Hectometer to Mil/Thou Converter

What is a Mil?

A mil (also called thou) is a unit of length in the imperial measurement system equal to one thousandth of an inch. The mathematical definition is:

1 mil = 0.001 inch = 1/1000 inch = 25.4 micrometers (μm) = 0.0254 millimeters

The mil is not a metric unit and should not be confused with the millimeter (mm), despite similar-sounding names. This confusion is one of the most common measurement errors in international manufacturing:

• 1 mil (imperial) = 0.0254 mm = 25.4 μm
• 1 millimeter (metric) = 39.37 mils = 1,000 μm

The mil exists as a natural subdivision of the inch, providing a convenient decimal-based measurement for very small imperial dimensions without resorting to awkward fractions like 1/1000″.

Mil vs. Thou: Regional Terminology

The terms "mil" and "thou" are completely interchangeable and refer to the exact same measurement:

• Mil: Predominant in American English, technical documentation, industry standards (ASTM, ANSI), and scientific contexts. The name derives from Latin "mille" (thousand).
• Thou: Common in British English shop-floor terminology, machining, and colloquial engineering speech. It's an abbreviated form of "thousandth" (of an inch).

Example usage:

• American engineer: "The coating should be 5 mils thick."
• British machinist: "Machine this to within 2 thou tolerance."
• Both mean the same thing: 0.005″ and 0.002″ respectively.

Decimal Imperial vs. Fractional Imperial

The mil represents a decimal approach to imperial measurement, contrasting with the traditional fractional approach:

Fractional imperial (traditional):

• 1/2″, 1/4″, 1/8″, 1/16″, 1/32″, 1/64″
• Awkward for very small measurements
• Difficult to add/subtract without common denominators

Decimal imperial (mils/thousandths):

• 0.500″ (500 mils), 0.250″ (250 mils), 0.125″ (125 mils)
• Easy arithmetic: 5 mils + 3 mils = 8 mils
• Natural compatibility with digital calipers and micrometers

Engineering drawings often show both: 0.250″ (1/4″) for clarity, but critical tolerances are always specified in decimal thousandths: ±0.005″ (±5 mils), never ±1/200″.

Mils in Wire Gauge Systems

American Wire Gauge (AWG) uses diameter in mils as the basis for its numbering system, though the relationship is logarithmic rather than linear:

| AWG Size | Diameter (mils) | Diameter (mm) | Common Use | |----------|----------------|---------------|------------| | 0000 (4/0) | 460 mil | 11.7 mm | Heavy power cables | | 00 (2/0) | 365 mil | 9.3 mm | Welding cable | | 10 AWG | 102 mil | 2.6 mm | Household 30A circuits | | 14 AWG | 64 mil | 1.6 mm | Household 15A circuits | | 18 AWG | 40 mil | 1.0 mm | Lamp cords, doorbells | | 22 AWG | 25 mil | 0.64 mm | Solid hookup wire | | 30 AWG | 10 mil | 0.25 mm | Wire-wrap wire | | 40 AWG | 3 mil | 0.08 mm | Magnet wire (coils) |

The AWG system was established in the 1850s based on the number of times wire was drawn through reducing dies, with each gauge step representing approximately a 20% reduction in diameter (factor of √2 for cross-sectional area).

Ancient and Medieval Precision (Before 1700)

Before the Industrial Revolution, precision measurement was limited by available tools. Ancient civilizations measured small lengths using:

• Barleycorns: 1 inch = 3 barleycorns (still referenced in shoe sizing)
• Hair breadth: Approximately 1/48 of an inch (about 21 mils)
• Poppy seed: Medieval unit ≈ 1/72 inch (14 mils)

These natural standards were inconsistent but adequate for carpentry, masonry, and traditional crafts where tolerances of 1/16″ to 1/32″ were acceptable. Precision metalworking (locksmithing, clockmaking, weapon-smithing) relied on master craftsmen's skill and direct comparison to reference standards rather than numerical measurement.

The finest medieval measurements were in clock and instrument making, where tolerances approaching 1/100″ (10 mils) were occasionally achieved, but not reliably measured or documented.

Industrial Revolution and the Birth of Precision (1750-1850)

The transformation of manufacturing from craft to industry created an urgent need for precision measurement:

1775-1800: John Wilkinson's cylinder boring machine (1775) achieved tolerances within 1/20″ (50 mils) for steam engine cylinders—revolutionary at the time, enabling James Watt's efficient steam engines.

1800-1840: Interchangeable parts manufacturing emerged. Eli Whitney's 1798 contract to produce 10,000 muskets with interchangeable parts required consistent tolerances around 1/32″ (31 mils), though he struggled to achieve this consistently.

1840s: Joseph Whitworth revolutionized precision measurement:

• Invented the first practical micrometer (1840s), capable of measuring to 0.001″ (1 mil)
• Developed precision surface plates and scrapers
• Standardized screw threads with tolerances of a few thousandths
• Established the "thou" as the standard British precision unit

Whitworth's work meant that for the first time, machinists could reliably measure and verify work to within one thousandth of an inch, making the mil/thou a practical working unit rather than a theoretical ideal.

1850s: American System of Manufacturing (Colt, Robbins & Lawrence, Singer) adopted decimal measurements in thousandths for gauging and inspection, establishing "mils" in American technical vocabulary.

Standardization and Proliferation (1850-1920)

1860s-1880s: Development of precision measuring instruments:

• Vernier calipers graduated in thousandths
• Micrometer calipers (marketed by Brown & Sharpe from 1867)
• Dial indicators (from 1890s) showing 0.001″ divisions

1857: American Wire Gauge (AWG) standardized by J. R. Brown, using wire diameter in mils as the basis.

1880s-1900s: Paint and coating industries adopted mils for dry film thickness:

• Paint manufacturers specified coverage rates based on mils of dry film
• Wet film thickness gauges calibrated in mils
• Quality standards (e.g., U.S. Navy specifications) required minimum coating thickness in mils

1900-1920: Sheet metal gauges proliferated (ironically, these use arbitrary numbering systems, but actual thickness is specified in decimal inches/mils):

• Manufacturer's Standard Gauge (MSG) for steel
• Birmingham Wire Gauge (BWG)
• Confusion from multiple gauge systems led to increasing use of direct mil specifications

1916: SAE (Society of Automotive Engineers) founded, establishing thousands of specifications with tolerances in thousandths of an inch for automotive parts.

Electronics Age and Micro-Precision (1920-1980)

1930s-1940s: Electronics manufacturing adopted mils for:

• Wire insulation thickness (enamel on magnet wire: 0.5-2 mils)
• Capacitor dielectric thickness
• Vacuum tube electrode spacing

1943: Printed Circuit Board (PCB) invention (Paul Eisler, 1943; mass production 1950s):

• Copper foil thickness: 1.4 mils (1 oz/ft²), 2.8 mils (2 oz/ft²)
• Trace width: typically 5-15 mils for signal traces
• Spacing between traces: 5-8 mils minimum in early designs
• PCB substrate thickness: 62 mils (1.57 mm) became standard

1950s-1960s: Plastic film industry standardized thickness in mils:

• Polyethylene film (bags, wrap): 0.5-6 mils
• Polyester film (Mylar): 0.5-10 mils
• Vinyl flooring underlayment: 6-20 mils

1960s: Integrated circuit (IC) manufacturing pushed precision far beyond mils:

• Early transistors: features measured in tens of mils
• By 1970: features approaching 100 microinches (0.1 mil)
• The mil remained relevant for IC package dimensions, lead spacing, and encapsulation thickness

1975: ANSI/ASTM standards codified mil-based specifications for coating thickness, plastic film, and adhesive tape across dozens of industries.

Modern Era and Metrication Resistance (1980-Present)

1980s-1990s: Global metrication movement:

• Britain officially metricated in 1965-1995, but "thou" persisted in machine shops
• U.S. industries largely resisted metrication in favor of established decimal-inch (mil) systems
• Aerospace, defense, and automotive industries retained imperial specs due to:
  • Enormous legacy of existing designs, tooling, and parts libraries
  • Cost of converting decades of technical documentation
  • Risk of conversion errors (Mars Climate Orbiter lost in 1999 due to metric/imperial confusion)

1990s-2000s: PCB design and microelectronics:

• PCB CAD software (OrCAD, Altium, Eagle) defaulted to mil grid spacing (5 mil, 10 mil, 25 mil grids)
• Modern PCB fabrication: 3-4 mil traces/spaces achievable in standard processes
• Advanced processes: sub-mil features (0.5 mil), but package and board dimensions still in mils

2000s-Present: Hybrid metric/imperial usage:

• American manufacturing: Part dimensions often in inches/mils, tolerances in mils
• International suppliers: Provide both metric and mil equivalents
• 3D printing: Software often accepts both (mil settings for layer height, nozzle diameter)
• Coating industry: Paint thickness gauges typically show both mils and microns

Present day: The mil remains dominant in:

• American PCB and electronics manufacturing
• U.S. aerospace and defense (military specifications)
• Coating and painting (ASTM standards)
• Plastic film and flexible packaging
• American Wire Gauge system
• Machining tolerances in U.S. shops

1. Precision Manufacturing and Machining

The mil is the fundamental tolerance unit in American manufacturing:

Engineering drawings and blueprints:

• Nominal dimensions in decimal inches: 1.250″, 0.375″
• Tolerances in thousandths: ±0.005″ (±5 mils), ±0.002″ (±2 mils)
• Geometric dimensioning and tolerancing (GD&T): Position tolerance ⌖ 0.010″ (10 mils)

Quality control and inspection:

• Calipers and micrometers graduated in 0.001″ (1 mil) divisions
• Dial indicators show 0.001″ or 0.0001″ (0.1 mil) graduations
• Coordinate measuring machines (CMM) measure to ±0.1 mil or better
• Pass/fail gauges: "Go" and "No-Go" plugs/rings differ by a few mils

Real-world tolerances by industry:

• General fabrication: ±5-10 mils (±0.005-0.010″)
• Automotive production: ±2-5 mils typical
• Aerospace critical parts: ±0.5-2 mils
• Medical implants (hip, knee): ±0.2-1 mil
• Semiconductor equipment: ±0.1 mil (±100 microinches)

Example: A shaft specified as Ø 1.000″ ± 0.002″ must measure between 0.998″ and 1.002″ (within ±2 mils). A shaft measuring 1.003″ (3 mils over) would be rejected.

2. Coating Thickness Measurement

Paint, plating, and protective coating thickness is universally measured in mils in American industry:

Paint inspection (wet film thickness gauges):

• Notch gauges (comb-style): Teeth graduated in mils (2, 4, 6, 8, 10 mils)
• Painter inserts gauge into wet paint; highest clean tooth indicates thickness
• Ensures proper coverage to meet specification (e.g., "apply to 6 mils wet film")

Dry film thickness (DFT) measurement:

• Magnetic gauges (ferrous substrates): Reed sensor or Hall effect, calibrated in mils
• Eddy current gauges (non-ferrous): For aluminum, brass, copper substrates
• Ultrasonic gauges: For non-metallic coatings on any substrate

Industry specifications:

• SSPC-PA 2 (paint inspection): Requires DFT measurement in mils
• U.S. Navy painting specs: Minimum DFT requirements (e.g., 5-7 mils for topcoat)
• Automotive OEM specs: Total paint system 4-6 mils
• Industrial maintenance coatings: Often 8-15 mils for severe environments

Example: A steel bridge specification might require: "Apply epoxy primer to 5-8 mils DFT, followed by polyurethane topcoat to 3-5 mils DFT." Inspectors measure at multiple points; any reading below minimum triggers rework.

Galvanizing and plating:

• Hot-dip galvanizing: ASTM A123 requires minimum 2.0 mils (for <1/4″ thick steel)
• Chrome plating: 0.5-1 mil decorative, 8-10 mils hard chrome (wear resistance)
• Anodizing (aluminum): Type II = 0.2-0.7 mils, Type III (hard anodize) = 2-4 mils

3. Plastic Film and Flexible Packaging

Plastic film thickness is specified in mils in the U.S. packaging industry:

Food packaging films:

• Shrink wrap: 2-4 mils (60-100 μm)
• Stretch wrap (pallet wrap): 12-20 gauge = 0.5-0.8 mil (gauge ≠ mils, confusingly)
• Vacuum seal bags (FoodSaver): 3-4 mils
• Frozen food bags: 2-3 mils
• Thicker film = better puncture resistance, higher material cost

Construction and industrial films:

• Vapor barriers (under-slab): 6-10 mils required by building codes
• Construction tarps: 5-12 mils depending on duty
• Agricultural greenhouse film: 4-6 mils (UV-stabilized)
• Geomembrane liners (landfills, ponds): 20-100 mils

Adhesive tapes:

• Scotch tape (Transparent): 1-1.5 mils
• Masking tape: 5-7 mils total thickness
• Duct tape: 10-12 mils
• Double-sided foam tape: 30-60 mils
• Specification includes backing + adhesive thickness

Industry standards:

• ASTM D6988: Standard specification for polyethylene film (thickness in mils)
• ASTM D374: Method for measuring tape thickness (to 0.1 mil)

Example: A customer ordering "6-mil poly sheeting" for a concrete vapor barrier receives polyethylene film exactly 0.006″ (6 mils = 0.15 mm) thick, ensuring compliance with IRC building code.

4. Electronics and Printed Circuit Boards

PCB design and manufacturing is dominated by mil-based dimensions in the United States:

PCB design software (Altium, Eagle, KiCAD, OrCAD):

• Default grid spacing: 50 mils, 25 mils, 10 mils, 5 mils, 1 mil
• Component libraries use 100-mil pin spacing for through-hole parts
• Trace width and clearance rules specified in mils

Design rules and capabilities:

• Standard PCB fabrication (budget services):
  • Minimum trace width: 6 mils
  • Minimum spacing: 6 mils
  • Via drill: 8-10 mils
  • Copper weight: 1 oz (1.4 mils)
• Advanced PCB fabrication:
  • Minimum trace/space: 3 mil / 3 mil
  • Microvias: 4-6 mil drill
  • HDI (high-density interconnect): sub-mil features

Copper thickness selection:

• 1 oz copper (1.4 mils): Standard for signal layers, adequate for currents <3A
• 2 oz copper (2.8 mils): Power planes, higher current capacity (5-10A per trace)
• 3-4 oz copper (4.2-5.6 mils): Power electronics, automotive
• Current-carrying capacity increases with thickness (more copper = less resistance = less heat)

PCB stackup (multilayer boards):

• 4-layer board example:
  • Top copper: 1.4 mils (1 oz)
  • Prepreg: 7 mils
  • Inner layer 1 (ground): 1.4 mils
  • Core: 47 mils
  • Inner layer 2 (power): 1.4 mils
  • Prepreg: 7 mils
  • Bottom copper: 1.4 mils
  • Total: 67 mils (1.7 mm)

Soldermask and silkscreen:

• Soldermask (green coating): 0.8-1.2 mils thickness
• Silkscreen (white text): 0.5-1 mil
• Surface finish (ENIG gold): 1-2 microinches (0.001-0.002 mil)

5. Wire Gauge and Cable Manufacturing

American Wire Gauge (AWG) is fundamentally based on diameter in mils:

AWG diameter formula:

• Each gauge step represents approximately a 1.123× change in diameter (10 steps = 1 decade = 10× area change)
• AWG 10 = 102 mils diameter
• AWG 20 = 32 mils diameter
• AWG 30 = 10 mils diameter

Wire insulation thickness (in mils over conductor diameter):

• Thin-wall insulation: 4-8 mils
• Standard insulation: 15-30 mils
• High-voltage insulation: 30-60+ mils
• Specification: "22 AWG with 10 mil insulation" = 25 mil conductor + 20 mil insulation total = 45 mil overall diameter

Magnet wire (enameled copper for motors, transformers):

• AWG 28-40 common for small coils
• Enamel coating: 0.5-2 mils depending on temperature rating
• Grade 1 (thinnest): 0.5-0.8 mil enamel
• Grade 2 (standard): 1-1.5 mil enamel
• Grade 3 (heavy build): 2-3 mil enamel
• Thicker enamel = better insulation, lower packing density in coil

Cable jacket thickness:

• Ethernet Cat6 cable jacket: 20-30 mils
• Power cord (SJOOW): 60-80 mils
• Mining cable: 125-250 mils (extreme abrasion resistance)

6. Sheet Metal and Gauge Systems

Sheet metal thickness is specified in gauge numbers, but actual thickness is in decimal inches (mils):

Manufacturer's Standard Gauge (steel):

• 10-gauge = 135 mils (0.1345″)
• 14-gauge = 75 mils (0.0747″)
• 20-gauge = 36 mils (0.0359″)
• 24-gauge = 24 mils (0.0239″)

Confusion and standardization issues:

• Gauge numbers are not universal: steel gauge ≠ aluminum gauge ≠ galvanized gauge
• Modern practice: Always specify in decimal inches (mils) to avoid ambiguity
• Example: "0.060″ aluminum" (60 mils) instead of "14-gauge aluminum"

HVAC ductwork:

• Residential ducts: 24-26 gauge (18-30 mils)
• Commercial ducts: 20-22 gauge (33-42 mils)
• Galvanized coating adds 2-5 mils to thickness

Automotive body panels:

• Hood outer skin: 28-30 mils (0.7-0.8 mm)
• Door outer skin: 26-28 mils
• Roof panel: 28-32 mils
• Frame rails: 90-120 mils (2.3-3.0 mm)

7. Quality Control and Standards Compliance

Mil-based specifications appear in thousands of ASTM, ANSI, SAE, and military standards:

ASTM coating standards:

• ASTM D3359: Adhesion of coatings (measured after cutting through coating, thickness in mils)
• ASTM D1186: Paint film thickness (magnetic gauges calibrated in mils)
• ASTM D6132: Nondestructive measurement of dry film thickness (mils)

Military specifications (MIL-SPEC):

• MIL-DTL-53030: Primer coating, epoxy, 2-3 mils DFT
• MIL-PRF-85285: Coating, polyurethane, aircraft, 1.5-2.5 mils
• Compliance requires thickness measurement at specified intervals

Building codes and construction:

• International Residential Code (IRC): Vapor retarders minimum 6 mils
• Roofing underlayment: Minimum thickness specifications in mils
• Window film (safety/security): 4-14 mils for various protection levels

Automotive and aerospace:

• SAE J1960: Brake hose specifications (wall thickness in inches/mils)
• AS9100 (aerospace quality): Dimensional inspections recorded in mils
• Engine bearing clearances: Specified in mils (e.g., 1.5-2.5 mils for main bearings)