Electronic – Efficiently regulating primary cells for a long-life IoT device

batteriespower supplyvoltage-regulator

I'm working on a long-life IoT sensor device which spends probably about 99.99% of its life asleep, waking up every 15 mins to take measurements and send data. I'm sure this is a problem that many people face as IoT becomes more popular.

I've figured out a few things to start: To get the longevity I require from the system the sleep mode current has to be tiny. Combined with this the primary cell has to be a high-capacity, low-self-discharge cell (Lithium Thionyl Chloride 3.6V battery, for example).

For example's sake, lets say the current requirements are typical of my typical wireless IoT device varying as follows, depending on the mode of operation over a period of 15 minutes:

  • Sleep mode: <10uA (99.99% of the time)

  • Measurement mode: 0.5-10mA (~10s)

  • Transmission mode: up to 50mA (2-5s)

Ideally I'd power the device straight from the cell, but a couple parts I'm using have a max input voltage of 3.6V, and a few LiSOCl2 cells I've seen will sit at 3.7V before settling into their nominal voltage of 3.6V.

I'm aware the cell voltage may droop when under heavier load, so to be safe, 3V seems like a reasonable level to operate without being affected by the droop.

What is the best way to go about efficiently regulating this sort of primary cell to provide around 3V? The regulator would also have to consume very little current itself.

Best Answer

OK, you're worrying about overvoltage.

I've never designed something like you're doing, but I wanted to focus your attention on something you could have forgotten: temperature. Temperature is something that has a tendency to behave like its other name is Murphy.

I know nothing about Lithium Thionyl Chloride, so I googled it, clicked on the first link, then clicked on a random datasheet for a random cell...

And whaddyaknow, the open circuit voltage rises with temperature at an alarming rate.

Will your stuff be exposed to direct sunlight?...

I would advise using a high-current CMOS micropower LDO.

High current, because you want the pass device to be enormous, so its dropout voltage is tiny under load.

CMOS and micropower, because idle current isn't your friend.