Taiwan's second remote sensing satellite

FORMOSAT-2 is Taiwan's first remote sensing satellite (RSS). It was launched on 20 May 2004 with five-year mission life and a very unique mission orbit at 891 km altitude. This orbit gives FORMOSAT-2 the daily revisit feature and the capability of imaging the Arctic and Antarctic regions due to the high enough altitude. For more than three years, FORMOSAT-2 has performed outstanding jobs and its global effectiveness is evidenced in many fields such as public education in Taiwan, Earth science and ecological niche research, preservation of the world heritages, contribution to the International Charter: space and major disasters, observation of suspected North Korea and Iranian nuclear facilities, and scientific observation of the atmospheric transient luminous events (TLEs). In order to continue the provision of earth observation images from space, the National Space Organization (NSPO) of Taiwan started to work on the second RSS from 2005. This second RSS will also be Taiwan's first indigenous satellite. Both the bus platform and remote sensing instrument (RSI) shall be designed and manufactured by NSPO and the Instrument Technology Research Center (ITRC) under the supervision of the National Applied Research Laboratories (NARL). Its onboard computer (OBC) shall use Taiwan's indigenous LEON-3 central processing unit (CPU). In order to achieve cost effective design, the commercial off the shelf (COTS) components shall be widely used. NSPO shall impose the up-screening/qualification and validation/verification processes to ensure their normal functions for proper operations in the severe space environments.     

Orbital maneuver and keeping of FORMOSAT-2

This paper presents the orbital maneuver (OM) and keeping of FORMOSAT-2 (or FS2, Formosa Satellite #2) since its launch on 20 May 2004. The successful launch put FS2 in a sun-synchronous parking orbit with 729.94 km perigee and 743.31 apogee. Taiwan’s National Space Organization (NSPO) then spent 11 days to perform the first orbital maneuver (OM#1) and raised FS2 to its sun-synchronous circular mission orbit at 888.47 km altitude. Due to various kinds of disturbances, FS2’s orbit shifts gradually but constantly. Therefore, four times of OM had been performed for orbital keeping. Details of all 5 OMs are described.     

The dive and ascent satellite program for lower ionosphere research

Lower ionosphere is a transition region from outer-space to low atmosphere and had been unexplored on a continuous basis before Atmosphere Explorer satellites flew in the region. Purpose of a new aeronomy satellite, DAS (Dive and Ascent Satellite) having a capability to control orbits and flying at the very low perigee altitude less than 130 km is to explore the bottomside of ionosphere spreading over between 100 and 300 km altitudes. Preliminary study on the new aeronomy satellite is conducted at National Aerospace Laboratory in cooperation with Radio Research Laboratories and Meteorological Research Institute.This paper reviews the mission design, orbit decay and transfer analysis, typical orbit profile, aerodynamic characteristics and satellite configuration study, aerodynamic heating and thermal control analysis, attitude control analysis, on-board propulsion and power subsystems, and operation analysis with emphasis on their technical feasibility.     

Post mission life plan for FORMOSAT-2

This paper presents the enhancement in mission operations, the mission life state-of-health (SOH) trending analysis, and the post mission life plan of the FORMOSAT-2 (or FS2, Formosa satellite #2, was called ROCSAT-2, or RS2, Republic of China satellite #2, previously) during its five years mission life from 20 May 2004 to 20 May 2009. There are two payloads onboard FS2: a remote sensing instrument (RSI) with nadir ground sampling distance (GSD) of 2 m for panchromatic (PAN) and GSD of 8 m for multi-spectral (MS, 4 bands) as the primary payload, and an imager for sprite and upper atmospheric lightning (ISUAL) as the secondary payload. It was launched on 20 May 2004. The design life is 7 years while the mission life is 5 years. In other words, the end of mission life date of FS2 is 20 May 2009. Generally speaking, FS2 is still at very good condition in its SOH. Post mission life plan for FS2 consists of: the practice of orbit transfer for global coverage and better resolution, the development of gyroless attitude control, and the method for life extension. It is expected that the working life of FS2 can be extended 3–5 years.     

The Brazilian scientific microsatellite SACI-1

The National Space Research Institute (INPE) is developing the first Brazilian Scientific Microsatellite (SACI-1) based on the vanguard technology and on the experience acquired through projects developed by Brazilian Space Program. The SACI-1 is a 750km polar orbit satellite. The spacecraft will combine spin stabilization with geomagnetic control and has a total mass of 60 kg. The overall dimensions are 640×470×470 mm. The SACI-1 satellite shall be launched together with CBERS (China-Brazil Earth Resource Satellite). Its platform is being designed for multiple mission applications. The Brazilian Academy of Sciences has selected four scientific payloads that characterize the mission. The scientific experiments are: ORCAS (Solar and Anomalous Cosmic Rays Observation in the Magnetosphere), PLASMEX (Study of Plasma Bubbles), FOTSAT (Airglow Photometer), and MAGNEX (Geomagnetic Experiment).     

改进的遥感卫星成像任务单轨最优团划分聚类方法

针对遥感卫星成像任务规划时对点目标的聚类效果不佳的问题,提出了一种改进的单轨最优团划分聚类方法。根据聚类约束条件,构建任务聚类图模型,并为图模型中的每一条边赋权值;根据图模型中边的权值,构建权值矩阵P;以卫星单轨姿态机动的最大次数作为聚类任务的数量限制,由P依次计算每个聚类任务所有可能的最优聚类方案,并生成对应的收益矩阵M和终点矩阵N;通过循环遍历的方式计算各个聚类方案下的总收益,其中总收益最大的方案即为最优团划分聚类方案。仿真结果表明:提出的改进的团划分聚类方法,能将点目标有效聚类,与传统任务聚类方法相比,可明显提高遥感卫星对点目标的观测效率。研究结果可为我国遥感卫星自主任务规划技术研究提供参考。     

Erdbeobachtende missionen—Anforderungen und konzepte

(Earth Observation Missions—Requirements and Concepts)—Ten years ago, on 23 July 1972. NASA launched the first satellite specifically designed for Earth observation. With Landsat 1 the importance and attractiveness of remote sensing from space increased worldwide.The paper presents in an overview former remote sensing missions with their applications and the system elements required for gathering Earth observation information. Main elements are the sensors (optical, microwave, and other instruments), the platforms (satellites, space stations, aircraft and Earth based stations) and their orbits.It is shown how these elements are interrelated and which constraints must be considered for planning an Earth observation mission. The feasibility, the amount of hard- and software, the costs, and the performance of a system are decisive for the realization of a satellite concept.Examples for different concepts investigated to date at Dornier System are given; included is the first ESA Remote Sensing Satellite ERS-1, which is now under definition at Dornier System, the main contractor of ESA.     

Super View-1-China's First Commercial Remote Sensing Satellite Constellation with a High Resolution of 0.5 m

Super View-1 satellite constellation(Super View-1 for short) is the first commercial remote sensing constellation with a resolution down to 0.5 m. It's an important part of the national spatial information infrastructure construction. It will play an important role for the global users providing remote sensing data, application solutions and remote sensing value-added services with its high-resolution and 24-hour observation capability. At present, 4 satellites of the constellation have been successfully launched and networked on orbit. The services cover surveying and mapping, land resource surveying, urban planning, agriculture, forestry, water conservancy, geological mining, environmental monitoring, defense, disaster reduction along with other traditional industries. There are also great potential applications in Mobile Internet, LBS, Smart city, insurance and other emerging professions. The successful operation of Super View-1 breaks the overseas monopoly for commercial high-resolution remote sensing satellite imagery in the China market. It's one of the major achievements in China space science and technology by actively exploring the development of commercial remote sensing markets, which is of strategic significance to the development of China remote sensing satellite business.     

嫦娥一号月球探测卫星轨道设计

嫦娥一号卫星航天使命的主要科学目标是对月球及月地空间进行多种遥感探测,航天使命设计的主要和基本的部分是卫星飞行轨道的设计,其中包括在飞行过程中的轨道控制策略的设计。嫦娥一号的这条飞行轨道由三大部分组成:第一部分是绕地飞行的调相轨道,它们由周期为16h、24h、48h的三段轨道组成;第二部分是关键的地月转移轨道;第三部分是200km高度绕月飞行的使命轨道。文章给出了整个飞行轨道的设计思想。     

Pakistan's space programme

Space research in Pakistan is conducted by the Pakistan Space and Upper Atmosphere Research Commission (Suparco). Suparco's programmes consist of the launching of sounding rockets and satellite applications, especially remote sensing and communications. Its long-term goals are to develop communications and remote sensing satellites and to launch lightweight scientific satellites in near-Earth orbits. To train its scientific staff at postgraduate level, Suparco is establishing an Aerospace Institute. The Commission is very active in international forums such as the UN COPUOS, Cospar, IAF and IUCN.     

A bistatic SAR mission for earth observation based on a small satellite

The authors present a new scientific space mission consisting of a satellite carrying a receiving- only SAR which receives the signal transmitted by the ENVISAT-1 SAR. The integration of ENVISAT-1 SAR and bistatic radar data offers an improved potentiality of surface classification, three-dimensional observation, and the opportunity of advanced scientific experiments in the field of bistatic scattering. The small satellite nominal orbit and the attitude manoeuvres are designed in order to maintain an adequate overlap between the two radar swaths along the whole orbit, taking into account the ENVISAT-1 attitude and pointing. A preliminary satellite design (2-year lifetime) is then performed to evaluate the orbit decay and to determine the appropriate orbit manoeuvres (every 4 days) to control the satellites relative phase. The numerical simulation shows that a spacecraft of about 584kg is able to meet the mission requirements.     

对GEO卫星照相的HEO卫星变轨策略研究

为对地球同步轨道卫星近距离光学照相,设计了大椭圆任务轨道.在考虑地球扁率J2的动力学模型下,研究了大椭圆轨道变轨策略,提出了轨道设计方案,并进行了仿真计算.基于STK软件对变轨方案进行了仿真验证,结果表明所提出的轨道设计方案能够满足对地球同步轨道卫星近距离光学照相要求.     

Rapid model-based inter-disciplinary design of a CubeSat mission

With an increase in the use of small, modular, resource-limited satellites for Earth orbiting applications, the benefit to be had from a model-based architecture that rapidly searches the mission trade-space and identifies near-optimal designs is greater than ever. This work presents an architecture that identifies trends between conflicting objectives (e.g. lifecycle cost and performance) and decision variables (e.g. orbit altitude and inclination) such that informed assessment can be made as to which design/s to take on for further analysis. The models within the architecture exploit analytic methods where possible, in order avoid computationally expensive numerical propagation, and achieve rapid convergence. Two mission cases are studied; the first is an Earth observation satellite and presents a trade-off between ground sample distance and revisit time over a ground target, given altitude as the decision variable. The second is a satellite with a generic scientific payload and shows a more involved trade-off, between data return to a ground station and cost of the mission, given variations in the orbit altitude, inclination and ground station latitude. Results of each case are presented graphically and it is clear that non-intuitive results are captured that would typically be missed using traditional, point-design methods, where only discrete scenarios are examined.     

Earth observation using low cost micro/minisatellites

Surrey Satellite Technology Ltd (SSTL) at the University of Surrey (UK) has pioneered cost-effective satellite engineering techniques for smaller, faster, cheaper satellites to provide affordable access to space. SSTL has designed, built, launched and operated a series of twelve 50kg microsatellites in low Earth orbit which carry a wide range of satellite communications, space science, remote sensing and in-orbit technology demonstration payloads — for both civil and military applications. Each of these has been built and launched for around US$3M. This paper reviews SSTL's remote sensing capabilities and presents image results from the microsatellite cameras in low Earth in orbit. The latest microsatellites (TMSAT & FASat-Bravo) under construction at SSTL and due for launch in mid-1997 will provide 3-band multispectral imaging with 80-metre resolution; autonomous on-board image analysis, processing and compression prior to transmission direct to ground-based users employing small portable terminals.     

中国空间站光学遥感载荷的发展研究

光学遥感载荷的空间站平台相比卫星平台具有很大的优势,吸引了包括俄罗斯、美国和欧空局在内的国际空间站成员国争相进行空间站光学遥感载荷的新技术实验验证和对地观测研究。文章介绍了国际空间站光学遥感载荷的观测方式和特点,结合国际空间站光学遥感载荷的应用情况,从新技术实验验证和对地观测两个方面分析了中国空间站光学遥感载荷发展应该注意的问题,为中国空间站光学遥感载荷的发展提出了几点建议。     

冻结轨道及其应用

近来在对地观测卫星系统的设计中越来越多地采用冻结轨道,因为它能使卫星(作为一个质点)在不同时刻通过同一纬度时具有相同的运动特性,这就使得卫星在不同时刻经过同一地区所得到的遥感图片具有相同的几何特性。本文详细地讨论了冻结轨道条件、性状及其应用     

ERDSAT,a satellite concept for Earth observations with combined optical and microwave payload

The concept of a European remote sensing satellite (ERDSAT) launched by ARIANE is characterized by a model payload, consisting of a synthetic aperture radar (SAR) and an optical multispectral scanner with 9 channels, for land applications or coastal zone missions. The mission goal of ERDSAT is based on European user requrements where a strong need for optical and microwave sensor operation on board the same satellite in a simultaneous or sequential mode is expressed. A data collection system is included. The proposed spacecraft is three-axes-stabilized and has a Sun-synchronous, near polar circular orbit with 750 km altitude. The selected configuration separates payload module and bus module. A thermostable carbon fibre grating structure is the central framework of the satellite. Each major subsystem is housed in a separate compartment and can be integrated and tested individually. First mass estimates resulted in 450 kg for the payload and 880 kg for the bus. The maximum power needed is 1750 W (for 6 min three times a day), which will be provided by a 1330 W solar array and two batteries. A “low cost” model philosophy is defined; the time schedule envisages a program start in late 1980 and a launch possibility end of 1985.     

我国卫星光学遥感技术的成就与新世纪展望

介绍我国已发射的光学型对地观测卫星和研制成功的航天光学遥感器 ,展示中国在卫星遥感领域取得的成就 ,并展望新世纪卫星光学遥感技术的发展     

火星卫星的冻结轨道研究

冻结轨道是一种稳定的轨道,地球、火星、月球的卫星因引力场的南北不对称,都存在冻结轨道.由于主星体引力场的不同,它们卫星的冻结轨道也有不同的特性.地球卫星的冻结执道的偏心率非常小,对卫星遥感非常有利,国内外已有相当多的近地遥感卫星采用这种轨道.月球卫星的冻结轨道偏心率随轨道倾角的不同有很大的变化,对月球卫星冻结轨道的研究...     

FY-1D极轨气象卫星

介绍了“风云一号D”（FY－1D）极轨气象卫星的主要技术参数和遥感仪器配置等总体组成概况。简述了卫星的技术特点和发展入轨过程，给出卫星姿轨控、可见光和红外扫描辐射计、空间粒子成分监视器、传输信道、星上记录储存和卫星其他功能、性能在轨测试的结果，并进行了分析。结果表明，卫星的性能优于设计要求。最后列举了卫星的某些应用结果。