[![Test and lint](https://github.com/yeatmanlab/jsCAT/actions/workflows/ci.yml/badge.svg)](https://github.com/yeatmanlab/jsCAT/actions/workflows/ci.yml) [![Coverage Status](https://coveralls.io/repos/github/yeatmanlab/jsCAT/badge.svg?branch=main)](https://coveralls.io/github/yeatmanlab/jsCAT?branch=main) [![npm version](https://badge.fury.io/js/@bdelab%2Fjscat.svg)](https://badge.fury.io/js/@bdelab%2Fjscat) # jsCAT: Computer Adaptive Testing in JavaScript A library to support IRT-based computer adaptive testing in JavaScript ## Installation You can install jsCAT from npm with ```bash npm i @bdelab/jscat ``` ## Usage For existing jsCAT users: to make your applications compatible to the updated jsCAT version, you will need to pass the stimuli in the following way: ```js // import jsCAT import { Cat, normal } from '@bdelab/jscat'; // declare prior if you choose to use EAP method const currentPrior = normal(); // create a Cat object const cat = new CAT({method: 'MLE', itemSelect: 'MFI', nStartItems: 0, theta: 0, minTheta: -6, maxTheta: 6, prior: currentPrior}) // option 1 to input stimuli: const zeta = {[{discrimination: 1, difficulty: 0, guessing: 0, slipping: 1}, {discrimination: 1, difficulty: 0.5, guessing: 0, slipping: 1}]} // option 2 to input stimuli: const zeta = {[{a: 1, b: 0, c: 0, d: 1}, {a: 1, b: 0.5, c: 0, d: 1}]} const answer = {[1, 0]} // update the ability estimate by adding test items cat.updateAbilityEstimate(zeta, answer); const currentTheta = cat.theta; const currentSeMeasurement = cat.seMeasurement; const numItems = cat.nItems; // find the next available item from an input array of stimuli based on a selection method > **Note:** For existing jsCAT users: To make your applications compatible with the updated jsCAT version, you will need to pass the stimuli in the following way: const stimuli = [{ discrimination: 1, difficulty: -2, guessing: 0, slipping: 1, item = "item1" },{ discrimination: 1, difficulty: 3, guessing: 0, slipping: 1, item = "item2" }]; const nextItem = cat.findNextItem(stimuli, 'MFI'); ``` ## Validation ### Validation of theta estimate and theta standard error Reference software: mirt (Chalmers, 2012) ![img.png](validation/plots/jsCAT_validation_1.png) ### Validation of MFI algorithm Reference software: catR (Magis et al., 2017) ![img_1.png](validation/plots/jsCAT_validation_2.png) # Clowder Usage Guide The `Clowder` class is a powerful tool for managing multiple `Cat` instances and handling stimuli corpora in adaptive testing scenarios. This guide provides an overview of integrating `Clowder` into your application, with examples and explanations for key features. --- ## Key Changes from Single `Cat` to `Clowder` ### Why Use Clowder? - **Multi-CAT Support**: Manage multiple `Cat` instances simultaneously. - **Centralized Corpus Management**: Handle validated and unvalidated items across Cats. - **Advanced Trial Management**: Dynamically update Cats and retrieve stimuli based on configurable rules. - **Early Stopping Mechanisms**: Optimize testing by integrating conditions to stop trials automatically. --- ## Transitioning to Clowder ### 1. Replacing Single `Cat` Usage #### Single `Cat` Example: ```typescript const cat = new Cat({ method: 'MLE', theta: 0.5 }); const nextItem = cat.findNextItem(stimuli); ``` #### Clowder Equivalent: ```typescript const clowder = new Clowder({ cats: { cat1: { method: 'MLE', theta: 0.5 } }, corpus: stimuli, }); const nextItem = clowder.updateCatAndGetNextItem({ catToSelect: 'cat1', }); ``` --- ### 2. Using a Corpus with Multi-Zeta Stimuli The `Clowder` corpus supports multi-zeta stimuli, allowing each stimulus to define parameters for multiple Cats. Use the following tools to prepare the corpus: #### Fill Default Zeta Parameters: ```typescript import { fillZetaDefaults } from './corpus'; const filledStimuli = stimuli.map((stim) => fillZetaDefaults(stim)); ``` **What is `fillZetaDefaults`?** The function `fillZetaDefaults` ensures that each stimulus in the corpus has Zeta parameters defined. If any parameters are missing, it fills them with the default Zeta values. The default values are: ```typescript export const defaultZeta = (desiredFormat: 'symbolic' | 'semantic' = 'symbolic'): Zeta => { const defaultZeta: Zeta = { a: 1, b: 0, c: 0, d: 1, }; return convertZeta(defaultZeta, desiredFormat); }; ``` - If desiredFormat is not specified, it defaults to 'symbolic'. - This ensures consistency across different stimuli and prevents errors from missing Zeta parameters. - You can pass 'semantic' as an argument to convert the default Zeta values into a different representation. #### Validate the Corpus: ```typescript import { checkNoDuplicateCatNames } from './corpus'; checkNoDuplicateCatNames(corpus); ``` #### Filter Stimuli for a Specific Cat: ```typescript import { filterItemsByCatParameterAvailability } from './corpus'; const { available, missing } = filterItemsByCatParameterAvailability(corpus, 'cat1'); ``` --- ### 3. Adding Early Stopping Integrate early stopping mechanisms to optimize the testing process. #### Example: Stop After N Items ```typescript import { StopAfterNItems } from './stopping'; const earlyStopping = new StopAfterNItems({ requiredItems: { cat1: 2 }, }); const clowder = new Clowder({ cats: { cat1: { method: 'MLE', theta: 0.5 } }, corpus: stimuli, earlyStopping: earlyStopping, }); ``` ## Early Stopping Criteria Combinations To clarify the available combinations for early stopping, here’s a breakdown of the options you can use: ### 1. Logical Operations You can combine multiple stopping criteria using one of the following logical operations: - **`and`**: All conditions need to be met to trigger early stopping. - **`or`**: Any one condition being met will trigger early stopping. - **`only`**: Only a specific condition is considered (you need to specify the cat to evaluate). ### 2. Stopping Criteria Classes There are different types of stopping criteria you can configure: - **`StopAfterNItems`**: Stops the process after a specified number of items. - **`StopOnSEMeasurementPlateau`**: Stops if the standard error (SE) of measurement remains stable (within a defined tolerance) for a specified number of items. - **`StopIfSEMeasurementBelowThreshold`**: Stops if the SE measurement drops below a set threshold. ### How Combinations Work You can mix and match these criteria with different logical operations, giving you a range of configurations for early stopping. For example: - Using **`and`** with both `StopAfterNItems` and `StopIfSEMeasurementBelowThreshold` means stopping will only occur if both conditions are satisfied. - Using **`or`** with `StopOnSEMeasurementPlateau` and `StopAfterNItems` allows early stopping if either condition is met. --- ## Clowder Example Here’s a complete example demonstrating how to configure and use `Clowder`: ```typescript import { Clowder } from './clowder'; import { createMultiZetaStimulus, createZetaCatMap } from './utils'; import { StopAfterNItems } from './stopping'; // Define the Cats const catConfigs = { cat1: { method: 'MLE', theta: 0.5 }, // Cat1 uses Maximum Likelihood Estimation cat2: { method: 'EAP', theta: -1.0 }, // Cat2 uses Expected A Posteriori }; // Define the corpus const corpus = [ createMultiZetaStimulus('item1', [ createZetaCatMap(['cat1'], { a: 1, b: 0.5, c: 0.2, d: 0.8 }), createZetaCatMap(['cat2'], { a: 2, b: 0.7, c: 0.3, d: 0.9 }), ]), createMultiZetaStimulus('item2', [createZetaCatMap(['cat1'], { a: 1.5, b: 0.4, c: 0.1, d: 0.85 })]), createMultiZetaStimulus('item3', [createZetaCatMap(['cat2'], { a: 2.5, b: 0.6, c: 0.25, d: 0.95 })]), createMultiZetaStimulus('item4', []), // Unvalidated item ]; // Optional: Add an early stopping strategy const earlyStopping = new StopAfterNItems({ requiredItems: { cat1: 2, cat2: 2 }, }); // Initialize the Clowder const clowder = new Clowder({ cats: catConfigs, corpus: corpus, earlyStopping: earlyStopping, }); // Running Trials const nextItem = clowder.updateCatAndGetNextItem({ catToSelect: 'cat1', catsToUpdate: ['cat1', 'cat2'], // Update responses for both Cats items: [clowder.corpus[0]], // Previously seen item answers: [1], // Response for the previously seen item }); console.log('Next item to present:', nextItem); // Check stopping condition if (clowder.earlyStopping?.earlyStop) { console.log('Early stopping triggered:', clowder.stoppingReason); } ``` --- By integrating `Clowder`, your application can efficiently manage adaptive testing scenarios with robust trial and stimuli handling, multi-CAT configurations, and stopping conditions to ensure optimal performance. ## References - Chalmers, R. P. (2012). mirt: A multidimensional item response theory package for the R environment. Journal of Statistical Software. - Magis, D., & Barrada, J. R. (2017). Computerized adaptive testing with R: Recent updates of the package catR. Journal of Statistical Software, 76, 1-19. - Lucas Duailibe, irt-js, (2019), GitHub repository, https://github.com/geekie/irt-js ## License jsCAT is distributed under the [ISC license](LICENSE). ## Contributors jsCAT is contributed by Wanjing Anya Ma, Emily Judith Arteaga Garcia, Jason D. Yeatman, and Adam Richie-Halford. ## Citation If you are use jsCAT for your web applications, please cite us: Ma, W. A., Richie-Halford, A., Burkhardt, A. K., Kanopka, K., Chou, C., Domingue, B. W., & Yeatman, J. D. (2025). ROAR-CAT: Rapid Online Assessment of Reading ability with Computerized Adaptive Testing. Behavior Research Methods, 57(1), 1-17. https://doi.org/10.3758/s13428-024-02578-y @article{ma2025roar, title={ROAR-CAT: Rapid Online Assessment of Reading ability with Computerized Adaptive Testing}, author={Ma, Wanjing Anya and Richie-Halford, Adam and Burkhardt, Amy K and Kanopka, Klint and Chou, Clementine and Domingue, Benjamin W and Yeatman, Jason D}, journal={Behavior Research Methods}, volume={57}, number={1}, pages={1--17}, year={2025}, publisher={Springer} }