An SDS 930 system consists of at least three standard cabinets, comprising the arithmetic and logic unit, at least 8,192 words magnetic-core memory, and the IO unit. Two's complement integer arithmetic is used. The machine has integer multiply and divide, but no floating-point hardware. An optional correlation and filtering unit can be added, which is capable of very fast floating-point multiply-add operations. Weighed about. A free-standing console is also provided, which includes binary displays of the machine's registers and switches to boot and debug programs. User input is by a Teletype Model 35 ASR unit and a high-speed paper-tape reader. Most systems include at least two magnetic-tape drives, operating at up to 75 in/s at 800 bpi. The normal variety of peripherals is also available, including magnetic-drum units, card readers and punches, and an extensive set of analog-digital/digital-analog conversion devices. A graphic display unit is also available, but it does not include a means of keyboard input. The SDS 930 is a typical small- to medium-scale scientific computer of the 1960s. Speed is good for its cost, but with an integer add time of 3.5 microseconds, it is not in the same league as the scientific workhorses of the day. A well equipped 930 can easily exceed 10 cabinets and require a climate-controlled room. The price of such a system in 1966 would be in the neighborhood of $500K. Programming languages available include FORTRAN II, ALGOL 60, and the assembly language known as Meta-Symbol. The FORTRAN system is very compact, having been designed and implemented by Digitek for SDS to compile and run in 4,096 word SDS 900 series machines. To do anything useful in such small memory space, the compiler relies on an SDS architectural feature known as Programmed OPeratorS, or POPS. This feature consists of a single bit in the instruction word that causes the machine to "mark place and branch" to the memory address of the instruction code value plus 100. As a result, pseudo instructions can be defined and implemented yielding very compact special-purpose code. Both the FORTRAN compiler and runtime take advantage of this capability. Towards the end of the SDS 930's market lifetime a real-time monitor system was introduced, which included a FORTRAN IV compiler. Neither the operating system nor the compiler were used heavily by customers. Many organizations modified and enhanced the 930's hardware. Project Genie at the University of California, Berkeley, added hardware to permit time-sharing with the Berkeley Timesharing System. These changes later formed the basis for the SDS 940. Other operating systems were also written for the machine by customers, including Arachnid at the University of Texas at Austin. SDS 930s could be found at most of the major US government labs at the time, including Los Alamos Scientific Laboratory. Early flight simulators used the SDS 930, because of its hardware integer multiply and divide capability and its real-time data acquisition and control peripheral modules. The machines are particularly well suited to this and other kinds of data acquisition and real-time analysis, as well as to serving as a digital control system for analog-hybrid systems. The Surface ShipASW Attack Trainer used a SDS 930 computer and was designed to train the ASW attack team of a US Navy destroyer in submarine warfare by providing realistic simulations ashore with cost savings in operating time and expense at sea. By 1974 estimates, there were about 200 SDS-930/940/945 computers still installed.