
mapbox-geospatial-operations
β 68by mapbox Β· part of mapbox/mapbox-agent-skills
Expert guidance on choosing the right geospatial tool based on problem type, accuracy requirements, and performance needs
Expert guidance on choosing the right geospatial tool based on problem type, accuracy requirements, and performance needs
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by mapbox
Expert guidance on choosing the right geospatial tool based on problem type, accuracy requirements, and performance needs
npx skills add https://github.com/mapbox/mapbox-agent-skills --skill mapbox-geospatial-operations
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Mapbox Geospatial Operations Skill
Expert guidance for AI assistants on choosing the right geospatial tools from the Mapbox MCP Server. Focuses on selecting tools based on what the problem requires - geometric calculations vs routing, straight-line vs road network, and accuracy needs.
Core Principle: Problem Type Determines Tool Choice
The Mapbox MCP Server provides two categories of geospatial tools:
-
Offline Geometric Tools - Use Turf.js for pure geometric/spatial calculations
-
Routing & Navigation APIs - Use Mapbox APIs when you need real-world routing, traffic, or travel times
The key question: What does the problem actually require?
Decision Framework
Problem Characteristic Tool Category Why Straight-line distance (as the crow flies) Offline geometric Accurate for geometric distance Road/path distance (as the crow drives) Routing API Only routing APIs know road networks Travel time Routing API Requires routing with speed/traffic data Point containment (is X inside Y?) Offline geometric Pure geometric operation Geographic shapes (buffers, centroids, areas) Offline geometric Mathematical/geometric operations Traffic-aware routing Routing API Requires real-time traffic data Route optimization (best order to visit) Routing API Complex routing algorithm High-frequency checks (e.g., real-time geofencing) Offline geometric Instant response, no latency
Decision Matrices by Use Case
Distance Calculations
User asks: "How far is X from Y?"
What They Actually Mean Tool Choice Why
Straight-line distance (as the crow flies) distance_tool Accurate for geometric distance, instant
Driving distance (as the crow drives) directions_tool Only routing knows actual road distance
Walking/cycling distance (as the crow walks/bikes) directions_tool Need specific path network
Travel time directions_tool or matrix_tool Requires routing with speed data
Distance with current traffic directions_tool (driving-traffic) Need real-time traffic consideration
Example: "What's the distance between these 5 warehouses?"
-
As the crow flies β
distance_tool(10 calculations, instant) -
As the crow drives β
matrix_tool(5Γ5 matrix, one API call, returns actual route distances)
Key insight: Use the tool that matches what "distance" means in context. Always clarify: crow flies or crow drives?
Proximity and Containment
User asks: "Which points are near/inside this area?"
Query Type Tool Choice Why
"Within X meters radius" distance_tool + filter Simple geometric radius
"Within X minutes drive" isochrone_tool β point_in_polygon_tool Need routing for travel-time zone, then geometric containment
"Inside this polygon" point_in_polygon_tool Pure geometric containment test
"Reachable by car in 30 min" isochrone_tool Requires routing + traffic
"Nearest to this point" distance_tool (geometric) or matrix_tool (routed) Depends on definition of "nearest"
Example: "Are these 200 addresses in our 30-minute delivery zone?"
-
Create zone β
isochrone_tool(routing API - need travel time) -
Check addresses β
point_in_polygon_tool(geometric - 200 instant checks)
Key insight: Routing for creating travel-time zones, geometric for containment checks
Routing and Navigation
User asks: "What's the best route?"
Scenario Tool Choice Why
A to B directions directions_tool Turn-by-turn routing
Optimal order for multiple stops optimization_tool Solves traveling salesman problem
Clean GPS trace map_matching_tool Snaps to road network
Just need bearing/compass direction bearing_tool Simple geometric calculation
Route with traffic directions_tool (driving-traffic) Real-time traffic awareness
Fixed-order waypoints directions_tool with waypoints Routing through specific points
Example: "Navigate from hotel to airport"
-
Need turn-by-turn β
directions_tool -
Just need to know "it's northeast" β
bearing_tool
Key insight: Routing tools for actual navigation, geometric tools for directional info
Area and Shape Operations
User asks: "Create a zone around this location"
Requirement Tool Choice Why
Simple circular buffer buffer_tool Geometric circle/radius
Travel-time zone isochrone_tool Based on routing network
Calculate area size area_tool Geometric calculation
Simplify complex boundary simplify_tool Geometric simplification
Find center of shape centroid_tool Geometric centroid
Example: "Show 5km coverage around each store"
-
5km radius β
buffer_tool(geometric circles) -
"What customers can reach in 15 min?" β
isochrone_tool(routing-based)
Key insight: Geometric tools for distance-based zones, routing tools for time-based zones
Performance and Scale Considerations
When Volume Affects Tool Choice
Small operations (< 100 calculations):
-
Geometric tools: Instant, iterate freely
-
Routing APIs: Fast enough for most uses
Medium operations (100-1,000 calculations):
-
Geometric tools: Still fast, no concerns
-
Routing APIs: Consider batch operations (matrix_tool)
Large operations (> 1,000 calculations):
-
Geometric tools: May need optimization but still fast
-
Routing APIs: Definitely use batch tools (matrix_tool handles up to 25Γ25)
Key insight: Volume rarely affects geometric tool choice, but routing APIs have batch tools for efficiency
Real-Time vs Batch
Use Case Approach Tool Choice
Real-time geofencing (every second) Geometric checks point_in_polygon_tool (instant)
Route planning (one-time) Full routing directions_tool or optimization_tool
Periodic proximity checks Geometric distance distance_tool
Live traffic routing Routing with traffic directions_tool (driving-traffic)
Architecture note for high-frequency geofencing: If the application calls containment checks at very high rates (e.g., 50 vehicles every 2 seconds = 25 checks/second), calling MCP tools over the network adds agent-reasoning overhead that makes it impractical. In those cases, recommend using Turf.js directly in-process (turf.booleanPointInPolygon) for the hot path, and reserve MCP tools for peripheral tasks like zone definition (isochrone_tool), rerouting (directions_tool), or visualization (static_map_image_tool).
Common Scenarios and Optimal Approaches
Scenario 1: Store Locator
User: "Find the closest store and show 5km coverage"
Optimal approach:
-
Search stores β
category_search_tool(returns distances automatically) -
Create coverage zone β
buffer_tool(5km geometric circle) -
Visualize β
static_map_image_tool
Why: Search already gives distances; geometric buffer for simple radius
Scenario 2: Delivery Route Optimization
User: "Optimize delivery to 8 addresses / stops"
Optimal approach:
-
Geocode addresses (if needed) β Use
search_and_geocode_toolto convert any street addresses to coordinates. Even when coordinates are already provided, mention this as an optional pre-step β real-world delivery lists often contain a mix of addresses and coordinates. -
Optimize route β
optimization_tool(TSP solver β reorders stops to minimize total drive time)
Why optimization_tool and NOT these alternatives:
-
directions_toolonly routes A β B (or through fixed-order waypoints). It does NOT reorder stops β if you pass 8 stops, it routes them in the order given, which is almost never optimal. -
matrix_toolgives travel times between all pairs of stops (8Γ8 = 64 values), but it does NOT compute the optimal ordering. You'd need to solve TSP yourself on top of the matrix βoptimization_tooldoes this for you in one call.
Always mention search_and_geocode_tool as a useful companion for geocoding delivery addresses before optimization.
Scenario 3: Service Area Validation
User: "Which of these 200 addresses can we deliver to in 30 minutes?"
Optimal approach:
-
Create delivery zone β
isochrone_tool(30-minute driving) -
Check each address β
point_in_polygon_tool(200 geometric checks)
Why: Routing for accurate travel-time zone, geometric for fast containment checks
Scenario 4: GPS Trace Analysis
User: "How long was this bike ride?"
Optimal approach:
-
Clean GPS trace β
map_matching_tool(snap to bike paths) -
Get distance β Use API response or calculate with
distance_tool
Why: Need road/path matching; distance calculation either way works
Scenario 5: Coverage Analysis
User: "What's our total service area?"
Optimal approach:
-
Create buffers around each location β
buffer_tool -
Calculate total area β
area_tool -
Or, if time-based β
isochrone_toolfor each location
Why: Geometric for distance-based coverage, routing for time-based
Anti-Patterns: Using the Wrong Tool Type
β Don't: Use geometric tools for routing questions
// WRONG: User asks "how long to drive there?"
distance_tool({ from: A, to: B });
// Returns 10km as the crow flies, but actual drive is 15km
// CORRECT: Need routing for driving distance
directions_tool({
coordinates: [
{ longitude: A[0], latitude: A[1] },
{ longitude: B[0], latitude: B[1] }
],
routing_profile: 'mapbox/driving'
});
// Returns actual road distance and drive time as the crow drives
Why wrong: As the crow flies β as the crow drives
β Don't: Use routing APIs for geometric operations
// WRONG: Check if point is in polygon
// (Can't do this with routing APIs)
// CORRECT: Pure geometric operation
point_in_polygon_tool({ point: location, polygon: boundary });
Why wrong: Routing APIs don't do geometric containment
β Don't: Confuse "near" with "reachable"
// User asks: "What's reachable in 20 minutes?"
// WRONG: 20-minute distance at average speed
distance_tool + calculate 20min * avg_speed
// CORRECT: Actual routing with road network
isochrone_tool({
coordinates: {longitude: startLng, latitude: startLat},
contours_minutes: [20],
profile: "mapbox/driving"
})
Why wrong: Roads aren't straight lines; traffic varies
β Don't: Use routing when bearing is sufficient
// User asks: "Which direction is the airport?"
// OVERCOMPLICATED: Full routing
directions_tool({
coordinates: [
{ longitude: hotel[0], latitude: hotel[1] },
{ longitude: airport[0], latitude: airport[1] }
]
});
// BETTER: Just need bearing
bearing_tool({ from: hotel, to: airport });
// Returns: "Northeast (45Β°)"
Why better: Simpler, instant, answers the actual question
Hybrid Approaches: Combining Tool Types
Some problems benefit from using both geometric and routing tools:
Pattern 1: Routing + Geometric Filter
1. directions_tool β Get route geometry
2. buffer_tool β Create corridor around route
3. category_search_tool β Find POIs in corridor
4. point_in_polygon_tool β Filter to those actually along route
Use case: "Find gas stations along my route"
Pattern 2: Routing + Distance Calculation
1. category_search_tool β Find 10 nearby locations
2. distance_tool β Calculate straight-line distances (geometric)
3. For top 3, use directions_tool β Get actual driving time
Use case: Quickly narrow down, then get precise routing for finalists
Pattern 3: Isochrone + Containment
1. isochrone_tool β Create travel-time zone (routing)
2. point_in_polygon_tool β Check hundreds of addresses (geometric)
Use case: "Which customers are in our delivery zone?"
Decision Algorithm
When user asks a geospatial question:
1. Does it require routing, roads, or travel times?
YES β Use routing API (directions, matrix, isochrone, optimization)
NO β Continue
2. Does it require traffic awareness?
YES β Use directions_tool or isochrone_tool with traffic profile
NO β Continue
3. Is it a geometric/spatial operation?
- Distance between points (straight-line) β distance_tool
- Point containment β point_in_polygon_tool
- Area calculation β area_tool
- Buffer/zone β buffer_tool
- Direction/bearing β bearing_tool
- Geometric center β centroid_tool
- Bounding box β bounding_box_tool
- Simplification β simplify_tool
4. Is it a search/discovery operation?
YES β Use search tools (search_and_geocode, category_search)
Key Decision Questions
Before choosing a tool, ask:
Does "distance" mean as the crow flies or as the crow drives?
-
As the crow flies (straight-line) β geometric tools
-
As the crow drives (road distance) β routing APIs
Does the user need travel time?
-
Yes β routing APIs (only they know speeds/traffic)
-
No β geometric tools may suffice
Is this about roads/paths or pure spatial relationships?
-
Roads/paths β routing APIs
-
Spatial relationships β geometric tools
Does this need to happen in real-time with low latency?
-
Yes + geometric problem β offline tools (instant)
-
Yes + routing problem β use routing APIs (still fast)
Is accuracy critical, or is approximation OK?
-
Critical + routing β routing APIs
-
Approximation OK β geometric tools may work
Terminology Guide
Understanding what users mean:
User Says Usually Means Tool Type "Distance" Context-dependent! Ask: crow flies or crow drives? Varies "How far" Often as the crow drives (road distance) Routing API "Nearby" Usually as the crow flies (straight-line radius) Geometric "Close" Could be either - clarify! Ask "Reachable" Travel-time based (crow drives with traffic) Routing API "Inside/contains" Geometric containment Geometric "Navigate/directions" Turn-by-turn routing Routing API "Bearing/direction" Compass direction (crow flies) Geometric
Quick Reference
Geometric Operations (Offline Tools)
-
distance_tool- Straight-line distance between two points -
bearing_tool- Compass direction from A to B -
midpoint_tool- Midpoint between two points -
point_in_polygon_tool- Is point inside polygon? -
area_tool- Calculate polygon area -
buffer_tool- Create circular buffer/zone -
centroid_tool- Geometric center of polygon -
bbox_tool- Min/max coordinates of geometry -
simplify_tool- Reduce geometry complexity
Routing & Navigation (APIs)
-
directions_tool- Turn-by-turn routing -
matrix_tool- Many-to-many travel times -
optimization_tool- Route optimization (TSP) -
isochrone_tool- Travel-time zones -
map_matching_tool- Snap GPS to roads
When to Use Each Category
Use Geometric Tools When:
-
Problem is spatial/mathematical (containment, area, bearing)
-
Straight-line distance is appropriate
-
Need instant results for real-time checks
-
Pure geometry (no roads/traffic involved)
Use Routing APIs When:
-
Need actual driving/walking/cycling distances
-
Need travel times
-
Need to consider road networks
-
Need traffic awareness
-
Need route optimization
-
Need turn-by-turn directions
Integration with Other Skills
Works with:
-
mapbox-search-patterns: Search for locations, then use geospatial operations
-
mapbox-web-performance-patterns: Optimize rendering of geometric calculations
-
mapbox-token-security: Ensure requests use properly scoped tokens
Resources
-
Turf.js Documentation (Powers geometric tools)
npx skills add https://github.com/mapbox/mapbox-agent-skills --skill mapbox-geospatial-operationsRun this in your project β your agent picks the skill up automatically.
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