User Manual 4.2 Assemblies in PATRIUS: Presentation : Différence entre versions

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Version actuelle en date du 14 janvier 2019 à 15:05

Introduction

Scope

This chapter presents the global architecture of the assembly: its decomposition in parts and the notion of “properties” of those parts. These are only the main principles of the theme. Other chapters are dedicated to the assembly building and use with code samples.

Javadoc

The main vehicle objects are available in the package fr.cnes.sirius.patrius.assembly

Library Javadoc
Patrius Package fr.cnes.sirius.patrius.assembly

Links

None as of now.

Useful Documents

None as of now.

Package overview

Main principles :

  • An assembly is described by its sub parts (and can be made of only one).
  • Each of these parts is definied by a name, a frame to know its position and orientation at any time, and a list of properties.
  • The first created part is the "main part". Its associated frame defines the "main frame" of the vehicle.
  • The assembly contains only information : it does not act as physical models (force computations for the spacecraft,...) and implements no complex algorithm. "Models" objects are used for this purpose.
  • The assembly's creation is made through a "builder" object.
Parts2.PNG


Classes of the package :

  • The builder allows the user to instantiate their own assembly, building it step by step (see "Building the assembly").
  • The assembly contains several parts , of the IPart type : one "MainPart" and some "Part" objects.
  • The parts contain "properties" of the "IPartProperty" type.
  • Each PartProperty is associated to a "PropertyType" that allows the user to add only one property of a certain type to a particular part.
VehicleUML2.PNG

Features Description

The tree of parts

Each Part is associated to a frame, which is defined relatively (position and orientation) to the frame of the parent part. The “main part” is associated to the main frame, that has no parent unless the vehicle is linked to the main tree of frames.


Part Properies

Each part has a list of properties that can be chosen arbitrarily amongst the ones available (e.g. mass, geometry, drag coefficient). The design of the Assembly package allows easy additions of new properties.
To ensure that a property of a particular type is added only once, a "Property type" list exists : different properties can be of a same "type" (for examples two ways of describing the drag coefficients).

PartsProp.png

Models

The physical models (such as forces computations on a spacecraft) are not part of the assembly package.
An assembly does not contain complex algorithm, it is only a description. A model shall be coded in a dedicated class, using if necessary an assembly to get its features.
This way, it is easy to create models implementing existing interfaces, or to create new models and interfaces

Models.PNG

Available models

Here is a summary of available models, what they stand for, and the properties needed on the assembly parts for the model to work :

Model Ability Properties
AeroModel Acceleration due to atmospheric drag At least one part with MASS, AERO_FACET or AERO_SPHERE
DirectRadiativeModel Acceleration due to radiation pressure At least one part with RADIATIVE, MASS and either RADIATIVE_FACET or RADIATIVE_SPHERE
InertiaComputedModel Inertia model for the assembly INERTIA (note : INERTIA property provides its own mass)
InertiaSimpleModel Inertia model provided by user No assembly required
MassModel Mass of the assembly MASS (not required : if no part has a MASS property, total mass will be zero, and valid)
RediffusedRadiativeModel Acceleration due to rediffused radiation At least one part with MASS and either RADIATIVE_FACET or RADIATIVE_SPHERE, and also with RADIATIVE if albedo is enabled in the model, or RADIATIVEIR if infrared is enabled in the model
RFLinkBudgetModel Accounting of all of the gains and losses from the transmitter (the satellite), through the medium, to the receiver (the ground station) RF for the part identified as the antenna
SensorModel Geometric properties of a given sensor (target visibility, masking, inhibition...) SENSOR for the part identified as a sensor, GEOMETRY for the masking parts

For a model to work, it needs an assembly providing parts with the right properties. This is done by building a suitable assembly, as described in the [SPC_VBU_Home "Building and using an assembly"] chapter.