Experiments In Motion by INABA

E x p er i m en ts IN M o t io n 1

Audi of America in partnership with...

E x p er i m en ts IN M o t io n Resource document for internal use by 2 Experiments in Motion participants

Columbia University’s Graduate School of Architecture, Planning, and Preservation (GSAPP)

Experiments in Motion

Our central hypothesis is that, for the last 100 years, cities have had to react to cars, for good and bad— mainly bad. But, for the next 100 years, cars are going to have to respond to cities. The city of the future is going to ask the car different questions and demand different answers. Cities might ask the car to be something else than a car. That’s very interesting to car manufacturers, in terms of the future of their business. At the same time, it’s very interesting to an architecture school, because we’re interested in the future of the city.

Introduction Mark Wigley

Of course, we don’t know very much about the city of the future; it’s entirely possible that we know more about life on Mars. The future of cities is really unclear, and the future of vehicles is really unclear, and so we have this interesting intersection between the research arm of a highly experimental business that makes vehicles, and a highly experimental school that is engaged in imagining the future of the city. Our starting position is to combine the research capacities of Audi’s insight teams and of GSAPP and to try to imagine possible ways to frame—if not answer— this question together. Even if we don’t know what our shared future is, our past is a shared dream of motion. Deep down in every architect, there’s some sort of fantasy about motion. And, if you talk to people who make cars, drive cars, advertise cars, or make films about cars, they’re always dreaming about space. One of the paradoxes is that the people who are experts in motion—the automobile makers—actually don’t think about motion, because it’s their core knowledge. It’s possible that architects don’t just dream about motion —we might know more about motion than people who make cars. What’s more, it’s equally possible that the reverse might be true. Architects don’t necessarily think about space in a 4

Experiments in Motion

conscious sense—it’s our core business, so we just assume we’re delivering it. Those fantasies about space that vehicle experts have might—perhaps—be even more interesting and more perceptive about space than our own ideas. This overlap—this strange relationship between motion and space—is not just found in our shared dreams and future, it’s as old as the very oldest images. In the oldest artwork in the world, the Chauvet cave paintings (fig. 1), movement is already being represented in the way that we think is later typical of the arrival of cinema.

Introduction

Experiments in Motion

Fig. 1. Chauvet Cave Art, Prehistoric The image itself hasn’t moved for 32,000 years, but it’s an image of movement—a motionless image that carries motion, in a way that is curiously reminiscent of the time motion studies of Marey from the 1890s (fig. 2–4). 5

Fig. 2. Etienne-Jules Marey, motion study, ca. 1890

Introduction

Experiments in Motion

Fig. 3. Etienne-Jules Marey, motion study, ca. 1890

Fig. 4. Etienne-Jules Marey, motion study, ca. 1890 These images have always been very influential on architects. If architecture is an object that doesn’t move, the thought that something that doesn’t move could communicate motion, like this cave painting or 6

like Marey’s images, has given us a lot of insights. And, as they become more precise and more refined over the course of the last century, it’s clear that not only are these images of motion but they are also images of space. At a certain point, the body that is moving has gone. What’s left is just the shadow of movement, and, from that, we can imagine how complicated it is for someone to walk. In other words, from this image of movement, we can try to understand the object, in the same way that when you look at leaves that move in the wind, you can see the wind and you can imagine its shape.

Introduction

This photograph shows the most influential architect of the twentieth century, Le Corbusier, and his wife, by his beloved Voisin car (fig. 5). In part, this is a classic example of the car as fetish object—it’s boys and their toys. She sits. She’s an object like a car. She’s touching the car—she’s part of the car—and he stands as the owner of both.

Fig. 5. Le Corbusier and wife with Voisin car 7

Experiments in Motion

Fig. 6.â&#x20AC;&#x201A; Le Corbusier, Villa Stein, 1927

But it’s more than that. For architects, the car has always been the very paradigm of modernity. Modern architecture is unthinkable outside a certain fantasy about the car—as movement, not just as an object— the way it is produced, its speed, its styling, its evolution... Le Corbusier was always attached to his car. The car is always attached to his architecture. In these iconic images of Villa Stein (fig. 6, 7), we see the same car, moved into perfect alignment as if it is part of the composition. Le Corbusier is thinking of the car as a kind of architecture. The car has the quality of a room—a room that moves. It’s already architecture, with seats, a view, and windows—horizontal windows, no less.

Introduction

Experiments in Motion

Fig. 7. Le Corbusier, Villa Stein, 1927 Meanwhile, Le Corbusier is dreaming about an architecture that moves—an object that dreams, perhaps, of being a car. The car looks at the house and says, “I’m like you but with wheels.” And the house looks at the car and says, “I’m like you but with more capacity.” Le Corbusier remains obsessed with these cars. He designs his city as the Plan Voisin (fig. 8); he shows photographs of automobile factories; he traces the history of the automobile as an architectural history, culminating in the most famous page of his most famous book, Toward An Architecture (fig. 9).

Introduction Fig. 8.â&#x20AC;&#x201A; Le Corbusier, Voisin sketch, ca. 1925

Fig. 9.â&#x20AC;&#x201A; Le Corbusier, Toward an Architecture, trans. 1927 The point of this page is not simply to argue that the automobile has the classical beauty that one would associate with the Parthenon. Le Corbusier is simply saying the Parthenon is just a technical object that 10

Experiments in Motion

over time has been perfected. The history of Greek temples is the history of a technical evolution that culminates in the Parthenon, which is art. And art transcends time. Likewise, after years of work, suddenly an automobile transcends its speed to become art. In Toward an Architecture, Le Corbusier shows this evolution of the car, which culminates, for him, in the Fiat building, with a racetrack atop the building (fig.10).

Introduction

Experiments in Motion Fig. 10. Giacomo Mattè-Trucco, Fiat building, 1923 Of course, Le Corbusier also designed his own car. Almost every architect you can think of designed a car: Adolf Loos, Walter Gropius, Frank Lloyd Wright, Jean Prouvé, Carlo Mollino, Buckminster Fuller, and so on. Almost all of these cars are terrible as cars, but they represent the architect’s dream to shape the space of speed. In Le Corbusier’s own history of speed—La Vitesse— you can see, from 1850, which marks the beginnings of modern engineering, an exponential acceleration from the train to the telegraph to the airplane and so on (fig. 11). The graph shows that the world of the modern architect is the world of speed, of which the paradigm is the automobile. Famously, of course. Le Corbusier designs these amazing projects for Rio de Janeiro in 1929 and Algiers in 1930, in which, like the Fiat building, the housing is an extension of the highway (fig. 12).

Fig. 11. Le Corbusier, La Vitesse sketch

Introduction

Fig. 12. Le Corbusier, sketch for Rio de Janeiro

Le Corbusier tells us that a city made for speed is made for success, and then he calls speed a brutal necessity. He’s thrilled when, finally, in 1934, he’s allowed to drive a car on the roof of the Fiat building (fig. 13). What’s going on here is much more than the architect falling in love with the speed or the technology. It’s about the perception. Le Corbusier shows us that the landscape seen from the highway is a different landscape.

Fig. 13. Le Corbusier, driving on Fiat building rooftop, 1934 Of course, when Le Corbusier says that a city built for speed is a beautiful city, he’s echoing Marinetti. Marinetti, shown here in his automobile (fig. 14), was 12

Experiments in Motion

another proud driver. The Futurists—and Marinetti, in particular—are famous for writing about the beauty of speed. The very first Futurist Manifesto is about Marinetti’s automobile accident, after which he feels himself to be more alive than before.

Introduction

Experiments in Motion

Fig. 14. Filippo Tommaso Marinetti in car, 1912

Fig. 15. Anton Bragaglia, motion study, 1911 But this is not just the kind of beauty found in automobiles or even automobile crashes—it’s also in a very particular kind of photography, which they call 13

photodynamism. It’s not like Étienne-Jules Marey; it’s not a series of fragmented or dissected motions. It’s motion itself in its continuity. These images are all understood to be a critique of Marey (fig. 15). What Bragaglia, whose photograph this is, says, is that “we seek the interior essence of things: pure movement; and we prefer to see everything in motion.” This is not simply the world in motion, or an object in motion; this is motion itself as a kind of object, as a way of being in the world.

Introduction

In these stunning images, a blur is the main event. What you see as the object—what you imagine to be a person—is just, in a way, the mechanism for allowing this movement to take place. There is also a psychological dimension. It’s as if you’re seeing the many faces of one person. This way of fragmenting the identity of a person should be seen in relationship to the Cubist paintings that broke up the face, and which, of course, are the subject of Le Corbusier’s first book, Après le Cubisme.

Fig. 16. Anton Bragaglia, ‘Typewriter,’ 1911 In images like this, what you see is not simply a head, moving; instead, there is a movement with a head inside it, with a head being produced by it. This is, in some ways, more like what one sees with the 14

Experiments in Motion

computer architecture of a younger generation in which the movement path is actually making form, as distinct from a form being put into motion. It would be too simple to say that someone is typing in this image (fig. 16). This is more an image of typing as movement, to which you could then imagine a typist. The typist is simply the prosthetic apparatus for making typing possible. A typist does not type; rather, typing requires someone we will call a typist. In the same way, the driver of the automobile is not simply the driver moving an object in space. Movement itself calls for an assistant, and the assistant is the driver.

Introduction

And then you see these famous images made by Giacomo Balla in 1912-1913, which are based on the speed of the automobile and which, again, reference the Marey images (fig. 17).

Fig. 17. Giacomo Balla, ‘Velocità d’automobile,’ 1913 Balla concentrates on a loss of fixed boundaries. No matter how much you look at this image, you can’t privilege one space over another. If you look more closely, you’ll see that there’s a lot of architecture (in the classic sense) defined here. Really, this is an image of streetscape and the movement of a car and the optical disturbance that that produces, so that the city is now no longer a space where the object moves but is a 15

Experiments in Motion

space defined by movement. Balla elaborates literally hundreds of these works, and they are all about time, although not time in a strictly linear way, nor in the sense of acceleration.

Introduction

Experiments in Motion

Fig. 18. Giacomo Balla, ‘Velocità astratta,’ 1913 This image of Balla’s will make its way into Sigfried Giedion’s Histories of Modern Architecture (fig. 18). The most influential historian of architecture was very inspired by these Futurist images of motion.

Fig. 19. Sigfried Giedion

Fig. 20. Sigfried Giedion, Eiffel Tower, 1928 16

This image of Giedion as a young man is set alongside his own photograph, looking up at the Eiffel Tower (fig. 19, 20). His first book on architecture,Bauen in Frankreich: Eisen und Eisenbeton [Building in France] of 1928, features the Eiffel Tower, which dates back to 1889. Avery Hall is from 1881, so this school here was born in the same moment as the Eiffel Tower, which is, of course, a temporary building, understood as a display building for creating a new perception of Paris, and a new form of movement. And what Giedion argues in his book is that at that moment, towards the end of the nineteenth century, perception had changed radically.

Introduction

Experiments in Motion

Fig. 21. Sigfried Giedion, Eiffel Tower, 1928 These are images of Giedion looking up into the vertiginous structure of the Eiffel Tower (fig. 21). What he’s saying here is that there’s no up, down, or sideways, and, instead, there’s a kind of blurring or reduction of boundaries. When we speak about modern architecture, we always speak of the loss of the boundary between inside and outside.This is that loss—which is to say, in this vertiginous world, it is no longer clear what is in or out, and all spaces interpenetrate (this was his favorite word).

The result is a blur. You look at these images, and, although every detail is very precise and every detail is a piece of metal, the overall effect is one of confusion. Even Bauen in Frankreich was designed for speed—the book designed by Moholy-Nagy with a very particular layout that was meant to be read in a hurry. Giedion imagined the reader as a hurried reader and he’s talking about experimental buildings like the Eiffel Tower that are built quickly and are meant to be taken away. He’s talking about a fast-moving reader of a fast-moving book about a fast-moving architecture that’s basing itself on speed.

Introduction

If Giedion loves the Eiffel Tower, which he photographs so well, he also has another set of photographs of this bridge in Marseille from 1905, and that is where he feels all of this argument has been perfected (fig. 22, 23). Writing of this bridge, Giedion makes the case that, in this world that is full of new possibilities, everything is based on movement. “The street has been transformed into a stream of movement,” he says, and almost everything streams through the open net of the building.

Fig. 22, 23. Sigfried Giedion, bridge in Marseille, 1905 What’s so beautiful for him about this structure is that it allows everything to stream through it, because there’s no inside or outside. In fact, it’s just a piece of the street that can be lifted up and floated across the river. Basically, it’s just a prosthetic device 18

Experiments in Motion

that allows the street to keep on going even when there’s a river in the way, by allowing a piece of the street to be suspended and carried across. The street is reduced to a fragmentary unit on which the car can rest and be moved, and the bridge is a device for keeping the movement path going even when there’s water underneath.

Introduction

Experiments in Motion

Fig. 24. Sigfried Giedion, bridge in Marseille, 1905 The bridge keeps your movement going, by becoming a virtual road—a temporary road that can come and go. And this bridge, photographed very beautifully by Giedion (fig. 24, 25), was then used by Moholy-Nagy as the cover of Bauen in Frankreich (fig. 26). Giedion’s image of the future of architecture, at that point, is this bridge from 1905.

Fig. 25. Sigfried Giedion, bridge in Marseille, 1905

Introduction

Experiments in Motion

Fig. 26. Sigfried Giedion, Bauen in Frankreich,1928 But if we look at Giedion’s Space, Time and Architecture of 1941, the bridge has been replaced by the Randall’s Island cloverleaf here in New York (fig. 27). A highway intersection is now his image of what he calls the “space-time conception,” both in the structuring and the handling of movement. The most influential historian of modern architecture used automobile traffic systems as his paradigms of what architecture should emulate. 20

Introduction

Experiments in Motion Fig. 27. Sigfried Giedion, Space, Time and Architecture,1941 A section of the book is called “Research into Movement”, and it starts with a Balla image called, Abstract Speed - The Car Has Passed—an image of a shadow in time of movement (fig. 28). Then Giedion also uses Harold Edgerton’s speed photographs of a tennis player (fig. 29).

Fig. 28. Giacomo Balla, ‘Abstract Speed - The Car has Passed,’ 1913

Fig. 29. Harold Edgerton, ‘Tennis Player in Motion,’ 1939

Introduction

The section culminates in one of Edgerton’s images of a golf swing placed alongside Giedion’s own photocollage of Rockefeller Center (fig. 30, 31). Giedion is showing that, in this breaking up of time, and in this world where there’s no longer a clear inside and outside—a world of pure movement, a world of streaming—the real way one sees the Rockefeller Center is from all these different angles in this interpenetrating collage. This relates to the Cubist sensibility, of course, but it’s not exactly Cubist in its nature.

Fig. 30. Harold Edgerton, ‘Golf Swing,’ 1938

Fig. 31. Sigfried Giedion, Rockefeller Center, 1941 22

Experiments in Motion

Introduction Fig. 32. Sigfried Giedion, Mechanization Takes Command, 1948 A few years later, in 1948, Giedion writes Mechanization Takes Command, in which, again, time-motion studies are absolutely central (fig. 32). In the book, he writes a sort of pre-history of motion studies, starting with Muybridge in 1878 (fig. 33), then moving on to Marey’s work between 1882 and 1900 (fig. 34, 35), and then arriving at Taylor, in the 1890s, and the subsequent Taylorization and Gilbreth images of movement.

Fig. 33. Eadweard Muybridge, man descending steps,1878

Experiments in Motion

Introduction Fig. 34, 35. Etienne-Jules Marey, ca. 1882-1900 Giedion makes a comparison between these kinds of movement—the Gilbreth image of the motion of someone’s hand, on the right, and a Miró on the left, to argue that artists were also sensitive to this new way of understanding movement (fig. 36).

Fig. 36. Joan Miró, ‘Composition,’ 1935 and Frank B. Gilbreth, ‘Chronocyclograph of a Motion,’ ca. 1917 24

Experiments in Motion

But the special gift of this book is to say that, if you really want to know the way the world is going, you have to look at industrial furniture in the United States—to look at designs for chairs that moved and adjusted themselves to the movement of your body. In other words, even when I’m sedentary, when I’ve finally stopped moving at the end of the day, my chair needs to move in order that I can not move. In order to rest, my chair needs to move.

Introduction

Experiments in Motion Fig. 37. Sigfried Giedion, Mechanization Takes Command, 1948 What that means is that each of these images shows a design that awaits the body that will complete it. All of this culminates in the surgical chair that you see in the bottom left. The surgical chair is perfectly designed so that your body will move in space—so that you can remain asleep and entirely comfortable while the surgeon takes things out and put things into your body (fig. 37). As Giedion notes, this surgical chair—this moving piece of architecture—is from the same year as the Eiffel Tower. Then, in the same book, he has images of prosthetic legs, as if to say that the motion machine, the surgical chair, is a part of your body—it extends your body, it’s an artificial body. This, in some ways, is the essence of twentiethcentury thought: that modern architecture is the architecture of motion, which is not the architecture of objects that move, but rather an act of defining the space of movement itself as a space, in which humans move through prosthetic extensions, and so these 25

prosthetic extensions are really the things that occupy movement (fig. 38).

Introduction

Fig. 38. Sigfried Giedion, Mechanization Takes Command, 1948 Le Corbusier and others repeatedly said that your building is like your car, and your typewriter is a prosthetic extension of your body, and so on. This obsession with motion and with cars is really an obsession with a new kind of prosthetics.

Fig. 39. Sigfried Giedion, Mechanization Takes Command, 1948 Fig. 40. Sigfried Giedion, Mechanization Takes Command, 1948 26

Experiments in Motion

It is not by accident that, in Mechanization Takes Command, Giedion sets alongside each other the mass production of the automobile (fig. 39) and the slaughterhouse (fig. 40), which he calls the dis-assembly plant. The production of the body of the car, which promises to be a new body that will allow one to move differently through the world, coincides with an incredible expansion of our abilities to destroy the existing body, and to reduce it to its constituent parts. This question of prosthetics is not just a philosophical point, it’s quite a literal point.

Introduction

Experiments in Motion

Fig. 41. Frank B. Gilbreth, motion study of a surgeon, ca. 1915 To return to Gilbreth, this is a time motion study of the movement of a surgeon’s hand—the most expert hand (fig. 41). In fact, Gilbreth did a lot of work with the crippled during the First World War. He disagreed with his French comrades who argued that we should just produce the most beautiful prosthetics, and that a wounded soldier with no arm or leg should just wait for the best prosthetic arm or leg possible. Gilbreth argued, instead, that we should see how their crippled body moves differently and find a way they can use their body to do their task. On the one hand, we have a surgeon repairing damage to the body (fig. 42), and then, in an image made by 27

Introduction Fig. 42. Frank B. Gilbreth, motion study of a surgeon, ca. 1915

Fig. 43.â&#x20AC;&#x201A; Frank B. Gilbreth, motion study of a sword, ca. 1915

Experiments in Motion

Gilbreth in the same year, the movement of a sword— an instrument that is designed to damage the body (fig. 43). The sword will cut you up and then the surgeon will sew you up, and both the damaging of your body and the repair of your body will be the same kind of movement in space. In these images, you can sense that there is an architecture and that even there are people there, but they have become secondary to the movement. The movement itself is the form.

Introduction

Experiments in Motion

Fig. 44. Frank and Lillian Gilbreth, motion study, 1913 Ultimately, what these images are doing is defining a space of movement as an extension of the body. In these typical time-motion studies, there is a space of movement and the person’s body is suspended in relationship to this space (fig. 44). The person becomes a kind of slow-moving object relative to a fastmoving space of movement, and the real prosthetic of the body is not an object but this space. The worker inhabits an extension of his or her own body. In fact, this extended field of movement is a new body—it is a new ability, a new kind of choreography, and we suddenly realize that the worker is a dancer. This is a dancer who is not simply moving around in an established space, but rather a dancer whose movement creates space, creates a kind of architecture.

We find similar arguments in László Moholy-Nagy, who publishes Vision in Motion in the same year as Mechanization Takes Command comes out (fig. 45). He takes very, very similar photographs to Giedion, of, for example, the Eiffel Tower and the bridge in Marseille. This is because Moholy-Nagy was on vacation in Paris with Giedion in 1925, when they took these photographs. It’s really Moholy-Nagy’s ideas about space, time-space, and time-space-motion that became the basis of Giedion’s famous Space, Time and Architecture in 1941.

Introduction

Experiments in Motion

Fig. 45. László Moholy-Nagy, Vision in Motion, 1947 Moholy-Nagy was already looking at this kind of movement during the war, with the movement of searchlights. Light is moving through a space in the sky, and if an airplane is seen in this space, it will be shot. This is a space you don’t want to be seen in, this is an architecture you don’t want to enter—but it is architecture. It is architecture defined in the sky above a city. Eventually these kinds of images will be photographed by György Kepes, who had been working with Moholy-Nagy since 1930 in Berlin, and then 30

came to be with him in Chicago, and then began producing these kinds of amazing images of movement in automobiles, in which the image itself has movement because the person is walking towards the automobile (fig.46).

Introduction

Experiments in Motion

Fig. 46.â&#x20AC;&#x201A; GyĂśrgy Kepes, The New Landscape in Arts and Sciences, 1956 These remarkable images become not even lines of movement, but a kind of blurry vibration. In 1956, Kepes published more of these images. In this one, a man is walking toward a hotel and the movement of his body is affecting the camera, which is moving in relationship to automobiles that have their own movement, and so architecture, automobile, and human are now suspended in this sort of vertiginous, overlapping space (fig. 47, 48). These are quite remarkable images, that would have been seen as images of modernity itselfâ&#x20AC;&#x201D;as images of the world in which we live and for which we would design.

Introduction Fig. 47. György Kepes, The New Landscape in Arts and Sciences, 1956

Fig. 48. György Kepes, motion study, 1953

Experiments in Motion

Fig. 49. György Kepes, The New Landscape in Arts and Sciences, 1956

Introduction

You can find these images of the virtual volume created by lights going all the way back to MoholyNagy’s first book in 1928, On Architecture, one of the first of the Bauhaus books. These are MoholyNagy’s own photographs of movement in space, seen through the neons of hotels (fig. 49). Kepes is picking up on Moholy-Nagy’s argument, and Moholy-Nagy is publishing Kepes’ images, such as this one.

Fig. 50. György Kepes, The New Landscape in Arts and Sciences, 1956 33

Experiments in Motion

Kepes did his own book in 1956, The New Landscape in Arts and Sciences (fig. 50), in which he captures the new motion of atomic particles captured in a cloud chamber (fig. 51, 52). You notice in all these pictures that it’s no longer about lines and about the movement of an object in space; it’s about ripples, about quakes, about vibrations, about networks, about swarms. These are amazing images, culminating in this image of automobiles seen by someone walking down the road in Chicago.

Introduction

Experiments in Motion

Fig. 51. György Kepes, The New Landscape in Arts and Sciences, 1956

Fig. 52. György Kepes, The New Landscape in Arts and Sciences, 1956 34

For Kepes, these images, which are mainly scientific but also artistic, capture the flux of modernity, the flux of motion. Traffic is the limit condition, and the automobile is hanging around this argument like a ghost.

Introduction

Experiments in Motion

Fig. 53. Richard Hamilton, Man, Machine, and Motion, 1965 Then, in 1965, Richard Hamilton curates an exhibition called Man, Machine and Motion in London (fig. 53). On the cover of the catalogue is an image that makes you feel the movement of this automobile. The exhibition is basically a display of 200 photographs documenting the new forms of motion, inspired by Giedion’s Mechanization Takes Command and Hamilton’s own artwork, which in turn was very influenced by Muybridge’s famous studies of the human figure in motion. Hamilton’s exhibition was originally called Human Motion in Relation to Adaptive Appliances, which is to say prosthetic extension of the body. The central question, for Hamilton, is how is the human becoming a new kind of body with a new kind of movement? 35

Hamilton thinks that the relation between man and machine is a kind of union, the two act together like a single creature, and this also is what Giedion says about your relationship with the moving chair. You’re becoming one organism with your chair, you are your chair, or even that you in your chair is more like you than you, because you complete the chair, and in sitting in the chair you complete yourself. This is exactly the prosthetic logic of this machine (fig. 54).

Introduction

Experiments in Motion Fig. 54. Richard Hamilton, Man, Machine, and Motion, 1965 Reyner Banham, the British architectural critic, also wrote an essay for this catalogue—a sort of opening speech called “Metal in Motion: The Iconography of the Automobile.” You have all these architects, these artists connected to architecture, and these teachers of design thinking about motion, photographing motion, studying the documentation of motion, and positioning their work in that context, in that year. In the same year, Banham wrote his famous Vehicles of Desire, about the shaping of the American automobile. Actually, Banham never wrote an essay that didn’t refer to cars. And he didn’t know how to drive, but he’s really obsessed with this thing that he didn’t know how to do. He knew how to ride bicycles and all the images we have of him are of him riding a bicycle. In 1965—still the same year—Banham also writes one of his most famous essays, “A House is not a Home,” in collaboration with Francois Dallegret, an architect trained at L’Ecole des Beaux-Arts in Paris. In this 36

photo, you can see that Dallegret’s relationship to his car is like Le Corbusier’s relationship to his Voisin (fig. 55).

Introduction

Experiments in Motion

Fig. 55. Francois Dallegret with car The car-obsessed non-driver Reyner Banham partnered with Dallegret, an equally car-obsessed dreamer of imaginary vehicles, and together they produced the famous Bubble house (fig. 56), in which you see a naked Banham with a naked Dallegret celebrating the fact that a house is no longer filled with anything but communication systems because your cars (and you see the car on the right) have everything else inside them. Architecture is entirely usurped by the car. Everything you normally associate with architecture is in the car. It’s a radical argument of the car as architecture, so that all you’re left with is this technical bubble. This is the argument that’s affecting the angelic Mike Webb of Archigram, who, in the same year, is doing his automobile-house and his driving housing 37

projects. He’s still working on these projects today, and you see some of the versions here (fig. 57–59).

Introduction

Experiments in Motion

Fig. 56. Reyner Banham and Francois Dallegret, ‘The Environment-Bubble,’ 1965 In Webb’s drawings, the automobiles drive into the house and become part of the house, and the house itself is like a technical extension of the system of houses. You can see that this early version leads to this next image, in which the automobile arrives, hits the corner of what you think is a house, and the corner itself turns like an airlock. As it turns, the car opens up and all the pieces of the inside of the car, the seats, music, air-conditioning, and so on—which are like architecture—then transform the parked car into architecture. You see it here opening up, and the seats coming out. Webb is making the argument, following everyone else, that a fast car is a fast house and that all the mechanisms for domestic comfort are already inside it (fig. 60, 61).

Introduction

Experiments in Motion Fig. 57. Michael Webb, ‘Automobile House,’ ca. 1965)

Fig. 58, 59. Michael Webb, ‘Drive-in House,’ 1987 These are extremely beautiful drawings in which Webb assumes that as you are sitting in the car, but, as the car turns, that’s not the way you will experience it. Instead, you will have the experience that the house itself is turning relative to you. In each of these 39

drawings, the position of the seats stays the same: I drive in, the house starts to turn, then my seat turns away from the car. It is an incredibly rigorous project. As the car is turning, it starts to expand. It’s not that the car is simply arriving into a space: there is only the space as the car unfolds and, as it unfolds, it creates the space (fig. 62).

Introduction

Experiments in Motion

Fig. 60. Michael Webb, ‘Drive-in House,’ 1987 In this drawing, we see a heat map that shows that as the car opens, the heat—my body heat and the heat of the car—creates the warm interior that is the house (fig. 63). In this earlier, more detailed version, we again see Webb getting the car to unfold into a house (fig. 64). Interestingly enough, he attaches a little clipping to this drawing which says, “In 1910, the Futurist Manifesto declared that ‘the motor bus rushes into the houses which it passes and in turn the houses throws themselves upon the motor bus and are blended with it.’” This is from the Technical Manifesto of Futurist Painting of 1910, and, again, we encounter this idea that the vehicle and the house (in this case, the bus and the house) will overlap and interlock and blend together. 40

Fig. 61. Michael Webb, ‘Drive-in House,’ 1987

Introduction

Experiments in Motion

Fig. 62. Michael Webb, ‘Drive-in House,’ 1991

Fig. 63. Michael Webb, ‘Heat Drawing,’ 2003

Fig. 64. Michael Webb, ‘Drive-in House,’ 1987

In some ways, we’ve come full circle. We started towards the beginning of the twentieth century with an early reflection by Giedion and Le Corbusier and others on the fact that in the nineteenth century, motion itself had become space, and that if one is interested in space, in humanity, in the future, one could only be interested in motion. All of this argument was deeply influenced by the Futurists, of course.

Introduction

That argument works itself so deeply into architecture that we forget about it, such that, when it returns again in the 60s and 70s, we have to be reminded of the Futurist link by Mike Webb and Archigram. Then, just 20 years later, a young generation of architects working with the computer will believe themselves to be finally capturing motion as such, and will become fascinated with the Marey images of the 19th century, forgetting about the fact that those images have already organized the thinking of the solid world that they want to surpass. And we could and should follow this history of thinking about motion into space travel, psychedelic drugs, the unconscious, skateboarding, animation, computation, and so on. But always—always—there will be this paradigm, which we might call the prosthetic paradigm. In other words, throughout this hundred-year history of the love affair between architecture and motion, motion has always been thought about as an extension of an object—motion as an extension of your body and of your mind. The Experiments in Motion project simply says, what if, over the next one hundred years, we work with some different paradigms, where motion is no longer conceived as an object in space, an idea moving through space, or even as the space itself, but something else more radical yet. The basic structure of Experiments in Motion begins with a kind of think tank, where we come up with a whole series of new paradigms, and then we do some experiments together, and then we create an 42

Experiments in Motion

interface to share our findings and our new ideas.

Introduction

The program is built around the assets we have: Columbia University, New York City, and the city’s strong design culture. First of all, we’re going around the university to ask people who never talk about cars and never talk about buildings to tell us about motion. We’re asking the most radical thinkers in the world of engineering, medicine, biochemistry, media, finance, anthropology, climate science, public health, epidemiology, policy, philosophy, history, and more, what motion means to them, in their field. And, in this way, we’re learning about the movement of particles, people, fluids, concepts, perceptions, resources, signals, images, data, money, food, words, viruses, tectonics plate, debt, clouds, sounds, tweets, and everything else besides. Then we’re going out to New York City, to find people who have developed an underground intelligence with motion—people who have become masters and mistresses of motion in order to achieve radical new business or artistic goals. And so we’re arriving at two kinds of new paradigms of motion: the new thoughts of motion going on inside the university and the new forms of motion that are going on in the streets. The next step is to talk to designers and ask them whether they can think of ways in which the relationship between design and motion can become more radical than it is. At the same time, we’ll put a bunch of students and a bunch of teachers into a very dynamic relationship with these questions. They will be thinking about New York, but to think about New York means also thinking about global forces, so these student-teacher teams studying the new forms of motion in New York will also be traveling to Rio and Mumbai and to Beijing to listen to those cities and learn about new forms of motion that might exist there, and bring that back to inform their projects. And, to come full circle myself, at the core of this fast story of motion and architecture is this central 43

Experiments in Motion

provocation: what if architects have actually forgotten about space, and think we just need to embroider it? What if the people who make cars have really forgotten about motion, and assume they understand it completely and just have to perfect it. What if we could shake each othersâ&#x20AC;&#x2122; assumptions up, by going back to motion and do some experiments, in an attempt to develop a new paradigm, with which we can start to think the future of the city differently, from which different ideas about transportation and communication and so on will inevitably flow.

Introduction

My challenge to you is to say: look how amazing our thinking about motion was in the twentieth centuryâ&#x20AC;&#x201D; but your job is to go way beyond all this and make that century look boring.

Experiments in Motion

Concepts in Motion I Car Names 67 Transit Names 68 Technologies 69

Personal Mobility Architects and Their Cars 82 Architects and Their Not-Cars 92

Table of Contents

Icon Mobility 97 Buildings and Their Cars 105

Eitan Grinspun 127 Andrew Blum 133 Michael Sheetz 135 Abe Burmeister 137

What Moves Movers 144 Representation 147 Point-Of-View 151 Apparent Stillness 154

Experiments in Motion

Convergence on the City Convergence Timeline 161 The Chosen Scale 176 City-States 181 Smart Systems 185 From Complex To Campus 192 Public Planning 197 Trojan Horse Planning 202

Table of Contents

Mothers Of Invention 207 Altered Realities 212

Natalie Jeremijenko 217 Austin Long 219 Greg Lindsay 223 George Hripcsak 225

City Primer Introduction 230 Maps 245

Juliette Spertus 279 Sean Basinski 282 Adam Mckeown 284 46

Experiments in Motion

Paul Scolieri 286

Sites Adventure Maps 290

Concepts in Motion II Concepts in Motion II 313

GSAPP/Audi Table of Contents

GSAPP/AUDI 321

Studios Architecture After the Street, Jeffrey Inaba 335 Under Over Out, Juergen Mayer and Marc Kushner 338 The City of Mobile Services, Geoff Manaugh and Nicola Twilley 340

Experiments in Motion

Concepts in Motion I

The history of the United States of America is a history of mobility.

Concepts in Motion I

“We see in order to move; we move in order to see.” William Gibson “Speed is the form of ecstasy the technical revolution has bestowed on man. As opposed to a motorcyclist, the runner is always present in his body, forever required to think about his blisters, his exhaustion; when he runs he feels his weight, his age, more conscious than ever of himself and of his time of life. This all changes when man delegates the faculty of speed to a machine: from then on, his own body is outside the process, and he gives over to a speed that is noncorporeal, nonmaterial, pure speed, speed itself, ecstasy speed.” Milan Kundera

Concepts in Motion I

“Consciousness is only possible through change; change is only possible through movement.” Aldous Huxley “If everything seems under control, you’re not going fast enough.” Mario Andretti The history of the United States of America is a history of mobility. Its greatest projects have built an enormous infrastructure to move people and goods around inside of its borders. It currently has 3.9 million miles of roads and highways, 5,400 public airports, 200,000 miles of freight and passenger railroad track, 5,800 miles of urban mass transit track with more than 2,300 stations, and 3,600 waterport terminals. This transportation infrastructure has a value of $1.75 trillion, the equivalent of 12 percent of the value of the nation’s total productive assets, or eight times the value of the entire telephone and telecommunications infrastructure. “If houses were built industrially, mass-produced like chassis, an aesthetic would be formed with surprising precision.” Le Corbusier

Concepts in Motion I

“The ultimate concept car will move so fast, even at rest, as to be invisible.” J.G. Ballard “I think that cars today are almost the exact equivalent of the great Gothic cathedrals: I mean the supreme creation of an era, conceived with passion by unknown artists, and consumed in image if not in usage by a whole population which appropriates them as a purely magical object.” Roland Barthes “Money may not buy happiness, but I’d rather cry in a Jaguar than on a bus.” Francoise Hagan

Concepts in Motion I

“Perhaps this is our strange and haunting paradox here in America—that we are fixed and certain only when we are in movement.” Thomas Wolfe “The secret point of money and power in America is neither the things that money can buy nor power for power’s sake... but absolute personal freedom, mobility, privacy.” Joan Didion “Until we design a bus experience that is more attractive, more effective, and more elegant than the car, we will be selling a losing proposition. The same applies to the car itself. We must imagine and redesign the car as a product with positive impact, and not make our design objective a car that is less negative. We must design an ecology of movement options that are thrilling in every way, and that also fit together as an ecological, sustainable—but most importantly, sexy—system.” Bruce Mau “Certain cities accommodate cars quite well. If cars become more sustainable, that will remain a quite persistent model because it gives flexibility that’s almost unimaginable through any other device. But in 50

Concepts in Motion I

existing cities, it’s much more problematic. In many European cities, you have a weakened public transport, weakened infrastructure of trains, and almost pervasive car use. They could have avoided a lot of this if the public sector had been enhanced. The result is a nightmare of the lack of public initiative.” Rem Koolhaas

Concepts in Motion I

The “Commuter Cookout” is a cookbook and stainless steel cooking set created by artists Marisa Jahn and Steve Shada. The cooking set wraps onto the engine block or muffler with a one-way valve that harnesses the heat to prepare a stew, spicy hot pot, or slowbaked casserole in a metal pouch. The accompanying cookbook suggests recipes tailored to the length of your commute. Jahn and Shada’s interest lies in exploring the American speeding up of food rituals as well as the fact that, for many families on busy weekdays, the car pool is the only “quality” time they share together. “Americans will put up with anything provided it doesn’t block traffic.” Dan Rather “Change means movement. Movement means friction. Only in the frictionless vacuum of a nonexistent abstract world can movement or change occur without that abrasive friction of conflict.” Saul Alinsky “Hell on Wheels” was the name given to the mobile city that followed the Transcontinental Railroad as it forged its way west across America in the 1860s. For example, as work ground to a halt in winter 1866, the temporary town of North Platte, Nebraska, sprang up to house and entertain the Union Pacific railroad builders. As temperatures rose, the railroaders began building westward, and the shacks and canvas lean-to sheds housing gambling dens, dance halls, saloons, and brothels picked up and followed them. North Platte emptied out, to be replaced by Julesburg, Colorado, which, by 1867, was itself described by 51

Concepts in Motion I

journalist Henry Morgan Stanley as “a played out place … now about to be abandoned by the transient sojourners, and many of them are shifting their portable shanties to some prospective city west...” * * * In August 2010, a traffic jam on the road between Inner Mongolia and the northwestern edge of Beijing began to form, eventually stretching more than 62 miles, eventually trapping vehicles in place for nine days.

Concepts in Motion I

As drivers began to turn off their cars altogether and sleep for 8 hours at a time, a temporary micro-culture of the motorway emerged. Mobile businesses broke out along the roadway. “Villagers along Highway 110 took advantage of the jam,” the Wall Street Journal reported at the time, “selling drivers packets of instant noodles from roadside stands and, when traffic was at a standstill, moving between trucks and cars to hawk their wares. Truck drivers, when they weren’t complaining about the vendors overcharging for the food, kept busy playing card games.” A spatial infrastructure of the traffic jam soon also emerged, including temporary awnings, tent walls, and small outdoor rooms, built with found materials such as food crates and truck tarps. As David Greene of Archigram once wrote, “a traffic jam is a collection of rooms,” but “so is a car park—they are really instantly formed and constantly changing communities. A drive-in restaurant ceases to exist when the cars are gone (except for cooking hardware). A motorized environment is a collection of service points.” * * * “The counter-intuitive finding is that streets without traffic signals mean that cars drive more slowly and carefully because the rules of the road are ambiguous—there’s no red, green or yellow to tell drivers precisely what to do.” A Wired article from 2004 52

Concepts in Motion I

quotes Hans Monderman, the late architect of Holland’s minimalist roads, explaining his approach to influencing driver behavior: “A wide road with a lot of signs is telling a story,” Monderman says. “It’s saying, go ahead, don’t worry, go as fast as you want, there’s no need to pay attention to your surroundings. And that’s a very dangerous message.” * * *

Concepts in Motion I

Each December, up to 200 kilometers of Manila’s streets are turned into Christmas Lanes—temporary highways, stripped of their street parking, stop signs, and traffic signals. The scheme relieves congestion as shoppers flock to the city’s malls, increasing average traffic speeds on major routes speeds by about 14 percent. Traffic controllers have also been known to dress as Santa Claus, to add to the festive spirit. * * * Imagine a city in the jungle—a speculative city that literally moves. It never rests. “When its inhabitants build new districts,” McKenzie Wark writes in his recent book The Beach Beneath The Street, “it is always to the west. Each time they cut the ribbon opening a new quarter, an old one to the east is abandoned, gradually to disappear beneath the overgrowth of tropical vegetation.” The city thus advances and disappears, advances and disappears, fully and relentlessly mobile, moving further into a state of wilderness it then welcomes back into the districts that it’s left behind. * * * Over 42 million Americans moved in the 1-year period between March 1992 and March 1993. This amounted to 16.8 percent of the population 1 year old and over. Most of these persons made local moves—26 million moved from one residence to another within the same county. Nearly 8 million persons moved between counties within the same State and another 53

Concepts in Motion I

nearly 7 million changed States. During that 1-year period, 1.3 million persons moved into the United States from abroad. The estimated number of international migrants worldwide is 214 million, a number that has increased by an estimated 64 million over the past decade. This means that one of out of every 33 persons in the world today is a migrant, a population that would qualify as the fifth largest nation in the world. * * *

Concepts in Motion I

A recent GAO report found the benefit-to-cost ratio of deploying a nationwide real-time traffic information system across the United States would be 25 to 1, with the $1.2 billion projected costs outweighed by $30.2 billion in safety, mobility and environmental benefits. Overall, the benefit-to-cost ratio of ITSenabled operational improvements is estimated to be 9 to 1, a significant return on investment over the more conventional solution of adding new highway capacity, which has a benefit-to-cost ratio estimated at 2.7 to 1. * * * In his 1994 bestseller The Hot Zone, Richard Preston recounts the paving of the Kinshasa Highway—now also known as the “AIDS Highway,” for its tragic side-effect of helping to bring AIDS from the African continental interior out along regional trucking routes and, eventually, to every country in the world. The Kinshasa Highway, Preston writes, is “the road that cuts Africa in half, along which the AIDS virus traveled during its breakout from somewhere in the African rain forest to every place on earth.” “The paving of the Kinshasa Highway,” Preston suggests, “affected every person on earth, and turned out to be one of the most important events of the twentieth century. It has already cost at least ten million lives, with the likelihood that the ultimate number of human casualties will vastly exceed the 54

Concepts in Motion I

deaths in the Second World War.” * * * The human lags in the speed competition, with the 27 mph speed of track star and fastest man on earth Michael Johnson paling in comparison to machines like Space Shuttle (20 Mach), the X-43A jet (9.8 mach), the CRH380A train in China (302.8 mph), and the Bugatti Veyron Super Sport automobile (267 mph). Johnson even lags behind fellow animals like the Peregrine falcon (202mph), cheetah (70mph), sailfish (68mph), and dragonfly (60mph). Of course, his record blows away some of nature’s most tardy, like an iceberg (.20mph) or garden snail (.02mph).

Concepts in Motion I

* * * Until recently, neuroscientists believed that human perception of motion was produced in the MT region, a single cortical area in the brain. However, a new study published in December 2011, based on research conducted at NYU, Stanford University, and the University of Washington, has found that the visual system processes local motion—tracking signals that fall within a small retinal area—and global motion— synthesizing several movements over larger areas— quite differently. By measuring brain activity in the MT region as humans watched carefully designed patterns in which local and global motion were in disagreement with each other, the scientists found that not only was another brain region, whose nature is currently unknown, involved in perceiving global motion, but that the perception of global motion takes precedence over that of local motion in humans. * * * Stanford University bioengineer Scott Delp has created an open-source application that accurately models human motion. By programming each of the more than 600 muscles in the human anatomy into OpenSim, Delp hopes to help medical professionals, 55

Concepts in Motion I

prosthetic device designers, and bioengineers study, diagnose and correct abnormalities in how people move: “It can help determine whether a simple surgery to lengthen a specific muscle might help victims of cerebral palsy. It can predict how simple changes in gait might reduce the incidence or severity of osteoarthritis. In addition to helping millions delay or avoid costly hip and knee replacements, OpenSim could help in the development of new, more sensitive prosthetics, able to read and interpret electrical impulses to control the devices.” * * *

Concepts in Motion I

On June 27, 1894, 24-year-old mother of three, Annie Kopchovsky departed Boston on a bike, inspired to circumnavigate the world on two wheels in response to a bet that a modern woman could do just about anything a man could (Thomas Stevens had previously biked around the world in 1887). Upon her return, 15 months later, she became an instant celebrity, enchanting readers under the byline “The New Woman” with stories of hunting tigers with German royalty in India and a spell in a Japanese prison with a bullet wound in her shoulder. Many of these anecdotes were of dubious veracity, and she was accused of spending most of journey traveling with a bike, rather than on one. Nonetheless, her story vividly illustrates Susan B. Anthony’s statement, in 1896, that bicycling had “done more to emancipate women than anything else in the world.” * * * A typical North American food serving involves, it has been estimated, at least 11 separate journeys, from the truck that delivers artificial fertilizer to the farm all the way to the truck that takes 40 percent of the food we buy to the landfill, uneaten. In fact, only a fraction of so-called “food miles” are 56

Concepts in Motion I

used up to bring exotic or out-of-season foods to our tables. It is the industrial food system as a whole and the distortions created by cheap carbon-based fuel, rather than any specific food/s, that creates these extended movable feasts. Today, fish that is caught locally is likely to be frozen and sent on a ship to China to be filleted, before being sent back to the US for retail, due to the relative costs of labor and refrigerated ocean-borne transport. * * *

Concepts in Motion I

For the past ten years, Operation Migration, a USCanadian partnership of government and nonprofits, has been trying to re-establish the 1,285 mile Eastern flyway, which disappeared in the late 1800s when the last flocks of whooping cranes migrating along that route were driven to extinction. From a low of 15 birds in 1941, the group has managed to establish a viable flock of more than 100 birds, and is training more each year. The first thing the baby cranes hear after they are hatched in spring at the Patuxent Wildlife Research Center in Maryland is the recording of a crane’s brood call mixed in with the sound of the small plane’s engine. By fall, they are ready to follow the plane south to Florida on their first migration. * * * The Arctic tern migrates the longest distances of any animal. It flies over 21,750 miles (35,000 km) each year—roughly the circumference of the Earth. The longest-migrating mammal is the Gray Whale, which covers roughly 12,500 miles (20,110 km) each year. The insect with the longest migration is the desert locust, which travels about 2,800 miles (4500 km) each year—just slightly further than the Monarch butterfly’s 2,000 mile journey from Canada to central Mexico each fall. The caribou is the land animal with the longest commute, at about 700 miles (1100 km). * * *

Concepts in Motion I

More than 60 different species of animals use storm drains or culverts to cross Maryland’s highways, according to a recent study carried out by the University of Maryland’s Environmental Science Center. Using motion-detecting infrared cameras, the study’s findings demonstrate the importance of these drainage tunnels as wildlife corridors, connecting habitat that has been fragmented by asphalt and cars. The design of the state’s culverts varies considerably: the underground drainage structures range from 2 feet to 15 feet in diameter; can be made of concrete, metal, or even earth; and can be arch-, cylinder-, or box-shaped. Ed Gates, the study’s author, found that although raccoons are not particular about the shape of the culvert they use, and all animals prefer culverts that offer an unobstructed view, some distinct formal preferences can be traced across species: “Deer wouldn’t go near tunnels with cobbled floors. Eastern gray squirrels were not found in any arch-shaped culverts. Domestic cats seemed to take a liking to the cylinder-shaped tunnel. And great blue herons used the box shape more often than thought, most often when the bottom was sandy.” * * * Researchers studying the effect of roads on rattlesnake mating journeys in New York state found that even minor roads create isolation between different snake populations, causing a significant increase in inbreeding and reduction in genetic diversity. As Rulon Clark, the study’s leader and a professor at San Diego State University explained, not only do rattlesnakes try to avoid roads, but when “they’re disturbed by noise or vibration, their natural response is to freeze and rely on their natural camouflage to hope they won’t be detected. With cars, that’s exactly the wrong response.” * * * Washington Post music critic Chris Richards has analyzed the music of the metro system’s run-down 58

Concepts in Motion I

escalators as a form of experimental jazz: “Listen to the west entrance at Petworth. It’s all honk and grind - the clatter of a hundred bop quartets cooking from 5 a.m. to midnight. The escalators at Benning Road drone like an Indian tambura while arbitrary notes squeak and blurt, as if leaked from Pharoah Sanders’ saxophone.”

Concepts in Motion I

According to Metro spokesman Steven Taubenkibel, this secret music “is the result of a small plastic device that is installed on the escalators to protect the metal panels that line each side of the escalator’s steps from being damaged.” Water, salt, grit, and varying temperatures all alter the level of friction, and thus the particular notes that each escalator makes. “When those little plastic pieces start chafing against the escalator steps,” Richards writes, “the band is warming up. Squeaks turn into creaks. Tiny squalls become tenor wails. Saxophonish sneezes give way to the ghost of Johnny Griffin trying to cram every note he ever blew between Bling-blong “Doors opening” and the surface of the Earth.” * * * The rise of the “suspicious package” as a security phenomenon—for instance, a suitcase abandoned on the train or a backpack left anonymously on the subway platform—has given rise to a different criteria for surveillance: stillness or immobility. Cameras and camera operators now scan not simply for odd movements or suspicious behaviors, but for things that have stayed in one place for too long. That which exhibits no motion, we might say, becomes a threat. Packages left in place; humans loitering in one location; abandoned vehicles in parking lots or city streets: these spatial and temporal anomalies catch the eye of a new security paradigm in which immobility is reason enough to distrust something. * * * In 2011, five of the top ten Google searches in the 59

Concepts in Motion I

New York Metro area were mobility-themed: “mta” was the clear winner, followed by “nj Transit,” “hopstop,” dmv Ny,” and “ezpass.” * * *

Concepts in Motion I

Manhattan has some of the highest population densities in the United States: nearly 67,000 people per square mile according to the 2000 census, compared with an average of 2,000 to 3,000 per square mile in most other developed areas. Combine one-quarter the auto-ownership rate with twenty times the population density and Manhattan turns out to have a much higher density of locally owned autos than all but a handful of communities, most of them bedroom suburbs. Specifically, as of the 2000 census, Manhattan residents owned (or leased) more than 8,350 cars per square mile. That’s considerably more than Brooklyn or Queens (both around 6,500 cars per square mile), and more than twice car-crazy Los Angeles (about 3,900 cars per square mile for the city) and more than four times auto-friendly Houston (about 1,800 per square mile, again for the city). Few Americans realize that trucks deliver 70 percent of all freight tonnage or that 80 percent of U.S. communities receive their goods exclusively by truck. Motor carrier revenues represent nearly 84 percent of the nation’s freight bill. “It should be noted that even New York, the most transit-using city in the USA, clocks in at 2,700 BTUs/p-m for its subway and 3,300 for the average of all its transit systems combined—only slightly better than cars.” Brad Templeton * * * It is estimated that, for every person living in NYC, 6.6 lbs (3 kg) of food, 13.2 lbs (6 kg) of construction 60

Concepts in Motion I

materials, 26.4 lbs (12 kg) of consumer goods, and 46 lbs (21 kg) of petroleum products are transported into the city on the average day (including container weight). * * *

Concepts in Motion I

Shifting some of Manhattan’s more than 110,000 daily curbside deliveries to off-peak hours creates major savings in both time and fuel. In a 2009 pilot program that shifted delivery times for 30 truckers to between 7pm and 6am, trucks reached their first stop 75 percent more quickly than during peak hours, and the following stops 50 percent more quickly, while they cut unloading and loading time by two thirds, from 90 minutes down to 30. In an article in The Journal of Commerce that describes the report’s findings, New York City Department of Transportation Commissioner Janette Sadik-Khan trumpeted the benefits of off-peak deliveries: “Drivers found they could make deliveries on-time and be much more fuel-efficient, while receivers didn’t spend hours waiting for deliveries each day.” What’s more, truckers saved an extra $1,000 per truck per month by avoiding daytime parking tickets. Truck driver Chubb Chang agreed, explaining that “You may have to circle a block for half an hour to find a place to park during the day. With off-peak delivery, you can do twice as many turns.” * * * From 2008-2009, bicycle ridership decreased in New York City. * * * The total mileage of New York City’s road network is 19,324, which is nearly seven times the distance between the city and Los Angeles. * * * Even in San Francisco, often thought of as an ideal 61

Concepts in Motion I

urban environment, the car and its support system rules. Experts estimate that 70 percent of San Francisco’s downtown outdoor space is devoted to the car. The total number of spaces, as Mayor Gavin Newsom recently announced on his Youtube site, is 441,541. “Manhattan represents the apotheosis of the ideal of density per se, both of population and of infrastructures; its architecture promotes a state of congestion on all possible levels, and exploits this congestion to inspire and support particular forms of social intercourse that together form a unique culture of congestion.” Rem Koolhaas

Concepts in Motion I

Every year, New York City hosts one of the “most complicated security event[s]” in the world, in the words of The Atlantic: the annual gathering of world leaders at the United Nations General Assembly. The organization tasked with making sure it all goes smoothly is the U.S. Secret Service. In addition to an extraordinary range of converted hotel rooms, sniper posts, mobile command centers, makeshift radiocommunications links, and more, there is a detailed plan in place for evacuating world leaders from Manhattan in the event of a large-scale terrorist attack. As investigative journalist Marc Ambinder writes in The Atlantic, the Secret Service has set up “a tactical command post, code-named ‘North Star,’ at a secret location in the city.” Run by the service’s Special Operations Division, North Star was responsible for arguably the most sensitive part of the assembly preparations. ‘One of the things we know,’ [Brian] Parr, [special agent in charge of the field office,] told me, ‘is that when things go wrong, we’ve got to get 150 world leaders and their spouses off the island’—that is, Manhattan—‘in a hurry.’ For weeks, the Special Operations Division scouted evacuation routes, hardened safe houses throughout the city, and secured Coast Guard assets. If a situation arose in which protectees needed to be moved to safety, 62

Concepts in Motion I

counter-assault (or CAT) teams would ‘crash’ the event and secure an evacuation pathway.” Ambinder continues: “As a last resort in the event a leader is shot or otherwise injured, the service has what Parr calls its ‘secret weapon’ on 24/7 standby. Dr. Maurizio Miglietta, a former chief of trauma at Bellevue who has been working these summits for years, provides the agency with a team of doctors and nurses, and sets up a mobile trauma unit at major venues. He can perform surgery on the spot, if necessary.” * * *

Concepts in Motion I

Much of New York City exists in a near-permanent state of quarantine. Due to the threat of the Asian Longhorned Beetle, wood debris—such as tree branches downed by heavy snow or thunderstorms— cannot be moved between the city’s boroughs. What the city classifies as “private wood debris” must thus remain in place, as “the only effective means to control the beetle is to remove infested trees and destroy them by chipping or burning the wood.” Unfortunately, so far “the beetle has been discovered in parts of Brooklyn, Manhattan, Queens, and Staten Island. As a result, quarantine has been established regulating the movement of any tree wood in these boroughs.” It is thus against city regulations to smuggle branches across borough lines. * * * In Rubble, a history of architectural demolition, author Jeff Byles tells the story of a man in New York City who refused to move, choosing instead to remain in his house while the city block around him was torn down in preparation for a private “urban renewal scheme.” “Much to his unpleasant surprise,” Byles write with considerable understatement, the man soon realized that the neighborhood’s rat population had no more buildings left to occupy—so they made straight for 63

Concepts in Motion I

his lone-standing house. The home was soon “commandeered by the entire block’s cohort of rats—two tons of them in all, done in by exterminators and shoveled from the basement. One witness, describing the teeming scene just before the rats were gassed, wrote that she ‘will never forget the extraordinary hum of the vermin that came from the house even though all the windows and doors were sealed.’” Sites that refuse to change as the city around them shifts—sites that resist historical or architectural mobility—can find that transformation is, often unfortunately, forced upon them. * * *

Concepts in Motion I

The elevator, along with the steel frame, makes tall buildings—and thus urban density—possible. New York City is home to roughly fifty-eight thousand elevators, with an estimated eleven billion elevator trips per year—thirty million every day. They are a surprisingly safe (ten times as safe as escalators, according to elevator professionals) as well as energy-efficient (the counterweight does a lot of the work, and most new systems actually regenerate electricity) form of urban transportation. However, as Nick Paumgarten reports in a fascinating New Yorker article on the subject, “the amount of core space that one must devote to elevators, in order to convey so many people so high, can make a building architecturally or economically infeasible. This limitation served to stunt the height of skyscrapers until, in 1973, the designers of the World Trade Center introduced the idea of sky lobbies.” “An escalator can never break: it can only become stairs.” Mitch Hedberg On Second Avenue between 61st and 62nd stands a largely windowless neo-Gothic tower behind whose walls “lies an ingenious system of steel vaults travel64

Concepts in Motion I

ing on rails.” The Day & Meyer, Murray & Young warehouse, which was built in 1928, was the subject of an October 2011 New York Times profile by architectural critic Mark Lamster, who described its mobile armored containers thus: “The Portovault units look a lot like modern shipping containers, which they predate by more than two decades. Each Portovault is essentially a steel safe, 11 feet long and tall enough to stand in, that can hold the contents of a typical one-bedroom apartment. It weighs almost a ton when empty but has four small steel wheels that allow it to be pushed along runners by a lone workman.”

Concepts in Motion I

“The innovation was that it could be delivered to the door of a client on the firm’s armored Diamond T truck, loaded, locked and then returned to the warehouse.” “There, the architects had installed a rail system, so that each unit could be routed from the loading dock into a large freight elevator, and then onto its designated floor and into its assigned space. The building, which can hold more than 500 of the units, is in a sense a giant storage rack.” The contents of the mobile containers is, of course, a closely guarded secret, although the firm’s spokesperson admits it ranges from moose heads to kayaks, in a “sort of a potpourri of madness.” * * * There is a “secret subway stop” beneath the WaldorfAstoria Hotel. As New York Magazine explained in 2008, this “now-abandoned subway track… was used as a special VIP entrance for fancy-pants rich people with their own private subway cars.” However, it was “also used by President Franklin Delano Roosevelt, so he could enter and leave the hotel without the public realizing he couldn’t walk unassisted because of his polio.” There was even “a private train” for the 65

Concepts in Motion I

president, parked beneath the hotel for special occasions (including emergency evacuation). *â&#x20AC;&#x201A; *â&#x20AC;&#x201A; *

Concepts in Motion I

In 2007, architect Annabelle Selldorf released her design for 200 Eleventh Avenue, in the Chelsea section of Manhattan. The 19-story, 16-unit, steel-clad condominium tower is most notable for the first of its kind, En Suite Sky Garage, an 8,000-pound car elevator that takes residents from the street to a personal garage steps away from their apartment. The garage is able to automatically identify a car and which apartment it belongs to. After driving into the elevator, the freight elevator transports the car to the correct floor and allows a resident to pull out of the elevator and into their very own garage. All units have been sold, with two penthouses selling for a combined $29 million.

Concepts in Motion I

Car Names

A4 Avant Armada Beetle California C-Class Challenger Eclipse Enclave Escape Fiesta 5 Series Focus Galant Genesis Ghost Golf Jazz Jetta Liberty M-Class Optima Outback Pathfinder Phantom Prius Q7 Quest R8 Spyder Regal Rogue S8 Saloon S-Class 7 Series Sienna Silverado Sonata Sonic Superb Terrain Titan Town & Country Tribeca TT Roadster Yukon 67

Concepts in Motion I

Transit Names

ABQ Ride BadgerBus BART CAT CATS Charm City Circulator! (CCC) Coaster COTA DART FAX FREX IndyGo Lolly the Trolley LYNX MARTA MATA MAX MAX MBTA MCTS Metro Metromover Metrorail Molly the Trolley Mountain Metro MTA Music City Star PeopleMover RapidRide RTA Rapit RTC Sac RT SEPTA SMART Sprinter Sun Metro Sun Tran TARC Triangle Transit Tulsa Transit U-Bahn Valley Metro/METRO Via + Via Primo WES 68

Concepts in Motion I

Disney’s Magic Highway USA, 1958

Technologies

App Lets You Auction Off Parking Spot Parking Auction, a new iPhone app, pairs drivers searching for a parking space with those ready to vacate theirs—for a fee. Crucially, it’s not the space itself that’s for sale—but the information of when a space might become available. Users determine how much that information is worth to them. Currently beta testing on the Upper West Side, founder Brian Rosetti hopes to soon expand Parking Auction’s coverage.

Ydreams, Santander robots, 2010 Bank Introduces Robot Escorts Santander, a banking group based in Spain, has solved its wayfinding problems creatively: autonomous friendly-looking red robots. The Santander 69

Concepts in Motion I

Interactive Guest Assistants (SIGAs) glide up once you’ve entered the Madrid Headquarters, and after you’ve entered your destination on a console, they escort you there. Ydreams, the Portuguese designers of the robots, notes that this is one of the first commercial applications of swarm robotics.

Technologies

Concepts in Motion I

Streetline, Parker application, 2010 San Francisco Parking Gets More Efficient with Streetline App Streetline, a new high-tech start-up in San Francisco, uses sensors on parking meters to offer real-time info on where available parking spaces are and how much to charge. The inexpensive sensors, which can be attached to existing meters, relay information to a citywide network, which points drivers to parking spaces and shows expired spaces to meter maids. Currently being beta tested in San Francisco, Los Angeles, and Sausalito, and coming soon to Washington, DC, and Roosevelt Island, Streetline can also offer cities the opportunity to dynamically price parking spaces based on demand. “The hope here is that guided parking becomes part and parcel of a next generation of services for citizens,” [Streetline CEO Zia] Yusuf 70

said. “That in seven to ten years, people will look at you funny when you say you used to have to drive around looking for a space.”

Audi, Audi TTS, 2010

Technologies

Audi’s Robotic Car Audi’s driverless car, the TTS, conquered Pikes Peak, a Colorado automotive hillclimb. By making it to the top, Audi says it is showing that new autonomous technology can handle the most challenging circumstances. “We are not trying to replace the driver,” Stanford professor Chris Gerdes said. “Instead we want to learn how the best drivers control the car so we can develop systems that assist our robotic driver and, eventually, you and me.”

Yusuke Sugahara and team, levitating plane-train, 2011 Levitating Plane-Trains as the Future of Mass Transit? Japanese researchers have debuted a a robotic planetrain that hovers above the ground. Riding within a concrete channel, the plane-train uses the increased 71

Concepts in Motion I

lift that its low flying altitude provides for propulsion. The researchers hope to eventually develop the plane-train into a functioning commuter train.

Technologies

Steven Spielberg, ‘Minority Report,’ 2002 Minority Report Maglev Transportation System Minority Report’s futuristic transportation system may seem a conceptual moment of fancy. Self-driving cars whizz along both horizontal and vertical magnetic roadways at top speeds. But the the movie’s rendering of 2054 may not be so far off. Computercontrolled cars have already been rolled out by a number of automotive companies such as Audi with the A2. Meanwhile, the maglev technology that the designers based Minority Report’s transportation system on already exists and is in use in bullet trains running in Japan, China, and South Korea. One of the designers, articulates the approach in thinking about the fictional future, “We discussed how a future goal will be individual transportation within a mass transport system,” says Harald Belker. The result is “something between a capsule and a car.” App Bumps Knowledge of Potholes A new Android app, Street Bump, has been introduced in Boston to track and report potholes while you drive. Using the phone’s sensors, the app senses bumps. The next step, to be rewarded with a $25,000 prize, is to figure out how to use the data to deter72

Concepts in Motion I

mine a pothole’s seriousness. “It’s a new kind of volunteerism,” Nigel Jacob, Co-Chair of New Urban Mechanics, the govermental office behind the app, told The Boston Globe. “It’s not volunteering your sweat equity. It’s volunteering the devices that are in your pocket to help the city.”

Technologies

EU SARTRE, road train, 2011 European Road Trains in Testing Road trains are in testing in the EU. A road train is a platoon of 6-8 cars which travel together, communicating wirelessly. Following a professionally-driven vehicle (for example, a bus), the linked cars become semi-autonomous en route to the shared destination, but drivers regain control when it’s time to turn off to their specific direction. The initiative behind the research, European Union’s Safe Road Trains for the Environment (EU Sartre), hopes that road trains increase aerodynamic efficiency and reduce congestion while allowing people use of an individual vehicle. Feds Testing Vehicle-to-Vehicle Communication The National Highway Traffic Safety Administration has begun tests of vehicle-to-vehicle (V2V) technology where cars communicate with one another, thus increasing safety. Using onboard sensors, cars talk in real-time, transmitting their speed and location to other cars. A car’s computer takes this data into account to prevent accidents, either warning the driver or actively deploying brakes. For V2V to take off, however, all cars must be able to communicate, making it crucial that the NHTSA set universal standards sooner rather than later. 73

Concepts in Motion I

L-Dopa, ShotSpotter, 2007

Technologies

ShotSpotter Oakland has renewed its contract with ShotSpotter, a sensor system designed to detect and locate the sound of gunfire. Originally installed in Oakland in 2006, Shotspotter neighborhood sensors pinpoint the sound of gunfire and then instantly relay the information to the police. This high-tech solution avoids the problem of citizens too scared or distrustful of the police to report gunshots as well as the hurdle actually figuring out where reported gunfire is actually coming from. Besides Oakland, ShotSpotter is being adopted by a number of cities prone to gun crime, such as LA and Washington, D.C. Piezoelectric Technology Powers up Through Vibrations Researchers at Cornell’s NanoScale Facility are developing sensors which can use vibrational energy to power devices. Piezoelectric technology has been in use for a while in microphones and phonographs, but pairing the piezoelectric material with razor-thin batteries allows for banking the created energy. A car going through potholes, for example, could be simultaneously providing energy to its devices. “Avoid-Ghetto” Mapping Microsoft has come out with an “avoid ghetto” feature on their Microsoft smartphone. Using crime statistics, the feature can map routes to avoid more dangerous areas. 74

Concepts in Motion I

Shoulder-Worn Acoustic Targeting System Soon to be used by US troops, the Indvidual Gunshot Detector (IGD) by Qinetiq, a two-pound unit worn at the shoulder, uses supersonic gunshot waves to calculate where enemy fire is coming from. The information is then transmitted into an earpiece worn by the solider. As Brig. Gen. Peter Fuller, Program Executive Officer Soldier, notes, it allows for a completely different mapping of sniper fire: “If you get shot at, not only do I know where that came from, but others know where it came from because I can network that capability.”

Technologies

Intelligent Transportation System Countries around the world are funding research into ITS, which aims to network all transport information, thus allowing for real-time data on congestion, public transportation, or even the location of an individual vehicle. Future in-car navigation systems will connect to the ITS network, allowing cars to communicate and prevent accidents. ITS can make parking less of a hassle, transform public transportation and reduce traffic. For now, the US Department of Transportation is focused on intercar networking: most of its 2010-2014 funding has been allocated for vehicleto-vehicle communication. The United States’ $100 million a year funding on ITS, however, pales in comparison to countries like Singapore, Japan and China, which spent more than $2.8 billion on ITS last year.

Department of Defense, Nett Warrior, 2011

Concepts in Motion I

GhostRider Vs Nett Warrior: Military Smartphones Though the army has been working on a way to network soldiers together for over 20 years, coming out recently with the Nett Warrior, defense company ITT might be outdoing it with the GhostRider. It’s a war of the smartphones. The Nett Warrior is a smartphone-like device, while the GhostRider is a small encryption add-on to a commercial smartphone like the Android. Both become secure devices that can allow soldiers to communicate and track others’ position. It’s unclear whether the Nett Warrior or the GhostRider will prevail—network testing results and costs will determine that, but more efficient networking will soon be coming to the military.

Technologies

Mini-Robots Map Out Building Interiors Mini-robots are being developed that can independently explore and map an unknown location or building. Using a technology called simultaneous localization and mapping (SLAM), researchers with Georgia Institute of Technology, the University of Pennsylvania, and the California Institute of Technology/Jet Propulsion Laboratory (JPL) have created robots that can map out their environment and locate themselves, of use to soldiers or firefighters. SLAM is of particular benefit when GPS is unavailable. Eventually, the researchers hope to couple the robots with another platform which would function from above, locating a specific building and its entrances and then calling in the droids to explore. Large Area Coverage Search-While-Track and Engage (LACOSTE) QinetiQ is developing a new sensor system, Large Area Coverage Search-while-Track and Engage (LACOSTE), which can work at high altitudes of around 20km. Using optical and infrared sensors and a very wide field-of-regard, LACOSTE will be able to detect and track moving vehicles in dense urban areas, tracking up to 10,000 targets simultaneously. Wireless Charging for Electric Cars Electric cars may soon be able to charge wirelessly. 76

Concepts in Motion I

WiTricity, a company focused on wireless chargers, is developing a a wireless network to charge electric vehicles that uses the principle of magnetic resonance coupling. Meanwhile, a team at the University of Michigan–Shanghai Jiao Tong University Joint Institute in China is pushing to develop dynamic charging, in which chargers are installed in the road, so that electric cars can charge while driving. Both systems, however, are impeded by the close distance needed to wirelessly recharge: 12 to 18 centimeters.

Technologies

The Car of the Future is a Node on a Network By 2020, according to Kaveh Hushyar “everyone will be a passenger.” In an Ars Technica interview, the CEO of Telemtria described the future of driving. Self-driving cars will require a suite of applications: both to run the car and to transform it into a mobile office. Safety applications like sleepy eye detection and vehicle-to-vehicle networking will be required for semi-autonomous driving, with voice enablement technology also on the rise, letting the driver multitask. These are just a few examples of the applications currently propagating; as Hushyar points out, “Every one of these could be running concurrently in the car, and the processor has to have the capability to handle it.” Hushyar also mentions that a soft infrastructure will need to be in place to collect, analyze and, if necessary, transmit, information about vehicular conditions, requiring cloud computing.

UniModal, rendering of SkyTran, 1999 77

Concepts in Motion I

Flying Pods a Solution for Personal Transportation? Patented in 1990 by aero-mechanical engineer Douglas Malewicki, SkyTran is a Personal Rapid Transit system where light passenger pods hang from elevated maglev tracks. Passive maglev technology means that the cars can move without any external power while the lightness of the cars allows the infrastructure itself to be fairly inexpensive, thus making SkyTran a cheap and sustainable form of transportation. NASA is currently helping develop SkyTran and there are talks of building the SkyTran in Detroit instead of the proposed light-rail.

Technologies

Concepts in Motion I

The Great Wharf, Chicago, 1893 Moving Sidewalks In 1871, Alfred Speer patented a system of moving sidewalks that could transport pedestrians on three separate belts, each running at different speed intervals, intended for use in New York City. In 1893, Eugene Henard implemented the first moving sidewalk at the Columbian Exposition in Chicago. The 1900 Paris Exposition also featured a moving sidewalk, which Thomas Edison sent a team to record. Like its 1871 predecessor, the sidewalks moved at different speed intervals, however they had a separate track for an electric car. Throughout the first part of the 20th century, the moving sidewalk continued to be associated with ‘the city of the future.’’ The 1962 cartoon The Jetsons prominently featuring them as 78

part of the outer space landscape. Goodyear took a particular interest in the technology, wanting to pair the sidewalks with New York Cityâ&#x20AC;&#x2122;s subway systems. They later worked with Disney to implement the moving sidewalks in their theme parks. The first moving walkway to be permanently installed was the Travolator, which connected a bridge to a new motel. This design was used at airports in London, Atlanta, and Los Angeles.

Technologies

Concepts in Motion I

Personal Mobility

A BRIEF HISTORY OF PERSONAL MOBILITY FOR AND BY DESIGN.

Personal Mobility

Any serious study of motion requires that attention be given not only to the systems and metrics behind the movement of goods, people, microscopic organisms, particles, etc. but also to the desires that underwrite a culture obsessed by individual mobility and freedom. Whether or not the automobile will persist as an instrument in this narrative remains to be seen, but the psychological impetus behind its rise to prominence will need to be reflected in whatever forms of mobility that emerge going forward. While the freedom to move suggests both creativity and sex appeal, it also embodies fugitive impulses, insular lives, and the symbolic weight of Manifest Destiny. From a collage of a Rolls Royce grill superimposed against the Manhattan skyline to image-conscious politicians cruising the streets on two wheels, the following presents a glimpse at our received history of personal mobility in all its ambivalence, through the lens of the architects, icons, and built objects of the twentieth century.

Personal Mobility

Architects and Their Cars

Personal Mobility

Frank Lloyd Wright in Packard car, 1929

Frank Lloyd Wrightâ&#x20AC;&#x2122;s car crash, 1933

Architects and Their Cars

Personal Mobility Buckminster Fuller, Dymaxion Car, 1933

Walter Gropius, Adler car, 1931

Le Corbusier and Pierre Jeanneret, Voiture Minimum, 1936

Mies van der Rohe, Neue Nationalgalerie, 1968

Architects and Their Cars

Personal Mobility

Carlo Mollino, Nardi-â&#x20AC;&#x2039;Giannini 750 Bisiluro, 1955

Richard Neutra, sketch of a nursing mother in a car at Garden Grove Community Church, ca. 1960

Architects and Their Cars

Personal Mobility

Ed Ruscha, Mike Salisbury, and Reyner Banham in â&#x20AC;&#x2DC;Reyner Banham Loves Los Angeles,â&#x20AC;&#x2122; 1972

Robert Venturi and Denise Scott Brown, Las Vegas studio, 1968

Architects and Their Cars

Personal Mobility

Adolf Loos, car sketch, 1923

Craig Ellwood-sponsored car, Long Beach Grand Prix, 1975

Architects and Their Cars

Personal Mobility

Craig Ellwoodâ&#x20AC;&#x2122;s Ferrari Dino at Art Center College of Design, 1976

Gio Ponti, Touring Superleggera, ca. 1920

Architects and Their Cars

Personal Mobility

Terreform ONE, Soft Car: LAMB, 2010

Architects and Their Cars

Personal Mobility

Zaha Hadid, Z-Car, 2006

Architects and Their Not-Cars

Personal Mobility

Antoine Predock, ca. 1990

Jane Jacobs, 1963 92

Charles and Ray Eames, 1948

Architects and Their Not-Cars

Reyner Banham, Scenes in America Deserta, 1989

Reyner Banham, ca. 1960s 94

Personal Mobility

Architects and Their Not-Cars

Personal Mobility Norman Foster, ‘How Much Does Your Building Weigh, Mr. Foster?,’ 2010

Alvar Aalto, Nemo Propheta in Patria, 1955

Architects and Their Not-Cars

Personal Mobility

Renzo Piano, Kirribilli, 2001

Icon Mobility

Michael Bloomberg, NYC Mayor, 2011. Mayor Bloombergâ&#x20AC;&#x2122;s subway trips to City Hall often began by private SUV transport from his home to the 59th Street and Lexington Avenue express stop 22 blocks away.

John Lindsay, former NYC Mayor commutes to work by subway on his last day in office, 1973 97

Personal Mobility

Icon Mobility

Personal Mobility A noted bicycle enthusiast, Mayor Lindsay banned cars from Central Park on weekends as part of his â&#x20AC;&#x2DC;Fun Cityâ&#x20AC;&#x2122; initiative for New York.

John Lindsay, Former NYC Mayor, 1968

Icon Mobility

Personal Mobility

Janette Sadik-Khan, NYCDOT Commissioner, 2007

Robert Moses, Walt Disney and Henry Ford II, publicity trip for the Magic Skyway, 1964 99

John F. Kennedy, Jr., ca. 1990

Icon Mobility

Personal Mobility

New York chef Mario Batali shuttles between his Chelsea and West Village restaurants on his Vespa, 2009

100

Icon Mobility

Personal Mobility Boris Johnson, London Mayor, 2010

Boris Johnson, London Mayor and Arnold Schwarzenegger, former California Governor, 2011 101

Icon Mobility

Personal Mobility

President Franklin Rooseveltâ&#x20AC;&#x2122;s cars were modified to include hand controls for the breaks and accelerator to allow him greater mobility despite lower body paralysis, ca. 1941

102

Icon Mobility

Personal Mobility

Marlon Brando, ‘The Wild One,’ 1953

Steve McQueen and his Ferrari 250 GT Berlinetta Lusso, 1964

John Hughes, ‘Ferris Bueller’s Day Off,’ 1986 103

Icon Mobility

Personal Mobility

OJ Simpson and LAPD, 1994

Gordon Brown, former UK Prime Minister, and George W. Bush, former US President, 2007

104

Buildings and Their Cars

Personal Mobility

Volkswagen Autostadt glass silos, 2000

105

Volkswagen Autostadt glass silos, 2000

106

Buildings and Their Cars

Personal Mobility Le Corbusier, Palace of Justice, 1963

Le Corbusier, Villa Savoye, 1931

107

Buildings and Their Cars

Personal Mobility

Michigan Theater Car Park

Coop Himmelblau, BMW Welt, 2007

108

Buildings and Their Cars

Russell G. Cory, Walter M. Cory, and Yasuo Matsui,Â Starrett-Lehigh Building, 1931

Russell G. Cory, Walter M. Cory, and Yasuo Matsui, Starrett-Lehigh Building, section with truck elevator, 1931

Annabelle Selldorf, car elevator, 200 Eleventh Avenue, 2010

109

Personal Mobility

Buildings and Their Cars

Personal Mobility

Bertrand Goldberg, Marina City, 1964

Ronnie Self, Saint Emanuel House, 2009 110

Buildings and Their Cars

Personal Mobility

Ludwig Hilberseimer, Vertical City, 1924

Michael Targe, Jean-Michel Wilmotte and Daniel Buren, Parc des Celestins, 1994

111

Buildings and Their Cars

Personal Mobility

Office dA, Helios House, 2007

Kanner Architects, United Oil Gas Station, 2009

112

Buildings and Their Cars

Personal Mobility Phillip Johnson, Crystal Cathedral, 1981

Richard Neutra, Garden Grove Community Church, ca. 1961 113

Buildings and Their Cars

First McDonaldâ&#x20AC;&#x2122;s franchise restaurant, 1955

MOS, Drive-In and Park rendering, 2009

114

Personal Mobility

Buildings and Their Cars

Personal Mobility

UN Studio, Mercedes Benz Museum, 2006

115

Buildings and Their Cars

Personal Mobility

Mies van der Rohe, Seagram Building, 1958

Delugan Meissl, Porsche Museum, 2009

116

Buildings and Their Cars

Personal Mobility

Futurama Exhibit, GM Pavilion, 1939 117

Buildings and Their Cars

Personal Mobility Jean Nouvel, Ferrari Factory, 2008

Herzog & de Meuron, 1111 Lincoln Road, 2010

118

George Applegarth, Bon Marche Parking Garage, 1960

Buildings and Their Cars

Personal Mobility

Victor Gruen, Millironâ&#x20AC;&#x2122;s Department Store, 1948

119

Buildings and Their Cars

Paul Rudolph, Temple Street Parking Garage, 1962

Owen Luder and Rodney Gordon, Tricorn Centre, 1966

120

Personal Mobility

Buildings and Their Cars

Personal Mobility

Caption goes here

OMA, Seattle Public Library, 2004

Santiago Calatrava, Milwaukee Art Museum, 2001

121

Walter Gropius, Bauhaus, 1925

Buildings and Their Cars

Personal Mobility

David Chipperfield, Americaâ&#x20AC;&#x2122;s Cup Building, 2006

Richard Meier, Italcementi i.lab, 2011 122

Pierre Koenig, Case Study House no. 21, 1958 123

Buildings and Their Cars

Frank Lloyd Wright, Guggenheim Museum, 1958

Hans Hollein, â&#x20AC;&#x2DC;Rolls Royce Grill on Wall Street,â&#x20AC;&#x2122; 1966

124

Personal Mobility

Buildings and Their Cars

Chris Burden, ‘Trans-fixed,’ 1974

Dorothea Lange, ‘There’s no way like the American Way,’ 1937

125

Personal Mobility

Buildings and Their Cars

Personal Mobility

Frank Gehry, Guggenheim Bilbao, 1997

126