Shuttle Global Positioning (GPS) System design study

Investigations of certain aspects and problems of the shuttle global positioning system GPS, are presented. Included are: test philosophy and test outline; development of a phase slope specification for the shuttle GPS antenna; an investigation of the shuttle jamming vulnerability; and an expression for the GPS signal to noise density ratio for the thermal protection system

Classification of hemispheric monthly mean stratospheric potential vorticity fields

International audienceMonthly mean NCEP reanalysis potential vorticity fields at the 650 K isentropic level over the Northern and Southern Hemispheres between 1979 and 1997 were studied using multivariate analysis tools. Principal component analysis in the T-mode was applied to demonstrate the validity of such statistical techniques for the study of stratospheric dynamics and climatology. The method, complementarily applied to both the raw and anomaly fields, was useful in determining and classifying the characteristics of winter and summer PV fields on both hemispheres, in particular, the well-known differences in the behaviour and persistence of the polar vortices. It was possible to identify such features as sudden warming events in the Northern Hemisphere and final warming dates in both hemispheres. The stratospheric impact of other atmospheric processes, such as volcanic eruptions, also identified though the results, must be viewed at this stage as tentative. An interesting change in behaviour around 1990 was detected over both hemispheres

Quantitative threat analysis via a logical service

It is increasingly important to analyze system security quantitatively using concepts such as trust, reputation, cost, and risk. This requires a thorough understanding of how such concepts should interact so that we can validate the assessment of threats, the choice of adopted risk management, etc.. To this end, we propose a declarative language Peal+ in which the interaction of such concepts can be rigorously described and analyzed. Peal+ has been implemented in PEALT using the SMT solver Z3 as analysis back-end. PEALT's code generators target complex back-ends and evolve with optimizations or new back-ends. Thus we can neither trust the tool chain nor feasibly prove correctness of all involved artefacts. We eliminate the need to trust that tool chain by independently certifying scenarios found by back-ends in a manner agnostic of code generation and choice of back-end. This scenario validation is compositional, courtesy of Kleene's 3-valued logic and potential re nement of scenarios. We prove the correctness of this validation, discuss how PEALT presents scenarios to further users' understanding, and demonstrate the utility of this approach by showing how it can express attack-countermeasure trees so that the interaction of attack success probability, attack cost, and attack impact can be analyzed

Static analysis of parity games: alternating reachability under parity

It is well understood that solving parity games is equivalent, up to polynomial time, to model checking of the modal mu-calculus. It is a long-standing open problem whether solving parity games (or model checking modal mu-calculus formulas) can be done in polynomial time. A recent approach to studying this problem has been the design of partial solvers, algorithms that run in polynomial time and that may only solve parts of a parity game. Although it was shown that such partial solvers can completely solve many practical benchmarks, the design of such partial solvers was somewhat ad hoc, limiting a deeper understanding of the potential of that approach. We here mean to provide such robust foundations for deeper analysis through a new form of game, alternating reachability under parity. We prove the determinacy of these games and use this determinacy to define, for each player, a monotone fixed point over an ordered domain of height linear in the size of the parity game such that all nodes in its greatest fixed point are won by said player in the parity game. We show, through theoretical and experimental work, that such greatest fixed points and their computation leads to partial solvers that run in polynomial time. These partial solvers are based on established principles of static analysis and are more effective than partial solvers studied in extant work

PEALT: A reasoning tool for numerical aggregation of trust evidence

We present a tool that supports the understanding and validation of mechanisms that numerically aggregate trust evidence { which may stem from heterogenous sources such as geographical information, reputation, and threat levels. The tool is based on a policy com- position language Peal [3] and can declare Peal expressions and intended analyses of such expressions as input. The analyses include vacuity checking, sensitivity analysis of thresh- olds, and policy re nement. We develop and implement two methods for generating veri - cation conditions for analyses, using the SMT solver Z3 as backend. One method is explicit and space intense, the other one is symbolic and so linear in the analysis expressions. We experimentally investigate this space-time tradeo by observing the Z3 code generation and its running time on randomly generated analyses and on a non-random benchmark modeling majority voting. Our ndings suggest both methods have complementary value and may scale up su ciently for the analysis of most realistic case studies

Shuttle Ku-band and S-band communications implementations study

The interfaces between the Ku-band system and the TDRSS, between the S-band system and the TDRSS, GSTDN and SGLS networks, and between the S-band payload communication equipment and the other Orbiter avionic equipment were investigated. The principal activities reported are: (1) performance analysis of the payload narrowband bent-pipe through the Ku-band communication system; (2) performance evaluation of the TDRSS user constraints placed on the S-band and Ku-band communication systems; (3) assessment of the shuttle-unique S-band TDRSS ground station false lock susceptibility; (4) development of procedure to make S-band antenna measurements during orbital flight; (5) development of procedure to make RFI measurements during orbital flight to assess the performance degradation to the TDRSS S-band communication link; and (6) analysis of the payload interface integration problem areas