PIC18F13K50, CDC USB communication and ultra-low power temperature logger


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  1. #1
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    Default PIC18F13K50, CDC USB communication and ultra-low power temperature logger

    Dear everyone!

    I am in the process of starting a new project around the 18F13K50, which have to mix ultra-low power and USB communication, a combination that seems to be difficult to mix.

    I had previous success (about 3 years ago) with a couple of very simple project around the 18F2550/4550 and CDC communication profile. But now it seems that there is much more new things added to USB coding, including new USB handling library, and of course new USB pics from microchip too! The PIC18F13K50/14K50 is now becoming an exciting candidate for very small USB projects, and after upgrading MPLAB, purchasing a PicKit 3 and trying to makes everything working back together I can now concentrate on writing code!

    Now onto the project, it is a temperature logger that will sample temperature at a preset interval of time and store it in EEPROM. Content of the EEPROM can then be uploaded to a computer using the CDC USB profile. This is actually very similar in conception to jellish00 ultrasonic logger project that was discussed a bit in this post.

    Temperature logger in standalone mode
    Now the challenge is to run the device out of an ultra-small 25mAh LiPO battery. That is not a whole lot of juice, but using power conservation technique I hope to be able to run it for a long period of time (namely, a few months).

    The hardware that will actually eat power on the device:
    - 3,3V Voltage regulator, TPS72933, quiescent current 500nA.
    - I2C EEPROM, quiescent current about 1µA, 5mA when writing.
    - I2C Temperature sensor TMP100, quiescent current about 1µA, 70µA when sampling.
    - A bicolor LED, for indicating errors (battery low, memory full). This will not be normally used.
    - The PIC, which is going to be the biggest battery drain.

    Here's my idea for power-saving for the PIC. Ideally a timer with the crystal used as a clock source (for accuracy) would be used to define my sampling interval (ideally 1sec, or 5sec). this would send an interrupt to the PIC, getting it out of sleep mode. It would then increment a counter (to get to longer sampling intervals), and when needed, trigger a temp sample on the TMP100 and store it to EEPROM. Then going back to sleep till next timer interrupt.

    The USB charger is also connected to INT0 to send an interrupt when the USB power is connected.

    The battery voltage level is also measured with the PIC ADC, but can be polled with temperature.

    While the timer is ran on the external crystal oscillator, the PIC core may have to be run on the LF internal oscillator (31kHz), providing the lower consumption. The operation in standalone mode is actually not very challenging, what is more is to do it with little power!

    Temperature logger in USB mode
    In USB mode the logger will charge its battery over the USB current. I will have to wake the USB module oscillator, and very likely to change the core frequency to a much faster pace in order to send the data rapidly. The complicated part is all the USB code to handle the CDC communication, and I don't see myself writing that in C or assembler!

    While I understood that the PIC can support all this in hardware, I am not sure about the capability yo implement it all in PicBasic, at least without using ASM calls. DEFINE OSC can only be used once, making a change in OSC frequency difficult for all PAUSE and delays used in the program. DEFINE OSC cannot accommodate for anything lower than 3.58MHz too. Hardware interrupt are not very obvious to handle in PicBasic, though I just found out the library written by Darrel Taylor which looks very promising. I have yet to dig in the details for using it.


    Here is the quick and dirty prototype... at least the hardware works nicely!



    Of course there's extra things too, the LCD is actually quite handy for debuging
    Here it is polling temperature from the TMP100 in "one shot" sample mode, displaying it as the raw 12bit data + converted value (Yes it is hot in Paris tonight!).

    Any consideration on the feasibility of such project with PicBasic?

    I will probably have more question that will arise while advancing in the programming...

    Looking forward to discuss around this!

  2. #2
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    Quote Originally Posted by aberco View Post
    Here it is polling temperature from the TMP100 in "one shot" sample mode, displaying it as the raw 12bit data + converted value (Yes it is hot in Paris tonight!)
    Ooh, I love your city. I'm turning red now...

    Well, that's a lot of info in one post. I think your project can be done in PBP with no problem. The part that I think is unrealistic is trying to get this device running for a few months with a 25mAh LiPO battery. Let's say that the average comsumed current of your device is 1mA, then with some luck you can run your device for 25 hours. You are taking into consideration only the quiescent currents, but what about the operating currents?

    Is this device going to be connected to the USB port all the time? Can you use a bigger battery?

    Robert
    "No one is completely worthless. They can always serve as a bad example."

    Anonymous

  3. #3
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    Hi Bob! thanks for your observations!

    Indeed, 1mA is waaaay too much!!!

    I am giving the quiescent current because this is what is consumed most of the time. The component will be turned on when sampling for a couple ms, a couple of time a day.

    Without counting the PIC, I have at most 3µA of current IDLE, and 5mA at most when writing to EEPROM. To simplify calculation let's say we use the sampling routine for 1 second every hour (that's likely to be longer than needed). So, for hourly consumption that gives: (1*5/3600)+(0.003*3599/3600) = 4,38 µAh
    That's about 190 days on 20mAh.

    I have already all conservation routines programmed and tested for the peripherals, so I'm confident that these numbers are meaningful. I measured them on my prototype.

    Now comes the PIC! The solution would be to shut off the CPU core between sampling and use interrupt from the timer to wake it up. Peripherals and timers can work on their own, and this would cut down the PIC consumption to a few µA too.


    Now the device itself will be build inside the body of an USB jumpdrive. It will not be connected to USB when sampling, so there's no available power. The limited amount of space within the jumpdrive body does not allows for much options as well. I have found the smallest LiPO battery, the 25mAh model, that can fit within 1 by 2cm space in the back of the enclosure. They have a 60mAh model too, but it is significantly larger, and I need to keep some space to cram SMD components on the PCB too. So, Is this device going to be connected to the USB port all the time? No, and Can you use a bigger battery? If I really have to that will be the option. However I first need to design the device to be the most power efficient, regardless of available battery capacity.

    I'll go through a step by step testing of these power saving possibilities with PicBasic... hopefully without ASM calls!

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    Default 18F13K50/14K50 clocking

    Trying to get the USB com. working.
    Now there's a little details that I have seen stated but not previously understood:

    The 18F13K50/14K50 requires the use of an external crystal of 12 or 48 Mhz ONLY! The internal clock circuitry is in fact simpler than what the 2550/4550 has, and the only option to feed the USB oscillator is either directly or using a x4 PLL. CPU frequency can then be derived from the PLL using ÷1, 2, 3 or 4.

    No problem for my USB mode, but for my low power mode running at 12Mhz is out of question. That will require the use of the internal RC oscillator, and a loss of timing precision between the temperature samples (which is not overly critical).

    An other solution is to use the second external oscillator and wire a 32,768kHz crystal to it (with a bit more PCB real estate used).

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    "No one is completely worthless. They can always serve as a bad example."

    Anonymous

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    Cool! I missed this thread, I'll dissect it carefully, looks pretty much like all I want!

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    Back on the PIC, dissecting the datasheet, this is what I have for the LF13K50

    • Sleep mode: 24 nA
    • Watchdog Timer: 450 nA
    • Timer1 Oscillator: 790 nA @ 32 kHz

    So using the watchdog timer to wake up the pic should lead to extremely low power consumption, provided that I don't need to wake the pic often, and that it won't do much when it'll be awake (turning back to sleep rapidly).

    I could even experiment the use of timer1 driven by the 32k crystal instead of the watchdog to give much more decent time accuracy on my measurements intervals.

    My power rail is 3.3V so I can use the LF model. I could reduce even more consumption by lower it down to 2.8V using another regulator. 2.5V or 1.8V would be even better, but then the temperature sensor TMP100 is off specs (2.7V min).

    Looks good on the paper, now onto the program to get this. I still need to fix the USB side first though...

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    I could not get the CDC demo to run on my 18F4550 board, (though, 3 years ago it was running fine... but since then I changed PBP, MCS and PMLAB versions...). I preferred to carry on the actual programming of the project. Getting almost done, now with automatic EEPROM identification and temperature logging.



    Just have to improve power consumption and add USB com.

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    Quote Originally Posted by aberco View Post
    Looks good on the paper, now onto the program to get this. I still need to fix the USB side first though...
    Aberco,

    It would be interesting to see a Battery vs. Time plot after you are done with your design to see how well the battery is holding on.

    Robert
    "No one is completely worthless. They can always serve as a bad example."

    Anonymous

  10. #10
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    Yep will do!
    I have setup the secondary oscillator with a 32k XTal. That way it will give me the time accuracy I need and I can clock the CPU using that source. I have yet to finish the main routine and get everything to work before implementing the power conservation tricks.... and that USB communication deal to figure out.

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    It was time to pack things down, I must say that it is not easy to drill vias using a 0.3mm drillbit and sticking a tiny copper wire in it to make the connexion!



    Not much progress on the programming yet due to lack of free time, but will work on that soon.

  12. #12
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    Back with more news, I made some great progress with the programming!

    I am trying to implement the low power mode, however I find microchip datasheet to be a bit confusing. I switch from a 48Mhz CPU clocked from 12MHz HS primary oscillator + PLL to the Timer1 clock source (SEC_RUN mode) when entering low power operation:

    Code:
    'Oscillator software configuration for 32.768kHz operation on Timer1 clock
    OSCCON.1 = 0
    OSCCON.0 = 1 'Use Timer1 oscillator as clock source
    OSCTUNE.6 = 0 'Disable PLL
    OSCCON2.2 = 0 'Disable primary oscillator
    OSCCON.7 = 1 'Device enters in IDLE mode when sleep instruction issued
    Then I have my main standalone operation loop. The only code executing are triggered by INT0 and TMR1 using DT_INTS-18.

    Code:
    StandAloneLoop:
    
    @ SLEEP
    
    GOTO StandAloneLoop
    It does work well if the operating mode is IDLE (IDLEN = 1). This mode turn off CPU clock but leave all peripheral clocked (here, from Timer1 source). I tried this instead:

    Code:
    OSCCON.7 = 0 'Device enters in SLEEP mode when sleep instruction issued
    This would allows to save even more by turning off the peripheral too, however the first interruption does work, and after the PIC doesn't wake up anymore. In the datasheet it says
    This shuts down the selected oscillator and all clock source status bits are cleared.
    However the only peripheral that needs to run is the Timer1 to trigger the interrupt, but that can only happen if the secondary oscillator is running. If there's no way to use SLEEP mode while keeping the secondary oscillator running, then I should probably use the SEC_IDLE mode... hopefully the peripherals don't drain that much power.

  13. #13
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    If you put a crystal on the Timer1 oscillator, enable T1OSCEN and change TMR1CS before going to sleep with an appropriate reload value for the lower frequency ... you could put it to sleep.
    DT

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    Hmm I don't really understand, I have this at the beginning of my code during initialization:

    Code:
    T1CON = %01101011 'Set Timer prescaler to /4 and enable Timer1 on external 32768Hz crystal
    T1OSCEN = 1 (secondary 32768Hz oscillator is enabled)
    TMR1CS = 1 (timer clock source is secondary 32768Hz oscillator)

    My setup already use the Timer1 for both interrupt and general clock source when in low power mode, and it does work as expected.

    I tried to add that T1CON configuration line above my @ SLEEP instruction but that didn't help much. If the SLEEP mode actually turn off all clocking sources then T1OSCEN bit should be set to 0 as well.

    Maybe using the IDLE mode and manually disable all peripherals that are enabled default would be a workaround.

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    Timer1 oscillator continues to run during sleep mode, but ... try it like this.
    First, comment all the OSCCON and OSCTUNE statements you showed above.

    Then ...
    Code:
    StandAloneLoop:
      ASM
        SLEEP
        NOP
        NOP
      ENDASM
    GOTO StandAloneLoop
    DT

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    Tried this step by step.

    Commenting either or all of these:

    Code:
    OSCCON.1 = 0
    OSCCON.0 = 1 'Use Timer1 oscillator as clock source
    OSCCON.7 = 1 'Device enters in IDLE mode when sleep instruction issued
    stop operation. However I'm not sure if it's because the interrupt is not triggered anymore or if that's because the CPU does not come back from sleep. I remember reading that Timer1 oscillator was always running, but looking carefully at the datasheet again I cannot find that statement back. Only mention is that SLEEP (not IDLE) mode turn off all clocks and all oscillators, expect for the WDT oscillator (if enabled).

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    And you had more statements than those 3.
    One of them disables the Primary Oscillator, which will keep it from running after it wakes up I would assume.
    Attached Images Attached Images  
    DT

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    Yes but I commented all others as well. I just quoted the lines that caused the interrupt to stop working.

    I want to disable the primary oscillator, because I have 2 operating modes:

    1) USB attached, clocked from a 12Mhz ceramic resonator, with PLL enabled and CPU clocked at 48Mhz

    2) USB detached, standalone, CPU and peripherial clocked from Timer1 secondary oscillator.

    When the CPU wakes from sleep it should resume on the oscillator defined by the SCS bits, here SEC_RUN mode:

    Code:
    OSCCON.1 = 0
    OSCCON.0 = 1 'Use Timer1 oscillator as clock source

    Now you found that statement back from the datasheet, there's hope to make it work! I'll investigate harder and make some tests on a simplified program.

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    I realized that I have a very strange problem when I write to my I2C EEPROM when the CPU is clocked at 32.768kHz, I get corrupted data if there's a long chain of "0" being sent.

    I record my temperature samples two by two, and they span 3 bytes in memory (Byte A, B and C). One sample is 12bit, 8 bit for integer value (Sign + 7 bit value), and 4 bits for decimal value (0.0625 steps). They are recoded with an interleave routine as such:

    Sample 1 : AAAAAAAA.BBBB
    Sample 2 : BBBBCCCC.CCCC

    1811 2010/10/29 0h44m00s +23.9375
    1812 2010/10/29 0h44m10s +23.9375

    1813 2010/10/29 0h44m20s +24.0000
    1814 2010/10/29 0h44m30s -7.9375

    1815 2010/10/29 0h44m40s +24.0000
    1816 2010/10/29 0h44m50s -7.9375

    1817 2010/10/29 0h45m00s +24.0000
    1818 2010/10/29 0h45m10s -8.0000

    1819 2010/10/29 0h45m20s +23.9375
    1820 2010/10/29 0h45m30s +23.9375
    I have a 5ms pause between the 3 write operations, and there's about 20 sec between the record of each packets of 3 bytes. I tried increasing the write delay to 20ms without changes, and EEPROM VCC is within range.

    This occurs when odd samples ends with .0000, .2500, .5000, and .7500, the problem does not appears if I run the CPU using the internal oscillator at 250kHz (and readjusting all the delay values accordingly), which makes me wonder if I2CWRITE can be used with a CPU clock of 32.768kHz...

    Also, this might be related to the issue I have... is doing such operation:
    Code:
    DataValue = TempH >> 4
    modify the original value of TempH?

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    The logger project is getting near completion! I am now into the autonomous mode power, and I was able to measure these figures while powering the device from a battery across a 10 ohm shunt.



    It is quite clear that I have to improve power consumption as at 900µA the 130mAh battery runs for about 6 days... The PIC sits most of the time at IDLE, and here it shows where a second sample is read and written to memory with the first previously read sample (hence the 3 write cycles for 2x 12bits).

    I have not managed yet to make the true sleep mode to work, but at IDLE the power consumption seems to be very high... there's no difference than when running the CPU from internal clock at 250kHz. As I said above I tried running the CPU from Timer1 oscillator but that gave me some memory writing issue so I quitted.

    Other than the PIC eating power I have (when IDLE):
    LDO regulator, 500nA
    I2C EEPROM, 1µA
    I2C Temperature sensor, 1µA
    220k/220k voltage divider, 5µA

    Will try to investigate more and post results

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    Maybe you can control EEPROM and Temp. Sensor power by a pin from your controller. When you have to make new measurements, just make the pin high, wait a little to let the circuit settle, and do your sampling and writing. Then switch them off again.

    Ioannis

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    Design is completed and can't be changed, beside there's no available I/O pin left.

    IDLE power consumption is actually from the PIC and not from the peripherals.

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    I managed to reduce consumption to less than 50uA.
    Here is main part of the code.

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    That would be pretty good! I will have a look at how you managed to get that and will let you know. Thanks for the help!

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    Took me too long to edit the previous post, I got locked!

    I have downloaded the XLP LowPower App note from microchip and it is helpful. The 14K50 does not allows for deep sleep, but regular sleep should do.

    Obviously IDLE mode consumes 25% less than the normal run power, so I will have to make the Sleep mode to work while getting the PIC to resume from it. However there's probably something else that I have to find out, as 900µA seems to be abnormal for IDLE at 250kHz... I'll have to double check if the peripherals are also turning into low power too. I have also reduced the power supply to 2.2V (the regulator is able to switch from 3.3V for USB operation to 2.2V - TPS780330220 from TI). that should help a bit with consumption.

    Could the I2C pullup be a problem? I have used 6.8k resistors which is pretty much the maximum, at 10k and beyond the operation of the I2C bus is unstable.
    Last edited by aberco; - 9th November 2010 at 01:39.

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    If the two resistors are grounded, then the current through them, is close to 900uA.

    Make sure the pins that these are connected, are set to high or z-state before sleep.

    Ioannis

  27. #27
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    Default Re: PIC18F13K50, CDC USB communication and ultra-low power temperature logger

    Anyone know if this is still an active item PIC18F13K50T-I/SO
    Last edited by tron235; - 4th November 2011 at 19:31.

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    Default Re: PIC18F13K50, CDC USB communication and ultra-low power temperature logger

    Quote Originally Posted by tron235 View Post
    Anyone know if this is still an active item PIC18F13K50T-I/SO
    Did you check at MCHP's website http://www.microchip.com/wwwproducts...cName=en533925
    Why pay for overpriced toys when you can have
    professional grade tools for FREE!!!

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