Battery cell monitor and balancer based on the AVR ATTiny85 MCU.
- reads cell voltage and temperature
- switches balancing FET
- communicates with a host controller via isolated serial
- low power consumption (<1mA when idle, ~2mA while active)
A cell monitor is intended to monitor a single cell as part of a larger series pack. The cell monitor is powered directly from the cell it monitors and works with any chemistry where the voltage remains within 1.8V-5.5V (i.e. lithium-ion, LiFePO4).
Dependencies:
make
make fuse
make flash
Cell monitors are wired in a daisy chain with the TX from the host controller connected to the RX of cell monitor 1, the TX of cell monitor 1 connected to the RX of cell monitor 2, etc. The TX of cell monitor N is connected to the RX of the host controller.
+-----------+
| HOST RX | <------------------------------------------+
| TX | >---+ +--->---+ +---> ... >---+ |
+-----------+ | | | | | |
| | | | | |
+--------+ +--------+ +--------+
| RX TX | | RX TX | ... | RX TX |
| 1 | | 2 | ... | N |
+--------+ +--------+ ... +--------+
Cell monitors are addressed by their position in the daisy chain.
The host controller initiates all communication with the network of cell monitors and does so at 9600 baud. The host controller sends a request packet which is forwarded through the daisy chain to an addressed cell monitor. The addressed cell monitor will reply with a similar response packet which will be forwarded through the remaining chain and eventually read by the host controller.
Communication consists of 5 byte packets with the following structure:
| Byte | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 |
|---|---|---|---|---|---|---|---|---|
| 1 | ADDR6 | ADDR5 | ADDR4 | ADDR3 | ADDR2 | ADDR1 | ADDR0 | REQ |
| 2 | REG6 | REG5 | REG4 | REG3 | REG2 | REG1 | REG0 | WRITE |
| 3 | VAL15 | VAL14 | VAL13 | VAL12 | VAL11 | VAL10 | VAL9 | VAL8 |
| 4 | VAL7 | VAL6 | VAL5 | VAL4 | VAL3 | VAL2 | VAL1 | VAL0 |
| 5 | CRC7 | CRC6 | CRC5 | CRC4 | CRC3 | CRC2 | CRC1 | CRC0 |
- ADDR6-0 - cell monitor address
- REQ - 1 if packet is a request, 0 if packet is a response
- REG6-0 - register (described below)
- WRITE - 1 if packet is a write command, 0 if packet is a read command
- VAL15-0 - value
- CRC7-0 - CRC8 of prior 4 bytes
0x1- cell address (1 byte, unsigned)0x2- reference voltage (2 bytes, unsigned)0x3- cell voltage (2 bytes, unsigned)0x4- celsius temperature (2 bytes, signed)0x5- balance (1 if balancing, 0 otherwise)
Reading the voltage from cell 1
Request:
| Byte | Value |
|---|---|
| 1 | 00000011 |
| 2 | 00000110 |
| 3 | 00000000 |
| 4 | 00000000 |
| 5 | 11010110 |
ADDR= 1REQbit set to 1REG= 3WRITEbit set to 0VALis not applicable for read requestCRC= crc8(50724864)
The following response will be received:
| Byte | Value |
|---|---|
| 1 | 00000010 |
| 2 | 00000110 |
| 3 | 00001100 |
| 4 | 11100100 |
| 5 | 01110111 |
ADDR= 1REQbit set to 0REG= 3WRITEbit set to 0VALis the returned voltage (3300mV in this example)CRC= crc8(33950948)
A cell monitor has an undefined address when it is initially powered on. The host controller needs to initiate an address assignment request (which has slightly different semantics than other value requests):
| Byte | Value |
|---|---|
| 1 | 00000001 |
| 2 | 00000011 |
| 3 | 00000000 |
| 4 | 00000001 |
| 5 | 00110011 |
ADDR= 0 (broadcast to all cell monitors)REQbit set to 1REG= 1WRITEbit set to 1VAL= first cell addressCRC= crc8(16973825)
The first cell monitor will receive the request and set its address to the value in the VAL field.
Instead of sending a response it will increment the VAL field and forward the request onward.
Eventually the host controller will receive the same request packet (with an incremented VAL).
The host controller should assert that VAL equals 1 more than the number of cell monitors in the
network.