DE3933437C2 - - Google Patents

Description

The invention is based on a retroreflective system in the preamble of the main claim specified Art.

Such a system is approximately as pulse radar from DE 24 52 448 C2 known. In general, such systems are used to measure Objects by distance and direction with respect to the transmit-receive antenna for vibrational energy, which is basically any Occupy frequency range in the electromagnetic radiation spectrum can, for example, by water sound energy (EP 02 47 375 A), by radio frequency energy (EP 01 87 397 A) or by radiation energy in or next to the optically visible spectral band (GB 20 29 664) given is.

Because the playback brightness of echo information on radar screens on the angular velocity of the polar coordinate write beam depends on it is known from DE 24 52 448 C2 cited at the beginning, the on-screen controls do not respond directly to the radar echoes to be charged, but first of all to store them temporarily. The cached The result of the radar echoes can then be used as often or can be read out on the screen as slowly as required the fluorescent reactivity of any bright radar image for to generate the distance range selected for display, independently from the fact that due to constant angular velocity the rotating radar antenna that causes the echoes, relative to the  Moving object at a shorter distance more often from the Radar beam is detected as at a large object distance.

For the distance measurement based on the echo runtime, the sent Frequency modulated energy in continuous wave mode (WO 83/02 830), or pulsed vibration packets are sent out and received (EP 01 87 397 A). The directional distance measurement can serve, for example, the course of a reflection front relative to the transmit / receive antenna or the distribution reflective objects (US 46 11 772; GB 12 70 729) to detect, or a once understood Control and track target object (US 30 64 924); in which the orientation of the antenna characteristics not with the plane of movement the location system or the reflective system to be understood with it Object must match. The system can also be stationary  be arranged around the contour of it (for example on a Conveyor belt) to capture objects passed and according to requirements the front geometry, for example, automatic handling machines for removal and to control the correct handover of the objects; or by one Classification of a defense mine or another Room surveillance system approaching object (GB 21 74 482) to lead.

In all implementation and deployment cases of such a re Beam location system is the repetition frequency of the antenna radiated transmission signals of the necessary for the location task Angular resolution in the largest distance range of the location area to adapt, for example, to a long distance Object sufficiently often for the opening desired for the contour analysis solution is scanned. Because of the beam geometry, a Object closer to the antenna is correspondingly more common scanned, and in particular also more frequently than for the required Resolution would be necessary. Because that when scanning the object resulting location information (distance measurements above the Or angle) are further processed in a signal processor, the less frequently the latter has to take in input information the distance between the antenna and the retroreflective object is. However, the working speed of a signal processor is limited and its capacity is also used for other signal processing engineering tasks (such as Fourier or correlation analysis sen) needed. The processor stands for such other tasks the less available, the more frequent it is distance information must take over and process, which (at short distance) denser are actually staggered than for the desired object resolution would be required.

The invention is based on the knowledge of these circumstances the basis for a location system of the generic type Distance information obtained causes stress on the signal processor to reduce.

According to the invention, this object is essentially achieved by that in the signal processing circuit of a retroreflection locator position of the generic type, the measures according to the labeling part of claim 1 are taken.

According to this solution, the distance between the Location system and the reflective object less individual Receive signals to the signal processor for further processing switched as actually picked up by the antenna, with what the angular resolution increasing with decreasing distance solution kept constant and above all the stress on the Signal processor becomes a good approximation independent of distance. Here can of the larger number with decreasing distance accruing received signals correspondingly more blanked out, ie be less let through to the signal processor; expediently however, such data reduction takes place without loss of information in that angularly offset from one another over a number received signals occurring are each averaged, so that only the smaller number of similar averages over each to transfer several distance measured values to the signal processor is.

Additional alternatives and further training as well as further features and advantages of the invention are specified in the further claims.

An embodiment is described in the following description of one in the drawing  Limitation to the essentials, highly abstracted and not measured preferred implementation example sketched in line with the staff specified.

The only figure in the drawing shows In the simplified single-pole block diagram, a retroreflection locator System with distance-dependent reduced output of distance information mations.

A retroreflection system 11 essentially has a periodically operating transmitter 12 , a transmitting and receiving antenna 13 for radiation and recording of location energy, a transmitting-receiving Wei surface 14 , a receiver 15 for amplifying and preprocessing the received signals 16 and a distance measuring circuit 17 on. The latter is controlled from the transmitter 12 in accordance with the periodicity of the transmission signals 18 in order to determine the distance 20 to the reflecting target object 21 in the current location direction 19 via the echo running time of the transmission signals 18 (by means of a transit time or frequency evaluation). which is output, for example, as a numerical value 20 ( 19 ). If the object 21 moves relative to the Rückstrahlor processing system 11 , ie to its antenna 13 , with a tangential path component - because the object 21 is moved for example on a conveyor belt (not shown) under the antenna 13 ; or because the locating direction 19 is changed as a result of a pivoting movement of the antenna 13 - then the sequence of measurement results over the distance 20 ( 19 ) provides the profile profile of the object front 22 facing the antenna 13 (as symbolically in the drawing on the output side behind the Measuring circuit 17 illustrative light). These measured values over the distances 20 ( 19 ) are transferred in their periodic sequence to a signal processor 23 in order to be further processed there, in particular with regard to a closer analysis of object-specific signal contents for target identification.

The detection information 24 thus prepared finally feeds a decision or control circuit 25 , for example for triggering an ignition signal for the military combat of the object 21 or for operating a manipulator for handling the object 21 .

The problem with regard to the design of the operating speed of the signal processor 23 is that a reflecting object 21 at a short distance 20 delivers signals in a much higher frequency sequence 16 than at a greater distance 20 '. Because if the directional resolution (i.e. the number of individual location directions 19 with which the distant object 21 is just still detected in its tangential extent) is designed for a certain number of reflections along its front 22 , then the radiation geometry (as from the drawing ersicht Lich) that the same object 21 standing at a shorter distance 20 is detected much more often than is actually required for the geometric resolution of the front 22 . At a shorter distance 20 , the signal processor 23 is thus used much more often for the recording and processing of distance information 20 ( 19 ), and accordingly less computing time is available for processing other signals 26 (for example for Fourier or correlation analyzes).

In order to avoid this unnecessarily high stress on the signal processor 23 at short distances 20 as far as possible, provision is now made to carry out a data reduction depending on the distance 20 , from which an approximately constant resolution results regardless of the current distance 20 . For this purpose, the number of input information 27 switched through from the distance measuring circuit 17 to the signal processor 23 - controlled from the measuring circuit 17 - is reduced with a decreasing distance 20 . In principle, this can be realized simply by the fact that a periodically closed switching path 28 has fewer pass intervals, the shorter the distance 20 ( 19 ). As a result, as many received signals 16 as input information 17 are transferred to the signal processor 23 from a shorter distance 20 than received signals 16 resulting from a greater reflector distance 20 . The signal processor 23 is then always uniform (and optimal with regard to the resolution requirements) regardless of the instantaneous distance of the object front 22 to be evaluated.

In terms of circuitry, this measure is particularly simple to implement if no continuous control of the forward duty cycle of the switching path 28 is made as a function of the distance 20-20 ' ; but if the location area 29 is defined discontinuously in this regard by defining predetermined distance ranges 30 . Then, a threshold control 31 can be used to individually control individual switching distances 28 that are predetermined with regard to their tactile behavior, and only a slight fluctuation in the local triggering of the reflecting object front 22 occurs in the individual distance ranges 30 .

However, it represents a loss of information to suppress received echo received signals 16 from the object front 22 of interest in the interest of constant resolution and thus in the interest of relieving the signal processor 23 by means of the retroreflection system 11 . According to a development of the solution according to the invention, provision is therefore made for the averaging circuit 32 to be connected downstream of the individual switching paths 28 and thus the individual distance ranges 30 . These provide input information 27 to the signal processor 23 , which represents an average of the more information about the distance 20 ( 19 ) that follows one another, the smaller the distance 20 . As a result of this averaging over a plurality of distance measured values 20 ( 19 ), the entire information already present in the received signals 16 is used without causing the periodicity of the input information 27 to increase significantly with the reduction in the object distance.

Claims (3)

1. reflective location system ( 11 ) for scanning the front ( 22 ) of distant objects ( 21 ); characterized in that the less distance measured values ( 20 ) are processed by a signal processor ( 23 ), the more often the object ( 21 ) is detected during a scanning process, so that there is a constant resolution of the front ( 22 ) of the object ( 21 ). 2. Retroreflecting system according to claim 1, characterized by switching ranges ( 28 ) assigned to different distance ranges ( 30 ) for distance-dependent switching of the number of distance values ( 20 ) obtained via a positioning angle (positioning directions 19 ). 3. retroreflection detection system according to claim 2, characterized by the switching distances ( 28 ) assigned to averager ( 32 ) for outputting distance information ( 27 ) which is averaged from the more angularly adjacent distance values ( 20 ), the smaller the object distance ( 20 ) is.