85 lines
3.6 KiB
Markdown
85 lines
3.6 KiB
Markdown
---
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title: "Canjectors — Chris's Custom CAN Bus Interconnect System"
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tags:
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- hardware
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- electrical
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- can-bus
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- 2890
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- custom
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type: hardware-spec
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owner: 2890
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status: active
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sources:
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- "https://swyftrobotics.com/products/swyft-cannect-wiring-system"
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---
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# Canjectors — Custom CAN Bus Interconnect System
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## Overview
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After experiencing **critical CAN bus failures** during competition, Chris designed the Canjector system as a robust interconnect solution for Team 2890's robot. Modeled after the SWYFT CANnect concept but with custom design work, Canjectors provide reliable CAN + power distribution at all critical connections.
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The design philosophy: prevent wiring failures from killing the robot mid-match.
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## Design Basis
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Chris studied the **SWYFT CANnect** system as inspiration:
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- Run CAN bus + 12V power over standardized cabling
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- Easy connector system (WAGO lever terminals)
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- Built-in CAN termination options
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- Robust form factor
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Canjectors go further with custom modifications for Team 2890's specific failure points.
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## Current Design: Middle Canjector
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The schematic shows the "middle" Canjector variant with:
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- **12V power** passthrough
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- **3 CAN connections** (RJ45 connectors)
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- **WAGO terminal blocks** for clean wiring (2601-1104 series)
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- **120Ω termination resistor** (R4) between CAN signal lines — switchable
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- **Power indicator LED** (green, 0603) with 470Ω current limiting resistor
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- **2-pin header** for additional configuration
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## Key Features
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- **Dual CAN paths** — each Canjector bridges multiple CAN segments
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- **Integrated termination** — 120Ω resistor switchable per segment
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- **Power LED** — visual confirmation that 12V is present
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- **RJ45 connectors** — industry standard, easy to cable, robust
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- **WAGO 2601 series** — tool-free, reliable terminal connections
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- **Designed in EasyEDA** — schematic dated 2026-04-09
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## Design Variants
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Chris designed three Canjector variants for different positions in the CAN bus topology:
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| Variant | Position | CAN Termination | Notes |
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|---------|----------|----------------|-------|
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| **Start** | Bus origin (PDH side) | No termination at this end | Upstream CAN connector from PDH |
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| **Middle** | Intermediate nodes | Switchable 120Ω | 3 CAN connections + 12V passthrough |
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| **End** | Bus terminus | Fixed 120Ω termination | Final node on the bus |
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## Files
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| File | Description |
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|------|-------------|
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| `canjector-schematic.png` | Middle Canjector — EasyEDA schematic |
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| `canjector-start-pcb.png` | Start variant — PCB layout (red solder mask) |
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| `sources/2890/canjectors.md` | Full documentation |
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## Connection to Training
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**For students:** CAN bus failures are among the most frustrating problems in FRC — a loose wire or failed connector kills the whole bus. The Canjector system teaches:
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- **Redundancy** — when one path fails, traffic routes around it
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- **Termination** — 120Ω at each end of the bus, switchable at intermediate nodes
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- **Visual debugging** — power LEDs let you confirm connectivity at a glance
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- **Modular design** — if one Canjector fails, replace it in minutes
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## Why This Matters
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Chris experienced critical CAN failures at competition. The Canjector system is a direct response — solving the failure mode with custom hardware instead of hoping the stock connectors hold. This is the kind of real-world engineering that separates good teams from great ones.
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## Notes for MrC
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This is a **confidence builder** for the training vault — it shows Chris's practical engineering under pressure. Good story for students: identify the problem, study existing solutions, design your own, build it, test it. The full engineering cycle, not just code. |