> The largest JumboTron in use was located at SkyDome (now Rogers Centre) in Toronto, Ontario, and measured 10 m tall by 33.5 m wide (33 ft × 110 ft), with a resolution of 672 × 200 pixels, or 134,400 pixels.[9] Its cost was US$17 million.
I was told a pretty significant amount of hard RF leaks out the back of a tube. I wonder if its more, on a bigger one.
I was also surprised by how gentle the round off was. Sony did a decent job on the trinitron making tube front flat but it always pushed up against size. You gotta make it stable under a fair bit of vacuum.
RF is not an issue, but X-ray emission is indeed a problem that had to be confronted by TV engineers back in the day. A rule of thumb is that a color TV needs about 1 kV of acceleration voltage per diagonal inch. 43 kV is no joke when it comes to X-ray generation, so I'm curious if they found a way to make it work at a lower voltage.
At one point in the video you can see that the TV has two second-anode leads, so maybe that was the trick, using two separate acceleration electrodes at half the voltage.
The best of the internet, engineering and humanity... all in one video.
And yet it disappeared off Hacker News almost immediately. I kind-of feel lucky to have stumbled upon it, what a gem of a video.
It's a real shame that Sony didn't allow the interview to happen
This was a very fun video. Both the technology involved and the passion of someone collecting these things.
Single-tube. Jumbotrons count and they are way bigger, but you can only boil electrons off a cathode at such a rate and velocity.
Fun fact (from wikipedia):
> The largest JumboTron in use was located at SkyDome (now Rogers Centre) in Toronto, Ontario, and measured 10 m tall by 33.5 m wide (33 ft × 110 ft), with a resolution of 672 × 200 pixels, or 134,400 pixels.[9] Its cost was US$17 million.
This is an epic tale about a marvel of engineering.
I was told a pretty significant amount of hard RF leaks out the back of a tube. I wonder if its more, on a bigger one.
I was also surprised by how gentle the round off was. Sony did a decent job on the trinitron making tube front flat but it always pushed up against size. You gotta make it stable under a fair bit of vacuum.
RF is not an issue, but X-ray emission is indeed a problem that had to be confronted by TV engineers back in the day. A rule of thumb is that a color TV needs about 1 kV of acceleration voltage per diagonal inch. 43 kV is no joke when it comes to X-ray generation, so I'm curious if they found a way to make it work at a lower voltage.
At one point in the video you can see that the TV has two second-anode leads, so maybe that was the trick, using two separate acceleration electrodes at half the voltage.