Corrigendum to: Analysis of a kinematic real-time robotic total station network for robot control

Otto Lerke; Volker Schwieger

doi:10.1515/jag-2021-2002

SISTEM PERINGATAN DINI: PEMANTAUAN LERENG TAMBANG MENGGUNAKAN APLIKASI TELEGRAM

Indonesian Mining Professionals Journal ◽

10.36986/impj.v2i2.35 ◽

2021 ◽

Vol 2 (2) ◽

pp. 103-110

Author(s):

Priema Wardani ◽

Zidni Ilman Munthaha

Keyword(s):

Real Time ◽

Total Station ◽

Total Movement ◽

Robotic Total Station

Metode pemantauan lereng menggunakan prisma merupakan salah satu metode yang masih diandalkan, salah satu alat yang digunakan untuk pick up data dari prisma adalah Robotic Total Station (RTS). RTS merupakan salah satu alat pantau kestabilan lereng secara real time di area tambang terbuka. Namun data tersebut masih belum bisa digunakan sebagai sistem peringatan dini untuk menyampaikan status pergerakan. Selain itu, kendala lainnya adalah keterbatasan personel untuk dapat memonitoring RTS selama 7x24 jam karena kurva yang dihasilkan masih bersifat kualitatif, sehingga masih membutuhkan interpretasi oleh seorang kompeten untuk menentukan pola pergerakan dan status lereng. Untuk membuat sistem peringatan dini diperlukan adanya nilai kuantitatif ambang batas sebagai acuan status pergerakan lereng, penentuan nilai ambang batas haruslah sesuai dengan kondisi aktual dilapangan sehingga tidak terjadi false evacuate alarm dan late evacuate alarm. Poin lainnya adalah media komunikasi yang dapat digunakan secara masif di lokasi pekerjaan agar penggunaan sistem peringan dini ini dapat efektif diterapkan. Dengan menggunakan metode penelitian tindakan dan dengan pendekatan four-D maka didapatlah suatu sistem yang dapat digunakan sebagai sistem peringatan dini deteksi pergerakan lereng tambang menggunakan aplikasi Telegram yang dapat berjalan pada perangkat mobile Android dan IOS. Hasil penelitian didapatkan bahwa data pengamatan RTS dapat dikonversi menggunakan bahasa pemrograman PHP dan database MySQL sehingga dapat diteruskan oleh sistem API dengan bantuan Bot pada aplikasi Telegram untuk menampilkan informasi berupa total movement (cm), velocity (cm/hari) dan status lereng pada chat group yang dapat menentukan tindakan selanjutnya yang akan dilakukan.

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Analysis of a kinematic real-time robotic total station network for robot control

Journal of Applied Geodesy ◽

10.1515/jag-2021-0016 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Otto Lerke ◽

Volker Schwieger

Keyword(s):

Real Time ◽

Geodetic Network ◽

Computational Design ◽

Global Navigation Satellite Systems ◽

Measurement Unit ◽

Automated Driving ◽

German Research Foundation ◽

Total Station ◽

Satellite Systems ◽

Robotic Total Station

Abstract The use of robots is widespread in the field of construction nowadays. Robots may be mobile or static depending on the specific task or application. One of the major challenges when implementing mobile robots is localisation. In the field of robotics, localisation is often performed in a relative sense, however some applications require absolute localisation. In order to provide absolute positions, appropriate sensors such as Global Navigation Satellite Systems (GNSS) or total stations can be employed. The underlying task is embedded within the Germany´s Excellence Strategy “Integrative Computational Design and Construction for Architecture (IntCDC)” funded by the German Research Foundation (DFG). The specific sub-project deals with issues of robot-robot collaboration and specifically aims the provision of absolute position and orientation, designated as pose, of a mobile construction robot. The determined pose information supports different control loops of the robot including automated driving, steering and tool operations. The choice of the sensor system favoured a robotic total station (RTS), because of its real-time capability and measurement accuracy. The measurement system is coupled with an Inertial Measurement Unit (IMU) for orientation. To counteract line-of-sight interference between the RTS and the target, the contribution proposes the use of a network of four spatially evenly distributed RTSs. The quality characteristics of different pose determination procedures of a mobile construction robot are investigated using methods from the geodetic network theory. Conclusions about accuracy and reliability distribution across the construction site are presented numerically and graphically.

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Sparse Gaussian process regression for compliant, real-time robot control

2015 IEEE International Conference on Robotics and Automation (ICRA) ◽

10.1109/icra.2015.7139547 ◽

2015 ◽

Cited By ~ 7

Author(s):

Jens Schreiter ◽

Peter Englert ◽

Duy Nguyen-Tuong ◽

Marc Toussaint

Keyword(s):

Gaussian Process ◽

Real Time ◽

Robot Control ◽

Gaussian Process Regression

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The Design of Gluing Robot Control System Based on CAN Bus

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.1006-1007.627 ◽

2014 ◽

Vol 1006-1007 ◽

pp. 627-630 ◽

Cited By ~ 1

Author(s):

Xu Dong Yang

Keyword(s):

Control System ◽

Real Time ◽

Software Design ◽

Robot Control ◽

Can Bus ◽

System Structure ◽

Reliable Control ◽

The Real ◽

Data Transferring ◽

Robot Control System

CAN bus was used as the data transferring channels in the two–level controllers, and the real-time,dexterity,expansibility and security for the Gluing control system based on CAN bus can be improved obviously.The system structure, principle and software design were introduced.The experiment shows that it is a reliable control system and it can meet the requirements of automatic gluing tasks.

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Point-Cloud Models of Historical Barns – Spatial Discrepancies of Laser Scanning versus Robotic Total Station

10.29007/2493 ◽

2020 ◽

Author(s):

Gustavo Maldonado ◽

Marcel Maghiar ◽

Brent Tharp ◽

Dhruv Patel

Keyword(s):

Service Learning ◽

Point Cloud ◽

Laser Scanning ◽

3D Point Cloud ◽

Spatial Accuracy ◽

Total Station ◽

Cloud Models ◽

Bulloch County ◽

Southern University ◽

Robotic Total Station

This study considers the generation of virtual, 3D point-cloud models of seven deteriorating historical, agricultural barns in Bulloch County, Georgia, USA, for preservation purposes. The work was completed as a service-learning project in a course on Terrestrial Light Detection and Ranging (T-LiDAR), offered at Georgia Southern University. The resulting models and fly-through videos were donated to Bulloch County Historical Society and to the Georgia Southern Museum, to make them available to the general public and future generations. Additionally, one of the seven barns was selected to be extensively measured to estimate the relative spatial accuracy of all seven resulting 3D point-cloud models, with respect to measurements completed with a highly accurate instrument. Three accurate benchmarks were established around it for georeferencing purposes. The positions of 44 points were measured in the field via an accurate, one- second, robotic total-station (RTS) instrument. Also, the coordinates of the same points were acquired from within georeferenced and non-georeferenced point-cloud models. These points defined 259 distances. They were compared to determine their discrepancy statistics. It was observed that this process produced virtual models with an approximate maximum spatial discrepancy of one-half inch (0.5 in) with respect to measurements performed by a highly accurate RTS device. There were no substantial differences in the relative accuracies of the georeferenced and non-georeferenced models.

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