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More formulas, added formula editor
2026-02-25 08:08:06 +00:00
# Formula and Unit File Format Guide
This document describes the format for contributing formulas and units to the d4rt_formulas project. It is intended for formula contributors and developers.
---
## Table of Contents
1. [Overview](#overview)
2. [Formula Files](#formula-files)
3. [Unit Files](#unit-files)
4. [Writing Descriptions](#writing-descriptions)
5. [Best Practices](#best-practices)
6. [Examples](#examples)
---
## Overview
The project uses two types of asset files:
| File Type | Location | Extension | Format |
|--------------|--------------------|---------------|---------------------------------|
| **Formulas** | `assets/formulas/` | `.d4rt` | Dart array literals (JSON-like) |
| **Units** | `assets/units/` | `.d4rt.units` | Dart array literals (JSON-like) |
Both formats use Dart set/array literals with map entries. Files are parsed at runtime to populate the formula calculator.
---
## Formula Files
### File Structure
Formula files are organized by topic (e.g., `geometry.d4rt`, `electromagnetism.d4rt`). Each file contains a Dart array literal with formula objects:
```dart
[
{
"name": "Formula Name",
"description": r"""Markdown description with LaTeX""",
"input": [
{"name": "variable1", "unit": "unit_name"},
{"name": "variable2", "unit": "unit_name"}
],
"output": {"name": "result", "unit": "unit_name"},
"d4rtCode": "result = expression;",
"tags": ["tag1", "tag2"]
},
// More formulas...
]
```
### Formula Object Fields
| Field | Type | Required | Description |
|---------------|--------|----------|------------------------------------------------------------------------------------------|
| `name` | String | Yes | Human-readable formula name |
| `description` | String | Yes | Markdown description with LaTeX math (see [Writing Descriptions](#writing-descriptions)) |
| `input` | Array | Yes | List of input variables with their units |
| `output` | Object | Yes | Output variable name and unit |
| `d4rtCode` | String | Yes | Dart code that computes the result |
| `tags` | Array | Yes | Categorization tags for search/filter |
### Input/Output Format
**Input variables:**
```dart
"input": [
{"name": "m", "unit": "kilogram"},
{"name": "a", "unit": "meters per square second"}
]
```
**Output variable:**
```dart
"output": {"name": "F", "unit": "newton"}
```
### Unit Names
Unit names must match entries in the `assets/units/` directory. Use the full unit name (lowercase), not the symbol:
| Correct | Incorrect |
|-----------------------|-----------|
| `"meter"` | `"m"` |
| `"kilogram"` | `"kg"` |
| `"meters per second"` | `"m/s"` |
| `"square meter"` | `"m²"` |
### Dart Code (`d4rtCode`)
The `d4rtCode` field contains valid Dart code that:
- Uses input variable names directly
- Assigns the result to the output variable name
- Can use Dart's `math` library functions (`sin`, `cos`, `sqrt`, `pow`, `pi`, etc.)
**Simple formula:**
```dart
"d4rtCode": "F = m * a;"
```
**Multi-line formula:**
```dart
"d4rtCode": """
var radians = angle * (pi / 180);
result = sin(radians);
"""
```
**With validation:**
```dart
"d4rtCode": """
if (a + b < c) {
signal("Invalid triangle: sides do not satisfy triangle inequality");
}
var s = (a + b + c) / 2;
A = sqrt(s * (s - a) * (s - b) * (s - c));
"""
```
---
## Unit Files
### File Structure
Unit files define units of measurement organized by category (e.g., `distance.d4rt.units`, `force.d4rt.units`). Each file contains a Dart array literal with unit objects:
```dart
[
{"name": "meter", "symbol": "m", "isBase": true},
{"name": "kilometer", "symbol": "km", "baseUnit": "meter", "factor": 1000},
// More units...
]
```
### Unit Object Fields
| Field | Type | Required | Description |
|------------|---------|-------------|---------------------------------------------------------------------|
| `name` | String | Yes | Full unit name (lowercase) |
| `symbol` | String | Yes | Unit symbol for display |
| `isBase` | Boolean | Conditional | `true` if this is a base unit (no conversion needed) |
| `baseUnit` | String | Conditional | Name of the base unit for conversion |
| `factor` | Number | Conditional | Multiplication factor to convert to base unit |
| `toBase` | String | Conditional | Expression/code to convert to base unit (for complex conversions) |
| `fromBase` | String | Conditional | Expression/code to convert from base unit (for complex conversions) |
### Base Units vs Derived Units
**Base units** define the reference for a category:
```dart
{"name": "meter", "symbol": "m", "isBase": true}
{"name": "newton", "symbol": "N", "isBase": true}
{"name": "joule", "symbol": "J", "isBase": true}
{"name": "Kelvin", "symbol": "K", "isBase": true}
```
**Derived units** specify conversion to their base unit. There are two types:
#### Simple Linear Conversions (using `factor`)
For units where conversion is a simple multiplication:
```dart
{"name": "kilometer", "symbol": "km", "baseUnit": "meter", "factor": 1000}
{"name": "inch", "symbol": "in", "baseUnit": "meter", "factor": 0.0254}
{"name": "pound-force", "baseUnit": "newton", "factor": 4.44822}
```
The `factor` converts **from** the defined unit **to** the base unit:
```dart
// 1 kilometer = 1000 meters
{"name": "kilometer", "baseUnit": "meter", "factor": 1000}
// 1 inch = 0.0254 meters
{"name": "inch", "baseUnit": "meter", "factor": 0.0254}
```
#### Complex Conversions (using `toBase` and `fromBase`)
For units requiring non-linear conversions (e.g., temperature scales), use `toBase` and `fromBase` expressions. The variable `x` represents the value to convert.
**Example: Celsius to Kelvin**
```dart
{
"name": "Celsius",
"symbol": "°C",
"baseUnit": "Kelvin",
"toBase": "x + 273.15", // °C → K
"fromBase": "x - 273.15", // K → °C
}
```
**Example: Fahrenheit to Kelvin**
```dart
{
"name": "Fahrenheit",
"symbol": "°F",
"baseUnit": "Kelvin",
"toBase": "(x - 32) * 5/9 + 273.15", // °F → K
"fromBase": "(x - 273.15) * 9/5 + 32", // K → °F
}
```
**Example: Multi-line conversion (Gas Mark to Kelvin)**
```dart
{
"name": "Gas Mark",
"symbol": "GM",
"baseUnit": "Kelvin",
"toBase": r"""
if (x < 1) {
double celsius = (243 - 25 * (log(1 / x) / log(2))) / 1.8;
return celsius + 273.15;
} else {
double celsius = x * 14 + 121;
return celsius + 273.15;
}
""",
"fromBase": """
double celsius = x - 273.15;
if (celsius < 135) {
return pow(2, (1.8 * celsius - 243) / 25);
} else {
return (celsius - 121) / 14;
}
"""
}
```
### Common Temperature Conversions
| Unit | toBase (→ K) | fromBase (← K) |
|------------|------------------------------|------------------------------|
| Celsius | `x + 273.15` | `x - 273.15` |
| Fahrenheit | `(x - 32) * 5/9 + 273.15` | `(x - 273.15) * 9/5 + 32` |
| Rankine | `x * 5/9` | `x * 9/5` |
| Réaumur | `x * 5/4 + 273.15` | `(x - 273.15) * 4/5` |
| Delisle | `373.15 - x * 2/3` | `(373.15 - x) * 3/2` |
| Rømer | `(x - 7.5) * 40/21 + 273.15` | `(x - 273.15) * 21/40 + 7.5` |
---
## Writing Descriptions
The `description` field uses **raw Dart string literals** (`r"""..."""`) with **Markdown** and **LaTeX** math.
### Format
```dart
"description": r"""
Short description of the formula.
$$F = m \cdot a$$
Where:
- $F$: Force (Newtons)
- $m$: Mass (kilograms)
- $a$: Acceleration (m/s²)
Additional context or notes.""",
```
### LaTeX Math
Use **MathJax/KaTeX** syntax for mathematical expressions:
| Type | Syntax | Example |
|---------------------|-----------------------------|--------------------------|
| Inline math | `$...$` | `$F = ma$` |
| Display math | `$$...$$` | `$$E = mc^2$$` |
| Fractions | `\frac{a}{b}` | `$$\frac{1}{2}mv^2$$` |
| Subscripts | `x_i` | `$v_0$` |
| Superscripts | `x^2` | `$a^2 + b^2$` |
| Greek letters | `\alpha`, `\beta`, `\theta` | `$$\sin(\theta)$$` |
| Special symbols | `\cdot`, `\times`, `\pm` | `$m \cdot a$` |
| Units in math | `\mathrm{m/s^2}` | `$9.81\ \mathrm{m/s^2}$` |
| Scientific notation | `\times 10^{-11}` | `$6.674\times 10^{-11}$` |
### Including Images
Add Wikipedia or other educational images using Markdown:
```markdown
![Description](https://upload.wikimedia.org/wikipedia/commons/...)
```
**Example:**
```dart
"description": r"""
Newton's law of universal gravitation.
$$F = G\frac{m_1m_2}{r^2}$$
![Gravitation Diagram](https://upload.wikimedia.org/wikipedia/commons/thumb/3/33/NewtonsLawOfUniversalGravitation.svg/1200px-NewtonsLawOfUniversalGravitation.svg.png)""",
```
### Description Structure
A well-structured description includes:
1. **Opening sentence** - Brief statement of what the formula calculates
2. **LaTeX formula** - The mathematical expression in display mode
3. **Variable definitions** - List of all variables with units
4. **Additional context** - Notes, assumptions, or applications
5. **Image** (optional) - Diagram or illustration
---
## Best Practices
### For Formulas
1. **Use clear variable names** - Single letters for physics conventions (`F`, `m`, `a`), descriptive names when clarity matters
2. **Match units precisely** - Ensure input/output units match what the formula expects
3. **Add validation** - Use `signal()` for invalid inputs (e.g., triangle inequality)
4. **Include tags** - Add relevant tags for discoverability
5. **Use LaTeX for all math** - Even simple formulas should have LaTeX representation
6. **Add images** - Include diagrams from Wikipedia when helpful
7. **Comment your code** - Use `//` comments before each formula object
### For Units
1. **Use lowercase names** - `"meter"` not `"Meter"`
2. **Include common conversions** - Add both metric and imperial units when relevant
3. **Use standard symbols** - Follow SI conventions where applicable
4. **Document the factor** - Ensure conversion factors are accurate
### For Descriptions
1. **Be concise but complete** - Explain what the formula does and what each variable means
2. **Use consistent formatting** - Follow the established pattern in existing files
3. **Include units in variable definitions** - Always specify units for each variable
4. **Add context** - Explain when/why the formula is used
5. **Note assumptions** - Mention any constraints or special conditions
---
## Examples
### Complete Formula Example
```dart
// Newton's Second Law
{
"name": "Newton's Second Law",
"description": r"""
Force equals mass times acceleration.
$$F = m \cdot a$$
Where:
- $m$: Mass of object ($\mathrm{kg}$)
- $a$: Acceleration ($\mathrm{m/s^2}$)
![Newton's Second Law](https://upload.wikimedia.org/wikipedia/commons/thumb/7/73/Newtonslawsofmotion.jpg/800px-Newtonslawsofmotion.jpg)""",
"input": [
{"name": "m", "unit": "kilogram"},
{"name": "a", "unit": "meters per square second"}
],
"output": {"name": "F", "unit": "newton"},
"d4rtCode": "F = m * a;",
"tags": ["physics", "mechanics", "newton"]
}
```
### Complete Unit Example
```dart
[
{
"name": "newton",
"symbol": "N",
"isBase": true
},
{
"name": "kilonewton",
"symbol": "kN",
"baseUnit": "newton",
"factor": 1000
},
{
"name": "pound-force",
"symbol": "lbf",
"baseUnit": "newton",
"factor": 4.44822
}
]
```
### Multi-line Dart Code Example
```dart
// Cosine Rule
{
"name": "Cosine Rule",
"description": r"""
Generalization of the Pythagorean theorem for any triangle.
$$c^2 = a^2 + b^2 - 2ab\cos(C)$$
Where:
- $a$, $b$, $c$: Sides of the triangle
- $C$: Angle opposite to side $c$""",
"input": [
{"name": "a", "unit": "meter"},
{"name": "b", "unit": "meter"},
{"name": "C", "unit": "degree"}
],
"output": {"name": "c", "unit": "meter"},
"d4rtCode": """
var angleCRad = C * (pi / 180);
c = sqrt(pow(a, 2) + pow(b, 2) - 2*a*b*cos(angleCRad));
""",
"tags": ["trigonometry", "triangle", "cosine"]
}
```
---
## File Organization
### Formula Categories
| File | Topic |
|----------------------------------|--------------------------------|
| `formulas.d4rt` | General physics formulas |
| `geometry.d4rt` | Geometric calculations |
| `electromagnetism.d4rt` | Electric and magnetic formulas |
| `energy_and_power.d4rt` | Energy, work, and power |
| `thermodynamics.d4rt` | Heat and thermodynamics |
| `fluids_and_pressure.d4rt` | Fluid mechanics |
| `optics.d4rt` | Light and optics |
| `trigonometry.d4rt` | Trigonometric relations |
| `materials_elasticity.d4rt` | Material properties |
| `medical_and_bio.d4rt` | Medical/biological formulas |
| `networking.d4rt` | Network calculations |
| `conversions_and_constants.d4rt` | Physical constants |
| `misc_math.d4rt` | Miscellaneous mathematics |
### Unit Categories
| File | Unit Type |
|--------------------------|------------------------|
| `distance.d4rt.units` | Length/distance |
| `mass.d4rt.units` | Mass |
| `time.d4rt.units` | Time |
| `force.d4rt.units` | Force |
| `energy.d4rt.units` | Energy |
| `power.d4rt.units` | Power |
| `pressure.d4rt.units` | Pressure |
| `velocity.d4rt.units` | Speed/velocity |
| `area.d4rt.units` | Area |
| `volume.d4rt.units` | Volume |
| `temperature.d4rt.units` | Temperature |
| `angle.d4rt.units` | Angles |
| `frequency.d4rt.units` | Frequency |
| `electricity.d4rt.units` | Electrical units |
| `derived.d4rt.units` | Derived/compound units |
---
## Quick Reference
### Common LaTeX Symbols
| Symbol | LaTeX | Symbol | LaTeX |
|--------|-----------|--------|----------|
| × | `\times` | · | `\cdot` |
| ± | `\pm` | ÷ | `\div` |
| ≤ | `\leq` | ≥ | `\geq` |
| √ | `\sqrt{}` | ∞ | `\infty` |
| π | `\pi` | θ | `\theta` |
| α | `\alpha` | β | `\beta` |
| Δ | `\Delta` | δ | `\delta` |
| Σ | `\Sigma` | σ | `\sigma` |
| Ω | `\Omega` | ω | `\omega` |
### Common Dart Math Functions
| Function | Description |
|---------------------------------|-----------------------------------|
| `sin(x)`, `cos(x)`, `tan(x)` | Trigonometric functions (radians) |
| `asin(x)`, `acos(x)`, `atan(x)` | Inverse trig functions |
| `sqrt(x)` | Square root |
| `pow(x, y)` | x raised to power y |
| `log(x)` | Natural logarithm |
| `log10(x)` | Base-10 logarithm |
| `abs(x)` | Absolute value |
| `exp(x)` | e raised to power x |
| `pi` | π constant |
---
## Contributing
1. **Choose the right file** - Add formulas to the appropriate category file
2. **Follow the format** - Match the structure of existing entries
3. **Test your code** - Ensure `d4rtCode` is valid Dart syntax
4. **Add description** - Include complete LaTeX documentation
5. **Tag appropriately** - Add relevant tags for searchability
6. **Review** - Check existing formulas for consistency
For questions or clarifications, refer to existing formulas in the `assets/formulas/` directory as examples.
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