This is a strong concept for a Marine Onboard Digital Control Panel, but it is too broad to safely start the schematic without a few key system choices.
I’d break it into these major blocks:
Main controller
Touchscreen or button/display control panel
MCU or embedded Linux module
Firmware update/debug interface
DC load control
Lighting outputs
Pump outputs
Fused/monitored high-current 12 V or 24 V channels
Manual override/failsafe options
Battery management
House battery voltage/current monitoring
Start battery voltage/current monitoring
Low-voltage disconnect logic
Alternator/generator/shore/solar awareness if needed
Solar input
Solar voltage/current sensing
MPPT/charge-controller interface, or integrated charge control if desired
Tank levels
Fresh water, black water, fuel, etc.
Need to know sensor type: resistive sender, capacitive, ultrasonic, pressure, NMEA 2000, etc.
Generator input
Start/stop control?
Runtime/status monitoring?
AC voltage/frequency sensing?
Safety interlocks required
Weather and wind
Barometer
Temperature/humidity
Wind speed/direction input
Optional GPS/NMEA 0183/NMEA 2000 integration
Marine communications
CAN/NMEA 2000 is likely the best long-term backbone
Optional Wi-Fi/Bluetooth/app interface
Optional RS-485/NMEA 0183
Before I design the schematic, I need these decisions:
Is the boat electrical system 12 V, 24 V, or both?
Maximum current per output channel for lights and pumps?
How many controlled outputs do you want?
Do you want a touchscreen, physical switches, or both?
Should this integrate with NMEA 2000, or be standalone?
What battery chemistry: lead-acid, AGM, lithium/LiFePO4?
Do you want this board to directly control high-current loads, or drive external relays/solid-state modules?
Is this for a prototype or something you intend to install permanently on a boat?
Recommended first architecture: 12/24 V marine input → protected power module → MCU control board → CAN/NMEA interface → isolated/ protected load driver outputs → sensor inputs → display/user interface.
Confirm those answers and I’ll turn this into a proper project specification, rename the project appropriately, and start the schematic architecture.
Wirelessly connects nets on schematic. Used to organize schematics and separate functional blocks. To wirelessly connect net portals, give them same designator. #portal
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