Impact Visualization Interface Developer (Consultant) At Asian Disaster Preparedness Center

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A. Purpose and Objectives:

ADPC is an autonomous international organization established for scientific, educational, developmental, and humanitarian purposes with a vision of safer communities and sustainable development through disaster risk reduction and climate resilience in Asia and the Pacific. Established in 1986 as a technical capacity building center, ADPC has grown and expanded its role to be for scientific, educational, developmental and humanitarian purposes. ADPC employs a wide range of professional expertise typically required for Disaster Risk Reduction (DRR) and Climate Resilience (CR) in an effective manner.

ADPC develops and implements cross-sectoral projects/programs on the strategic themes of risk governance, urban resilience, climate resilience, health risk management, preparedness for response and resilient recovery. Our strategic themes are complemented and underpinned by the cross-cutting themes of gender and diversity, regional and transboundary cooperation as well as poverty and livelihoods.

Through its work, ADPC supports the implementation of the Sendai Framework for Disaster Risk Reduction 2015–2030, the Sustainable Development Goals (SDGs), the New Urban Agenda, the United Nations Framework Convention on Climate Change, the agenda defined at the World Humanitarian Summit in 2016, and other relevant international frameworks.

For details, please refer to ADPC website at http://www.adpc.net/.

B. Department Introduction

The Risk Analytics and Climate Services Department is a multi-disciplinary team of experts committed to providing innovative, science-based solutions for actions to adapt to climate change and mitigate the impacts of disasters. The innovations include uses of geospatial technology, satellite data, numerical models, cloud computing, and artificial intelligence for assessing vulnerability and risk, generating climate data, developing early warning systems, forecasting possible climate impact, and informing anticipatory actions. These lead to risk-informed developments in the sectors such as agriculture, transportation, water resources, energy, communications and health.

The department also applies advanced geoinformatics and climate analytics to address water and food security issues by assessing water availability and water-use efficiency, groundwater monitoring, assessing drought risks, and optimizing agricultural productivity, hence ensuring sustainable water and food systems in vulnerable regions. The department promotes Nature-Based Solutions by leveraging ecosystem services such as wetland restoration, agroforestry, and green-gray infrastructure to reduce disaster risks and build climate resilience. Lastly, the department produces risk analytics and integrates them into urban plans and engineering designs of critical infrastructures, hence improving their resilience to disasters and climate change.

With a commitment to science-based approach, the department envisions empowering stakeholders to reduce risks, adapt to climate change, and build more resilient communities and ecosystems.

C. Statement of Intent

Asian Disaster Preparedness Center, in collaboration with International Union for Conservation of Nature and Natural Resources (IUCN), is implementing a six years project named “URBAN: Urban Resilience Building and Nature” in two provinces of Thailand (Chiang Rai and Surat Thani). The overall goal of the project is that the focal urban areas and wider landscapes in which they are embedded enjoy significantly enhanced social, economic and environmental resilience to climate change impacts through the wide scale adoption of nature-based solutions NbS. The project will make a significant contribution to climate change adaptation in up to 6 local administrative organizations in the selected provinces in Thailand.

As part of the project implementation, ADPC intends to hire a consultant on a lump-sum output-based contract to prepare flood hazard maps for select urban areas in the targeted provinces of Chiang Rai and Surat Thani considering future climate change impacts including increasing flood risks and sea-level rise where applicable.

D. Scope of Work

The scope of work covers the development of a comprehensive online geospatial Impact Visualization tool to support the visualization, interpretation, and analysis of multi‑hazard risk assessment data for Chiang Rai and Surat Thani provinces. The platform will serve government agencies, technical institutions, and decision-makers involved in disaster risk reduction, climate resilience planning, and emergency response.

The Impact Visualization Interface Developer will be responsible for designing, developing, integrating, and deploying a user‑friendly, high‑performance, and secure web‑based geospatial system that transforms complex hazard, exposure, and vulnerability datasets into actionable insights. The specific responsibilities and tasks are detailed in subsections below:

E. Expected Outputs:

The consultant will be responsible for delivering the following Outputs:

  1. System architecture and UI/UX design package
  2. Fully functional web‑based Impact Visualization Interface
  3. Integrated geospatial database and API services
  4. Analytical tools and dashboards
  5. Technical documentation and user manuals
  6. Training sessions for national stakeholders
  7. Final deployment and handover package

F. Responsibilities and Tasks:

The Consultant will be responsible for the following tasks and duties:

1 System Architecture & Design

  • Design a modular, scalable system architecture suitable for national‑level deployment.
  • Develop UI/UX wireframes, user flows, and interface prototypes aligned with stakeholder needs.
  • Define data structures, metadata standards, and geospatial data pipelines.
  • Ensure compatibility with existing national platforms, APIs, and data repositories.

2 Front-End Development

  • Build an intuitive, responsive, and accessible web interface using modern JavaScript frameworks (e.g., React, Vue, Angular).
  • Implement interactive geospatial visualization components.
  • Develop dashboards, charts, and analytical widgets for hazard, exposure, vulnerability, and risk layers.
  • Enable multi‑layer visualization, filtering, comparison, and temporal analysis.

3 Back-End Development

  • Develop secure APIs for data retrieval, processing, and visualization.
  • Implement geospatial data services using platforms such as GeoServer, MapServer
  • Set up databases (PostgreSQL/PostGIS or equivalent) for storing and managing geospatial and tabular datasets.
  • Ensure efficient data caching, tiling, and performance optimization for large datasets.

4 Data Integration & Processing

  • Integrate multi‑hazard risk assessment datasets for Chiang Rai and Surat Thani, including:
    • Hazard layers (flood, landslide, drought, etc.)
    • Exposure datasets (population, infrastructure, land use)
    • Vulnerability indicators
    • Composite risk indices and impact scenarios
  • Develop automated or semi‑automated data ingestion workflows.
  • Ensure metadata completeness, data quality, and adherence to national geospatial standards.

5 Analytical & Decision-Support Tools

  • Implement tools for:
    • Hazard intensity visualization
    • Exposure and vulnerability overlay analysis
    • Risk scoring and classification
    • Scenario comparison (baseline vs. extreme events)
    • Administrative boundary‑based summaries (province, district, sub‑district)
  • Provide export functions for maps, reports, and datasets.

6 User Management & Security

  • Implement secure authentication and role‑based access control.
  • Ensure compliance with national cybersecurity and data protection requirements.

7 Testing, Validation & Optimization

  • Conduct unit, integration, performance, and security testing.
  • Facilitate user acceptance testing (UAT) with national stakeholders.
  • Optimize system performance for low‑bandwidth environments.
  • Ensure cross‑browser and cross‑device compatibility.

8 Documentation & Capacity Building

  • Prepare comprehensive technical documentation, including:
    • System architecture
    • API documentation
    • Data workflows
    • User manuals and admin guides
  • Provide handover of source code, configuration files, and deployment scripts.

9 Deployment & Maintenance

  • Deploy the system on a secure hosting environment (cloud or on‑premise).
  • Provide post‑deployment support, bug fixes, and performance tuning.

G. Working Principles: Consultant will report to the Program Lead, Climate Services, Risk Analytics and Climate Services Department and will work closely with and other specialists from Risk Analytics and Climate Services Department. Regular meetings with designated ADPC personnel (at least once a month) reviewing progress, identifying obstacles and designing the way forward is required.

H. Qualifications:

Consultant shall have the following qualifications

  • Master’s degree or higher in Spatial Science, Geospatial Science, Remote Sensing, Marine/Environmental Science, GIS, Earth Observation, or a closely related field.
  • Minimum 2–3 years of experience in geospatial data analysis, satellite data processing, or geospatial application development.
  • Strong proficiency in JavaScript, TypeScript, HTML, CSS, and experience with web frameworks for interactive mapping.
  • Proficiency in Python and R for geospatial data processing, visualization, and analysis.
  • Experience working with SQL based databases (e.g., SQL Server, Oracle) and geospatial data management.
  • Ability to design visually appealing, user friendly interfaces and data visualization tools.
  • Demonstrated experience in developing and integrating web APIs, Satellite data visualization and analysis, or environmental geospatial research, Multi‑hazard or environmental data interpretation.
  • Proven experience in developing geospatial web applications, including front end and back-end components.
  • Excellent writing, presentation, and analytical skills.

I. Duty Station: Home-based

J. Duration: The contract will be for a period of 6 months between 1st June – 30th November, 2026 and will be deliverable-based.

K. Itinerary: The contract is expected to commence on June 1, 2026 and conclude on November 30, 2026 with a total input of 4 months over a 6-month period. This consultancy service doesn’t require any travel and will be home-based.

L. Condition of payment:

Paid to the Consultant as the final payment upon submission of all deliverables as mentioned in above in Section E. Expected Outputs.

Payment will be made as per the payment schedule given below. All payments will be credited to the bank account provided by the consultant. The consultant shall not be entitled for any other payments in relation to this assignment. The consultant shall request for payments and shall bear the bank charges incurred during payments.

Deliverable

Deliverable 1 – Inception & System Design Package

Upon submission and acceptance of:

  • Inception Report outlining methodology, work plan, and development timeline
    • System architecture design
      • UI/UX wireframes and interface prototypes
      • Data structure and metadata framework
      • Technical specifications for front‑end, back‑end, and hosting environment

Percentage of Maximum amount: 20%

Deliverable 2 – Fully Functional Beta Version of the Impact Visualization Interface

Upon submission and acceptance of:

  • Operational beta version of the online geospatial platform
    • Integrated hazard, exposure, vulnerability, and risk datasets for Chiang Rai and Surat Thani
      • Functional analytical tools, dashboards, and geospatial visualization components
      • API services, database integration, and back‑end workflows
      • User testing session and documented feedback log

Percentage of Maximum amount: 50%

Deliverable 3 – Final System Deployment, Documentation

Upon submission and acceptance of:

  • Final deployed version of the Impact Visualization Interface
    • Complete technical documentation (system architecture, API documentation, data workflows)
      • User manuals and administrator guides
      • Handover of source code, configuration files, and deployment scripts
      • Resolution of all issues identified during final testing.

Percentage of Maximum amount: 30%

M. Selection Method

The candidate will be selected in accordance with ADPC’s recruitment process and policy guidelines.

How to apply

Interested Candidates can submit the completed ADPC application form, (downloadable from www.adpc.net), resume, copy of degrees/certificate(s) together with a cover letter, to: procurement@adpc.net

The email subject should clearly indicate the position being applied for, for example:

[Impact Visualization Interface Developer, Name of Candidate]

Female candidates are especially encouraged to apply.

ADPC encourage diversity in its workplace and support an inclusive work environment.