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DUART-cable: update for DUART28
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Thu, 24 Sep 2020 02:47:14 +0000 |
parents | 6d7486db31cb |
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I, Mother Mychaela, hold the belief that any newly designed FreeCalypso hardware made in 2020 or later needs to be fully quadband, supporting all 4 possible GSM frequency bands of 850, 900, 1800 and 1900 MHz, nothing less. Furthermore, we do not need to invent or innovate anything in order to produce a quadband Calypso phone or modem: TI already had a quadband reference design back in the early 2000s, called Leonardo or Leonardo+ (the exact proper designation is unclear), we just need to resurrect it, adding some updates of our own like we always do. Our current FCDEV3B modem board is triband rather than quadband because of historical circumstances: while I had *always* desired a quadband solution since the very beginning of FreeCalypso (since I started gathering TI Calypso docs from Chinese sites in 2011), back in 2015 we did not have the necessary know-how to confidently resurrect TI's lost quadband reference design by doing a new PCB layout on the basis of the available surviving documentation, which consists of just schematics and a floorplan drawing - instead going with Openmoko's PCB layout and their triband RFFE was the only viable option at that time. We have now successfully produced both 900 MHz and 850 MHz versions of our FCDEV3B (different SAW filter parts populated on the same PCB footprint) and both work flawlessly as verified with our CMU200 instrument, so we do already support all 4 GSM frequency bands in a way - but only 3 at a time with our current hardware. A major breakthrough happened in December of 2019: we found a certain extremely obscure historical commercial Calypso modem module that is almost a verbatim clone of the core section of TI's Leonardo+ quadband reference design, and the knowledge gained from examination of this obscure historically-made modem module (both physical PCB reverse eng and evaluation of its RF performance with our CMU200 instrument) has given us the necessary confidence boost with this particular way of implementing a quadband GSM MS. Epcos M034F aka D1016 ===================== TI's Leonardo+ and E-Sample boards used a magic component made by Epcos (the canonical SAW filter manufacturer during that era) that was called M034 or M034F at the time of TI's designs in question. However, the same component is also known by a completely different name of Epcos D1016; this new D1016 name is the only one under which this component can be bought for the purpose of building new quadband FreeCalypso hw, and the physical markings on the component package only say "EPCOS D1016", no mention of M034. We (FreeCalypso) have no idea as to how and why this component got two completely different names. Here is a picture of the part: https://www.freecalypso.org/members/falcon/pictures/Epcos_D1016.jpeg The component in question is an integrated quadband FEM (front end module), integrating the antenna switch and SAW filters in one component package, with a special twist. The special twist is that even though there are 4 separate Rx band SAW filters inside that M034 "chip" module, corresponding to its advertised quadband capability, only 3 Rx signal path differential pairs come out of it, neatly corresponding to the 3 LNA inputs on TI's Rita transceiver. This twist is important because even though the Rita transceiver itself is fully quadband internally, it has only 3 LNA inputs, with GSM850 and EGSM bands sharing the same LNA input while each of DCS and PCS get their own. Thus this M034 FEM is special in that it facilitates building a quadband GSM MS using transceivers like TI Rita or Silabs Si4200 with only 3 LNA inputs, and the name M034 itself reflects this specialness: the digit 3 in the name refers to the 3 differential Rx signal paths, while the digit 4 refers to the 4 SAW filters inside which provide full quadband capability. We do have an M034F.pdf datasheet for this magic component (came along with Calypso and Leonardo docs), and the block diagram on page 6 shows the magic quite clearly: there is a baseband-controlled switch selecting between EGSM Rx and GSM850 Rx (in addition to the two usual Tx switches), this switch directs the low band Rx path toward one of two different SAW filters, and the outputs of those two filters are then joined. The high band Rx path always goes to both DCS and PCS band SAW filters, and each of those high band Rx SAW filters gets its own output going to its own dedicated Rita LNA input. Note the lack of a baseband-controlled switch between DCS and PCS in the high band Rx path! For a long time prior to the 2019-12 breakthrough I was concerned about this lack of a baseband-controlled switch between DCS and PCS in the high band Rx path: this switch is present in every triband RFFE design I am familiar with, including the one we got from Openmoko, and I was concerned that feeding the high band Rx path to both DCS and PCS SAW filters without a switch would introduce a 3 dB penalty into these high band Rx paths. But when I got my hands on the newly discovered Tango modem modules, looked at the GMagic numbers written into their FFS as part of the manufacturer's production calibration and then independently verified them with our CMU200, all fears were dispelled: the Rx performance of this M034 FEM in all 4 bands is exactly the same as our current Openmoko-based triband RFFE, with GMagic around 200 half-dB units. Now that we have physical proof that our desired quadband RFFE based on this Epcos M034 FEM and other aspects of TI's Leonardo design that go with it really works exactly as we would like and has been used successfully by a historical commercial modem module manufacturer (albeit an obscure non-mainstream one), the way forward for FreeCalypso is clear: instead of continuing with Openmoko's PCB layout and triband RFFE for our future hardware products, we can confidently go with a new PCB layout based on Leonardo/Tango, using Epcos M034 as our FEM and achieving the full quadband capability we have always wanted. The matching networks ("RF black magic") that would need to be placed between M034 Rx outputs and Rita LNA inputs were also a big area of concern for a long time - I did not feel confident with blindly going with the matching networks depicted on Leonardo schematics (or the slightly different E-Sample version) with no ability to actually understand them - but the new Tango find has once again saved the day. Tango uses exactly the same matching networks as depicted on Leonardo+ schematics (not the slightly different E-Sample version), or more precisely, it uses exactly the same topology (PCB layout), but with slightly different component values populated. The safest approach for FreeCalypso is once again clear: copy Leonardo+ matching network topology and Tango component values. Firmware compatibility ====================== Our current FreeCalypso firmwares drive TSPACT RFFE control signals as follows on FC hw family targets (CONFIG_TARGET_FCFAM): TSPACT1 = Rx PCS band TSPACT2 = Tx high bands TSPACT4 = Tx low bands TSPACT5 = Rx GSM850 band The driving of TSPACT1, TSPACT2 and TSPACT4 matches the way these signals have been assigned by Openmoko and thus the way they function on our current OM-based triband RFFE, whereas TSPACT5 is a new signal which is not wired anywhere on our current FCDEV3B. If and when we actually produce a new FreeCalypso hw product with the newly-confident M034 FEM, we will need to wire its control signals (going through logic-inverting PNP transistors as usual) to TSPACT2, TSPACT4 and TSPACT5 as mapped above, leaving TSPACT1 unconnected as there is no switch between DCS and PCS in the high band Rx path. This new control signal wiring is an original FreeCalypso invention, different from TI's original Leonardo and E-Sample TSPACT signal assignments, but in my maternal opinion having the same fcmodem firmware build run on both legacy FCDEV3B and future FC quadband modems would be more valuable than paying tribute to the historical Leonardo. Other ideas =========== In a previous version of this article I entertained the idea of getting an entirely new M034-like FEM custom-designed and made specifically for us, asking someone with the necessary capabilities to produce a new FEM for us that would be very much like the historical M034F, but with just two key differences: 1) A rearranged pinout so that the putative new FEM could be just "plopped" into our current OM-based PCB layout in the place of OM's triband RFFE; 2) Better-understood Rx output impedance specifications so that simpler and more intuitive matching networks like OM's could be retained as well. That desire was driven by the mystery of Epcos M034 and the lack of empirical test data for it, stemming from the lack of an already-existing historically- made physical specimen that could be examined and tested: I simply could not stomach the idea of expending a monumental effort on a new PCB layout followed by thousands of dollars of cost to physically produce the new experimental board batch while doing it as a completely blind stab-in-the-dark with the unknown Epcos FEM. But the discovery of Tango modems in 2019-12 has drastically changed the situation, and all mysteries and unknowns surrounding that M034 FEM have now been cleared. In the new reality that exists from 2020 onward that idea of commissioning the design of a new FEM to replace Epcos M034 no longer makes any sense and can be taken off the table: while it is true that using the existing M034 FEM will require doing an entirely new PCB layout (no more reuse of OM's version), it is now just a matter of doing the layout labor, no more risks or uncertainties, and the cost of this PCB layout job will certainly be much less than having a new FEM custom-made for us. Of course there are also myriad other, completely different ways of implementing a quadband GSM MS without using an M034-style FEM. The approach used by TI in the days of Calypso, using FEMs that combine the antenna switch and SAW filters in one component while the PA is separate, fell out of fashion shortly afterward, replaced with a competing approach where the PA and the antenna switch are combined into one component while Rx SAW filters are external - the latter approach is featured on TI's I-Sample (LoCosto) board, and it is quadband - LoCosto has 4 separate LNA inputs, not 3 like Rita. One could even implement the same approach while keeping the Calypso+Iota baseband, perhaps replacing TI's Rita transceiver with Silabs Si4210 (Aero II) that has 4 LNA inputs like LoCosto. But such ideas are far outside the scope of FreeCalypso, so if anyone feels like pursuing them, feel free to do so on your own, not involving FC - my mission in life is NOT to invent or innovate anything new, instead I am all about resurrecting and bringing back to availability those perfectly good and perfectly working technical solutions which already existed once before, but which have been wrongfully discontinued and thus taken away from us. In the present situation, the goal of producing a quadband GSM MS while reusing as much of the already existing FreeCalypso IP and know-how as possible would be accomplished most efficiently by using the newly-confident M034 FEM and doing a new PCB layout with it, hence that is the approach I am currently pursuing.