Education Technology
Article | July 14, 2022
Due to the increased exposures and positive COVID-19 cases, the educational industry is adapting to the fourth industrial revolution more swiftly than intended. Both students and educational institutions are realizing the requirement of technology to support the learning process. It has also led to the development of digital badges and the adoption of blockchain in this sector.
But, why should we adopt blockchain? Blockchain which is originally known as being the support of digital currencies like bitcoin is not new to the academe. Blockchain can be used as a validation tool for learning. With blockchain as the backbone of the educational system, institutions will become able to list courses, manage training badges, and issue certificates to the students. It will in return reduce the chances of issuing fraudulent certificates. Moreover, having high-end encryption, even the most experienced hackers will not be able to tamper the credentials.
And, what’s a digital badge? A digital badge validates the accomplishment, skills, and certifications of students. It can also be offered to the student after completing internships.
In the educational sector, a digital badge can be acquired by a student after learning a skill or completing a course. It should be considered by every institution to help students in showcasing their skills in the job market as well. The digital badges are multipurpose. It can be used for certifications to show the acquired skills, transparency for other universities or schools to collect key details of the student, and validation to show that the individual has participated in a workshop or training program.
Besides the basic reasons discussed, how these digital badges can help and why should institutions opt for digital badges?
Why Should Educational Institutions Opt For Digital Badges?
Among numerous reasons why an educational institution should go for digital badges, let’s check some of the most important reasons.
Personalized Learning
Micro-credentials help in dividing the part of the subjects into certain skills that enables students and educational institutions to design plans according to their needs. With the availability of personalized learning, a learner can complete the course anywhere regardless of the time and earn a badge.
Skill-Based Learning
A digital badge can enable students to showcase their skills while applying for an internship or part-time job. These badges must be connected with professional capabilities that confirm that it is worthy to the students. These skill badges either can be for technical skills like programming or soft skills like leadership, teamwork, and so on.
Open Standards
As we know that digital badges are verifiable, it offers a chance for students to learn something outside their typical classroom. It increases the achievement and abilities of the students creating a new opportunity for them at the time of recruitment.
Some of the companies and institutions that are using digital certifications include Certif-ID, Stamford University, Georgetown University, and MIT. For those who want to implement blockchain and digital badges in their educational institutions, you can easily hire developers that will build a powerful system to glorify the entire education process.
Wrapping it up!
To maintain educational records, a digital badge is the most innovative solution. Moreover, the education industry is gradually moving towards record maintenance on blockchain to eliminate fake degrees due to which many deserving candidates lose their chance to attain better opportunities. It is also beneficial for the companies as they will not have to hire less staff for cross-checking the information which will increase their profitability and productivity as well. Despite the increasing acceptance of digital badges and blockchain in the education sector, many educators are unaware of their power. Plausibly, it is about to change soon.
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Online Education
Article | July 12, 2022
This entry is the 13th in a blog series called Pandemic Response and Educational Practices (PREP), which aims to highlight and further the important work educators are doing amid the worldwide COVID-19 crisis. Based on Creating the Anywhere, Anytime Classroom. Gloria’s situation is not unfamiliar. In fact, over the last six months, millions of teachers everywhere have been asked to suddenly transition from traditional face-to-face instruction to working either fully online or in some type of blended-learning configuration.
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Education Technology
Article | July 15, 2022
Artificial Intelligence is a branch of science producing and studying the machines aimed at the stimulation of human intelligence processes. The main objective of AI is to optimize the routine processes, improving their speed and efficiency (provided it has been implemented and supported properly). As a result, the number of companies adopting AI continues to grow worldwide. According to Research and Markets, “The analysts forecast the Artificial Intelligence Market in the US Education Sector to grow at a CAGR of 47.77% during the period 2018-2022.
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Education Technology
Article | December 9, 2021
After almost two years of disruption due to the pandemic, our ongoing recovery has highlighted the value of embracing change and working much more flexibly than before, refusing to give up at the first hurdle and a willingness to work together to achieve a common goal. These transferable skills are becoming ever more important for us to thrive in our increasingly automated world, and they are skills that can be developed and embedded through the medium of mathematics.
Fluency, reasoning, and problem-solving are the three foundations of our mathematics curriculum. By valuing them all, we will ensure that our future workforce has the confidence and skills to work together much more effectively to solve problems, overcome hurdles, and sustain our recovery. Let’s begin with fluency. Although AI is becoming increasingly prevalent, benefiting both our social and working lives, we still need number skills, perhaps now more than ever. Too many high-profile technology projects have failed due to basic mathematical errors. We need our education system to nurture the types of number skills needed in industry, especially a much greater focus on using and applying number skills. We must encourage students to develop their confidence in estimating quantities and a willingness to check calculations, even when they’ve used a spreadsheet or calculator.
From NASA’s disintegrating space probes to trains that don’t fit their platforms and submarines that are just too big, the tech world is littered with avoidable, costly mistakes. Acquiring number fluency means developing a ‘feel’ for numbers so that we can easily spot when something is not quite right; the NASA probe disintegrated due to a simple error converting units, the trains would not fit because no-one checked the platform sizes, and the submarines needed refitting due to an error entering spreadsheet error. Each of those three were incredibly costly, totalling millions, if not billions of pounds, but they were all avoidable too. We must nurture a willingness to estimate and develop a ‘feel’ for numbers, known as ‘number sense,’ alongside the more traditional approach of performing more formal calculations when needed. After all, few people head to the shops armed with a pencil, squared paper, and a ruler in readiness to calculate their change at the cash register.
We need to value number sense and rethink our expectations of the primary curriculum.
Encouraging a different approach towards the teaching and learning of mathematics may also help to address the gender imbalance in the subject. If you filled a room with a hundred math professors, the chances are that less than ten would be female. However, female mathematicians have played key roles in the fight against COVID. Mathematical modellers such as Professor Julia Gog, based at the University of Cambridge, drew on her research as an adviser to the government’s SAGE committee.
Nevertheless, even though more students study A-Level mathematics than any other subject, few female students choose to apply to study mathematics at university. My own research with female A-Level candidates reveals their preference for careers which help others and contribute towards a better society.
However, they often do not appreciate how studying mathematics might help them to realise their dreams by helping thousands, if not millions, of others through research on climate change, medicine, and networks.
We know that the gender gap in mathematical performance starts at a young age, and researchers have suggested that the changing expectations in the curriculum as students progress through their schooling might dissuade girls from continuing to study mathematics at a higher level. At primary school, pupils are expected to master written calculations such as long division and long multiplication to achieve ‘age-related expectations.’ However, to progress further, they also need to be able to solve problems, and this seems to be the point where female students lose out.
It has been argued that the switch from being rewarded for learning procedures to solving problems favours boys over girls, and the persistent gender gap in results for higher-achieving primary pupils appears to add weight to that argument. Effort are being made to encourage more females to consider studying mathematics, including the Maths 4 Girls project which organises school visits from female role models and the careers arm of the Institute of Mathematics and its Applications which organises poster competitions to encourage more school students to think carefully about studying mathematics, both projects which I support. Yet more needs to be done.
Our curriculum and assessment system are designed to value number sense, estimating and problem-solving skills and perhaps rethink the time schools devote to rehearsing written calculations. Otherwise, we risk overlooking the huge potential of our current female students to contribute and build on the work of their predecessors, including Florence Nightingale, Mary Boole, Ada Lovelace, and Julia Gog, among many others.
To continue our recovery from COVID and rebuild our economy, we must embrace the potential of mathematics for developing and embedding the skills and attitudes that our students will need to thrive in their increasingly automated world: a willingness to "play" with numbers, estimate and check their answers; an enthusiasm for solving problems and working together; and an understanding that it’s OK to get stuck sometimes. We can overcome the hurdles that we face by working together as a team.
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