Shutdown Problem with External Reg/PIC and ADC

[carl]

Hi There,

I need a little help if possible.
The problem is related to my previous threads:

http://www.ccsinfo.com/forum/viewtopic.php?t=45743&highlight=
http://www.ccsinfo.com/forum/viewtopic.php?t=46204&highlight=

Prerequisite:
The PIC is powered on its own supply.
The PIC controls (on and off) the boost converter.
The ADC and other circuitry is powered from the boost converter.
The Program works perfectly when the boost converter is always 'on' output_low(SHUTDN2).
The Program fails to work when the boost converter is varied 'on/off' output_low(SHUTDN2)/output_low(SHUTDN2).



I am using an external boost convereter with shutdown. The problem is not with the converter - but trying to incorporate the 'shutdown code' CORRECTLY in the program.

The converter is 'OFF' when a high is applied to the 'shutdown pin' and 'ON' when a low is applied to the 'shutdown pin'. I have been using 'output_high(SHUTDN2)' and 'output_low(SHUTDN2)' in various guises, but I cannot get it to work - and it is corrupting the ADC. The 'Relevent' code is below

[RF_Developer]

There's a number of problems. A powered down device will kill the SPI bus, it may even physically damage the PIC and any other still powered SPI devices. I think you're already seeing this.

[carl]

Hi RF_Developer,

Thankyou for your detailed response.
The CS line is now tied to ground - so the ADC is permanantly on. Initially I had been controlling this with a pic pin. Sorry I didnt mention that.

I'm using Pin_A7 (PIC_SDI or ADC_SDO) which incorporates the 'end of conversion' and is in the datsheet (desciptively and also in the code sample at the back as PIn_C4). Extract(s) from datasheet:

[RF_Developer]

Ahhh, my reading of the data sheet is that unless you are using internal SCLK mode, and hence the PIC is running as an SPI slave, its raising /CS that triggers the next conversion. If you hold /CS low all the time it'll just do one conversion, send the result back and then stop.... waiting... for you to trigger it again by raising /CS.

Would it be fair to say you may not be very familiar with SPI? A "normal" SPI transaction is to activate /CS for the chip on the bus you want to talk to; send and receive data as required, then deactivate the chip (raise /CS). This chip is SPI compatible but the EOC thing is an add on: you can select it by lowering /CS, test the data bit BUT NOT by clocking it in the SPI manner, then doing the SPI transfer if its ready. If not you can raise /CS and let the ADC get on with its conversion. There is a problem in that you need to both have the SPI peripheral reading the data AND you reading the state of the relevant pin through normal I/O. You might have to use input_state() instead of input, and you may have to mess with the TRIS selects for the relevant pin. I'm not sure which will work best.

Also this extra to SPI thing may not be compatible with other SPI devices on the bus, but it seems likely you are just talking to this ADC and so you shouldn't have that sort of problem.

You haven't set the SPI speed, and you may - because you've specified all the pins - be using a software SPI instead of the actual hardware. The ADC works with SPI clock of up to 4MHz by BAUD=4000000, or lower - certainly its often easier to see what's happening during development to run much slower: the ADC will run quite happily down to 10kHz SPI clock.

So, once you've sorted the SPI issues, you need to do something like:

power on
Wait for power supply to settle.
Initialise ADC.
Wait for it to get to its ready state.
Trigger a reading by raising /CS
every now and then wait for completion by dropping /CS, checking the state of the pin. If Ready then
take adc reading
power off, somehow preventing ADC from overloading the SPI bus due to its clamp diodes...
else
raise /CS
do something....
etc.

I'd actually get this running by leaving the power on all the time. Something like this:

power on
Wait for power supply to settle.
Initialise ADC.
Wait for it to get to its ready state.

Trigger a reading by raising /CS

Main loop:

Drop /CS
Check the state of the pin.
If ADC Ready
{
take adc reading
}
raise /CS // Do this regardless of whether we took a reading or not.

do other stuff....

Note, no delays in the main loop. Only in the initialisation stuff.

RF Developer

[carl]

Hi RF_Developer,

THanks again for your feedback. I have commented on your points below, however as I said previously - the ciruit works fully and succesfully if the power is maintained at all times. So the 'set-up' or way in which the 'bulk' of the code is written is good - but not when trying to implement the power down. I also didn't say that the whole idea of the power down will be happening every half a second or so to conserve power - so:

1) power on for 500ms
2) Take ADC reading
3) do something
4) Power off for 500ms
5) do something else not ADC/SPI related

[RF_Developer]

[temtronic]

I know some 'features' are nice and 'conserving energy' seems to be a mantra but...

You might want to grab a pencil and paper and see what energy savings you're really going to get over say a 1 week period as opposed to just using a couple of AA LI-Ion batteries.Microchip did a great study for 'low power RTC in a chip' a decade+ ago and it was clear that while savings could be had in chip selection, clever coding,etc. it was actually more cost effective to just use a bigger( greater aHr) battery.All too often you can get lured by 'smaller is better' but it ends up costing you more in R&D time($$$),testing($$$$),etc. and the end product is delayed,allowing the competition to gain your marketshare.
Having gone down that road decades ago, I learned that 'smaller' is not better and that some 'features' are only good on paper.

[carl]

Thankyou both for your help.

The idea is that being able to shut down 'several' different sections of a design with only ONE control line is advantagous when compared to individulaly having to use seperate lines for each 'shutdown' feature for each seperate I.C.

So if the only parts concerned were a PIC and ADC, then doing it in this way would be silly. BUT if you had a PIC, ADC, A.I., Transmitter, something else, something else...... then in my opinion it would save lots of power, reduce pin count, reduce tracking etc.

I understand what you mean RF_Developer about the 'power up time' and this is what I tried fiddling about with first - but no matter how long I power it up for it doesn't work. For instnce if I change the code below for 5000ms it should have powered up, initialised and 'ready to take the reading' - but it doesn't. it starts to read the data 'at the end of the 5000ms'. I am obviously doing something wrong, but cant work in out.

[asmboy]

can't you then simply leave the ADC powered -
and just shut off the load cell bias power?

have you done an analysis of what your power demand is for each component?

also
if any PIC lines to the LTC chip are high by default-
powering down the ADC may very well be causing unintended conduction from the pic I/O system that is potentially excessive or maybe even damaging.

have you carefully measured inline current consumption for the whole circuit when running and when shut down to verify:

1- actual power saving
2- a spike in current when you shutdown the ADC?

considered other ADC chips?

16 bit parts like the ads8320 mange their OWN shutdown between readings and are great at conserving power AND taking very fast readings when powered up. i think you can find 24 bit parts from TI that follow the same low power conserving approach too.

[carl]

HI ASM,

can you elaborate more on this

[asmboy]

use a P mosfet - high side switch

if the load cell voltage is greater than Pic Vcc
only 3 parts are needed or
if the same or close to pic V cc -then just 1 part ;-))

is your load cell using 10 v ??

let me know the bias volts you are using - and i will show simple schematic to add very low drop ( .1v or less when ON ) hi side switch

[SherpaDoug]

I am joining this thread late, but be sure to get your A/D reference voltage from the switched side of the load cell power, or use another A/D channel to monitor this voltage so you can compensate for voltage loss in the switch.

Also see if your load cell prefers to run from a current source instead of a voltage source. Many load cells are better temperature compensated while operating from a current source.
_________________
The search for better is endless. Instead simply find very good and get the job done.

[carl]

Hi ASM,

Thanks for the reply.
As I thought you would use a power switch rahter than a buffer - excellent.

I have two designs:
1) Everything is powered from the same voltage 3.6V.
2) Only the pic is powered from 3.6V and everything else is 5V.

And believe me the 3.6V version will be 3.6V and Its good - no need to explain all the downsides of reduced headroom/resolution - I am happy with the design.

The load cell has 1000Ohm bridge. Therefore current consumption @3.6V = 3.6mA. And at 5V you get 5mA.

because the aim of both designs is to be ratiometric, I need the output from the switch to be nearly the same as the input. I understand that this depends on the internal switch resistance - the lower the better.

I have looked at STMPS2141 part (90mOhm). So am I correct in saying that Ron = V/I. Therefore if I want the V(volt drop) = 1mV, then

Ron = 0.001/0.005 = 200mOhm MAX.

And STMPS2141 has a 90mOhm resistance - so volt drop will actually be a lot lower:

0.09 x 0.005 = 0.00045V Volt drop - excellent!!!!!!!!!!

But am I correct?????

Carl

[asmboy]

that part ought to work

BUT ANY good low Ron P fet will work as well or better
with source connected to bias supply

drain to load cell and
GATE to PIC -
when pic control is LOW FET conducts

when gate is raised to Vcc - FET is off

i think you will find there are small P fet Low volt parts that can do less than
90 mohms

the Si5419DU

is only 33 mohms in your zone of voltage switching

[carl]

Thanks ASM,

I have got the idea now.