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Friday, March 24, 2023

Citing ChatGPT: A Comprehensive Guide on Proper Attribution

Citing ChatGPT: A Comprehensive Guide to Proper Attribution

Introduction:

ChatGPT, an AI-generated content tool, has become an increasingly popular resource for users seeking information or assistance with various tasks. However, citing ChatGPT as a source might be a novel concept for many. In this guide, we will create a hypothetical citation for ChatGPT in various citation formats and explain how to correctly attribute information obtained from ChatGPT.

Hypothetical Information:

Suppose you used ChatGPT to generate information about the impacts of climate change on polar bear populations. The AI model provided a comprehensive analysis on March 24, 2023.

Citation Formats:

APA (7th Edition)

OpenAI. (2023). Impacts of climate change on polar bear populations [ChatGPT-generated content]. Retrieved March 24, 2023, from https://www.example.com/chatgpt/conversation-id

MLA (8th Edition)

OpenAI. "Impacts of Climate Change on Polar Bear Populations." ChatGPT-generated content, March 24 2023, https://www.example.com/chatgpt/conversation-id.

Chicago (17th Edition)

OpenAI. 2023. "Impacts of Climate Change on Polar Bear Populations." ChatGPT-generated content. Accessed March 24, 2023. https://www.example.com/chatgpt/conversation-id.

A step-by-step guide to citing ChatGPT:

Identify the source:

In this case, the source is ChatGPT, an AI model developed by OpenAI. Therefore, the content generated by ChatGPT should be cited as "ChatGPT-generated content."

Determine the citation format:

Select the appropriate citation format (e.g., APA, MLA, or Chicago) depending on the requirements of your work. Each design has specific guidelines, so adhering to the respective citation style is essential.

Include the author:

For ChatGPT-generated content, the author should be cited as "OpenAI." This attribution acknowledges the organization responsible for creating and maintaining the AI model.

Add the title of the content:

Provide a descriptive title for the generated content in the citation. In this example, we used "Impacts of Climate Change on Polar Bear Populations" as the title.

Specify the content type:

Indicate that ChatGPT generates the content by including "ChatGPT-generated content" in the citation.

Include the date:

Add the date when the ChatGPT-generated content was accessed or generated. This information is crucial, as AI models like ChatGPT are continually updated and can produce different results over time.

Provide the URL:

Lastly, include the URL where the ChatGPT-generated content was obtained. If you have a direct link to the conversation or the unique identifier for the generated content, this information should be included in the citation. If no specific URL is available, you may use the general URL for the ChatGPT platform.

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#OpenAI

ChatGPT Library Research Templates

Creating generic library reference search templates can help streamline the search process when finding resources or information. 

Here are some generic ChatGPT Library Research templates that can be used in various contexts:

Author search template:

"[Author's first name] [Author's last name] works"

Title search template:

"[Book/Article/Journal title] by [Author's name]"

Subject search template:

"[Subject/Topic] resources/articles/books"

Keyword search template:

"[Keyword 1] [Keyword 2] [Keyword 3]"

Publication date range search template:

"[Publication type] published between [Year range start] and [Year range end]"

Library call number search template:

"Call number: [Call number prefix] [Call number]"

ISBN/ISSN search template:

"ISBN: [ISBN number]" or "ISSN: [ISSN number]"

Format search template:

"[Format type] materials (e.g., e-books, audiobooks, DVDs, etc.)"

Language search template:

"[Language] materials/resources"

Advanced search template:

"[Search term 1] AND/OR [Search term 2] NOT [Search term 3]"

Remember to replace the brackets and their content with the appropriate search terms, depending on your query.

Topic Overview Search Template:

[Topic] + "overview" OR "introduction" OR "summary" OR "guide"
Example:
climate change + "overview" OR "introduction" OR "summary" OR "guide"

Academic Research Search Template:

[Topic] + "research" OR "study" OR "journal article" OR "peer-reviewed" + [Keywords]

 Example:
 artificial intelligence + "research" OR "study" OR "journal article" OR "peer-reviewed" + ethics

Historical Context Search Template:

[Topic] + "history" OR "historical context" OR "origins" OR "timeline"

Example:
feminism + "history" OR "historical context" OR "origins" OR "timeline"

Biographical Information Search Template:

[Person's Name] + "biography" OR "background" OR "profile" OR "life story"

Example:
Jane Austen + "biography" OR "background" OR "profile" OR "life story"

Local and Regional Information Search Template:

[Location] + "history" OR "culture" OR "economy" OR "geography" + [Keywords or specific aspects]

Example: 
New York City + "history" OR "culture" OR "economy" OR "geography" + architecture


Dealing with ambiguous ChatGPT answers

It is essential to recognize that AI language models like ChatGPT are trained on large datasets of text from the internet. 

Their knowledge is derived from the patterns, information, and structures they've been exposed to during training. 

However, these models do not possess human-like understanding or reasoning. Consequently, they sometimes need to provide more precise answers.

Here are a few factors that contribute to ambiguous answers:

Vague or broad prompts:

If the input prompt is too broad or ambiguous, the AI model might need help identifying the precise information you seek. For example, if you ask, "What is the best way to learn?" the answer might be unclear because "best" is subjective and depends on the individual and the subject matter. A more specific prompt, such as "What are some effective study techniques for learning a new language?" will likely yield a more precise answer.

Ambiguity in the question itself: 

The AI will likely generate a vague answer if the question contains ambiguous wording.

Multiple interpretations:

Some questions can have multiple valid interpretations. 

For instance, if you ask, "How can I improve my computer?" the AI might be unsure if you're referring to upgrading hardware, updating software, or enhancing performance. 

Therefore, a more specific prompt, such as "What are some hardware upgrades to improve my computer's gaming performance?" would be more explicit.

Absence of a definitive answer: 

Some questions may have a vague-cut answer, making it difficult for the AI to respond concisely.

Ambiguity in the training data:

The AI's training data may contain conflicting or ambiguous information, which can result in the AI generating unclear answers.

Limitations of the AI model:

AI language models have inherent limitations in understanding and reasoning capabilities, sometimes leading to ambiguous responses.

Unclear terminology: 

If a question contains jargon, slang, or unclear terms, the AI might need help to provide a clear answer.

Insufficient context:

The AI might only understand the topic or situation if a question has sufficient context. For example, asking, "What should I do next?" could lead to a wide range of answers. Providing more context, like "After completing my Master's degree in Library Science, what are some career options to consider?" will help the AI generate a more focused response.

Overlapping topics or concepts:

Questions that touch on multiple related issues or concepts can result in ambiguous answers, as the AI may need help discerning which aspect to focus on.

Implicit Biases: 

AI models may unintentionally reproduce biases in their training data, leading to ambiguous or skewed answers.

To improve the clarity of answers from an AI language model, consider the following tips when crafting prompts:

What to do.

Phrase questions clearly:

Use concise language and avoid complex sentence structures to minimize the possibility of misinterpretation.

Use relevant keywords:

Include essential terms or concepts related to your topic to help the AI focus on the specific area you're interested in.

Request step-by-step explanations:

Request a step-by-step breakdown to ensure a more comprehensive response when requesting a solution or procedure.

Set boundaries:

Define any constraints or limitations to help the AI respond to your requirements.

Encourage comparison:

If seeking advice on multiple options, ask the AI to compare and contrast them to provide a more nuanced understanding.

Specify the desired format: 

If you prefer how the information should be presented (e.g., a list, a summary, or a detailed explanation), mention it in your prompt.

Clarify the purpose: 

Explain your question's intended use or goal to help the AI generate a more relevant and targeted response.

Incorporate timeframes:

If applicable, mention relevant timeframes or deadlines to ensure the AI's response is timely and appropriate for your situation.

Wednesday, March 22, 2023

AI Changes Librarian Science Search




Discovering scientific information involves not only searching for keywords in databases but also considering the relevance, presentation, and accessibility of the content. 

The digital age has brought new technologies and challenges that affect how we discover information, making information literacy essential for managing the increasing volume of publications. 

Various search methods, such as keyword and natural language searching, APIs, and linked data interfaces, are used to retrieve information from multiple sources. 

Browsing, skimming, and scanning are quick ways to find relevant information, and semantic search engines can improve retrieval performance. 

As a librarian, staying informed about new search engines and technologies is essential, considering appropriate resources for finding scientific literature and understanding the different search options and ways to refine results. 

Text mining, visualization, and linked data can help manage and discover information, while citation linking and cited reference searching have become powerful tools for finding scientific information.
 Serendipitous connections and accidental information discovery can lead to critical new themes in research while sharing research data and depositing it in publicly accessible databases can increase discoverability.

New technologies based on AI are transforming the way scientists do research, communicate findings, and discover scientific information. At the same time, social networks enable researchers to connect, collaborate, and stay up-to-date with the latest research in their field.

Tuesday, March 21, 2023

Evaluating the Success of Academic Libraries in an Evolving Landscape

Academic libraries have traditionally played a central role in supporting higher education institutions' teaching, learning, and research activities. 

Over the last 15-20 years, however, the landscape has changed dramatically, with rapid advancements in technology, shifting user preferences, and the expanding roles of libraries within higher education. As the information environment evolves, academic libraries must adapt their strategies and services to maintain their value to stakeholders and the academic community. 


A critical component of this adaptation involves reevaluating the metrics used to measure the success of these essential institutions. Understanding how libraries have historically measured their success and identifying ways to update these measures to reflect their role and effectiveness is crucial for ensuring the continued provision of meaningful and relevant services in an ever-changing landscape.

Traditional Success Metrics in Academic Libraries

Traditional Metrics of Success


Over the past fifteen to twenty years, academic libraries have used various metrics to gauge their success. These metrics have primarily fallen into two categories: input and output measures.


Traditional success metrics often need to capture the full scope of the services and resources provided by modern academic libraries. Historically, academic libraries have relied on quantitative measures such as collection size, circulation statistics, gate counts, reference transactions, and library expenditures to assess their performance. 


For example, they may need to adequately account for digital resources, online services, and collaborative spaces that have become increasingly important in recent years.


Additionally, these metrics prioritize quantitative data over qualitative information, which can lead to an incomplete understanding of how well the library meets the diverse needs of its users and the broader academic community.


  • Collection size:


The library's number of physical and digital resources, such as books, journals, and multimedia.


  • Circulation statistics:


The frequency of resource borrowing and usage.


  • Reference transactions:


The number of interactions between librarians and users to provide research assistance.


  • Instruction sessions: 


The number of library-led workshops or training sessions.



These traditional measures have been crucial for several reasons:


These measures have been necessary for demonstrating the libraries' value to stakeholders, such as university administrators, funding bodies, and accreditation agencies. 


And have also served as indicators of the libraries' commitment to providing robust collections and services to meet the needs of their users.


Accountability:


Quantitative metrics allow libraries to explain their value and justify budget allocations to university administrations and funding agencies.


Benchmarking:


Libraries can compare their performance against similar institutions, enabling them to identify areas of strength and opportunities for improvement.


Decision-making


Metrics guide collection development, staffing, and service provision by helping libraries understand user needs and preferences.



Input Measures


Input measures focus on the resources invested in the library, including:


  • Budget allocations

  • Collection size

  • Staff numbers


These measures have been necessary for understanding the level of financial support and resource allocation the library receives, which can impact its ability to provide comprehensive services.

Output Measures


Output measures track the results produced by the library, including:


  • Circulation statistics,

  • Reference transactions

  • Library instruction sessions


These metrics have been essential for assessing the immediate impact of library services on users and their perceived value by the academic community.



The Need for New Measures


Standard input and output measures have been valuable in understanding the resources and services provided by academic libraries. However, these metrics have limitations in capturing the evolving roles of these institutions within the broader intellectual landscape, particularly in light of the technological advancements that have transformed libraries over time.


Historically, libraries have transitioned from primarily physical spaces, housing print materials and focusing on in-person services to digital resources and technology. This shift began with the introduction of computerized library systems and the digitization of catalog records in the late 20th century. The advent of the internet and the proliferation of electronic resources, such as e-books and digital databases, further accelerated this transformation.


As libraries evolve from repositories of physical materials to information creation and dissemination hubs, it becomes increasingly important to accurately gauge their success using measures that reflect these changes. The rapid advancements in digital technology, the growing reliance on electronic resources, and the evolving roles of libraries necessitate the adoption of new success metrics that consider the following aspects:


  • Emphasizing the user-centric approach:


  • New metrics prioritize the needs and experiences of library users, ensuring that libraries remain relevant and responsive to their communities.


  • Capturing qualitative dimensions: 


  • Evaluating library services and resources based on user satisfaction, learning outcomes, and research impact provides a more nuanced understanding of the library's value.


  • Personalized services: 


  • By evaluating user satisfaction and preferences, libraries can tailor their services to serve individual needs better.


  • Research impact: 


  • Measuring the library's role in supporting and enhancing faculty research productivity and quality.


  • Learning outcomes: 


  • Assessing the library's contribution to developing students' information literacy and critical thinking skills.


  • Community engagement: 


  • Evaluating the library's outreach efforts and partnerships with various stakeholders within and beyond the academic community.


  • Support for research and learning: 


  • By assessing learning outcomes and research impact, libraries can continually refine their instructional programs, workshops, and research support services.


  • Digital Resource Usage:


  • As digital resources become increasingly important, measuring their usages, such as e-book downloads and database access, can provide a more accurate picture of the library's role in the digital age.


  • Technological Infrastructure:


  • Assessing the library's technological infrastructure, including hardware, software, and network capabilities, can help determine how effectively it adapts to technological advancements and serves its users in an increasingly digital environment.


  • Digital Literacy and Support: 


  • Evaluating the library's efforts to promote digital literacy through workshops, tutorials, and other support services, can demonstrate its commitment to empowering users in the digital age.


  • Online Services and User Experience:


  • Analyzing the quality and effectiveness of online services, such as virtual reference, digital repositories, and user-friendly interfaces, can offer insights into how well the library is meeting users' needs in a digital context.


  • Collaborative Initiatives


  • By measuring community engagement, libraries can build strategic partnerships and expand their reach to serve diverse populations and address societal challenges.


  • Participation in interdisciplinary research, partnerships with other institutions, and community outreach programs can demonstrate the library's commitment to fostering collaboration and engagement beyond its walls.


The Benefits of Adopting New Metrics


By adopting these new success metrics, academic libraries can more effectively demonstrate their impact on users and the broader academic community. In addition, these measures provide a more comprehensive understanding of the library's role in supporting research, teaching, and learning and its ability to adapt to changing user needs and preferences.


By adopting new success metrics that account for the technological history and ongoing evolution of libraries, academic institutions can better assess the impact and effectiveness of their libraries in the digital age, ensuring their continued relevance and value to the academic community.