FU-Dyson-BMS | Firmware Upgrade for Dyson V6
kandi X-RAY | FU-Dyson-BMS Summary
kandi X-RAY | FU-Dyson-BMS Summary
FU-Dyson-BMS is a C library typically used in Xiaomi applications. FU-Dyson-BMS has no bugs, it has no vulnerabilities and it has low support. However FU-Dyson-BMS has a Non-SPDX License. You can download it from GitHub.
(Unofficial) Firmware Upgrade for Dyson V6/V7 Vacuum Battery Management System
(Unofficial) Firmware Upgrade for Dyson V6/V7 Vacuum Battery Management System
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Quality
Security
License
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Support
FU-Dyson-BMS has a low active ecosystem.
It has 375 star(s) with 38 fork(s). There are 13 watchers for this library.
It had no major release in the last 12 months.
There are 24 open issues and 5 have been closed. On average issues are closed in 8 days. There are no pull requests.
It has a neutral sentiment in the developer community.
The latest version of FU-Dyson-BMS is release-v1
Quality
FU-Dyson-BMS has no bugs reported.
Security
FU-Dyson-BMS has no vulnerabilities reported, and its dependent libraries have no vulnerabilities reported.
License
FU-Dyson-BMS has a Non-SPDX License.
Non-SPDX licenses can be open source with a non SPDX compliant license, or non open source licenses, and you need to review them closely before use.
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FU-Dyson-BMS releases are available to install and integrate.
Installation instructions are available. Examples and code snippets are not available.
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Currently covering the most popular Java, JavaScript and Python libraries. See a Sample of FU-Dyson-BMS
FU-Dyson-BMS Key Features
No Key Features are available at this moment for FU-Dyson-BMS.
FU-Dyson-BMS Examples and Code Snippets
No Code Snippets are available at this moment for FU-Dyson-BMS.
Community Discussions
No Community Discussions are available at this moment for FU-Dyson-BMS.Refer to stack overflow page for discussions.
Community Discussions, Code Snippets contain sources that include Stack Exchange Network
Vulnerabilities
No vulnerabilities reported
Install FU-Dyson-BMS
Warning: The firmware flash process is irreversible. It is not possible to restore the factory firmware.
Be careful. Li-ion batteries are no joke and must be respected. You're working on a live battery pack that can output 100+ Amps if short-circuited.
Disassemble battery pack to access PCB
Make sure all cells are charged above 3V and that the pack LEDs do something when you press the button (with magnet on reed switch if using V7). This confirms the 3.3V rail is regulating and the PIC is awake/working.
Remove conformal coating over programming connection points (if applicable)
Connect PICkit to computer and, if you using a PICkit 3 or clone, install the PICkit 3 Programmer App and Scripting Tool v3.10. (https://www.microchip.com/en-us/tools-resources/archives/mplab-ecosystem)
Connect PICkit to BMS board as shown below: (Note: I now recommend not connecting the VDD wire at all. The ISL94208 chip seems keen to fail with an externally supply voltage. I'd still suggest waking up the battery pack as describe in step 6 to power the board up for programming. One user has suggested (https://github.com/tinfever/FU-Dyson-BMS/issues/24) even this may be unnecessary though.)
Wake up battery pack by pressing button and placing magnet on reed switch (if using V7 vacuum).
While maintaining tension on wires to BMS board, make sure PICkit can see the PIC16LF1847 microcontroller, then import and write the hex file from the latest GitHub release. For more details, see video linked at the top (https://www.youtube.com/watch?v=dwyA5rBjncg).
Be careful. Li-ion batteries are no joke and must be respected. You're working on a live battery pack that can output 100+ Amps if short-circuited.
Disassemble battery pack to access PCB
Make sure all cells are charged above 3V and that the pack LEDs do something when you press the button (with magnet on reed switch if using V7). This confirms the 3.3V rail is regulating and the PIC is awake/working.
Remove conformal coating over programming connection points (if applicable)
Connect PICkit to computer and, if you using a PICkit 3 or clone, install the PICkit 3 Programmer App and Scripting Tool v3.10. (https://www.microchip.com/en-us/tools-resources/archives/mplab-ecosystem)
Connect PICkit to BMS board as shown below: (Note: I now recommend not connecting the VDD wire at all. The ISL94208 chip seems keen to fail with an externally supply voltage. I'd still suggest waking up the battery pack as describe in step 6 to power the board up for programming. One user has suggested (https://github.com/tinfever/FU-Dyson-BMS/issues/24) even this may be unnecessary though.)
Wake up battery pack by pressing button and placing magnet on reed switch (if using V7 vacuum).
While maintaining tension on wires to BMS board, make sure PICkit can see the PIC16LF1847 microcontroller, then import and write the hex file from the latest GitHub release. For more details, see video linked at the top (https://www.youtube.com/watch?v=dwyA5rBjncg).
Support
For any new features, suggestions and bugs create an issue on GitHub.
If you have any questions check and ask questions on community page Stack Overflow .
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