• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
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    • 专利摘要:
    The present invention relates to a method for measuring the distance of environmental targets (U) by transit time measurement of pulses reflected therefrom, in particular laser pulses, which are emitted according to a predefinable pulse repetition rate (PRR) successively to a transmission time (TS) and after their reflection in each case at a reception time (TE ), comprising: selecting a first pulse repetition rate (PRR1) from a set (M) of at least two different pulse repetition rates (PRRi) and specifying the selected pulse repetition rate (PRR1) for the transmission, determining a transmission time (TS) which corresponds to the reception time ( TE) of a reflected pulse (E) is closest in time, and a period of time (Δ) between them, and if the determined period of time (Δ) falls below a predetermined first threshold (σ1), selecting a second pulse repetition rate (PRR2) from the set (M) and specify the second pulse repetition rate (PRR2) for sending.
    公开号:AT517300A1
    申请号:T50491/2015
    申请日:2015-06-15
    公开日:2016-12-15
    发明作者:Peter Dipl Ing Rieger;Andreas Dr Ullrich
    申请人:Riegl Laser Measurement Systems Gmbh;
    IPC主号:
    专利说明:

    PATENT OFFICER DIPL.-ING. Dr.techn. ANDREAS WEISER EUROPEAN PATENT AND TRADEMARK ATTORNEY A-1130 VIENNA · KOPFGASSE 7 06984 RIEGL Laser Measurement Systems GmbH A-3580 Horn (AT)
    The present invention relates to a method for measuring the range of environmental targets by measuring the transit time of pulses reflected therefrom. The pulses can be of any kind, e.g. Light pulses, in particular laser pulses, radio pulses, in particular radar pulses, sound pulses or the like.
    Modern pulse duration rangefinders such as laser rangefinders or scanners operate with high pulse power over long distances and / or high pulse repetition rate for the rapid creation of a plurality of distance measuring points of the environment, achieving a high time and / or spatial resolution. In either case, the situation may arise that the next pulse is already being transmitted even before the reflection of the last pulse has been received, so that the incoming receive pulses can no longer be unambiguously assigned to their respective transmit pulse. This is known as "multiple time around" (MTA) or "multiple pulses in the air" problem. The maximum size dmax of the clearly measurable distance range, the so-called MTA zone, results from the pulse repetition rate PRR and the speed of light c to dmax = c / (2-PRR).
    For example, if a laser scanner offers a pulse repetition rate of 400 kHz, this corresponds to an MTA zone size dmax of approximately 375 m.
    For correct mutual assignment of the transmit and receive pulses for clear distance measurement results a variety of methods are known. A first option is to make sure that all expected environmental targets are in one and the same MTA zone when planning the survey task, so that the correct assignment can be made. This method is naturally only applicable for special measuring tasks and e.g. for highly mobile or large-scale surveying or scanning tasks, e.g. the airborne scanning of terrain or the ground-based surveying of mountain ranges or moving aircraft, unsuitable.
    Another group of methods is based on making the individual transmission pulses distinguishable by varying or coding their polarization, amplitude or wavelength in order to be able to assign the received pulses accordingly. However, these methods are either suitable only for a few "pulses in the air" or require complex coded pulses, which in each case limits the pulse repetition rate and the measurable distance range and extends the measurement time.
    An alternative method employing pulse position modulation is known from patent EP 2 694 996 B1 of the same Applicant. In this case, a sequence of pulses modulated in their mutual pulse intervals is transmitted and the correct MTA zone is determined by searching for the least noisy received pulse train.
    However, all these methods have in common that the reception of a reflected (former) pulse at the time of transmission of a (subsequent) pulse is not possible by design, u.zw. because the receiving electronics are reflected by age reflections or the backscattering of an emitted pulse to components of the rangefinder, e.g. Housing or mounting parts or an exit window of the same, saturated or overloaded and thus "blind" for the reception of a reflected pulse.At each boundary between two MTA zones thus remains a receiving gap, a so-called "blind range" in the distance measurement , Reflections on environmental targets at such a distance can not be received at all - or in pulse position modulation only in individual cases and thus only with very little time or spatial resolution.
    The invention has as its object to provide a method of distance measurement of environmental targets by which the effects of blind ranges on MTA zone boundaries are reduced or even eliminated.
    This object is achieved by a method for distance measurement of environmental targets by propagation time measurement of pulses reflected therefrom, in particular laser pulses, which are transmitted in accordance with a prescriptive pulse repetition rate successively each at a transmission time and received after ih rer reflection to a receiving time, which method comprises:
    Selecting a first pulse repetition rate from a set of at least two different pulse repetition rates and specifying the selected pulse repetition rate for the transmission,
    Determining a transmission time which is closest in time to the reception time of a reflected pulse, and a time interval between them, and if the determined time interval falls below a predetermined first threshold value, selecting a second pulse repetition rate from the quantity and setting the second pulse repetition rate for the transmission ,
    The method is based on the knowledge that even with large-area scanning, e.g. the airborne scanning of terrain, especially at the now achievable very high pulse repetition rates and the resulting very high density measurement point and thus spatial resolution, and even more when distance measuring moving environment targets large differences in the pulse durations of successively received pulses are very rare. Therefore, the reception timings of the successively received pulses reflected at the surrounding destinations generally approach the transmission timings at one and the same pulse repetition rate of successively transmitted pulses slowly and approximately equally, i.e., at the same time. a terrain course approaches a blind range in practice mostly gradually. According to the present method, if the reception time of a reflected pulse comes too close to the transmission time of a transmission pulse, the terrain is thus approaching a blind range, the following transmission time shifted by specifying a different pulse repetition rate and thus a different pulse spacing, which proportionally the blind ranges in their distance to the laser scanner or rangefinder be offset. By selectively displacing or displacing the blind ranges, the reflection of a reflection at a transmission time and thus a reception gap are very effectively prevented, if the above-mentioned first threshold value is set appropriately.
    The present method is also useful with all known in the art for the proper mutual assignment of the transmit and receive pulses, i. for detection of the MTA zone, combinable; when using pulse position modulation methods, the pulse repetition rates from the said quantity correspond in each case to a mean pulse repetition rate of the pulse position modulation.
    According to a preferred embodiment of the invention, the reciprocal of the largest pulse repetition rate and the reciprocal of the smallest pulse repetition rate from the set differ from one another by at least twice the first threshold value. In this way, in the practical case that the pulse durations of successive pulses do not change abruptly but only gradually, a collapse of the transmission and reception time or of the surrounding area distance and blind range is avoided particularly reliably since the difference in the pulse repetition rates is so great in that the following transmission times have been postponed sufficiently far.
    Depending on whether a reception time is close to the last or the next transmission time or whether an environmental target from the viewpoint of the laser scanner before or after a near blind range, the setting of a different pulse repetition rate thus acts either as a "retreat" of the blind range the environmental target or how to "skip" the environment target; The next following transmission time will therefore be either further away from the following reception time ("retreat") or its time sequence will be reversed ("skip").
    In order to achieve a purposeful skipping or retreating, in a particularly preferred embodiment of the method, if the transmission time determined when the first threshold value is undershot is before the said reception time, the second or the next highest repetition rate, or if none, the smallest pulse repetition rate the set selected, and, if the detected when falling below the first threshold transmission time is after said receiving time point, as the second pulse repetition rate, the next smallest or, if none available, the largest pulse repetition selected from the set. By thus shifting the transmission times and offsetting the blind ranges, their effect can be selectively suppressed.
    It is furthermore particularly favorable if, in the case where the determined period of time exceeds a fixed second threshold value, which is greater than the first threshold value, the second or highest pulse repetition rate from the set is selected as the second pulse repetition rate. In this way, the distance measurement method returns to the highest possible pulse repetition rate more rapidly after skipping the blind ranges, thereby faster achieving a higher or the highest possible time resolution.
    The invention will be explained in more detail with reference to embodiments illustrated in the accompanying drawings. In the drawings show:
    1 is a schematic example of the pulse transit time distance measurement of a terrain course by means of an airborne laser scanner according to the prior art;
    FIG. 2 shows exemplary timing diagrams of transmit and receive pulses for various steps and variants of the method of the invention; FIG.
    FIG. 3 shows exemplary variants of an application of the method according to the invention of FIG. 2 to the situation of FIG. 1 with an associated diagram of pulse repetition rates over the scanning angle or the time; and FIGS. 4a to 4h show different variants of the method of FIGS. 2 and 3 in diagrams of pulse repetition rates over the scanning angle or the time.
    According to the example of FIG. 1, an aircraft-based laser scanner 1 scans a pulsed laser measuring beam 2 over a terrain course V, e.g. a mountain, with individual environmental targets (sampling points) Ui, U2, ..., generally U, guided, e.g. fan-shaped line by line. From transit time measurements at the individual emitted pulses Si, S2,..., Generally S, which are received back after the ambient reflection as receive pulses Ei, E2,..., Generally E, the target distances Di, D2, D, to the individual environmental targets U are determined.
    The laser scanner 1 operates at a very high pulse repetition rate (PRR) and thereby determines the target distances D of a plurality of environmental targets U in rapid succession, thereby enabling a high time or spatial resolution with a short overall measurement duration. If an environmental target U, e.g. Ui, from the laser scanner 1 farther than it corresponds to the quotient of the speed of light c and double pulse repetition rate PRR, the next transmission pulse S is already transmitted before the reflection E of the last transmitted pulse S has been received. The incoming received pulses E can no longer be unambiguously assigned to their respective transmit pulse S. This is known as "multiple time round" (MTA) or "multiple pulses in the air" problem. In the example of FIG. 1, five distinct measurable distance ranges, also called "MTA zones", Z.sub.z, Z.sub.2,..., Z.sub.5, in general Z, are formed in this way, the widths of which are respectively dmax = c / (2 × PRR).
    Zone boundaries G1 (2, G2, 3,..., Generally G, between in each case two MTA zones Z thus represent that distance from the laser scanner 1 beyond which there is another "pulse in the air." If an environmental target U2 is present a zone boundary G, here: the zone boundary G4,5, so the reflected pulse E arrives at the time of sending a following transmission pulse S at the laser scanner 1 and can for the reasons mentioned by device-Nahreflexionen or backscattering of the transmitted pulses S in the Ambient targets U at the zone boundaries G are thus invisible to the laser scanner 1, so that around each zone boundary G forms a blind area or a "blind range" B whose width b depends, inter alia, on the width or duration of the transmitted pulse S and the removal of disturbing near targets in the laser scanner 1, eg housing parts or passage windows Erlauf V in the example of FIG. 1, three concrete areas Bi, B2 and B3 arise at the zone boundaries G4,5 and G3,4, in which no environmental objectives U can be detected.
    With reference to various examples shown in FIGS. 2 to 4, a method for the pulse transit time will now be described.
    Distance measurement described which reduces or avoids the impact of blind ranges B.
    According to FIGS. 2 and 3, three exemplary transmission pulses Sk, Sk + i, Sk + 2 (shown in the diagram of FIG. 2 as transmit pulse power Ps over time t) with a predetermined first mutual pulse spacing ii, which is the reciprocal 1 / PRRi of a first pulse repetition rate PRRi is sent out sequentially at a transmission timing TSk, TSk + i, TSk + 2, respectively. The first pulse repetition rate PRRi is selected from a set M = {PRRi} (i = 1, 2,..., I; I> 2) of at least two different pulse repetition rates PRRi, as explained in more detail later. Accompanyingly, at reception times TEk, TEk + i, ... receive pulses Ek, Ek + i, ... (shown in the diagram of FIG. 2 as received pulse power PE over time t) are received by the laser scanner 1.
    In order to simplify the explanation of the present method, in the example of FIGS. 2 and 3 the same index k is used for the received pulse E assigned to a respective transmit pulse S and the temporal superimposition of the transmit and receive pulse trains Ps (t) and PE selected in FIG (t) suggests environmental targets U in the first MTA zone Z ±; for targets U in other MTA zones, such as the targets Uk, Uk + i, Uk + 2 in the fourth and fifth MTA zones Z4, Z5, there is a corresponding time offset between the two pulse trains Ps (t) and PE ( t) in Fig. 2 to be considered. The corresponding MTA zone-correct assignment of the transmit and receive pulses S, E of the two pulse trains Ps (t) and PE (t) can be carried out independently of the present method in any manner known in the art and is not further described here ,
    It is understood that the mutual distance of the received pulses E does not depend exclusively on the pulse spacing (in this case: τι) of the associated transmission pulses S, but also on the distance of the respectively surrounding environmental targets U. Therefore, in the example of FIG. 2, the reception times TEk approach , TEk + i, and TEk + 2 are progressively applied to the nearest transmission times TSk, TSk + i and TSk + 2, respectively, as in the example of Fig. 3 in a line-by-line scanning scan in an angular range between the sampling limit angles and from left to right, continuously reduce the target distances Dk, Dk + i, Dk + 2 of three sampled environmental targets Uk, Uk + i, Uk + 2 from the laser scanner 1.
    According to FIG. 2, upon receiving a reflected reception pulse Ek, the transmission time TS closest to its reception time TEk (here: the transmission time TSk) and a time interval Ak between these two are determined. Subsequently, it is checked whether the determined period of time Ak falls below a fixed first threshold, i. whether the reception time TEk is within a window which extends with the "width" of the first threshold value σι to the left and to the right of the next-average transmission time TSk in the example of Fig. 2, this does not apply to the reception pulses Ek, Ek + i on the other hand, the time interval Ak + 2 determined for the time of reception TEk + 2 of the third receiving pulse Ek + 2 is shorter than the first threshold value o ± at the time closest to the transmission time TSk + 2, if desired, such a time period Ak, Ak +; ... are also determined only for every second received pulse E or more rarely, for example as a function of a previously determined time period Ak_i, Ak_2,...
    In the case of the undershooting of the first threshold value o ±, a second pulse repetition rate PRR2 is selected from the stated quantity M = {PRR ±} and predefined for the subsequent transmission of transmission pulses S, here: Sk + 3, Sk + 4. The transmission pulses
    Sk + 2, Sk + 3 and Sk + 4 thus have a mutual pulse spacing τ2, which corresponds to the reciprocal 1 / PRR2 of the second pulse repetition rate PRR2 and differs from the first pulse spacing ii by an amount Δτ, see the hypothetical transmission time TS'k + 3 in FIG. 2 with pulse interval ii from the transmission time TSk + 2. The zone boundaries G thereby shift from the positions shown by solid lines to the positions shown by dashed lines, e.g. the border G4j5 to the border G'4,5.
    3 shows such a selection of the second pulse repetition rate PRR2 from the set M at a scanning angle θι in a diagram of the pulse repetition rates PRR over the scanning angle ü and the time t as a jump from the first pulse repetition rate PRRi to the (smaller) second pulse repetition rate PRR2; this can also be taken from the schematic diagram of FIG. 4a. The alternative case for this example that the first pulse repetition rate PRRi is smaller than the second PRR2 is shown in FIG. 4b.
    The temporal approach of the reception time TEk + 2 to the transmission time TSk + 2 (FIG. 2) can also be seen in FIG. 3 by the terrain course V at the scanning angle dr, as it were, in a local section Ai corresponding to the first threshold value σλ about the zone boundary G4 (FIG. By specifying the first threshold α ±, the section Ai, for example, has approximately the same width b (Figure 1) as the blind ranges B, but may alternatively be wider or (less preferably) narrower ,
    Returning to the example of FIG. 2, the next transmission time TSk + 3 after the aforementioned pulse repetition rate change from PRRi to PRR2 is now sufficiently distant from the next occurring reception time TEk + 3, in this example thereafter; Fig. 3 shows this skipping as an offset of the zone boundary from G4j5 (due to the first pulse repetition rate PRRi) to G'4,5 (due to the second pulse repetition rate PRR2), as it were the blind range B at the scanning angle üi the terrain course V "skips". For this purpose, furthermore, the first threshold value σι could optionally be determined as a function of the respectively considered MTA zone Z.
    Alternatively to such skipping, by appropriate selection of a different pulse repetition rate PRR
    Quantity M, a "retreat" of the transmission times S with respect to the reception times E or a zone boundary G with respect to the terrain V are realized, as for the Abtastwinkelbereich ü2 to ü3 in the example of Fig. 4a for a set M of two and in the example of FIG. In the latter example, starting from the lowest pulse repetition rate (here: PRR2), the next higher pulse repetition rate first approaches the course of the terrain V to the laser scanner 1 and the zone boundary G'3,4 PRR3 and on further approaching the new resulting zone boundary the even higher pulse repetition rate PRR4 specified, etc. etc., up to the highest pulse repetition rate (here: PRRi) .On further approach, a retreat is not possible because of lack of higher pulse repetition rates PRRi in the set M; in this case the scanning angle 33 is the smallest momentum value Rhol rate (here: PRR2) of the set M selected and thereby skipped the terrain V, see Figs. 3 and 4a.
    Fig. 4c shows the same situation for a set M with a plurality of pulse repetition rates PRRi as quasi-continuous, ramped course. In Fig. 4d, this situation is shown for the opposite example, with the course of the terrain V approaching a zone boundary G with removal from the laser scanner 1, so that the specification of ever smaller pulse repetition rates PRRi of the set M initially leads to a retreat and when the smallest one reaches Pulse repetition rate PRRi the setting of the largest pulse repetition rate PRR ± the amount M skipping results, as is shown for a set M = {PRR1 (PRR2} of two pulse repetition rates PRRi for the scanning angle ü5 to ü6 in the example of FIG.
    As can be seen from these examples, the reciprocal (in the example of Fig. 2: the pulse interval ii) of the largest pulse repetition rate (here: PRRi) and the reciprocal (here: the pulse interval τ2) of the smallest pulse repetition rate (here: PRR2) differ the amount M of each other by at least twice the first threshold σι; if the reception of individual reflected pulses can be dispensed with, the difference of the mentioned reciprocals could also be smaller.
    In practice, it is favorable if the highest pulse repetition rate PRRi from the set M (in the present example: PRRi) is given as often as possible, since this causes the fastest pulse sequence and thus the highest possible measurement resolution. For this purpose, a terrain course V removing from a zone boundary G is optionally "hurried", as will be explained below with reference to the scanning angle θ4 and for the receiving pulse Ek + 5 in the examples of FIGS. 2 and 3.
    For this purpose, a second threshold value σ 2, which is greater than the first threshold value σ 1 (and thereby a second location section A 2 (FIG. 3), is established.) The time period k k + 5 of the reception time T TE + 5 to the nearest transmission time T k + 5 exceeds this second threshold value σ 2 which has not yet been the case for the time period uk + 4 at the time of reception TEk + 4, and the contour V leaves the section A2 at the scanning angle θ4, thus selecting the next larger or equal to the largest pulse repetition rate (here: PRRi) from the set M. The time period ük + 5 can, as in the example shown, already starting from the transmission time TSk + 5 changed according to the newly selected pulse repetition rate PRRi - according to FIG. 3, the portion A2 lies at the zone limit G3,4 of the newly selected pulse repetition rate PRRi. or alternatively, starting from the transmission time TS'k + 5, ie based on the last predetermined pulse repetition rate PRR2 determined become.
    By the interaction of the first and second threshold σι, σ2 as a hysteresis is generated: Approach the reception times TE the transmission times TS or the terrain V of a blind range B, so that the first threshold is below Gi, then there is a retreat or skip , see the scanning angles θι, θ2 and ü3 in the example of Fig. 3; if neither the first threshold value Gi is exceeded nor the second threshold value σ2 exceeded, then no new pulse repetition rate PRRi is selected from the set M, which occurs only when the second threshold value σ2 is exceeded; If, as a result, the second threshold value σ2 is again undershot by renewed approach, the pulse repetition rate PRRi remains unchanged until the first threshold value G1 is undershot.
    It is understood that the mentioned lag - as well as the previously described retreat - on the one hand at a set M of two pulse repetition rates PRRi jump-shaped (as in the scanning angle ü4 in Fig. 3) or on the other hand at a larger amount M of pulse repetition rates PRRi multi-stage or ramped (Figure 4e) or, eg with larger difference between the first and second threshold o ±, o2 as in the example of Fig. 4f, can be done ramp-shaped with kink, u.zw. on the one hand with the laser scanner 1 according to FIGS. 4e and 4f approaching and on the other hand with itself from the laser scanner 1 according to the example of Fig. 4g removing terrain V. Furthermore, the retreat or lag could also be approximately S-shaped (Fig. 4h). FIG. 4h also illustrates the particular case in which the terrain course V approaching a zone boundary G is initially dodged, but the course of the terrain V is again removed in the sequence, so that a hurrying without skipping becomes possible.
    The invention is not limited to the illustrated embodiments, but includes all variants, combinations and modifications that fall within the scope of the appended claims. For example, the distance measurement could be based on general light pulses, radio pulses, in particular radar pulses, sound pulses or the like. and / or-of-stationary or mobile-ground, air or sea-based scanners or rangefinders, which are directed, for example, to mobile environmental targets U.
    权利要求:
    Claims (4)
    [1]
    claims:
    1. A method for measuring the range of environmental targets (U) by transit time measurement of pulses reflected therefrom, in particular laser pulses, which are emitted according to a predetermined pulse repetition rate (PRR) successively each at a transmission time (TS) and received after their reflection in each case to a receiving time point (TE) comprising: selecting a first pulse repetition rate (PRRi) from a set (M) of at least two different pulse repetition rates (PRRi) and specifying the selected pulse repetition rate (PRRi) for the transmission, determining a transmission time (TS) which corresponds to the reception time (TE ) of a reflected pulse (E) is closest in time, and a time span (Δ) between them, and, if the determined time interval (Δ) falls below a fixed first threshold value (σι), selecting a second pulse repetition rate (PRR2) from the set ( M) and setting the second pulse repetition rate (PRR2) for the transmission.
    [2]
    2. The method according to claim 1, characterized in that the reciprocal of the largest pulse repetition rate (PRRi) and the reciprocal of the smallest pulse repetition rate (PRR2) from the set (M) differ from each other by at least twice the first threshold value (σι).
    [3]
    3. The method according to claim 2, characterized in that when the falls below the first threshold (σι) determined transmission time (TS) before said reception time (TE), as the second pulse repetition rate (PRRi) is the next larger or, if none exist , the smallest pulse repetition rate (PRRi) from the set (M) is selected, and, if the below when the first threshold (σι) determined transmission time (TS) after said reception time (TE), as the second pulse repetition rate (PRRi) the next smaller or, if none exist, the largest pulse repetition rate (PRR ±) is selected from the set (M).
    [4]
    4. The method according to any one of claims 1 to 3, characterized in that when the determined time period (Δ) exceeds a predetermined second threshold value (σ2), which is greater than the first threshold value (σι), as a second pulse repetition rate (PRRi) the next larger or largest pulse repetition rate (PRRi) is selected from the set (M).
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50491/2015A|AT517300B1|2015-06-15|2015-06-15|Method for distance measurement|ATA50491/2015A| AT517300B1|2015-06-15|2015-06-15|Method for distance measurement|
    US15/579,288| US10725155B2|2015-06-15|2016-06-14|Method for measuring a distance|
    CA2984362A| CA2984362A1|2015-06-15|2016-06-14|Method for measuring a distance|
    PCT/AT2016/050196| WO2016201469A1|2015-06-15|2016-06-14|Method for measuring a distance|
    EP16735981.9A| EP3308195B1|2015-06-15|2016-06-14|Method for measuring a distance|
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