Pengukuran Ketepatan Alignment Sistem Penjejak Gerak Benda Langit dengan Metode Drift Berbantuan Tracker

Lukmanul Hakim; Yudhiakto Pramudya

doi:10.30599/jipfri.v4i2.767

Authors

Lukmanul Hakim Universitas Ahmad Dahlan
Yudhiakto Pramudya Universitas Ahmad Dahlan

DOI:

https://doi.org/10.30599/jipfri.v4i2.767

Keywords:

Telescope, Mounting, Drift, Azimuth, Altitude

Abstract

The simulation of the drift method application using a celestial body tracker has been done. Experiments were carried out by recording the movement of a celestial body tracker with variation orientation of polar angle and azimuth from the true south and polar angle a particular location. The variation is between -2° to +2°. It was found that the greater the difference in the mounting orientation from the true orientation, the greater the shift in altitude and azimuth of the celestial object’s path.

Downloads

Download data is not yet available.

References

Amrozi, M., & Amiranti, S. (2012). Perancangan Museum Astronomi Bertema Paradoks (Big Bang) Sebagai Pusat Informasi Perbintangan di Indonesia. Jurnal Sains Dan Seni ITS, 1(1), 59–64. http://ejurnal.its.ac.id/index.php/sains_seni/article/view/2133

Azzam, Y. A., Kosuge, K., Wang, Z., Alawy, A. A., & Y Hirata. (2004). Telescope Automatic Alignment and Pointing using Pattern Matching. The Fourth International Conference on the Advanced Mechatronics, 96–102.

Barrett, F. (2016a). Determining Polar Axis Alignment Accuracy (2nd Edition (ed.); pp. 1–11).

Barrett, F. (2016b). Measuring Polar Axis Alignment Error (3rd Edition (ed.); pp. 1–12).

Gautama, S. E. (2010). Astronomi Dan Astrofisika (Revisi Ke-3). SMA Negeri 1 Makasar.

Handhita, E. T., Akhlis, I., & Marwanto, P. (2016). Pengembangan Media Pembelajaran Materi Astronomi Berbasis Visual Novel Ren’Py. Unnes Physics Education Journal, 5(2), 35–41. https://doi.org/10.15294/upej.v5i2.13617

Irvan, & Hermawan, L. (2019). Mengenal Jenis-Jenis Teleskop dan Penggunaannya. Al-Marshad: Jurnal Astronomi Islam Dan Ilmu-Ilmu Berkaitan, 5(1), 74–89. https://doi.org/10.30596/jam.v5i1.3125

Ishaq, U. M., Supatmi, S., Mustika, M. E., & Komputer, J. T. (2012). Pengendalian Sudut Pada Pergerakan Teleskop Refraktor Menggunakan Personal Computer. Jurnal Sistem Komputer Unikom, 1(1), 38–43. https://ojs.unikom.ac.id/index.php/komputika/article/view/116

Kunjaya, C. (2014). Suplemen ASTROFISIKA untuk SMA. PT.Trisula Adisakti.

Latief, M. B., Muchlas, & Pramudya, Y. (2014). Sistem pelacak otomatis gerakan benda langit pada teleskop refraktor berbasis mikrokontroler. Jurnal Fisika Indonesia, XVIII(54), 82–85. https://journal.ugm.ac.id/jfi/article/view/24378/15870

Rahman, A. A., Rivai, M., & Tasripan. (2017). Sistem Otomatisasi Pelacakan Objek Astronomi Menggunakan Teleskop Berdasarkan Stellarium. Jurnal Teknik ITS, 6(2), 539–543. https://doi.org/10.12962/j23373539.v6i2.24121

Riswanto, & Suseno, N. (2015). Dasar-Dasar Astronomi Dan Fisika Kebumian. Lembaga Penelitian UM Metro Press.

Saputra, O. (2018). Revolusi dalam Perkembangan Astronomi: Hilangnya Pluto Dalam Keanggotaan Planet Pada Sistem Tata Surya. Jurnal Filsafat Indonesia, 1(1), 71–74. https://doi.org/10.23887/jfi.v1i2.13992

Pengukuran Ketepatan Alignment Sistem Penjejak Gerak Benda Langit dengan Metode Drift Berbantuan Tracker

Authors

DOI:

Keywords:

Abstract

Downloads

References

Downloads

Published

How to Cite

Issue

Section

Most read articles by the same author(s)

menu3

Template_Sanguilmu

Accreditation_Sanguilmu

Citation_Sanguilmu

Tools_Sanguilmu

Visitor_Sanguilmu

Information_Sanguilmu

crossref

supervised