IS_prelim-notes.pdf

Transcript

INFORMATION SYSTEMS Frameworks of IS
Information System 5 components of IS
A collection of hardware, software, data,  Hardware
procedures, and people that work together to  Software
provide information necessary for the  Data
functioning of an organization.  Procedures
 People
Encompasses a wide range of technologies
and processes that manage and manipulate Hardware
data into meaningful information for various
Physical devices like computers, servers, and
users.
networking equipment.
Data vs. Information
Software
Data
Programs and applications that enable data
Refers to raw, unprocessed facts and figures
processing and manipulation.
without any context or meaning.
Data
Information
Raw facts and figures that serve as the
Processed, organized, or structured data that
foundation for information.
has been given context and meaning, making
it useful for decision-making or understanding. Procedures
Information System vs. Information Sets of instructions or protocols for handling
Technology data and making decisions.

IT is a critical component of an IS but is not the People
entirety of it.
Users, analysts, developers, and other
IS incorporates IT along with people, processes, personnel involved in Is lifestyle.
and data to achieve organizational goals.
Information Systems Pyramid
Attributes of IS
 Accuracy
 Relevance
 Timeliness
 Completeness
 Reliability

Accuracy
Information should be free form errors and
should reflect reality as closely as possible.

Relevance
Strategic Information System
Information should be pertinent to the task or
decision at hand. Play an integral role in an organization’s
strategic planning, allowing it to gain a
Timeliness competitive advantage by effectively
aggregating, processing, and managing data
Information should be available when
to inform decision-making.
needed, with current and up-to-date data.
Computer Resources
Completeness
Serve as the backbone of information systems,
Information should be comprehensive,
enabling organizations to process data, make
providing all necessary data without missing
informed decisions, and optimize operations.
any critical components.
Components and Elements of Computer
Reliability
Resources
Information should be trustworthy, consistent,
 Hardware
and dependable. It should come from
 Software
credible sources and be verified for accuracy.
 Network
 Data Storage
Hardware
Played a vital role in early information systems
Comprises physical devices such as central for tasks like accounting and inventory
processing units (CPUs), memory, storage management.
devices, input/output peripherals, and network
Personal Computers (PCs)
equipment.
Decentralized computing, empowering
*Different types of hardware serve specific
individual users.
functions within an organization's information
systems.* Facilitated personal productivity and led to the
development of client-server architectures.
Software
*The importance of desktop applications and
Encompasses operating systems, application
graphical user interfaces (GUIs) in information
software, and middleware that enable
systems.*
hardware components to work together.
Servers
*Distinguishing between system software (e.g.,
OS) and application software (e.g., word Evolved to support networked computing
processing, CRM) is essential.* environments.
*The role of software in managing hardware *Discussion on file servers, application servers,
resources and facilitating information web servers, and their roles in modern
processing is explored.* information systems.*
Middleware *Emphasis on scalability and redundancy in
server architectures.*
Software that lies between an operating
system and the applications running on it. Cloud Computing
Network Resources are accessed remotely via the
internet.
Including LANS (local area networks) and
WANS (wide area networks), connect Advantages: scalability, cost-effectiveness,
hardware components and enable data and reduced IT infrastructure management.
exchange.
Significance of Computer Resources in
*Understanding network protocols, topologies, Information Systems
and security measures is crucial.*
The critical role of computer resources in
*Modern advancements like wireless networks information systems for data processing,
and the internet of things (IOT) impact decision-making, and communication.
information systems.
The impact of resource allocation and
Data Storage management on the efficiency and
effectiveness of an organization's operations.
Store and manage the vast amount of data
used by organizations. Parallel Computing
*Types of storage devices (e.g., hard drives, A computational approach where multiple
SSDs), databases, and data storage tasks or processes are executed concurrently,
technologies are discussed. with the aim of achieving improved
*Emphasis on data security, redundancy, and computational performance and efficiency.
scalability in data storage solutions.* *Sequential computing faces limitations in
processing speed and scalability, driving the
Evolution of Computer Resources
need for parallelism.*
 Mainframes
 Personal Computers (PCs) Types of Parallelism
 Servers  Task Parallelism
 Cloud Computing  Data Parallelism
Mainframes Task Parallelism
The initial computing resources used for large- Dividing a problem into smaller tasks that can
scale data processing. be executed simultaneously.
Characterized by high processing power,
reliability, and centralized control.
Data Parallelism Shared Memory Parallelism
Processing multiple data elements Thread-Based Programming
concurrently. Threads within a single process share memory,
allowing for shared data structures and
Multi-core Processors
communication.
 Symmetric Multiprocessing (SMP)
 Asymmetric Multiprocessing (AMP) OpenMP

Shared Memory A directive-based API simplifying the creation
ofmulti-threaded applications.
Symmetric Multiprocessing (SMP)
Message Passing
Two or more identical processors are MPI (Message Passing Interface)
connected to a single, shared main memory,
have full access to all input and output Facilitates communication among distributed
devices, and are controlled by a single processes via message passing, common in
operating system. high-performance computing (HPC) and
cluster computing.
Distributed Memory
Data Parallelism
Asymmetric Multiprocessing (AMP)
SIMD (Single Instruction, Multiple Data)
Not all of the multiple interconnected central
processing units (CPUs) are treated equally. Executes the same operation on multiple data
elements simultaneously.
Only a master processor runs the tasks of the
operating system. GPU Computing

Benefits of Multi-Core Processors Leveraging Graphics Processing Units (GPU) for
data-parallel workloads using frameworks like
Enhanced Performance CUDA and OpenCL.
Energy Efficiency
Relevance in Today's Computing
Enhanced Performance Landscape
Execution of multiple threads or processes in 1. Scientific and High-Performance
parallel leads to improved performance. Computing (HPC)
Energy Efficiency Parallelism is essential for complex simulations,
scientific research, and weather forecasting.
Better performance per watt, reducing power
consumption. 2. Big Data Analytics
Challenges Parallel processing accelerates data analysis,
enabling real-time decision-making in analytics
Parallel Programming Complexity and data-driven industries.
Amdahl's Law
3. Artificial Intelligence (AI) and Machine
Parallel Programming Complexity Learning
Developing software that efficiently utilizes Training large AI models benefits from
multiple cores requires expertise in parallel parallelism, reducing training times and
programming. enabling faster insights.
Amdahl's Law 4. Gaming and Graphics
Highlights potential bottlenecks in Multi-core processors and GPUs power
parallelization. immersive gaming experiences and complex
Parallel Programming Techniques 3D rendering.

1. Shared Memory Parallelism 5. Web Services and Cloud Computing
2. Message Passing Scalable, parallelized services are vital for
3. Data Parallelism meeting the demands of cloud-based
applications and web services.
1. Computer Resources as Enabler of 2.2. Internet of Things (IoT)
Organizations Processes and Decision
Smart Manufacturing: IoT sensors in
Making manufacturing enable predictive
Enable automation, data management, and maintenance, reducing downtime and
communication. enhancing productivity.

1.1. Supporting Organizations Processes Supply Chain Optimization: Real-time data
from lot devices helps track products, reduce
Operations Management: ERP (Enterprise costs, and improve inventory management.
Resource Planning) system, automated
production lines, and data analysis tools Smart Cities: lot systems enhance urban living
enhance operational efficiency. through smart infrastructure, energy efficiency.
and real-time traffic monitoring.
Communication: Cloud services and
collaboration platforms (like Slack, MS Teams) 2.3. Edge Computing
allows seamless information sharing. Reduced Latency: Edge computing enables
Customer Relationship Management (CRM): faster data processing by reducing the time it
Manage customer interactions, improve takes to transmit data to a central server.
service delivery, and faster long-term customer Security: By decentralizing data, edge
relationship. computing enhances security, particularly in
1.2. Facilitating Decision-Making sensitive industries like healthcare and finance.

Data Analytics: Computer resources provide Scalability: Companies can scale operations
access to real-time data, enabling more more efficiently by integrating edge
informed and timely decision-making. computing into their networks.

Business Intelligence (BI): Tools like Power BI or 3. Developing a Forward-looking Strategy
Tableau help organizations convert data into for Harnessing Emerging Technology
actionable insights. 3.1. Strategic Integration of Al
Predictive Analytics: Forecasting tools and Al- Al-driven Decision Support Systems: Invest in Al
powered algorithms help decision-makers to enhance predictive analytics and decision-
anticipate future trends and customer needs. making frameworks.
1.3. Driving Strategic Initiatives Al in Customer Interactions: Deploy chatbots
and Al- driven virtual assistants to improve
Digital Transaction: Leveraging cloud customer service efficiency.
computing and digital tools helps businesses
stay competitive. Al in Operations: Automate repetitive tasks to
streamline workflows and improve operational
Innovation: Computer resources support R&D efficiency.
through simulation, 3D modeling, and
prototyping. 3.2. IoT-Enabled Connectivity
Globalization: Cloud-based systems enable lot in Supply Chain: Implement lot sensors for
companies to operate across borders with real-time tracking and inventory
shared resources and global collaboration. management, reducing waste and increasing
SC transparency.
2. Current Trends and Emerging
Technologies Impacting Computer Smart Workplace: Use lot devices to monitor
Resources and manage energy usage, workspace
utilization, and employee productivity.
2.1. Artificial Intelligence (AI)
Automation: Al enhances process automation, 3.3. Leveraging Edge Computing
from robotic process automation (RPA) in Hybrid Cloud-Edge Architectures: Create
business operations to machine learning systems that blend cloud and edge
algorithm that optimize supply chains. computing for faster processing and increased
Data Analysis: Al-driven analytics tools can scalability.
detect patterns in large datasets, enabling Data Security Protocols: Integrate edge
faster and more accurate decision-making. computing to protect sensitive data through
Personalization: In marketing, AI tailors content decentralized systems.
and recommendations to individual users,
improving customer experience.
Emerging Technologies and their Impact
Enhance Operational Efficency: By
automating routine tasks and optimizing
resource allocation, organizations can reduce
costs and improve productivity.
Improve by Customer Insights: Advance
analytics provide a deeper understarding of
customer’s needs and preferences allowing…
Facilitate Agile Decision Making: