Anthropometry(Redirected from Anthropometric)
Anthropometry (from Greek ἄνθρωπος anthropos, "human", and μέτρον metron, "measure") refers to the measurement of the human individual. An early tool of physical anthropology, it has been used for identification, for the purposes of understanding human physical variation, in paleoanthropology and in various attempts to correlate physical with racial and psychological traits. Anthropometry involves the systematic measurement of the physical properties of the human body, primarily dimensional descriptors of body size and shape.
Today, anthropometry plays an important role in industrial design, clothing design, ergonomics and architecture where statistical data about the distribution of body dimensions in the population are used to optimize products. Changes in lifestyles, nutrition, and ethnic composition of populations lead to changes in the distribution of body dimensions (e.g. the rise in obesity) and require regular updating of anthropometric data collections.
The history of anthropometry includes and spans various concepts, both scientific and pseudoscientific, such as craniometry, paleoanthropology, biological anthropology, phrenology, physiognomy, forensics, criminology, phylogeography, human origins, and cranio-facial description, as well as correlations between various anthropometrics and personal identity, mental typology, personality, cranial vault and brain size, and other factors.
At various times in history, applications of anthropometry have ranged vastly—from accurate scientific description and epidemiological analysis to rationales for eugenics and overtly racist social movements—and its points of concern have been numerous, diverse, and sometimes highly unexpected.
Human height varies greatly between individuals and across populations for a variety of complex biological, genetic, and environmental factors, among others. Due to methodological and practical problems, its measurement is also subject to considerable error in statistical sampling.
The average height in genetically and environmentally homogeneous populations is often proportional across a large number of individuals. Exceptional height variation (around 20% deviation from a population's average) within such a population is sometimes due to gigantism or dwarfism, which are caused by specific genes or endocrine abnormalities. It is important to note that a great degree of variation occurs between even the most 'common' bodies (66% of the population), and as such no person can be considered 'average'.
In the most extreme population comparisons, for example, the average female height in Bolivia is 142.2 cm (4 ft 8.0 in) while the average male height in the Dinaric Alps is 185.6 cm (6 ft 1.1 in), an average difference of 43.4 cm (1 ft 5.1 in). Similarly, the shortest and tallest of individuals, Chandra Bahadur Dangi and Robert Wadlow, have ranged from 1 ft 9 in (53 cm) to 8 ft 11.1 in (272 cm), respectively.
Human weight varies extensively both individually and across populations, with the most extreme documented examples of adults being Lucia Zarate who weighed 4.7 pounds (2.1 kg), and Jon Brower Minnoch who weighed 1,400 pounds (640 kg), and with population extremes ranging from 109.3 pounds (49.6 kg) in Bangladesh to 192.7 pounds (87.4 kg) in Micronesia.
Adult brain size varies from 974.9 cm3 (59.49 cu in) to 1,498.1 cm3 (91.42 cu in) in females and 1,052.9 cm3 (64.25 cu in) to 1,498.5 cm3 (91.44 cu in) in males, with the average being 1,130 cm3 (69 cu in) and 1,260 cm3 (77 cu in), respectively. The right cerebral hemisphere is typically larger than the left, whereas the cerebellar hemispheres are typically of more similar size.
Size of the human stomach varies significantly in adults, with one study showing volumes ranging from 520 cm3 (32 cu in) to 1,536 cm3 (93.7 cu in) and weights ranging from 77 grams (2.7 oz) to 453 grams (16.0 oz).
Human beauty and physical attractiveness have been preoccupations throughout history which often intersect with anthropometric standards. Cosmetology, facial symmetry, and waist–hip ratio are three such examples where measurements are commonly thought to be fundamental.
Anthropometric studies today are conducted to investigate the evolutionary significance of differences in body proportion between populations whose ancestors lived in different environments. Human populations exhibit climatic variation patterns similar to those of other large-bodied mammals, following Bergmann's rule, which states that individuals in cold climates will tend to be larger than ones in warm climates, and Allen's rule, which states that individuals in cold climates will tend to have shorter, stubbier limbs than those in warm climates.
On a microevolutionary level, anthropologists use anthropometric variation to reconstruct small-scale population history. For instance, John Relethford's studies of early 20th-century anthropometric data from Ireland show that the geographical patterning of body proportions still exhibits traces of the invasions by the English and Norse centuries ago.
Similarly, anthropometric indices, namely comparison of the human stature was used to illustrate anthropometric trends. This study was conducted by Jörg Baten and Sandew Hira and was based on the anthropological founds that human height is predetermined by the quality of the nutrition, which used to be higher in the more developed countries. The research was based on the datasets for Southern Chinese contract migrants who were sent to Suriname and Indonesia and included 13,000 individuals.
3D body scannersEdit
Today anthropometry can be performed with three-dimensional scanners. A global collaborative study to examine the uses of three-dimensional scanners for health care was launched in March 2007. The Body Benchmark Study will investigate the use of three-dimensional scanners to calculate volumes and segmental volumes of an individual body scan. The aim is to establish whether the Body Volume Index has the potential to be used as a long-term computer-based anthropometric measurement for health care. In 2001 the UK conducted the largest sizing survey to date using scanners. Since then several national surveys have followed in the UK's pioneering steps, notably SizeUSA, SizeMexico, and SizeThailand, the latter still ongoing. SizeUK showed that the nation had become taller and heavier but not as much as expected. Since 1951, when the last women's survey had taken place, the average weight for women had gone up from 62 to 65 kg. However, recent research has shown that posture of the participant significantly influences the measurements taken, the precision of 3D body scanner may or may not be high enough for industry tolerances, and measurements taken may or may not be relevant to all applications (e.g. garment construction). Despite these current limitations, 3D Body Scanning has been suggested as a replacement for body measurement prediction technologies which (despite the great appeal) have yet to be as reliable as real human data. 
Baropodographic devices fall into two main categories: (i) floor-based, and (ii) in-shoe. The underlying technology is diverse, ranging from piezoelectric sensor arrays to light refraction, but the ultimate form of the data generated by all modern technologies is either a 2D image or a 2D image time series of the pressures acting under the plantar surface of the foot. From these data other variables may be calculated (see data analysis.)
The spatial and temporal resolutions of the images generated by commercial pedobarographic systems range from approximately 3 to 10 mm and 25 to 500 Hz, respectively. Sensor technology limits finer resolution. Such resolutions yield a contact area of approximately 500 sensors (for a typical adult human foot with surface area of approximately 100 cm2). For a stance phase duration of approximately 0.6 seconds during normal walking, approximately 150,000 pressure values, depending on the hardware specifications, are recorded for each step.
Direct measurements involve examinations of brains from corpses, or more recently, imaging techniques such as MRI, which can be used on living persons. Such measurements are used in research on neuroscience and intelligence. Brain volume data and other craniometric data are used in mainstream science to compare modern-day animal species and to analyze the evolution of the human species in archeology.
Epidemiology and medical anthropologyEdit
Anthropometric measurements also have uses in epidemiology and medical anthropology, for example in helping to determine the relationship between various body measurements (height, weight, percentage body fat, etc.) and medical outcomes. Anthropometric measurements are frequently used to diagnose malnutrition in resource-poor clinical settings.
Forensics and criminologyEdit
Forensic anthropologists study the human skeleton in a legal setting. A forensic anthropologist can assist in the identification of a decedent through various skeletal analyses that produce a biological profile. Forensic anthropologists utilize the Fordisc program to help in the interpretation of craniofacial measurements in regards to ancestry or race determination.
One part of a biological profile is a person's racial or ancestral affinity. People with significant European or Middle Eastern ancestry generally have relatively no[clarification needed] prognathism; a relatively long and narrow face; a prominent brow ridge that protrudes forward from the forehead; a narrow, tear-shaped nasal cavity; a "silled" nasal aperture; tower-shaped nasal bones; a triangular-shaped palate; and an angular and sloping eye orbit shape. People with considerable African ancestry typically have a broad and round nasal cavity; no dam or nasal sill; Quonset hut-shaped nasal bones; notable facial projection in the jaw and mouth area (prognathism); a rectangular-shaped palate; and a square or rectangular eye orbit shape. A relatively small prognathism often characterizes people with considerable East Asian ancestry; no nasal sill or dam; an oval-shaped nasal cavity; tent-shaped nasal bones; a horseshoe-shaped palate; and a rounded and non-sloping eye orbit shape. Many of these characteristics are only a matter of frequency among particular races: their presence or absence of one or more does not automatically classify an individual into a racial group.
Today, ergonomics professionals apply an understanding of human factors to the design of equipment, systems and working methods to improve comfort, health, safety, and productivity. This includes physical ergonomics in relation to human anatomy, physiological and bio mechanical characteristics; cognitive ergonomics in relation to perception, memory, reasoning, motor response including human–computer interaction, mental workloads, decision making, skilled performance, human reliability, work stress, training, and user experiences; organizational ergonomics in relation to metrics of communication, crew resource management, work design, schedules, teamwork, participation, community, cooperative work, new work programs, virtual organizations, and telework; environmental ergonomics in relation to human metrics affected by climate, temperature, pressure, vibration, and light; visual ergonomics; and others.
Biometrics refers to the identification of humans by their characteristics or traits. Biometrics is used in computer science as a form of identification and access control. It is also used to identify individuals in groups that are under surveillance. Biometric identifiers are the distinctive, measurable characteristics used to label and describe individuals. Biometric identifiers are often categorized as physiological versus behavioral characteristics. Example applications include dermatoglyphics and soft biometrics.
United States military researchEdit
The US Military has conducted over 40 anthropometric surveys of U.S. Military personnel between 1945 and 1988, including the 1988 Army Anthropometric Survey (ANSUR) of men and women with its 240 measures. Statistical data from these surveys encompasses over 75,000 individuals.
Civilian American and European Surface Anthropometry Resource Project—CAESAREdit
CAESAR began in 1997 as a partnership between government and industry to collect and organize the most extensive sampling of consumer body measurements for comparison. The project collected and organized data on 2,400 U.S. & Canadian and 2,000 European civilians and a database was developed. This database records the anthropometric variability of men and women, aged 18–65, of various weights, ethnic groups, gender, geographic regions, and socio-economic status. The study was conducted from April 1998 to early 2000 and included three scans per person in a standing pose, full-coverage pose and relaxed seating pose. Data collection methods were standardized and documented so that the database can be consistently expanded and updated. High-resolution measurements of body surfaces were made using 3D Surface Anthropometry. This technology can capture hundreds of thousands of points in three dimensions on the human body surface in a few seconds. It has many advantages over the old measurement system using tape measures, anthropometers, and other similar instruments. It provides detail about the surface shape as well as 3D locations of measurements relative to each other and enables easy transfer to Computer-Aided Design (CAD) or Manufacturing (CAM) tools. The resulting scan is independent of the measurer, making it easier to standardize. Automatic landmark recognition (ALR) technology was used to extract anatomical landmarks from the 3D body scans automatically. Eighty landmarks were placed on each subject. More than 100 univariate measures were provided, over 60 from the scan and approximately 40 using traditional measurements. Demographic data such as age, ethnic group, gender, geographic region, education level, and present occupation, family income and more were also captured.
Scientists working for private companies and government agencies conduct anthropometric studies to determine a range of sizes for clothing and other items. Measurements of the foot are used in the manufacture and sale of footwear: measurement devices may be used either to determine a retail shoe size directly (e.g. the Brannock Device) or to determine the detailed dimensions of the foot for custom manufacture (e.g. ALINEr).
In popular cultureEdit
In art Yves Klein termed his performance paintings anthropometries, where he covered nude women with paint and used their bodies as paintbrushes.
- Anthropometric cosmetology
- Genetic fingerprinting
- Guidonian hand
- Digit ratio
- Human height
- Human weight
- Samuel George Morton
- Single transverse palmar crease
- Statistical shape analysis
- World Engineering Anthropometry Resource
- Md.[clarification needed] Ariful, Islam; Md.[clarification needed], Asadujjaman; Md.[clarification needed], Nuruzzaman; Md.[clarification needed] Mosharraf, Hossain. "Ergonomics Consideration for Hospital Bed Design: A Case Study in Bangladesh". Journal of Modern Science and Technology 01 (01): 30-44.
- Ganong, William F. (Lange Medical, 2001) Review of Medical Physiology (pp. 392-397)
- Gill, Simeon; Parker, Christopher J. (2014). "The True Height of the Waist: Explorations of Automated Body Scanner Waist Definitions of the TC2 scanner". Proc. of 5th Int. Conf. on 3D Body Scanning Technologies: 55–65. doi:10.15221/14.055. Retrieved 1 May 2018.
- Shortest man world record: It’s official! Chandra Bahadur Dangi is smallest adult of all time Guinness World Records
- "Tallest Man". Guinness World Records. March 19, 2010. Archived from the original on March 19, 2010. Retrieved 2010-03-19. at Wayback machine
- Chivers, Tom (2009-09-24). "Human extremes: the tallest, shortest, heaviest and lightest people ever". The Telegraph. Retrieved 2013-05-26.
- Quilty-Harper, Conrad; Andrew Blenkinsop; David Kinross; Dan Palmer (2012-06-21). "The world's fattest countries: how do you compare?". The Telegraph. Retrieved 2013-05-26.
- Cosgrove, KP; Mazure CM; Staley JK (2007). "Evolving Knowledge of Sex Differences in Brain Structure, Function and Chemistry". Biol Psychiatry. 62 (8): 847–55. doi:10.1016/j.biopsych.2007.03.001. PMC 2711771. PMID 17544382.
- Allen, JS; Damasio H; Grabowski TJ (2002). "Normal neuroanatomical variation in the human brain: An MRI-volumetric study". Am J Phys Anthropol. 118 (4): 341–58. doi:10.1002/ajpa.10092. PMID 12124914.
- Cox, Alvin J. (1945). "Variations in size of the human stomach" (PDF). California and Western Medicine. 63 (6): 267–268. PMC 1473711. PMID 18747178. Retrieved 2013-05-26.
- Wessells, H.; Lue, T. F.; McAninch, J. W. (1996). "Penile length in the flaccid and erect states: Guidelines for penile augmentation". The Journal of Urology. 156 (3): 995–997. doi:10.1016/S0022-5347(01)65682-9. PMID 8709382.
- Chen, J.; Gefen, A.; Greenstein, A.; Matzkin, H.; Elad, D. (2000). "Predicting penile size during erection". International Journal of Impotence Research. 12 (6): 328–333. doi:10.1038/sj.ijir.3900627. PMID 11416836.
- Morber, Jenny (2013-04-01). "The average human vagina". Double X Science. Retrieved 2013-05-26.
- Baten, Jörg (November 2008). "ANTHROPOMETRIC TRENDS IN SOUTHERN CHINA,1830–1864". Australian Economic History Review. Vol. 48 (No. 3).
- Gill, Simeon; Parker, Christopher J. "Scan posture definition and hip girth measurement: the impact on clothing design and body scanning". Ergonomics. 60 (8): 1123–1136. doi:10.1080/00140139.2016.1251621. Retrieved 30 April 2018.
- Parker, Christopher J.; GIll, Simeon; Hayes, Steven G. (2017). "3D Body Scanning has Suitable Reliability: An Anthropometric Investigation for Garment Construction". Proc. of 3DBODY.TECH 2017 - 8th Int. Conf. and Exh. on 3D Body Scanning and Processing Technologies: 298–305. doi:10.15221/17.298. Retrieved 30 April 2018.
- Gill, Simeon; Ahmed, Maryam; Parker, Christopher J.; Hayes, Steven G. (2017). "Not All Body Scanning Measurements are Valid: Perspectives from Pattern Practice". Proc. of 3DBODY.TECH 2017 - 8th Int. Conf. and Exh. on 3D Body Scanning and Processing Technologies: 43–52. doi:10.15221/17.043. Retrieved 30 April 2018.
- Januszkiewicz, Monika; Parker, Christopher J.; Hayes, Steven G.; Gill, Simeon (2017). "Online Virtual Fit Is Not Yet Fit For Purpose: An Analysis Of Fashion e-Commerce Interfaces". Proc. of 3DBODY.TECH 2017 - 8th Int. Conf. and Exh. on 3D Body Scanning and Processing Technologies: 210–217. doi:10.15221/17.210. Retrieved 9 May 2018.
- Lord M 1981. Foot pressure measurement: a review of methodology. J Biomed Eng 3 91-9.
- Gefen A 2007. Pressure-sensing devices for assessment of soft tissue loading under bony prominences: technological concepts and clinical utilization. Wounds 19 350-62.
- Cobb J, Claremont DJ 1995. Transducers for foot pressure measurement: survey of recent developments. Med Biol Eng Comput 33 525-32.
- Rosenbaum D, Becker HP 1997. Plantar pressure distribution measurements: technical background and clinical applications. J Foot Ankle Surg 3 1-14.
- Orlin MN, McPoil TG 2000. Plantar pressure assessment. Phys Ther 80 399-409.
- Birtane M, Tuna H 2004. The evaluation of plantar pressure distribution in obese and non-obese adults. Clin Biomech 19 1055-9.
- Blanc Y, Balmer C, Landis T, Vingerhoets F 1999. Temporal parameters and patterns of the foot roll during walking: normative data for healthy adults. Gait & Posture 10 97-108.
- Forensic Anthropology - Ancestry Archived 2012-02-06 at the Wayback Machine.
- International Ergonomics Association. What is Ergonomics Archived May 20, 2013, at the Wayback Machine.. Website. Retrieved 6 December 2010.
- "Home Page of Environmental Ergonomics Society". Environmental-ergonomics.org. Retrieved 2012-04-06.
- "Biometrics: Overview". Biometrics.cse.msu.edu. 6 September 2007. Archived from the original on 2012-01-07. Retrieved 2012-06-10.
- Jain A.; Hong L.; Pankanti S. (2000). "Biometric Identification" (PDF). Communications of the ACM. 43 (2): 91–98. doi:10.1145/328236.328110.
- Jain, Anil K.; Ross, Arun (2008). "Introduction to Biometrics". In Jain, AK; Flynn; Ross, A. Handbook of Biometrics. Springer. pp. 1–22. ISBN 978-0-387-71040-2.
- U.S. Military personnel Archived October 16, 2004, at the Wayback Machine.
- "CAESAR Fact Sheet". www.sae.org.
- Robinette, Kathleen M, Daanen, Hein A M, Precision of the CAESAR scan-extracted measurements, Applied Ergonomics, vol 37, issue 3, May 2007, pp. 259–265.
- Goonetilleke, R. S., Ho, Edmond Cheuk Fan, and So, R. H. Y. (1997). "Foot Anthropometry in Hong Kong". Proceedings of the ASEAN 97 Conference, Kuala Lumpur, Malaysia, 1997. pp. 81–88.
- Anthropometric Survey of Army Personnel: Methods and Summary Statistics 1988
- ISO 7250: Basic human body measurements for technological design, International Organization for Standardization, 1998.
- ISO 8559: Garment construction and anthropometric surveys — Body dimensions, International Organization for Standardization, 1989.
- ISO 15535: General requirements for establishing anthropometric databases, International Organization for Standardization, 2000.
- ISO 15537: Principles for selecting and using test persons for testing anthropometric aspects of industrial products and designs, International Organization for Standardization, 2003.
- ISO 20685: 3-D scanning methodologies for internationally compatible anthropometric databases, International Organization for Standardization, 2005.
- Pheasant, Stephen (1986). Bodyspace : anthropometry, ergonomics, and design. London; Philadelphia: Taylor & Francis. ISBN 0-85066-352-0. (A classic review of human body sizes.)
- Redman, Samuel (2016). Bone Rooms: From Scientific Racism to Human Prehistory in Museums. Cambridge: Harvard University Press. ISBN 9780674660410.
|Look up anthropometry in Wiktionary, the free dictionary.|
|Wikimedia Commons has media related to Anthropometry.|
- Anthropometry at the Centers for Disease Control and Prevention
- Anthropometry and Biomechanics at NASA
- Anthropometry data at faculty of Industrial Design Engineering at Delft University of Technology
- Manual for Obtaining Anthropometric Measurements Free Full Text
- Prepared for the US Access Board: Anthropometry of Wheeled Mobility Project Report Free Full Text
- Civilian American and European Surface Anthropometry Resource Project—CAESAR at SAE International
- Engineering Anthropometry and Workstation Design