KT11-B Technical Manual

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As a Special Systems Option, the KT11-B does not have the usual DEC Technical Manual. This page attempts to provide at least the high-level portions of such a manual.

Note:: The KT11-B theory of operation (either from the page above, or the Option Description manual), must be thoroughly understood before trying to read this page. In particular, register names must be known, as well as the function of high-level internal entities such as the associative memory and the scratchpad memory.

Prints

The Engineering Drawings for the KT11-B (7605071) include the following logic prints:

Number Page Count Content
2 2 Address Bus and Control Logic
3 1 State Control Logic
4 1 SP Input Mux
5 2 Associative Memory Control
6 1 Scratch Pad and State Control Logic
7 3 Data Bus and Control Logic
8 1 Keys and Associative Memory
9 1 XP Option for KT11 Associative Memory Control
10 1 PGM Register
11 1 PGC Register
12 1 Timing Logic
13 1 Buffered Signals and Main Logic
14 1 Extended Associative Memory
15 1 KA11 to KT11 Interface
17 1 KT11-B Bus Connectors

The KT11-B is not composed of discrete boards, but rather a large number of mostly small FLIP CHIPs, so the division into drawings, some of which are multi-sheet (as opposed to them all being single-sheet) is a bit arbitrary. It is probably intended to align the drawings with the high-level internal structure.

References to drawing pages are given as 'x-y', where 'x' the drawing number, and 'y' is the individual sheet.

Drawing Conventions

The drawings are somewhat easier to understand if the conventions used in the drawings are understood. Although no document lists them, they can be ascertained by study of the drawings.

Signal Names

Signal names in this drawing set usually start with 'Dxx', where 'xx' is related to the drawing number (given in the table above). (This is similar to the convention in the KA11 drawings, where 'Kxx-y' means that the signal originates on page y of drawing xx.) Note that the 'Dxx' correspondence seems to sometimes be off by one; i.e. a signal tagged 'D04' can be found originating on drawing 05.

In signal names of the form 'XXX (yy)', 'yy' is a bit number (in standard PDP-11 order) in a register or bus. For signals which are provided in both asserted low and asserted high forms, one will see signal names of the form 'XXX (y)', where 'y' is 1 or 0. Note that sometimes these two notations are combined, and one can find signal names of the form 'XXX (yy) (z)'. Inverted (asserted low) signals are also sometimes shown as '-XXX'.

The following specific signal names have the meaning given:

  • Signals of the form 'x.y' are states, with 'x' being the major state, and 'y' being the minor state.
  • Signal names starting with 'SP' refer to the scratchpad memory, which holds both cache page table entries, as well as some KT11-B registers; SPIN is its input bus, and SPDA is its output bus.
  • Signal names starting with 'AM' refer to the associative memory.
  • Signal names starting with 'DV' refer to the UNIBUS from the KT11-B to the devices and memory of the system.
  • Signal names starting with 'CP' refer to the UNIBUS to the KT11-B from the KA11 CPU.
  • Signal names starting with 'PGC' refer to the contents of the Control Status register.
  • Signal names starting with 'PGM' refer to the contents of the Maintainence register.

Common Circuits

Latching mux

This circuit (first used in the KA11) is seen in several places in the KT11-B. It is almost always seen as an array of identical circuits, since it provides a 3-input multiplexor with latching capability, and it is used on data paths (usually 16 bits wide).

The latch is cleared by de-asserting the 'Latch' input; data from any of the three inputs (A, B, C) may then be selected for output, and potentially storage, by asserting the matching 'Gate' input. Asserting 'Latch' then stores the current output of the mux.

(Asserting more than one input simultaneously ORs the two inputs together; this capability is used in the KA11, but probably not here.)

States

The KT11-B has a state composed of two parts, the 'X' or major part, and the 'Y' or minor part; the progression of this through the various states is the major control mechanism in the KT11-B.

The X state counter is on print 12; it is composed of a 2-bit counter (allegedly a shift register, but that could not generate 4 discrete states) composed of a pair of D flops, with 4 AND gates with inverting inputs to create individual major state outputs, signals 'XSRx' (x = 0-3).

The Y state counter is an M826 Flip Chip, shown on print 8; its outputs are signals 'YSRx' (x = 0, 1 ,3, 7, 15, 14, 12, 8). (The odd sequence of minor state numbers, and the fact that they are not in numerical order, is confusing, but since that's what's on the prints, that nomenclature has to be used.)

The two groups of signals are combined into signals which indicate that the KT11-B is in that state, for each individual major/minor state, by NAND gates shown on drawing 12; inverters then provide non-inverted forms of each.

There are 4 signals XSHL, XSHR, YSHL, YSHR which control state transitions.

State Table

The following table shows the state transitions:

State Next State(s) Comment
0.0 0.8, 1.0 Idle
0.8 0.12 Interrupt, Trap and Start User
0.12 0.14
0.14 0.15
0.15 0.7A
0.7A 0.3A
0.3A 0.1A
0.1A 0.0
0.7B 0.3B Although the state names are identical to the preceding ones, this is shown on the state diagram as a separate state loop
0.3B 0.1B Window?
0.1B 1.1
1.0 1.1, 3.0
1.1 1.3
1.3 1.7, 3.3 Exec-per-Process
1.7 0.7B, 1.15
1.15 1.14 Page Violation?
1.14 1.12
1.12 0.12
1.8 1.0
2.0 0.0
2.1 2.0, 2.3 Shared Entry?
2.3 2.7
2.7 2.15
2.15 2.14 Page Violation?
2.14 0.14
2.12 - State does not exist
2.8 - State does not exist
3.0 2.0, 3.1, 3.8
3.1 1.1, 2.1, 3.0
3.3 3.1, 3.7A
3.7A 1.7 Although the state name is identical to the preceding ones, this is shown on the state diagram as a separate state loop
3.7B 3.3
3.15 3.7B
3.14 3.15
3.12 3.14
3.8 1.8, 3.12

This table is a transcription of the single-page one in the KT11-B Option Description; that diagram contains a number of labels, but it is not completely clear which states (or transitions) the labels apply to. Over time the hope is to check this table against the multi-page table in that document, and also better described what each state means.

Detailed logic description

This section covers each drawing in more detail, explaining what functions are found in each one.

Address Bus and Control Logic

The first sheet contains buffering between the address lines of the CPU's UNIBUS, and an internal address bus; and also random control logic.

The left side of the second sheet contains an address latching mux (see above), divided into high and low 9-bit halves, which selects between:

  • Scratch-pad data output (9 bits wide, repeated in the low and high halves)
  • Scratch-pad data input (17 bits wide, although the 17th bit is a synthetic signal, with the low and high halves swapped)
  • An internal address bus

The right half of the second sheet contains drivers for the address lines of the KT11-B's output UNIBUS, sourced from the above mux.

State Control Logic

This drawing contains random logic which generates the two major and two minor state change control signals (XSHL, XSHR, YSHL, YSHR).

Scratchpad Input Mux

At the top, a 16-bit wide latching mux (see above) which provides the input to the scratchpad memory. The three inputs are:

  • An internal address bus
  • An internal data bus
  • Scratchpad data output

At the bottom is random logic which generates the selection control signals for the mux.

Associative Memory Control

The first sheet contains a number of different logical units:

  • The top right corner contains logic to recognize references to KT11-B internal registers

The second sheet also contains a number of different logical units:

  • The right side contains logic to load individual associative memories
  • The center bottom contains logic to indicate an associative memory match

Scratchpad and State Control Logic

Random logic which controls the scratchpad memory.

Data Bus and Control Logic

The first sheet contains random control logic.

The left side of the second sheet contains the drivers for data lines of the output UNIBUS, which are fed from the data lines of the input UNIBUS. The right side contains half of a multiplexor (built from NAND gates connected in a wired-OR network) which drives the data lines of the UNIBUS to the CPU; the inputs are:

  • The data lines of the output UNIBUS (through a set of receivers, which also generate the internal data bus)
  • Scrarchpad data output
  • The KT11-B Control and Maintainence registers

The left side of the third sheet contains the other half of the data mux; the right side shows the KW11-L Line Time Clock card.

Keys and Associative Memory

The left-hand side shows the scratchpad memories; the top center shows the associative memories; the top right shows a comparator (use unknown); the bottom right is the counter?/shift register? which generates the minor state. The bottom center is a 3-bit wide latching mux which generates and holds key information.

XP Option for KT11 Associative Memory Control

This contains logic to control the optional cache entries; the left-hand side contains gates to control loading of associative memories, and the right hand side contains logic processing matches.

PGM Register

The KT11-B's Maintenance register: the center top is the replacement counter; the rest of the page is random logic (including S/R flops) to generate the currently undocumented other bits in the Maintenance register - bits 6, 7, 11, 12, 13, 14. (The Option Description indicates - Section 3.3.2.6 - that there are 5 bits, but the drawings show 6.)

PGC Register

The KT11-B's Control and Status register - S/R flops to store the bits, and random logic to control setting and clearing them: in the upper right, the Source and Destination bits; in the center and lower right, the five Violation bits; in the upper left and center, the two Function bits; in the left and center middle, the User and Interrupted User bits, respectively.

Timing Logic

The top and lower right contain gates which combine major and minor state lines into lines for each individual state. The lower left contains the counter (not a shift register, as per the Option Description Section 4.3; it can produce 4 different states from 2 bits, not possible with a shift register) to produce the major state, and logic to produce major state lines.

Buffered Signals and Main Logic

The left side shows the W130 Maintaince Card; the top and right contains buffering for various internal signals.

Extended Associative Memory

The scratchpad memory and associative memories for the optional 16-entry extension (to 24 entries total) for the page table entry cache.

Construction

As mentioned, the KT11-B is constructed out of a large number of smaller Flip Chips, plugged into a custom-wired backplane.

Module Counts

The module type usage counts are:

Type Function Count Comment
M111 16 x Inverters 10 9?
M112 10 x 2-input NOR 5 4? (but there's a '117' could be 112)
M116 6 x 4-input NOR 10
M133 10 x 2-input NAND 24
M135 8 x 3-input NAND 6
M139 3 x 8-input NAND 1
M167 Magnitude comparator 1
M203 8 x R/S flip flops 1
M206 6 x D flip flops 1
M207 6 x J/K flip flops 1
M225 Scratchpad memory 1 2 for 24 cache entries
M240 R/S flip flop 1
M244 6 x quad-2-input-AND/OR gates 6 Used as multiplexor latches (see above)
M259 Associative memory 4 12 for 24 cache entries
M602 2 x Pulse amplifier 1
M611 14 x Power inverter 3
M627 6 x NAND amplifier 7
M721 UNIBUS transceiver 4
M783 12 x UNIBUS NAND transmitters 6
M784 16 x UNIBUS inverter receivers 2
M826 Clock/shift register 1

(The counts are from the list in the "KT11-B Option Description" document; they have been cross-checked against the 'Module Utilization' sheet from the KT11-B Engineering Drawings, and there are still some variances to be sorted out.)

Module Locations

Slot A B C D
01 UNIBUS In M259 Mxx
02 M930 M259 M133
03 UNIBUS Out M259 M133
04 M930 M259
05 M721 M721 M259%
06 M721 M721 M259%
07 M783 M784 M259%
08 M783 M784 M259% M133
09 M783 M787 $ M259% M133
10 M783 M244 M259% M133
11 M783 M244 M259% M133
12 M783 M244 M259% M903 @
13 M826 M244 M627 M111
14 W130 $ M244 M627 M133
15 M116 M244 M627 M133
16 M225 M627 M133
17 M225% M117 X M133
18 M116 M112 M627 M133
19 M116 M112 M627 M133
20 M116 M112 M627 M133
21 M116 M112 M133
22 M116 M112 M133
23 M116 M602 M133
24 M116 M135 M133
25 M116 M135 M611 M133
26 M116 M135 M611 M133
27 M203 M135 M111 M133
28 M206 M135 M111 M133
29 M207 M135 M611 M133
30 M240 M133 M111 M111
31 M139 M111 M111
32 M167 M111 M111
  •  % = Optional
  • $ = Not part of KT11-D
  • @ = Cable
  •  ? = Could be M173

Card Information

The drawings contain a number of different Flip Chips as blocks, without showing individual details; those are given here.

M167

Shown on page 8-1, this is a 8-bit comparator; it compares the value of two 8-bit numbers and provides four outputs which provide the relationships between those two numbers (A=B, A>B, A>=B, and B>=A). (An EQUAL IN input is provided for cascading them, but it is not used here.)

Inputs (bits nummbered in PDP-11 style, with LSB = bit 0):

Input Pin Input Pin
A7 F2 B7 H2
A6 H1 B6 S1
A5 E2 B5 D2
A4 F1 B4 E1
A3 C1 B3 D1
A2 J1 B2 M1
A1 K1 B1 M2
A0 B1 B0 A1

Outputs:

Pin Signal
P1 EQUAL OUT (L)
R1 EQUAL OUT (H)
V1 A>B (H)
U1 B>=A (H)
L1 A>=B (H)

M203

Shown on pages 7-1, 10-1 and 11-1, although not as as a single block, but rather individual units, this contains R/S flip flops. They are formed from a pair of NAND gates interconnected in the usual fashion; they provide inverted S and R inputs, and normal and inverted outputs.

M225

Shown on pages 8-1 and 14-1, this is a 16x16-bit scratchpad memory; this card is also used in the KA11 processor of the PDP-11/20, and is documented there. In addition to 16-bit wide input and output, and byte write controls, it also provides an 4 sets of the 4 address inputs, and 4 inputs to select the desired set of addresz input. (I.e. the address lines are binary encoded, but the address input select lines are not.) An internal 4-way mux selects the desired set of address inputs.

Data pins:

Input Pin Output Pin
I00 AF2 O00 AE1
I01 AA1 O01 AC1
I02 AK2 O02 AL1
I03 AH1 O03 AJ1
I04 AE2 O04 AF1
I05 AD2 O05 AD1
I06 AJ2 O06 AM1
I07 AH2 O07 AK1
I08 BR2 O08 BM2
I09 BL1 O09 BM1
I10 BV2 O10 BU1
I11 BP1 O11 BR1
I12 BP2 O12 BT2
I13 BN2 O13 BN1
I14 BU2 O14 BV1
I15 BS2 O15 BS1

Control pins:

Address set select Pin Address set A Pin Address set B Pin Address set C Pin Address set D Pin
A0 BE1 AA0 BF2 AB0 BH1 AC0 BE2 AD0 BF1
A1 BJ1 AA1 BD1 AB1 BD2 AC1 BC1 AD1 BA1
A2 AP2 AA2 AV2 AB2 AV1 AC2 AU1 AD2 AU2
A3 AS1 AA3 AT2 AB3 AS2 AC3 AR2 AD3 AR1

Pin BK1 is 'WRITE 15/8', and pin AM2 is 'WRITE 7/0'. In addition, pin AN1 is a control input of some sort, but it is not yet clear what it does.

M240

Shown on pages 10-1 and 11-1, although not as as a single block, but rather individual units, this contains R/S flip flops.

M259

Shown on pages 8-1 and 14-1, this is a dual 8-bit associative memory.

M602

Shown on pages 6-1 and 13-1, although not as as a single block, but rather individual units, this is a dual pulse amplifier. It produces a negative-going pulse (nominally 50 nsec wide), triggered by an input transitioning from high to low; the input is a triple-input OR with inverting inputs.

M787

Shown on page 7-3, this is actually not a part of the KT11-B; rather, it is the KW11-L Line Time Clock, which must reside in the KT11-B's backplane.

M826

Shown on page 8-1, this is a clock with counter?/shift-register?

W180

Shown on page 13-1, this is actually not a part of the KT11-B; rather, it is the Maintenance Card, which must plug into the KT11-B's backplane.