Targeting and Scaling Out Agricultural Water Management Interventions in the Volta River Basin...

CPWF Volta V1: Targeting and scaling out

Volta Basin Science and Reflection Meeting

Ouagadougou3-6 July 2012

Andes • Ganges • Limpopo • Mekong • Nile • Volta

Outline

- V1 research question and expected outputs, timelines and linkages- Research findings : synthesis of Stakeholder Consultations- Research findings (draft) : do we know how much AWMi already exist?- Research findings (draft): Cases of AWMi in Ghana and Burkina Faso with PGIS- Young Professionals poster presentations with draft results(LUNCH)- Research findings (draft): Outscaling tool developments using Bayes model, database and interface- Findings (draft): Innovation and learning- Next steps of V1

Project aim, status and linkages in VBDC

Objective of V1 is to develop and evidence a knowledge-based tool to assess and map the likelihood that a given intervention will be successful in given locations, at the basin scale. Secondly , evaluate potential environmental impacts of outscaling at basin-scale.

“The project seeks to answer the question of what AWMi can work where and why”

V1 Expected Results & Contribution to Volta BDC

Outscaling tool with improved capacity to target areas of particular interventions to contribute to poverty alleviation and (resilient ) development pathways in a collaborative way with boundary partners

An iterative research process in dialogue with stakeholders and potential end usersSeveral human capacity elements incl. MSc and professional training

Research activity: Develop protocolSynthesise data CPWF phase 1

Consultation activity: Protocol, identify cases

External actors: local agents in ag. development,( public, NGO)Researchers in ag-water

Research activity:Assess casesDevelop model tool and databases

Research activity:Improve tool and databaseCharacterise CPWF L/V field sitesCharacterise potential outscaling locations

Consultation activity: Test prototype tool

12 m 24 m 36 m

External actors: Local/regional agents in ag. development, (public, NGO)Investors in ag. development

Consultation activity: Provide learning events in out-scaling toolDemonstrate/share /distribute research outputs

External actors: Local/regional/national, international agents in ag. water and rural development, public, NGOs, possibly private sectorInvestorsNational, international decision makers

LINKAGES with other VBDC projects and CPWF basins

Initial plan: Actual interactions:

- Cross-project partners

- V1 contributing to V2 review

- In-kind contribution of information - Ex-post domain analysis of sites

(outstanding)

- Topic Working Groups

- Initiative by Kizito, and contribution of resources

- Collaborations external to VBDC

V1 (& L1) Synthesis of initial stakeholder consultations

By V1 partners prepared by Annemarieke de Bruin

Result: No pattern in success or failure related to complexity of technology Type of technology Failure Successful ??

Rainfed Soil and water conservation/DRS/CES SA - BF

Planting pits BF-Zim

Trench technology SA SA Conservation agriculture SA SA

Bunding Gha Gha BF Contour

bunds/ridges/ploughing Zim Gha-Zim

Tied ridges Sa-Zim Sa-Gha-BF Cover crop Gha Tree planting SA- Gha-BF Bunding Gha Gha Mulching SA-Zim SA Zim Shallow groundwater Gha Shallow wells Gha BF Waste water re-use Zim Zim Treadle pump SA BF Water pumps (small scale

irrigation) Gha Gha

Sprinkler irrigation SA-Zim Zim Zim Drip irrigation SA-Zim SA-Zim BF-Zim

Punched bag Zim Micro irrigation Gha Supplemental irrigation (rice) BF

Roof Rainwater Harvesting Zim

Ferro-cement tanks SA Earth dams SA - Gha BF Underground level dams SA

Full irrigation Small dams/reservoirs SA BF BF-Zim

Large scale irrigation SA

Result: Best practises (‘due diligence’) was stated as having significant impact on success/failure of AWMi

South Africa (n=11) Zimbabwe (n=13) Ghana (n=16) Burkina Faso (n=6)

Factor category

Success %

Failure % Success %

Failure %

Natural 9 9 27 31 24 10 25 16

Human 26 13 25 28 18 21 14 8

Social 30 6 7 3 3 6 11 24

Physical 4 17 11 14 18 25 11 28

Financial 4 17 9 6 9 15 7 12

Other 26 38 20 19 27 23 32 12

Other= ‘BEST PRACTISE IN IMPLEMENTATION’• Community owns initiative

• Early engagement with stakeholders

• Continuous assistance/backstopping, Appropriate implementation

• Direct benefit, Clear demand

• Clear objective

• Appropriate design of technology

Definition of a success• Direct benefit of well-

• Substantial practise beyond >2 years intervention to end-user

Do we know how much land already under AWMi?

Prepared by Joanne Perry, Jennie Barron based on review by Douxchamps et al,

Learning from the past – following V2 review Douxchamps et al ,V1 Presentation from 3rd IFWF 16 Nov 2011

Farmers already manage rain and have AWMi, but to what extent and to what impact?

• We have identified 3 major streams of technology adoption and adaptationSWC, small reservoirs, irrigation with small electric/diesel pumps

What impact have these changes?

• Look at high level impacts addressing desired benefits (yield food security, income), undesired externalities on environment (water resources ,flows appropriation, ES loss)

Can we measure these benefits and impacts at various scales? Can we estimate extent of AWMi in use?

Learning from the past: map with sites of documented ground assessment of SWC adoption

Learning from the past: example of dataAWMi development per region Cereal yield (t/ha) per region

No conclusions yetMore data needed

Verification? (we don’t agree…..)

Participatory GIS Assessment - Burkina Faso and Ghana

presented by Mariam Balima (INERA) and Mathias Fosu (CSIR-SARI)

Purpose of PGIS• To validate information from

consultation meeting• To validate the Bayesian

Methodology• Google maps of selected

towns in Burkina and Ghana

• High Level stakeholder consultation and mapping

• Community level consultation & mapping

- identification of prominent features, landmarks & techs.

Methodology cont..Community level mapping

- Take GPS coordinates of features, landmarks & techs not captured on Google map - Georeferencing of features, landmarks and technologies.

Technologies identified

GHANA BURKINA FASO

Treadle Pumps + +Shallow wells + +Dugouts + +Small reservoirs + +Stone and Earth bunds + +Water pumps + +Tree /Field crop integration - +

Résultats préliminaires (Ghana)

1. Petits réservoirs• Largement rependus et communément utilisé• Disponible en saison sèche• Réduction de l’exode rurale Problème: maintenance des infrastructures

2. Puits de bas-fond utilisable en saison pluvieuse mais tarissent pendant la saison sèche3. Pompage nécessite une source d’eau pérenne

4. Boulis, spécifiquement pour l’abreuvement des animaux Problèmes:• Faiblement construits• N’est pas adapte pour l’agriculture de contre-saison• Généralement de petite taille et par conséquent l’eau tarit

rapidement• Perte de l’eau par infiltration• Ensablement des ouvrages5. Digues en terre et en pierreCommunément utilisé en zones dotées en pierres avec une

pente > 20%

Observations généralesAu delà des pompages, toutes les techniques identifiées sont

utilisées par les hommes et aussi bien les femme

Résultats préliminaires (Ghana) (cont)

• Croissance de l’adoption et de l’adaptation des technologies par les bénéficiaires

• Accès des ouvrages à toutes les couches sociales

• Amélioration du niveau de vie des communautés (sécurité alimentaire, éducation, santé)

• Diversification des revenus (réduction de la pauvreté)

• Participation à la gestion durable des infrastructures

• Renforcement des capacités des producteurs en terme d’organisation et d’engagement

• Contribution à la réduction de l’exode rurale

• Amélioration des facteurs de productions

Résultats préliminaires (Burkina Faso)

• Meilleure disponibilité de l’eau pour des usages multiples en saison sèche: irrigation et l’abreuvement des animaux

• Meilleure rétention d’eau pour l’agriculture pluviale

Similarities and différence

Simalarité – même technologie utilisée au Ghana et au Burkina

Faso– Les problèmes des technologies sont identiques

(exemple la gestion et l’utilisation des petits réservoirs sont identiques)

Différence- 7 technologies (Burkina) et 6 (Ghana)-

Conclusion• Les informations obtenues lors des PGIS confirment

celles des ateliers de consultations• Les petits barrages sont plus importants dans la

gestion de l’eau• Toutes les technologies sont accessibles de façon

égale aux hommes et aux femmes à l’exception des motopompes

• Les technologies ont contribué à la réduction de l’exode rurale

• Les technologies ont contribué à l’augmentation des productions et a l’amelioration du niveau de vie des beneficiaires

Limites

• difficultés d’obtention de données quantitatives

• Longueur du temps d’enquête (4 à 5 heures)• Indisponibilité d’image récente et de cartes

topographiques aux échelles adaptées (1/50 000 eme)

Perspectives

• Utilisation des données PGIS pour valider le modèle bayésien

Merci pour votre attention

V1 Young professionals (poster session)

Targeting and scaling out tool Eric Kemp Benedict with contributions from Annemariekede Bruin, Frank Annor,

Douglas Wang

Background

V1 Project

• Aim: To produce a framework and web-based “decision support”, (or targeting and scaling out tool) that will assist in identifying sites where the introduction of AWM interventions for smallholder farming systems are likely to be successful.

• Related projects– Extrapolation domains– Bayesian poverty mapping– AgWater Solutions suitability maps– Nile Basin outscaling tool

• The novelty of this approach– Including social and institutional factors– Eliciting information from experts on the ground– Open-source infrastructure

CPWF History (1):Extrapolation Domains

CPWF History (2):Bayesian Poverty Mapping

Outside of CPWF:AgWater Solutions

• Suitability map for small reservoirs

• Data– Biophysical– Economic

Current CPWF Work:Nile BDC N3

Landscape-level analysis

Combining expert insights and dataIncluding social and institutional data

• Similar goals• Similar inputs• Perhaps less flexible (?)• Outscaling is important, and the world

needs more than one method

The Targeting Problem

• We want to out-scale agricultural water management (AWM) technologies

• We want to pick sites where the chances of success are relatively good

• A good way to decide is through rapid assessment in the field at prospective sites

• But where to do the rapid assessments?

The Pre-targeting Problem• Decide where conditions are promising

enough that it is worth investing in a rapid field assessment

• Only use existing and easily accessible data that is available over a large part of the basin

• Other considerations:– Make it affordable– Build on accumulated experience and knowledge

Conceptual Model• There are factors that contribute to the

success or failure of AWM technologies– Biophysical– Social and institutional– Technological– Implementation-specific

• The factors usually cannot be observed directly, but there is indirect evidence that that they are present or absent

Realities• The needed data are incomplete and

imperfect• No model can capture all the complexities of

agricultural communities and their environments

• There will be continued learning and therefore a need to update the model

Specifics

Implem.

Structure of Bayesian ModelEvidence

Factors of success

“Pseudo-factors”*

* Reduce the number of model parameters

Indicator of success

Implementation factors

Implementation score

Experts Provided Guidance on Sources of Evidence

Factor Indicator SourceAccessibilité à l’eau Nombre de retenues d’eau DR Agric, INERA, IGB, AMB, VAREK, PAGIRE

Nombre de points d’eau DR Agric, INERA, IGB, AMB, VAREK, PAGIREExistance de cours d’eau DR Agric, INERA, IGB, AMB, VAREK, PAGIREEffectif du cheptel local DR-elevage, INSD

Encadrement des producteurs Nombre de structures d’encadrement Etat, ONG, OPNombre de personnel d’encadrement Etat, ONG, OPNombre de centres de formation Etat, ONG, OP, DR-MEBATaux d’alphabetisation MEBATypes/natures de formations OP, ONG, Etat

Disponibilité de main d’oeuvre Effectif de population INSD, CommuneDensité de population INSD, CommuneRepartition par classe d’age et par sexe INSD, CommuneMigration de population INSD, Communes

proximité d’un marché de consommationDistance aux centres urbainsPopulation locale village, communeEtats des routes DG-routePouvoir d’achat des populations Plan, MEFCircuit de commercialisation Chambre de commerce, ONG, OPTypes d’elevage DR-elevage, ONG, OPEffectif du cheptel DR-elevage, ONG, OPNombre de fosses fumieres ONG, OPProduction cerealiere (quantité) DR-agric

Factor Indicator Source of data

Availability of low lands for rice cultivation in northern region

Rice valleys GIDA, MoFA, CSIR-SARI

Provision of technology Trained farmers are available in all beneficiary communities, Contour bunds constructed are still being used.

CSIR-SARI & MoFA

Provision of credit (Agro Inputs)

Seeds ( ie. TOX 3107) are still available.

CSIR-SARI,

Marketing arrangements made

Buyers such as NASI and NASIA Rice company

Culture and interest of the people in rice cultivation

…but we still need to collect most of the data

( |{ })jP s e

evidencefactors ofsuccess

successindicator

pseudo-factors

Core model

Additional model elements

For the Mathematically Inclined

Probability of success given observations (evidence)

( |{ }) ( |{ }) ({ }|{ })i

j i i jf

P s e P s f P f e

successindicator

pseudo-factors

Core model

Probability of success given

factors of success

Probability of factor of success given evidence

1{ }{ }

( |{ }) ( |{ }) ( | ) ({ } |{ })i i

j i i i i jif f

P s e A s f P f f P f e

successindicator

pseudo-factors

Core model

A “noisy-and” «et-bruyant» relationship:Factor of success 1 and factor of

success 2 and factor of success 3 … must be present, but we don’t have

perfect information

Status

• General model design • Expert consultation

– Measures and factors of success – Sources of evidence/data layers – Detailed model structure

• Tool development– Components (see next slide)– User feedback and input

Fully implemented

Partially implemented

Not implemented (yet)

These should have been further along. Otherwise, we are reasonably on track.

Summary Status of Tool Components

Fully implemented

Partially implemented

Not implemented (yet)

Implementation factors in the project’s control

Color (hue): estimated likelihood of successIntensity (value): degree of confidence

Selecting items on the “checklist” changes likelihood of success

Conclusions and Ways Forward• Potential scientific outputs

– Demonstrating that social and institutional variables can be meaningfully included in a targeting tool

– Conceptual framework of evidence factors of success indicator of success as a way of framing the targeting problem

– Novel elicitation techniques• Potential practical outputs

– Better-informed decisions of where in a basin to direct resources– Clarity on data needs for improved decision-making– An open-source tool with generically useful source code for spatial Bayesian

models• Next steps during this project

– Build Bayesian models using expert elicitation– Improve on tool interface through consultation– Continue developing data base– Validation with PGIS and case studies

What Would We Like to Do?• We are aiming at a tool that could have a life of its

own after this project. Some possibilities to help make this happen:– Release the code in an open-source repository (GitHub,

SourceForge)– Seek funding for further data collection, elaboration,

dissemination, and hosting– Identify a potential long-term home for the web-based

tool and code

Innovation and learning

Project TeamSEIINERASARIKNUSTUniv Ouaga

Researchers

CP researchersVBDC researchersWider researcher community

V5 Project

Regional Government

CAADP (NEPAD)VBA..

Communities

NGOs(DVT agents)

National/Provincial

GovernmentAgric Dept.Extension servicesPlanning

Project sphere of influence Project sphere of concern

Boundary PartnersBeneficiaries

Other stakeholders

Project Team

Unions/ Associations

ACTIONSVision, mission,

inputs, activities, outputs

IMPACTSchanges in conditions, well-being

OUTCOMES changes in

knowledge, attitudes, skills,

actions)

NGO networks

Partner engagements in 1st project year (2011):

Mostly national level researchers and various gvt

3% 3%GVT national

Devt agents/implementors (local Gvt, Ngos)

farmers

other local stakeholders / private formal-informal

regional research

intl research

regional policy

international policyBurkina FasoGhana

9%3%3%

GVT national

Devt agents/implementors (local Gvt, Ngos)

farmers

other local stakeholders / private formal-informal

private parastatsal

regional research

intl research

regional policy

international policy

FOR THE V1

We have likely missed important stakeholders in consultations (private sector actors), and we have not yet tried to correct for these potential limitations, and we recognise the challenges

‘Adaptive research’ can be rewarding, but also time-consuming and we underestimated the time required to fully engage in this as team lead and as team partners

What have we learned about process?

NEXT STEPS AND PRIORITIES

What V1 will do

FIRST PRIORITY:

• Learning events in Ghana and Burkina Faso (Aug-Sep 2012??)• Revise , and update and improve tool• Learning events In Ghana and Burkina Faso (Feb-Mar 2012?)

• NEXT PRIORITY• Synthesise PGIS across cases and sites : writeshop?• Complement with AWMi Rainfed case in BF?• Carry out ex-post domain analysis for VBDC projects• Finalise review on extent of AWMi in adoption over time• Model potential hydrological impacts at basin scale• Contribute to VBDC cross-project on story lines and scenario• Develop documentations and outreach products

What we would like to do :

‘Best practise of AWMi’ needs to be verified more: what does it mean ? Who is doing it ? Costs and impacts?

Develop a framework for evidence factors of success indicator of success

Meaningful spatial information layers of social and institutional factors: review being done for Limpopo L1 also to benefit V1(Improve the tool accordingly)

Find a permanent ‘home’ for tool and associated data Compare findings of tool application across L1 and V1

Test tool fro v2, V3, V4 AWMi

THANK YOU!

MERCI!

Targeting and Scaling Out Agricultural Water Management Interventions in the Volta River Basin...

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