Usability Engineering

Usability Engineering Dr. Dania Bilal IS 582 Spring 2007

Usability Engineering? • Measures multiple components of the user interface • Addresses the relationships between system and its users • Focuses on the HCI field

What Is Usability Engineering? • Bridges the gap between human and machines • Measures the quality of a system in relation to its intended users • Involves several methods, each applied at appropriate time of the design and development process

Importance of Usability • The sooner problems are found, the less expensive it is to fix them • Saves money by reducing designers’ time • Provides information about user experience • Cognitive, affective, and psychomotor • Depends on method(s) employed

Importance of Usability • Learn more about users, tasks, expectations, successes, failures, information seeking, etc. and take these into consideration in redesigning a system or designing new one

Usability Attributes • As described by Neilsen • Learnability • Efficiency • Memorability • Errors & their severity • Subjective satisfaction

Learnability • System must be easy to learn, especially for novice users • Hard to learn • systems are usually designed for expert users • Learning curve for novice and expert users

Efficiency • System should be efficient to use so that once the user has learned how to use it, the user can achieve a high level of productivity • Efficiency increases with learning

Memorability • System should be easy to remember, especially by casual users • No need to learn how to use system all over again after a period of not using it

Errors • System should have a low error rate • System should provide user with a recovery mechanism • Minor errors • Major errors

Minor Errors • Errors that did not greatly slow down user’s interaction with the system • User is able to recover from them • through system feedback • through awareness of error made

Major Errors • Difficult to recover from them • Lead to faulty work if high in frequency • May not be discovered by the user • Errors can be catastrophic

Subjective Satisfaction • System should be likeable by users (affective) • Satisfaction varies with purpose of system • Educational vs. entertainment

Assumptions • The designer’s best guess is not good enough • The user is always right • The user is not always right • Users are not designers • Designers are not users • More features are not always better • Minor interface details matter • Online help does not really help Source: Nielsen, J. (1993). Usability Engineering. San Diego: Morgan Kaufman.

Factors Influencing User Interaction • Address the functionality of the system vis-à-vis: • user needs • user tasks • user information seeking • user expectations • user cognitive processes

Evaluation • Component of usability engineering • Involves users in the evaluation • Users perform tasks developed by evaluator • Main goal • Uncover problems and correct them

Evaluation • Can be done before, during, and after system is designed and developed • Before design • During design • After release

Usability Methods: Cognitive Walkthrough • Involves experts acting on behalf of actual users • Goal- and task- driven of how user approaches a task in a system • An observer “experimenter” is present • Prepares tasks • Takes notes • Provides help

Usability Testing • Actual users interact with system • Users perform tasks assigned by evaluator • Users’ activities are captured • Methods • Users may also be interviewed • Captured data are coded, analyzed, and reported • Interview data are coded, analyzed, and reported

Heuristic Evaluation • Evaluators interact with an interface several times and map interface to specific heuristics or guidelines • See Neilsen’s ten heuristics • Each evaluator generates a report • Reports are aggregated and final report is generated • An observer may be present

Field Studies • Actual users • Users are observed in naturalistic setting • No tasks are assigned to users • Users’ interaction with system are captured, analyzed, interpreted, etc. • Interviews can be used in addition to observations

Usability Heuristics • http://www.usabilityfirst.com/methods • http://www.useit.com/papers/heuristic/heuristic_list.html (Neilsen’s usability heuristics) • http://www.useit.com/papers/heuristic/heuristic_evaluation.html (how to conduct a heuristic evaluation) • http://www.uie.com/articles (collection of articles) • http://www.uie.com/articles/usability_tests_learn/ Learning about usability test (Jared Spool) • http://www.useit.com/papers/heuristic/severityrating.html (Severity rating)

Usability Tests • Stages • Preparation • Introduction • User interaction and caputre • Debriefing Neilsen, J. (1993). Usability Engineering. San Diego: Morgan Kaufman.

Preparation • Preparation for the experiment and data collection • Location of test (e.g., room to be used) • System to be used, capturing software, etc. • Test materials, instructions, questionnaires to be completed, as applicable

Introduction • Purpose of the test • Results will be used to improve interface • User cnfidentiality & IRB • Software and equipment used to collect data

Introduction • Users to ask questions before and during experiment • Type of questions accepted • Users to report problems and difficulty in using system (e.g., screen freeze) • May provide verbal instructions

Running the Test • Experimenter(s) should refrain from interacting with users • Don’t give your personal opinion • Don’t tell user how to perform certain function • Don’t distract user during the interaction

Debriefing • User is debriefed after the test • Experimenter may follow up with questions about interaction • Likes, dislikes, comments, suggestions for system improvements, etc. • Verbally (individual interview) • Structured or semi-structured • Questionnaire with both closed and open-ended questions

Debriefing • Experimenter ensures that data collected from each user are labeled • User is given a code or number for identification purposes • Experimenter writes a brief preliminary report while events are still fresh • Collected data are coded, analyzed, interpreted, and reported

Usability Engineering