Mastery-based learning draft
This commit is contained in:
parent
aa5936c70b
commit
4654b8de5f
|
|
@ -0,0 +1,96 @@
|
|||
+++
|
||||
title = "Mastery-Based Learning"
|
||||
date = 2022-07-19
|
||||
tags = ["education"]
|
||||
draft = true
|
||||
+++
|
||||
|
||||
A thought I've been brewing probably since undergrad is the idea of
|
||||
mastery-based education for skill-based practices. Directly inspired by the
|
||||
language learning apps, I wonder whether we can enhance a traditional spaced
|
||||
repetition system with a topic graph, where mastery can "spill" throughout the
|
||||
graph to better model learning. Since I'm never going to have time to actually
|
||||
build such a system, I thought I'd just jot these ideas down.
|
||||
|
||||
### Knowledge Graph
|
||||
|
||||
The first piece of this setup would require having an extensive knowledge graph.
|
||||
Think Wikipedia, where it has a lot of related topics, but rather than just
|
||||
being linked in an ad-hoc manner, each link has one or more of the following
|
||||
specific purposes:
|
||||
|
||||
- **Dependency.** The linked topic needs some percentage of mastery in order
|
||||
to best experience the current topic.
|
||||
- **Spill.** Not really sure what a good term for this would be, but basically
|
||||
mastery of the current topic would result in some percentage of "spilled"
|
||||
mastery gain for the linked topic.
|
||||
|
||||
The dependency aspect allows people to work backwards, starting from what they
|
||||
don't know and being able to query what the required context is. They can build
|
||||
themselves a learning plan based on a topological sorting of those topics and
|
||||
tackle them individually.
|
||||
|
||||
The spill aspect allows people to "skip" learning things they already know, for
|
||||
a faster onboarding experience. For example, since "the quadratic formula"
|
||||
requires someone to know "algebra", then if someone masters the quadratic
|
||||
formula before algebra, it should boost the mastery of algebra too.
|
||||
|
||||
### Mastery Level
|
||||
|
||||
I think the current way tests are handled are not only stressful, but a horrible
|
||||
way to measure mastery. Rather than promoting long-term learning, it encourages
|
||||
the cram-and-forget workflow. I think what the language learning apps taught us
|
||||
is not only is it good to repeat things when we get it wrong, it's also good to
|
||||
repeat things when we get it right.
|
||||
|
||||
The vision would be something like this:
|
||||
|
||||
1. First, the student learns some material. They take a short quiz immediately,
|
||||
and their mastery is boosted by a small percentage depending on their score,
|
||||
maybe up to 30%.
|
||||
|
||||
2. Then, the student goes off and learns some related material. After a length
|
||||
of time has passed, they are quizzed on the first topic again. By this time,
|
||||
their mastery score should fall a bit simply on the basis of "forgetfulness
|
||||
over time".
|
||||
|
||||
3. At the end of the semester, if they have reached required thresholds of
|
||||
mastery in each required topic, they will pass the class.
|
||||
|
||||
Not only does this simplify final grading, it also removes the whole concept of
|
||||
stress in the middle, since doing badly on one exam doesn't hurt your grade
|
||||
permanently. On top of that, doing _well_ on a single exam doesn't guarantee
|
||||
that you know it, and the system models that by not giving you full mastery
|
||||
after a single test.
|
||||
|
||||
But this doesn't necessarily mean that the student must re-take tests on things
|
||||
they already know. The great thing about the whole "spill" system is that if
|
||||
they learn topic A first, then topic B that depends on topic A, then topic B can
|
||||
indirectly keep topic A's mastery afloat.
|
||||
|
||||
### Implementation Challenges
|
||||
|
||||
Implementation is the toughest part. There's a couple technical hurdles I would
|
||||
like to complete before attempting such a system, which are:
|
||||
|
||||
- A markup similar to Restructured Text. This should make learning material be
|
||||
produced and overlayed in an intuitive way for readers.
|
||||
|
||||
- A bunch of interactive widgets for allowing users to play around with the
|
||||
material directly. This is more applicable in math and science curriculums.
|
||||
|
||||
- Quiz generation software. There's probably good off-the-shelf components
|
||||
already, I haven't looked.
|
||||
|
||||
Another problem is that I never want to think about dealing with cheating. If
|
||||
this idea were to be neatly packaged up and deployed into schools, you bet the
|
||||
first problem teachers are going to have is with cheating. While there are some
|
||||
stopgaps such as auto-generated quizzes and personalized curriculums, there's
|
||||
never a guaranteed solution. Instead, fostering a healthy learning attitude
|
||||
among students is the best way for these systems to be effective.
|
||||
|
||||
My final disclaimer is that I'm not an educator. I've TA'd for a functional
|
||||
programming course in undergrad and helped many peers learn programming concepts
|
||||
from time to time. Watching people learn is a very interesting process, and
|
||||
while I don't have time to conduct studies on how this process works, there's
|
||||
general patterns I picked up on while following this train of thought.
|
||||
Loading…
Reference in New Issue