- Source: Jupiter Ace
The Jupiter Ace by Jupiter Cantab was a British home computer released in 1982. The Ace differed from other microcomputers of the time in that its programming environment used Forth instead of the more popular BASIC. This difference, along with limited available software and poor character based graphic display, limited sales and the machine was not a success.
History
Jupiter Cantab was formed by Richard Altwasser and Steven Vickers. Both had been on the design team for the ZX Spectrum: Altwasser worked on ZX81 development and hardware design of the Spectrum. Vickers adapted and expanded the 4K ZX80 ROM to the 8K ZX81 ROM and wrote most of the ROM for the Spectrum.
The Jupiter Ace was named after an early British computer, the Pilot ACE, and went on sale on 22 September 1982 with a price of £89.95.
Sales to the general public were slow. Initially the computer was only available by mail order, and Jupiter Cantab reported that there were production difficulties, but these had been overcome by January 1983 and that units were arriving in shops.
The use of Forth rather than the more usual choice of BASIC, and the availability and success of the ZX Spectrum, as well as limited published software, the poor case and small initial memory all weighed against wider market acceptance. Eventually Jupiter Cantab ceased trading by the end of October 1983.
The brand was then acquired by Boldfield Computing Ltd in 1984 that sold the remaining stock by mail order for £26. The brand was again sold to Paul Andrews's company Andrews UK Limited in 2015.
= Sales
=Sales of the machine were never very large; the reported number of Aces sold before Jupiter Cantab closed for business was around 5,000. As of the early 2000s, surviving machines are uncommon, often fetching high prices as collector's items.
Forth, while being structured and powerful, was considered difficult to learn, and a knowledge of BASIC acquired from familiarity with other home computers was of no practical help in learning it. A 1982 review stated that "The success of the Jupiter Ace will depend on the machine-buying public's acceptance of another microcomputer language."
Further, there was only a very limited range of published software – either commercial programs or type-in programs printed in hobby magazines – for the machine, and these were restricted by the base model's small amount of RAM.
Attempts to promote the Ace in the educational market also failed; doubts over whether Forth would be relevant for exam syllabuses, and the lack of support for Forth from teaching staff were key issues. Pupils were more interested in learning the widely used BASIC than a language used by only one (uncommon) machine with a peculiar RPN syntax.
Finally, the tile-based graphics compared poorly to the pixel-based graphics of other machines – which were also colour rather than the Ace's monochrome. This restricted sales largely to a niche market of technical programming enthusiasts.
Design
The Jupiter Ace is often compared with ZX81 due to its similar size, low cost, and similar form factor. Internally its design is more similar to the ZX Spectrum although the Ace also had a dedicated video memory of 2 KB, partly avoiding the slow down when programs accessed the same bank (same chips) as the video memory. Like the Spectrum, the Ace used black conductive rubber keys although unlike the Spectrum, the keys had a conductive pad that was squashed directly onto tracks on the PCB rather than using a membrane. As a result, the keys would often stop working reliably until they were cleaned or the conductive material was refreshed.
Audio capabilities were CPU-controlled with programmable frequency and duration. Sound output was through a small built-in speaker.
As was common at the time, it used a common tape recorder instead of disk/tape drives. Similarly, a television was needed as a display – but this was in black and white only, rather than the colour supported by competing models such as the Spectrum. A secondary (undocumented) edge connector on the back of the case made some video signals available, presumably for a forthcoming colour video card, but no official product that used this connector was ever released.
The Jupiter Ace was based on the Zilog Z80, which the designers had previous experience of from working on the Sinclair ZX81 and ZX Spectrum.
Both graphics and text could be displayed at the same time: (1) redefinition of the character tiles provided standard 256×192 graphics limited to the 128 available (definable) 8×8 chars, concurrent with plotting of 64×48 graphics.
Internal speaker directly controlled by the CPU in single task mode, with control of sound frequency and duration in milliseconds.
Storage was through a cassette-tape interface at 1500 baud. Files could be used for either storage of Forth programs (compiled code) or raw dumps of memory.
= Memory
=The Ace had an 8 KB ROM containing the Forth kernel and operating system, and the predefined dictionary of Forth words in about 5 KB. The remaining 3 KB of ROM supported several functionalities: floating-point numbers library and character definitions table, tape recorder access, decompiling and redefining newly re-edited 'words' (i.e. routines). Some of the ROM was written in Z80 machine code, but some was also coded in Forth.
The next 8 KB was built in RAM that was only partially decoded, with 2 KB of video RAM echoed twice, and 1 KB of user RAM echoed 4 times (with the same memory appearing at several different memory addresses).
Using the lower-address mirror of the video RAM would select CPU priority, resulting in some momentary random pixels on the screen when video subsystem and the CPU accessed the video RAM in the same clock cycle. Using the higher-address would briefly pause the CPU on the interference, affecting the program timing and making this mode unsuitable for I/O operations. Since video RAM was partially separated from the main address and data busses, for the most part the video subsystem and the CPU could operate in parallel.
The first 16 KB of the memory map was used for ROM, Video and User-available RAM, leaving the second 16 KB of the memory map free for RAM extension and the topmost 32 KB undefined.
One 1K bank allowed redefinition of most of its 128 ASCII-based characters in 8×8 pixel bitmap format. The other 1K bank stored the full screen display of 24 rows × 32 columns of characters in black and white. Colour was intended to be achieved as expansion, but although a colour-graphics board was designed, none was ever produced commercially.
1 KB RAM with the option of a 16 KB RAM-Pack, and later a 32 KB one. A PCB was also marketed by Boldfield Computing that converted the edge connector to electrical compatibility with a Sinclair ZX81, allowing use of the ZX81 16K RAM pack.
= Specifications
=References to the Ace RAM sometimes include the separate 2 KB video memory, which was not available for programming, thus leading to some confusion. Similarly, it is sometimes argued that because of Forth's efficiency, the 1 KB standard RAM was in effect comparable to at least 2 KB on a BASIC system.
Programming
Its most distinctive characteristic was the choice of Forth, a structured language. Threaded compilation allowed programs written to run nearly as fast as many native-compiled languages loaded by more expensive computers. Forth was considered well-adapted to microcomputers with their small memory and relatively low-performance processors. Forth programs are memory-efficient; as they become bigger, they reuse more previously-defined code. Control structures could be nested to any level, limited only by available memory. This allowed complex programs to be implemented, even allowing recursive programming. The Ace's Forth was stated to be "ten times faster than Basic" and used less than half the memory (a significant cost percentage of low end computers of the time) of an equivalent program written in interpreted BASIC. It also allowed easy implementation of machine code routines if needed.
Ace's Forth was based mostly on Forth-79, with some relevant differences,: 176 in particular it added syntax checking to control structures and definer constructions and a few extra words were added based on common BASIC sound, video and tape commands. The implementation lacked some less frequently used Forth words, these being easily implemented if needed. Runtime error checking could be turned off to raise speed by 25% to 50%.: 171
= Decompiling
=Its Forth was adapted to the disk-less tape-using home computer hardware by being able to save/load user "compiled vocabularies", instead of the usual numbered programming blocks used by diskette systems.
Decompiling avoided wasting RAM in simulating an absent Block System, used with both disk and tape drivers (these last not to be confused with tape recorders). As replacement, it included an extra data file, for raw binary data. These solutions were unique to the Jupiter Ace.
= DEFINER vs COMPILER
=To allow decompile, it distinguished usual Forth definer and compiler words creation, replacing the CREATE .. DOES>, creation pair with:
DEFINER .... DOES> : Create new Defining words, usually used to define and build data structures. Similar to CREATE..DOES usage in standard FORTH.: 120 (Example: Adding Data Structures as Arrays, Records, ...).
COMPILER .. RUNS> : Create new Compiling words, less frequently used to extend the language with compiler words where CREATE..DOES> is FORTH implementation dependent.: 136 (Example: New Compiler Control Structures as Case, Infinite Loop, ...).
These two defining pairs, instead of one alone, allowed the Ace to decompile its programs, unlike usual Forth systems. This decompiling ability was a solution to the absence of the more flexible disk system used by Forth. Not storing the source of a Forth program, but compiling the code after editing, it avoided completely the emulation of a disk/tape drive on RAM saving computer memory. It also saved time in reading and writing programs from cassette tape. This tape-friendly and RAM-saving solution was unique to the Jupiter Ace Forth.
The names can be equivocal out of a Forth context, as all Words are compiled when declared.
DEFINER defines a new Class (as an array) that will build (compile) an array Object. These are active on 'Interpreter'. Pairing this Interaction mode, COMPILER defines a programming structure (usually a pair or a triplet) as IF-ELSE-THEN. These 'Structured Programming' are active on 'Compile' mode (which is simply building a new Forth Word). In short, "Interpreting mode" means Run stage, while "Compiling mode" refers to an Editing stage.
= Development
=Avoiding sources was compensated by storing comments entered in the code with the compiled output, traditional compilation would discard such comments. The comments were then recovered on decompiling. As a result of "code is the source", modified words (edited) would demand actualization of all code using the one newly edited. This was done with the non standard REDEFINE command.
Although not explicitly designed for such a purpose, the compiled Forth could be utilised for ROM extensions to the built in system. External ROMs were developed with Ace Forth to be used as control applications.
Add-ons
The machine was able to use some ZX81 add-ons due to similar RAM locations, and external expansion slot. Jupiter Cantab made a 16 KB RAM pack, and external companies made similar RAM packs as well as other peripherals and interfaces.
RAM packs
16 KB by Jupiter Cantab.
16 KB and 32 KB by Stonechip Electronics.
16 KB by Sinclair, with adaptor board from Jupiter Cantab for electrical compatibility.
48 KB by Boldfield (new Jupiter Ace owner after Jupiter Cantab).
Keyboard
Memotech Keyboard, by Memotech.
Sound
SoundBoard (1983) by Essex Micro Electronics,
Storage
Jet-Disc Disc Drive System (1983) by MPE (control up to four 3", 5", or 8" drives).
"Deep Thought" Disc interface with a 4K AceDOS in an EPROM (1986) by J Shepherd & S Leask.
Printer Adapters
ADS Centronics Interface Machine (1983), by Advanced Digital Systems,
RS232 & Centronics PrinterCard (1984) by Essex Micro Electronics.
It was possible to connect the Sinclair ZX Printer via an adaptor board and software.
Graphics Card
Gray Scale card – 4 shades of gray by S Leask (1986)
Models
= Jupiter Ace issue 1
=The original Jupiter Ace issue 1 was introduced in 1982, and came in a vacuum-drawn case. Reportedly 5000 units were produced.
= Jupiter Ace 4000
=The Jupiter Ace 4000 was introduced in 1983, and came on stronger injection-moulded case. Reportedly 800 units were produced.
Video game
There are 51 known commercially released video games for Jupiter Ace
See also
Other Forth-based microcomputers:
Hector HRX
Canon Cat
References
External links
Jupiter Ace Resource Site: The Jupiter Ace restoration and preservation project.
ACE-ROM-PROJECT: Latest ROM Docs E-Book(PDF) with restored ACE ROM (ZIP).
theregister.co.uk: The Jupiter Ace is 30, schematic (2012)
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