From: scsu-announce-bounces@lists.stcloudstate.edu [mailto:scsu-announce-bounces@lists.stcloudstate.edu] On Behalf Of Rysavy, Sr. Del Marie
Sent: Tuesday, November 12, 2013 12:50 PM
To: scsu-announce@stcloudstate.edu
Subject: [SCSU-announce] course in programming for beginners
Our beginning programming course, CNA 267, is now using Python as the programming language. Students learn to work with decision and loop control structures, variables, lists (arrays) and procedures, etc. Python is becoming one of the most widely-accepted languages for business professionals and scientists.
Please inform your students (who need to learn programming) of this course. It is being offered during spring semester, as well as next fall.
Sr. Del Marie Rysavy
ECC 254
CSIT Department
telephone: 308-4929
Why faculty need to talk about microcredentials
There is reason to believe that shorter, competency-based programs will play an important role in the university landscape in the coming years.
Australian commentator Stephen Matchett expands: “MCs are the wild west of post-compulsory education and training, with neither law on what they actually are or order as to how they interact with formal providers. … Until (or if) this is sorted by regulators there needs to be a sheriff providing workable rules that stop the cowboys running riot.”
The lack of standards is also an issue in Canada. While degree standards have been agreed upon – the Canadian Degree Qualification framework, contained in the Council of Ministers of Education, Canada (CMEC)’s 2007 Ministerial Statement on Quality Assurance of Degree Education in Canada, outlines expectations for bachelor’s, master’s, and doctoral degrees – the CMEC has yet to issue a pan-Canadian framework for microcredentials.
In the absence of a pan-Canadian model or definition, for the purposes of this column I will use the Higher Education Quality Council of Ontario (HEQCO)’s definition, put forward in its May 2021 report, Making Sense of Microcredentials:
“A microcredential is a representation of learning, awarded for completion of a short program that is focused on a discrete set of competencies (i.e., skills, knowledge, attributes), and is sometimes related to other credentials.”
Developing and running effective microcredential programs is not simply a matter of bundling a group of existing classes into a new sub-degree level program (although there will certainly be some who try that approach). Effective microcredential programming needs to be an institution-wide effort, with appropriate resourcing and guidelines, along with effective recruiting and student support.
department chairs and other unit leaders to lead collegial discussions about the following questions:
- Gaps: who is not being served by our current degree offerings? Is there potential demand for our disciplinary knowledge and skills from people who don’t want a full degree program? Are there ways people could upgrade their skills by taking certain types of our courses? Can we identify potential short programs to meet new, distinct learning outcomes?
- Student diversity: are there opportunities to develop short programs that could introduce a new demographic of students to our discipline? How might microcredentials be developed that meet the needs and interests of Indigenous students, first-generation students, or international students?
- Connection: how might we create partnerships with external organizations to inform our understanding of skill-training needs? Can these partnerships be leveraged to create new career pathways for students, and/or new research opportunities for faculty, postdocs, and graduate students?
- Impact: in what ways do our discipline’s insights relate to Canada’s current and future public needs? How might our disciplinary knowledge be combined with knowledge from other disciplines to train students to help address particular challenges? In what ways could our discipline contribute to student competency development that we consider meaningful and impactful?
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more on microcredentials in this IMS blog
https://blog.stcloudstate.edu/ims?s=microcredential
Critical Infrastructure Studies & Digital Humanities
Alan Liu, Urszula Pawlicka-Deger, and James Smithies, Editors
Deadline for 500-word abstracts: December 15, 2021
For more info:
https://dhdebates.gc.cuny.edu/page/cfp-critical-infrastructure-studies-digital-humanities
Part of the Debates in the Digital Humanities Series A book series from the University of Minnesota Press Matthew K. Gold and Lauren F. Klein, Series Editors
Defintion
Critical infrastructure studies has emerged as a framework for linking thought on the complex relations between society and its material structures across fields such as science and technology studies, design, ethnography, media infrastructure studies, feminist theory, critical race and ethnicity studies, postcolonial studies, environmental studies, animal studies, literary studies, the creative arts, and others (see the CIstudies.org Bibliography )
CI Studies Bibliography
Debates in the Digital Humanities 2019
https://dhdebates.gc.cuny.edu/projects/debates-in-the-digital-humanities-2019
teaching quantitative methods:
https://dhdebates.gc.cuny.edu/read/untitled-f2acf72c-a469-49d8-be35-67f9ac1e3a60/section/620caf9f-08a8-485e-a496-51400296ebcd#ch19
Problem 1: Programming Is Not an End in Itself
An informal consensus seems to have emerged that if students in the humanities are going to make use of quantitative methods, they should probably first learn to program. Introductions to this dimension of the field are organized around programming languages: The Programming Historian is built around an introduction to Python; Matthew Jockers’s Text Analysis with R is at its heart a tutorial in the R language; Taylor Arnold and Lauren Tilton’s Humanities Data in R begins with chapters on the language; Folgert Karsdorp’s Python Programming for the Humanities is a course in the language with examples from stylometry and information retrieval.[11] “On the basis of programming,” writes Moretti in “Literature, Measured,” a recent retrospective on the work of his Literary Lab, “much more becomes possible”
programming competence is not equivalent to competence in analytical methods. It might allow students to prepare data for some future analysis and to produce visual, tabular, numerical, or even interactive summaries; Humanities Data in R gives a fuller survey of the possibilities of exploratory data analysis than the other texts.[15] Yet students who have focused on programming will have to rely on their intuition when it comes to interpreting exploratory results. Intuition gives only a weak basis for arguing about whether apparent trends, groupings, or principles of variation are supported by the data.
From Humanities to Scholarship: Librarians, Labor, and the Digital
Bobby L. Smiley
https://dhdebates.gc.cuny.edu/read/untitled-f2acf72c-a469-49d8-be35-67f9ac1e3a60/section/bf082d0f-e26b-4293-a7f6-a1ffdc10ba39#ch35
First hired as a “digital humanities librarian,” I saw my title changed within less than a year to “digital scholarship librarian,” with a subject specialty later appended (American History). Some three-plus years later at a different institution, I now find myself a digital-less “religion and theology librarian.” At the same time, in this position, my experience and expertise in digital humanities (or “digital scholarship”) are assumed, and any associated duties are already baked into the job description itself.
Jonathan Senchyne has written about the need to reimagine library and information science graduate education and develop its capacity to recognize, accommodate, and help train future library-based digital humanists in both computational research methods and discipline-focused humanities content (368–76). However, less attention has been paid to tracking where these digital humanities and digital scholarship librarians come from, the consequences and opportunities that arise from sourcing librarians from multiple professional and educational stations, and the more ontological issues associated with the nature of their labor—that is, what is understood as work for the digital humanist in the library and what librarians could be doing.
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More on digital humanities in this blog
https://blog.stcloudstate.edu/ims?s=Digital+humanities
After studying children ages 4 to 11 on their use of screen time, a University of Michigan study found that “how children use the devices, not how much time they spend on them, is the strongest predictor of emotional or social problems connected with screen addiction.”
According to an Australian study on active and passive screen uses, there are actually two types of active screen use: physical and cognitive. Kids can actually get similar benefits to physical exercise when they play with active video game systems like the Nintendo Switch, XBox Kinect or Pokemon Go.
Playing active games has been proven to have similar effects to moderate walking, skipping and jogging. There are also plenty of active screen uses that spark the cognitive side of the brain.
Studies show that children respond to activity-based programming when it is fun, designed for them and encourages imitation or participation.
Emerging Trends and Impacts of the Internet of Things in Libraries
https://www.igi-global.com/gateway/book/244559
Chapters:
Holland, B. (2020). Emerging Technology and Today’s Libraries. In Holland, B. (Eds.), Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 1-33). IGI Global. http://doi:10.4018/978-1-7998-4742-7.ch001
The purpose of this chapter is to examine emerging technology and today’s libraries. New technology stands out first and foremost given that they will end up revolutionizing every industry in an age where digital transformation plays a major role. Major trends will define technological disruption. The next-gen of communication, core computing, and integration technologies will adopt new architectures. Major technological, economic, and environmental changes have generated interest in smart cities. Sensing technologies have made IoT possible, but also provide the data required for AI algorithms and models, often in real-time, to make intelligent business and operational decisions. Smart cities consume different types of electronic internet of things (IoT) sensors to collect data and then use these data to manage assets and resources efficiently. This includes data collected from citizens, devices, and assets that are processed and analyzed to monitor and manage, schools, libraries, hospitals, and other community services.
Makori, E. O. (2020). Blockchain Applications and Trends That Promote Information Management. In Holland, B. (Eds.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 34-51). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch002Blockchain revolutionary paradigm is the new and emerging digital innovation that organizations have no choice but to embrace and implement in order to sustain and manage service delivery to the customers. From disruptive to sustaining perspective, blockchain practices have transformed the information management environment with innovative products and services. Blockchain-based applications and innovations provide information management professionals and practitioners with robust and secure opportunities to transform corporate affairs and social responsibilities of organizations through accountability, integrity, and transparency; information governance; data and information security; as well as digital internet of things.
Hahn, J. (2020). Student Engagement and Smart Spaces: Library Browsing and Internet of Things Technology. In Holland, B. (Eds.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 52-70). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch003The purpose of this chapter is to provide evidence-based findings on student engagement within smart library spaces. The focus of smart libraries includes spaces that are enhanced with the internet of things (IoT) infrastructure and library collection maps accessed through a library-designed mobile application. The analysis herein explored IoT-based browsing within an undergraduate library collection. The open stacks and mobile infrastructure provided several years (2016-2019) of user-generated smart building data on browsing and selecting items in open stacks. The methods of analysis used in this chapter include transactional analysis and data visualization of IoT infrastructure logs. By analyzing server logs from the computing infrastructure that powers the IoT services, it is possible to infer in greater detail than heretofore possible the specifics of the way library collections are a target of undergraduate student engagement.
Treskon, M. (2020). Providing an Environment for Authentic Learning Experiences. In Holland, B. (Eds.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 71-86). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch004The Loyola Notre Dame Library provides authentic learning environments for undergraduate students by serving as “client” for senior capstone projects. Through the creative application of IoT technologies such as Arduinos and Raspberry Pis in a library setting, the students gain valuable experience working through software design methodology and create software in response to a real-world challenge. Although these proof-of-concept projects could be implemented, the library is primarily interested in furthering the research, teaching, and learning missions of the two universities it supports. Whether the library gets a product that is worth implementing is not a requirement; it is a “bonus.”
Rashid, M., Nazeer, I., Gupta, S. K., & Khanam, Z. (2020). Internet of Things: Architecture, Challenges, and Future Directions. In Holland, B. (Ed.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 87-104). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch005The internet of things (IoT) is a computing paradigm that has changed our daily livelihood and functioning. IoT focuses on the interconnection of all the sensor-based devices like smart meters, coffee machines, cell phones, etc., enabling these devices to exchange data with each other during human interactions. With easy connectivity among humans and devices, speed of data generation is getting multi-fold, increasing exponentially in volume, and is getting more complex in nature. In this chapter, the authors will outline the architecture of IoT for handling various issues and challenges in real-world problems and will cover various areas where usage of IoT is done in real applications. The authors believe that this chapter will act as a guide for researchers in IoT to create a technical revolution for future generations.
Martin, L. (2020). Cloud Computing, Smart Technology, and Library Automation. In Holland, B. (Eds.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 105-123). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch006As technology continues to change, the landscape of the work of librarians and libraries continue to adapt and adopt innovations that support their services. Technology also continues to be an essential tool for dissemination, retrieving, storing, and accessing the resources and information. Cloud computing is an essential component employed to carry out these tasks. The concept of cloud computing has long been a tool utilized in libraries. Many libraries use OCLC to catalog and manage resources and share resources, WorldCat, and other library applications that are cloud-based services. Cloud computing services are used in the library automation process. Using cloud-based services can streamline library services, minimize cost, and the need to have designated space for servers, software, or other hardware to perform library operations. Cloud computing systems with the library consolidate, unify, and optimize library operations such as acquisitions, cataloging, circulation, discovery, and retrieval of information.
Owusu-Ansah, S. (2020). Developing a Digital Engagement Strategy for Ghanaian University Libraries: An Exploratory Study. In Holland, B. (Eds.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 124-139). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch007This study represents a framework that digital libraries can leverage to increase usage and visibility. The adopted qualitative research aims to examine a digital engagement strategy for the libraries in the University of Ghana (UG). Data is collected from participants (digital librarians) who are key stakeholders of digital library service provision in the University of Ghana Library System (UGLS). The chapter reveals that digital library services included rare collections, e-journal, e-databases, e-books, microfilms, e-theses, e-newspapers, and e-past questions. Additionally, the research revealed that the digital library service patronage could be enhanced through outreach programmes, open access, exhibitions, social media, and conferences. Digital librarians recommend that to optimize digital library services, literacy programmes/instructions, social media platforms, IT equipment, software, and website must be deployed. In conclusion, a DES helps UGLS foster new relationships, connect with new audiences, and establish new or improved brand identity.
Nambobi, M., Ssemwogerere, R., & Ramadhan, B. K. (2020). Implementation of Autonomous Library Assistants Using RFID Technology. In Holland, B. (Ed.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 140-150). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch008This is an interesting time to innovate around disruptive technologies like the internet of things (IoT), machine learning, blockchain. Autonomous assistants (IoT) are the electro-mechanical system that performs any prescribed task automatically with no human intervention through self-learning and adaptation to changing environments. This means that by acknowledging autonomy, the system has to perceive environments, actuate a movement, and perform tasks with a high degree of autonomy. This means the ability to make their own decisions in a given set of the environment. It is important to note that autonomous IoT using radio frequency identification (RFID) technology is used in educational sectors to boost the research the arena, improve customer service, ease book identification and traceability of items in the library. This chapter discusses the role, importance, the critical tools, applicability, and challenges of autonomous IoT in the library using RFID technology.
Priya, A., & Sahana, S. K. (2020). Processor Scheduling in High-Performance Computing (HPC) Environment. In Holland, B. (Ed.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 151-179). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch009Processor scheduling is one of the thrust areas in the field of computer science. The future technologies use a huge amount of processing for execution of their tasks like huge games, programming software, and in the field of quantum computing. In real-time, many complex problems are solved by GPU programming. The primary concern of scheduling is to reduce the time complexity and manpower. Several traditional techniques exit for processor scheduling. The performance of traditional techniques is reduced when it comes to the huge processing of tasks. Most scheduling problems are NP-hard in nature. Many of the complex problems are recently solved by GPU programming. GPU scheduling is another complex issue as it runs thousands of threads in parallel and needs to be scheduled efficiently. For such large-scale scheduling problems, the performance of state-of-the-art algorithms is very poor. It is observed that evolutionary and genetic-based algorithms exhibit better performance for large-scale combinatorial and internet of things (IoT) problems.
Librarians are beginning to offer virtual reality (VR) services in libraries. This chapter reviews how libraries are currently using virtual reality for both consumption and creation purposes. Virtual reality tools will be compared and contrasted, and recommendations will be given for purchasing and circulating headsets and VR equipment. Google Tour Creator and a smartphone or 360-degree camera can be used to create a virtual tour of the library and other virtual reality content. These new library services will be discussed along with practical advice and best practices for incorporating virtual reality into the library for instructional and entertainment purposes.
Heffernan, K. L., & Chartier, S. (2020). Augmented Reality Gamifies the Library: A Ride Through the Technological Frontier. In Holland, B. (Ed.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 194-210). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch011Two librarians at a University in New Hampshire attempted to integrate gamification and mobile technologies into the exploration of, and orientation to, the library’s services and resources. From augmented reality to virtual escape rooms and finally an in-house app created by undergraduate, campus-based, game design students, the library team learned much about the triumphs and challenges that come with attempting to utilize new technologies to reach users in the 21st century. This chapter is a narrative describing years of various attempts, innovation, and iteration, which have led to the library team being on the verge of introducing an app that could revolutionize campus discovery and engagement.
Miltenoff, P. (2020). Video 360 and Augmented Reality: Visualization to Help Educators Enter the Era of eXtended Reality. In Holland, B. (Eds.),
Emerging Trends and Impacts of the Internet of Things in Libraries (pp. 211-225). IGI Global.
http://doi:10.4018/978-1-7998-4742-7.ch012The advent of all types of eXtended Reality (XR)—VR, AR, MR—raises serious questions, both technological and pedagogical. The setup of campus services around XR is only the prelude to the more complex and expensive project of creating learning content using XR. In 2018, the authors started a limited proof-of-concept augmented reality (AR) project for a library tour. Building on their previous research and experience creating a virtual reality (VR) library tour, they sought a scalable introduction of XR services and content for the campus community. The AR library tour aimed to start us toward a matrix for similar services for the entire campus. They also explored the attitudes of students, faculty, and staff toward this new technology and its incorporation in education, as well as its potential and limitations toward the creation of a “smart” library.
