Carpool Apps Are on the Rise—Here’s How to Make Them Go Big

The cell phone ride hail apps like Uber and Lyft are now reporting great success with actual ride-sharing, under the names UberPool, LyftLines and Lyft Carpool. In addition, a whole new raft of apps to enable semi-planned and planned carpooling are out making changes.

The most remarkable number I have seen has Uber stating that 50% of rides in San Francisco are now UberPool. With UberPool, the system tries to find people with overlapping ride segments and quotes you a flat price for your ride. When you get it, there may already be somebody there, or your car may travel a small bit out of your way to pick up or drop somebody off. It’s particularly good for airports but is also working in cities. The prices are often extremely good. During a surge, it might be a much more affordable alternative.

It’s often been observed that as you watch any road, you see a huge volume of empty seats go down it. Even partial filling all those empty seats would make our roads vastly more efficient and higher capacity, as well as greener. Indeed, the entire volume of most transit systems could probably be easily absorbed, and a great deal more, if those empty seats were filled.

The strongest approach to date has been the hope that carpool lanes would encourage people to carpool. Sadly, this doesn’t happen very much. Estimates suggest that only 10% of the cars in the carpool lane are “induced” carpools — the rest are people like couples who already would have gone together. As such, many carpool lanes actually increase congestion rather than reducing it, because they create few induced carpools and take away road capacity. That’s why many cities are switching to HOT lanes where solo drivers can pay to get access to excess carpool lane capacity, or allowing electric/PHEV vehicles into the carpool lane.

Most carpool apps today have a focus on people who are employees of the same company. Companies have had tools to organize carpools for ages, and this works modestly well, but typically the carpools are semi-permanent — the same group rides in together each day, sometimes trading off who drives. The companies provide incentives like cash and special parking.

The new generation of carpool apps (outside Uber) tend to focus on people at the same company, and as such, they mostly work with big companies. There they can add the magic of dynamic carpooling, which means allowing people to be flexible about when they come and go, and matching them up with different cars of other employees. This makes sense as an early business for many reasons:

  • People can inherently trust their co-workers
  • Co-workers naturally share the same workplace, so you only have to find one who live within a reasonable distance
  • Companies will subsidize the carpooling for many reasons, including saving them parking.

The subsidies can often include a very important one, the guaranteed ride back. Some of these apps say that when you want to leave, if they can’t find a carpool going near your house, they will provide alternate transportation, such as transit tickets or a Taxi/Uber-style ride. This gives people the confidence to carpool in with one dynamically assigned group, knowing they will never be stuck at the office with no way home. Independent carpool services can also offer such a guarantee by adding a cost to every ride, but it’s easier for a company to do it. In fact, companies will often pay for the cost of the apps that do this, so that all the employees see is the car operating cost being shared among the poolers.

Multi-leg carpools

What has not happened much today is the potential of the multi-leg carpool, where you ride in one car for part of the trip, and another car (or another mode) for another part. Of course, changing cars or modes is annoying compared to door-to-door transportation, though it’s the norm for transit riders.

Today, most carpool apps will have the driver go slightly off their route — often off the highway — to pick up a rider or return one home. (Normally the morning destination is a commercial building, usually the same building.)

carpool-apps-infrastructure-21
Image credit: Esparales/FlickrCC

A multi-leg service has some similarities to the concepts of multi-leg robocar transit I outlined previously. In one vision, the actual carpool sticks to highways and arterial roads, and never deviates from the expected route of the driver or any of the poolers. Poolers get to the carpool by using some other means — including a private Uber-style ride — and then join it for the highway portion. If they are not going to the same place as other poolers, they can also use such a ride at the other end, though having two transfers reduces the appeal a fair bit.

This “last mile” leg can be something like Uber, or transit, or a bicycle (including one-way bicycle systems) or a “kiss and ride” drop-off by a spouse, or even another carpool. The difference is to make it dynamic, with live tracking of all parties involved, to reduce waits at the transfer points to very short times. (With robocars and vans, the waits will be measured in seconds, but human drivers won’t be that reliable.)

In spite of the inconvenience of having to do a transfer, if the wait is short, it’s better than the downsides of the driver or other poolers having to go far off the highway to handle a fellow pooler, and there can even be financial incentives to make things smooth.

Transfer points on arterials

The main barrier in the way of a truly frictionless transfer is the absence of good and easy places to do the transfer in many locations. This might be something that highway planners should consider in building or modifying future roads. The benefits can happen today, well before robocars, so it can get on the radar of the planners today. When the robocar transit arrives, tremendous benefits are possible.

Today, there is something a bit like this. In many cities, there are bus lines that run on highways. In some cases, bus stops have been built embedded in the highway, allowing the bus to stop without fully leaving the highway. A common example can be found on intersections which have a private on-ramp/off-ramp lane which stops mergers from interfering with primary traffic. Sometimes these are just off to the side of the regular highway, but in all cases, the bus pulls off the highway and then into the bus stop. Riders have some safe path from the non-highway world, including bus stops on regular streets and arterials.

In the fast-transfer world, you want something like this, though you don’t necessarily need a path to other roads. A rider brought in an Uber can be dropped off there, and in interchanges with a private collector lane, the car that drops the rider off can easily get back onto the regular road in the opposite direction.

In the map is an intersection that already has all the ingredients needed for carpool transfer points — collector lanes, long ramps and lots of spare space. Most intersections are not as adaptable as this one, but new and reconstructed intersections can be adapted in much less space. In addition, transfer points may be possible in the center median, if there is room, under bridges, through the installation of a staircase from the bridge. (If there is no elevator, the disabled can be brought to the transfer point through a longer route that goes on the highway.) This is a common layout for transit lines which run down the median.

Full cloverleaf is better for the placement of transfer points, though there are other places they can go in other intersection designs. (It’s become popular of late to replace full cloverleaf intersections with the parclo design that comes from my hometown of Toronto. This change is mostly done to avoid the complex merge and tight turns of a full cloverleaf, though robocars can handle the full clover just fine. You can easily put some transfer points in a parclo, you just have an extra minute or two spent by the stopping carpool.

Transfer points are dirt cheap infrastructure, pretty much identical to bus stops, though ideally, they would use angled parking so vehicles can come and go without blocking others. You do want space for a van or even a bus to come when you have found a super-carpool synergy, as will probably be the case at the peak of rush hour. Of course, if the volume of poolers grows very high, it justifies making larger transfer points and more of them. For super peak times, it’s OK to use transfer points that are just off the highways (where parking lots to do this are plentiful) because, with high volume, pools are making just one stop to pick up passengers and can handle a small detour.

Transfer with parking

Of course, today the easiest way to do these carpools is with “carpool lots” not too far from the highway — places with spare parking which allow carpool riders to drive to the lot to meet their carpool driver. Indeed, carpoolers should be those who own cars because the first goal is to take a car off the road that otherwise have driven, and the second goal is to fill the empty seat with somebody who would otherwise have been on transit.

It can be difficult to get lots of parking convenient to the highway. One carpool lot I use has room for only about 50 cars. Nice that it’s there, but it takes no more than 50 cars off the road. At scale, one could imagine it being worthwhile to have shuttles from parking lots to on-highway transfer points, though nobody likes having to do 3 or 4 legs for a trip unless it’s zero wait time. If Robocars were not coming, one could imagine designing future highways with transfer points connected to parking lots. The people of the past did not imagine robocars or cell phone coordination of carpooling.


This article was first published on Brad’s blog. Go here to read the original article.

Image credit: Michiel1972/Wikimedia Commons

Brad Templeton
Brad Templetonhttp://www.templetons.com/brad/bio.html
Brad Templeton is a developer of and commentator on self-driving cars, software architect, board member of the Electronic Frontier Foundation, internet entrepreneur, futurist lecturer, writer and observer of cyberspace issues, hobby photographer, and an artist. Templeton has been a consultant on Google's team designing a driverless car and lectures and blogs about the emerging technology of automated transportation. He is also noted as a speaker and writer covering copyright law and political and social issues related to computing and networks. He is a director of the futurist Foresight Nanotech Institute, a think tank and public interest organization focused on transformative future technologies. Templeton was founder, publisher and software architect at ClariNet Communications Corp., which in the 1990s became the first internet-based business, creating an electronic newspaper. He has been active in the computer network community since 1979, participated in the building and growth of USENET from its earliest days, and in 1987 founded and edited a special USENET conference devoted to comedy. Templeton has been involved in the development of important pieces of software including VisiCalc, the world's first computer spreadsheet, and Stuffit for archiving and compressing computer files. In 1996, ClariNet joined the ACLU and others in opposing the Communications Decency Act, part of the Telecom bill passed during Clinton Administration. The U.S. Supreme Court sided with the plaintiffs and ruled that the Act violated the First Amendment in seeking to impose anti-indecency standards on the internet.
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