The charger voltage limits in my un

The charger voltage limits in my unit are 4.217 and 4.223 V, luckily very well inside the 1% margin. So the charger is perfect for my needs.

The output is common to both ports, and can deliver in theory up to 2.1A total, it can not deliver 2+1A. Both ports are connected in parallel as one 2.1A, only the current sensing is separate for each port.

The uC senses the current of each port and shut downs the converter (always both ports) when any exceeds its rating. I did not check the current limits for each port nor if the uC checks the sum to be below 2.1A for the maximum combined output. I verified that the 2A port can deliver 1.5A, good for most or all standard BC devices, and the 1A good only for devices known to draw 1A or less.

The charger port identification resistors are set for the proprietary, non standard, Apple approach, and are the same for both ports as 1A ports (which is wrong). I think the reason to identify both as 1A for Apple devices, driving both D+ and D- above VREF, is to achieve compatibility with standard BC1.2 devices, although it is not the standard way to do it (it should be a short between D+ and D-, but the chosen Apple 1A setting should work with most or all BC devices too). For BC devices, it would mean that they can draw up to 1.5A, and that’s why we see up to about 1.4A with most devices, and why these devices (those that can draw more than 1A) do not work well with the port marked as 1A. In theory, it could deliver 2A but only Apple devices would draw it, and will not because the port identifies as 1A port to Apple devices.

The drop in d4…d7 diodes causes the converter to stop working with battery voltage below 3.4..3.5V. With better diodes it could go down to 3.15..3.25V, but only with smart bypass diodes will go down to 3.0 V to exploit the full battery capacity. There are not smart bypass diodes with the similar packaging as the SS32, but probably they could be mounted anyway.
The converter is designed to work with single cell without bypass diode, but here it is used with bypass diodes, that’s the reason for the abnormally high shutdown voltage and efficiency losses.
The theoretical converter efficiency is about 85%, which should be achieved if the inductor used is good enough.
The overall efficiency is much worse though, because the bypass diodes. With smart bypass diodes it could go down to 3.0V and reach about 85% overall efficiency.

Overall, as charger the product is very decent. As power bank, not so much, but could be improved easily to be pretty good only changing the diodes, and placing a switch to avoid the excessive drain when unused.