This article'slead sectionmay be too short to adequatelysummarize the key points. Please consider expanding the lead toprovide an accessible overview of all important aspects of the article.(June 2014)

TheVAXstation is a discontinued family ofworkstationcomputers developed and manufactured byDigital Equipment Corporation using processors implementing theVAXinstruction set architecture. VAXstation systems were typically shipped with either theOpenVMS orULTRIXoperating systems. Many members of the VAXstation family had correspondingMicroVAX variants, which primarily differ by the lack of graphics hardware.^[1]

TheVAXstation 100 is an intelligentgraphics terminal (also described as aDisplay subsystem) introduced by Digital in May 1983 for theVAX-11 line of computers.^[2] The VAXstation 100 was Digital's first workstation hardware for the VAX platform; the graphics terminal approach was selected due to the lack of availability of a VLSI VAX CPU necessary to create a standalone VAX workstation when the project began in 1981. The VAXstation 100's design was based on two internal research projects at Digital - a dedicated VAX workstation namedSUVAX (Single User VAX),^[3] and a project to portSmalltalk-80 to a VAX-11/780 equipped with a bitmap display, the latter being noted as having a greater influence on the finished product.^[2] Digital's literature suggested various configurations for the VAXstation 100, such as attaching multiple VAXstation 100s to a large VAX-11/78x system, or attaching a single one to a smaller system such as a VAX-11/725 to create a single user workstation.^[4]

The VAXstation 100 consisted of a desk-side unit housing aMotorola 68000 processor, a dedicatedbit blit accelerator built fromAMD 2901 logic, and a total of 640KB of RAM (128KB for the CPU, and a 512KB frame buffer). Attached to this unit was a 19" monochrome monitor, anLK201 keyboard, a mouse, and optionally a graphics tablet and five-button puck.^[4] The VAXstation 100 interfaced with the host VAX system over a fibre optic cable with a maximum length of 300 meters to a Unibus card named theUnibus Window Module.^[5] Application logic ran on the host's VAX CPU, and the code for displaying graphics ran on the VAXstation 100's processor.^[2] The VAXstation 100's processor was capable of directly accessing a 256KB window of the host system's memory, which was used to share data and commands between the host and the workstation.

Digital's official software for the VAXstation was theVAX Display Subsystem Software (VDSS) which was installed under VAX/VMS and provided a basic GUI environment for the VAXstation 100 with terminal emulation software.^[4] Custom GUI applications could be developed using theVAXstation Display Management Library (known as VSTA) and theVAXstation Core Graphics Library.^[6] Third-party interfaces were developed for the VAXstation 100, most notably, the earliest versions of theX Window System.^[7]

TheVAXstation 500 was a VAXstation system with color graphics, introduced in March 1985.^[3][8] It consisted of aMicroVAX I and aTektronix 4125 colour terminal.

TheVAXstation 520 was a follow-on to the VAXstation 500 which used a MicroVAX II as the host system instead of a MicroVAX I. At the time of its introduction in September 1985, a configuration with 2MB of memory, a 32MB hard disk and two 400KB floppy disk drives cost $40,790.^[9]

Introduced in October 1984, it was code named "Seahorse", and used theKD32 CPU module containing a 4 MHz (250 ns)MicroVAX I processor.^[1]

Code named "Mayflower", it used theKA630 CPU module containing a 5 MHz (200 ns)MicroVAX 78032 microprocessor. It was essentially aMicroVAX II in a workstation configuration.^[1]

A short-lived, lower-cost "Reduced Configuration" variant of the VAXstation II. Compared with the standard VAXstation II, a number of the slots on the backplane were filled with epoxy to limit the system's upgradability.^[10] It was discontinued when Digital discovered that enterprising customers were removing the epoxy, or replacing the backplane in order to convert the RC into a standard VAXstation II.^[11]

Introduced in December 1985, it was code named "Caylith", and was a variant of the VAXstation II with hardware-enhanced, high-performance color graphics.^[1]

Introduced in February 1987, it was code named "VAXstar" or"Kapri", and used theKA410 CPU module containing a 5 MHz MicroVAX II processor with no cache. It was essentially aMicroVAX 2000 in a workstation configuration.^[1]

Code named "PVAX", it used theKA42-A CPU module containing an 11.12 MHz (90 ns)CVAX microprocessor with a 64 KB external cache.^[1]

TheVT1300X terminal was essentially a diskless VAXstation 3100 Model 30, running theVAXELN operating system.^[12]

Code named "PVAX rev#7", it used theKA42-B CPU module containing a 16.67 MHz (60 ns) CVAX+ microprocessor with a 64KB external cache.^[1]

Code named "PVAX", it used theKA42-A CPU module containing an 11.12 MHz (90 ns) CVAX microprocessor with a 64KB external cache.^[1] It used the same CPU module and system board as the Model 30, but was housed in a larger case which could hold additional 5.25" and 3.5" drives.^[13]

Code named "PVAX rev#7", it used theKA42-B CPU module containing a 16.67 MHz (60 ns) CVAX+ microprocessor with a 64KB external cache.^[1]

Code named "RigelMAX", it used theKA43-A CPU module containing a 35.71 MHz (28 ns) Rigel microprocessor with a 128 KB external cache. It provided two separate SCSI buses, one for internal devices and one for external.^[1]

TheVXT 2000 was anX terminal using theSOC microprocessor. This system was essentially a VAXstation 3100 Model 30 without any mass storage and set up to network boot a VAXELN image that allowed it to be an X Window System terminal.

Code named "Mayfair/GPX", it used theKA650 CPU module containing a CVAX chip set operating at 11.12 MHz (90 ns cycle time) with 64 KB of external secondary cache.^[1] They differed by the enclosure used, the 3200 using a BA23,^[14] whereas the 3500 used the BA213.^[15] As such, they were effectively workstation configurations of theMicroVAX III^[16] andMicroVAX 3500 respectively.

TheVAXstation 3520 andVAXstation 3540, code named "Firefox", were multiprocessor computers with two or four CVAX chip sets respectively, contained onKA60 CPU modules running at 12.5 MHz (80 ns cycle time).^[1] They were based on the experimentalDEC Firefly multiprocessor workstation, and were positioned as mid-range workstations. The first official announcement from Digital regarding these workstations was on 10 January 1989, although it was a "programme announcement" with no dates or prices provided.

TheVAXstation 4000 VLC (Very Low Cost), aka VAXstation 4000 M30, was an entry-level workstation introduced on 30 October 1991.^[1] It was code named "PVAX2/VLC". It used theKA48 CPU module containing a 25 MHz (40 ns cycle time)SOC microprocessor. It had 8 to 24 MB of memory, using theMS40-BA SIMM, which was a low-height standard 72-pin 80 ns memory module with parity.

TheVAXstation 4000 Model 60, code named "PMariah",^[1] was announced on 30 October 1991 and became available on 25 November 1991. It used theKA46 CPU module containing a Mariah chip set operating at 55 MHz (18 ns cycle time) with 256 KB of external cache. It supported 8 to 104 MB of memory, with SIMMs installed in pairs. SIMMs used were the 4 MBMS44L-AA and the 16 MBMS44-DA, which both had parity. It was the first VAX system to use theTURBOchannel interconnect. The upgrade path was to the VAXstation 4000 Model 96.

TheVAXstation 4000 Model 90, code named "Cougar",^[1] was a further development of the VAXstation 4000 Model 60. Development of the VAXstation 4000 Model 90 began in mid-1991.

The workstation used the KA49-A CPU module containing aNVAX microprocessor operating at 74.43 MHz (14 ns cycle time) with a 256 KB external secondary cache. The NVAX had a 64-bit data bus to the NMC (NVAX Memory Controller) two gate array. The system module contained eight SIMM slots, and the workstation supported 16 to 128 MB of memory with parity. 16 MB MS44L-BC and 64 MB MS44-DC memory kits were used to populate the SIMM slots. Each memory kit contained four SIMMs with capacities of 4 MB and 16 MB respectively.

The VAXstation 4000 Model 90 supported 3D graphics hardware, the SPXg and SPXgt options. These modules had their own connector on the system module.

I/O was based around the NCA, a gate array which implemented an input/output adapter. The I/O subsystem had two independent 32-bit buses that communicated with the I/O and graphics options available. One of the buses interfaced to aTURBOchannel slot, the firmware contained within ROMs and the graphics options. The other bus interfaced to the Ethernet and EDAL controllers. EDAL was a 16-bit general-purpose bus for I/O. The EDAL controller consisted of a CEAC (CDAL-to-EDAL Chip) and a SQWF chip.

Ethernet was provided by the SGEC (Second-Generation Ethernet Controller) chip. SCSI was provided by the NCR 53C94, which connected to the EDAL bus. Serial lines were provided by a DC7085 quad UART. The four serial lines were used for the keyboard, mouse, modem and printer/console. A 64-entry FIFO queue was provided for all four serial lines and was implemented by a small external SRAM. Voice-quality sound was provided by an AMD Am79C30.

The VAXstation 4000 Model 90 could be upgraded to a VAXstation 4000 Model 96.

TheVAXstation 4000 Model 90A, code named "Cougar+",^[1] was a faster version of the Model 90. It used theKA49-A CPU module containing a NVAX microprocessor operating at 83 MHz (12 ns cycle time) but was otherwise the same. The upgrade path was to the VAXstation 4000 Model 96.

TheVAXstation 4000 Model 96, code named "Cougar++",^[1] was a faster version of the Model 90A. It was discontinued on 30 September 1999, with the last shipments concluding on 31 December 1999.^[17]

It used theKA49-C CPU module containing a NVAX microprocessor operating at 100 MHz (10 ns cycle time) but was otherwise the same.

TheVAXstation 8000, code named "Lynx",^[1] was a high-end workstation introduced on 2 February 1988. It was essentially aVAX 8250 packaged in a deskside enclosure with a 3D graphics pipeline developed jointly withEvans & Sutherland. It was the only VAXstation to use a Full VAX processor instead of a MicroVAX as its main CPU.

DTP software forVMS on the VAXstation includedInterleaf IWPS/IWPS-Plus,^[18] CGS Digi-Design/ORIS,^[19] DECwrite^[20] andWordPerfect.

Mechanical CAE software:Applicon Bravo (in 1988; with 3D-views),SDRC applications (incl.FEM pre- and postprocessing,I-DEAS),Prime GNC (GNC i.e. Graphical Numerical Control; aNumerical control application), MCS (Manufacturing & Consulting Services) ANVIL-5000,^[21] ISYKON (bought byIntergraph) Proren,^[22]EUCLID-IS,Unigraphics,^[23] andMEDUSA

• Michael A. Callander, Sr. et al., "The VAXstation 4000 Model 90". Digital Technical Journal, Volume 4, Number 3, Summer 1992. Digital Equipment Corporation.

• DEC workstations
• Computer-related introductions in 1984
• 32-bit computers

• Webarchive template wayback links
• Articles with short description
• Short description is different from Wikidata
• Wikipedia introduction cleanup from June 2014
• All pages needing cleanup
• Articles covered by WikiProject Wikify from June 2014
• All articles covered by WikiProject Wikify