TW201510958A - Method of orientating calibration for aircraft approach guiding system - Google Patents
Method of orientating calibration for aircraft approach guiding system Download PDFInfo
- Publication number
- TW201510958A TW201510958A TW102133309A TW102133309A TW201510958A TW 201510958 A TW201510958 A TW 201510958A TW 102133309 A TW102133309 A TW 102133309A TW 102133309 A TW102133309 A TW 102133309A TW 201510958 A TW201510958 A TW 201510958A
- Authority
- TW
- Taiwan
- Prior art keywords
- point
- horizontal
- distance
- line
- laser beam
- Prior art date
Links
Landscapes
- Length Measuring Devices By Optical Means (AREA)
- Optical Radar Systems And Details Thereof (AREA)
Abstract
Description
本發明乃是關於一種航空器進場導引系統的校正定位方法。特別是指一種利用雷射光束及資訊顯示看板用以定位、識別並且導引目標物到特定地點停靠過程的校正定位方法。 The invention relates to a method for correcting and positioning an aircraft approach guidance system. In particular, it refers to a method of correcting positioning using a laser beam and an information display kanban to locate, identify, and guide a target to a specific location.
航空器的進場導引作業,先前使用的技術包括人工導引方式、以環路線圈感測技術的導引方式及較為先進的以雷射偵測技術的導引方式。 The aircraft's approach guidance operation, the previously used techniques include manual guidance, guidance by loop coil sensing technology and more advanced guidance methods using laser detection technology.
以雷射偵測方式的導引方式在處理定位及J-LINE每位移的方式上,先前的專利例如有美國專利號US 6,023,665及US 6,324,489,以距離角度分佈圖的方式,在垂直方向上,雷射導引設備前約1至100米,每隔一米做一記錄點,及水平方向上,從-5°到5°間,每隔0.1°的範圍內做一記錄點,交叉成一個100 X 100的資料庫記錄區。當航空器進入此一區域時,在比對實際偵測到的數值與預存資料庫之間的差異性,以判定航空器的所在距離及左右偏移情形。 In the manner of laser detection, in the manner of processing the positioning and J-LINE per displacement, the prior patents include, for example, US Patent Nos. US 6,023,665 and US 6,324,489, in the vertical direction, in a distance angle map. About 1 to 100 meters in front of the laser guiding device, make a recording point every one meter, and in the horizontal direction, from -5° to 5°, make a recording point every 0.1°, cross into one 100 X 100 database record area. When the aircraft enters this area, the difference between the actual detected value and the pre-stored database is compared to determine the distance of the aircraft and the left-right offset.
該做法雖然在技術上是可行,但由於一方面牽涉到數量龐大的數值比對,另方面現行市面上大部份的雷射測距設備已不支援純粹對雷射脈波做發射/收集的動作,只提供雷射所在角度上所測得的距離資料。對於此類的應用方式,必需使用特別的雷射測距設備才能達到,所以在應用上並不方便。 Although this method is technically feasible, it involves a large number of numerical comparisons on the one hand. On the other hand, most of the laser ranging devices currently on the market do not support the pure emission/collection of laser pulses. The action only provides the distance data measured at the angle of the laser. For this type of application, special laser ranging equipment must be used to achieve this, so it is not convenient in application.
本案發明人基於已申請中華民國專利申請號102211977『航空器進場導引系統』,使用現有先進的雷射測距設備及步進馬達,配合所提出的演算法即可達到對特定位置點的馬達初始位置(home position)定位及對航空器進場導引線偏移校正的目的。改善導引作業中所需要的設備等級及運算效率。例如航空器在降落後,要停靠到機場閘門特定停止線上時,需藉助於導引系統執行導引及機型辨識作業。導引系統的裝設位置受限於機場的建築物結構,而航空器的進場路線與機坪位置有關,當兩者無法在同一直線上時,導引過程中的偵測作業就必須有一套偏移校正方法,以確保機型辨識與導引距離及偏移角度偵測的正確性。 The inventor of the present invention based on the application for the Republic of China Patent Application No. 102211977 "Aircraft Approach Guidance System", using the existing advanced laser ranging equipment and stepping motor, with the proposed algorithm can reach the motor at a specific position Home position positioning and the purpose of offset correction for aircraft approach guides. Improve the equipment level and computational efficiency required for guiding operations. For example, when the aircraft is landing, it is necessary to use the guidance system to perform guidance and model identification operations when docking to the specific stop line of the airport gate. The installation position of the guidance system is limited by the structure of the airport, and the approach route of the aircraft is related to the position of the apron. When the two cannot be on the same line, the detection operation during the guidance must have a set. Offset correction method to ensure correctness of model identification and guidance distance and offset angle detection.
本發明所要解決的技術問題,在於提供一種航空器進場導引系統的校正定位方法,首先需要先能執行定位作業,也就是雷射光束的定位作業,包括垂直方向與水平方向的初始位置定位。所謂垂直方向的定位,就是設定用以控制雷射光束之垂直馬達的初始位置(vertical home position),可以使此時的雷射光束剛好平行於量測物所在的地平面,例如機坪地面。上述水平方向的定位,就是針對雷射掃瞄器前方的某一點,設定用以控制雷射光束之水平馬達的初始位置(horizental home position),可以使此時的雷射光束可以剛好打在目標點上。 The technical problem to be solved by the present invention is to provide a method for correcting and positioning an aircraft approaching guidance system. First, it is necessary to perform a positioning operation, that is, a positioning operation of a laser beam, including initial positional positioning in a vertical direction and a horizontal direction. The so-called vertical positioning is to set the vertical home position of the vertical motor for controlling the laser beam, so that the laser beam at this time is just parallel to the ground plane where the measuring object is located, such as the apron ground. The above horizontal orientation is to set a horizontal home position for controlling the horizontal beam of the laser beam for a certain point in front of the laser scanner, so that the laser beam at this time can just hit the target. Point.
此外,本發明所要解決的技術問題,還在於提供偏移校正的方法,對於進場導引線與導引設備不在一直線上時的偏移調整的校正方法,以使雷射掃瞄器能針對航空器在不同的位置點上,做中心位置點的修正,對準正確的掃瞄區域,產生正確的掃瞄結果。 In addition, the technical problem to be solved by the present invention is also to provide a method for offset correction, which is a correction method for offset adjustment when the approach guide line and the guiding device are not in a straight line, so that the laser scanner can be targeted At different points in the aircraft, the center point is corrected and aligned to the correct scanning area to produce the correct scanning result.
為了解決上述技術問題,根據本發明之方案,提供一種航空器進場導引系統的校正定位方法,包括下列步驟:提供一雷射掃瞄器以產生雷射光束射向一反射鏡組; 分別沿著水平軸及垂直軸旋轉上述反射鏡組;掃瞄位於一前進線上的被偵測物;在一電腦的資料庫內設定雷射光束掃瞄範圍的水平中心座標及垂直的中心座標;設定雷射光束沿著水平方向的取樣間隔;設定雷射光束沿著垂直方向的取樣間隔;執行取樣作業,沿著上述的中心座標,分別向外相隔上述的取樣間隔沿著水平方向及垂直方向取複數個掃瞄點;執行掃瞄作業,依上述取樣的掃瞄點,測量每一點並記錄測得的距離;依照每點顯示的距離,判斷是否需要改變上述的中心座標;以及判斷上述取樣間隔是否需要調整;若要調整取樣間隔,則回到上述執行取樣作業的步驟,若不需要調整取樣間隔,則完成。 In order to solve the above technical problem, according to the solution of the present invention, a method for correcting positioning of an aircraft approach guidance system is provided, comprising the steps of: providing a laser scanner to generate a laser beam directed toward a mirror group; Rotating the mirror group along the horizontal axis and the vertical axis respectively; scanning the detected object on a forward line; setting a horizontal center coordinate and a vertical center coordinate of the laser beam scanning range in a computer database; Setting a sampling interval of the laser beam along the horizontal direction; setting a sampling interval of the laser beam along the vertical direction; performing a sampling operation along the central coordinate, respectively, respectively separating the sampling interval along the horizontal direction and the vertical direction Taking a plurality of scanning points; performing a scanning operation, measuring each point according to the scanning points sampled above, and recording the measured distance; determining whether the above-mentioned central coordinates need to be changed according to the distance displayed by each point; and judging the sampling Whether the interval needs to be adjusted; if the sampling interval is to be adjusted, return to the above step of performing the sampling operation, and if it is not necessary to adjust the sampling interval, it is completed.
其中依本發明的一實施例,為著完成上述另一技術問題,其中當該雷射掃瞄器的位置未位於上述前進線的線上,進一步執行偏移調整方法,利用線性插植法推估一預定點的距離。 According to an embodiment of the present invention, in order to accomplish the above other technical problem, wherein the position of the laser scanner is not located on the line of the forward line, the offset adjustment method is further performed, and the linear interpolation method is used to estimate The distance of a predetermined point.
本發明具有以下有益效果:本發明可供雷射掃瞄器對準於正確的掃瞄位置,再者,當進場導引線與雷射光束沒有辦法設定在同一條線上時,不管這兩條線之間是不是平行線,都可以依照此方法求得任何一位置的對應偏移校正量。 The present invention has the following beneficial effects: the present invention can be used to align the laser scanner to the correct scanning position, and further, when the approaching guide line and the laser beam are not set on the same line, regardless of the two Whether the lines are parallel lines or not, the corresponding offset correction amount of any position can be obtained according to this method.
為了能更進一步瞭解本發明為達成既定目的所採取之技術、方法及功效,請參閱以下有關本發明之詳細說明、圖式,相信本發明之目的、特徵與特點,當可由此得以深入且具體之瞭解,然而所附圖式與附件僅提供參考與說明用,並非用來對本發明加以限制者。 In order to further understand the technology, method and effect of the present invention in order to achieve the intended purpose, reference should be made to the detailed description and drawings of the present invention. The drawings and the annexed drawings are intended to be illustrative and not to limit the invention.
100‧‧‧雷射掃瞄器 100‧‧‧Laser scanner
10‧‧‧基座 10‧‧‧ Pedestal
102‧‧‧資訊顯示板 102‧‧‧Information display board
20‧‧‧固定框架 20‧‧‧Fixed frame
30‧‧‧可動框架 30‧‧‧ movable frame
40‧‧‧反射鏡組 40‧‧‧Mirror group
50‧‧‧第一旋轉模組 50‧‧‧First Rotary Module
52‧‧‧第一馬達 52‧‧‧First motor
60‧‧‧第二旋轉模組 60‧‧‧Second Rotary Module
62‧‧‧第二馬達 62‧‧‧second motor
70‧‧‧光源模組 70‧‧‧Light source module
200‧‧‧台車 200‧‧‧Trolley
201‧‧‧桿體 201‧‧‧ rod body
202‧‧‧偵測板 202‧‧‧Detection board
2021‧‧‧垂直參考桿 2021‧‧‧Vertical reference rod
2022‧‧‧水平參考桿 2022‧‧‧ horizontal reference rod
Xa、Ya‧‧‧取樣間隔 Xa, Ya‧‧ ‧ sampling interval
R‧‧‧雷射光束 R‧‧‧Laser beam
J‧‧‧進場導引線 J‧‧‧ Approach guide line
A‧‧‧空橋 A‧‧‧ empty bridge
B‧‧‧機場建築物 B‧‧‧Airport buildings
F‧‧‧前進線 F‧‧‧Foreign line
S‧‧‧停止線 S‧‧‧Stop line
M‧‧‧掃瞄區域 M‧‧ ‧ scan area
圖1為本發明利用的航空器進場導引系統。 1 is an aircraft approach guidance system utilized by the present invention.
圖2為航空器沿著地面的進場導引線前進的示意圖。 Figure 2 is a schematic illustration of the advancement of the aircraft along the approach guide line of the ground.
圖3為本發明之校正定位方法沿著X軸取樣的示意圖。 3 is a schematic diagram of sampling of the calibration positioning method of the present invention along the X-axis.
圖4為本發明之校正定位方法沿著Y軸取樣的示意圖。 4 is a schematic view of the calibration positioning method of the present invention taken along the Y-axis.
圖5為本發明之校正定位方法的流程圖。 FIG. 5 is a flowchart of a method for correcting positioning according to the present invention.
圖6為本發明之偏移調整的俯視示意圖。 Figure 6 is a top plan view of the offset adjustment of the present invention.
圖7為本發明之偏移調整的流程圖。 Figure 7 is a flow chart of the offset adjustment of the present invention.
本案發明人利用基於上述先前專利之結構分散而安裝複雜,已申請中華民國專利申請號102211977『航空器進場導引系統』,特別是指一種用以供定位、識別並且追蹤目標物體,例如應用於機場在航空器降落後,量測航空器距離預定點(SPOT)的距離,以供導引航空器移動至正確的位置,或者應用於其他的地面交通工具。 The inventor of the present invention has been complicated to install by using the structure of the above-mentioned prior patents, and has applied for the Republic of China Patent Application No. 102211977 "Aircraft Approach Guidance System", particularly for locating, identifying and tracking a target object, for example, The airport measures the distance of the aircraft from the predetermined point (SPOT) after the aircraft has landed to guide the aircraft to the correct position or to other ground vehicles.
基於上述專利,本實施例以上述航空器進場導引系統(以下簡稱導引系統,或稱之為雷射掃瞄器)配合說明本案的校正定位方法。請參閱圖1以下再簡述本發明利用的航空器進場導引系統,其包括一基座10、一固定於該基座10上且大體呈方形的固定框架20、一架設於固定框架20內且大體呈U形的可動框架30、一架設於可動框架30的反射鏡組40、用以驅動可動框架30沿Y軸轉動的第一旋轉模組50、用以驅動反射鏡組40沿X軸轉動的第二旋轉模組60、及一光源模組70。其中可動框架30沿著一垂直於基座10的垂直軸Y可旋轉地架設於固定框架20上。反射鏡組40沿著一平行於基座10的水平軸X可旋轉地架設於可動框架30上。第一旋轉模組50利用第一馬達52沿著上述垂直軸Y以驅動上述可動框架30;第二旋轉模組60利用第二馬達62沿著上述水平軸X以驅動上述反射鏡組。光源模組70固定地架設於可動框架30且 提供射向一反射鏡組40的雷射光束R。上述主要是本案使用的導引系統的雷射掃瞄器100,導引系統還包括資訊顯示板102…等,關於導引系統的細節已載於上述本發明人的專利申請案,因此容不贅述。 Based on the above patent, this embodiment cooperates with the above-mentioned aircraft approach guidance system (hereinafter referred to as a guidance system, or laser scanner) to explain the correction positioning method of the present invention. Referring to FIG. 1 , the aircraft approach guiding system utilized by the present invention is further described below, which includes a base 10 , a substantially square fixed frame 20 fixed to the base 10 , and a rack mounted in the fixed frame 20 . And a substantially U-shaped movable frame 30, a mirror group 40 disposed on the movable frame 30, a first rotating module 50 for driving the movable frame 30 to rotate along the Y-axis, and driving the mirror group 40 along the X-axis The rotating second rotating module 60 and a light source module 70. The movable frame 30 is rotatably mounted on the fixed frame 20 along a vertical axis Y perpendicular to the base 10. The mirror group 40 is rotatably mounted on the movable frame 30 along a horizontal axis X parallel to the base 10. The first rotation module 50 drives the movable frame 30 along the vertical axis Y by the first motor 52. The second rotation module 60 drives the mirror group along the horizontal axis X by the second motor 62. The light source module 70 is fixedly mounted on the movable frame 30 and A laser beam R directed to a mirror group 40 is provided. The above is mainly the laser scanner 100 of the guiding system used in the present case, and the guiding system further includes an information display panel 102, etc., and details about the guiding system have been described in the above-mentioned inventor's patent application, so Narration.
本實施例利用高精密的步進控制馬達,配合反射鏡面來定位雷射光束的角度,定位解析度可以達到水平0.018°/step,垂直方向0.036°/step。由於步進馬達的刻度很精細,在360°的角度內,可以區分為10,000步的解析度,所使用的雷射光又是在紅外線範圍內的不可見光。如何可以達到設定目的,可使雷射光剛好投射到標的物的位置上,就是本發明所謂的校正定位作業。 In this embodiment, a high-precision step-control motor is used, and the angle of the laser beam is positioned with the mirror surface, and the positioning resolution can reach a level of 0.018°/step and a vertical direction of 0.036°/step. Since the scale of the stepping motor is very fine, it can be distinguished into a resolution of 10,000 steps in the angle of 360°, and the laser light used is invisible light in the infrared range. How to achieve the setting purpose, the laser light can be projected to the position of the target object, which is the so-called correction positioning operation of the present invention.
如圖2所示,為航空器沿著地面的進場導引線J(J-LINE),進場導引線J為航空器進場靠近空橋A時所依循的前進線,進場導引線J的畫設取決於機場為航空器的前進動線,無法任意更改。因此,本發明提供正方法以供雷射掃瞄器100能對準於正確的掃瞄區域,例如可應用於導引系統安裝完成以後,或者使用一段時間以後,甚至在每次使用前,均執行本發明的校正定位方法,藉此以產生正確並有效的距離掃瞄結果。 As shown in Fig. 2, it is the approach guide line J (J-LINE) of the aircraft along the ground. The approach guide line J is the forward line followed by the aircraft approaching the empty bridge A. The approach guide line J's paintings depend on the airport's forward movement and cannot be changed at will. Accordingly, the present invention provides a positive method for the laser scanner 100 to be aligned to the correct scanning area, for example, after the guiding system is installed, or after a period of use, even before each use. The correct positioning method of the present invention is performed whereby a correct and efficient distance scan result is produced.
再者,航空器導引系統的位置常需受限在機場建築物B的水泥牆面上才可以裝設,玻璃牆面無法裝設,以圖2的位置,顯然雷射光束R與導引航空器的進場導引線J無法為同一條線或甚至是平行線上。因此,本發明還進一步在此環境下,做到能導引航空器。即使上述導引系統不是位於在航空器前進的路線上,每一個掃瞄點都要能估算其中心點位置。因此本發明進一步提出一偏移調整方法來補償,以取得正確的距離。 Furthermore, the position of the aircraft guidance system is often limited to be installed on the cement wall of the airport building B. The glass wall surface cannot be installed. In the position of Figure 2, the laser beam R and the guided aircraft are apparent. The approach guide line J cannot be the same line or even a parallel line. Therefore, the present invention is further capable of guiding an aircraft in this environment. Even if the above guidance system is not located on the route forward of the aircraft, each scan point must be able to estimate its center point position. Therefore, the present invention further proposes an offset adjustment method to compensate for the correct distance.
首先,說明本發明的校正定位方法之原理。雷射光束碰到被偵測物(例如航空器)時會依照光學原理反射回來,利用光線來回所經過的時間,即可回算出雷射掃瞄器(或導引系統)與被偵測物之間 的距離。如圖2所示,假設將雷射掃瞄器100放置在一預定高度H上,對一固定角度掃瞄,若該掃瞄位置上沒有任何遮蔽物,那麼雷射光束將會碰到地面後反射回來,傳回雷射掃瞄器100與地面間的距離。如果雷射掃瞄器100與地面間有一遮蔽物,則雷射偵測到的距離便會是其與該被偵測物之間的距離。因為被偵測物(例如航空器)有一定的高度,所以測得的距離與沒有該被偵測物的情況有明顯的分別。根據這樣距離的分別,本實施例可藉以推定被偵測物(例如航空器)的存在。 First, the principle of the correction positioning method of the present invention will be explained. When the laser beam hits the detected object (such as an aircraft), it will be reflected back according to the optical principle. By using the time that the light passes back and forth, the laser scanner (or guiding system) and the detected object can be calculated. between the distance. As shown in FIG. 2, it is assumed that the laser scanner 100 is placed at a predetermined height H for a fixed angle scan. If there is no obstruction at the scanning position, the laser beam will hit the ground. Reflected back, the distance between the laser scanner 100 and the ground is returned. If there is a shield between the laser scanner 100 and the ground, the distance detected by the laser will be the distance between it and the object to be detected. Since the detected object (such as an aircraft) has a certain height, the measured distance is significantly different from the case without the detected object. Based on the difference in such distances, the present embodiment can be used to estimate the presence of a detected object (e.g., an aircraft).
請配合圖3及圖4,為本發明之定位方法的示意圖,並請參閱圖5,為本發明之校正定位方法的流程圖。本發明設計一個特殊形狀的被偵測物,此實施例為一台車200,台車200主要包括由二根桿體201立起的偵測板202。偵測板202還需要設有一垂直參考桿2021及一水平參考桿2022以模擬飛機的橫向機翼或引擎。當以雷射掃瞄附近區域時,就可以掃出一個特定的距離分佈圖。根據此分佈情形,本發明即可以據以判定被偵測物相對於雷射掃瞄器100所在的方位。 Please refer to FIG. 3 and FIG. 4 , which are schematic diagrams of the positioning method of the present invention, and FIG. 5 is a flowchart of the calibration positioning method of the present invention. The present invention designs a specially shaped object to be detected. This embodiment is a vehicle 200. The trolley 200 mainly includes a detecting plate 202 which is erected by two rods 201. The detection board 202 also needs to be provided with a vertical reference rod 2021 and a horizontal reference rod 2022 to simulate the lateral wing or engine of the aircraft. When scanning a nearby area with a laser, you can sweep out a specific distance map. According to this distribution, the present invention can determine the orientation of the detected object relative to the laser scanner 100.
如圖5所示,首先,校正開始,如步驟A10,在校正目標點放置一校正用被偵測物,在本實施例中,校正目標點可以是位於地面的一前進線上,前進線可以是在機場的進場導引線J-LINE,或在室內校正用臨時劃設的直線。校正用被偵測物,可以是一台車200代替飛機,即可由人員方便配合校正定位過程移動。 As shown in FIG. 5, first, the calibration starts. In step A10, a calibration object is placed at the correction target point. In this embodiment, the correction target point may be a forward line on the ground, and the forward line may be At the airport, the guide line J-LINE, or the temporary alignment line for indoor calibration. The object to be detected for correction may be a vehicle 200 instead of an airplane, and the person can conveniently cooperate with the correction positioning process to move.
如步驟A11,在一電腦的資料庫內設定水平及垂直的中心座標(X0,Y0)。此中心座標(X0,Y0)在開始時不一定就對準於台車200的偵測板202,可以經過掃瞄後,依據掃瞄數據中,推論被偵測物(台車200)的存在處的座標而調整。 In step A11, the horizontal and vertical center coordinates (X 0 , Y 0 ) are set in a computer database. The center coordinates (X 0 , Y 0 ) are not necessarily aligned with the detection board 202 of the trolley 200 at the beginning, and after scanning, the presence of the detected object (the trolley 200) can be inferred based on the scan data. Adjusted at the coordinates of the place.
如步驟A12,設定雷射光束沿著水平方向(X軸)取樣間隔(scan interval)Xa,請配合圖3所示。此處的取樣間隔Xa,例如可以是20個步階(step),每一步階的角度依雷射掃瞄器的設備而定;步驟 A13,設定雷射光束沿著垂直方向(Y軸)取樣間隔(scan interval)Ya,請配合圖4所示。此處的取樣間隔Ya,例如可以是20至30個步階(step),此數值可以針對被偵測物調整。依本發明的雷射掃瞄器之垂直馬達(亦即上述第一馬達52)的定位解析度的每一步階(step),垂直方向(Y軸)可達到0.036°/step。水平馬達的定位解析度(亦即第二馬達62)的水平方向(X軸)可達到0.018°/step。 In step A12, the laser beam is set along the horizontal direction (X-axis) scan interval Xa, as shown in FIG. The sampling interval Xa here may be, for example, 20 steps, and the angle of each step depends on the device of the laser scanner; A13, set the laser beam along the vertical direction (Y-axis) scan interval Ya, please match Figure 4. The sampling interval Ya here may be, for example, 20 to 30 steps, and this value may be adjusted for the object to be detected. In each step of the positioning resolution of the vertical motor of the laser scanner (i.e., the first motor 52 described above), the vertical direction (Y-axis) can reach 0.036°/step. The horizontal resolution (X-axis) of the positioning resolution of the horizontal motor (i.e., the second motor 62) can reach 0.018°/step.
如步驟A14所示,執行取樣作業,本實施例的取樣作業的是沿著上述的中心座標,分別向外相隔上述的取樣間隔Xa、Ya沿著水平方向及垂直方向取複數個掃瞄點。具體的說,X軸方向從X0-N1*Xa到X0+N1*Xa,每隔一取樣間隔Xa取一點;Y軸方向從Y0-N2*Ya到Y0+N2*Ya,每隔一取樣間隔Ya取一點。此範圍也就是掃瞄區域M(參圖4)。在本實施例中,N1以及N2為取點數量,可以是5到7點,視實際需要加以調整。當取得更多點,掃瞄時間較長,範圍比較廣。若取點數量N1以5點計算,N2以7點計算,本實施例在X軸上將有11個掃瞄點(2*N1+1,左右各5點再加上中心座標點),Y軸將有15個掃瞄點(2*N2+1,上下各7點再加上中心座標點)。關於上述取樣間隔Xa、Ya,以及取樣中心座標(X0,Y0)可以是由操作人員在電腦輸入設定。 As shown in step A14, the sampling operation is performed. The sampling operation of this embodiment is along the above-mentioned central coordinates, and a plurality of scanning points are respectively taken along the horizontal and vertical directions from the sampling intervals Xa and Ya. Specifically, the X-axis direction is from X 0 -N 1 *Xa to X 0 +N 1 *Xa, taking one point every other sampling interval Xa; the Y-axis direction is from Y 0 -N 2 *Ya to Y 0 +N 2 *Ya, take a little every other sampling interval Ya. This range is also the scan area M (see Figure 4). In this embodiment, N 1 and N 2 are the number of points taken, which may be 5 to 7 points, and are adjusted according to actual needs. When you get more points, the scanning time is longer and the range is wider. If the number of points N 1 is calculated by 5 points and N 2 is calculated by 7 points, this embodiment will have 11 scanning points on the X axis (2*N 1 +1, 5 points on the left and right plus the central coordinate point). ), the Y-axis will have 15 scan points (2*N 2 +1, 7 points above and below plus the central coordinate point). The above sampling intervals Xa, Ya, and the sampling center coordinates (X 0 , Y 0 ) may be set by the operator at the computer input.
如步驟A15所示,執行掃瞄作業,依上述取樣的掃瞄點,測量每一點並記錄測得的距離。本實施例,共掃瞄(2*N1+1)*(2*N2+1)的矩陣數列,每一點記錄其測得的距離。本實施例中,掃瞄點的數量以為11*15=165點的矩陣數列。在X軸可以依取樣間隔Xa標明座標的距離數值,在Y軸可以依取樣間隔Ya標明座標的距離數值。此實施例中,較佳的,掃瞄作業的結果,亦即上述矩陣數列可以是依水平及垂直位置,顯示測得距離於螢幕上。更方便操作人員即時判斷。 As shown in step A15, the scanning operation is performed, and each point is measured and the measured distance is recorded according to the scanning points sampled above. In this embodiment, a matrix of (2*N 1 +1)*(2*N 2 +1) matrix is scanned, and each measured point is recorded. In this embodiment, the number of scanning points is a matrix of 11*15=165 points. In the X-axis, the distance value of the coordinate can be indicated by the sampling interval Xa, and the distance value of the coordinate can be indicated by the sampling interval Ya on the Y-axis. In this embodiment, preferably, the result of the scanning operation, that is, the matrix sequence may be a horizontal and vertical position, and the measured distance is displayed on the screen. It is more convenient for the operator to judge immediately.
如步驟A16所示,依照每點顯示的距離,判斷是否需要改變中心座標(X0,Y0),主要乃是依該掃瞄區域是否為被偵測物200 所在位置,考量是否需要改變中心座標(X0,Y0)。若是需要改變(Y),改變後再回到步驟A11,重新在電腦的資料庫內設定水平及垂直的中心座標(X0,Y0);若否(N),則不需要改變中心座標,意思是判斷中心座標所在的位置及其掃瞄區域,已顯示出被偵測物(台車200)。此處判斷的依據,亦即上述的校正定位原理,因為被偵測物(主要是觀察台車200的偵測板202)有一定的高度,所以測得的距離與沒有該被偵測物(台車200的偵測板202)遮蔽的情況有明顯的分別。藉此判斷被偵測物是否落在上述的掃瞄區域內。 As shown in step A16, according to the distance displayed by each point, it is determined whether the center coordinate (X 0 , Y 0 ) needs to be changed, mainly according to whether the scanning area is the position of the object to be detected 200, and whether the center needs to be changed. Coordinates (X 0 , Y 0 ). If it is necessary to change (Y), change back to step A11, and then set the horizontal and vertical center coordinates (X 0 , Y 0 ) in the computer database; if not (N), you do not need to change the center coordinates. This means that the position of the center coordinates and its scanning area are judged, and the object to be detected (trailer 200) has been displayed. The basis for the judgment here is the above-mentioned correction positioning principle, because the detected object (mainly the detection plate 202 of the observation trolley 200) has a certain height, so the measured distance and the object to be detected (the trolley) There is a clear distinction between the masking of the detection panel 202 of 200. Thereby, it is judged whether the detected object falls within the above-mentioned scanning area.
如步驟A17,判斷取樣間隔(Xa及Ya)是否需要調整,以更能對焦於被偵測物(台車200)。例如若取樣間隔更小,可以更明確的知道被偵測物的邊緣所在位置。若是(Y),要調整取樣間隔,則回到步驟A12,若不需要(N)調整取樣間隔,則校正作業完成。 In step A17, it is judged whether or not the sampling interval (Xa and Ya) needs to be adjusted to more focus on the object to be detected (the trolley 200). For example, if the sampling interval is smaller, the position of the edge of the detected object can be more clearly known. If it is (Y), to adjust the sampling interval, return to step A12. If it is not necessary to adjust the sampling interval (N), the calibration operation is completed.
本發明以圖4在具有天花板的室內實驗為例,配合圖5流程圖,舉例掃瞄後的矩陣數列,說明如下: The present invention takes an indoor experiment with a ceiling as an example in FIG. 4, and uses the flow chart of FIG. 5 to exemplify the matrix sequence after scanning, which is as follows:
首先,使用一台高度接近於雷射掃瞄器高度的偵測物,將該被偵測物(台車200)移到所希望定位的位置上,然後調整雷射掃瞄器100的掃瞄區塊角度,經過幾次的掃瞄與修正後,就可以得到該位置在雷射掃瞄器上的相對座標。 First, using a detector whose height is close to the height of the laser scanner, the object to be detected (the trolley 200) is moved to the desired position, and then the scanning area of the laser scanner 100 is adjusted. The block angle, after several scans and corrections, can get the relative coordinates of the position on the laser scanner.
例如,設定校正的中心座標(X0,Y0)=(1200,2200),此座標值為雷射掃瞄器100預設的相對座標。補充說明的是,上述座標值是依據本發明使用的雷射掃瞄器100的馬達可以達到10000步階(step)的解析度,然而,配合反射鏡組40的反射範圍,約在2500步階(step)以內。換言之,上述座標值主要是對照於雷射掃瞄器100的第二馬達62(水平馬達)及第一馬達52(垂直馬達)的位置點。 For example, set the corrected center coordinate (X 0 , Y 0 ) = (1200, 2200), which is the relative coordinate preset by the laser scanner 100. It should be noted that the above coordinate value is that the motor of the laser scanner 100 used in accordance with the present invention can achieve a resolution of 10,000 steps, however, the reflection range of the mirror group 40 is matched to about 2500 steps. Within (step). In other words, the above coordinate values are mainly compared with the position points of the second motor 62 (horizontal motor) of the laser scanner 100 and the first motor 52 (vertical motor).
本實施例中,X軸的取樣間隔為20步,Y軸的取樣間隔為20步,單位為步階(step);如下表一顯示的,矩陣數列的X軸座標值以1200為中心,向左依序減20,向右依序加20。Y軸座標值以2200為中心,向上依序減20,向下依序加20。X軸方向每一點的 對應角度數值為0.018度;Y軸方向每一點的對應角度數值為0.036度。 In this embodiment, the sampling interval of the X-axis is 20 steps, and the sampling interval of the Y-axis is 20 steps, and the unit is step; as shown in Table 1 below, the X-axis coordinate value of the matrix sequence is centered at 1200. The left is reduced by 20, and the right is added by 20. The Y-axis coordinate value is centered at 2200, and is sequentially decreased by 20 in the upward direction and 20 in the downward direction. Every point of the X-axis direction The corresponding angle value is 0.018 degrees; the corresponding angle value of each point in the Y-axis direction is 0.036 degrees.
從掃瞄結果來看,X軸位置在1160的位置會是被偵測物所在的位置,因為在Y軸部份,該處位置遮蔽高度較高。 From the scanning results, the position of the X-axis at 1160 will be the position of the object to be detected, because in the Y-axis portion, the position is highly shielded.
X軸座標大於1320,Y軸座標大於2140部份,都讀到>=149的數值,相較其他地方,較大的數值表示反射回來的偵測距離較遠,表示該方位沒有被台車200遮蔽,Y軸數值小於2120的部份表示讀到天花板位置,此部份是因為配合本實施例的雷射掃瞄器置於室內較靠近天花板的較高位置,進行測試。 The X-axis coordinate is greater than 1320, and the Y-axis coordinate is greater than 2140. The value of >=149 is read. Compared with other places, the larger value indicates that the detected distance from the reflection is far, indicating that the orientation is not obscured by the trolley 200. The portion where the Y-axis value is less than 2120 indicates that the ceiling position is read. This portion is because the laser scanner equipped with the present embodiment is placed in a higher position in the room closer to the ceiling for testing.
X軸座標在小於1300部份,在相對於Y軸數值2320的位置距離數值變小為91,可以明顯看出該方位已經被台車200的偵測板202擋住。 The X-axis coordinate is less than 1300, and the distance is reduced to 91 at a position relative to the Y-axis value of 2320. It can be clearly seen that the orientation has been blocked by the detection plate 202 of the trolley 200.
X軸座標在1160部份被擋住的高度最高,在相對於Y軸數值在2240的位置,距離數值為97,在該點的左右數據比較之下較大而沒有被遮蔽到,表示此位置就是測試用台車200的中心線,也就是偵測板202的位置。根據以上資料即可判斷出,該台車200的偵測板202所在的水平位置是在1160位置,垂直位置在2240 的位置。 The X-axis coordinate is blocked at the highest height in the 1160 part, and the value is at the position of 2240 with respect to the Y-axis. The distance value is 97, which is larger and not obscured at the left and right data of the point, indicating that the position is The center line of the test trolley 200, that is, the position of the detection board 202. According to the above information, it can be determined that the horizontal position of the detection board 202 of the trolley 200 is at 1160, and the vertical position is at 2240. s position.
然後,可以考量修改X0到1160的位置,Y0到2240位置,作為本實施例的初始位置(home position)。垂直的初始位置,在應用上取水平所在位置,因偵測時雷射掃瞄器100的高度與被偵測物的高度大致上相同,所以可以推估垂直的初始位置在2240的位置上。 Then, it is possible to consider the position of X 0 to 1160, the position of Y 0 to 2240, as the home position of the present embodiment. The vertical initial position is the position of the horizontal position in the application. Since the height of the laser scanner 100 is substantially the same as the height of the object to be detected, the vertical initial position can be estimated to be 2240.
當本發明之雷射掃瞄器未位於上述前進線的線上,亦即導引系統的裝設位置與航空器的進場路線兩者無法在同一直線上時,本發明進一步提供一偏移調整方法,以確保機型辨識與導引距離及偏移偵測的正確性。以下描述其原理及其操作步驟。請參閱圖6及圖7,分別為本發明之偏移調整的俯視示意圖,及其流程圖。本發明乃是利用線性插植法(linear interpolation),在直線上的斜率為固定值的原理,推估其中間點的距離。 The present invention further provides an offset adjustment method when the laser scanner of the present invention is not located on the line of the forward line, that is, the mounting position of the guiding system and the approach path of the aircraft cannot be on the same line. To ensure the correctness of the model identification and guiding distance and offset detection. The principles and operational steps thereof are described below. Please refer to FIG. 6 and FIG. 7 , which are schematic top views of the offset adjustment of the present invention, and a flow chart thereof. The present invention is based on the principle of linear interpolation, the slope of the line is a fixed value, and the distance between the intermediate points is estimated.
如圖6所示,本發明之特點及功能在於雷射掃瞄器100的位置並沒有與前進線F(例如可以是進場導引線J)在同一線上,乃是傾斜地掃瞄在進場導引線J的點。依圖7,在偏移調整開始,步驟B10選取前進線F上的停止線S(參圖6)為位置一,此點距離為D1,測量出該點水平座標為X1。步驟B20選擇前進線F上的一點作為位置二,此點距離為D2,測量出該點水平座標為X2。 As shown in FIG. 6, the feature and function of the present invention is that the position of the laser scanner 100 is not on the same line as the forward line F (for example, may be the approach guide line J), but is obliquely scanned in the approach. The point of the lead J. According to FIG. 7, at the beginning of the offset adjustment, step B10 selects the stop line S (refer to FIG. 6) on the forward line F as the position one, the distance of the point is D1, and the horizontal coordinate of the point is measured as X1. Step B20 selects a point on the forward line F as position two, the distance of this point is D2, and the horizontal coordinate of the point is measured as X2.
如步驟B30所示,當被偵測物前進至前進線F上的某一預定點,假設此點的距離為D時,則當時的水平偏移量X可以用以下方式預估:依線性插植法在直線上的斜率為固定值的原理:(X-X1)/(X2-X1)=(D-D1)/(D2-D1);所以上述預定點的水平座標X=X1+((D-D1)/(D2-D1))*(X2-X1)。 As shown in step B30, when the detected object advances to a predetermined point on the forward line F, assuming that the distance of the point is D, then the horizontal offset X at that time can be estimated in the following manner: The principle that the slope of the planting method on the straight line is a fixed value: (X-X1)/(X2-X1)=(D-D1)/(D2-D1); therefore the horizontal coordinate of the above predetermined point X=X1+((D -D1)/(D2-D1))*(X2-X1).
接著,如步驟B40所示,若繼續測量(Y),則再回到步驟B30,若不繼續測量(N),則結束偏移調整的流程。 Next, as shown in step B40, if the measurement (Y) is continued, the process returns to step B30, and if the measurement (N) is not continued, the flow of the offset adjustment is ended.
依照上述方式可以得到每個距離的對應水平偏移量,當進場 導引線J(J-LINE)與雷射光束沒有辦法設定在同一條線上時,不管這兩條線之間是不是平行線,都可以依照此方法求得任何一位置的對應偏移量。 According to the above method, the corresponding horizontal offset of each distance can be obtained when entering the field. When the guide wire J (J-LINE) and the laser beam are not set on the same line, regardless of whether the two lines are parallel lines, the corresponding offset of any position can be obtained according to this method.
依照國際民航公約(ICAO)飛航標準Annex 14機場設計與運作的建議,當飛機偏離中心線的距離達到飛機與雷射偵測設備距離達百分之一時,即應出現偏離告警。依照本發明的方法,當進場導引線J-LINE與雷射光束偏移達9度時,仍能正確量測出飛機的距離及相對於J-LINE的偏移量,並進行導引。 In accordance with the recommendations of the International Civil Aviation Convention (ICAO) flight standard Annex 14 airport design and operation, when the distance from the centerline reaches the distance between the aircraft and the laser detection equipment by one percent, a deviation warning should occur. According to the method of the present invention, when the approach guide line J-LINE is offset from the laser beam by 9 degrees, the distance of the aircraft and the offset with respect to the J-LINE can be accurately measured and guided. .
以上所述僅為本發明之較佳可行實施例,凡依本發明申請專利範圍所做之均等變化與修飾,皆應屬本發明之涵蓋範圍。 The above are only the preferred embodiments of the present invention, and all changes and modifications made to the scope of the present invention should be within the scope of the present invention.
指定代表圖為流程圖,故無元件的符號說明。 The specified representative diagram is a flowchart, so there is no symbolic description of the component.
Claims (7)
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
TW102133309A TWI539412B (en) | 2013-09-14 | 2013-09-14 | Method of orientating calibration for aircraft approach guiding system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
TW102133309A TWI539412B (en) | 2013-09-14 | 2013-09-14 | Method of orientating calibration for aircraft approach guiding system |
Publications (2)
Publication Number | Publication Date |
---|---|
TW201510958A true TW201510958A (en) | 2015-03-16 |
TWI539412B TWI539412B (en) | 2016-06-21 |
Family
ID=53186792
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
TW102133309A TWI539412B (en) | 2013-09-14 | 2013-09-14 | Method of orientating calibration for aircraft approach guiding system |
Country Status (1)
Country | Link |
---|---|
TW (1) | TWI539412B (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111986522A (en) * | 2020-07-29 | 2020-11-24 | 广州市新航科技有限公司 | Airborne equipment positioning method based on ADS-B signal, airborne equipment and storage medium thereof |
-
2013
- 2013-09-14 TW TW102133309A patent/TWI539412B/en active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111986522A (en) * | 2020-07-29 | 2020-11-24 | 广州市新航科技有限公司 | Airborne equipment positioning method based on ADS-B signal, airborne equipment and storage medium thereof |
CN111986522B (en) * | 2020-07-29 | 2022-03-22 | 广州市新航科技有限公司 | Airborne equipment positioning method based on ADS-B signal, airborne equipment and storage medium thereof |
Also Published As
Publication number | Publication date |
---|---|
TWI539412B (en) | 2016-06-21 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US10562644B2 (en) | System and method for aircraft docking guidance and aircraft type identification | |
AU2011333763B2 (en) | Rotating laser | |
US11143505B2 (en) | Surveying instrument | |
CN203405182U (en) | Tunnel-section profile measuring device based on vision measurement | |
CN111268530B (en) | Method and apparatus for measuring, positioning and installing elevator shaft | |
CN111044990B (en) | Airborne laser radar beam pointing calibration method and system and laser spot detector | |
JPH02129581A (en) | Apparatus for detecting position of object moving in plane, especially aircraft | |
US9177483B2 (en) | Guiding method for aircraft docking process | |
JP2004317507A (en) | Axis-adjusting method of supervisory device | |
CN108311545A (en) | A kind of y-type rolling mill tandem rolling centering and pass detecting system and method | |
CN113157005B (en) | Rotating holder for monitoring deformation of tunnel section and control system thereof | |
KR101706209B1 (en) | Leveling equipment for improving accuracy | |
CN105261025A (en) | Line-scan camera fast and high-precision calibration device of high-speed rail detection system | |
TWI539412B (en) | Method of orientating calibration for aircraft approach guiding system | |
CN104443423B (en) | The correction localization method of airborne vehicle approach guidance system | |
CN1606764A (en) | Centerline identification in a docking guidance system | |
CN112558046B (en) | Offline acceptance check method with multi-line laser radar intelligent equipment | |
CN205718848U (en) | Glass plate geometric parameter detects device and uses its safety glass board assembly line | |
CN1053512C (en) | Aircraft identification and docking guidance systems | |
US4505590A (en) | Mobile testing apparatus | |
US12117564B2 (en) | Scanning surveying system | |
CN113375638B (en) | Building engineering perpendicularity measuring instrument and using method | |
CN103768729A (en) | Method and device for detecting movement of medical device on basis of laser positioning lamp | |
JPH11287651A (en) | Indoor positioning device | |
CN109959354A (en) | A kind of large scale road surface evenness measuring device and its measurement method |