It is a presentation for the Embedded System Basics. It will be very useful for the engineering students who need to know the basics of Embedded System.
Challenges faced during embedded system design:
The challenges in design of embedded systems have always been in the same limiting requirements for decades: Small form factor; Low energy; Long-term stable performance without maintenance.
In this ppt you will learn about the various memory and its types inside the computer. The ppt also describes an analogy for your better understanding. Hope it will be fun learning.
SYBSC IT SEM IV EMBEDDED SYSTEMS UNIT I Core of Embedded SystemsArti Parab Academics
Core of embedded systems: microprocessors and microcontrollers, RISC and CISC controllers, Big endian and Little endian processors, Application specific ICs, Programmable logic devices, COTS, sensors and actuators, communication interface, embedded firmware, other system components.
EDLC-EMBEDDED PRODUCT DEVELOPMENT LIFE CYCLESabeel Irshad
Embedded Product Development Life Cycle (Let us call it as EDLC, though it is not a standard and universal term) is an 'Analysis -Design -Implementation' based standard problem solving approach for Embedded Product Development. In any product development application, the first and foremost step is to figure out what product needs to be developed (analysis), next you need to figure out a good approach for building it (design) and last but not least you need to develop it (implementation).
Embedded systems and their applications in our daily routineAsad Qayyum Babar
Embedded systems perform specific tasks. They have micro-controller as the main part which controls all the operations required through them. This presentation on examples of embedded systems can help you to get an idea of common systems which we use in our daily lives. These systems are smart and more efficient, which is increasing their use day by day. Almost every device that we use today is an example of embedded systems. Embedded systems examples can be seen at our homes, at offices, in industries and in automation systems. So, in simple words, most of the daily routine appliances, devices or automated equipment lies in the circle of Embedded Systems Examples.
Few of these Examples of Embedded Systems were discussed in this presentation, if you learn embedded systems then you can also create something, helpful to society. So, let’s get started with these Examples of Embedded Systems.
It is a presentation for the Embedded System Basics. It will be very useful for the engineering students who need to know the basics of Embedded System.
Challenges faced during embedded system design:
The challenges in design of embedded systems have always been in the same limiting requirements for decades: Small form factor; Low energy; Long-term stable performance without maintenance.
In this ppt you will learn about the various memory and its types inside the computer. The ppt also describes an analogy for your better understanding. Hope it will be fun learning.
SYBSC IT SEM IV EMBEDDED SYSTEMS UNIT I Core of Embedded SystemsArti Parab Academics
Core of embedded systems: microprocessors and microcontrollers, RISC and CISC controllers, Big endian and Little endian processors, Application specific ICs, Programmable logic devices, COTS, sensors and actuators, communication interface, embedded firmware, other system components.
EDLC-EMBEDDED PRODUCT DEVELOPMENT LIFE CYCLESabeel Irshad
Embedded Product Development Life Cycle (Let us call it as EDLC, though it is not a standard and universal term) is an 'Analysis -Design -Implementation' based standard problem solving approach for Embedded Product Development. In any product development application, the first and foremost step is to figure out what product needs to be developed (analysis), next you need to figure out a good approach for building it (design) and last but not least you need to develop it (implementation).
Embedded systems and their applications in our daily routineAsad Qayyum Babar
Embedded systems perform specific tasks. They have micro-controller as the main part which controls all the operations required through them. This presentation on examples of embedded systems can help you to get an idea of common systems which we use in our daily lives. These systems are smart and more efficient, which is increasing their use day by day. Almost every device that we use today is an example of embedded systems. Embedded systems examples can be seen at our homes, at offices, in industries and in automation systems. So, in simple words, most of the daily routine appliances, devices or automated equipment lies in the circle of Embedded Systems Examples.
Few of these Examples of Embedded Systems were discussed in this presentation, if you learn embedded systems then you can also create something, helpful to society. So, let’s get started with these Examples of Embedded Systems.
Describes ARM7-TDMI Processor Instruction Set. Explains classes of ARM7 instructions, syntax of data processing instructions, branch instructions, load-store instructions, coprocessor instructions, thumb state instructions.
Presents features of ARM Processors, ARM architecture variants and Processor families. Further presents, ARM v4T architecture, ARM7-TDMI processor: Register organization, pipelining, modes, exception handling, bus architecture, debug architecture and interface signals.
This presentation is a short introduction to issues in Hardware-Software Codesign. It discusses definition of codesign, its significance, design issues in Hardware-software codesign, Abstraction levels, Duality of harware and software
EDLC-EMBEDDED PRODUCT DEVELOPMENT LIFE CYCLESabeel Irshad
Embedded Product Development Life Cycle (Let us call it as EDLC, though it is not a standard and universal term) is an 'Analysis -Design -Implementation' based standard problem solving approach for Embedded Product Development. In any product development application, the first and foremost step is to figure out what product needs to be developed (analysis), next you need to figure out a good approach for building it (design) and last but not least you need to develop it (implementation).
Future Trends of Embedded Systems - Technical Paper PresentationKaushik Gupta
Runner-Up for the State Level Technical Paper Presentation
Certification: Indian Society for Technical Education
More Details on https://www.kaushikgupta.in
This Presentation describes the ARM CORTEX M3 core processor with the details of the core peripherals. Soon a CORTEX base controller(STM32F100RBT6) ppt will be uploaded. For more information mail me at:gaurav.iitkg@gmail.com.
Chaired a Technical Session in NATIONAL CONFERENCE ON EMBEDDED SYSTEMS & SIGNAL PROCESSING (NESP-2014) (Jain University)
My Lead talk title of the presentation: Trends and Implications in Embedded Systems Development
Describes ARM7-TDMI Processor Instruction Set. Explains classes of ARM7 instructions, syntax of data processing instructions, branch instructions, load-store instructions, coprocessor instructions, thumb state instructions.
Presents features of ARM Processors, ARM architecture variants and Processor families. Further presents, ARM v4T architecture, ARM7-TDMI processor: Register organization, pipelining, modes, exception handling, bus architecture, debug architecture and interface signals.
This presentation is a short introduction to issues in Hardware-Software Codesign. It discusses definition of codesign, its significance, design issues in Hardware-software codesign, Abstraction levels, Duality of harware and software
EDLC-EMBEDDED PRODUCT DEVELOPMENT LIFE CYCLESabeel Irshad
Embedded Product Development Life Cycle (Let us call it as EDLC, though it is not a standard and universal term) is an 'Analysis -Design -Implementation' based standard problem solving approach for Embedded Product Development. In any product development application, the first and foremost step is to figure out what product needs to be developed (analysis), next you need to figure out a good approach for building it (design) and last but not least you need to develop it (implementation).
Future Trends of Embedded Systems - Technical Paper PresentationKaushik Gupta
Runner-Up for the State Level Technical Paper Presentation
Certification: Indian Society for Technical Education
More Details on https://www.kaushikgupta.in
This Presentation describes the ARM CORTEX M3 core processor with the details of the core peripherals. Soon a CORTEX base controller(STM32F100RBT6) ppt will be uploaded. For more information mail me at:gaurav.iitkg@gmail.com.
Chaired a Technical Session in NATIONAL CONFERENCE ON EMBEDDED SYSTEMS & SIGNAL PROCESSING (NESP-2014) (Jain University)
My Lead talk title of the presentation: Trends and Implications in Embedded Systems Development
Embedded systems The Past Present and the FutureSrikanth KS
This presentation provides an overview of the trends in embedded systems. It will mainly help engineering students to select a good final year project.
This presentation describes the future perspectives of embedded devices due to the spread of ubiquitous applications. The presentation shows the transition from Internet of Things to Web of Things and presents Webinos as a platform for WoT
Industrial Automation: Global Demand Continues to Rise | An Aranca InfographicAranca
The global manufacturing industry is becoming increasingly competitive with heavy focus on international standards. Demand for industrial automation especially in emerging manufacturing hubs like India and China is on the rise.
Learning objective: The goal of this signature seminar is to examine the current trends that are driving the rapid growth in the use of Embedded Systems; what employers and solutions providers are looking for in talent, and how Aerotek and EASi can help to connect buyers and sellers in this vast marketplace.
As more and more mechanical and electrical devices rely heavily on embedded hardware and software to function effectively, the future of the already expansive embedded systems marketplace continues to look bright.
At the end of this seminar, participants will gain a greater awareness of:
a. The major trends that are driving the growth of Embedded Systems; specifically, Connectivity and the Internet of Things (IOT).
b. The types of Embedded Systems related solutions and skillsets that will be in demand in the future, and how Aerotek and EASi can help to connect buyers and sellers.
Presented by Matthew Brems and Melissa Hannebaum, students at Franklin College, documenting results of summer research under the direction of Dr. Robert Talbert, PhD.
This presentation goes through several topics areas that are of specific interest in developing IoT Gateway solutions. IoT is a popular area of development that presents unique challenges like hardware and operating system selection, product life-cycle support and maintainability, software architectural solutions, connectivity, security, secure updates, and API availability. We discuss technologies and concepts like Hardware acceleration support, Linux kernel maintenance, Edge networking, LXC/Docker/KVM, Zigbee, 6loPAN, BLE, IoTivity, Allseen Alliance, SELinux and Trusted boot.
The aim of the presentation is to give an overview of the challenges in building an IoT Gateway and the Solutions available using Embedded Linux.
This presentation was delivered at LinuxCon Japan 2016 by Jim Gallagher
Introduction to Cloud Computing
Cloud computing is a transformative technology that allows businesses and individuals to access computing resources over the internet. Instead of owning and maintaining physical hardware and software, users can leverage cloud services provided by companies like Amazon Web Services (AWS), Microsoft Azure, Google Cloud Platform (GCP), and others. This shift has revolutionized how we think about IT infrastructure, software development, data storage, and more.
Key Concepts of Cloud Computing
On-Demand Self-Service:
Users can provision computing resources as needed without human intervention from the service provider. This includes servers, storage, and applications.
Broad Network Access:
Cloud services are available over the network and accessed through standard mechanisms, enabling use from a variety of devices like laptops, smartphones, and tablets.
Resource Pooling:
Providers use a multi-tenant model to serve multiple customers with dynamically assigned resources. This model allows for economies of scale and efficient resource utilization.
Rapid Elasticity:
Resources can be elastically provisioned and released, sometimes automatically, to scale rapidly outward and inward commensurate with demand.
Measured Service:
Cloud systems automatically control and optimize resource use by leveraging a metering capability, allowing for pay-as-you-go pricing models.
Types of Cloud Computing Services
Infrastructure as a Service (IaaS):
Provides virtualized computing resources over the internet. Examples include AWS EC2, Google Compute Engine, and Azure Virtual Machines.
Platform as a Service (PaaS):
Offers hardware and software tools over the internet, typically used for application development. Examples include Google App Engine, AWS Elastic Beanstalk, and Azure App Services.
Software as a Service (SaaS):
Delivers software applications over the internet, on a subscription basis. Examples include Google Workspace, Microsoft Office 365, and Salesforce.
Deployment Models
Public Cloud:
Services are delivered over the public internet and shared across multiple organizations. It offers cost savings but might pose concerns regarding data security and privacy.
Private Cloud:
Dedicated to a single organization, offering enhanced security and control over data and infrastructure. It's more expensive than public cloud but can be tailored to specific business needs.
Hybrid Cloud:
Combines public and private clouds, allowing data and applications to be shared between them. This model offers greater flexibility and optimization of existing infrastructure, security, and compliance.
Community Cloud:
Shared between organizations with common concerns (e.g., security, compliance, jurisdiction). It can be managed internally or by a third-party.
Advantages of Cloud Computing
Cost Efficiency: Reduces the need for significant capital expenditure on hardware and software.
Scalability and Flexibility: Easily scales up or down based on
Embedded system, basic structure, characteristics, advantages, disadvantages of Embedded system, open source Embedded platforms and its benefits, sensors, actuators, DAS.
What is Your Edge From the Cloud to the Edge, Extending Your ReachSUSE
As companies continue to take advantage of the benefits of cloud – increased flexibility, speed of innovation and quickly responding to business demands, it is no wonder that they want to extend these benefits to the edge. But there are still a lot of questions.
2. 1. Embedded system
2. Trends:
• SoC (System on a Chip)
• Wireless Technology
• Multi-core Processor
• Multi-language support
• User interface
• Use of open Source Technology
• Inter- operatability
• Automation
• Security
• Power consumption
3. • An embedded system is some combination of computer
hardware and software.
• An embedded system is housed on a single
microprocessor board with the programs stored in ROM.
•Virtually all appliances that have a digital interface -- watches,
microwaves, VCRs,cars -- utilize embedded systems.
4. Various recent trends in embedded system are :-
1. SoC (System on a Chip)
2. Wireless Technology
3. Multi-core Processor
4. Multi-language support
5. User interface
6. Use of open Source Technology
7. Inter-operatability
8. Automation
9. Security
10.Power consumption
5. •A system on a chip (SoC) is an integrated circuit (IC) that
integrates all components of a computer or other
electronic system into a single chip.
•SoCs are very common in the mobile electronics market because
of their low power consumption. A typical application is in the area
of embedded systems.
6.
7. •The term "wireless" refers, in the most basic and obvious sense, to
communications sent without wires or cables.
• It is a broad term that encompasses all sorts of wireless
technologies and devices, including cellular communications,
networking between computers with wireless adapters, and wireless
computer accessories.
•Wireless communications travel over the air via electromagnetic
waves (radio frequencies, infrared, satellite, etc).
8.
9. A multi-core processor is an integrated circuit (IC) to which two or
more processors have been attached for enhanced performance,
reduced power consumption, and more efficient simultaneous
processing of multiple tasks.
10.
11. •Embedded system provides us facility of multiple languages. For
example ATM is a typical example of embedded system.
•In ATM there are three types of languages are used like
Hindi,Punjabi,English.
12.
13. •Visual part of computer application or operating system through
which a user interacts with a computer or a software.
•It determines how commands are given to the computer or
the program and how information is displayed on the screen.
14.
15. •Open source technology refers to a program in which the source
code is available to the general public for use and/or modification
from its original design free of charge, i.e., open.
•Open source code is typically created as a collaborative effort in
which programmers improve upon the code and share the
changes within the community.
16.
17. •Ability to work with each other. In the loosely coupled
environment of a service-oriented architecture, separate
resources don't need to know the details of how they each
work, but they need to have enough common ground to
reliably exchange messages without error or
misunderstanding.
•Interoperability is when services can interact with each other
without encountering such problems.
19. •Automation or automatic control, is the use of various control
systems for operating equipment such as machinery, processes
in factories, switching in telephone networks, steering and
stabilization of ships, aircraft and other applications with minimal
or reduced human intervention. Some processes have been
completely automated.
•The biggest benefit of automation is that it saves labor, however,
it is also used to save energy and materials and to improve
quality, accuracy and precision.
20.
21. •Secure Design
Capture system security and performance requirements and develop a secure
architecture
•Threat Model Analysis
Ensure your system is analyzed without bias and based on expert knowledge of
the attack landscape
•Software & Code Testing
Uncover serious problems early and avoid crash-causing defects in code
•Crypto Implementation
Leverage our expertise to ensure crypto is implemenented securely
22.
23. •Power consumption has traditionally been something
influenced only by hardware developers. But power
consumption depends not only on the hardware, but also
on how it is used and how it is controlled by the system
software.
•Through power consumption – it becomes possible to test
and tune for power optimisation.
