1. Sentinel Payload Ground Segment Industry Information Day
GMES Space Component
Sentinel Payload Ground Segment
Industry Information Day

2. Purpose of the Mtg
Inform Industry about Procurement Plans for the GSC Sentinel Payload Ground Segment
Collect general questions to be responded to all prior to release of the ITTs

3. Sentinels PDGS Sub-Systems Procurements way forward
Sentinels PDGS Industry Information Day
Introduction
Welcome & General Introduction
Overall Scope of the activity
Sentinels PDGS Procurement rules
Sentinels PDGS Sub-Systems
Front End Processor
Precise Orbit Determination
Operational Instrument Processors
Mission Planning
Sentinels PDGS
S-1 Payload Data Ground Segment (PDGS)
S-2 and S-3 PDGS
Procurements way forward
Best practices
Schedule and way forward

4. GMES & GSC Introduction

5. GMES is an EU led initiative Services Component – led by EC
GMES components
GMES is an EU led initiative
Services Component – led by EC
Produces information services in response to European policy priorities in environment and security
Relies on data from in-situ and space component
In-situ component – led by EEA
Observations mostly within national responsibility, with coordination at European level
Space Component – led by ESA
Sentinels - EO missions developed specifically for GMES:
Contributing Missions - EO missions built for purposes other than GMES but offering part of their capacity to GMES (EU/ESA MSs, EUMETSAT, commercial, international)

6. GMES dedicated missions: Sentinels
Sentinel 1 – SAR imaging
All weather, day/night applications, interferometry
Sentinel 2 – Multispectral imaging
Land applications: urban, forest, agriculture, etc Continuity of Landsat, SPOT data
Sentinel 3 – Ocean and global land monitoring
Wide-swath ocean color, vegetation, sea/land surface temperature, altimetry
Sentinel 4 – Geostationary atmospheric
Atmospheric composition monitoring, trans-boundary pollution
Sentinel 5 – Low-orbit atmospheric
Atmospheric composition monitoring
2011
2012
2012
2017+
2019+

7. Sentinel-1: C-band SAR mission
Applications:
monitoring sea ice zones and the arctic environment
surveillance of marine environment
monitoring land surface motion risks
mapping in support of humanitarian aid in crisis situations
4 nominal operation modes:
strip map (80 km swath, 5X5 m res.)
interferometric wide swath (250 km swath, 20X5 m res.)
extra wide swath (400 km swath, 25X100 m res.)
Wave (5X20 m res.)
2300 Kg spacecraft mass
Sun synchronous orbit at 693 Km mean altitude
12 days repeat cycle
7 years design life time, consumables for 12 years
Sentinel-1:
C-band
SAR mission

8. Superspectral imaging mission
Sentinel-2
Applications:
Generic land cover maps
risk mapping and fast images for disaster relief
generation of leaf coverage, leaf chlorophyll content and leaf water content
Pushbroom filter based multi spectral imager with 13 spectral bands (VNIR & SWIR)
Spatial resolution: 10, 20 and 60 m
Field of view: 290 km
1180 kg spacecraft mass
5 days repeat cycle
Sun synchronous orbit at 786 km mean altitude
7 years design life time, consumables for 12 years
Sentinel-2:
Superspectral imaging mission

9. ocean & global land mission
Sentinel-3
Applications:
Sea/land colour data and surface temperature
sea surface and land ice topography
coastal zones, inland water and sea ice topography
vegetation products
1198 kg spacecraft mass
Sun synchronous orbit at km mean altitude over geoid
27 days repeat cycle
7 years design life time, consumables for 12 years
Sentinel-3:
ocean & global land mission

10. Sentinel-3 Instruments:
Ocean and Land Colour Instrument (OLCI) with 5 cameras, 8 bands (only VIS) for open ocean (low res), 15 bands (only VIS) for coastal zones (high res). Spatial sampling: SSP
Sea and Land Surface Temperature (SLST) with 9 spectral bands, 0.5 (VIS, SWIR) to 1 km res (MWIR, TIR). Swath: 180rpm dual view scan, nadir & backwards
RA package SRAL Ku-C altimeter (LRM and SAR measurement modes), MWR, POD (with Laser Retro Reflector, GNSS and DORIS)

11. GEO atmospheric mission
Sentinel-4
Applications:
monitoring changes in the atmospheric composition (e.g. ozone, NO2, SO2, BrO, formaldehyde and aerosol) at high temporal resolution
tropospheric variability
Narrow field spectrometer covering UV ( nm), visible ( nm) and near-IR ( nm) bands
Spatial sampling 5-50 km and spectral resolution between 0.06 nm and 1 nm (depending on band)
Geostationary orbit, at 0o longitude
Embarked on MTG-S and operated by EUMETSAT
Sentinel-4:
GEO atmospheric mission

12. LEO atmospheric mission
Sentinel-5
Applications:
monitoring changes in the atmospheric composition (e.g. ozone, NO2, SO2, BrO, formaldehyde and aerosol) at high temporal (daily) resolution
tropospheric variability
Wide-swath pushbroom spectrometer suite, covering UV ( nm), visible ( & nm), NIR ( nm) and SWIR ( nm) bands.
Spatial sampling 5-50 km and spectral resolution between 0.05 nm and 1 nm (depending on band)
Low Earth orbit (reference altitude of about 817 km)
Sentinel-5 precursor to fill data gaps ( ). Sentinel-5 embarked on post-EPS and operated by EUMETSAT
Sentinel-5:
LEO atmospheric mission

13. GMES Ground Segment and Data Access
Sentinel-3
GCM GS
Sentinel-1
GCM GS
TM/TC
ISPs
GCM GS
GMES
Space
Component
GCM GS
TT&C Stations
Acquisition Stations
Sentinels PDGS
GCM GS
FOS
GCM GS
(ESA, EUMETSAT, NOAA, national member-states missions, etc…)
GMES Contributing Missions GS’s
GMES Sentinels GS
GSC Coordinated
Data Access System
GSC
Data Request
GSC
Data Provision
USER Segment
GMES Service Segment
Final end-user information products

14. Preparatory programme
GSC implementation schedule
Preparatory programme
Build-up phase
(Segments 1 + 2)
Operational programme
2004
2005
2006
2013
2014
2023

15. Content of GSC programme
Sentinel-1 A: Phase B2/C/D/E1. Sentinel-1B: up to flight readiness
Sentinel-2 A: Phase B2/C/D/E1. Sentinel-2B: up to flight readiness
Sentinel-3 A: Phase B2/C/D/E1. Sentinel-3B: up to flight readiness
Sentinel-4 (MTG-S): Phase B/C/D incl, processor & 2nd unit
Sentinel-5 (post-EPS): Phase B1 & pre-development
Sentinel 5 pre-cursor up to Launch and IOV; UV-NIR instrument provided by NL
Ground Segment Development for Sentinel-1, -2, -3
Data Access (management, operations & data procurement)
GSC Evolution Studies, incl. low-inclination altimetry (Jason follow-on)
Segment 2

16. GSC Data Access Status today
First Set of data requirements consolidated in May 08 GMES Fast Track Pilot Services & Urban Atlas (Start Sep08-Apr09) Several Requirements Review loops and updates GSCDA portal open since early Dec 08; ESA- data, ESA-TPM data & Eumetsat data are provided since; 9 Contracts placed or under negotiation with GMES Contributing Missions EU Agency interfaces being discussed Requirements strongly evolved and evolve

17. GSCDA Pre-operations Status
GSCDA Pre-operations started with ESA and ESA-TPMs in Dec. 2008
Deployed DataSets
Help Desk Statistics
GSCDA DataSets advertised on GSC Portal
Delivered Products

18. GSCDA System Infrastructure Development
Development of Data Access System infrastructure on-going
System requirements Review held in June 2008
Preliminary Design Review on-going
Development of interfaces with GSC Contributing Missions on-going

19. Requirements Vs Architecture
GSC shall respond to all current and expected (*1) requirements. Accordingly the Sentinel GS will consist of a ESA Sentinel Core Ground Segment (*2) and Collaborative Ground Segment of - national ground segment elements - GS functions within the GMES Services Segment (*1) from new GMES Services, EU agencies, member states, science etc (*2) incl. interfaces and mgt functions for the collaborative parts; incl EDRS interfaces in the architecture)

20. Main GSC GS Design / Development Drivers
High Data Volume Operational Data Delivery from Beginning - Maximum ‘systematic’ functions - Simple, easy design - highest reliability for E2E data access for users Flexibility (Without impact of systematic functions) - clear interfaces to complementary GS functions - Re-processing as part of system budgets Sentinel PDGS Integration into an already ‘operational’ GCM service, during commissioning

21. GMES Space Component funding
Segment 1 & 2 Co Funding Scheme
Financing – ESA GSC programme
758 M€ Segment 1
831 M€ Segment 2
Financing – EC FP7
600 M€ FP7 Space
~ 2.2 bn€ for development of first generation of Sentinels, data access to MS/EUM missions, ground segment, early operations

22. ESA (and ESA procedures *)
Funding and Procurement
ESA-only funded elements and ESA-EC joint-funded elements
Open to
ESA Member States and ESA- Member States and EC FP7 participating States
Issued via
ESA Emits and ESA- Emits and EC Cordis
Managed by
ESA (and ESA procedures *)
* No georeturn targets but georeturn reporting

23. Sentinels PDGS Developments
Overall Scope

24. Introduction to the GMES Space Component infrastructure and services
Introduction to Sentinels PDGS
Drivers
Infrastructure and Services
Development Logic
Introduction to Sentinels Procurement
Procurement Logic and phasing
Procurement Sizing
Schedule

25. GSC Ground Segment infrastructure
GSC infrastructure is decomposed into :
GSC Core Space Segment : Space infrastructure (Sentinels constellation)
GSC Contributing Missions (GCMs): National, ESA or Third Party missions partially or fully supporting the GMES Space Component, complementing the Sentinels services according to the GSC operational gap filling analysis
GSC Core Ground Segment : Sentinels Flight Operation Segment (FOS) and Payload Data Ground Segment (PDGS). The Core Ground Segment also includes capabilities for assembling data from external sources and for interfacing with the third party entities (GCM or collaborative GS)
GSC Collaborative Ground Segments: Third party entities that contribute to the GSC infrastructure, providing complementary services or improving overall performances (e.g. local stations)

26. GSC Core Ground Segment Services (1/2)
Space Segment operations
Sentinels TT&C data uplink and downlink (S-band link)
Sentinels satellites commanding & control
Mission exploitation
Sentinels data acquisition: (X-Band/Ka-Band data downlink and ingestion), through a Sentinels Core Ground Stations network
Sentinels Mission planning: for Sentinels data downlink and instrument sensing.
Systematic and rush generation of mission data products: (at least to a calibrated product level) and access through satellite broadcast link over Europe or ground network to a pick up point
Mission data preservation and access: long-term preservation (25 years) of all Sentinels and relevant GCM products (Including Mission reprocessing function). These data are accessed on-line through automated request mechanism.

27. GSC Core Ground Segment Services (2/2)
Mission exploitation
Sentinels mission performances monitoring and control: characterisation of the space and ground infrastructure performances (e.g. sensors ageing, network availability), adjustment of on-ground services to guaranty services performance continuity, regular reporting on measured operations performances
GSC data-sets assembly: The assembly service offers the possibility to generate, consolidate and retrieve some of the large data sets required by GMES Services Projects, (e.g. coverage or stack data sets), including the integration of non-Sentinels mission data whenever necessary.
GSC Users Coordinated Interface: Interface to the GSC users for:
Coordination of multi-mission rush satellite tasking requests in support to emergencies and crises management
Service support for GSC users, including user registration and service desk

28. Sentinels PDGS Drivers
High data rates and on-ground volumes to be managed
Initial development is organised to support the B-series as a natural upgrade
Missions are considered operational and commissioning phase shall be completed within 3 to 4 months
25 years of mission exploitation
All developments are defined as operational software development

29. Sentinels PDGS infrastructure and services
The Payload Data Ground Segment (PDGS) covers the infrastructure necessary for :
Sentinels data acquisition
Demodulation and front end processing elements
Sentinels Mission planning
Systematic and rush generation of mission data products
Production data flow control including: processors, auxiliary data management, precise orbit determination, dissemination, rolling and on-line repositories
Mission data preservation and access
Long term archive, catalogue, dissemination
Sentinels mission performances monitoring and control
Instrument performance monitoring, quality control, cal/val tools, end-to-end system performances monitoring and reporting
GSC data-sets assembly
Product consolidation and data assembly elements

30. Sentinels PDGS Development logic
Common elements regrouped into separate ITTs
Demodulator and Front End Processor
Precise orbit determination services
Maximise reuse of existing European infrastructure and ESA supported operational interfaces:
X-Band Antenna Acquisition System
Long term data archiving infrastructure
User Services
Auxiliary data handling services
Elements will be procured as services within a separate ITT (for stations & centres) based on customisation of standard interfaces
Three Satellite missions leading to specific procurements (ITTs or Best practices)
“PDGS core contract” for end-to-end design and integration (including development of required specific elements)
Mission Planning
Operational Instrument Processor and Performance monitoring and QC

31. Sentinels PDGS Procurement Logic
Definition of the PDGS operational interfaces
Development of the PDGS infrastructure elements
Reference platform integration
Procurement of the centres according to PDGS interfaces specifications
Deployment of PDGS elements into the procured centres
Overall verification
Commissioning operations
Maintenance of PDGS system during commissioning
Phase 1:
Definition of the PDGS operational interfaces
Development of the PDGS infrastructure elements
Reference platform integration
Phase 2 :
Procurement of the centres according to PDGS interfaces specifications
Phase 3:
Deployment of PDGS elements into the procured centres
Overall verification
Phase 4:
Commissioning operations
Maintenance of PDGS system during commissioning
Procurement of the centres according to PDGS interfaces specifications
Commissioning operations
Part of current ITT
Part of operations ITT in 2010

32. Project timeline overview

33. Sentinels PDGS Procurement Sizing S1 PDGS Core ~18 M€ S2 PDGS Core
Including Best Practices
S2 PDGS Core
~17 M€
S3 PDGS Core
~20 M€
Values may be refined while preparing the SOW, targets will be indicated with the issue of the ITT
S1 Mission Planning
~600 k€
S1 is considered the most complex (~400 k€ for S2)
S1 Mission Performances tools
~1,5 M€
S2 and S3 figures will be consolidated (IPF best practices between 1.5M € and 2.0M€, and Performances tools between 1M€ and 2M€)

34. Sentinels PDGS Invitations to Tender:
proposal requirements & selection
O. Leonard
RES-POE

35. http://emits.esa.int -> Open Invitations to Tender Cordis:
1. Publication of ITT
Emits:
-> Open Invitations to Tender
Cordis:
English only
Closing Date
Requests for clarifications/extensions

36. 2. Content of ITT Package
Cover letter
Statement of Work
Draft Contract
Special Conditions of Tender

37. Content of ITT Package 1. Cover letter Eligible bidders:
-ESA + EU FP7 (
-no industrial policy requirements / Geo-return clause
-requested expertise of bidding consortium
-exclusions in case of conflict of interest (if any)
Overall max. budget
Responsible Contracts Officer
Closing date and place of submission.
-at least 6 weeks left for submission of bids
-Possibility of request for extension (request must be made at least 2 weeks before closing date)
Number and type of copies required and where to address (ESA)

38. 2. Technical Documentation (Appendix 1 to ITT) Statement of Work
Content of ITT Package
2. Technical Documentation (Appendix 1 to ITT)
Statement of Work
Formal statement of the work required by ESA (evaluation techn. Crit)
Tasks descriptions, outputs
Annexes: Applicable and reference documents
Technical requirements
Technical specifications to be observed for performance of work (mandatory)

39. 3. Draft Contract (Appendix 2 to ITT)
Content of ITT Package
3. Draft Contract (Appendix 2 to ITT)
Content
ESA GCC applicable, specific conditions in the contract
Applicable documents
Price type and payment scheme
Place and date of delivery, Agency furnished Items, penalties, acceptance and rejection
IPR: all Operational Software – IPR assigned to ESA (see Part II. (Option A)ESA GCC, esp. Clauses 39 to 44)
Best practices (Annex)
Specific provisions stemming from ESA/EC Delegation Agreement
Publicity related to Contract (specific EU mentions and logo)
Availability of deliverables to EC or EC-designated entities
IPR
waiver liability towards EC

40. 4. Special Conditions of Tender (Appendix 3 to ITT)
Content of ITT Package
4. Special Conditions of Tender (Appendix 3 to ITT)
Purpose
Conditions specific to the procurement and related to submission of offers (not a contractual doc)
Ensure the offers contain enough information as to its quality, that offers are structured in a similar way, to identify easily non-compliances and allow fair assessment
Content
Structure of the tender (cover letter, technical-management-financial/administrative/contractual proposal)
Technical requirements
Management requirements (incl. best practices organisation)
Financial proposal
Contractual proposal: acceptance (incl. best practices)/reservation, IPR conditions
Annexes: checklist, evaluation criteria

41. 3. Evaluation process
ESA evaluation procedure applicable
Evaluation criteria
TEB (incl. EC)
Contract negotiation
Award of contract
Regret letter and debriefing

42. Sentinel-1 PDGS
Procurement Overview

43. Sentinel-1 Mission Overview
Main Mission Objectives & Characteristics
Sentinel-1 is a polar-orbiting SAR satellite constellation for operational SAR applications, primarily focussed on those offered by the GMES Fast Track Services (Land Monitoring Core Service, Ocean Monitoring Core Service, and Emergency Respond Core Service).
The Sentinel-1 mission will ensure the C-band data continuity to satisfy requirements defined in the Sentinel-1 Mission Requirements Document, current requirements from GMES Core Services and Downstream services, the projection of these requirements for the GSC operations phase from 2012 onwards and the expected National and scientific requirements.
Orbit: Near Polar Sun-Synchronous
Repeat cycle: 12 days. 175 orbits
Payload: C-Band Synthetic Aperture Radar (central frequency GHz)
Constellation: Sentinel-1 system will be composed of two satellites, Sentinel-1 A & B
Duty cycle: up to 25 min in high rate mode and the rest of the orbit in WV mode
Schedule (Sentinel-1A): Launch Q4 2011
360
100 Km
200 Km 1 2 3 4 5
80 Km

44. S-1 PDGS Key Design & Operations Drivers
Key drivers for S-1 PDGS design and operations from GMES Services needs
Large down-linked data volume (~ 60 GB/orbit, ~ 900 GB/day from 1 satellite)
Priority downlink from memory to support NRT, direct downlink at Core Ground Stations and downlink support to local stations
Highly pre-defined systematic observation plan
Systematic data driven processing, dissemination and archiving of all acquired data. NRT data provided in less than 1 h from station acquisition, the rest within h
Rush on-request planning, processing and dissemination supported for emergency and security.
Access to systematic data flow on subscription basis (no ordering required)
On-line access to past mission data
Stable and traceable product quality meeting the quality requirements and accurate product calibration
Capability to support Sentinel-1A & Sentinel-1B

45. Sentinel-1 PDGS Implementation Contracts
Generic services
at PDGS centres
Sentinels Common Elements/Facilities
S-1 Core PDGS
S-1 PDGS specific
Future Procurements
(2010)
Service provided as part of a future “Stations & Centres” procurement activity
X-Band
Acquisition Service
Long-term data
archiving service
Centres Commissioning
Operations
Definition and integration of the S-1 end-to-end PDGS
Including:
Development of new elements
Update/configuration of suitable existing elements
Integration of elements or services provided by ESA
Best Practices specification and organization
Overall PDGS AIV activities
Support to GS OSV
Sentinel-1 PDGS System maintenance till the end of the Commissioning Phase
Future Procurements
Demodulator & FEP
Precise Orbit
Determination
Generic ESA
multi-mission services
User services
Auxiliary data
handling service
Service provided as part of customisation of Multi-mission services
S-1 Specific Elements
On-going separate procurements
S-1 IPF

46. Sentinels Common Elements/Facilities multi-mission services
Sentinel-1 PDGS Implementation Contracts
Info Day Scope
Scope of this presentation
Generic services
at PDGS centres
Sentinels Common Elements/Facilities
S-1 Core PDGS
S-1 PDGS specific
X-Band
Acquisition Service
Definition and integration of the S-1 end-to-end PDGS
Including:
Development of new elements
Update/configuration of suitable existing elements
Integration of elements or services provided by ESA
Best Practices specification and organization
Overall PDGS AIV activities
Support to GS OSV
Sentinel-1 PDGS System maintenance till the end of the Commissioning Phase
Future Procurements
Long-term data
archiving service
Demodulator & FEP
Centres Commissioning
Operations
Generic ESA
multi-mission services
Precise Orbit
Determination
User services
Auxiliary data
handling service
Service provided as part of customisation of Multi-mission services
S-1 Specific Elements
S-1 IPF

47. Sentinel-1 Core PDGS Contract Scope (1/2)
S-1 Core PDGS
S-1 elements/facilities
implementation
PDGS System
end-to-end Design
S-1 PDGS Reference Facility
S-1 PDGS System maintenance
Includes specific S-1 development as well as elements operationally proven with other missions and reusable with update/configuration for S-1
Set-up of a reference PDGS facility for testing and maintenance
Maintenance activities till end Commissioning Phase
The required task covers the full PDGS end-to-end design, including interfaces with external elements to the PDGS core contract, e.g.:
Interfaces with collaborative entities
S-1 PDGS AIV
Integration and Testing activities leading to PDGS Acceptance.
Includes integration of S-1 elements procured separately & configuration of any provided CFI element
Procured through Best Practices within the Core PDGS
Instrument
Performance Monitoring,
QC and cal/val
Mission Planning
Mission Planning
Instrument
Performance Monitoring,
QC and cal/val
L0 generation
Data Assembly
Processing control …
Support to GS OSV
Support to the integration of the PDGS in the GS and OSV tests leading to GS Acceptance

48. Sentinel-1 Core PDGS Contract Scope (2/2)
S-1 PDGS AIV activities within the Core PDGS contract will include:
Set-up of a reference PDGS facility to support end-to-end PDGS tests before deployment and maintenance activities
Integration of elements procured inside the S-1 Core PDGS Contract
Integration with ESA non-specific services (e.g. user services)
Integration of S-1 specific elements procured separately and provided as ESA CFI (e.g. S-1 L1/2 processor)
Integration of Sentinel common elements provided separately and provided as ESA CFI (e.g. FEP)
Organisation and deployment of the PDGS system (including ESA provided CFIs) in the ESA-procured centres and Integration with generic services at these centres (Acquisition, Long-term data archiving)
-> PDGS sites (X-Band Ground Receiving Stations and Assembly, Processing and Archiving Centres) will be procured as part of a separate ITT

49. Sentinel-1 Core PDGS Procurement Approach (1/2)
S-1 Core PDGS Procurement will be based on the following system technical baseline documentation:
S-1 PDGS System Requirements Document
Provides the system level requirements to be fulfilled by the S-1 PDGS as a whole and the parent requirements for the PDGS elements. Does not pre-define a system architecture.
S-1 PDGS Operations Concept Document
Describes the PDGS end-to-end system operations concept to be satisfied.
In addition, the following complementary system technical information will be provided:
S-1 PDGS Master ICD
Defines the main internal and external interfaces of the S-1 PDGS
S-1 PDGS System Technical Budget
Describes a set of observation scenarios for system sizing purposes
S-1 PDGS System Test Concept
Provides the guidelines PDGS testing

50. Sentinel-1 Core PDGS Procurement Approach (2/2)
For the ESA CFI elements (e.g. S-1 IPF or common PDGS elements), the integration will be based on ESA provided interface specifications
For some specific S-1 PDGS elements to be implemented as part of the Core PDGS, ESA will provide preliminary version of technical requirements to be refined as part of this contract
e.g. for mission planning, Instrument performance monitoring, S-1 products Quality verification and calibration
For the generic services at PDGS centres - procured independently by ESA-, the integration will be based on the interfaces specified within the present contract

51. Sentinel-2 and Sentinel-3 PDGS
Procurement Overview

52. Superspectral imaging mission
Sentinel-2 Mission Overview
Applications:
Generic land cover maps
risk mapping and fast images for disaster relief
Damage evaluation
Burned areas mapping
Pushbroom filter based multi spectral imager with 13 spectral bands (VNIR & SWIR)
Spatial resolution: 10, 20 and 60 m
Field of view: 290 km
1180 kg spacecraft mass
10-day repeat cycle (5 day revisit with two satellites)
Sun synchronous orbit at 786 km mean altitude
7 years design life time, consumables for 12 years
Sentinel-2:
Superspectral imaging mission

53. Sentinel-2 PDGS Drivers
Key drivers for S-2 PDGS design and operations from GMES Services needs
Large down-linked data volume (~55 GB/orbit, 800 GB /day from 1 satellite)
Priority downlink from memory for supporting Near-Real Time, downlink at Core Ground Stations and possibility of live image downlink to local stations
Uninterrupted land imaging following seasonal sun elevation between 83 and -56
Systematic data driven processing, dissemination and archiving of all acquired data. NRT data provided in less than 1 h from station acquisition, the rest within h
Access to systematic data flow on subscription basis (no ordering required)
Systematic production of continental-scale cloud-free coverages (i.e. image collections) available online and via subscriptions
On-line access to past mission data
Stable and traceable product quality meeting the quality requirements and accurate product calibration
Capability to support Sentinel-2 A and Sentinel-2 B

54. ocean & global land mission
Sentinel-3 Mission Overview (1/2)
Applications:
Sea/land colour data and surface temperature
sea surface and land ice topography
coastal zones, inland water and sea ice topography
vegetation products
1198 kg spacecraft mass
Sun synchronous orbit at km mean altitude over geoid
27 days repeat cycle
7 years design life time, consumables for 12 years
Sentinel-3:
ocean & global land mission

55. Sentinel-3 Mission Overview (2/2)
Instruments:
Ocean and Land Colour Instrument (OLCI) with 5 cameras, 8 bands (only VIS) for open ocean (low res), 15 bands (only VIS) for coastal zones (high res). Spatial sampling: SSP
Sea and Land Surface Temperature (SLST) with 9 spectral bands, 0.5 (VIS, SWIR) to 1 km res (MWIR, TIR). Swath: 180rpm dual view scan, nadir & backwards
RA package SRAL Ku-C altimeter (LRM and SAR measurement modes), MWR, POD (with Laser Retro Reflector, GNSS and DORIS)

56. Sentinel-3 PDGS Drivers
Key drivers for S-3 PDGS design and operations from GMES Services needs
Large down-linked data volume (~20 GB/orbit, 300 GB /day from 1 satellite)
Systematic Near-Real Time L-1/2 processing and on-line availability of 100% of the data
Archiving and precision reprocessing of 100% of the data to level 1/2
Possibility of direct image downlink to local stations (from imagers)
Continuous payload operations (except OLCI operating only in daylight)
Access to systematic data flow on subscription basis (no ordering required)
Direct access to past mission data
Stable and traceable product quality meeting the quality requirements and accurate product calibration
Capability to support Sentinel-3 A and Sentinel-3 B

57. Sentinel-2 PDGS Implementation Contracts (1/2)
Generic services
at PDGS centres
Sentinels Common Elements/Facilities
S-2 Core PDGS
S-2 PDGS specific
Future Procurements
(2010)
Service provided as part of a future “Stations & Centres” procurement activity
Future Procurements
Generic ESA
multi-mission services
Service provided as part of customisation of Multi-mission services
S-2 specific elements procurement

58. Sentinel-2 PDGS Implementation Contracts (2/2)
Info Day Scope
Scope of this presentation
Generic services
at PDGS centres
Sentinels Common Elements/Facilities
S-2 Core PDGS
Definition and integration of the S-2 end-to-end PDGS
X-Band
Acquisition Service
Future Procurements
Long-term data
Archiving
Including:
Development of new elements
Update/configuration of suitable existing elements
Integration of elements or services provided by ESA
Best Practices specification and organization
Overall PDGS AIV activities
Support to GS OSV
Sentinel-2 PDGS System maintenance till the end of the Commissioning Phase
Demodulator & FEP
Centres Commissioning
Operations
Generic ESA
multi-mission services
Precise Orbit
Determination
User services
Auxiliary data
handling service
S-2 specific elements procurement
S-2 Mission Planning

59. Sentinel-3 PDGS Implementation Contracts
Info Day Scope
Generic services
at PDGS centres
Scope of this presentation
Sentinels Common Elements/Facilities
S-3 Core PDGS
X-Band
Acquisition Service
Definition and integration of the S-3 end-to-end PDGS
Future Procurements
Long-term data
Archiving (land)
Centres Commissioning
Operations
Including:
Development of new elements
Update/configuration of suitable existing elements
Integration of elements or services provided by ESA
Best Practices specification and organization
Overall PDGS AIV activities
Support to GS OSV
Sentinel-3 PDGS System maintenance till the end of the Commissioning Phase
Demodulator & FEP
Generic ESA
multi-mission services
Precise Orbit
Determination
User services
Auxiliary data
handling service
PDGS EUMETSAT
Elements
S-3 specific elements procurement
S-3 Mission Planning (EUMETSAT)
Marine User Access
Marine processing and
long term
Archive centre

60. Sentinel-2 Core PDGS Contract Scope
S-2 Core PDGS
Specific S-2 elements/facilities
Development
S-2 PDGS Reference Facility
S-2 PDGS System maintenance
PDGS System
end-to-end Design
Set-up of a reference PDGS facility for testing and maintenance
Maintenance activities till end Commissioning Phase
The required task covers the full PDGS end-to-end design, including interfaces with external elements to the PDGS core contract, e.g.:
Interfaces with collaborative entities
Includes specific S-2 development as well as elements operationally proven with other missions and reusable with update/configuration for S-2
S-2 PDGS AIV
Integration and Testing activities leading to PDGS Acceptance.
Includes integration of S-2 elements procured separately & configuration of any provided CFI element
Instrument
Processing Facility
Instrument
Performance Monitoring,
QC and cal/val
L0 generation
Data Assembly
Support to GS OSV
Processing control
Support to the integration of the PDGS in the GS and OSV tests leading to GS Acceptance …
Procured through Best Practices within the Core PDGS

61. Sentinel-3 Core PDGS Contract Scope
S-3 Core PDGS
Specific S-3 elements/facilities
Development
S-3 PDGS Reference Facility
S-3 PDGS System maintenance
PDGS System
end-to-end Design
Set-up of a reference PDGS facility for testing and maintenance. Including deployment of reference facilities at EUMETSAT
Maintenance activities till end Commissioning Phase
The required task covers the full PDGS end-to-end design, including interfaces with external elements to the PDGS core contract, e.g.:
Interfaces with collaborative entities
Includes specific S-3 development as well as elements operationally proven with other missions and reusable with update/configuration for S-3
S-3 PDGS AIV
Instrument
Processing Facility
(Land & Marine)
Integration and Testing activities leading to PDGS Acceptance.
Includes integration of S-3 elements procured separately & configuration of any provided CFI element
Instrument
Performance Monitoring,
QC and cal/val
L0 generation
Data Assembly
Support to GS OSV
Processing control
Support to the integration of the PDGS in the GS and OSV tests leading to GS Acceptance …
Procured through Best Practices within the Core PDGS

62. Sentinel-2 / Sentinel-3 Core PDGS Scope
S-2/3 Core PDGS Procurement will be based on the following system technical baseline documentation (jointly prepared with EUMETSAT for S-3):
S-2/3 PDGS System Requirements Document
Provides the system level requirements to be fulfilled by the S-2/3 PDGS as a whole and the parent requirements for the PDGS elements. Does not pre-define a system architecture.
S-2/3 PDGS Operations Concept Document
Describes the S-2/3 PDGS end-to-end system operations concept to be satisfied.
In addition, the following complementary system technical information will be provided:
S-2/3 PDGS Master ICD
Defines the main internal and external interfaces of the S-2/3 PDGS
S-2/3 PDGS System Technical Budget
Describes a set of observation scenarios for system sizing purposes
S-2/3 PDGS System Test Concept
Provides the guidelines PDGS testing

63. Satellite and FOS Interfaces Documents
Sentinel-2 / Sentinel-3 ESA CFIs
Satellite and FOS Interfaces Documents
Detailed processing model and reference test data
Sample satellite Test Data
S2 Decompression Software & all related documentation

64. Sentinels PDGS
Demodulator and
Front End Processor

65. Technical Assessment and Market Survey
The technical feasibility assessment has shown that a common procurement is feasible across Sentinels:
RF level – commonality confirmed.
Data level (commonality based on standards, e.g., CCSDS)
Downlink Channel Management – Commonality issue found.
Sentinel 3 only: inter-channel downstream dependency (implies extra development and more stringent ground performances) – Function allocation still TBC.
Other differences are mainly at configuration level.
The market survey indicates the presence of some equipment closed to Sentinel needs (not extensive development phase expected).

66. The Scope of the Procurement Main Sub-elements
MODEM  Demodulator and Modulator
FEP  Front End Processor

67. Activities and Driving Principles
One Procurement Action
The bidder(s) need to provide a proposal compatible with the two sub-elements subject to delivery.
The bidder(s) need to cover the following activities:
Design and Development activities
AIV (Factory and on-Site) activities
Management activities involving the sub-element(s) subject to its bidding.
Driving Principles:
The new development should be kept at minimum in favour of evolving existing units already available on the market
Multi-mission programmable demodulators (based on standards) and front end processing systems.

68. Core Stations Approach Local Stations Approach
Quotation and Delivery
Core Stations Approach
The bidder(s) need to deliver and support the integration for:
Initial number of units necessary for reference and validation platforms.
Units for the Sentinel 1, 2 and 3 Core Stations (locations and number TBD).
The bidder(s) need to provide a quotation showing the benefits of scale:
Purchase up to 4 recurrent units; purchase from 4 to 8 recurrent units; purchase from 8 to 12 recurrent units, etc.
The bidder(s) need to provide the quotation also for maintenance
Local Stations Approach
The bidder(s) need to provide a quotation showing the benefits of recurrent units (including maintenance):
Available to Local Stations at recurrent price
As an option, ESA could procure the units and provide them to the Local Stations

69. Precise Orbit Determination
Sentinel PDGS
Precise Orbit Determination

70. GMES POD Service Objective
The GMES Precise Orbit Determination (POD) Service shall provide orbit products to the Sentinels 1, 2 and 3 missions for supporting the PDGS operations

71. NRT and OFL Orbit Products Computation
GMES POD Service Functions
The GMES POD Service shall ensure the following functions for each of the Sentinel missions:
NRT and OFL Orbit Products Computation
GNSS In-orbit Sensor Performance Monitoring
Long Term Monitoring & Validation of PDGS Orbits
Orbit Reprocessing

72. GMES POD System - Context
Two entities:
NRT POD
OFL POD
S-3 Specific

73. GMES POD Interfaces

74. GMES POD Project Objectives
The GMES POD Service shall :
Be compliant and tailored to the mission specific objectives, error budgets, expected performance and availability requirements
Rely on common and shared infrastructure and expertise
Rely on specific expertise for OFL orbit processing (e.g. Altimetry)
Be scalable for the integration of additional EO Sentinel Satellites
Support to Integration and Verification Phases

75. GMES POD - Procurement Approach
One single contract based for:
Service Level Agreement based on an available POD Service Capability
Delivery of NRT POD for integration in Sentinel PDGS
=> No DPM provided as ESA CFI
=> Only Sat to ground ICD
Incremental Delivery and Service Provision approach for each Sentinel mission

76. Operational Instrument Processors and Cal/Val and Quality tools
Sentinels PDGS
S-2, S-3
Operational Instrument Processors
and Cal/Val and Quality tools

77. Procurement objectives
Procurement will cover :
Processors for Sentinel-2 and Sentinel-3 products IPF – Instrument Processing Facility
Quality Tools for Sentinel-2 and Sentinel-3
Cal/Val tools, QC tools
Sentinel-1 processor covered by previous contract
(already initiated)

78. Sentinel-3: Optical Sensors Processing
L1 IPF
OLCI
L1 IPF SLSTR
Level 1
IPFs
L1C IPF SLSTR/OLCI
L1B
L1B
L1C
Combined
OLCI/SLSTR
L2 IPF
OLCI
L2 IPF SLSTR
Level 2
IPFs
L2 IPF SLSTR/OLCI
SST
Land surface
product
Water
products
Land
products
Surface Directional
Reflectances

79. Sentinel-3 : Altimetry Processing

80. Sentinel-2: Instrument Processor Facility
IPF L1
L1B
DEM
CFI
L1C orthorectified product
IPF L2
Atmospheric correction.

81. IPF: Engineering approach
Input from ESA
Baseline for IPF development
Detailed Processing Model L1 / L2
Input Output Data Description
Test data set
Generic Interface Specification
ECSS standard
NB: DPM / IODD / TDS provided by “Prototype contracts”
Deliveries
Software – code, exe
Documentation (Product specification, Test reports, user manual, Software release note, Product Specification, ICD…etc)
Support, maintenance, expertise, commissioning phase support
Operational
development
ESLs
Algorithms Engineering
Algorithms Specification
S2 / S3 prototypes
S2 / S3
IPF
ESA
Algorithm definition and prototyping contracts
Operational implementation contracts
Algorithm Specifications
and prototyping
Software
Processors ICDs

82. Procurement Scope IPF main input Level 0
Aux files (including orbit files)
Orders files
IPF main output
Level 1 products
Level 2 products
Basic Level 3 products
Browse / catalogue
Cal/Val and quality tools
Calibration and validations functions
Initial analysis and monitoring functions
Reporting functions

83. Procurement Organization
Procurement will be done through “Best Practices”
2 ITTs / within each core PDGS contract
- IPF  software development
- Quality Tools  software development,
algorithm development and earth observation
products expertise
Incremental procurement according to mission schedule
Maintenance until end of commissioning phase
Support to commissioning phase, maintenance of reference chain

84. Sentinels PDGS
Mission Planning

85. On-board recording resource management (packet store management)
Procurement Scope
Instrument Planning
On-board recording resource management (packet store management)
Downlink Planning
Handling of multi-satellite constellation as single resource
Support to local Stations
Support to EDRS
X-Band conflict handling to be solved outside mission planning by operational agreements

86. FOS interface: customized from Earth Explorer missions interface
Mission Planning Interfaces
FOS interface: customized from Earth Explorer missions interface
Mission Management Interface for ingestion of systematic observation requirements from GMES Service Providers
User Service interfaces to be based on current multi-mission ICDs with possible customizations
Station Interface to be based on multi-mission station interface with possible customizations

87. Mission Planning: S-1
variable on-board compression make location of actual downlink difficult to predict ==> mission planning probabilistic packet store management algorithm requires capability of stations and assembly centres to handle non-nominal scenarios
MP was incorporated into the PDGS contract => "best practise" approach
Output: fully operational system integrated in PDGS and support to commissioning phase

88. Variable Compression Algorithm
Mission Planning System will need to rely on an external library that evaluates the expected compressed size of each data take
size evaluation has to be provided with a probabilistic approach (i.e. with 95% of probability the size will be smaller than ...)
library to be provided as part of PDGS development ==> expert knowledge required

89. separate MP system will be procured as separate competitive tender
Mission Planning: S-2
separate MP system will be procured as separate competitive tender
Output:
fully operational system
support to integrate the system into the PDGS
support to commissioning phase

90. systematic planning, no conflict management due to user requests
Mission Planning: S-3
systematic planning, no conflict management due to user requests
procurement as separate tender by Eumetsat

91. S-1 On-board data compression algorithm description provided as CFI
Procurement CFI
ESA will provide mission CFIs for orbit propagation and for the ingestion of FOS orbit files
S-1 On-board data compression algorithm description provided as CFI

92. Sentinels PDGS: Best Practices for the Selection of Subcontractors
Luc Govaert
RES-POE

93. 1. Best Practices
Code of Best Practices, Definition and Governing Principles/Purpose of Best Practices
ESA has a Code of Best Practices, approved by the Industrial Policy Committee as industrial policy ruling.
Definition of Best Practices: Basically, a mechanism through which a Prime selects subcontractors for a given element within an ESA programme prior or subsequent to his own selection by ESA.
The principle and purpose of Best Practices is to achieve fairness of competition at all levels (Prime and subcontractors) and to guarantee fair, impartial and equal treatment of non-primes.

94. PDGS Best Practices: Origin and Extent
Statement in the ESA Procurement Plan approved by IPC: “The ESA Best Practices may be followed for some elements within the PDGS Core Procurement.”
The bulk of the Sentinels PDGS procurement will be placed further to ESA ITTs, only a limited part through Best Practices (up to 40%).
ESA will decide which elements of a given procurement will be awarded through Best Practices.

95. Implementation and Guarantees to ensure Fairness of Competition (I)
3. Best Practices
Implementation and Guarantees to ensure Fairness of Competition (I)
ESA shall have full visibility on the ITT preparation by the Prime (ITT package to be approved by the Agency), on the evaluation and on the selection (Prime’s recommendation will be submitted to ESA; ESA will either endorse the recommendation or request to submit the recommendation for decision to a Joint ESA/Industry Procurement Board), with the right to audit the full process.
The Prime shall have to state his acceptance of the Best Practices principles and of his obligation to organize Best Practices.

96. Implementation and Guarantees to ensure Fairness of Competition (II)
3. Best Practices
Implementation and Guarantees to ensure Fairness of Competition (II)
To guarantee impartiality, the Prime shall be required to accept and cooperate with the Agency’s Industrial Ombudsman.
The Prime shall have to implement a SIMPLIFIED Best Practices selection procedure drafted by ESA and based on the principles of fair and open competition (procedure will be included in the ESA ITT package).
IITT and ITT to be approved by the Agency and issued on EMITS (EXTERNAL ENTITIES) and CORDIS.

97. Implementation and Guarantees to ensure Fairness of Competition (III)
3. Best Practices
Implementation and Guarantees to ensure Fairness of Competition (III)
Conflict of interest: If the Prime and/or any subcontractor wish to bid for any element, the Prime/subcontractor shall be excluded from the evaluation of the proposals, this in the interest of impartiality and the Agency shall run the TEB.
Same applies in case of companies belonging to the same industrial and/or legal organisation, or affiliated companies, meaning any form of association giving a company a vested interest in the outcome of the evaluation. However, the Prime’s responsibility vis-à-vis selected subcontractor is left untouched.

98. Implementation and Guarantees to ensure Fairness of Competition (IV)
3. Best Practices
Implementation and Guarantees to ensure Fairness of Competition (IV)
ESA Staff may be involved in the Tender Evaluation Board set up by the Prime (one Technical Representative, ESA CO at his discretion). Notwithstanding this, the Agency at any moment reserves the right to initiate a parallel evaluation performed by its Staff in accordance with the ESA tender evaluation process.
Confidentiality of proposals submitted will have to be guaranteed by the Prime.
The SoW/technical requirements, to be written by the Prime and to be reviewed and approved by the Agency, shall not be ambiguous or company tailored.
The selection criteria shall be defined and made available to all potential bidders.

99. Schedule and way forward
Sentinels PDGS
Schedule and way forward

100. Sentinels PDGS Engineering life-cycle
The Payload Data Ground Segment undergoes a complete
ESA system engineering lifecycle
The following reviews are defined:
PDGS System requirements : Definition of the PDGS core procurement technical baseline
PDGS Preliminary Design (supported by the core PDGS team): the review is performed at facility specification, architecture and interface level
PDGS Critical design review and Qualification reviews (supported by the core PDGS team): These reviews characterise the reference system integration and centres deployment statuses
PDGS Acceptance review (supported by the core PDGS team): The review characterise the integration with the GMES Service Projects shall be verified

101. Sentinels PDGS Engineering life-cycle 2/2
The Core PDGS prime supports the Ground Segment milestones (PDR, CDR, AR) where coherencies between Satellite, FOS and PDGS systems, interfaces and operations are reviewed
Highlight on PDGS System Requirements review
-> Technical Documentation package based on:
System requirement documents
Operation concept document
System technical budget
Updated technical documentation will be publicly released following the review recommendation updates:
S-1: Released on EMITS end of May (board is 20 May…)
S-2, S-3: Released together with intended ITT announcement
Technical Baseline may be consolidated for the ITT without pre-announcement

102. PDGS Core Indicative Schedule
S-1 PDGS SRR: On-going: Panel Collocation foreseen for 7th May 2009
S-1 PDGS core ITT: end July 2009
S-2 PDGS SRR: Nov. 2009
S-2 PDGS core ITT: Feb. 2010
S-3 PDGS SRR: July 2009
S-3 PDGS core ITT: Oct. 2009

103. PDGS Facilities Indicative Schedule
Demodulator & FEP: Sept. 2009
Precise Orbit Determination: ITT Dec. 2009
S-1 Mission Planning : PDGS core KO + 3 months
S-1 Instrument Performance Monitoring, QC and cal/val elements: PDGS core KO + 3 months
S-2 Mission Planning : ITT March 2010
S-2 Processors and performances elements : PDGS core KO + 3 months
S-3 Mission Planning : March 2010
S-3 Processors and performances elements : PDGS core KO + 3 months

104. Questions and Answers
Questions can be ed to
…until May 18st 2009
Answers to questions will be published on EMITS News, towards end of May

105. Summary

106. Information Day Highlights
3 independent ITTs for 3 sentinel PDGS development contracts
Including best practices for few sub-systems (mission planning, processors and mission performances elements)
… ITTs for common elements (FEP, POD)
Drivers for ‘operational’ systems delivery
Re-use of proven technology & interfaces
Sentinels are part of the GSC overall and share the data flows and interface
Systematic generation of all data into lvl1b and retrieval on-line is a challenging technical driver to cope with the high data volume
ITT organisation
ITTs Issued and open both via ESA and EC contract systems
Response to, Selection and Mgt according to normal ESA procedures
Process is ready to start