DE102010006943A1 - Pulse retention sensor for measuring long distances, has pulse groups coded such that pulse groups or part of pulse groups are filtered from noise during signal processing and are laterally assigned for distance measurement - Google Patents

Abstract

The sensor has a pulse transmitter, a pulse receiver, and pulse groups (104), which are transmitted, and coded such that the pulse groups or part of the pulse groups are filtered from noise during signal processing and are laterally assigned for distance measurement. The pulse groups are controlled by a random number generator according to frequencies of the pulse groups. The pulse groups are encoded in such a way that information transfer to a system to be measured during distance measurement. Time domain for the pulse groups is reduced.

Description

State of the art

• – DE 41 27 168.8
• – DE 197 17 399.3
• – DE 101 62 668 B4

beschrieben.Pulse transit time sensors for medium distances and their signal processing methods are z. B. in the writings

• - DE 41 27 168.8
• - DE 197 17 399.3
• - DE 101 62 668 B4

described.

These systems all have the disadvantage that either a light pulse is evaluated in terms of its shape with respect to the noise or in each case after the arrival of the signal further light pulses are delivered to the destination and these are then integrated.

Object of the invention

The object of the invention is to provide for relatively large distances to be bridged a system that manages with low pulse peak power and still the signal is detected from the noise out. At the same time the transmission signal is given an identifier that allows discrimination of the system's signals from noise and other sources of interference.

Description of the invention

The invention is achieved by means of 1 to 5 described.

Instead of a single pulse per measurement will be accordingly 1 several pulses delivered at short intervals or groups of pulses.

Corresponding 1 are the amplitudes of the pulses respectively on the axes 101 and 101 shown. Time is on the axes 102 and 102 shown. The interruption of the time axis until the arrival of the signals is with the characters 103 and 103a characterized.

The transmission system gives a pulse group 104 with the single pulses 105 with their time intervals 106 from. The pulse group is reflected by the target and shows up at the receiver with the signal 104r , Illustrative are transmission pulses 105 and receive pulses 107 represented with the same amplitude. The distance 106 remains with both signals. The evaluation of the pulse group 104r can with z. As a digital or analog filter or with a processor system. The pulse groups are used only for large distances or with a low signal-to-noise ratio, for low-noise signals, the first pulse is generally sufficient. In order to avoid ambiguity, only the first or further pulses with short intermediate distances are used for nearby targets. By the one with the pulse interval 106 Given frequency and the number of pulses is for the further evaluation of a lower signal processing bandwidth applicable than would be necessary for the evaluation of a single pulse. This overall improves the signal-to-noise ratio. In order to distinguish signals of the own system from those of other systems, the respective frequency per pulse group can be determined by a random generator.

In order to use a digital filter which filters out the pulse group to be detected even more clearly from the noise level, the pulses can be emitted at different intervals. This procedure is with the amplitude 101 and with the timeline 102 shown. The different times between the emitting pulses are with 106a . 106b 106c and 106d shown. The pulses reflected by the object with their time intervals are with 106ar . 106br . 106cr and 106dr shown. Due to the different times between the pulses, the signal is given an identifier at the same time. This achieves a further increase in the signal-to-noise ratio.

In 1a As an example, a possible evaluation method is shown with equidistant pulses for the sake of simplicity. The respective amplitudes are on the axis 101b shown, time is on the axis 102b shown. The transit time between the transmitted and the reflected pulses is as an interruption with 103b designated. The delivered pulses have the same time intervals 112 , The impulses themselves are with 108 . 109 . 110 and 111 designated. The transmitted pulses reflected at the target appear as pulses at the receiver 108a . 109a and 110a and 111 , These received pulses will be because the time intervals 112 are known, each delayed so that the pulse 108a three units 112 , the impulse 109a two units 112 and the impulse 110a one unity 112 after the arrival of the first pulse accumulate later in a summing and there together with the pulse 111 z. Over the time domain 113 be summed up. This creates an impulse 114 at least by a factor of √ (Number of pulses) So √4 and so with double amplitude protrudes from the noise. The method can be used in the same way with different distances of the pulses. Only the sequence of different times is to be considered.

So that the first impulse does not have to be detected precisely in its temporal position in order to enable the described method, it becomes appropriate 2 acquires and digitizes the entire signal using a conventional method. Such methods are for. B. in the known publications
DE 197 17 399.3
DE 101 62 668 B4
shown. The signal is z. B. acquired these fonts and as in 2 schematically shown with two pulses processed.

There are two light pulses 201 and 202 with a time interval of 203 sent out. After a time through 204 is interrupted for presentation, the light pulses from the target as 201r and 202r reflected.

For schematic representation, transmitted light pulses and received light pulses are drawn with the same amplitude. To filter out the pulses, the signal z. B. in quantization steps over time 205 acquired and saved. Then, the entire signal is processed so that each of the signals 1 to 13 of the group 203a with the respective signals 1 to 13 of the group 203b are added so that an addition of the signal parts respectively with the pulse spacing 203 he follows. This evaluation takes place over the entire time in which the backscatter signal is expected.

This will be the impulses 201r and 202r 6 to 12 are added to each other at the quantization points and yield the pulse 206 as an addition of both pulse amplitudes 201r and 202r , After this new impulse sticks out of the noise at least by a factor of 1.4, it and its distance can be registered. With multiple pulses or pulse groups will be as in 2 described procedure only that then several distance groups are processed.

As examples are in 2a three pulses 209 . 210 and 211 shown. The impulse 209 has the impulse 210 the distance 212 , The impulse 210 has the impulse 211 the distance 213 , To filter out the signal we use the entire signal as in 2 sampled and evaluated with the difference that the different pulse intervals of 212 and 213 in the summation over the period 114 be taken into account. This makes the three pulses possible 209 . 210 and 211 to add to each other.

At other time intervals or pulse groups, the entire acquired data stream of the backscattered signal is treated as described taking into account the different time difference. This method can be performed with all possible pulses and pulse groups with appropriate choice of the signals to be added in the appropriate time intervals. It is also possible to use different time intervals for the individual pulse groups.

The entire signal can thereby be treated by means of a microprocessor so that different time intervals between the transmission time pulse and the acquired received signals are selected and then the signal with the highest signal / noise ratio is filtered out of the summation and from this the time difference of the pulse group to the transmission signal is well determined , If a code in which the pulse intervals and the combination of different pulses have unique values for the pulse groups, the recognition of parts of the code can still be used to determine the exact distance, since the individual parts of the code are recognizable and can be assigned. This can still be an accurate distance determination performed even if some pulses in the noise are no longer recognizable. By this method, an improvement of the signal-to-noise ratio can be achieved almost by the factor of the number of still detectable pulses.

The block diagram of a system according to the invention is shown in FIG 3 shown. The control of the system and adjustment of the pulse groups as well as the evaluation of the echo signals takes place in the microprocessor module 314 that's over the bus 313 the pulse generator 305 controls. The pulse generator 305 controls the pulse shaper stage 302 over the interface 304 at. The pulse shaper stage 302 controls the laser diode 301 on, their light pulses through the optics 303 on the scene to be measured. The pulse sequences reflected by the object pass through the receiving optics 308 and the filter 307 on the detector 306 , The signals of the detector 306 be in the amplifier unit 309 conditioned and pass through the interface 310 in the analog-to-digital converter 311 to which an evaluation unit 312 is connected downstream, corresponding to the delay of the individual pulses according to the pulse intervals 1 . 2 . 2a and evaluates the summation or the signals by recognizing parts of the pulse group. The result arrives via the bus 313 to the microprocessor and is there checked for plausibility and effectiveness of the signal-to-noise ratio gain and the partial code recognition compared to the raw signal and passes as distance information via the interface 315 to supply and interface module 316 , With a plausibility, effectiveness check and code recognition, since all signals are stored, iteratively, several improvement runs can be performed by the microprocessor. Will these signal scores be in a subset of the building block 312 a new measurement can already be started during the improvement runs. The building blocks 302 . 305 and 312 can mainly z. B. be represented by a fast freely programmable logic. The building block 316 is sent from the corresponding carrier via the interface 317 via the electrical system supplied and delivered via the outputs 318 all necessary voltages for the system. About the external interface 319 the connection to the carrier is made. With carrier is in the following z. B. the entire system such as vehicle, aircraft, drone or monitoring system called. The corresponding pulse intervals in the pulse generator 305 and in the unit 312 are either fixed or per measurement cycle by the microprocessor 314 controlled from.

• – Eigengeschwindigkeit
• – Bewegungsvektor
• – Eigenmanövrierfähigkeit
• – Eigenposition
• – Eigene Ausweichstrategie
• – Vorschlag einer Ausweichstrategie für einen Kollisionspartner
• – Rückmeldung der Tendenz der Wirksamkeit des Ausweichmanövers

objektselektiv übertragen werden. Die Information kann mit einem Kode mit unverwechselbaren Werten übertrage werden. Das System ist auch geeignet für Entfernungsmessung und Informationsübertragung unterschiedliche Kodierungen anzuwenden. Damit ist für mögliche Kollisionspartner nur ein passiver Empfänger entsprechen 4 nötig. In 4 ist ein solcher passiver Empfänger gezeigt.The pulse intervals can also be controlled by the microprocessor 314 be controlled so that information like

• - Airspeed
• - motion vector
• - Self-maneuverability
• - Own position
• - Own evasion strategy
• - Proposing an evasion strategy for a collision partner
• - Feedback of the tendency of the effectiveness of the evasive maneuver

be transferred objectively. The information can be transmitted with a code with distinctive values. The system is also suitable for distance measurement and information transmission to apply different codes. This means that only one passive receiver can be used for possible collision partners 4 necessary. In 4 such a passive receiver is shown.

The transmission pulses of a system after 3 be via the receiving optics 401 the filter 402 on the photodetector 403 directed. The signal is in the stage 404 conditioned and over the interface 405 the analog / digital converter 406 fed. The digital signals are sent over the bus 407 the evaluation unit 408 consisting of a programmable logic with microprocessor supplied for evaluation. The result is over the bus 413 to the interface block 409 passed. This module is carried by the carrier via the input 411 supplies and provides the system with all the necessary voltages via the interfaces 410 available and gives at the same time the result over the bus 412 to the carrier on.

In 5 another embodiment of the system is shown. About the transmission optics 303 become several laser diodes 501 and 502 pictured on the scene. The laser diodes are from the controllable pulse shaper 503 driven. The light pulses scattered back by objects pass through the receiving optics 308 , the filter 307 on several imagewise the laser diodes 501 and 502 assigned receiving diodes 506 and 507 , The signals of the receiving diodes are in the block 508 amplified, multiplexed and converted into digital values and sent to the valuation unit 510 over the bus 509 forwarded. The selection of the laser and the receiver is via the bus 512 from the microprocessor 514 met.

The evaluation of the signals via the corresponding pulse intervals of the individual pulses or pulse groups via the block 510 who gives his results on the bus 512 the microprocessor 514 forwards. For fast signal exchange between pulse shaper 505 and evaluation unit 510 is the fast bus 513 intended. Are from the receiving group 308 to 510 Receive pulse groups from another system of the same type that are not correlated with the coding of the distance measurement, these signals are transmitted over the bus 512 to the unit 516 forwarded and there z. B. decoded as data of a corresponding collision partner and evaluated for evasive maneuvers. The supply of the entire system via the carrier supply 317 on the interface module 316 who in turn has the system through the interfaces 318 supplied with the necessary voltages and the data of the units 515 and 516 over the bus 319 leads to the carrier.

The multiple lasers 501 and 502 and the multiple receivers 506 and 507 can be carried out both as rows and as a matrix with a plurality of such units in order to be able to carry out an electronically multiplexed distance measurement, signal evaluation and data transmission in one row or one area.

To avoid interference with other similar systems, the coding of the pulses per single laser, per line or per revolution of the system can be controlled by a random generator. Despite this measure, the coding can be carried out in each case so that the code even in case of failure of some pulses by z. B. noise is still at least partially recognizable and evaluable.

An arrangement after 5 can also be accommodated in a device that the system azimuthally z. B: swivels 360 ° and either electronically scans the elevation area as described or also passes over it mechanically.

This allows the system to monitor the entire space around the wearer.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4127168 [0001]
• DE 19717399 [0001, 0010]
• DE 10162668 B4 [0001, 0010]

Claims (7)

Pulse transit time sensor for long distances with at least one pulse transmitter and at least one pulse receiver, signal acquisition and digitization of the received signals, characterized in that pulse groups are transmitted, which are coded so that the pulse group itself or parts thereof in a further signal processing filters out of the noise and in time be assigned for a distance measurement. Pulse transit time sensor for long distances with at least one pulse transmitter and at least one pulse receiver, a signal acquisition and a digitization of the received signals according to claim 1, characterized in that the pulses have known, variable time intervals. Pulse transit time sensor for long distances with at least one pulse transmitter and at least one pulse receiver, a signal acquisition and digitization of the received signals according to claim 1, characterized in that the pulse groups are controlled by a random number generator in their frequency. Long-term pulse transit time sensor with at least one pulse transmitter and at least one pulse receiver, a signal acquisition and a digitization of the received signals according to claim 1, characterized in that the coding of the pulse group is controlled by a random number generator. Pulse transit time sensor for long distances with at least one pulse transmitter and at least one pulse receiver, signal acquisition and digitization of the received signals according to claim 1 to 4, characterized in that the pulse group are coded so that information is transmitted to a same system at the same time with the distance measurement. A long-term pulse transit time sensor having at least one pulse transmitter and at least one pulse receiver, signal acquisition and digitization of the receive signals according to any one of the preceding claims, characterized in that adequate objects include passive receivers capable of receiving and decoding the information of the measuring system. Pulse transit time sensor for long distances with at least one pulse transmitter and at least one pulse receiver, a signal acquisition and digitization of the received signals according to one of the preceding claims, characterized in that the time range of the pulse groups is so low that no motion blur occurs during this time by the movement of the objects.

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