GIS

Objective

The Centre for Geographic Information Systems (GIS) serves as a hub for the development, application, and dissemination of geographic information science and technology. Its main objectives are to:

  • Promote the use of geographic data and tools for better decision-making across various sectors.
  • Develop advanced methods for spatial data collection, analysis, and visualization.
  • Support interdisciplinary research that leverages geographic data to solve real-world problems in areas like urban planning, environmental management, and public health.
  • Facilitate the integration of GIS technology into policy-making and governance to improve resource management and planning.

 

Roles

The Centre for GIS plays several important roles that contribute to its mission of advancing the use of spatial data in research, industry, and public services:

  • Research and Development: It engages in cutting-edge research on spatial data analysis, mapping technologies, remote sensing, and the development of geographic information systems to improve the collection, analysis, and representation of geographic data.
  • Capacity Building and Training: The centre provides education and training programs to enhance the skills of students, professionals, and policymakers in using GIS tools. Through workshops, courses, and certification programs, it fosters a skilled workforce proficient in geospatial technologies.
  • Consultation and Collaboration: The centre collaborates with government agencies, private organizations, and academic institutions to apply GIS in solving complex spatial problems. It provides expertise on geospatial data management, spatial planning, and data-driven decision-making for sectors like transportation, agriculture, and environmental conservation.
  • Data Repository and Management: The centre often acts as a repository of geographic data, managing large datasets that include maps, satellite imagery, and spatial databases. It ensures the availability, accessibility, and accuracy of geographic data for research, industry, and public use.

 

Research Areas

The Centre for GIS undertakes diverse research projects that span several key areas of geographic science and technology:

  • Spatial Data Analysis and Modeling: Research in this area focuses on the development of advanced techniques for analyzing spatial data, such as spatial statistics, machine learning for geospatial data, and predictive modeling to understand geographic patterns and processes.
  • Urban and Regional Planning: GIS plays a vital role in urban development by providing insights into land use patterns, infrastructure planning, and sustainable city development. The center researches ways to integrate GIS with urban modeling to improve zoning, transportation, and smart city initiatives.
  • Environmental and Ecosystem Management: Researchers at the centre work on using geospatial technologies to monitor ecosystems, biodiversity, and environmental sustainability. They investigate how GIS can be applied to conservation efforts, natural resource management, and disaster risk reduction.
  • Public Health and Epidemiology: The centre applies GIS in tracking disease outbreaks, monitoring public health issues, and planning healthcare infrastructure. Spatial data analysis helps in identifying the geographical distribution of diseases and resources, which is crucial for effective health policy and intervention.

 

Innovations

The Centre for GIS has driven several innovations in geospatial science and its applications:

  • Geospatial Data Integration: A key innovation is the integration of various data sources—such as satellite imagery, sensors, social media data, and mobile data—into GIS platforms. This integration allows for more accurate, dynamic, and real-time spatial analysis.
  • 3D GIS and Virtual Reality (VR): The centre has developed advanced 3D GIS systems that allow for the visualization and simulation of geographic spaces in three dimensions. This is particularly useful for urban planning, disaster simulation, and environmental modeling. Virtual reality technologies are also being incorporated to create immersive environments for better spatial understanding.
  • AI and Machine Learning in GIS: Recent advancements include the use of artificial intelligence (AI) and machine learning algorithms to automate processes like land cover classification, pattern recognition, and predictive analytics. These innovations enhance the accuracy of spatial data analysis and forecasting.
  • Web GIS and Mobile GIS Applications: The development of web-based GIS platforms and mobile applications allows users to access, visualize, and interact with spatial data from anywhere. This innovation has democratized the use of GIS technology, making it accessible to a broader audience, including non-experts and the general public.

 

Future Directions

The future of the Centre for GIS is closely tied to advancements in technology, data science, and global challenges. Some key future directions include:

  • Big Data and Geospatial Analytics: With the increasing availability of big data from sources like IoT devices, satellites, and mobile apps, the centre is poised to advance its research in big data analytics. It will focus on harnessing large, complex datasets to gain insights into global challenges like climate change, urbanization, and resource depletion.
  • Climate Change and Sustainability: In response to global environmental challenges, the centre will focus on applying GIS for climate change mitigation and adaptation strategies. Research in renewable energy planning, carbon footprint mapping, and environmental impact assessments will become more prominent.
  • Smart Cities and Urban Innovation: The role of GIS in the development of smart cities is expected to grow. Future research will focus on integrating GIS with IoT and AI technologies to optimize urban services like traffic management, energy distribution, and waste management, contributing to the sustainability and efficiency of cities.
  • Geospatial AI: The integration of AI into GIS workflows will continue to evolve. The centre will explore more sophisticated AI models that can predict spatial phenomena, automate mapping processes, and assist in real-time decision-making in sectors like agriculture, logistics, and emergency management.
  • Collaborative and Open GIS Platforms: In the future, GIS technology will become more collaborative and open. The centre will focus on developing open-source GIS tools and platforms that allow data sharing and collaboration across borders. This will foster a more inclusive approach to solving global issues by enabling participation from researchers, governments, and the public.

 

The Centre for Geographic Information Systems plays a vital role in advancing geospatial science and technology, with a strong focus on interdisciplinary research, practical applications, and innovation. As GIS technology continues to evolve, the centre’s work will contribute to solving complex spatial challenges across fields like urban planning, environmental management, and public health. The future of GIS will be marked by its integration with emerging technologies like AI, big data, and smart city infrastructure, positioning the Centre for GIS as a leader in shaping the future of geospatial solutions.

Coordinator CASS

Prof. Dr. Prafulla Parlewar
Professor of Urban Planning
B.Arch., M.Plan. (UP), Ph.D. (Japan)

www.prafullaparlewar.com

(prafulla.parlewar@spa.ac.in)

Junior System Analyst

Jagdish Kumar
B.Sc.(Computer Sc.), M.Sc (Maths)
(jagdeesh[dot]kumar[at]spa[dot]ac[dot]in)
abhi
Abhishek Jain
B.Tech
(abhispa[at]spa[dot]ac[dot]in)