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168 lines
5.9 KiB
Markdown
168 lines
5.9 KiB
Markdown
---
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title: "Troubleshooting a TommyPROM Build"
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permalink: /docs/troubleshooting
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exerpt: "Troubleshooting TommyPROM hardware and software"
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---
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## Hardware Verifier Tool
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A [Hardware verification Arduino sketch](https://github.com/TomNisbet/TommyPROM/tree/master/HardwareVerify)
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is provided to assist with troubleshooting. Loading this sketch onto the TommyPROM
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hardware allows access to individual control lines from the Arduino to verify that the
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hardware was assembled correctly.
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The verifier sketch can be used without a chip installed to scope out address and data
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lines. It also offers low-level control when the chip is installed.
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THIS TOOL USES DIRECT PORT ACCESS ON THE ARDUINO. CHECK TO MAKE SURE IT IS COMPATIBLE
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WITH YOUR BOARD BEFORE USING. It will work correctly on the Uno, Nano, and Boarduino. It
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WILL NOT WORK on the Micro.
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Note that the commands write to the individual 28C control lines with some exceptions to
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protect the chip and the host Arduino:
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* When the O command is used to enable chip output, the Arduino data bus is set to INPUT
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* When the D command is used to write data from the Arduino, the chip output is disabled
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* The R command sets the output enable (OE) on the chip, but not the chip enable (CE)
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* The L and U commands reset CE, OE, and WE back to disabled on completion and change the
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data and address
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The session below shows how a write fails to a locked chip and then succeeds once the chip
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is unlocked.
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```
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Hardware Verifier - 28C series EEPROM
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Valid commands are:
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Axxxx - Set Address bus to xxxx
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Dxx - Set Data bus to xx
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Cs - Set Chip enable to state (e=enable, d=disable)
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Os - Set Output enable to state (e=enable, d=disable)
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Ws - Set Write enable to state (e=enable, d=disable)
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R - Read and print the value on the data bus
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L - Send Lock sequence to enable device Software Data Protection
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U - Send Unlock sequence to disable device Software Data Protection
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#l
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Writing the lock code to enable Software Write Protect mode.
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#a0000
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#ce
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#r
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22
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#d55
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#we
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#wd
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#r
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22
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#u
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Writing the unlock code to disable Software Write Protect mode.
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#d33
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#we
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#wd
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#r
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33
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#cd
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```
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## Troubleshooting
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If the programmer seems to be working, but 28C256 EEPROMs cannot be written, the problem
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may simply be a locked chip. Some chips have been received with the Software Data
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Protection (SDP) enabled, even though the data sheet states that it should be disabled
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from the factory. If the chip does not write (try the Zap command in the TommyPROM code),
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then try an Unlock command and then retry the write.
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If the programmer is not working, the most common problem is a simple wiring error. The
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hardware verify sketch can help to find missing or crossed connections.
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The hardware has three sections: an 8-bit read-write data bus connected to the target
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PROM's data line, a set of write-only address lines generated by shift registers and
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connected to the target PROM's address lines, and a set of write-only control lines from
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the Arduino that toggle the PROM's output enable and write lines.
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The first step in general testing it to remove the target chip and then toggle single
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lines from the Arduino. The result should be measured at the target PROM footprint, not
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at the Arduino. To fully test, use a multimeter to verify that the lines that should be
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active are active and that any other lines are not.
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Note that the Dx and Ax commands can be a bit confusing. The command _D5_ means "set the value 05 HEX on the eight data lines". It does not specifically refer to the D<sub>5</sub> data pin on the ROM or the D5 pin on the Arduino. In the example above, 05 HEX is the same as 00000101 BINARY. This would set the ROM D<sub>0</sub> and D<sub>2</sub> pins HIGH and the other six pins would be LOW.
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### Testing the data bus
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Issue a set of Data commands from the Hardware Verify sketch and measure EACH data line at
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the PROM footprint. **If the expected result is "D<sub>0</sub> HIGH", verify not only
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that D<sub>0</sub> reads HIGH, but that all of the other lines read LOW.**
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Data test commands
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|Command|Result|
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|:--- |:--- |
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|D0 |All data lines LOW|
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|D1 |D<sub>0</sub> HIGH|
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|D2 |D<sub>1</sub> HIGH|
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|D4 |D<sub>2</sub> HIGH|
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|D8 |D<sub>3</sub> HIGH|
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|D10 |D<sub>4</sub> HIGH|
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|D20 |D<sub>5</sub> HIGH|
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|D40 |D<sub>6</sub> HIGH|
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|D80 |D<sub>7</sub> HIGH|
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|Dff |all data lines HIGH|
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### Testing the address lines
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As with the data tests above, verify not only the line with the expected result, but all
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other address lines as well.
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|Command|Result|
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|:--- |:--- |
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|A0 |All address lines LOW|
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|A1 |A<sub>0</sub> HIGH|
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|A2 |A<sub>1</sub> HIGH|
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|A4 |A<sub>2</sub> HIGH|
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|A8 |A<sub>3</sub> HIGH|
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|A10 |A<sub>4</sub> HIGH|
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|A20 |A<sub>5</sub> HIGH|
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|A40 |A<sub>6</sub> HIGH|
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|A80 |A<sub>7</sub> HIGH|
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|A100 |A<sub>8</sub> HIGH|
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|A200 |A<sub>9</sub> HIGH|
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|A400 |A<sub>10</sub> HIGH|
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|A800 |A<sub>11</sub> HIGH|
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|A1000 |A<sub>12</sub> HIGH|
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|A2000 |A<sub>13</sub> HIGH|
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|A4000 |A<sub>14</sub> HIGH|
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|A7fff |all address lines HIGH|
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### Testing the control lines
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The PROM control lines are active LOW, so an enable command will set the corresponding
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control line LOW and a disable will set it HIGH. Try the commands in the following table.
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Note that they should be done in the order listed, because a test command on one control
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line will not change the state of any of the other lines.
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To begin, issue the following commands: D0, A0, Cd, Od, Wd. Note that the Od command is
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the letter 'O', not the number zero. All three control lines should read HIGH after these
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commands are complete.
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|Command|Result|
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|:--- |:--- |
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|Ce | Chip Enable (CE) LOW, others HIGH|
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|Cd | CE, OE, WE all HIGH|
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|Oe | Output Enable (OE) LOW, others HIGH|
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|Od | CE, OE, WE all HIGH|
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|We | Write Enable (WE) LOW, others HIGH|
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|Wd | CE, OE, WE all HIGH|
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