Installation

Install with CLI Recommended 
gh skills-hub install azure-smart-city-iot-solution-builder

Don't have the extension? Run gh extension install samueltauil/skills-hub first.

Download and extract to your repository:

.github/skills/azure-smart-city-iot-solution-builder/

Extract the ZIP to .github/skills/ in your repo. The folder name must match azure-smart-city-iot-solution-builder for Copilot to auto-discover it.

Skill Files (2)

SKILL.md 5.2 KB 
---
name: azure-smart-city-iot-solution-builder
description: 'Design and plan end-to-end Azure IoT and Smart City solutions: requirements, architecture, security, operations, cost, and a phased delivery plan with concrete implementation artifacts.'
---

# Azure Smart City IoT Solution Builder

Use this skill to rebuild and standardize a complete workflow for Azure IoT and Smart City solutions.

## When to use it

Use this skill when the user asks for things like:

- "I want to build an IoT solution on Azure"
- "Smart City architecture for traffic, lighting, or waste"
- "How do I connect devices, analytics, and alerts?"
- "I need a roadmap and backlog for an urban platform"

## Objectives

- Convert a high-level idea into a deployable architecture.
- Reuse existing Azure-focused skills whenever possible.
- Produce concrete artifacts the team can implement.

## Workflow

### 0) Mandatory documentation review (before any architecture)

Before proposing architecture or technology decisions that involve edge computing, review Azure IoT Edge documentation first:

- https://learn.microsoft.com/azure/iot-edge/

Minimum pages to review:

- What is Azure IoT Edge
- Runtime architecture
- Supported systems
- Version history/release notes
- Relevant Linux/Windows quickstarts for the scenario

If documentation cannot be consulted, state this explicitly and continue with clearly marked assumptions.

### 1) Scope and constraints

Collect and confirm:

- City domain: mobility, parking, air quality, water, energy, public safety, waste, etc.
- Scale: number of devices, telemetry frequency, retention, regions.
- Latency and availability objectives.
- Regulatory and privacy constraints.
- Existing systems to integrate (SCADA, GIS, ERP, ticketing, APIs).

### 2) Capability map

Split the platform into layers:

- Device and edge: onboarding, identity, firmware, OTA, edge processing.
- Ingestion and messaging: command and control, event routing, buffering.
- Data and analytics: hot path vs cold path, dashboards, historical analysis.
- Operations: observability, incident flow, SLOs.
- Governance: RBAC, secrets, policies, network isolation.

### 3) Azure service selection (reference)

- Device connectivity: Azure IoT Hub, Azure IoT Operations, IoT Edge.
- Event streaming: Event Hubs, Service Bus, Event Grid.
- Storage: Blob Storage, Data Lake, Cosmos DB, SQL.
- Analytics: Azure Data Explorer, Stream Analytics, Fabric/Synapse.
- APIs and applications: API Management, App Service, Container Apps, Functions.
- Monitoring: Azure Monitor, Application Insights, Log Analytics.
- Security: Key Vault, Defender for IoT, Private Endpoints, Managed Identity.

### 4) Non-functional design

Define and document:

- Reliability model (zones/regions, retries, dead-letter handling, replay).
- Security controls (zero trust, encryption, secret rotation, least privilege).
- Cost controls (retention tiers, rightsizing, autoscaling, workload scheduling).
- Data lifecycle (raw, curated, aggregated, archived).

### 5) Delivery plan

Create a phased execution:

- Phase 1: Pilot district or single use case.
- Phase 2: Multi-domain integration.
- Phase 3: City-scale rollout and optimization.

For each phase, include:

- Exit criteria
- Dependencies
- Risks and mitigations
- KPI set

## Reuse other skills first

There are two sources of skills:

- Runtime-provided skills (external to this repository): only available when the Copilot host environment exposes them.
- Local repository skills (this repository): available as local files under `skills/`.

### Runtime-provided Azure skills (optional)

If they are available in the execution environment, delegate to these specialized skills for deeper guidance:

- `azure-kubernetes`
- `azure-messaging`
- `azure-observability`
- `azure-storage`
- `azure-rbac`
- `azure-cost`
- `azure-validate`
- `azure-deploy`

### Local repository alternatives (use in this repo)

When runtime skills are not available, prioritize existing local skills in this repository:

- `azure-architecture-autopilot` for architecture generation and refinement.
- `azure-resource-visualizer` for resource relationship diagrams.
- `azure-role-selector` for role selection guidance.
- `az-cost-optimize` and `azure-pricing` for cost and pricing analysis.
- `azure-deployment-preflight` for pre-deployment checks.
- `appinsights-instrumentation` for telemetry instrumentation patterns.

If no specialized skill is available, continue with this skill and keep assumptions explicit.

## Required output artifacts

Always provide these outputs:

1. Smart City solution summary (scope, assumptions, constraints).
2. Reference architecture (components and data flow).
3. Security and governance checklist.
4. Cost and scaling strategy.
5. Phased implementation backlog (epics and milestones).

## Output template

Use this response structure:

1. Context and objectives
2. Proposed architecture
3. Technology decisions and trade-offs
4. Security, operations, and cost controls
5. Phased implementation plan
6. Risks and open questions

## Guidelines

- Do not jump to deployment before validating prerequisites.
- Do not recommend single-region production for critical city workloads.
- Do not omit operational ownership (who handles incidents, SLAs, change windows).
- Clearly separate assumptions from confirmed facts.
references/
smart-city-solution-template.md 1.3 KB 
# Smart City IoT Solution Template

Use this template to standardize outputs for each new smart city scenario.

## 1. Use case summary

- Domain:
- Stakeholders:
- Problem statement:
- Success metrics:

## 2. Device and data profile

- Device types and count:
- Telemetry schema:
- Ingestion rate:
- Command/control requirements:
- Retention policy:

## 3. Reference architecture

- Edge and field layer:
- Ingestion layer:
- Processing layer:
- Storage layer:
- API and integration layer:
- Monitoring and security layer:

## 4. NFR checklist

- Availability target:
- Latency target:
- Security controls:
- Data privacy constraints:
- DR strategy:
- Cost target:

## 5. Phased roadmap

### Phase 1 - Pilot

- Scope:
- Deliverables:
- Exit criteria:

### Phase 2 - Scale

- Scope:
- Deliverables:
- Exit criteria:

### Phase 3 - Optimize

- Scope:
- Deliverables:
- Exit criteria:

## 6. Initial backlog baseline

- Epic: Device onboarding and identity
- Epic: Telemetry ingestion and routing
- Epic: Real-time alerting and incident workflow
- Epic: Historical analytics and reporting
- Epic: Security and compliance hardening
- Epic: Governance and cost optimization

## 7. Risks

- Vendor/device interoperability gaps
- Network reliability in field locations
- Data quality issues and schema drift
- Over-retention that increases costs
- Ambiguity in operational ownership

License (MIT)

MIT Source: github/awesome-copilot
View full license text 
MIT License

Copyright GitHub, Inc.

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.