the even channels of these same subchannels can be used between moments tt2 and tt3. The odd channels can then be taken between moments tt3 and tt4.

Fig. 9 shows in detail an embodiment of a transmit / receive station of a system according to the invention with which operation of the channels indicated in FIG. 8 is possible. The identification code of the networks here consists of four binary elements b0 *, b1 ', b2', b3 ', which are fed to terminals B0', B1 ', B2 * and B3', respectively. These terminals are connected to first inputs of four "modulo 2" adders Δ5, Δ4, A2 and A1, the second inputs of which receive series SQ5, SQ4, SQ2 and SQ1 from a generator GEN.

The sub channels are defined by means of the binary elements present on inputs F5 * F4 »F3 of a converter; because the binary element f3 is always "1", it can be seen that one only has to deal with the subchannels whose reference has an odd number. The scrambling circuit BRO is formed by two parts BRO 'and BRO ". The part BRO * performs a random permutation between the binary elements present on its terminals G5 and G4 and for its return to the terminals F5 and F4, the terminals G5 and G4 are connected to the outputs of the adders A5 and A4 · The section BRO "performs a random permutation between the binary elements present on terminals G2 and G1 before passing them on to terminals F2 and F1, the terminals G2 and G1 are connected to the outputs of the adders A2 and A1. The terminal FO is connected to the output of the device 25, which alternately supplies the logic values "1" and "0".

It is possible to divide the set of channels in a different way. For example, as shown in Fig. 10, one can take a first subchannel comprising all channels (ie per ke® · the even and odd channels) of the subchannels whose numerical reference is odd ie the subchannels SG1, SG3 »SG5 and SG7 and as the second subchannel all channels of the subchannels whose reference number is; each jump actually moves from one subchannel to another. Fig. 11 shows the manner in which the sub-channels can be obtained. The number of the subchannels is determined by the binary elements fed to the terminals F5, F4> F3, wherein for the transmission of subchannels with even reference to the subchannels with odd references the terminal F3 is connected to the circuit 25. The terminals F5 and F4 are connected to a part BRO * of the scrambling chain, the terminals F2, F1, FO of the converter are connected to the outputs of the second part BRO "of the scrambling chain, the parts BRO 'and BRO" function in a mutually independent manner but in the same rhythm. The inputs of the BRO * chain are connected to the outputs of the "modulo 2" adders A5 and A4 and those of the chain BRO "to the outputs of the adders A2, A1 and A0. The inputs of these adders Δ5, A4> A3, A2, A1, A0 receive the binary identification code fed to terminals BO ', B1', B2 ', B3 *, B4' »B5 '. The second inputs of these adders receive the binary elements of the series S (* 5 »S <44» SQ2, SQ1 and SQ, respectively supplied by the generator GEN; it should be noted that the latter solution shown in Figs. 11 and 10 uses at most the set of available channels when providing high-frequency decoupling. n_c 1 usies -

Claims (2)

1. An information transmission system (constituted by nets which exploit a set of channels by means of frequency jumps, characterized in that the system is divided into separate subsystems and each of these subsystems is operated at each jump. The information transmission system of claim 1, wherein each network identified by an identification code regroups a number of transmit / receive stations, each comprising a frequency synthesizer used for determining the exploited channel, characterized in that for controlling the frequency synthesizer each transmitting / receiving station comprises a switching unit for matching an exploited channel determining data with a numerical code fed to its inputs, a device for supplying consecutive numerical codes as a function of the identification codes whose outputs are connected to the inputs of the switching unit, and a circuit which supplies alternating numerical data and the output of which is connected to one of the inputs of the switching unit.