Artificial Intelligence-Driven Talent Management System: Exploring the Risks and Options for Constructing a Theoretical Foundation
Abstract
:1. Introduction
2. Background of the Study
2.1. Ethical, Cultural, Relational and Personal Implications of AI
2.2. Application of AI in Talent Management
2.2.1. Talent Acquisition
2.2.2. Talent Development
2.2.3. Talent Retention
2.3. Risks Management for AI Adoption
2.4. AI in Small and Medium-Sized Enterprises
2.5. Theories in Technological Adoption
2.6. TOE Framework and DOI Theory
2.6.1. Technological Factors
2.6.2. Organizational Factors
2.6.3. Environmental Factors
2.6.4. Talent and Organisational Agility
3. Design Science Methodology
3.1. Big Data in Talent Management
3.2. Risk Mitigation
- Create a legally enforceable code of ethics for AI that takes into account human conventions, values, and cultures.
- Ensure human oversight and monitoring of AI choices respecting fundamental rights, equality, and non-discrimination.
- Install a high-quality talent management system to guarantee ethically sound AI decision-making and dataset quality.
- Convert AI’s moral code into a programming language, and continuously train and test AI systems to guarantee that it is being used correctly.
- Ensure that AI systems do not infringe on people’s autonomy and freedom (e.g., decision-making).
- Before a product is launched, make sure that it complies with ethical standards that have been trained for and tested.
4. Proposed AI Oriented TM Approach
- CV Screening: Supervised learning algorithms such as Support Vector Machines (SVMs) and Decision Trees can be used to classify and score resumes based on their relevance and suitability for a particular job.
- Job Matchmaking: Unsupervised learning algorithms such as K-Means Clustering and Collaborative Filtering can be used to identify and match job seekers with job opportunities based on their skills, experience, and preferences.
- Personality trait Assessment: One common approach is to use machine learning algorithms, such as decision trees or support vector machines, to classify and score individuals based on their answers to a series of personality trait-related questions. These algorithms can be trained on a large dataset of personality trait assessments to accurately predict an individual’s personality traits based on their responses to the questions. Another approach is to use natural language processing (NLP) techniques to analyze written or spoken responses and extract personality traits based on the words and phrases used. This approach can be particularly useful for assessing personality traits in unstructured data, such as open-ended responses to interview questions.
- Career Guidance Chatbot: Natural Language Processing (NLP) algorithms such as Text Classification and Sentiment Analysis can be used to identify and analyze the questions and concerns of talent, and to provide personalized and relevant career guidance.
- Attrition Predictive: Supervised learning algorithms such as Random Forests and Gradient Boosting can be used to predict the likelihood of talent attrition based on various factors such as salary, job satisfaction, and career development opportunities.
- Talent Training Recommendation: Collaborative Filtering algorithms can be used to identify and recommend relevant training courses and programs for employees based on their skills, experience, and career goals.
5. Discussion and Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Studies Done on AI Applications in Talent Management | Used ML Approaches | Key Findings of the Papers |
---|---|---|
(Fritts and Cabrera 2021) | ML concepts identification | Examines the issue of recruitment algorithms with an eye toward the under-explored concerns of HR managers. |
(Xiao and Yi 2021) | Tensorflow platform for supervised ML | Implements a design using AI to career planning or related areas. |
(Joshi et al. 2020) | Support Vector Machine (SVM) | Builds AI solutions for career-related services. |
(Zhao et al. 2021) | Algorithm model design | AI for addressing fairness concerns for designing recruitment systems |
(Aleisa et al. 2022) | A minimum viable product (MVP), Natural Language Processing (NLP), and explanatory knowledge derived system. | AI architecture that holds AI models and a data repository for recruiting models |
(Shafagatova and Van Looy 2021) | Supervised ML | AI for “process-oriented appraisals and rewards” |
(Meng and Dai 2021) | Supervised ML | Utilises the design routine of modular design, real-time evaluation, and standard analysis for assessing people’s emotional stability |
DSR Adopted Guideline | Its Relevant to the Proposed Solution |
---|---|
Guideline 1: Design as an Artifact: Design: | Design-science research must result in a valid construct, model, technique, or instance. |
Guideline 2: Problem Relevance: | The objective of design-science research is to create technological response to significant business issues. Identified is a genuine issue domain that supports the specified software solution prototype. |
Guideline 3: Design Evaluation: | The utility, quality, and feasibility of a AI design need to be stringently shown by well-executed assessment procedures in order to satisfy the requirements. For prototype testing with industry various stakeholders, a descriptive assessment approach will be used with utilizing secondary data. |
Guideline 4: Research Contributions: | The models utilised for the AI artifact’s features were designed by domain specialists with information gleaned from actual practice, through prototyping. |
Guideline 5: Research Rigor: | DSR is dependent on the use of rigors procedures in the creation and assessment of the AI design artefact informing through IS theories. |
Guideline 6: Design as a Search Process: | The search for a functional artefact necessitates the utilisation of accessible ways to achieve desired purposes in compliance with the issue domain, |
Guideline7: Communication of Research: | DSR will help successfully communicated about the research outcome to both technical and managerial groups. |
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Faqihi, A.; Miah, S.J. Artificial Intelligence-Driven Talent Management System: Exploring the Risks and Options for Constructing a Theoretical Foundation. J. Risk Financial Manag. 2023, 16, 31. https://doi.org/10.3390/jrfm16010031
Faqihi A, Miah SJ. Artificial Intelligence-Driven Talent Management System: Exploring the Risks and Options for Constructing a Theoretical Foundation. Journal of Risk and Financial Management. 2023; 16(1):31. https://doi.org/10.3390/jrfm16010031
Chicago/Turabian StyleFaqihi, Ali, and Shah Jahan Miah. 2023. "Artificial Intelligence-Driven Talent Management System: Exploring the Risks and Options for Constructing a Theoretical Foundation" Journal of Risk and Financial Management 16, no. 1: 31. https://doi.org/10.3390/jrfm16010031
APA StyleFaqihi, A., & Miah, S. J. (2023). Artificial Intelligence-Driven Talent Management System: Exploring the Risks and Options for Constructing a Theoretical Foundation. Journal of Risk and Financial Management, 16(1), 31. https://doi.org/10.3390/jrfm16010031