STD Bus
STD Bus is a computer bus popular with industrial control applications but has also been used in computing applications. The STD Bus has been called "STD-80" as well, this has created a popular confusion that the bus contains 80 pins, however its in reference to its bus being related to the Zilog Z80 series processors in practical use. The STD Bus stands for "Simple to Design", not "Standard" which is also another common confusion.
General Description
The STD Bus uses 6.5" by 4.5" cards with an edge connector with 56 pins. There are many different types of STD cards, from processing cards, RAM cards, I/O cards and specialized cards for various applications. There are prototyping cards available from Vector Electronics, and many PCB companies will produce cards with the proper edge connector.
The STD bus, although suffering a decline in use, as evident from the over 100 manufacturers of components in its peak, down to under a dozen today, is still used by hobbyists, manufacturers and in industrial applications.
One application which made a STD bus system more adaptable the then current computers of the mid-80s is the ability to use servo control cards along with a fully programmable computer to be used for mathematical work. One mention of this is the article written by Russell M. Genet and Douglass J. Sauer on the application of computers for astrophysics. In the article, it is mentioned that due to the then large industrial base of cards to control the observatory, and the systems expandability they are more desirable for use in a photometry lab to control the telescope as well as do the data logging and computations required. [1]
STD Bus Configuration
The STD Bus has a card edge connector of 56 pins. The pin configuration is as follows (Flow is relative using a STD Bus Processor Card)[2].
Pin | Mnemonic | Signal Flow | Description | Pin | Mnemonic | Signal Flow | Description |
---|---|---|---|---|---|---|---|
1 | +5V | In | Logic Power | 2 | +5V | In | Logic Power |
3 | GND | In | Logic Ground | 4 | GND | In | Logic Ground |
5 | -5V | In | Negative Logic Power | 6 | -5V | In | Negative Logic Power |
7 | D3 | In/Out | Data Bus | 8 | D7 | In/Out | Data Bus |
9 | D2 | In/Out | Data Bus | 10 | D6 | In/Out | Data Bus |
11 | D1 | In/Out | Data Bus | 12 | D5 | In/Out | Data Bus |
13 | D0 | In/Out | Data Bus | 14 | D4 | In/Out | Data Bus |
15 | A7 | Out | Address Bus | 16 | A15 | Out | Address Bus |
17 | A6 | Out | Address Bus | 18 | A14 | Out | Address Bus |
19 | A5 | Out | Address Bus | 20 | A13 | Out | Address Bus |
21 | A4 | Out | Address Bus | 22 | A12 | Out | Address Bus |
23 | A3 | Out | Address Bus | 24 | A11 | Out | Address Bus |
25 | A2 | Out | Address Bus | 26 | A10 | Out | Address Bus |
27 | A1 | Out | Address Bus | 28 | A9 | Out | Address Bus |
29 | A0 | Out | Address Bus | 30 | A8 | Out | Address Bus |
31 | WR | Out | Write to Memory or I/O | 32 | RD | Out | Read to Memory or I/O |
33 | IORQ | Out | I/O Address Select | 34 | MEMRQ | Out | Memory Address Select |
35 | IOEX | Out | I/O Expansion | 36 | MEMEX | Out | Memory Expansion |
37 | REFRESH | Out | Refresh Timing | 38 | MCSYNC | Out | CPU Machine Cycle Sync |
39 | STATUS 1 | Out | CPU Status | 40 | STATUS 0 | Out | CPU Status |
41 | BUSAK | Out | Bus Acknowledge | 42 | BUSRQ | In | Bus Request |
43 | INTAK | Out | Interrupt Acknowledge | 44 | INTRQ | In | Interrupt Request |
45 | WAITRQ | In | Wait Request | 46 | NMIRQ | In | Non-Maskable Interrupt |
47 | SYSRESET | Out | System Reset | 48 | PBRESET | In | Push Button Reset |
49 | CLK | Out | Clock from Processor | 50 | CNTRL | In | Aux Timing |
51 | PCO | Out | Priority Chain Out | 52 | PCI | In | Priority Chain In |
53 | AUX GND | In | AUX Ground | 54 | AUX GND | In | AUX Ground |
55 | AUX +12V | In | AUX Positive | 56 | AUX -12V | In | AUX Negative |
STD-32
The STD-32 is a pin compatible STD interface that allows the co-existence of both 8-bit and 32-bit systems on a single bus. This is accomplished by the addition of pins between the normal pins that do not connect, nor do they interfere with the original specification. This allows with the proper STD-32 backplane the ability to run legacy cards used for specific applications on the same bus without having to upgrade the complete system.