Additional information from Patron Peter Kooiman: it appears this drive is the (or is similar to) the Priam DiskOS1070 and that the interface card is the Priam Smart Interface. There is documentation on it here: www.bitsavers.org/pdf/priam/DISCOS_1070_Product_Specification.pdf www.bitsavers.org/pdf/priam/SMART_Interface_Product_Specification_Nov80.pdf It does require a spin-up command so that explains the lack of activity! Computer Design 1981 volume 10 has an ad for the drive: US$1985 with the interface card included, power supply an extra US$295 Ad: imgur.com/XZPVZ9w
If you reference the #4 from the listing of defunct HDD companies, you will notice down in the tables that #6 lists that Priam used/contracted Hokushin Electric as the assembler for the HDDs itself in the early 80's. So that would make sense. 👍😁
That's a really great find. Reading the manual explains the hour counter, mean time to failure 10 000 hours which is just over one year. They do say that most repairs should be completed in ½ hour.
I found old adverts 1980 to 1982 they started at $1899.99 (matchmaker technology) other info i found was a page in mini-micro systems 1982 sad to say its digital scans are gone
i recognized that pcb before it need pc to tell it power up to turn on motor if no communication from pc it does nothing it in standby mode saving power waiting for communication from pc when it get communication from pc it switch to power up mode i heard it from someone own it just trying save it self from not being worn out unlike other hdd just get power and spring up i think there is way troubleshooting it if you have hook up to pc with diagonal in slot can be come handy i dont know if they video still out there or not i take look n see what can find
That power supply was built in Hackensack NJ. I was the computer operator for their business applications. This unit was most likely early 80's as the later part of that decade RTE from Wisconsin purchased PowerMate rebranding was RTE/PowerMate. BTW that was not the original power cord.
Ive used a few different PowerMate supplies, they are good stuff. Those arent a good match for the drive... I guess the last operator had them on hand, so thats what he used...
We used to maintain giant 14" Shugart hard drives sold as Altos 8000 CP/M and MP/M systems. Total capacity 15 MB. We learned that if you checked the heads for continuity with a multimeter it would burn out the heads as the wires were so fine - and they used to spin up too fast and the drive belt would spin off so Workshop Terry devised a plan to put a 1 ohm resister on the motor to slow it down at start up - but it got hot. He them mixed araldite and heat sink compound to try and stick the resistor to the casting that the drive was built on. He found his mixture combined the sticking power of heat sink compound with the thermal qualities of araldite. Fun times.
The "Computer History Museum" has a link to a "CD-8010P" Hard Drive (Inside an Advanced Computer Design PDQ-3 Computer) You can also find ( from "bitsavers" ) "PDQ-3 System Users Manual Ver 3.1 Apr81" and "PDQ-3 Hardware Users Manual Jan81" (I'm not sure if the weblinks I added in prior messages will get deleted)
Makes sense, Computer History Museum is in Mountain View and that Priam board was made in San Jose a few minutes away. I bet that thing at some point passed through a place I used to work called WeirdStuff Warehouse in Sunnyvale, I miss that place heh
@@alakani Ah, WeirdStuff. The best place to buy swag from defunct companies. I still have my MediaVision screwdriver that I bought from that store. Across the street from the old Fry's that had "Enter" and "Escape" keys on the doors. Pre DotCom implosion.
It seems the only links RUclips leaves alone are links to other RUclips video's You can probably blame this on all the scam artists with links (and Telegram 'codes') to various get rich quick crowds (In reality, get poor quick, with their help)
Does that mean with the extra info we can have a part 2?? Basic knowledge only of electronics and logic and this was way above me but I was fascinated.
The spikes you see on the 5v rail and other places is caused by the long ground lead on your scope probe. 1: It picks up noise from the board and that is "in series" with probe so it looks like it is on the signal. 2: Your grounding is far away from where you are probing. Ground is not ground when it comes to high frequency AC signals. Always try to use a short ground cable to the probe as close as possible to the place you are probing.,
In about 1983 I was working for Link House publications as a Analyst Programmer. The computer room was quite large. 60 foot by 40 foot. Filled with 4 foot square hard drives. The operator used to walk around the hard drives every morning checking the temperature of the air coming out of the hard drive, One morning he noticed one drive was hotter than the others hence he closed the computer system down and called an IBM engineer who changed a bearing on the drive.
For some of us it does not matter that you might not get something going, it is still enjoyable to watch you work through your thought process, as we still learn from it.
I worked at British Airways as an HVAC Engineer, 21 years ago at their Data Center area, at Bodicia Hse. In the background on this Huge site there were a couple of Condemned Buildings, one of them was called Comet House, which was infact the Airway Staff Medical Center and Hospital. The Building had been 'Ear Marked' for Demolition but there was alot of Politics involved because of Asbestos Presence and was Boarded up. But, we got through the Boarding and went on a journey of discovery. Now, me being interested in Computers and Technology found a Redundant Storage area of Dozens of old Form Computers, Boxes and Boxes, lines and lines of shelving containing electronic components. Now, I saw a few dozen of the Hard drive and boards that you are exhibiting. They certainly weren't screwed to a Board like yours and were in a Proper or appropriate Container in a similar configuration to the Machine you are showing us. I noted the 50 Pin configuration and here you have revealed this to us. Apparently the PC's then were used for and by the Pay Offices and Staff Records.
In the mid-1980s, we had Hokushin hard drives - 5mg and 10mg attached in an outboard cabinet to a hot rodded MicroVax and the interface was Shugart ST412.
I'm guessing that drive was made prior to 1983, since Hokushin Electric Works was merged with Yokugawa to become Yokugawa Hokushin Electric Works in 1983. Back in the 90's, there was a massive text list of HD drive info called "hdlist". I tried to find a copy of it to see if Hokushin was on it, but couldn't find a copy.
Irregardless of this drive, it may be good idea to find and archive this document. If you looked at it in the past, you might remember some text that was definitely in there. Try to google all different things that could be in it in one search query. Did it just have names, or also some kind of parameters? Like heads/cyls/tracks? Or interface? Or size? If so, you could probably find some parameters somewhere else and google them all together. Try putting a dash between numbers that were close together. Although it could easily have been just an internal document that got passed about a few companies.
I demilitarised took apart and destroyed the discs in many of those like that at Puget Sound Naval Shipyard I was working for. And stripped out many boards on computer server towers for precious metals of gold platinum and silver recovery in the late '80s and early '90s. So I have seen so many of those. I would see that one there a lot. Those and tape drives. A lot of optical hard drives too. I loved stripping them apart. I would have to smash and drill holes in so many Hard drive discs. Some really old and very big ones. I saw so much cool stuff most did not get to see or know what they are and even now I am still learning what they were. Some were so secret I will never know. And they are so outdated now though back then they were very high-tech. I saw the first CD ROMs before most did. A lot of things the average consumer could not get or afford I had to play around with. I even saw many Commador 64 used that were on ships. A lot of them came through where I worked in a large tall pile on many pallets for me to ship to be sold in DRMO DLA auctions. Many Printers Tape and Floppy Drives and Monitors for them too. I would grab the best ones and play games on them till they died I would have many of them at my work desk in case one died on me I could not fix myself when on break or at lunch or get there early to play them tell I start working. I used them to make documents I printed for shipping things too. I made my own program for it just to do that.
I used to work for circuit (PCB) makers in the late 70s early 80s, and I would bet that the E.C.1283 marking is the circuit Manufacturers initials followed by the month and 2-digit year, Dec 1983. It was a common practice back then. For example, a company I worked with in Fort Lauderdale, FL was called Tropical Circuits and they would have put TC1283 on their boards.
Ah, the TMS2516, I recall when that was released and I know the story... or at least the outside view if it. The story starts first with Intel's first EPROM in 1971 - The 1702 2Kbit UV erasable EPROM. The was followed up in 2704 and 2708 in 1975. They revolutionized development since you could reprogram your ROM. Soon everyone (including TI) started copying it and racing to see if they could beat Intel to make a 2716 before they could. The one annoyance with the 1st and 2nd gen EPROM is to use them you needed more than just 5V. Well, Intel surprised EVERYONE when they introduced their 2716 which was 5V only (for reading). Also, it could reuse those supply pins for address pins so the 2716 an 2732 could use the same 24-pin package as the 2708. That made TI's 2716 inferior and incompatible with Intel's 2716 which forced it to change its part number. The TMS2516 was TI's "copy" of the Intel (5V only) 2716.
I haven't a clue anything Adrian talks about. I just enjoy watching all his videos, pleasant and intelligent guy talking passionately about his interests.
I remember some of the IBM servers we had used an option via the SCSI controller to either start up the attached SCSI drives instantly, or used a 'cascaded' start up based on the drives SCSI ID. This allowed them to start up one by one and reduce the load on the PSU. Pure speculation, but perhaps this drive is only programmed to spin up when it receives the correct command from an attached controller / host rather than when it's simply switched on?
Since the start current on drives this size was massive, sequential start was important to not blow a breaker or smoke some wires. I have an old 5.25" SCSI that takes 15 Amps to start (at 12V) and is like a jet engine as it winds up, and this thing is even bigger, so I don't doubt the external start signal required. I worked with an old NCR mini in the 90's, and its power supply was good for 200 amps at 12V for the 4 drive chassis expansion module, running off 220V. That monster cabinet was something like 300 lbs and about the size of a large tower PC of the time to house 4 drives.
The voltages seems a bit wonky. TTL chips need 5V +/- 0.25V. So, 4.7V is too low. You might want to adjust the 5V supply to 5.1V to allow for power loss in the cables/traces.
Patent Number: 4,638,383 Date of Patent: "Jan. 20, 1987 Page 21 states Hokushin Electric Works, Ltd., "CD 8000 Expand Your System Versatility with Low Cost 8 inch Winchester', 1980.
This is fascinating. The controller board certainly looked different than others shown on the channel - those strips - I don't think we've seen something like that on the channel before. It's fascinating seeing different ways people made boards and solved problems.
You might like to look at main board of Centurion computer that "Usagi Electric" is restoring. That one has actual wires (not traces) INSIDE the board epoxy. The video is called "Minicomputer Part 4: In-depth Look at all the Computer PCBs" at timestamp 19:56
I remember seeing ad's for very similar strips, they were advertised as bringing low impedance DC and bypass caps right up to the IC:s. These days with multi layer circuit boards with a ground & supply plain this is no longer an issue, but back then two layers PCB's was all most had access to
Back in my dim dark past of the early 80's I was working on/supported some Basic 4 (en.wikipedia.org/wiki/MAI_Basic_Four) computers and S100 devices around Sydney For Rank industry's one fun job was that they had an s100 card system that was installed in the Sydney(Australia) container port that some ham-fisted dock worker attempted to reseat some cards one card had strips like that but mounted 90" to the surface of the board they supplied the power rails and also isolated each row of chips my muscled friend had managed to break a few connections and making them intermittent. a couple of hours with a magnifier and fine wire fixed the issue in those days it was weeks/months to get weird parts by ship or $ 1000s for air freight so it was mostly surgery, canablise or invent something to replace what was broken once knocked up a replacement lm741 op amp out of bits to get a industrial metal detector working while I waited a week for a replacement part
Yes, 5.25", and 8" drives drew a ton of current on startup. I remember on Intel based servers, when the power supplies were getting a little weak, we would have to unplug the power connector from one, or more, 5.25" drives, and plug them in one at a time. Once they were all spun up, do a hard reset, and then you could load the OS. Once we got to 3.5" hd's, the current demands were less, but the problem remained due to a much larger number of drives. On the Compaq servers, they would sequentially power up the hard drives (by SCSI id order) as part of the POST, in order to minimize peak loads. Great video...not a failure at all.
I still have a Compaq Prolinea server in my "digital basement" (of course not powered on 24/7), and you can clearly hear the drop of the +12V supply while the hard drive spins up, as the fan RPM goes down. And that's just with the single Fujitsu M2623F half-height 3.5inch drive that was the basic storage option. The peak spin-up current is 2.5A @ 12V. Don't believe marketing touting this drive as "high-performance [...] hard drives, which increase the performance levels of high-end personal computers, workstations and network file servers", though. They are solid drives, but at 4400rpm and less than snappy seek times, they are mid-level for workstations and bottom-of-the-barrel for servers. An official option for that system was the Compaq SMART-RAID controller with up to 7 drives connected to it, and you would most likely buy bigger and faster drives if you went the RAID route. Of course they did staggered spin-up by default.
I worked on some DTC (Data Technology Corp) SASI controllers, integrating them into the Heath/Zenith Z-100 ecosystem. The Z-100 was DOD's "Desktop One" back in the 1980s and our customers were mostly military installations, and folks from the Heathkit world. 50-pin is almost certainly SASI, but that host adapter (the upper board) is a weird one for sure! "EC" is probably Engineering Change and a date-code.
Looking forward to part II of this very interesting hardware. Thank you Adrian for posting these even when there isn't an instant resolution. Gives me something to look forward to!
I have an old MiniStor 40MB 1.8-inch hard disk which doesn't seem to exist except in the documentation which came with it. I bought it NOS. It seems to have come out of a lot of disks which were made for one particular computer manufacturer. It was made in 1992, and it certainly wasn't made down to a price since it has a lot of parts on the main PCB which were quite expensive back then, and are still quite expensive today, an example of which are a few Sprague Tatamount tantalum capacitors which are designed for high reliability applications.
The spin up problem maybe because the drive is set on " Start on Command " this is set with a jumper on the drive itself it will power up the board but will not spin the drive until it receives a command to start the clunk you hear on starting the drive is the head locking to parked position.
The terminator pack you're looking at 41:26 is on the board directly connected to the drive, right? I feel like there is confusion here, if anything here is going to be a peripheral bus like scsi/sasi it's not going to be that, it's going to be the connector that goes from the other board -- presumably the drive controller -- to (whatever host adapter installed in) the computer. Like think about how ST506 drives were used with SCSI using ST506 to SCSI drive controllers like ACB-4000A you would then connect to your scsi bus, and those are later more miniaturized 5 1/4" hard drives.
Awesome video, as always! 27:33 There's a 4th option, I'm certain has already been discussed. Just sticky bearings, that often can be freed up by giving the chassis of the drive a quick and sudden "spin" by hand, in the direction perpendicular to the drive motor axle. Of course, this is easy with a 5.25" drive, much harder with an 8", but there's always a way! Has this been tried yet? Well, moving ahead to 30:38 I can see that you've ruled this out, as you've exposed part of the drive motor, and you could just spin it by hand there and see if it moves freely...and you've determined that the BLDC circuit is not even trying to spin the drive...anyway... LOVE this stuff, Adrian...we'll get the flux transitions off of this device yet for you!!!
Fascinating. I have found much info searching eBay listings and blowing up pics found there. If the item is sold you can still search completed listings for it! I was very frustrated for you at 32.00! I have actually contacted sellers to get additional pics of items and/or documentation even after an item has sold. In most cases they have obliged. I call it "mining" eBay for technical info (maybe not an original term, LOL!). Once a seller even contacted a buyer for me to ask if they could give contact info to me to pursue technical data on an item. It worked!
I’ve didn’t even know an 8” disk drive existed until I worked on an old GPT ISDx telephone exchange with HERMA processor shelf, during the early 2000’s!😂
Hi Adrian, it looks to me as its primed and ready to go. The psu rails look good and the buss looks correct. I guess once the interface is plugged in to an appropriate card at the PC end, the drive will get its activation signal and start spinning. And yes, reversing those roms without any i/o or memory mapping data would be tricky indeed.
Had something similar in a PDP-11 at work, it was a laser marking semiconductor chips. I was the service engineer maintaining the machine and I remember the 10Meg Winchester HDD was very heavy and it needed several minutes to spin up and get warm before being able to use it...
About 110 chips on the top board. Almost as many on the other board, this accounts for about 200 chips. Can you imagine these were most likely installed by hand before going to the soldering wave.
I had a strange feeling watching this video: once you mentioned Hokushin, the first thing that came into my mind was Yokogawa, I don't know why. Later when you mentioned it was absorbed by Yokogawa this kept me thinking if there was something in the bottom of my mind that made me think if I read something in the past about it or it was because the name Hokushin Electric Works made me remember Yokogawa Electric Works (more know by YEW) as it advertised in the 80's.
A quick note on the white strips on the processor board: I agree that they’re for power distribution and decoupling. I forget the manufacturer (US, I think it started with an “R”, Rogers maybe?), but I used a product back around ~1990 for decoupling chips on problematic boards. They were thin flat packages that sat under the chips, with pins sticking down into the power and ground pads. You’d stuff them in the board, stuff the chips in on top of them and then solder. The big advantage was that they had essentially zero inductance because the pins commented directly to the flat electrodes of the capacitor. I used them on a 2-layer board that had noise problems and they did the trick. I think the same company also made longer units for power distribution. They made the board layout easier because you didn’t have to worry about power/ground routing, and also had the advantage of very low resistance and inductance (the conductors were flat strips of relatively heavy-gauge metal), and the bypass capacitance was fully distributed along the length of the bus.
@SiliconValeyGeek Ah, I'd forgotten about the SIP versions; we had some as samples, but only used the flat packs in production. Good note on the 74Sxx parts - I never had to deal with them but think I used some 74AS, which were actually faster, but their speed-power product was less than a third that of 74S.
Definitely not a disappointing video. It's always interesting just to see the older boards that are filled with logic chips over single packages. I've built my own emulation setups that use microcontrollers similar to how something like the C64 had a handful of special purpose-built chips to handle tasks. It's a bit silly when you could easily just emulate it all on a Pi nano or something, but I like the idea of this microcontroller handles io/storage access, this microcontroller acts as a main processor, another mc circuit handles graphics/sound, etc. It's cheaper and easier for me to breadboard that type of design with spare atmegas I used to use for custom keyboards or something over buying an fpga board and recreating the logic from scratch using schematics for something like an Apple ][. Of course, now something like the RP2040 would be way overkill and let you build a basic Apple][ in the size of a thumb drive almost.
when you ask "How complicated can it be to put 1's and 0's from the data bus onto physical media... well, this is the answer! Also interesting is the clock speed seems to be competing quite well with the clock speeds of the computers it was hooked up to!
@@Rx7man The Ohio Scientific floppy disk interfaces were nothing but a PIA (6821) to control the head and a serial adapter (6850) to read and write the data. There was also a "data separator" to remove the clock from the data stream, but that was it! Three main chips and everything else was done in software. Hell, it wasn't much more complicated than their cassette tape interface.
At first, I thought it just looked like a clone of a Shugart SA1000 series, the actual HDA mechanism looks similar from the outside at first glance, but then you showed that it has the newer, fancier SASI interface on the drive instead of the standard, old-school Shugart interface derived from the 800 series floppy interface. I have a Shugart SA1004 (8 meg formatted at Wang's 256-byte sectors, _"10 meg"_ raw) in my Wang 2200LVP, and it still works fine. 😀 That beast needs 120 VAC for the spindle, 24 VDC for the head stepper motor, as well as 5 VDC and -5VDC for the electronics. *(edit:* The SA1000 series manual is available on the bitsavers archive, I won't post a link or else this comment will probably be blocked. *Also,* don't get me started on the 14" CDC model 9448 80 meg _"Phoenix"_ SMD-interface drive for my 2200 *MVP.* Supposedly, somewhere out there actually exist some kind of SMD interface cards for the ISA IBM PC-style bus, I would love to get my hands on one of those if anyone has one!! *)*
That drive is HUGE! Was probably very expensive. I worked for a graphics company in the early 90s that had a big Scitex computer system with big 2MB drives like this. And tape backup on reel to reel. Looked like something from a movie.
@@Birb_of_Judge I was so excited when I got an external 1GB SCSI drive for my PowerMac 6100! Lol. When I got that in 1994 I added 8 MB of RAM for about $800! Then prices came down and I sold that to a co worker for like $300 and bought 16MB for $700! And don’t get me started in my $600 Iomega Jaz drive!
"Stiction" - stuck hard drive platter... was a common issue with some 5.25" drives where the grease from the bearings would leak out on the heads, or just heat from the head to the platter, will cause the drive to not start up as the heads are sticking to the platter, presumably on that drive in the head parking spot. So... to get it to start, if you've got the right voltages - open the drive up in as clean a room as possible, and manually start spinning the drive in the right direction. Then put the drive back together and see if it will start up. If not try actually powering up with the cover off and help it start and put the lid on immediately.
nothing 'sketchy' about those power supplies, less likely to give issues than many modern switch mode things, i'd leave them present if you use the drive..
Drat, I should have read further down the comments. Said basically the same thing higher up this list. Custom 8086 computer accessing SASI drive via special controller with state machine implemented from 4 x 4-bit PROMS. Hell on earth to troubleshoot
Yeah, combinatorial logic in PROM was a very common trick back then. You use the address lines essentially as logic inputs, and the data lines as logic outputs. You can shrink a lot of 74 series chips into a PROM this way if you're clever about it. The result of course will be *very* random looking until you understand the logic function going on. I might take a poke around in that PROM and see if I can't figure out the logic equations used.
Great video. Those old drives can sometimes take a long time to start, like 15mins. Maybe you are switching it off too quickly before it has a chance to properly execute the startup sequence.
This huge clunker reminds me of the 20mb SCSI drive I bought for my Amiga 500 in the mid 80s. It was in it's own big box like Adrian's, connected by a ribbon to a sidecar that attached to the Zorro slot on the side, unlike the Commodore or GVC brands that were card and drive in the sidecar. The heads were driven by a stepper motor not a voice coil, and it was loud as a vacuum cleaner and typewriter combined when running, you could hear the beast 2 rooms away, and there was some kind of conflict where if you installed the boot ROM into the sidecar, it took over 30 seconds of gray screen before the thing would begin to boot. It was faster to boot Kickstart from floppy and use the HD purely as storage. Those were the days, my friends.
my first HD was a MFM 20MB drive i had for my A2000 came with a proprietary PC MFM controller which then was hooked up to another board which had a little contoller and two roms on it to translate the XT bus from that MFM card to the zorroII bus of the Amiga, it also had drivers for the ISA bus as well for the amiga and it also was bootable (!!)and it was fast back than.i measured 2.8MB/sec that was about trippled compared to what i could read on the PC side using a A2286 and also an AT computer.....and it was about 500bucks total. i later added another 80MB MFM drive and then i bought a A2091 and finally a GeForce 040/33 with its own scsi....all in all 15grand for a computer system...think about what you wpuld get for 15grand today....those had been the days of geeky hardware used by geeky people to get things up and running....;)
I love such videos. Thanks Adrian! Would be great to post more videos like this where you do investigation of some old electronic artifact from the past.
The lamp cord may have been added by a subsequent owner, but the rest of it looks like a product of its time. Given it has an hour meter, could be a test unit. That said, all spinning HDD's have a limit on their life, and earlier ones did not have the same life time as later ones. PMC, Power / Mate Corr, Made a lot of power supply units, both linear and switching power supplies. They definitely did not make this enitre contraption, but the PSU's were likely made by them and would have been decent quality and quite reliable at the time.
I really love this non-standard stuff. Trickle it in whenever you have the time to. I'll look forward to the next episode after I'm done with this one.
Keep the original PSUs. In 50 years, someone will have an easier time fixing those than whatever switch mode PSUs you put in there which will almost certainly have failed by then even when not in use.
I feel like everything is actually working as it should be. You just need to issue a spin-up command to start the drive. SCSI does something similar. (1B START STOP UNIT)
Hi Adrian - I love the forensic work you do old gear, such as this hard drive and controller. Your approach and thought process is very impressive and very educational. Thank you for the great work and even greater videos. I cannot imagine how much time this must all take. Thanks again.
SASI is short for Shugart Associates System Interface. The standard committee did not want a commercial reference in the standard name, and chose SCSI instead.
That could easily be a Control Data Corporation (CDC) SMD (Storage Module Drive) interface. Just recently I had at hand an 8'' Fujitsu HDD from 1984. using that interface. It was used in Boroughs (Unisys) mini and micro computers.
I’ve worked on those systems. I’ve also seen that drive here in the UK. I cannot remember if it was on an ICL system or a Boroughs/Unisys one as it was a long time ago. IIRC, we had to keep spares in the room with the mainframes so they were at the right humidity and temperature inside when they were fired up as not doing so reduced their life.
From what I remember SMD has the common shared control and per-disk data cable, and neither of them were 50-pin. Yeah, SMD was standardized as ANSI X3.91M and the Internet Archive had a copy. According to this SMD uses 60 or 75-pin control cable and 34 or 26-pin "read/write cable", so it's not standard SMD at least. Beyond that, anybody knows.
@@Torbjorn.Lindgren I still have access to those drives (as they are now part of the company's 'mini museum' so I can have another look. You might be right about the cables and pin counts.
@@Torbjorn.Lindgren According to new documments Adrian just posted in pinned comment it seems that his drive is of Winchester (or variation) type. SMD was an attempted improvement upon Winchester and an incompatible competition protocol so I'm afraid my experience wth Fujistu drives is of no use in this case. Ihope that someone else can help. It would be interesting to see the drive working again.
@@null_carrier SMD is just a protocol like SCSI, SATA, MFM and so on, there were even more of them them back in the day. Exactly how high or low-level each protocol was varied but they're still "cables and what runs over them". All modern disks drives are of "Winchester type", named after the 1973 IBM 3340 disk drive with code-name Winchester, meaning they are based on the formula this introduced (sealed unit with lightweight heads floating on a air cushion generated by the spinning disk). It was so influental that in a few years everyone was using the same basic idea and as a result was common to use Winchester or Winchester disk as the name for hard disks even in official documentation for pretty much all computer equipment. I strongly suspect every single 8" fixed hard disk was "of Winchester type" so it really doesn't narrow things that much. This use gradually faded away in the early 90s because no one built any disks that weren't "Winchester type" but it's not surprising that the document use that term. Heck, if you find the technical manuals for your Fujitsu it'll probably use that term too.
What we are looking at here were the business computers of the 80s. People did still love and cherish their home computers after the 80 bit era did end, because they causes so many great moments for people. This wasn't the case with the business computers; once companies bought better computers, the old ones were turned into trash. There was no one trying to preserve the documentation because nobody had any love for those big machines. Especially proprietary hardware was simply erased from history. It's kind of a problem: When in say, 200 years people dive computer history, they will find a treasure chest of well preserved 8-bit computers and enough video on RUclips to spend years of time. However, the 80s were also the great decade of mainframes. Next to nothing has been preserved and this will result in a wrong picture of history.
Not disappointing at all. Pretty cool to start with no information at all and start building out all of the info that you've already collected. The collaborative effort that comes into play makes stuff like this even better as information that would never see the light of day suddenly stands out when people realize there is a "market" and that it's not dead technology.
the coloured ribon cable reminded me of some old computer then when you mentioned winchester i remember where i saw the cable an old bbc master system that winchester was a glass disk hdd ?
Test the power supply independently - it doesn't need much load to stabilise it. I had a career in R&D, electronics and embedded systems design. And, among other projects I designed one of the first ever graphics display systems in the late 70s.
I I’m a be mistaken, but if memory serves, [no pun intended, or may be a little], what you have there is an actual full computer from a rack of a 1980 Hakuhō Shō and super computer.
The speed sensor is very likely a variable reluctance type, as evidenced by there being only two wires feeding it. (Hall devices require power). Variable reluctance sensors are a essentially a magnet inside a coil of wire that generates an AC voltage when a ferrous metal comes closer/farther away. Very simple and robust!
DIP SWITCHES: it's a long shot, however some of them oxidizes, try flipping all of them, a couple of times, ending where they are now, and/or check their continuity, if not already done.. of course.
I wanted to see the gigantic drive spin :c Oh well - I wonder if you could place this in your TRS-80 Model II, in place of the 8-inch floppy drive, if you could get that to work somehow, I think you said earlier hard drives were modeled on Floppy tech and that had an 8-inch Floppy - you can probably think of a baker's dozen reasons why that wouldn't work right away, but to a layperson like me - it's an interesting idea at least. 10MB in the late 70s and early 80s was probably quite a bit, you'd never fill it.
It could be that the RELAY on the bottom board has dirty contacts. I think it might be some kind of 'soft start' for this drive. But I would start by testing the relay contacts.
I worked for a systems integrator which specialized connecting SASI (SCSI precursor) to TRS-80 Mod II systems as we had one of these 8" drives -- it was either from Ricoh or Hitachi and I still remember the spin up sound almost 40 years later. IIRC it was a 300-350 MB drive. It was "huge" for its day.
Too bad you didn't save screenshots of the eBay listing you could have contacted the seller and maybe he could have told you who the buyer was because maybe the buyer has a computer setup that uses this hard drive or have they may have the information you need.
With the serial number starting with CD would that suggest that this might be built under license from Control Data corporation? Maybe it would be substantially similar to one of their models…
Certainly in the UK in the 80s qe have various drives that used their own interface, but also had a add on board to allow it to be hooked upto SASI. I wouldn't be surprised if that board does the same, ie translates the drives own proprietary interface to SASI or SCSI. Ive seen various systems use 40 pin cables for SASI connections to the host computer.
We saw a lot of Adaptec / Omti / Wester Digital / Control Data / Fujitsu / IMI - The controllers always seemed to be the most reliable part of any system.
Additional information from Patron Peter Kooiman: it appears this drive is the (or is similar to) the Priam DiskOS1070 and that the interface card is the Priam Smart Interface. There is documentation on it here: www.bitsavers.org/pdf/priam/DISCOS_1070_Product_Specification.pdf
www.bitsavers.org/pdf/priam/SMART_Interface_Product_Specification_Nov80.pdf
It does require a spin-up command so that explains the lack of activity!
Computer Design 1981 volume 10 has an ad for the drive: US$1985 with the interface card included, power supply an extra US$295
Ad: imgur.com/XZPVZ9w
I"m sold. All of that for as little as $1895 with Terminator included, of course!
If you reference the #4 from the listing of defunct HDD companies, you will notice down in the tables that #6 lists that Priam used/contracted Hokushin Electric as the assembler for the HDDs itself in the early 80's. So that would make sense. 👍😁
That's a really great find. Reading the manual explains the hour counter, mean time to failure 10 000 hours which is just over one year. They do say that most repairs should be completed in ½ hour.
I found old adverts 1980 to 1982 they started at $1899.99 (matchmaker technology) other info i found was a page in mini-micro systems 1982 sad to say its digital scans are gone
i recognized that pcb before it need pc to tell it power up to turn on motor if no communication from pc it does nothing it in standby mode saving power waiting for communication from pc when it get communication from pc it switch to power up mode
i heard it from someone own it just trying save it self from not being worn out unlike other hdd just get power and spring up
i think there is way troubleshooting it if you have hook up to pc with diagonal in slot can be come handy
i dont know if they video still out there or not i take look n see what can find
That power supply was built in Hackensack NJ. I was the computer operator for their business applications. This unit was most likely early 80's as the later part of that decade RTE from Wisconsin purchased PowerMate rebranding was RTE/PowerMate. BTW that was not the original power cord.
The internet sure is small sometimes. Cool to know!
Dang newjersey
Ive used a few different PowerMate supplies, they are good stuff. Those arent a good match for the drive... I guess the last operator had them on hand, so thats what he used...
Related to the Roughgarden family of Midland Park? Paul, Nancy.
That means you're old.
We used to maintain giant 14" Shugart hard drives sold as Altos 8000 CP/M and MP/M systems. Total capacity 15 MB. We learned that if you checked the heads for continuity with a multimeter it would burn out the heads as the wires were so fine - and they used to spin up too fast and the drive belt would spin off so Workshop Terry devised a plan to put a 1 ohm resister on the motor to slow it down at start up - but it got hot. He them mixed araldite and heat sink compound to try and stick the resistor to the casting that the drive was built on. He found his mixture combined the sticking power of heat sink compound with the thermal qualities of araldite. Fun times.
The "Computer History Museum" has a link to a "CD-8010P" Hard Drive (Inside an Advanced Computer Design PDQ-3 Computer) You can also find ( from "bitsavers" ) "PDQ-3 System Users Manual Ver 3.1 Apr81" and "PDQ-3 Hardware Users Manual Jan81" (I'm not sure if the weblinks I added in prior messages will get deleted)
Makes sense, Computer History Museum is in Mountain View and that Priam board was made in San Jose a few minutes away. I bet that thing at some point passed through a place I used to work called WeirdStuff Warehouse in Sunnyvale, I miss that place heh
@@alakani Ah, WeirdStuff. The best place to buy swag from defunct companies. I still have my MediaVision screwdriver that I bought from that store. Across the street from the old Fry's that had "Enter" and "Escape" keys on the doors. Pre DotCom implosion.
@@alakani man, Weird Stuff. Used to love just walking through there and seeing what they had.
It seems the only links RUclips leaves alone are links to other RUclips video's
You can probably blame this on all the scam artists with links (and Telegram 'codes') to various get rich quick crowds (In reality, get poor quick, with their help)
Does that mean with the extra info we can have a part 2??
Basic knowledge only of electronics and logic and this was way above me but I was fascinated.
I love how this channel has gone from swapping chips on a commodore 64 to some serious hard core geek material. Awesome stuff.
The spikes you see on the 5v rail and other places is caused by the long ground lead on your scope probe. 1: It picks up noise from the board and that is "in series" with probe so it looks like it is on the signal. 2: Your grounding is far away from where you are probing. Ground is not ground when it comes to high frequency AC signals. Always try to use a short ground cable to the probe as close as possible to the place you are probing.,
Yep ground noise will get you every time 👍
In about 1983 I was working for Link House publications as a Analyst Programmer. The computer room was quite large. 60 foot by 40 foot. Filled with 4 foot square hard drives. The operator used to walk around the hard drives every morning checking the temperature of the air coming out of the hard drive, One morning he noticed one drive was hotter than the others hence he closed the computer system down and called an IBM engineer who changed a bearing on the drive.
a living resource monitor lmao
That thing is small considering the original harddrives were the size of a washing machine...
LOL - I accidentally replied to someone else's comment!
Wow, what a different world. These days the whole contents of that room would fit on a USB memory stick, kind of crazy
@@paulstubbs7678 : indeed
For some of us it does not matter that you might not get something going, it is still enjoyable to watch you work through your thought process, as we still learn from it.
100%
Exactly.
Enjoyed this episode really much, thank you.
+1
Quick hint for disassemblers:
11K is 8085 code 0000-07FF
12K is 8085 code 2000-2FFF (same address space as 11K)
L15 is 8085 code 0000-07FF
Given that you mentioned seeing 4.7V on the board, I'm guessing the power supply was turned up to 5.3V to give 5V on the board.
Yes, that might be the case because of voltage drop. I wasn't checking the voltage at the chips
@@adriansdigitalbasement Does the PSU have a sense line? That would explain the voltage going up under load when measuring on the PSU.
I worked at British Airways as an HVAC Engineer, 21 years ago at their Data Center area, at Bodicia Hse. In the background on this Huge site there were a couple of Condemned Buildings, one of them was called Comet House, which was infact the Airway Staff Medical Center and Hospital. The Building had been 'Ear Marked' for Demolition but there was alot of Politics involved because of Asbestos Presence and was Boarded up. But, we got through the Boarding and went on a journey of discovery. Now, me being interested in Computers and Technology found a Redundant Storage area of Dozens of old Form Computers, Boxes and Boxes, lines and lines of shelving containing electronic components. Now, I saw a few dozen of the Hard drive and boards that you are exhibiting. They certainly weren't screwed to a Board like yours and were in a Proper or appropriate Container in a similar configuration to the Machine you are showing us. I noted the 50 Pin configuration and here you have revealed this to us. Apparently the PC's then were used for and by the Pay Offices and Staff Records.
In the mid-1980s, we had Hokushin hard drives - 5mg and 10mg attached in an outboard cabinet to a hot rodded MicroVax and the interface was Shugart ST412.
Milligrams? Thanks Doc! 😆
I'm guessing that drive was made prior to 1983, since Hokushin Electric Works was merged with Yokugawa to become Yokugawa Hokushin Electric Works in 1983. Back in the 90's, there was a massive text list of HD drive info called "hdlist". I tried to find a copy of it to see if Hokushin was on it, but couldn't find a copy.
Yes indeed, the date codes on the ICs are all 1981.
Irregardless of this drive, it may be good idea to find and archive this document.
If you looked at it in the past, you might remember some text that was definitely in there.
Try to google all different things that could be in it in one search query.
Did it just have names, or also some kind of parameters? Like heads/cyls/tracks? Or interface? Or size? If so, you could probably find some parameters somewhere else and google them all together. Try putting a dash between numbers that were close together.
Although it could easily have been just an internal document that got passed about a few companies.
I demilitarised took apart and destroyed the discs in many of those like that at Puget Sound Naval Shipyard I was working for. And stripped out many boards on computer server towers for precious metals of gold platinum and silver recovery in the late '80s and early '90s. So I have seen so many of those. I would see that one there a lot. Those and tape drives. A lot of optical hard drives too. I loved stripping them apart. I would have to smash and drill holes in so many Hard drive discs. Some really old and very big ones. I saw so much cool stuff most did not get to see or know what they are and even now I am still learning what they were. Some were so secret I will never know. And they are so outdated now though back then they were very high-tech. I saw the first CD ROMs before most did. A lot of things the average consumer could not get or afford I had to play around with. I even saw many Commador 64 used that were on ships. A lot of them came through where I worked in a large tall pile on many pallets for me to ship to be sold in DRMO DLA auctions. Many Printers Tape and Floppy Drives and Monitors for them too. I would grab the best ones and play games on them till they died I would have many of them at my work desk in case one died on me I could not fix myself when on break or at lunch or get there early to play them tell I start working. I used them to make documents I printed for shipping things too. I made my own program for it just to do that.
Very cool read, thank you for sharing this experience with us!
I used to work for circuit (PCB) makers in the late 70s early 80s, and I would bet that the E.C.1283 marking is the circuit Manufacturers initials followed by the month and 2-digit year, Dec 1983. It was a common practice back then. For example, a company I worked with in Fort Lauderdale, FL was called Tropical Circuits and they would have put TC1283 on their boards.
Ah, the TMS2516, I recall when that was released and I know the story... or at least the outside view if it.
The story starts first with Intel's first EPROM in 1971 - The 1702 2Kbit UV erasable EPROM. The was followed up in 2704 and 2708 in 1975. They revolutionized development since you could reprogram your ROM. Soon everyone (including TI) started copying it and racing to see if they could beat Intel to make a 2716 before they could. The one annoyance with the 1st and 2nd gen EPROM is to use them you needed more than just 5V. Well, Intel surprised EVERYONE when they introduced their 2716 which was 5V only (for reading). Also, it could reuse those supply pins for address pins so the 2716 an 2732 could use the same 24-pin package as the 2708. That made TI's 2716 inferior and incompatible with Intel's 2716 which forced it to change its part number. The TMS2516 was TI's "copy" of the Intel (5V only) 2716.
I haven't a clue anything Adrian talks about. I just enjoy watching all his videos, pleasant and intelligent guy talking passionately about his interests.
Adrian is the Bob Ross of Retro Computing!
Same, I know very little about what goes on inside a computer. Adrian makes it so interesting.
@@ricardog2165
Happy little IC’s!
I remember some of the IBM servers we had used an option via the SCSI controller to either start up the attached SCSI drives instantly, or used a 'cascaded' start up based on the drives SCSI ID. This allowed them to start up one by one and reduce the load on the PSU. Pure speculation, but perhaps this drive is only programmed to spin up when it receives the correct command from an attached controller / host rather than when it's simply switched on?
This option varies on different controllers . Remebering SCSI drives - there was a jumper option to enable/disable disc behavior on power on.
Since the start current on drives this size was massive, sequential start was important to not blow a breaker or smoke some wires. I have an old 5.25" SCSI that takes 15 Amps to start (at 12V) and is like a jet engine as it winds up, and this thing is even bigger, so I don't doubt the external start signal required. I worked with an old NCR mini in the 90's, and its power supply was good for 200 amps at 12V for the 4 drive chassis expansion module, running off 220V. That monster cabinet was something like 300 lbs and about the size of a large tower PC of the time to house 4 drives.
The voltages seems a bit wonky. TTL chips need 5V +/- 0.25V. So, 4.7V is too low. You might want to adjust the 5V supply to 5.1V to allow for power loss in the cables/traces.
if 5.25 is upper threshold of the spec then it should be safe to go around 5.3 on the PSU end from the start.
Patent Number: 4,638,383 Date of Patent: "Jan. 20, 1987
Page 21 states
Hokushin Electric Works, Ltd., "CD 8000 Expand Your System Versatility with Low Cost 8 inch Winchester', 1980.
This is fascinating. The controller board certainly looked different than others shown on the channel - those strips - I don't think we've seen something like that on the channel before. It's fascinating seeing different ways people made boards and solved problems.
You might like to look at main board of Centurion computer that "Usagi Electric" is restoring.
That one has actual wires (not traces) INSIDE the board epoxy.
The video is called "Minicomputer Part 4: In-depth Look at all the Computer PCBs" at timestamp 19:56
@@jwhite5008 ooh! I've watched some in that series, I don't know if I've watched that part. Thanks!
I remember seeing ad's for very similar strips, they were advertised as bringing low impedance DC and bypass caps right up to the IC:s. These days with multi layer circuit boards with a ground & supply plain this is no longer an issue, but back then two layers PCB's was all most had access to
Back in my dim dark past of the early 80's I was working on/supported some Basic 4 (en.wikipedia.org/wiki/MAI_Basic_Four) computers and S100 devices
around Sydney For Rank industry's
one fun job was that they had an s100 card system that was installed in the Sydney(Australia) container port that some ham-fisted dock worker attempted to reseat some cards
one card had strips like that but mounted 90" to the surface of the board they supplied the power rails and also isolated each row of chips
my muscled friend had managed to break a few connections and making them intermittent. a couple of hours with a magnifier and fine wire fixed the issue
in those days it was weeks/months to get weird parts by ship or $ 1000s for air freight so it was mostly surgery, canablise or invent something to replace what was broken
once knocked up a replacement lm741 op amp out of bits to get a industrial metal detector working while I waited a week for a replacement part
Merry Christmas Adrian and everybody that is watching this channel....
Yes, 5.25", and 8" drives drew a ton of current on startup. I remember on Intel based servers, when the power supplies were getting a little weak, we would have to unplug the power connector from one, or more, 5.25" drives, and plug them in one at a time. Once they were all spun up, do a hard reset, and then you could load the OS. Once we got to 3.5" hd's, the current demands were less, but the problem remained due to a much larger number of drives. On the Compaq servers, they would sequentially power up the hard drives (by SCSI id order) as part of the POST, in order to minimize peak loads. Great video...not a failure at all.
I still have a Compaq Prolinea server in my "digital basement" (of course not powered on 24/7), and you can clearly hear the drop of the +12V supply while the hard drive spins up, as the fan RPM goes down. And that's just with the single Fujitsu M2623F half-height 3.5inch drive that was the basic storage option. The peak spin-up current is 2.5A @ 12V. Don't believe marketing touting this drive as "high-performance [...] hard drives, which increase the performance levels of high-end personal computers, workstations and network file servers", though. They are solid drives, but at 4400rpm and less than snappy seek times, they are mid-level for workstations and bottom-of-the-barrel for servers.
An official option for that system was the Compaq SMART-RAID controller with up to 7 drives connected to it, and you would most likely buy bigger and faster drives if you went the RAID route. Of course they did staggered spin-up by default.
I worked on some DTC (Data Technology Corp) SASI controllers, integrating them into the Heath/Zenith Z-100 ecosystem. The Z-100 was DOD's "Desktop One" back in the 1980s and our customers were mostly military installations, and folks from the Heathkit world. 50-pin is almost certainly SASI, but that host adapter (the upper board) is a weird one for sure! "EC" is probably Engineering Change and a date-code.
I remember the zenith machines! Bulletproof monsters those were!
Looking forward to part II of this very interesting hardware. Thank you Adrian for posting these even when there isn't an instant resolution. Gives me something to look forward to!
I have an old MiniStor 40MB 1.8-inch hard disk which doesn't seem to exist except in the documentation which came with it. I bought it NOS. It seems to have come out of a lot of disks which were made for one particular computer manufacturer. It was made in 1992, and it certainly wasn't made down to a price since it has a lot of parts on the main PCB which were quite expensive back then, and are still quite expensive today, an example of which are a few Sprague Tatamount tantalum capacitors which are designed for high reliability applications.
The spin up problem maybe because the drive is set on " Start on Command " this is set with a jumper on the drive itself it will power up the board but will not spin the drive until it receives a command to start the clunk you hear on starting the drive is the head locking to parked position.
21:00 I just use car light bulbs as loads for power supply. Different combinations for different voltages or currents.
The terminator pack you're looking at 41:26 is on the board directly connected to the drive, right? I feel like there is confusion here, if anything here is going to be a peripheral bus like scsi/sasi it's not going to be that, it's going to be the connector that goes from the other board -- presumably the drive controller -- to (whatever host adapter installed in) the computer. Like think about how ST506 drives were used with SCSI using ST506 to SCSI drive controllers like ACB-4000A you would then connect to your scsi bus, and those are later more miniaturized 5 1/4" hard drives.
It's a proprietary bus from Priam, an NRZ serial type.
Awesome video, as always! 27:33 There's a 4th option, I'm certain has already been discussed. Just sticky bearings, that often can be freed up by giving the chassis of the drive a quick and sudden "spin" by hand, in the direction perpendicular to the drive motor axle. Of course, this is easy with a 5.25" drive, much harder with an 8", but there's always a way! Has this been tried yet? Well, moving ahead to 30:38 I can see that you've ruled this out, as you've exposed part of the drive motor, and you could just spin it by hand there and see if it moves freely...and you've determined that the BLDC circuit is not even trying to spin the drive...anyway... LOVE this stuff, Adrian...we'll get the flux transitions off of this device yet for you!!!
SASI = "Shugart Associates System Interface"
Hokushin Denki later became Yokogawa-Hokushin Denki, and now called Yokogawa Electric...
Fascinating. I have found much info searching eBay listings and blowing up pics found there. If the item is sold you can still search completed listings for it! I was very frustrated for you at 32.00! I have actually contacted sellers to get additional pics of items and/or documentation even after an item has sold. In most cases they have obliged. I call it "mining" eBay for technical info (maybe not an original term, LOL!). Once a seller even contacted a buyer for me to ask if they could give contact info to me to pursue technical data on an item. It worked!
I’ve didn’t even know an 8” disk drive existed until I worked on an old GPT ISDx telephone exchange with HERMA processor shelf, during the early 2000’s!😂
Have been subscribed for years love your Channel Dave uk
Hi Adrian, it looks to me as its primed and ready to go. The psu rails look good and the buss looks correct. I guess once the interface is plugged in to an appropriate card at the PC end, the drive will get its activation signal and start spinning. And yes, reversing those roms without any i/o or memory mapping data would be tricky indeed.
Had something similar in a PDP-11 at work, it was a laser marking semiconductor chips. I was the service engineer maintaining the machine and I remember the 10Meg Winchester HDD was very heavy and it needed several minutes to spin up and get warm before being able to use it...
About 110 chips on the top board. Almost as many on the other board, this accounts for about 200 chips. Can you imagine these were most likely installed by hand before going to the soldering wave.
I had a strange feeling watching this video: once you mentioned Hokushin, the first thing that came into my mind was Yokogawa, I don't know why. Later when you mentioned it was absorbed by Yokogawa this kept me thinking if there was something in the bottom of my mind that made me think if I read something in the past about it or it was because the name Hokushin Electric Works made me remember Yokogawa Electric Works (more know by YEW) as it advertised in the 80's.
A very Merry Christmas to you, Adrian! Another fine video 👍I've learned a lot from watching all of your videos!
Time to pull out the logic analyzer
That old drive is miniature. My grandad had a platter from an old hard drive in his workshop. It was about 3 feet in diameter and about a 1/4" thick!
A quick note on the white strips on the processor board: I agree that they’re for power distribution and decoupling. I forget the manufacturer (US, I think it started with an “R”, Rogers maybe?), but I used a product back around ~1990 for decoupling chips on problematic boards. They were thin flat packages that sat under the chips, with pins sticking down into the power and ground pads. You’d stuff them in the board, stuff the chips in on top of them and then solder.
The big advantage was that they had essentially zero inductance because the pins commented directly to the flat electrodes of the capacitor. I used them on a 2-layer board that had noise problems and they did the trick.
I think the same company also made longer units for power distribution. They made the board layout easier because you didn’t have to worry about power/ground routing, and also had the advantage of very low resistance and inductance (the conductors were flat strips of relatively heavy-gauge metal), and the bypass capacitance was fully distributed along the length of the bus.
@SiliconValeyGeek Ah, I'd forgotten about the SIP versions; we had some as samples, but only used the flat packs in production. Good note on the 74Sxx parts - I never had to deal with them but think I used some 74AS, which were actually faster, but their speed-power product was less than a third that of 74S.
How about connecting it to good old Adaptec 2940 scsi controller and see if gets recoqnized.
Or atleast map out the pins voltage of the drive board and the empty connector at the adapter board, then see if the pinout matches anything known
Definitely not a disappointing video. It's always interesting just to see the older boards that are filled with logic chips over single packages. I've built my own emulation setups that use microcontrollers similar to how something like the C64 had a handful of special purpose-built chips to handle tasks. It's a bit silly when you could easily just emulate it all on a Pi nano or something, but I like the idea of this microcontroller handles io/storage access, this microcontroller acts as a main processor, another mc circuit handles graphics/sound, etc. It's cheaper and easier for me to breadboard that type of design with spare atmegas I used to use for custom keyboards or something over buying an fpga board and recreating the logic from scratch using schematics for something like an Apple ][. Of course, now something like the RP2040 would be way overkill and let you build a basic Apple][ in the size of a thumb drive almost.
In 40 years of owning computers, I've never owned a computer that had as many chips as that disk drive.
when you ask "How complicated can it be to put 1's and 0's from the data bus onto physical media... well, this is the answer!
Also interesting is the clock speed seems to be competing quite well with the clock speeds of the computers it was hooked up to!
@@Rx7man The Ohio Scientific floppy disk interfaces were nothing but a PIA (6821) to control the head and a serial adapter (6850) to read and write the data. There was also a "data separator" to remove the clock from the data stream, but that was it! Three main chips and everything else was done in software. Hell, it wasn't much more complicated than their cassette tape interface.
At first, I thought it just looked like a clone of a Shugart SA1000 series, the actual HDA mechanism looks similar from the outside at first glance, but then you showed that it has the newer, fancier SASI interface on the drive instead of the standard, old-school Shugart interface derived from the 800 series floppy interface. I have a Shugart SA1004 (8 meg formatted at Wang's 256-byte sectors, _"10 meg"_ raw) in my Wang 2200LVP, and it still works fine. 😀 That beast needs 120 VAC for the spindle, 24 VDC for the head stepper motor, as well as 5 VDC and -5VDC for the electronics.
*(edit:* The SA1000 series manual is available on the bitsavers archive, I won't post a link or else this comment will probably be blocked. *Also,* don't get me started on the 14" CDC model 9448 80 meg _"Phoenix"_ SMD-interface drive for my 2200 *MVP.* Supposedly, somewhere out there actually exist some kind of SMD interface cards for the ISA IBM PC-style bus, I would love to get my hands on one of those if anyone has one!! *)*
SAS is a teeeny bit newer than SASI, though :-)
That drive is HUGE! Was probably very expensive. I worked for a graphics company in the early 90s that had a big Scitex computer system with big 2MB drives like this. And tape backup on reel to reel. Looked like something from a movie.
I wonder how people during that time would have reacted if you told them that you can buy a 4TB 3,5" hard drive for under 100$.
@@Birb_of_Judge I was so excited when I got an external 1GB SCSI drive for my PowerMac 6100! Lol. When I got that in 1994 I added 8 MB of RAM for about $800! Then prices came down and I sold that to a co worker for like $300 and bought 16MB for $700! And don’t get me started in my $600 Iomega Jaz drive!
"Stiction" - stuck hard drive platter... was a common issue with some 5.25" drives where the grease from the bearings would leak out on the heads, or just heat from the head to the platter, will cause the drive to not start up as the heads are sticking to the platter, presumably on that drive in the head parking spot.
So... to get it to start, if you've got the right voltages - open the drive up in as clean a room as possible, and manually start spinning the drive in the right direction.
Then put the drive back together and see if it will start up. If not try actually powering up with the cover off and help it start and put the lid on immediately.
nothing 'sketchy' about those power supplies, less likely to give issues than many modern switch mode things, i'd leave them present if you use the drive..
That no-code ROM could implement a drive control state machine.
I was thinking it might contain a hardcoded bad block map or something. It would be a pain to update it but I guess it's still doable.
Drat, I should have read further down the comments. Said basically the same thing higher up this list. Custom 8086 computer accessing SASI drive via special controller with state machine implemented from 4 x 4-bit PROMS. Hell on earth to troubleshoot
Yeah, combinatorial logic in PROM was a very common trick back then. You use the address lines essentially as logic inputs, and the data lines as logic outputs. You can shrink a lot of 74 series chips into a PROM this way if you're clever about it. The result of course will be *very* random looking until you understand the logic function going on. I might take a poke around in that PROM and see if I can't figure out the logic equations used.
Great video. Those old drives can sometimes take a long time to start, like 15mins. Maybe you are switching it off too quickly before it has a chance to properly execute the startup sequence.
This huge clunker reminds me of the 20mb SCSI drive I bought for my Amiga 500 in the mid 80s. It was in it's own big box like Adrian's, connected by a ribbon to a sidecar that attached to the Zorro slot on the side, unlike the Commodore or GVC brands that were card and drive in the sidecar. The heads were driven by a stepper motor not a voice coil, and it was loud as a vacuum cleaner and typewriter combined when running, you could hear the beast 2 rooms away, and there was some kind of conflict where if you installed the boot ROM into the sidecar, it took over 30 seconds of gray screen before the thing would begin to boot. It was faster to boot Kickstart from floppy and use the HD purely as storage. Those were the days, my friends.
my first HD was a MFM 20MB drive i had for my A2000 came with a proprietary PC MFM controller which then was hooked up to another board which had a little contoller and two roms on it to translate the XT bus from that MFM card to the zorroII bus of the Amiga, it also had drivers for the ISA bus as well for the amiga and it also was bootable (!!)and it was fast back than.i measured 2.8MB/sec that was about trippled compared to what i could read on the PC side using a A2286 and also an AT computer.....and it was about 500bucks total. i later added another 80MB MFM drive and then i bought a A2091 and finally a GeForce 040/33 with its own scsi....all in all 15grand for a computer system...think about what you wpuld get for 15grand today....those had been the days of geeky hardware used by geeky people to get things up and running....;)
@@tubical71 I really miss those times, sometime. It was a great time to grow up loving tech.
I love such videos. Thanks Adrian! Would be great to post more videos like this where you do investigation of some old electronic artifact from the past.
The lamp cord may have been added by a subsequent owner, but the rest of it looks like a product of its time. Given it has an hour meter, could be a test unit. That said, all spinning HDD's have a limit on their life, and earlier ones did not have the same life time as later ones.
PMC, Power / Mate Corr, Made a lot of power supply units, both linear and switching power supplies. They definitely did not make this enitre contraption, but the PSU's were likely made by them and would have been decent quality and quite reliable at the time.
Merry Christmas Adrian! 🎄😊
Don't touch that relic. That belongs in a museum next to an egyptian mummy
It looks a lot like a PRIAM 14" Winchester drive: here is the service manual:
bitsavers.org/pdf/priam/3350_6650_15450_OEM_Manual_Jan84.pdf
Merry Christmas, Adrian!
Thank you for another year of awesome videos! ^_^
I really love this non-standard stuff. Trickle it in whenever you have the time to. I'll look forward to the next episode after I'm done with this one.
11:55 there is a *nix console command "strings" to do just that
Was thinking the same. Looks like Adrian use Windows. Cygwin's binutils package has the same utility.
@@NicolaiDufva I found my version was even one of the many Sysinternals tools
After buying my son a 512GB Micro SD card for Christmas for $49 to replace the 32GB one he had and promptly threw away really puts 10MB in perspective
Keep the original PSUs. In 50 years, someone will have an easier time fixing those than whatever switch mode PSUs you put in there which will almost certainly have failed by then even when not in use.
Software Manual: www.bitsavers.org/pdf/advancedComputerDesign/PDQ-3_System_Users_Manual_Ver_3.1_Apr81.pdf
I feel like everything is actually working as it should be. You just need to issue a spin-up command to start the drive. SCSI does something similar. (1B START STOP UNIT)
That 1541 on the sticker suggest to me that you should definitely try to hook that bad boy up to a c64! Definitely a sign.
More like an omen. 😉
That was my first (cheeky) thought, too.
Seriously thought you were using the Ultima 4 map underneath that piece of plywood. Lol glad it's not.
me with my 256gb microsd card:
*goddamn technology has evolved so much.*
I bet one of the dip switches enables auto spin up on power up, the 8 inch SMD drives from Fujitsu and Sabre had that option.
Hi Adrian - I love the forensic work you do old gear, such as this hard drive and controller. Your approach and thought process is very impressive and very educational. Thank you for the great work and even greater videos. I cannot imagine how much time this must all take. Thanks again.
SASI is short for Shugart Associates System Interface. The standard committee did not want a commercial reference in the standard name, and chose SCSI instead.
Omg. That amount of disregard for mains voltage gives me anxiety.
Power cords not withstanding... Linear Power Supplies could hardly be described as sketchy... :(
Great video Adrian. You should check Usagi Electrics YT channel, he spends a lot of time on this stuff on his Centurion minicomputer.
it could be waiting for commands from a host computer before it spins up
The product specification says: "Light weight--only 20 pounds--reduces cost of installation.". Yes! :)
That could easily be a Control Data Corporation (CDC) SMD (Storage Module Drive) interface.
Just recently I had at hand an 8'' Fujitsu HDD from 1984. using that interface.
It was used in Boroughs (Unisys) mini and micro computers.
I’ve worked on those systems. I’ve also seen that drive here in the UK. I cannot remember if it was on an ICL system or a Boroughs/Unisys one as it was a long time ago. IIRC, we had to keep spares in the room with the mainframes so they were at the right humidity and temperature inside when they were fired up as not doing so reduced their life.
From what I remember SMD has the common shared control and per-disk data cable, and neither of them were 50-pin. Yeah, SMD was standardized as ANSI X3.91M and the Internet Archive had a copy. According to this SMD uses 60 or 75-pin control cable and 34 or 26-pin "read/write cable", so it's not standard SMD at least. Beyond that, anybody knows.
@@Torbjorn.Lindgren I still have access to those drives (as they are now part of the company's 'mini museum' so I can have another look. You might be right about the cables and pin counts.
@@Torbjorn.Lindgren According to new documments Adrian just posted in pinned comment it seems that his drive is of Winchester (or variation) type. SMD was an attempted improvement upon Winchester and an incompatible competition protocol so I'm afraid my experience wth Fujistu drives is of no use in this case. Ihope that someone else can help. It would be interesting to see the drive working again.
@@null_carrier SMD is just a protocol like SCSI, SATA, MFM and so on, there were even more of them them back in the day. Exactly how high or low-level each protocol was varied but they're still "cables and what runs over them".
All modern disks drives are of "Winchester type", named after the 1973 IBM 3340 disk drive with code-name Winchester, meaning they are based on the formula this introduced (sealed unit with lightweight heads floating on a air cushion generated by the spinning disk).
It was so influental that in a few years everyone was using the same basic idea and as a result was common to use Winchester or Winchester disk as the name for hard disks even in official documentation for pretty much all computer equipment. I strongly suspect every single 8" fixed hard disk was "of Winchester type" so it really doesn't narrow things that much. This use gradually faded away in the early 90s because no one built any disks that weren't "Winchester type" but it's not surprising that the document use that term. Heck, if you find the technical manuals for your Fujitsu it'll probably use that term too.
What we are looking at here were the business computers of the 80s. People did still love and cherish their home computers after the 80 bit era did end, because they causes so many great moments for people. This wasn't the case with the business computers; once companies bought better computers, the old ones were turned into trash. There was no one trying to preserve the documentation because nobody had any love for those big machines. Especially proprietary hardware was simply erased from history.
It's kind of a problem: When in say, 200 years people dive computer history, they will find a treasure chest of well preserved 8-bit computers and enough video on RUclips to spend years of time. However, the 80s were also the great decade of mainframes. Next to nothing has been preserved and this will result in a wrong picture of history.
Adrian, do you take any ESD measures? It seems you touch all those old sram RAM chips with your fingers while moving around. This could damage them.
I wondered about that too.
Not disappointing at all. Pretty cool to start with no information at all and start building out all of the info that you've already collected. The collaborative effort that comes into play makes stuff like this even better as information that would never see the light of day suddenly stands out when people realize there is a "market" and that it's not dead technology.
the coloured ribon cable reminded me of some old computer then when you mentioned winchester i remember where i saw the cable an old bbc master system that winchester was a glass disk hdd ?
LOL, this drive had a 10,000 hour MTBF! That's only a little more than 1 year of continuous runtime!
Test the power supply independently - it doesn't need much load to stabilise it. I had a career in R&D, electronics and embedded systems design. And, among other projects I designed one of the first ever graphics display systems in the late 70s.
Don't depend on wiki- they seem to have lost their original soul and seem to want to promote more useless entertainment info...
I I’m a be mistaken, but if memory serves, [no pun intended, or may be a little], what you have there is an actual full computer from a rack of a 1980 Hakuhō Shō and super computer.
The speed sensor is very likely a variable reluctance type, as evidenced by there being only two wires feeding it. (Hall devices require power). Variable reluctance sensors are a essentially a magnet inside a coil of wire that generates an AC voltage when a ferrous metal comes closer/farther away. Very simple and robust!
Happy Holidays Adrian!
Thank you for all the great videos you've brought us throughout the year. I wish you health and happiness for 2023 and beyond!
I wonder if some of those 8085's were manufactured with built-in ROM like 6800's were? That could also account for missing code.
DIP SWITCHES: it's a long shot, however some of them oxidizes, try flipping all of them, a couple of times, ending where they are now, and/or check their continuity, if not already done.. of course.
I wanted to see the gigantic drive spin :c Oh well - I wonder if you could place this in your TRS-80 Model II, in place of the 8-inch floppy drive, if you could get that to work somehow, I think you said earlier hard drives were modeled on Floppy tech and that had an 8-inch Floppy - you can probably think of a baker's dozen reasons why that wouldn't work right away, but to a layperson like me - it's an interesting idea at least. 10MB in the late 70s and early 80s was probably quite a bit, you'd never fill it.
It could be that the RELAY on the bottom board has dirty contacts. I think it might be some kind of 'soft start' for this drive. But I would start by testing the relay contacts.
I worked for a systems integrator which specialized connecting SASI (SCSI precursor) to TRS-80 Mod II systems as we had one of these 8" drives -- it was either from Ricoh or Hitachi and I still remember the spin up sound almost 40 years later. IIRC it was a 300-350 MB drive. It was "huge" for its day.
I wonder if the EC1283 is a mfg. date? 12th month of 1983?
I'm curious whether or not the serial outputs on the 8085s are used for anything. They'd be great for diagnostic output in something like this.
Now we know what progress looks like.
Too bad you didn't save screenshots of the eBay listing you could have contacted the seller and maybe he could have told you who the buyer was because maybe the buyer has a computer setup that uses this hard drive or have they may have the information you need.
That looks like an IDE cable. I was actually thinking you were going to have an MFM cable when I saw the size of that drive.
With the serial number starting with CD would that suggest that this might be built under license from Control Data corporation? Maybe it would be substantially similar to one of their models…
Or a clone of a CDC model.
Certainly in the UK in the 80s qe have various drives that used their own interface, but also had a add on board to allow it to be hooked upto SASI.
I wouldn't be surprised if that board does the same, ie translates the drives own proprietary interface to SASI or SCSI.
Ive seen various systems use 40 pin cables for SASI connections to the host computer.
We saw a lot of Adaptec / Omti / Wester Digital / Control Data / Fujitsu / IMI - The controllers always seemed to be the most reliable part of any system.