I need help finding information on this mysterious computer

I used to be a systems programmer working on CP/M, for my sins I pioneered the concept of expanded memory/extended memory. I kind of recognise this but bear in mind I dealt with lots of stuff that all looked like this. It could be the prototype for the Vector Graphic, Horizon or Crem.. something.. (cant remember) that never got to market because S100 bus took over. The RAM PCB is interesting, I am racking my brains, I think they are 2114s that were replaced by the 4116, the difference is that what you are looking at is static,. The BIG thing the Z80 brought us was support for dynamic memory, BUT, we quickly discovered the 16kx1 bit 4116 RAMs needed a dual data/address bus to work above 1MHz (hence why S100 was born), this unit hasnt got enough pins for that and the old 48k static RAM based systems never got off the ground because of the huge cost and super unreliability due to thermal stresses! It would have supported two Micropolis 5.25" floppy drives pre DMA and vectored interrupts (that came later) using the NEC something or other (cant remember but I remember the sleepless nights!)... The problem in that era was the monitor, the monitor display was memory mapped (usually at F800 or thereabouts) and always had a weird interface (RS232 came later, remember we had no way of making plus/minus 15v cheaply and no way of driving the line or discerning the signal!). Consequently I reckon its one of the original prototypes of the early Z80-era, lots of companies made loads that like this and my job was to write the BIOS to load the BDOS. Back in those days we junked prototype after prototype, it wasnt because the technology changed, back in those days we didnt know what the future would look like and EVERYTHING had to be pioneered. We didnt even know how to make stuff reliable because we didnt know what made it go wrong, until about 1-2 years after the era that is on your bench! I have obviously long long retired now, but as a hobby, I still write assembler software.

This seems like CuriousMarc and his friends could decipher this box, but they're busy working on Apollo microwave circuits, the blackest of black arts in analog electronics.

I worked at Tek in the mid 70s. to 79. I believe what you have is a “Bit Box.. it was a custom designed development system.that the company used to develop software for embedded systems within instruments. It is definitely a tek design as few manufacturers gold plated all the runs on the board. Also the bread boards are the way we made prototypes.

I doubt it was "home" made as it would have been pretty expensive in those days, especially the PCBs. I think a prototype or 1-off for some kind of industrial/scientific use, or maybe a college.

Classic look and feel of a custom controller for a specific scientific or industrial application. Video video because it's not a general purpose computer, it was likely desinged for a specific control application.

For development work at Tektronix without use of an operating system on the board bucket, the Microprocessor Development group also had a skilled software team that developed a nice Macro Assembler, Re-locating Linker, and downloader toolset that ran on the Tektronix Control Data Cyber 73 timeshare system running KRONOS. Most of the toolset was written in PASCAL, and worked very well. The assemblers for the different processors were made to be as consistent with each other as possible. The team also wrote great documentation for the software tools they made, that made it quite easy to come up to speed on the use of the tools for developing code for the system. This was the environment most frequently used for doing software development for the board bucket systems within Tektronix.
The earliest versions of the Board Bucket system were used as development systems for what became the famous and rather incredible (for the time) Tektronix 4051 all-in-one BASIC-language Graphics Computer. The 4051 was the first of its kind, providing a cable Tektronix-written dialect of BASIC in ROM, augmented by the ability to do high resolution graphics, drawn on the systems' storage tube display.
(th-cam.com/video/xWrIS_l5HWk/w-d-xo.html).
The success of using board bucket as a development system for the 4051 made them quite popular as a development platform for all kinds of things within product groups at Tektronix.
The board bucket circuit boards were hand laid-out by a very nice lady named Dixie who worked in the Microprocessor Development Group. It was amazing to watch her working with tape and Mylar on a big light board to lay out the pads and traces for the boards. This was before there were CAD systems were commonly used for this kind of thing, although Tektronix did have an early REDAC printed circuit board CAD system based on a Digital Equipment PDP 8/I system down in the basement CAD laboratory at the main Tektronix campus, but this system was typically very busy doing production circuit board layouts.
Dixie was a real artist. The art of her work is evident in routing of the circuit boards. Most of the boards were two layer boards, with a sandwiched ground plane, and etch on the top and bottom of the boards, with plated-through feedthroughs. Dixie was well-known throughout the company as one of the best hand-tapers around. The boards she laid out were always beautiful to look at, but as electronically sound as could be made. It was an extreme rarity for one of Dixie's circuit boards to not come up when a prototype run was done and a board stuffed with parts. Almost every time the problem proved to be in assembly, not having to do anything with the board layout. As much as I can remember, only once was a second-run of a board required due to a layout issue resulting in some kind of noise problem that took quite some time to track down.
Tektronix' ECB (as they were called there, for "Etched Circuit Board") manufacturing plant was legendary for creating some of the best circuit boards in the industry. Gold was heavily used, even on internal engineering boards, and the quality was impeccable. Even the internal engineering boards were produced as if they were going to go into a Tektronix product, making them vastly superior to most all of the hobby computer S-100 boards on the market. And, in the end, they were a considerably less expensive than comparable boards in the hobbyist marketplace if you built them out yourself. If you opted to buy the boards fully built-out, they were still less expensive than an rough equivalent S-100 board in the hobby marketplace.
I did not work in the Microprocessor Development Group, but because of my interest, I became quite close with the members of this group, and spent a lot of my free time over in their area hob-nobbing with the folks there. I learned a great deal from them in terms of digital design and microprocessor interfacing. I purchased a number of the unpopulated boards and built them up myself to make a small system to play with at home, which grew over time.
Later, as a "spare-time G-job " project, I was "signed up" by the Microprocessor Development group to develop a custom system based on this hardware to serve as a wafer tracking system in Tektronix' IC fabrication facility(later sold to Maxim).
I designed a video board based on a Texas Instruments video controller (can't remember the part number, but it was compatible with TI's 9900 CPU and required a little work to interface it to the bus). The board would hook up to a large (CRT) TV. There were a number of these systems planted around the fabrication areas, mounted so they were easily readable from just about anywhere in the area. The systems all talked to each other over a syingle RS-232 line where I used a time-slicing protocol so each system got a slot of time where it could talk to the others to relay status information. Each system had a CRT terminal attached via serial port where operators could enter information and query the system. The video board also had the National Semiconductor real-time clock chip on-board along with battery-backup. I also modified the floppy controller with a daughter board that plugged in place of the NEC floppy controller that provided the capability to used double-sided, double-density 5 1/4" floppy drives so I had enough disk space for the data the system needed to store. The system used the 6809 CPU (my favorite 8-bitter). It was packaged in a similar chassis, and used Technical Systems Consultants' Flex-09 operating system, which I wrote custom drivers for to talk to the floppy controller, serial ports, and video display subsystem. The system was prototyped and tested out with a couple of select folks from the IC fab, and they made a few recommendations for some changes, which I incorporated, and then it was installed in the Fab. It worked great, and really improved the efficiency of the fab's production workflow.
The system that you have uses a different bus structure, but the concept is very similar to the board bucket. I think that the board with all of the 8?-square-pin connectors along the top is a multi-port serial board. The sockets might be for async interface chips.

It’s not a homemade computer. It’s in a rack mount 3U or 4U box. The boards are made in house to support the various test equipment/instrumentation. I worked in the oilfield industry and as various instrumentation was being converted to the digital age, it wasn’t uncommon to make in-house boards to bring the various instrumentation we acquired from all the acquisitions during the oilfield crash in the early 80’s. The funny soldering are field repairs we made in field because we couldn’t drive back to the base camp as we were on customer time. We pulled the rack mount, opened the top, slapped replacement boards or started soldering jumper wires. The braided soldering wick ground wire was just some guy panicking, and slapped that as a strong ground. We ran off generators that would surge or during lightening storms and not fully grounded, so I think they panicked and used that. We had humidity problems as our mobile office is a peterbilt unit with a box office and on hot days in West Texas, the AC and the heat from the rack mount systems didn’t play well. Good times then. Nothing is homemade, it’s propertary boards.

Greetings the device you have is part of ATE system bulit by a company I worked for in the early 80's in salem oregon. It was bulit for one of their customers on contract.. please contact me for more info.

It could be custom instrumentation for a test lab. I used build stuff like that for engineers in an Automotive Safety instrumentation lab. They would hand me drawings and I'd create it all from scratch, even the boards.

what a trip, this box looks like it came right out of my old lab. i worked a LOT with boxes very similar to this one. Its early 80's, late 70's so i'm not surprised it isn't covered in asset tags, but i am a bit surprised it doesn't have a single company mark on it. the boards were almost certainly rolled by a company with their own pcb manufacturing, like any aerospace from that period. Most aerospace firms plastered their logo on everything they rolled though, which makes me think this isn't aero. It's definitely not "homemade" though, and has all the hallmarks of a professional research lab.
In general terms, i'd put my money on this box being a control system. I'd trace back the ribbon cables and see if one of them is actually DIO or not. Floppy drive cables got used a lot for DIO because why not; you already have a thousand of the cables.
I would also be pretty shocked if it had any visual output. Even today, that is exceedingly rare for this kind of hardware because its a beyond a waste of time and effort to add video out of any kind. I'd take a close look and see if its RS-232 or RS-422 though, that would be a big clue. basically, different industries use different serial methods (more or less).
If it is a control system, or a test bed for control systems, then it probably does have a boot loader or boot boot loader output on the serial port when its powered on. I found it pretty common to get at least something from serial ports at each level of firmware because it saves you a ton of work to quickly see what is going on (is it working, what version, etc).
The fact that it seems to be completely Zilog based is also interesting. That makes me think this box was used as a test bed or for R&D for some consumer product, or at least not a government only product. I'm a lot more familiar with 90's junk, but i don't think Zilog stuff saw a lot of use in aerospace or similar areas.
This video makes me miss my crusty dusty lab with its mix of 90's and modern hardware, all custom made with 80's design like the box you have! See if you can dump those roms, and then look for ascii text baked in (with all offsets). If there is something like version info for a boot, it will be in there stored hard coded

It's an STD Bus machine ( en.wikipedia.org/wiki/STD_Bus ).
Edit: The board with the four 40-pin packages and which is connected to the ZIF socket board appears to be a Mostek 3870 system ( www.cpu-world.com/CPUs/3870/index.html ), which is a direct derivative of the Fairchild F8 family ( en.wikipedia.org/wiki/Fairchild_F8 ). Wild!
Edit 2: Z280 is a 16-bit extension of the Z80. TIL! ( en.wikipedia.org/wiki/Zilog_Z280 )
More edits:
- The 6402 is one of the earliest single-chip UARTs I'm aware of. Both 6402s are associated with the expected level shifters for RS-232, in both cases in the form of the little 8-pin SN75150 driver on two outgoing lines and the SN75154 receiver for four incoming lines. One line in each direction will be for data (TX and RX) and the others will most likely be modem status/hardware flow control.
- So there are... what, three separate CPUs in that thing? Four? And at least three different architectures too (F8/3870, Z80, Z280). Wow.
It's a beautiful machine. Those handmade cards are works of art. I'm glad you were able to rescue it.

Correction: The "Z80 math coprocessor" is actually a Z280 CPU; it is binary compatible with the Z80 but is *much* beefier, including instruction pipelining, a built-in cache and MMU, and more complex instructions like hardware multiply/divide, similar to an 80286 vs an 8088. Being Z80 compatible it could probably run CP/M but considering the rest of the hardware it looks pretty custom. My guess would be the Z280 is the main CPU and the other CPUs on different cards act as coprocessors for other subsystems.

That EPROM programmer's processor card is based on a Fairchild F8 CPU which is made up from those four 40 pin chips; a Mostek MK3850 ALU, an MK3852 Dynamic Memory Interface (DMI) to control additional RAM or ROM (or EPROM), an MK3854 DMA controller for the MK3852 connected memory, and finally a MK90071P a.k.a. MK3851 Program Storage Unit (PSU) which contained 1 KB of program ROM and handled instruction decoding. The MK90071 number on the MK3851 is the ROM mask number for the EPROM programmer code. The Z280 was to the Z80 like what the 65C816 was to the 6502, but much more so. It looks like two complete separate systems in there with the EPROM programmer as a smart peripheral. Everything is serially interfaced and the EPROMS on the card likely contain a very basic ROM Monitor program for developing firmware on the Z80 system. The floppy controller PCB also contains a 1K PROM, possibly for boot code. I could tell more, but you keep moving the boards around randomly and holding them at angles so it's terribly hard to see.

WOW! I haven't seen a Bus machine in years! Back in the late 80s, I worked at a brick factory where we had a packing machine that used an articulating robotic arm. It used a full array STD bus to run the software. As the bricks came down the line, the arm would swing around and grab the bricks than pallet them up. It only had a maximum of 12 complete movements and 3 pinch positions, the bus array was as tall as me and had 12 total boxes. Gawd, they were a pain in the arse when one went down. We kept extras in a storage room because they had to cleaned and maintained constantly, they would suck in dust and the circuits would get damaged or burnt. I even remember one catching fire when a capacitor popped...You'll never forget the smell of burning circuit board and brick dust, it smells like burning hair ugh. Great find! this really brought back memories...both good & bad lol

Back in the day we called those riser cards "extender cards" because they would extend the signals outside the card cage so you could actually probe signals on the card you were troubleshooting.

Extremely similar to pieces of equipment I have that were obsoleted from radio telescope installations. They were rack mount, custom made with bespoke proper tools such as panel punching, nicely engraved fascia panels, custom PCBs but hand soldered/soddered, good nylon card guides, cable hold-downs, star washers under screws etc etc. They are well made because they had a government budget to do it, and it had to live a long service life.

The security was really good on the Star Trek Computer Too. "Captain, Someone is accessing the Transporter" "Lock them out Mr. Worf".... Guy in transporter room opens a unlocked panel and moves two control crystals... "Captain, he has over rode the lockout and transported off the ship."

So - at one point in my career I worked at a Company that produced alot of high end sensor equipment, and they had to support said equipment for a life of at least 25 years, they had alot of this sort of kit around - none of it was my responsibility so I barely got to interact with it much
Long story short they had alot of sensor calibration gear in ancient rack mounted machines, in cases just like those - with machines built 20+ years ago either in house or typically from small engineer sector businesses that would sell some kind of bespoke equipment that would come with a machine as part of the rig. Mega obsolence in place, if there was ever a problem with these they'd be out of order for a long time whilst guys who had no idea what they were doing would try diagnose because the guys that used them in anger were long retired. They'd have serial coming out of the senors, into these machines and out again at times into other hardware. I'm talking 2010s with even Sun servers and VAX terminals still being actively used
Whilst I couldn't/ wouldn't say that is the purpose of this machine, the similarity is pretty remarkable

My first job was in a computer store starting in the latish 70's. All that wire wrapping was original From the factory. When IBM was selling for $10,000, these sold for around an easy $4,000ish. I couple of the boards are home brew. We sold the blank cards. Unfortunately I'm at that age my memory is failing and I can not remember muck about them. I sold 3 in my first year. All to the same guy. He was a Dr, and set up his office. One was a server and it was headless. The other 2 both had video cards. It used the old green or orange screens. I may have some documentation in my filing cabinet, but it is in storage, and right now in New Brunswick it's COLD!! Especially for this old fart! I plan on going down there sometime next week or the week after to bring a few things home and dropping some stuff off. I'll take a quick look through the cabinet, and if there is anything there I will male it out. I have cleaned out a lot of that stuff as I never thought I'd see the day I would wish for the old slow machines!

The whole package looked like something out of Tektronix so I was pleased that it had the Tek label on the transformer. In a previous life I worked at Tek and took a leave of absence in 1973 to go to the Oregon Graduate Center ( later to become the Oregon Graduate Institute and eventually merged with Oregon Health and Sciences University) to construct a special piece of test equipment. When I completed that project I decided that it was more enjoyable than my job at Tek and stayed there until retirement in 2008 at 70. The prototyping boards looked like some we used at Tek and it seems possible that it was prototype for a piece of test gear. When I was in the component evaluation group at Tek, we would often have to build a one off piece of gear for testing some particular component or group of components. I later moved to the CRT instrumentation group where we designed and built test equipment for the CRT manufacturing department. In that group we usually made custom circuit boards since there were typically multiple pieces needed for the large number of test bays for the testing process. The wire used for those hand built cards looked like it was transformer wire which seemed logical since it was easily available from the transformer department and was not going to have insulation melting problems to dal with. I am afraid that I have no idea what was built for and could have easily been someone's home project. A lot of us built our own home projects using our experience from work and that build looked like something I might have tried. Hand manufacturing such equipment just seemed normal for a lot of us.

Tech Time Traveler might be a good resource for deciphering a machine of this era.
It feels like it would've been used for some sort of scientific or industrial control application to be. It looks pretty clean so maybe not a shop-floor system. Then again, it could've been tucked away in a clean environment and just operated from a nearby terminal. The newer bits obviously suggest that it was actively maintained and expanded for a long time.

Card ejectors are what's missing on the corners. And yes, that is enameled magnet wire used for rework on the back. Mil-grade stuff had it all embedded afterward in epoxy so this is likely not that. They would also have littered everything with identification and serial numbers, also in epoxy, each numeral applied with a tweezer and a little rubber stamp. In yellow.

My Z80 system from Heathkit used a terminal that emulated a monitor system (VT-100??). 2 8” DSDD floppy’s, and 2 5.25” DSDD floppy’s. I think it was the H89. Ran CPM and later MSDOS. It was a workhorse and I used to write Z80 Assembly code for Z80 projects I used to wire wrap.
The PIO is parallel input/output (2 8bit ports) with printer handshake but also highly configurable for bit input and output. The Serial Input/output chip (SIO) is a dual port serial (both ports can be asynchronous or synchronous) with modem handshake. The Counter/Timer IC (CTC) is used to generate the clocks for the SIO baud-rate generation. The CTC has 4 independent counters or timers as needed by the hardware. Precision outputs for different clock frequencies.
Love the Z80 family of chips. Very well engineered.

The EPROMs might contain clues as to the source of this machine (e.g., a message printed to a serial console).

z80 mini computer running CP/M, I used to go to a video store for rentals, and they ran one. This was in the late 80's, I seem to recall it used a serial terminal as the console.

Being a rack mount system I find it extremely likely that this would have just used a serial terminal and not had a display adapter

Z280 is a 16-bit version of a Z80, so I'd speculate the actual Z80 card was the original, and the machine was upgraded to a Z280 and the old board just left floating around in the case.

Looks like aerospace ATE I started in 1972 at King Radio that made Avionics for aircraft. They had 2 different test equipment departments. Automated and Custom ATE and CTE. I worked in CTE. Back then it was very expensive to lay out PCB's A draftsman to lay it out, artwork fees and several hundred for the boards. They would hand wire them. This looks ATE, they would have a large box of boards and cables going out to a bed of nails, That's what they used for laying a PCB production board on for testing.

Using early CP/M systems by terminal was particularly common as I understand it. I mean, I was using terminal time-sharing systems up through the late 80s at University of Delaware and University of Utah. A video controller integrated with a CP/M machine wasn't so common.

I worked as an electrician in a steel rolling mill (retired now) and this looks like something that was used to replace some analog logic. Proms were used to help match different production modules as needed. This was all done inhouse as you could not buy anything that would work with the local setup. Serial ports may have gone to seven segment displays

Around 1980, I helped build industrial control systems and this computer is very similar to the stuff we did. We even had the extra solder wick on the riser boards to handle amp loads that increased over time as we got more power hungry chips. I actually kind of miss those days when I could have told you exactly what every chip and/or trace was for.

Wow, you got yourself a treasure trove! Z280 is a very fast enhanced Z80 with expanded memory (bank switching), and extra instructions. I built a CP/M computer in the mid-80's using similar technology (Eurocard experimenter board and wires, 64-pin Elektor backplane), using a 10MHz HD64180 CPU, which is virtually the same as the Z280. Also built a floppy controller (FD1793 I believe), a Z80-based VDU/keyboard controller, and a SASI (not a typo) controller to run an Adaptec ACB-4070 SASI-to-RLL bridge board. Hundreds of individual wires, can't even fathom how I found the time for this back then. Wrote my own Z-80 monitor program and CP/M BIOS. I really wish it had survived the cleaning frenzies, but unfortunately it's gone.

All those extra wires reminds me of when I built my Heath/Zenith 148 (ca 1984, my first computer). Although, H/Z was nice enough to show a diagram of where the trace jumper wires should be and what (if any) component should go with it. The video card never did work, and, at that time, there were H/Z stores you could go to and exchange non-working boards for good. Great vid

I wouldn’t say “home made” necessary. I worked in a prototype lab at ITT Defense Communications in the late 70s and. We made lots of stuff like this. A lot of it was wire wrap.

Having worked in steel industry research and development from 1975 to 2013, I feel this has the look and feel of the sort of the sort of equipment we might have made (we didn't, I'm in the UK). A wide range of dates on the I.C.s and the modifications suggest it might have been made for one purpose/project, and rebuilt for another. In the 1970s and 1980s, if it needed to generate graphics there were "graphics generator" units, also 19" rack mounted, which took HP-GL commands over RS232 and created the video signals.
If the method being developed succeeded a more finished design would have been made.

This is classic Tektronix R&D type of development computer. Lots of gold plated circuit boards, and the crimped wires were the normal engineers method of design.
I was at Tektronix from 1980 until late 2000, and have seen plenty of these during my time there.
Could have been used for prototypes of there graphics terminals or Phaser printers.

385x parts appear to be the components of the Fairchild F8 microprocessor line:
en.wikipedia.org/wiki/Fairchild_F8
3850 CPU, 3851 1KB ROM, 3852 Dynamic Memory Interface, 3853 Static Memory Interface, 3854 DMA controller
According to that article Mostek released an improved version of that CPU, so no surprise there are also Mostek parts on that board.

I'm betting this was some prototype/engineering built test interface equipment for Boeing. When every plane is being qualified, a lot of instrumentation is mounted in it and the equipment is short run/custom built. I designed and built a combo vga computer display/analog video display/vt100 terminal for such a setup for Boeing about 20 years ago.

It's a CP/M STD-Bus machine of some homebrew vintage. I ran an IMSAI 8080 S100... brings back memories. Most all CP/M systems were terminal based via RS232, You'll need to find an old ADM-3a, VT-52, Hazeltine 1500 or VT-100 terminal.

Myself and three other guys started a company out in Silicon Valley. I wrote the software, they did the prototyping boards using your “hodge” technique. It was highly effective and quite quick to implement. The only drawback was if you found out you had made a mistake ten wires back you would have to carefully pull the unsoldered wire through pack of good ones hoping nothing would snap.

I actually bought 4 gigantic dual 8" floppy drives made by Wang from a surplus auction in the early 80's. Absolutely massive units, with linear power supplies inside. The two 8" floppy drives. And then a card cage that held huge circuit boards with 30-50 74LS logic chips. Nothing bigger. There were 8-12 of these cards.
All of that just for a dual 8" floppy storage system.
Would love to have those today, simply as a source of parts.

Homebuilt CP/M machine, maybe for industrial CNC or some other numerical control? A bit pricey and complicated for a hobby machine....
I say industrial as it looks beefy enough to be running 24/7 in some plant... The PSU was stolen out of some Tektronix equipment and definitely over-kill for the purpose. It's not S100 though.
I have done similar wirewrap jobs in my past but this guy didn't use wirewrap so it would have taken a looong time to wore though boards up. Nice neat job though.. well done. A quick tip one doing a neat wirewrap job is to put in "croquette hoops" of bare wire on the wiring side prior to starting the wiring then use the hoops to guide and hold the wiring.
The little plastic thingys that were missing were called "card extractors".
Cheers,

Those boards are definitely Tektronix made, but it is hard to tell where they originated from. Tek made a lot of automated test equipment in the 60s-90s, so this may have been a prototype system, or maybe just something that a Tek engineer cobbled together. If you could find some additional part numbers, some of the Tek-savvy community might be able to track down the data, maybe even an instruction manual. Great video, love the channel. Cheers!

Prototyping station/University research project.
Get an idea, work out the logic, make the board, install it for testing.
If it works, you have a new functionality for your computer!
I saw some amazing machines when I worked at University.
Example:
A multi-touch stylus pad in the form a glass slab; CRT behind it.
Solid slab of glass, about 22 mm thick, slightly larger than a typical monitor of the day.
Dozens of piezo-crystals lined the edges.
Sequential 'pings' through the glass would be attenuated by finger contact, more pressure, more signal loss.
By pinging from many different locations, up to 4 finger contacts could be read with confidence.
All hand-made using common shop tools, 1973 according to the label.
No CPU: all 7400 series logic, analog or digital outputs.
It got sold 'by-the-pound' at surplus...

In a conversation with Don French who was one of the developers of the TRS-80 Model I he mentioned that he liked the S100 bus, and based the Model I on the S100 bus, and even wanted it in the computer, but Tandy wouldn't have it because they wanted their own proprietary system instead.

I remember a prototyping system in the late 70's early 80's that utilized a special type of "enamel" coated wire that was actually a plastic coating that would vaporize when you applied soldering iron heat; it eliminated the need to strip the wire. I don't recall the name of the system but it looks like it was utilized extensively in this box.

Wow, this is cool! It's like a time capsule of old prototyping and small scale building techniques!

You need to read those roms to get any hint till then all speculation unless the builder(s) are watching

DZUS fasteners, I've seen those screw locks on old military equipment.

I have a feeling that browsing early issues of Byte magazine (started in '75), one would find something made of many of the parts we can see here, back in the era of partly homebrew/built in kit form computers, and yes, this is a reference to Shelby's video on his complete collection of the magazine.

At first glance it initially looked like the rubidium reference clock used by the BBC in their HF broadcasting stations.
This "homemade" equipment was commonplace with them. Their various teams, working as if isolated islands of development, were scattered about their network, of which was full of this shabby looking heath Robinson stuff - aluminium absolutely everywhere - even the toilet seats were made of aluminium!
When you threw this box in the bench, it sent a shudder down my spine.
When I went to work there 20 years ago, this bespoke stuff was antiquated then. It was quite a shock to the system seeing such primitive systems serving the network like that.

All the boards (even the hand-wired ones) inside of the unit have E0000XA or ...B numbers. This means those boards were produced by Tektronix for internal purposes. So this is either a unit which was created to do some factory internal development or one of the engineers took the boards and other parts home to build his own computer.

Looks just like a piece of rack mounted equipment you'd find on any of the subs I served on that still had lots of legacy equipment rolling around the new stuff. Cool find.

If someone has never had-wired circuit boards like that, they have no idea how hard it is to do it right.

I have seen very similar one-off / modified computers used for tracking radars. The radars were used on a military test range in the 1980s. The computers were used for an upgrade to the signal processing side and/or the control of the radar. The computers were mostly hand made, the circuit boards were made in house. The jumpers were for correcting errors in the design or using slightly different components. There were probably only 2 made, 1 for spare.

Awesome find! I hope yall can find out more about it, would love to see a follow-up vid with some more info

This might be the most beautiful thing I've seen on your channels so far. I love those PCBs with wavy traces, presumably hand-drawn. I'm having a hard time finding anything from the history about how exactly such circuits were made. I would love to see a video documentary with someone plotting those. And also the later techniques like using a tape and things like Bishop Graphics Inc. templates and how scaling down was done. There seems to be very little on those topics, maybe due to the rivalry in electronics between countries. It's a pity. Finding someone who worked on this machine, whether it was an early expensive Arduino-like home project of a hobbyist or commercial prototype, to tell the story of it, would be great.

Z280 is a 16bit Z80. The Z80 itself had 16 bit registers and in a lot of ways was like a 16 bit processor although only an 8 bit accumulator.

I have a lot of respect for who ever wired these cards up.

It reminds me a lot of the things my dad used to work with in the aircraft industry. From what I've seen during family day visits, you either have a "server" that connects to some dumb terminals through serial connections or a buffer to fit between equipment and a plotter.

My first though with any strange/mysterious computer was support equipment for testing, there are a lot of custom and strange boxes that were used to interface with sensors/testing equipment. But it looks more like a true home-built computer. Proto boards for actual components, home built floppy controller and rtc/serial board, and to my mind that Sony SRAM chip. The computer was built and modified with considerable skill over at least 5-6 years. I would assume there never was a display controller, as serial access was very common in the late 70's when this was being started. Further, I assume it was a hobby project by a real electronics/computer engineer, those proto boards are just beautiful, and routing 5v along the perimeter of the board just screams of experience.
Many cite cost or quality of materials as a factor against being a home build, I disagree, just because there were cheaper alternatives doesn't mean some wouldn't buy it. And the level of detail and knowledge going into these components hints at a professional building it, so maybe some stuff from the office just fell into his bag. Or he was allowed and or encouraged to take a few odds and ends home.

The funky IC sockets, component choice, font on the boards and the circuit board layout says Tektronix to me. That would correspond nicely with the transformer. Probably a one-off test system for internal use.

That enamelled wiring is beautiful work! Whatever that machine is, it was a real labour of love. Maybe you should consider framing and wall-mounting those boards!

I could tell those boards were laid out by hand. I worked as a test engineer and built several test stands that interfaced with an Hp85 and several HP analyzes and volt meters. We created our own back plane which had a half dozen cards for signal processing and I/O. We had a pc lab so we were able to layout all of the boards. All painstakingly done either by cutting rubylith or using Brady tape and stencils. We did everything 2:1 and then made negatives for exposing the boards. It really was a dream job!

Beyond the fact that the riser cards were also likely used to make the ROM programmer accessable in addition to their normal diagnostic function. If I had to wager a guess I'd say it looks similar to an early TRS-80. Like maybe a development model or something. Beyond that I'm stumped. You might try asking @CuriousMark if he knows anything about this unit. It's certainly fascinating...

To me, this looks like a device (I can't call it a computer because it's more than one computer in one case) that was part of the McDonnell Douglas DC-10 control module, which served in this class of aircraft from mid-1978 until 1985 when it was replaced by a more modern, smaller and more powerful device.

That point about Star Trek never mishearing the cast made me imagine something along the lines of: “computer, I need a 3 second tachyon burst”; “okay, 3 second tetryon burst, coming right up”; “no no that’ll be dangerou-“ and then the ship blows up.
My personal pet peeve is when I ask for a two minute timer and I get a ten minute one. Or a quarter of an hour timer and I get a one hour timer. Different types of mishearing for each, but both happen about 10% of the time for me.

A college near me had around 6 of these (or very similar) sat in the corner of a storage room in the early 90s. Each had similar cards to what you see and one had a HDD (5MB I believe) and what looked like a memory mapped jumper board (confirmed by a old nerd and tutor who worked there) with over 500 wires.
He would occasionally fire that HDD one up with a grinding a screeching noise and some of the loudest beeps you've ever heard!
Apparently they came from a "database farm" at a local ship builders/heavy engineering company.

Adrian, are the two backplanes even connected?
Based on the fact that both sides had their own CPU installed, (Mostek 3870 in the right backplane and Z280 in the left backplane), and each size had both RAM and Serial IO boards, I have to wonder if this chassis might actually have two almost completely independent computers.
The only thing the left side is missing is a ROM.
Maybe this is a development platform, where you access the right computer via serial and then use it to upload software to the left computer and debug it. But that would require partial interconnection between the buses.

Those were the days when you built a computer "You literally built the computer!"
Some amazing work went into that masterpiece!

Back in the late 90's I was working in elevator maintenance and I remember we had some elevators from the mid- to late-80's that were controlled by similar computers.
We had maintenance units that provided graphics, keyboard and HDDs to perform software updates or changes.
The riser cards were used to make the cards acsessible for onsite-troubleshooting.
Empty spaces in the housing were usually used to store spare cards.
The power supply units often were modified to provide some extra power and/or to bridge power failures (sometimes by big capacitors, sometimes by rechargeable batteries).
Later versions also provided control-LEDs in the front panel that showed the most common errors to save time for diagnosing.
Since this looks very common, the units we used back then were more evaluated and normally had standard PCBs without all the wild wiring on th e back.
I don't think that one of these self-engineered elevator controls have made its way from Germany all over to your place in Portland. But since this is no rocket science, I could imagine that someone over in the U.S. developed something similar to the units we used back then.

What a neat piece of history. Would love for you to find the original owner and interview them.

Fascinating! Some kind of development chassis? It looks too expensive, in money and time, to be any sort of homebrew. I wonder if dumping the ROM's might provide a clue?

Reminds me of the computer controller we had back in 74, that was used to run instructions to repair different Avionic gear, seems like it was more advanced since it had a floppy controller and real memory IC's. The ones we had iron core memory, and reel tape drives, first you would put on a bootstrap tape in the upper reel, then once you got the machine kickstarted then you put on the version tape, then on the lower deck you put on the program tape for the program to tell what instrument to use and what settings to check that part of the avionics box you where testing.

No idea what this exact machine was but definitely something custom. The EEPROM programmer reminded me of a story my dad told me of when he repaired Apple machines. Came across an Apple II with some wacky custom cards and 2 hacked-in EEPROM readers in holes cut in the case at the front. His best guess is it was used for copying cartridge ROMS or something as the custom card allowed the contents of one EEPROM to be dumped to RAM, then written to the other. Made sense also since it had lots of RAM upgrade cards. Wish he still had it.

I had 24 hours to think about this. Start with the cards that have a known pin out cpu. You should be able to map the bus on from there. Presumably the rest of the cards will follow the same standard. Doing so will also help you troubleshoot the backplane and the voltages on it. It is very possible if there are other voltages besides 5 you can look at the cards with ram to further help map the bus. It's as good a place to start because once you know the bus you can figure out part by part if things are not working. But first map the bus then test the power rails.

The NEC 765 floppy controller is pretty late relative to the rest of the system... definitely fits with the idea that this was adapted over the decade or more that it was used...

I have no problem seeing this as a serious hobbyist's home built personal machine. It almost certainly *evolved* over many years. For instance, it might have had many different cpu cards over time etc. The handbuilt cards are amazing and very consistent in build style. Nothing wrong with terminal interfaces. People wrote software and books and did serious science with machines like this. Graphics are not always necesary. Also, just because this stuff wasn't cheap doesn't mean it had to be a business or institutional machine. The lack of labelling suggests this was one person's machine. Some people pour their money into hot rods or boats or vacations or big families. Some people build their dream computers (and maybe some of that other stuff too). This is definately outside of Adrian's wheelhouse. I hope he finds someone to take it on if he's not gonna try to make it work again. It looks pretty complete. Not obvious that it won't boot CP/M off of those roms, btw.

I opted to submit my assignment for my TTL digital course as a physical built unit. you could have submitted just the design, but I like building stuff. i wasnt great at digital logic, but managed to design and build a discrete logic digital clock. the combo wire-wrap/point to point style Is a really satisfying way to build a dense, pro looking board. until you look at the back... but I very much enjoyed the process
I only got an OK grade for the project, because it was a pretty basic design. but we did use it as a demo unit for other classes and it proved a very robust build. If i was 20 years younger, I could really see my self rolling my own Z80 CP/M machine like this.
I built my first PC with the proceeds of my 12th birthday money. I made it known that I didnt want any plastic rubbish, but needed a bankroll for this project. I got a VGA screen and a 800mb HDD n some cash. enough for a Mobo n ram n awful GPU. case, CD, sound, better graphics, were added over the years. I 100% Grok the origional builder of this rig. such things are not bought, but lovingly crafted. my pinnicale was a hodgepodge 100% DIY watercooling rig that got my Athlon 2100+ to benchmark as a 3500+. 3200+ was the fastest off the shelf. Alot of ram tweaking went into that. Dual PSU (one for the mobo only, the other ran all the disks), Full tower AT case that was modded for ATX, window, neons (this is pre CCFL's, neon baby), paint job. 7x HDD's, all PATA. only weighted around 30KG. everything that could be modded was.
I'd love to have a pint with whoever built this rig and just let their eyes glaze over as they talk about their baby.

I'm no expert, obviously, but running my imagination I came up with this wild guess:
It could come from a small company or department of bigger one, that designed some devices / chips / software for such. I highly doubt this is a private machine.
What threw me off the most at first was having programming logic inside a rackmounted chassis.
wouldnt it be much more convenient to have it more accessible? as a private solution i would never make it so inconvenient to access. i had built a 90° angle raiser card and a cut out on the chassis to get there probably.
but in my scenario it would make some sense. If a team of maybe 3-4 people would write code for a project on their client machines to programm something and "upload" it via serial/parallel
the machine would get instructions like what type or chip is used and what addresses to write and right away burn the rom onto it and just sent a "completed" message back to the client machine when its done.
at least to me that would explain why there is no video neccessary, if all it did was giving status messages and writing roms on to an IC
That computer would be mounted in a rack maybe along some sort network storage for archival purposes or something. like saving revisions of what they did (and didnt work)
leads me to a different version too. what if it was used in clean room reverse engineering? i think i heard of it once that creating own boards and stuff was necessary for that or am i wrong?
finally, in a heavily customized machine like this, i'd be surprised if there is anything unpopulated for any reason. i think it is straight up missing and maybe that's why it is not making sense to people who deal with computers a lot.
if they went through all the trouble building this, i just cant imagine an empty socket for no reason.

I can't imagine how many days/weeks it took to painstakingly build that system!

Makes me think of some of the early automation gear used in broadcast. If something failed or it didn't quite do what was needed then out came the soldering iron and there would be braided copper and caps bodged all over it to quiet down the RF blasting from a nearby transmitter a problem I still deal with and about the only soldering I do these days besides making cables. It's just board swapping if not entire unit swapping. It is difficult at times because the station owners are still in the mindset that the chief engineer could fix anything with a trip to the radio shack down the road. Such things just do not exist or are not possible any more. Newer stuff doesn't even come with board schematics or service manuals any more kinda back to the no user serviceable parts thing again. I doubt this was the exact purpose of the unit but given how many of us can go yeah I have seen something like that means it's overall style/design was used for a bunch of custom equipment. My closest guess that would fit with everyone else's is some form of early industrial control/lab/telemetry/automation system before there were a lot of standards and off the shelf components in that area. It of course would have evolved over the years as technology and needs changed until being retired completely. I hope you will find a way to dump the eproms and get some clue as to who was behind it but I am betting give or take dodgy caps that this thing might fire up enough to give you a serial console or two. Also Mr. Carlson might have an idea if not know exactly what it does by looking at it.

Adrian living his best life right here !
Great Vid . Nice archeological exploration .

Those homemade boards are beautiful that's basically something that's a lost art in today's computer world I hope the corrosion on the clock can be fixed and I hope that it works would love to see a part too

We had a similar box where I used to work. It was issued to us by a government agency and the only ports were power and network. It has a CD ROM drive. All black paint, no markings whatsoever, and every screw and panel was epoxied shut. We were shipped the box, told to install it and connect it and leave it alone. Once in a while, we got CDs in the mail and it was marked in the order to install them. Put in a disc, wait until it popped out, insert next disc. No other instructions. Yes I tried to read the disc. It was all encrypted. That black box ran on our network for years and was actively sending and receiving network traffic. Eventually "they" sent a shipping case and it got sent somewhere.

I was an AEGIS Comp Tech in the Navy. This gave me serious flash back to some of my gear that ran the Combat systems in the CIC. It is not exact, but wow!

I had something similar to this back in the late 70s early 80s. It was a development system based around an S100 bus back plain. Over the years it was modified and hacked about as it was used for different projects until it ended up in my "useful junk" pile, and got parted out. I wish I'd kept it now as it would be great to be able to play with it again.

Someone ought to show this to the TH-camr "Tech Time Traveller." This looks like one of those home-built computers from back in the early days of computing, like something you would put together based on plans/schematics from a magazine back in the 70s (or maybe even the 60s?) Tech Time Traveller specializes in those type of homebrew systems, and might know a thing or two about it.

Seems industrial or scientific, and surely functioned as some kind of server. Realistically, I think you've just got a bunch of spare parts. I suppose you could try to power it up and see if you can communicate with it serially somehow.

Would love to see the ROMs dumped. Maybe you'll find a clue, like a text string with a company name, or a testing prompt. This definitely looks like a custom industrial controller of some kind. I used to hand build test panels for testing electric motors, at my old job. We were just doing analog circuits to connect things like motor windings to off the shelf text equipment, switching the windings read based on hall effect commutation signals, so we didn't need a whole computer inside, but it's the same principal. All hand made equipment meant for a specific application. You might have a few identical panels, or a singular, one off machine, depending on the application requirements. For the stuff I built, we had maybe a dozen test stations around the plant. I was responsible for occasionally making a new one, as well as calibrating and repairing the existing ones.
The nature of what you have makes me think it was operated remotely, by way of a terminal. I think that's the right assumption. With so many serial interfaces, I very possibly could have been connected to not only a terminal, but one or more bits of industrial hardware, with serial control I/O.
About a decade ago, I snagged a really intriguing bit of custom industrial control kit. It has dozens of BNC connectors on different modules. Some are marked as monitors with In, out, and monitor BNCs, Others have BNC marked with things like Clocks, burst clocks, indexes, etc... No idea what it all does. The highlight of the device is a module that uses TI smart LED displays and thumbwheels to read or load data to or from various addresses. No idea what it was used for, but it's neat that it can power up. It's obviously some sort of custom digital industrial hardware, but it seems to be all discrete analog and digital I/O controls. Very interesting.

You can indeed still buy those odd sockets you mention around 5:40--I use them all the time for making sockets for parts that aren't DIP or SIP (and you can get them rated to quite high temperatures too, so I use them for that as well--my job involves testing electronics at up to 175 °C). I get them mostly from Mill-Max, but another company called Preci-Dip makes them too, and I'm sure there are others; Samtec might make them too, I wouldn't be surprised.

Those "screws" on the top are Dzus fasteners. Start looking for 7805 regulators! This does not look like S-100, but does look S-100-ish (maybe SS-50? I'm not sure.)

24k is basically the bare minimum of ram needed for cpm with a relatively standard bios the programmer would have access to approximately 4k. This would depend on specific customization... Very plausible roms were used for program storage with very little ram, it's also very unlikely the "display" is just a serial terminal, as display routines would take much of the remaining 4k.

Since I can only have one pinned comment, I'm consolidating there. Side note, I plan to dump all the ROM chips with hope they can give us a clue about the origin or this machine.
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I got an email from a viewer:
"Many of the parts of the units were made by Tektronix. The case with the "special" openers are Tektronix stlye. The powersupply comes from a Tektronix 31 calculator. The numbers on the PCB (EXXXX = Tek prototype boards) and arrows indicating pin1, the style of the pin-row headers, the style of the extender boards,.... Thats tektronix all over the place. Since you're from the protland area you should contact the vintageTEK museum. I think they can help you to identify the unit."
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I reached out to the TEKmuseum and heard back from Bob: "The consensus was that some boards were indeed made by Tek. But 'Ennnn' numbers imply an engineering project, as opposed to a product for sale. The boards are the same form factor as used in the first Tek terminal, the T4002. As to whether the wired boards were home-made or Tek-made, we couldn't decide. But it looks like a home computer made with partly Tek-made parts. A lot of employees were doing the same thing in the late '70's."
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Also another TH-cam comment seems to be revealing:
Sam Cross: Greetings the device you have is part of ATE system bulit by a company I worked for in the early 80's in salem oregon. It was bulit for one of their customers on contract.. please contact me for more info.

Wow those cards look amazing! I wouldn’t be surprised if this came out of a physics lab. It reminds me alot of the stuff I used to use.

5:19 could be 7-segment displays perhaps?

See if you can read out some of those roms on your retrochip tester and see if any of the dump is legible - maybe a copyright comment or sys reference or maker clue?

It is a "server box" for an automotive assembly line. These are the modules that hook up to the different arm "robots" on the lines. May have been a diagnostic module, not a main one.

Whoever made that computer was clearly very knowledgeable about that stuff... those custom boards are absolutely beautiful

It's a time machine!
If you can figure out how to get everything going & apply 1.21 gigawatts of electricity. You will have access to the secrets of all mankind! 👍😎👍