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5,394 results on '"Unmanned spacecraft"'

1. Analytical solution for autonomous determination of near circular orbits

Author

Hashida, Yoshikazu

Subjects
629, Unmanned spacecraft, satellites
Abstract

An analytical approach for satellite orbit determination methodology will be investigated in this work. The motivation for this study is the realisation that enhanced microsatellites can be expected which require accurate orbital knowledge and control onboard to support their payloads. However, a satellite tracking capability has not yet been implemented at Surrey even on the ground segment, as this would involve a considerable cost to maintain and operate. Advanced modern technology enables micro or nanosatellites to have low cost and low power Global Positioning System (GPS) receivers, which opens the way for onboard orbit determination. However, the heavy computational demand required for executing orbit determination has made such an approach unsuitable given the onboard processing environment. In order to overcome this problem, a novel analytical description of a perturbed orbit has been developed by focusing on near circular orbits which is appropriate for Low Earth Orbit (LEO) satellites. To use this analytic description of the orbit for orbit determination extensively reduces the computational demand as no numerical integrator is required to propagate the orbit, the variational equation of the orbit, or state transition matrix. Thus analytical solutions to the orbit perturbation problem are the main focus of this work. The majority of extensive studies made mainly in the late 50's to 60's on this subject considers the general case of orbits, so that the solutions are extremely lengthy and complex. Due to the conventional methods they have chosen, the solutions have a singularity when the eccentricity approaches zero and the argument of perigee becomes undefined. The new description of the perturbed motion of near circular orbits is developed in this work, which does not have a singularity when the eccentricity is zero. This novel description is a natural expansion of the epicyclic motion of a small eccentric orbit, which results in a much simpler expression in the solutions and provides a greater understanding of orbital geometry. A fully analytical orbit determination system is also developed based on this epicyclic description of a perturbed orbit. As this orbit estimator requires no numerical integration scheme, it has extensive computational advantages and suits most onboard applications. This analytical orbit estimator is practically implemented onboard UoSat-12, which is Surrey's 350 kg class minisatellite. It has been operated for more than two years, and has demonstrated reliable autonomous onboard orbit determination. The in-orbit orbit determination results as well as the evaluations of practical accuracy are also presented.

Published
2003

2. Satellite constellation design and radio resource management using genetic algorithm

Author

Asvial, Muhamad

Subjects
621, Unmanned spacecraft, satellites
Abstract

A novel strategy for automatic satellite constellation design with satellite diversity is proposed. The automatic satellite constellation design means some parameters of satellite constellation design can be determined simultaneously. The total number of satellites, the altitude of satellite, the angle between planes, the angle shift between satellites and the inclination angle are considered for automatic satellite constellation design. Satellite constellation design is modelled using a multiobjective genetic algorithm. This method is applied to LEO, MEO and hybrid constellations. The advantage of this algorithm is automatic satellite constellation design whilst achieving dual satellite diversity statistics. Furthermore a new strategy of dynamic channel allocation is proposed using a genetic algorithm for use in MSS networks. The main idea behind this algorithm is to use minimum cost as a metric to provide optimum channel solutions for specified interference constraints. The frequency reuse condition for all spotbeams is investigated as a function of time. The update interval time and the sampling time are introduced in order to track time valiant coefficients and constraints of the algorithm. The method is demonstrated for S-UMTS based on a MEO satellite constellation. Using this algorithm, it is shown that the proposed model outperforms conventional DCA schemes in terms of capacity of the system and Quality of Service (QoS).We show in the thesis that the genetic algorithm is a robust method for calculation of dynamic variations in satellite constellation design and provides resource allocation improvements over DCA in MSS system networks.

Published
2003

3. Adaptive Neural Network Control of a Flexible Spacecraft Subject to Input Nonlinearity and Asymmetric Output Constraint

Author

Hiroshi Yokoi, Yilin Wu, Yu Liu, He Cai, and Xiongbin Chen

Subjects
Lyapunov function, Artificial neural network, Spacecraft, Unmanned spacecraft, Computer Networks and Communications, Computer science, business.industry, Computer Science Applications, Constraint (information theory), Nonlinear system, symbols.namesake, Artificial Intelligence, Control theory, Robustness (computer science), Backstepping, symbols, business, Software
Abstract

This article focuses on the vibration reducing and angle tracking problems of a flexible unmanned spacecraft system subject to input nonlinearity, asymmetric output constraint, and system parameter uncertainties. Using the backstepping technique, a boundary control scheme is designed to suppress the vibration and regulate the angle of the spacecraft. A modified asymmetric barrier Lyapunov function is utilized to ensure that the output constraint is never transgressed. Considering the system robustness, neural networks are used to handle the system parameter uncertainties and compensate for the effect of input nonlinearity. With the proposed adaptive neural network control law, the stability of the closed-loop system is proved based on the Lyapunov analysis, and numerical simulations are carried out to show the validity of the developed control scheme.

Published
2022

4. Development of sensor technology to facilitate in-situ measurement of damage in composite materials for spacecraft applications

Author

Mowlem, Matthew Charles

Subjects
629, Unmanned spacecraft, satellites
Abstract

The work presented in this thesis, which details the development and evaluation of an optical fibre damage sensor, was supported by The European Space Administration and by a DTI-NERC LINK grant under the SEASENSE programme. The sensing system developed as part of this programme uses fibre Bragg gratings as sensing elements. The translation of the output of these sensors into strain information is achieved using a novel interrogation system described in this work. The work presented in this thesis is believed to be the first evaluation of this technology for the detection / characterisation of hypervelocity impacts and impact damage. In order to evaluate the suitability of this system for spacecraft impact damage assessment, this work explores the response of aerospace composites to impact by reviewing previous work in composite modelling, acoustics and experimental evaluation. This knowledge is extended by the use of the system in both high and low velocity impact experiments with sensors embedded in carbon fibre reinforced plastic. Alternative optical techniques and conventional sensing methods are compared to the observed performance. The system has also proved to be of sufficient resolution and close to sufficient accuracy for use in monitoring an array of Bragg grating based temperature and pressure sensors for oceanographic applications. This work enabled a detailed examination of the system's accuracy, and stability, which was required for structural sensing studies, and illustrates the breadth of possible applications for this technology. The work concludes that this system would be capable of measuring impacts large enough to cause damage that would threaten the integrity of the composite component. Very few of the large number of small impacts expected would occur close enough to a Bragg grating sensor to register a reading. However, with further development, an interrogation system could be created that was capable of monitoring the impact induced flexural wave in the composite. An array of sensors would allow triangulation of the location of impact, and measurement of the impact: momentum.

Published
2002

7. Alternative geometry hybrid rockets for spacecraft orbit transfer

Author

Haag, Gary S.

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

The cost-effectives mall spacecrafht as becomea n enablingt ool in the pursuit of near earth space commerce. Although small spacecraft have typically forgone the complexity and historically high cost of spacecraft propulsion, the inability to cost-effectively reach specific data gathering orbits from secondary launches presents a serious limitation to the small spacecraft industry. A cost-effective propulsion system capable of moving the secondary spacecraft from the launch orbit to the required mission orbit will effectively increase the number of viable secondary launch opportunities and in some cases provide a higher scientific or commercial return. Propulsion will also allow the dispersing of multiple spacecraft from a single launch vehicle and the inherent ability to de-orbit after a useful mission life. While other propulsion alternatives were considered in this research program, the hybrid rocket was identified as having high potential for suiting the established high-performance, lowcost and safety criteria. However, as this research has shown, the conventional hybrid rocket is not well suited to incorporation within small spacecraft; this is primarily due to the required length verses diameter (UD) to achieve high performance in the conventional hybrid. This research program has produced and tested a novel hybrid rocket engine. The all-new engine is significantly different from the conventional hybrid, exhibiting higher performance and with a geometry that drastically reduces hybrid rocket integration and operation issues. In addition, the new hybrid design has been successfully tested at higher volumetric loading factors than the conventionadl esignsi dentifiedi n the literature. The new alternative geometry hybrid rocket employs tangential oxidiser injectors that induce a vortex flow field to the centrally mounted rocket nozzle. The induced flow field has been shown to provide better fuel and oxidiser mixing. In addition, the tangential oxidiser injection provides an inherent film cooling effect for the combustion chamber wall, allowing the chamber to be fabricated of low cost materials. The new hybrid rocket engine was dubbed the Vortex Flow "Pancake" hybrid or "VFP". This researchp rogramr epresentsth e most technologicallya mbitiousp ropulsionr esearch program conducted by the Surrey Space Centre to date as the tools to analyse and design this engine had to be experimentally derived. Although the fundamental process of burning solid fuel remains unchanged, the combustion chamber gas-dynamics - so vital for predicting fuel liberation and performance within the conventional hybrid - are radically changed in the new configuration. Whereas the conventional hybrid has demonstrated a strong correlation with increasing combustion port diameter and fuel liberation, this research has shown that fuel liberation within the VFP does not obey any such relationships. Operationally, this research has shown that the VFP exhibits a higher fuel volumetric loading factor, higher combustion efficiency and less of an O/F (and consequent performance) shift than conventional designs. This research has proven the VFP to be superior to the conventional hybrid design in every aspect tested. However, this is only part of the benefit realised by the new VFP design as the external geometry of the VFP is the primary benefit enabling the technology to be applied to small spacecraft. Conventional hybrids need L/D ratios in excess of 15 to provide adequate performance, the novel VFP design has been regularly tested at UD's less than 1 with combustion efficiency very near 100%. This unique hybrid characteristic allows the VFP to be integrated on the outside of a spacecraft, in or as part of the spacecraft separation system. An externally mounted engine conserves centrally located spacecraft volume (reducing the need for multiple oxidiser tank scenarios). In addition, the external mount also allows waste heat to be radiated to space rather than other (internal) spacecraft components.

Published
2001

8. The long-term interactions of satellite constellations with the orbital debris environment

Author

Walker, Roger

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

An increasing number of multiple-satellite constellations, providing global telecommunications, will be launched into low Earth orbit (LEO) within the next decade. These systems could be utilised for many years in a growing debris environment that presents, a significant long-term collision hazard. The main objective of this PhD is to examine the long-term impact of these systems on the LEO debris environment, and vice versa. The high-resolution simulation of the historical and long-term future evolution of the LEO debris environment, and the detailed long-term prediction of collision risk to any target orbit intersecting LEO, is not trivial to achieve within a single model. The Integrated Debris Evolution Suite (IDES) has been developed as an extremely flexible tool, with a wide scope of state-of-the-art capabilities in all of these areas. A highly novel aspect of the IDES model is the new target-centred approach to the prediction of future collision events. This approach has made an advance over other traditional methods in the area of future collision event prediction and has improved the accuracy of modelling the all-important future collision fragment source within long-term debris evolution models. The IDES simulation software has undergone a rigorous validation programme to assess its accuracy. The historical debris environment simulated by IDES was validated by comparison with reliable measurement data. This validation exercise has greatly improved the confidence in the IDES model for the prediction of the long-term evolution of the debris environment and mission collision risks. The validated IDES model has been used in a number of comprehensive state-of-the-art applications. The long-term collision interactions of a wide range of different constellation designs with the LEO debris environment have been extensively simulated in a 'business as usual' future traffic scenario, both with and without the implementation of debris mitigation measures. The long-term impact of these different constellation designs on the future collision rate, population levels and collision risks in LEO has been evaluated to determine the sizes and orbits of constellations that the LEO debris environment can tolerate. An overall assessment of the long-term impact of the currently foreseen constellation traffic on the LEO debris environment has been performed. The effectiveness of a package of different routine mitigation measures on stabilising the long-term LEO debris environment has been studied and presented in the thesis. Long-term forecasts of LEO constellation collision risk have been produced by the IDES model. These forecasts are state-of-the-art and should be of considerable interest to constellation mission designers. Estimated debris-induced satellite failure rates were assessed for varying constellation architectures in order to find the sensitivity of the predictions to influential design parameters such as orbit selection, the number of satellites in the system, and satellite cross-sectional area. To put these predictions into context, the estimated debris-induced failure rates were compared to the rates expected from satellite component or sub-system failure.

Published
2000

9. Nonlinear dynamics of spacecraft power systems

Author

Lim, Yan Hong

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

This thesis pioneers the application of nonlinear dynamics to spacecraft power systems. Two areas of general interest are addressed. On the one hand, the fundamental dynamics of space power systems were investigated from a nonlineax dynamics perspective, and on the other, nonlinear dynamics concepts were used to realise a practical engineering application. The former examines four simple but relevant space power system models. The study revealed a variety of bifurcations, coexisting attractors and chaotic behaviour that could potentially shed light on some familiar but poorly understood effects in space power systems operations, including bus voltage collapse, spurious oscillations, and chaotic 'noise'. Because such behaviour manifests itself in nonlinear systems but could not be exposed by customary linear systems theory, potential anomalies may remain unpredicted which could lead to catastrophic consequences. As such, these results have important implications to reliability issues, critical in space. The exposition of the concepts and tools used in this thesis would serve the practising engineer by providing the basis and pave the way for studying larger and more complex systems, in the quest for improved system performance and reliability. In the course of this work, an algorithm to compute the maximum Lyapunov exponent from differential equations with discontinuities was required to confirm chaos. Although the concepts and tools for investigating smooth equations are well established, dynamics of non-smooth systems have not been extensively studied. Here, the algorithm proposed by Miiller to cope with the discontinuities in mechanics was reviewed and was found to be applicable to power electronics in general. As a confirmation, this algorithm was applied successfully to a well known Buck DC-DC converter. Although the exploitation of nonlinear dynamics to engineer direct practical applications is still in its infancy, one is presented in this thesis. A maximum power point tracker was synthesised via nonlinear dynamics principles, simulated and experimentally verified. Excellent static and dynamic performance were exhibited. In addition, a two-dimensional stroboscopic map was derived which adequately described the fundamental dynamics of the system. This is confirmed from the good agreement between the simulated and experimental return maps. Via this map and further bifurcation study, preliminary design guidelines were established.

Published
2000

11. Predicting the reliability of electronic subsystems and 'commercial-off-the-shelf' microprocessors on low-cost small satellites

Author

Asenek, Veronica

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

This thesis presents an investigation into methods for predicting and improving the reliability of electronic subsystems on low cost small satellites [LCSS]. Current methods for predicting the reliability of electronic systems were identified and the feasibility of these methods for predicting the reliability of electronic systems on LCSS were analysed. Trends in satellite failures and satellite design methodologies were studied. It was identified that, highly capable, LCSS have became possible due to the existence of advanced commercial-off-the-shelf (COTS) very large scale integrated circuits (VLSI) components. Typically, a large number of these components are employed on these satellites and the effect of space radiation on these components is a significant source of risk to their reliability. This research program therefore concentrated on addressing the effects of space radiation on the reliability of COTS VLSI components. In particular, traditional methods for predicting the rate and effects of radiation induced spontaneous logic state changes (Single Event Upsets (SEUs)) in satellite on-board microprocessors were critically examined. Problems associated with these methods were identified, and two new models to enable more accurate predictions were proposed, developed and tested. One of the models, a duty cycle prediction model, enables a better prediction of the "observable SEU induced error rate" in satellite microprocessor systems; and the other model, a SEU simulation model, enables the nature of SEU induced errors observed at microprocessor system level to be studied. The practical applications of both models were demonstrated by analysing a real satellite application system. These models will be particularly useful to engineers in the selection and application of reliable COTS microprocessors for satellite onboard computer intensive tasks without jeopardising reliability.

Published
1998

15. Control of colocated geostationary satellites

Author

Hardacre, S. and Bowling, Tom

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

Control of the inter-satellite distances within a cluster of colocated satellites located in the same GEO window is examined with regards to the close approaches between pairs of satellites. Firstly, the orbital evolution and station keeping control of a single GEO satellite is examined and a new IBM PC based software program capable of performing both these functions autonomously from initial values of the orbital position and date is detailed and validated. Cluster design ideas are then examined in detail and the propagation software is used to generate data for a cluster of four satellites. Two test cases are examined to quantify the frequency of close approaches between individual satellite pairs, each test case using a different orbital element separation strategy but the same station keeping control scheme. The results of the study are then compared with previous research and discussions are presented on the advantages of each method. Finally, a cluster geometry correction manoeuvre, based on Hill's equations of relative motion, is presented which requires only those thrusters used by typical station keeping. This manoeuvre is integrated into the computer software and the two test cases noted previously are again propagated and the close approach results analysed to demonstrate the reduction in the number of close approaches below 5 km.

Published
1996

17. The design and implementation of a small satellite navigation unit based on a global positioning system receiver

Author

Unwin, Martin

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

This thesis describes the definition, implementation, and in-orbit testing of an autonomous navigation unit based upon a GPS receiver for use on board a small satellite in low Earth orbit. It explains the motivation for the use of GPS to provide this function, and describes the practical application and integration of this technology into an existing microsatellite system. Until now, the technology for any satellite to track itself has not existed. Space agencies spend significant funds supporting a network of tracking stations around the world for orbit determination. With the recent realisation of the Global Positioning System and the availability of inexpensive receiver hardware, it has become a practical proposition to include a GPS receiver within the demanding constraints of a small satellite. A GPS receiver on-board a satellite can eliminate the necessity for ground-based tracking by providing an autonomous orbit determination capability. During the course of these studies, the requirements and constraints of a small satellite were identified by the author and matched with the capabilities of a GPS receiver. A GPS Navigation Unit was defined to provide autonomous services available oil demand for the satellite platform and payloads; position and velocity; time synchronisation; orbital elements; payload triggering and GPS data logging (for experimental and research purposes). The GPS Navigation Unit includes a processing facility capable of command and initialisation of the GPS receiver, and data processing to give orbit determination capability. When used on a microsatellite, the additional constraints of low power consumption necessitate the intermittent operation of the GPS receiver. To test the concept of the GPS Navigation Unit, a commercial Trimble TANS II GPS receiver system that had been modified for orbital velocities was integrated into the PoSAT-1 microsatellite which was launched into low Earth orbit in September 1993. A method for orbit determination was developed for use with the output from the GPS receiver, and the GPS Navigation Unit was implemented in software according to the constraints of the PoSAT-1 mission. The significant results from these studies include: The first use of a GPS receiver on a microsatellite, PoSAT-1. The implementation, test and validation of a GPS Navigation Unit in low Earth orbit. The first satellite mission to demonstrate the capability for autonomous orbit determination through the GPS Navigation Unit. The definition of the general-purpose interfaces between a small satellite and a satellite- borne GPS Navigation Unit.

Published
1995

19. Structural analysis of a joint for deployable space systems

Author

York, Darren M.

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

The establishment of large space systems in the Earth's orbit requires the development of new construction techniques. As large structures are being proposed for future projects, several orbit construction processes have evolved. Of these, the concept of deployable truss structures is one which is appraised during this research. An energy loaded joint is presented which realises the potential of this technique. Incorporated into a skeletal truss framework, however, the structural characteristics of the joint will influence the overall performance of the structure. In order to assess the significance of this, an investigation is conducted into the structural behaviour of the joint. Although the deployable concept has been primarily developed for realising large structures in the Earth's orbit, the technique can also be used in terrestrial applications. Accordingly, a numerical study evaluates the static stress distribution generated through the joint; the structure is considered to be in a fully deployed state. The investigation appraises the effects of manufacturing tolerances and indicates their significance on design. Dynamic loading induced in the space environment highlights the joint to possess a strong geometrical nonlinearity. The joint describes a bilinear flexural stiffness property that is associated with the design. As a consequence, resonant frequencies exhibited by small truss structures are found to be dependent on a variety of geometric and loading parameters. Large trusses are also found to be affected although their behaviour is seen to be less dependent on the characteristics of individual joints. An experimental investigation confirms the presence of nonlinearity within the energy loaded joint. The characteristic response during vibration highlighted the difficult task of predicting structural behaviour. This instigated a redevelopment of the joint design incorporating measures which eradicate the cause of the geometrical nonlinearity. Tests reveal this design to be a significant improvement and an important contribution to the development of deployable structures.

Published
1992

20. Narrowband characterisation of high elevation angle land mobile satellite channel

Author

Butt, Gulraiz

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

The demand for the mobile communications is growing, as is the trend for the introduction of new services and for these to be available over wide geographical areas. Satellites, due to their inherent ability to support long distance reliable communication, are believed to play a pivotal role in realising such systems at national and international levels. Until the recent past, satellites were used to provide a communication facility to mobile platforms that could afford to carry relatively heavy and complex terminals such as those in maritime use. However, many mobile services for aeronautical and land users have also been introduced since 1990. Land Mobile Satellite (LMS) communications have until now been restricted to low data rates and geostationary orbit (GEO) satellites. Increasingly the demand is for integrated speech and data services. Signal propagation in land mobile conditions is one of the most important design considerations limiting the performance of a satellite based mobile communication system. In order to provide communication services through a viable satellite network, a proper knowledge of link degradation due to the mobile channel conditions is essential. In the land mobile environment, shadowing of the line-of-sight (LOS) signal and multipath propagation can limit the link performance for considerable percentages of time. Satellites in orbits other than the geostationary orbit have, therefore, been proposed for mid-to-high latitude regions in order to provide high elevation angles at the mobiles, thus reducing losses due to blockage, and as a result improve link margin requirements. In addition, to achieve world-wide mobile communications, constellations of low earth orbit (LEO) satellites have been proposed. However, sufficient information on link performance, under reduced shadowing conditions at high elevation angles, does not exist and this is critically important in the planning or implementation of future HEO and LEO based satellite systems. The research work reported here was carried out in an attempt to extend the existing propagation database applicable to high elevation angle land mobile satellite (LMS) channel at the L-band. However, other frequencies corresponding to the S and Ku bands, were also included to generate data at frequencies for likely future applications and enable a direct comparison of propagation characteristics to be made between the bands. In the absence of appropriate satellite source(s), the multiband propagation measurement campaign was undertaken using a helicopter. The helicopter provided a platform which simulated the high elevation angle satellite signal. Different environments such as suburban, wooded and open were considered, and mobile measurements were made at various high path elevation angles in each environment. The statistical analysis of the measurement data provided useful information on LMS channel behaviour and its dependency on the signal frequency, elevation angle and the mobile channel environment. It has been observed that smaller attenuations are experienced as the elevation angle increases or the radio frequency decreases. Significant effect on the channel fading is observed due to variable amounts of shadowing encountered under varying channel environments. Using the results of the measurement campaign described in this thesis, it has been possible to propose a fading model for use in future planning for high elevation paths that will be encountered in both HEO and LEO mobile satellite systems.

Published
1992

23. Optimal collision-free path planning of a free-floating space robot using spline-based trajectories

Author

Tomasz Rybus, Mateusz Wojtunik, and Fatina Liliana Basmadji

Subjects
Unmanned spacecraft, Spacecraft, Computer science, business.industry, Monte Carlo method, Aerospace Engineering, Computer Science::Robotics, Spline (mathematics), Control theory, Position (vector), Path (graph theory), Motion planning, business, Robotic arm
Abstract

A significant number of the planned on-orbit servicing and active debris removal missions will be performed by a spacecraft equipped with a robotic arm. In this paper we propose a new method for the path planning of the robotic arm mounted on the free-floating unmanned spacecraft. In the proposed approach the path of the arm is described in the joint space by a spline function. The coordinates of spline knots form the vector of decision variables. The constrained nonlinear optimization problem is formulated and solved with an active-set algorithm. The proposed method generates a collision-free path of the arm that results in the desired position and orientation of the gripper and the desired attitude of the spacecraft. The possibility of achieving all these goals at the same time is the major advantage of the proposed approach. The practical applicability of the presented method is demonstrated in experiments performed on the planar air-bearing microgravity simulator (for a planar case) and using numerical simulations performed with the Monte Carlo method (for a spatial case). In the planar case the optimal path is compared with the path obtained using the bi-directional Rapidly-exploring Random Trees (RRT) algorithm. It is shown that the path obtained using the proposed method is shorter and smoother than the RRT path.

Published
2022

24. Reptiles in Space Missions: Results and Perspectives

Author

Victoria Gulimova, Alexandra Proshchina, Anastasia Kharlamova, Yuliya Krivova, Valery Barabanov, Rustam Berdiev, Victor Asadchikov, Alexey Buzmakov, Denis Zolotov, and Sergey Saveliev

Subjects
spaceflight adaptation, unmanned spacecraft, Foton-M2, Foton-M3, Bion-M1, Foton-M4, thick-toed gecko (Chondrodactylus turneri), ornate day gecko (Phelsuma ornata), X-ray microtomography, Biology (General), QH301-705.5, Chemistry, QD1-999
Abstract

Reptiles are a rare model object for space research. However, some reptile species demonstrate effective adaptation to spaceflight conditions. The main scope of this review is a comparative analysis of reptile experimental exposure in weightlessness, demonstrating the advantages and shortcomings of this model. The description of the known reptile experiments using turtles and geckos in the space and parabolic flight experiments is provided. Behavior, skeletal bones (morphology, histology, and X-ray microtomography), internal organs, and the nervous system (morphology, histology, and immunohistochemistry) are studied in the spaceflight experiments to date, while molecular and physiological results are restricted. Therefore, the results are discussed in the scope of molecular data collected from mammalian (mainly rodents) specimens and cell cultures in the parabolic and orbital flights and simulated microgravity. The published data are compared with the results of the gecko model studies after the 12−44.5-day spaceflights with special reference to the unique peculiarities of the gecko model for the orbital experiments. The complex study of thick-toed geckos after three spaceflights, in which all geckos survived and demonstrated effective adaptation to spaceflight conditions, was performed. However, future investigations are needed to study molecular mechanisms of gecko adaptation in space.

Published
2019
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25. Business

Subjects
Boeing Co. -- Officials and employees, Aircraft industry -- Officials and employees, Unmanned spacecraft, Spacecraft, Space stations, Business, Economics, Business, international
Abstract

The problems mounted at Boeing, as it more than doubled the cost it expects to incur from the grounding of the 737 MAX airliner, to $18.6bn. The aerospace company reported [...]

Published
2020

26. Imperial's programming could go down as the most devastating software mistake of all time

Subjects
Unmanned spacecraft, Pride, Space vehicle accidents, Time, Budgets, Spacecraft, General interest, News, opinion and commentary, University of London. Imperial College of Science and Technology
Abstract

Byline: Opinion By David Richards and Konstantin Boudnik In the history of software mistakes, Mariner 1 was probably the most notorious. The unmanned spacecraft was destroyed seconds after launch from [...]

Published
2020

27. Boeing 737 Max fallout: CEO Muilenburg out

Subjects
Boeing Co. -- Officials and employees, Aircraft industry -- Officials and employees, Unmanned spacecraft, Chief executive officers, Spacecraft, Chairpersons, News, opinion and commentary
Abstract

Byline: Dawn Gilbertson and John Bacon, USA TODAY Boeing CEO Dennis Muilenburg, who faced intense criticism over his handling of the 737 Max crisis, resigned effective immediately, the company announced [...]

Published
2019

28. Starliner lands softly in New Mexico

Subjects
Boeing Co., Spacecraft, Aircraft industry, Unmanned spacecraft, Deployment (Military science), News, opinion and commentary
Abstract

Byline: Emre Kelly, Florida Today, USA TODAY NETWORK MELBOURNE, Fla. - Despite complications after launch from Cape Canaveral, Florida, Boeing's Starliner capsule softly touched down in New Mexico early Sunday, [...]

Published
2019

29. Arc of progress [...]

Subjects
Boeing Co., Aircraft industry, Control systems, Unmanned spacecraft, Spacecraft, Space stations, General interest
Abstract

Arc of progress The Boeing Starliner, an unmanned spacecraft launched yesterday from Nasa's Cape Canaveral base, was supposed to fly to the International Space Station in a test mission but [...]

Published
2019

30. Cтратегія поводження з космічним сміттям

Author

Viktoriia Kovalska, Lesia Pavliukh, Olena Todorovych, and Irina Syrotina

Subjects
Collision avoidance (spacecraft), Unmanned spacecraft, Spacecraft, business.industry, Electromagnetic shielding, Shields, Environmental science, General Medicine, Aerospace engineering, business, Debris, Space environment, Space debris
Abstract

Purpose and Objectives of the Work. This scientific article is devoted to space debris management issues. The aim of this scientific investigation is assessment of the protection methods from the influence of space debris on the Earth. Methods of Research: ground-based measurements, space-based measurements, analysis of the protection strategies. Research Results. Providing of two protection strategies: shielding (space debris shields for both manned and unmanned spacecraft can be quite effective against small particles. Protection against particles 0.1-1 cm in size can be achieved by shielding spacecraft structures) and collision avoidance which is possible by reducing the amount of new debris created and, in the longer term, removing existing debris. Discussion. To improve the space environment we need to develop the complex approach, which, first of all, must include: 1) reducing creation of debris; 2) removing existing debris.

Published
2018

31. Shielding of Cosmic Radiation by Fibrous Materials

Author

Andrea Ehrmann and Tomasz Blachowicz

Subjects
space radiation, QH301-705.5, QC1-999, Chemicals: Manufacture, use, etc, Cosmic ray, Astrobiology, Biomaterials, cosmic rays, TP890-933, Biology (General), Civil and Structural Engineering, Physics, Potential impact, Unmanned spacecraft, long-term space travel, business.industry, TP200-248, Textile bleaching, dyeing, printing, etc, Space radiation, high energy interactions, Mechanics of Materials, Electromagnetic shielding, Ceramics and Composites, Radiation protection, business, radiation protection
Abstract

Cosmic radiation belongs to the challenges engineers have to deal with when further developing space travel. Besides the severe risks for humans due to high-energy particles or waves, the impact of cosmic radiation on electronics and diverse materials cannot be neglected, even in microsatellites or other unmanned spacecraft. Here, we explain the different particles or waves found in cosmic radiation and their potential impact on biological and inanimate matter. We give an overview of fiber-based shielding materials, mostly applied in the form of composites, and explain why these materials can help shielding spaceships or satellites from cosmic radiation.

Published
2021

34. Ionospheric corrections for SHF satellite radar altimetry

Author

Leigh, Richard Peter

Subjects
621.382, Unmanned spacecraft, satellites
Abstract

To measure the satellite-ocean altitude, a radar altimeter transmits a nadir-directed microwave pulse and times the return of the surface reflection. The intervening free electrons of the ionosphere cause group delay of the pulse resulting in an overestimate of the platform altitude by an amount directly proportional to the sub-satellite electron content. In effect the figure of the ocean surface detected by the altimeter is modulated by the spatial and temporal variation of the ionospheric electron content. A two stage technique has been developed to remove the bias imposed by the ionosphere on altimetric measurements. The first stage generates a prediction of electron content based on ionospheric climatology. The second stage is an adaptive modelling procedure which makes use of data from satellite-ranging radar systems. The first chapter of this thesis gives an introduction to the Earth's ionosphere, describes its effect on radar altimetry and suggests a technique to correct for this influence. Chapter Two reviews previous work in related areas before Chapter Three embarks on a description of the spatial and temporal behaviour of electron content. Chapter Four describes the mathematical sub-models which form the basis of the empirical model and Chapter Five is devoted to the calibration and validation of this model. Chapter Six covers the calculation of the coherence functions of electron content which are crucial for the operation of the adaptive procedure. Chapter Seven compares the new model with one employed for a previous altimeter mission and Chapter Eight summarizes what has gone before and suggests topics for future research.

Published
1989

36. Gravity gradient and magnetorquing attitude control for low-cost low earth orbit satellites : the UOSAT experience

Author

Hodgart, M. S.

Subjects
629.46, Unmanned spacecraft, satellites
Abstract

An important concern in spacecraft engineering is attitude determination control and stabilisation (ADCS) - the combination of applied mathematics, classical physics and modern technology which maintains the pointing direction of one or more axes of an Earth-orbiting satellite. This thesis is a detailed study of a particular type of ADCS which exploits the gravity-gradient effect, which is just the weak tendency for an appropriately shaped body to point naturally in preferred directions; reinforced by magnetorquing, which is the active interaction of the geomagnetic field with a switched current passing through coils in the spacecraft body. The advantages of this technology is that it is low-cost, non-consumable and has no moving parts - so constituting no limitation to the satellite's life. The thesis is a detailed study of this form of ADCS with specific application to low Earth polar-orbiting (LEO) satellites, for which it is particularly suitable. The work is also a study in attitude determination based solely on a 3-axis magneometer measurement of the geomagnetic field, which is in principle a simple way, in terms of technology, of determining the attitude of the spacecraft, and from this controlling the attitude, if mediated by an on-board computer implementing appropriate algorithms. The results are for the most part practically based on the author's involvement with two satellites over a six year period with the satellites UOSAT-1 and UOSAT-2, which were designed, built, and continue to be controlled from the University of Surrey. A practical innovation in 2-axis attitude control is described: the active 'delibration' by active damping of a gravity-gradient controlled LEO satellite in an attitude-stabilised state, using a threshold comparison algorithm. A new theory and algorithms are then developed for 3-axis attitude control, based on a complementary use of magnetorquing and gravity gradient. Subject to further development these could alter the general perception of the most effective way of controlling low Earth orbiting satellites.

Published
1989

37. VZLUSAT-1: Nanosatellite with miniature lobster eye X-ray telescope and qualification of the radiation shielding composite for space application

Author

René Hudec, Martin Urban, Veronika Stehlikova, O. Nentvich, Tomas Baca, and Vladimir Daniel

Subjects
Physics, 010504 meteorology & atmospheric sciences, Unmanned spacecraft, business.industry, Payload, Aerospace Engineering, X-ray telescope, 01 natural sciences, law.invention, Telescope, law, 0103 physical sciences, Electromagnetic shielding, CubeSat, Satellite, Aerospace engineering, business, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Constellation, Remote sensing
Abstract

In the upcoming generation of small satellites there is a great potential for testing new sensors, processes and technologies for space and also for the creation of large in situ sensor networks. It plays a significant role in the more detailed examination, modelling and evaluation of the orbital environment. Scientific payloads based on the CubeSat technology are also feasible and the miniature X-ray telescope described in this paper may serve as an example. One of these small satellites from CubeSat family is a Czech CubeSat VZLUSAT-1, which is going to be launched during QB50 mission in 2017. This satellite has dimensions of 100 mm × 100 mm × 230 mm. The VZLUSAT-1 has three main payloads. The tested Radiation Hardened Composites Housing (RHCH) has ambitions to be used as a structural and shielding material to protect electronic devices in space or for constructions of future manned and unmanned spacecraft as well as Moon or Martian habitats. The novel miniaturized X-ray telescope with a Lobster Eye (LE) optics represents an example of CubeSat's scientific payload. The telescope has a wide field of view and such systems may be essential in detecting the X-ray sources of various physical origin. VZLUSAT-1 also carries the FIPEX payload which measures the molecular and atomic oxygen density among part of the satellite group in QB50 mission. The VZLUSAT-1 is one of the constellation in the QB50 mission that create a measuring network around the Earth and provide multipoint, in-situ measurements of the atmosphere.

Published
2017

38. An analysis of soft-switching boost-converters for the spacecraft’ power system

Author

Yu.A. Shiniykov, A.V. Osipov, E.V. Zagorodskikh, V.N. Shkolnyi, and S.A. Zapolskiy

Subjects
Service module, Electric power system, Spacecraft, Unmanned spacecraft, Soft switching, business.industry, Computer science, Electrical engineering, General Medicine, Converters, business, Spacecraft design
Published
2017

39. Micrometeoroid/Orbital Debris (MMOD) Impact Detection and Location Using Fiber Optic Bragg Grating Sensing Technology

Author

Eric L. Christiansen, Francisco Pena, Anthony Piazza, Allen R. Parker, W. Lance Richards, and Steven L. Rickman

Subjects
Engineering, Spacecraft, Unmanned spacecraft, business.industry, Micrometeoroid, 010401 analytical chemistry, Space Shuttle, 02 engineering and technology, General Medicine, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Space Shuttle thermal protection system, International Space Station, Hypervelocity, Aerospace engineering, 0210 nano-technology, business, Space debris, Remote sensing
Abstract

Spacecraft in low earth orbit (LEO) experience a variety of hazards including exposure to micrometeoroids and orbital debris (MMOD). Average impact speeds for orbital debris on spacecraft in LEO are 9 to 10 km/s, and 20 km/s for micrometeoroids. Due to their high speeds, MMOD can cause considerable impact damage to sensitive spacecraft surfaces such as windows, structural elements, electronic boxes, solar arrays, radiators, thermal protection system (TPS) materials covering crew/cargo return vehicles, as well as crew modules. Prolonged exposure to the on-orbit MMOD environment can potentially compromise the TPS covering return vehicles such as the future crewed vehicles expected to visit and remain for a half-year or longer at the International Space Station (ISS). However, determination of MMOD impact damage to the TPS on crew/cargo return vehicles, or damage to other orbiting spacecraft currently requires visual inspection. For human-rated spacecraft such as the ISS and, previously, the Space Shuttle Orbiter, this has required crew time as well as vehicle assets to identify damage due to MMOD strikes. For unmanned spacecraft, there are no human assets present to conduct detailed surveys to identify potential damage. While the practice of visual inspection may successfully indicate the location of a debris strike, it does not currently allow precise determination of exactly when the debris strike occurred. It is only possible to determine that a debris strike has occurred between two successive inspection events unless damage to other components can allow inference that a debris strike occurred at a specified time. Initial development testing of a novel MMOD sensing concept amenable for potential implementation in a structural health monitoring system is discussed. Using fiber Bragg grating (FBG) sensing technology, a test article representative of a spacecraft MMOD shield layer or spacecraft structure was subjected to hypervelocity impact testing. The FBG array successfully detected that an impact had occurred, when it occurred and where it occurred on the structure. Detection of both the impact wave and the residual strain in the structure can be used to infer the location of the impact. The potential application of this technology to spacecraft is discussed.

Published
2017

40. Investigating Miniaturized Electrodynamic Tethers for Picosatellites and Femtosatellites

Author

Sven G. Bilén, Jesse K. McTernan, Iverson C. Bell, and Brian E. Gilchrist

Subjects
020301 aerospace & aeronautics, Engineering, 010504 meteorology & atmospheric sciences, Spacecraft, Unmanned spacecraft, business.industry, Aerospace Engineering, 02 engineering and technology, Propulsion, 01 natural sciences, Spacecraft design, 0203 mechanical engineering, Space and Planetary Science, Range (aeronautics), Physics::Space Physics, Orbit (dynamics), Miniaturization, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, Electrodynamic tether, 0105 earth and related environmental sciences
Abstract

The success of nanosatellites (1–10 kg) and the miniaturization of sophisticated low-power electronics has motivated interest in even smaller “smartphone”-sized spacecraft as either standalone spacecraft or elements in a maneuverable fleet. These spacecraft, known as picosatellites (100 g–1 kg) and femtosatellites (less than 100 g), have the potential to enable missions requiring a distributed fleet of sensor spacecraft (for example, distributed aperture, simultaneous spatial sampling, etc.). However, without some degree of propulsion capability, these spacecraft would behave more as an uncontrolled swarm than as a coordinated formation. Furthermore, lifetime in low Earth orbit can be limited for low-mass spacecraft with high area-to-mass ratios. This paper shows that a relatively short (few meters) electrodynamic tether is capable of providing picosatellites and femtosatellites with propellantless drag cancellation and even the ability to change orbit over an altitude range determined by the ionospheric ...

Published
2017

41. The Design of Low Thrust Engine Spacecraft for Near-earth Asteroid Exploration

Author

Hu Yudong, Maxim K. Fain, Olga L. Starinova, B. Alipova, and Roman M. Khabibullin

Subjects
020301 aerospace & aeronautics, Engineering, Near-Earth object, Unmanned spacecraft, Spacecraft, business.industry, Potentially hazardous object, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Thrust, 02 engineering and technology, General Medicine, 01 natural sciences, Spacecraft design, Service module, 0203 mechanical engineering, Physics::Space Physics, 0103 physical sciences, Trajectory, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, 010303 astronomy & astrophysics
Abstract

This paper discusses the application of computer-assisted design systems to development of low thrust spacecraft intended to take an exploratory flight to potentially hazardous asteroids. The design model of the low thrust spacecraft that is created with computer-aided design systems is described. The mathematical motion model within the heliocentric system of coordinates for such type of spacecraft is considered and used for a motion simulation session. The simulation of flight to the potentially hazardous asteroid is performed with the aid of special complex software that is developed for the purpose of the work. The results of the paper consist of a detailed three-dimensional model of the low thrust spacecraft, heliocentric trajectory of the spacecraft, the values of flight duration and propellant consumption during exploratory flight.

Published
2017

42. UML-MODEL CONTROL SYSTEM UNMANNED AIRCRAFT SYSTEMS

Author

Sergiі Nesterenko and Аndrii Akymenko

Subjects
Model control, Unified Modeling Language, Unmanned spacecraft, Computer science, Systems engineering, computer, computer.programming_language
Published
2017

43. Introducing manufacturing features into numerical modeling of hypervelocity impact damage of composite pressure vessels

Author

Igor Telichev and Aleksandr Cherniaev

Subjects
Propellant, Filament winding, Materials science, Unmanned spacecraft, Spacecraft, business.industry, 02 engineering and technology, General Medicine, Structural engineering, 021001 nanoscience & nanotechnology, Pressure vessel, 020303 mechanical engineering & transports, 0203 mechanical engineering, Hypervelocity, Aerospace engineering, 0210 nano-technology, business, Space environment, Space debris
Abstract

Composite pressure vessels are extensively used in unmanned spacecraft systems due to high specific strength of composites, which provides higher mass savings as compared to metallic vessels. The most common example is their use as liquid propellant tanks. Being a part of spacecraft, composite vessels are exposed to space environment, and therefore, may be subjected to hypervelocity impacts (HVI) by orbital debris or micrometeoroids. This paper analyzes the manufacturing features such as filament winding pattern and defects of fabrication that may influence the response of composite pressure vessels to HVI, and discusses the ways to introduce those features into the numerical modeling.

Published
2017

44. The implementation of cost effective debris protection in unmanned spacecraft

Author

Stokes, P.H. and Swinerd, G.G.

Subjects
*SPACE vehicles, *SPACE debris, *ALGORITHMS, *GENETIC algorithms
Abstract

Proper characterisation of the survivability of an unmanned spacecraft to debris impact must go beyond just a simple assessment of the probability of penetration. Some penetrative damage may be survivable, particularly if critical internal equipment is arranged judiciously. Consideration of the satellite architecture can be seen as a potentially cost-effective and complementary approach to the more traditional method of adding shielding mass. To quantify the benefits of both strategies, and identify candidate protection solutions for a typical satellite design, a new model called SHIELD has been developed. Competing protection options are evaluated using a survivability metric. Rapid convergence on one or more `good'' designs can also be achieved with a built-in genetic algorithm search method. SHIELD''s potential as a project support tool is illustrated by applying it to the survivability evaluation of a satellite currently under design. The effectiveness of the genetic algorithm is also demonstrated, but on a more idealised spacecraft design. [Copyright &y& Elsevier]

Published
2004
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46. LUNAR SURFACE SAMPLING FEASIBILITY EVALUATION METHOD FOR CHANG’E-5 MISSION

Author

X. He, C. Ma, Y. You, Xin Wang, X. Feng, Weixing Wan, Man Peng, Jiyang Wang, Zhiye Zhang, and Y. Wang

Subjects
lcsh:Applied optics. Photonics, Pixel, Unmanned spacecraft, lcsh:T, Sampling (statistics), lcsh:TA1501-1820, Terrain, Kinematics, lcsh:Technology, Visualization, lcsh:TA1-2040, Environmental science, Digital elevation model, lcsh:Engineering (General). Civil engineering (General), Robotic arm, Remote sensing
Abstract

As China’s first unmanned spacecraft to collect lunar surface samples and return them to Earth, the Chang’E-5 detector is a crucial probe that will complete lunar surface sampling in China’s lunar exploration project. This lunar sampling will be the first successful lunar surface sampling return mission in China. Sampling decisions needs to be made based on topographical analysis results and characteristics of the area to be explored. Due to the unknown extraterrestrial terrain and uncertainty of sampled objects, we propose a sampling feasibility estimation for safely implementing lunar surface sampling.Our strategy took into account the influence of factors that may interfere with the sampling process, and provided quantitative assessment of the sampling feasibility for the area to be explored. We combined the three-dimensional topography of the lunar surface with five parameters of the sampling area, flatness, slope, slope aspect, accessibility of the mechanical arm distal end, and safety of sampling conditions. The first three values were calculated based on a digital elevation model (DEM) of the landing area generated using stereo images. The other values were computed based on the mechanical properties of the arm and kinematic analysis of its articulated joints. Based on the above-mentioned quantitative parameters, they were weighed to obtain an evaluation value for the sampling feasibility of each DEM pixel. Meanwhile, a multichannel sampling area analysis graph was generated that combined all the above indicators as well as the sampling feasibility values, which provides a visualization for determining detection targets in the Chang’E-5 sampling mission.

Published
2019

47. Reptiles in Space Missions: Results and Perspectives

Author

Sergey Saveliev, Alexandra Proshchina, R.K. Berdiev, Alexey Buzmakov, Anastasia Kharlamova, D. A. Zolotov, Yuliya Krivova, Victor Asadchikov, Victoria Gulimova, and V.M. Barabanov

Subjects
Parabolic flight, Review, thick-toed gecko (Chondrodactylus turneri), Biology, Spaceflight, Catalysis, Space exploration, ornate day gecko (Phelsuma ornata), Bone and Bones, law.invention, lcsh:Chemistry, Inorganic Chemistry, law, unmanned spacecraft, Animals, Gecko, Physical and Theoretical Chemistry, lcsh:QH301-705.5, Molecular Biology, Spectroscopy, Weightlessness Simulation, Weightlessness, Organic Chemistry, Brain, Reptiles, Foton-M2, Lizards, General Medicine, Foton-M3, Bion-M1, Foton-M4, Space Flight, biology.organism_classification, Adaptation, Physiological, Computer Science Applications, Turtles, body regions, lcsh:Biology (General), lcsh:QD1-999, Simulated microgravity, spaceflight adaptation, Evolutionary biology, X-ray microtomography
Abstract

Reptiles are a rare model object for space research. However, some reptile species demonstrate effective adaptation to spaceflight conditions. The main scope of this review is a comparative analysis of reptile experimental exposure in weightlessness, demonstrating the advantages and shortcomings of this model. The description of the known reptile experiments using turtles and geckos in the space and parabolic flight experiments is provided. Behavior, skeletal bones (morphology, histology, and X-ray microtomography), internal organs, and the nervous system (morphology, histology, and immunohistochemistry) are studied in the spaceflight experiments to date, while molecular and physiological results are restricted. Therefore, the results are discussed in the scope of molecular data collected from mammalian (mainly rodents) specimens and cell cultures in the parabolic and orbital flights and simulated microgravity. The published data are compared with the results of the gecko model studies after the 12–44.5-day spaceflights with special reference to the unique peculiarities of the gecko model for the orbital experiments. The complex study of thick-toed geckos after three spaceflights, in which all geckos survived and demonstrated effective adaptation to spaceflight conditions, was performed. However, future investigations are needed to study molecular mechanisms of gecko adaptation in space.

Published
2019

48. Bifurcation Analysis of DC Electric Power Systems for Deep Space Exploration Spacecraft

Author

Kenneth A. Loparo, Marc A. Carbone, and Amirhossein Sajadi

Subjects
Spacecraft, Unmanned spacecraft, business.industry, Computer science, 020209 energy, 020208 electrical & electronic engineering, 02 engineering and technology, Space exploration, Electric power system, Reliability (semiconductor), Bifurcation analysis, Deep space exploration, Position (vector), Physics::Space Physics, 0202 electrical engineering, electronic engineering, information engineering, Aerospace engineering, business
Abstract

Electric power system reliability is needed to guarantee the success of space exploration missions for manned and unmanned spacecraft. Understanding the behavior of these electric systems is essential to determine the safe operating conditions, and subsequently, prevent undesired conditions that may cause system-wide blackouts, leaving the spacecraft in a vulnerable position. This study uses bifurcation analysis to determine the behavior of DC spacecraft electric power systems to identify major causes of voltage instability.

Published
2019

49. Enhanced Kinetic Impactor for Deflecting Large Potentially Hazardous Asteroids via Maneuvering Space Rocks

Author

Mingtao Li, Yirui Wang, Binghong Zhou, Wei Zheng, and Youliang Wang

Subjects
010504 meteorology & atmospheric sciences, lcsh:Medicine, FOS: Physical sciences, Close encounter, 01 natural sciences, Article, Physics - Space Physics, 0103 physical sciences, Aerospace engineering, lcsh:Science, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Propellant, Earth and Planetary Astrophysics (astro-ph.EP), Multidisciplinary, Unmanned spacecraft, business.industry, lcsh:R, Rendezvous, Potentially hazardous object, Space Physics (physics.space-ph), Deflection (ballistics), Asteroid, Trajectory, Environmental science, lcsh:Q, business, Asteroids, comets and Kuiper belt, Astrophysics - Earth and Planetary Astrophysics
Abstract

Asteroid impacts pose a major threat to all life on Earth. The age of the dinosaurs was abruptly ended by a 10-km-diameter asteroid. Currently, a nuclear device is the only means of deflecting large Potentially Hazardous Asteroids (PHAs) away from an Earth-impacting trajectory. The Enhanced Kinetic Impactor (EKI) concept is proposed to deflect large PHAs via maneuvering space rocks. First, an unmanned spacecraft is launched to rendezvous with an intermediate Near-Earth Asteroid (NEA). Then, more than one hundred tons of rocks are collected from the NEA as the EKI. The NEA can also be captured as the EKI if the NEA is very small. Finally, the EKI is maneuvered to impact the PHA at a high speed, resulting in a significant deflection of the PHA. For example, to deflect Apophis, as much as 200 t of rocks could be collected from a NEA as the EKI based on existing engineering capabilities. The EKI can produce a velocity increment (delta-v) of 39.81 mm/s in Apophis, thereby increasing the minimum geocentric distance during the close encounter in 2029 by 1,866.93 km. This mission can be completed in 3.96 years with a propellant cost of 2.98 t. Compared with a classic kinetic impactor, the deflection distance can be increased one order of magnitude. The EKI concept breaks through the limitation of the ground-based launch capability, which can significantly increase the mass of the impactor. We anticipate that our research will be a starting point for efficient planetary defense against large PHAs., Comment: We added more details about the design results and design methods, which will make it more accessible for reader to reproduce our results

Published
2019
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50. Germany : Europlanet launches 10 million euro research infrastructure supporting planetary science

Subjects
Solar System, Research institutes, Infrastructure (Economics), Unmanned spacecraft, Telescopes, Volcanoes, Spacecraft, Retirement benefits, Business, international
Abstract

Europlanet 2024 RI will provide open access to the world's largest group of facilities for planetary simulation and analysis, as well as a global network of small telescopes, data services [...]

Published
2020

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