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SIST EN 16603-10-02:2019

(Main)

Space engineering - Verification

Space engineering - Verification

This Standard establishes the requirements for the verification of a space system product.
It defines the fundamental concepts of the verification process, the criteria for defining the verification strategy and specifies the requirements for the implementation of the verification programme. It includes also the list of the expected documentation (i.e. Document requirements definitions, DRDs).
This Standard is intended to apply to different products at different levels from a single equipment to the overall system.
Discipline related verification aspects are complemented in Standards specific to those disciplines.
For verification process for SW the following standards are considered fully sufficient for development of these items:
-   ECSS-E-ST-40 Space engineering - Software
-   ECSS-Q-ST-80 Space product assurance - Software product assurance
Detailed requirements for Testing are covered in the ECSS E-ST-10-03.
This standard does not specifically address Validation of space products as a separate process, since product Verification is performed against requirements that also address the suitability of the product to fulfil the needs of its intended use. As such, Validation is achieved through the Verification process provided adequate requirements are placed on the product.
It is recognised that testing and analysis also occur during the product development process, but they are not addressed by this standard as they are not formal requirement verification activities in the sense of the customer-supplier relationship.
The guidelines on verification are provided in the associated handbook ECSS-E-HB-10-02A.
The requirements on the systems engineering process are gathered in ECSS-E-ST-10 "System Engineering"; specific aspects of the SE process are further elaborated in dedicated standards, in particular: ECSS-E-ST-10-06 "Technical Specification", ECSS-E-ST-10-02 "Verification" (the present standard), and ECSS-E-ST-10-03 "Testing". These standards are based on the same principles, process and documentation model.
The applicability of each these standards can therefore not be considered in isolation from the others
This standard may be tailored for the specific characteristic and constraints of a space project in conformance with ECSS-S-ST-00.

Raumfahrttechnik - Verifikation

Ingénierie spatiale - Vérification

La présente norme définit les exigences applicables à la vérification d'un produit du système spatial.
Elle définit les concepts fondamentaux du processus de vérification, ainsi que les critères pour définir la stratégie de vérification, et spécifie les exigences de mise en oeuvre du programme de vérification. Elle inclut en outre la liste de la documentation attendue (définitions des exigences documentaires ou DRD).
La présente norme est destinée à s'appliquer à différents produits et à différents niveau, depuis un équipement particulier jusqu’à l'ensemble du système.
Les aspects de la vérification associés à des disciplines particulières sont traités par des normes spécifiques.
Concernant le processus de vérification des logiciels, les normes suivantes sont considérées comme suffisantes pour le développement de ces éléments :
-   ECSS-E-ST-40 Ingénierie spatiale - Logiciels
-   ECSS-Q-ST-80 Assurance produit des projets spatiaux - Assurance produit logiciel
Les exigences d'essai détaillées sont décrites dans l'ECSS E-ST-10-03.
La présente norme ne traite pas de manière spécifique de la validation des produits spatiaux en tant que processus distinct, car la vérification des produits est effectuée en fonction d'exigences liées à la capacité du produit à satisfaire les besoins associés à son utilisation prévue. C'est pourquoi la validation est effectuée dans le cadre du processus de vérification, sous réserve que le produit s'accompagne des exigences appropriées.
Il est admis que les essais et analyses interviennent également au cours du processus de développement du produit. Ils ne sont cependant pas traités dans la présente norme, dans la mesure où ils ne sont pas considérés comme des activités formelles de vérification des exigences au sens de la relation client-fournisseur.
Les lignes directrices relatives à la vérification sont fournies dans le manuel associé ECSS-E-HB-10-02A.
Les exigences relatives au processus d'ingénierie des systèmes sont réunies dans l'ECSS-E-ST-10, « Ingénierie système » ; les aspects spécifiques au processus d'IS sont décrits de façon plus détaillée dans des normes dédiées, à savoir : ECSS-E-ST-10-06 « Spécification technique de besoin », ECSS-E-ST-10-02 « Vérification » (la présente norme) et ECSS-E-ST-10-03 « Vérification par essai ». Ces normes se fondent sur les mêmes principes, les mêmes processus et le même modèle de documentation.
L'applicabilité de chacune de ces normes ne peut donc être envisagée de manière indépendante.
La présente norme peut être adaptée aux caractéristiques et contraintes spécifiques d'un projet spatial conformément à l'ECSS-S-ST-00.

Vesoljska tehnika - Preverjanje

Ta standard določa zahteve za preverjanje izdelka vesoljskega sistema.
Opredeljuje temeljne koncepte postopka preverjanja, merila za določanje strategije preverjanja in določa zahteve za izvajanje programa preverjanja. Vključuje tudi seznam pričakovane dokumentacije (tj. dokumente z definicijami zahtev, DRD-je).
Ta standard se uporablja za različne izdelke na različnih ravneh od posameznega kosa opreme do celotnega sistema.
Vidiki preverjanja, povezani s posamezno disciplino, so dopolnjeni s standardi, specifičnimi za te discipline.
V okviru postopka preverjanja programske opreme naslednji standardi povsem zadostujejo za razvoj teh postavk:
– ECSS-E-ST-40 Vesoljska tehnika - Programska oprema
– ECSS-Q-ST-80 Zagotavljanje varnih proizvodov v vesoljski tehniki - Zagotavljanje varne programske opreme
Podrobne zahteve za preskušanje so zajete v standardu ECSS E-ST-10-03.
Ta standard se posebej ne nanaša na preverjanje vesoljskih izdelkov v smislu ločenega procesa, saj se preverjanje izdelkov izvaja glede na zahteve, ki obravnavajo tudi primernost izdelka za izpolnitev potreb njegove predvidene uporabe. Preverjanje se tako izvaja s postopkom preverjanja, v katerem mora izdelek izpolnjevati ustrezne zahteve.
Znano je, da se preskušanje in analiza izvajata tudi med procesom razvoja izdelka, vendar ju ta standard ne zajema, ker nista formalni dejavnosti preverjanja zahtev v smislu razmerja med stranko in dobaviteljem.
Smernice za preverjanje so navedene v pripadajočem priročniku ECSS-E-HB-10-02A.
V standardu ECSS-E-ST-10 »Sistemski inženiring« so zajete zahteve za postopek sistemskega inženiringa; posebni vidiki postopka sistemskega inženiringa so natančneje določeni v namenskih standardih, točneje: ECSS-E-ST-10-06 »Tehnična specifikacija«, ECSS-E-ST-10-02 »Preverjanje« (ta standard) in ECSS-E-ST-10-03 »Preskušanje«. Navedeni standardi temeljijo na enakih načelih, procesu in modelu dokumentiranja.
Zato uporabnosti posameznega standarda ni mogoče presojati ločeno od ostalih standardov.
Ta standard se lahko prilagodi posameznim lastnostim in omejitvam vesoljskega projekta v skladu s standardom ECSS-S-ST-00.

General Information

Status
Published
Public Enquiry End Date
31-Aug-2018
Publication Date
09-Dec-2018
ICS
49.140 - Space systems and operations
Technical Committee
I13 - Imaginarni 13
Current Stage
6060 - National Implementation/Publication (Adopted Project)
Start Date
06-Dec-2018
Due Date
10-Feb-2019
Completion Date
10-Dec-2018
Mandate
M/496 - Mandate addressed to CEN, CENELEC and ETSI to develop standardisation regarding space industry (Phase 3 of the process)
Ref Project
EN 16603-10-02:2018 - Space engineering - Verification

Relations

Replaces
SIST EN 14725:2004 - Space engineering - Verification
Effective Date
01-Feb-2019

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Standards Content (Sample)

SLOVENSKI STANDARD
SIST EN 16603-10-02:2019
01-februar-2019
1DGRPHãþD
SIST EN 14725:2004
Vesoljska tehnika - Preverjanje
Space engineering - Verification
Raumfahrttechnik - Verifikation
Ingénierie spatiale - Vérification
Ta slovenski standard je istoveten z: EN 16603-10-02:2018
ICS:
49.140 Vesoljski sistemi in operacije Space systems and
operations
SIST EN 16603-10-02:2019 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN 16603-10-02:2019

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SIST EN 16603-10-02:2019


EUROPEAN STANDARD
EN 16603-10-02

NORME EUROPÉENNE

EUROPÄISCHE NORM
November 2018
ICS 49.140
Supersedes EN 14725:2003
English version

Space engineering - Verification
Ingénierie spatiale - Vérification Raumfahrttechnik - Verifikation
This European Standard was approved by CEN on 28 September 2018.

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. Up-to-date lists and bibliographical
references concerning such national standards may be obtained on application to the CEN-CENELEC Management Centre or to
any CEN and CENELEC member.

This European Standard exists 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, Former Yugoslav Republic of Macedonia, France, Germany,
Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania,
Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom.
























CEN-CENELEC Management Centre:
Rue de la Science 23, B-1040 Brussels
© 2018 CEN/CENELEC All rights of exploitation in any form and by any means Ref. No. EN 16603-10-02:2018 E
reserved worldwide for CEN national Members and for
CENELEC Members.

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
Table of contents
European Foreword . 4
1 Scope . 6
2 Normative references . 7
3 Terms, definitions and abbreviated terms . 8
3.1 Terms from other standards . 8
3.2 Terms specific to the present standard . 8
3.3 Abbreviated terms. 9
3.4 Nomenclature . 9
4 Verification principles . 10
4.1 Verification process . 10
4.1.1 Verification objectives . 10
4.1.2 Verification activities . 10
4.1.3 Verification documentation . 11
4.2 Verification planning . 12
4.2.1 Verification approach . 12
4.2.2 Verification methods . 12
4.2.3 Verification levels . 12
4.2.4 Verification stages . 13
4.2.5 Model philosophy . 13
4.2.6 Verification tools . 13
4.3 Verification execution and reporting . 13
4.4 Verification control and closeout . 13
5 Verification requirements . 14
5.1 Verification process . 14
5.2 Verification planning . 14
5.2.1 Verification approach . 14
5.2.2 Verification methods . 15
5.2.3 Verification levels . 17
5.2.4 Verification stages . 17
2

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
5.2.5 Models . 19
5.2.6 Verification tools . 19
5.2.7 Verification process phasing . 20
5.2.8 Verification planning documents. 21
5.3 Verification execution and reporting . 22
5.3.1 General . 22
5.3.2 Verification execution and reporting documentation . 22
5.4 Verification control and close-out . 24
5.4.1 General . 24
5.4.2 Verification control board (VCB) . 24
5.4.3 Re-verification . 25
5.4.4 Verification control and close-out documentation . 26
6 Pre-tailoring matrix per space product types . 27
Annex A (normative) Verification plan (VP) - DRD . 36
Annex B (normative) Verification control document (VCD) - DRD . 39
Annex C (normative) Test report - DRD . 42
Annex D (normative) Review-of-design report - DRD . 44
Annex E (normative) Inspection report - DRD . 46
Annex F (normative) Verification report - DRD . 48
Bibliography . 50

Figures
Figure 4-1: Verification process and activities . 11

Tables
Table 5-1: Product categories according to heritage . 18
Table 6-1: Definitions of the columns of Table 6-2 . 28
Table 6-2: Pre-tailoring matrix per “Space product types” . 29

3

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
European Foreword
This document (EN 16603-10-02:2018) has been prepared by Technical Committee CEN/CLC/TC 5
“Space”, the secretariat of which is held by DIN (Germany).
This document (EN 16603-10-02:2018) originates from ECSS-E-ST-10-02C Rev.1.
This European Standard shall be given the status of a national standard, either by publication of an
identical text or by endorsement, at the latest by May 2019, and conflicting national standards shall be
withdrawn at the latest by May 2019.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CEN [and/or CENELEC] shall not be held responsible for identifying any or all such
patent rights.
This document supersedes EN 14725:2003.
The main differences between EN 14725:2003 (that was based on ECSS-E-10-02A) and this standard
are:
• Restructuring of the document following, in particular: moving of the guidelines in the
associated Handbook, inclusion of an introductive clause on the Verification principles,
structuring of the requirement clauses in line with the verification process flow as
summarized in the principles.
• Clarification on standard applicability to different types of products (e.g. launcher,
transportation system, ground segment, GSE).
• Clarification of the verification vs. validation coverage.
• Moving of detailed test requirements to EN 16603-1003 (based on ECSS-E-ST-10-03C)
“Testing” including AIT Plan, Test Specification and Test Procedure DRDs.
• Introduction of risk assessment and mitigation plan concerning those requirements not
verified by test.
• Clarification on the applicability of verification by similarity as analysis method in
relationship to different types of products (requirement 5.2.2.3c)
• Clarification on product categories vs. heritage and relevant qualification requirements (clause
5.2.4.2)
• Clarification on in-orbit stage verification activities, in particular the relationship with the
commissioning (clause 5.2.4.5)
• Inclusion of a requirement concerning the verification database delivery in electronic form
(requirement 5.4.1c)
• Introduction of “status of compliance” in the VCD data (VCD DRD)
4

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
• Simplification of DRD’s number and content
This document has been prepared under a standardization request given to CEN by the European
Commission and the European Free Trade Association.
This document has been developed to cover specifically space systems and has therefore precedence
over any EN covering the same scope but with a wider domain of applicability (e.g. : aerospace).
According to the CEN-CENELEC Internal Regulations, the national standards organizations of the
following countries are bound to implement this European Standard: Austria, Belgium, Bulgaria,
Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of
Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania,
Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Serbia, Slovakia, Slovenia,
Spain, Sweden, Switzerland, Turkey and the United Kingdom.
5

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
1
Scope
This Standard establishes the requirements for the verification of a space system
product.
It defines the fundamental concepts of the verification process, the criteria for
defining the verification strategy and specifies the requirements for the
implementation of the verification programme. It includes also the list of the
expected documentation (i.e. Document requirements definitions, DRDs).
This Standard is intended to apply to different products at different levels from
a single equipment to the overall system.
Discipline related verification aspects are complemented in Standards specific
to those disciplines.
For verification process for SW the following standards are considered fully
sufficient for development of these items:
• ECSS-E-ST-40 Space engineering – Software
• ECSS-Q-ST-80 Space product assurance - Software product assurance
Detailed requirements for Testing are covered in the ECSS E-ST-10-03.
This standard does not specifically address Validation of space products as a
separate process, since product Verification is performed against requirements
that also address the suitability of the product to fulfil the needs of its intended
use. As such, Validation is achieved through the Verification process provided
adequate requirements are placed on the product.
It is recognised that testing and analysis also occur during the product
development process, but they are not addressed by this standard as they are
not formal requirement verification activities in the sense of the customer-
supplier relationship.
The guidelines on verification are provided in the associated handbook ECSS-E-
HB-10-02A.
The requirements on the systems engineering process are gathered in ECSS-E-
ST-10 “System Engineering”; specific aspects of the SE process are further
elaborated in dedicated standards, in particular: ECSS-E-ST-10-06 “Technical
Specification”, ECSS-E-ST-10-02 “Verification” (the present standard), and
ECSS-E-ST-10-03 “Testing”. These standards are based on the same principles,
process and documentation model.
The applicability of each these standards can therefore not be considered in
isolation from the others
This standard may be tailored for the specific characteristic and constraints of a
space project in conformance with ECSS-S-ST-00.
6

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
2
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 16601-00-01 ECSS-S-ST-00-01 ECSS system — Glossary of terms.
EN 16603-10 ECSS-E-ST-10 Space engineering – System engineering general
requirements
EN 16603-10-03 ECSS-E-ST-10-03 Space engineering — Testing
EN 16601-10 ECSS-M-ST-10 Space project management — Project planning and
implementation
EN 16602-10-09 ECSS-Q-ST-10-09 Space product assurance — Nonconformance control
system
EN 16602-20 ECSS-Q-ST-20 Space product assurance — Quality assurance.

7

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
3
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, in particular for the following terms:
1. acceptance
2. analysis
3. commissioning
4. inspection
5. qualification
6. test
7. validation
8. verification
3.2 Terms specific to the present standard
3.2.1 model philosophy
definition of the optimum number and the characteristics of physical, virtual,
and hybrid models required to achieve confidence in the product verification
with the shortest planning and a suitable weighting of costs and risks
3.2.2 review-of-design
verification method using approved records or evidence that unambiguously
show that the requirement is met
NOTE design documents, design reports, technical
descriptions, engineering drawings
3.2.3 Verification Control Board (VCB)
board composed of customer and supplier representatives that monitors the
verification process and assesses the requirements verification close-out.
3.2.4 verification level
product architectural level at which the relevant verification is performed
8

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
3.3 Abbreviated terms
For the purpose of this Standard, the abbreviated terms from ECSS-S-ST-00-01
apply.
3.4 Nomenclature
The following nomenclature applies throughout this document:
a. The word “shall” is used in this Standard to express requirements. All
the requirements are expressed with the word “shall”.
b. The word “should” is used in this Standard to express recommendations.
All the recommendations are expressed with the word “should”.
NOTE It is expected that, during tailoring,
recommendations in this document are either
converted into requirements or tailored out.
c. The words “may” and “need not” are used in this Standard to express
positive and negative permissions, respectively. All the positive
permissions are expressed with the word “may”. All the negative
permissions are expressed with the words “need not”.
d. The word “can” is used in this Standard to express capabilities or
possibilities, and therefore, if not accompanied by one of the previous
words, it implies descriptive text.
NOTE In ECSS “may” and “can” have completely
different meanings: “may” is normative
(permission), and “can” is descriptive.
e. The present and past tenses are used in this Standard to express
statements of fact, and therefore they imply descriptive text.
9

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
4
Verification principles
4.1 Verification process
4.1.1 Verification objectives
The overall objective of verification is to demonstrate, through a dedicated
process, that the deliverable product meets the specified requirements.
A satisfactory completion of the verification process is the basis for a
contractual acceptance (as defined in ECSS-S-ST-00-01) of the product by the
Customer.
The objectives of the Verification process are as follows:
• to demonstrate the qualification of design and performance, as meeting
the specified requirements at the specified levels;
• to ensure that the product is in agreement with the qualified design, is
free from workmanship defects and acceptable for use;
• to confirm product integrity and performance at particular steps of the
project life cycle (e.g. launch, commissioning, mission events and
landing).
• to confirm that the overall system (including tools, procedures and
resources) is able to fulfil mission requirements;
4.1.2 Verification activities
The verification process activities consist of planning, execution, reporting,
control and closeout as summarized in Figure 4-1.
10

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
Initial Verification
Product Control Document
requirements Verification Verification
planningplanning
Verification
Plan
Supplier Customer
Verification
Execution &
Additional technical
reporting
documentation to support
Verification
Final Verification
Supplier
Verification
Control Document
Control &
Closeout
Verification
Control Board

Figure 4-1: Verification process and activities
4.1.3 Verification documentation
The verification process and its implementation activities are documented by
means of a specific set of verification documents.
• Verification plan (VP), see clause 5.2.8.1.
• Assembly, integration and test (AIT) plan, see ECSS-E-ST-10-03.
NOTE The Verification Plan and the AIT Plan can be
combined in one single AIV Plan (i.e. in this
case VP and AIT plans do not exist anymore as
single entities).
• Verification control document (VCD), see clauses 5.2.8.2 and 5.4.4.1.
• Test specification, see ECSS-E-ST-10-03.
• Test procedure, see ECSS-E-ST-10-03.
• Test report, see ECSS-E-ST-10-03, and clause 5.3.2.1 of the present
standard.
• Analysis report, see ECSS-E-ST-10, and clause 5.3.2.2 of the present
standard.
• Review of design report, see clause 5.3.2.3.
• Inspection report, see clause 5.3.2.4.
• Verification report, see clause 5.3.2.5.
11

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
4.2 Verification planning
4.2.1 Verification approach
To reach the verification objectives the verification approach is established in
early phases of a project by analyzing the requirements to be verified, taking
into account:
• design peculiarities and constraints,
• qualification status of candidate solutions (product category),
• availability and maturity of verification tools,
• verification (including test) methodologies,
• ground segment and in orbit constraints for the in-orbit stage (including
commissioning),
• programmatic constraints, and
• cost and schedule.
In generating the verification approach, the supplier conducts the following
steps:
 Identify “what” are the products and requirements subject of the
verification process;
 Identify “How” to verify them by considering the methods stated
in the technical specification
 Identify “When” to implement by applying the chosen verification
strategy.
These steps are generally conducted in an iterative process based on technical,
cost and schedule considerations, ensuring that the approach is agreed by both
the supplier and the customer.
4.2.2 Verification methods
The verification is executed by one or more of the following verification
methods: test, analysis, review of design and inspection. This list shows the
order of precedence that, in general, provides more confidence in the results.
4.2.3 Verification levels
The verification is performed incrementally at different product decomposition
levels. The number and type of verification levels depends upon the complexity
of the project and on its characteristics.
The usual verification levels for a space product are equipment, subsystem,
element, segment and overall system.
12

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
4.2.4 Verification stages
The verification process is implemented in subsequent verification stages along
the project life cycle.
The stages depend upon project characteristics and identify a type of
verification. The verification stages are qualification, acceptance, pre-launch,
in-orbit (including commissioning) and post-landing.
4.2.5 Model philosophy
The verification by test is implemented on the selected models chosen for the
project.
Model philosophy is defined by means of an iterative process which combines
programmatic constraints, verification strategies and the integration and test
programme, taking into account the development status of the candidate design
solution.
4.2.6 Verification tools
The verification tools to be used to perform verification activities are identified
and their procurement and utilisation planned. The extent to which the tools
are themselves subjected to formal verification depends upon their role.
4.3 Verification execution and reporting
The verification process activities are incrementally performed at different
product decomposition levels and in different stages, applying a coherent
bottom-up strategy and utilizing a suitable combination of different verification
methods.
In particular the verification by test is carried-out on different physical models
in agreement with the selected model philosophy.
4.4 Verification control and closeout
The verification process is monitored in its execution by the Verification Control
Board (see 5.4.2) and confirmed completed when, based on objective evidence,
the VCD deems the product as verified against the identified requirements and
the associated verification objectives. This has to be finally confirmed by the
customer.
13

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SIST EN 16603-10-02:2019
EN 16603-10-02:2018 (E)
5
Verification requirements
5.1 Verification process
a. The verification process shall demonstrate that the deliverable product
meets the specified customer requirements and is capable of sustaining
its operational role through:
1. Verification planning;
2. Verification execution and reporting;
3. Verification control and close-out.
5.2 Verification planning
5.2.1 Verification approach
a. The supplier shall identify any constraints on the verification process
arising from both the verification objectives and the requirements
defined by the customer as needing verification.
NOTE For example, ground segment characteristics,
launch service, envisaged end to end tests
involving several suppliers. The usual general
objectives are listed in clause 4.1.1 “Verification
objectives”.
b. The requirements specified in 5.2.1a shall always include those of the
technical specification.
c. The supplier shall define the verification approach by conducting the
following steps:
1. Identify and agree with the customer the set of requirements to be
subject of the verification process.
2. Select the methods and the levels of verification, the associated
model philosophy and the verification tools.
3. Identify the stages and events in which the verification is
implemented.
14

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EN 16603-10-02:2018 (E)
d. The verification approach shall be defined by the supplier in the
Verification Plan (VP) for approval by the customer prior to
implementation.
e. For each requirement to be verified, the verification strategy shall be
defined in terms of the combination of the selected verification methods
for the different verification levels at the applicable verification stages, in
the initial issue of the Verification Control Document (VCD) also called
verification matrix (see Annex B), for approval by the customer.
5.2.2 Verification methods
5.2.2.1 General
a. Verification shall be accomplished by one or more of the following
verification methods:
1. test (including demonstration);
2. analysis (including similarity);
3. review-of-design;
4. inspection.
b. <>
c. <>
d. For each requirement verified only by analysis or review-of-design, a risk
assessment (part of the VP) shall be conducted to determine the level
(major/minor) of the impact of this requirement on the mission.
e. For each case where the risk assessment performed as a result of 5.2.2.1d
identifies the impact of the requirement as being major, risk mitigation
planning shall be defined and reported as part of the Verification Plan.
5.2.2.2 Test
a. Verification by test shall consist of measuring product performance and
functions under representative simulated environments.
b. <>
c. <>
d. <>
e. <>
f. <>
g. <>
5.2.2.3 Analysis
a. Verification by analysis shall consist of performing theoretical or
empirical evaluation using techniques agreed with the Customer.
15

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EN 16603-10-02:2018 (E)
NOTE Techniques comprise systematic, statistical and
qualitative design analysis, modelling and
computational simulation.
b. <>
c. Analysis to demonstrate qualification of a product by similarity with an
already qualified product shall fulfil the following criteria:
1. The already qualified product was not qualified by similarity.
2. The product to be verified belongs to category A or to category B
(defined in Table 5-1) but no testing is required to achieve
qualification.
NOTE Implicitly the product to be verified cannot
belong to categories C and D equipment
(defined in Table 5-1).
d. Similarity analysis shall define differences that can dictate additional
verification activities.
e. An analysis programme shall be defined in the Verification Plan (VP).
f. An analysis programme shall be applicable to qualification and in-orbit
stages only.
5.2.2.4 Review-of-design (ROD)
a. Verification by Review-of design (ROD) shall consist of using approved
records or evidence that unambiguously show that the requirement is
met.
NOTE Examples of such approved records are design
documents and reports, technical descriptions,
and engineering drawings.
b. A review-of-design programme shall be defined in the Verification Plan
(VP).
c. A review-of-design programme shall only be applicable in the
qualification stage or in the in-orbit stage.
5.2.2.5 Inspection
a. Verification by inspection shall consist of visual determination of
physical characteristics.
NOTE Physical characteristics include constructional
features, hardware conformance to document
drawing or workmanship requirements,
physical conditions, software source code
conformance with coding standards.
b. An inspection programme shall be defined in the Verification Plan (VP).
16

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...

SLOVENSKI STANDARD
kSIST FprEN 16603-10-02:2018
01-september-2018
Vesoljska tehnika - Preverjanje
Space engineering - Verification
Raumfahrttechnik - Verifikation
Ingénierie spatiale - Vérification
Ta slovenski standard je istoveten z: FprEN 16603-10-02
ICS:
49.140 Vesoljski sistemi in operacije Space systems and
operations
kSIST FprEN 16603-10-02:2018 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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kSIST FprEN 16603-10-02:2018

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kSIST FprEN 16603-10-02:2018


EUROPEAN STANDARD
FINAL DRAFT
FprEN 16603-10-02
NORME EUROPÉENNE

EUROPÄISCHE NORM

June 2018
ICS 49.140
Will supersede EN 14725:2003
English version

Space engineering - Verification
Ingénierie spatiale - Vérification Raumfahrttechnik - Verifikation
This draft European Standard is submitted to CEN members for unique acceptance procedure. 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, Former Yugoslav Republic of Macedonia, France, Germany,
Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, 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.

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
© 2018 CEN/CENELEC All rights of exploitation in any form and by any means Ref. No. FprEN 16603-10-02:2018 E
reserved worldwide for CEN national Members and for
CENELEC Members.

---------------------- Page: 3 ----------------------
kSIST FprEN 16603-10-02:2018
FprEN 16603-10-02:2018 (E)
Table of contents
European Foreword . 4
1 Scope . 6
2 Normative references . 7
3 Terms, definitions and abbreviated terms . 8
3.1 Terms from other standards . 8
3.2 Terms specific to the present standard . 8
3.3 Abbreviated terms. 9
3.4 Nomenclature . 9
4 Verification principles . 10
4.1 Verification process . 10
4.1.1 Verification objectives . 10
4.1.2 Verification activities . 10
4.1.3 Verification documentation . 11
4.2 Verification planning . 12
4.2.1 Verification approach . 12
4.2.2 Verification methods . 12
4.2.3 Verification levels . 12
4.2.4 Verification stages . 13
4.2.5 Model philosophy . 13
4.2.6 Verification tools . 13
4.3 Verification execution and reporting . 13
4.4 Verification control and closeout . 13
5 Verification requirements . 14
5.1 Verification process . 14
5.2 Verification planning . 14
5.2.1 Verification approach . 14
5.2.2 Verification methods . 15
5.2.3 Verification levels . 17
5.2.4 Verification stages . 17
2

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FprEN 16603-10-02:2018 (E)
5.2.5 Models . 19
5.2.6 Verification tools . 19
5.2.7 Verification process phasing . 20
5.2.8 Verification planning documents. 21
5.3 Verification execution and reporting . 22
5.3.1 General . 22
5.3.2 Verification execution and reporting documentation . 22
5.4 Verification control and close-out . 24
5.4.1 General . 24
5.4.2 Verification control board (VCB) . 24
5.4.3 Re-verification . 25
5.4.4 Verification control and close-out documentation . 26
6 Pre-tailoring matrix per space product types . 27
Annex A (normative) Verification plan (VP) - DRD . 36
Annex B (normative) Verification control document (VCD) - DRD . 39
Annex C (normative) Test report - DRD . 42
Annex D (normative) Review-of-design report - DRD . 44
Annex E (normative) Inspection report - DRD . 46
Annex F (normative) Verification report - DRD . 48
Bibliography . 50

Figures
Figure 4-1: Verification process and activities . 11

Tables
Table 5-1: Product categories according to heritage . 18
Table 6-1: Definitions of the columns of Table 6-2 . 28
Table 6-2: Pre-tailoring matrix per “Space product types” . 29

3

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FprEN 16603-10-02:2018 (E)
European Foreword
This document (FprEN 16603-10-02:2018) has been prepared by Technical Committee CEN/CLC/TC 5
“Space”, the secretariat of which is held by DIN (Germany).
This document (FprEN 16603-10-02) originates from ECSS-E-ST-10-02C Rev.1.
This document is currently submitted to the Unique Acceptance Procedure.
This document will supersede EN 14725:2003.
The main differences between EN 17725:2003 (that was based on ECSS-E-10-02A) and this standard
are:
• Restructuring of the document following, in particular: moving of the guidelines in the
associated Handbook, inclusion of an introductive clause on the Verification principles,
structuring of the requirement clauses in line with the verification process flow as
summarized in the principles.
• Clarification on standard applicability to different types of products (e.g. launcher,
transportation system, ground segment, GSE).
• Clarification of the verification vs. validation coverage.
• Moving of detailed test requirements to EN 16603-1003 (based on ECSS-E-ST-10-03C)
“Testing” including AIT Plan, Test Specification and Test Procedure DRDs.
• Introduction of risk assessment and mitigation plan concerning those requirements not
verified by test.
• Clarification on the applicability of verification by similarity as analysis method in
relationship to different types of products (requirement 5.2.2.3c)
• Clarification on product categories vs. heritage and relevant qualification requirements (clause
5.2.4.2)
• Clarification on in-orbit stage verification activities, in particular the relationship with the
commissioning (clause 5.2.4.5)
• Inclusion of a requirement concerning the verification database delivery in electronic form
(requirement 5.4.1c)
• Introduction of “status of compliance” in the VCD data (VCD DRD)
• Simplification of DRD’s number and content
This document has been developed to cover specifically space systems and will the-refore have
precedence over any EN covering the same scope but with a wider do-main of applicability (e.g.:
aerospace).
4

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This document has been prepared under a mandate given to CEN by the European Commission and
the European Free Trade Association.
5

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1
Scope
This Standard establishes the requirements for the verification of a space system
product.
It defines the fundamental concepts of the verification process, the criteria for
defining the verification strategy and specifies the requirements for the
implementation of the verification programme. It includes also the list of the
expected documentation (i.e. Document requirements definitions, DRDs).
This Standard is intended to apply to different products at different levels from
a single equipment to the overall system.
Discipline related verification aspects are complemented in Standards specific
to those disciplines.
For verification process for SW the following standards are considered fully
sufficient for development of these items:
• ECSS-E-ST-40 Space engineering – Software
• ECSS-Q-ST-80 Space product assurance - Software product assurance
Detailed requirements for Testing are covered in the ECSS E-ST-10-03.
This standard does not specifically address Validation of space products as a
separate process, since product Verification is performed against requirements
that also address the suitability of the product to fulfil the needs of its intended
use. As such, Validation is achieved through the Verification process provided
adequate requirements are placed on the product.
It is recognised that testing and analysis also occur during the product
development process, but they are not addressed by this standard as they are
not formal requirement verification activities in the sense of the customer-
supplier relationship.
The guidelines on verification are provided in the associated handbook ECSS-E-
HB-10-02A.
The requirements on the systems engineering process are gathered in ECSS-E-
ST-10 “System Engineering”; specific aspects of the SE process are further
elaborated in dedicated standards, in particular: ECSS-E-ST-10-06 “Technical
Specification”, ECSS-E-ST-10-02 “Verification” (the present standard), and
ECSS-E-ST-10-03 “Testing”. These standards are based on the same principles,
process and documentation model.
The applicability of each these standards can therefore not be considered in
isolation from the others
This standard may be tailored for the specific characteristic and constraints of a
space project in conformance with ECSS-S-ST-00.
6

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2
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 16601-00-01 ECSS-S-ST-00-01 ECSS system — Glossary of terms.
EN 16603-10 ECSS-E-ST-10 Space engineering – System engineering general
requirements
EN 16603-10-03 ECSS-E-ST-10-03 Space engineering — Testing
EN 16601-10 ECSS-M-ST-10 Space project management — Project planning and
implementation
EN 16602-10-09 ECSS-Q-ST-10-09 Space product assurance — Nonconformance control
system
EN 16602-20 ECSS-Q-ST-20 Space product assurance — Quality assurance.

7

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3
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, in particular for the following terms:
1. acceptance
2. analysis
3. commissioning
4. inspection
5. qualification
6. test
7. validation
8. verification
3.2 Terms specific to the present standard
3.2.1 model philosophy
definition of the optimum number and the characteristics of physical, virtual,
and hybrid models required to achieve confidence in the product verification
with the shortest planning and a suitable weighting of costs and risks
3.2.2 review-of-design
verification method using approved records or evidence that unambiguously
show that the requirement is met
NOTE design documents, design reports, technical
descriptions, engineering drawings
3.2.3 Verification Control Board (VCB)
board composed of customer and supplier representatives that monitors the
verification process and assesses the requirements verification close-out.
3.2.4 verification level
product architectural level at which the relevant verification is performed
8

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3.3 Abbreviated terms
For the purpose of this Standard, the abbreviated terms from ECSS-S-ST-00-01
apply.
3.4 Nomenclature
The following nomenclature applies throughout this document:
a. The word “shall” is used in this Standard to express requirements. All
the requirements are expressed with the word “shall”.
b. The word “should” is used in this Standard to express recommendations.
All the recommendations are expressed with the word “should”.
NOTE It is expected that, during tailoring,
recommendations in this document are either
converted into requirements or tailored out.
c. The words “may” and “need not” are used in this Standard to express
positive and negative permissions, respectively. All the positive
permissions are expressed with the word “may”. All the negative
permissions are expressed with the words “need not”.
d. The word “can” is used in this Standard to express capabilities or
possibilities, and therefore, if not accompanied by one of the previous
words, it implies descriptive text.
NOTE In ECSS “may” and “can” have completely
different meanings: “may” is normative
(permission), and “can” is descriptive.
e. The present and past tenses are used in this Standard to express
statements of fact, and therefore they imply descriptive text.
9

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4
Verification principles
4.1 Verification process
4.1.1 Verification objectives
The overall objective of verification is to demonstrate, through a dedicated
process, that the deliverable product meets the specified requirements.
A satisfactory completion of the verification process is the basis for a
contractual acceptance (as defined in ECSS-S-ST-00-01) of the product by the
Customer.
The objectives of the Verification process are as follows:
• to demonstrate the qualification of design and performance, as meeting
the specified requirements at the specified levels;
• to ensure that the product is in agreement with the qualified design, is
free from workmanship defects and acceptable for use;
• to confirm product integrity and performance at particular steps of the
project life cycle (e.g. launch, commissioning, mission events and
landing).
• to confirm that the overall system (including tools, procedures and
resources) is able to fulfil mission requirements;
4.1.2 Verification activities
The verification process activities consist of planning, execution, reporting,
control and closeout as summarized in Figure 4-1.
10

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kSIST FprEN 16603-10-02:2018
FprEN 16603-10-02:2018 (E)
Initial Verification
Product Control Document
requirements Verification Verification
planningplanning
Verification
Plan
Supplier Customer
Verification
Execution &
Additional technical
reporting
documentation to support
Verification
Final Verification
Supplier
Verification
Control Document
Control &
Closeout
Verification
Control Board

Figure 4-1: Verification process and activities
4.1.3 Verification documentation
The verification process and its implementation activities are documented by
means of a specific set of verification documents.
• Verification plan (VP), see clause 5.2.8.1.
• Assembly, integration and test (AIT) plan, see ECSS-E-ST-10-03.
NOTE The Verification Plan and the AIT Plan can be
combined in one single AIV Plan (i.e. in this
case VP and AIT plans do not exist anymore as
single entities).
• Verification control document (VCD), see clauses 5.2.8.2 and 5.4.4.1.
• Test specification, see ECSS-E-ST-10-03.
• Test procedure, see ECSS-E-ST-10-03.
• Test report, see ECSS-E-ST-10-03, and clause 5.3.2.1 of the present
standard.
• Analysis report, see ECSS-E-ST-10, and clause 5.3.2.2 of the present
standard.
• Review of design report, see clause 5.3.2.3.
• Inspection report, see clause 5.3.2.4.
• Verification report, see clause 5.3.2.5.
11

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4.2 Verification planning
4.2.1 Verification approach
To reach the verification objectives the verification approach is established in
early phases of a project by analyzing the requirements to be verified, taking
into account:
• design peculiarities and constraints,
• qualification status of candidate solutions (product category),
• availability and maturity of verification tools,
• verification (including test) methodologies,
• ground segment and in orbit constraints for the in-orbit stage (including
commissioning),
• programmatic constraints, and
• cost and schedule.
In generating the verification approach, the supplier conducts the following
steps:
 Identify “what” are the products and requirements subject of the
verification process;
 Identify “How” to verify them by considering the methods stated
in the technical specification
 Identify “When” to implement by applying the chosen verification
strategy.
These steps are generally conducted in an iterative process based on technical,
cost and schedule considerations, ensuring that the approach is agreed by both
the supplier and the customer.
4.2.2 Verification methods
The verification is executed by one or more of the following verification
methods: test, analysis, review of design and inspection. This list shows the
order of precedence that, in general, provides more confidence in the results.
4.2.3 Verification levels
The verification is performed incrementally at different product decomposition
levels. The number and type of verification levels depends upon the complexity
of the project and on its characteristics.
The usual verification levels for a space product are equipment, subsystem,
element, segment and overall system.
12

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4.2.4 Verification stages
The verification process is implemented in subsequent verification stages along
the project life cycle.
The stages depend upon project characteristics and identify a type of
verification. The verification stages are qualification, acceptance, pre-launch,
in-orbit (including commissioning) and post-landing.
4.2.5 Model philosophy
The verification by test is implemented on the selected models chosen for the
project.
Model philosophy is defined by means of an iterative process which combines
programmatic constraints, verification strategies and the integration and test
programme, taking into account the development status of the candidate design
solution.
4.2.6 Verification tools
The verification tools to be used to perform verification activities are identified
and their procurement and utilisation planned. The extent to which the tools
are themselves subjected to formal verification depends upon their role.
4.3 Verification execution and reporting
The verification process activities are incrementally performed at different
product decomposition levels and in different stages, applying a coherent
bottom-up strategy and utilizing a suitable combination of different verification
methods.
In particular the verification by test is carried-out on different physical models
in agreement with the selected model philosophy.
4.4 Verification control and closeout
The verification process is monitored in its execution by the Verification Control
Board (see 5.4.2) and confirmed completed when, based on objective evidence,
the VCD deems the product as verified against the identified requirements and
the associated verification objectives. This has to be finally confirmed by the
customer.
13

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5
Verification requirements
5.1 Verification process
a. The verification process shall demonstrate that the deliverable product
meets the specified customer requirements and is capable of sustaining
its operational role through:
1. Verification planning;
2. Verification execution and reporting;
3. Verification control and close-out.
5.2 Verification planning
5.2.1 Verification approach
a. The supplier shall identify any constraints on the verification process
arising from both the verification objectives and the requirements
defined by the customer as needing verification.
NOTE For example, ground segment characteristics,
launch service, envisaged end to end tests
involving several suppliers. The usual general
objectives are listed in clause 4.1.1 “Verification
objectives”.
b. The requirements specified in 5.2.1a shall always include those of the
technical specification.
c. The supplier shall define the verification approach by conducting the
following steps:
1. Identify and agree with the customer the set of requirements to be
subject of the verification process.
2. Select the methods and the levels of verification, the associated
model philosophy and the verification tools.
3. Identify the stages and events in which the verification is
implemented.
14

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FprEN 16603-10-02:2018 (E)
d. The verification approach shall be defined by the supplier in the
Verification Plan (VP) for approval by the customer prior to
implementation.
e. For each requirement to be verified, the verification strategy shall be
defined in terms of the combination of the selected verification methods
for the different verification levels at the applicable verification stages, in
the initial issue of the Verification Control Document (VCD) also called
verification matrix (see Annex B), for approval by the customer.
5.2.2 Verification methods
5.2.2.1 General
a. Verification shall be accomplished by one or more of the following
verification methods:
1. test (including demonstration);
2. analysis (including similarity);
3. review-of-design;
4. inspection.
b. <>
c. <>
d. For each requirement verified only by analysis or review-of-design, a risk
assessment (part of the VP) shall be conducted to determine the level
(major/minor) of the impact of this requirement on the mission.
e. For each case where the risk assessment performed as a result of 5.2.2.1d
identifies the impact of the requirement as being major, risk mitigation
planning shall be defined and reported as part of the Verification Plan.
5.2.2.2 Test
a. Verification by test shall consist of measuring product performance and
functions under representative simulated environments.
b. <>
c. <>
d. <>
e. <>
f. <>
g. <>
5.2.2.3 Analysis
a. Verification by analysis shall consist of performing theoretical or
empirical evaluation using techniques agreed with the Customer.
15

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kSIST FprEN 16603-10-02:2018
FprEN 16603-10-02:2018 (E)
NOTE Techniques comprise systematic, statistical and
qualitative design analysis, modelling and
computational simulation.
b. <>
c. Analysis to demonstrate qualification of a product by similarity with an
already qualified product shall fulfil the following criteria:
1. The already qualified product was not qualified by similarity.
2. The product to be verified belongs to category A or to category B
(defined in Table 5-1) but no testing is required to achieve
qualification.
NOTE Implicitly the product to be verified cannot
belong to categories C and D equipment
(defined in Table 5-1).
d. Similarity analysis shall define differences that can dictate additional
verification activities.
e. An analysis programme shall be defined in the Verification Plan (VP).
f. An analysis programme shall be applicable to qualification and in-orbit
stages only.
5.2.2.4 Review-of-design (ROD)
a. Verification by Review-of design (ROD) shall consist of using approved
records or evidence that unambiguously show that the requirement is
met.
NOTE Examples of such approved records are design
documents and reports, technical descriptions,
and engineering drawings.
b. A review-of-design programme shall be defined in the Verification Plan
(VP).
c. A review-of-design programme shall only be applicable in the
qualification stage or in the in-orbit stage.
5.2.2.5 Inspection
a. Verification by inspection shall consist of visual determination of
physical characteristics.
NOTE Physical characteristics include constructional
features, hardware conformance to document
drawing or workmanship requirements,
physical conditions, software source code
conformance with coding standards.
b. An inspection programme shall be defined in the Verification Plan (VP).
16

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5.2.3 Verification levels
a. Verification shall be accomplished through the verification levels in
conformance with those defined with the Annex A Verification Plan
DRD.
NOTE Usual levels are defined in 4.2.3.
b. When a requirement is fully verified at lower level, the traceability to
lower level verification evidence shall be identified.
c. Formal close-out of qualification and acceptance at lower levels shall be
performed
...

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2021-04-21: This EN is based on ECSS-Q-ST-70-40C

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SIST
SIST EN 16602-60:2023(Main)
Space product assurance - Electrical, electronic and electromechanical (EEE) components
EN 16602-60:2023

The Scope of the Standard remains unchanged.
This standard defines the requirements for selection, control, procurement and usage of EEE components for space projects.
This standard differentiates between three classes of components through three different sets of standardization requirements (clauses) to be met.
The three classes provide for three levels of trade-off between assurance and risk. The highest assurance and lowest risk is provided by class 1 and the lowest assurance and highest risk by class 3. Procurement costs are typically highest for class 1 and lowest for class 3. Mitigation and other engineering measures may decrease the total cost of ownership differences between the three classes. The project objectives, definition and constraints determine which class or classes of components are appropriate to be utilised within the system and subsystems.
a.   Class 1 components are described in Clause 4.
b.   Class 2 components are described in Clause 5
c.   Class 3 components are described in Clause 6.
The requirements of this document apply to all parties involved at all levels in the integration of EEE components into space segment hardware and launchers.

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SIST
SIST EN 16602-70-61:2022(Main)
Space product assurance - High-reliability soldering for surface mount, mixed technology and hand-mounted electrical connections
EN 16602-70-61:2022

This standard defines:
- the basic requirements for the verification and approval of automatic machine w ave soldering for use in spacecraft hardware. The process requirements for w ave soldering of doublesided and multilayer boards are also defined.
- the technical requirements and quality assurance provisions for the manufacture and verification of manuallysoldered, high-reliability electrical connections.
- 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 acceptance and rejection criteria for high reliability manufacture of manually-soldered electrical connections intended to w ithstand normal terrestrial conditions and the vibrational g-loads and environment imposed by space flight.
- the proper tools, correct materials, design and w orkmanshipt. Workmanship standards are included to permit discrimination betw een proper and improper work.
SCOPE
This Standard defines the technical requirements and quality assurance provisions for the manufacture and verification of high-reliability electronic circuits of surface mount, through hole and solderless assemblies.
The Standard defines w orkmanship requirements, the acceptance and rejection criteria for high-reliability assemblies intended to withstand normal terrestrial conditions and the environment imposed by space flight.
The mounting and supporting of components, terminals and conductors specified in this standard applies only to assemblies designed to continuously operate over the mission w ithin the temperature limits of -55 °C to +85 °C at solder joint level.
Requirements related to printed circuit boards are contained in ECSS-Q-ST-70-60 (equivalent to EN 16602-70-60) and ECSS-Q-ST-70-12 (equivalent to EN 16602-70-12).
This Standard does not cover the qualification and acceptance of the EQM and FM equipment w ith high-reliability electronic circuits of surface mount, through hole and solderless assemblies.
This Standard does not cover verification of thermal properties for component assembly.
This Standard does not cover pressfit connectors.
The qualification and acceptance tests of equipment manufactured in accordance w ith this Standard are covered by ECSS-EST-10-03 (equivalent to EN 16603-10-03).

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SIST
SIST EN 16603-20-07:2022(Main)
Space engineering - Electromagnetic compatibility
EN 16603-20-07:2022

EMC policy and general system requirements are specified in ECSS-E-ST-20 (equivalent to EN 16603-20).
This ECSS-E-ST-20-07 (equivalent to EN 16603-20-07) Standard addresses detailed system requirements (Clause 4), general test conditions, verification requirements at system level, and test methods at subsystem and equipment level (Clause 5) as w ell as informative limits (Annex A).
Associated to this standard is ECSS-E-ST-20-06 (equivalent to EN 16603-20-06) "Spacecraft charging", w hich addresses charging control and risks arising from environmental and vehicle-induced spacecraft charging w hen ECSS-E-ST-20-07 addresses electromagnetic effects of electrostatic discharges.
Annexes A to C of ECSS-E-ST-20 document EMC activities related to ECSS-E-ST-20-07: the EMC Control Plan (Annex A) defines the approach, methods, procedures, resources, and organization, the Electromagnetic Effects Verification Plan (Annex B) defines and specifies the verification processes, analyses and tests, and the Electromagnetic Effects Verification Report (Annex C) document verification results. The EMEVP and the EMEVR are the vehicles for tailoring this standard.

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SIST
SIST EN 16603-10-03:2022(Main)
Space engineering - Testing
EN 16603-10-03:2022

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.

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SIST
SIST-TP CEN/CLC/TR 17603-10-03:2022(Main)
Space engineering - Testing guidelines
CEN/CLC/TR 17603-10-03:2022

This handbook provides additional information for the application of the Testing standard EN 16603-10-03.
This handbook will be the guideline for all space projects, related equipment and complete systems, by providing background information that aids the reader to better understand and meet the requirements of the standard.
The document would follow the flow of the Testing standard and in particular w hatever is excluded from the testing standard (see Scope of EN 16603-10-03) should also be excluded.
NOTE: EN 16603-10-03:2014 will be in parallel also updated to take into account the new TR.

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SIST
SIST EN 16603-50:2022(Main)
Space engineering - Communications
EN 16603-50:2022

This Standard specifies the requirements for the development of the end­to­end data communications system for spacecraft.
Specifically, this standard specifies:
-   The terminology to be used for space communication systems engineering.
-   The activities to be performed as part of the space communication system engineering process, in accordance with the ECSS-E-ST-10 standard.
-   Specific requirements on space communication systems in respect of functionality and performance.
The communications links covered by this Standard are the space­to­ground and space­to­space links used during spacecraft operations, and the communications links to the spacecraft used during the assembly, integration and test, and operational phases.
Spacecraft end­to­end communication systems comprise components in three distinct domains, namely the ground network, the space link, and the space network. This Standard covers the components of the space link and space network in detail. However, this Standard only covers those aspects of the ground network that are necessary for the provision of the end­to­end communication services.
NOTE    Other aspects of the ground network are covered in ECSS-E ST 70.
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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SIST EN 16603-50-25:2022(Main)
Space engineering - Adoption Notice of CCSDS 232.0-B-3, TC Space Data Link Protocol
EN 16603-50-25:2022

This document identifies the clauses and requirements modified w ith respect to the standard CCSDS 131.0-B-3, TM Synchronization and Channel Coding, Issue 3, September 2017 for application in ECSS.

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SIST EN 16603-50-26:2022(Main)
Space engineering - Adoption Notice of CCSDS 232.1-B-2, Communications Operation Procedure-1
EN 16603-50-26:2022

This document identifies the clauses and requirements modified with respect to the standards CCSDS 232.1-B-2, Communications Operation Procedure-1, Issue 2, September 2010 for application in ECSS.
NOTE The recently published technical corrigendum has modified CCSDS 232.1-B-2. However, the changes are not affecting the Adoption Notice.

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