M. Thomas, M. Trenti, A. Sanna, R. Campana, G. Ghirlanda, J. Řípa, L. Burderi, F. Fiore, Y. Evangelista, L. Amati, S. Barraclough, K. Auchettl, M. O. del Castillo, A. Chapman, M. Citossi, A. Colagrossi, G. Dilillo, N. Deiosso, E. Demenev, F. Longo, A. Marino, J. McRobbie, R. Mearns, A. Melandri, A. Riggio, T. di Salvo, S. Puccetti, M. Topinka
{"title":"来自SpIRIT+HERMES-TP/SP联合纳米卫星星座的伽马射线暴定位","authors":"M. Thomas, M. Trenti, A. Sanna, R. Campana, G. Ghirlanda, J. Řípa, L. Burderi, F. Fiore, Y. Evangelista, L. Amati, S. Barraclough, K. Auchettl, M. O. del Castillo, A. Chapman, M. Citossi, A. Colagrossi, G. Dilillo, N. Deiosso, E. Demenev, F. Longo, A. Marino, J. McRobbie, R. Mearns, A. Melandri, A. Riggio, T. di Salvo, S. Puccetti, M. Topinka","doi":"10.1017/pasa.2023.4","DOIUrl":null,"url":null,"abstract":"Abstract Multi-messenger observations of the transient sky to detect cosmic explosions and counterparts of gravitational wave mergers critically rely on orbiting wide-FoV telescopes to cover the wide range of wavelengths where atmospheric absorption and emission limit the use of ground facilities. Thanks to continuing technological improvements, miniaturised space instruments operating as distributed-aperture constellations are offering new capabilities for the study of high-energy transients to complement ageing existing satellites. In this paper we characterise the performance of the upcoming joint SpIRIT and HERMES-TP/SP constellation for the localisation of high-energy transients through triangulation of signal arrival times. SpIRIT is an Australian technology and science demonstrator satellite designed to operate in a low-Earth Sun-synchronous Polar orbit that will augment the science operations for the equatorial HERMES-TP/SP constellation. In this work we simulate the improvement to the localisation capabilities of the HERMES-TP/SP constellation when SpIRIT is included in an orbital plane nearly perpendicular (inclination = 97.6°) to the HERMES-TP/SP orbits. For the fraction of GRBs detected by three of the HERMES satellites plus SpIRIT, we find that the combined constellation is capable of localising 60% of long GRBs to within \n${\\sim}30\\,\\textrm{deg}^{2}$\n on the sky, and 60% of short GRBs within \n${\\sim}1850\\,\\textrm{deg}^{2}$\n ( \n$1\\sigma$\n confidence regions), though it is beyond the scope of this work to characterise or rule out systematic uncertainty of the same order of magnitude. Based purely on statistical GRB localisation capabilities (i.e., excluding systematic uncertainties and sky coverage), these figures for long GRBs are comparable to those reported by the Fermi Gamma Burst Monitor instrument. These localisation statistics represents a reduction of the uncertainty for the burst localisation region for both long and short GRBs by a factor of \n${\\sim}5$\n compared to the HERMES-TP/SP alone. Further improvements by an additional factor of 2 (or 4) can be achieved by launching an additional 4 (or 6) SpIRIT-like satellites into a Polar orbit, respectively, which would both increase the fraction of sky covered by multiple satellite elements, and also enable localisation of \n${\\geq} 60\\%$\n of long GRBs to within a radius of \n${\\sim}1.5^{\\circ}$\n (statistical uncertainty) on the sky, clearly demonstrating the value of a distributed all-sky high-energy transient monitor composed of nano-satellites.","PeriodicalId":20753,"journal":{"name":"Publications of the Astronomical Society of Australia","volume":"115 1","pages":""},"PeriodicalIF":4.5000,"publicationDate":"2023-01-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"3","resultStr":"{\"title\":\"Localisation of gamma-ray bursts from the combined SpIRIT+HERMES-TP/SP nano-satellite constellation\",\"authors\":\"M. Thomas, M. Trenti, A. Sanna, R. Campana, G. Ghirlanda, J. Řípa, L. Burderi, F. Fiore, Y. Evangelista, L. Amati, S. Barraclough, K. Auchettl, M. O. del Castillo, A. Chapman, M. Citossi, A. Colagrossi, G. Dilillo, N. Deiosso, E. Demenev, F. Longo, A. Marino, J. McRobbie, R. Mearns, A. Melandri, A. Riggio, T. di Salvo, S. Puccetti, M. Topinka\",\"doi\":\"10.1017/pasa.2023.4\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abstract Multi-messenger observations of the transient sky to detect cosmic explosions and counterparts of gravitational wave mergers critically rely on orbiting wide-FoV telescopes to cover the wide range of wavelengths where atmospheric absorption and emission limit the use of ground facilities. Thanks to continuing technological improvements, miniaturised space instruments operating as distributed-aperture constellations are offering new capabilities for the study of high-energy transients to complement ageing existing satellites. In this paper we characterise the performance of the upcoming joint SpIRIT and HERMES-TP/SP constellation for the localisation of high-energy transients through triangulation of signal arrival times. SpIRIT is an Australian technology and science demonstrator satellite designed to operate in a low-Earth Sun-synchronous Polar orbit that will augment the science operations for the equatorial HERMES-TP/SP constellation. In this work we simulate the improvement to the localisation capabilities of the HERMES-TP/SP constellation when SpIRIT is included in an orbital plane nearly perpendicular (inclination = 97.6°) to the HERMES-TP/SP orbits. For the fraction of GRBs detected by three of the HERMES satellites plus SpIRIT, we find that the combined constellation is capable of localising 60% of long GRBs to within \\n${\\\\sim}30\\\\,\\\\textrm{deg}^{2}$\\n on the sky, and 60% of short GRBs within \\n${\\\\sim}1850\\\\,\\\\textrm{deg}^{2}$\\n ( \\n$1\\\\sigma$\\n confidence regions), though it is beyond the scope of this work to characterise or rule out systematic uncertainty of the same order of magnitude. Based purely on statistical GRB localisation capabilities (i.e., excluding systematic uncertainties and sky coverage), these figures for long GRBs are comparable to those reported by the Fermi Gamma Burst Monitor instrument. These localisation statistics represents a reduction of the uncertainty for the burst localisation region for both long and short GRBs by a factor of \\n${\\\\sim}5$\\n compared to the HERMES-TP/SP alone. Further improvements by an additional factor of 2 (or 4) can be achieved by launching an additional 4 (or 6) SpIRIT-like satellites into a Polar orbit, respectively, which would both increase the fraction of sky covered by multiple satellite elements, and also enable localisation of \\n${\\\\geq} 60\\\\%$\\n of long GRBs to within a radius of \\n${\\\\sim}1.5^{\\\\circ}$\\n (statistical uncertainty) on the sky, clearly demonstrating the value of a distributed all-sky high-energy transient monitor composed of nano-satellites.\",\"PeriodicalId\":20753,\"journal\":{\"name\":\"Publications of the Astronomical Society of Australia\",\"volume\":\"115 1\",\"pages\":\"\"},\"PeriodicalIF\":4.5000,\"publicationDate\":\"2023-01-24\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"3\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Publications of the Astronomical Society of Australia\",\"FirstCategoryId\":\"101\",\"ListUrlMain\":\"https://doi.org/10.1017/pasa.2023.4\",\"RegionNum\":3,\"RegionCategory\":\"物理与天体物理\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q1\",\"JCRName\":\"ASTRONOMY & ASTROPHYSICS\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Publications of the Astronomical Society of Australia","FirstCategoryId":"101","ListUrlMain":"https://doi.org/10.1017/pasa.2023.4","RegionNum":3,"RegionCategory":"物理与天体物理","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ASTRONOMY & ASTROPHYSICS","Score":null,"Total":0}
引用次数: 3
摘要
瞬态天空的多信使观测,以探测宇宙爆炸和引力波并合,严重依赖于轨道宽视场望远镜,以覆盖大气吸收和发射限制了地面设施的使用的宽波长范围。由于技术的不断改进,作为分布式孔径星座运行的小型化空间仪器为高能瞬变现象的研究提供了新的能力,以补充老化的现有卫星。在本文中,我们描述了即将到来的联合SpIRIT和HERMES-TP/SP星座的性能,通过信号到达时间的三角测量来定位高能瞬态。精神号是澳大利亚的一颗技术和科学演示卫星,设计用于在近地太阳同步极轨道运行,将增强赤道HERMES-TP/SP星座的科学运行。在这项工作中,我们模拟了当SpIRIT被包括在与HERMES-TP/SP轨道几乎垂直(倾角= 97.6°)的轨道平面中时,对HERMES-TP/SP星座定位能力的改进。对于三颗HERMES卫星加上SpIRIT探测到的grb的比例,我们发现合并后的星座能够定位60个% of long GRBs to within ${\sim}30\,\textrm{deg}^{2}$ on the sky, and 60% of short GRBs within ${\sim}1850\,\textrm{deg}^{2}$ ( $1\sigma$ confidence regions), though it is beyond the scope of this work to characterise or rule out systematic uncertainty of the same order of magnitude. Based purely on statistical GRB localisation capabilities (i.e., excluding systematic uncertainties and sky coverage), these figures for long GRBs are comparable to those reported by the Fermi Gamma Burst Monitor instrument. These localisation statistics represents a reduction of the uncertainty for the burst localisation region for both long and short GRBs by a factor of ${\sim}5$ compared to the HERMES-TP/SP alone. Further improvements by an additional factor of 2 (or 4) can be achieved by launching an additional 4 (or 6) SpIRIT-like satellites into a Polar orbit, respectively, which would both increase the fraction of sky covered by multiple satellite elements, and also enable localisation of ${\geq} 60\%$ of long GRBs to within a radius of ${\sim}1.5^{\circ}$ (statistical uncertainty) on the sky, clearly demonstrating the value of a distributed all-sky high-energy transient monitor composed of nano-satellites.
Localisation of gamma-ray bursts from the combined SpIRIT+HERMES-TP/SP nano-satellite constellation
Abstract Multi-messenger observations of the transient sky to detect cosmic explosions and counterparts of gravitational wave mergers critically rely on orbiting wide-FoV telescopes to cover the wide range of wavelengths where atmospheric absorption and emission limit the use of ground facilities. Thanks to continuing technological improvements, miniaturised space instruments operating as distributed-aperture constellations are offering new capabilities for the study of high-energy transients to complement ageing existing satellites. In this paper we characterise the performance of the upcoming joint SpIRIT and HERMES-TP/SP constellation for the localisation of high-energy transients through triangulation of signal arrival times. SpIRIT is an Australian technology and science demonstrator satellite designed to operate in a low-Earth Sun-synchronous Polar orbit that will augment the science operations for the equatorial HERMES-TP/SP constellation. In this work we simulate the improvement to the localisation capabilities of the HERMES-TP/SP constellation when SpIRIT is included in an orbital plane nearly perpendicular (inclination = 97.6°) to the HERMES-TP/SP orbits. For the fraction of GRBs detected by three of the HERMES satellites plus SpIRIT, we find that the combined constellation is capable of localising 60% of long GRBs to within
${\sim}30\,\textrm{deg}^{2}$
on the sky, and 60% of short GRBs within
${\sim}1850\,\textrm{deg}^{2}$
(
$1\sigma$
confidence regions), though it is beyond the scope of this work to characterise or rule out systematic uncertainty of the same order of magnitude. Based purely on statistical GRB localisation capabilities (i.e., excluding systematic uncertainties and sky coverage), these figures for long GRBs are comparable to those reported by the Fermi Gamma Burst Monitor instrument. These localisation statistics represents a reduction of the uncertainty for the burst localisation region for both long and short GRBs by a factor of
${\sim}5$
compared to the HERMES-TP/SP alone. Further improvements by an additional factor of 2 (or 4) can be achieved by launching an additional 4 (or 6) SpIRIT-like satellites into a Polar orbit, respectively, which would both increase the fraction of sky covered by multiple satellite elements, and also enable localisation of
${\geq} 60\%$
of long GRBs to within a radius of
${\sim}1.5^{\circ}$
(statistical uncertainty) on the sky, clearly demonstrating the value of a distributed all-sky high-energy transient monitor composed of nano-satellites.
期刊介绍:
Publications of the Astronomical Society of Australia (PASA) publishes new and significant research in astronomy and astrophysics. PASA covers a wide range of topics within astronomy, including multi-wavelength observations, theoretical modelling, computational astronomy and visualisation. PASA also maintains its heritage of publishing results on southern hemisphere astronomy and on astronomy with Australian facilities.
PASA publishes research papers, review papers and special series on topical issues, making use of expert international reviewers and an experienced Editorial Board. As an electronic-only journal, PASA publishes paper by paper, ensuring a rapid publication rate. There are no page charges. PASA''s Editorial Board approve a certain number of papers per year to be published Open Access without a publication fee.