Difference between revisions of "Sega G80"

From Sega Retro

(Removed Atari Asteroids and Lunar Lander references, as they don't in any way resemble what was done with the G80 system. There isn't a special Z80 chip; the CPU uses a standard Z80A along with a custom 40 pin security chip, which are not game specific.)
 
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{{ConsoleBob
 
{{ConsoleBob
 
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| logos=
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| consoleimage=G80 Arcade.jpg
| imgwidth=
 
 
| name=
 
| name=
 
| maker=[[Sega]]
 
| maker=[[Sega]]
 
| processor=[[Zilog Z80]]
 
| processor=[[Zilog Z80]]
| releases={{releases
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| releases={{releasesArcade
| arcade_date_world=1981-03
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| g80_date_us=1981-06{{fileref|ConvertaGames Arcade US Flyer.pdf|page=2}}
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| g80_date_jp=1981
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| g80_date_de=198x
 
}}
 
}}
 
}}
 
}}
The '''Sega G80''' is an [[arcade]] system produced by [[Sega]] in 1981. It can be considered a successor to the [[Sega VIC Dual]] system, and was Sega's arcade platform of choice before the release of the [[Sega System 1]].
+
The '''Sega G80''' is an [[arcade]] system produced by [[Sega]] in 1981. It can be considered a successor to the [[VIC Dual]] system, and was Sega's arcade platform of choice before the release of the [[Sega System 1]].
  
The G80 was designed to be a more versatile system than those seen in arcade cabinets of the past. Rather than rely on bespoke cabinet designs for each game, Sega opted for a more cost-effective "Convert-a-Game" system (as it was marketed in the US), in which games housed on CPU boards could be easily swapped by arcade operators. The G80 system consisted of a card cage with a 6 slot backplane that could be populated in different game configurations from a selection of 10+ different pluggable boards, allowing it to be configured it as either a raster system if a raster video board was inserted, or a vector system that could display color vector graphics.
+
The Sega G80 platform provided a basis for many reasonably successful vector-based games from the company, some of which, such as ''[[Space Fury]]'', ''[[Tac/Scan]]'', and, perhaps most famously, ''[[Star Trek: Strategic Operations Simulator]]'', saw home console/computer ports.
 +
 
 +
==Hardware==
 +
The G80 was designed to be a more versatile system than those seen in arcade cabinets of the past. Rather than rely on bespoke cabinet designs for each game, Sega opted for a more cost-effective "Convert-a-Game" system (as it was marketed in the US), in which games housed on CPU boards could be easily swapped by arcade operators. Announced at [[Visions '81]]{{magref|cb|1981-07-042|57}}, Sega's plan was to be able to cut install times down to 15 minutes, while also minimising production costs and tackling the poor resale value of used games{{magref|cb|1981-07-042|57}}. As a result, "ConvertaPaks" would cost less to buy than brand new cabinets{{magref|cb|1981-07-042|58}} (about $1,000 USD each{{fileref|ConvertaGames Arcade US Flyer.pdf|page=2}}, versus the $3,000 Sega estimated the average arcade game to cost in 1981{{fileref|ConvertaGame Arcade US Flyer.pdf|page=2}}).
 +
 
 +
The G80 system consists of a card cage with a 6 slot backplane that can be populated in different game configurations from a selection of 10+ different pluggable boards, allowing it to be configured as either a raster system if a raster video board is inserted, or a vector system that can display color vector graphics (or X/Y "Colorbeam" games, as Sega called them at the time).
 +
 
 +
The G80 gets its name from its Z80 CPU which was coupled with a custom security chip to prevent operators from abusing the swappable system.  The security chip would obfuscate the "ld (address),a" instruction (opcode 32h) differently based on the security chip installed — an early form of copy protection. The mangling algorithms are rather complicated, and differ from security chip to security chip.{{ref|[https://github.com/mamedev/mame/tree/master/src/mame/drivers/segag80r.cpp Sega G-80 raster hardware (MAME)]}}
  
The G80 gets its name from its Z80 CPU which was coupled with a custom security chip to prevent operators from abusing the swappable system.  The security chip would obfuscate the "ld (address),a" instruction (opcode 32h) differently based on the security chip installed — an early form of copy protection. The mangling algorithms are [https://github.com/mamedev/mame/blob/master/src/mame/machine/segag80.c rather complicated, and differ from security chip to security chip].
+
==History==
 +
''[[Space Odyssey]]'' was the first game to use the G80 system, followed by ''[[Space Fury]]''{{magref|cb|1981-07-042|57}}.
  
The Sega G80 platform provided a basis for many reasonably successful vector-based games from the company, some of which, such as ''[[Space Fury]]'', ''[[Tac/Scan]]'', and, perhaps most famously, ''[[Star Trek: Strategic Operations Simulator]]'', saw home console/computer ports.
+
For a while, Sega believed the "Convert-a-Game" concept was the future. [[David Rosen]] predicted that improvements in microprocessor technology would mean players would be constantly seeking new experiences, and as a result, arcade operators would have to keep changing their lineup of games; a business strategy that would not be economically viable if entirely new systems had to be purchased from manufacturers (who in turn relied on these new sales to stay in business){{magref|cb|1981-12-26|84}}.
 +
 
 +
At the time, Sega sold their products to a network of distributors in the US, who would then sell on to customers. By only selling boards rather than fully assembled cabinets, it was possible for Sega to bypass its distributors after the initial cabinet was sold. It was also noted that a fixed hardware specification could mean games designed for it would appear outdated within months, and thus be harder to sell.
 +
 
 +
Despite assurances from Sega that its current sales model would not change, and that the G80 board could be upgraded, it struggled to convince its distributors, and despite advocating its benefits across 1981 and 1982, found itself releasing games like ''[[Pengo]]'' and ''[[Zaxxon]]'' on bespoke hardware. ''Zaxxon'''s subsequent popularity would undermine the "Convert-a-Game" concept, with Sega's last G80 releasing in 1983.
 +
 
 +
Sega was not the first company to try and produce a reusable arcade system. In 1980, [[Data East]] released the [[wikipedia:DECO Cassette System|DECO Cassette System]] which would load games from compact cassette, however this system was prone to failure due to the mechanical nature of the system (and the potential for tapes to be demagentised).
 +
 
 +
In hindsight, Sega's analysis was correct, but its solution came to the market too early. Genuine arcade standards would arrive in the years which followed; the JAMMA specifications from 1985/1986 are built around the same idea of swappable arcade PCBs, but do not tie developers down to specific hardware (it is mainly the input and output connectors that are standardised instead, meaning the large cabinets could stay in place). The idea of "swappable games" never went away; [[Nintendo]] would see some success with their "VS" system in 1985, and by the 1990s, the reuse of hardware become necessary for arcade companies to survive, particularly when home consoles became the dominant form of playing video games.
  
==Technical Specifications==
+
==Technical specifications==
 
{{multicol|
 
{{multicol|
 
* Board composition: One board
 
* Board composition: One board
* Main [[wikipedia:Central processing unit|CPU]]:
+
* Main [[wikipedia:Central processing unit|CPU]]:{{intref|Sega G80 Hardware Reference (1997-10-25)}}
** [[wikipedia:Raster graphics|Raster]]: [[Zilog]] [[Z80]] @ 8 MHz (8-bit & 16-bit instructions @ 1.16 [[wikipedia:Instructions per second|MIPS]])
+
:* [[wikipedia:Raster graphics|Raster]]: [[Zilog]] [[Z80]] @ 8 MHz (8/16-bit instructions, 1.16 [[wikipedia:Instructions per second|MIPS]])
** [[wikipedia:Vector graphics|Vector]]: [[Zilog Z80]] @ 3.86712 MHz (8-bit & 16-bit instructions @ 0.561 MIPS)
+
:* [[wikipedia:Vector graphics|Vector]]: [[Zilog Z80]] @ 3.86712 MHz (8/16-bit instructions, 0.561 MIPS)
* [[wikipedia:Sound card|Sound boards]]: {{ref|https://github.com/mamedev/mame/tree/master/src/mame/drivers/segag80r.cpp}}
+
* [[wikipedia:Sound card|Sound boards]]:{{intref|Sega G80 Hardware Reference (1997-10-25)}}{{ref|[https://github.com/mamedev/mame/tree/master/src/mame/drivers/segag80r.cpp Sega G-80 raster hardware (MAME)]}}
** Sega USB (Universal Sound Board)
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:* Sega USB (Universal Sound Board){{magref|databus|0401|2}}
*** [[wikipedia:Microcontroller|MCU]]: [[wikipedia:Intel MCS-48|Intel i8035]] @ 3.12 MHz (8-bit instructions @ 3.12 MIPS, 1 [[wikipedia:Instructions per cycle|instruction per cycle]])
+
::* [[wikipedia:Microcontroller|MCU]]: [[Intel]] [[i8035]] @ 3.12 MHz (8-bit instructions, 3.12 MIPS, 1 [[wikipedia:Instructions per cycle|instruction per cycle]])
*** [[wikipedia:Sound chip|Sound chip]]: Sega Melody Generator ([[wikipedia:Programmable sound generator|programmable sound generator]])
+
::* [[wikipedia:Sound chip|Sound chip]]: Sega Melody Generator ([[wikipedia:Programmable sound generator|programmable sound generator]])
** Speech Board (optional)
+
:* Speech Board (optional)
*** MCU: [[wikipedia:Intel MCS-48|Intel i8035/i8039]] @ 3.12 MHz (8-bit instructions @ 3.12 MIPS)
+
::* MCU: [[Intel]] [[i8035]]/[[i8039]] @ 3.12 MHz (8-bit instructions, 3.12 MIPS)
*** [[wikipedia:Speech synthesis|Speech synthesizer]]: [[wikipedia:General Instrument SP0256|General Instrument SP0250]] ([[wikipedia:Linear predictive coding|linear predictive coding]])
+
::* [[wikipedia:Speech synthesis|Speech synthesizer]]: [[wikipedia:General Instrument SP0256|General Instrument SP0250]] ([[wikipedia:Linear predictive coding|linear predictive coding]])
** [[Sega System 1]] sound board (optional, used for ''Sindbad Mystery'' in 1983)  
+
:* [[Sega System 1]] sound board (optional, used for ''Sindbad Mystery'' in 1983)  
*** Sound chips: [[wikipedia:Texas Instruments SN76496|Sega SN76496]] @ 4 MHz, Sega SN76496 @ 2 MHz
+
::* Sound chips: Sega [[SN76496]] @ 4 MHz, Sega SN76496 @ 2 MHz
* [[wikipedia:Raster graphics|Raster]] [[wikipedia:Graphics card|graphics board]]: Sega Video I {{ref|https://github.com/mamedev/mame/tree/master/src/mame/drivers/segag80r.cpp}}
+
* [[wikipedia:Raster graphics|Raster]] [[wikipedia:Graphics card|graphics board]]: Sega Video I{{ref|[https://github.com/mamedev/mame/tree/master/src/mame/drivers/segag80r.cpp Sega G-80 raster hardware (MAME)]}}
** Raster [[wikipedia:Video display controller|display controller]]: Sega Raster Display Controller @ 15.468 MHz
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:* Raster [[wikipedia:Video display controller|display controller]]: Sega Raster Display Controller @ 15.468 MHz
** Video resolution:
+
:* Video resolution:
*** Horizontal: 256×224 (display), 328×262 (overscan)
+
::* Horizontal: 256×224 (display), 328×262 (overscan)
*** Vertical: 224×256 (display), 262×328 (overscan) {{ref|http://web.archive.org/web/20130104202105/mamedev.org/source/src/mame/video/segag80r.c.html}}
+
::* Vertical: 224×256 (display), 262×328 (overscan){{ref|[https://github.com/mamedev/mame/tree/master/src/mame/video/segag80r.cpp Sega G-80 raster video hardware (MAME)]}}
** [[Palette|Color palette]] [[wikipedia:Colour look-up table|table]]: 256 ([[wikipedia:8-bit color|8-bit RGB]] [[wikipedia:Programmable read-only memory|PROM]])
+
:* [[Palette|Color palette]] [[wikipedia:Colour look-up table|table]]: 256 ([[wikipedia:8-bit color|8-bit RGB]] [[wikipedia:Programmable read-only memory|PROM]])
** [[wikipedia:Color depth|Colors on screen]]: 64 to 128 ([[wikipedia:Video memory|palette RAM]])
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:* [[wikipedia:Color depth|Colors on screen]]: 64 to 128 ([[wikipedia:Video memory|palette RAM]])
** [[wikipedia:Tile engine|Tilemap]] planes: 2 layers, horizontal and vertical [[wikipedia:Scrolling|scrolling]],{{ref|http://web.archive.org/web/20130104202105/mamedev.org/source/src/mame/video/segag80r.c.html}} 8×8 tiles, 4 colors per tile
+
:* [[wikipedia:Tile engine|Tilemap]] planes: 2 layers, horizontal and vertical [[wikipedia:Scrolling|scrolling]],{{ref|[https://github.com/mamedev/mame/tree/master/src/mame/video/segag80r.cpp Sega G-80 raster video hardware (MAME)]}} 8×8 tiles, 4 colors per tile
** [[Sprite]] capabilities: 28 to 32 sprites per [[wikipedia:Scan line|scanline]], 224 to 256 [[wikipedia:Texel (graphics)|sprite pixels/texels]] per scanline, 4 colors per sprite, 8×8 to 16×16 sizes
+
:* [[Sprite]] capabilities: 28 to 32 sprites per [[wikipedia:Scan line|scanline]], 224 to 256 [[wikipedia:Texel (graphics)|sprite pixels/texels]] per scanline, 4 colors per sprite, 8×8 to 16×16 sizes{{intref|Sega G80 Hardware Reference (1997-10-25)}}
* [[wikipedia:Vector monitor|Vector display]] controller: Sega Display Controller
+
* [[wikipedia:Vector monitor|Vector display]] controller: Sega Display Controller{{ref|[https://github.com/mamedev/mame/tree/master/src/mame/drivers/segag80v.cpp Sega G-80 vector hardware (MAME)]}}
** [[wikipedia:Color depth|Color depth]]: 64 ([[wikipedia:List of monochrome and RGB palettes#6-bit RGB|6-bit RGB]]) {{ref|https://web.archive.org/web/20130104202114/mamedev.org/source/src/mame/video/segag80v.c.html}}
+
:* [[wikipedia:Color depth|Color depth]]: 64 ([[wikipedia:List of monochrome and RGB palettes#6-bit RGB|6-bit RGB]]){{ref|[https://github.com/mamedev/mame/tree/master/src/mame/video/segag80v.cpp Sega G-80 vector video hardware (MAME)]}}
* [[RAM]]: {{ref|https://github.com/mamedev/mame/blob/master/src/mame/drivers/segag80r.cpp}}
+
* [[RAM]]:{{intref|Sega G80 Hardware Reference (1997-10-25)}}{{ref|[https://github.com/mamedev/mame/tree/master/src/mame/drivers/segag80r.cpp Sega G-80 raster hardware (MAME)]}}
** Default: 10 [[Byte|KB]] (2 KB main, 8 KB [[VRAM|video]])
+
:* Raster: 14 [[Byte|KB]] (2 KB main, 8 KB [[VRAM|video]], 4 KB audio)
** ''Monster Bash'': 20 KB (4 KB main, 16 KB video)
+
:* Vector: 10 KB (2 KB main, 4 KB video, 4 KB audio)
** ''Sindbad Mystery'': 22 KB (4 KB main, 16 KB video, 2 KB sound)
+
:* ''Monster Bash'' & ''Sindbad Mystery'': 24 KB (4 KB main, 16 KB video, 4 KB audio)
 
}}
 
}}
  
==List of Games==
+
==List of games==
 
===Raster===
 
===Raster===
 
{{multicol|
 
{{multicol|
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* ''[[Zektor]]'' (1982)
 
* ''[[Zektor]]'' (1982)
 
}}
 
}}
 +
 +
==Promotional material==
 +
<gallery>
 +
ConvertaGame Arcade US Flyer.pdf|US flyer
 +
ConvertaGames Arcade US Flyer.pdf|US "New Games" flyer
 +
</gallery>
 +
 +
==References==
 +
<references/>
  
 
{{Sega Arcade Boards}}
 
{{Sega Arcade Boards}}
 
[[Category:Pre-System 1 arcade systems]]
 
[[Category:Pre-System 1 arcade systems]]

Latest revision as of 16:13, 15 May 2024

G80 Arcade.jpg
Sega G80
Manufacturer: Sega
Release Date RRP Code
Arcade (G80)
JP
¥? ?
Arcade (G80)
US
$? ?
Arcade (G80)
DE
? ?


































The Sega G80 is an arcade system produced by Sega in 1981. It can be considered a successor to the VIC Dual system, and was Sega's arcade platform of choice before the release of the Sega System 1.

The Sega G80 platform provided a basis for many reasonably successful vector-based games from the company, some of which, such as Space Fury, Tac/Scan, and, perhaps most famously, Star Trek: Strategic Operations Simulator, saw home console/computer ports.

Hardware

The G80 was designed to be a more versatile system than those seen in arcade cabinets of the past. Rather than rely on bespoke cabinet designs for each game, Sega opted for a more cost-effective "Convert-a-Game" system (as it was marketed in the US), in which games housed on CPU boards could be easily swapped by arcade operators. Announced at Visions '81[2], Sega's plan was to be able to cut install times down to 15 minutes, while also minimising production costs and tackling the poor resale value of used games[2]. As a result, "ConvertaPaks" would cost less to buy than brand new cabinets[3] (about $1,000 USD each[1], versus the $3,000 Sega estimated the average arcade game to cost in 1981[4]).

The G80 system consists of a card cage with a 6 slot backplane that can be populated in different game configurations from a selection of 10+ different pluggable boards, allowing it to be configured as either a raster system if a raster video board is inserted, or a vector system that can display color vector graphics (or X/Y "Colorbeam" games, as Sega called them at the time).

The G80 gets its name from its Z80 CPU which was coupled with a custom security chip to prevent operators from abusing the swappable system. The security chip would obfuscate the "ld (address),a" instruction (opcode 32h) differently based on the security chip installed — an early form of copy protection. The mangling algorithms are rather complicated, and differ from security chip to security chip.[5]

History

Space Odyssey was the first game to use the G80 system, followed by Space Fury[2].

For a while, Sega believed the "Convert-a-Game" concept was the future. David Rosen predicted that improvements in microprocessor technology would mean players would be constantly seeking new experiences, and as a result, arcade operators would have to keep changing their lineup of games; a business strategy that would not be economically viable if entirely new systems had to be purchased from manufacturers (who in turn relied on these new sales to stay in business)[6].

At the time, Sega sold their products to a network of distributors in the US, who would then sell on to customers. By only selling boards rather than fully assembled cabinets, it was possible for Sega to bypass its distributors after the initial cabinet was sold. It was also noted that a fixed hardware specification could mean games designed for it would appear outdated within months, and thus be harder to sell.

Despite assurances from Sega that its current sales model would not change, and that the G80 board could be upgraded, it struggled to convince its distributors, and despite advocating its benefits across 1981 and 1982, found itself releasing games like Pengo and Zaxxon on bespoke hardware. Zaxxon's subsequent popularity would undermine the "Convert-a-Game" concept, with Sega's last G80 releasing in 1983.

Sega was not the first company to try and produce a reusable arcade system. In 1980, Data East released the DECO Cassette System which would load games from compact cassette, however this system was prone to failure due to the mechanical nature of the system (and the potential for tapes to be demagentised).

In hindsight, Sega's analysis was correct, but its solution came to the market too early. Genuine arcade standards would arrive in the years which followed; the JAMMA specifications from 1985/1986 are built around the same idea of swappable arcade PCBs, but do not tie developers down to specific hardware (it is mainly the input and output connectors that are standardised instead, meaning the large cabinets could stay in place). The idea of "swappable games" never went away; Nintendo would see some success with their "VS" system in 1985, and by the 1990s, the reuse of hardware become necessary for arcade companies to survive, particularly when home consoles became the dominant form of playing video games.

Technical specifications

  • Board composition: One board
  • Main CPU:[7]
  • Sega USB (Universal Sound Board)[8]
  • Speech Board (optional)
  • Sega System 1 sound board (optional, used for Sindbad Mystery in 1983)
  • Sound chips: Sega SN76496 @ 4 MHz, Sega SN76496 @ 2 MHz
  • Horizontal: 256×224 (display), 328×262 (overscan)
  • Vertical: 224×256 (display), 262×328 (overscan)[9]
  • Raster: 14 KB (2 KB main, 8 KB video, 4 KB audio)
  • Vector: 10 KB (2 KB main, 4 KB video, 4 KB audio)
  • Monster Bash & Sindbad Mystery: 24 KB (4 KB main, 16 KB video, 4 KB audio)

List of games

Raster

Vector

Promotional material

References


Sega arcade boards
Originating in arcades









Console-based hardware








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