Shared Mobility

A.I. BETTER PREDICTS DEMAND FOR TAXIS AND RIDE-SHARES

AI Taxis

By 
In a study, the researchers used two types of neural networks—computational systems modeled on the human brain—that analyzed patterns of taxi demand. This deep learning approach, which lets computers learn on their own, could then predict the demand patterns significantly better than current technology.
Ride sharing companys like Uber in the United States, and Didi Chuxing in China, are becoming more and more popular and have really changed the way people approach transportation,” says Jessie Li, associate professor of information sciences and technology at Penn State. “And you can imagine how important it would be to predict the taxi demand because the taxi company could dispatch the cars even before the need arises.”
Ride India
Better predictions could lessen the time taxis idle waiting for rides, making cities cleaner, the researchers add. Because accidents tend to happen more often in congested areas, better ride prediction technology could also improve safety.

REQUESTS, NOT JUST RIDES

The researchers analyzed a large dataset of ride requests to Didi Chuxing, one of the largest car-hailing companies in China, according to Huaxiu Yao, doctoral student in information sciences and technology and lead author of the paper.
When users need a ride they first make a request through a computer application—for example, a mobile phone app. Using these requests for rides, rather than relying solely on ride data, better reflect overall demand, according to the researchers.
“This is really good data because it’s based on demand,” says Yao. “If you just know how many people took a ride, that doesn’t really tell you the demand because it could be that people didn’t get a ride, or others just gave up trying.”
With the historical data, which includes the time and location of the request, the computer can then predict how the demand will change over time. When visualized on the map, the researchers could see that evolving demand.

“In the morning, for example, you can see that in a residential section there are more pickups, and there are more drop-offs in the downtown area,” says Li. “In the evening, it’s reversed. What we are doing is using historical pickup data to predict how this map changes 30 minutes from now, one hour from now, and so on.”
The researchers, who presented their findings at the recent AAAI Conference on Artificial Intelligence, used data on taxi requests in Guangzhou, China, from February 1 to March 26, 2017. Guangzhou residents make about 300,000 ride requests each day. By comparison, there are about 500,000 rides per day in New York City.

LET THE COMPUTER DO IT

While technology uses one type of neural network, the researchers combined two neural networks—the convolutional neural network, or CNN, and Long Short Term Memory network, or LSTM—to help guide the complex sequences of predictions. CNNs can better model complex spatial correlations and LSTMs can better handle sequential modeling.
“Basically, we used a very complicated neural net to simulate how people digest information, in this case, the image of the traffic patterns,” says Li.
Li says access to larger data sets—”big data”—and advances in computer technology that can process this large amount of data have helped this project and enabled other deep learning developments.
“In traditional computer programming, people need to tell the computer what aspects—or features—it needs to look at and then they have to model it, which takes a huge effort,” says Li. “Why deep learning is revolutionary is now we can skip that step. You can just give the computer the images, for example. You don’t need to tell the computer what it needs to look at.”
Additional researchers contributed from Penn State; Hong Kong University of Science and Technology; and Didi Chuxing.
The National Science Foundation supported this work.

Exit mobile version