ISL6258 ISL6259 Troubleshooting
ACIN ACIN pin on the charger IC detects if the input voltage is high enough, it is connected to a voltage divider on the DC-in voltage. As indicated on the schematics, the pin should be at least at 3.25V, the exact voltage will depends on the machine (the value of the resistors are similar but not the same across different machine) and the Magsafe version and power. That said, it should always be at least 3.4V, and if using a 85W Magsafe, at least 3.9V. If it's lower than 3.25V you get 0V on PPBUS_G3H.
The value on ACIN is calculated like this (like your usual voltage divider): Vin the input voltage (DC-in voltage here) Vo the output voltage (ACIN pin here) R1 the resistor between the input voltage and output voltage. R2 the resistor between the output voltage and ground. Vo = Vin * R2 / (R1 + R2)
DCIN DCIN pin on the charger IC is its input voltage. If the charger IC dies, it can take out the resistor between DC-in and this pin. The voltage on this pin should be almost the same as DC-in voltage. If it's missing you get 0V on PPBUS_G3H
CELL CELL pin on the charger IC sets the initial output voltage on PPBUS_G3H. CELL is named as such because it is related to the number of cells in series in the battery. With a charging voltage of 4.2V for each cell, a 2-cells battery requires an overall charging voltage of 8.4V, a 3-cells battery requires an overall charging voltage of 12.6V. That's why PPBUS_G3H is around 8.4V (or a little more but doesn't matter) on Macbook Air and 12.6V on Macbook Pro, since it's the voltage that will charge the battery.
The voltage on CELL sets the number of cells like this (from ISL6255 datasheet):
Voltage on CELL | Connected to… | Nb of cells | Output voltage
CELL < 2V | pulled to ground | 2 cells | 8.4V 2.1V < CELL < 4.2V | floating or fixed | 3 cells | 12.6V 4.3V < CELL | pulled to VDD | 4 cells | 16.8V
On Macbook Air, this pin is pulled to ground for the 2 cells battery. On Macbook Pro, this pin is pulled to PP3V42_G3H for the 3 cells battery.
If the pulldown resistor is missing on a Macbook Air, you may get 12.6V on PPBUS_G3H
Note: in fact the definitive output voltage is set by SMC, initial voltage is a few percents lower but doesn't matter here.
VDD/VDDP The VDD pin is an internal 5V LDO, meaning the charger IC creates that rail. VDDP is connected to it through a resistor. If VDD is missing but DCIN is present, the charger IC is most likely dead. Both pins should have 5V on them if the charger IC receives power.
ACOK Indicates that the DC-in voltage is ok. Connected to SMC_BC_ACOK. I don't exactly know the requirements, but most likely if DCIN, ACIN and VDD are ok then this should come up, and most likely turn on the DC-in MOSFETs at the same time.
AMON Output from AC current sensing. A 1V drop across the current sense resistor would set this pin to 20V (impossible but it gives the ratio) The current sense resistor is usually 0.02ohm, using Ohm's law: I = U/R = 1/0.02 = 50 A So, 50A across the current sense resistor would set this pin to 20V. You'd expect the current to be lower than 4.6A, so that means a 0.092V voltage drop across the current sense resistor, so 1.84V on the AMON pin. This can be useful to know if you have an ID0R sensor issue you cannot figure out.
BMON Output from battery current sensing. A 1V drop across the current sense resistor would set this pin to 36V (impossible but it gives the ratio) The current sense resistor is usually 0.01ohm or 0.005ohm, using Ohm's law with 0.01ohm: I = U/R = 1/0.01 = 100 A So, 100A across the current sense resistor would set this pin to 36V. You'd expect the current to be lower than 7A (I don't know the threshold for ASD but that'd be already 70W with 10V on the battery), so that means a 0.07V voltage drop across the current sense resistor, so 2.52V on the AMON pin. Note that while running on battery this should be strictly below 0 since the battery provides current to the system (although I never measured it…). While running on AC with the battery charging, it should be strictly above 0 since the charger provides current to the battery. This can be useful to know if you have an IB0R sensor issue you cannot figure out.