FreeCalypso > hg > freecalypso-tools
view doc/SIM-hardware-debugging @ 800:8dc93aac9a9c
pcm-sms-decode & sms-pdu-decode: use new function for
alphanumeric From/To addresses
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Thu, 25 Mar 2021 01:29:05 +0000 |
parents | 0f138858ff39 |
children |
line wrap: on
line source
This article is only going to be of interest to those who are physically producing Calypso-based hardware and therefore get to deal with the joys of yield troubleshooting and failure analysis. If you are a mere user or software developer working on known-good hardware made by someone other than you, then none of the following applies to you. Testing the SIM interface on a Calypso device ============================================= A basic pass/fail test of the SIM interface is quite straightforward: simply insert a test SIM into the socket (at FreeCalypso hw manufacturing we currently use Sysmocom SIMs for this purpose) and issue an AT+CFUN=1 command to the standard firmware; if the SIM interface hardware is good, the command will complete successfully with an OK response, otherwise it will throw up an error. But what do you do when this basic test fails? If you get a "SIM not inserted" error even though the SIM *is* in fact inserted, how do you debug it further? In order to facilitate lower-level debugging of SIM interface woes, we have implemented a standalone simtest program described in this article. To run this simtest program on your Calypso device, run an fc-iram command like this: fc-iram -h fcfam /dev/ttyXXX /opt/freecalypso/target-bin/simtest.srec Like other interactive programs in our target-utils suite, this simtest program will present a '=' prompt for you to type further commands. The following sequence of commands should bring up the SIM interface if the hardware is good: abbinit volt 1.8 setup poll on reset 1 (Update for fc-host-tools-r11: the explicit abbinit command is no longer needed, but it is harmless to issue this extra command like before.) You can change volt 1.8 to volt 3 if needed, but all recently made SIMs prefer 1.8 V and merely tolerate higher voltages. TI's Iota ABB chip, which is what we target in FreeCalypso, does not support 5V SIMs - it doesn't have a charge pump or any other boost converter to produce 5 V from lower battery voltages. (It is not just TI but all mobile chipset vendors; it has been a very long time since anyone made a phone that can power 5V SIMs, and any old 5V-only SIMs have thus stopped being usable just as long ago.) If the hardware is good and you have a working SIM inserted in the socket as you execute the above commands, you should see ATR bytes from your SIM appear in your terminal window the moment you issue the last reset 1 command: that final command transitions the SIM reset line from low to high, if the SIM has been given good power and clock prior to this event, this transition causes it to initialize and emit its Answer To Reset, and once you issue the poll on command, our simtest program listens for incoming bytes from the SIM at the same time while it listens for you to type further commands. If you execute the above command sequence with a known-good SIM inserted in the socket and you don't see any ATR bytes on the final reset 1 command, then you have confirmed with a lower-level tool that your SIM interface hardware is having some issues. Give it a poweroff command, rerun the fc-iram command to get a fresh session, and get your oscilloscope ready. Now execute the commands slowly, probing with your o'scope at each step: abbinit volt 1.8 The volt command enables the VRSIM regulator in the Iota ABB chip and causes it to put out the selected voltage. You should see this voltage appear on SIM socket contact C1 (VCC); if it fails to appear there, then trace out the circuit coming from VRSIM, and the VRSIM regulator itself (inside the chip) may also be suspect. setup This command puts the SIM interface block inside the Calypso into a sensible state and enables the SIM interface level shifters in the Iota ABB. After this command you should see a good 3.25 MHz clock (13 MHz divided by 4) with selected SIM voltage levels on the SIM CLK line (socket contact C3), the RST line (socket contact C2) should be low, and the I/O line (socket contact C7) should be high. The SIM clock is produced in the Calypso and then voltage-translated by a unidirectional buffer in the Iota ABB, thus if the clock fails to appear at the SIM socket, look for issues in that signal path. For the I/O line to be high at this point in the bring-up sequence, the resistor pull-ups on both DBB-to-ABB and ABB-to-socket sides need to be working; if the I/O line is high on the DBB-to-ABB side and the pull-up on the ABB-to-socket side is good, but the I/O line on the ABB-to-socket side is still low, then there may be something wrong with the level shifter in the ABB holding it low. poll on reset 1 (The poll on command can be omitted if you are doing o'scope probing on an empty socket and thus not expecting any ATR.) As you issue that reset 1 command, hold your oscilloscope probe on SIM socket contact C2, which is the RST line - it should go from low to high. Our simtest utility's reset command (reset 0 or reset 1) manipulates one bit in one Calypso register that controls the Calypso chip's SIM_RST output, which then passes through a unidirectional level shifter in the Iota ABB on its way to SIM socket contact C2. On those two FCDEV3B V2 boards that have been rejected as defective because of a non-working SIM interface and which are now being revisited for a more thorough investigation, we have not yet seen any problems with the SIM power supply voltage, with the SIM CLK line or with the I/O line pull-up, but on both boards the SIM RST line is not working: we see a constant low at socket contact C2 (the only probe-able point in the entire SIM reset signal path), and reset 1 produces no effect. Unfortunately there is no way to probe the DBBSRST signal going from Calypso to Iota (it goes from one BGA to the other on an inner layer without coming up to the surface except right under the two ball pads), thus it is too difficult to tell where the breakage occurs: is it the Calypso failing to put out a high on its SIM_RST output when commanded to do so by the register setting, is it some fault in the PCB shorting this signal to GND before it reaches Iota's DBBSRST input, is it some fault inside the Iota chip itself that causes it to put out a low on its SIMRST output even though the DBBSRST input is high, or is it some fault in the PCB shorting the ABB-to-socket SIM RST output to GND? Given that FCDEV3B is not intended to be a high-volume product (we only need to make enough good boards to provide one to every interested developer or tinkerer), it will probably make more economic sense to simply reject SIM- defective boards and write them off as a loss than to spend astronomical amounts on PCB microsurgery to expose the DBBSRST signal for probing or other in-depth troubleshooting measures along those lines. For future board designs that may need to be produced in higher volumes, the Mother's current plan is to add probe-able test points on DBBSCK and DBBSRST lines, so that if similar problems recur, we'll be able to quickly isolate them to the Calypso side or the Iota side.