Zeta SBC V2



Zeta SBC is an Zilog Z80 based single board computer. It is inspired by Ampro Little Board Z80 and N8VEM project. Zeta SBC is software compatible with N8VEM SBC and Disk I/O boards.




Complete Board

Zeta SBC

Zeta SBC with ParPortProp and a Floppy Drive

Zeta SBC with ParPortProp




Zeta SBC features following components:

  • Z80 CPU
  • 16550 UART - for connecting a console
  • 8255 PPI - can be used for attaching a hard drive using PPIDE or controlling some external devices
  • SMC FDC9266 floppy disk controller - NEC 765A / Intel 8272 compatible, with integrated data separator
  • 512 KiB of battery backed SRAM
  • 512 KiB of flash memory
  • RTC


Zeta SBC is compact and easy to build:

  • Footprint of an 3.5" floppy drive (100 mm x 170.18 mm) and PCB can be mounted under a 3.5" drive.
  • Uses only through hole components.
  • Assumes using commonly available 3.5" floppy drives (not many people have 5.25" drives and even less 8" ones). Although it should work with 5.25" drives too.
  • Only 3 configuration jumpers.
  • Easy to use flash memory instead of UV EPROM.
  • PCB mounted connectors, no need to build cables. 
  • Uses widely available components
  • An easy way to get a "taste" of CP/M era computing.


Hardware Documentation



Zeta SBC - Schematics - Color - 1.0.pdf (see attachments at the bottom of this page)

Zeta SBC - Schematics - BW - 1.0.pdf (see attachments at the bottom of this page)


PCB Version 1.0

Zeta SBC - Board - Color - 1.0.pdf (see attachments at the bottom of this page)


PCB Version 1.1

Zeta SBC - Board - Color - 1.1.pdf (see attachments at the bottom of this page)


PCB Version 1.2

Zeta SBC - Board - Color - 1.2.pdf (see attachments at the bottom of this page)


PCB Version 1.3

Zeta SBC - Board - Color - 1.3.pdf (see attachments at the bottom of this page)


Input/Output ports

  • Compatible with N8VEM SBC and N8VEM Disk I/O boards (FDC part only, no XT-IDE)
  • 30h (aliases 32h, 34h, 36h) - FDC Main Status Register (N8VEM Disk I/O uses 36h)
  • 31h (aliases 33h, 35h, 37h) - FDC Data Register (N8VEM Disk I/O uses 37h)
  • 38h (aliases 39h - 3Fh)
    • Write - FDC Diginal Output Register (DOR), also known as latch.
      • Bit 0 - TC
      • Bit 1 - MOTOR (0 = Motor off, 1 = Motor on)
      • Bit 2 - MINI
      • Bit 3 - P2
      • Bit 4 - P1
      • Bit 5 - P0
      • Bit 6 - DENSEL (0 = High density, 1 = Low density)
      • Bit 7 - ~FDC_RST (0 = FDC RESET active, 1 = normal operation)
    • Read - FDC Digital Input Register (DIR)
      • Bit 0 - ~DC
      • Bits 1-7 - unused  
    • N8VEM FDC compatibility notes:
      • Bit 1 is inverted, so upon system reset floppy drive motor(s) will be turned off
      • Bit 6 is inverted, but it is unlikely that it will cause any compatibility problems, as modern 3.5" drives don't use this signal
      • Bit 7 of the latch is used differently (and incorrectly) on N8VEM Disk I/O as an input to ~DC (disk change) line. In Zeta SBC this output is connected to FDC RESET input, and allows software controlled FDC reset.
      • ~DC (disk change) output from floppy drives can be read from DIR register, bit 0. It could be used by the system to detect floppy disk change. In such case CP/M should be warm rebooted.
  • 60h-63h (alias 64h-67h) - PPI Registers
  • 68h-6Fh - UART Registers
  • 70h (aliases 71h-77h) - RTC Registers
    • Write:
      • Bits 0-3 - unused
      • Bit 4 - RTC Chip Enable
      • Bit 5 - RTC Write Enable
      • Bit 6 - RTC Clock
      • Bit 7 - RTC Input
    • Read:
      • Bit 0 - RTC Output
      • Bits 1-5 - unused
      • Bit 6 - Configuration Jumper (JP1)
      • Bit 7 - unused
  • 78h (aliases 79h-7Bh) - RAM Page Select Register (CFG1)
    • Bits 0-3 - RAM page selection (A15-A18)
    • Bits 4-7 - unused
  • 7Ch (aliases 7Dh-7Fh) - ROM Page register (CFG2)
    • Bits 0-3 - ROM page selection (A15-A18)
    • Bits 4-6 - unused
    • Bit 7 - ROM disable (~ROM_ENA signal)
  • N8VEM compatibility notes:
    • Zeta SBC qualifies ~WR signal when accessing configuration registers, so accidental read access to them won't corrupt their content. This makes programs like SURVEY.COM work without crashing the system.
    • Zeta SBC doesn't check A1 when accessing configuration registers range (78h-7Fh), so write access to any of 78h-7Dh addresses will change CFG1 (78h-79h in N8VEM SBC) and write access to 7Ch-7Fh will change CFG2 (7Ch-7Dh in N8VEM SBC). This should not cause any compatibility problem, unless in the future N8VEM SBC or some N8VEM I/O devices will use 7Ah-7Bh or 7Eh-7Fh, and some software will try to access these ports.




  • UART interrupt output is connected to the ~INT of the Z80
  • FDC interrupt output has three connection options, selected by JP3 jumper:
    1. JP3 position 1-2 - FDC interrupt output is connected to the ~INT input of the Z80. This setting is compatible with N8VEM interrupt and fast interrupt modes.
    2. JP3 position 2-3 - FDC interrupt output is connected to the ~NMI input of the Z80
    3. JP3 not installed - FDC interrupt line is not connected to the CPU. This setting can be used with polling I/O mode.


Jumpers and Connectors


Jumper JP1 - CONFIG

JP1 is a software configuration jumper. It can be read by software using RTC port (70h) bit 6. This jumper is not currently used by software.


Jumper JP2 - PIN25_GND/VCC

JP2 connects pin 25 of the parallel port P4 to either GND or Vcc (+5). Note that pin 1 is the pin that is closer to the parallel connector.

Warning: If JP2 is set incorrectly, it is possible to create a short circuit of the 5 Volt power supply.

Jumper Position
P4 pin 25 is connected to the ground
P4 pin 25 is connected to Vcc. Use this position with PPIDE, make sure to set jumper K1 on PPIDE to position 2-3. Please refer to PPIDE documentation for more information.
no jumper*
P4 pin 25 is left open

* default


Jumper JP3 - FDC_INT/NMI

Jumper Position
FDC interrupt is connected to the ~INT input of  Z80. This is the default setting. Both interrupt and polling mode will work with it.
FDC interrupt is connected to the ~NMI input of Z80.
no jumper*
FDC interrupt is not connected. FDC polling mode will work with this setting

* default


Connector P1 - POWER

Connect regulated +5V power supply to this connector.

tip (the inner contact)
Positive terminal - +5V
barrel / sleeve
Negative terminal - ground


Connector P2 - RESET

P2 is the connector for an external reset button.


Connector P3 - SERIAL

P3 is the serial port connector. It is normally used for connecting a console or terminal. P3 uses pinout similar to that of IBM AT serial port (with some signals missing). Use a null modem cable to connect to a PC.

Pin Number
Not used - Not connected on the SBC
7 - 9
Not used - Not connected on the SBC
shield GND


Connector P4 - PARALLEL

P4 is the parallel port connector. It is connected directly to the 8255 PPI and can be used for attaching an IDE hard disk using the PPIDE mini board, for controlling external devices (e.g. printer, watering system), or for extending the SBC (e.g. connecting an LCD display and a keyboard). The pinout of P4 is the same as in other N8VEM boards (SBC V1, SBC V2, SBC-188).

Pin Number
Pin Number
Pin Number
Pin Number
GND or Vcc (see JP2)
3 PC1 11 PC5 19 PB6    
5 PC2 13 PC6 21 PB5    
6 PA2 14 PA6 22 PB2    
7 PC3 15 PC7 23 PB4    
8 PA3 16 PA7 24 PB3    


Connector P5 - FLOPPY

P5 is the floppy interface connector. It uses PC compatible pinout. When using a PC floppy cable with a twist, Drive A (ID 0) is the drive after the twist and Drive B (ID 1) is the drive before the twist. When using only one FDD, either a twisted cable can be used, or the BIOS can be patched to use Drive B.

Pin Number
Direction (relative to the SBC) Connected to
Odd pins are GND
High Density. This signal is ignored by most (all?) 3.5" drives.
Output DOR (bit 6)
4, 6
Not used
  No connection
Index Pulse
Input Schmidt Trigger, FDC (IDX)
Motor On B
Output DOR (bit 1), Buffer
Drive Select A
Output FDC (US0, US1), Decoder
Drive Select B
Output FDC (US0, US1), Decoder
16 Motor On A Output DOR (bit 1), Buffer
18 Direction Output FDC (LCT/DIR), Multiplexer
20 Step Output FDC (FR/STEP), Multiplexer
22 Write Data Output FDC (WDOUT), OC Buffer
24 Write Enable Output FDC (WE), OC Buffer
26 Track Zero Input Multiplexer, FDC (FLT/TR0)
28 Write Protect Input Multiplexer, FDC (WP/TS)
30 Read Data Input Schmidt Trigger, FDC (~DSKD)
32 Select Head Output FDC (HD), OC Buffer
34 Disk Changed Input DIR (bit 0)


Connector P6 - 5V

P6 is the 5V power output for the floppy drive. Alternatively it can be used instead of P1 for supplying power to the board. It is recommended to use a polarized header for P6 to avoid incorrect power polarity which probably will destroy FDD or components on the SBC board.

Pin Number


Bill of Materials (BOM)


BOM Notes

Disclaimer: I did my best to make sure that components listed in this BOM will be compatible with Zeta SBC. Obviously I didn't order all of components listed here, and I was not able to actually verify that they will work. Please make sure to double check specifications on manufacturer's and seller's web site before ordering. Please let me know (or update the BOM) if you found any problems or incompatibilities.


Many components have multiple part numbers listed in BOM. There are some differences between various part numbers, such as:

  • Different manufacturer (e.g. Texas Instruments vs. National Semiconductor for IC). Usually these ICs will be 100% compatible and won't have any differences in specifications. For some other components (e.g. connectors) different manufacturer also means different quality. It for example is likely to get a better quality connector from TE (was AMP/Tyco) than from some obscure manufacturer (e.g. components sold under Jameco ValuePro brand).
  • Specification differences
    • Different IC families (LS, ALS), different technologies (TTL and CMOS). They have different specs, and you might prefer to use certain IC family.
    • Different IC speed/frequency, especially for CPU, PPI, and memory.
    • Mechanical differences, especially for switches. Pick whatever suits best in your enclosure.
    • Minor differences. For example: RoHS or Pb-free vs. regular components; thickness of gold plating on connectors; frequency stability of oscillators and crystals.
  • Price differences

If unsure what to order, read specifications on seller's and manufacturer's web sites. There are some datasheets available in Zeta's Documentation folder. Also please read Replacement Notes below. Finally, consult people on N8VEM news group.



Component type  Reference
Possible sources and notes
PCB   Zeta SBC PCB Version 1.0 1 Order from Sergey
Battery Holder BT1
CR2032 batter holder, 20 mm lead spacing
Jameco 355434, Mouser 122-2620-GR, 122-2520-GR, 122-2420-GR, Radio Shack 270-009
C1 - C28
0.1 uF ceramic, 5.08 mm lead spacing

Mouser 80-C323C104K5R

Jameco 25523

Capacitor C29 47 uF, 6.3 V electrolytic 1 Jameco 31114, Mouser  667-ECA-1HHG470
Capacitor C30 10 uF, 6.3 V electrolytic 1 Jameco 94221, Mouser  667-ECA-1HHG100B
Diode D1 1N4148 1 Jameco 36038, 179215; Mouser 512-1N4148, 771-1N4148-T/R
D2, D3
Bi-level LED indicator
Jameco 2006676; Mouser 696-SSF-LXH240GYD
Standoff HOLE1, HOLE2, HOLE3, HOLE4
Standoff, M3 male / female, 20 mm
Mouser 534-24317534-25505, 855-R30-3012002
Note: The length of male end of these standoffs is 8 mm. It is too long for some floppy disk drives (you'll notice that standoff doesn't go completely inside the floppy drive mount hole). In this case cut a few millimeters using a file or a fine saw.
Screw, M3, 6 mm 4

Use regular floppy or CD-ROM drive mounting screws.

Mouser 534-29311


Connector JP1, P2 2x1 pin header 2
Jameco 108338; Mouser 649-78229-102HLF
JP2, JP3
3x1 pin header
Jameco 109576; Mouser 649-69190-103HLF, 649-78229-103HLF
Connector P1
DC jack
Jameco 101178; Mouser 806-KLDX-0202-A
DE9M, right angle PCB mount
Jameco 104943, 614441, 614459, 614432; Mouser 806-K22X-E9P-N, 806-K22X-E9P-N-99
(teal color), 571-1734351-1, 571-7478404
13x2 pin header

Jameco 53495; Mouser 649-68602-126HLF, 649-77313-824-26LF

Note: don't use shrouded connector, as it will interfere with the standoff and other components.

Connector P5
17x2 pin header shrouded
Jameco 68583, 753547; Mouser 737-BHR-34-VUA
Connector P6 2 pin header with friction lock

Jameco 232266, 613931; Mouser 571-6404562, 571-3-641126-2, 571-3-641215-2

Corresponding female connector: Jameco 234798; Mouser 571-770602-2; Contacts (2 contacts needed): Jameco 234923, 736501; Mouser 571-770666-1

It is recommended to use a polarized header to avoid incorrect power polarity.

Resistor R1 10 Ohm, 1/4 W 1

Jameco 690380

Mouser 291-10-RC

Resistor R2 10 kOhm, 1/4 W 1

Jameco 691104

Mouser 291-10K-RC

Resistor R3, R4 470 Ohm, 1/4 W 2

Jameco 690785

Mouser 291-470-RC

Resistor Array RR1 4.7 kOhm, 6 pin, bussed resistor array 1 Mouser 264-4.7K-RC, 652-4306R-1LF-4.7K
Resistor Array RR2 1 kOhm, 6 pin, bussed resistor array 1 Mouser 264-1.0K-RC, 652-4306R-1LF-1K
Tactile switch, right angle

Mouser 611-PTS645VL39LFS, 611-PTS645VL58LFS, 611-PTS645VL83LFS, 611-PTS645VL15LFS (Note: these switches have different actuator length, the number at the end of the part number denotes the length measured from ground terminal - from 3.9 mm to 15 mm. You might want to select it according your own preferences, for example the enclosure type you want to use, and whatever you want the reset button to stick out of the enclosure, or to stay hidden inside)

Jameco 1953575, 202956

IC U1 Z80 CPU, CMOS, 40 pin DIP - Z84C00xxPEC 1

Mouser 692-Z84C0010PEG, 692-Z84C0008PEG

Jameco 35781, 35705 (It appears that Jameco doesn't have 8MHz+ Z80 any more)

Frequency of U21 (CPU clock) oscillator should be less or equal to CPU frequency. 8MHz CPU recommended for 1.44 MB floppy disks support.

IC U2 512 KiB flash, 32 pin DIP - 29F040, 29C040, 39SF040 1 Mouser 804-39SF0407CPHE; Jameco 242667, 242659
IC U3 512 KiB SRAM, 32 pin DIP - AS6C4008-55PCN 1

Mouser 913-AS6C4008-55PCN; Jameco 1927617

Note: Jameco 242448 and 157358 (BS62LV4006P) should work too, but they are way too expensive

16550 UART
Mouser 701-ST16C550CP40-F; Jameco 27596, 288809
8255 PPI

Mouser 968-CP82C55AZ, 968-CP82C55A; Jameco 52417

Unicorn Electronics (order 82C55);

Order from Sergey; Utsource; eBay (beware, some sellers have way too high price on this IC). Can be replaced with FDC9268, in this case U23 frequency should be 16 MHz.

Mouser 595-SN74ALS273N, 512-DM74ALS273N, 595-SN74LS273N, 595-SN74AHCT273N; Unicorn Electronics; Jameco 47386, 308398, 45049

IC U8 74LS240 1

Mouser 595-SN74ALS240AN, 595-SN74LS240N, 595-SN74AHCT240N; Unicorn Electronics; Jameco 47141, 308291, 45014

IC U9, U10, U11 74LS174 3

Mouser 595-SN74ALS174N, 595-SN74LS174N, 595-SN74AHCT174N; Unicorn Electronics; Jameco 46931301760

IC U12 74F139 1

Mouser 595-SN74ALS139N, 595-SN74LS139AN, 595-CD74ACT139E, 512-74ACT139PC, 595-SN74AHCT139N; Unicorn Electronics; Jameco 46623, 301268, 63773, 239011

IC U13 74LS138 1

Mouser 595-SN74ALS138AN, 512-DM74ALS138N, 595-SN74LS138N, 595-SN74AHCT138N; Unicorn Electronics; Jameco 46607, 46608, 301233, 44927

IC U14 74LS125 1

Mouser 595-SN74LS125AN, 595-SN74AHCT125N; Unicorn Electronics; Jameco 46501

IC U15, U16, U17 74LS32 3

Mouser 595-SN74ALS32N, 512-DM74ALS32N, 595-SN74LS32N, 595-SN74AHCT32N; Unicorn Electronics; Jameco 44134, 47466, 47467, 295515

IC U18,U19 74LS14 2

Mouser 595-SN74LS14N595-SN74AHCT14N; Unicorn Electronics; Jameco 46640, 295460, 44935

IC U20 74LS06 1 Mouser 595-SN74LS06N; Unicorn Electronics; Jameco 46359
IC U21 CPU clock oscillator, full can 1

See frequency selection note for U1.

4 MHz: Jameco 27967, 354889; Mouser 815-ACO-4-EK, 520-TCF400-X

6 MHz: Mouser 520-TCF600-X

8 MHz: Jameco 27991; Mouser 815-ACO-8-EK, 520-TCF800-X (see Mods section below)

10 MHz: Jameco 27887; Mouser 815-ACO-10-EK, 520-TCF1000-X

20 MHz: Jameco 27932; Mouser 815-ACO-20-EK, 520-TCF2000-X

IC U22 1.8432 MHz oscillator, full can 1

Mouser 520-TCF184-X, 73-XO54B184

Jameco 27879

IC U23 8 MHz oscillator, full can 1

Mouser 815-ACO-8-EK, 520-TCF800-X

Jameco 27991

IC U24 MAX232A 1

Mouser 595-TRS202ECN, 701-SP202ECP-L, 700-MAX202CPE, 700-MAX232ACP

Jameco 875384, 1127599, 1800552,

IC U25 DS1302 1

Mouser 700-DS1302, 700-DS1302N

Jameco 176778, 780481, 1194644

IC U26 DS1210 1

Mouser 700-DS1210, 700-DS1210N

Jameco 114198, 2052040, 861880

IC Socket U1, U4 - U6 40 pin 600 mil DIP socket 4

Jameco 41111

Mouser 649-DILB40P223TLF, 517-4840-6000-CP

IC Socket U2, U3 32 pin 600 mil DIP socket 2

Jameco 112301

Mouser 649-DILB32P223TL, 517-4832-6000-CP

IC Socket U7, U8 20 pin 300 mil DIP socket 2

Jameco 112248

Mouser 649-DILB20P-223TLF, 517-4820-3000-CP

IC Socket U9 - U13, U24 16 pin 300 mil DIP socket 6

Jameco 37373

Mouser 649-DILB16P-223TLF, 517-4816-3000-CP

IC Socket U14 - U20 14 pin 300 mil DIP socket 7

Jameco 37162

Mouser 649-DILB14P-223TLF, 517-4814-3000-CP

IC Socket
U25, U26
8 pin 300 mil DIP socket 2

Jameco 51571

Mouser 649-DILB8P223TLF, 517-4808-3000-CP

Oscillator Socket U21 - U23 4 pin 300 mil DIP full can oscillator socket 3

Jameco 133006

Mouser 535-1107741

32768 Hz crystal

Mouser 732-C002RX32.76K-EPB, 695-CFS206-327KB-U

Jameco 14584





Replacement Notes

  • 74xx logic
    • TTL logic families: 74LS, 74ALS, 74F, or TTL-compatible CMOS: 74HCT and 74AHCT could be used.
    • Plain 74LS should work with CPU frequency up to 8 MHz. But it is recommended to use higher speed and lower power 74ALS ICs.
    • It is recommended to use 74F139 or 74ACT139 for U12, especially if using older 5.25" FDDs. I tested it with 74LS139, 74ALS139, and 74AHCT139 and it worked for me with modern 3.5" FDDs.
    • Tested with 74LS, 74ALS and 74HCT / 74AHCT  (except of 74LS06) logic families. Works on frequency up to 20MHz.
  • Z80-CPU
    • Either NMOS or CMOS Z80 CPU works. It is recommended to use at least 4 MHz CPU. 6 MHz or faster CPU is required for 1.44MB disk support. 8 MHz is recommended.
    • CMOS versions - Z84C00xxPEC or Z84C00xxPEG are recommended. Note: PEC or PEG suffixes mean 40 pin plastic DIP package, PEG is RoHS compliant, PEC is not.
    • Tested with CMOS Z84C00 (6MHz, 8MHz, 20MHz) and NMOS Z8400 (4MHz)
  • 16550 UART
    • 8250, 16450, or 16550.
    • 16550 is recommended
    • Tested with: Texas Instruments TL16C550, Exar ST16C550, National Semiconductor NS16550AFN, California Micro Devices CM16C550, Goldstar GM16C450, and UMC 8250B
  • 8255 PPI
    • It is recommended to use higher speed CMOS versions. For example 8 MHz Intersil / Harris CP82C55A part (note CP82C55A-5 is 5 MHz), 10 MHz Toshiba TMP82C55AP-10 or NEC D71055C-10 parts. 
    • Tested with: Harris/Intersil CP82C55, TMP82C55AP-10, NEC D71055C-10, Intel 8255-5
  • MAX232A
    • Can be replaced by pin compatible devices like Intersil HIN232 and Analog Devices ADM202. Make sure to use part that works with 0.1uF capacitors. See mods section below if using part that works only with 1uF capacitors.
  • Bi-Level LED Indicator
    • Can be replaced by two 3 mm LEDs with pins bended at 90 degrees.


Power Supply

Zeta SBC requires a regulated 5V power supply. Make sure that the tip of the power supply is the positive lead. System's power consumption varies depending on components used on SBC (CMOS CPU/PPI/UART vs. n-MOS components, CMOS logic vs. TTL/LS vs. TTL/ALS) and CPU clock frequency. Also floppy disk drives are relatively power hungry (about 1 A max). Jameco carries quite a few regulated switching 5V wall adapters with different amperage. See these catalog pages:



Alternatively it is possible to use a linear power supply with 7805 or similar voltage regulator (make sure to use a heatsink, especially if powering a floppy drive).




Mods described here were intentionally not implemented on PCB to keep it simple.

  • It is possible to use MAX232 for U24 instead of MAX232A, in this case capacitors C25 - C28 need to be replaced with 1uF electrolytic capacitors. Please refer to MAX232 datasheet for proper polarity.
    • Note: Zeta SBC version 1.3 has capacitors polarity marked on the silkscreen. The orientation of the capacitors on Zeta SBC version 1.3 differs from previous versions, so don't use its silkscreen to determine capacitors polarity on the previous PCB versions. Use this picture instead (Sergio, thanks for the picture).
  • It is possible to use half can oscillators instead of full can ones. In this case install oscillator at pins 4 - 11 and connect oscillator's pin 14 (VCC) to pin 11 using a piece of wire.
    • Note: Zeta SBC version 1.3 supports half can oscillators without any modifications.
  • If using 8 MHz CPU it is possible to save one oscillator, by using single 8 MHz oscillator for both CPU and FDC. In this case connect pins 8 of U21 and U23 using a piece of wire. (Douglas says: I am doing this and it works great)
  • It is possible to use FTDI DB9-USB-M module instead of the serial port connector P3. This module contains RS232 to USB converter IC and provides a mini USB connector. (Alexey, thank you for this tip). It even might be possible to use FTDI DB9-USB-D5-M module, eliminating MAX232A and related capacitors, and connecting the module directly to the UART.
  • It can be possible to use 1 MiB 27C080 EPROM. It has a bit different pinout from 29F040, so doing this will require cutting a couple of traces and adding some wires. Please compare datasheets for proper connection. Connect pin 12 of U10 to A19 of 27C080.  
  • It is possible to use 128 KiB 29F010 or 256 KiB 29F020 flash, and 128 KiB SRAM. Lower size flash devices should work without any changes (note, some AMD AM29F002 parts use pin 1 as ~RESET pin, apparently in this case pin 1 should be connected to Vcc). 128 KiB SRAM parts have two chip select inputs, in this case the second chip select CE2, pin 30, should be connected to Vcc.
  • If you don't plan to use 8255 PPI, it can be omitted. In this case it is not needed to install U4, C4, P4, and JP2.
  • It is possible to build Zeta SBC without floppy disk controller (for example for the test purposes, or if you don't need floppy). In this case following components can be omitted: U6, U7, U8, U19, U20, U23, C6, C7, C8, C19, C20, C23, JP3, RR2, P5, P6 (Note U20 also used for UART interrupt, so don't take it out if using interrupt-driven UART I/O)
  • It is possible to build system without RTC, in this case following components can be omitted: U11, C11,  U25, X1
  • If you don't want battery backup for SRAM, it is possible to omit U26. In this case it is needed to connect U26 pin 5 to pin 6 (~RAM_CS) and pin 1 to pin 8 (VCC).



PCB Versions


PCB Version 1.0

  • First PCB run, no major issues reported.
  • Reverse power supply polarity protection would be nice.


PCB Version 1.1

  • No changes to copper layers, a few minor updates to the silkscreen:
    • Added a drawing indicating power jack polarity.
    • Added outline for shrouded floppy interface connector, and moved floppy connector labels outside of that outline.
    • Added outline for keyed floppy power connected, and moved (+), (-) signs outside of the outline.
    • Added a logo.


PCB Version 1.2

  • No schematics changes
  • Minor updates to copper layers and to the silkscreen:
    • 20% wider power traces - 24 mils instead of 20 mils.
    • Some minor traces optimization.
    • Updated version and copyright information on the silkscreen.
  • Blue solder mask


PCB Version 1.3 (Current Version)

  • No schematics changes
  • Footprint of MAX232 charge pump capacitors C24 - C28 changed to C1-1, allowing using either capacitors with 5.08 mm (0.2") lead pitch or with 2.54 mm (0.1") lead pitch, for example electrolytic capacitors.
  • Added polarity (+) sign for C24 - C28 capacitors.
  • Connected pin 11 of oscillators U21 - U23 to VCC, so that half size oscillators can be used without any modifications to PCB.
  • Added half size oscillators footprint to the silkscreen.
  • Rotated crystal X1 (32768 Hz) by 90 degrees. Added pads for horizontal mounting bracket.


Various Ideas

  • Image enhancements
    • NVRAM support (BIOS configuration using NVRAM), NVRAM configuration utility 
  • Enhance utility for programming the BIOS, CP/M, and ROM disk separately. (It already supports the full image programming)
  • Add incorrect power supply polarity protection
    • Option 1: Schottky diode in series
    • Option 2: Diode connected in parallel to power supply, in reverse (could be dangerous if power supply is not short circuit protected)
    • Option 3: Use FET
  • DSR/DTR signals from UART are currently exposed on RS-232 connector.  However, 16C550C UART provides for auto flow control on the RTS/CTS lines which are not currently connected.  Ideally, provide a mechanism (jumpers?) to choose whether to expose RTS/CTS as an alternative to DSR/DTR.  The Z80 SBC V2 has an example of this.
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - Gerber - 1.0.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - Gerber - 1.1.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - Gerber - 1.2.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - Gerber - 1.3.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - KiCAD - 1.0.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - KiCAD - 1.1.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - KiCAD - 1.2.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Zeta SBC - KiCAD - 1.3.zip
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM
Sergey Kiselev,
Jan 23, 2015, 11:38 AM