Wk05 Cloud Computing for AI-enabled IoT_student.pdf

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Cloud
Computing
for AI-
enabled IoT
The Future of Smart
Systems
Introduction to
Cloud
Computing
What is cloud computing?
What does cloud computing mean to you?
Why do we need to use cloud computing for AI-enabled IoT?
Please type your thoughts on Padlet.
https://padlet.com/enpauli/eie3127wk5

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Cloud computing defined

Cloud computing is the on-demand delivery of compute power, database,
storage, applications, and other IT resources via the internet with pay-as-
you-go pricing.

© 2019 Amazon Web Services, Inc. or its Affiliates. All rights reserved. 4
Infrastructure as software

Cloud computing enables you to stop thinking of your infrastructure as
hardware, and instead think of (and use) it as software.

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Traditional computing model

Infrastructure as hardware
Hardware solutions:
Require space, staff, physical security,
planning, capital expenditure
Have a long hardware procurement
cycle
Require you to provision capacity by
guessing theoretical maximum peaks

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Cloud computing model

Infrastructure as software
Software solutions:
Are flexible
Can change more quickly, easily, and
cost-effectively than hardware
solutions
Eliminate the undifferentiated heavy-
lifting tasks

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Cloud service models

IaaS PaaS SaaS
(infrastructure as a (platform as a (software as a
service) service) service)

More control Less control
over IT resources over IT resources

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Cloud computing deployment models

Cloud Hybrid On-premises
(private cloud)

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 Cloud computing is the
Section 1 key delivery of IT resources via the internet
with pricing.
takeaways Cloud computing enables you to think of
(and use) your as
software.
There are three cloud service models:.
There are three cloud deployment models:.
Almost anything you can implement with
traditional IT can also be implemented as
an AWS cloud computing service.

10 © 2019 Amazon Web Services, Inc. or its Affiliates. All rights reserved.
Why do we need to
use cloud
computing for AI-
enabled IoT?

Advantages of cloud computing for IoT
and AI integration
Benefits of Using Cloud
Computing for AI-Enabled IoT
Processing Power
AI requires significant computing power to analyze
large amounts of data and train complex models.

Storage and Data Management
Cloud computing provides flexible and scalable
storage options for IoT applications that generate
huge amounts of data.

Data Analytics and AI Services
Pre-built AI Services
Big Data Analytics
Benefits of Using Cloud
Computing for AI-Enabled IoT
Scalability
scalable infrastructure
allowing for easy expansion as the system grows in
complexity.

Cost-Effectiveness
reducing the need for physical hardware and minimizing
maintenance costs.
pay only for the resources they use

Flexibility
allowing organizations to choose the right services and
configurations that best meet their needs.
Benefits of Using Cloud
Computing for AI-Enabled IoT
Reduced Latency
Cloud computing can reduce latency by providing
localized computing resources that are closer to the
devices.

Improved Efficiency
offloading some of the processing and storage
requirements to the cloud
free up resources on the devices and allow them to
focus on their primary functions

Increased Security
providing centralized control over data access,
authentication, and encryption
Challenges of Cloud Computing for IoT
Latency
Distance to Data Centers
Impact on Performance

Security
Data Privacy Concerns

Reliability
Service Downtime
Disaster Recovery

Bandwidth and Connectivity
Data Transfer Limitations
Dependency on Internet Connectivity
Balancing the Benefits and Challenges

Strategies for Success
Hybrid Approaches
Enhanced Security Measures
Optimizing Cloud Usage
 Introduction to Cloud
Computing Platforms
for IoT
An overview of AWS IoT and Microsoft Azure IoT
AWS IoT
Overview:
AWS IoT is a managed cloud platform that enables devices to connect, interact, and exchange data
securely with cloud applications and other devices.
Key Features:
Device Management
Real-Time Analytics
Secure Communication
AWS IoT
Examples:
AWS IoT Core
AWS Greengrass
AWS IoT Analytics
AWS IoT Greengrass Solution Demo for Process Manufacturing Optimization, Advantech (EN)

https://youtu.be/rYGQsf7h3Es?si=u5sCKqmCrq8CVdey
Microsoft Azure IoT
Overview:
Microsoft Azure IoT offers a comprehensive suite of IoT services that enable users to build, connect,
monitor, and manage IoT applications securely and at scale.
Key Features:
IoT Hub
Edge Computing
Advanced Analytics
Microsoft Azure IoT
Examples:
Azure IoT Hub
Azure IoT Central
Azure Sphere
Azure IoT Services | IoT Hub, IoT Central, Azure Sphere

https://youtu.be/RHkqFxJWhr8?si=zW8tve7XiOgSVMcJ
Azure IoT Operations Demo

https://youtu.be/cw9nhPFE_qE?si=34QRiR7AWhP3r2u1
 Edge
Computing for
AI-enabled IoT
Distributed Computing
for Faster IoT and AI
What is Edge
Computing?
Distributed Computing Paradigm
Edge computing is a distributed
computing paradigm that brings
computation and data storage
closer to the devices where it is
being gathered, enabling faster
processing and reduced latency.
What is edge computing? (pizza example)

https://youtu.be/WMvb9LLXzUs?si=Umq7Et38_c5zeyhC
What is Edge Computing?

https://youtu.be/3hScMLH7B4o?si=PpWn5PpPRCY-JjCi
 Cloud Computing
centralized computing model
ideal for applications that require a high degree

Edge
of scalability and availability

Edge Computing

Computing vs distributed computing model
ideal for applications that require real-time data

Cloud processing and low latency

Key Differences
Computing related to data processing, network latency, and
security
Benefits of Edge Reduced Latency
Edge computing reduces latency by

Computing for IoT bringing computing power closer to
the data source.

Improved Security
Edge computing improves security by
keeping data closer to the source

Decreased Bandwidth Usage
Edge computing decreases
bandwidth usage by processing data
locally
AI-enabled Edge Computing
 Benefits of AI-enabled Edge
Computing
improved response times, reduced
latency, increased security, and lower
bandwidth requirements.
more efficient and real-time decision-
making for IoT devices

Machine Learning
enable predictive maintenance and
anomaly detection

Deep Learning
enable more accurate and
sophisticated image and speech
AI at the Edge recognition
Challenges of AI-enabled
Edge Computing
Limited Computational Resources
running AI algorithms on devices with
limited computational resources

Data Security
sensitive data may be processed on the
edge devices and transmitted over insecure
networks

Data Privacy
personal data may be processed on the
edge devices and transmitted over insecure
networks.
Use Cases of
Edge Computing
in IoT
Federated
Learning for AI
enabled IoT
Revolutionizing Machine Learning
with IoT devices
What is Federated
Learning?
Federated Learning Advantages of Federated
Learning
increased privacy and security,
reduced data transfer and
storage requirements, and
better performance on edge
devices.

Federated Learning in AI-
Enabled IoT
By training machine learning
models on edge devices,
Federated Learning enables
more efficient and effective AI
applications in IoT.
How does
Federated Learning
work?
Centralized Model Initialization

Device Training

Model Aggregation

Further Training
Workflow Summary

Step 1: Devices collect and store data locally.
Step 2: Local models are trained on-device using this data.
Step 3: Trained model updates are sent to a central server.
Step 4: The server aggregates updates to form an improved global
model.
Step 5: The global model is redistributed to devices, where the process
repeats.
What is Federated Learning?

https://youtu.be/X8YYWunttOY?si=KDqSTz_kqrUa0VvZ
Making every phone smarter with Federated Learning

https://youtu.be/gbRJPa9d-VU?si=QBcjjIWoFjI5H-AS
Federated Learning for AI-enabled IoT
Federated Learning Architecture
distributed machine learning approach that promotes data privacy while also enabling the
development of more accurate machine learning models

AI-Enabled IoT Devices
great potential for building AI-enabled IoT devices that can operate effectively in real-world
environments

Potential Applications
including predictive maintenance, anomaly detection, and real-time decision-making.
 Personalized Smart Assistants

Use Cases of Remote Health Monitoring

Autonomous Vehicles and
Federated Transportation

Computing in Predictive Maintenance and Quality
Control
AI-Enabled
IoT