1953 NTSC Color Gamut

[pidade]

Quote:

Originally Posted by old_tv_nut

1) "dimmer, less saturated" is not a good blanket description. Green became yellower. Blue became more violet and saturated. Red became brighter but more orange and less saturated for a few years when sulfide red was used, then was restored to close to NTSC with rare earth reds.

2) Receivers adjusted the R-Y, B-Y, G-Y decoding, but not right away when the phosphors first changed. You can see the difference in successive RCA chassis. Electrical coding of the chroma was always per FCC, even for PAL transmission, which matrixed the R,G,B linear signals differently before gamma correction to R',G',B'.

3)The CTC-100 with 15GP22 is the only set guaranteed to have both NTSC decoding and NTSC phosphors. CTC5 and some successive RCA chassis have NTSC coding, but the phosphors may differ. 21AXP22 and 21CYP22 CRTS may have NTSC phosphors, but that needs to be measured to verify, because the introduction of sulfide blue is not clearly documented. Sets I saw at the Museum of Science and Industry in the late 50s had suspiciously violet blues and greenish yellows, which you would expect from a more-violet blue phosphor combined with NTSC decoding.

4) Yes it was very chaotic

5) I suspect that re-issued LIVE programs shot with TK-41 image orthicon cameras, such as the Dean Martin show, may not have been rematrixed in any way, and only had the chroma amplitude and phase adjusted.
Assuming no rematrixing:
The adjustments may have been made looking at a later non-NTSC monitor, but if there was no re-matrixing, receiver controls on a CT-100 could easily reverse any error. Later sets of the same vintage as the program or earlier will accurately reflect what those sets would have shown at the time.

6) Re-issued film programs, like Bonanza, that have been rescanned on later gear, are completely suspect as to whether they show the same color as the original broadcasts on the sets of the time. Subjectively, the color is probably much better because the newer scanners are much improved over the old Vidicon chains in terms of shading and color distortions caused by the Vidicon's nonlinearity.

Thanks for the reply.

I think you may have answered this in your third point, but did receivers *always* adjust decoding of NTSC signals for newer phosphors after the '60s, even in the '90s or '00s, or was it ever designed out of the standard, i.e. encoding directly for SMPTE-C, receivers decoding without assuming 1953 NTSC? It seems nonsensical that they would continue encoding for, really, a dead standard decades after the last full NTSC sets were produced, but then if they did alter the target, that would probably wreak havoc with receivers that adjusted decoding.

Also, is "R-Y, B-Y, G-Y" just the decoded R'G'B' in the receiver?

[old_tv_nut]

Quote:

Originally Posted by pidade

Thanks for the reply.

I think you may have answered this in your third point, but did receivers *always* adjust decoding of NTSC signals for newer phosphors after the '60s, even in the '90s or '00s, or was it ever designed out of the standard, i.e. encoding directly for SMPTE-C, receivers decoding without assuming 1953 NTSC? It seems nonsensical that they would continue encoding for, really, a dead standard decades after the last full NTSC sets were produced, but then if they did alter the target, that would probably wreak havoc with receivers that adjusted decoding.

Also, is "R-Y, B-Y, G-Y" just the decoded R'G'B' in the receiver?

Analog NTSC receivers continued to have modified decoding until the end.
The major decoding adjustment is increased R-Y gain to compensate for the excess of effective red content in the yellower green phosphor. Because the yellowish green was like having extra red whenever the green was turned on, it reduced the hue shift between red and green. The R-Y signal controls the balance of red in a given color, so increasing R-Y means that the difference in red as the transmitted hue changes is emphasized. This only works up to a point with the non-linear CRT and new phosphors, because 1) it can't really change the hue of the pure yellow-green phosphor when pure green is called for, and 2) it adds too much red on bright red colors.

R-Y, G-Y, and B-Y should really be all primed, e.g. R'-Y', because they are derived from R', G', and B' in the encoder, but the primes are usually omitted, just like they are for I and Q. They are the color difference signals that are derived from the chroma signal in the receiver, and can be obtained either by wideband IQ demodulation and matrixing or by equiband direct demodulation on the appropriate three different axes. These three color difference signals are then added to Y' in the receiver to get R', G', and B' drives for the picture tube. The CT-100 did the adding in external matrix circuits and then drove the 15GP22 grids. In many tube receivers that followed, the final addition was done in the picture tube by applying Y' to all three cathodes and R-Y, G-Y or B-Y to the appropriate grid (G1). Later tube designs that did not have separate grids required adding the Y' and color difference signals in the circuits before driving the picture tube cathodes.

R-Y, G-Y and B-Y are not independent, and any one can be derived from the other two, just as any one can be derived from I and Q. So some tube sets had R-Y and B-Y demodulators with a matrix for G-Y, a few had a different choice of the two axes and matrix, and a few had three separate demodulators and needed no matrix.

RCA chassis from CTC-7 onward for several years used a clever matrix that included DC restoration for the signals, but had some cross coupling between R-Y and B-Y outputs, so the demodulator axes were adjusted to compensate, and were called X and Z axes. The signals to drive the CRT grids then came out to be R-Y, G-Y and B-Y, but were adjusted further in later chassis to get approximate compensation for the newer phosphors, as discussed in previous posts.

[pidade]

Quote:

Originally Posted by old_tv_nut

Analog NTSC receivers continued to have modified decoding until the end.
The major decoding adjustment is increased R-Y gain to compensate for the excess of effective red content in the yellower green phosphor. Because the yellowish green was like having extra red whenever the green was turned on, it reduced the hue shift between red and green. The R-Y signal controls the balance of red in a given color, so increasing R-Y means that the difference in red as the transmitted hue changes is emphasized. This only works up to a point with the non-linear CRT and new phosphors, because 1) it can't really change the hue of the pure yellow-green phosphor when pure green is called for, and 2) it adds too much red on bright red colors.

R-Y, G-Y, and B-Y should really be all primed, e.g. R'-Y', because they are derived from R', G', and B' in the encoder, but the primes are usually omitted, just like they are for I and Q. They are the color difference signals that are derived from the chroma signal in the receiver, and can be obtained either by wideband IQ demodulation and matrixing or by equiband direct demodulation on the appropriate three different axes. These three color difference signals are then added to Y' in the receiver to get R', G', and B' drives for the picture tube. The CT-100 did the adding in external matrix circuits and then drove the 15GP22 grids. In many tube receivers that followed, the final addition was done in the picture tube by applying Y' to all three cathodes and R-Y, G-Y or B-Y to the appropriate grid (G1). Later tube designs that did not have separate grids required adding the Y' and color difference signals in the circuits before driving the picture tube cathodes.

R-Y, G-Y and B-Y are not independent, and any one can be derived from the other two, just as any one can be derived from I and Q. So some tube sets had R-Y and B-Y demodulators with a matrix for G-Y, a few had a different choice of the two axes and matrix, and a few had three separate demodulators and needed no matrix.

RCA chassis from CTC-7 onward for several years used a clever matrix that included DC restoration for the signals, but had some cross coupling between R-Y and B-Y outputs, so the demodulator axes were adjusted to compensate, and were called X and Z axes. The signals to drive the CRT grids then came out to be R-Y, G-Y and B-Y, but were adjusted further in later chassis to get approximate compensation for the newer phosphors, as discussed in previous posts.

Some fascinating reading in all of the engineering involved in analogue color TV, thanks for the insight. Literally couldn't find any information about modified NTSC decoding outside of a vague mention here or there in a couple ITU or SMPTE papers, though it seems kind of significant.

Was there ever a standard set for this modified decoding, considering the phosphors used were generally fairly consistent across different tubes from the '70s onwards? I also wonder how white balance affected it (FCC specified CIE Illuminant C, SMPTE specified D65, TV manufacturers generally went for ~D93). I found this 1969 patent, though it could just be one of many kinds of decoders (or unrelated).

[old_tv_nut]

Quote:

Originally Posted by pidade

... Literally couldn't find any information about modified NTSC decoding outside of a vague mention here or there in a couple ITU or SMPTE papers, though it seems kind of significant.

Was there ever a standard set for this modified decoding, considering the phosphors used were generally fairly consistent across different tubes from the '70s onwards? I also wonder how white balance affected it (FCC specified CIE Illuminant C, SMPTE specified D65, TV manufacturers generally went for ~D93).

Some papers on modified chroma decoding were published in the IEEE Transactioins on Broadcast and Television Receivers.

The SMPTE-recommended switchable matrix for monitors was the only standard one I know of. TV makers did their own thing, based on their own subjective views. One of the things that affected the TV makers decision was the decidedly cyan white balance of receivers for many years. The subjective effect of white balance is dependent on surround conditions, which vary greatly in the home. The effects are much smaller in a dark theater environment with a screen occupying much of your view.

Referring to it as D93 is incorrect, as the D series of daylight colors had not been established. It was labeled as 9300K + 27 mpcd. This means it coreesponds to a black body color at 9300K and an adjustment perpendicular to the black body locus towards blue-green by 27 minimum perceptible color differences. It really was Illuminant C with the red reduced, so it was off the daylight locus toward cyan. This was strictly a measure to reduce the ratio of red gun current to the other guns, as obtaining daylight color ran the risk of spot blooming in the red highlights. Professional monitors could get away with actual daylight white (and unequal beam currents) because they weren't intended to be searchlight-bright in a store showroom. Not all manufacturers used 9300K. One of Zenith's secrets was its specified white point, which was less blue than others. Some manufacturers (Mitsubishi large screen rear projectors in particular) maintained the extreme cyan white balance forever, even when most others were offering a customer choice of a cool or warm (at least not so blue) setting.