Through his fundamental electromagnetic discovery, Faraday took notice of circular motion in general, and he reportedly observed two gears in a mine whose motion was
normally
not perceptible at all because of speed and thus because of the after- image effect (Zglinicki, 1979, p.
Kittler-Friedrich-Optical-Media-pdf
134).
It must he pointed out again how right Manfred Frank is (although probably unintentionally) when he celebrates the human - freely quoting Schleiermacher and Sartre - as a collective individual. In the age of the monopoly of writing, Goethe could explain that individu- als do not exist at all, but rather only genera or types. In spite of all attempts to project the protagonists of novels before the inner eye like a lanterna magica, no one knew what they actually looked like. Because language belongs to everyone, according to Hegel's insight, descriptions always already transform individuals into universals. The most glaring literary example of this transubstantiation was the arrest warrant that Georg Buchner inserted into his comedy Leonce and Lena after his own bitter experiences with the Hessian police in 1835:
FIRST POLICEMAN. Gentlemen, we are looking for someone, a
subject, an individual, a person, a delinquent, an interrogatee, a
rogue. (To the SECOND POLICEMAN. ) Have a look, is either of
them blushing?
SECOND POLICEMAN. Neither of them is blushing.
FIRST POLICEMAN. So we must try something else. Where is the
"wanted" poster, the description, the certificate? (The SECOND POLICEMAN takes a paper from his pocket and hands it to him. ) Scrutinise the subjects while I read: "A man . . . "
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SECOND POLICEMAN. No good, there are two of them.
FIRST POLICEMAN. Numbskull! ". . . walks on two feet, has two arms, also a mouth, a nose, two eyes, two ears. Distinguishing fea-
tures: a highly dangerous individual. "
SECOND POLICEMAN. That fits both of them. Shall I arrest them
both? (Btichner, 1987, p. 129)
So much for the comical aspect of old European warrants. Now for the sad part: the actual warrant for the fugitive Georg Biichner that the Grand Duchy of Hessen pubhshed m the Frankfurter Journal on June 18, 1835 contained little more:
Arrest warrant. Georg Buchner, student of medicine from Darmstadt, has fled the fatherland to evade criminal invesigation of his participa- tion in acts of treason against the state. Public authorities both at home and abroad therefore request that he be arrested and turned over to Councillor Georgi, the examining magistrate appointed by the Grand Ducal court of the province of Upper Hesse. Darmstadt, June 13, 1835. Personal description. Age: 21 years. Size: 6 feet, 9 inches according to new Hessian measurements. Hair: blonde. Forehead: very arched. Eyebrows: blonde. Eyes: grey. Nose: str()ng. Mouth: small. Beard: blonde. Chin: round. Face: oval. Complexion: fresh. Stature: strong, thin. Distinguishing features: near-sighted. (Buchner, 1985, p. 92)
In Biichner's ingenious simplification, the literary warrant reveals how the high absolutist authorities had invented him very literally as a single subject, which means that it conflated so to speak all actual subjects into one subject. In the empirical press, like the Frankfurter Journal, things were only marginally more complicated: Biichner's warrant did not actually describe all the subjects of the Grand Duchy of Hessen, but rather it only pertained to the ideal of a healthy, blond student, and there were at least a few hundred real students who fitted this literary model. Modern forensic evidence, on the other hand, works with media rather than arts - its correlate, therefore, is nothing but statistically singularized individuals who (as in Poe's famous tale The Man in the Crowd) can themselves still be fished out of the masses.
Two photographic examples related to modern forensic evidence now follow. The first is fictional, and the second is its historical confirmation.
The literary and therefore fictional example is taken from a book by Gerhard Plumpe with the entitled Der tote Blick (The Dead Look). In a slightly redundant way, this book shows how nineteenth-century
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photography legally disrupted the copyright law concerning images (at that time, this of course meant hand-painted images), which had only just recently been introduced. Despite this preoccupation with laws (and not with media technologies), Der tote Blick contains several observations for which one can be grateful.
Plumpe summarizes the content of a comedy that the high pros- ecutor and forgotten poet Apollonius von Maltitz produced in 1865 under the title Photography and Revenge:
The arrival of a traveling photographer at a bathing resort causes a disturbance, as the photographed guests feel that their portraits are an imposition in every respect. "That's how I should look? " - complains a young woman - "not simply ugly enough to horrify people, but mali- cious, like an ex-convict [. . . ], That is my poor deceased father's favor- ite child! Could you love these grimaces, my unfortunate Rudolph? - Everyone who looks at me this way must see me as the crooked daughter of a wealthy factory owner, who married an aristocrat only because of his money. " Aod her mothe~ who is also photographed, is appalled: "Led to the altar from the nursery, beautifully named, deified by painters [. . . Jsculpted in marble by Thorwaldsen - now in the hands of a charlatan. " It continues this way for a while longer, and the confused indignation of the bathing guests is made complete when an "art expert" confirms the success of the portraits. "Do you find a faint similarity? " the expert is asked, and he answers: "It is not ideal, but rather perfect. It is not similar, but rather absolutely the same! " The horror of the guests eventually becomes so extreme that the doctor of the resort forbids the photographer from practicing his trade. The story takes its first turn of events when the photographer accidentally succeeds in photographing a criminal who is up to some mischief at the resort and is stealing from the guests. With the help of "realistic" photography, the thief is arrested. Photography is thus rehabilitated and the guests ultimately praise the mastery of his "art. "
(Plumpe, 1990, p. 193)
So much for the comedy Photography and Revenge. Mediocre poets c;n therefore also be good lawyers and even better media theorists. On the one hand, the media technique of photography destroys pre- cisely the "ideal" or imaginary, which sculptors or painters repro- dnced again and again when they dutifully "deified" their models, because it manifests for the first time something real that makes even the noblest daughter suddenly look like an ex-con (guillotine grimaces, as Pynchon said). (For this reason, by the way, there has been a law in the German Reich since 1902 that gives every man and woman the "right to one's own image," which protects them against
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the mIsuse of photography. ) On the other hand, however, photogra- phy also demonstrates the completely new ability to recognize and thus produce real convicts. And third, the fact that it did not become famous as "art" (in the old European understanding of the term) until or rather precisely after this criminalistic success proves - and here I deviate from Plumpe's thesis - that all talk about photography as art actually serves to conceal its strategic functions.
To conclude this digression concerning the cultural effects of the new medium, I would only like to point out that photography as legal retributIOn not only celebrated Its tnumph in literary fiction. As early as 1883, "a rapid photographic printing process" for arrest warrants, which Bertillon reportedly took over and standardized, enabled the arrest of "the dangerous anarchist Stellmacher" in Vienna (Eder, 1978, p. 441). As you may remember, nitrocellulose can be used to make either bombs, like the anarchists, or roll film, like the Viennese police. Between these two barrages, the anarchistic and the photo- graphic, the human as collective individual explodes.
3. 2 Film
3. 2. 1 Preludes
Now we come unceremoniously to the prehistory of film. For the storage of moving images it is just not enough to make a donnish assistant like Morse stand still for half an hour, as Draper did for the first photographic portrait, or to bind a criminal during an anthro- pometric sitting, as Bertillon did. Rather, it involves fixing the object or target precisely while it is fleeing and being able to reproduce this fixed movement again anywhere. For these two reasons, I will begin the prehistory of film with an American ship's boy named Samuel Colt. His history is actually slightly mythical and it will need to be expanded more correctly and precisely in a future lecture on the history of weapons technology, but it will suffice for today. In 1828, the ship's boy went to the East Indies and on the way he had a technical epiphany - namely, the revolver that is now named after him. Colt revolvers, as celebrated and not by accident in all western films, no longer aim their six shots from one man to another, but rather from one white man to six Indians or Mexicans at virtually the same time. This was the reason why Colt, whose factory almost bankrnpted him, did not become a wealthy arms supplier until the American-Mexican War of 1847.
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The colt not only introduced the Innovation of being able to
shoot six moving targets in quick succession at a time when contem-
porary soldiers still needed a full minute to load the next round in their muzzle-loaded rifles, but rather it fundamentally revolutionized the process of industrial manufacturing. For promotional purposes, Colonel Colt was always fond of demonstrating to his astonished visi- tors that it was possible to disassemble six colts on a table, jnmble up their component parts, and in the end - despite this artificial introduc- tion of statistics or noise - reassemble six fully functional colts once again from the individual pieces. I do not need to delve any further into the complicated prehistory of this trick, which can be traced from Ludwig XVI's artillery to the almost forgotten but not unim- portant British-American War of 1812 and the US Army Ordnance Office. It is enough to say that even though Colt did not invent the principle of the industrial serial production of interchangeable parts, he still publicized it very successfully. The series of shots in time and the series of devices in space were two equally important aspects of one single innovation. The arms supplier of Napoleon's great army worked on similar standardizations at practically the same time, as did the English computer pioneer Charles Babbage, particularly with regard to screws and other precision mechanics. As you know, however, Colt's model prevailed in America - and this was actually for the simple reason that every conceivable emigrant with every conceivable occupation that was not demanded elsewhere streamed into the country of unlimited serialism. There were only two groups
of workers who did not emigrate from Europe, where they enjoyed much better working conditions: skilled labor and the military. And behold: the manufacturing technology of Colt's revolver compen- sated for the first shortage and the weapons technology compensated for the second.
Both of these aspects were also crucial for film. First, conceruing the seriality of the production process, film distinguishes itself from photography in that the sender's finished product - the film in reels - is entirely useless if a projector with precisely the same specifications is not available on the receiver side. The purchaser of a photograph does not himself need a camera, but the purchaser of a film needs a projection room and a projection device. While Shannon's channel concept is rather anachronistic and unsuitable for photography, as I have said, film comes considerably closer to this concept and thus requires highly industrial conditions. It is no coincidence that many early film producers carne from the sphere of precision engineering (Faulstich, 1979, p. 159).
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The seriality of shootmg a revolver, on the other hand, naturally corresponds to the serial time in film, into which the movements of the filmed object must be broken down. In terms of pure mathemat- ics, this has not been a problem since Aristotle's theory of movement was adopted in the early modern period. In tbe fourteentb century, as I have mentioned, Nicolas Oresme already sketched the individual phases of the flight of a missile on paper, and Leibniz developed dif- ferential calculus around 1690 in order to calculate the ballistics of cannonballs. dy over dt means analyzing the results of an arbitrary mathematical fnnctlon m extremely small intervals of time t, and these intervals eventually approach zero until the differential quotient indicates the tangent and that means the change of the relevant func- tion itself at all individual points in time.
Technically, however, this border crossing is simply impossible because (according to Shannon) there are no infinite scanning speeds. It was thus replaced with the problem of how small the segments of time must be made in order to provide at least the appearance of such a border crossing. At the same time that Charles Babbage constructed his first proto-computer, which converted Leibniz' differential equa- tions into technically realizable difference equations, the nineteenth century developed a machine that operated even below the smallest difference that would still be physiologically perceptible. But that suddenly changed the technical question into a physiological question and the construction of machines thus changed into the measurement of human senses.
To identify this new physiology of the senses, it will suffice first of all to point out in general that its scientific structure would have been inconceivable prior to the nineteenth century. In his remark- able book about the techniques of the observer, Jonathan Crary even postulated the thesis (inspired by Foucault's historiography) that the turn away from physically natural optics, as represented by Lambert, for example, towards physiologically embodied optics was a veritable scientific paradigm shift. The principle support for Crary's thesis is no less than Goethe, whose theory of colors was fundamentally based on the phenomenon of optical after-images. Someone looks at something red for a few minutes, then closes the eyes - and suddenly the complementary color green appears to these closed eyes. Goethe boldly concluded from this, as I already men- tioned at the very beginning of these lectures, that the eye is like the sun: out of its own creative activity it generates a suitable complement to every passively pre-existing color, and the end sum is always a totality.
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Crary's thesis reduces many events in the history of science that led to photography and film to a hrilliant denominator. Nevertheless, I would like to raise two objections. The first concerns Crary's over- emphasis on the body, which is fashionable among contemporary scholars. There seem to be entire branches of scholarship today that believe they have not said anything at all if they have not said the word"body" a hundred times. There is no doubt that in the nine- teenth century the geometric model of optics, which prevailed from the time of Brunelleschi to Lambert, was replaced with a materialis- tic one, but that by no way means that the material effects of light always impact on human bodies and eyes. It can just as easily be, as we have seen, Schulze's photochemical effect on silver salts and, even more conclusively, Herschel and Ritter's history of infrared and ultraviolet. Crary's thesis would therefore be more precise if he had not spoken about physiology but rather about material effects in general, which can impact on human bodies just as well as on technical storage media.
Second, I do not see how Crary can equate Goethe's gentle experi- ments with the more brutal and in my eyes first true physiological experiments and self-experiments of his successors. Goethe himself boasted of his "delicate empiricism," and he surely never caused pain for the sake of his theory of colors. However, the Weber brothers, to whom the sciences of motion (as they were called in the nineteenth century) owe much, falsified the alleged creative power of Goethe's eye by simply delivering a mechanical blow to their own eyes: what then emerged as an after-image or lighting on the retina was no longer a totality, but rather the trace of a shock (Crary, 1991).
The Leipzig scientist Gustav Theodor Fechner was even worse than the Webers because he first attempted to prove Goethe's pre- cious theory of after-images experimentally. As a physicist, Fechner also wanted to determine the measurable quantities and measurable periods of this after-image effect, and he spent three years reading all the relevant books on the subject and then staring into the sun. At the end of this series of experiments, which exposed his eyes to two rather opposed extremes, he was blind and fit only for a mental institution (see Lasswitz, 1910). You can see that in the nineteenth century the physiology of the senses did not simply ruin experimen- tal rabbits - or rats, like today - but rather it ruined the research pioneers themselves. Media always presuppose disabilities, and thus
optical media also presuppose the blindness of their researchers (in addition to a lack of natural pigments). Enlightenment philosophers like Diderot or Condorcet had only postulated theories about the
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blIndness of others, because the Enlightenment itself was supposed to be pure light. Fechner, on the other hand, was able to write the general mathematical formula of all sensory perception, the so-called basic law of psychophysics, precisely because he sacrificed his eyes to research his subject and then only managed to improve his condition again through sheer force of will. According to this basic law, a linear increase in objective stimulation only corresponds to a logarithmic increase in subjective sensation; by the same token, an exponential increase in stimulation is necessary for a linear increase in sensation - in Fechner's tragic case, therefore, the sun must shine four times hrighter to blind twice as much. With such optimistic and also not undisputed assumptions about sensory resistance, one can imagine how much solar power Fechner exposed his eyes to.
Fechner is admittedly less important for the physiology of film than another hlind man, to whom we will shortly come. Fechner only serves to illustrate a research field that began making numerical state- ments about perceptual processes and above all stimulus thresholds. It is clear that eyes can only believe in the apparent continuity of film movements when the projected images change quickly enough that the sequence of individual frames drops below a certain temporal threshold. The so-called positive after-image then takes effect. In contrast to Goethe's celebrated concept of the negative after-image, the positive after-image occurs when the eye continues to see an object in the same place a moment after it has already disappeared or moved away. This happens because the stimnlation of the nerve fibers only wears off gradually, and the after-image remains in the same color as the original image rather than the complementary color, as with a negative after-image. Since about 1750, it has been known (or rather rediscovered, as Ptolemy'S Optics was reportedly aware of the after-image effect) that the positive after-image lasts for an eighth of a second. The eye is therefore no longer able to differen- tiate movements faster than this from one another. It was not until the nineteenth century, however, that researchers proceeded to take advantage of this effect with small technical devices that produced
illusionistic effects as toys. In 1824, for example, Sir John Herschel, the son of the aforementioned astronomer and discoverer of infrared, rotated a coin so quickly that by all appearances the front and the back, the number and the emblem, were visible at the same time as a single image (Zglinicki, 1979, p. 109).
And yet the after-image effect alone is still not enough to make cinema possible. It only supports the cinematic illusion in one respect: it dampens the flickering during the film advance and completely
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suppresses it upon reaching the flicker fusion threshold. But to produce the illusion that one and the same object has moved from the place it occupied on frame A to another place on frame B, another optical effect must be added: the stroboscope effect. Hopefully, it IS not necessary to say much about the effectiveness of this effect, as all of the better discos employ stroboscopic lights so that people's dance movements can be cut up into their individual phases, much like film editing. The twentieth century, in other words, has successfully reimported a film effect into everyday life. The nineteenth century, on the other hand, had to first discover the stroboscope effect to make film possible at all.
It is a great pleasure to inform you that the great physicist Michael Faraday was among these discoverers. Faraday will appear later in these lectures as a genius at theater lighting, but in 1831 he also discovered electromagnetic induction or the possibility of produc- ing voltage and ultimately alternating current through the circular motion of an electric circuit in a magnetic field. What he discov- ered for optics is not so very far from induction, because it already prepared for the possibility of one day electrifying optical media like film and television. As in the case of the rotation press or the revolver, circular motion once again plays the decisive role, which will culminate in roll film.
Through his fundamental electromagnetic discovery, Faraday took notice of circular motion in general, and he reportedly observed two gears in a mine whose motion was normally not perceptible at all because of speed and thus because of the after- image effect (Zglinicki, 1979, p. 114). On the basis of this observa- tion, Faraday constructed purely experimental gear couplings, until he determined a new optical law: the periodic breaks in the equally p. eriodic images - which occur approximately when the front gear allows the viewer to see the individual teeth of the rear wheel but then conceals them again - leads to the lovely illusion that the eye mistakenly identifies tooth A from image 1 with another tooth B from image 2 with a third tooth C from image 3, etc. A virtual movement thus emerges, and at certain rotation speeds or frequencies the gears even virtually stop. Electro-technicians and information theorists like Shannon would say that the sampling frequency together with the frequency of the samples produces an aliasing effect, which is perhaps a free English translation of Brecht's alienation effect. The possibility of this aliasing effect is only present when the sampling frequency is not at least twice as large as the maximum frequency in the signal of interest. For this reason, sophisticated filter chains provide for a meticulously precise observation of Shannon's sampling theorem
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during the digital recording and playback of compact discs. And the fact that the stroboscope effect does not hinder but is actually neces- sary for film says everything about the difference between film and electro-acoustics, the imaginary and the real (this is already a slight anticipation of statements that are yet to come). It only becomes obtrusive and disruptive when film scenes themselves demonstrate the very effect on which they are based. You all know that when a western is shown at 24 frames per second and the famous covered wagons of the American pioneers have exactly the right frequency, their spokes appear to be standing still or even running backwards.
So much for Faraday, who admittedly appears to have been more mterested in a basic theory of frequency than in its media-technical applications. The physicist neglected to demonstrate his stroboscope effect not only with the teeth of gears and slits but rather with images, which was a small but decisive step in the development of film. However, Joseph Plateau, the Belgian professor of experimental physics and astronomy at Ghent University, was working on optical illusions at the same time and completely independent of Faraday. In 1832, he thought of feeding the stroboscope with 16 drawings of a dancer, presenting her in successive phases of movement and ending once again in the initial position.
On the outer edge of the disk and between the individual images there were 16 slits. When the spectator positioned the disk in front of a mirror, set it in motion, and continued looking through the same slit into the mirror, the dancer herself would proceed to perform endless pirouettes or circular movements. For the first time, a tecbni- cal trick had changed the zero frequency, which was the rate at which all representative artworks had been displayed ever since the Stone Age, into frequencies as high as one likes. This must have so deeply fascinated Plateau that he was no longer able to leave his optical experiment alone and he gradually went blind; in contrast to his col- league Fechner, however, his blindness was permanent.
Perhaps the extent of the sacrifice that Plateau made enables us to appreciate the advance that his stroboscope represented. If one thinks back to Athanasius Kircher's smicroscope, which was able to present the 14 Stations of the Cross one after another, the first important difference is the novelty of Plateau's representation of the successive phases of the dancer's movements. The 14 Stations of the Cross were 14 different images as such, one on the Mount of Olives, one with Pilate, one on Golgatha, etc. , from the night before Good Friday until the famous sixth hour. The 16 drawings of the dancer, on the other hand, are absolute snapshots of one and the same object - and
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this was done seven years before Daguerre was able to reduce photo- graphic recording time to two to three minutes. Imagine if the devout Jesuit Kircher had presented the passion playas endless pirouettes. With his virtual circular motion, Plateau is a worthy contemporary of all the acoustic experimenters between 1830 and 1880, or between Weber and Edison, who made analogous attemps to achieve millisec- ond recordings of sound and speech periods, which finally culminated in Edison's phonograph in 1877.
That means at the same time that film was not yet techmcally possible during Plateau's lIfetime simply because mstantaneous pho- tography lagged far behind the rotation speeds that were attainable with the stroboscope. For this reason, only scientific deVices and toys were initially developed from the stroboscope. The device was sng- gested by Doppler, who also discovered the acoustic effect that was named after him: to analyze motion, whose speed strips it of every visual perception, Doppler employed a systematic reversal of the stroboscope, which did not set images and slits into periodic motion but rather the light source itself - as a rapid snccession of electrical sparks, for example (Zglinicki, 1979, p. 120). This is precisely what in the meantime is employed in discos, most likely to train the speed of our perception - in defiance of all physiology - for the extreme requirements of a technical war.
The development of toys also proceeds in a similarly militaristic way. You may recall that one of the reasons why Leibniz developed his wonderful differential calculus was to make missile trajectories calculable. Now in 1811, a certain Franz von Uchatius came into the world, which at that time still had an Austrian Empire. In 1829, Uchatius voluntarily joined the second field artillery regiment as an artillery gunner. After graduating from the Bombardier Corps Academy iu 1837, he was promoted to sergeant and commissioned to teach physical chemistry. In 1841, he began his - at least for the Austrian artillery - groundbreaking research on canuon casting, which ultimately led him to the invention of steelbronze and also of the aforementioned explosive Uchatius powder, which is chemically closely related to old roll film. As a reward, Kaiser Franz Joseph pro- moted him to Field Marshal Lieutenant and at the same time, because this promotion would have otherwise been impossible, made him a
baron. In the symbolic world, on which monarchies are based, things fell into place very well, but Austria-Hungary did not have the least interest in the technical real world. After walking a great distance, a certain Mitterhofer from South Tyrol was permitted to present his wooden typewriter - the very first that we know of - to this same
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Kaiser. He received a personal donatIOn, but hIS machine dId not go into production. Uchatius fared even worse: due to bureaucratic difficultIes with the introduction of Uchatius cannons in the impe- rial army, the artilleryman and Field Marshal Lieutenant became his own target. On June 4, 1881 he shot himself in the head (Zglinicki, 1979, pp. 130-5).
After this requiem we now return to the history of film. Before Field Marshal Lieutenant Franz von Uchatius took aim at himself, it must have been important to him to teach all cadets and officer candidates the principle of artilleristic shooting. Plateau's newly dis- covered stroboscope lent itself easily to this purpose. Like Edison's kinetoscope, it also admittedly had the one crucial disadvantage that it was not a mass medium, but rather it always only allowed a single viewer to look through the observation slit. For his lectures on weapons technology, therefore, Uchatius spent his scarce free time first combining the well-known lanterna magica witb the strobo- scope. And behold: all of the cadets were immediately able to watch Uchatius' sketches of projectiles flying through the air at the same time, as they were projected onto the wall of the auditorium. The lanterna magica thus no longer produced merely virtual motion, like Schriipfer's curtains of smoke, but by means of a crank - much like early cinema - made successive images really dance in front of a fixed light source. It is no wonder, then, that Uchatius' constructions were purchased by a carnival showman, who gave magical performances that turned the weapon back into money, as Schriipfer or Robertson had once done (Zglinicki, 1979, p. 133).
What is interesting here is not this reversion, but rather the fact that the individual technical elements of film - the recording device, the storage medium, the projection apparatus - were combined with one another very gradually and in stages. Technical media are never the inventions of individual geniuses, but rather they are a chain of assemblages that are sometimes shot down and that sometimes crys- tallize (to quote Stendhal). After Uchatius combined the stroboscope and the lanterna magica, the only element that was still missing was the camera obscura that Talbot had already automated. However, its inclusion in the communication system known as film not only encountered technical obstacles, such as exposure times that were much too long, but also the traditionalism of an entire artistic epoch. As contemporaries of these experiments, draughtsmen like Toepfer in Geneva and Wilhelm Busch in his village near Giittingen were actu- ally quick enough to grasp the new method of drawing in phases as an art form, which means quite simply that they invented the comic
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strip, which led in turn to the animated cartoon. However, it was precisely because painters learned to break motion down into suc- cessive phases in the oineteenth century that they did not want to relinquish this new art form once again and replace it with technical media. On December 1, 1888, a certain Emile Reynaud received the French patent number 194 482 for his projection praxinoscope. As the name already suggests, this device projects moving stories, which Reynaud drew on perforated and flexible ribbons as animated films. All of these features, but above all the interplay between the perfora- tions and a gripping mechanism, guaranteed perfect synchronization. The musical accompaniment synchronized with the projection also practically anticipated Edison's kinetoscope, except that throughout his lifetime Reynaud stubbornly refused to replace his "artistic" drawings with photographs (Zglinicki, 1979, p. 136). As Hiilderlin so accurately wrote, it is hard to leave a place when one lives near the source. And what lives closer to the source than art according to European tradition?
3. 2. 2 Implementation
It was thus left to a European emigrant to the US to take the last step. Edward Muggeridge from Kingston-on-Thames, who changed his name to Eadweard Muybridge either out of Anglo-Saxon pride or an American desire for self-promotion, combined for the first time all the elements of film: instantaneous photography, iantema magica, and stroboscope. Muybridge's zoopraxiscope of 1879 showed, as its name claims, life (Zglinicki, 1979, p. 175).
The key word "life" naturally compels us to disregard momen- tarily this lecture's physical image of the world and to touch upon nineteenth-century zoology. However, to understand Muybridge's feat we are now in the same fortunate position as film history: we only need to combine the already existing or already recounted ele- ments. Colt's revolver, Daguerre's photography, Weber's acoustic experiments - all of these elements recur once again.
The initial push was supplied by acoustics. It was possible to record the frequencies of the human voice long before Edison, but there were no researchers who also thought to play back this voice at another place and time. The trick simply consisted in sending the voice into an amplifying funnel at whose end a membrane vibrated. The other side of this membrane was attached to an innocent hog's bristle, which finally scrawled the captured frequencies onto a lamp- blackened glass plate - provided that the experimenter rolled this
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plate past the bristle fast enough. In this simple way, for example, the very voice of the British phonetician who was the inspiration for Professor Higgins in Shaw's Pygmalion and the musical My Fair Lady has been preserved to this very day. For the first time, the physiology of a living human being was coupled with a storage medium rather than a chain of symbols with a repertoire of signs, as with writing.
3. 2. 2. 1 Marey and Muybridge
Phonographic recording, which at that time was also called visible speech, became the accepted thing among European physiologists. When France established a professorship in natural history at the Parisian College de France at the instigation of the great physiolo- gist Claude Bernard, for whom we have Zola's entire naturalism to thank, the holder, Prof. Etienne-Jules Marey, immediately began constructing devices. Doctors like Goethe's Mephisto had actually already strongly recommended taking the pulse of, above all, women with tenderness, and it was precisely because of such pleasures that it had not occurred to a doctor before Marey to replace his own hand with a machine. At the College de France, one device emerged after another: a heart recorder, a pulse recorder, and finally also a device that was connected to the four extremities of animals and could record their movements. None of these devices bore the least similarity to photographic cameras, but rather they worked, exactly like visible speech, with a pencil and a steadily moving paper cylinder.
As only luck would have it, Marey became acquainted with a captain in the French army who was also a horse enthusiast. This captain converted the results of the professor's measurements back into traditional art. His visual reconstruction of the measurements of a horse's legs manifested the incredible fact that there is a moment while galloping when only one of the horse's legs is touching the ground? The Anglo-Saxon world in particular was overrun with watercolors featuring horses and riders, yet there was not a single picture showing the leg position that Marey claimed.
Imagine for the blink of an eye if film had been invented in India and the leg position was not that of horses but rather of women and men according to the rules of the Kama Sutra . . .
7Kittler is incorrect here and in the following paragraphs when he states that one horse's leg is always touching the ground during a gallop. The theory of "unsup- ported transit" referred to here actually claimed that all of the horse's legs were in the air at the same time.
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Instead, the story continues m puritamcal America, where Leland Stanford Sr. became a millionaire by constructing a pacific railroad and consequently, long before Ronald Reagan, also became governor of the state of California. Stanford, the horse enthusiast and trotting horse breeder, saw the measurements of the horse's legs, but was unable to believe the results of Marey's experiments. We can only assume the reason was that the watercolor images of horses' legs remained so deeply imbedded in the subconscious minds of people who had not yet seen a film. However, where belief is lackmg, m America there is money and experimentation. Stanford had the for- tunate idea of calling in Muybridge, the landscape photographer, and commissioning a photographic test of tl,e horse's leg problem.
Muybridge thus exchanged the Californian wilderness for Califor- nian civilization, or the timelessness of Yosemite Valley, which he had immortalized in his landscape photographs, for the millisecond realm of telegraphy. Stanford's breeding establishment for trotting horses was located at his ranch in Palo Alto, precisely where the Leland Stanford Junior University - renowned for being the best for the study of electronics - stands today. Muybridge constructed a white wall with a short race track in front of it, and in front of this race track he placed a row of 12 instant cameras, which were all connected electronically. With relay circuits supplied notably by the San Francisco Telegraph Supply Company, another media industry firm, Muybridge succeeded in triggering these 12 cameras one after another at intervals of only 40 milliseconds, whereby each individual camera had a shutter speed of a single millisecond. Then all he needed was to make a horse gallop along the race track and Governor Stanford had a black-and-white photograph proving that during a certain phase of movement while galloping only one of the horse's hooves was touching the ground.
You see: Muybridge's experimental set-up no longer had even the smallest resemblance to the stroboscope, but rather it recorded movements for as long and extensively as the experimenter wanted and the race track allowed. Cylindrical storage media, which - from Plateau to Marey - were confined to repetitions and periods, and thus choreography and poetry, were superseded by the prose of science and later also of entertainment media. You know that in poetry, which was formerly identical to dance, everything must come back around as in the stroboscope; in novels, on the other hand, there is always an unforeseen and contingent future, as in Muybridge's series of instantaneous photographs, which can consequently also only stop through an interruption. All of so-called modern life therefore depends entirely on nineteenth-century media technologies.
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Muybridge's empincal confirmation of Marey's experiment took place in 1878. Five years later, the very same instantaneous record- ing technology used by Muybridge also made all of Field Marshal Lieutenant von Uchatius' dreams of artillery pedagogy come true. The physicist Ernst Mach sealed a wire in a glass tube, connected the wire electrically to the shutter of an instant camera, and then fired on the glass tube. The result was a photographic speed record: a real bullet, rather than a drawn one as in the stroboscope, generated shock waves as It entered the chamber. It is no wonder that the same Mach was also the first to achieve the opposite record: the time-lapse film for analyzing infinitely slow movements (Eder, 1978, p. 523).
Muybridge, as far as I can trust my optical memory, also invented another trick. The library of Stanford University, which the old gover- nor founded on the site of his fonner horse breeding establishment to memorialize his son (whose death was caused by bungling European doctors, of course) and to prevent similar tragic cases in the future through science, contains stacks of enormous photo albums, in which Muybridge gradually shifts from horses and cows to people. When- ever an athletic Stanford student and sprinter enters the photograph from behind, he is naked, but whenever he turns his front towards the camera a swimsuit suddenly appears out of nowhere, as if the image has been retouched. Muybridge thus invented the stop trick, one of the most important film tricks, long before George Meli"s. As far as I can see, frontal nudity first appears in Muybridge's photographs only during his later time at the University of Pennsylvania.
The purpose of the swimsuit in California is clear: only the nude photographs require some explanation. After Muybridge finally abol- ished the hand of the artist (which had appeared so irreplaceable to his predecessor Reynaud) and manufactured a pure multimedia system, he also wanted to reform painting. His magnificent volumes on "animal locomotion" were published for the express purpose of preventing artists from drawing or painting false positions, like the galloping horse. Muybridge's nude photographs provided them instead with a scientific model of all possible body movements. Like Renaissance perspective and the camera obscura, instantaneous pho- tography was supposed to discipline art. Admittedly, this time it did not involve abolishing the dominance of the symbolic, as in medieval holy images, and introducing a human scale through perspective, but rather at the end of the nineteenth century the imaginary also had to believe in it. The reason we never see three legs of a horse in the air is because the eye projects a familiar general shape on all of the phases of an animal's movements.
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I am pleased to be able to say that Muybridge's propaganda was a crowning success in at least one famous case. Duriug his European travels, Muybridge's patron Leland Stanford Senior also went to Paris, where he became acquainted - presumably in Muybridge's company - with the painter Meissonier. Jean Louis Ernest Meisso- nier, who unfortunately hardly anyone appreciates any more except for Salvador Dali and myself, had already painted practically all of the legs of the horses in Napoleon's Great Army on extremely expensive canvas out of an explicit admiration for Napoleon's "orga- nizational genius" (Greard, 1897, p. 47), but he confessed that he only knew how to represent these legs while striding and trotting and not while galloping (Greard, 1897, p. 194). Stanford demanded that Meissonier paint his portrait, which the painter would have refused to do had Stanford not revealed to him on this occasion the secret of Muybridge's instantaneous photographs of horses. Meis- sonier was converted, and it was because of him that this secret was eventually conveyed to the vice-president of the Paris Academy of Fine Arts. From then on, Meissonier employed photographic source material to paint real horses' legs rather than picturesque imagi- nary ones. According to his biography, he used these photographic models"only for verification," but in his private park in Poissy, near Versailles, he built a short railroad track, seated himself in a sleigh- like locomotive whose speed could be adjusted, and studied a gallop- ing horse in motion with his own mobilized painter's eye (Greard, 1897, p. 73). You see once again how the railroad replaced the horse in media history, and how the nineteenth-century railroad journey celebrated by Schivelbusch (1986) was not limited to being passively transported, but rather in the wonderful case of Meissonier it was already an active automobile in the literal sense of a forward-moving, self-propelling technology. It is hard to say whether this tremendous expense made Meissonier's war paintings more valuable or realistic, and there is no need to know. The death of traditional painting was quickly approaching, for in the same Paris salon where Stanford had met Meissonier, Muybridge also met Marey.
For the first time in this history of invention, therefore, we are con- fronted with a case of positive feedback. Sixty years earlier, Niepce and Daguerre had met purely by chance, even though they both lived in France, and their collaboration had to be insured through a civil contract. Now, in 1882, Marey's machine for measuring movement inspired Muybridge to design a follow-up invention in California, and Muybridge's serial photography, in turn, inspired Marey to design his own follow-up invention. Muybridge, as I have
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said, went as far as inserting his sequences of images - which were photographic and no longer merely drawn - into a stroboscope in order to be able to project real movements. This was still not a film, however, not only because a minute of horse galloping would have required 270 images instead of the available 12 (see Clark, 1977), but also because Muybridge was stubborn: as a prior landscape pho- tographer, he never gave up using the heavy, immovable glass plates that Niepce's cousin had introduced to photography in 1847. For this reason, namely, because a human life is far too short to comprehend avalanches of technical innovations, teamwork and feedback loops
become essential . . .
Muybridge and Marey, these twins or Dioscuri who were present
at the birth of fillll, were both born in 1830 and died in 1904. It is therefore possible to shift from one to the other without any prob- lems. After the soiree at Meissonier's, Marey realized that all of his machines for measuring heartbeats, pulse rates, and the movements of horses' legs had been historically superseded by Muybridge's serial photography - with one exception. By holding tight to the unifying, linearizing power of writing paper, Marey always only needed one single piece of equipment, while Muybridge had to position 12 dif- ferent cameras. The task, therefore, was to dispose of 11 cameras and still be able to supply serial photographs. In the process, Colt's good old revolver was once again honored, as it had also reduced the need for six pistols down to one. In 1874, a French astronomer, Pierre Jules Cesar Janssen, had already converted the revolver from the wars with the Red Indians into a revolver for the stars in order to capture 18 different positions of the planet Venus on a single photographic plate, whereby the astronomical revolver repeatedly closed his camera lens between these 18 instantaneous recordings
with a Maltese cross (Zglinicki, 1979, p. 170). While Marey still had to install his individual images into a stroboscope by hand, this new device supplied the stroboscopes all by itself. After this preparatory work, it was easy for Marey to improve on Jannssen's astronomical revolver. Marey developed a device that was roughly 50 centimeters long, which he dubbed a chronophotographic gun or fusil chronophotographique because it handles photographs much in the same way as a gun. It was braced against the shoulder for stabil- ity, it had gun sights for aiming, and firing the trigger produced an instantaneous photograph, whereupon the barrel, which contained 11 more unexposed negatives, turned 30 degrees, bringing the next negative into position. If the metaphor of shooting a photograph was ever taken literally, then it was in the case of Marey, whose assistant
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Georges Demeny was reportedly even ordered by the French general staff to record and optimize the standardized marches of soldiers using serial photography in 1904.
At a time when France was mourning a lost war and the lost provinces of Alsace-Lorraine, Marey's photographic rearmament considerably helped his career. The physiologist, who had already received his own physiological institute, rose even further to become president of the French photographic society. In this position, he put into place the penultimate step to film technology. The rigid barrel or disk, which had been maintained from Plateau's stroboscope through to tbe chronophotographic gun, was transformed into a flexible roll, which was transported automatically past the lens through a clock- work mechanism in the camera. And even though it still was not a celluloid roll, the technique of fihu recording was in principle fixed. Marey would only have had to put his photographic paper rolls into a projection apparatus driven by clockwork, but he did not, and he thus missed the chance of becoming Lumiere or technical light itself. For this reason, we are still faced with the pressing task of recon- structing the commercialization of the half-military, half-scientific technology of instantaneons photography throngh Edison and the Lnmiere brothers.
3. 2. 3 Silent Film
We no longer need, as in previons lectnres, to represent the history of this industrialization as a detailed acconnt of individual inventions. Up until now, the presentation of these individual inventions illus- trated the simplest, namely earliest attempts to solve the fundamental problems of optical media technology. This no longer applies, as the individual inventions and patents related to film began to explode in 1890: while there were only around 200 film-related patents issued worldwide between 1875 and 1890, this number had already risen to 500 between 1890 and 1910. In the age of indnstry, therefore, film emerged from pure teamwork. That is why I will only make rough cuts that treat silent film, sound film and color film as epochal structures. The two world wars will also serve as crude landmarks.
Before discussing the actual development of silent film, I want to point out again how far Marey had already come conceptually despite the fact that he failed to project his sequences of images. In 1891, his assistant, the aforementioned Georges Demeny, developed the won- drous photography of speech or photographie de la parole. Precisely like the earlier telephone inventor Alexander Graham Bell, Demeny
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It must he pointed out again how right Manfred Frank is (although probably unintentionally) when he celebrates the human - freely quoting Schleiermacher and Sartre - as a collective individual. In the age of the monopoly of writing, Goethe could explain that individu- als do not exist at all, but rather only genera or types. In spite of all attempts to project the protagonists of novels before the inner eye like a lanterna magica, no one knew what they actually looked like. Because language belongs to everyone, according to Hegel's insight, descriptions always already transform individuals into universals. The most glaring literary example of this transubstantiation was the arrest warrant that Georg Buchner inserted into his comedy Leonce and Lena after his own bitter experiences with the Hessian police in 1835:
FIRST POLICEMAN. Gentlemen, we are looking for someone, a
subject, an individual, a person, a delinquent, an interrogatee, a
rogue. (To the SECOND POLICEMAN. ) Have a look, is either of
them blushing?
SECOND POLICEMAN. Neither of them is blushing.
FIRST POLICEMAN. So we must try something else. Where is the
"wanted" poster, the description, the certificate? (The SECOND POLICEMAN takes a paper from his pocket and hands it to him. ) Scrutinise the subjects while I read: "A man . . . "
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SECOND POLICEMAN. No good, there are two of them.
FIRST POLICEMAN. Numbskull! ". . . walks on two feet, has two arms, also a mouth, a nose, two eyes, two ears. Distinguishing fea-
tures: a highly dangerous individual. "
SECOND POLICEMAN. That fits both of them. Shall I arrest them
both? (Btichner, 1987, p. 129)
So much for the comical aspect of old European warrants. Now for the sad part: the actual warrant for the fugitive Georg Biichner that the Grand Duchy of Hessen pubhshed m the Frankfurter Journal on June 18, 1835 contained little more:
Arrest warrant. Georg Buchner, student of medicine from Darmstadt, has fled the fatherland to evade criminal invesigation of his participa- tion in acts of treason against the state. Public authorities both at home and abroad therefore request that he be arrested and turned over to Councillor Georgi, the examining magistrate appointed by the Grand Ducal court of the province of Upper Hesse. Darmstadt, June 13, 1835. Personal description. Age: 21 years. Size: 6 feet, 9 inches according to new Hessian measurements. Hair: blonde. Forehead: very arched. Eyebrows: blonde. Eyes: grey. Nose: str()ng. Mouth: small. Beard: blonde. Chin: round. Face: oval. Complexion: fresh. Stature: strong, thin. Distinguishing features: near-sighted. (Buchner, 1985, p. 92)
In Biichner's ingenious simplification, the literary warrant reveals how the high absolutist authorities had invented him very literally as a single subject, which means that it conflated so to speak all actual subjects into one subject. In the empirical press, like the Frankfurter Journal, things were only marginally more complicated: Biichner's warrant did not actually describe all the subjects of the Grand Duchy of Hessen, but rather it only pertained to the ideal of a healthy, blond student, and there were at least a few hundred real students who fitted this literary model. Modern forensic evidence, on the other hand, works with media rather than arts - its correlate, therefore, is nothing but statistically singularized individuals who (as in Poe's famous tale The Man in the Crowd) can themselves still be fished out of the masses.
Two photographic examples related to modern forensic evidence now follow. The first is fictional, and the second is its historical confirmation.
The literary and therefore fictional example is taken from a book by Gerhard Plumpe with the entitled Der tote Blick (The Dead Look). In a slightly redundant way, this book shows how nineteenth-century
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photography legally disrupted the copyright law concerning images (at that time, this of course meant hand-painted images), which had only just recently been introduced. Despite this preoccupation with laws (and not with media technologies), Der tote Blick contains several observations for which one can be grateful.
Plumpe summarizes the content of a comedy that the high pros- ecutor and forgotten poet Apollonius von Maltitz produced in 1865 under the title Photography and Revenge:
The arrival of a traveling photographer at a bathing resort causes a disturbance, as the photographed guests feel that their portraits are an imposition in every respect. "That's how I should look? " - complains a young woman - "not simply ugly enough to horrify people, but mali- cious, like an ex-convict [. . . ], That is my poor deceased father's favor- ite child! Could you love these grimaces, my unfortunate Rudolph? - Everyone who looks at me this way must see me as the crooked daughter of a wealthy factory owner, who married an aristocrat only because of his money. " Aod her mothe~ who is also photographed, is appalled: "Led to the altar from the nursery, beautifully named, deified by painters [. . . Jsculpted in marble by Thorwaldsen - now in the hands of a charlatan. " It continues this way for a while longer, and the confused indignation of the bathing guests is made complete when an "art expert" confirms the success of the portraits. "Do you find a faint similarity? " the expert is asked, and he answers: "It is not ideal, but rather perfect. It is not similar, but rather absolutely the same! " The horror of the guests eventually becomes so extreme that the doctor of the resort forbids the photographer from practicing his trade. The story takes its first turn of events when the photographer accidentally succeeds in photographing a criminal who is up to some mischief at the resort and is stealing from the guests. With the help of "realistic" photography, the thief is arrested. Photography is thus rehabilitated and the guests ultimately praise the mastery of his "art. "
(Plumpe, 1990, p. 193)
So much for the comedy Photography and Revenge. Mediocre poets c;n therefore also be good lawyers and even better media theorists. On the one hand, the media technique of photography destroys pre- cisely the "ideal" or imaginary, which sculptors or painters repro- dnced again and again when they dutifully "deified" their models, because it manifests for the first time something real that makes even the noblest daughter suddenly look like an ex-con (guillotine grimaces, as Pynchon said). (For this reason, by the way, there has been a law in the German Reich since 1902 that gives every man and woman the "right to one's own image," which protects them against
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the mIsuse of photography. ) On the other hand, however, photogra- phy also demonstrates the completely new ability to recognize and thus produce real convicts. And third, the fact that it did not become famous as "art" (in the old European understanding of the term) until or rather precisely after this criminalistic success proves - and here I deviate from Plumpe's thesis - that all talk about photography as art actually serves to conceal its strategic functions.
To conclude this digression concerning the cultural effects of the new medium, I would only like to point out that photography as legal retributIOn not only celebrated Its tnumph in literary fiction. As early as 1883, "a rapid photographic printing process" for arrest warrants, which Bertillon reportedly took over and standardized, enabled the arrest of "the dangerous anarchist Stellmacher" in Vienna (Eder, 1978, p. 441). As you may remember, nitrocellulose can be used to make either bombs, like the anarchists, or roll film, like the Viennese police. Between these two barrages, the anarchistic and the photo- graphic, the human as collective individual explodes.
3. 2 Film
3. 2. 1 Preludes
Now we come unceremoniously to the prehistory of film. For the storage of moving images it is just not enough to make a donnish assistant like Morse stand still for half an hour, as Draper did for the first photographic portrait, or to bind a criminal during an anthro- pometric sitting, as Bertillon did. Rather, it involves fixing the object or target precisely while it is fleeing and being able to reproduce this fixed movement again anywhere. For these two reasons, I will begin the prehistory of film with an American ship's boy named Samuel Colt. His history is actually slightly mythical and it will need to be expanded more correctly and precisely in a future lecture on the history of weapons technology, but it will suffice for today. In 1828, the ship's boy went to the East Indies and on the way he had a technical epiphany - namely, the revolver that is now named after him. Colt revolvers, as celebrated and not by accident in all western films, no longer aim their six shots from one man to another, but rather from one white man to six Indians or Mexicans at virtually the same time. This was the reason why Colt, whose factory almost bankrnpted him, did not become a wealthy arms supplier until the American-Mexican War of 1847.
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The colt not only introduced the Innovation of being able to
shoot six moving targets in quick succession at a time when contem-
porary soldiers still needed a full minute to load the next round in their muzzle-loaded rifles, but rather it fundamentally revolutionized the process of industrial manufacturing. For promotional purposes, Colonel Colt was always fond of demonstrating to his astonished visi- tors that it was possible to disassemble six colts on a table, jnmble up their component parts, and in the end - despite this artificial introduc- tion of statistics or noise - reassemble six fully functional colts once again from the individual pieces. I do not need to delve any further into the complicated prehistory of this trick, which can be traced from Ludwig XVI's artillery to the almost forgotten but not unim- portant British-American War of 1812 and the US Army Ordnance Office. It is enough to say that even though Colt did not invent the principle of the industrial serial production of interchangeable parts, he still publicized it very successfully. The series of shots in time and the series of devices in space were two equally important aspects of one single innovation. The arms supplier of Napoleon's great army worked on similar standardizations at practically the same time, as did the English computer pioneer Charles Babbage, particularly with regard to screws and other precision mechanics. As you know, however, Colt's model prevailed in America - and this was actually for the simple reason that every conceivable emigrant with every conceivable occupation that was not demanded elsewhere streamed into the country of unlimited serialism. There were only two groups
of workers who did not emigrate from Europe, where they enjoyed much better working conditions: skilled labor and the military. And behold: the manufacturing technology of Colt's revolver compen- sated for the first shortage and the weapons technology compensated for the second.
Both of these aspects were also crucial for film. First, conceruing the seriality of the production process, film distinguishes itself from photography in that the sender's finished product - the film in reels - is entirely useless if a projector with precisely the same specifications is not available on the receiver side. The purchaser of a photograph does not himself need a camera, but the purchaser of a film needs a projection room and a projection device. While Shannon's channel concept is rather anachronistic and unsuitable for photography, as I have said, film comes considerably closer to this concept and thus requires highly industrial conditions. It is no coincidence that many early film producers carne from the sphere of precision engineering (Faulstich, 1979, p. 159).
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The seriality of shootmg a revolver, on the other hand, naturally corresponds to the serial time in film, into which the movements of the filmed object must be broken down. In terms of pure mathemat- ics, this has not been a problem since Aristotle's theory of movement was adopted in the early modern period. In tbe fourteentb century, as I have mentioned, Nicolas Oresme already sketched the individual phases of the flight of a missile on paper, and Leibniz developed dif- ferential calculus around 1690 in order to calculate the ballistics of cannonballs. dy over dt means analyzing the results of an arbitrary mathematical fnnctlon m extremely small intervals of time t, and these intervals eventually approach zero until the differential quotient indicates the tangent and that means the change of the relevant func- tion itself at all individual points in time.
Technically, however, this border crossing is simply impossible because (according to Shannon) there are no infinite scanning speeds. It was thus replaced with the problem of how small the segments of time must be made in order to provide at least the appearance of such a border crossing. At the same time that Charles Babbage constructed his first proto-computer, which converted Leibniz' differential equa- tions into technically realizable difference equations, the nineteenth century developed a machine that operated even below the smallest difference that would still be physiologically perceptible. But that suddenly changed the technical question into a physiological question and the construction of machines thus changed into the measurement of human senses.
To identify this new physiology of the senses, it will suffice first of all to point out in general that its scientific structure would have been inconceivable prior to the nineteenth century. In his remark- able book about the techniques of the observer, Jonathan Crary even postulated the thesis (inspired by Foucault's historiography) that the turn away from physically natural optics, as represented by Lambert, for example, towards physiologically embodied optics was a veritable scientific paradigm shift. The principle support for Crary's thesis is no less than Goethe, whose theory of colors was fundamentally based on the phenomenon of optical after-images. Someone looks at something red for a few minutes, then closes the eyes - and suddenly the complementary color green appears to these closed eyes. Goethe boldly concluded from this, as I already men- tioned at the very beginning of these lectures, that the eye is like the sun: out of its own creative activity it generates a suitable complement to every passively pre-existing color, and the end sum is always a totality.
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Crary's thesis reduces many events in the history of science that led to photography and film to a hrilliant denominator. Nevertheless, I would like to raise two objections. The first concerns Crary's over- emphasis on the body, which is fashionable among contemporary scholars. There seem to be entire branches of scholarship today that believe they have not said anything at all if they have not said the word"body" a hundred times. There is no doubt that in the nine- teenth century the geometric model of optics, which prevailed from the time of Brunelleschi to Lambert, was replaced with a materialis- tic one, but that by no way means that the material effects of light always impact on human bodies and eyes. It can just as easily be, as we have seen, Schulze's photochemical effect on silver salts and, even more conclusively, Herschel and Ritter's history of infrared and ultraviolet. Crary's thesis would therefore be more precise if he had not spoken about physiology but rather about material effects in general, which can impact on human bodies just as well as on technical storage media.
Second, I do not see how Crary can equate Goethe's gentle experi- ments with the more brutal and in my eyes first true physiological experiments and self-experiments of his successors. Goethe himself boasted of his "delicate empiricism," and he surely never caused pain for the sake of his theory of colors. However, the Weber brothers, to whom the sciences of motion (as they were called in the nineteenth century) owe much, falsified the alleged creative power of Goethe's eye by simply delivering a mechanical blow to their own eyes: what then emerged as an after-image or lighting on the retina was no longer a totality, but rather the trace of a shock (Crary, 1991).
The Leipzig scientist Gustav Theodor Fechner was even worse than the Webers because he first attempted to prove Goethe's pre- cious theory of after-images experimentally. As a physicist, Fechner also wanted to determine the measurable quantities and measurable periods of this after-image effect, and he spent three years reading all the relevant books on the subject and then staring into the sun. At the end of this series of experiments, which exposed his eyes to two rather opposed extremes, he was blind and fit only for a mental institution (see Lasswitz, 1910). You can see that in the nineteenth century the physiology of the senses did not simply ruin experimen- tal rabbits - or rats, like today - but rather it ruined the research pioneers themselves. Media always presuppose disabilities, and thus
optical media also presuppose the blindness of their researchers (in addition to a lack of natural pigments). Enlightenment philosophers like Diderot or Condorcet had only postulated theories about the
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blIndness of others, because the Enlightenment itself was supposed to be pure light. Fechner, on the other hand, was able to write the general mathematical formula of all sensory perception, the so-called basic law of psychophysics, precisely because he sacrificed his eyes to research his subject and then only managed to improve his condition again through sheer force of will. According to this basic law, a linear increase in objective stimulation only corresponds to a logarithmic increase in subjective sensation; by the same token, an exponential increase in stimulation is necessary for a linear increase in sensation - in Fechner's tragic case, therefore, the sun must shine four times hrighter to blind twice as much. With such optimistic and also not undisputed assumptions about sensory resistance, one can imagine how much solar power Fechner exposed his eyes to.
Fechner is admittedly less important for the physiology of film than another hlind man, to whom we will shortly come. Fechner only serves to illustrate a research field that began making numerical state- ments about perceptual processes and above all stimulus thresholds. It is clear that eyes can only believe in the apparent continuity of film movements when the projected images change quickly enough that the sequence of individual frames drops below a certain temporal threshold. The so-called positive after-image then takes effect. In contrast to Goethe's celebrated concept of the negative after-image, the positive after-image occurs when the eye continues to see an object in the same place a moment after it has already disappeared or moved away. This happens because the stimnlation of the nerve fibers only wears off gradually, and the after-image remains in the same color as the original image rather than the complementary color, as with a negative after-image. Since about 1750, it has been known (or rather rediscovered, as Ptolemy'S Optics was reportedly aware of the after-image effect) that the positive after-image lasts for an eighth of a second. The eye is therefore no longer able to differen- tiate movements faster than this from one another. It was not until the nineteenth century, however, that researchers proceeded to take advantage of this effect with small technical devices that produced
illusionistic effects as toys. In 1824, for example, Sir John Herschel, the son of the aforementioned astronomer and discoverer of infrared, rotated a coin so quickly that by all appearances the front and the back, the number and the emblem, were visible at the same time as a single image (Zglinicki, 1979, p. 109).
And yet the after-image effect alone is still not enough to make cinema possible. It only supports the cinematic illusion in one respect: it dampens the flickering during the film advance and completely
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suppresses it upon reaching the flicker fusion threshold. But to produce the illusion that one and the same object has moved from the place it occupied on frame A to another place on frame B, another optical effect must be added: the stroboscope effect. Hopefully, it IS not necessary to say much about the effectiveness of this effect, as all of the better discos employ stroboscopic lights so that people's dance movements can be cut up into their individual phases, much like film editing. The twentieth century, in other words, has successfully reimported a film effect into everyday life. The nineteenth century, on the other hand, had to first discover the stroboscope effect to make film possible at all.
It is a great pleasure to inform you that the great physicist Michael Faraday was among these discoverers. Faraday will appear later in these lectures as a genius at theater lighting, but in 1831 he also discovered electromagnetic induction or the possibility of produc- ing voltage and ultimately alternating current through the circular motion of an electric circuit in a magnetic field. What he discov- ered for optics is not so very far from induction, because it already prepared for the possibility of one day electrifying optical media like film and television. As in the case of the rotation press or the revolver, circular motion once again plays the decisive role, which will culminate in roll film.
Through his fundamental electromagnetic discovery, Faraday took notice of circular motion in general, and he reportedly observed two gears in a mine whose motion was normally not perceptible at all because of speed and thus because of the after- image effect (Zglinicki, 1979, p. 114). On the basis of this observa- tion, Faraday constructed purely experimental gear couplings, until he determined a new optical law: the periodic breaks in the equally p. eriodic images - which occur approximately when the front gear allows the viewer to see the individual teeth of the rear wheel but then conceals them again - leads to the lovely illusion that the eye mistakenly identifies tooth A from image 1 with another tooth B from image 2 with a third tooth C from image 3, etc. A virtual movement thus emerges, and at certain rotation speeds or frequencies the gears even virtually stop. Electro-technicians and information theorists like Shannon would say that the sampling frequency together with the frequency of the samples produces an aliasing effect, which is perhaps a free English translation of Brecht's alienation effect. The possibility of this aliasing effect is only present when the sampling frequency is not at least twice as large as the maximum frequency in the signal of interest. For this reason, sophisticated filter chains provide for a meticulously precise observation of Shannon's sampling theorem
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during the digital recording and playback of compact discs. And the fact that the stroboscope effect does not hinder but is actually neces- sary for film says everything about the difference between film and electro-acoustics, the imaginary and the real (this is already a slight anticipation of statements that are yet to come). It only becomes obtrusive and disruptive when film scenes themselves demonstrate the very effect on which they are based. You all know that when a western is shown at 24 frames per second and the famous covered wagons of the American pioneers have exactly the right frequency, their spokes appear to be standing still or even running backwards.
So much for Faraday, who admittedly appears to have been more mterested in a basic theory of frequency than in its media-technical applications. The physicist neglected to demonstrate his stroboscope effect not only with the teeth of gears and slits but rather with images, which was a small but decisive step in the development of film. However, Joseph Plateau, the Belgian professor of experimental physics and astronomy at Ghent University, was working on optical illusions at the same time and completely independent of Faraday. In 1832, he thought of feeding the stroboscope with 16 drawings of a dancer, presenting her in successive phases of movement and ending once again in the initial position.
On the outer edge of the disk and between the individual images there were 16 slits. When the spectator positioned the disk in front of a mirror, set it in motion, and continued looking through the same slit into the mirror, the dancer herself would proceed to perform endless pirouettes or circular movements. For the first time, a tecbni- cal trick had changed the zero frequency, which was the rate at which all representative artworks had been displayed ever since the Stone Age, into frequencies as high as one likes. This must have so deeply fascinated Plateau that he was no longer able to leave his optical experiment alone and he gradually went blind; in contrast to his col- league Fechner, however, his blindness was permanent.
Perhaps the extent of the sacrifice that Plateau made enables us to appreciate the advance that his stroboscope represented. If one thinks back to Athanasius Kircher's smicroscope, which was able to present the 14 Stations of the Cross one after another, the first important difference is the novelty of Plateau's representation of the successive phases of the dancer's movements. The 14 Stations of the Cross were 14 different images as such, one on the Mount of Olives, one with Pilate, one on Golgatha, etc. , from the night before Good Friday until the famous sixth hour. The 16 drawings of the dancer, on the other hand, are absolute snapshots of one and the same object - and
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this was done seven years before Daguerre was able to reduce photo- graphic recording time to two to three minutes. Imagine if the devout Jesuit Kircher had presented the passion playas endless pirouettes. With his virtual circular motion, Plateau is a worthy contemporary of all the acoustic experimenters between 1830 and 1880, or between Weber and Edison, who made analogous attemps to achieve millisec- ond recordings of sound and speech periods, which finally culminated in Edison's phonograph in 1877.
That means at the same time that film was not yet techmcally possible during Plateau's lIfetime simply because mstantaneous pho- tography lagged far behind the rotation speeds that were attainable with the stroboscope. For this reason, only scientific deVices and toys were initially developed from the stroboscope. The device was sng- gested by Doppler, who also discovered the acoustic effect that was named after him: to analyze motion, whose speed strips it of every visual perception, Doppler employed a systematic reversal of the stroboscope, which did not set images and slits into periodic motion but rather the light source itself - as a rapid snccession of electrical sparks, for example (Zglinicki, 1979, p. 120). This is precisely what in the meantime is employed in discos, most likely to train the speed of our perception - in defiance of all physiology - for the extreme requirements of a technical war.
The development of toys also proceeds in a similarly militaristic way. You may recall that one of the reasons why Leibniz developed his wonderful differential calculus was to make missile trajectories calculable. Now in 1811, a certain Franz von Uchatius came into the world, which at that time still had an Austrian Empire. In 1829, Uchatius voluntarily joined the second field artillery regiment as an artillery gunner. After graduating from the Bombardier Corps Academy iu 1837, he was promoted to sergeant and commissioned to teach physical chemistry. In 1841, he began his - at least for the Austrian artillery - groundbreaking research on canuon casting, which ultimately led him to the invention of steelbronze and also of the aforementioned explosive Uchatius powder, which is chemically closely related to old roll film. As a reward, Kaiser Franz Joseph pro- moted him to Field Marshal Lieutenant and at the same time, because this promotion would have otherwise been impossible, made him a
baron. In the symbolic world, on which monarchies are based, things fell into place very well, but Austria-Hungary did not have the least interest in the technical real world. After walking a great distance, a certain Mitterhofer from South Tyrol was permitted to present his wooden typewriter - the very first that we know of - to this same
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Kaiser. He received a personal donatIOn, but hIS machine dId not go into production. Uchatius fared even worse: due to bureaucratic difficultIes with the introduction of Uchatius cannons in the impe- rial army, the artilleryman and Field Marshal Lieutenant became his own target. On June 4, 1881 he shot himself in the head (Zglinicki, 1979, pp. 130-5).
After this requiem we now return to the history of film. Before Field Marshal Lieutenant Franz von Uchatius took aim at himself, it must have been important to him to teach all cadets and officer candidates the principle of artilleristic shooting. Plateau's newly dis- covered stroboscope lent itself easily to this purpose. Like Edison's kinetoscope, it also admittedly had the one crucial disadvantage that it was not a mass medium, but rather it always only allowed a single viewer to look through the observation slit. For his lectures on weapons technology, therefore, Uchatius spent his scarce free time first combining the well-known lanterna magica witb the strobo- scope. And behold: all of the cadets were immediately able to watch Uchatius' sketches of projectiles flying through the air at the same time, as they were projected onto the wall of the auditorium. The lanterna magica thus no longer produced merely virtual motion, like Schriipfer's curtains of smoke, but by means of a crank - much like early cinema - made successive images really dance in front of a fixed light source. It is no wonder, then, that Uchatius' constructions were purchased by a carnival showman, who gave magical performances that turned the weapon back into money, as Schriipfer or Robertson had once done (Zglinicki, 1979, p. 133).
What is interesting here is not this reversion, but rather the fact that the individual technical elements of film - the recording device, the storage medium, the projection apparatus - were combined with one another very gradually and in stages. Technical media are never the inventions of individual geniuses, but rather they are a chain of assemblages that are sometimes shot down and that sometimes crys- tallize (to quote Stendhal). After Uchatius combined the stroboscope and the lanterna magica, the only element that was still missing was the camera obscura that Talbot had already automated. However, its inclusion in the communication system known as film not only encountered technical obstacles, such as exposure times that were much too long, but also the traditionalism of an entire artistic epoch. As contemporaries of these experiments, draughtsmen like Toepfer in Geneva and Wilhelm Busch in his village near Giittingen were actu- ally quick enough to grasp the new method of drawing in phases as an art form, which means quite simply that they invented the comic
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strip, which led in turn to the animated cartoon. However, it was precisely because painters learned to break motion down into suc- cessive phases in the oineteenth century that they did not want to relinquish this new art form once again and replace it with technical media. On December 1, 1888, a certain Emile Reynaud received the French patent number 194 482 for his projection praxinoscope. As the name already suggests, this device projects moving stories, which Reynaud drew on perforated and flexible ribbons as animated films. All of these features, but above all the interplay between the perfora- tions and a gripping mechanism, guaranteed perfect synchronization. The musical accompaniment synchronized with the projection also practically anticipated Edison's kinetoscope, except that throughout his lifetime Reynaud stubbornly refused to replace his "artistic" drawings with photographs (Zglinicki, 1979, p. 136). As Hiilderlin so accurately wrote, it is hard to leave a place when one lives near the source. And what lives closer to the source than art according to European tradition?
3. 2. 2 Implementation
It was thus left to a European emigrant to the US to take the last step. Edward Muggeridge from Kingston-on-Thames, who changed his name to Eadweard Muybridge either out of Anglo-Saxon pride or an American desire for self-promotion, combined for the first time all the elements of film: instantaneous photography, iantema magica, and stroboscope. Muybridge's zoopraxiscope of 1879 showed, as its name claims, life (Zglinicki, 1979, p. 175).
The key word "life" naturally compels us to disregard momen- tarily this lecture's physical image of the world and to touch upon nineteenth-century zoology. However, to understand Muybridge's feat we are now in the same fortunate position as film history: we only need to combine the already existing or already recounted ele- ments. Colt's revolver, Daguerre's photography, Weber's acoustic experiments - all of these elements recur once again.
The initial push was supplied by acoustics. It was possible to record the frequencies of the human voice long before Edison, but there were no researchers who also thought to play back this voice at another place and time. The trick simply consisted in sending the voice into an amplifying funnel at whose end a membrane vibrated. The other side of this membrane was attached to an innocent hog's bristle, which finally scrawled the captured frequencies onto a lamp- blackened glass plate - provided that the experimenter rolled this
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plate past the bristle fast enough. In this simple way, for example, the very voice of the British phonetician who was the inspiration for Professor Higgins in Shaw's Pygmalion and the musical My Fair Lady has been preserved to this very day. For the first time, the physiology of a living human being was coupled with a storage medium rather than a chain of symbols with a repertoire of signs, as with writing.
3. 2. 2. 1 Marey and Muybridge
Phonographic recording, which at that time was also called visible speech, became the accepted thing among European physiologists. When France established a professorship in natural history at the Parisian College de France at the instigation of the great physiolo- gist Claude Bernard, for whom we have Zola's entire naturalism to thank, the holder, Prof. Etienne-Jules Marey, immediately began constructing devices. Doctors like Goethe's Mephisto had actually already strongly recommended taking the pulse of, above all, women with tenderness, and it was precisely because of such pleasures that it had not occurred to a doctor before Marey to replace his own hand with a machine. At the College de France, one device emerged after another: a heart recorder, a pulse recorder, and finally also a device that was connected to the four extremities of animals and could record their movements. None of these devices bore the least similarity to photographic cameras, but rather they worked, exactly like visible speech, with a pencil and a steadily moving paper cylinder.
As only luck would have it, Marey became acquainted with a captain in the French army who was also a horse enthusiast. This captain converted the results of the professor's measurements back into traditional art. His visual reconstruction of the measurements of a horse's legs manifested the incredible fact that there is a moment while galloping when only one of the horse's legs is touching the ground? The Anglo-Saxon world in particular was overrun with watercolors featuring horses and riders, yet there was not a single picture showing the leg position that Marey claimed.
Imagine for the blink of an eye if film had been invented in India and the leg position was not that of horses but rather of women and men according to the rules of the Kama Sutra . . .
7Kittler is incorrect here and in the following paragraphs when he states that one horse's leg is always touching the ground during a gallop. The theory of "unsup- ported transit" referred to here actually claimed that all of the horse's legs were in the air at the same time.
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Instead, the story continues m puritamcal America, where Leland Stanford Sr. became a millionaire by constructing a pacific railroad and consequently, long before Ronald Reagan, also became governor of the state of California. Stanford, the horse enthusiast and trotting horse breeder, saw the measurements of the horse's legs, but was unable to believe the results of Marey's experiments. We can only assume the reason was that the watercolor images of horses' legs remained so deeply imbedded in the subconscious minds of people who had not yet seen a film. However, where belief is lackmg, m America there is money and experimentation. Stanford had the for- tunate idea of calling in Muybridge, the landscape photographer, and commissioning a photographic test of tl,e horse's leg problem.
Muybridge thus exchanged the Californian wilderness for Califor- nian civilization, or the timelessness of Yosemite Valley, which he had immortalized in his landscape photographs, for the millisecond realm of telegraphy. Stanford's breeding establishment for trotting horses was located at his ranch in Palo Alto, precisely where the Leland Stanford Junior University - renowned for being the best for the study of electronics - stands today. Muybridge constructed a white wall with a short race track in front of it, and in front of this race track he placed a row of 12 instant cameras, which were all connected electronically. With relay circuits supplied notably by the San Francisco Telegraph Supply Company, another media industry firm, Muybridge succeeded in triggering these 12 cameras one after another at intervals of only 40 milliseconds, whereby each individual camera had a shutter speed of a single millisecond. Then all he needed was to make a horse gallop along the race track and Governor Stanford had a black-and-white photograph proving that during a certain phase of movement while galloping only one of the horse's hooves was touching the ground.
You see: Muybridge's experimental set-up no longer had even the smallest resemblance to the stroboscope, but rather it recorded movements for as long and extensively as the experimenter wanted and the race track allowed. Cylindrical storage media, which - from Plateau to Marey - were confined to repetitions and periods, and thus choreography and poetry, were superseded by the prose of science and later also of entertainment media. You know that in poetry, which was formerly identical to dance, everything must come back around as in the stroboscope; in novels, on the other hand, there is always an unforeseen and contingent future, as in Muybridge's series of instantaneous photographs, which can consequently also only stop through an interruption. All of so-called modern life therefore depends entirely on nineteenth-century media technologies.
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Muybridge's empincal confirmation of Marey's experiment took place in 1878. Five years later, the very same instantaneous record- ing technology used by Muybridge also made all of Field Marshal Lieutenant von Uchatius' dreams of artillery pedagogy come true. The physicist Ernst Mach sealed a wire in a glass tube, connected the wire electrically to the shutter of an instant camera, and then fired on the glass tube. The result was a photographic speed record: a real bullet, rather than a drawn one as in the stroboscope, generated shock waves as It entered the chamber. It is no wonder that the same Mach was also the first to achieve the opposite record: the time-lapse film for analyzing infinitely slow movements (Eder, 1978, p. 523).
Muybridge, as far as I can trust my optical memory, also invented another trick. The library of Stanford University, which the old gover- nor founded on the site of his fonner horse breeding establishment to memorialize his son (whose death was caused by bungling European doctors, of course) and to prevent similar tragic cases in the future through science, contains stacks of enormous photo albums, in which Muybridge gradually shifts from horses and cows to people. When- ever an athletic Stanford student and sprinter enters the photograph from behind, he is naked, but whenever he turns his front towards the camera a swimsuit suddenly appears out of nowhere, as if the image has been retouched. Muybridge thus invented the stop trick, one of the most important film tricks, long before George Meli"s. As far as I can see, frontal nudity first appears in Muybridge's photographs only during his later time at the University of Pennsylvania.
The purpose of the swimsuit in California is clear: only the nude photographs require some explanation. After Muybridge finally abol- ished the hand of the artist (which had appeared so irreplaceable to his predecessor Reynaud) and manufactured a pure multimedia system, he also wanted to reform painting. His magnificent volumes on "animal locomotion" were published for the express purpose of preventing artists from drawing or painting false positions, like the galloping horse. Muybridge's nude photographs provided them instead with a scientific model of all possible body movements. Like Renaissance perspective and the camera obscura, instantaneous pho- tography was supposed to discipline art. Admittedly, this time it did not involve abolishing the dominance of the symbolic, as in medieval holy images, and introducing a human scale through perspective, but rather at the end of the nineteenth century the imaginary also had to believe in it. The reason we never see three legs of a horse in the air is because the eye projects a familiar general shape on all of the phases of an animal's movements.
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I am pleased to be able to say that Muybridge's propaganda was a crowning success in at least one famous case. Duriug his European travels, Muybridge's patron Leland Stanford Senior also went to Paris, where he became acquainted - presumably in Muybridge's company - with the painter Meissonier. Jean Louis Ernest Meisso- nier, who unfortunately hardly anyone appreciates any more except for Salvador Dali and myself, had already painted practically all of the legs of the horses in Napoleon's Great Army on extremely expensive canvas out of an explicit admiration for Napoleon's "orga- nizational genius" (Greard, 1897, p. 47), but he confessed that he only knew how to represent these legs while striding and trotting and not while galloping (Greard, 1897, p. 194). Stanford demanded that Meissonier paint his portrait, which the painter would have refused to do had Stanford not revealed to him on this occasion the secret of Muybridge's instantaneous photographs of horses. Meis- sonier was converted, and it was because of him that this secret was eventually conveyed to the vice-president of the Paris Academy of Fine Arts. From then on, Meissonier employed photographic source material to paint real horses' legs rather than picturesque imagi- nary ones. According to his biography, he used these photographic models"only for verification," but in his private park in Poissy, near Versailles, he built a short railroad track, seated himself in a sleigh- like locomotive whose speed could be adjusted, and studied a gallop- ing horse in motion with his own mobilized painter's eye (Greard, 1897, p. 73). You see once again how the railroad replaced the horse in media history, and how the nineteenth-century railroad journey celebrated by Schivelbusch (1986) was not limited to being passively transported, but rather in the wonderful case of Meissonier it was already an active automobile in the literal sense of a forward-moving, self-propelling technology. It is hard to say whether this tremendous expense made Meissonier's war paintings more valuable or realistic, and there is no need to know. The death of traditional painting was quickly approaching, for in the same Paris salon where Stanford had met Meissonier, Muybridge also met Marey.
For the first time in this history of invention, therefore, we are con- fronted with a case of positive feedback. Sixty years earlier, Niepce and Daguerre had met purely by chance, even though they both lived in France, and their collaboration had to be insured through a civil contract. Now, in 1882, Marey's machine for measuring movement inspired Muybridge to design a follow-up invention in California, and Muybridge's serial photography, in turn, inspired Marey to design his own follow-up invention. Muybridge, as I have
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said, went as far as inserting his sequences of images - which were photographic and no longer merely drawn - into a stroboscope in order to be able to project real movements. This was still not a film, however, not only because a minute of horse galloping would have required 270 images instead of the available 12 (see Clark, 1977), but also because Muybridge was stubborn: as a prior landscape pho- tographer, he never gave up using the heavy, immovable glass plates that Niepce's cousin had introduced to photography in 1847. For this reason, namely, because a human life is far too short to comprehend avalanches of technical innovations, teamwork and feedback loops
become essential . . .
Muybridge and Marey, these twins or Dioscuri who were present
at the birth of fillll, were both born in 1830 and died in 1904. It is therefore possible to shift from one to the other without any prob- lems. After the soiree at Meissonier's, Marey realized that all of his machines for measuring heartbeats, pulse rates, and the movements of horses' legs had been historically superseded by Muybridge's serial photography - with one exception. By holding tight to the unifying, linearizing power of writing paper, Marey always only needed one single piece of equipment, while Muybridge had to position 12 dif- ferent cameras. The task, therefore, was to dispose of 11 cameras and still be able to supply serial photographs. In the process, Colt's good old revolver was once again honored, as it had also reduced the need for six pistols down to one. In 1874, a French astronomer, Pierre Jules Cesar Janssen, had already converted the revolver from the wars with the Red Indians into a revolver for the stars in order to capture 18 different positions of the planet Venus on a single photographic plate, whereby the astronomical revolver repeatedly closed his camera lens between these 18 instantaneous recordings
with a Maltese cross (Zglinicki, 1979, p. 170). While Marey still had to install his individual images into a stroboscope by hand, this new device supplied the stroboscopes all by itself. After this preparatory work, it was easy for Marey to improve on Jannssen's astronomical revolver. Marey developed a device that was roughly 50 centimeters long, which he dubbed a chronophotographic gun or fusil chronophotographique because it handles photographs much in the same way as a gun. It was braced against the shoulder for stabil- ity, it had gun sights for aiming, and firing the trigger produced an instantaneous photograph, whereupon the barrel, which contained 11 more unexposed negatives, turned 30 degrees, bringing the next negative into position. If the metaphor of shooting a photograph was ever taken literally, then it was in the case of Marey, whose assistant
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Georges Demeny was reportedly even ordered by the French general staff to record and optimize the standardized marches of soldiers using serial photography in 1904.
At a time when France was mourning a lost war and the lost provinces of Alsace-Lorraine, Marey's photographic rearmament considerably helped his career. The physiologist, who had already received his own physiological institute, rose even further to become president of the French photographic society. In this position, he put into place the penultimate step to film technology. The rigid barrel or disk, which had been maintained from Plateau's stroboscope through to tbe chronophotographic gun, was transformed into a flexible roll, which was transported automatically past the lens through a clock- work mechanism in the camera. And even though it still was not a celluloid roll, the technique of fihu recording was in principle fixed. Marey would only have had to put his photographic paper rolls into a projection apparatus driven by clockwork, but he did not, and he thus missed the chance of becoming Lumiere or technical light itself. For this reason, we are still faced with the pressing task of recon- structing the commercialization of the half-military, half-scientific technology of instantaneons photography throngh Edison and the Lnmiere brothers.
3. 2. 3 Silent Film
We no longer need, as in previons lectnres, to represent the history of this industrialization as a detailed acconnt of individual inventions. Up until now, the presentation of these individual inventions illus- trated the simplest, namely earliest attempts to solve the fundamental problems of optical media technology. This no longer applies, as the individual inventions and patents related to film began to explode in 1890: while there were only around 200 film-related patents issued worldwide between 1875 and 1890, this number had already risen to 500 between 1890 and 1910. In the age of indnstry, therefore, film emerged from pure teamwork. That is why I will only make rough cuts that treat silent film, sound film and color film as epochal structures. The two world wars will also serve as crude landmarks.
Before discussing the actual development of silent film, I want to point out again how far Marey had already come conceptually despite the fact that he failed to project his sequences of images. In 1891, his assistant, the aforementioned Georges Demeny, developed the won- drous photography of speech or photographie de la parole. Precisely like the earlier telephone inventor Alexander Graham Bell, Demeny
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