DE2819376B2 - Navigation system with at least two interacting stations - Google Patents

Description

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The invention relates to a navigation system with at least two interacting stations as in The preamble of claim 1 specified. Such a navigation system is in the book »radio systems for Ortung und Navigation «by E. Kramar, Verlag Berliner Union GmbH, Stuttgart 1973, on pages 147 to 169.

With the navigation systems described there, distance and angle measurements can be carried out will. For many purposes, however, it is desirable to use the same navigation systems additional information, e.g. B. for air monitoring purposes to be able to transmit.

A solution to this problem is known from DE-AS 19 32 294. For a secure transfer of information, w) it is necessary with this solution that none or only very few of the transmitted pulses are lost or may be falsified.

It is the object of the invention to specify a navigation system with which one is insensitive to interference before information transfer is possible.

The solution to this problem takes place with the generally advantageous further

Formations can be found in the subclaims.

Existing facilities can be expanded in a simple manner so that the additional Information transfer is possible. It will be itself then the information is received unadulterated if a large number of Pulses or pairs of pulses is lost or falsified will.

The invention is explained in more detail with reference to the drawings, for example. It shows

F i g. 1 an excerpt from a pulse group consisting of several pulse trains,

F i g. 2 several successive pulse groups, F i g. 3 shows a block diagram of an exemplary embodiment.

The invention is described using a DME system, for example. She can also help other navigation systems (e.g. TACAN, Sector-TACAN etc.) can be used.

It is advantageous if pairs of pulses are emitted from the transmitting station of the navigation system, because this can result in an erroneous evaluation of foreign individual pulses - z. B. L-band radars - can be avoided. A single pulse of a DME or TACAN pulse pair has a pulse duration of 3.5 μ ± 0.5 μ $. The distance between two single pulses is 12.30 or 36 μ5. The distance between consecutive. Pulse pairs fluctuates statistically between 100 \ is and 1 ms.

The pulse trains A, B (Fig. 1) emitted by the new transmitting station consist of three pulses for the transmission of information by means of a binary code, the first two pulses 1, H being the DME pulse pair and the third pulse III for the second pulse II des Pulse pair has a first TA or a second TB distance, whereby the two pulse trains are distinguishable from each other. The distance between the pulse trains A, B is determined by the distance between the DME pulse pairs; in FIG. I two possible distances Ti, Tl are shown.

Pulse groups with pulse trains A and pulse groups with pulse trains B are emitted alternately from the ground station. This is shown in FIG. A different number of pulse trains per pulse group is assigned to each binary value. The binary value is not contained in the distance TA, death of the third pulse III from the pulse pair I, II, but in the number of pulse trains per pulse group. The different distances TA; TB are used to distinguish between successive bits.

In the receiving station, the received pulse trains are decoded and it is determined when a transition from one pulse group with pulse trains A to the other pulse group with pulse trains B takes place. Then the number of pulse trains between successive pulse group changes is counted to determine the transmitted binary value. In the in F i g. 2a, five pulse sequences are assigned to the first binary value (e.g. "0") and thirteen pulse arcs are assigned to the second binary value (e.g. "1").

With this assignment of the number of pulse trains between successive pulse group changes to a binary value, it was assumed that no pulses are lost. It is explained below how the number of pulse trains has to be chosen so that a safe Uhertrauiinp (is guaranteed.

In order to be able to reliably determine a pulse group change, it is required that at least per pulse group there are two pulse trains. It is assumed that from the transmitting station emitted pulse trains a maximum of half is not received and that successive maximum three pulse trains are lost. It follows that the minimum number of pulse trains per Pulse group for the first binary value, which is »Ck, equal to five. The second binary value, the "1", must have a larger number of pulse trains per pulse group can be assigned. With the assumed faults - Half and a maximum of three consecutive pulse trains can be missing - the minimum number must be be twelve, because this is the only way that half is greater than the number assigned to the first binary value

To avoid incorrect decoding of the pulse trains causing errors (a disturbance For example, if it is decoded as a pulse train), six pulse trains are assigned to the first in the receiver Binary value to, although the transmitting station only emitted five pulses for the first binary value will. Accordingly, thirteen pulse trains are assigned to the second binary value on the transmission side.

The evaluation is therefore carried out with the assignment described above as follows

Number of pulse trains between two pulse group changes 2 to 6 - first binary value ("0")
7 to 13 - second binary value ("1")

An example in which only part of the emitted pulse wave is received is in Fig. 2b shown. In Fig. 2a and in Fig. 2b it is assumed that the emitted signals are the same was. It can be seen from the illustration that although the changes between adjacent pulse groups are compared with the undisturbed case to be recognized at other times, however, because of the above the correct binary value is always determined. Both in the representation according to FIG. 2a as well as in the illustration according to FIG. 2b, the binary values 0 0 1 were received.

In the previous description it was assumed that the two pulse trains differ in the distance between the third pulse and the pulse pair. However, other differentiation criteria are also possible. For example, a pulse train can only consist of the pulse pair, the respective second pulses of a pulse pair being phase-modulated differently in order to distinguish the pulse train A from the pulse train B.

Based on the F i g. 3 will briefly explain how the Sending station and the receiving station can be constructed.

On page 153 of E. Kramar's book is one Ground response station for a DME system described. This ground response station contains a pulse former / modulator and an antenna 3. The new ground answering station 1 differs from that known ground answer station only by another pulse shaper / modulator 2. It must be suitable, to generate the desired pulse trains. That on

2-j page 154 of this book described DME-B Drdgerät 5 contains an antenna 4 and an IF part f \ The signals taken from the IF part are used for information evaluation first fed to a demodulator 7, which consists of a double pulse and another

ii) Pulse existing pulse trains A. B demodulated. These demodulated pulse trains are sent, on the one hand, to a pulse shaping device 9, which generates an individual pulse for each pulse train, and, on the other hand, to a decoding device 8, which generates each pulse group.

Jj penwechsel emits a pulse, supplied. A counter 10 counts the amounts from the pulse shaping device 9 pulses delivered between two consecutive pulse group changes. Every output pulse the decoder 8 switches the counter 10 back to zero; the maximum count becomes one Evaluation device ll supplied, the respective binary value from the respective maximum counter reading determined and, if necessary, displays the information received. The individual assemblies are general

4 ^r ) are known and are therefore not explained in more detail.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Navigation system with at least two interacting stations, in which pulsed signals are emitted from the first station to the second station, in particular DME or TACAN navigation system, characterized in that for information transmission by means of a binary code from the first station (1) alternately from one another distinguishable (A, B) groups of pulses, with one group containing a different number of pulses (I) for each of the two binary values, so that the change between successive groups is determined in the second station (5), since the number of pulses between successive changes is counted and that the first or the second binary value is recognized when a first or a second minimum number of pulses is present, the minimum number for the second binary value being greater than the number of pulses emitted for the first binary value. 2. Navigation system according to claim 1, characterized in that each pulse (I) is assigned a second 2 ^r > pulse (II) so that pulse pairs are emitted. 3. Navigation system according to claim 1 or 2, characterized in that the groups can be distinguished in that the pulse pairs or the j <> pulses of one group each have at least one further pulse (III) at a first distance (TA) and the pulse pairs or the impulses of the other group are followed by at least one further impulse (III) at a second interval (TB) . r> 4. Navigation system according to claim 1 or 2, characterized in that the groups are characterized are distinguishable from each other that the pulse pairs or pulses of one group are different from the Pulse pairs or pulses from the other group are modulated.