This is a repository containing code and data for the paper:
U. Upadhyay, G. Lancashire, C. Moser and M. Gomez-Rodriguez. Large-scale randomized experiment reveals machine learning helps people learn and remember more effectively., npj Science of Learning, 6, Article number: 26 (2021).
Spaced Selection is a method for optimally selecting the items which the user should revise during a given session to optimize learning.
The modeling of human memory is based on our previous work, Memorize, but instead of choosing the optimal time to review each item, in this work, we allow the user to select the session time and we choose the set of items which she will study during the session.
This repository consists of scripts for analysis of Spaced selection and baseline as well as code to run simulations to compare the performance of different item selection strategies.
The model was trained using data from the popular smart driving-learning app by Swift. The data generated during the randomized trial of the app with different learning algorithms is available for download here.
To prepare, download all the csv files to the data/spaced-algorithms folder. An example file for 1 day of data has been added to the folder already. An IPython notebook has been added to showcase the performance of the leraners for different algorithms.
Unless otherwise stated, the code should be run from the root folder.
pip install -r code/requirements.txt➔ ./swift_to_hlr.py --help
Usage: swift_to_hlr.py [OPTIONS] INPUT_DIR OUTPUT_HLR_CSV OUTPUT_SIM_CSV
Convert CSV files in INPUT_DIR from Swift.ch format to Duolingo's HLR
format and save in OUTPUT_HLR_CSV, as well as to extract each attempt and
save in OUTPUT_SIM_CSV.
Options:
--verbose / --no-verbose Verbose output. [default: True]
--force / --no-force Overwrite output. [default: False]
--min-count INTEGER Minimum number of times a user must have practiced
a question to include it for training/prediction.
[default: 1]
--results-dir TEXT The results folder for Lineage. [default:
results]
--help Show this message and exit.
The processed folder contains an example of learned difficulty parameters for
the HLR model. However, the user sessions file is not included with the
repository.
➔ ./hlr_learning.py --help
usage: hlr_learning.py [-h] [-b] [-l] [-t] [-m METHOD] [-x MAX_LINES]
[-h_reg HLWT] [-l2wt L2WT] [-bins BINS]
[-epochs EPOCHS] [-shuffle SHUFFLE]
[-training_fraction TRAINING_FRACTION] [-l_rate L_RATE]
[-o OUTPUT_FOLDER]
input_file
Fit a SpacedRepetitionModel to data.
positional arguments:
input_file log file for training
optional arguments:
-h, --help show this help message and exit
-b omit bias feature
-l omit lexeme features
-t omit half-life term
-m METHOD hlr, lr, leitner, pimsleur, hlr-pw, power
-x MAX_LINES maximum number of lines to read (for dev)
-h_reg HLWT h regularization weight
-l2wt L2WT L2 regularization weight
-bins BINS File where the bins boundaries are stored (in days).
-epochs EPOCHS Number of epochs to train for.
-shuffle SHUFFLE The seed to use to shuffle data, -1 for no shuffling.
-training_fraction TRAINING_FRACTION
The fraction of data to use for training.
-l_rate L_RATE Where to save the results.
-o OUTPUT_FOLDER Where to save the results.
This is a side script for executing the model on a SLURM engine, if one is available, for easy parameter search.
➔ ./slurm/grid_search_run.py --help
Usage: grid_search_run.py [OPTIONS] INPUT_CSV OUTPUT_DIR
Options:
--slurm-output-dir TEXT Where to save the output [default: slurm-output]
--dry / --no-dry Dry run. [default: True]
--epochs INTEGER Epochs. [default: 500]
--mem INTEGER How much memory will each job need (MB).
[default: 10000]
--timeout INTEGER Minutes to timeout.
--shuffle INTEGER Seed to shuffle training/testing using.
--l-rate FLOAT Initial learning rate.
--help Show this message and exit.
➔ ./hlr_eval.py --help
Usage: hlr_eval.py [OPTIONS] RESULTS_DIR OUTPUT_CSV
Read all *.detailed files from RESULTS_DIR, calculate the metrics, and
save output to OUTPUT_CSV.
Options:
--debug / --no-debug Run in single threaded mode for debugging.
--help Show this message and exit.
➔ ./simulation.py --help
Usage: simulation.py [OPTIONS] DIFFICULTY_PARAMS USER_SESSIONS_CSV
SIM_RESULTS_CSV
Run the simulation with the given output of training the memory model in
the file DIFFICULTY_PARAMS weights file.
It also reads the user session information from USER_SESSIONS_CSV to
generate feasible teaching times.
Finally, after running the simulations for 10-seeds, the results are saved
in SIM_RESULTS_CSV.
Options:
--seed INTEGER Random seed for the experiment. [default: 42]
--difficulty-kind [HLR|POWER] Which memory model to assume for the
difficulty_params. [default: HLR]
--student-kind [HLR|POWER|REPLAY]
Which memory model to assume for the
student. [default: HLR]
--teacher-kind [RANDOMIZED|SPACED_SELECTION|REPLAY_SELECTOR|ROUND_ROBIN|SPACED_SELECTION_DYN|SPACED_RANKING]
Which teacher model to simulate.
[default: RANDOMIZED]
--num-users INTEGER How many users to run the experiments for.
[default: 100]
--user-id TEXT Which user to run the simulation for? [Runs
for the user with maximum attempts
otherwise.]
--force / --no-force Whether to overwrite output file.
[default: False]
--help Show this message and exit.
The required files DIFFICULTY_PARAMS (an example included in processed/
folder) and USER_SESSIONS_CSV are produced by the swift_to_hlr.py script above.
The different version of the Spaced-selection algorithm which can be simulated are:
-
SPACED_RANKINGchooses the top-kitems in terms of forgetting probability (that depends on the current half-life factor) for each session deterministically, wherekcan be tuned/modified per session (produced by the simulator or sampled from real data). -
SPACED_SELECTION_DYNchooses thekitems probabilistically with each item's selection proportional to the probability of forgetting it (that depends on the current half-life factor) for each session, wherekcan be tuned/modified per session (produced by the simulator or sampled from real data). -
SPACED_SELECTIONsampleskitems at random proportionally to the forgetting probability (that depends on the current half-life factor) for each session, wherekis set by the population average size of sessions.