This is a good analysis of the changes in store for us once true
electrical vehicles along with automatic driving comes on stream.
Right now driving is massively labor intensive with most of the
implied cost dumped onto the owner. Once a superior alternative
becomes available, the switch will be quick as it should be.
This oncoming transportation revolution will also lower the hard
costs as well. Even better, one will simply book one's own vehicle
off for three hours in the off chance it can acquire credit while you
are engaged in a luncheon meeting. All this flexibility draws down
the costs of ownership.
A less obvious expectation is that the space will be made usable. It
can become a comfortable work space or entertainment space. This
enhances the value of the vehicle.
New design factors
for Robot Cars
Many of the big
changes that will come about form robocars will come from how they
free car designers from the constraints of human-driven cars which
are the owner's sole, or almost-sole vehicle.
Much of this depends
on this yet-untested idea:
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If one can hire a cheap specialized "robotaxi"
(or whistlecar) on demand when one has a special automotive
need, car users can elect to purchase a vehicle only for their
most common needs, rather than trying to meet almost all of them
-- or to not purchase at all.
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For example, for many,
most trips are short, single passenger and do not require significant
cargo room. Almost nobody purchases a vehicle good only for that
purpose, because they want to cover the occasional needs for long
trips, taking extra people, carrying cargo, towing or going off-road.
Some of these changes
would also apply to what I'm calling "whistlecars" -- owned
or rented cars that deliver themselves to you when you summon them,
but which you still drive.
Let's consider some of
these changes, and the constraints they remove from vehicle
designers.
Range is much less
important
Today, car buyers
demand long range. Electric cars are mostly of modest range, and
worse, after they reach their range, must find a rare charging
station and sit at it for many hours. This is probably the greatest
impediment to their sale.
A robocar need only
meet the range needs of most of its owner's usual trips,
since a longer range car can be called for when needed. It is also
possible to combine vehicles, so a short-range robocar might take the
passenger to a longer-range robocar, or to an intercity train.
Battery problems
are considerably reduced
With no need for long
range, electric vehicle design overcomes its largest challenge -- the
batteries. Decent range demands lots of batteries, and lots of
batteries means lots of cost and weight, with significant expense and
recycling trouble required to get lower weight batteries.
Short range electric
cars can have minimal batteries, and can thus get away with cheaper
and heavier battery technologies. Other short range clean power
technologies, such as compressed air, also become practical.
Refueling is not
usually done while humans travel
A robocar or
whistlecar will refuel/recharge itself after dropping of
its passengers. Fueling/charging stations need not be conveniently
located on major travel routes. Vehicles can travel a modest distance
(vacant) to reach them. (As they do this, energy is wasted, but human
time is not.) This allows slower and more expensive refueling
systems, including pressurized gas refueling (hydrogen, LNG or even
compressed air.)
It also allows -- at
an energy cost -- early adoption of new refueling technologies
without having to put stations everywhere. As long as trips to
stations do not require a significant or expensive fraction of the
vehicle's range, stations can be rare and still work. (The lack of
suitable refueling infrastructure is often cited as the main barrier
to several alternative fuel technolgies, such as hydrogen.)
Because
refueling/charging will be done just prior to trips, and the energy
will be expended immediately after, some alternate energy storage
methods may become practical, such as leakier hydrogen storage,
supercapacitors, flywheels (even lossy ones) or liquid nitrogen.
Electric vehicles can
do slow recharge, at a cost of increased downtime. Fancier
high-current charging stations can offer fast recharge. Also
possible, and more suitable for robotaxis, is battery exchange.
Battery exchange, with a standardized battery module, can be human
guided or done by robots -- we are, after all, presuming many general
advances in robotics on the way to robocars.
Electric recharge
(even of removable battery modules) can also be moved into the night,
where power is much cheaper. In some cases, such as coal and nuclear
plants, electricity demand at night is a must that can be well-met
here. Alternately if most power became solar, daytime charging would
be done.
(Obviously there are
limits to this, and in an all-electric world, battery packs will have
to be charged at times that balance load. This calls for cheaper
batteries, so you can pick and choose.)
Single passenger
vehicles will be much more common
Most trips will have
just one passenger, so single person form factors become open to car
designers. Single-width cars can fit far more easily on roads and
reduce congestion. Dual person cars can be designed both side-by-side
and inline, including inline face-to-face, thus still taking just
half or 2/3rds of a lane.
Because robocars can
negotiate with one another, 3 cars, each 2/3 of a lane, could work
together to fit in 2 lanes.
Reverse and face to
face seating
In general,
face-to-face seating will be a popular choice for multi-person cars
of the 2 and 4 person variety. Single cars may also offer backwards
seating. While this will be reviled by many, it offers two
advantages. First, in any front impact accident, sitting backwards
can greatly reduce the risk of injury as long as pre-impact braking
has pushed the person's head and body against the seat and headrest.
A seatbelt is possiby not even needed here. Secondly, the most
aerodynamic shape is the teardrop shape which is fat at the front and
a point at the back, and in a very small car this may fit a backwards
facing person better.
Windshield
requirements are different
While a nice
windshield may be good for visibilty for forward-facing passengers,
there is no need to have a large unobstructed view for safety. The
windshield can be reinforced with bars, for example, allowing it to
be much stronger in the case of impacts, notably impacts with
animals. Other than for passenger comfort, the windshield barely has
to be there at all.
Cargo space is not
necessary in all vehicles
Those wishing to move
more than personal cargo can call for a robotruck/deliverbot with the
capacity they need. If they already have their personal robocar on
hand, the truck can follow them to their destination. Otherwise they
can call for a robotruck with passenger compartments, or a car with
cargo capacity.
Acceleration is not
a big requirement
While electric
vehicles all have good acceleration, an ideal robocar trip is
perfectly timed with traffic lights and other traffic so it does not
stop and start regularly. We like this because it's more efficient,
but it also means that acceleration is rare, and need not be that
zippy. Indeed, for comfort, you may prefer it slow.
This may allow
transmissions to be designed differently, to be cheaper and more
efficient -- or even non-existant.
Sport driving vehicles
will continue to have good acceleration, of course. Whistlecars would
probably want this acceleration too.
Today, the price of a
car is often strongly linked to its acceleration. This may change.
Speed may not be
that important
Vehicles meant just
for urban trips need not even be capable of highway speeds. Vehicles
only for long trips need not be fully efficient at slower speeds.
If passengers find a
pleasant working/talking/reading/viewing environment in the vehicle,
trip time may become less important than comfort. If the passenger
can work efficiently while in the vehicle, they might accept a longer
trip to be cheaper or have fewer stops. Such vehicles do not need to
be fast. Save that for rental sportscars.
Different needs for
speed and acceleration may allow entirely different engine and
transmission designs.
Cars may be much
lighter
All of the above
factors allow the car to be much lighter than today's designs. In
addition, once the risk of crashes is greatly reduced, more weight
currently devoted to safety systems can be reduced.
Smaller battery
requirements, motors, inability to go on highways and being single
seat all point to a much lighter -- and thus more energy efficient –
vehicle.
Suspensions can be
super-soft
Human driven vehicles
(HDVs) want suspensions which transmit the feel of the road. A
robocar should have a suspension that eliminates bumps &
vibrations from the road as much as it can. It may even have a
computer-controlled suspension, using shocks with electromagnets or
ferofluids, combined with a scanner which examines the road surface
ahead of the wheels, and adapts in real time to eliminate the effects
of potholes or other problems.
One can also conceive
of having more than 4 wheels, so that any one wheel can be decoupled
from the body as it goes over a small bump or hole.
Vehicles may also
mount the passenger compartment on arms so it can be pitched in turns
or tilted on acceleration and braking to provide minimal distraction
to the passengers.
In time, safety
concerns change considerably
Robocars will be
highly unlikely to get in accidents. Once this is proven, their
designs can be made lighter, and many safety features many not be as
important. (This is not to say that accidents become impossible, but
they may become so rare as to change the economic trade-offs of these
safety features.)
As long as human
drivers share the road, safety belts will presumably be required, as
a robocar may need to brake or swerve suddenly to react to a sudden
stop by a vehicle ahead, road obstacle or pedestrian on the road.
Airbags, however, may be able to suffice if such events become rare,
as they will on highway lanes where pedestrians, and eventually
human-driven vehicles (HDVs) are forbidden.
Today we allow
passengers on trains and buses to not wear seat-belts, and to get up
and walk around during travel. As robocars attain the safety record
of a bus, this can be allowed in them.
The in-car
environment changes considerably
The in-car environment
will become more of a work and entertainment space than just a travel
space. Passengers will expect things like a screen, a keyboard, and a
desk. Passengers may wish to face one another (though not all are
comfortable riding backwards.)
Quiet will be a very
important consideration, though passengers will be allowed to wear
headphones if desired, unlike drivers today.
Sleeper cars
The smooth ride
(especially on the highway) of a robocar may generate demand for cars
for night-travel, while the passengers sleep. Such vehicles might aim
to make a trip last 8 hours rather than make the fastest possible
trip, and as such would be much more energy efficient for such trips.
(This also requires a
very low crash rate, as seat belts don't work as well on flat beds.)
While a sleepercar
could be a whistlecar, it would only work with a series of drivers
who could take shifts.
Reversing the green
trend of the short-range electric vehicle, there will be demand among
the wealthier for RV type vehicles. Robo-RVs may be larger than
today's RVs due to the computer's ability to safely move a larger
vehicle, or an articulated one.
It also becomes
possible to have a "multi-unit" RV, where several vehicles
travel together and then dock or simply park closely together at a
campsite. It may also be possible to rent additional modules in local
areas and only move a smaller main module along with the people.
Taken to extremes,
some may create an entire "mobile home" consisting of many
towable units which can move to a location and dock. Because of the
energy cost of this, and the fact that they can be sent ahead by
slower means, such mobile home units might move themselves to
conventional railways for the longest part of their journey. Railways
are the most energy efficient land transport. (Sea transport is even
more efficient through routes are longer.)
Of course, in many
cases it would make sense to instead have permanent buildings with
the desired extra space and facilities, and have the robo-RV with the
user's personal gear dock to that, but such motels would not be found
everywhere, of course. It becomes a question of whether the added
cost of hauling your own facilities is worth the added convenience
and customization, compared to the cost of renting local
robo-RV-modules or motel space.
Parking is not a
problem for the humans (or society.)
Robocars will park
themselves (if they are not hiring out for more work) after dropping
off their passenger. They can park some distance from their owner, at
a cost of energy and slight delay when the owner requests the vehicle
come to her. They can park far more densely in existing parking
areas, and half-width cars can park yet more densely. If there is a
good estimate for when they will be needed (commute times, fixed
length events) they can park, if need be, remotely for a while, and
then park more closely around the estimated time of need.
Parking structures
could also be built for robocars that have many "half height"
floors since humans will not walk frequently on the floors. However,
it is debatable if new parking will actually be needed since robocars
will park so efficiently, and often be hired out and not parking at
all in dense areas. The more cars are shared, the fewer cars there
are total in the city.
Robocars/Whistlecars
can store themselves in many places HDVs cannot, such as at the
entrances to driveways on city streets, since they can always accept
a request to temporarily unblock the entrance. They can also make
dynamic use of street-sides, if necessary taking up every lane but
one during low traffic periods, but clearing out when traffic
increases. It is not a problem to have robocars "double park"
and even "triple park" as they will clear out on request.
Individuals need not
have garages in their homes, even if they own robocars. Their
robocars can find dense parking somewhere near the home, and come to
the door on very short notice. This in turn changes many of the rules
of how we design buildings around cars, offering more useful street
frontage in the homes.
Zero emission vehicles
may also be allowed to enter buildings to drop off people or cargo.
Many car owners may
rent out their cars
A new market will
probably develop for people who wish to own a robocar, but wish to
rent it out when they are not using it, either to be greener and help
pay for it; perhaps even profit from it.
As such, these
vehicles would be designed to facilitate such rental, including
cameras which can photograph the interior before and after (but not
during) any rental to identify who does any damage.
Cars will of course
be able to take themselves to car cleaning stations as appropriate,
when not in use.
Also desirable will be
a special lock-box for the owner's personal gear that they like to
have with them when they travel. It should be easy (with the keys) to
move this lock-box to another vehicle, or to have a robot extract it
from the owner's vehicle and get it delivered to where the owner is
if they need something from it. The boxes would come in a few
standard sizes to make them easy to move from car to car, but it
might also be possible to make one almost as big as a regular trunk
that moves only among a limited set of cars, or involves swap-out
among a set of users of one specific car.
Car clubs
Buyers may wish to
form car clubs, where they share a pool of vehicles but rarely or
never rent them out to strangers. Such clubs would allow members to
express themselves through their vehicles without the cost of a
wholly private vehicle. In effect this would be like buying a
"time-share" of a car, except it comes to you when you call
it.
Car-clubs might form
ad-hoc around a single vehicle. For example, one might join a club
with no other purpose than to share one or more of a certain hot car,
and belong to another club to share a different car.
In all cases, members
of car clubs could still rely on hiring outside vehicles if 2 members
want the same vehicle at the same time.
Cars would be designed
expressly for car clubs, with ways to do automated customizations for
the particular occupant.
Cost concerns
The ability to share
vehicles in this manner may alter cost equations. While full-time
taxi companies will choose vehicles that give them the best return,
private buyers may be willing to buy more expensive cars due to the
return they get on renting them or sharing them. Cars that are shared
will, like taxis, put on far more mileage that the typical private
vehicle today, and will be designed to get the best lifetime under
those circumstances. Fewer cars will be sold, however.
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