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Mary Lee Woods

From Wikipedia, the free encyclopedia

Mary Lee Woods
Colour photograph of Mary Lee Woods, taken in 2013
Born(1924-03-12)12 March 1924
Hall Green, Birmingham, England
Died29 November 2017(2017-11-29) (aged 93)[1]
London, England
Alma materUniversity of Birmingham
Employer(s)Telecommunications Research Establishment, Mount Stromlo Observatory, Ferranti
Spouse
(m. 1954)
ChildrenSir Tim Berners-Lee (Timothy)
Peter
Helen
Mike Berners-Lee (Michael)
Parents
  • Bertie John Woods (father)
  • Ida Frances Lee Burrows (mother)

Mary Lee Berners-Lee (née Woods; 12 March 1924 – 29 November 2017) was an English mathematician and computer scientist who worked in a team that developed programs in the Department of Computer Science, University of Manchester Mark 1, Ferranti Mark 1 and Mark 1 Star computers.[2][3][4] She was the mother of Sir Tim Berners-Lee, the inventor of the World Wide Web, and Mike Berners-Lee, an English researcher and writer on greenhouse gases.[5]

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Transcription

[Class Assembling] Hi! Welcome to FilmmakerIQ.com - I'm John Hess and today we'll explore Hollywood's history of visual trickery with the backstory of modern greenscreen compositing. With cameras and computers everywhere in our modern world, it's easy to forget that the very first motion pictures were, themselves, essentially a special effect. It's here at the beginning of filmmaking that we'll start our journey: the close of the 19th century with one of the world's first prolific filmmakers - a man who spent his life studying the art of illusion - Georges Méliès. In his 1898 film "Four Haads are better than one", Méliès employs a visual trick that is the rudimentary beginnings of what we now think of as greenscreen compositing. The use of mattes for multiple exposures. Compositing is a technique combining different shots and elements into one image. The matte shot was the first compositing techniques employed by early filmmakers such as Melies. In his film, Melies would black out parts of the frame using a piece of glass with some black paint. This "matte" made it so no light would reach the film so it wouldn't get exposed. Then Melies would rewind the film and this time matted out of everything else and expose only the part of the frame that was under the matte earlier. The resulting double exposure could combine two or more different shots into one frame all done inside the camera. This matte technique was used again on Edwin S. Porter's 1903 The Great Train Robbery but this time not as magic trick but as a means to create a larger more realistic world Notice the train moving outside the window of the train station - also the open door of the mail car with the scenery in the background. Both of these shots were done using mattes and double exposure. Now the fair question to ask here is why didn't they just shoot it in a real train station or a real train car? The answer is it was technically impossible at the time. Early orthochromatic film needed a lot of light and the technology for efficient electrical lighting for film was still a decade or two away. That's not even considering the inherent exposure problems of shooting an interior scene with a window in the shot. Even modern day cameras have trouble with the brightness differences between interiors and exteriors. In order to make film behave they way we experience the world, visual trickery had to be done. As film grew up in the 1900s and 1910s more techniques for augmenting sets and creating false realities would be developed. The Glass shot was a technique of painting elements on a piece of glass and placing that glass between the subject and the camera - a sort of real world compositing which was refined by early filmmaker Norman Dawn, using it to augment sets making them look much bigger and more elaborate without the costs of construction. But the problem with the glass shot was the paintings had to be ready on set. Norman Dawn solved this problem by painting the glass black and treating the shot like a matte shot. The matted film would be transfer to a second camera where matte artists could take their time creating the matte paintings. This matte painting concept continued seeing use in the golden era of Hollywood and continues with us even in our digital world. The problem with mattes is the camera had to stay perfectly still and no action could cross the matte line - the "hopefully" invisible line between the live action and the matte painting. This is where the traveling matte came into place. The process patented by Frank Williams in 1918 and demonstrated here in F.W. Murnau's 1927 film"Sunrise" - was a black matting process which photographed subjects against a pure black background. The film would then be copied to increasingly high contrast negatives until a black and white silhouette emerged. This black and white silhouette was used as the matte - called a traveling matte because it moved throughout the frame. This "black back matte" effect which was called the Williams Process was used quite famously by John P. Fulton in 1933 for the film "The Invisble Man". The shots where the invisible man was taking off his clothes were accomplished by photographing actor Claude Rains wearing a full black velvet suit standing against a black background. This effect was so memorable and startling it was used on follow up sequels even after more effective processes came along. The Williams Process had some issues - for one, any shadows on the subject would be lost in the traveling matte. An alternative came about in 1925, invented C. Dodge Dunning which would eventually be called the Dunning Process. This process used colored lights, lighting a background screen blue and the foreground subject in yellow. Using dyes and filters, the blue and yellow light could be split apart to create traveling mattes. The Dunning Process would first see use on King Kong in 1933. The problem with the Dunning Process was it only worked with black and white film. Color Film needed a new technique and it would come in 1940 by special effects artist Larry Butler in the Thief of Bagdad. Using the three strip technicolor process, Butler shot the subject against a blue background. Blue was used because it was the farthest away from skin tones and the blue film stock had the smallest grain. Taking the blue separation from the three technicolor negatives, Butler was able to create a silhouette matte just like with Williams process. Then, using an optical printer, a relatively new invention at the time that could combine multiple film strips into one, Butler would first remove the blue background from the foreground plate and, using the negative of the travelling matte, remove the foreground space from the background plate and then finally combining both foreground and background plates together. This bluescreen technique won an Academy award for Best Special Effects for Larry Butler in 1940 but it was not without its inherent problems. Firstly the process was extremely time consuming as it involved several steps with an optical printer. Secondly, it still had some edge issues where a thin blue line was almost always visible in the shots. It also couldn't handle any fine details like hair or smoke or motion blur. Despite these limitations, the blue screen process was used extensively including in such blockbusters as The Ten Commandments in 1956: Hollywood kept experimenting with other variations on the bluescreen process including the ultraviolet matte as used in "The Old Man and The Sea". But the real challenger to blue screen was created in the late 50s and credited to one of the giants in world of compositing Petro Vlahos. Developed by Vlahos in the mid 50s and used extensively by the Walt Disney Studios in the 60s and 70s: The Sodium vapor process used actors, who were lit normally, standing in front of a white screen which was lit by powerful sodium vapor lights - those are the orange lights you see on street corners. Sodium vapor emits light in a very specific wavelength - averaging 589.3 nanometers - and nothing else. Using a specially coated prism in an old three strip Technicolor camera, the very specific wavelength of the sodium vapor light was split off and captured on special black and white film - automatically creating the black and white traveling matte. The remaining light would be captured by regular three strip Technicolor Film which was relatively unaffected by the yellow/orange sodium vapor lights. This technique produced some of the best travelling mattes of the time and was used by Disney first on film The Parent Trap and then The Absent Minded Professor both in 1961. Mary Poppins in 1964 demonstrated the capability of the sodium vapor process winning an academy award for best special effects. There was just one problem. Only One Sodium Vapor prism was ever made so there was only one camera that was capable of this process. Disney owned the camera and they didn't let it rent for cheap. Revenge of the Blue Screen In the late 50s, When MGM was ready to produce Ben Hur in the MGM Camera 65 format (a 65mm film process) they turned to Petro Vlahos, the inventor of the sodium vapor process for help on the compositing. They didn't want the problems that Ten Commandments had with bluescreen but The sodium vapor process wouldn't work as it prism it used was been made for 35mm film, not 65mm. So Vlahos was asked to see if he could do something about trying to improve the bluescreen process. After six months of hard work, Vlahos had a discovery. And this is where it gets pretty complicated. Most colors that aren't purely green or purely blue have about equal amounts of blue and green in them. So when creating a matte from bluescreen, Vlahos used a Green Cancellation separation (or positive), ran it though with the original color negative exposing both pieces of film together under a blue to light to create a "blue difference matte". This matte was clear where the blue and green were the same - Then the blue separation positive was combined with the original negative and exposed under red light to get a cover matte. This cover matte was applied back to the original color separations except that the blue separation was replaced with a composite of the green and the green difference mask - essentially a synthetic blue separation. This complicated process required 12 film elements to get from the composite negative to the composite internegative but it was remarkable in the way it single handedly solved the edge and fine detail problems that plagued blue screen. It was so successful in fact that the process remained in popular use for almost 40 years. Developments like microprocessor controlled quad optical printers, employed by Richard Edlund for The Empire Strikes Back made the process faster and more accurate but the next big change to come would be in the form of digital. I have consciously avoided the the term "chroma key" as historically the term applied only to video systems only. That's not the case anymore. In rudimentary video mixers, a keyer was a mathematical process that would make a range of colors in a video signal and make it transparent. This is, of course, a common effect that television newsrooms all over would use weather map special effects. Blue as a screen color was still predominate but green started to take over as films began getting the digital post production treatment in the late nineties. Why Green? Basically Green was easier and cheaper to light than blue, green registers brighter on electronic displays, worked well for outdoor keys (where the blue screen might match the sky) and the bold green color was less common in costumes than blue is. And now as digital camera are replacing film, many digital sensors use a Bayer Pattern which have twice the number of green photosites than red or blue to capture luminance. This makes modern digital cameras much more sensitive to the green part of the spectrum making pulling a matte from greenscreen a little easier. Blue is still commonly used as are other colors depending on the needs of the shot. So now with advanced software and motion controlled cameras, Chroma Key, a term that has grown now to encapsulate much more than it's original video technique, can be used to insert backgrounds and set extensions in ways that Georges Milies and Norman Dawn could only dream of. There are cynics today that believe modern film is too reliant on CGI and that we should return to a simpler form of real filmmaking. But as I hope you learned, that era never existed - filmmakers from the very beginning have sought to push the medium with special effects. The undeniable truth about filmmaking is the only thing that matters is what's on that screen. From Edwin S. Porter's matted train station window to the modern action spectacle, it's all about creating a window onto another world. A world where each of us can find our dreams our fears and ourselves. All these effects we have are just tools to help us get there.. And we have some fantastic tools, so use them, and make something great. I'm John Hess and I'll see you at FilmmakerIQ.com

Early life and education

Woods was born on 12 March 1924, in Hall Green, Birmingham to Ida (née Burrows) and Bertie Woods. Both her parents were teachers. She had a brother who served in the Royal Air Force during World War II and was killed in action. She attended Yardley Grammar School in Yardley, Birmingham, where she developed an aptitude for mathematics.[5] From 1942 to 1944, she took a wartime compressed two-year degree course in mathematics at the University of Birmingham. She then worked for the Telecommunications Research Establishment at Malvern until 1946 when she returned to take the third year of her degree. After completing her degree she was offered a fellowship by Richard van der Riet Woolley to work at Mount Stromlo Observatory in Canberra, Australia, from 1947 to 1951 when she joined Ferranti in Manchester as a computer programmer.

Ferranti computer programming group

On joining the UK and electrical engineering and equipment firm, Ferranti, she started working in a group led by John Makepeace Bennett.

She worked on both the Ferranti Mark 1 and the Ferranti Mark 1 Star computers. The programs for these computers were written in machine code, and there was plenty of room for error because every bit had to be right.[6] The machines used serial 40-bit arithmetic (with a double length accumulator), which meant that there were considerable difficulties in scaling the variables in the program to maintain adequate arithmetic precision.[7]

The Ferranti programming team members found it useful to commit the following sequence of characters to memory, which represented the numbers 0–31 in the International Telegraph Alphabet No. 1, which was a 5-bit binary code of the paper tape that was used for input and output:

/E@A:SIU½DRJNFCKTZLWHYPQOBG"MXV£

Another difficulty of programming the Ferranti Mark 1 computers was the two-level storage of the computers. There were eight pages of Williams cathode ray tube (CRT) random access memory as the fast primary store, and 512 pages of the secondary store on a magnetic drum. Each page consisted of thirty-two 40-bit words, which appeared as sixty-four 20-bit lines on the CRTs. The programmer had to control all transfers between electronic and magnetic storage, and the transfers were slow and had to be reduced to a minimum. For programs dealing with large chunks of data, such as matrices, partitioning the data into page-sized chunks could be troublesome.

The Ferranti Mark 1 computer worked in integer arithmetic, and the engineers built the computer to display the lines of data on the CRTs with the most significant bit on the right due to their background in radar. This could be argued as the logically sensible choice, but was changed to the more conventional system of the most significant bit on the left for the Mark 1 Star. The Mark 1 Star worked with both fractions and integers.[7] The Baudot teleprinter code was also abandoned for one that was in the following order:[8]

ø£½0@:$ABCDEFGHIJKLMNPQRSTUVWXYZ

Program errors for the Ferranti Mark 1 computers were difficult to find. Programmers would sit at the computer control desk and watch the computer perform one instruction at a time in order to see where unintended events occurred. However, computer time became more and more valuable, so Dr Bennett suggested that Woods write a diagnostic program to print out the contents of the accumulator and particular store lines at specific points in the program so that error diagnosis could take place away from the computer. The challenge of her routine, 'Stopandprint', was that it had to monitor the program under diagnosis without interfering with it, and the limited space in the fast store made this difficult. Along with Bennet and Dr D.G. Prinz, Woods was involved in writing interpretive subroutines that were used by the Ferranti group.[7][9][10]

Errors with the programs were one problem, but errors caused by the computer were another. The computer frequently misread the binary digits it was given. The engineers thought the mathematicians could compensate for this by programming arithmetic checks, and the mathematicians would too readily assume that a wrong program result was due to a computer error when it was due to a program error. This caused inevitable friction between the mathematicians and the engineers. At the centre of this was a program that Woods had written for inverting a matrix to solve 40 simultaneous equations, which was a large number for the time. The long rows of data required by this calculation took the computer too long to process without an error. For one dispute Woods went to Tom Kilburn, who was second only to Professor Sir Frederic Calland Williams in the engineering department. Kilburn was polite but did not argue, and she felt he was ignoring her complaint. However, 50 years later when she asked him about the exchange, he said that he had not argued "because [he] knew [she was] right."[11]

While at Ferranti, Woods discovered that the women in her department were getting less pay than the men. She presented the case to the personnel department and was able to convince them to grant equal pay and rights for women.[12]

Cottage industry programming

Woods left Ferranti in 1955, when her first child was born. She continued to get involved in smaller programming projects, that she termed "cottage industry programming,"[5] so that she could complete jobs from home. Most notably she did some work with the London Transport Executive, to develop a simulation for bus routes that could prevent hold ups and bus bunching. She also developed a program for the RAF at Boscombe Down to track weather balloons and translate their readings. Then she came out of retirement in 1963 to work for a London-based company called K and H. While at K and H she wrote programming manuals until she retired in 1987.

Personal life

In 1954 she married Conway Berners-Lee whom she met while working in the Ferranti team, and together they had four children; Timothy (Tim), Peter, Helen and Michael (Mike). Their eldest son, Sir Tim Berners-Lee is the inventor of the World Wide Web, and their youngest son Mike is an academic.[13][14][15]

After a period devoted to bringing up children, she became a schoolteacher of mathematics, and then a programmer using BASIC, Fortran and other languages before retiring in 1987.

She died on 29 November 2017, aged 93.[16][5]

References

  1. ^ "Mary Lee Berners-Lee: Pioneering computer programmer whose son invented the world wide web", The Times, p. 77, 20 January 2018
  2. ^ "Scientific pioneers honoured by The University of Manchester – The University of Manchester". manchester.ac.uk. Retrieved 23 January 2018.
  3. ^ "I am Tim Berners-Lee. I invented the WWW 25 years ago and I am concerned and excited about its future. AMA • r/IAmA". reddit. Retrieved 23 January 2018.
  4. ^ Conway and Mary Lee Berners-Lee, interviewed by Thomas Lean, 2010–2011, An Oral History of British Science, British Library Sound & Moving Image reference C1379/23 Audio and Transcript (at British Library only but brief Content summary available online).
  5. ^ a b c d Ferry, Georgina (23 January 2018). "Mary Lee Berners-Lee obituary". The Guardian. Retrieved 23 January 2018.
  6. ^ The University of Manchester (1999), Programming on the Ferranti Mark 1, archived from the original on 5 July 2009, retrieved 12 November 2009
  7. ^ a b c Campbell-Kelly, Martin (1980). "Programming the Mark I: Early Programming Activity at the University of Manchester". Annals of the History of Computing. 2 (2). American Federation of Information Processing Societies: 155. doi:10.1109/mahc.1980.10018. S2CID 10845153.
  8. ^ The University of Manchester (2008). "The Ferranti Mark 1*". Archived from the original on 15 May 2009. Retrieved 12 November 2009.
  9. ^ Bennett, J. M.; Prinz, D.G.; Woods, M. L. (1952), "Interpretative sub-routines", Proc. ACM Nat. Conf., Toronto, pp. 81–87, doi:10.1145/800259.809002, S2CID 17531732
  10. ^ J. M., Bennett, "Comments on Programming the Manchester Mark I", Annals of the History of Computing, 3 (2), doi:10.1109/MAHC.1981.10014
  11. ^ Abbate, Janet (12 September 2001), Mary Lee Berners-Lee: An Interview, IEEE History Center Interviews, vol. 578, IEEE History Center – via Engineering and Technology History Wiki
  12. ^ Abbate, Janet, Recoding Gender
  13. ^ Berners-Lee, Tim; Fischetti, Mark (1999), Weaving the Web: The Past, Present and Future of the World Wide Web by its Inventor, London: Orion Business, ISBN 978-0-7528-2090-3
  14. ^ Bellis, Mary, Father of the Internet Tim Berners-Lee, archived from the original on 13 July 2012, retrieved 10 November 2009
  15. ^ "Mary Lee Berners-Lee". The British Library. Archived from the original on 30 September 2023.
  16. ^ News Bulletin from the Parish of SS Alban & Stephen (PDF), 24–25 December 2017, archived from the original (PDF) on 9 January 2018, retrieved 9 January 2018
This page was last edited on 15 May 2024, at 00:20
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