DE3706870B3 - Sea mine, has remote-control device comprising gate circuit and switching-on device that is provided for activating decoder, code-memory and comparator for selected time periods such that default codes valid for time periods are selected - Google Patents

Abstract

The mine has a remote-control device (11) for activating and/or deactivating an acoustic ignition mechanism (10) and comprising a decoder (18), a code-memory (20) and a comparator (21). A set of temporally limited default codes is stored in the code-memory. The remote-control device comprises a gate circuit (19) and a switching-on device (22) that is coupled with a real-time clock (23). The switching-on device activates the decoder, the code-memory and the comparator for arbitrarily selected time periods such that the default codes valid for the time periods are selected.

Description

The invention relates to a marine mine with an acoustic ignition device and a telecontrol device for at least sharpening and / or defusing the ignition of the type specified in the preamble of claim 1.

Marine mine acoustical igniters respond to the sound of passing ships being evaluated for location of the vessel according to one or more criteria, such as bearing, level and / or level rise speed. If the ascertained ship location lies or reaches the effective range of the mine, an ignition signal is generated which causes the mine to detonate.

In order to increase the strategic and tactical applications, maritime mines are often equipped with a so-called telecontrol control device, which makes it possible to activate the generally inactive or disarmed designed mines in case of need but also to defuse sharp minefields temporarily or long term. The arming or disarming of the mines should be able to be carried out wirelessly from a great distance.

In a known marine mine with a device for arming or defusing the ignition device ( DE-PS 977 974 ), the direction-dependent telecontrol signal receiver three in their position with respect to the horizontal plane by 60 ° offset from each other coils. The electrical AC line signals emitted by the command station, the frequency of which either itself represents the control command or which are modulated by the control command, cause AC voltages in the coils. These are demodulated to recover the control command and then summed similar, so containing the same control command voltages and fed to a exciter system of a switching relay, which is turned on in the ignition circuit of the ignition device. The sum voltage containing the control command "sharpening" is thereby supplied to an excitation coil which moves the relay contact in the closing direction, while the sum voltage containing the control command "defusing", a second excitation coil is fed, which drives the relay contact in the opening direction.

Such a telecontrol device is structurally complex and requires a not inconsiderable amount of space, which, together with the not inconsiderable volume requirement of the acoustic ignition device, additionally increases the already quite voluminous mine already by the explosive part. Not only does the mine become unwieldy for the direct launching of the deck of a refiner, it also reduces the radius of action and the efficiency of the refiner, as his predetermined transport capacity allows only a limited number of mines to be stashed.

There is already a sea mine known ( DE 29 35 821 A1 ), which has a sensor for the identification of target objects, the operation of a geophone or a pressure transducer on z. B. piezoelectric base corresponds. The sensor is able to identify targets due to typical engine noise. For this purpose, the sensor is connected to an electronic evaluation device, which for example via a frequency filter causes a selection such that only those frequencies are permitted for evaluation, which are characteristic of the target objects. This sensor is in addition to the intentional ignition of the mine also used to achieve a targeted information input and thus influencing the mine behavior, z. B. to transfer the mine from the sharp state to the secured state or vice versa. For this information input the sensor is followed by a filter which selects from the totality of the received signals of the sensor those which are typical in terms of their frequency for the information. In order to identify the received information, a comparison device is provided which compares the information with a stored code and permits further processing of the information only if it matches.

This known marine mine thus uses the sound receiver required for the acoustic ignition device at the same time as a receiving part of the telecontrol control device and thus saves an additional circuit complexity for the telecontrol control device and thus space. Due to the relatively small additional space requirement, the telecontrol device can be easily integrated into the intended for the acoustic ignition body portion of the mine, whereby the maritime mine is replaced by the additional telecontrol controller no greater length.

Another problem of such maritime mines is the protection against foreign interference, d. H. Secured against manipulation of the telecontrol device by unauthorized third parties, which can usually only be achieved with considerable additional signal technical overhead.

The invention has for its object to keep the signal processing effort for telecontrol control device with reliable protection against foreign intervention small.

The object is in a marine mine the genus defined in the preamble of claim 1 solved according to the invention by the features in the characterizing part of claim 1.

The use of a plurality of default codes, which are stored in the telecontrol control unit or test unit and of which a code is selected as a control command in the telecontrol signal, provides the ability to constantly change the control command code and thus the protection against manipulation from the outside considerably to increase. In order not to have to check all the default codes, which would require a considerable signal processing and computer power, the validity of the individual default codes is limited in time, the synchronization of validity on the send and receive side is made by real-time clocks. Thus, not all preset codes must be called during the adjustment, but only those valid for the respective period, in the simple case only two default codes, namely the currently valid default code for arming and the currently valid default code for disarming. A limitation of Kommandierhäufigkeit for sharpening or disarming the sea mine using new codes must not be taken into account.

The security against alien intervention can be increased if the decoder is activated so that it only reacts once to a sent control command code. For this purpose, the default code with which the control command matches, then locked or deleted after performing the command function.

The invention is explained in more detail below with reference to an embodiment shown in the drawing. The drawing shows a block diagram of the signaling part of a marine mine, namely the acoustic ignition device and the telecontrol signal control device.

In the drawing, the circuit part of the acoustic ignition device with 10 and the circuit part of the telecontrol controller with 11 designated. The acoustic ignition device 10 comprises a working in the low frequency range sound receiver 12 consisting of a hydrophone or a hydrophone arrangement 13 and a signal amplifier 14 , for receiving ship noises and a signal evaluation device 15 , which the amplified received signals of the sound receiver 12 according to certain criteria, such as bearing, level, rate of rise of the level, evaluates and generates an electrical ignition signal, which is supplied to a detonator, not shown here in the explosive part of the mine.

An acoustic ignition device, which monitors an opened space above the mine and detonates the mine when a ship enters this surveillance zone, is disclosed in US Pat DE-PS 22 40 041 described. This acoustic ignition device has a gradient system of four crosswise placed hydrophones. The signal evaluation device forms the signal difference of the received signals of two respective opposite hydrophones and measures them at default voltages. If the default criterion is met, an electrical ignition signal is generated. It is possible to use such a known acoustic ignition device in the embodiment described here, but an ignition device used here in detail can also be constructed differently and use other criteria for obtaining the ignition signal, for. As the strength of a received low-frequency noise and / or their slew rate.

The telecontrol control device 11 has a telecontrol signal receiver also operating in the low-frequency range 16 from the sound receiver 12 and a downstream bandpass filter 17 is formed whose bandwidth equal to the frequency band of the telecontrol signals is selected. The band filter 17 is a demodulator or decoder 18 downstream of the control command contained encoded in the telecontrol signal. To telecontrol control device 11 further includes a locking device for suppressing or releasing the ignition signal, here as a gate 19 is formed and of one in the decoder 18 decoded control command that has been recognized as valid, disabled or perverted.

To check a valid control command, which is necessary for reasons of protection against unauthorized foreign interference in the remote control device, is a code memory 20 provided in which a plurality of default codes is stored in association with a respective time period. The memory output S _{out of} the code memory 20 is with the one input of a comparator 21 connected to the other input of the output of the decoder 18 lies. The output of the comparator 21 is with the control input of the gate circuit 19 connected. The control command input "read / write" and the address input of the code memory 20 are with a power-on device 22 connected with a real time clock 23 is coupled. The switch-on device 22 controls the decoder 18 in that it activates it only for certain arbitrarily selected predetermined periods of time and thus enables it to decode a received telecontrol signal. The time periods specified in absolute time become the switch-on device 22 from the real time clock 23 fed. These time periods are known on the transmitter side of the remote control device, so that any control commands to arm or disarm the mine are sent only in these periods. Once the power on 22 the decoder 18 For a predetermined period of time, it sets an address command and a read command to the code memory 20 , From the code memory stored under the called address default codes are read and the comparator 21 gradually fed. If you restrict yourself to the control commands "arming" and "defusing", these are each two default codes, which are valid in every period of time. The comparator 21 now compares these default codes with that of the decoder 18 issued control command and switches depending on the agreement with one or the other default code, the gate 19 on passage or blocking. The output of the comparator 21 is on the power-on device 22 fed back. A control signal for the gate circuit occurring at the comparator output 19 triggers in the switch-on device 22 a Write command, which overwrites the default codes written in under the currently called address with an empty or null information, and thus these default codes in the code memory 20 extinguished. This ensures that the telecontrol device 11 responded to a sent control command code only once. This avoids that the interception and decrypting transmitted telecontrol signals enables third parties to address the telecontrol device in turn. A sufficiently large supply of default codes ensures a large Kommandierhäufigkeit each with new codes. Since only a few control command or default codes are valid for certain periods of time, the computational outlay for checking the default codes is reduced to a minimum, namely to the number of possible control commands, such as "sharpening" or "defusing". In addition to the two types of control command mentioned but also control commands can be provided which change the criteria for the generation of an ignition signal, so the response characteristic of the acoustic ignition device.

As indicated in the drawing by dotted outline, the functions of the signal evaluation device 15 , the gate circuit 19 , the comparator 21 , the switch-on device 22 and the code memory 20 from a microcomputer 24 executed. As a result, the hardware costs for the acoustic ignition device 10 and for the telecontrol device 11 be minimized, since the available computer power alternately completely for the acoustic ignition device 10 or for the telecontrol device 11 can be used.

Claims (3)

Seemine with an acoustic ignition device having a vehicle noise receiving sound receiver and an ignition signals in response to the received signals of the sound receiver generating signal evaluation, and with a telecontrol device for sharpening and / or defusing the ignition device, a remote control signal receiver, the sound receiver of the An ignition device and a downstream thereof, matched to the frequency band of the acoustic telecontrol signals band filter comprises a decoder for recovering the control command contained in the telecontrol signal and a test unit for comparing the decoded control command having at least one default code, characterized in that in the test unit ( 20 . 21 ) a plurality of time-limited default codes is stored and that the telecontrol device ( 11 ) one of the test unit ( 20 . 21 ) controlled locking device ( 19 ) for suppressing or releasing the ignition signal of the ignition device ( 10 ) and one with a real-time clock ( 23 ) coupled switch-on device ( 22 ) containing the decoder ( 18 ) and the test facility ( 20 . 21 ) are activated only for predetermined, arbitrarily selected periods of time so that only the default codes valid for the respective period are called. Mine according to claim 1, characterized in that the test unit has a code memory ( 20 ) in which a plurality of default codes are stored in association with the predetermined time periods, and a comparator ( 21 ), whose one input is connected to the decoder output and whose other input is connected to the memory output (S _out ), and in that the switch-on device ( 22 ) with each turn on of the decoder ( 18 ) a read-out command for reading out the default code assigned to the current time period to the code memory ( 20 ). Mine according to one of claims 1 or 2, characterized in that the signal evaluation device ( 15 ) from a microcomputer ( 24 ) and that the microcomputer ( 24 ) functionally the test unit ( 20 . 21 ) and the switch-on device ( 22 ) contains.

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