Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?


  • Hero Member

    @mfalkvidd Good catch! I'll take your word for it. Thank you!

    Reporting back: I found a critical error. The library defaults to leaving the TX_EN and RX_EN pins disconnected. However, this module has a PA and LNA, so it is relevant to it. Since my first attempt merely followed the wiring instructions in the library, I had failed to enable these pins. Now that I have, it's a big improvement.


  • Hero Member

    Thanks to feedback from @mfalkvidd, I've constructed this as the new target:
    faster.JPG

    The directional sensitivity of the trace antenna is still a problem, so it'll have to wait until this Thursday, when the dipole antenna drives, to see whether the latest revision will be good enough or not.


  • Mod

    @NeverDie I am unable to find a better FCC reference than https://lowpowerlab.com/forum/rf-range-antennas-rfm69-library/fcc-rules-for-frequency-hopping/msg16006/?PHPSESSID=6e7efa8daee6de15d09c2b954879be34#msg16006 but that reference says:

    The maximum allowed 20 dB bandwidth of the hopping channel is 500 kHz.

    Since the module is now using 1,625 kHz bandwidth, it is again outside FCC rules.


  • Mod


  • Hero Member

    @mfalkvidd How about this then?

    better.png

    I'm spitballing this. If anyone has a better idea, or a correction, please do post!


  • Mod

    @NeverDie yes, looks good to me


  • Hero Member

    I found an IPEX to SMA adapter, and so I changed the antenna selector to select the soldered on IPEX connector and then borrowed an antenna from an unused wifi base station and connected it to the Ebyte module, like so, just to see if it would work at all.
    antenna_selector.JPG

    Doing this yielded a big improvement in Link Budget. Doing the same type of conversion on the LoRa transmitter module should make a noticeable difference, though I'm doubtful as to whether it will make enough of an improvement that it will perform as well as my AI-Thinker LoRa modules. Nonetheless, I'll attempt another, different, antenna hookup tomorrow when more antenna parts arrive from Amazon, and after testing it, I'll endeavor to reach a final conclusion.

    Chasing down all these loose ends has been tedious, so if anyone finds this blog useful, please leave a thumbs-up to this posting. so that I know I'm not wasting my time writing it all down. At the moment I'm liking my AI-Thinker LoRa modules better: they have much better range and without all this fanfare they seem to "just work" straight out of the box.


  • Hero Member

    It turns out Ebyte is kind enough to recommend specific antennas to use with this LoRa module:
    Ebyte_recommended_antennas_for_2.4Ghz_LoRa.png
    Unfortunately, these recommended antenna antenna models do not appear to be stocked by either Amazon or Mouser. Instead, it appears you may have to order them fromAliexpress:
    https://www.ebyte.com/en/product-class.html?key=tx2400 So, your best bet would be to order the Ebyte antennas at the same time you order your Ebyte LoRa modules. Unfortunately, I didn't, and I'm now getting the distinct impression that ordering suitable antennas from Amazon is a crapshoot, because I've found supposedly different dipole antennas, but with the exact same dimensions, being marketed for both the 915Mhz band and for the 2.4Ghz band. Surely that can't be right?! 🙄

    https://www.amazon.com/BETAFPV-Omnidirectional-Receiver-Connector-Receiver/dp/B09B21WBYW/ref=sr_1_3?crid=1I052I5H1UXHX&keywords=915mhz%2Bdipole%2Bantenna&qid=1650497087&sprefix=915mhz%2Bdipole%2Bantenna%2Caps%2C124&sr=8-3&th=1


  • Hero Member

    This is, allegedly, one of the TX2400-JW-5 antenna's that Ebyte recommends:
    https://www.aliexpress.com/item/1005003096039403.html?spm=a2g0o.cart.0.0.63133c00YzHVcW&mp=1

    and this, it looks to me, is probably the same antenna, available on amazon:
    https://www.amazon.com/gp/product/B093BVNPBW/ref=ppx_yo_dt_b_asin_title_o04_s00?ie=UTF8&th=1

    and which I'll be testing whenever it finally arrives from amazon (sometime soon). That way I'll be testing within manufacturer guidelines.


  • Hero Member

    Reporting back: I first tried a dipole antenna bought on amazon (link above) that was allegedly for 2.4ghz:
    dipole_antenna.JPG
    I put this on both the transmitter and the receiver. The good news is that the IPEX connector made a very snug fit with the EBYTE module, but the bad news is that the results were terrible:

    5s  Hello World 1234567890*,CRC,DAAB,RSSI,-81dBm,SNR,-2dB,Length,23,Packets,1,Errors,0,IRQreg,8012
    8s  Hello World 1234567890*,CRC,DAAB,RSSI,-87dBm,SNR,-18dB,Length,23,Packets,2,Errors,0,IRQreg,8012
    10s PacketError,RSSI,-78dBm,SNR,-20dB,Length,23,Packets,2,Errors,1,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    13s PacketError,RSSI,-78dBm,SNR,-14dB,Length,23,Packets,2,Errors,2,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    15s  Hello World 1234567890*,CRC,DAAB,RSSI,-87dBm,SNR,-16dB,Length,23,Packets,3,Errors,2,IRQreg,8012
    18s PacketError,RSSI,-80dBm,SNR,-7dB,Length,23,Packets,3,Errors,3,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    32s PacketError,RSSI,-80dBm,SNR,-14dB,Length,23,Packets,3,Errors,4,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    40s PacketError,RSSI,-85dBm,SNR,-21dB,Length,23,Packets,3,Errors,5,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    41s PacketError,RSSI,-86dBm,SNR,-17dB,Length,23,Packets,3,Errors,6,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    101s RXTimeout
    106s PacketError,RSSI,-72dBm,SNR,-12dB,Length,23,Packets,3,Errors,7,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    114s PacketError,RSSI,-75dBm,SNR,-11dB,Length,23,Packets,3,Errors,8,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    116s PacketError,RSSI,-76dBm,SNR,-11dB,Length,23,Packets,3,Errors,9,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    

    So, time to finally try the factory recommended antenna (also linked above). Unfortunately, the IPEX to SMA adapter I got was the wrong kind (female SMA instead of male SMA), so I had to fall back onto the only one Ipex-to-male-sma adapter I had. So, I put that on the receiver and left the transmitter with the dubious dipole antenna:
    factory_recommended.JPG
    More bad news was that the IPEX connector on this adapter made a rather loosey-goosey connection to the Ebyte module. How can that be? Are there different sizes/types of IPEX connectors or something? But, I went with it anyway because it's all I have at the moment, and the good news is that the result was tangible improvement:

    4s  Hello World 1234567890*,CRC,DAAB,RSSI,-67dBm,SNR,-3dB,Length,23,Packets,1,Errors,0,IRQreg,8012
    6s PacketError,RSSI,-67dBm,SNR,-2dB,Length,23,Packets,1,Errors,1,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    7s  Hello World 1234567890*,CRC,DAAB,RSSI,-72dBm,SNR,-11dB,Length,23,Packets,2,Errors,1,IRQreg,8012
    9s  Hello World 1234567890*,CRC,DAAB,RSSI,-66dBm,SNR,-3dB,Length,23,Packets,3,Errors,1,IRQreg,8012
    10s  Hello World 1234567890*,CRC,DAAB,RSSI,-67dBm,SNR,-2dB,Length,23,Packets,4,Errors,1,IRQreg,8012
    11s  Hello World 1234567890*,CRC,DAAB,RSSI,-71dBm,SNR,-7dB,Length,23,Packets,5,Errors,1,IRQreg,8012
    13s  Hello World 1234567890*,CRC,DAAB,RSSI,-66dBm,SNR,2dB,Length,23,Packets,6,Errors,1,IRQreg,8012
    15s PacketError,RSSI,-68dBm,SNR,-6dB,Length,23,Packets,6,Errors,2,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    18s  Hello World 1234567890*,CRC,DAAB,RSSI,-66dBm,SNR,-5dB,Length,23,Packets,7,Errors,2,IRQreg,8012
    19s PacketError,RSSI,-71dBm,SNR,-14dB,Length,23,Packets,7,Errors,3,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    20s  Hello World 1234567890*,CRC,DAAB,RSSI,-64dBm,SNR,0dB,Length,23,Packets,8,Errors,3,IRQreg,8012
    23s  Hello World 1234567890*,CRC,DAAB,RSSI,-65dBm,SNR,0dB,Length,23,Packets,9,Errors,3,IRQreg,8012
    25s  Hello World 1234567890*,CRC,DAAB,RSSI,-66dBm,SNR,1dB,Length,23,Packets,10,Errors,3,IRQreg,8012
    28s  Hello World 1234567890*,CRC,DAAB,RSSI,-65dBm,SNR,-3dB,Length,23,Packets,11,Errors,3,IRQreg,8012
    29s  Hello World 1234567890*,CRC,DAAB,RSSI,-73dBm,SNR,-10dB,Length,23,Packets,12,Errors,3,IRQreg,8012
    30s  Hello World 1234567890*,CRC,DAAB,RSSI,-71dBm,SNR,-10dB,Length,23,Packets,13,Errors,3,IRQreg,8012
    32s PacketError,RSSI,-66dBm,SNR,-15dB,Length,23,Packets,13,Errors,4,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    33s  Hello World 1234567890*,CRC,DAAB,RSSI,-71dBm,SNR,-9dB,Length,23,Packets,14,Errors,4,IRQreg,8012
    34s  Hello World 1234567890*,CRC,DAAB,RSSI,-75dBm,SNR,-12dB,Length,23,Packets,15,Errors,4,IRQreg,8012
    36s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,-10dB,Length,23,Packets,16,Errors,4,IRQreg,8012
    37s  Hello World 1234567890*,CRC,DAAB,RSSI,-67dBm,SNR,-1dB,Length,23,Packets,17,Errors,4,IRQreg,8012
    38s PacketError,RSSI,-72dBm,SNR,-20dB,Length,23,Packets,17,Errors,5,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    39s PacketError,RSSI,-68dBm,SNR,-5dB,Length,23,Packets,17,Errors,6,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    42s  Hello World 1234567890*,CRC,DAAB,RSSI,-71dBm,SNR,-7dB,Length,23,Packets,18,Errors,6,IRQreg,8012
    

    What's immediately evident is a big improvement in both the RSSI and the SNR. Bear in mind that this improvement is with the factory recommended antenna on only the receiver module. The seemingly lousy dipole antenna is still on the transmitter module.

    So.... next step is to order the right kind of IPEX to male SMA connector and see how it fares when the factory recommended antenna is connected to both the transmitter module and the receiver modules.


  • Hero Member

    A related topic is: just what kind of component is the antenna selector anyway?
    antenna_selector.png
    My measurements suggest it is just a zero ohm resistor. It's very tiny, however, which makes it difficult to desolder and then re-solder to the right pads when changing the selection. I did do that on the receiver module, but on the transmitter module I removed the selector component and then used a solder bridge to enable the IPEX antenna connector and disable the trace antenna.


  • Hero Member

    Reporting back: Answering my own question about the retention force on u.fl connectors, it turns out you may get only 5 connects/disconnects before the connector is shot and needs replacing. Source:
    How to Achieve Maximum U.fl RF Connector Reliability – 07:09
    — airborne0x0

    So, I'm guessing that why the u.fl connector on only my u.fl to sma adapter cable became loosey-goosey, as I described above. Fortunately, at least according to this source, the u.fl connector on the PCB doesn't wear out. It's just the cable connector side that does.


  • Mod

    Yes, the antenna selector is normally just a zero ohm resistor.

    About the antenna sma connector: there are 4 connectors, not 2.
    1f36edb6-0bb4-420b-b60a-f6ac252178e2-image.png


  • Hero Member

    @mfalkvidd Thanks for that! So, it appears that what I need are the RP-SMA connectors, not the SMA connectors. All the wifi stuff is generally RP-SMA for instance. Yet another picture (duplicative of yours) to drive it home:
    alt text
    I had thought that maybe the threading was also different, but what I now gather that's not the case, as it wasn't needed to render the two standards incompatible. It's helpful to know that the RP-SMA standard was created for wifi, specifically so that wifi users wouldn't plug their wifi stuff into non-wifi stuff. Well, you potentially can, because the threading is the same, but you'll either get no joy from it or might even damage your connectors, because the inner connector will be the wrong gender. IMHO, they really should have changed the threading too as a further precaution and named it "reverse gender" instead of "reverse polarity", since polarity seemingly has nothing to do with it. i.e. the outer casing is ground in both standards, and the inner conductor is what carries the signal in both standards. But, they didn't, and now we have to live with it.

    Fun fact: what I was calling the number of "connect/disconnects" is technically referred to as the number of "mating cycles".


  • Mod

    @NeverDie note that the picture you found has different naming for the RP variant than the picture I found.

    RP-SMA male vs RP-SMA plug female socket
    RP-SMA female vs RP-SMA jack male pin

    Confusion deluxe.


  • Hero Member

    @mfalkvidd Good catch! I hadn't even noticed until you pointed it out. If even the people who make pictures meant to clarify are confused.....


  • Mod

    @NeverDie the rule I learned (which is not politically correct, but memorable) is that the male always does the screwing and if the male doesn't have a d**k it's reverse polarity.

    The key here is to not focus on the signal connector, but on the mating. The female versions are fixed, the male versions screw on to the female.


  • Hero Member

    @mfalkvidd After checking just now what's for sale on amazon, your picture seems to be the right one. However, that phrase you have is bringing me to the wrong conclusion (the picture I posted). I mean, consider the RP-SMA female connector picture (referring to the picture you posted). You would think that would be male if anything is if that phrase was right. I mean, it screws "into" something else, and it has a d**k. Yet, evidently, its proper designation is female. Go figure.


  • Mod

    @NeverDie no. It doesn’t screw into anything. It is fixed. It cannot be turned without turning the entire cable. Hence the male is the one doing the screwing. The male variant can turn without turning the cable.


  • Hero Member

    @mfalkvidd Thanks! It finally makes sense now that you've explained it like that.


  • Hero Member

    Which thickness of coax cable should one prefer? Is thicker generally better? For instance, here are two connector cables of the same type, and both 50 ohm, but one is 0.81mm coax, and the other is 1.13mm coax. Does the difference matter?

    https://www.amazon.com/gp/product/B098QGFZ2J/ref=crt_ewc_title_dp_3?ie=UTF8&psc=1&smid=AODZVW3FCSGNT

    https://www.amazon.com/gp/product/B098QF5XF8/ref=crt_ewc_title_dp_1?ie=UTF8&psc=1&smid=AODZVW3FCSGNT

    [Edit: I do notice that they have different IPEX connectors, but I'm wondering just about the coax diameter.]


  • Hero Member

    I'll see it through to the end, but I think at this point Ebyte 2.4Ghz LoRa is now academic. With all this antenna nonsense getting in the way of a simple, inexpensive solution, it just doesn't hold a candle to a fully integrated solution, like this simple, compact LoRa gateway, where even a simple spring antenna is sufficient:
    LoRa_gateway.JPG

    The shield on top can be demounted and is a fully-standalone atmega328p driving the LoRa radio, which makes for a complete solution that's not much larger than the AI-Thinker module itself! I'll just drop a 915Mhz Ai-Thinker LoRa module into place instead of the 433Mhz module currently there, and, bang, it should "just work."

    I suppose desoldering the IPEX connector on the EBYTE module I could perhaps make a short jumper run from a custom PCB onto the EBYTE antenna pad..... Hmmm.... Kludgy, but it might work. In contrast, however, with the AI-Thinker modules there's a through-hole already set aside for a whip antenna.



  • @NeverDie The characteristic impedance of the coax is what matters. And that is all determined by the construction, which includes the thickness, but also other things, like what dielectric, and probably even what metal is used. (I don't know all the variables that they have to play with.)

    So it could be that both of those options you posted are fine. But buying stuff like this on Amazon, especially through third parties is a crap shoot. No telling if it will be good or not, and the reviews aren't usually very helpful, either, on RF stuff. Not saying you shouldn't do it - I will gamble myself, but just go in fully aware that your chances of getting something shoddy are good, and make sure the price you pay is worth the gamble.


  • Hero Member

    @ejlane Agreed. Where is it that you prefer to shop?

    A lot of the amazon stuff is the same as what one might find on Aliexpress, but the difference is I can get it fast and with free shipping from Amazon, and returns are a breeze. When it comes to quality, I think Mouser or Digikey usually has the best, but at usually higher prices even before you figure in shipping. Is there anywhere else worth considering? Maybe there's a good resource I've overlooked.



  • @NeverDie I think you've pretty much covered it. Yes, sometimes there's no good hobby-level alternative to Amazon/Aliexpress if you want it cheap.

    Though someplace like SparkFun or Adafruit can be good for hobbyists, though you'll pay for it.

    Along with Mouser and Digikey, sometimes I have good luck with Arrow or Newark. But really, it's nice to do a search with octopart.com or findchips.com if you have a pretty good idea of what you want. They will look at lots of vendors, even some that might be shading towards gray market. Can really save some time, and sometimes find things that I never would have otherwise. Saved me a few months ago on a customer project that would have otherwise had to be completely redesigned.


  • Hero Member

    Reporting back: Today I received proper IPEX to RP-SMA connector cable. I hooked up both the transmitter and receiver using them to the factory recommended 2.4ghz antennas. The transmitter and receiver are two rooms apart, and the signal has to pass through two closed doors. What I'm getting doesn't look great:

    4s PacketError,RSSI,-74dBm,SNR,-4dB,Length,23,Packets,0,Errors,1,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    7s PacketError,RSSI,-79dBm,SNR,-15dB,Length,23,Packets,0,Errors,2,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    9s PacketError,RSSI,-77dBm,SNR,-11dB,Length,23,Packets,0,Errors,3,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    12s PacketError,RSSI,-73dBm,SNR,-1dB,Length,23,Packets,0,Errors,4,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    13s  Hello World 1234567890*,CRC,DAAB,RSSI,-78dBm,SNR,-6dB,Length,23,Packets,1,Errors,4,IRQreg,8012
    14s PacketError,RSSI,-79dBm,SNR,-8dB,Length,23,Packets,1,Errors,5,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    16s PacketError,RSSI,-78dBm,SNR,-4dB,Length,23,Packets,1,Errors,6,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    18s PacketError,RSSI,-82dBm,SNR,-17dB,Length,23,Packets,1,Errors,7,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    26s PacketError,RSSI,-80dBm,SNR,-22dB,Length,23,Packets,1,Errors,8,IRQreg,8020,IRQ_HEADER_ERROR,IRQ_PREAMBLE_DETECTED
    28s PacketError,RSSI,-79dBm,SNR,-9dB,Length,23,Packets,1,Errors,9,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    31s PacketError,RSSI,-85dBm,SNR,-19dB,Length,23,Packets,1,Errors,10,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    32s PacketError,RSSI,-83dBm,SNR,-7dB,Length,23,Packets,1,Errors,11,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    35s  Hello World 1234567890*,CRC,DAAB,RSSI,-77dBm,SNR,-8dB,Length,23,Packets,2,Errors,11,IRQreg,8012
    37s PacketError,RSSI,-82dBm,SNR,-15dB,Length,23,Packets,2,Errors,12,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    50s  Hello World 1234567890*,CRC,DAAB,RSSI,-81dBm,SNR,-17dB,Length,23,Packets,3,Errors,12,IRQreg,8012
    51s  Hello World 1234567890*,CRC,DAAB,RSSI,-81dBm,SNR,-12dB,Length,23,Packets,4,Errors,12,IRQreg,8012
    54s PacketError,RSSI,-79dBm,SNR,-4dB,Length,23,Packets,4,Errors,13,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    57s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,-6dB,Length,23,Packets,5,Errors,13,IRQreg,8012
    60s PacketError,RSSI,-78dBm,SNR,-14dB,Length,23,Packets,5,Errors,14,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    62s  Hello World 1234567890*,CRC,DAAB,RSSI,-75dBm,SNR,-6dB,Length,23,Packets,6,Errors,14,IRQreg,8012
    67s PacketError,RSSI,-84dBm,SNR,-20dB,Length,23,Packets,6,Errors,15,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    69s PacketError,RSSI,-78dBm,SNR,-12dB,Length,23,Packets,6,Errors,16,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    72s  Hello World 1234567890*,CRC,DAAB,RSSI,-77dBm,SNR,-11dB,Length,23,Packets,7,Errors,16,IRQreg,8012
    76s PacketError,RSSI,-79dBm,SNR,-13dB,Length,23,Packets,7,Errors,17,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    78s  Hello World 1234567890*,CRC,DAAB,RSSI,-79dBm,SNR,-12dB,Length,23,Packets,8,Errors,17,IRQreg,8012
    80s  Hello World 1234567890*,CRC,DAAB,RSSI,-76dBm,SNR,-7dB,Length,23,Packets,9,Errors,17,IRQreg,8012
    83s PacketError,RSSI,-75dBm,SNR,-7dB,Length,23,Packets,9,Errors,18,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    86s PacketError,RSSI,-78dBm,SNR,-6dB,Length,23,Packets,9,Errors,19,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    103s PacketError,RSSI,-76dBm,SNR,-18dB,Length,23,Packets,9,Errors,20,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    105s PacketError,RSSI,-81dBm,SNR,-18dB,Length,23,Packets,9,Errors,21,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    108s PacketError,RSSI,-79dBm,SNR,-3dB,Length,23,Packets,9,Errors,22,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    109s  Hello World 1234567890*,CRC,DAAB,RSSI,-78dBm,SNR,-3dB,Length,23,Packets,10,Errors,22,IRQreg,8012
    110s  Hello World 1234567890*,CRC,DAAB,RSSI,-79dBm,SNR,-6dB,Length,23,Packets,11,Errors,22,IRQreg,8012
    112s PacketError,RSSI,-78dBm,SNR,-3dB,Length,23,Packets,11,Errors,23,IRQreg,8052,IRQ_RX_DONE,IRQ_HEADER_VALID,IRQ_CRC_ERROR,IRQ_PREAMBLE_DETECTED
    

    I think maybe the breadboard construction and long wires are introducing too much unwanted signals, resulting in lowered performance. The only way I can think of to get rid of that would be to make a specialty PCB that puts an atmega328p in close proximity with the module, so that there aren't long wires or long traces to pick up noise along the way.

    Or, maybe it's something else. In any case, I'm going to pause this and switch-over to a 915Mhz AI-Thinker module to see whether I get more traction there.


  • Hero Member

    Re-thinking this, probably the easiest way to exclude whether or not the breadboarding and related wiring is a crippling source of noise would be to create a PCB that an Arduino Pro Mini can dock with and which makes all the needed connections directly to the E28-2G4M27S. It's so easy that I should have thought of it in the first place! I have started work on it, and I'll post a rendering when its ready. I may post it in openhardware.io, and I think I may take a similar approach to future breakout boards as well. Pro-mini's are so cheap that it will make for a good way to test different radio modules.


  • Hero Member

    What happened to prices? I checked just now and pro mini's are selling for $5+. Pre-pandemic they could be had for closer to $1.



  • @NeverDie Haven't you heard of the chip shortage? It's changed everything, and prices for those things that are even available have generally gone up. (Though somehow magically, the ESP32 seems to be pretty much untouched. You can still buy them, and prices have been relatively stable. I don't know how they've done it.) AVR, PIC, STM chips have all been hard to get specific models, and at times any model that has the features. I expect other brands were similar, but those are the ones that I've looked for.

    I hope they someday go back, but for the foreseeable future, expect it to be like this.

    Pro minis for close to $1 was always a shock, since even at 1k qty, just the chip itself costs more than that. So to get to that price for the whole assembled board, there must be some kind of gray-market thing going on. If I were to try to make a profit on 1k at a time, assembled and everything, I'm pretty sure the final price would have to be in the ballpark of $10 each.



  • @ejlane & @NeverDie: Amazing technology that was available for $1 was … too hard to believe. Even $5 for a ProMini is pretty mind-blowing. Not that I buy commodities, I do buy these components a dozen at a time to save on shipping even when it is ‘free’. I laugh at myself when I spend a week of my time on a $2 chip and then wonder how I can rework it from a PCB (never worth the attempt). Compared to any other hobby or habit this radio-electronic stuff is cheaper than cooking top-ramen at home.
    BTW, thanks for the radio discussion posted last week. I will read and learn later.


  • Hero Member

    Here's the schematic for what I have in mind:
    Drop_In.png

    Thinking about it more, I don't think it makes sense to post it to openhardware.io until I've proven that it provides a big improvement over the breadboard, because if it turns out that it isn't an improvement, it might be drawing attention away from more worthy projects.

    Anyhow, I'll most likely use a similar method for building a test setup for the 915Mhz Thinker-AI radio, as it's ultimately more robust and less clumsy than breadboarding. In the meantime though I'll be breadboarding some old school 915Mhz LoRa modules to see whether going down that path is likely to bear fruit or not.


  • Hero Member

    So as to have a point of comparison, I today hooked up some old school SX1276 915Mhz LoRa modules (based on an Adafruit breakout board: https://www.adafruit.com/product/3072?gclid=EAIaIQobChMIxJm5r6-w9wIV_WxvBB0GjwCCEAQYASABEgLRofD_BwE ), and the difference is like night and day in performance:
    adafruit915MhzLora.JPG
    At the same distance as with previous tests, it works 100% flawlessly:

    377s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,10dB,Length,23,Packets,108,Errors,0,IRQreg,50
    378s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,109,Errors,0,IRQreg,50
    379s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,10dB,Length,23,Packets,110,Errors,0,IRQreg,50
    381s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,10dB,Length,23,Packets,111,Errors,0,IRQreg,50
    382s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,10dB,Length,23,Packets,112,Errors,0,IRQreg,50
    383s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,113,Errors,0,IRQreg,50
    384s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,114,Errors,0,IRQreg,50
    385s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,115,Errors,0,IRQreg,50
    386s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,116,Errors,0,IRQreg,50
    387s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,117,Errors,0,IRQreg,50
    388s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,118,Errors,0,IRQreg,50
    389s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,119,Errors,0,IRQreg,50
    390s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,120,Errors,0,IRQreg,50
    391s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,121,Errors,0,IRQreg,50
    392s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,122,Errors,0,IRQreg,50
    394s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,10dB,Length,23,Packets,123,Errors,0,IRQreg,50
    395s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,124,Errors,0,IRQreg,50
    396s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,9dB,Length,23,Packets,125,Errors,0,IRQreg,50
    397s  Hello World 1234567890*,CRC,DAAB,RSSI,-75dBm,SNR,10dB,Length,23,Packets,126,Errors,0,IRQreg,50
    398s  Hello World 1234567890*,CRC,DAAB,RSSI,-71dBm,SNR,10dB,Length,23,Packets,127,Errors,0,IRQreg,50
    399s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,10dB,Length,23,Packets,128,Errors,0,IRQreg,50
    400s  Hello World 1234567890*,CRC,DAAB,RSSI,-73dBm,SNR,9dB,Length,23,Packets,129,Errors,0,IRQreg,50
    401s  Hello World 1234567890*,CRC,DAAB,RSSI,-75dBm,SNR,9dB,Length,23,Packets,130,Errors,0,IRQreg,50
    402s  Hello World 1234567890*,CRC,DAAB,RSSI,-74dBm,SNR,10dB,Length,23,Packets,131,Errors,0,IRQreg,50
    
    

    which, quite frankly, is what I had been expecting from the 2.4GHz modules. Notice that these are also on breadboards, yet the SNR is vastly superior to what the Ebyte modules were reporting. So, although I can't yet say so definitively, I'm starting to suspect that there's something wrong with the Ebyte 2.4Ghz LoRa modules that I received. If I had a couple 2.4Ghz LoRa modules from a different manufacturer, it might tell the tale. As it stands, it doesn't much matter the reason, since performance at 915Mhz is so much better.

    I'll next try running the Ebyte modules direct from two AA batteries. If there's noise in the present power supplies, that should remove it. I've already put decoupling caps on the radio module, but I could also do the same with the Arduino Pro Mini. Sooner or later we'll find the culprit. If worse comes to worst, I'll fabricate this low noise test board and try it with that:
    low_noise_test_board.png


  • Hero Member

    Semtech did write a paper analyzing possible interference between the SX1280 LoRa and WiFi. Here is the conclusion:

    LoraWifiImmunity.png

    Not exactly sure what it means. Looks as though it doesn't have as much immunity to 802.11n as to 802.11g, which is maybe(?) a problem given how common 802.11n is these days. Reducing bandwidth and increasing spreading factor are the recommended workarounds. Unfortunately, all my neighbors have wi-fi, so finding unused spectrum, or with low enough signal, may not be feasible at 2.4Ghz.

    Come to think of it, I do have a dual-band meshed wi-fi network at home. I hadn't thought I needed tri-band, but this might be a case where backhauling over that third band, or possibly ethernet, might knock down some of the wi-fi generated "noise" in the 2.4Ghz spectrum. If this turns out to be part of the issue, then, indeed, going to 915Mhz instead would be a lot easier solution.


  • Hero Member

    One more reason for preferring 915Mhz over 2.4Ghz: The SX1262 (915Mhz) has a receive sensitivity of -148dBm, whereas the SX1280 (2.4Ghz) is only -132dBm. I hadn't realized the gap was so large. All by itself that's an appreciable difference. I suspect that to cash-in on all the potential receive sensitivity, it may require a TCXO, but I'd have to look that up to be sure. Now granted, external PA's and LNA's might be employed, but as far as the chips themselves, the max transmit power on the SX1280 is 12.5dBm, whereas on the SX1262, it's 22dBm, so at the chip level the SX1262 is more capable on the transmit side by a considerable degree.

    Comparing the SX1262 to the SX1276 (Adafruit that I tested today), the receive sensitivities are the same. The SX1276 has a max Tx power of 20dBm, so the SX1262's 22dBm transmit power is only just a little better. The SX1262 may be more energy efficient, but in terms of raw link budget, it's almost the same as the SX1276. So, for some applications, such as gateways, using SX1276 chips/modules might make sense if they're cheaper. However, looking at current market pricing, they don't appear to be. Strange.


  • Hero Member

    Reporting back: I tried running both transceivers off of two AA's with decoupling capacitors and... no change. I also tried varying the location, in case there was a strong local interference source. No change. Again, to recap: RSSI seems good, but SNR seems bad. So, the next thing left to try is the low noise PCB I pictured above. I'll do that, but fabrication will have to wait until I have other PCB's ready to be fabbed as well so as to save on shipping by combining the orders, because at this point getting these Ebyte SX1280 modules to work satisfactorily is looking more and more like a long shot. 😞 Given that Andreas Spiess was also not particularly sanguine about his Ebyte SX1280 LoRa modules, I suspect the blame may lay with the modules. Anyhow, it's becoming academic, because I'm moving on to 915Mhz LoRa, since from what I've seen firsthand so far that seems much more robust, and on paper an SX1262 or SX1276 handily outperforms an SX1280.



  • @NeverDie Hi, I've just started playing with a pair of these modules that I've had kicking around for a while. Fascinating thread and I haven't finished reading through yet, thanks for being so thorough!

    I'm using the same library. When it comes to enabling the TX_EN and RX_EN pins, can you clarify how? Is it done through the microcontroller script, or by setting the pin inputs to high (+3.3v)?


  • Hero Member

    @samh For the receiver node, I simply wired RX_EN to 3.3V and TX_EN to GND. For the transmitter module, I found that wiring TX_EN direcctly to 3.3V doesn't work so well (probably too high a duty cycle for the PA to be operating continuously like that), so I instead wired TX_EN to a spare pin and I modified the code so as to drive that pin HIGH just prior to transmitting and drive it to LOW when done transmitting. Also, on the transmitter node I wired RX_EN to ground. This seemed to work. However, it reminds me now that this was really just improvisation on my part for expediency in getting something setup fast.. Perhaps I should be using pull-up and/or pull-down resistors instead. Thanks for bringing up this topic! I'll investigate further. Please do post what you end up using youself, as well as whether you are getting similar or different results regarding noise (SNR) and/or range.


  • Hero Member

    Reporting back: It turns out that in the settings.h file, you can assign pins for TX_EN and RX_EN. I assigned Arduino pin 4 for TX_EN and pin 5 for RX_EN, and it works fine.

    I also inserted 10K resistors as a "just in case". I also increased TX_POWER to 10.

    I'm not sure which of the 3 changes made the most difference, but the result is noticeable improvement. SNR is still reported as low., but I am now getting reliable longer range than previously. Maybe SNR is just not measured accurately by the module?

    IIRC, the module has two forms of integrated step-down within the chip: an LDO and a buck converter. Not sure which one the library defaults to (I'll have to look it up) but if it's the buck, then switching over to the LDO might help with the SNR.

    [Edit: I just now checked, and the library defaults to using the LDO rather than the buck converter]


  • Hero Member

    Last update: I changed frequencies to 2.42Ghz, and SNR became a bit better, so maybe interference in the 2.4Ghz band really does play a role. It still performs much worse than the 915Mhz LoRa nodes I i discussed above however. At this point the next noticeable improvement, if anything, probably won't happen until I fab the custom low noise PCB which I showed above.



  • Thanks for letting me know, I'm going to play around with these over the weekend and I'll try to report back. Not too bothered about getting optimal performance since it's my first time messing with RF specifically in an arduino project, just want to do some basic testing. Some 868 modules are for sure on my list to check out next


  • Hero Member

    @samh Great! Looking forward to hearing how it goes for you. It's very helpful to compare notes.


  • Hero Member

    Regarding the 915Mhz SX1262, the Dorji brand seems interesting. They sell two different module types: one, the DRF1262T, with a TCXO at 1ppm, and one, the DRF1262G, with a non-TCXO crystal (uses less power) which they say is 10ppm. They also have a breakout board for Arduino Uno to facilitate testing:
    https://www.ebay.com/itm/192665058568
    https://www.ebay.com/itm/202574135410
    https://www.ebay.com/itm/202436579399

    So, in addition to the AI-Thinker Ra-01SH modules, I've ordered some of these DRF1262T/G to compare performance. Hopefully at least one of the three different models will be a winner.



  • @NeverDie, Thanks again for all the blogging on this subject. If you have not yet ordered your custom low-noise PCB, I had one design idea. If you flip the ProMini orientation end over end most of the traces will be shorter, especially the RX/TX lines. I’ve not examined the code, but I’d think that the RX/TX connections have the most signal activity on the board, thus EMI potential. I like how you keep all the traces on one side. That should solve the interrupted ground-plane problem we learned from Rick Hartley above.

    It is far more fun to roll-your-own. Alternatively, I was thinking … I just checked the Moteino breakout boards from Felix at LowerPowerLabs to see if those would work with your Ebyte radios: too bad, different pinout. I just bought a few Moteinos (915 mhz) boards to save myself from my low-quality solder jobs and shaky hands – only $13 but I have to add my own radio or spend another $7. Everything I've seen from LowPowerLabs has been high quality.



  • I've finally made a little progress over the last two days. Lots of background reading on the excellent SX12XX library and some tinkering to make a portable radio modem for future testing

    Here's the transmit end soldered up to a little bit of prototyping board I had lying around, which it turned out was the perfect size to fit the E28+breakout, Arduino Pro Mini, and voltage reg! All powered off a tiny 2S LiPo at the moment. The antennas are external Happymodel ELRS-intended and are supposedly 5dB...

    20220429_185809.jpg

    20220502_204110.jpg

    The voltage divider is included for battery monitoring. I modified the 'varying power' library examples (numbers 10/20) to include sending one battery voltage packet per test and print serial bytes in a slightly more interpretable format for a python script to read and save to csv.

    Just as a proof of concept, I looked at how RSSI/SNR vary with Tx power and RF attenuation, see below:

    • TC1 = line of sight, 3-4m separation
    • TC2 = as TC1 but cross-polarised antennas
    • TC3 = several brick walls of attenuation
    • TC4 = as TC3 but cross-polarised antennas
      (and yes, the axes are intentionally the wrong way around since it's easier to fit the plots on a horizontal screen this way!)

    untitled_2.png

    Clearly something is working right as RSSI drops off linearly with Tx power! SNR performance leaves a bit to be desired but seems that @NeverDie had similar results. Not very exciting but showing the setup is correct for now and I can move on to some more interesting things.

    Next up is to have a look at implementing the PA/LNA on the E28 modules and seeing what kind of difference I get in performance. Spotted the RX/TX_EN pins in the library documentation so I'll give those a go


  • Hero Member

    @samh Great stuff! I look forward to hearing more. As you probably know, the buck/boost converter (whichever it is) that's in your photo is a possible source of noise. I can't say whether, in reality, it would be or not. That's one of the reasons why (below), I'm planning to run directly from batteries only.

    @Larson Good suggestions. I decided to dump the pro mini idea and just make my own barebones pro mini, because pro mini's come with three things that aren't useful and actually get in the way: 1. the LDO, 2. the oscillator, and 3. the LED on pin 13. I'm hoping (but haven't confirmed) that by eliminating the oscillator on pins D20 and D21, I can use those pins to drive two LED's kinda "for free" since nobody uses those pins for anything. So, the first draft looked like this:
    Ra-01_pro_mini.png
    to get the shortest possible lines, like you said. It also includes a TPL5010 as an ultra low current wakeup timer. The main thing, though, is that it runs from two AA batteries, which are directly attached to the PCB itself. Well, this design was working out fine, but it seemed a bit tedious to redo it for each possible radio I wanted to test, so I think I'm settling on this instead as a test platform:
    new_draft.png
    which amounts to a stripped down pro mini (plus two I2C pinsout at the bottom for plugging in a TH sensor, or whatnot). In this case, the idea is to do a simple breakout board for each radio and connect it as a shield to the unused pins on the atmega328p. I figure it should be easier than doing a complete, fully integrated board for each radio. And I like that it's of minimal size (the footprint of two AA batteries), yet packs enough power that I expect it should have no trouble supplying even 200ma if needed just from the batteries themselves.

    I'm lucky in that I have a Dragon programmer, so I can both burn the bootloader and set the fuses on the atmega328p prior to soldering it into place on the PCB. From past experience, the sleep current on the atmega328p itself can be as low as 100na. In the past when Pro Mini's sold for only a buck, I leaned toward using Pro Mini's for everything. These days I guess I'll roll my own.

    I think eventually I want to replace the canonical 6 pin FTDI connection with a 5 pin picoblade. I've only just started looking into that. I was favoring the idea of using 1.0mm pitch JST-SH conectors for the task, but sourcing them didn't look easy. So, I'm reluctantly settling on the 1.25mm pitch picoblade instead. If there exists something even more compact (maybe some kind of 2x3 row of pins on a connector), then I'd be keen to hear what it is.

    The AA battery connectors are the Keystone 92, which look like this:
    Kyestone92.jpeg

    In the end, it might look like an improved variation of one of these:
    https://www.openhardware.io/view/395/LoRa-Ra-01-ATmega328P-Node
    https://www.openhardware.io/view/268/Arduino-Pro-Mini-Shield-for-RFM69HW
    https://www.openhardware.io/view/480/Compact-nRF24L01-Pro-Mini-Bottom-Shield
    but this time a bit more of a general purpose razor and blades system, if you catch my meaning. This time it will be a little wider than a pro mini, so it will be possible to fit any radio onto the shield. That said, I always liked the simplicity and ease of assembly of the "LoRa Ra-01 ATmega328P node". Perhaps the biggest improvement is the tight integration of the batteries, which in most designs are left "flapping in the breeze" as an afterthought for the builder to sort out.

    Anyhow, I have a bit more work to do, but that's the current evolution. As always, any thoughts, reactions, suggestions, or feedback appreciated.



  • @NeverDie. You are way out there, man! Thanks to the references to the other boards made by you. What fantastic contributions to the maker market.
    I suppose D20 and D21 are the same as PCINT6/XLTAL1 and PCINT7/XTAL2? I once reassigned RX and TX on an Attiny85 to RX and TX (edit: output functions) as I was pin limited. It took some doing, but that is the beauty of these multifunction pin assignments. The code, if I remember, had to be in the loop after a delay in the setup; that gave me a way to access the RX/TX pins again to reprogram if necessary. Maybe there are similar challenges with bypassing the crystal.
    @samh. So you are setting power levels on the fly. Very clever.


  • Hero Member

    @samh My first reaction is that your SNR is better than mine, especially for the measurements of going through several brick walls--though it's a bit hard to read the TC1-4 symbols when they're printed over one another, so I'm not completely sure. Since you also have some longish wires, I wouldn't be at all surprised if the cheap breadboards I used are, in one manner or another, impairing my SNR. This is where comparing notes can really be helpful. Thanks!

    Despite China's lockdown, it looks as though my Ra-01SH modules may be here before long, so I want to get my test PCB orders in soon!

    Looking forward to finally having a single test bed for comparing the performance of different radios modules! i.e. the only thing to change from one test to another will be the radio (and possibly software). For instance, it will be nice to know that when the bits "absolutely, positively, have to get there", which radio can do it reliably but also with the least amount of total energy? I mean, LoRa has the promise of great range, but the transmission time can be so long that may come at a pretty high energy price.... unless maybe the link budget allows the Tx power to be hugely reduced. That's what I'd very much like to know. i.e. which is ultimately better, if the figure of merit is energy spent per successfully delivered bit? FSK or LoRa? Or something else? Probably somebody out there in industry or the military or in academia has studied this question using the best equipment (or at least simulations) and published about it, but nothing beats real empirical results from whatever gear you have in your actual hands--because at the end of the day that's all you have to work with anyway. The cool thing is that the Semtech chips can do both FSK and LoRa, so you have the option to choose whatever best fits the situation, or switch back and forth depending on changing conditions. Ask near as I can tell, the FSK component of the Semtech LoRa radio chips is, essentially, an improved form of the RFM69's radio (which is also made by Semtech). My guess is that if you can get your packets delivered at 2mbps using an NRF24L01 (or equivalent NRF5x), then that's going to be the most energy efficient delivery method. But, if that doesn't work reliably enough, what's your next best option to get your bits delivered, and your next best option after that, etc.? And it's not just that: you need to compare sleep current consumption and wake-up times as well. Fun fact: when in the past I ran the numbers for mostly sleeping sensor devices, most often it's the sleep current consumption that dominates.


  • Hero Member

    @ejlane said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie Haven't you heard of the chip shortage? It's changed everything, and prices for those things that are even available have generally gone up. (Though somehow magically, the ESP32 seems to be pretty much untouched. You can still buy them, and prices have been relatively stable. I don't know how they've done it.) AVR, PIC, STM chips have all been hard to get specific models, and at times any model that has the features. I expect other brands were similar, but those are the ones that I've looked for.

    I hope they someday go back, but for the foreseeable future, expect it to be like this.

    Pro minis for close to $1 was always a shock, since even at 1k qty, just the chip itself costs more than that. So to get to that price for the whole assembled board, there must be some kind of gray-market thing going on. If I were to try to make a profit on 1k at a time, assembled and everything, I'm pretty sure the final price would have to be in the ballpark of $10 each.

    When is this chip shortage supposed to end? I thought the prices for atmega328pb's on mouser were reasonable enough, but then I just now noticed they weren't expected to be in stock until March 2023! LOL. Matter of fact, Mouser doesn't have any atmega328p's of any kind in stock at all. Unfortunately, as near as I can tell, the new attiny3226's, which are in stock, don't appear to be picopower, so the sleep currents aren't as good. Matter of fact, I can't deduce from its datasheet just what the poweroff current consumption of it is.



  • @NeverDie As far as when the shortage ends, ??? I've seen estimates different times that it's "right around the corner" but nothing that was very convincing to me. Intel just this week or last came out and said that they think it's going to be better soon. NVidia chips/cards are getting to be more available. And random different chips have re-appeared, so maybe they're right this time? I wouldn't bet on it, though. There are still tons of parts that are hard or impossible to get in any quantity. I'm no insider, though. I shop at Digikey, Mouser, etc. same as you. Just maybe more often and a bit higher qty sometimes.

    I actually have some of the Attiny3226 here to play with. When they came into stock, I bought a small bag of them. I haven't yet had a chance to do anything with them, though. I do see power consumption tables. pg 477-478 of the datasheet. https://www.mouser.com/datasheet/2/268/ATtiny3224_3226_3227_Data_Sheet_DS40002345B-2887812.pdf Numbers seem pretty reasonable, for a claimed 'low power' family of chips.


  • Hero Member

    @ejlane Aha! Bingo! Thanks for the page reference! Looks as though attiny3226 is the same 100na in powerdown as the atmega328p:
    attiny3226_powderdown_consumption.png
    Giving it a quick look, it seems both better and cheaper. What's not to like about this thing? I guess maybe just the total dearth of tutorials regarding it?



  • @NeverDie Yeah, I think they are the next gen device. I believe that this batch that came out in the past ~6 months was the first production run of the '2' series devices. At least it was the first time that I had seen them available, though it wasn't something I had been actively searching for.

    Should be about an identical AVR instruction set, but some of the low level stuff like registers might have changed, so it might take a bit of work to convert projects to it. I haven't done it yet to know.


  • Hero Member

    Something to consider regarding the modules is that the maximum rated instantaneous current draw, according to the datasheet is 580ma:
    maxCurrent.png
    That's worthy of note because the maximum current rated for a usb 2.0 port is just 500ma. So, if you're powering it from a USB 2.0 port off your computer via an LDO, that's potential problem #1. A USB 3.0 port, on the other hand, is rated for 900ma, so that would be fine. However, if you're powering it from most FTDI connectors (which typically max out at 50ma when operating at 3.3v mode), that's still going to be a problem. In this case, powering it from a Sparkfun Beefy 3 may be a solution, as "Built upon the same foundation as our 3.3V SparkFun FTDI Basic Breakout, the Beefy 3 is equipped with an AP2112K voltage regulator making this FTDI basic breakout board capable of handling a current load of up to 600 mA!" However, that's still cutting it very close though to the 580ma that the datasheet says is required. If you're powering it by some other means, you'll want to be sure you aren't backdriving your FTDI connection, as that wouldn't be good either.

    My solution? I'm going to create my own custom 3.3v FTDI to UART board that can handle higher current (probably 1 amp or more) just to be sure I have enough headroom for a standalone solution. While I'm at it, I'll make sure to pick a low noise LDO....

    [Edit: I think I'll go with the LT1965 LDO: https://www.mouser.com/datasheet/2/609/1965fb-1269903.pdf for it's overkill capability. Rated at 1.1a current, low noise, and big enough that it should be able to disappate heat better than some of the smaller, lower cost alternatives. That will also make it useful as a more general purpose tool. ]



  • @NeverDie But that's only the instantaneous current needed for transmitting data over the radio. The receive current is more like what it will be doing the majority of the time. Put a beefy capacitor or two on the power line and they should handle those short little spikes.

    I mean, you're not going to have a super-complicated web page on there or something. The packets being sent out will be what 1kB or something max, even serving a simple web page? According to this page: https://docs.espressif.com/projects/esp-idf/en/latest/esp32/api-guides/wifi.html#esp32-wi-fi-throughput you might get close to 80MBit/s speed. With some overhead, maybe the packet needs 10kBit, so it would only need to be on for 125uS. Even if the packets were far larger, the amount of time the radio needs to transmit is still a small fraction of the overall time. So just choose your capacitor(s) accordingly, and you'll be fine.



  • @NeverDie Oh, whoops, looks like you're probably talking about a different module? I saw the transmit number, and had been recently talking about the ESP32, which has a similar TX power number, and looks like I misread your post.

    The overall point remains, but it depends on the TX time vs. the rest of the time for the overall average power consumption and the size of capacitor needed.


  • Hero Member

    @ejlane Yes, good point about using a capacitor to compensate.
    27dB Tx power is, not considering inefficiencies, nominally equal to roughly 0.5amp, so the stated 580ma is probably about right and not mostly just in-rush current. LoRa transmissions can be rather lengthy, but I suppose a sufficiently large capacitor could compensate for that as well.

    As it turns out I already went ahead and did a draft layout in KiCad for it:
    High_amperage_3.3v_FTDI.png
    Having already invested the time, I'm going to build it. The low noise aspect LT1965 LDO might (?) still make a difference. I also like that it has a USB-B connector on it for a nice solid connection that's mechanically anchored to the PCB (none of that surface mount micro usb rubbish). I've wanted one for quite a while, and now its moment has finally come. If anyone else has interest, I can post it to openhardware.io


  • Hero Member

    Anyhow, back to the project at hand. I completed design of two different barebones mcu boards (one is just atmega328p and the other allows an Arduino pro mini to dock with it instead) that are 2xAA battery powered:
    basic_mcu_boards_horz.JPG
    Given the wait time from a PCB fab, I went with two different designs just in case I made an error and one of them doesn't work. They both have identical test points where I can separately monitor current consumed by the mcu vs current consumed by the radio--all the better to tease apart what's really going on. Then I also have five different radio shields that fit either mcu board exactly the same:
    5_different_radio_shields.JPG

    As JLPCB doesn't work on weekends, I'm going to design a few more boards and then submit them all on Sunday night. When they finally do arrive in the mail, I'll not only be better able to evaluate the E28-2G4M27S (because the new design should practically eliminate any hardware noise), but also compare the following radios against one another for their relative performance on the exact same platform: 2.4Ghz E28-2G4M27S, three different kinds of 915Mhz SX1262 LoRa, a number of different kinds of 2.4GHz nRF24L01 (all with PA and LNA to put them on the same playing field as the other radios in the round-up), a 915Mhz RFM69HW, and a 400Mhz Ra-01 LoRa. Of interest to me are what makes for a reliable "worst case" range in my home environment at different transmission power levels and if anything stands out as a clear winner in terms of energy efficiency for bits that are reliably delivered. By worst case, I mean transmitting from behind a cement footer almost 6 feet beneath grade to a second story room across the house diagonally at the point furthest from it. If transmissions can work reliably along that transmission path, then they're probably good between any other two points in the house as well. There is, for instance, no way that a bog standard nRF24L01 could deliver any packets along that path, because its transmit power is just 0dB. However, with appropriate "boosting" via PA and LNA, I think it has a chance. In comparison, I previously tested the 400Mhz LoRa along this path, and it worked without a hitch. Matter of fact it could reach a quarter mile (or better) in all directions outside the house as well using just the default parameters in the old RadioHead libraries. I'll try that test again, but this time with the new library to see if it fares any differently this time around, as well as try LoRa at 915Mhz and 2.4Ghz.

    Depending on how the testing goes, I may leverage the same platform to also try out some other inexpensive radio modules that I've seen on Aliexpress that, up to now, I've lacked an easy way to comparison test. For instance, some featuring radio chips made by Texas Instruments (CC1101, CC1310, CC1352, CC1120, CC2450, CC2640, CC2650, and a whole slew of others) and some featuring radio chips made by Silicon Labs (e.g. Si4463). If you know of chips that you're keen to try, let me know and maybe I can try them for you in a way that will be meaningful because of the comparisons. I'm not expecting that big differences will emerge that aren't already known, but testing will cut through the marketing propaganda and (hopefully) reveal the truth.



  • @NeverDie I've never done a LoRa project, but I remember reading somewhere that some packets can take multiple seconds! So yeah, that would take a very large capacitor. I'm not sure what I would do in that scenario. I'd have to give it some thought, but I also might go with a dedicated power supply that could just handle the full current. Of course it would also depend on the specific trade-offs that were best for that project. Interesting problem.

    Are you sure about JLCPCB not working on weekends? I 95% sure that I've submitted designs on Saturdays before and gotten a reply that they were accepted later that same day. I've also once or twice gotten things rejected when I made a silly mistake that they caught. I'm sure that it's a person reviewing things, and they have caught a couple errors. (Not in logic, obviously, but I had done a quick change one time, and a trace on another part of the board also got moved somehow, and it crossed over another. That's the only one I remember what the problem was.)

    However, you can also always add boards to an order that is in process and they'll ship together for one price. Though if you're adding enough boards then there will be a bit of a shipping differential to pay for.

    Those sound like some fun tests, and I look forward to hearing the results!


  • Hero Member

    @ejlane said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    Are you sure about JLCPCB not working on weekends? I 95% sure that I've submitted designs on Saturdays before and gotten a reply that they were accepted later that same day.

    On Thursday I asked "Eric", their sales rep, and he said they don't work or do production on weekends. He said that if I send the files Sunday night, it would most likely ship on Wednesday. And he said the same would be true if I sent them on Friday. All this assumes no errors in the gerber/drill files.

    I'm impressed with JLBPCB in that they take the size of the board into consideration when quoting larger quantities. So, for instance, on one tiny board, I'll be getting 30 for just $4.40, even though getting 5 would cost me the $4 minimum. For some reason, though, if the order is larger than 30 boards of the same design, then it triggers a new minimum fee of around $9 or $10, IIRC. Not really sure why that is. It's a pity, because if I wanted a hundred or something for cheap, I'd have to panelize onto one PCB (Eric said no v-grooving or mouse bites allowed without paying a price penalty) and then saw/cut the boards apart after they're delivered. Fortunately, for most things, quantity 30 is a big enough number.



  • @NeverDie Okay, sounds like you know more than I do about it, I guess. I was sure that I had gotten responses/work done on a weekend, but maybe my memory is just faulty.

    But yes, their service is very impressive. And for a 2 layer board, I can get it delivered here on the west coast USA in usually 6 calendar days from ordering with the quickest shipping. That's shockingly quick, and faster than most local places can even just make the board. (Well faster than any that I know of. I've pretty much switched to only using JLCPCB. Hardly even bother quoting other places these days.)

    I believe if you really needed a bunch, they would be a decent price even with the penalties. Every time I've had to pay an extra charge for something, it was a reasonable amount. Though I've never tried to order 100 of anything through them, so I could be wrong.


  • Hero Member

    @ejlane said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie Okay, sounds like you know more than I do about it, I guess. I was sure that I had gotten responses/work done on a weekend, but maybe my memory is just faulty.

    But yes, their service is very impressive. And for a 2 layer board, I can get it delivered here on the west coast USA in usually 6 calendar days from ordering with the quickest shipping. That's shockingly quick, and faster than most local places can even just make the board. (Well faster than any that I know of. I've pretty much switched to only using JLCPCB. Hardly even bother quoting other places these days.)

    In pre-pandemic times, I could order on a Monday from allpcb.com and get my order delivered by Friday here in the US. These days... not sure if that's true anymore, as I haven't ordered from them since before the pandemic.

    I believe if you really needed a bunch, they would be a decent price even with the penalties. Every time I've had to pay an extra charge for something, it was a reasonable amount. Though I've never tried to order 100 of anything through them, so I could be wrong.

    Eric basically said "Please don't panelize" and that it wouldn't save money. Now I think I understand why: if you do a lousy job of either the vgrooving or mouse bites, it's going to interfere with their manufacturing process. e.g. maybe that part of their much larger project board shatters to bits during fabrication because it's too weak structurally. It's much better for them (at least from their cost of business) to be in complete control of it. Otherwise, some engineer might have to remediate somebody's poor panelization, which takes extra time and throws a wrench into their work flow.


  • Hero Member

    @ejlane said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    I've also once or twice gotten things rejected when I made a silly mistake that they caught. I'm sure that it's a person reviewing things, and they have caught a couple errors. (Not in logic, obviously, but I had done a quick change one time, and a trace on another part of the board also got moved somehow, and it crossed over another. That's the only one I remember what the problem was.)

    I took JLCPCB's capabilities and, to the degree possible, imported them into KiCAD's design rule constraints:
    jlcpcb_constraints.png

    This has surfaced violations that didn't get flagged by KiCAD's default design rule constraints--problems that I'm guessing JLCPCB would have kicked back at me if this method hadn't found them first.



  • @NeverDie this video is very useful


  • Hero Member



  • @NeverDie I've only done my own panelization maybe 2 or 3 times ever. Usually just leave it to the board house, but 10 or so years ago, before the board houses were quite this cheap and I was on more of a budget because of saving for a down payment, I did try it out for some personal projects as an experiment.

    But I didn't even try to do v-grooves. Not sure if whichever one I was using would even allow it. I just left extra room between the active parts of the board on the PCB and literally took tin snips and cut them apart with that. With 1 cm between boards it's easy to not hit anything.

    Obviously doing it like that wouldn't weaken their board, but if you need precise board shape/size then this wouldn't do it. Ever since then the prices have gotten so low that I don't bother trying. I would be interested knowing what about JLCPCB's process makes them want to limit any order to the 30 pieces. That's always seemed a bit weird to me. I would think they would welcome the extra volume/money.

    But weirdly enough, I don't even know where to go for larger orders. I mean, I can do a search like anyone else, but I don't have direct experience. By the time it gets to that qty, then the assembly house deals directly with whoever they work with to get the boards made. At that point it's not me dealing with them directly, except for passing requirements to the client, who then passes them to the assembly house, etc.

    I've also entered some of their limitations into KiCad, but I'm not sure if I did a complete job of it. I try to be a bit more conservative than being right at the manufacturable edge. But yeah, get the rules to catch as much as possible. I think my problems came in when I did something that such a minor change I didn't even really think about running the rules again, and of course something like that is usually harmless, but every once in a while it does something unexpected, so obviously the rules need to be checked after every change, and every time before exporting gerbers for manufacturing. And I try to do that, but still these days I'm sure that are times that I forget.



  • @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    If you know of chips that you're keen to try, let me know

    Since you asked, maybe look at the good-old cheap 433 MHz transmitter/receivers? Maybe you are sticking to transceivers so this wouldn’t fly. Or maybe you are staying away from ASK modulations. I’m sure these cheapo radios won’t pass your fundaments concrete/cross-house test, but it would be another data point. This season I’ve been slowly reworking my limited 433 MHz home network of motion detectors. Having failed to transmit through concrete/cross-house pathways, I built some 433 repeaters that successfully worked on a line-of-site pathways that allowed me to look around the corners. I have found these TX radios & SR501 motion detectors just sip energy and my 4-pack of AA batteries last for, in some cases, over 3 years.

    As you are working with JLCPCB are you using them for assembly? I did so last year with different project and had really good results. I did have some difficulty finding compatible components, so I suspect that they won’t be able to resource all your radios… but that was some time ago and I have much to learn. I look forward to doing more assembly with JLCPCB. It was also really inexpensive and a great way to get around my poor home soldering quality.

    [edit: forgot to say, @NeverDie and everyone else: What a great thread. Thanks for building and sharing. I have learned much here.]


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    As you are working with JLCPCB are you using them for assembly? I did so last year with different project and had really good results. I did have some difficulty finding compatible components, so I suspect that they won’t be able to resource all your radios… but that was some time ago and I have much to learn. I look forward to doing more assembly with JLCPCB. It was also really inexpensive and a great way to get around my poor home soldering quality.

    Good idea. I haven't tried it, because I've been locked in a mindset of using radio modules, in which case soldering things is easy enough that I can do it myself manually without much effort. But for small, fine pitched chips (the kind I've been avoiding for just that reason), it sounds like a worthwhile thing to try. Maybe I could use better components than are typically found in aliexpress modules as well. 😀


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    If you know of chips that you're keen to try, let me know

    Since you asked, maybe look at the good-old cheap 433 MHz transmitter/receivers? Maybe you are sticking to transceivers so this wouldn’t fly. Or maybe you are staying away from ASK modulations. I’m sure these cheapo radios won’t pass your fundaments concrete/cross-house test, but it would be another data point. This season I’ve been slowly reworking my limited 433 MHz home network of motion detectors. Having failed to transmit through concrete/cross-house pathways, I built some 433 repeaters that successfully worked on a line-of-site pathways that allowed me to look around the corners. I have found these TX radios & SR501 motion detectors just sip energy and my 4-pack of AA batteries last for, in some cases, over 3 years.

    Interesting idea. I'll have to give that one some thought. A lot of the cheap wireless temperature-humidity sensors seem to use ASK, and I've never been clear as to why. e.g. Oregon Scientific, and similar companies. There are a number of hacker-type projects aimed at receiving and decoding those signals precisely because the wireless sensors are so cheap. And those cheap wireless key-finder fobs I think may use it as well. Maybe the receiver current can be extremely low? Those fobs always have to be listening for a wireless signal. All I know is that low frequency implies less energy consumption by whatever oscillator is being used.



  • @NeverDie: Yes, as you describe elswere, and taught me, the design trade-off parameters are frequency, bandwith, dwell time, bit transfer rate, power demand, and most importantly, range. I'm looking forward to your findings.

    Regarding the low reciever current: don't know about the FOB's but I have found the transmitter power to be key. My design has the "always on" reciever connected to mains. so I don't worry about that power. But the battery-limited transmitter devices are brought to life and triggered by the signal pin of the SR501 sensors that is high enough, long enough to complete a transmission, or several. The HT12E (encoder) chip is connected to the SR501 pin is fired and sends the settings of the dip-switch pin hi/low settings that is recieved by the always-on HT12d (decoder) that the Atmega 328PU can understand. I think the HT devices are MCUs in a different form, like what I imagine a FPLC to be like... don't know for sure. Why do I drone on? Because of the HT12D and HT12E pariings are very specific and very low on power demand due to their design. When I built my configuration (6 years ago) I knew more than I do now. But I'm relearning more. Andreas Spiess, Great Scott, Big Clive, and YOU, explore this stuff extensively, and I thank you all.

    In summary, my repeaters and base RX station are mains powered so I don't worry about power & batteries. The primary focus for conservation of batteries is on the TX/Motion devices. Everything downstream of TX is mains powered or can be suitably backed up in the short term.


  • Hero Member

    I think I'll pass on the ASK, and the reason is that it tends to be noise/interference sensitive. The usual workaround for noise/interference by ASK garage door openers, for instance, is to send the same packet multiple times, with the hope that at least one of them will get through. Well, I suppose that strategy works "good enough" in some sense for that application, but I'd say that all those extra packets being sent is a waste of energy for a battery powered sensor application that's transmitting, say, once every 5 minutes. On the other hand, if it doesn't really matter if you lose packets from time to time (e.g. a wireless TH sensor), maybe you don't need to send multiple redundant packets in the hopes that one gets through. That said, IIRC, Oregon Scientific TH sensors send their packets in triplicate. Well, that's my off-the-cuff take on it. Feel free to disagree if I'm missing something important.

    Anyhow, I think that's why one tends to see ASK being used at 433Mhz: it's a relatively clean channel, so the noise/interference isn't as big a factor as it would be at 915Mhz or certainly 2.4Ghz.

    At the end of the day, I think ASK was popular because, historically, it was easy and cheaper to make. Think 1940's, 1950's, and maybe 1960's, before integrated circuits. Now that FSK, its main competitor, is widespread and cheap anyway, I just don't see much benefit in reverting to old school ASK unless maybe you're manufacturing millions of something and want to save every penny possible. Because of the possible noise issue, you're also limited to slower bit rates with ASK than the alternatives, which, in turn, also lead to longer transmit times.

    P.S. Build time at JLCPCB is now running 2-3 days. Out of the 10 boards I submitted on Sunday (China time), 9 are still awaiting "data preparation." Only 1 of the 10 is currently in production. I think they're manpower limited right now, maybe because of China's zero-tolerance covid policy.



  • @NeverDie Yes, you are correct: the HT12D datasheet indicates that multiple signals must be recieved before the enable pin is activated. I think the 'multiple' is a count of three and there is probably a preamble in advance of the main message of high/low settings. The transmitter, again I think, just keeps sending the message until the SR501 drops power (2 seconds on the minimum settings). I get alot of double hits because of this. Good to know about the noise and history. Thanks.


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie Yes, you are correct: the HT12D datasheet indicates that multiple signals must be recieved before the enable pin is activated. I think the 'multiple' is a count of three and there is probably a preamble in advance of the main message of high/low settings. The transmitter, again I think, just keeps sending the message until the SR501 drops power (2 seconds on the minimum settings). I get alot of double hits because of this. Good to know about the noise and history. Thanks.

    Worthy of note is, as you may already know, you can skip the HT12D and HT12E altogether if you're driving it from an Arduino. You can do all the encoding/decoding in software, and all you need on the transmit side is a mosfet to control the on/off of the transmit on the transmitter. I did this once by rolling my own software to do it, but I think it may also be handled in the wire library, IIRC. On the receiver side, I got better results by upgrading to an Arduino Due, because it has 12 bit instead of 10 bit Analog-to-digital converter, and a faster speed to do the processing. However, maybe I could have done it all digital and skipped that. I was just trying to eek the most reception I could out of possibly weak signals.

    Fun fact: on a 900Mhz Raspberry Pi (Version 1), you can make a 900Mhz radio transmitter just by putting a wire of appropriate length in one of the GPIO pins and then toggling PWM to it at the 900Mhz clock cycle. Of course, you'll need something more sensitive on the receive side. This would be an ASK scheme, by the way.

    Also, fun fact: the speed on the Due is fast enough that light (radio waves) doesn't move all that far per clock cycle, so you can detect when signals arrive directly between transmitter and receiver from an on-pulse, and you can also detect fainter echoes of that same pulse arriving later because they've bounced off a wall or something and took a longer path between the transmitter and receiver. I thought that was kinda cool, because I ordinarily think of the speed of light as being more or less instant in such close quarters. Anyhow, I forgot the name for this kind of temporal transmit "smearing", but it's a very real effect where the transmitter kinda interfers with itself, so to speak, because of the layout of reflecting surfaces in the environment. [Edit: just now looked it up. "Multipath interference" is the term. MIMO thrives on multipath signals, but it's a problem for regular radio to deal with it--though, as you'd expect, there are all kinda of ways to handle it; the easiest being just putting a long enough time interval after an ON pulse for the echoes to die out to background noise levels. ] 🙂

    P.P.S. All 10 of my JLCPCB boards are now in production, though it is now technically early Tuesday morning in China. Looking at the time stamps, the production process itself appears to run around the clock, not just during daytime business hours, so that's good. Hopefully that means there's no complicating factor left standing in the way of completing the production and shipping it.



  • @NeverDie : Very interesting stuff. Even at the lowly 8MHz, the speed of processing pretty much blows away the human concept of time. Fun to hear of the Raspberry and Due. I’ll have to play with those.

    HT12D/HT12E: Yes, I learned that the processing could be done on a MCU and I did that on the repeaters I built. I put a Pro-Mini in between a 433 Mhz RX and TX. This repeater sits and listens in the RX mode until it is pinged with a transmission from one of the 433-HT12E detectors. Once a message comes in, the MCU then switches to TX mode and passes the message along, then reverts to listening again. The repeaters and the base station are mains powered as I figured the always ON state would be a battery killer whereas the 433-HT12E’s are very low power and outfitted with batteries.

    Rather than using the IIRC library I used RCSwitch – probably because I found that first. RadioHead was another option. The biggest challenge for me was learning which protocol to use for the 433 radios. The command mySwitch.setProtocol(11); did the trick.


  • Hero Member

    @Larson The Due has an 84Mhz clock speed, making it easier to spot the effect. These days you could save some coin by using an ESP8266 (80Mhz) or even faster ESP-32, not to mention the crazy fast Teensy 4.1 (600Mhz). At 600Mhz, light moves only 20 inches per clock cycle. Pretty cool for cheap parts, isn't it? 🙂


  • Hero Member

    I received the Dorji parts I had ordered. They arrived very fast and very well packed. I got them on ebay, but for comparison I'm still waiting on everything else that I had ordered from aliexpress.

    It turns out it took 3 days for JLCPCB to build my simple 2 layer PCB's. Either they're overwhelmed with business or understaffed. With any luck they'll ship out tomorrow, so probably another week to get here.

    Meanwhile I received a Nord PPK2 Power Profiler, as I found a seller who briefly had some in stock. So, I'll be putting that to use to accurately compare current consumption of the various test builds after the PCBs eventually arrive from JLPCB. Meanwhile, I may try it out on an ESP8266 to finally get some solid current consumption numbers on how much power it takes to wake-up into ESP-NOW mode from a cold start. If it's good, then maybe so-called trigger boards will bring the ESP8266 back to life as a low power competitor. Also, I'm really curious as to how sensitive (or not) the ESP8266 2.4Ghz ESP-NOW communications will be to interference in a home environment that, at least so far, seems to have shredded 2.4Ghz LoRa. According to the labeling on the tin, they come with 25dBa power amplifiers, so I expect they'll do far better than a bog standard nRF24L01, which has a maximum of only just 0dBa transmit power. Of course, when you add in the cost of a trigger board, then total cost may (?) turn out to be a wash compared to other mcu/radio combos that don't require a trigger board. We'll see!


  • Hero Member

    @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    I'm hoping (but haven't confirmed) that by eliminating the oscillator on pins D20 and D21, I can use those pins to drive two LED's kinda "for free" since nobody uses those pins for anything.

    Reporting back: I have the answer. It turns out that the standard arduino core for atmega328p that's baked into the standard Arduino IDE does not support Arduino pins 20 and 21 as digital GPIO pins for driving LEDs. However, the good news is that there's an even better Arduino core, called MCUDude MiniCore which does support exactly those pins for such purposes. Here's the TL;DR:

    This core gives you two extra IO pins if you're using the internal oscillator! PB6 and PB7 is mapped to Arduino pin 20 and 21.

    https://mcudude.github.io/MiniCore/package_MCUdude_MiniCore_index.json
    It's very easy to use. You can install it into the regular Arduino IDE, pick from among the MiniCore "boards" in the board manager, select the 8Mhz option and a few other obvious options, and then you're done with instalation. From that point on your code will automagically compile using MiniCore. Just to be sure, I gave it a try myself, and I'm now blinking a blue LED off of Ardino Pin 20. It works!



  • @NeverDie More good information - thanks for posting. Good work on finding the alternate core. I have a couple of questions:

    1. By “trigger board”, are you referring to the TPL5010 discussed above? (Adafruit carries the TPL5110, I think.) Is the idea here to power and de-power the radio, or mcu, to discover the rock-bottom minimum current requirement?
    2. What are you sacrificing when not using the external crystal? And to do this, are you setting fuses to tell the 328 to use the internal crystal? I've found setting fuses to be a complicated affair.


  • @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    At 600Mhz, light moves only 20 inches per clock cycle. Pretty cool for cheap parts, isn't it?

    Yes, mind-blowing. I got into this hobby via the Parallax Basic kits. The second MCU I bought from them was about $60 and I thought that was stunning. So when I found the ATTINY85 I was addicted, if only because the access to this technology costs less than a cup of coffee. The progression to Arduinos and ESP's was a natural extension for this cheap hobby.


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie More good information - thanks for posting. Good work on finding the alternate core. I have a couple of questions:

    1. By “trigger board”, are you referring to the TPL5010 discussed above?  (Adafruit carries the TPL5110, I think.)    Is the idea here to power and de-power the radio, or mcu, to discover the rock-bottom minimum current requirement?
      
    2. What are you sacrificing when not using the external crystal? And to do this, are you setting fuses to tell the 328 to use the internal crystal? I've found setting fuses to be a complicated affair.

    Good questions!

    1. Yes, by "trigger board", the adafruit tpl5110, or something like it, is what I have in mind. The goal would be zero leakage current beyond the ~40 nanoamps of management overhead. I don't know if the p-channel mosfet design in adafruit's tpl5110 breakout board achieves zero leakage (or near enough),but it would be worth measuring. I think Kevin Darrah may be the one who coined the term "trigBoard". His design is a lot more elaborate and, I assume, costly: https://www.kevindarrah.com/wiki/index.php?title=TrigBoardV7

    Is the idea here to power and de-power the radio, or mcu, to discover the rock-bottom minimum current requirement?

    Yes. It's a little more complicated though, because generally the mcu/radio wake-up time is much longer from a cold start than from a deep sleep, so the real objective would be to find the breakeven point at which power-off is the better choice (i.e. how long does the duty cycle need to be).

    What are you sacrificing when not using the external crystal?

    Accuracy. If you were interfacing to something that had extremely tight timing requirements, the crystal would be more accurate. In practice, I haven't ever noticed a difference in anything that I've done.

    And to do this, are you setting fuses to tell the 328 to use the internal crystal? I've found setting fuses to be a complicated affair.

    Yes, I set the fuses. Currently I use the following fuse settings:
    atmega328p_fuse_settings.png
    By running from the 8Mhz internal oscillator and sleeping, not only can you sleep the atmega328p at just 100na, but as a bonus the atmega328p can wake up in just 3 microseconds (I previously measured it with an oscilloscope, so that number is solid). For being such an old mcu, the atmega328p can be amazingly high performance when it comes to saving power. This becomes of greater relevance if you're getting your power by harvesting weak energy sources.

    If you want to play around with setting fuse bits, the standard advice is to leave the Extended bits alone until you know what you're doing. Even then, there's probably no need to change them. It's the High and Low bits that are of relevance.

    A great source of information is: https://www.gammon.com.au/power



  • @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    sleep the atmega328p at just 100na

    Wow, that is pretty close to zero in my view. Consider battery self-discharge in comparison: I use 18650 LiOn batteries in most of my projects. Say a 2000 mAh battery loses 1%/month in self discharge s(ome say it is much higher). Well, the math, if I did it right, shows a self-discharge of about 25 uA. So sleeping at 100nA is really impressive.

    Thanks for the fuse guidance. I will employ this next chance I get.


  • Hero Member

    @Larson Yes. The RFM69 can also be slept at just 100na, so taken together they are an awesome duo. If you're running from 2xAA batteries, then the the combined 200na are essentially zero. If, in contrast, you're trying to harvest energy from a small solar cell in an indoor environment that's dimly lit by LED lighting only rarely, then it becomes more relevant.

    Anyhow, I've noticed that a lot of people measure very small currents incorrectly, so just trying to find answers on the internet, which is full of wrong measurements, isn't easy. Datasheets can provide some insight.



  • @NeverDie Yes, the experience and knowledge found by doing (measuring) is always deeper,

    Forgot to mention: Kevin Darah. I have bought several of his TrigBoards. I find the price to be a good value for the design, components, assembly, and all the content he has posted. The quality of his boards is great. I am a Patreon of his. I just need to play with the TrigBoards some more.


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie Yes, the experience and knowledge found by doing (measuring) is always deeper,

    Forgot to mention: Kevin Darah. I have bought several of his TrigBoards. I find the price to be a good value for the design, components, assembly, and all the content he has posted. The quality of his boards is great. I am a Patreon of his. I just need to play with the TrigBoards some more.

    I'd be interested to hear your thoughts on Kevin's trigBoards after you've had a chance to get familiar with them. A compare/contrast of his board to the adafruit board would be even more awesome. The adafruit board is a very simple design and would cost less than $1 in parts if you were to source them yourself. I suppose its main limitation is 1. the maximum sleep time is two hours, and 2. not as accurate as a proper RTC. In its favor is that at 40na the sleep current consumption is next to nothing. On the other hand, some RTCs have a sleep current less than 1ua, so maybe that's good enough.



  • @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    In its favor is that at 40na the sleep current...

    I'll order several. Then compare to the TrigBoards. Adafruit's TPL5011 advertises a run current of 20uA. Is that acceptable for you? If so I'll buy several. Couple of limitations for me: 1. Time - I'm about a month out, 2. My Ammeter is a standard DMM from Harbor Freight. The smallest range is 200uA and I've found it very useful. Certainly fine enough to show the 20uA, but inadequate for nanoAmps.


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    In its favor is that at 40na the sleep current...

    I'll order several. Then compare to the TrigBoards. Adafruit's TPL5011 advertises a run current of 20uA. Is that acceptable for you? If so I'll buy several. Couple of limitations for me: 1. Time - I'm about a month out, 2. My Ammeter is a standard DMM from Harbor Freight. The smallest range is 200uA and I've found it very useful. Certainly fine enough to show the 20uA, but inadequate for nanoAmps.

    Hmmmm... Something's wrong then with Adafruit's design if it's 20uA. The chip itself consumes only 35na according to its datasheet:
    https://www.ti.com/lit/ds/symlink/tpl5110.pdf?ts=1652658923819&ref_url=https%3A%2F%2Fwww.google.com%2F
    Maybe their p-channel mosfet has high leakage current with the circuit has they've designed it? I would pass if it really is 20uA. I'm sure I could do better than that.

    You need something like either a Current Ranger or a MicroCurrent Gold to accurately measure microamps and nanoamps. Cost is around $100.

    Also, I just now looked at one of Kevin Darrah's videos:
    PART 3 Cellular -The Ultimate DIY Home Security System - ESP8266 (trigBoard) + 4G LTE Modem – 22:37
    — Kevin Darrah

    where he has embraced ESP-NOW. He said his esp8266 still takes around 1.5 seconds to wake up and transmit, even though running ESP-NOW, which is a very long time, as the module will be burning current through out that wake-up interval. In the example he showed, the delay was quite noticeable (though definitely an improvement compared to before when he was using plain wi-fi). Of course, the devil is in the details, but seeing that I'm more skeptical now than before.



  • @NeverDie I recognized the KD image as soon as I saw it. I'll watch... again... after dinner. Yes, the battery economics depend on time and power as you say. One of the tricks I have learned is aggregating data at the MCU level in RTC memory. I'm using both a 328 and an ESP; each dedicated to it's task. When 20 samples (minutes of data) are gathered the MCU wakes the ESP so it can bulk-load data to Thingspeak. This economizes the cost of the ESP wake-up by a factor of 20. This is all for my water-meter monitoring project. It has been fun stuff and I've learned a bunch. And I'm not using ESP-NOW because I'm going directly from the ESP transmitter to my home network - so I could do even better if I injected an ESP repeater that would transmit to the network. I think my wake-up/network-connection is about 8 seconds.

    We have strayed far away from your initial "anyone-useing..." post. I hope that is okay?


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    We have strayed far away from your initial "anyone-useing..." post. I hope that is okay?

    Yes, it's fine. I'll be testing the E28-2G4M27S once more after my JLCPCB's arrive.


  • Hero Member

    The PCB's arived today, about 1 week after I placed the order. I already put together one mote:
    v1.JPG
    It nicely fits the footprint of two AA batteries. I'll be running some tests soon and hopefully getting definitive answers.

    By the way, the flashing green LED is being driven by Arduino Pin 20. 😄


  • Hero Member

    Mea Culpa. I found a mistake in my original setup which may explain at least some of the poor performance. I had thought that both my usb-to-serial converters were operating at 3.3v, but I noticed during disassembly that one was operating at 5v instead. Even though I was using pro mini's with 3.3v LDO's on them, it turns out that the 3.3v LDO only functions when the voltage is being fed to the pro mini over the RAW pin (which is never in my setup). Instead, the usb-to-serial converter fed its 5v directly to VCC over the header pin, and from there directly to the radio module. Although I did later do experiments where the entire setup was being run off of 3v of battery only, it may be that the radio module was already damaged by then.

    I wouldn't be surprised if others besides just me have fallen into this same trap, as it might be natural to assume that a "3.3v pro mini" regulates all of its voltage sources to be 3.3v. However, such is not the case, as confirmed by checking the schematic.

    So, to remove all doubt, I'll use brand new radio modules when testing with this new test setup, which won't be using pro mini's at all this time around. It turns out my barebones atmega328p design works just fine, and this way I have total control over the quality of all the components going into it, including X7R on all the capacitors (whereas who knows exactly what quality of components are used on pro mini's).


  • Hero Member

    Here's an end-view of the test platform:
    end_view.JPG
    As you can see, I wouldn't want the batteries to be any closer together than they already are, or they would likely short out between them. As it stands, they're firmly in place, so no worries for now. These kinds of placement tolerance issues are hard to vet in advance prior to building a prototype. The keystone datasheet gave no guidance at all on side by side positioning. If I were to do it over, I think I'd give it another millimeter or two of safety factor separation.

    Of bigger concern is the switch placement. A side mounted switch might be too tight a fit because of the battery connectors. On the other hand, the existing vertical switch can potentially can get in the way of things, so I may try mounting it upside down on the battery side. This would make it less accessible than it currently is, but, at the same time, it wouldn't get bumped by accident either. I reckon that with the aid of an insulated paperclip, or maybe a chop-stick, it should be possible to turn it on-off even in the more cramped position. Probably a more correct solution would be a surface mounted side-switch that's tiny but somehow good enough to carry 600ma+ currents. Finding such a thing may take some searching though, assuming it exists at all.

    In a perfect world, the radio module, if it were to use its trace antenna, would be hanging over the end of the base PCB below. Part of the reason it wasn't was out of concern as to whether the breakout board might collide with the switch. Well, with the new switch position, that won't be a worry, so if I create a new version of the breakout board for the radio module, I'd make it so that the radio module has its trace antenna hang out over the end of not just the breakout adapter, but the end of the test platform as well.

    I normally use regular headers, but out of an interest in making the whole thing more compact, and for snugger connections, I made a last minute decision to use machine pin headers instead. This was after the board had already been fab'd to use regular headers. If I were to do it over, I would have bigger diameter through-holes drilled into the PCB in order to seat the machine pin female headers properly. I'll do that in the next version I get fab'd, assuming there is a next version.

    At the opposite end there's space to add a pico-blade for the FTDI attachment. If that works, then in a future design there will be space for extending a few more pins out from the MCU, making for a more complete universal test platform. For present testing purposes, though, things are good enough as they are.

    If anyone reading this has any further thoughts or suggestions, please feel free to jump in and post them. I find it's less fun to do everything single handedly.


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    In its favor is that at 40na the sleep current...

    I'll order several. Then compare to the TrigBoards. Adafruit's TPL5011 advertises a run current of 20uA. Is that acceptable for you? If so I'll buy several. Couple of limitations for me: 1. Time - I'm about a month out, 2. My Ammeter is a standard DMM from Harbor Freight. The smallest range is 200uA and I've found it very useful. Certainly fine enough to show the 20uA, but inadequate for nanoAmps.

    I don't see any uCurrent Gold's for sale at the moment, but I did find a clone of it, which has what looks like a nice improvement over the original: you can plug it directly into an oscilloscope via its BNC connector.
    alt text
    https://www.n-fuse.co/devices/tinyCurrent-precision-low-Current-Measurement-Shunt-and-Amplifier-Device.html
    or
    https://github.com/nfhw/tinycurrent
    as it is open source.

    I temporarily misplaced my Dave Jones uCurrent Gold that I bought from him directly during his Kickstarter campaign. However, if I can't locate it soon, I may be either buying or making one of these tinyCurrent's to take advantage of the built-in BNC connector.


  • Hero Member

    Reporting back: Problem solved!

    Using two of the new test nodes, one in transmit and the other in receive, and each using a brand new E28-2G4M27S with just the trace antenna only, and with the default library settings for each, and with the transmit node in a different room with two closed doors in-between (exactly as before, with the initial testing at the start of this thread), I'm now getting the kind of flawless communication that I had expected all along from LoRa on the 2.4Ghz band:

    
    12:23:12 May 18 2022
    V1.0
    
    104_LoRa_Receiver_Detailed_Setup Starting
    
    LoRa Device found
    
    SX1280,PACKET_TYPE_LORA,2444999936hz,SF7,BW406250,CR4:5
    SX1280,PACKET_TYPE_LORA,Preamble_12,Explicit,PayloadL_255,CRC_ON,IQ_NORMAL,LNAgain_HighSensitivity
    
    Reg    0  1  2  3  4  5  6  7  8  9  A  B  C  D  E  F
    0x900  80 FF 77 41 20 FA BC 13 C1 80 00 00 00 00 00 61 
    0x910  9C 44 00 00 00 19 00 00 00 19 87 65 43 21 7F FF 
    0x920  FF FF FF 00 70 37 12 50 D0 80 00 C0 5F D2 8F 0A 
    0x930  00 C0 00 00 00 24 00 21 28 B0 30 0D 01 51 63 0C 
    0x940  58 0B 32 0A 16 24 6B 96 00 18 00 00 00 00 00 00 
    0x950  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x960  00 00 00 00 00 00 00 00 00 00 FF FF FF FF FF FF 
    0x970  FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF 04 
    0x980  00 0B 18 70 00 00 00 4C 00 F0 64 00 00 00 00 00 
    0x990  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9A0  00 08 EC B8 9D 8A E6 66 04 00 00 00 00 00 00 00 
    0x9B0  00 08 EC B8 9D 8A E6 66 04 00 00 00 00 00 00 00 
    0x9C0  00 16 00 3F E8 01 FF FF FF FF 5E 4D 25 10 55 55 
    0x9D0  55 55 55 55 55 55 55 55 55 55 55 55 55 00 00 00 
    0x9E0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9F0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    
    
    Receiver ready - RXBUFFER_SIZE 32
    
    5s  Hello World 1234567890*,CRC,DAAB,RSSI,-54dBm,SNR,10dB,Length,23,Packets,1,Errors,0,IRQreg,8012
    9s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,14dB,Length,23,Packets,2,Errors,0,IRQreg,8012
    13s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,10dB,Length,23,Packets,3,Errors,0,IRQreg,8012
    18s  Hello World 1234567890*,CRC,DAAB,RSSI,-58dBm,SNR,13dB,Length,23,Packets,4,Errors,0,IRQreg,8012
    22s  Hello World 1234567890*,CRC,DAAB,RSSI,-56dBm,SNR,14dB,Length,23,Packets,5,Errors,0,IRQreg,8012
    26s  Hello World 1234567890*,CRC,DAAB,RSSI,-52dBm,SNR,13dB,Length,23,Packets,6,Errors,0,IRQreg,8012
    30s  Hello World 1234567890*,CRC,DAAB,RSSI,-53dBm,SNR,9dB,Length,23,Packets,7,Errors,0,IRQreg,8012
    34s  Hello World 1234567890*,CRC,DAAB,RSSI,-51dBm,SNR,8dB,Length,23,Packets,8,Errors,0,IRQreg,8012
    38s  Hello World 1234567890*,CRC,DAAB,RSSI,-54dBm,SNR,13dB,Length,23,Packets,9,Errors,0,IRQreg,8012
    42s  Hello World 1234567890*,CRC,DAAB,RSSI,-52dBm,SNR,14dB,Length,23,Packets,10,Errors,0,IRQreg,8012
    46s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,13dB,Length,23,Packets,11,Errors,0,IRQreg,8012
    50s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,12dB,Length,23,Packets,12,Errors,0,IRQreg,8012
    54s  Hello World 1234567890*,CRC,DAAB,RSSI,-56dBm,SNR,9dB,Length,23,Packets,13,Errors,0,IRQreg,8012
    58s  Hello World 1234567890*,CRC,DAAB,RSSI,-59dBm,SNR,9dB,Length,23,Packets,14,Errors,0,IRQreg,8012
    62s  Hello World 1234567890*,CRC,DAAB,RSSI,-59dBm,SNR,13dB,Length,23,Packets,15,Errors,0,IRQreg,8012
    66s  Hello World 1234567890*,CRC,DAAB,RSSI,-61dBm,SNR,13dB,Length,23,Packets,16,Errors,0,IRQreg,8012
    70s  Hello World 1234567890*,CRC,DAAB,RSSI,-57dBm,SNR,13dB,Length,23,Packets,17,Errors,0,IRQreg,8012
    75s  Hello World 1234567890*,CRC,DAAB,RSSI,-54dBm,SNR,14dB,Length,23,Packets,18,Errors,0,IRQreg,8012
    79s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,14dB,Length,23,Packets,19,Errors,0,IRQreg,8012
    83s  Hello World 1234567890*,CRC,DAAB,RSSI,-54dBm,SNR,13dB,Length,23,Packets,20,Errors,0,IRQreg,8012
    
    

    Notice that now both the RSSI is very good and the SNR is very high as compared to when I was having trouble with the earlier setup.

    The E28-2G4M27S is vindicated. Case closed! 😃


  • Hero Member

    Epilog: I hooked up the old receiver, with its external antenna, to the new mote, and it's not obviously worse for the wear:

    
    12:23:12 May 18 2022
    V1.0
    
    104_LoRa_Receiver_Detailed_Setup Starting
    
    LoRa Device found
    
    SX1280,PACKET_TYPE_LORA,2444999936hz,SF7,BW406250,CR4:5
    SX1280,PACKET_TYPE_LORA,Preamble_12,Explicit,PayloadL_255,CRC_ON,IQ_NORMAL,LNAgain_HighSensitivity
    
    Reg    0  1  2  3  4  5  6  7  8  9  A  B  C  D  E  F
    0x900  80 FF 77 41 20 FA BC 13 C1 80 00 00 00 00 00 61 
    0x910  9C 44 00 00 00 19 00 00 00 19 87 65 43 21 7F FF 
    0x920  FF FF FF 00 70 37 12 50 D0 80 00 C0 5F D2 8F 0A 
    0x930  00 C0 00 00 00 24 00 21 28 B0 30 0D 01 51 63 0C 
    0x940  58 0B 32 0A 16 24 6B 96 00 18 00 00 00 00 00 00 
    0x950  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x960  00 00 00 00 00 00 00 00 00 00 FF FF FF FF FF FF 
    0x970  FF FF FF FF FF FF FF FF FF FF FF FF FF FF FF 04 
    0x980  00 0B 18 70 00 00 00 4C 00 F0 64 00 00 00 00 00 
    0x990  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9A0  00 08 EC B8 9D 8A E6 66 04 00 00 00 00 00 00 00 
    0x9B0  00 08 EC B8 9D 8A E6 66 04 00 00 00 00 00 00 00 
    0x9C0  00 16 00 3F E8 01 FF FF FF FF 5E 4D 25 10 55 55 
    0x9D0  55 55 55 55 55 55 55 55 55 55 55 55 55 00 00 00 
    0x9E0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9F0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    
    
    Receiver ready - RXBUFFER_SIZE 32
    
    4s  Hello World 1234567890*,CRC,DAAB,RSSI,-57dBm,SNR,12dB,Length,23,Packets,1,Errors,0,IRQreg,8012
    8s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,13dB,Length,23,Packets,2,Errors,0,IRQreg,8012
    12s  Hello World 1234567890*,CRC,DAAB,RSSI,-57dBm,SNR,13dB,Length,23,Packets,3,Errors,0,IRQreg,8012
    16s  Hello World 1234567890*,CRC,DAAB,RSSI,-57dBm,SNR,12dB,Length,23,Packets,4,Errors,0,IRQreg,8012
    20s  Hello World 1234567890*,CRC,DAAB,RSSI,-54dBm,SNR,9dB,Length,23,Packets,5,Errors,0,IRQreg,8012
    24s  Hello World 1234567890*,CRC,DAAB,RSSI,-52dBm,SNR,3dB,Length,23,Packets,6,Errors,0,IRQreg,8012
    29s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,11dB,Length,23,Packets,7,Errors,0,IRQreg,8012
    33s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,13dB,Length,23,Packets,8,Errors,0,IRQreg,8012
    37s  Hello World 1234567890*,CRC,DAAB,RSSI,-50dBm,SNR,12dB,Length,23,Packets,9,Errors,0,IRQreg,8012
    41s  Hello World 1234567890*,CRC,DAAB,RSSI,-53dBm,SNR,13dB,Length,23,Packets,10,Errors,0,IRQreg,8012
    45s  Hello World 1234567890*,CRC,DAAB,RSSI,-56dBm,SNR,14dB,Length,23,Packets,11,Errors,0,IRQreg,8012
    49s  Hello World 1234567890*,CRC,DAAB,RSSI,-53dBm,SNR,8dB,Length,23,Packets,12,Errors,0,IRQreg,8012
    53s  Hello World 1234567890*,CRC,DAAB,RSSI,-51dBm,SNR,3dB,Length,23,Packets,13,Errors,0,IRQreg,8012
    57s  Hello World 1234567890*,CRC,DAAB,RSSI,-52dBm,SNR,8dB,Length,23,Packets,14,Errors,0,IRQreg,8012
    61s  Hello World 1234567890*,CRC,DAAB,RSSI,-52dBm,SNR,12dB,Length,23,Packets,15,Errors,0,IRQreg,8012
    65s  Hello World 1234567890*,CRC,DAAB,RSSI,-52dBm,SNR,11dB,Length,23,Packets,16,Errors,0,IRQreg,8012
    69s  Hello World 1234567890*,CRC,DAAB,RSSI,-52dBm,SNR,13dB,Length,23,Packets,17,Errors,0,IRQreg,8012
    73s  Hello World 1234567890*,CRC,DAAB,RSSI,-50dBm,SNR,13dB,Length,23,Packets,18,Errors,0,IRQreg,8012
    77s  Hello World 1234567890*,CRC,DAAB,RSSI,-51dBm,SNR,13dB,Length,23,Packets,19,Errors,0,IRQreg,8012
    82s  Hello World 1234567890*,CRC,DAAB,RSSI,-55dBm,SNR,12dB,Length,23,Packets,20,Errors,0,IRQreg,8012
    86s  Hello World 1234567890*,CRC,DAAB,RSSI,-56dBm,SNR,7dB,Length,23,Packets,21,Errors,0,IRQreg,8012
    90s  Hello World 1234567890*,CRC,DAAB,RSSI,-57dBm,SNR,13dB,Length,23,Packets,22,Errors,0,IRQreg,8012
    94s  Hello World 1234567890*,CRC,DAAB,RSSI,-56dBm,SNR,13dB,Length,23,Packets,23,Errors,0,IRQreg,8012
    98s  Hello World 1234567890*,CRC,DAAB,RSSI,-48dBm,SNR,6dB,Length,23,Packets,24,Errors,0,IRQreg,8012
    
    

    One thing I do notice,though, when reviewing the receive packet data, with both the new and old radios are considerable variances in SNR. The 915Mhz adafruit transceivers don't show much variance (see earlier post for the telemetry). I presume, therefore, the larger SNR variances are caused by environmental interference that varies over time in the 2.4Ghz band, or at least the default channel in that band chosen by the library.

    The end! 😄


  • Hero Member

    Putting a Yagi antenna on this, one could perhaps gather data pointing to where the interference sources are located by backing out the "noise" value from the RSSI and SNR data collected.


  • Hero Member

    One last thing to try: to eliminate the possibility that the USB-to-FTDI might be introducing noise into the receiver, I think I'll try a test setup with three motes. Two will be completely battery powered with no external connection, and one will be connected to the computer for datalogging over USB. The main change is that the receive node will receive packets, as before, from the battery powered transmitter mote, but instead of directly feeding those results over USB to the computer, it will transmit those results (including the RSSI and SNR on the packets it received) to the third mote. The third mote will be located in the same room as the receiver mote, and it is the third mote that will be connected to the computer over USB. The third mote being in the same room as the receive mote guarantees it won't lose any packets, and if any noise is introduced over USB to the third mote, it will be irrelevant, because the primary receiver mote will be stand-alone and entirely battery operated, with no possibility of USB injecting noise into it.

    I suspect it won't make any difference to the final results, but the only way to know for sure is to test it. Going forward, to eliminate all doubt, I'll use the same type of three mote setup when testing other radios also. When testing different radios, all I'll need to do is swap in new radio shields and re-program the bases.

    Anyhow, this thread has turned out to be more of a blog than anything, but, as always, it becomes more interesting if other people post too so that it's not just me recording a monolog. I'll start a new thread when I start testing other radios, with the goal being to compare the performance of different radio modules to see whether any one module stands out as obviously "best" in the general sense, or at least better understand under which use-cases which radio module would be better than the alternatives.


  • Hero Member

    I haven't yet set up the 3 mote testing structure that I outlined above, but, for comparison, using the same two mote system for testing 915Mhz Dorji modules (each with a 3.25" wire whip antenna), with the same transmit and receive locations, the results there were rock solid SNR values with no variance over the sample:

    
    12:16:09 May 20 2022
    V1.1
    
    104_LoRa_Receiver_Detailed_Setup Starting
    
    LoRa Device found
    
    SX1262,434000000hz,SF7,BW125000,CR4:5,LDRO_Off,SyncWord_0x1424,IQNormal,Preamble_8
    SX1262,PacketMode_LoRa,Explicit,LNAgain_Boosted
    
    Reg    0  1  2  3  4  5  6  7  8  9  A  B  C  D  E  F
    0x800  00 00 00 00 29 07 20 09 00 10 19 D4 10 C9 10 00 
    0x810  10 C7 0F FE 10 C7 0F FE 00 76 8A A9 4A 00 00 00 
    0x820  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x830  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x840  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x850  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x860  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x870  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x880  03 00 00 5F 10 08 00 00 08 04 00 1B 20 00 00 0C 
    0x890  00 00 00 10 BD 0F 0A 07 10 00 26 01 01 53 06 07 
    0x8A0  10 00 AD 20 5A 04 F0 02 56 56 54 43 96 20 40 00 
    0x8B0  00 83 11 00 01 04 0A 4C 14 0A 2F 01 6B FF FF 00 
    0x8C0  00 A0 20 00 00 00 AC 00 1C 00 00 AB 05 30 11 14 
    0x8D0  0C 15 16 40 06 00 00 10 E8 00 00 00 00 09 31 39 
    0x8E0  90 39 0C 04 40 20 16 38 06 00 05 04 03 02 01 01 
    0x8F0  03 00 00 00 30 00 00 00 00 00 00 00 00 00 00 00 
    0x900  30 00 00 00 00 64 00 00 00 00 00 00 24 04 47 04 
    0x910  00 2F 00 00 00 03 0A 00 15 35 09 00 02 2A 67 08 
    0x920  07 04 05 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x930  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x940  00 07 00 03 02 00 10 00 0A 00 03 04 00 14 0C 00 
    0x950  00 00 00 06 00 00 00 00 00 00 00 00 00 00 00 00 
    0x960  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x970  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x980  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x990  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9A0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9B0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9C0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9D0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9E0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9F0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    
    
    Receiver ready - RXBUFFER_SIZE 32
    
    4s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,1,Errors,0,IRQreg,16
    5s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,2,Errors,0,IRQreg,16
    6s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,3,Errors,0,IRQreg,16
    7s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,4,Errors,0,IRQreg,16
    8s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,5,Errors,0,IRQreg,16
    9s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,6,Errors,0,IRQreg,16
    10s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,7,Errors,0,IRQreg,16
    12s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,8,Errors,0,IRQreg,16
    13s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,9,Errors,0,IRQreg,16
    14s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,10,Errors,0,IRQreg,16
    15s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,11,Errors,0,IRQreg,16
    16s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,12,Errors,0,IRQreg,16
    17s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,13,Errors,0,IRQreg,16
    18s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,14,Errors,0,IRQreg,16
    19s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,15,Errors,0,IRQreg,16
    20s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,16,Errors,0,IRQreg,16
    21s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,17,Errors,0,IRQreg,16
    23s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,18,Errors,0,IRQreg,16
    24s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,19,Errors,0,IRQreg,16
    25s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,20,Errors,0,IRQreg,16
    26s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,21,Errors,0,IRQreg,16
    27s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,22,Errors,0,IRQreg,16
    28s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,23,Errors,0,IRQreg,16
    29s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,24,Errors,0,IRQreg,16
    30s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,25,Errors,0,IRQreg,16
    31s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,26,Errors,0,IRQreg,16
    32s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,27,Errors,0,IRQreg,16
    34s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,28,Errors,0,IRQreg,16
    35s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,29,Errors,0,IRQreg,16
    36s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,30,Errors,0,IRQreg,16
    37s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,31,Errors,0,IRQreg,16
    38s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,32,Errors,0,IRQreg,16
    39s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,33,Errors,0,IRQreg,16
    40s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,34,Errors,0,IRQreg,16
    41s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,35,Errors,0,IRQreg,16
    42s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,36,Errors,0,IRQreg,16
    43s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,37,Errors,0,IRQreg,16
    45s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,38,Errors,0,IRQreg,16
    46s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,39,Errors,0,IRQreg,16
    47s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,40,Errors,0,IRQreg,16
    48s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,12dB,Length,23,Packets,41,Errors,0,IRQreg,16
    49s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,42,Errors,0,IRQreg,16
    50s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,43,Errors,0,IRQreg,16
    51s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,44,Errors,0,IRQreg,16
    52s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,45,Errors,0,IRQreg,16
    53s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,46,Errors,0,IRQreg,16
    55s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,47,Errors,0,IRQreg,16
    56s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,48,Errors,0,IRQreg,16
    57s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,49,Errors,0,IRQreg,16
    58s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,50,Errors,0,IRQreg,16
    59s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,51,Errors,0,IRQreg,16
    60s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,52,Errors,0,IRQreg,16
    61s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,53,Errors,0,IRQreg,16
    62s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,54,Errors,0,IRQreg,16
    63s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,55,Errors,0,IRQreg,16
    64s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,56,Errors,0,IRQreg,16
    66s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,57,Errors,0,IRQreg,16
    67s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,58,Errors,0,IRQreg,16
    68s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,59,Errors,0,IRQreg,16
    69s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,60,Errors,0,IRQreg,16
    70s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,61,Errors,0,IRQreg,16
    71s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,62,Errors,0,IRQreg,16
    72s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,63,Errors,0,IRQreg,16
    73s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,64,Errors,0,IRQreg,16
    74s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,65,Errors,0,IRQreg,16
    75s  Hello World 1234567890*,CRC,DAAB,RSSI,-94dBm,SNR,11dB,Length,23,Packets,66,Errors,0,IRQreg,16
    77s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,67,Errors,0,IRQreg,16
    78s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,68,Errors,0,IRQreg,16
    79s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,69,Errors,0,IRQreg,16
    80s  Hello World 1234567890*,CRC,DAAB,RSSI,-93dBm,SNR,11dB,Length,23,Packets,70,Errors,0,IRQreg,16
    

    This was with the Dorji set to its maximum transmit power of 22dB, as compared to the E28-2G4M27S, which has the advantage of an even higher 27dB transmit power.

    [Edit: oops. Reviewing the output, I see that the library defaulted to 434Mhz! So, these results were great even with the wrong length antenna installed for 434Mhz. I'll try again at the proper frequency. 😊 ]


  • Hero Member

    OK, here it is corrected for 915Mhz, as it should have been the first time:

    
    12:34:34 May 20 2022
    V1.1
    
    104_LoRa_Receiver_Detailed_Setup Starting
    
    LoRa Device found
    
    SX1262,915000000hz,SF7,BW125000,CR4:5,LDRO_Off,SyncWord_0x1424,IQNormal,Preamble_8
    SX1262,PacketMode_LoRa,Explicit,LNAgain_Boosted
    
    Reg    0  1  2  3  4  5  6  7  8  9  A  B  C  D  E  F
    0x800  00 00 00 00 29 07 20 09 00 10 19 D4 10 4E 10 13 
    0x810  10 4B 10 1E 10 4B 10 1E 00 DA AA E6 DB 00 00 00 
    0x820  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x830  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x840  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x850  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x860  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x870  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x880  03 00 00 5F 10 08 00 00 08 04 00 39 30 00 00 0C 
    0x890  00 00 00 10 BD 0F 0A 07 10 00 26 01 01 53 06 07 
    0x8A0  10 00 AD 20 5A 04 F0 02 56 56 54 43 96 20 40 00 
    0x8B0  00 83 11 00 01 04 0A 4C 14 0A 2F 01 6B FF FF 00 
    0x8C0  00 A0 20 00 00 00 AC 00 1C 00 00 AB 05 30 12 13 
    0x8D0  0C 15 16 40 06 00 00 10 E8 00 00 00 00 00 39 39 
    0x8E0  90 39 0C 04 40 20 16 38 06 00 05 04 03 02 01 01 
    0x8F0  03 00 00 00 30 00 00 00 00 00 00 00 00 00 00 00 
    0x900  30 00 00 00 00 64 00 00 00 00 00 00 24 04 47 04 
    0x910  00 2F 00 00 00 03 0A 00 15 35 09 00 02 29 67 08 
    0x920  07 04 05 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x930  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x940  00 07 00 03 02 00 10 00 0A 00 03 04 00 14 0C 00 
    0x950  00 00 00 06 00 00 00 00 00 00 00 00 00 00 00 00 
    0x960  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x970  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x980  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x990  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9A0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9B0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9C0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9D0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9E0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    0x9F0  00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 
    
    
    Receiver ready - RXBUFFER_SIZE 32
    
    4s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,1,Errors,0,IRQreg,16
    5s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,2,Errors,0,IRQreg,16
    6s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,3,Errors,0,IRQreg,16
    7s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,4,Errors,0,IRQreg,16
    8s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,5,Errors,0,IRQreg,16
    9s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,6,Errors,0,IRQreg,16
    11s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,7,Errors,0,IRQreg,16
    12s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,12dB,Length,23,Packets,8,Errors,0,IRQreg,16
    13s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,12dB,Length,23,Packets,9,Errors,0,IRQreg,16
    14s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,10,Errors,0,IRQreg,16
    15s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,11,Errors,0,IRQreg,16
    16s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,12,Errors,0,IRQreg,16
    17s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,13,Errors,0,IRQreg,16
    18s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,14,Errors,0,IRQreg,16
    19s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,15,Errors,0,IRQreg,16
    21s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,16,Errors,0,IRQreg,16
    22s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,17,Errors,0,IRQreg,16
    23s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,18,Errors,0,IRQreg,16
    24s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,19,Errors,0,IRQreg,16
    25s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,11dB,Length,23,Packets,20,Errors,0,IRQreg,16
    26s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,21,Errors,0,IRQreg,16
    27s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,11dB,Length,23,Packets,22,Errors,0,IRQreg,16
    28s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,12dB,Length,23,Packets,23,Errors,0,IRQreg,16
    29s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,24,Errors,0,IRQreg,16
    30s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,25,Errors,0,IRQreg,16
    32s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,26,Errors,0,IRQreg,16
    33s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,27,Errors,0,IRQreg,16
    34s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,28,Errors,0,IRQreg,16
    35s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,29,Errors,0,IRQreg,16
    36s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,30,Errors,0,IRQreg,16
    37s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,11dB,Length,23,Packets,31,Errors,0,IRQreg,16
    38s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,12dB,Length,23,Packets,32,Errors,0,IRQreg,16
    39s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,33,Errors,0,IRQreg,16
    40s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,34,Errors,0,IRQreg,16
    41s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,35,Errors,0,IRQreg,16
    43s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,36,Errors,0,IRQreg,16
    44s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,37,Errors,0,IRQreg,16
    45s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,38,Errors,0,IRQreg,16
    46s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,39,Errors,0,IRQreg,16
    47s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,40,Errors,0,IRQreg,16
    48s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,41,Errors,0,IRQreg,16
    49s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,42,Errors,0,IRQreg,16
    50s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,12dB,Length,23,Packets,43,Errors,0,IRQreg,16
    51s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,44,Errors,0,IRQreg,16
    52s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,45,Errors,0,IRQreg,16
    54s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,11dB,Length,23,Packets,46,Errors,0,IRQreg,16
    55s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,47,Errors,0,IRQreg,16
    56s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,48,Errors,0,IRQreg,16
    57s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,49,Errors,0,IRQreg,16
    58s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,50,Errors,0,IRQreg,16
    59s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,51,Errors,0,IRQreg,16
    60s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,52,Errors,0,IRQreg,16
    61s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,53,Errors,0,IRQreg,16
    62s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,54,Errors,0,IRQreg,16
    64s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,55,Errors,0,IRQreg,16
    65s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,56,Errors,0,IRQreg,16
    66s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,57,Errors,0,IRQreg,16
    67s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,58,Errors,0,IRQreg,16
    68s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,59,Errors,0,IRQreg,16
    69s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,60,Errors,0,IRQreg,16
    70s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,61,Errors,0,IRQreg,16
    71s  Hello World 1234567890*,CRC,DAAB,RSSI,-42dBm,SNR,12dB,Length,23,Packets,62,Errors,0,IRQreg,16
    72s  Hello World 1234567890*,CRC,DAAB,RSSI,-42dBm,SNR,12dB,Length,23,Packets,63,Errors,0,IRQreg,16
    73s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,64,Errors,0,IRQreg,16
    75s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,12dB,Length,23,Packets,65,Errors,0,IRQreg,16
    76s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,12dB,Length,23,Packets,66,Errors,0,IRQreg,16
    77s  Hello World 1234567890*,CRC,DAAB,RSSI,-44dBm,SNR,11dB,Length,23,Packets,67,Errors,0,IRQreg,16
    78s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,68,Errors,0,IRQreg,16
    79s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,69,Errors,0,IRQreg,16
    80s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,70,Errors,0,IRQreg,16
    81s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,71,Errors,0,IRQreg,16
    82s  Hello World 1234567890*,CRC,DAAB,RSSI,-43dBm,SNR,11dB,Length,23,Packets,72,Errors,0,IRQreg,16
    83s  Hello World 1234567890*,CRC,DAAB,RSSI,-45dBm,SNR,12dB,Length,23,Packets,73,Errors,0,IRQreg,16
    84s  Hello World 1234567890*,CRC,DAAB,RSSI,-46dBm,SNR,11dB,Length,23,Packets,74,Errors,0,IRQreg,16
    

    Interestingly, even though the RSSI is vastly better, the SNR stays at around 11 to 12dB. Well, regardless, the Dorji plainly appears to perform much better in my particular home environment, at least so far, at the given frequencies and other library defaults (which do appear to be different between the SX1280 and the SX1262 (e.g. default bandwidth), so a fair comparison will need to be more equal than what's provided by only just the library defaults).

    When I'm a bit more prepared, I'll compare/contrast the two different radios performance along what I would guess is the worst possible transmission path in my house. When that time comes, I'll report the results on a new thread that will be meant for comparing the performance of different radio modules. For now this was just a preliminary test to confirm that the DORJI radio module was working at all, but the results were interesting anyway.



  • @NeverDie You Rock. That looks like a great testing platform... and tiny. In my 5-minute review I have two points to add that your post(s) solicit: 1. To protect the battery gap, as it is, how about a thin piece of cardboard? It appears that the offsets in the machine pin headers have a little room to slip a small zip-tie to restrain the cardboard so that it does not interfere with the test rig on top. It is easier to hack it than redesign, resubmit, repay and all that. 2. Love to join you on this venture so you are not single handed. I'm guilty of leaching and not teaching. I can't do it now (excuses) but hope to join you and help contribute.



  • @NeverDie said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    I don't see any uCurrent Gold's for sale at the moment, but I did find a clone of it, which has what looks like a nice improvement over the original: you can plug it directly into an oscilloscope via its BNC connector.

    Andreas Spiess [https://www.youtube.com/watch?v=LUB8RWzzLWc] has convinced me to buy a Power Profiler Kit II, or one that is assembled. That way I don't need to also buy a scope! I have more work to do.


  • Hero Member

    @Larson said in Anyone using/tried the E28-2G4M27S 2.4Ghz LoRa SX1280 27dB module?:

    @NeverDie You Rock. That looks like a great testing platform... and tiny. In my 5-minute review I have two points to add that your post(s) solicit: 1. To protect the battery gap, as it is, how about a thin piece of cardboard? It appears that the offsets in the machine pin headers have a little room to slip a small zip-tie to restrain the cardboard so that it does not interfere with the test rig on top. It is easier to hack it than redesign, resubmit, repay and all that. 2. Love to join you on this venture so you are not single handed. I'm guilty of leaching and not teaching. I can't do it now (excuses) but hope to join you and help contribute.

    By all means! The more the merrier!

    I posted some PPK2 screenshots on another thread that I recently started: https://forum.mysensors.org/topic/11954/most-reliable-best-radio

    It does a nice job of measuring milliamps. I wouldn't say the PPK2 is good at measuring <1ua currents though, such as sleep currents. If that matters to you, you'll want a Current Ranger, or TinyCurrents or similar.


  • Hero Member

    Worth mentioning is that the SX1280 includes a FLRC (Fast Long Range Communications) modem that can, in theory, go as fast as 1.3mbps. When time allows it may be worth giving it a try.


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