Difference between revisions of "KD11-EA CPU"

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Like the [[KD11-E CPU|KD11-E]], it also supported the KY11-LB Programmer's Console, including the maintainence functionality which allowed the CPU's microcode to be [[single-step]]ped.
 
Like the [[KD11-E CPU|KD11-E]], it also supported the KY11-LB Programmer's Console, including the maintainence functionality which allowed the CPU's microcode to be [[single-step]]ped.
  
The interface to the KY11-LB was carried over two 10-wire [[flat cable]]s connected to [[Berg connector]] headers (denominated J1 and J2) on the M8266 module. The [[pinout]] for P1 is the same as for the KD11-E; P2 has additional signals (other than uPC08) added in the KD11-EA, though:
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The interface to the KY11-LB was carried over two 10-wire [[flat cable]]s connected to [[Berg connector]] headers (denominated J1 and J2) on the M8266 module. The [[pinout]] for P1 is the same as for the KD11-E; P2 has additional signals (other than μPC08) added in the KD11-EA, though:
  
 
J2:
 
J2:

Revision as of 17:11, 9 January 2019

The KD11-EA CPU was the second CPU version for the PDP-11/34; it consisted of two hex printed circuit boards, the M8265 Data Paths module and the M8266 Control module.

It also supported the optional FP11-A floating point (FP11 floating point type) unit and/or the KK11-A cache (it could work with either, or both).

Apparently, the microcode address space was increased by one bit in the KD11-EA over the KD11-E, probably to support the extra microcode needed for the floating point instructions.

FP11-A/KK11-A installation

Adding either the FP11-A or KK11-A is fairly simple (provided there is adequate power available); they are plugged into the backplane slot next to the two CPU boards, and special over the top (OTT) connectors in the form of small PCB cards are used to connect them up.

(It is not clear why DEC adopted a design which used the OTT cards, although avoiding them would have required the more-expensive upgrade path of a new backplane; there may also not have been enough spare pins on the edge connectors.)

The KK11-A needs only an H8821 two-connector OTT card (40-pin connectors, although the ones used in the H8821 also have 2 blank pins on each end, i.e. the physical form is that of a 44-pin), which goes from the KK11-A to the M8265 card of the CPU.

The FP11-A needs both an H8821, and also the smaller 54-12416 two-connector OTT card, which goes from the M8266 card of the CPU to the FP11-A (28-pin connectors, although 2 pins on each end, and 4 in the centre, are blocked off).

If both an FP11-A and a KK11-A are plugged in, things become slightly more complex. The FP11-A has to be mounted in the slot next to the CPU boards, and the KK11-A has to be mounted in the second slot up from that one.

(The KY11-LB Programmer's Console is mounted in the slot in the middle; as far as is known, there is nothing special about that slot, and the KY11-LB could just have been moved over one slot, but DEC must have decided that the documentation would be simpler if it were always in the same slot.)

Instead of the two-connector H8821 OTT card, the very similar H8822 OTT card, with three connectors, must be used instead.

KY11-LB Interface

Like the KD11-E, it also supported the KY11-LB Programmer's Console, including the maintainence functionality which allowed the CPU's microcode to be single-stepped.

The interface to the KY11-LB was carried over two 10-wire flat cables connected to Berg connector headers (denominated J1 and J2) on the M8266 module. The pinout for P1 is the same as for the KD11-E; P2 has additional signals (other than μPC08) added in the KD11-EA, though:

J2:

  1. Micro-PC 08
  2. FP11-A Attached
  3. Unused
  4. Unused
  5. Unused
  6. Micro-PC 09
  7. Service Br Power Fail
  8. Load Instruction Register
  9. Power Fail Br Pending
  10. Unused

See also