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[[Image:ND-100-FrontPanel.jpg|400px|thumb|right|[[ND-100 front panel]]]] The '''ND-100''' was a 16-bit minicomputer series made by [[Wikipedia:Norsk Data|Norsk Data]], introduced in 1979. It shipped with the [[Wikipedia:SINTRAN_III|SINTRAN III]] operating system, and the architecture was based on, and backwards compatible with, the [[NORD-10]] line.
The '''ND-100''' was a 16-bit minicomputer series made by [[Norsk Data]], introduced in [[1979]]. It shipped with the [[SINTRAN III]] operating system, and the architecture was based on, and backwards compatible with, the [[NORD-10]] line.


The NORD-100 was originally named the NORD-10/M (''M'' for ''Micro'') as a bitsliced OEM processor. The board was laid out and finished and tested when they realized that the CPU was far faster than the NORD-10/S. The result was that all the marketing material for the new NORD-10/M was discarded, the board was rechristened the NORD-100, and extensively advertised as the successor of the NORD-10 line. Later, in an effort to internationalize their line, the machine was renamed ND-100.
The NORD-100 was originally named the NORD-10/M (''M'' for ''Micro'') as a bitsliced OEM processor. The board was laid out and finished and tested when they realized that the CPU was far faster than the NORD-10/S. The result was that all the marketing material for the new NORD-10/M was discarded, the board was rechristened the NORD-100, and extensively advertised as the successor of the NORD-10 line. Later (the year was 1978), in an effort to internationalize their line, the machine was renamed ND-100.
[[Image:ND-100_Satellite.jpg | thumb | ND 100 Satellite]]


==Performance==
==Performance==
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! !! ND-100 !! ND-100/CE !! ND-110 !! ND-110/CX !! ND-120/CX !! ND-125/CX  
! !! ND-100 !! ND-100/CE !! ND-110 !! ND-110/CX !! ND-120/CX !! ND-125/CX  
|-
|-
| Minimum number of microinstructions per instruction || 3 || 3 || 1 || 1  
| Minimum number of microinstructions per instruction || 3 || 3 || 1 || 1 || || 
|-
|-
| Minimum microinstruction cycle time || 150ns || 150ns || 100ns || 100ns
| Minimum microinstruction cycle time || 150ns || 150ns || 100ns || 100ns || ||
|}
|}


==CPU==
==CPU==
The ND-100 line used a custom processor, and like the [[Wikipedia:PDP-11|PDP-11]] line, the CPU decided the name of the computer.
The ND-100 line used a custom processor, and like the [[Wikipedia:PDP-11|PDP-11]] line, the CPU decided the name of the computer.


*NORD-100/CE, Commercial Extended, with decimal arithmetic instructions (The decimal instruction set was later renamed CX)
*NORD-100/CE, Commercial Extended, with decimal arithmetic instructions
*ND-110, incrementally improved ND-100
*ND-100/CX, improved the CE instructions and added some new instructions
*ND-110/CX, an ND-110 with the decimal instructions.
*ND-110, incrementally improved ND-100. Same performance and instruction set as the ND-100/CX.
*ND-120/CX, completely redesigned.  
*ND-110/CX, a faster version of the ND-110 (1.5-3.5 times faster).
 
*ND-120/CX, completely redesigned using one big VLSI gate array (The so-called Delilah chip). Performance is approximate 1.9 times faster than the ND-110/CX. Minor changes in the microcode, no changes in the macrocode/opcodes.
The ND-100 line was machine-instruction compatible with the Nord-10 line, except for some "extended instructions", all in supervisor mode, mostly used by the operating system. Like most processors of its time, the native bit grouping was [[octal]], despite the 16-bit word length.
*ND-125/CX, a 120 CPU board with faster access to onboard memory and increased onboard memory size.


The ND-100 series had a [[Microprogram|microcoded]] central processing unit, with [[microcode#Writable_control_stores | downloadable microcode]], and was considered a [[Complex instruction set computer|CISC]] processor.
The ND-100 line was machine-instruction compatible with the Nord-10 line, except for some "extended instructions", all in supervisor mode, mostly used by the operating system. Like most processors of its time, the native bit grouping was octal, despite the 16-bit word length.


<!-- The structuring might seem a little excessive for now, but I'm planning on including more info ASAP. -->===ND-100===
The ND-100 series had a [[Microprogram|microcoded]] central processing unit, with [[microcode#Writable_control_stores | downloadable microcode]], and was considered a CISC processor.


The ND-100 was implemented using [[Integrated circuit#SSI, MSI, LSI|medium-scale integration]] (MSI) logic and [[bit-slice]] processors.
The ND-100 was implemented using medium-scale integration (MSI) logic and bit-slice processors.


The ND-100 was frequently sold together with a [[memory management unit|memory management card]], the MMS. The combined power use of these boards was 90 watts. These boards would usually occupy slots 2 and 3, for the CPU and MMS, respectively. Slot 1 was reserved for the Tracer, a hardware debugger system.
The ND-100 was frequently sold together with a memory management card, the MMS. The combined power use of these boards was 90 watts. These boards would usually occupy slots 2 and 3, for the CPU and MMS, respectively. Slot 1 was reserved for the Tracer, a hardware debugger system.


===ND-100/CE===
===ND-100/CE===
The CE stood for Commercial Extended. The processor was upgraded by replacing the microcode PROM.


The CE stood for Commercial Extended. The processor was upgraded by replacing the microcode PROM.
It added instruction for decimal arithmetic and conversion ([[ND-1xx_Instructions#Decimal_Instructions|decimal instructions]]) and [[ND-1xx_Instructions#Stack_Handling_Instructions|stack handling instructions]].


It added instruction for decimal arithmetic and conversion, stack instructions, segment-change instructions used by the OS, a block move, test-and-set, and a read-without-cache instruction.
===ND-100/CX===
The CX option improved the instructions introduced with the CE option, and added some [[ND-1xx_Instructions#Additional_instructions_in_the_CX_option|new instructions]]: [[MOVEW]], [[TSET]], [[RDUS]] and [[ND-1xx_Instructions#SINTRAN-III_Segment_Change_Instructions|segment change instructions]].


===ND-110===
===ND-110===
 
{{Main|ND-110 CPU|ND-110 Satellite Series}}
The ND-110 was an incremental improvement over the ND-100.
The ND-110 was an incremental improvement over the ND-100.


The ND-110 combined the Memory Management System and CPU, previously separate cards, on one board. The single CPU/MMS board was plugged into the memory management board slot, usually numbered 3. The power consumption was reduced from 90 watts to 60.  
The ND-110 combined the Memory Management System and CPU, previously separate cards, on one board. The single CPU/MMS board was plugged into the memory management board slot, usually numbered 3. The power consumption was reduced from 90 watts to 60.  


The ND-110 made extensive use of [[Programmable Array Logic|PAL]]s and [[gate array]]s - with "semi-custom" [[VLSI]] chips.  
The ND-110 made extensive use of PALs and gate arrays - with "semi-custom" VLSI chips.  


The ND-110 had three gate arrays:
The ND-110 had three gate arrays:


* The Micro Instruction Controller, the MIC - also known as RMIC, for "Rask MIC" ("Speedy MIC"). It replaced three 74S482 sequencers and about 30 other ICs.
* The Micro Instruction Controller, the MIC - also known as RMIC, for "Rask MIC" ("Speedy MIC"). It replaced three 74S482 sequencers and about 30 other ICs.
* The Arithmetical and Logical Unit gate array ([[Arithmetic logic unit|ALU]], also known as the "BUFALU"). Replaced four [[AMD Am2900|Am2901]] bit-slice processors, and some additional registers like the data bus register the general purpose register, and the internal register block.
* The Arithmetical and Logical Unit gate array (ALU, also known as the "BUFALU"). Replaced four Am2901 bit-slice processors, and some additional registers like the data bus register the general purpose register, and the internal register block.
* The Micro Address Controller (The MAC, also called RMAC, for "Rask MAC" ("Speedy MAC"). It implemented hardware address arithmetic, which in the ND-100 had been done in microcode.
* The Micro Address Controller (The MAC, also called RMAC, for "Rask MAC" ("Speedy MAC"). It implemented hardware address arithmetic, which in the ND-100 had been done in microcode.


Line 57: Line 57:
Unlike the ND-100 CPU, it handled synchronous interrupts as traps, similar to how it was handled by the ND-500.
Unlike the ND-100 CPU, it handled synchronous interrupts as traps, similar to how it was handled by the ND-500.


The [[control store]] consisted of 4K x 4 bit 40ns [[Static Random Access Memory|SRAM]] chips. This meant that [[microcode#Writable_control_stores | the control store was writable]]. It was loaded at power up and Master Clear from two 32Kx8 bit [[EPROM]]s.
The [[control store]] consisted of 4K x 4 bit 40ns SRAM chips. This meant that [[microcode#Writable_control_stores | the control store was writable]]. It was loaded at power up and Master Clear from two 32Kx8 bit EPROMs.


The CPU clock and the bus arbitration network were implemented using 15ns PALs.
The CPU clock and the bus arbitration network were implemented using 15ns PALs.
Line 64: Line 64:


===ND-110/CX===
===ND-110/CX===
This is the fast version of the [[ND-110 CPU]], also known as '''RASK'''.


This was the ND-110 with the CX microcode [[programmable read-only memory | PROM]]. The added instructions were the same as the /CE.
===ND-110PCX===
This is the CPU used in the [[BUTTERFLY 110]] PC-based workstation. The CPU is implemented on two full length ISA cards and based on the same design as ND-110/CX.  


===ND-120/CX===
===ND-120/CX===
 
The ND-120 CPU was a complete reimplementation on an LSI chip (The so-called [[Delilah]] chip), and was originally intended to be sold as the ''ND-1000'', to reflect the technology change, which paralleled the change from the [[ND-500]] series to the [[ND-5000 family|ND-5000]] (Codenamed [[Samson]]).
The ND-120 CPU was a complete reimplementation on an LSI chip (The so-called [[Delilah]] chip), and was originally intended to be sold as the ''ND-1000'', to reflect the technology change, which paralleled the change from the [[ND-500]] series to the [[ND-5000]] (Codenamed [[Samson]]).


The Samson/Delilah naming scheme may reflect that around the time of the development of the ND-120, it was increasingly clear that the mixed 16/32-bit architecture was a bottleneck for the ND-500(0) architecture; Internal technical documentation used at Norsk Data for the Delilah chip has a drawing of a grinning woman with hair in her clenched fist.
The Samson/Delilah naming scheme may reflect that around the time of the development of the ND-120, it was increasingly clear that the mixed 16/32-bit architecture was a bottleneck for the ND-500(0) architecture; Internal technical documentation used at Norsk Data for the Delilah chip has a drawing of a grinning woman with hair in her clenched fist.


==This is the place where I thought to add information about the Nord 100 minicomputer,
===ND-125/CX===
and document the instruction set etc.==
The ND-125 CPU appears to be based on an ND-120 CPU, but with improved performance by speeding up memory access to the on-board memory, and by increasing the on-board memory size to 8, 12, or 16 megabytes (the ND-120/CX could have a maximum of 6MB on-board). The larger memory size is achieved by using 4-Mbyte SIMMs instead of 1-Mbyte SIPs. Memory cycle time is reduced to 150 ns by using 70 ns memory modules instead of 100 ns modules.<ref>[http://sintran.com/sintran/library/libeco/ECO-ND-100-786.pdf sintran.com, ECO 100-786, date: 1994.09.09]</ref>


== ND100 Boot Loaders ==
==Surviving systems==
The ND100  has bootstrap loaders for mass storage and character oriented devices. There is two load formats.
There are quite a lot of surviving ND-100 systems remaining. This list is far from complete.
* Binary load format.
* ND-100 serial 383 : In the collections of Telemuseet<ref>[http://digitaltmuseum.no/021026130703 Collections of Telemuseet, TELE.Hf-226]</ref>
* Mass storage load.


=== Binary load format ===
==Gallery==
<gallery>
Image:ND-100 CPU RACK-001.jpg|ND-100 rack with a lot of serial ports but missing CPU
Image:ND100-CPU-board.jpg | [[3002]] ND-100 CPU board.
Image:ND-100-FrontPanel.jpg|[[ND-100 front panel]]
Image:ND-100_Satellite.jpg | [[ND-100 Satellite]]
</gallery>


[[Image:ND-100-binloadformat.svg | The binary load format structure]]
== See also ==
 
*[[Wikipedia:NORD-100]]
A, B and C (all in grey) are optional.
 
* A - Any characters not including ! (ASCII 33).
* B - Octal number (any number of digits) terminated with a CR (linefeed is ignored).
* C - Octal number (any number of digits).
* ! - Termination character of header.
* D - Block start address. Presented as two bytes, most significant byte first.
* E - Word count of block F. Presented as two bytes, most significant byte first.
* F - Binary data. Each word presented as two bytes, most significant byte first.
* G - Checksum word. Presented as two bytes, most significant byte first. The checksum is the 16 bit arithmetic sum of all words in F.
* H - Action code. A bit fuzzy in the manual about which of B or C is used.
 
Binary load is started by typing:
 
<physical device address>& or <physical device address>$
 
Loading will take place from the specified device. This device must conform with
the programming specifications of either Teletype or tape reader. The device
address is the lowest address associated with the device. Binary load will be
performed if & or $ is written (or the LOAD button is pressed) and the switch
selected ALD has bit 13 equal to "0".
 
If no device address precedes the & command, then the & is equivalent to pushing
the LOAD button on the operator's panel.
 
If a checksum error is detected, "?" is typed on the console and control is returned
to the operator's communication.
 
Note that the binary loader does not require any of the main memory.
 
The binary load will change the registers on level 0.
 
The binary load format is compatible with the format dumped by the )BPUN
command in the MAC assembler.
 
=== Mass storage load ===
 
Mass storage load is started in the same way as binary format load, except that bit
13 in the device address should be a "1".
 
When loading from mass storage, 1K words will be read from mass storage
address 0 into main memory starting in address 0. After a successful load, the CPU
is started in main memory address 0.
 
The mass storage device must conform with either drum or disk programming specifications.
 
== ND100 CPU registers and organisation ==
 
=== Register File ===
The ND100 CPU has a register file of 256 registers, organised as 16 registers on 16 different runlevels.
Of those 16 registers, the top 8 are only accessible by the microprogram.
On switch between runlevels, the current register set is stored in the register file from the ALU and
the new one is loaded.
 
[[Image:ND-100-regfile.svg | The register file]]
 
=== Internal registers ===
==== STS ====
The Status register STS is formed by having a common upper 8 bits and the lower 8 is separate for
each program level.
 
[[Image:ND-100-statusreg.svg | The status register]]
 
* IONI - Interrupt system ON indicator.
* PONI - Memory management ON indicator.
* SEXI - Extended indicator to show that MMS is in 24 bits extended addressing mode instead of the usual 19 bits addressing mode.
* N100 - N100 indicator to tell the operating system that this is a ND100 machine.
* PIL - Current program level indicator.
* M - multishift link indicator. Temporary storage for discarded bits in shift instructions, used to ease the shifting of multiple precision words.
* C - Carry indicator.
* O - Static overflow indicator. Remains set after an overflow condition until reset by program.
* Q - Dynamic overflow indicator.
* Z - Error indicator. Static and thus remains set until reset by program. The Z indicator may be internally connected to an interrupt level such that an error message routine may be triggered.
* K - One bit accumulator. Used by the BOP instructions operating on one bit data.
* TG - Rounding indicator for floating point operations.
* PTM - Page table modus. Enables use of the alternate page table.
 
These indicators are fully program controlled either by means of the BOP instruction or the TRA or TRR instructions where all indicators may be transferred to and from the A register.
 
==== IIE ====
The Internal Interrupt Enable Register controls the internal interrupt system
 
[[Image:ND-100-IIEreg.svg | The IIE register]]
 
* POW - Power fail interrupt.
* MOR - Memory out of range, addressing non-existent memory.
* PTY - Memory parity error.
* IOX - [[IOX error]], no answer from external device.
* PI - Privileged instruction.
* Z - Error indicator, the Z indicator is set.
* II - Illegal instruction.
* PF - page fault, page not in memory.
* PV - Protect violation. Page number is found in the Paging Status Register.
* MC - Monitor call.
* n/a - Not assigned.
 
==== PGS ====
[[Image:ND-100-PGSreg.svg | The PGS register]]
 
==== PCR ====
[[Image:ND-100-PCRreg.svg | The PCR register]]
 
== Instruction Set ==
=== Memory Reference Instructions ===
==== Store Instructions ====
* [[STZ]]
* [[STA]]
* [[STT]]
* [[STX]]
* [[MIN]]
 
==== Load Instructions ====
* [[LDA]]
* [[LDT]]
* [[LDX]]
 
==== Arithmetic and Logical Instructions ====
* [[ADD]]
* [[SUB]]
* [[AND]]
* [[ORA]]
* [[MPY]]
 
==== Double Word Instructions ====
* [[LDD]]
* [[STD]]


==== Floating Instructions ====
== References ==
* [[LDF]]
<references/>
* [[STF]]
*{{OriginWP-EN|NORD-100|4th August 2008}}
* [[FAD]]
*{{ND-doc|06.014.02}}
* [[FSB]]
* [[FMU]]
* [[FDV]]
 
==== Byte Instructions ====
* [[BFILL]]
* [[MOVB]]
* [[MOVBF]]
* [[SBYT]]
* [[LBYT]]
 
=== Execute Instruction ===
* [[EXR]]
 
=== Bit Instructions ===
* [[BSKP]]
* [[BSET]]
* [[BSTA]]
* [[BSTC]]
* [[BLDA]]
* [[BLDC]]
* [[BANC]]
* [[BORC]]
* [[BAND]]
* [[BORA]]
 
=== Shift Instructions ===
* [[SHT]]
* [[SHD]]
* [[SHA]]
* [[SAD]]
* [[ROT]]
* [[ZIN]]
* [[LIN]]
* [[SHR]]
 
=== System Control Instructions ===
* [[IOF]]
* [[ION]]
* [[LWCS]]
* [[MON]]
* [[PIOF]]
* [[PION]]
* [[POF]]
* [[PON]]
* [[REX]]
* [[SEX]]
* [[WAIT]]
* [[OPCOM]]
 
=== Transfer Instructions ===
==== Load Independent Instructions ====
* [[TRA]]
* [[TRR]]
==== Inter-level Instructions ====
* [[IRR]]
* [[IRW]]
 
=== Register Operations ===
==== Arithmetic Operations, RAD=1: ====
C,O,Q may be affected by the following operations
* [[RADD]]
* [[RSUB]]
* [[COPY]]
* [[AD1]]
* [[ADC]]
 
==== Logical Operations, RAD=0: ====
* [[SWAP]]
* [[RAND]]
* [[REXO]]
* [[RORA]]
* [[CLD]]
* [[CM1]]
 
==== Combined Instructions: ====
* [[EXIT]]
* [[RCLR]]
* [[RINC]]
* [[RDCR]]
 
==== Extended Arithmetic Operations: ====
* [[RMPY]]
* [[RDIV]]
 
=== Floating Conversion ===
* [[NLZ]]
* [[DNZ]]
 
=== Memory Examine/Deposit Instructions ===
* [[EXAM]]
* [[DEPO]]
 
=== Sequencing Instructions ===
==== Unconditional Jump ====
* [[JMP]]
* [[JPL]]
 
==== Conditional Jump ====
* [[JAP]]
* [[JAN]]
* [[JAZ]]
* [[JAF]]
* [[JXN]]
* [[JPC]]
* [[JNC]]
* [[JXZ]]
 
==== Skip Instructions ====
* [[SKIP]]
 
== See also ==
For more information look at [[Wikipedia:NORD-100]]


== Sources ==
[[Category:ND-100 hardware]]
*{{OriginTransl-EN|NORD-100|4th August 2008}}
* ND-100 Reference Manual (ND-06.014.02 rev A)
* ND-100 Instant Instruction Codes (ND-06.021Q02 12/83)

Latest revision as of 14:31, 26 December 2023

The ND-100 was a 16-bit minicomputer series made by Norsk Data, introduced in 1979. It shipped with the SINTRAN III operating system, and the architecture was based on, and backwards compatible with, the NORD-10 line.

The NORD-100 was originally named the NORD-10/M (M for Micro) as a bitsliced OEM processor. The board was laid out and finished and tested when they realized that the CPU was far faster than the NORD-10/S. The result was that all the marketing material for the new NORD-10/M was discarded, the board was rechristened the NORD-100, and extensively advertised as the successor of the NORD-10 line. Later (the year was 1978), in an effort to internationalize their line, the machine was renamed ND-100.

Performance

Relative CPU performance
ND-100 ND-100/CE ND-110 ND-110/CX ND-120/CX ND-125/CX
Minimum number of microinstructions per instruction 3 3 1 1
Minimum microinstruction cycle time 150ns 150ns 100ns 100ns

CPU

The ND-100 line used a custom processor, and like the PDP-11 line, the CPU decided the name of the computer.

  • NORD-100/CE, Commercial Extended, with decimal arithmetic instructions
  • ND-100/CX, improved the CE instructions and added some new instructions
  • ND-110, incrementally improved ND-100. Same performance and instruction set as the ND-100/CX.
  • ND-110/CX, a faster version of the ND-110 (1.5-3.5 times faster).
  • ND-120/CX, completely redesigned using one big VLSI gate array (The so-called Delilah chip). Performance is approximate 1.9 times faster than the ND-110/CX. Minor changes in the microcode, no changes in the macrocode/opcodes.
  • ND-125/CX, a 120 CPU board with faster access to onboard memory and increased onboard memory size.

The ND-100 line was machine-instruction compatible with the Nord-10 line, except for some "extended instructions", all in supervisor mode, mostly used by the operating system. Like most processors of its time, the native bit grouping was octal, despite the 16-bit word length.

The ND-100 series had a microcoded central processing unit, with downloadable microcode, and was considered a CISC processor.

The ND-100 was implemented using medium-scale integration (MSI) logic and bit-slice processors.

The ND-100 was frequently sold together with a memory management card, the MMS. The combined power use of these boards was 90 watts. These boards would usually occupy slots 2 and 3, for the CPU and MMS, respectively. Slot 1 was reserved for the Tracer, a hardware debugger system.

ND-100/CE

The CE stood for Commercial Extended. The processor was upgraded by replacing the microcode PROM.

It added instruction for decimal arithmetic and conversion (decimal instructions) and stack handling instructions.

ND-100/CX

The CX option improved the instructions introduced with the CE option, and added some new instructions: MOVEW, TSET, RDUS and segment change instructions.

ND-110

The ND-110 was an incremental improvement over the ND-100.

The ND-110 combined the Memory Management System and CPU, previously separate cards, on one board. The single CPU/MMS board was plugged into the memory management board slot, usually numbered 3. The power consumption was reduced from 90 watts to 60.

The ND-110 made extensive use of PALs and gate arrays - with "semi-custom" VLSI chips.

The ND-110 had three gate arrays:

  • The Micro Instruction Controller, the MIC - also known as RMIC, for "Rask MIC" ("Speedy MIC"). It replaced three 74S482 sequencers and about 30 other ICs.
  • The Arithmetical and Logical Unit gate array (ALU, also known as the "BUFALU"). Replaced four Am2901 bit-slice processors, and some additional registers like the data bus register the general purpose register, and the internal register block.
  • The Micro Address Controller (The MAC, also called RMAC, for "Rask MAC" ("Speedy MAC"). It implemented hardware address arithmetic, which in the ND-100 had been done in microcode.

In addition to the macro-instruction cache memory also found in the ND-100, the ND-110 had a unique implementation of cache memory on the micro-instruction level. The step known as mapping in the ND-100 was then avoided because the first micro-instruction word of a macro-instruction was written into the control store cache.

Unlike the ND-100 CPU, it handled synchronous interrupts as traps, similar to how it was handled by the ND-500.

The control store consisted of 4K x 4 bit 40ns SRAM chips. This meant that the control store was writable. It was loaded at power up and Master Clear from two 32Kx8 bit EPROMs.

The CPU clock and the bus arbitration network were implemented using 15ns PALs.

The main oscillator was a 39.3216 MHz crystal oscillator.

ND-110/CX

This is the fast version of the ND-110 CPU, also known as RASK.

ND-110PCX

This is the CPU used in the BUTTERFLY 110 PC-based workstation. The CPU is implemented on two full length ISA cards and based on the same design as ND-110/CX.

ND-120/CX

The ND-120 CPU was a complete reimplementation on an LSI chip (The so-called Delilah chip), and was originally intended to be sold as the ND-1000, to reflect the technology change, which paralleled the change from the ND-500 series to the ND-5000 (Codenamed Samson).

The Samson/Delilah naming scheme may reflect that around the time of the development of the ND-120, it was increasingly clear that the mixed 16/32-bit architecture was a bottleneck for the ND-500(0) architecture; Internal technical documentation used at Norsk Data for the Delilah chip has a drawing of a grinning woman with hair in her clenched fist.

ND-125/CX

The ND-125 CPU appears to be based on an ND-120 CPU, but with improved performance by speeding up memory access to the on-board memory, and by increasing the on-board memory size to 8, 12, or 16 megabytes (the ND-120/CX could have a maximum of 6MB on-board). The larger memory size is achieved by using 4-Mbyte SIMMs instead of 1-Mbyte SIPs. Memory cycle time is reduced to 150 ns by using 70 ns memory modules instead of 100 ns modules.[1]

Surviving systems

There are quite a lot of surviving ND-100 systems remaining. This list is far from complete.

  • ND-100 serial 383 : In the collections of Telemuseet[2]

Gallery

See also

References