Pearson Artificial Intelligence: A Modern Approach Review

Pearson Artificial Intelligence: A Modern Approach Review

Table of Contents

Have we ever wondered what it would be like to unravel the enigmatic realms of artificial intelligence? Well, we may have just stumbled upon the perfect companion for this intellectual journey. “Pearson Artificial Intelligence: A Modern Approach, Global Edition” is here to guide us through the intricate world of AI with a friendly hand and a wise mind. What a gem for our curious brains!

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A Walkthrough of Artificial Intelligence

To say that artificial intelligence is a complex field might be the understatement of the century. Fortunately, “Artificial Intelligence: A Modern Approach, Global Edition” manages to make this vast subject accessible. Here, we’ll break down various elements covered in the book to see how it aids in our understanding.

What is Artificial Intelligence?

The book starts by introducing us to the very essence of AI. It explains it as the simulation of human intelligence in machines that are programmed to think and learn like humans. Sound simple? That’s where the goodness begins. This explanation serves as our foundation, providing the necessary context to advance our learning.

Historical Perspectives

We are treated to a journey through the timeline of artificial intelligence. From the early days of Alan Turing’s groundbreaking work to the modern advancements of today, we get to appreciate the evolution of this fascinating field. The book, published in 2011, also touches upon the significant milestones in AI history, which makes us feel like we’re a part of this ever-evolving journey.

Key Components of AI

There’s no denying the complexity of AI, but this book manages to simplify it by breaking it down into digestible components. Major areas such as machine learning, neural networks, and natural language processing are explored in a way that even the most novice among us can comprehend. Here’s a little table for an easy breakdown:

Component Description
Machine Learning Enables systems to learn from data and improve from experience.
Neural Networks A series of algorithms that mimic the operations of a human brain.
Natural Language Processing Helps computers understand and respond to human language.

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Diving Deeper Into Machine Learning

Supervised vs. Unsupervised Learning

The book elucidates the differences between supervised and unsupervised learning in machine learning. Supervised learning involves training a model on labeled data, whereas unsupervised learning deals with unlabeled data. It’s like teaching a child by showing them flashcards with pictures (supervised) versus letting them explore a playground full of toys unassisted (unsupervised).

Algorithms and Models

Oh, the joy of algorithms! They are the beating heart of AI, and the book explains them in such a delightful manner. From decision trees to support vector machines, we get a comprehensive overview of the various algorithms used in AI. Each algorithm is explained with real-life examples, making us feel like we’re coding geniuses ourselves.

Navigating Neural Networks

The Beauty of Artificial Neurons

Neural networks can sound like something straight out of a sci-fi movie, but this book breaks them down so simply that anyone can grasp the concept. Artificial neurons are the building blocks of neural networks, which are modeled after the human brain. They are the tiny soldiers working hard to make our AI dreams a reality.

Layers and Architecture

Understanding the layers of a neural network can get a bit tricky, but our trusty book has our back. It patiently explains the different types of layers—input, hidden, and output—and how they interact with each other. Think of it as layers in a cake; each layer adds to the complexity and flavor, making the entire structure more robust and delectable.

The Poetry of Natural Language Processing

Sentiment Analysis

Ever wondered how companies know exactly what we’re feeling when we post something on social media? The book dives into sentiment analysis, a crucial part of NLP, which helps in identifying emotions in a text. Now, we can understand how AI reads between the lines, literally.

Chatbots and Voice Assistants

The book doesn’t hold back in explaining how chatbots and voice assistants like Siri or Alexa work. From the basics to the more advanced aspects, we get to peek behind the curtain of these technologies that have seamlessly integrated into our daily lives.

Real-world Applications

Natural language processing isn’t confined to just tech giants. It’s used in healthcare, finance, and even in our favorite hobby—gaming! The book dishes out examples across various industries, showing us how NLP revolutionizes fields we wouldn’t have thought of.

Ethical Considerations in AI

The Moral Compass

No AI discussion would be complete without pondering over the ethical implications. The book nudges us to contemplate the moral responsibilities involved in creating intelligent machines. It’s like having a friend remind us to brush our teeth before bed—important and absolutely necessary.

Privacy Concerns

With great power comes great responsibility, and AI is no exception. The book delves into privacy concerns, helping us understand the fine line between innovation and intrusion. It brings up thought-provoking questions about data security and individual privacy, leaving us more aware of the stakes involved.

Practical Implementation in AI

Tools and Frameworks

If we’re itching to get our hands dirty, the book doesn’t disappoint. It provides insights into the various tools and frameworks used in AI development, like TensorFlow and PyTorch. Like handing us a toolkit, it encourages us to start building our AI models, one line of code at a time.

Real-World Projects

What’s more exciting than theory? Practical application! The book includes project ideas that allow us to apply what we’ve learned. From creating a chatbot to developing a recommendation system, these projects are a fantastic way to test our newfound knowledge.

Get your own Pearson Artificial Intelligence: A Modern Approach, Global Edition today.

A Peek into the Future

Emerging Trends

The book doesn’t just stop at the present; it gives us a tantalizing glimpse into the future of AI. Quantum computing, advanced robotics, and AI ethics boards are among the exciting trends it explores. These predictions make us feel like we’re in on some grand secret, part of an exclusive club for forward-thinkers.

Challenges Ahead

But it’s not all rosy. The book also prepares us for the challenges that lie ahead. From technical limitations to ethical dilemmas, it doesn’t shy away from discussing the potential roadblocks on the path to AI advancement. This balanced perspective equips us with a realistic view, blending optimism with caution.

Final Thoughts on “Pearson Artificial Intelligence: A Modern Approach, Global Edition”

Comprehensiveness

When it comes to comprehensive guidance on artificial intelligence, “Pearson Artificial Intelligence: A Modern Approach, Global Edition” stands head and shoulders above the rest. It deftly covers basic to advanced topics, ensuring that whether we’re beginners or seasoned professionals, we can benefit from its contents.

User-Friendly Approach

The conversational tone and practical examples make a world of difference. We’re not just reading a textbook; we’re having a guided conversation, and that makes all the difference. It’s like having a knowledgeable friend explain complex topics over a cup of coffee, making everything more relatable and less intimidating.

Lasting Learning Experience

Ultimately, this book offers us more than just information; it provides a lasting educational experience. We come away with not just knowledge but with the ability to think critically and ethically about the future of AI.

In the world of artificial intelligence, finding a trusted guide is invaluable. With “Pearson Artificial Intelligence: A Modern Approach, Global Edition,” we have not just a book but a mentor. The intricate world of AI may still be vast and complex, but armed with this book, our journey through it becomes an adventure, a learning expedition, and most importantly, a joy.

Check out the Pearson Artificial Intelligence: A Modern Approach, Global Edition here.

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University Student Essentials
University Student Essentials

About Me

With 25 years of experience in healthcare IT implementation, Emmanuel began his career at the University of Pittsburgh Medical Center, working as an assistant manager for a billing system implementation. Over the years, he has explored various aspects of the healthcare IT domain, successfully implementing several laboratory information systems and electronic medical record (EMR) systems, such as Cerner Millennium and Epic EMR.

In 2005, Emmanuel shifted his focus to public health, working on bio-surveillance implementation for the Centers for Disease Control and Prevention (CDC). He contributed to the BioSense Data Provisioning Project and performed extensive analysis of HL7 messages in hospitals and healthcare facilities. Additionally, Emmanuel requirements analysis for the CDC BioSense Analysis, Visualization and Reporting (AVR) project and played a key role in publishing the Situational Awareness updates to the BioSense System Requirements Specification (SRS).

Over the past 11 years, Emmanuel has worked in the Middle East, implementing the Epic EMR system at Cleveland Clinic Abu Dhabi. As a multidisciplinary team member, he has taken on various roles, including SCRUM Master, Project Manager, Integration Engineer, and Platform Engineer. Concurrently working as an adjunct university faculty member, teaching graduate-level courses in Systems Life Cycle and undergraduate courses in Health Information Systems

From a technological standpoint, Emmanuel has designed, installed, and implemented complete hospital integration systems using Rhapsody Integration Engine, MS SQL Server, and Public Health Information Networks Messaging System (PHINMS). He has also developed over 10,000 interfaces some of which coded in Java and JavaScript.

In 2019, Emmanuel expanded his skill set and entered the field of digital marketing, quickly becoming a proficient Digital Marketing Strategist. He has since helped numerous clients develop robust digital marketing strategies for their businesses. His expertise encompasses Social Media Marketing, On-page and Off-page SEO, Google Ads, and Google Analytics. Additionally, he and a team have managed clients’ website development projects, ensuring that each site is optimized for SEO, further enhancing their online presence and performance.

Alongside their digital marketing expertise, Emmanuel has delved into the world of Affiliate Marketing, where Emmanuel and his team successfully managed and executed campaigns for a variety of clients. By identifying the right products and services to promote, Emmanuel and his team helped clients generate passive income streams and increase their overall revenue.

Their approach to Affiliate Marketing involves creating valuable content that educates and engages the target audience, while strategically incorporating affiliate links. Emmanuel and his team have experience working with multiple affiliate networks and platforms, ensuring optimal tracking and reporting of performance metrics. By staying up to date with the latest trends and best practices, Emmanuel and his team have been able to optimize affiliate campaigns for maximum results, fostering long-term partnerships and sustainable growth for their clients.

As an accomplished professional, Emmanuel holds dual Bachelor of Arts degrees in Linguistics and English, a Master of Science in Health Information Systems from the University of Pittsburgh, and a Ph.D. in Information Systems from Nova Southeastern University.

My Teaching History

Professor Bazile is a dedicated technology instructor and Adjunct Faculty professor, who began his teaching career in April 2000 at the Business Career Institute in Las Vegas, Nevada.

In 2001, he expanded his expertise by training nurses in the use of Electronic Medical Records (EMR) systems. His experience in both technology and healthcare led to his appointment as an Adjunct Faculty professor at the University of Phoenix in May 2008, where he has taught several graduate-level information technology and healthcare information systems courses.

Dr. Bazile has also developed an HL7 course, which he has taught at various healthcare facilities, drawing from his own book, “HL7: Introductory and Advanced Concepts,” currently available on Amazon. With a passion for teaching and a commitment to ensuring students get the most out of each course he teaches, Dr. Bazile is a valuable asset to both his students and the institutions he serves.

My Teaching Philosophy

My teaching philosophy as an Information Systems professor in healthcare is built on the concept that education should equip students to be confident and capable problem solvers who are prepared to traverse the complicated and ever-changing landscape of Healthcare IT.

In order to accomplish this, I prioritize the creation of a dynamic and engaging learning environment that encourages students to engage with course material and with one another. This involves employing a range of teaching approaches, such as lectures, seminars, and hands-on activities, to ensure that students learn in the manner that best matches their learning style.

I believe the reason we have Information Systems as a discipline is to allow students to apply technology to solve real world problems. If that is the case, both undergraduate and graduate students have to be challenged to incorporate their core academic courses with their matriculated subjects. As such, it is important that students enter their Junior and Senior years with a strong command of the core courses such as Programming, databases, networks, hardware and software, as they serve as the foundation upon which real-world solutions will be built.

I also believe in the importance of incorporating real-world examples and case studies into my courses, as this helps to connect abstract concepts to practical applications. Additionally, I encourage students to apply what they are learning to their own personal and professional goals, as this helps to make the material more meaningful and relevant to their lives.

I strive to foster a positive and supportive learning environment where all students feel comfortable asking questions and participating in class discussions. I believe that this is key to fostering a sense of community and ensuring that all students have the opportunity to succeed.

I have also taught online courses. I have found in an asynchronous learning environment it can be difficult to apply the Peer Teaching or Experiential Learning Pedagogical Approaches. However, I have found the Discovery Learning approach to works quite well. Along with a boost to students’ self-confidence, Discovery Learning in an online environment allows students to synthesize information, expand on existing concepts on their own, while experiencing a positive outcome through trial and error.

Ultimately, my mission as an educator, and a Healthcare IT Information Systems professor is to provide students with the knowledge, skills, and confidence they need to thrive and succeed in their careers and to be technological leaders. By creating a positive and supportive learning environment, incorporating real-world examples and case studies, and encouraging students to apply what they are learning to their own objectives; my hope is to inspire and empower all students to achieve their full potential.

Population Size:

A total of 310 responses were originally received. Any response containing missing data due to unclicked radio buttons or unchecked checkboxes were first reviewed, and, if justified, were omitted from analysis. For surveys with missing data, a total of 18 responses were removed. In order to address any issues with response-set, the data was downloaded into Microsoft Access and queries ran to identify responses that contained the same values for each question. A total of 16 responses were found to be qualified for removal. Another 18 were identified as outliers and removed leaving a total of 258 responses for the study analysis.

In order to assess multivariate outliers, the Mahalanobis distances were calculated and plotted against their corresponding Chi-Square distribution percentiles (Schmidt & Hunter, 2003). The resulting scatterplot is similar to a univariate normal Q-Q plot, where deviations from a straight line show evidence of non-normality. The data showed indications of moderate deviations from multivariate normality, as indicated by the concavity of the data points. There were no additional multivariate outliers or missing values in the data after the removal of 52 responses.

Descriptive Statistics

Frequencies and percentages were conducted for the demographics indicators, while means and standard deviations were calculated for the continuous indicators. For gender, there were 151 females (59%) and 107 males (41%) in the sample. For ethnicity, most participants were Caucasian (119, 46%), followed by African American (56, 22%). The two most populous education levels were Bachelor’s (90, 35%) and Master’s (62, 22%). The biggest proportion of the sample by age group was the 35-44 age group (101, 39%) followed by the 45-54 age group (59, 23%).

Analysis:

Confirmatory Factor Analysis and Composite Reliability

A CFA was conducted along with a reliability analysis to assess construct validity. Examination of modification indices and factor loadings indicated that CSE1, CSE5, CSE7, PC5, ATE1, ATE6, ATE8, PP5, and PP6 were all causing significant problems with the model parameters. The results of the last iteration of the CFA performed in R showed significantly improved fit, although still poor overall (χ2(545) = 2125.61, p < .001, CFI = 0.82, TLI = 0.81, RMSEA = 0.11). The high degrees of freedom indicate that a very large number of parameters are being estimated in this model.

Composite Reliability

For the full model, each construct had excellent reliability. The ATE latent construct had a composite reliability value of 0.89. The ORC construct had a composite reliability value of 0.94. The CSE latent construct had a composite reliability value of 0.85 and PC had a composite reliability value of 0.95. For PP and RES, the composite reliability scores were 0.80 and 0.96 respectively. These values indicate that the loadings for each construct were all directionally similar, and that the items in each construct show a high degree of consistency.

Cronbach’s Alpha

Cronbach’s alpha values were calculated for the items in each construct. The alphas for PC (α = 0.90), AXY (α = 0.94), and RES (α = 0.94) indicated excellent reliability. The alphas for CSE (α = 0.80), ATE (α = 0.88), and PP (α = 0.83) all showed good reliability. These values confirm the results of the composite reliability tests, and reiterate the high degree of reliability within each latent construct.

Partial Least Squares – Structural Equation Modeling

A partial least squares- structural equation modeling (PLS-SEM) was conducted to determine how well the data fit the proposed model, and discern whether significant relationships existed between the independent and dependent constructs. The full model showed AVE values of 0.53 for ATE, 0.69 for AXY, 0.44 for CSE, .72 for PC, .35 for PP, and 0.81 for RES. The high values for AXY, PC, and RES indicate that the amount of variance accounted for in the manifest variables is sufficiently high. The values for ATE, CSE, and PP indicate that some of the variance in the manifest variables is left unexplained.

Structural Model

Once the measurement model had been tested for model specification, the structural model was tested to determine if ATE, AXY, CSE, PC, and PP had a significant effect on RES. A path weighted model was calculated using 10,000 bootstrap samples in R. The results showed a pseudo R-squared value of 0.78. This indicates that approximately 78% of the variance in RES is explainable by the collective effects of CSE, PC, ATE, PP, and AXY.

Further examination of the effects indicated that AXY had a highly significant effect on RES (= 0.87, < .001). This indicates that a standard deviation increase in AXY increases the expected value of RES by 0.87 standard deviations. CSE did not have a significant effect on RES (= 0.02, = .423). Additionally, CSE (= 0.02, = .423), PC (= 0.05, = .334), ATE (= 0.00, = .983), and PP (= 0.03, = .407) did not have significant effects on RES. Table 11 outlines the results of the path estimates.

Correlation Analyses

Both Pearson and Spearman correlations were calculated on the composite scores. The results of the Pearson correlations indicated that CSE was significantly correlated AXY (= 0.22, < .001) and RES (= 0.21, < .001). The results also indicated that PC was significantly correlated with ATE (= -0.79, < .001), AXY (= 0.18, < .001), and RES (= 0.20, < .001). ATE was significantly correlated with AXY (= -0.19, < .001) and RES (= -0.19, < .001). AXY was significantly correlated with RES (= 0.85, < .001).

ANCOVA Analyses

An analysis of covariance (ANCOVA) was conducted to determine if a significant relationship existed between the AXY, PP, CSE, PC, ATE scores and RES controlling for Gender, Age, Ethnicity, Education, and Specialty. The overall model was found to be significant (F(63,194) = 53.39, < .001), with an R2 value of .95, indicating that 95% of the variance in RES was explained by the collective effect of the independent variables and covariates.

Since the overall model was found to be significant, the model’s covariates were assessed. The AXY (F(10,194) = 262.20, < .001), ATE (F(7,194) = 2.20, = .036), Years computers (F(1,194) = 5.71, = .018), and PC (F(12,194) = 2.00, = .026) scores were found to be significant, indicating that a significant amount of variance in RES is explained by AXY, ATE, and PC.

A path diagram depicting the results of the structural model.

Results

This research investigated Computer Self-Efficacy (CSE), Perceived Complexity (PC), Attitudes toward EMR Systems (ATE), Peer Pressure (PP), and Anxiety (AXY) to determine whether these constructs as individuals, or as a group, or coupled together with some other factors could significantly explain resistance to EMR systems. Quantitative examination of self-reported survey results was performed to understand the strength and significance of the relationships, while these relationships were investigated to test the strength of model fit.

the regression paths of the structural model were examined to test the hypotheses. Significance was determined using an alpha level of .05. The model had an overall R2 value of 0.78. This indicates that approximately 78% of the variability in RES can be accounted for by CSE, PC, ATE, PP, and AXY. Since the overall model was significant, the individual coefficients can be interpreted. Some of the hypotheses were supported by the results of this study, and some were rejected. The construction of a data model of the relationships in this study could not meet thresholds that would be evidence of a good fit of the relationships identified in the study.

The fifth hypotheses tested the influence of AXY on resistance to EMR systems. AXY was expressed to be significantly related to resistance (r=.87, p<.001). This finding supports the hypothesis that anxiety with the EMR system will lead to medical care professionals rejecting use of the system. Unlike the findings of the first four hypotheses, the findings of the current study support previous research. Angst and Agarwal (2009) indicated that AXY is a factor which is significantly related to the problem of EMR system resistance. Based on the empirical findings of previous research, the present research and conceptual propositions and conclusions in previously written scholarly articles, there is a great deal of support for the finding that AXY is significantly influenced by EMR resistance.

The findings of this research do not support all findings by previous researchers, and there are multiple relationships which had been established as being significant that were identified as being insignificant in the current research. Generally, because of the inconsistency of previous findings and the current study there may be elements related to the sample examined or other contextual factors which may contribute to the inconsistency that exists. Ultimately, it is suggested that there be further research done on the problem of resistance to EMR system use.

Ultimately the findings support a new take on the problem of EMR system resistance that may contribute to the ways in which scholars investigate the problem of EMR resistance in general. This may also help with the way practitioners approach EMR systems, and articulate value of the systems to medical professionals investing record-keeping systems in the workplace.