Difference between revisions of "Minimig Board v1.0 issues"
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− | + | == Power == | |
+ | * Suggestion: Include a +5V regulator on board OR use an ATX-style powerplug if you go Mini-ITX. The +5V regulator should be capable of providing about 1A to safely power all peripherals one might attach. | ||
− | + | * FYI: Peak & average powerconsumption of the minimig v1 ..? | |
− | + | :From what I have seen the power consumption is pretty constant. All boards I've built so far consume about <B>100mA</B> (excluding keyboard/mouse). | |
− | * | + | * FYI: Any power or grounding issues? |
+ | :I did use a "local-plane" setup. I have set most IO's to slow slewrates and drive currents. | ||
− | * Hardwire the patch needed to get the current board to run. Alternatively, you can also swap pin 81 and pin 79 on the FPGA. This way you still have four user- | + | == Issue: FPGA SPI_DOUT == |
+ | * Hardwire the patch needed to get the current board to run. Alternatively, you can also swap pin 81 (IO_L31_4/DOUT/BUSY=SPI_DOUT) and pin 79 (IO_L32P_4/GCLK0=RAM A15) on the FPGA. This way you still have four user-IOs left. You do need to change the .UCF file though and recompile the core. | ||
+ | <!-- Pin documentation at lower page 141 in ds099.pdf --> | ||
* PATCH needed to get rev 1 board working: | * PATCH needed to get rev 1 board working: | ||
− | :Disconnect net SPI_DOUT from pin 81 of FPGA. | + | :Disconnect net SPI_DOUT from pin 81 (IO_L31_4/DOUT/BUSY) of FPGA. |
− | :Connect net SPI_DOUT to pin 19 of FPGA (net USER3). | + | :Connect net SPI_DOUT to pin 19 (IO_L23N_7) of FPGA (net USER3). |
:Reason: | :Reason: | ||
− | :Pin 81 is an output during FPGA config that blocks SPI to MMC during startup. | + | ::Pin 81 is an output during FPGA config that blocks [[SPI]] to [[MMC]] during startup. |
+ | |||
+ | == Issue: SD/MMC == | ||
+ | * SPI_DOUT from SD-Card via 1k resistor and FPGA (pin81) conflicts ..? | ||
+ | : A gate would be better. During normal operation, the SPI out of the MMC card is tristated by disabling the MMC, the same goes at the FPGA side (it's a tristate port). This way, they can share the SPI bus. | ||
* The MMC card interface has a resistor based clock gate circuit around R50,R51. This should be replaced with a proper (single) gate "OR" chip. The margins on this signal are pretty tight on the current board. Also, R49 should be 0 ohm ideally to avoid problems when upgrading the PIC to a newer PIC18LF2620 or something similair. Margins are tight on that signal too atm. | * The MMC card interface has a resistor based clock gate circuit around R50,R51. This should be replaced with a proper (single) gate "OR" chip. The margins on this signal are pretty tight on the current board. Also, R49 should be 0 ohm ideally to avoid problems when upgrading the PIC to a newer PIC18LF2620 or something similair. Margins are tight on that signal too atm. | ||
+ | * Footnote: R49 sits between SD/MMC pin7 "D0" and SPI_DOUT ([[Minimig Board v1.0 sd-card|Picture]]). | ||
+ | |||
+ | * Improvement: pin11 SW#2 (write protect) and pin12 SW#3 (no card) maybe should be utilised to avoid accidential writes and interference with spi transfers ..? | ||
+ | :(SW#2=open => write protect, SW#3=open => no card present) | ||
+ | |||
+ | == Issue: Possible back emf on audio output? == | ||
+ | * [http://en.wikipedia.org/wiki/Headphone Headphones] may cause [http://en.wikipedia.org/wiki/Counter-electromotive_force back-emf]? (maybe supposed to be used as line-out only?) | ||
+ | == Issue: X1,X2 operating mode? == | ||
+ | * Crystals X1 and X2 is operating in parallel or serial mode ? | ||
+ | :Parallel. X1 is the base PAL clock of 4.433MHz for the FPGA. X2 is the 20MHz PIC clock | ||
+ | :Both are working independent of each other | ||
+ | |||
+ | == Issue: Video D/A inconsistency == | ||
+ | * Current Video D/A use non linear resistor ladder values. | ||
+ | :Current values: 4000Ω 2000Ω 1000Ω 560Ω | ||
+ | :Suggested values: 4220Ω 2100Ω 1050Ω 523Ω | ||
+ | : | ||
+ | :[[Minimig Video d/a resistor ladder|Video D/A resistor ladder maths & simulations]] | ||
+ | |||
+ | == Issue: SRAM == | ||
+ | [http://www.amiga.org/modules/newbb/viewtopic.php?topic_id=39358&forum=8&viewmode=flat&order=ASC&start=40#forumpost460135 Dennis 070725]:<br> | ||
+ | |||
+ | * The original SRAM used [http://rocky.digikey.com/WebLib/ST%20Micro/Web%20Data/M68AW512M.pdf M68AW512M] is [http://www.digikey.com/scripts/DkSearch/dksus.dll?Detail?name=497-1744-ND no longer available] | ||
+ | |||
+ | * Use a single chip ram like [http://www.cypress.com/portal/server.pt?space=CommunityPage&control=SetCommunity&CommunityID=209&PageID=259&fid=37&rpn=CY62167DV30&ref=sch this] one, available at [http://www.digikey.com/scripts/DkSearch/dksus.dll?Detail?name=428-1860-ND digikey] for example. | ||
+ | |||
+ | * Replacing the two 512k x 16 with one 1M x 16 bit ram will do away with one chip and free RAM_SEL1 | ||
+ | |||
+ | == Issue: LED resistors incorrect == | ||
+ | Seems R2, R61, R62 is incorrect due that R2 is powered by +5V, while R61, R62 is powered by +3,3V but all of them use the resistance value. [[LED|See LED maths]]. | ||
+ | |||
+ | == Info needed? RS232 pin header wiring == | ||
+ | * Connection, RS232: | ||
+ | :[http://www.scantips.com/serial-db9.html Internal x86-pc bracket pin mapping] | ||
+ | :Which wiring scheme is the most common for [[COTS]] sourcing? | ||
+ | |||
+ | == Optimization: Clock generation == | ||
* You could consider using a single 20MHz oscillator and figure out how to program the DCM to generator the proper clocks, this would spare a crystal. | * You could consider using a single 20MHz oscillator and figure out how to program the DCM to generator the proper clocks, this would spare a crystal. | ||
− | * | + | == Optimization: MCU & FPGA TxD sharing == |
− | : | + | * MCU(pic18) & FPGA TxD via AND-gate to rid of one jumper: |
− | : | + | :Yes, no problem. However, all debug output of the PIC has to be disabled as not to interfer with the FPGA serial output. |
+ | |||
+ | == Optimization: Use cdrom-soundcard cable? == | ||
+ | * Connection, Audio: | ||
+ | :[http://pinouts.ru/Multimedia/analog_creative_pinout.shtml internal x86-pc cdrom -> soundcard analogue audio pinout] | ||
+ | :Voltage level: (3.3V/(560ohm + 560ohm + 32ohm))*32 ohm*1000 = 91,7mV | ||
+ | |||
+ | == FYI: Power optimisation == | ||
+ | [http://www.amiga.org/modules/newbb/viewtopic.php?topic_id=39358&forum=8&viewmode=flat&order=ASC&start=260#forumpost461745 Dennis 070803]:<br> | ||
+ | * +1.25V and +2.5V can be hooked from +3.3V to save power ? | ||
+ | :No gain | ||
− | * | + | * Why is R42 present, it's just sitting between +1,25V and GND? |
− | : | + | :Provides a minimum load for the LM1117. |
− | * | + | == FYI: CPU A0 == |
− | : | + | * Why is the CPU pin 19 (A0) not connected to anything ..? |
+ | :The 68SEC000 is run in 16bit (selected by pin 8 (MODE=Vcc) ) mode, which means that only even addresses are used, hence the lsb address select is not needed. | ||
+ | :The addressing of byte wide memory addresses is done using the LDS/UDS strobes. | ||
− | * Why does the | + | == FYI: SRAM UB/LB == |
+ | * Why does the SRAM use /UB and /LB when data is 16-bit anyway? | ||
:[http://www.amiga.org/modules/newbb/viewtopic.php?topic_id=39358&forum=8&viewmode=flat&order=ASC&start=240#forumpost461433 jkonstan 070801]:<br> | :[http://www.amiga.org/modules/newbb/viewtopic.php?topic_id=39358&forum=8&viewmode=flat&order=ASC&start=240#forumpost461433 jkonstan 070801]:<br> | ||
:The UB & LB strobes on the SRAM are due to data bus addressing needed for the 68K cpu. 68K CPU has UDS* strobe for upper byte lane D15-D8 access, and 68K CPU has LDS* strobe for lower byte lane D7-D0 access. When 68K does a read, D15-D0 can be accessed as a word with 68K reading what it requires off of its Databus; however, a write access on a 68K CPU requires the byte lane be qualified. When UDS* active on a write cycle, UB* on SRAM must be active. When LDS* active on a write cycle, LB* on SRAM must be active. | :The UB & LB strobes on the SRAM are due to data bus addressing needed for the 68K cpu. 68K CPU has UDS* strobe for upper byte lane D15-D8 access, and 68K CPU has LDS* strobe for lower byte lane D7-D0 access. When 68K does a read, D15-D0 can be accessed as a word with 68K reading what it requires off of its Databus; however, a write access on a 68K CPU requires the byte lane be qualified. When UDS* active on a write cycle, UB* on SRAM must be active. When LDS* active on a write cycle, LB* on SRAM must be active. | ||
Line 45: | Line 103: | ||
:Ie 68k writes are byte wide. | :Ie 68k writes are byte wide. | ||
+ | == FYI: SD/MMC pcb layout pins == | ||
* The SD-MMC slot has a 12-pin wide connection to pcb. | * The SD-MMC slot has a 12-pin wide connection to pcb. | ||
:CD/D3, CMD, GND, VDD, CLOCK, GND, D0, D1, D2, SW#1, SW#2, SW#3 | :CD/D3, CMD, GND, VDD, CLOCK, GND, D0, D1, D2, SW#1, SW#2, SW#3 | ||
:SW#1="gnd", SW#2=open=>write protect, SW#3=open=>no card present | :SW#1="gnd", SW#2=open=>write protect, SW#3=open=>no card present | ||
+ | == FYI: Fpga pin ordering == | ||
* Why is address/data pins to ram/cpu spread around despite dedicated board? | * Why is address/data pins to ram/cpu spread around despite dedicated board? | ||
:Became such way to ease the PCB layout. <!-- check --> | :Became such way to ease the PCB layout. <!-- check --> | ||
− | * | + | * Why FPGA I/O pins aren't in numerical order? |
− | + | :Was simple when starting out. | |
− | |||
− | * | + | == FYI: FPGA config voltage == |
− | + | * FPGA configuration mode select M1,M0,M2 (pin 54, 55, 56) pins use VccAUX at +2.5V | |
+ | == FYI: keyboard + mouse wire sharing == | ||
* Keyboard and mouse can share connection? | * Keyboard and mouse can share connection? | ||
:Won't save data lines. <!-- check --> | :Won't save data lines. <!-- check --> | ||
+ | == FYI: Port overvoltage protection == | ||
* Over/under voltage protection for keyboard or mouse port? | * Over/under voltage protection for keyboard or mouse port? | ||
:It is a minimal design. The Spartan has built-in ESD protection that this design relies on. :However, monitors and TV's are notorious for blowing up video ports so extra protection has been added there! | :It is a minimal design. The Spartan has built-in ESD protection that this design relies on. :However, monitors and TV's are notorious for blowing up video ports so extra protection has been added there! | ||
+ | == FYI: BAV99 is 3-pin == | ||
* BAV99 diodes in the schematic is 3-pin not 2-pin as can be thought. | * BAV99 diodes in the schematic is 3-pin not 2-pin as can be thought. | ||
− | + | == FYI: 15/31kHz missing reference == | |
− | |||
* 15/31kHz selector is missing reference designation. | * 15/31kHz selector is missing reference designation. | ||
+ | == FYI: Component sizes == | ||
* Component size is missing. | * Component size is missing. | ||
+ | :Seems resistor size 0805 or 0603 will fit solder pads. See also [http://en.wikipedia.org/wiki/Surface-mount_technology#Package_sizes Wikipedia: Package sizes] | ||
− | + | == FYI: C37 value == | |
− | + | * Value of capacitor C37 is 100uF/6.3V | |
− | |||
− | |||
− | |||
− | |||
− | |||
− | * Value of C37 100uF/6.3V | ||
− | |||
− | |||
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− | |||
− | |||
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− | |||
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− | |||
+ | == FYI: Video setup == | ||
* Video, in 15kHz mode: | * Video, in 15kHz mode: | ||
:/VSYNC = high (scart RGB enable) | :/VSYNC = high (scart RGB enable) | ||
:/HSYNC = composite sync | :/HSYNC = composite sync | ||
− | |||
− | |||
− | |||
− | |||
− | |||
+ | == FYI: Possible SD/MMC incompability == | ||
+ | * Some (esp Sandisk.com) SD/MMC cards aren't standards compliant! see [http://jderogee.tripod.com/FAQ_1541.htm 1541-III FAQ] | ||
+ | |||
+ | == FYI: Seems nFPGA_SEL2 is unused == | ||
+ | Neither MCU or FPGA firmware sources reference this line in any active way. This could free one I/O.<!-- Confirm with Dennis --> | ||
+ | |||
+ | == FYI: I/O mode alternative == | ||
+ | LVTTL could be used instead of LVCMOS33. No cons/pros found at this time. | ||
+ | == FYI: Xilinx Place & Route limitation == | ||
[http://www.xilinx.com/ise/products/webpack_config.htm Xilinx ISE Webpack device support]<br> | [http://www.xilinx.com/ise/products/webpack_config.htm Xilinx ISE Webpack device support]<br> | ||
:Free version supports Spartan3 XC3S50 - XC3S1500 <!-- Has implication for m68k in hdl or expansions --> | :Free version supports Spartan3 XC3S50 - XC3S1500 <!-- Has implication for m68k in hdl or expansions --> |
Latest revision as of 09:12, 24 August 2008
Contents
- 1 Power
- 2 Issue: FPGA SPI_DOUT
- 3 Issue: SD/MMC
- 4 Issue: Possible back emf on audio output?
- 5 Issue: X1,X2 operating mode?
- 6 Issue: Video D/A inconsistency
- 7 Issue: SRAM
- 8 Issue: LED resistors incorrect
- 9 Info needed? RS232 pin header wiring
- 10 Optimization: Clock generation
- 11 Optimization: MCU & FPGA TxD sharing
- 12 Optimization: Use cdrom-soundcard cable?
- 13 FYI: Power optimisation
- 14 FYI: CPU A0
- 15 FYI: SRAM UB/LB
- 16 FYI: SD/MMC pcb layout pins
- 17 FYI: Fpga pin ordering
- 18 FYI: FPGA config voltage
- 19 FYI: keyboard + mouse wire sharing
- 20 FYI: Port overvoltage protection
- 21 FYI: BAV99 is 3-pin
- 22 FYI: 15/31kHz missing reference
- 23 FYI: Component sizes
- 24 FYI: C37 value
- 25 FYI: Video setup
- 26 FYI: Possible SD/MMC incompability
- 27 FYI: Seems nFPGA_SEL2 is unused
- 28 FYI: I/O mode alternative
- 29 FYI: Xilinx Place & Route limitation
Power[edit]
- Suggestion: Include a +5V regulator on board OR use an ATX-style powerplug if you go Mini-ITX. The +5V regulator should be capable of providing about 1A to safely power all peripherals one might attach.
- FYI: Peak & average powerconsumption of the minimig v1 ..?
- From what I have seen the power consumption is pretty constant. All boards I've built so far consume about 100mA (excluding keyboard/mouse).
- FYI: Any power or grounding issues?
- I did use a "local-plane" setup. I have set most IO's to slow slewrates and drive currents.
Issue: FPGA SPI_DOUT[edit]
- Hardwire the patch needed to get the current board to run. Alternatively, you can also swap pin 81 (IO_L31_4/DOUT/BUSY=SPI_DOUT) and pin 79 (IO_L32P_4/GCLK0=RAM A15) on the FPGA. This way you still have four user-IOs left. You do need to change the .UCF file though and recompile the core.
- PATCH needed to get rev 1 board working:
- Disconnect net SPI_DOUT from pin 81 (IO_L31_4/DOUT/BUSY) of FPGA.
- Connect net SPI_DOUT to pin 19 (IO_L23N_7) of FPGA (net USER3).
- Reason:
Issue: SD/MMC[edit]
- SPI_DOUT from SD-Card via 1k resistor and FPGA (pin81) conflicts ..?
- A gate would be better. During normal operation, the SPI out of the MMC card is tristated by disabling the MMC, the same goes at the FPGA side (it's a tristate port). This way, they can share the SPI bus.
- The MMC card interface has a resistor based clock gate circuit around R50,R51. This should be replaced with a proper (single) gate "OR" chip. The margins on this signal are pretty tight on the current board. Also, R49 should be 0 ohm ideally to avoid problems when upgrading the PIC to a newer PIC18LF2620 or something similair. Margins are tight on that signal too atm.
- Footnote: R49 sits between SD/MMC pin7 "D0" and SPI_DOUT (Picture).
- Improvement: pin11 SW#2 (write protect) and pin12 SW#3 (no card) maybe should be utilised to avoid accidential writes and interference with spi transfers ..?
- (SW#2=open => write protect, SW#3=open => no card present)
Issue: Possible back emf on audio output?[edit]
- Headphones may cause back-emf? (maybe supposed to be used as line-out only?)
Issue: X1,X2 operating mode?[edit]
- Crystals X1 and X2 is operating in parallel or serial mode ?
- Parallel. X1 is the base PAL clock of 4.433MHz for the FPGA. X2 is the 20MHz PIC clock
- Both are working independent of each other
Issue: Video D/A inconsistency[edit]
- Current Video D/A use non linear resistor ladder values.
- Current values: 4000Ω 2000Ω 1000Ω 560Ω
- Suggested values: 4220Ω 2100Ω 1050Ω 523Ω
- Video D/A resistor ladder maths & simulations
Issue: SRAM[edit]
- The original SRAM used M68AW512M is no longer available
- Replacing the two 512k x 16 with one 1M x 16 bit ram will do away with one chip and free RAM_SEL1
Issue: LED resistors incorrect[edit]
Seems R2, R61, R62 is incorrect due that R2 is powered by +5V, while R61, R62 is powered by +3,3V but all of them use the resistance value. See LED maths.
Info needed? RS232 pin header wiring[edit]
- Connection, RS232:
- Internal x86-pc bracket pin mapping
- Which wiring scheme is the most common for COTS sourcing?
Optimization: Clock generation[edit]
- You could consider using a single 20MHz oscillator and figure out how to program the DCM to generator the proper clocks, this would spare a crystal.
Optimization: MCU & FPGA TxD sharing[edit]
- MCU(pic18) & FPGA TxD via AND-gate to rid of one jumper:
- Yes, no problem. However, all debug output of the PIC has to be disabled as not to interfer with the FPGA serial output.
Optimization: Use cdrom-soundcard cable?[edit]
- Connection, Audio:
- internal x86-pc cdrom -> soundcard analogue audio pinout
- Voltage level: (3.3V/(560ohm + 560ohm + 32ohm))*32 ohm*1000 = 91,7mV
FYI: Power optimisation[edit]
- +1.25V and +2.5V can be hooked from +3.3V to save power ?
- No gain
- Why is R42 present, it's just sitting between +1,25V and GND?
- Provides a minimum load for the LM1117.
FYI: CPU A0[edit]
- Why is the CPU pin 19 (A0) not connected to anything ..?
- The 68SEC000 is run in 16bit (selected by pin 8 (MODE=Vcc) ) mode, which means that only even addresses are used, hence the lsb address select is not needed.
- The addressing of byte wide memory addresses is done using the LDS/UDS strobes.
FYI: SRAM UB/LB[edit]
- Why does the SRAM use /UB and /LB when data is 16-bit anyway?
- jkonstan 070801:
- The UB & LB strobes on the SRAM are due to data bus addressing needed for the 68K cpu. 68K CPU has UDS* strobe for upper byte lane D15-D8 access, and 68K CPU has LDS* strobe for lower byte lane D7-D0 access. When 68K does a read, D15-D0 can be accessed as a word with 68K reading what it requires off of its Databus; however, a write access on a 68K CPU requires the byte lane be qualified. When UDS* active on a write cycle, UB* on SRAM must be active. When LDS* active on a write cycle, LB* on SRAM must be active.
D15........D8 D7........D0 Byte 0= Even Byte 1= Odd => (Word 0) /UDS /LDS etc..
- Ie 68k writes are byte wide.
FYI: SD/MMC pcb layout pins[edit]
- The SD-MMC slot has a 12-pin wide connection to pcb.
- CD/D3, CMD, GND, VDD, CLOCK, GND, D0, D1, D2, SW#1, SW#2, SW#3
- SW#1="gnd", SW#2=open=>write protect, SW#3=open=>no card present
FYI: Fpga pin ordering[edit]
- Why is address/data pins to ram/cpu spread around despite dedicated board?
- Became such way to ease the PCB layout.
- Why FPGA I/O pins aren't in numerical order?
- Was simple when starting out.
FYI: FPGA config voltage[edit]
- FPGA configuration mode select M1,M0,M2 (pin 54, 55, 56) pins use VccAUX at +2.5V
FYI: keyboard + mouse wire sharing[edit]
- Keyboard and mouse can share connection?
- Won't save data lines.
FYI: Port overvoltage protection[edit]
- Over/under voltage protection for keyboard or mouse port?
- It is a minimal design. The Spartan has built-in ESD protection that this design relies on. :However, monitors and TV's are notorious for blowing up video ports so extra protection has been added there!
FYI: BAV99 is 3-pin[edit]
- BAV99 diodes in the schematic is 3-pin not 2-pin as can be thought.
FYI: 15/31kHz missing reference[edit]
- 15/31kHz selector is missing reference designation.
FYI: Component sizes[edit]
- Component size is missing.
- Seems resistor size 0805 or 0603 will fit solder pads. See also Wikipedia: Package sizes
FYI: C37 value[edit]
- Value of capacitor C37 is 100uF/6.3V
FYI: Video setup[edit]
- Video, in 15kHz mode:
- /VSYNC = high (scart RGB enable)
- /HSYNC = composite sync
FYI: Possible SD/MMC incompability[edit]
- Some (esp Sandisk.com) SD/MMC cards aren't standards compliant! see 1541-III FAQ
FYI: Seems nFPGA_SEL2 is unused[edit]
Neither MCU or FPGA firmware sources reference this line in any active way. This could free one I/O.
FYI: I/O mode alternative[edit]
LVTTL could be used instead of LVCMOS33. No cons/pros found at this time.
FYI: Xilinx Place & Route limitation[edit]
Xilinx ISE Webpack device support
- Free version supports Spartan3 XC3S50 - XC3S1500