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author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Thu, 07 Nov 2019 22:41:19 +0000 |
parents | aa2533be2ec1 |
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The Tx power levels put out by a GSM mobile station are subject to strict specifications, and on the Calypso+Iota+Rita chipset they are produced by writing different values into the APC DAC register. But what value should be written into the APC DAC in order to produce a given Tx power level in dBm? The answer varies from one produced device unit to the next, and even more from one board design to the next, hence these APC values need to be calibrated. The general procedure for calibrating Tx power levels is described in both Sara and LoCosto calibration documents (see TI-docs), but the LoCosto document adds one crucial detail which the Sara one fails to describe. The instructions given in the Sara document appear to be perfectly intuitive at first: go through all power levels in turn (PL numbers 5-19 for EGSM and GSM850 or 0-15 for DCS and PCS), and for each power level command the DUT to transmit at that level, measure the actual Tx output power with the CMU200 or other RF test equipment, and adjust the APC DAC value up or down to make the output power match the spec. The problem is with the very last part: the output power you get with the compiled-in APC DAC value is one number, the spec-defined target power is a different number, exactly how do you adjust the APC DAC value to hit the target power level? The LoCosto document gives the answer which was not at all obvious to me at first. I draw the reader's attention to section A.3.1 on page 43 of that document. The trick is as follows: the relation between the APC DAC value and the resulting Tx output power (or rather the equivalent in terms of voltage) is modeled as a piecewise linear function, and this piecewise linear function is constructed from a preliminary set of output power measurements with a fixed set of APC DAC values. Looking at the Vout/LSB slope in each segment of this constructed piecewise linear function, one can see that the relation stays mostly linear throughout most of the RF PA's valid control range, and at least in the case of GSM MS devices made by Openmoko, the factory-calibrated power levels all fall into this "good" range in which the PA's response to the APC DAC control value is mostly linear. We also have a strong piece of evidence that the Tx power level calibration procedure performed by Openmoko at their factory was based on the same principle as the LoCosto document version. If you look at the /gsm/rf/tx/levels.900 table in Om-calibrated GTA02 units and compare it against the firmware's compiled-in version, you will see that the APC DAC values for power levels 5-19 have been replaced with calibrated ones as expected, but there is also this oddity: the APC DAC value for power level 0 (not a valid number for this band) has been replaced with 600. Always 600, a perfect round number, on every unit. Having understood the calibration method described in the LoCosto document, the mystery of this fixed number 600 becomes clear: the calibration program establishes the basis for the calibration by temporarily overwriting the APC DAC value in the power level 0 slot with a series of fixed values, 600 being the last of them. It constructs the piecewise linear model for the APC from power measurements made with these fixed DAC values, and uses this model to compute the DAC value for each target power level. The latter DAC values are then written into Tx levels table slots 5-19 for EGSM and GSM850, or 0-15 for DCS and PCS. In the case of DCS and PCS no visible artifacts remain from the calibration basis run (because slot 0 is a valid power level for these bands), but an artifact remains in the levels.900 table in the unused slot 0. Target power level numbers ========================== Ideally the power level numbers to be used as the targets for the calibration process would be the levels given in the GSM 05.05 spec: from 33 dBm down to 5 dBm for the EGSM and GSM850 bands or from 30 dBm down to 0 dBm for DCS and PCS, in 2 dB steps in each case. However, the evidence from TI's calibration documents (both Sara and LoCosto) is that some devices are not able to produce the very highest and sometimes the very lowest power levels given in the spec, and getting a successful calibration requires setting the calibration targets to slightly shifted numbers, although still within the tolerances allowed by the GSM 05.05 spec. The table in TI's Sara calibration document (page 26) has the highest power level reduced by 1.2 relative to the spec, the next highest by 0.5, whereas the lowest 4 (EGSM) or 6 (DCS) levels are raised and compacted together. The table in the LoCosto document (page 44) has the highest power level for each band reduced by 0.8, making it 32.2 dBm for EGSM and GSM850 and 29.2 dBm for DCS and PCS, while all other levels are set to the spec numbers. The calibration that was performed by Openmoko's factory (FIC?) on their GTA02 units is similar to what the old Sara document calls for: the highest power level is set to 31.8 dBm for EGSM or GSM850 and to 28.8 dBm for DCS and PCS, the next one down is 30.5/27.5 dBm instead of 05.05-spec-given 31/28 dBm, and for the lowest 4 (EGSM or GSM850) or 6 (DCS and PCS) power levels the decrement between levels is 1.5 instead of 2, putting the lowest EGSM or GSM850 power level at 7 dBm instead of 5 dBm, and the lowest DCS and PCS power levels at 3 dBm instead of 0 dBm. When it comes to the highest power levels, my (Mychaela's) first thought was that OM's calibration had them reduced to 31.8/28.8 dBm for no good reason other than OM/FIC mindlessly using some TI-provided calibration software that had those settings by default, as a leftover from some much older hw platform that was poorer in this department than OM's GTA0x hardware. As a matter of fact, it *is* possible to make an Openmoko-made GTA02 device put out the full 33 dBm in the EGSM band and the full 30 dBm in the DCS and PCS bands by setting the APC DAC to higher values than those used by OM's factory calibration. However, a closer look reveals that those higher-than-OM's APC DAC values which produce the full 33/30 dBm output put the PA outside of its linear range, i.e., the relation between the APC DAC control value and the resulting RF Vout no longer has the same linearity as is maintained at the lower power levels. In our own FreeCalypso calibration, we used to set the higher 32.2/29.2 or even the full 33/30 dBm targets for the highest power levels prior to the discovery of the linearity issue, but our current rf3166 profile set (see below) uses the same conversative upper-end targets as OM's original: 31.8/28.8 dBm for the highest power level and 30.5/27.5 dBm for the next one down. When it comes to the lowest power levels, the empirical observation is that the official spec bottom power levels of 5 dBm for the low bands and 0 dBm for the high bands are perfectly attainable both on Openmoko-made units and on our own FCDEV3B, with APC DAC values that are only a tiny bit lower than the lowest values in OM's calibration. We currently use 70 as the lowest basis point in the EGSM and GSM850 bands and 60 as the lowest basis point for DCS and PCS, following the LoCosto document; we are consistently able to get 5 dBm for the low bands or 0 dBm for the high bands within our basis range, and examination of the piecewise Vout/LSB slopes shows that the PA appears to be happily linear in this range. Therefore, we use the official spec numbers for the lowest power level targets in our current rf3166 profile set, not the raised target numbers from TI's older platforms. Profiles for Tx levels calibration ================================== Our fc-rfcal-txband program that performs the actual per-unit calibration of Tx power levels for each band requires a preconfigured txlevels calibration profile for each band as one of its inputs; if you are performing calibration on individual units of a board design for which the correct profiles have already been crafted, you simply use those given profiles (rf3166 for Openmoko and OM-based FreeCalypso hardware), but if you are doing Tx power level calibration on a new board design for the first time, you first need to characterize the Tx output level behaviour of your new board design and craft the appropriate set of profiles. The profiles for txlevels calibration reside in /opt/freecalypso/rfcal/txlevels; each per-band profile is sought in a file named profile_name-band_number, where profile_name is the profile name argument given to fc-rfcal-txband and band_number is one of 850, 900, 1800 or 1900. For example, if you are using the rf3166 profile set (appropriate for recalibrating Openmoko GTA02 devices and for factory production of new FreeCalypso devices with the same RF PA), the individual profile config files are rf3166-900, rf3166-1800 and rf3166-1900 for the tri900 band configuration. Each profile provides two key pieces of data: the list of fixed APC DAC values to be used as the basis set for constructing the piecewise linear model, and the list of power levels in dBm that will be the targets for the calibration. Crafting the txlevels calibration profiles for a new board design ================================================================= If you are working with a new (or new-to-you) board design with no previous Tx levels calibration experience, you need to begin by characterizing its Tx output level behaviour so you can determine what APC values are appropriate for the basis set, whether or not you need to shift the highest and/or lowest target levels from their nominal spec values, and if some target shifting is needed, which levels need to be shifted and by how much. The tool you will need for this investigation is fc-rfcal-txbasis. It requires fc-cmu200d and rvinterf to be running, talking to the CMU200 and to the DUT, respectively, and it takes the band number (850/900/1800/1900) and a set of APC DAC values on the command line; no pre-existing txlevels profile is needed. It commands the DUT to transmit at each of the specified APC DAC values in turn and reports the power output levels measured by the CMU200. VERY IMPORTANT: You need to be very sure that your CMU200 or other measuring instrument is itself in good calibration standing, i.e., that the measurements it reports are trustworthy, and that the insertion loss in your cabling setup (all the way from the actual DUT's antenna connector or RF test port to your CMU200) really matches the numbers you have put in your cable configuration file (see Cable-config-howto). If you fail to ensure these prerequisites, your fc-rfcal-txbasis observations will be meaningless, as the cable insertion losses and instrument errors are typically of the same order of magnitude as the transmitter differences you are trying to determine. You will need to run fc-rfcal-txbasis with a guesstimated set of APC DAC values, to be revised iteratively, and get a feel for what your DUT is putting out. Are you able to hit the lowest spec power level consistently while the APC DAC value remains well above zero? Are you able to hit the highest spec power level as well, or does the measured power output fall short of this target no matter how high you crank the APC DAC? These observations will tell you whether or not you need to shift the highest and/or lowest target power levels in your new txlevels calibration profile. 2018-02 addition: fc-rfcal-txbasis takes a new command line option -l; this option causes it to compute and print the Vout/LSB slope after the second and subsequent basis points; this option is useful for studying the linearity of the RF PA's response to APC DAC control values. Regular calibration runs ======================== Once you have a good set of profiles for the type of Calypso GSM device you are calibrating, just run fc-rfcal-txband with the band number and the name of your profile. Channel correction calibration ============================== The APC DAC values given in the levels tables apply directly only to the channels in the centre of each band. The transfer function from APC DAC control values to power output levels in dBm depends on the frequency, and the APC DAC values need to be adjusted for different subbands within each band in order to produce the correct output power levels for all channels. TI's RF driver code and calibration data structures provide for a Tx channel calibration, and all historical commercial manufacturers of Calypso GSM devices that are known to us have performed this Tx channel calibration on a per-unit basis on their production lines. Our fc-rfcal-txband calibration tool implements Tx channel correction calibration as of 2018-02, and we do it a little better than the way it was done by the big folks Back In The Day. TI's RF data structures allow for up to 4 channel calibration tables, to be used for different power levels, but Openmoko's factory only did one channel calibration set (calibrated at the highest power level for each band), using only one table out of the possible 4, and this one table (calibrated at the highest power level) is then used for all power levels. As far as we can tell, other Calypso GSM device manufacturers have done likewise. Our Tx calibration implementation makes use of all 4 available channel correction table slots. We divide the 15 power levels of EGSM and GSM850 bands or the 16 power levels of DCS and PCS into 4 groups (5-7, 8-11, 12-15, 16-19 for EGSM and GSM850; 0-3, 4-7, 8-11, 12-15 for DCS and PCS), perform channel calibration at the highest power level in each group, and set the resulting channel calibration table to be used for all 3 or 4 power levels in that group. Our procedure produces Tx behaviour that is identical to Openmoko's for the highest 3 or 4 power levels, but the lower power levels run with channel calibration that was made closer to them, as opposed to the very highest power level. The price of our approach is more time spent in RF calibration for each unit on the production line, but our approach is perfectly suited for low volume production and aftermarket recalibration services. Checking existing calibration ============================= fc-rfcal-txcheck is a completely non-invasive program (does not make any writes to any L1 RF tables or to FFS) that steps through all power levels for the specified band (5-19 for EGSM or GSM850, or 0-15 for DCS or PCS), performs a power measurement at each level, and displays the measured result. By default the test is performed at the centre frequency of the specified band, but the ARFCN to be used can also be specified on the command line.