TataKelola dan KamSiber Kecerdasan Buatan v022.pdf
Principle of GIS and Application in Fisheries Management .pptx
1. Department of Fisheries science
B.F.Sc. 3rd year 5th Semester
Course: Coastal Zoon Management
Topic: Principle of GIS and Application in
Fisheries Management
Presented by: Subhadip Bar
2. Content
Introduction
Key Principle of GIS
Major Steps in GIS
Effectivity in Fisheries Management
Disadvantage of GIS in Fisheries Management
2
3. Introduction
3
Geographic Information Systems (GIS) play a crucial role in fisheries management by
providing tools and techniques to collect, analyse, and visualize spatial data related to fishery
resources. The principles of GIS involve the use of geographic data to better understand and
manage resources, and this can be applied effectively in fisheries management Here are some
specific applications of GIS in fisheries management:
Data Integration
Fishery Planning and Site Selection
Stock Assessment
Resource Assessment
Environmental Monitoring
Risk Assessment
Habitat Analysis
Effort and Catch Analysis
Ecosystem-Based Management
Research and Modelling
4. Key Principles
4
The key principles of Geographic Information Systems (GIS) into four important points, here they are:
Spatial Data Management: GIS is centred around the collection, storage, and efficient
management of spatial data, which includes information tied to geographic locations.
Spatial Analysis: GIS allows for the analysis of spatial relationships and patterns within data. Like
buffering, overlay, proximity analysis, and modelling.
5. Key Principles
5
Effective Visualization: GIS principles emphasize the importance of creating clear and
informative maps and visualizations. Proper cartographic design, data representation, and data
visualization.
Data Quality and Ethics: Ensuring the accuracy, completeness, and reliability of data is a core
GIS principle. Additionally, ethical considerations, including responsible data collection and use,
respecting privacy, and minimizing biases in spatial analysis, are vital aspects of GIS practice.
6. Major Steps
6
Researchers, technicians, analysts that
ask questions, choose, collect, analyze
the data, and interpret results.
Spatial Data (spatially located)
Vector Data
Raster Data
Image Data
Attribute Data (non-spatial)
The computer systems, technical equipment,
and networks where GIS operates.
Provides the functions needed to store,
analyze, and display geographic
information.
Guidelines, specs, procedure, and standards
for analyzing and applying GIS.
7. 7
1. Data Integration: GIS principles emphasize the integration of various types of spatial data
relevant to fisheries, including biological data (e.g., fish populations), environmental data
(e.g., oceanography, water quality), and socioeconomic data (e.g., fishing activities, market
demand). The integration of these datasets enables a comprehensive understanding of the
fisheries ecosystem.
2. Fishery Planning and Site Selection: GIS helps in identifying suitable locations for
fishing activities based on factors like water depth, temperature, salinity, and proximity to
fish habitats. It aids in optimizing fishing efforts while minimizing environmental impact.
Effectively in Fisheries Management
8. 8
3. Stock Assessment: GIS is used to integrate data on fish catch, environmental conditions, and
habitat characteristics. This enables fisheries managers to assess the health and abundance of
fish stocks, which is essential for setting sustainable catch limits.
4. Environmental Monitoring: GIS can be used to monitor environmental factors that affect
fisheries, such as water temperature, salinity, and ocean currents. This information helps in
understanding the impact of climate change and other environmental changes on fish habitats.
5. Habitat Analysis: GIS tools allow for the identification and analysis of critical fish habitats,
such as spawning areas, nurseries, and feeding grounds. This information is vital for
implementing conservation measures to protect these areas.
9. 9
6. Risk Assessment: GIS can be employed to identify areas prone to overfishing or habitat
destruction. By analysing historical data and modelling future scenarios, fisheries managers can
assess the risks associated with different management strategies.
7. Research and Modeling: GIS facilitates the development of models for predicting fish
populations, assessing the effects of management strategies, and conducting scenario analyses.
These models are crucial for evidence-based decision-making.
10. Disadvantages of GIS in Fisheries
Sector
10
While Geographic Information Systems (GIS) offer numerous advantages in the fisheries sector.
Like:
Cost and Resource Intensiveness: Implementing and maintaining a GIS system can be expensive.
It requires investment in hardware, software, training, and ongoing maintenance.
Technical Expertise Required: Effective use of GIS demands specialized knowledge and skills.
Fisheries professionals need training to operate GIS software, interpret spatial data, and perform
spatial analyses
11. 11
Ethical and Privacy Concerns: GIS applications can involve sensitive information, such as the
locations of fishing operations, which may need to be protected for security or privacy reasons.
Managing and protecting this information ethically can be challenging.
Limited Accessibility: In remote or less developed areas, access to GIS technology and expertise
may be limited. This can create disparities in the capacity to utilize GIS for fisheries management.