With support for multicolor sprites and a custom chip for waveform generation, the C64 could create superior visuals and audio compared to systems without such custom hardware.
The C64 dominated the low-end computer market (except in the UK and Japan, lasting only about six months in Japan[7]) for most of the later years of the 1980s.[8] For a substantial period (1983–1986), the C64 had between 30% and 40% share of the US market and two million units sold per year,
In the UK market, the C64 faced competition from the BBC Micro, the ZX Spectrum, and later the Amstrad CPC 464.[11] but the C64 was still the second most popular computer in the UK after the ZX Spectrum.[12] The Commodore 64 failed to make any impact in Japan. The Japanese market was dominated by Japanese computers, such as the NEC PC-8801, Sharp X1, Fujitsu FM-7, and MSX.[13]
Part of the Commodore 64's success was its sale in regular retail stores instead of only electronics or computer hobbyist specialty stores.
One computer gaming executive stated that the Nintendo Entertainment System's enormous popularity – seven million sold in 1988, almost as many as the number of C64s sold in its first five years – had stopped the C64's growth. Trip Hawkins reinforced that sentiment, stating that Nintendo was "the last hurrah of the 8-bit world".[57]
In January 1981, MOS Technology, Inc., Commodore's integrated circuit design subsidiary, initiated a project to design the graphic and audio chips for a next-generation video game console. Design work for the chips, named
“Commodore has always paid lip service to software,” Charpentier said. “They do enough to get by and then rely on outside sources to fill the gap. Commodore was an extension of Jack Tramiel, and to him software wasn’t tangible—you couldn’t hold it, feel it, or touch it—so it wasn’t worth spending money for.”
What is next? 16/32-Bit but which one? (- Macintosh) - Atari ST? (like C64) - Amiga (Multimedimaschine) expensive - Amiga 500 - Sinclair 68000 - Archimedes? (- NEXT very expensive!)
The Tandy Color Computer was the runner up. The Apple II was the winner in the category of home computer over $500, which was the category the Commodore 64 was in when it was first released at the price of $595.
n the United States, the greatest competitors were the Atari 8-bit 400, the Atari 800, and the Apple II. The Atari 400 and 800 had been designed to accommodate previously stringent FCC emissions requirements and so were expensive to manufacture. Though similar in specifications, the C64 and Apple II represented differing design philosophies; as an open architecture system, upgrade capability for the Apple II was granted by internal expansion slots, whereas the C64's comparatively closed architecture had only a single external ROM cartridge port for bus expansion.
Aggressive pricing of the C64 is considered to have been a major catalyst in the video game crash of 1983.
The price war with Texas Instruments was seen as a personal battle for Commodore president Jack Tramiel.[25] Commodore dropped the C64's list price by $200 within two months of its release.[6] I
Meanwhile, TI lost money by selling the TI-99/4A for $99.[26] TI's subsequent demise in the home computer industry in October 1983 was seen as revenge for TI's tactics in the electronic calculator market in the mid-1970s, when Commodore was almost bankrupted by TI.[27]
Although many early C64 games were inferior Atari 8-bit ports, by late 1983, the growing installed base caused developers to create new software with better graphics and sound.[34]
Subject: 'Re: VIC-II colors' From: Robert 'Bob' Yannes To: Philip 'Pepto' Timmermann Date: 27.09.1999 I was involved with the development of the VIC-II, however the actual implementation of the design, including the Color Palette, was done by someone else. I have forwarded your message to him, but it is up to him if he wants to respond. I can tell you that the design was based on the principle that adding a sine wave of a particular frequency and amplitude to an inverted version of the same sine wave at a different amplitude produces a phase-shifted sine wave of the same frequency. The amount of phase shift is directly proportional to the amplitudes of the two sine waves. The VIC-II used the 14.31818 MHz master clock input (4 times the NTSC color burst frequency of 3.579545 MHz) to produce quadrature square-wave clocks. These clock signals were then integrated into triangle waves sing analog integrators. The triangle waves were then integrated again into sine waves (actually rounded triangle waves, but good enough for this application). This produced a 3.579545 MHz sine wave, inverse sine wave, cosine wave and inverse cosine wave. An analog summer was used to create the phase-shifts in the Chroma signal by adding together the appropiate two waveforms at the appropiate amplitudes. The Color Palette data went to a look-up table that specified the amplitude of the waves by selecting different resistors in the gain path of the summer. The end result was that we could create any hue we wanted by looking at the NTSC color wheel to determine the phase-shift and then picking the appropiate resistor values to produce that phase-shift. Color Saturation was controlled by scaling the gain of the summer. When we picked the resistor values to determine the output phase-shift, we also scaled them to produce the desired output amplitude. Luminance was controlled using a simple voltage divider which switched different pull-down resistors into the open-drain output. We could create any Luminance we wanted by choosing the desired resistor value. I'm afraid that not nearly as much effort went into the color selection as you think. Since we had total control over hue, saturation and luminance, we picked colors that we liked. In order to save space on the chip, though, many of the colors were simply the opposite side of the color wheel from ones that we picked. This allowed us to reuse the existing resistor values, rather than having a completely unique set for each color I believe that Commodore actually got a patent on this technique. It was certainly superior to the Apple or Atari approach at the time, as they ended up with whatever colors that came out--ours allowed the designer to freely select Hue, Saturation and Luminance. Since all of this was based on selecting different resistor values and resistance varied from chip lot to chip lot, there was variation from one Commodore 64 to another. It wasn't as bad as it could have been though, since all of the Chrominance selection was based on resistor ratios, which could be kept constant even if the actual resistor values varied. Luminance was more of a problem. A trimmer resistor should really have been used to pull up the output. This would have allowed the Luminance to be adjusted for consistency from unit to unit, however Commodore didn't care enough about consistency to bother with adjusting each unit Robert 'Bob' Yannes
IN JANUARY 1981, a handful of semiconductor engineers at MOS Technology in West Chester, Pa., a subsidiary of Commodore International Ltd., began designing a graphics chip and a sound chip to sell to whoever wanted to make “the world’s best video game.”
Instead, he decided, the chips would go into a 64-kilobyte home computer to be introduced at the Consumer Electronics Show in Las Vegas the second week of January 1982. The computer had yet to be designed, but that was easily remedied.
The MOS designers freely borrowed ideas that they liked—sprites from the TI machine, collision-detection techniques and character-mapped graphics from the Intellivision, and a bit map from their own VIC-20. They then packed as many of those ideas as they could into a predefined area of silicon.
In November 1981, the chips were complete. The original intent had been a game machine, but at this point the personal-computer market was beginning to look promising.
The technical limitation on the C64 Keyboard hardware is that not more than 2 keys may be pressed at the same time if you want to be 100% sure the result is valid. In some cases, three keys will work fine but whenever 3 keys form a right angle in the keyboard scan matrix, a 4th letter will appear. The combination “ABC” will work fine but the combination “ASD” will form such a triangle and the matrix will also report that the “F” key is pressed. Same goes for “ASF” which would incorrectly read a “D” the same way.
In short, the C64 keyboard is not a piano where you can play choords and stuff.
Commodore 64
With support for multicolor sprites and a custom chip for waveform generation, the C64 could create superior visuals and audio compared to systems without such custom hardware.The C64 dominated the low-end computer market (except in the UK and Japan, last
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The Ultimate Commodore 64 Talk
The successor decision (8bit > 16bit): ATARI ST or Amiga
Whats next? Big Question after the end of C64 - new maschines!
(- Macintosh)
- Atari ST? (like C64)
- Amiga (Multimedimaschine) expensive - Amiga 500
- Sinclair 68000
- Archimedes?
(- NEXT very expensive!)
.
.
Computerclubs
Datasette
C64-Assembler-Dev
Market WAR
C64 Sprites 8 and extended (like in the atari 2600)
Sprite multiplexer C64
Visual style with the same color-palette 16 colors
C64 - Colorpalette - Inbetween Picked, Cheap and transistors (luminance)
'Re: VIC-II colors'
From: Robert 'Bob' Yannes
To: Philip
'Pepto' Timmermann
Date: 27.09.1999
I was involved with the development of the VIC-II, however the actual implementation of the design, including the Color
Palette, was done by someone else. I have forwarded your message to him, but it is up to him if he wants to respond.
I can tell you that the design was based on the principle that adding a sine wave of a particular frequency and amplitude
to an inverted version of the same sine wave at a different amplitude produces a phase-shifted sine wave of the same
frequency. The amount of phase shift is directly proportional to the amplitudes of the two sine waves.
The VIC-II used the 14.31818 MHz master clock input (4 times the NTSC color burst frequency of 3.579545 MHz) to produce
quadrature square-wave clocks. These clock signals were then integrated into triangle waves sing analog integrators. The
triangle waves were then integrated again into sine waves (actually rounded triangle waves, but good enough for this
application). This produced a 3.579545 MHz sine wave,
inverse sine wave, cosine wave and inverse cosine wave.
An analog summer was used to create the phase-shifts in the Chroma signal by adding together the appropiate two waveforms
at the appropiate amplitudes. The Color Palette data went to a look-up table that specified the amplitude of the waves by
selecting different resistors in the gain path of the summer. The end result was that we could create any hue we wanted by
looking at the NTSC color wheel to determine the phase-shift and then picking the appropiate resistor values to produce
that phase-shift.
Color Saturation was controlled by scaling the gain of the summer. When we picked the resistor values to determine the
output phase-shift, we also scaled them to produce the desired output amplitude. Luminance was controlled using a simple
voltage divider which switched different pull-down resistors into the open-drain output. We could create any Luminance we
wanted by choosing the desired resistor value.
I'm afraid that not nearly as much effort went into the color selection as you think. Since we had total control over hue,
saturation and luminance, we picked colors that we liked. In order to save space on the chip, though, many of the colors
were simply the opposite side of the color wheel from ones that we picked. This allowed us to reuse the existing resistor
values,
rather than having a completely unique set for each color
I believe that Commodore actually got a patent on this technique. It was certainly superior to the Apple or Atari approach
at the time, as they ended up with whatever colors that came out--ours allowed the designer to freely select Hue,
Saturation and Luminance.
Since all of this was based on selecting different resistor values and resistance varied from chip lot to chip lot, there
was variation from one Commodore 64 to another. It wasn't as bad as it could have been though, since all of the Chrominance
selection was based on resistor ratios, which could be kept constant even if the actual resistor values varied. Luminance
was more of a problem. A trimmer resistor should really have been used to pull up the output. This would have allowed the
Luminance to be adjusted for consistency from unit to unit, however Commodore didn't care enough about consistency to
bother with adjusting each unit
Robert
'Bob'
Yannes
Videoram 8bit
.
Raster
NoAccess
C64 Raster Example - different graphic modes on one screen
Magic of programming
Toyballs C64, 1992
Videoram 8bit
DevToday
CBM prg studio - integrated develoment tool c64
homecomputer 16-bit 1985+
Atari ST (Atari) 16/32Bit 1985 - 1995
Amiga (Commodore) 16/32Bit 1985 - 1994
Magic of computers
c64 basic
c64 c
gamedesign c64
.
c64 hardware development
CREATING THE COMMODORE 64: THE ENGINEERS’ STORY
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Tramiel, Jack
MOS Technology
“We looked heavily into the Mattel Intellivision,” recalls Winterble.
Intellivision The Intellivision is a home video game console test marketed by Mattel Electronics in 1979, and officially released in 1980. The name is a portmanteau of 'intelligent television'. Development began in 1977, the same year as the launch of its
The MOS designers freely borrowed ideas that they liked—sprites from the TI machine, collision-detection techniques and character-mapped graphics from the Intellivision, and a bit map from their own VIC-20. They then packed as many of those ideas as the
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aquarius intellivision (computer by intellivsion)
Spectravideo
.
coding media (books)
Keyboard C64
Scanning the Keyboard the correct and non-KERNAL way
Intellivsion
abstract vs analog settings (why? wanna be meaningful)
'C64 eine 8bit Consolencomputer auf Steroiden'
6502 assembler on the web
8-bit gamedesign
c64 demoscene today
c64 experimental archeologie - new games
Kleinert, Tim (Swiss Muscian, C64)
c64 sound/music - SID music
Robox
Akropolis C64 1988
warriors c64 1988 (not published, rainbow)
graphic design c64
design: videoconsole
VICE - the Versatile Commodore Emulator
input 64 1964+
gamedev tools
S.E.U.C.K. Shoot Em Up Construction Kit 1987 C64/Atari ST/Amiga