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The Power of Spatial Analytics in Business Intelligence

Since the pandemic, a newfound appreciation for spatial data has emerged. With digital transformation, enterprises collected more data. Research by the Environmental Systems Research Institute indicates that about 80% of this data contains a spatial component, for example, customer location details paired with information on transactions and purchasing habits. Spatial data can be further augmented with added layers of demographic details, including age, income, race, and education.

For Further Reading:

Spatial Data Science: The Basics You Need to Know

Executive Q&A: The Future of Geospatial Data

3 Trends for Data Analytics in 2021: No-Coding Storytelling, Data Sharing, and 3D Visualization

The integration of spatial components with transactional data allows enterprises to uncover patterns and correlations that were previously obscured. Conventional data representation methods that were mostly two-dimensional are swiftly giving way to the integration of spatial data and advanced visualization technologies. This shift facilitates more accurate insights, especially when paired with the power and complexities of multidimensional data. Leveraging this, a new branch of businesses intelligence has emerged, known as spatial analytics.

Spatial analytics involves understanding data in relation to its geographical context. Humans inherently think visually and spatially, which is why spatial analytics brings an immediate boost to comprehension. Maps excel in representing spatial phenomena or relationships and facilitate the understanding of statistical measures for a given area or region. Using maps with layers of location, business, and demographic data, enterprises visualize, analyze, and comprehend how various elements interconnect within a specified geographic area. This approach is crucial for making informed decisions, especially when “where” matters.

Spatial Data Interpretation Techniques  

Several data analytics techniques that lend themselves to adding value to spatial data have emerged. They enhance data interpretation and contribute significantly to the depth of insights derived from geographic information. These techniques amplify the accuracy of analysis and provide a more intuitive and interactive approach to understanding complex spatial relationships. Techniques include:

Geographic search enables on-the-fly location lookup without explicit geographic coordinates. This feature automatically populates and updates dashboards and digital maps with data relevant to a particular location or area.

Clustering visualizes geographic density patterns, allowing users to identify groupings of high or low values in data. Highlighted concentrations or anomalies assist nuanced planning and resource allocation and are useful for strategic decisions.

Formatting and annotating utilize colors, lines, and shapes to transform complex data sets into visually intuitive narratives. This improves data interpretation and is particularly effective for dissecting customer behaviors or market trends and for communicating insights.

Layers offer a multidimensional approach, going beyond data points on maps to enrich the narrative. Visual mapping with data sets overlaid on background maps provides a comprehensive appreciation of spatial relationships, transforming analytics into an immersive experience.

Target highlighting is another technique that allows selective analysis of data points on any layer for closer examination and focused insights. For example, a retail store manager analyzing sales data can use target highlighting to focus on customers who frequently buy certain products, are high-spenders, or live within a certain distance from the store. Highlighting these data points on a map can assist in identifying trends or patterns that might not be obvious when looking at the entire data set.

Temporal analysis examines spatial data over time to identify trends, changes, and time-based patterns. It offers a dynamic perspective, crucial for understanding how spatial relationships evolve, which is extremely important for insights into time-dependent phenomena.

For example, temporal analysis can be used in agriculture to analyze trends and correlations between historical crop yield data alongside weather data collected over several seasons. Farmers can use this to predict future crop yields based on forecasted weather conditions.

Another use of temporal analysis is by health officials to track the spread of a contagious disease. By analyzing data over time regarding disease cases, including the location and date of infection, officials can discern where the disease is most prevalent and how it is spreading.

Sentiment analysis in a spatial context probes into sentiments or opinions associated with specific geographic locations. Adding a qualitative layer to spatial data, this analysis provides insights into public perception and sentiment variations across different regions.

Network analysis and graph theory is applied to spatial data to examine relationships and connections between spatial entities. It allows us to build a web of connections between locations, like roads in a city. By analyzing these connections, we can understand how delays on one route can impact another or how to design efficient delivery routes. This empowers businesses and organizations to make data-driven decisions about everything from transportation planning to emergency response.

For example, consider a pizza delivery company using network analysis. They view city streets as a web, with pizzerias and customers as points. Analyzing this network helps them understand how traffic affects delivery routes, ensuring timely pizza arrivals.

Applications of Spatial Analytics Across Industries

Spatial analytics excels in transforming complex data into visually intuitive maps, charts, and graphs. Decision-makers can swiftly discern spatial patterns, identify outliers, and uncover correlations, underscoring the immense utility of spatial analytics within business intelligence. Considering its benefits, spatial analytics in the BI environment finds diverse applications across various industries, including:

For Further Reading:

Spatial Data Science: The Basics You Need to Know

Executive Q&A: The Future of Geospatial Data

3 Trends for Data Analytics in 2021: No-Coding Storytelling, Data Sharing, and 3D Visualization

Retail and marketing: Retailers analyze spatial data to determine optimal locations for new stores based on target market, area demographics, traffic patterns, existing store locations and competitor proximity. They also run location-based marketing campaigns to drive traffic to a newly opened local store, which can offer a huge improvement on return on ad spending over traditional advertising.

Supply chain and logistics: Businesses adjust warehouse locations and stock levels based on demand patterns in different regions using BI driven by spatial analytics. Moreover, it helps in optimizing delivery routes, reducing transportation costs, and improving overall efficiency.

Healthcare: Spatial analytics is crucial in tracking and understanding the spread of diseases, helping healthcare organizations allocate resources effectively.  For example, the Center for Disease Control’s PLACES project tracks local data for better health. It helps in understanding the health issues affecting the residents of local areas and in developing and implementing effective and targeted prevention activities. Combined with social determinants of health measures, it proves to be a valuable resource in planning public health, disease prevention, disease management, and monitoring spread.

Finance: Banks use spatial analytics to optimize the location and distribution of branches based on customer demographics and market demand. BI-powered spatial analytics also assists financial institutions in assessing risk by analyzing geographic factors such as economic conditions and regional stability.

Urban planning: City planners utilize spatial analytics to plan the development of infrastructure, considering factors such as traffic patterns, population density, and environmental impact. The technology also aids in determining appropriate land use and zoning regulations, thus ensuring sustainable urban development.

Agriculture: Farmers can implement precision agriculture and optimize crop yield by analyzing factors such as local soil quality, weather patterns, and topography. Data about crop health identifies areas that need special attention, improving farm produce management.

Energy: Spatial analytics aids in identifying optimal locations for renewable energy projects by considering factors such as sunlight exposure and wind patterns. Furthermore, utility companies also use spatial data to manage and optimize the distribution of energy across the grid efficiently.

Telecommunications: It is vital for telecom providers to map customer and call distribution for targeted coverage and service improvements. They use spatial analytics for network planning, ensuring better connectivity.

Environmental monitoring: Environmental scientists use spatial data to analyze the impact of climate change on specific regions while guiding conservation efforts. Environmentalists also monitor and manage natural resources, such as forests and bodies of water, using insights from spatial data to ensure sustainable development.

A Final Word

The future of BI driven with spatial analytics promises to be transformative. For example, real-time spatial analytics using Internet of Things (IoT) devices can offer instant insights into the movement of people, goods, and assets. This would be useful in emergency response systems, monitoring traffic patterns, and managing dynamic events such as public gatherings. Additionally, integration with advanced technologies such as artificial intelligence and machine learning, particularly in geospatial artificial intelligence, holds immense potential to enhance prediction accuracy.

About the Author

Anurag Sanghai is the principal solutions architect at Intellicus Technologies where he is responsible for consulting, architecting, and implementing state-of-the-art data analytics and business intelligence solutions for clients worldwide. He has experience in a variety of roles, including full stack engineer, data architect, engineering manager, and solutions architect. has been involved in the development of enterprise data warehouses, trending and forecasting systems, and information visualization initiatives. You can reach the author at via email or LinkedIn.


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