Sony s Breakthrough Color TV

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Throughout his long career, Sony co-founder  Masaru Ibuka presided over many special devices. The one he was most proud of?  A color TV, of all things. No product better explains Sony's  engineering prowess and tenacity. It took Sony nearly eight years to bring  it to the market. But when it came out,   no one else’s color TV could compare.

In this video, we look at Sony's  breakthrough color TV, the Trinitron. ## Beginnings Before we begin, I want to mention that this   video is part of a series on the  histories of the color Television. Done in collaboration with our friends at IEEE  Spectrum. More later. Now on with the show ... Inside Sony's beating heart  are its two cofounders.

Masaru Ibuka, the company's whirlwind  engineer. Somewhat naive, playful,   and guileless in the real  world, but also tenacious,   relentlessly driven towards excellence, and  an incredibly motivating engineering leader. And then there is Akio Morita, 13 years younger  than Ibuka. Scion of a wealthy sake family -  

though funny enough, he does not drink. Morita was  Sony's charismatic business leader and spokesman. Pragmatic and to the point, Morita gets  things done and done fast. And though his   family was Sony's single biggest shareholder,  Morita looked up to Ibuka. Morita's guiding   principle was to ensure that Ibuka and his  team got the money to produce their projects.

Ibuka and Morita worked together for forty years  and almost never argued. They were perfectly   suited for each other in achieving their dreams of  bringing consumer electronics to ordinary people. They started off producing professional  audio equipment like the G-type,   Japan's first commercially  available tape recorder. They then early on licensed the  transistor from Western Electric   and harnessed its power. Sony's team  of cracked engineers then used it to   produce popular consumer devices like the  breakthrough TR-55 and TR-63 pocket radios.

## TVs Rising competition in transistor radios however  motivated the company to research new categories. The obvious next candidate for transistorization  was the black-and-white television,   which were then getting extremely popular. These worked with an electron gun  pointed at a screen. The inside  

of the screen is painted with a  glowing material, or phosphor. During operation, the gun  fires electrons at the screen. When those electrons hit the phosphors, the  phosphor gets energized and releases light. To put images onto the screen, you use  energy to deflect the beam. Because you   need a good amount of energy to do this and  things can get rather hot inside the TV,   normal Germanium power transistors are not  sufficient. You needed something stronger. ## Silicon Transistors Namely, you need silicon. Its higher melting  point lets it handle these higher temperatures.

In 1956, Ibuka and his top technology  R&D guy Kazuo Iwama attended a Bell   Labs seminar. The people there claimed  that silicon would be the future. Ibuka   echoed this sentiment when he predicted  that "this will be the age of silicon". Silicon transistors did already exist then,   but they were small - more suitable for handling  signals rather than power currents. Nevertheless,   Ibuka assigned a team to produce these  silicon power transistors from the ground-up. It was an interesting time in semiconductor  technology. Pure silicon then cost more than   its weight in gold. Sony had to buy  20 millimeter crystals from France.

Photolithography had not yet been  invented. So to apply the pattern design,   the Sony team had to use oxide and mesa masking. This involved selectively applying and  etching away layers on top of the raw silicon.

## The Micro-TV Their first product with silicon transistors,  released in 1960, was the TV8-301. Despite being transistorized, it was small,  fragile and did not sell well. So what next? At the time, the American market seemed  to prefer big-screen TVs. The obvious   thing to do then would be to follow the  crowd and produce those big-screen TVs. But Sony had hit the limit of their  silicon power transistors. Existing   impurities in the silicon caused excess  power leakage. The larger the chip got,  

the worse the leakage was. Since the  power transistor cannot get any bigger,   the transistorized TV could not have a  screen much larger than 5 or 8 inches. American marketing consultants very  strongly insisted that a TV with   such a small screen would fail in the  market. But Ibuka pushed to turn this   supposed weakness into a strength,  and lean into the TV's small size. So they did. Morita, then spending time in  Sony America's headquarters in New York City,  

began preparing a marketing campaign  for what was called the "Micro-TV". He   spent long nights sitting in front  of the TV studying commercials. He snagged Volkswagen's advertising agency  in the US, somehow convincing them that the   Sony name will soon be a big one. And the  Sony salespeople worked harder than they  

ever before thought was possible.  One Japanese salesperson recalls: > We had never distributed before in our  lives. We didn't even know how to price   our products. I had been in the Japanese  army and knew what it meant to go all out,   even to risk your life; but  I worked harder in New York The efforts paid off. The 5-303W  Micro-TV sold very well. 50+ years  

later, Redditors are playing Call of Duty on it. ## Color TV As soon as Sony's engineers  finished engineering the TV,   Ibuka started talking about turning to  the color TV. This one was a bit tricky. In the 1940s, a team at CBS patented the field  sequential system for color television. It   involved mechanically rotating a set of red,  blue, and green filters at 1,400 revolutions   per minute in front of the camera. This  creates red, blue, and green images.

A special color TV would then show the red, blue,   and green images, one after the other  sequentially. It displays this so fast   that the human brain perceives  it as a single full-color image. The concept behind this CBS system  is reminiscent of an earlier work   by John Logie Baird in 1928, but  it produced a far better image. The catch is that to avoid a noticeable  flicker, we needed a high refresh rate,   which would have meant sending three times the  number of images as black-and-white broadcasts. This was unacceptable, so the CBS  engineers instead slightly reduced the   frame rate as well as the size of the frames  themselves - creating a rather small image.

These modifications made the CBS  setup incompatible with existing   black-and-white systems. At the time,  RCA had a sizable investment in this   black-and-white ecosystem. They risked losing  it all if the US adopted the CBS color system. So in a six-month crash program  starting September 1949,   RCA produced the Shadow Mask  Tube as a credible alternative. In this system, you have three electron  guns - one for each primary color red,   green and blue - placed in the back of the TV. The guns fire converging beams  towards the eponymous "Shadow Mask",   a thin metal sheet with tiny  holes drilled into them.

The Shadow Mask is positioned right in front  of a screen coated on the inner side with red,   blue, and green phosphors set in pixels. The electron guns are positioned in  relation to the shadow mask such that   the right electron beam passes through the  mask's holes to hit the right phosphor. So, electrons from the green beam only hit the  green phosphors on the screen, making it glow. The red, green, and blue phosphors glowing next to   each other fools our primitive carbon-based  meat brains into thinking there is color. It wasn't super bright, but it was compatible with   existing black-and-white systems  and that was what mattered.

## The Shadow Mask Tube's Weaknesses Unlike the black-and-white TV, which  caught lightning in a bottle as soon   as it hit the market, color TV  adoption started off slowly. Six years after the release  of the first RCA color TV,   US consumers bought just one color  set for fifty black-and-whites. The   situation was even worse in Japan, just 300 of  9 million sets sold that year were color sets. At first, you could blame this to  content availability. But in 1962,   the US's National Broadcasting Company or  NBC started producing two-thirds of their   nighttime programming in color, kicking  off new growth in color TV content.

Thus one must also blame the Shadow Mask Tubes.  First of all, the screen was not particularly   bright. 85% of the guns' electrons hit the mask,  not the screen. You can do brighter phosphors   or more powerful guns, but 15% efficiency  will always look pretty bad on the screen. More importantly, the need for three  separate electron guns converging   towards a single point meant extra  manufacturing work and higher cost.  

Each TV set had to be manually tuned  by a skilled and trained human worker. The setup was also vulnerable to external  magnetic fields from nearby appliances or even   the Earth itself. Any such interference  would mess with the three beams' aim,   creating these annoying colored patches.  This issue would not be solved for years. This is all in addition to the  difficult challenges of making   the shadow mask itself - produced  using a combination of chemical,   mechanical, and photographic techniques.  You can see why it was not super-ideal. ## Sony Meets the Chromatron RCA made its Shadow Mask Tube system  widely available for licensing. And  

despite its warts, many companies licensed it. Sony considered licensing the system too.  They were seemingly behind in this market   and an RCA license would have been the fastest  way to get a Sony color TV onto the shelves.

But in a moment of cheekiness, Ibuka  thought it would be "no fun" in merely   copying the market leader. But  if not RCA's tech, then what? In 1961, Ibuka and Morita attended  a trade show sponsored by the IEEE   in New York and there on the show  floor, they saw the Chromatron. The Chromatron has a fascinating  history. It was invented in 1951  

by Dr. Ernest Lawrence. Lawrence is a Physics  Nobel winner and also invented the cyclotron. He was the guy that Josh Hartnett  portrayed in the movie Oppenheimer. IEEE Spectrum has a fantastic video on the  history of Dr. Lawrence's efforts inventing   the Chromatron in a video on their own YouTube  channel. Go watch that right after this one! So Morita sees a crowd gathering around  the sharpest and brightest color screen   he has ever seen. He is so impressed that he  immediately calls the technology's owner - a  

subsidiary of the movie studio Paramount  Pictures - and gets a technical license. A few months later, Sony sends a young,  Argentina-born Japanese physicist named Senri   Miyaoka to learn the Chromatron's technology from  the licensor. Miyaoka recalled going to a dark,   windowless basement lab and meeting a team  of 10 glum, very frustrated Americans. As the Americans explained  the Chromatron's technology   to him - one even thanked him for releasing  them from such a thankless task - Miyaoka   sensed that Sony had gotten itself  involved in something formidable.

## Making the Chromatron If the RCA Shadow Mask Tube system's  main headache was the intricately   aligned convergence of three electron guns, then  replacing the three guns with one fixes that. But as they say, out of the frying pan  and into the fire. This thing is insane. The Chromatron works similarly to  the Shadow Mask Tube in that it   fires electrons at phosphors on the inside  of a glass screen ... but with some changes.

First, the three-gun arrangement  is replaced with a single gun. The screen phosphors are no  longer arranged in pixels,   but instead in parallel, vertical stripes.  Green stripes, blue stripes, red stripes. The gun is loaded with sequential information of  the color image - green, blue, red data - and then   fires. To trick the human brain into seeing  a full color image, we need the right color   information from the gun hitting the right color  phosphor stripe. Red info to red stripe, right? How do we achieve this? The Shadow Mask Tube used   the shadow mask to keep unwanted electrons  from reaching the phosphors on the screen. Chromatron did this differently.  It had a "grill" of charged wires  

running vertically up and down  positioned just inside the screen. These are color-selecting wires  and there are up to 400 of them.   They activate at just the right time and  deflect unwanted electrons such that only   the red signal information hits the red  phosphor stripes. What a high wire act! ## Troubles Sony spun up a brand new factory  in Tokyo to build the Chromatron,   but mass production dragged on and on. One big challenge was synchronizing the electron   beam and the activation/deactivation  of the metal lines in the grill. I have seen it described as something  like swinging your arms back and forth,   and snapping your fingers at  the apex of every arm swing.

When it worked, it worked beautifully. But  when it did not work - and that happened   quite often - you got sickening color variations. In September 1964, Sony had a 17-inch  Chromatron prototype and put it in the   Sony showrooms to build hype and air horns. But  behind the scenes, the factory was struggling.   With 27 vacuum tubes and delicate wires spaced  less than a millimeter apart from one another,   it was ten times more complicated to produce  than a standard shadow mask tube color TV.

For every 1,000 TV sets that Sony made, just two  or three worked as intended. If the grid moved,   the misalignment would cause people's faces  to turn green like as if they were the Hulk. Ibuka though refused to back  down from mass production, saying   that if one set worked, then improvement  can be achieved. And to be fair,  

he said the same thing before when Sony  was struggling to ramp up its transistors   for its first transistor radio and  that worked out. But not this time. In 1965, the Sony team decided that the 1-gun  method that Dr. Lawrence originally used for   the Chromatron could not be used. The cost of  the color-switching grill was just too high. So they switched to a three-gun method,  one for each color like as before. This   brought back the gun alignment issue - a tiny  misalignment can cause more color variations.  

But it loosened the tolerances between the  vertical wires, so it was easier to make. So in May 1965, they released a 19-inch Chromatron  to the Japan market, eventually selling 13,000   sets there. Each set sold for 198,000 yen or $550  but cost 400,000 yen or $1,111 to make. Not to   mention all the defects plaguing buyers. Sony had  to grant a lifetime warranty, and boy was it used. These economics are not favorable.  Yet Ibuka again refused to shut it   down and switch to the RCA shadow mask.  In fact, he doubled down and made the   Chromatron Sony's single highest priority  - with 150 people working on the team.

## It Gets Worse By 1966, the Shadow Mask Tube  system was fully mature in the   market and color TVs were going mainstream. Sony's distributors and dealers  urged the company to bring a color   TV to the US or see their position  there come increasingly at risk. Every Chromatron TV set Sony sold though  lost them money. Not to mention the $700,000   in development costs the company was  spending each year on fixing issues. For the first time, people sensed  tension between the two legendary   co-founders. Morita wanting to cut their losses,   but Ibuka digging in. No one ever saw them  actually arguing, but the strain was palpable.

During the worst of it, accountants  and business planners started   appearing at the Chromatron engineering  brainstorming sessions. They said nothing,   but everyone in the sessions knew that they  were reporting back to "Morita's people". Then there was the time Morita  himself angrily berated the Chromatron   team for exploiting Ibuka's commitment to the  Chromatron so to explore "curiosities in the   problem-solving process" without  actually solving said problems. Despite this, behind the scenes,  Morita worked with the Japan   Development bank for a $2 million loan  to continue funding the R&D effort.

Finally in 1966, Ibuka agreed to dissolve the  team and adopt the Shadow Mask Tube if a viable   alternative cannot be discovered by the end of  the year. He agreed to personally lead them,   feeling the lost preceding  five years to be all his fault. The color TV team split up,   exploring varying approaches in parallel.  Ibuka went between them, asking questions,   offering encouragement, and sometimes even  directly participating in the experiments. ## Three in a Line In 1966, General Electric released  their "Portacolor" TV color set. It was also a Shadow Mask Tube, but  with a twist. It had a single electron  

gun equipped with three cathodes arranged  in a straight line, creating three beams. By contrast, the Chromatron  arranged its three guns/three   beams in a triangle, or delta, formation. One of the team's managers Susumu Yoshida went   to General Electric to review  the idea and maybe license it. But Yoshida didn't think that the  Portacolor was bright enough. It  

still used a shadow mask. But he  was intrigued by the three-cathode,   one-gun setup and how it might work  when paired with the Chromatron's grill. So he suggested this idea to his subordinate  Senri Miyaoka - the guy who went to the American   dungeon to first learn the Chromatron  process. Miyaoka then rigged it up by  

strapping two cathodes to the sides of  a standard black-and-white electron gun. He was surprised to find that this arrangement  created a bright - albeit blurry - picture.   Miyaoka did a few experiments and  then wrote it down into a report.

Ibuka read that report and summoned Miyaoka to  discuss just before the latter had to go to his   weekly orchestra practice. In a hurry  to end the conversation, Miyaoka said,   "Yes this can work in a commercial system" and  rushed out the meeting to go play the cello. The following Monday, Ibuka reoriented his 7,000  person company towards this one thing. He became   obsessed with it - dropping whatever he was doing  at the time whenever someone came to him with a   question about it. Sometimes he even wandered  off with them to the lab afterwards to see. ## Trinitron The Trinitron gun was completed by  February of 1967 and the prototype   completed in November 1967. It  is a beautiful piece of work. On one end, you have a single electron gun,   with the three RGB cathodes arranged  in a horizontal line. At the other end,  

you have as usual the screen with the three  color types of phosphors painted on the inside. The gun uses its three cathodes  to fire three electron beams. They they converge towards a common point,  crossing each other at the center of a large   electron lens. This crossing or convergence  is also the origin of the name, Trinitron. After crossing over, they expand outwards again,   like as if from a single point.  Deflection plates are then used   to focus and direct the beams towards the  right phosphor stripe inside the screen. Instead of a shadow mask in front  of the screen, the Trinitron has an   aperture grill. It is comprised of etched  vertical metal wires, one for each color.

The grill does the same thing as the  shadow mask - separating the color beams   to ensure that right beam hits the right  phosphors. But the vertical lines allow   more electrons to pass through,  which means a brighter picture. One can argue that the aperture grill is as big  a breakthrough for the Trinitron as the electron   gun. It certainly brought its share of engineering  challenges. The electron bombardment heated up the   metal, causing it to expand or shrink. That gave  Ibuka and everyone else involved a big headache. ## Game-changer Sony announced the Trinitron on April  15th 1968, four days after Ibuka's 60th   birthday. Ibuka hosted the press conference  himself in Tokyo with ten prototypes on the stage.

Yoshida had earlier estimated that it would take  about a year to ramp up production. So he must   have had a mini-heart attack when he heard  Ibuka tell the world that Sony would offer   ten thousand Trinitrons for the public by October.  Morita said the same thing later in New York. The team protested. Ibuka told them to  study the American Manhattan Project  

for inspiration, and to Yoshida he said: > "I will never do this to you again,  so please indulge me this once". Yoshida had to be the Bad Guy to turn the  ten prototypes into a commercial product.   His team started calling him "Shogun Yoshida",   due to his ferocity in running  the team towards the finish line. Sony dealers from the start  wanted a Trinitron with a   17-inch screen size. But to speed  up the commercialization process,   Sony opted to first bring out a 12-inch  screen version of the Trinitron.

Competitors later claimed the set's  brightness and quality was because of its   smaller size. Not true. The smaller  screen was just to get it out faster. Six grueling months later, the team  of 100+ engineers and scientists   started rolling the first sets  off the Tokyo factory line. The   culmination of an eight-year and  $12 million development odyssey.

## Conclusion The Trinitron broke RCA's years-long virtual  monopoly on color TVs. It was a true game-changer. On the basis of its far brighter  screen and simpler production process,   the Trinitron quickly won the  small color TV market in Japan. By March 1969, they were selling 10,000 sets each  month, ramping up to 20,000 a few months later.

They could not keep up with  demand and factories had to   be spun up in San Diego and the United Kingdom. From 1968 to 1998, Sony sold 180 million  Trinitrons. Sony finally ended the Trinitron line   in the 2000s when LCD and other semiconductor  displays finally took over. Remarkably,  

the system remained largely the same for  some twenty years after its introduction. The Trinitron was one of the last Sony products  that Ibuka directly oversaw. Afterwards,   he transitioned out of day-to-day operations  and into more personal pursuits like youth   education. He passed away in 1997  at age 89. What a thing to end on.

2024-09-17

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