Friday, October 31, 2014

Console Upgrading Overkill

Sometimes, upgrades to a console are a good thing.  For example, I have no quarrel with flash carts.  Even though they were not period correct for the most part, the convenience of using one beats buying dozens and dozens of rare and expensive cartridges to play your favorite games.

I have no issue with repairs to a console, where feasible.  Some repairs, like recapping a Turbo Duo or replacing the CD lens of a Playstation SPCH-1001, are necessary to restore the console to working order.  Recapping a board may require a certain advanced level of skill, but it may be necessary to return the console to something as close to the out-of-the-box experience as possible.  For systems with ABS plastic yellowed by UV light, retr0bright and repainting may be the way to go.  I modded my precious Famicom AV, which I bought new in the box around 2003, to support a NES Zapper Light Gun in Controller Port 2.  The mod was simple, I only needed to solder two wires to connect the necessary bits from the 15-pin expansion port to the 2nd controller port.  You would not be able to tell the board had been modified unless you completely removed the PCB from the shell.

However, certain mods I am very uncomfortable with.  Modding a NES to display graphics above composite video quality is one of them.  The true Famicom and NES used the 2C02 PPU that generated NTSC composite color signals, mixing the brightness, hue and saturation signals inside the chip.  The video output is on one pin, making composite video the best video available from the chip.  (S-video would require two pins). For the original Famicom and NES Top Loader, RF was officially the only output available.  Composite video was available from the NES Front Loader and Famicom AV.

The 2C02 PPU has an official RGB variant called the 2C03 PPU which was used in the Playchoice-10 arcade machine and an identically functioning 2C05 PPU used in the Sharp Famicom Titler.  You can replace a 2C02 with a 2C03 in a Famicom or NES, but desoldering the chip is not for beginners.  The 2C03s are hard to come by and extremely expensive.  However, the 2C03 PPU is not 100% compatible with its composite brother.  Two of the grays in the composite PPU are missing from the RGB PPU, which will render them as black, resulting in a loss of detail in games that use them.  Colors will look a bit off and rather garish compared to the composite PPU.  Second, The Immortal, James Bond Jr., Just Breed, Magician, The Jungle Book, the Lion King, Noah's Ark and Felix the Cat use the color emphasis bits to darken the entire screen with a composite PPU, but with an RGB PPU, these games will show a totally white screen, making them completely unplayable.  (Just Breed is one of the very few Japanese games to use color emphasis throughout the game, so the issue is not as pronounced for Japanese games.)  A few other games, Final Fantasy 1 and 2, Super Spy Hunter and The Fantastic Adventures of Dizzy, use color emphasis for minor effects that do not affect gameplay.  The Titler converts RGB into S-Video, it doesn't output RGB natively but can do so without too much trouble.  Now there is one caveat to the rule that NES games should always use composite video.  It would seem likely that Nintendo's in-house development hardware may have used 2C03 PPU.

Today there is a modification board called the NESRGB.  This is a daughterboard which you mount the PPU into (after desoldering it from the NES mainboard).  The FPGA on the NESRGB monitors PPU accesses, take information from the palette registers and combines them with the video output signal to digitally convert the color into RGB.  This mod has the huge advantages of not requiring a rare 2C03 and does not perform an imprecise analog composite to RGB conversion like the French NES.  Unfortunately, the mod is more difficult than the 2C03 mod because you must save the 2C02 PPU.

Kevin Horton (kevtris) and Jason over at Game-Tech.us are deep in development of a Hi-Def NES mod that installs similarly to the NESRGB.  However, it outputs to an HDMI cable at 720p or 1080p.  It also emulates the NES and expansion audio channels, because they cannot be captured digitally like the video can.  It can also apply smoothing scalers and scanline filters.

If you don't want to mod your NES, then you could consider the Super 8-bit Video Game System :  https://www.tindie.com/products/low_budget/super-8-bit-console-with-new-v30-pcb/
At $499.00, it will hit the wallet really hard.  Its case is made out of aluminum and it supports RGB, S-Video, composite video and stereo sound.  It uses 2A03s and 2C02s reclaimed from Nintendo machines but the PCB is a custom design and the rest of the components are new.  It has a NESRGB board built in. It has two NES controller ports properly spaced for the four player adapters and a Famicom expansion port.  The latest revision of the PCB also supports the Famicom microphone, something not implemented elsewhere outside an original Famicom.

Bunnyboy of NES PowerPak fame has been devolping an HDMI NES.  This is a complete clone, and should be far more accurate than the typical Taiwanese System-on-a-Chip designs.  However, the hardware that will emulate the NES is far, far more powerful than the NES, so I ask how different is it than running a NES emulator and outputting it to a TV?  One advantage will be that there will be less, if any input lag to deal with from reading the controllers or having the LCD interpolate the standard definition frame, since the system will output in 720p/60fps.  The picture will be sharp as it can be on modern LCD TVs, hopefully the device will be able to get all the PPU and APU quirks right.

Another unnecessary NES mod is the so-called stereo sound mod.  The 2A03 CPU contains an Audio Processing Unit that outputs audio on two pins.  One pin contains the two pulse wave channels and triangle wave channel, the second pin contains the noise and PCM channel.  These can be split into separate outputs easy enough, but the NES was not designed for stereo sound.  Most games use the pulse and triangle waves for music and the noise and PCM for percussion and sound effects.  I think the resulting sound is very unbalanced toward the waveform output.  Earlier games tended not to use the PCM channel, so the output for it and noise would sound very quiet.

On the other hand, modding the original Famicom or Top Loader NES to output composite video is a worthy endeavor.  The Famicom was RF only, and the Japanese RF channels are well-nigh impossible to turn perfectly to US TVs.  Composite video is universal in NTSC countries, RF is not.  When the Famicom was released, the Sharp My Computer C1 TV was also released and it used an internal composite video connection.  Gaming magazines would take their screenshots from this TV because of the improved picture quality.  The video output quality of a standard Top Loader NES is comparative garbage, but it can be brought into line with the Front Loader NES and Famicom AV with a mod.  The Sega Master System Model 1 has composite and RGB output at its DIN, but the Model 2 has RF only and requires a mod to support either.

When you upgrade to the 4th and 5th generation systems, then RGB becomes available for all of them, many via a modification, but the original SNES, Playstation, NeoGeo, Atari Jaguar, Phillips CD-i, the Sega Master System, Sega Genesis Models 1 and 2, Sega Saturn and Dreamcast offer it on their AV connector.  The N64, Turbo Grafx, CD-i and 3D0 can be modified to support it, one way or another.  For those of us in the United States, true analog 15kHz RGB monitors were rare.  Component video is the closest substitute, but RGB to Component video conversion requires a converter box.  RGB is pushing it, especially with the Genesis.  The Genesis was known to use dithering that NTSC resolution and decoding would not completely resolve, but would look extremely pixelated on an RGB system.  The SNES games can also take advantage of the fuzziness of composite video when dithering.  The early 3D consoles like the N64 and Playstation tend to take advantage of the natural anti-aliasing effect that composite video can produce.  Viewing these consoles in RGB, where most of their 3D is in a low resolution form, shows sharp jaggies.

One last issue I want to address is how many people enjoyed RGB when these consoles were the current generation?  RGB, even in Japanese (JP-21 connector) and European TVs (SCART connector) was strictly high end in the 1990s.  The main TV may have had a connection in the more affulent homes, but many video game consoles tended to be relegated to the second TV.  Hours of video game playing tended to tie up the main TV, so parents tended to insist that a video game system be connected to another TV.  The second TV would be lucky to have composite video, and many people didn't know better and simply used their RF switch.

7 comments:

  1. I was thinking of paying to have my front-load NES modded with the NESRGB board, but then I thought about it and realized that I was keeping the hardware around to show to my two-year old daughter what I had when I was a kid.

    Modding it wouldn't really be showing the genuine experience, so I decided against it.

    I did go through the trouble of finding a second-generation SNES for the (supposed) improvement in picture quality, but I was stupid enough to sell my first-gen, so I don't even know if there's a difference!

    Excellent article, as usual. Everything I've read here is always an interesting read.

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  2. Here in France during the mid 80s, no single TV didn't have SCART (read RGB), it was de facto. Rather what was rare and did not appear until the 90s was the front composite cinch, mainly for cameras as they are essentially using this socket. Now since true RGB SCARTs were the norm, cinch was available from it through the means of an adapter. What was sought in those type of TVs is more the SVHS socket :D which was quite rare since it was on selected models. Regarding the NES you can get a pretty good RGB output by buying a French model, they were exclusively using SCART as the output. You can fit that internal adapter in a US model, relatively easily. If you ever buy one off eBay or price minister, make sure you get the cable with it !

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  3. To further comment your post, having more than 1 TV in the 80s wasn't very common here, comparatively to the US. Later, though in the 90s it was pretty much the norm :D Also regarding the NES, it is indeed RGB and not a cinch/fake through SCART. While you can visually confirm that with the crispness, two things further confirms that : the tv switches to AV thanks to the 5v signal sent by the RGB device, and trying to record the NES with a VCR produced a black image. AFAIK a composite device/signal would not exhibit such behavior.

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  4. Raifield :

    Regarding the 1-chip SNES, the later revision people seem to want, its overrated. I would rather have a slightly softer picture than the graphical glitches and graphics and audio slowdowns identified here :
    http://www.racketboy.com/forum/viewtopic.php?f=52&t=46303

    Aybe :

    The French NES converts composite video to RGB. The PPU inside it is the same 2C07 PAL PPU used in every PAL country. There is a special converter chip in the shielded box that converts composite video to RGB. It should have many of the flaws of composite video and its not true RGB output. Only the Famicom Titler has true (via a mod) RGB output.

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  5. Great Hierophant:

    The Famicom Titler is clearly the purist choice but the entry price is a major stopper, though :D

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  6. You forgot to mention the rather popular and easy NES mod of connecting expansion audio on the expansion connector to the cart bus for Famicom sound chip support with the Everdrive and Powerpak. Normally this is a 47k resistor connected between pins 3 and 9 of the expansion port under the NES. My NES uses a grounded 10k audio pot instead for adjustable output.

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