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Tahir-yamin

legacy-circuit-mockups

by @Tahir-yamin in AI & LLM
4
1
# Install this skill:
npx skills add Tahir-yamin/dev-engineering-playbook --skill "legacy-circuit-mockups"

Install specific skill from multi-skill repository

# Description

Generate breadboard circuit mockups and visual diagrams using HTML5 Canvas drawing techniques. Use when asked to create circuit layouts, visualize electronic component placements, draw breadboard diagrams, mockup 6502 builds, generate retro computer schematics, or design vintage electronics projects. Supports 555 timers, W65C02S microprocessors, 28C256 EEPROMs, W65C22 VIA chips, 7400-series logic gates, LEDs, resistors, capacitors, switches, buttons, crystals, and wires.

# SKILL.md

name: legacy-circuit-mockups
description: 'Generate breadboard circuit mockups and visual diagrams using HTML5 Canvas drawing techniques. Use when asked to create circuit layouts, visualize electronic component placements, draw breadboard diagrams, mockup 6502 builds, generate retro computer schematics, or design vintage electronics projects. Supports 555 timers, W65C02S microprocessors, 28C256 EEPROMs, W65C22 VIA chips, 7400-series logic gates, LEDs, resistors, capacitors, switches, buttons, crystals, and wires.'

Legacy Circuit Mockups

A skill for creating breadboard circuit mockups and visual diagrams for retro computing and electronics projects. This skill leverages HTML5 Canvas drawing mechanisms to render interactive circuit layouts featuring vintage components like the 6502 microprocessor, 555 timer ICs, EEPROMs, and 7400-series logic gates.

When to Use This Skill

  • User asks to "create a breadboard layout" or "mockup a circuit"
  • User wants to visualize component placement on a breadboard
  • User needs a visual reference for building a 6502 computer
  • User asks to "draw a circuit" or "diagram electronics"
  • User wants to create educational electronics visuals
  • User mentions Ben Eater tutorials or retro computing projects
  • User asks to mockup 555 timer circuits or LED projects
  • User needs to visualize wire connections between components

Prerequisites

  • Understanding of component pinouts from bundled reference files
  • Knowledge of breadboard layout conventions (rows, columns, power rails)

Supported Components

Microprocessors & Memory

Component Pins Description
W65C02S 40-pin DIP 8-bit microprocessor with 16-bit address bus
28C256 28-pin DIP 32KB parallel EEPROM
W65C22 40-pin DIP Versatile Interface Adapter (VIA)
62256 28-pin DIP 32KB static RAM

Logic & Timer ICs

Component Pins Description
NE555 8-pin DIP Timer IC for timing and oscillation
7400 14-pin DIP Quad 2-input NAND gate
7402 14-pin DIP Quad 2-input NOR gate
7404 14-pin DIP Hex inverter (NOT gate)
7408 14-pin DIP Quad 2-input AND gate
7432 14-pin DIP Quad 2-input OR gate

Passive & Active Components

Component Description
LED Light emitting diode (various colors)
Resistor Current limiting (configurable values)
Capacitor Filtering and timing (ceramic/electrolytic)
Crystal Clock oscillator
Switch Toggle switch (latching)
Button Momentary push button
Potentiometer Variable resistor
Photoresistor Light-dependent resistor

Grid System

// Standard breadboard grid: 20px spacing
const gridSize = 20;
const cellX = Math.floor(x / gridSize) * gridSize;
const cellY = Math.floor(y / gridSize) * gridSize;

Component Rendering Pattern

// All components follow this structure:
{
  type: 'component-type',
  x: gridX,
  y: gridY,
  width: componentWidth,
  height: componentHeight,
  rotation: 0,  // 0, 90, 180, 270
  properties: { /* component-specific data */ }
}

Wire Connections

// Wire connection format:
{
  start: { x: startX, y: startY },
  end: { x: endX, y: endY },
  color: '#ff0000'  // Wire color coding
}

Step-by-Step Workflows

Creating a Basic LED Circuit Mockup

  1. Define breadboard dimensions and grid
  2. Place power rail connections (+5V and GND)
  3. Add LED component with anode/cathode orientation
  4. Place current-limiting resistor
  5. Draw wire connections between components
  6. Add labels and annotations

Creating a 555 Timer Circuit

  1. Place NE555 IC on breadboard (pins 1-4 left, 5-8 right)
  2. Connect pin 1 (GND) to ground rail
  3. Connect pin 8 (Vcc) to power rail
  4. Add timing resistors and capacitors
  5. Wire trigger and threshold connections
  6. Connect output to LED or other load

Creating a 6502 Microprocessor Layout

  1. Place W65C02S centered on breadboard
  2. Add 28C256 EEPROM for program storage
  3. Place W65C22 VIA for I/O
  4. Add 7400-series logic for address decoding
  5. Wire address bus (A0-A15)
  6. Wire data bus (D0-D7)
  7. Connect control signals (R/W, PHI2, RESB)
  8. Add reset button and clock crystal

Component Pinout Quick Reference

555 Timer (8-pin DIP)

Pin Name Function
1 GND Ground (0V)
2 TRIG Trigger (< 1/3 Vcc starts timing)
3 OUT Output (source/sink 200mA)
4 RESET Active-low reset
5 CTRL Control voltage (bypass with 10nF)
6 THR Threshold (> 2/3 Vcc resets)
7 DIS Discharge (open collector)
8 Vcc Supply (+4.5V to +16V)

W65C02S (40-pin DIP) - Key Pins

Pin Name Function
8 VDD Power supply
21 VSS Ground
37 PHI2 System clock input
40 RESB Active-low reset
34 RWB Read/Write signal
9-25 A0-A15 Address bus
26-33 D0-D7 Data bus

28C256 EEPROM (28-pin DIP) - Key Pins

Pin Name Function
14 GND Ground
28 VCC Power supply
20 CE Chip enable (active-low)
22 OE Output enable (active-low)
27 WE Write enable (active-low)
1-10, 21-26 A0-A14 Address inputs
11-19 I/O0-I/O7 Data bus

Formulas Reference

Resistor Calculations

  • Ohm's Law: V = I × R
  • LED Current: R = (Vcc - Vled) / Iled
  • Power: P = V × I = I² × R

555 Timer Formulas

Astable Mode:

  • Frequency: f = 1.44 / ((R1 + 2×R2) × C)
  • High time: t₁ = 0.693 × (R1 + R2) × C
  • Low time: t₂ = 0.693 × R2 × C
  • Duty cycle: D = (R1 + R2) / (R1 + 2×R2) × 100%

Monostable Mode:

  • Pulse width: T = 1.1 × R × C

Capacitor Calculations

  • Capacitive reactance: Xc = 1 / (2πfC)
  • Energy stored: E = ½ × C × V²

Color Coding Conventions

Wire Colors

Color Purpose
Red +5V / Power
Black Ground
Yellow Clock / Timing
Blue Address bus
Green Data bus
Orange Control signals
White General purpose

LED Colors

Color Forward Voltage
Red 1.8V - 2.2V
Green 2.0V - 2.2V
Yellow 2.0V - 2.2V
Blue 3.0V - 3.5V
White 3.0V - 3.5V

Build Examples

Build 1 — Single LED

Components: Red LED, 220Ω resistor, jumper wires, power source

Steps:

  1. Insert black jumper wire from power GND to row A5
  2. Insert red jumper wire from power +5V to row J5
  3. Place LED with cathode (short leg) in row aligned with GND
  4. Place 220Ω resistor between power and LED anode

Build 2 — 555 Astable Blinker

Components: NE555, LED, resistors (10kΩ, 100kΩ), capacitor (10µF)

Steps:

  1. Place 555 IC straddling center channel
  2. Connect pin 1 to GND, pin 8 to +5V
  3. Connect pin 4 to pin 8 (disable reset)
  4. Wire 10kΩ between pin 7 and +5V
  5. Wire 100kΩ between pins 6 and 7
  6. Wire 10µF between pin 6 and GND
  7. Connect pin 3 (output) to LED circuit

Troubleshooting

Issue Solution
LED doesn't light Check polarity (anode to +, cathode to -)
Circuit doesn't power Verify power rail connections
IC not working Check VCC and GND pin connections
555 not oscillating Verify threshold/trigger capacitor wiring
Microprocessor stuck Check RESB is HIGH after reset pulse

References

Detailed component specifications are available in the bundled reference files:

# Related Skills

# Supported AI Coding Agents

This skill is compatible with the SKILL.md standard and works with all major AI coding agents:

Amp 🚀 Antigravity 🤖 Claude Code 🦀 Clawdbot 📝 Codex ▶️ Cursor 🤖 Droid 💎 Gemini CLI 🐙 GitHub Copilot 🪿 Goose 📊 Kilo Code 🔧 Kiro CLI 💻 OpenCode 🦘 Roo Code 🌲 Trae 🏄 Windsurf

Learn more about the SKILL.md standard and how to use these skills with your preferred AI coding agent.