DE2500210B2 - QUERY-ANSWER RADAR SYSTEM WITH TRIGGERING THE ANSWER BY A PRE-SIGNAL - Google Patents

Description

The invention relates to an interrogation-response radar system. with the one in the query signa! a distant signal and a special information signal are included. the particular information signal following the distant signal and the distant signal in the transponder after decoding an otherwise blocked gate circuit for opens a certain time, during which the event is drawn by lots \\ ird.

A system of the type mentioned above is known from DT-OS 20 51916. There a system is described which sends the discard signal of a secondary radar device as an advance signal. The transmission pulse of the associated primary radar device follows at a corresponding time interval. In the answering device, the interrogation signal is decoded, with an output signal being fed to a gate circuit in the form of an AND gate when the interrogation has been recognized as correct. The primary radar transmission pulse occurring after the interrogation signal ¹ is fed to the / wide input of the AND gate. The coincidence signal obtained at the output is used to trigger the response signal, which is provided in a memory. The response signal itself does not contain any components from the interrogation signal or the primary radar transmission signal, but is made up of everything from the information contained in the memory.

Line inaccuracies ("litter") therefore arise from both the interrogation signal and the primary radar transmission signal when resolving the response signals. Another disadvantage is that for the operation of a Such a response device both a primary radar and a secondary radar device are necessary, what a Requires a correspondingly high wall.

From the German Offenlegungsschrift 18 01 850 isi a method for eliminating intrinsic disturbances at a secondary radar system known in which additional information is included in the query of an interrogator is recorded. This additional information is used to identify the inquiring station and is used by the transponder after decoding in a suitable manner Way adopted as an address part in the response signal. In the interrogator the response signal then checked whether the response signal contains your own or someone else's station identifier is. This makes it possible to weed out all responses from external query stations triggered by a transponder.

A secondary radar system is known from the German Offenlegungsschrift 21 34 678, in which the ant word devices by means of a special address in the

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■ interrogation signals can be interrogated one after the other. A answering device that contains the information contained in the interrogation signal Address as its own Erkent.i, then emits a / response signal if a radar pulse follows of the associated primary radar system arrives. This enables a selective determination of the distance usable accuracy for the individual response devices possible; but there is the disadvantage that a primary and a secondary radar device are required and the transponders must also be designed to process both signals.

The invention is based on the object of providing a query-response system with as little effort as possible to realize, in which despite the temporal inaccuracy ("jitter") when decoding the Queries in the response device the runtime of the query-response signals can be adhered to very precisely. According to the invention, which relates to an interrogation-response radar system of the type mentioned above, This is achieved by sending the special information signal directly from the open gate circuit durchgeschaliet and from the answering device as an answer is delivered.

The connection of the special information signal due to the opening of the gate circuit k.itin taken in and of themselves by these measures, it may be inaccurate in terms of time, without affecting the accuracy the distance determination is received. This makes it possible for the decoding of the distant signal in particular to use simple components or a particularly small number of components, in particular those components that are constructed using MOS technology and whose operating speed is low. Even low clock frequencies of the queries can be implemented. Nevertheless, there is no disturbing "jitter" on. because the special information signal is directly connected through the open gate circuit in an uneodised manner and is used as a response signal. This ensures that the runtime, starting with failure of the interrogation signal at the answering device to for the delivery of the response signal can be adhered to very precisely without any special effort.

The invention can be used with particular advantage when the response to the interrogation device incoming special information signals for the sole determination of the distance for the location of the Answer device are used because the response received is particularly timely and practical has no "jitter".

The invention and further developments of the invention are explained in more detail with reference to drawings. It demonstrate:

Fig. I the structure of an interrogation signal,

Fig. 2 in the block diagram the structure of an interrogation station,

F i g. 3 the structure of a transponder.

The interrogation signal consists of a two-part distant signal _{V1 1} V2 and a special information signal BIS that follows it. In the present example 9 bits are assumed to be necessary for the first distant signal V1, 15 bits for the / wide distant signal V2 and 3 bits for the special information signal. The distant signal Vl is used for synchronization, ie it signals the beginning of an interrogation and can also be used in the response device for the purpose of automatic sensitivity control. The distant signal V2 contains a selective address including the necessary data backup for the targeted query of a specific response device to which the respective address is assigned. The special information sign! BIS is used directly as a response signal in the _t response device. Further details on this are given with reference to FIG. 3 explained.

In the arrangement according to FIG. 2 it is assumed that an interrogation station is connected to a control center via a line 1. Clock signals are fed to the interrogation station via this line 1 if synchronization is desired. The clock signals are fed to a clock circuit 2 which controls a modulator-demodulator unit 3. This unit 3 controls the triggering of interrogation signals and prepares the received response signals so that they can be transmitted via line 1 to the control center. The identifier (address) for the responder to be queried is processed in a device 4. The preparatory interrogation signals obtained in this way reach the eiru-m transmission memory 5, which is controlled by a clock device 6. This clock device 6 gives the command to read out the transmission memory 5, whereby the addressed interrogation signals, so the pre-signals Vl. 12 and the special information signal BIS according to FIG. The interrogation signals reach the antenna JOa via a switch 9 and are sent to the transponder according to FIG. 3 supplied.

The interrogation signals reach the receiver 12 at the transponder via the switch II. The distant signal V 2 arrives at a decoder 14 in which the address characteristic of the respective response device is stored. Will. / .. B. through passive decoding, if the address signal in the distant signal V2 is recognized as its own address, the decoder emits a control signal. which is fed to the gate circuit 15. This gate circuit is connected to the output of the receiver 12 and thus receives the entire interrogation signal according to FIG. 1. The switch 16 of the gate circuit 15 is normally open and thus blocks the forwarding of the interrogation signals. Only at the moment in which a pre-signal V2 containing one's own address has arrived as an interrogation signal, the switch 16 is closed by the decoder 14 via a control pulse (see FIG. 1) occurring at the end of the pre-signal V2. As a result, only the special information signal BIS reaches the modulator 17, which controls the transmitter 18 and returns the response signal via the switch 11 and the antenna 106 to the interrogation device according to FIG. The opening of the gate circuit 15 by the control pulse 5 / takes place inaccurately in terms of time because the decoding cannot be carried out with arbitrarily tight tolerances in terms of time. This is especially true when particularly simple components such. B. MOS-Schiebercgistcr should be used. The resulting gate impulse does not affect the accuracy in its time tolerance / no further. because the special information signal ß / S is switched through directly to the output of the transponder and thus transmitted back to the interrogator. The time delay which the special information signal BIS im

bs transponder learns is only through the very small Runtime in the answering device depends, which is also practically always highly constant. This eliminates the errors in the To keep distance measurement particularly small. That

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The information signal BIS is thus used in the transponder. 3 is

not decoded but directly processed, make sure that the transmission and reception path (amplified) and emitted again. are sufficiently decoupled from each other so that not

The structure of the transponder can be mistakenly simplified by a special information signal UIS that is received again instead of a modulator and 5. For this purpose, it is expedient to simply provide an amplifier for a transmitter. his, separate transmitting and receiving antennas in which the particular information signals amplified the transponder according to Fi g. 3 to be provided. In addition, antenna! (»» ^Feeds . ™ <> uch ™ ^f a suitable frequency selection for the

The gate circuit 15 is to be designed in such a way that at the end of the query and response signals as well as the superimposition of the special information signal BIS of the switch 16 local oscillators. To increase the security it is reopened. For this control process, for example, a monostable multivibrator with a corresponding additional in the modulator 17 according to FIG. 3 a pulse breaker of the time constant can be used. tcn limitation are provided.

This is the special information signal BIS that can improve the signal-to-noise ratio

The response signal containing the response signal reaches the interrogator ₁₅ special information signal BIS a pulse command according to Fig. 2 via the antenna 10a and the switch 9 represent pressure code (autocorrelation), for which the receiver 19. In a special ß / S decoder 20 decoder 20 at the interrogator according to FIG. 2 the received received signal would then have to be interpreted accordingly. In this case, there is a check as to whether it is actually a response signal from a special information signal BIS from a grid of (e.g. by passive decoding). This after 20 pulses, from which in the transponder with the help of the decoding output signal, z. B. in gate pulses. which in turn may be strongly jittered. In the form of a pulse ABIS, the counter 21 is supplied with the necessary for the formation of the response code, which is stopped thereby. The Startim- pulses are originally hidden, the pulse for this counter comes from the read-out signal, another option for expanding the idea

which from the transmission memory 5 to the molulator 7 25 consists in the fact that the special information signal will be given. This point in time thus defines the start of signal BIS already tapped on the high-frequency side in its query. Which subsequently converts based on the frequency and thus used directly as an answer. Clock pulses from the clock generator 6 to the arrival In this manner, beacon systems can with the a response signal indicative of pulse SOIA realize frequency shift, which thereby provides reached count thus a measure for the 30 characterized in that each query station on a base distance of the transponder of Fig. 3 from interrogates different carrier frequency and that it represents the interrogation device according to FIG. 2. The response thus obtained to its own interrogation by a defined counter result is recognized in a distance memory 22 frequency shift.

enrolled and via the unit 3 to the line 1 The arrangement of the response output is particularly advantageous, where the distance signal may be used as a particularly portable transponder with the special identifier of the queried response for ships that z. B. drive through a channel, along the device is transferred to the control center. the queries are carried out.

1 sheet of drawings

Claims (13)

25 OO 210 claims: 1. Interrogation-response radar system, in which the interrogation signal contains a distant signal and a special information signal, the special information signal following the distant signal and the distant signal in the transponder after decoding opens an otherwise locked gate for a certain time during which the The response is triggered, characterized in that the special information signal (BIS) is directly switched through by the open gate circuit (15) and is emitted as a response by the response device (11 to 18). 2. interrogation-response radar system according to claim 1, characterized in that due to the response from the interrogator (2 to 9, 19 to 22) arriving special information signal (BIS) the sole determination of the distance (in 21) carried out for the position of the response device earth. 3. interrogation-response radar system according to one of the preceding claims, characterized in that the particular information signal (BIS) passed through by the gate circuit (15) is emitted as a response. 4. interrogation-response radars \ stem according to one of claims 1 or 2, characterized in that the special information signal (BIS) let through by the gate circuit (15) is used for modulation (in 17) of the transmitter (18) of the transponder. 5. interrogation-response radar system according to one of the preceding claims, characterized in that the particular information signal (BIS) passed by the gate circuit (15) is not decoded in the response device. 6. interrogation-response radar system according to one of the preceding claims, characterized in that the special information signal (BIS) let through by the gate circuit (15) is transmitted as undelayed as possible. 7. query-response radarsystcm according to any one of the preceding claims, characterized by the use of the transponder on ships. 8. interrogation-Anlwori radar system according to one of the preceding claims, characterized in that the distant signal (VI, V2) contains an address signal (V2) for the selection of a specific response station. 9. query-response radar system according to one of the preceding claims, characterized in that the distant signal (Vl. V2) has a signal component (Vl) serving for input level control (13) and / or synchronization. 10. Interrogation-response radar system for a of the preceding claims, characterized by the use of components in §MOS technology in the transponder. 11. Inquiry-response radar system for a of the preceding claims, characterized in that that the antenna (10 ^ bc in the transponder (us separate transmitting and receiving antennas confesses. 12. Interrogation-response radar system after a of the preceding claims, characterized in that to increase security against line, unwanted feedback in the transponder also implemented a pulse width limitation is. 13. query-answer radar system according to one of the preceding claims, characterized in that the special information signal (BIS) represents a pulse compression code and the pulse compression is carried out in the response device. 14, interrogation-response radar system according to one of the preceding claims, characterized in that the special information signal (BIS) in the response device is already separated in terms of high frequencies, converted in its frequency and emitted in amplified form as a response signal.