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̽��ֱ��team, from the ̽��ֱ�� of Cambridge and the ̽��ֱ�� of Dundee, developed a new context-aware method that reduces this communication gap by eliminating between 50% and 96% of the keystrokes the person has to type to communicate.

̽��ֱ��system is specifically tailed for nonverbal people and uses a range of context ‘clues’ – such as the user’s location, the time of day or the identity of the user’s speaking partner – to assist in suggesting sentences that are the most relevant for the user.

Nonverbal people with motor disabilities often use a computer with speech output to communicate with others. However, even without a physical disability that affects the typing process, these communication aids are too slow and error-prone for meaningful conversation: typical typing rates are between five and 20 words per minute, while a typical speaking rate is in the range of 100 to 140 words per minute.

“This difference in communication rates is referred to as the communication gap,” said Professor Per Ola Kristensson from Cambridge’s Department of Engineering, the study’s lead author. “ ̽��ֱ��gap is typically between 80 and 135 words per minute and affects the quality of everyday interactions for people who rely on computers to communicate.”

̽��ֱ��method developed by Kristensson and his colleagues uses artificial intelligence to allow a user to quickly retrieve sentences they have typed in the past. Prior research has shown that people who rely on speech synthesis, just like everyone else, tend to reuse many of the same phrases and sentences in everyday conversation. However, retrieving these phrases and sentences is a time-consuming process for users of existing speech synthesis technologies, further slowing down the flow of conversation.

In the new system, as the person is typing, the system uses information retrieval algorithms to automatically retrieve the most relevant previous sentences based on the text typed and the context the conversation the person is involved in. Context includes information about the conversation such as the location, time of day, and automatic identification of the speaking partner’s face. ̽��ֱ��other speaker is identified using a computer vision algorithm trained to recognise human faces from a front-mounted camera.

̽��ֱ��system was developed using design engineering methods typically used for jet engines or medical devices. ̽��ֱ��researchers first identified the critical functions of the system, such as the word auto-complete function and the sentence retrieval function. After these functions had been identified, the researchers simulated a nonverbal person typing a large set of sentences from a sentence set representative of the type of text a nonverbal person would like to communicate.

This analysis allowed the researchers to understand the best method for retrieving sentences and the impact of a range of parameters on performance, such as the accuracy of word-auto complete and the impact of using many context tags. For example, this analysis revealed that only two reasonably accurate context tags are required to provide the majority of the gain. Word-auto complete provides a positive contribution but is not essential for realising the majority of the gain. ̽��ֱ��sentences are retrieved using information retrieval algorithms, similar to web search. Context tags are added to the words the user types to form a query.

̽��ֱ��study is the first to integrate context-aware information retrieval with speech-generating devices for people with motor disabilities, demonstrating how context-sensitive artificial intelligence can improve the lives of people with motor disabilities.

“This method gives us hope for more innovative AI-infused systems to help people with motor disabilities to communicate in the future,” said Kristensson. “We’ve shown it’s possible to reduce the opportunity cost of not doing innovative research with AI-infused user interfaces that challenge traditional user interface design mantra and processes.”

̽��ֱ��research paper was published at CHI 2020.

̽��ֱ��research was funded by the Engineering and Physical Sciences Research Council.

Reference:
Kristensson, P.O., Lilley, J., Black, R. and Waller, A. ‘.’ In Proceedings of the 38th ACM Conference on Human Factors in Computing Systems (CHI 2020). DOI: 10.1145/3313831.3376525