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Ken to Micrometer Converter

Convert ken to micrometers with our free online length converter.

Quick Answer

1 Ken = 1818000 micrometers

Formula: Ken × conversion factor = Micrometer

Use the calculator below for instant, accurate conversions.

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All conversion formulas on UnitsConverter.io have been verified against NIST (National Institute of Standards and Technology) guidelines and international SI standards. Our calculations are accurate to 10 decimal places for standard conversions and use arbitrary precision arithmetic for astronomical units.

Last verified: December 2025Reviewed by: Sam Mathew, Software Engineer

Ken to Micrometer Calculator

How to Use the Ken to Micrometer Calculator:

  1. Enter the value you want to convert in the 'From' field (Ken).
  2. The converted value in Micrometer will appear automatically in the 'To' field.
  3. Use the dropdown menus to select different units within the Length category.
  4. Click the swap button (⇌) to reverse the conversion direction.
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How to Convert Ken to Micrometer: Step-by-Step Guide

Converting Ken to Micrometer involves multiplying the value by a specific conversion factor, as shown in the formula below.

Formula:

1 Ken = 1.8180e+6 micrometers

Example Calculation:

Convert 10 ken: 10 × 1.8180e+6 = 1.8180e+7 micrometers

Disclaimer: For Reference Only

These conversion results are provided for informational purposes only. While we strive for accuracy, we make no guarantees regarding the precision of these results, especially for conversions involving extremely large or small numbers which may be subject to the inherent limitations of standard computer floating-point arithmetic.

Not for professional use. Results should be verified before use in any critical application. View our Terms of Service for more information.

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What is a Ken and a Micrometer?

The Ken (間) is a traditional Japanese unit of length, primarily used in architecture and related fields. It is fundamentally defined as being equal to 6 Shaku (尺). Based on the modern standardized kanejaku Shaku (10/33 meters), the Ken is equivalent to:

  • 6 * (10/33) = 60/33 = 20/11 meters
  • Approximately 1.818 meters
  • Approximately 5.965 feet

Historically, the Ken represented the interval between pillars in traditional Japanese buildings and served as a fundamental module for architectural design, influencing room sizes and the dimensions of elements like tatami mats.

A micrometer is a unit of length in the metric system equal to one millionth (1/1,000,000) of a meter. The term derives from the Greek "mikros" (small) and "metron" (measure). It is abbreviated as μm, where μ (mu) is the Greek letter representing the prefix "micro-."

Note on terminology: While "micron" was widely used from 1879 to 1967, it was officially deprecated by the International System of Units (SI) in favor of "micrometer" to maintain consistent naming conventions. However, "micron" remains common in some industries, particularly semiconductor manufacturing and filtration.

The micrometer sits between the millimeter and nanometer on the metric scale:

  • 1 meter = 1,000,000 micrometers
  • 1 millimeter = 1,000 micrometers
  • 1 micrometer = 1,000 nanometers

This scale makes micrometers perfect for measuring objects visible under optical microscopes but invisible to the naked eye.

Convert Micrometers to Other Units →

Note: The Ken is part of the imperial/US customary system, primarily used in the US, UK, and Canada for everyday measurements. The Micrometer belongs to the metric (SI) system.

History of the Ken and Micrometer

The concept of the Ken, like the Shaku, originated from Chinese architectural practices (where the equivalent unit is Jian 間). It was adopted into Japan along with other elements of Chinese culture and measurement systems.

  • Early Use: The Ken was used early on as a standard interval in temple and palace construction. Its length, however, was not strictly fixed and could vary based on the specific building style, region, or period. It was often tied directly to the prevailing length of the Shaku.
  • Standardization Attempts: Over time, particularly during the Edo period (1603–1868), attempts were made to standardize measurements. The Ken became strongly associated with architectural modules. Two prominent regional standards emerged:
    • Kyōma (京間): The Kyoto module, typically based on a slightly larger Ken (often around 6.5 Shaku or based on tatami dimensions), leading to larger room sizes.
    • Inakama (田舎間) / Edoma (江戸間): The rural or Edo (Tokyo) module, typically adhering more closely to the 6 Shaku standard or sometimes slightly smaller (e.g., 6.3 Shaku), resulting in slightly smaller rooms. This became more common.
  • Meiji Restoration (1868 onwards): With the standardization of the Shaku at 10/33 meters in 1891, the Ken was implicitly standardized as 6 Shaku = 20/11 meters (approx. 1.818 m). This is the value generally understood as the modern Ken.
  • Metrication: Although Japan officially adopted the metric system, the Ken remains a crucial unit in traditional architecture and related fields.

The concept of the micrometer emerged alongside the development of precision microscopy in the 17th and 18th centuries. As scientists like Robert Hooke and Antonie van Leeuwenhoek observed cells and microorganisms for the first time, they needed standardized ways to describe these microscopic dimensions.

The term "micron" (μ) was officially adopted at the First International Electrical Congress in Paris in 1879 as a convenient shorthand for one millionth of a meter. This simplified notation became widely used in scientific literature, particularly in biology, materials science, and optics.

In 1960, the International System of Units (SI) was established to create consistent naming conventions across all units. By 1967-1968, the SI officially deprecated "micron" in favor of "micrometer" to align with the systematic naming structure where prefixes like "micro-," "nano-," and "kilo-" are clearly indicated.

Despite this official change, the term "micron" persists in several industries:

  • Semiconductor manufacturing: Process nodes like "5-micron technology"
  • Filtration systems: "10-micron water filter"
  • Materials science: Particle size specifications
  • Aerospace: Surface finish requirements

The symbol μm is universally recognized in scientific and technical documentation, combining the Greek letter μ (representing the micro- prefix meaning 10⁻⁶) with m for meter.

Today, micrometers are fundamental to numerous high-precision fields, from medical diagnostics and semiconductor fabrication to quality control and environmental monitoring.

Common Uses and Applications: ken vs micrometers

Explore the typical applications for both Ken (imperial/US) and Micrometer (metric) to understand their common contexts.

Common Uses for ken

The Ken's primary importance lies in its role as an architectural module:

  • Traditional Japanese Architecture: It defines the standard bay (pillar-to-pillar distance) in the ken module system (kenshin system 間真). This dictates the layout and proportions of temples, shrines, traditional houses (minka), teahouses, and castles. Room sizes are often described in terms of tatami mats, whose standard dimensions (historically 1 Ken by 0.5 Ken) are derived from the Ken.
  • Construction and Carpentry: Used for planning layouts, cutting timber, and sizing building components like fusuma (sliding doors) and shōji (screens).
  • Real Estate and Land: Room sizes in Japan are often measured by the number of tatami mats they can hold (e.g., a "6-mat room" - 六畳 rokujō), which indirectly relates to the Ken. Historically, it was also used for land parcel dimensions.
  • Martial Arts: The concept of distance or interval (maai 間合い) between opponents is crucial and sometimes measured or conceptualized in terms of Ken. The length of certain weapons, like the (staff), is often around 1 Ken (6 Shaku).
  • Traditional Garden Design: Used for establishing proportions and spacing elements within Japanese gardens.
  • Cultural and Historical Context: Understanding the Ken is essential for interpreting historical architectural plans, documents, and cultural descriptions of space.

When to Use micrometers

1. Microscopy and Biology

Micrometers are the standard unit for measuring cells, bacteria, and other microorganisms under optical microscopes. Lab technicians and researchers use calibrated eyepiece scales marked in micrometers to measure biological specimens. Cell biology, microbiology, and histology all depend on micrometer measurements for specimen identification and analysis.

Convert for Biology Labs →

2. Semiconductor Manufacturing

The semiconductor industry uses micrometers (often called "microns") to specify process node sizes, though modern chips have moved to nanometer scales. Wafer thickness (typically 725 μm for 300mm wafers), photoresist layers, and older chip features are measured in micrometers. Quality control requires precise measurements to ensure manufacturing tolerances.

Convert Chip Dimensions →

3. Precision Engineering

Manufacturing engineers specify tolerances in micrometers for high-precision components. CNC machining, grinding, and polishing operations achieve accuracies of ±1-10 μm. Measuring instruments like micrometers (the tool) can measure to 0.001 mm = 1 μm precision. Critical aerospace, medical device, and automotive components require micrometer-level quality control.

Convert Tolerances →

4. Fiber Optics and Telecommunications

Fiber optic cables have core diameters measured in micrometers: single-mode fibers typically use 8-10 μm cores, while multi-mode fibers range from 50-62.5 μm. The precise core diameter determines light transmission characteristics, bandwidth, and distance capabilities. Telecom technicians reference these specifications when installing and troubleshooting fiber networks.

Calculate Fiber Specs →

5. Filtration and Air Quality

Filter manufacturers rate products by the size of particles they capture, measured in micrometers. HEPA filters capture 99.97% of particles ≥0.3 μm. Water filters, air purifiers, and industrial filtration systems all use micrometer ratings. Environmental agencies track PM2.5 (particulate matter <2.5 μm) and PM10 pollution, which pose respiratory health risks.

Convert Filter Ratings →

6. Medical Diagnostics

Medical laboratories measure blood cells in micrometers: red blood cells average 6-8 μm, while variations may indicate conditions like anemia. Pathologists examine tissue samples and tumor margins at micrometer scale. Medical device manufacturing (catheters, needles, implants) requires micrometer-precision specifications for safety and efficacy.

Convert Medical Measurements →

7. Surface Finish and Coatings

Surface roughness is measured in micrometers using parameters like Ra (average roughness). A mirror finish might be <0.1 μm Ra, while machined surfaces range from 0.8-25 μm Ra. Coating thickness—paint, anodizing, plating—is specified in micrometers to ensure corrosion protection and aesthetic quality.

Calculate Surface Specs →

Additional Unit Information

About Ken (ken)

How long is a Ken?

The modern standard Ken is defined as 6 Shaku. Using the standardized kanejaku Shaku (10/33 m):

  • 1 Ken = 20/11 meters
  • Approximately 1.818 meters
  • Approximately 181.8 centimeters
  • Approximately 5.965 feet
  • Approximately 71.58 inches Historical and regional variations (like the kyōma) existed, often resulting in slightly different lengths.

How does the Ken relate to the Shaku?

The Ken is a direct multiple of the Shaku:

  • 1 Ken = 6 Shaku

Is the Ken related to the Tatami mat?

Yes, very closely. The standard size of a tatami mat was traditionally defined in relation to the Ken, typically 1 Ken long by 0.5 Ken wide (though dimensions varied slightly with regional modules like kyōma and inakama). Room sizes are often measured by the number of tatami mats they contain.

Is the Ken an SI unit?

No, the Ken is not an SI unit. It is a traditional Japanese unit belonging to the Shakkanhō (尺貫法) system. The SI base unit for length is the meter (m).

Is the Ken still used today?

Yes. While the metric system is the official standard in Japan for commerce and science, the Ken remains highly relevant and actively used in:

  • Traditional Japanese architecture, design, and construction.
  • Carpentry and traditional crafts.
  • Real estate descriptions (indirectly via tatami count).
  • Martial arts contexts.
  • Cultural and historical studies.
  • Traditional garden design.

About Micrometer (μm)

Is a micrometer the same as a micron?

Yes, micrometer and micron refer to the same unit: one millionth of a meter (1×10⁻⁶ m or 1 μm). The term "micron" (symbol: μ) was officially used from 1879 to 1967 but was deprecated by the International System of Units (SI) in favor of "micrometer" to maintain consistent naming conventions.

Despite being officially deprecated, "micron" remains common in several industries:

  • Semiconductor manufacturing ("5-micron process")
  • Filtration ("10-micron filter")
  • Materials science (particle size specifications)

In scientific and technical writing, "micrometer" (μm) is the preferred term, but both are universally understood.

How many micrometers are in a millimeter?

There are 1,000 micrometers (μm) in 1 millimeter (mm). This makes sense when you consider the metric prefixes:

  • "Milli-" means one thousandth (1/1,000)
  • "Micro-" means one millionth (1/1,000,000)

Since a micrometer is 1,000 times smaller than a millimeter, dividing 1 mm into 1,000 equal parts gives you 1 μm per part.

Examples:

  • 0.5 mm = 500 μm
  • 0.1 mm = 100 μm
  • 0.075 mm = 75 μm (typical human hair)

Convert Millimeters to Micrometers →

What are some examples of things measured in micrometers?

Biological:

  • Bacteria: 1-10 μm (E. coli ≈ 2 μm)
  • Red blood cells: 6-8 μm
  • Human hair diameter: 50-100 μm
  • Pollen grains: 10-100 μm

Technology:

  • Fiber optic core: 8-62.5 μm (depending on type)
  • Semiconductor features: 0.01-10 μm (older processes)
  • Surface roughness: 0.1-25 μm (machining)

Materials:

  • Paint thickness: 25-100 μm
  • Plastic wrap: 10-15 μm
  • Paper thickness: 70-100 μm

Essentially, anything visible under an optical microscope but invisible to the naked eye is measured in micrometers.

Explore All Length Units →

How do I convert micrometers to inches?

To convert micrometers to inches, multiply by 0.00003937 (or divide by 25,400).

Formula: inches = micrometers × 0.00003937

Examples:

  • 100 μm × 0.00003937 = 0.003937 inches (≈ 0.004")
  • 1,000 μm × 0.00003937 = 0.03937 inches (≈ 0.04")
  • 2,540 μm × 0.00003937 = 0.1 inches

For context, 1 inch = 25,400 μm (or 25.4 mm), so micrometers are extremely small when expressed in imperial units.

Convert Micrometers to Inches →

Can the human eye see micrometers?

The human eye's resolution limit is approximately 50-100 micrometers under ideal conditions. This means:

Barely visible (with perfect vision):

  • Thick human hair: 100 μm
  • Fine sand grains: 100-500 μm
  • Large dust particles: 100+ μm

Invisible without magnification:

  • Bacteria: 1-10 μm
  • Red blood cells: 6-8 μm
  • Fine dust: <50 μm
  • Most microorganisms: <50 μm

To see objects smaller than ~50 μm, you need a microscope. Optical microscopes can resolve features down to about 0.2 μm (200 nm), while electron microscopes can see structures at the nanometer scale.

Compare Microscopic Scales →

What is the difference between micrometer and nanometer?

A micrometer (μm) equals one millionth of a meter (10⁻⁶ m), while a nanometer (nm) equals one billionth of a meter (10⁻⁹ m). This means 1 micrometer = 1,000 nanometers.

Scale comparison:

  • Micrometer scale: bacteria, cells, human hair (1-100 μm)
  • Nanometer scale: viruses, molecules, atoms (1-100 nm)

Examples:

  • Red blood cell: 7,000 nm = 7 μm
  • Coronavirus particle: 100 nm = 0.1 μm
  • DNA helix width: 2 nm = 0.002 μm
  • Silicon atom: 0.2 nm = 0.0002 μm

Optical microscopes work at the micrometer scale, while electron microscopes are needed for nanometer-scale imaging.

Convert Micrometers to Nanometers →

How accurate are micrometer measuring tools?

A micrometer (the measuring instrument, also called a "mike") typically measures with an accuracy of ±0.001 mm (±1 μm) for standard models, and ±0.0001 mm (±0.1 μm) for digital precision models.

Types and accuracy:

  • Standard mechanical: ±0.001 mm (±1 μm)
  • Vernier micrometer: ±0.001 mm (±1 μm)
  • Digital micrometer: ±0.0005-0.001 mm (±0.5-1 μm)
  • High-precision digital: ±0.0001 mm (±0.1 μm)

Accuracy depends on:

  • Tool quality and calibration
  • Temperature (thermal expansion affects readings)
  • Operator technique (proper force and reading)
  • Workpiece surface condition

For even higher precision, coordinate measuring machines (CMMs) and optical comparators can achieve sub-micrometer accuracy in controlled environments.

Compare Precision Units →

Why was "micron" deprecated?

The International System of Units (SI) deprecated "micron" in 1967-1968 to maintain consistent naming conventions across all metric units. The SI system uses standard prefixes (micro-, nano-, kilo-, etc.) combined with base units (meter, gram, second) to create derived units.

Reasons for change:

  • Consistency: "Micrometer" follows the pattern of millimeter, nanometer, kilometer
  • Clarity: Combines "micro-" (10⁻⁶) with "meter" to clearly indicate the scale
  • International standardization: Reduces confusion in scientific communication
  • Symbol standardization: μm is unambiguous, while μ alone could be confused with other uses

Why "micron" persists:

  • Shorter and easier to say ("micron" vs "micrometer")
  • Decades of industry usage before 1967
  • Well-established in semiconductor, filtration, and materials industries
  • No confusion in context (everyone knows what "10-micron filter" means)

In formal scientific writing, use "micrometer (μm)" for SI compliance.

What equipment measures in micrometers?

Precision measuring instruments:

  • Micrometer caliper (the tool): Measures dimensions to ±1 μm accuracy
  • Dial indicator: Measures displacement to ±1-5 μm
  • Coordinate Measuring Machine (CMM): Sub-micrometer accuracy
  • Optical comparator: Projects magnified image for micrometer-scale inspection
  • Laser interferometer: Measures to nanometer/sub-micrometer accuracy

Microscopy equipment:

  • Optical microscope: With calibrated eyepiece scales (reticles) marked in micrometers
  • Confocal microscope: 3D imaging with micrometer resolution
  • Scanning Electron Microscope (SEM): Nanometer resolution but calibrated in micrometers

Surface analysis:

  • Surface roughness tester (profilometer): Measures Ra, Rz in micrometers
  • Thickness gauge: Coating thickness to ±1 μm
  • Film thickness measurement: Non-contact optical methods

Quality control:

  • Particle size analyzers: Measure suspended particles in micrometers
  • Laser diffraction instruments: Characterize powders and emulsions

Convert Measurement Specs →

How is micrometer used in air quality standards?

Air quality standards use micrometers to classify particulate matter (PM) by size, which determines health impacts:

PM10 (Particulate Matter <10 μm):

  • Includes dust, pollen, mold
  • Can reach lungs but often trapped in nose/throat
  • EPA 24-hour standard: 150 μg/m³

PM2.5 (Particulate Matter <2.5 μm):

  • Includes combustion particles, smoke, fine dust
  • Small enough to enter deep into lungs and bloodstream
  • EPA 24-hour standard: 35 μg/m³
  • More dangerous than PM10 due to deep lung penetration

Why size matters:

  • >10 μm: Trapped in nose and throat
  • 2.5-10 μm: Can reach upper respiratory tract and lungs
  • <2.5 μm: Can penetrate deep into lungs and enter bloodstream
  • <0.1 μm (ultrafine): Can cross into organs and brain

Filter effectiveness:

  • HEPA filters: Capture 99.97% of particles ≥0.3 μm
  • N95 masks: Filter 95% of particles ≥0.3 μm
  • Standard HVAC filters: Typically 3-10 μm particle capture

Understanding micrometer-scale particle sizes is critical for respiratory health, especially for vulnerable populations.

Convert Air Quality Measurements →

Conversion Table: Ken to Micrometer

Ken (ken)Micrometer (μm)
0.5909,000
11,818,000
1.52,727,000
23,636,000
59,090,000
1018,180,000
2545,450,000
5090,900,000
100181,800,000
250454,500,000
500909,000,000
1,0001,818,000,000

People Also Ask

How do I convert Ken to Micrometer?

To convert Ken to Micrometer, enter the value in Ken in the calculator above. The conversion will happen automatically. Use our free online converter for instant and accurate results. You can also visit our length converter page to convert between other units in this category.

Learn more →

What is the conversion factor from Ken to Micrometer?

The conversion factor depends on the specific relationship between Ken and Micrometer. You can find the exact conversion formula and factor on this page. Our calculator handles all calculations automatically. See the conversion table above for common values.

Can I convert Micrometer back to Ken?

Yes! You can easily convert Micrometer back to Ken by using the swap button (⇌) in the calculator above, or by visiting our Micrometer to Ken converter page. You can also explore other length conversions on our category page.

Learn more →

What are common uses for Ken and Micrometer?

Ken and Micrometer are both standard units used in length measurements. They are commonly used in various applications including engineering, construction, cooking, and scientific research. Browse our length converter for more conversion options.

For more length conversion questions, visit our FAQ page or explore our conversion guides.

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Verified Against Authority Standards

All conversion formulas have been verified against international standards and authoritative sources to ensure maximum accuracy and reliability.

NIST Guide for the Use of SI

National Institute of Standards and TechnologyOfficial US standards for length measurements

SI Brochure

Bureau International des Poids et MesuresInternational System of Units official documentation

Last verified: December 3, 2025