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prEN 16603-10-03

(Main)

Space engineering - Testing

Space engineering - Testing

This standard addresses the requirements for performing verification by testing of space segment elements and space segment equipment on ground prior to launch. The document is applicable for tests performed on qualification models, flight models (tested at acceptance level) and protoflight models.
The standard provides:
• Requirements for test programme and test management,
• Requirements for retesting,
• Requirements for redundancy testing,
• Requirements for environmental tests,
• General requirements for functional and performance tests,
NOTE Specific requirements for functional and performance tests are not part of this standard since they are defined in the specific project documentation.
• Requirements for qualification, acceptance, and protoflight testing including qualification, acceptance, and protofight models’ test margins and duration,
• Requirements for test factors, test condition, test tolerances, and test accuracies,
• General requirements for development tests pertinent to the start of the qualification test programme,
NOTE Development tests are specific and are addressed in various engineering discipline standards.
• Content of the necessary documentation for testing activities (e.g. DRD).
Due to the specific aspects of the follow ing types of test, this Standard does not address:
• Space system testing (i.e. testing above space segment element), in particular the system validation test,
• In-orbit testing,
• Testing of space segment subsystems,
NOTE Tests of space segment subsystems are often limited to functional tests that, in some case, are run on dedicated models. If relevant, qualification tests for space segment subsystems are assumed to be covered in the relevant discipline standards.
Testing of hardware below space segment equipment levels (including assembly, parts, and components),
• Testing of stand-alone software,
NOTE For verification of flight or ground softw are, EN 16603-40 (ECSS-E-ST-40) and EN 16602-80 (ECSS-Q-ST-80) apply.
• Qualification testing of tw o-phase heat transport equipment,
NOTE For qualification testing of tw o-phase heat transport equipment, EN 16603-31-02 (ECSS-E-ST-31-02) applies.
• Tests of launcher segment, subsystem and equipment, and launch facilities,
• Tests of facilities and ground support equipment,
• Tests of ground segment.
This activity will be the update of EN16603-10-03:2014
NOTE: Parallel development of update of EN Standard and the new European TR17603-10-03.

Raumfahrttechnik - Tests

Ingénierie spatiale - Vérification par essai

Vesoljska tehnika - Preskušanje

General Information

Status
Not Published
ICS
49.140 - Space systems and operations
Technical Committee
CEN/CLC/TC 5 - Space
Drafting Committee
CEN/CLC/TC 5/WG 6 - Upstream standards
Current Stage
4599 - Dispatch of FV draft to CMC - Finalization for Vote
Due Date
22-Feb-2022
Completion Date
22-Feb-2022
Mandate
M/496 - Mandate addressed to CEN, CENELEC and ETSI to develop standardisation regarding space industry (Phase 3 of the process)
Ref Project
oSIST prEN 16603-10-03:2021 - Space engineering - Testing

RELATIONS

Revised
EN 16603-10-03:2014 - Space engineering - Testing
Effective Date
02-Dec-2020

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SLOVENSKI STANDARD
oSIST prEN 16603-10-03:2021
01-september-2021
Vesoljska tehnika - Preskušanje
Space engineering - Testing
Raumfahrttechnik - Tests
Ingénierie spatiale - Vérification par essai
Ta slovenski standard je istoveten z: prEN 16603-10-03
ICS:
49.140 Vesoljski sistemi in operacije Space systems and
operations
oSIST prEN 16603-10-03:2021 en,fr,de

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST prEN 16603-10-03:2021
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oSIST prEN 16603-10-03:2021
EUROPEAN STANDARD
DRAFT
prEN 16603-10-03
NORME EUROPÉENNE
EUROPÄISCHE NORM
June 2021
ICS 49.140
Will supersede EN 16603-10-03:2014
English version
Space engineering - Testing
Ingénierie spatiale - Vérification par essai Raumfahrttechnik - Tests

This draft European Standard is submitted to CEN members for enquiry. It has been drawn up by the Technical Committee

CEN/CLC/JTC 5.

If this draft becomes a European Standard, CEN and CENELEC members are bound to comply with the CEN/CENELEC Internal

Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any

alteration.

This draft European Standard was established by CEN and CENELEC in three official versions (English, French, German). A

version in any other language made by translation under the responsibility of a CEN and CENELEC member into its own

language and notified to the CEN-CENELEC Management Centre has the same status as the official versions.

CEN and CENELEC members are the national standards bodies and national electrotechnical committees of Austria, Belgium,

Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy,

Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia,

Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom.

Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are

aware and to provide supporting documentation.Recipients of this draft are invited to submit, with their comments, notification

of any relevant patent rights of which they are aware and to provide supporting documentation.

Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without

notice and shall not be referred to as a European Standard.
CEN-CENELEC Management Centre:
Rue de la Science 23, B-1040 Brussels

© 2021 CEN/CENELEC All rights of exploitation in any form and by any means Ref. No. prEN 16603-10-03:2021 E

reserved worldwide for CEN national Members and for
CENELEC Members.
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
Table of contents

European Foreword ................................................................................................... 5

Introduction ................................................................................................................ 6

1 Scope ....................................................................................................................... 8

2 Normative references ........................................................................................... 10

3 Terms, definitions and abbreviated terms .......................................................... 11

3.1 Terms from other standards .................................................................................... 11

3.2 Terms specific to the present standard ................................................................... 12

3.3 Abbreviated terms................................................................................................... 17

3.4 Nomenclature ......................................................................................................... 19

4 General requirements........................................................................................... 21

4.1 Test programme ..................................................................................................... 21

4.2 Development test prior qualification ........................................................................ 21

4.3 Test management ................................................................................................... 22

4.3.1 General ..................................................................................................... 22

4.3.2 Test reviews .............................................................................................. 22

4.3.3 Test documentation ................................................................................... 26

4.3.4 Anomaly or failure during testing ............................................................... 27

4.3.5 Test data ................................................................................................... 27

4.4 Test conditions, input tolerances, and measurement uncertainties ......................... 27

4.4.1 Test conditions .......................................................................................... 27

4.4.2 Test input tolerances ................................................................................. 28

4.4.3 Measurement uncertainties ....................................................................... 30

4.5 Test objectives ........................................................................................................ 32

4.5.1 General requirements ............................................................................... 32

4.5.2 Qualification testing ................................................................................... 32

4.5.3 Acceptance testing .................................................................................... 32

4.5.4 Protoflight testing ...................................................................................... 33

4.6 Retesting ................................................................................................................ 34

4.6.1 Overview ................................................................................................... 34

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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)

4.6.2 Implementation of a design modification after completion of qualification .. 34

4.6.3 Storage after protoflight or acceptance testing .......................................... 34

4.6.4 Space segment element or equipment to be re-flown ................................ 35

4.6.5 Flight use of qualification Space segment element or equipment .............. 35

5 Space segment equipment test requirements ................................................... 36

5.1 General requirements ............................................................................................. 36

5.2 Qualification tests requirements .............................................................................. 38

5.3 Acceptance test requirements ................................................................................ 48

5.4 Protoflight test requirements ................................................................................... 54

5.5 Space segment equipment test programme implementation requirements ............. 60

5.5.1 General tests ............................................................................................. 60

5.5.2 Mechanical tests ....................................................................................... 63

5.5.3 Structural integrity tests ............................................................................. 67

5.5.4 Thermal tests ............................................................................................ 68

5.5.5 Electrical/RF tests ..................................................................................... 70

5.5.6 Mission specific test .................................................................................. 71

6 Space segment element test requirements ........................................................ 73

6.1 General requirements ............................................................................................. 73

6.2 Qualification test requirements ............................................................................... 73

6.3 Acceptance test requirements ................................................................................ 81

6.4 Protoflight test requirements ................................................................................... 88

6.5 Space segment elements test programme implementation requirements ............... 95

6.5.1 General tests ............................................................................................. 95

6.5.2 Mechanical tests ....................................................................................... 99

6.5.3 Structural integrity tests ........................................................................... 106

6.5.4 Thermal tests .......................................................................................... 107

6.5.5 Electromagnetic tests .............................................................................. 109

6.5.6 Mission specific tests .............................................................................. 110

6.5.7 Crewed mission specific tests ................................................................. 110

7 Pre-launch testing .............................................................................................. 112

Annex A (normative) Assembly, integration and test plan (AIT Plan) - DRD .... 114

Annex B (normative) Test specification (TSPE) - DRD ....................................... 117

Annex C (normative) Test procedure (TPRO) - DRD .......................................... 120

Annex D (informative) Guidelines for tailoring and verification of this standard

............................................................................................................................ 123

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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)

Bibliography ........................................................................................................... 127

Figures

Figure 5-1: Space segment equipment typical sequence of tests ......................................... 38

Figure D-1 : Logic for customer tailoring and supplier answer through compliance and

verification matrix ............................................................................................. 124

Figure D-2 : Clauses selection in First step of the tailoring ................................................. 125

Tables

Table 4-1: Allowable test input tolerances ............................................................................ 29

Table 4-2: Typical measurement uncertainties from test centers .......................................... 31

Table 5-1: Space segment equipment - Qualification test baseline ....................................... 39

Table 5-2: Space segment equipment - Qualification test levels and duration ...................... 41

Table 5-3: Space segment equipment - Acceptance test baseline ........................................ 49

Table 5-4: Space segment equipment - Acceptance test levels and duration ....................... 51

Table 5-5: Space segment equipment - Protoflight test baseline .......................................... 54

Table 5-6: Space segment equipment - Protoflight test levels and duration .......................... 56

Table 6-1: Space segment element - Qualification test baseline ........................................... 74

Table 6-2: Space segment element - Qualification test levels and duration .......................... 77

Table 6-3: Space segment element - Acceptance test baseline ............................................ 81

Table 6-4: Space segment element - Acceptance test levels and duration ........................... 84

Table 6-5: Space segment element - Protoflight test baseline .............................................. 88

Table 6-6: Space segment element - Protoflight test levels and duration .............................. 91

Table D-1 : Guideline for verification close-out ................................................................... 125

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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
European Foreword
This document (prEN 16603-10-03:2021) has been prepared by Technical Committee
CEN/CLC/TC 5 “Space”, the secretariat of which is held by DIN (Germany).

This document (prEN 16603-10-03:2021) originates from ECSS-E-ST-10-03C Rev.1 DIR1.

This document is currently submitted to the ENQUIRY.
This document will supersede EN 16603-10-03:2014.
The main changes with respect to EN 16603-10-03:2014 are listed below:
• Implementation of Change Requests received to the ECSS equivalent standard
• xxxx --- The final Change log will be completed before publication --- xxxx

This document has been developed to cover specifically space systems and will therefore

have precedence over any EN covering the same scope but with a wider do-main of
applicability (e.g.: aerospace).
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
Introduction

The requirements on the systems engineering process are gathered in ECSS-E-ST-10;

while specific aspects are further elaborated in dedicated standards, in particular: ECSS-

E-ST-10-06, ECSS-E-ST-10-02 and the present standard (ECSS-E-ST-10-03)
In the System Engineering branch (ECSS‐E‐10) this standard aims at a consistent
application of on ground testing requirements to allow proper qualification and
acceptance of space products

Experience has demonstrated that incomplete or improper on ground testing approach

significantly increase project risks leading to late discovery of design or workmanship

problem(s) or in-orbit failure(s).

Testing is part of the system engineering process as defined in ECSS‐E‐ST‐10. This starts

at the early phase of the mission when defining verification process in terms of the model

philosophy and sequences of tests and ends at the last testing phase prior launch.

In the level of decomposition of a space system, this standard addresses the requirements

for space segment element and space segment equipment.
The document is organised such that:

 clause 4 provides requirements for overall test programme, test management test

conditions, test input tolerances and measurement uncertainties;
 clause 5 provides requirements for Space segment equipment;
 clause 6 provides requirements for Space segment element;
 clause 7 provides requirements for Pre-launch testing.
Clauses 5 and 6 are organised as follows:

 general requirements for the products under test applicable to all models (clause

5.1 or 6.1);
 requirements applicable to qualification model (clause 5.2 or 6.2);
 requirements applicable to acceptance model (clause 5.3 or 6.3);
 requirements applicable to protoflight model (clause 5.4 or 6.4);
 detailed implementation requirements (clause 5.5 or 6.5);

In the clause providing requirements for each model (i.e. clauses 5.2, 5.3, 5.4, 6.2, 6.3 and

6.4), the first table of the clause:
 lists all types of test and defines their applicability and conditions;
 links to the second table of the clause that defines tests level and duration;
 provides reference to the clause defining the detailed implementation
requirements for the given test (clause 5.5 or 6.5).
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)

For space segment equipment, the required sequence of tests, for each model, is defined

by tailoring the two tables in clause 5.2, 5.3 or 5.4.

Since testing activities are part of the overall verification activities, test documentation to

be produced (DRD’s) are either specified in the ECSS-E-ST-10-02 (case of the test report)

or in this document.

Annex D gives guidelines for performing the tailoring of this standard as well as the

generation of the compliance and verification matrices.
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
Scope

This standard addresses the requirements for performing verification by testing of space

segment elements and space segment equipment on ground prior to launch. The

document is applicable for tests performed on qualification models, flight models (tested

at acceptance level) and protoflight models.
The standard provides:
 Requirements for test programme and test management,
 Requirements for retesting,
 Requirements for redundancy testing,
 Requirements for environmental tests,
 General requirements for functional and performance tests,
NOTE Specific requirements for functional and performance
tests are not part of this standard since they are defined
in the specific project documentation.
 Requirements for qualification, acceptance, and protoflight testing including
qualification, acceptance, and proto-fight models’ test margins and duration,
 Requirements for test factors, test condition, test input tolerances, and
measurement uncertainties,
 General requirements for development tests pertinent to the start of the
qualification test programme,
NOTE Development tests are specific and are addressed in
various engineering discipline standards.
 Content of the necessary documentation for testing activities (e.g. DRD).

Due to the specific aspects of the following types of test, this Standard does not address:

 Space system testing (i.e. testing above space segment element), in particular the

system validation test,
 In-orbit testing,
 Testing of space segment subsystems,
NOTE Tests of space segment subsystems are often limited to
functional tests that, in some case, are run on dedicated
models. If relevant, qualification tests for space segment
subsystems are assumed to be covered in the relevant
discipline standards.
 Testing of hardware below space segment equipment levels (including assembly,
parts, and components),
 Testing of stand-alone software,
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
NOTE For verification of flight or ground software, ECSS-E-ST-
40 and ECSS-Q-ST-80 apply.
 Testing of two-phase heat transport equipment,
NOTE For acceptance and qualification testing of two-phase
heat transport equipment, ECSS-E-ST-31-02 applies.
 Tests of launcher segment, subsystem and equipment, and launch facilities,
 Tests of facilities and ground support equipment,
 Tests of ground segment.

This standard may be tailored for the specific characteristic and constrains of a space

project in conformance with ECSS-S-ST-00. Annex D gives guidelines for performing this

tailoring.
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
Normative references

The following normative documents contain provisions which, through reference in this

text, constitute provisions of this ECSS Standard. For dated references, subsequent

amendments to, or revision of any of these publications do not apply. However, parties

to agreements based on this ECSS Standard are encouraged to investigate the possibility

of applying the more recent editions of the normative documents indicated below. For

undated references, the latest edition of the publication referred to applies.
EN reference Reference in text Title
EN 16601-00 ECSS-S-ST-00-01 ECSS system - Glossary of terms
EN 16603-10-02 ECSS-E-ST-10-02 Space engineering - Verification
EN 16603-20 ECSS-E-ST-20 Space engineering - Electrical and electronic
EN 16603-20-01 ECSS-E-ST-20-01 Space engineering - Multipactor design and test
EN 16603-20-06 ECSS-E-ST-20-06 Space engineering - Spacecraft charging
EN 16603-20-07 ECSS-E-ST-20-07 Space engineering - Electromagnetic compatibility
EN 16603-20-08 ECSS-E-ST-20-08 Space engineering - Photovoltaic assemblies and
components

EN 16603-31 ECSS-E-ST-31 Space engineering - Thermal control general requirements

EN 16603-32 ECSS-E-ST-32 Space engineering - Structural general requirements

EN 16603-32-02 ECSS-E-ST-32-02 Space engineering - Structural design and verification of

pressurized hardware

EN 16603-32-10 ECSS-E-ST-32-10 Space engineering - Structural factors of safety for

spaceflight hardware
EN 16603-32-11 ECSS-E-ST-32-11 Space engineering - Modal survey assessment
EN 16603-33-01 ECSS-E-ST-33-01 Space engineering - Mechanisms
EN 16601-40 ECSS-M-ST-40 Space project management - Configuration and
information management
EN 16602-10-09 ECSS-Q-ST-10-09 Space product assurance - Nonconformance control
system

EN 16602-20-07 ECSS-Q-ST-20-07 Space product assurance - Quality assurance for test

centres
EN 16602-40 ECSS-Q-ST-40 Space product assurance - Safety

EN 16602-70-01 ECSS-Q-ST-70-01 Space product assurance - Cleanliness and contamination

control
ISO 3740:2000 Acoustics - Determination of sound power levels of noise
sources - Guidelines for the use of basic standards
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
Terms, definitions and abbreviated terms
3.1 Terms from other standards

a. For the purpose of this standard; the terms and definitions from ECSS-S-ST-00-01

apply, and in particular the following:
1. flight model
2. lifetime
3. protoflight model
4. qualification model
5. space segment element
6. space segment equipment
7. space segment subsystem
8. structural model
9. system

b. For the purpose of this standard, the following terms and definitions from ECSS-

E-ST-10-02 apply:
1. commissioning
2. model philosophy
3. test

c. For the purpose of this Standard, the following terms and definitions from ECSS-

E-ST-31 apply:
1. acceptance temperature range
2. design temperature range
3. minimum switch ON temperature
4. predicted temperature range
5. qualification temperature range
6. temperature reference point (TRP)

d. For the purpose of this Standard, the following terms and definitions from ECSS-

E-ST-32 apply:
1. burst pressure
2. design burst pressure
3. factor of safety
4. limit load (LL)
5. maximum design pressure (MDP)
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
6. proof factor
7. proof pressure
8. proof test
3.2 Terms specific to the present standard
3.2.1 24-hour equivalent noise exposure level

equivalent sound pressure level (Leq) to which the crew members are exposed over a 24-

hour period; expressed in dBA
NOTE 0 dBA corresponds to 20 µPa.
3.2.2 <>
3.2.3 abbreviated functional test (AFT)
See "reduced functional test (RFT)"
3.2.4 acceptance level

test level reflecting the maximum level expected to be encountered during the flight

product lifetime increased by acceptance margins
3.2.5 acceptance margin

increase of the environmental, mechanical, thermal, electrical, EMC, or operational

extremes above the worst case levels predicted over the specified product lifetime for the

purpose of workmanship verification
NOTE 1 Margins can include an increase in level or
range, an increase in duration or cycles of
exposure, as well as any other appropriate
increase in severity.
NOTE 2 For thermal acceptance margin refer also to
ECSS-E-ST-31.
3.2.6 <>
3.2.7 crewed space segment element
space segment design to ensure the safe presence of crew onboard
3.2.8 <>
3.2.9 dwell time

duration necessary to ensure that internal parts or subassembly of a space segment

equipment have achieved thermal equilibrium, from the start of temperature stabilisation

phase, i.e. when the temperature reaches the targeted test temperature plus or minus the

test tolerance
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
3.2.10 environmental tests

tests applied to a product simulating (together or separately) environmental conditions

as encountered during its operational life cycle
NOTE Environmental tests cover natural and induced
environments.
3.2.11 full functional test (FFT)

comprehensive test that demonstrates the integrity of all functions of the item under test,

in all operational modes, including back-up modes and all foreseen transitions
NOTE 1 The main objectives of this test is to
demonstrate absence of design manufacturing
and integration error.
NOTE 2 FFT exists at the different level of
decomposition of a space segment element. For
satellite they also called system functional test
(SFT) or integrated system test (IST).
3.2.12 maximum expected acceleration

acceleration value determined from the combined effects of the steady state acceleration

and the transient response of the item as it will experience during its life time

NOTE 1 This term is equivalent to limit load (as defined
in E-ST-32).
NOTE 2 Examples of events during life time are
transportation, handling, engine ignition,
engine burnout, and stage separation.
3.2.13 maximum expected acoustic spectrum

maximum value of the time average root-mean-square (r.m.s.) sound pressure level (SPL)

in each frequency band occurring inside the payload fairing, orbiter, or cargo bay, which

occurs during flight events
NOTE 1 E.g. lift-off, powered flight or re-entry.
NOTE 2 The maximum expected acoustic environment
test spectrum is specified in octave or 1/3
octave bands over a frequency range of 31,5 Hz
to 10 kHz. The duration of the maximum
environment is the total period when the
overall amplitude is within 6 dB of the
maximum overall amplitude.
3.2.14 maximum expected shock

worst cases of the collection of the shock at their mounting interface due to every possible

cause
NOTE 1 For example: causes of shocks are stage, shroud
or satellite separation pyro elements, non-
explosive actuators, mechanisms with energy
release, appendage latching, and fuel valves.
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oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
NOTE 2 Shocks can be characterized by their time
histories, shock response spectrum, or impulse
geometry.
NOTE 3 Refer to ECSS-E-HB-32-25 for additional
information.
3.2.15 maximum expected random vibration spectrum
maximum expected environment imposed on the space segment element and space
segment equipment due to broad band random forcing functions within the launch
element or space segment element during flight or from ground transportation and
handling
NOTE 1 E.g. lift-off acoustic field, aerodynamic
excitations, and transmitted structure-borne
vibration.
NOTE 2 A different spectrum can exist for different
space segment equipment zones or for
different axis. The space segment equipment
vibration levels are based on vibration
response measurements or model prediction
made at the space segment equipment
attachment points during ground acoustic tests
or during flight. The duration of the maximum
environment is the total period during flight
when the overall level is within 6 dB of the
maximum overall level.
NOTE 3 The power spectral density is based on a
frequency resolution of 1/6 octave (or
narrower) bandwidth analysis, over a
frequency range of 20 Hz to 2000 Hz.
3.2.16 <>
3.2.17 maximum predicted temperature
maximum value of the predicted temperature range
3.2.18 minimum predicted temperature
minimum value of the predicted temperature range
3.2.19 <>
NOTE
3.2.20 notching

reduction of the input level or spectrum to limit structural responses at resonant

frequencies according to qualification or acceptance loads during a vibration test

NOTE Notching is a general accepted practice in vibration
testing to avoid over testing of the item under test.
Implementation of notching is subject to customer
approval and when relevant to Launcher authority
approval
---------------------- Page: 16 ----------------------
oSIST prEN 16603-10-03:2021
prEN 16603-10-03:2021 (E)
3.2.21 operational modes

combination of operational configurations or conditions that can occur during the

product lifetime for space segment equipment or space segment element
NOTE For example: Power-on or power-off, command modes,
readout modes, attitude control modes, antenna stowed
or deployed, and spinning or de-spun.
3.2.22 performance test

test to verify that the item under test performs according to its specifications while

respecting its operational requirements
NOTE Performance tests are mission specific therefore their
details are not specified under this standard.
3.2.23 polarity test

test to verify the correct polarity of the functional chains (mainly AOCS) or equipment of

the space segment element from sensors to actuators, through a number of interfaces and

processing.
NOTE 1 A polarity error can be generated throughout
the development process: interface
documentation, design, H/W manufacturing,
S/W development, satellite AIT, satellite
database.
NOTE 2 A polarity error can be generated by any
element of the functional chain: sensor or
actuator design, sensor or actuator mounting,
harness, interface units, software alg
...

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SIST EN 16602-10-09:2020

This Standard defines the requirements for the control of nonconformances.
This Standard applies to all deliverable products and supplies, at all levels, which fail to conform to project requirements.
This Standard is applicable throughout the whole project lifecycle as defined in ECSS-M-ST-10.
This standard may be tailored for the specific characteristics and constrains of a space project in conformance with ECSS-S-ST-00.

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EN 16603-50-12:2020(Main)
Space engineering - SpaceWire - Links, nodes, routers and networks
SIST EN 16603-50-12:2020

This Standard specifies the physical interconnection media and data communication protocols to enable the reliable sending of data at high­speed (between 2 Mb/s and 400 Mb/s) from one unit to another. SpaceWire links are full­duplex, point­to­point, serial data communication links.
The scope of this Standard is the physical connectors and cables, electrical properties, and logical protocols that comprise the SpaceWire data link. SpaceWire provides a means of sending packets of information from a source node to a specified destination node. SpaceWire does not specify the contents of the packets of information.
This Standard covers the following protocol levels:
•   Physical level: Defines connectors, cables, cable assemblies and printed circuit board tracks.
•   Signal level: Defines signal encoding, voltage levels, noise margins, and data signalling rates.
•   Character level: Defines the data and control characters used to manage the flow of data across a link.
•   Exchange level: Defines the protocol for link initialization, flow control, link error detection and link error recovery.
•   Packet level: Defines how data for transmission over a SpaceWire link is split up into packets.
•   Network level: Defines the structure of a SpaceWire network and the way in which packets are transferred from a source node to a destination node across a network. It also defines how link errors and network level errors are handled.
This Standard may be tailored for the specific characteristics and constraints of a space project in conformance with ECSS-S-ST-00.

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EN 16602-20:2020(Main)
Space product assurance - Quality assurance
SIST EN 16602-20:2020

This Standard defines the quality assurance (QA) requirements for the establishment and implementation of a Quality Assurance
programme for products of space projects. Discipline related qualification activities are complemented in standards specific to those
disciplines (e.g. ECSS-E-ST-32-01 for fracture control).
For software quality assurance, the software product assurance standard, ECSS-Q-ST-80 is applicable.
This Standard is applicable to all space projects.
This standard may be tailored for the specific characteristic and constrains of a space project in conformance with ECSS-S-ST-00.
For the tailoring of this standard the following information is provided:
- A table providing the pre-tailoring per "Product types" in clause 6
- A table providing the pre-tailoring per "Project phase" in Annex J

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EN 16604-20:2020(Main)
Space sustainability - Planetary protection
SIST EN 16604-20:2020

This standard contains planetary protection requirements, including:
-   Planetary protection management requirements;
-   Technical planetary protection requirements for robotic and human missions (forward and backward contamination);
-   Planetary protection requirements related to procedures;
-   Document Requirements Descriptions (DRD) and their relation to the respective reviews.
This standard may be tailored for the specific characteristic and constraints of a space project in conformance with ECSS-S-ST-00.

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EN 16603-11:2019(Main)
Space engineering - Definition of the Technology Readiness Levels (TRLs) and their criteria of assessment (ISO 16290:2013, modified)
SIST EN 16603-11:2020

This European Standard defines Technology Readiness Levels (TRLs). It is applicable primarily to space system hardware, although the definitions could be used in a wider domain in many cases.
The definition of the TRLs provides the conditions to be met at each level, enabling accurate TRL assessment.

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EN 16602-70-60:2019(Main)
Space product assurance - Qualification and Procurement of printed circuit boards
SIST EN 16602-70-60:2019

This standard addresses the qualification and procurement of printed circuit boards, which are necessary for all type of space projects.

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EN 16604-10:2019(Main)
Space sustainability - Space debris mitigation requirements (ISO 24113:2011, modified)
SIST EN 16604-10:2019

This document defines the primary space debris mitigation requirements applicable to all elements of systems launched into, or passing through, near-Earth space, including launch vehicle orbital stages, operating spacecraft and any objects released as part of normal operations or disposal actions.
The requirements contained in this document are intended to reduce the growth of space debris by ensuring that spacecraft and launch vehicle orbital stages are designed, operated and disposed of in a manner that prevents them from generating debris throughout their orbital lifetime.
This document is the top-level standard in a family of standards addressing debris mitigation. It will be the main interface for the user, bridging between the primary debris mitigation requirements and the lower-level implementation standards that will ensure compliance.
This document does not cover launch phase safety for which specific rules are defined elsewhere.
This document identifies the clauses and requirements modified with respect to ISO 24113, Space systems - Space debris mitigation requirements, Second edition 2011-05-15 for application in ECSS.

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EN 16603-33-11:2019(Main)
Space engineering - Explosive subsystems and devices
SIST EN 16603-33-11:2019

This Standard defines the requirements for the use of explosives on all spacecraft and other space products including launch vehicles. It addresses the aspects of design, analysis, verification, manufacturing, operations and safety.
This standard may be tailored for the specific characteristics and constraints of a space project in conformance with ECSS-S-ST-00.

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EN 16602-70-38:2019(Main)
Space product assurance - High-reliability soldering for surface-mount and mixed technology
SIST EN 16602-70-38:2019

This Standard defines the technical requirements and quality assurance provisions for the manufacture and verification of high-reliability electronic circuits based on surface mounted device (SMD) and mixed technology.
The Standard defines acceptance and rejection criteria for high-reliability manufacture of surface-mount and mixed-technology circuit assemblies intended to withstand normal terrestrial conditions and the vibrational g loads and environment imposed by space flight.
The proper tools, correct materials, design and workmanship are covered by this document. Workmanship standards are included to permit discrimination between proper and improper work.
The assembly of leaded devices to through-hole terminations and general soldering principles are covered in ECSS-Q-ST-70-08.
Requirements related to printed circuit boards are contained in ECSS-Q-ST-70 10, ECSS-Q-ST-70-11 and ECSS-Q-ST-70-12 . The mounting and supporting of devices, terminals and conductors prescribed herein applies to assemblies at PCB level designed to continuously operate over the mission within the temperature limits of -55 C to +85 C.
For temperatures outside this normal range, special design, verification and qualification testing is performed to ensure the necessary environmental survival capability.
Special thermal heat sinks are applied to devices having high thermal dissipation (e.g. junction temperatures of 110 C, power transistors) in order to ensure that solder joints do not exceed 85 C.
Verification of SMD assembly processes is made on test vehicles (surface mount verification samples). Temperature cycling ensures the operational lifetime for spacecraft. However, mechanical testing only indicates SMD reliability as it is unlikely that the test vehicle represents every flight configuration.
This Standard does not cover the qualification and acceptance of the EQM and FM equipment with surface-mount and mixed-technology.
The qualification and acceptance tests of equipment manufactured in accordance with this Standard are covered by ECSS-E-ST-10-03.
This standard may be tailored for the specific characteristics and constraints of a space project, in accordance with ECSS-S-ST-00.

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