The kilogram and measurements of mass and force.

This paper describes the facilities, measurement capabilities, and ongoing research activities in the areas of mass and force at the National Institute of Standards and Technology National Institute of Standards and Technology, governmental agency within the U.S. Dept. of Commerce with the mission of "working with industry to develop and apply technology, measurements, and standards" in the national interest. (NIST (National Institute of Standards & Technology, Washington, DC, www.nist.gov) The standards-defining agency of the U.S. government, formerly the National Bureau of Standards. It is one of three agencies that fall under the Technology Administration (www.technology. ). The first section of the paper is devoted to mass metrology and starts with a brief historical perspective on the developments that led to the current definition of the kilogram kilogram, abbr. kg, fundamental unit of mass in the metric system, defined as the mass of the International Prototype Kilogram, a platinum-iridium cylinder kept at Sèvres, France, near Paris. . An overview of mass measurement procedures is given with a brief discussion of current research on alternative materials for mass standards and surface profiles of the U.S. national prototype kilograms. A brief outlook into the future possible redefinition Noun 1. redefinition - the act of giving a new definition; "words like `conservative' require periodic redefinition"; "she provided a redefinition of his duties"
definition - a concise explanation of the meaning of a word or phrase or symbol of the unit of mass based on fundamental principles is included. The second part of this paper focuses on the unit of force and describes the realization of the unit, measurement procedures, uncertainty in the realized force, facilities and current efforts aimed at the realization of small forces.

Key words: force; kilogram; mass; uncertainty.

Available online: http://www.nist.gov/jrcs

1. The Kilogram and Mass Measurements

1.1 The Unit of Mass

From the early history of humankind to modern times, mass measurements have formed the corner stone for trade and commerce. The use of weights and balances as tools to perform mass measurements for trade dates back thousands of years and is most likely associated with the early civilizations of the Nile Valley and the Middle East. Since those times, mass standards and the technology of balances and mass measurements have greatly evolved to meet the growing and changing needs of society. The activities of everyday life have always been affected either directly or indirectly by mass measurements. Whenever one buys groceries, takes medication, designs a bridge, space shuttle space shuttle, reusable U.S. space vehicle. Developed by the National Aeronautics and Space Administration (NASA), it consists of a winged orbiter, two solid-rocket boosters, and an external tank. , or airplane, trades goods--whether grains, gold, or gemstones-mass plays a crucial and vital role. In addition to the direct impact on trade and commerce, mass measurements impact the scientific community as well as a broad range of manufacturing industries manufacturing industries npl → industrias fpl manufactureras

manufacturing industries npl → industries fpl de transformation

including aerospace, aircraft, automotive, chemical, semiconductor, materials, nucl ear, pharmaceutical, construction, and instrument manufacturing. To ensure equity and equivalence in trade and manufacturing at the national and international levels, uniform standards are needed. While mass standards have been in existence for thousands of years and some countries had rather controlled policies on weights, uniformity was not guaranteed across boundaries and sometimes not even within the boundaries of one country. In the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. , the unit of mass was the avoirdupois avoirdupois /av·oir·du·pois/ (av?er-dah-poiz´) (av-wahr?doo-pwah´) see under weight.

av·oir·du·pois
n.
Avoirdupois weight. pound, and many standards were brought over from England to the colonies to serve as standards for trade. However, this did not form a robust system and non-uniformity remained a major issue. The United States government formally recognized this need and empowered Congress to "fix the standards of weights and measures weights and measures, units and standards for expressing the amount of some quantity, such as length, capacity, or weight; the science of measurement standards and methods is known as metrology. " in the Constitution of the United States Constitution of the United States, document embodying the fundamental principles upon which the American republic is conducted. Drawn up at the Constitutional Convention in Philadelphia in 1787, the Constitution was signed on Sept. . Many attempts at adopting a uniform system of weights were made. It wasn't until 1875 that the United States along with 16 other countries signed the Meter Convention that established the foundations of the International System of Units International System of Units, officially called the Système International d'Unités, or SI, system of units adopted by the 11th General Conference on Weights and Measures (1960). It is based on the metric system. (SI) that would finally provide the long sought after uniformity in the standards of weights and measures. A detailed account of the history of weights and measures in the United States can be found in Ref. (1).

The foundation of the SI lies with the 1791 decision of the French National Assembly to adopt a uniform system based entirely on the unit of length, the meter, defined at the time as being equal to one ten-millionth of the length of the quadrant quadrant, in analytic geometry
quadrant.

1 In analytic geometry, one of the four regions of the plane determined by two lines, the x-axis and the y-axis. of the earth meridian Meridian (mərĭd`ēən), city (1990 pop. 41,036), seat of Lauderdale co., E Miss., near the Ala. line; settled 1831, inc. 1860. . The unit of mass would be the mass of a cubic decimeter dec·i·me·ter
n. Abbr. dm
A metric unit of length equal to one-tenth (10^-1) of a meter.

Noun 1. decimeter - a metric unit of length equal to one tenth of a meter
decimetre, dm of water at 4 [degrees]C, the temperature of maximum density. Based on these definitions, a prototype meter and kilogram were manufactured and deposited in the Archives of the French Republic in 1799 forming the basis of the presently adopted SI. The prototype kilogram became known as the Kilogram of the Archives. In 1875, the Meter Convention founded the "Comite International des Poids et Mesures" (CIPM CIPM Comité International des Poids et Mesures (International Committee of Weights and Measures)
CIPM Center for Integrated Pest Management
CIPM Certificate in Investment Performance Measurement ), which took the responsibility of manufacturing replicas of the meter and kilogram prototypes, and the "Bureau International des Poids et Mesures (body, standard) Bureau International des Poids et Mesures - (BIPM) The standards body that ensures world-wide uniformity of measurements and their traceability to the International System of Units (SI). " (BIPM BIPM - Bureau International des Poids et Mesures ) whose function would be to serve as the custodian bailee (custodian) n. a person with whom some article is left, usually pursuant to a contract (called a "contract of bailment"), who is responsible for the safe return of the article to the owner when the contract is fulfilled. of the prototypes, carry out future international comparisons, and serve as the cente r for disseminating dis·sem·i·nate
v. dis·sem·i·nat·ed, dis·sem·i·nat·ing, dis·sem·i·nates

v.tr.
1. To scatter widely, as in sowing seed.

2. the metric system metric system, system of weights and measures planned in France and adopted there in 1799; it has since been adopted by most of the technologically developed countries of the world. . In 1878, three 1 kg cylinders, KI, KII, and KII, made of 90 % platinum- 10 % iridium iridium (ĭrĭd`ēəm), metallic chemical element; symbol Ir; at. no. 77; at. wt. 192.22; m.p. about 2,410°C;; b.p. about 4,130°C;; sp. gr. 22.55 at 20°C;; valence +3 or +4. alloy were ordered from Johnson Matthey Johnson Matthey plc (LSE: JMAT) is a British chemical company which has its headquarters near Holborn in central London. It is traded on the London Stock Exchange and is a constituent of the FTSE 100 Index. in England; they were delivered in 1879. They were polished, adjusted, and compared with the Kilogram of the Archives by four observers in 1880 at the Observatory observatory, scientific facility especially equipped to detect and record naturally occurring scientific phenomena. Although geological and meteorological observatories exist, the term is generally applied to astronomical observatories. of Paris. The mass of KIII was found to be the closest to that of the Kilogram of the Archives. KIII was placed in a safe at the BIPM in 1882, was chosen by the CIPM to be the International Prototype Kilogram, and was ratified rat·i·fy
tr.v. rat·i·fied, rat·i·fy·ing, rat·i·fies
To approve and give formal sanction to; confirm. See Synonyms at approve. as such by the 1st "Conference Generale des Poids et Mesures" (CGPM CGPM Conférence Générale des Poids et Mesures (French: General Conference on Weights and Measures) ) in 1889. In 1901, the 3rd CGPM in Paris established the definition of the unit of mass: "The Kilogram is the unit of mass; it is equal to the mass of the International Prototype of the Kilogram." The International Prototype Kilogram is often referred to as "IPK IPK Institut für Pflanzengenetik und Kulturpflanzenforschung Gatersleben (Institute of Plant Genetics and Crop Plant Research)
IPK International Prototype Kilogram
IPK Intractable Plantar Keratosis
IPK In-Process Kanban " and is frequently designated with the Gothic letter K. In 1884, 40 replicas of the kilogram were delivered from Johnson Matthey; they were compared to the mass of the IPK in 1888. In 1889, 34 of these replicas were distributed to the signatories of the Meter Convention who requested them. Calibration certificates accompanied the replicas with mass values based on comparisons with the IPK. These replicas were in turn used by the different countries as national standards. At that time, the United States was allocated two Pt-Ir prototype kilograms, K20 and K4. K20 arrived in the United States in 1890 and was designated as the primary national standard of mass. K4 arrived later that same year and was assigned as a check standard to monitor the constancy con·stan·cy
n.
1. Steadfastness, as in purpose or affection; faithfulness.

2. The condition or quality of being constant; changelessness.

Noun 1. of K20. Over a century later, K20 and K4 still hold their respective positions. The six remaining replicas were kept at the BIPM to serve as check standards for IPK. In addition to the original 40 copies, more replicas were constructed to serve the growing needs of the international community. In 1996, the U.S. acquired a new prototype kilogram, K79.

Since its foundation in 1875 and until 1973, the BIPM used two equal-arm mechanical balances: the Bunge balance that was in service between 1879 and 1951 and the Rueprecht balance that served the BIPM's needs from 1878 until 1974 (2). In 1970, the National Bureau of Standards National Bureau of Standards: see National Institute of Standards and Technology.

National Bureau of Standards - National Institute of Standards and Technology (NBS (National Bureau of Standards) See NIST.

NBS - National Bureau of Standards: part of the US Department of Commerce, now NIST. ), predecessor to NIST, donated a 1 kg balance, known as NBS-2, to the BIPM. NBS-2 was designed and developed at NIST to allow for the simultaneous measurement of six 1 kg standards. The unique constant-load, double-knife-edge design allowed metrologists to achieve state-of-the-art resolution and repeatability (3). NBS-2 was used for the calibration of 1 kg standards at the BIPM between 1973 and 1992, replacing the Rueprecht balance that was nearing 100 years of age. Currently the BIPM uses state-of-the-art balances that are either commercially available or developed at the BIPM.

The unit of mass is only available at the BIPM. Therefore, the prototypes serving as national standards of mass must be returned periodically to the BIPM for calibration either on an individual basis, which could be done anytime, or as part of a simultaneous recalibration of all the prototypes known as "periodic verification." Since the existence of the prototypes there has been only three such periodic verifications. The latest one, the third periodic verification, took place between 1988 and 1992. For it, the IPK was used with the NBS-2 balance. The results of the third periodic verification demonstrated a long-term instability of the unit of mass on the order of approximately 30 [mu]g/kg over the last century (4); this instability is attributed to surface effects that are not yet fully understood. Mass standards, including IPK and its replicas, are stored in ambient air; therefore, their surfaces are subject to the adsorption adsorption, adhesion of the molecules of liquids, gases, and dissolved substances to the surfaces of solids, as opposed to absorption, in which the molecules actually enter the absorbing medium (see adhesion and cohesion). or absorption of atmospheric contamination resulting in a gain in mass over t ime; they also may lose mass from usage. The BIPM has developed a recommended method (5) for cleaning platinum-iridium (Pt-Ir) prototypes to remove surface contaminants and restore the artifact A distortion in an image or sound caused by a limitation or malfunction in the hardware or software. Artifacts may or may not be easily detectable. Under intense inspection, one might find artifacts all the time, but a few pixels out of balance or a few milliseconds of abnormal sound to its original state. In 1989, the CIPM interpreted the 1901 definition of the kilogram (6). The interpretation, which does not imply a redefinition of the kilogram, refers to the kilogram as being equal to the mass of the IPK just after cleaning and washing using the BIPM method.

In 2001, the kilogram remains as the only SI base unit defined by an artifact and thus is constantly in danger of being damaged or destroyed. In addition, the definition of the kilogram makes no provision for either the artifact surface parameters or for any environmental storing conditions. Environmental effects combined with wear and other material and surface properties constitute the most probable reason for the observed instability in mass over time. The instability in the definition of the kilogram propagates to other SI base units that are tied to the kilogram such as the ampere ampere (ăm`pēr), abbr. amp or A, basic unit of electric current. It is the fundamental electrical unit used with the mks system of units of the metric system. , mole, and candela candela (kăndĕ`lə), in weights and measures: see candle.

A unit of measurement of the intensity of light. Part of the SI system of measurement, one candela (cd) is the monochromatic radiation of 540THz with a radiant intensity . It also propagates to derived quantities such as density, force, and pressure. Therefore, the impact of the instability in the unit of mass spans a broad range of applications in the scientific and engineering sectors.

While comparisons of nearly identical 1 kg mass standards can be performed with a relative precision of [10.sup.-10] with commercially available balances and with [10.sup.-12] with special balances, it is clear that the limitation in the field of mass metrology lies within the artifact definition itself. Therefore, the ultimate need for mass metrology is to redefine Verb 1. redefine - give a new or different definition to; "She redefined his duties"
define, delimit, delimitate, delineate, specify - determine the essential quality of

2. the unit of mass in terms of a fundamental constant of nature. At the same time, it is also crucial to pursue more stable and ideal artifacts artifacts

see specimen artifacts. and transfer standards, as this will be, at least for the foreseeable future, the only practical dissemination dissemination Medtalk The spread of a pernicious process–eg, CA, acute infection Oncology Metastasis, see there tool.

1.2 Mass Measurement

1.2.1 Cleaning and Handling of Mass Standards

Mass standards are typically stored and used in ambient air; therefore, they accumulate contaminants and must be cleaned occasionally to restore them to their original mass values. Cleaning policies and protocols depend on the artifact material and can vary greatly among laboratories.

The internationally accepted cleaning method of the platinum-iridium prototypes is known as "the BIPM cleaning method" and it is described in Ref. (5). This method was developed at the BIPM between 1939 and 1946; it evolved from years of experimentation on cleaning methods that included using a variety of solvents. The currently used BIPM method consists of rubbing the artifact with chamois cloth Noun 1. chamois cloth - a piece of chamois used for washing windows or cars
piece of cloth, piece of material - a separate part consisting of fabric that has been soaked in a mixture of equal proportions of ether ether, in chemistry
ether, any of a number of organic compounds whose molecules contain two hydrocarbon groups joined by single bonds to an oxygen atom. and alcohol. Since the ether and alcohol mixture leaves a residue, the artifact is then cleaned in a jet of steam from doubly distilled water Noun 1. distilled water - water that has been purified by distillation
H2O, water - binary compound that occurs at room temperature as a clear colorless odorless tasteless liquid; freezes into ice below 0 degrees centigrade and boils above 100 degrees centigrade; . Results show that this procedure is effective in removing contamination from the surface (4). It is worth noting that this method relies on the human touch and therefore can be highly irreproducible. NIST follows this protocol to clean the national standards of mass K20, K4, and K79 when necessary. All other NIST mass standards and those submitted for calibration are gene rally made of stainless steel stainless steel: see steel.

stainless steel

Any of a family of alloy steels usually containing 10–30% chromium. The presence of chromium, together with low carbon content, gives remarkable resistance to corrosion and heat. and are sub jected to different cleaning procedures, depending on their size and construction, as described below.

Mass standards made of one-piece construction in the range of 1 g to 1 kg are cleaned by washing the artifacts with condensing con·dense
v. con·densed, con·dens·ing, con·dens·es

v.tr.
1. To reduce the volume or compass of.

2. To make more concise; abridge or shorten.

3. Physics
a. alcohol vapor, usually referred to as "vapor degreasing." Following washing, the artifacts are allowed to dry and any droplets on the surface are gently patted dry.

Mass standards larger than 1 kg and all weights of two-piece construction are cleaned by wiping with lint-free cheesecloth cheese·cloth
n.
A coarse, loosely woven cotton gauze, originally used for wrapping cheese.

cheesecloth
Noun

a light, loosely woven cotton cloth

Noun 1. moistened with alcohol.

Fractional weights (1 mg to 500 mg) are cleaned by soaking them in alcohol followed by gently patting the dry.

When mass standards are contaminated contaminated,
v 1. made radioactive by the addition of small quantities of radioactive material.
2. made contaminated by adding infective or radiographic materials.
3. an infective surface or object. with oily residues, they are cleaned with acetone acetone (ăs`ĭtōn), dimethyl ketone (dīmĕth`əl kē`tōn), or 2-propanone (prō`pənōn), CH₃COCH₃ followed by alcohol using lint-free cheesecloth. Typically, unless specified otherwise by the customers, all mass standards are cleaned before calibration.

After cleaning, weights are allowed to stabilize for a period of 7 to 10 days before calibration. The stabilization period stabilization period

The time elapsing between the offering of a security issue for sale and its final distribution, during which the underwriter enters the secondary market in order to stabilize the price of the security. is determined based on the results of characterization of the stability of mass standards by monitoring the mass of a selected set of weights after cleaning (7). Before calibration, weights are stored inside or near the balance, under cover, for a period of at least 24 hours to reach thermal equilibrium thermal equilibrium

The condition under which two substances in physical contact with each other exchange no heat energy. Two substances in thermal equilibrium are said to be at the same temperature. See also thermodynamics.

Noun 1. with the surrounding temperature. Weights larger than 10 kg require a longer thermal stabilization period depending on their size.

The handling of mass standards requires special precautions precautions Infectious disease The constellation of activities intended to minimize exposure to an infectious agent; precautions imply that the isolation of an infected Pt is optional, but not mandatory. . Care must always be taken to minimize the risks of dropping and therefore damaging the surface of the artifacts. In order to minimize contamination, mass standards must always be kept in a relatively dust free environment with appropriate air filtration. When not in use, mass standards must be kept under a glass bell jar or other appropriate cover. In addition, mass standards must never be handled with bare hands. Usually special handling devices such as tweezers tweezers An instrument with pincers used to grasp or extract. See Optical tweezers. are used to avoid direct contact. If handling by hand is required, gloves must be worn. Gloves must be chosen to be powder free and such that their use doesn't result in contamination of the artifact. In addition to contamination, handling by direct contact with the human body results in change in temperature that will later require additional thermal stabilization time. If handling devices are used, the part that comes in contact with the mass standards must be clean, non-abrasive, and no n-magnetic. Before calibration, dust particles that could have accumulated on the surface of the artifacts can be removed by either blowing air using a bulb type rubber syringe syringe /sy·ringe/ (si-rinj´) (sir´inj) an instrument for injecting liquids into or withdrawing them from any vessel or cavity. or by lightly brushing with a clean brush.

1.2.2 Density Determination

High precision mass measurements require applying an air buoyancy buoyancy (boi`ənsē, b

`yən–), upward force exerted by a fluid on any body immersed in it. Buoyant force can be explained in terms of Archimedes' principle. correction that in turn requires the knowledge of the air density as well as the volumes or densities of the artifacts.

The air density is computed using the internationally accepted equation for the determination of the density of moist air (8) from the measurement of the [CO.sub.2] concentration, temperature, barometric ba·rom·e·ter
n.
1. An instrument for measuring atmospheric pressure, used especially in weather forecasting.

2. Something that registers or responds to fluctuations; an indicator: pressure, and relative humidity relative humidity
n.
The ratio of the amount of water vapor in the air at a specific temperature to the maximum amount that the air could hold at that temperature, expressed as a percentage. . All the environmental transducers are regularly calibrated cal·i·brate
tr.v. cal·i·brat·ed, cal·i·brat·ing, cal·i·brates
1. To check, adjust, or determine by comparison with a standard (the graduations of a quantitative measuring instrument): by the appropriate groups at NIST and are traceable to the national standards of temperature, pressure, and humidity. The standard uncertainty in the air density is 0.000 17 kg/[m.sup.3] based upon standard uncertainties of the measured temperature, barometric pressure, and relative humidity of 5 mK, 10 Pa, and 0.5 %, respectively.

Mass standards typically have rounded edges, knobs, and recessed re·cess
n.
1.
a. A temporary cessation of the customary activities of an engagement, occupation, or pursuit.

b. The period of such cessation. See Synonyms at pause.

2. bottoms, therefore determining the volume by geometric means (mathematics) geometric mean - The Nth root of the product of N numbers.

If each number in a list of numbers was replaced with their geometric mean, then multiplying them all together would still give the same result. is neither very accurate nor practical. Volumes (or densities) are measured using an immersed im·merse
tr.v. im·mersed, im·mers·ing, im·mers·es
1. To cover completely in a liquid; submerge.

2. To baptize by submerging in water.

3. balance and hydrostatic hy·dro·stat·ic or hy·dro·stat·i·cal
adj.
Of or relating to fluids at rest or under pressure.

hydrostatic

pertaining to a liquid in a state of equilibrium or the pressure exerted by a stationary fluid. weighing systems. Since both systems require immersion of the weights in a fluid, all standards must be of a one-piece construction to avoid introducing fluid into any cavities in the weights.

The immersed balance procedure developed at NIST by Davis and Schoonover (9) uses the novel idea of immersing a modified electronic balance in a bath of fluorocarbon fluorocarbon /flu·o·ro·car·bon/ (floor´o-kahr?b?n) any of the class of organic compounds consisting of carbon and fluorine only. fluid. Volumes of mass standards in the range from 100 g to 1 kg are measured by comparison to volume standards, of the same nominal value Nominal Value

The stated value of an issued security that remains fixed, as opposed to its market value, which fluctuates.

Notes:
When referring to fixed-income securities, the nominal value is also the face value. , determined to a higher precision by the hydrostatic technique described below. Check standards are incorporated in the measurements to monitor the accuracy of the process. The relative combined standard uncertainty in the density using this procedure is 0.004 %. Artifacts of other denominations between 100 g and 1 kg, and special requests requiring higher precision, are performed using hydrostatic weighing techniques.

The hydrostatic weighing procedure uses silicon as density reference standards (10). The use of solid objects as reference standards for density measurements was first developed at NIST in 1974 (11); this method eliminated the use of water as a density reference standard and is currently used in most laboratories where high-precision density measurements are required. The hydrostatic weighing system currently in use is essentially the same system developed at NIST in 1974 for the measurement of silicon density standards with an electronic top-loading balance replacing the mechanical balance. A fluorocarbon fluid is used for most of the measurements while water is occasionally used. Check standards are incorporated in the measurements to monitor the accuracy of the process. Mass determinations in air and in the fluid are done against NIST mass standards to eliminate errors due to non-linearity of the balance. The density of the silicon reference standards used is known with a relative standard uncertainty of 7.5 X [10.sup.-7] from hydrostatic weighing by comparison against stainless steel spheres whose volumes were measured using laser interferometry (1). The relative combined standard uncertainty in the density using the hydrostatic system is 0.001 %.

Typically for large weights (above 1 kg), the density of a sample of the same material is measured. The sample should preferably be from the same bar and cut from a location as close to the weight as possible to minimize any effects due to nonhomogeneity of the material.

For weights smaller than 100 g and for all weights made of two-piece construction, either the manufacturer's stated density or the density supplied by the customer is used.

A new, fully automated hydrostatic density measuring system based on silicon spheres as reference standards is currently being developed. A new system for measuring the density of artifacts in the range from 2 kg to 10 kg is also under development. Both systems are expected to be in operation by 2002.

1.3 Dissemination of the Unit of Mass

While the unit of mass is defined at the one kilogram level, the mass scale must be realized over a range broad enough to be of practical use in commerce and manufacturing. The first stage in the realization of the mass scale is to disseminate dis·sem·i·nate
v. dis·sem·i·nat·ed, dis·sem·i·nat·ing, dis·sem·i·nates

v.tr.
1. To scatter widely, as in sowing seed.

2. the unit from the International Prototype Kilogram to the national standard followed by a transfer to a set of working standards at the one kilogram level. This is followed by dissemination to multiples and submultiples of the kilogram covering the range from 1 mg to 27 200 kg. The traceability from the International Prototype Kilogram to the multiples and submultiples of the kilogram is shown in Fig. 1. The procedures involved are discussed in the following sections.

1.3.1 Dissemination From the International Prototype Kilogram to the National Standards

The link between the SI unit of mass and the U.S. national standard of mass is maintained through periodic calibrations of the national standard at the BIPM. The U.S. national standard of mass, K20, was calibrated at the BIPM six times during its lifetime, the latest calibration being in 1999 when it was calibrated against the BIPM working standards using a commercial electronic balance. K4, the U.S. check standard, was calibrated at the BIPM three times. Table 1 shows the dates of calibration along with the masses reported on the calibration certificates of the U.S. prototypes from the BIPM. The combined standard uncertainty (coverage factor k = 1) ranged from 2 [mu]g to 4 [mu]g. The densities of the prototype kilograms K20 and K4 have been measured at the BIPM using hydrostatic weighing techniques with water as a reference standard; the measured values are 21 539.14 kg/[m.sup.3] and 21 531.77 kg/[m.sup.3], respectively with a relative standard uncertainty estimated at 0.003 %(13).

The masses reported in Table 1 are obtained after cleaning and washing of the prototypes using the BIPM method. When the prototype kilograms are not cleaned a correction to the "after cleaning" mass is applied. This correction is based on a model developed by the BIPM. Based on this model, a platinum-iridium kilogram gains 1.11 [mu]g per month for the first 3 months after cleaning. The rate of change of mass then decreases to approximately 1 [mu]g per year (4).

1.3.2 Dissemination to the Stainless Steel Secondary Standards

The U.S. unit of mass is traceable to the IPK through the primary national standard of mass, K20. The mass unit is first transferred from K20 to a set of secondary stainless steel (SS) kilogram standards manufactured from nonmagnetic SS alloys with nominal density of 8000 kg/[m.sup.3], polished surfaces, and chamfered edges. Prior to the mass calibration, the densities are determined using the hydrostatic weighing method with silicon reference standards, as described above.

The standards are cleaned after the density measurements by vapor degreasing and are allowed to stabilize before calibration as outlined earlier. Subsequent cleaning is performed only if a weight has been subject to unusual contamination. A commercially available and fully automated electronic 1 kg mass comparator comparator

Instrument for comparing something with a similar thing or with a standard measure, in particular to measure small displacements in mechanical devices. In astronomy, the blink comparator is used to examine photographic plates for signs of moving bodies. with a resolution of 1 [mu]g is used. This comparator is equipped with a weight-handling mechanism that allows for the simultaneous measurement of four mass standards of equal nominal mass The nominal mass is the integer mass of the most abundant naturally occurring stable isotope of an element. The nominal mass of a molecule is the sum of the nominal masses of the elements in its empirical formula. , which in this case is 1 kg. Figure 2 shows K20, K4, and two stainless steel kilogram standards inside the balance during calibration. K20 and K4 are cylindrical cyl·in·dri·cal
adj.
Of, relating to, or having the shape of a cylinder, especially of a circular cylinder. weights while the knob weights are the stainless steel secondary standards. Since a balance is essentially a force transducer transducer, device that accepts an input of energy in one form and produces an output of energy in some other form, with a known, fixed relationship between the input and output. that measures the net vertical forces acting on an object, the balance rending rend
v. rent or rend·ed, rend·ing, rends

v.tr.
1. To tear or split apart or into pieces violently. See Synonyms at tear¹.

2. reflects the difference between the gravitational grav·i·ta·tion
n.
1. Physics
a. The natural phenomenon of attraction between physical objects with mass or energy.

b. The act or process of moving under the influence of this attraction.

2. and buoyant Buoyant

The term used to describe a commodities market where the prices generally rise with ease when there are considerable signals of strength.

Notes:
These types of markets can be very volatile as the prices are rapid to rise and fall with investor sentiment. forces; if the balance is calibrated and the sensitivity is measured [14], the balance re ading allows for the determination of the mass value. Typically, mass measurements are performed by comparison weighing involving a reference R and an unknown X:

[m.sub.R] - [[rho].sub.a][V.sub.R] = [C.sub.R] (1)

[m.sub.x]-[[rho].sub.a][V.sub.x] = [C.sub.x] (2)

where [m.sub.R] and [m.sub.x], [V.sub.R] and [V.sub.x], [C.sub.R] and [C.sub.x] denote de·note
tr.v. de·not·ed, de·not·ing, de·notes
1. To mark; indicate: a frown that denoted increasing impatience.

2. the mass, volume, and balance reading for the reference R and the unknown X, respectively while [[rho].sub.a] refers to the air density during the measurement.

Comparing the above two equations by taking the difference allows for the determination of the value of the unknown:

[m.sub.x]=[m.sub.R]-[[rho].sub.a]([V.sub.R]- [V.sub.x])-C (3)

where C = [C.sub.R]-[C.sub.x], and the assumption was made that the air density [[rho].sub.a] does not change during this comparison. Equation (3) represents the simplest and most fundamental mass measurement process. It is evident from Eq. (3) that the air buoyancy correction is proportional to the difference in volumes between the reference and the unknown. Therefore, the comparison of two artifacts of different volumes such as a 1 kg weight made of Pt-Ir and a 1 kg weight made of stainless steel results in a buoyancy correction of 94.2 mg assuming an air density of 1.2 kg/[m.sup.3], a volume of 125 [cm.sup.3] for a stainless steel kilogram, and a volume of 46.5 [cm.sup.3] for a Pt-Ir kilogram. In order to minimize any effect of balance nonlinearity, small weights with total mass of approximately 94 mg are added to the stainless steel kilograms. The stainless steel kilograms are calibrated in pairs, denoted X1 and X2, against the national standard K20 while K4 acts as a check standard. The small added masse s to X1 and X2 are represented by z1 and z2, respectively. Difference measurements [Y.sub.i] are obtained with all possible combinations between all four standards; this results in six differences:

Observation  (1)  (2)   (3)    (4)

             K20  K4   X1+z1  X2+z2
[Y.sub.1]     +    -
[Y.sub.2]     +          -
[Y.sub.3]     +                 -
[Y.sub.4]          +     -
[Y.sub.5]          +            -
[Y.sub.6]                +      -

The (+) and (-) signs in the above matrix indicate the order in the difference measurement: (+) and (-) for observation [Y.sub.1] indicates a measurement of the difference between K20 and K4 where K20 is measured first. Therefore, the above matrix translates into the following equations after taking into account the buoyancy correction:

([m.sub.K20] - [[rho].sub.a1] [V.sub.K20]) - ([m.sub.K4] - [[rho].sub.a1] [V.sub.K4]) = [Y.sub.1] (1)

([m.sub.K20] - [[rho].sub.a2] [V.sub.K20]) - ([m.sub.X1] - [[rho].sub.a2] [V.sub.X1] + [m.sub.z1] - [[rho].sub.a2] [V.sub.z1]) = [Y.sub.2] (2)

([m.sub.K20] - [[rho].sub.a3] [V.sub.K20]) - ([m.sub.X2] - [[rho].sub.a3] [V.sub.x2] + [m.sub.z2] - [[rho].sub.a3] [V.sub.z2]) = [Y.sub.3] (3)

([m.sub.K4] - [[rho].sub.a4] [V.sub.K4]) - ([m.sub.x1] - [[rho].sub.a4] [V.sub.x1] + [m.sub.z1] - [[rho].sub.a4] [V.sub.z1]) = [Y.sub.4] (4)

([m.sub.K4] - [[rho].sub.a5] [V.sub.K4]) - ([m.sub.x2] - [[rho].sub.a5] [V.sub.x2] + [m.sub.z2] - [[rho].sub.a5] [V.sub.z2]) = [Y.sub.5] (5)

([m.sub.x1] - [[rho].sub.a6] [V.sub.x1] + [m.sub.z1] - [[rho].sub.a6]) - ([m.sub.x2] - [[rho].sub.a6] [V.sub.x2] + [m.sub.z2] - [[rho].sub.a6][V.sub.z2]) = [Y.sub.6] (6)

Such a series of difference measurements is known as a weighing design. This particular weighing design is referred to as a 4-1 design indicating that it involves four weights of equal nominal mass. Fixing the value of one of the standards allows one to solve this system of equations using the method of the least squares (15). In this case, the mass of K20 is known from the calibration at the BIPM and is therefore used as the restraint:

[m.sub.K20] = R. (7)

These weighing designs have been developed at NIST by Cameron et al. in 1979. A full description can be found in Ref. (15). Such measurements allow one to determine the masses of the unknown standards X1 and X2 as well as K4 from linear combinations of the mass differences [Y.sub.1],........,[Y.sub.6] and the value of the restraint a described in Ref. (15) after correcting each mass difference for the buoyancy correction associated with the standards involved (16).

Since the mass of K4 is known from a calibration at the BIPM, the determination of its mass here serves as a check of the accuracy of the process as discussed below.

The difference in the geometry between the Pt-Ir and stainless steel standards results in a difference in the relative locations of the center of mass. This results in a change in the measured mass that is proportional to the gravitational gradient over the range between the locations of the two centers of gravity center of gravity
n. pl. centers of gravity
1. Abbr. CG The point in or near a body at which the gravitational potential energy of the body is equal to that of a single particle of the same mass located at that point . The gravitational correction is given by:

1 kg 1/g [partial]g/[partial]h ([delta]h) (8)

where [delta]h represents the distance between the centers of mass of the two artifacts being compared, g is the acceleration eration of free fall, and [partial]g/[partial]h is the gravitational field Noun 1. gravitational field - a field of force surrounding a body of finite mass
field of force, force field, field - the space around a radiating body within which its electromagnetic oscillations can exert force on another similar body not in contact with it gradient. In order to quantify this correction, the gravitational gradients as well as the absolute acceleration of free fall at the location where the mass calibrations are performed were measured by the National Geodetic Survey geodetic survey
n.
A survey of a large area of land in which corrections are made to account for the curvature of the earth.

geodetic survey to be [(3.35 X [10.sup.-6]) [+ or -] (0.06 X [10.sup.-6)] [s.sup.-2] and (9.800 998 6 [+ or -] [10.sup.-7]) m/[s.sup.2], respectively. For [DELTA]h = 1 cm, which is typical, the gravitational correction is 3 [mu]g.

The combined standard uncertainty in the mass of a secondary stainless steel kilogram is computed from the basic equation for mass determination [Eq. (3)] based on the ISO (1) See ISO speed.

(2) (International Organization for Standardization, Geneva, Switzerland, www.iso.ch) An organization that sets international standards, founded in 1946. The U.S. member body is ANSI. Guide for the Expression of Uncertainty in Measurement (17), resulting in the following contributions:

a) Air density: the uncertainty component due to air density is proportional to the difference in volume between the two standards being compared. It is evident here that the dominant component is due to the large difference in volume [approximately equal to]80 [cm.sup.3]) between the Pt-Ir and secondary SS kilograms. This uncertainty component is [u.aub.air] = 13.3 [mu]g for an uncertainty in the air density of 0.000 17 kg/[m.sup.3].

b) Balance: the uncertainties due to repeatability and reproducibility are computed in accordance with the model developed by C. M. Croarkin using the procedures outlined in Ref. (18). In this case, [U.sub.balance] = 2.3 [mu]g.

c) Reference, K20: this component is taken from the calibration certificate of K20 supplied by he BIPM; [u.sub.reference] = 4 [mu]g based on the 1999 calibration certificate.

d) Added masses In fluid mechanics, added mass is the inertia added to a system due to the fact that an accelerating or decelerating body must move some volume of surrounding fluid as it moves through it, since the object and fluid cannot occupy the same physical space simultaneously. : uncertainty in the small masses added to the stainless steel kilograms to compensate for the large difference due to the buoyancy correction. The uncertainty in the 94 mg as obtained from previous calibration against NIST standards is given by [u.sub.add-mass] = 0.1 [mu]g.

e) Volume of standards: this component of the uncertainty, [u.sub.volumes], is due to the uncertainty in the volumes of the reference K20 and the unknown weights, X1 or X2. This uncertainty component is negligible when the air densities at the time of calibration and the time of use of the standards are comparable (19).

f) Other less significant uncertainty components not included in the above list are: [u.sub.temperature], due to possible errors in the temperature volume expansion coefficients and [u.sub.gravity], from the gravitational corrections.

The combined standard uncertainty is given by

U = [square root of ([u.sup.2.sub.air]+[u.sup.2.sub.balance]+[u.sup.2.sub.reference]+[u.s up.2.sub.add-mass]+[u.sup.2.sub.volumes]+[u.sup.2.sub.temperature]+[u .sup.2.sub.gravity)]. (9)

When all the uncertainties mentioned above are included, the combined standard uncertainty of the mass of a secondary stainless steel standard kilogram is found to be 14 [mu]g (coverage factor k = 1).

The secondary standards are used as reference standards in the calibration of the working standards at the 1 kg level. The calibration procedure is similar and uses the same automated comparator. However, since the secondary and working standards have similar volumes, the buoyancy correction is very small. Therefore, the need for added masses is eliminated and the uncertainty in the buoyancy correction is minimized. The major contributions to the uncertainty become the uncertainty in the reference standard used, [u.sub.reference] = 14 [mu]g and the combined repeatability and reproducibility of the balance, [u.sub.balance] = 2.3 [mu]g. The combined standard uncertainty in the 1 kg working standard is therefore computed to be 14.2 [mu]g.

1.3.3 Dissemination to Multiples and Submultiples of the Kilogram

Two sets of stainless steel working standards at the kilogram level are used to disseminate the unit of mass to multiples and submultiples of the kilogram. These standards have similar properties as the secondary standards. At NIST, mass measurements traceable to the national standard of mass are regularly performed in the range from 1 mg to 27 200 kg. Typically, weights come in sets consisting of weights of various denominations. For example, a 1 g to 1 kg set consists of the following weights: 1 kg, 500 g, two 200 g, 100 g, 50 g, two 20 g, 10 g, 5 g, two 2 g, and 1 g. Weighing designs were developed to allow one to transfer the unit of mass from the kilogram to other denominations while optimizing the number of measurements and the statistical uncertainty. The protocol used for the calibration of such a weight set is illustrated in Fig. 3. Starting with the first series, four weights of nominal mass of 1 kg are used: (1) 1 kg NIST reference standard, (2) 1 kg check standard, (3) 1 kg unknown, (4) a 1 kg un known sum denoted by [SIGMA]1 kg consisting of a combination of 500 g, two 200 g, and 100 g. Six observations are made using the following difference measurements:

Observation  (1)   (2)   (3)       (4)
             1 kg  1 kg  1 kg  [SIGMA]1 kg

 [Y.sub.1]    +     -
 [Y.sub.2]    +           -
 [Y.sub.3]    +                     -
 [Y.sub.4]          +     -
 [Y.sub.5]          +               -
 [Y.sub.6]                +         -
 Restraint    +

In this case, the restraint is on the reference 1 kg weight in position (1).

The second series consists of difference measurements among 6 weights: (1) 500 g, (2) 200 g, (3) 200 g, (4) 100 g, (5) 100 g, and (6) [SIGMA] 100 g consisting of a combination of 50 g, two 20 g, and 10 g. In this case, the restraint is placed on the sum of the weights in positions (1) to (4); this summation summation n. the final argument of an attorney at the close of a trial in which he/she attempts to convince the judge and/or jury of the virtues of the client's case. (See: closing argument) is known from series 1; weight (5) serves as a check standard while (6) serves as the restraint for the subsequent series. In this case the following difference measurements are performed:

Observation   (1)    (2)    (3)    (4)    (5)       (6)
             500 g  200 g  200 g  100 g  100 g  [SIGMA]100 g

 [Y.sub.1]     +      -      -      -      -         +
 [Y.sub.2]     +      -      -      -      +         -
 [Y.sub.3]     +      -      -      +      -         -
 [Y.sub.4]     +      -             -      -         -
 [Y.sub.5]     +             -      -      -         -
 [Y.sub.6]            +      -      +      -
 [Y.sub.7]            +      -      -                +
 [Y.sub.8]            +      -             +         -
 Restraint     +      +      +      +

A complete description of the weighing designs for the calibration of mass standards can be found in Ref. (15). NIST check standards are incorporated into each series of measurements, and a NIST reference standard is only used at the starting series; the tie to the subsequent series is provided by the measurement of the unknowns as determined from the previous series. Similar procedures are used for calibration of the multiples of the kilogram. The observations are corrected for air buoyancy as well as temperature before the masses are calculated using the least squares method least squares method

Statistical method for finding a line or curve—the line of best fit—that best represents a correspondence between two measured quantities (e.g., height and weight of a group of college students). (15).

Since most mass standards in use are made of stainless steel of similar density to that of the NIST working and check standards, the uncertainty in the buoyancy correction is negligible. Therefore the major contributions to the uncertainty are (1) the uncertainty in the reference standard and (2) the combined repeatability and reproducibility of the balance. Uncertainties due to the volumes of the unknowns cannot be included due to the correlation between the measurements at the time of calibration and at the future time of use of the standard (19); this component can be added later by the customer based on the value for the air density at the time of calibration of the weight at NIST and at time of use by the customer. Figure 4 shows the combined standard uncertainties and relative combined standard uncertainties plotted against mass values in the most commonly used range from 1 mg to 5000 kg. The "V-shaped" curve is a characteristic of a mass calibration uncertainty curve since the smallest uncertainty is at the 1 kg level where the unit is defined and the uncertainty increases as the unit is disseminated to multiples and submultiples of the kilogram. The curve representing the estimated industrial needs is derived from the tightest requirements in legal metrology and contacts with customers.

1.4 Statistical Process Control

Statistical process control procedures are incorporated into the measurements to monitor the precision and accuracy of the calibration process and form the basis of the measurement assurance program for mass calibrations. Measurement assurance programs have been pioneered at NIST since the 1960s (20) with some concepts, such as check standards, dating back to the earlier days of NBS in 1926 (21). Such procedures have been applied to mass calibrations since 1979 (15). Only a brief summary is given below.

For each measurement series, the standard deviation In statistics, the average amount a number varies from the average number in a series of numbers.

(statistics) standard deviation - (SD) A measure of the range of values in a set of numbers. of the least-squares fit to the data is calculated and compared to the accepted standard deviation of the balance using F-test statistics (15). The accepted standard deviation of a balance is the pooled standard deviation Pooled standard deviation is a way to find a better estimate of the true standard deviation given several different samples taken in different circumstances where the mean may vary between samples but the true standard deviation (precision) is assumed to remain the same. based on a very large number of measurements collected over a long period of time. By monitoring the scatter scat·ter
v.
1. To cause to separate and go in different directions.

2. To separate and go in different directions; disperse.

3. To deflect radiation or particles.

n. of the data obtained in the weighing design measurements, the F-test monitors the precision of the measurement process. The validity of the F-test relies on the assumption that the scatter of the data is typical of the scatter obtained from previous measurements using the same balance. Control charts are maintained for all the balances used in the calibration services. For each series of measurements, the standard deviation is calculated and compared to the accepted value that is normally obtained from a pooled standard deviation of multiple measurements. Such control charts monitor the performance of the balance; for example, a con tinuously increasing standard deviation indicates a possible degradation of the balance.

Check standards are mass standards with known or "accepted" mass values. Check standards are incorporated into weighing designs; they are treated as unknowns and their masses are measured and compared to accepted values using T-test statistics. Monitoring the measured mass of an artifact of known mass monitors the accuracy of the measurement process. The validity of the T-test is based on the assumption that the mass of the check standard does not change from its accepted value.

Accepted values for the standard deviations of the balances and the check standards are obtained from yearly updates of control charts. More frequent updates are performed if judged necessary from any unusual results. A control chart for a particular check standard consists of the measured values as a function of time with a computed accepted value and statistical control limits. Control charts monitor the stability and/or drift of mass standards as well as abrupt changes that would indicate possible damage. Such control charts are maintained for check standards covering the full mass scale covered by the calibration services.

1.5 Facilities

Electronic mass comparators, fully and partially automated, are used for calibrations in the range from 1 mg to 10 kg, while mechanical balances are used to cover the range between 10 kg and 27 200 kg. Partial automation refers to the automation of the data collection from the comparators and from the transducers monitoring the environment, as well as the automatic analysis of the collected data; full automation also includes the remote operation of the comparators (22). The environmental conditions in the calibration laboratories are such that the relative humidity is set between 40 % and 50 % with variations of no more than 5 % per 24 h and the temperature is set between 20 [degrees]C and 22 [degrees]C with maximum variations of 0.5 [degrees]C over a period of 12 h. Electrostatic Stationary electrical charges in which no current flows. For example, laser printers and copier machines place a positive charge of the image on a drum, and negatively charged toner is attracted onto the drum. The toner is then transferred to positively charged paper and fused to the paper by heat. filters are used to insure proper cleanliness Cleanliness
See also Orderliness.

Cleverness (See CUNNING.)

Berchta

unkempt herself, demands cleanliness from others, especially children. [Ger. Folklore: Leach, 137]

cat

continually “washes” itself. with 97 % filtration efficiency.

A special area is dedicated to the calibration of large weights between 30 kg and 27 200 kg using mechanical balances. The temperature is maintained between 21 [degrees]C and 23 [degrees]C with maximum variations of 1.5 [degrees]C per 12 h. This special area was designed to allow for the receiving, handling, and shipping of large weights and lacks any humidity control Humidity control

Regulation of the degree of saturation (relative humidity) or quantity (absolute humidity) of water vapor in a mixture of air and water vapor. Humidity is commonly mistaken as a quality of air. .

A clean room facility with tight environmental control houses a state-of-the-art, fully automated and remotely operated 1 kg, 100 g, and 10 kg comparators. The environmental conditions are such that temperature is controlled to within 0.1 [degrees]C at a temperature between 20 [degrees]C and 22 [degrees]C and the temperature gradients temperature gradient
n.
The rate of change of temperature with displacement in a given direction from a given reference point.

temperature gradient are less than 0.1 [degrees]C over an elevation of 1 m. The relative humidity is controlled to within 2 % at a relative humidity between 45 % and 50 %. Cleanliness of class 1000 is accomplished with a HEPA HEPA
abbr.
1. high-efficiency particulate air

2. high-efficiency particulate arresting filtration system with 99.99 % efficiency for particles of size 0.5 [mu]m or larger.

NIST also maintains facilities for hydrostatic (10,11) and immersed (9) solid density measurements and for the characterization of the magnetic properties of mass standards (23).

1.6 Alternative Materials for Mass Standards

Efforts are currently underway to develop and manufacture alternative mass standards to minimize the uncertainty due to the buoyancy correction, the major contribution to the uncertainty. Two of the methods for minimizing this uncertainty are to minimize the difference in volume between the mass standard and unknown or perform measurements in vacuum. Since the behavior of mass standards under vacuum is not yet fully understood and is not practical as a dissemination method, methods to minimize the difference in volume have been investigated. This requires using a material whose density is close to that of platinum-iridium. Tungsten tungsten (tŭng`stən) [Swed.,=heavy stone], metallic chemical element; symbol W; at. no. 74; at. wt. 183.85; m.p. about 3,410°C;; b.p. 5,660°C;; sp. gr. 19.3 at 20°C;; valence +2, +3, +4, +5, or +6. with a density of 19 300 kg/[m.sup.3] satisfies this criteria and reduces the uncertainty associated with the air buoyancy correction to [approximately equal to] 1 [mu]g. At the time of publication of this paper, the possibility of machining a surface of tungsten to an average surface roughness of 100 nm using chemo-mechanical polishing techniques have been demonstrated [24]. Stabi lity tests of such artifacts is planned for the near future.

1.7 Characterization of the Surfaces of Mass Standards

In an effort to understand the stability of mass standards, we have characterized the surface roughness and profiles of our national prototype kilograms K4 and K79 using noncontact surface profiling and optical microscopy microscopy /mi·cros·co·py/ (mi-kros´kah-pe) examination under or observation by means of the microscope.

mi·cros·co·py
n.
1. The study of microscopes.

2. techniques. K4 and K79 are representatives of the two existing types of surface finish for primary platinum-iridium kilograms. K4 is one of the first 40 replicas made; it was hand polished. K79 is representative of the newer family of Pt-Ir kilograms manufactured at the BIPM turned using a diamond tool summary of the results is provided here. For a more detailed account of the work, see Ref. (25).

1.7.1 K4

K4 is one of two mass standards originally allocated to the United States. The second mass standard, K20, is the national standard of mass in the United States. Both K4 and K20 belong to the original group of 40 prototype kilograms. All 40 kilograms were manufactured from the same alloy and by the same process. It is believed that the surface of K4 is representative of the surfaces of the original national mass standards.

The machining lines on K4 are visible to the naked eye. In addition, a few scratches are notably present on the flat and cylindrical surfaces and have been historically reported (19). Optical microscope optical microscope

See under microscope. profiles reveal, in addition to the machining lines and numerous random scratches, wear lines due to usage on balance pans for period spanning over more than a century. These lines can be seen in Fig. 5 as short line-segments perpendicular to the machining lines. Using a white-light scanning interferometer interferometer: see interference under Interference as a Scientific Tool. See also virtual telescope.

An instrument that measures the wavelengths of light and distances. , we have measured average roughness values, [R.sub.a], ranging from 63 nm to 84 nm at different locations on the flat surfaces of K4 excluding the center. The repeatability in a single measurement location of the average roughness is 1 nm. A detailed mapping of the surface of K4 can be found in Ref. (25).

It is worth noting that in spite of the peculiar surface texture that K4 exhibits, its mass, relative to IPK, has only changed by 41 [mu]g between calibrations at the BIPM in 1889 and 1999. We are currently in the process of reexamining the surface of K4 after cleaning at the BIPM with the hope of shedding some light on the effects of cleaning on surface characteristics and possibly finding at least a qualitative correlation between changes in surface characteristics and changes in mass for platinum-iridium standards.

1.7.2 K79

K79 was acquired by NIST in 1996. It was manufactured at the BIPM in 1986 by turning with a diamond tool. To the naked eye, the surface of K79 looks very specular spec·u·lar
adj.
Of, resembling, or produced by a mirror or speculum.

specu·lar·ly adv.

Adj. 1. in comparison with K4. When K79 was placed under the microscope, the improved surface quality was obvious, yet, some peculiarities were found.

The surface roughness was measured with a phase-measuring microinterferometer. The average roughness, [R.sub.a], ranged from 10 nm to 15 nm at different locations on the flat surfaces of K79 with repeatability of 1 nm for a single measurement location.

In addition, the optical microscopy profiles show evidence of increasing grain size with increasing distance from the center, as shown in Fig. 6. The origin of this nonuniformity in grain size is still under investigation and is most likely attributed to the interaction between the platinum-iridium artifact and the diamond tool or to Pt-Jr material properties. Only a few wear marks were observed compared to the surface of K4.

While it is commonly believed that the prototype kilograms with improved surface properties obtained from diamond turning are more stable than the ones hand polished, long-term history is not yet available to support this hypothesis.

1.8 Current Efforts for an Alternative Definition of the Unit of Mass

Efforts to replace the artifact kilogram definition with one based on an invariant (programming) invariant - A rule, such as the ordering of an ordered list or heap, that applies throughout the life of a data structure or procedure. Each change to the data structure must maintain the correctness of the invariant. of nature have been ongoing for years and have been a challenge to the scientific community. These efforts are based on two approaches: mechanical electrical measurements Electrical measurements

Measurements of the many quantities by which the behavior of electricity is characterized. Measurements of electrical quantities extend over a wide dynamic range and frequencies ranging from 0 to 10¹² Hz. , and atom counting.

The mechanical electrical measurement approach, which uses what has become known as a "moving-coil watt balance The watt balance is an experimental electromechanical apparatus that may one day serve as the delineation of an electronic-based definition of the kilogram.

The watt balance is a more accurate version of the ampere balance, in which the force between two current-carrying ," is described in detail in this issue by Elmquist et al (26). The main concept is to compare a power measured mechanically in terms of the kilogram, meter, and second to the same power measured electrically using the Josephson and quantum Hall effects The quantum Hall effect is a quantum-mechanical version of the Hall effect, observed in two-dimensional electron systems subjected to low temperatures and strong magnetic fields, in which the Hall conductance . This links the kilogram to one of nature's time invariants, the Planck constant The Planck constant (denoted $\text{[math]}$ ) is a physical constant that is used to describe the sizes of quanta. h. One can thus consider defining the kilogram in such a way as to fix the value of h and to use a watt balance to implement the definition and to directly calibrate To adjust or bring into balance. Scanners, CRTs and similar peripherals may require periodic adjustment. Unlike digital devices, the electronic components within these analog devices may change from their original specification. See color calibration and tweak. standards of mass.

The atom counting approach aims at relating the mass of an atom to the kilogram. Within this framework, two paths can be taken:

a) Count the number of atoms in a macroscopic macroscopic /mac·ro·scop·ic/ (mak?ro-skop´ik) gross (2).

mac·ro·scop·ic or mac·ro·scop·i·cal
adj.
1. Large enough to be perceived or examined by the unaided eye.

2. object of known mass. This is the basis of the "silicon" project (27). The main concept is to relate the mass and volume of a i kg single crystal sphere of silicon, lattice (theory) lattice - A partially ordered set in which all finite subsets have a least upper bound and greatest lower bound.

This definition has been standard at least since the 1930s and probably since Dedekind worked on lattice theory in the 19th century; though he may not spacing of a unit cell of the silicon crystal, mean molar mass Molar mass, symbol M,^[1] is the mass of one mole of a substance (chemical element or chemical compound).^[2] It is a physical property which is characteristic of each pure substance. of the silicon atoms in the sphere, number of atoms in a unit cell, and the Avogadro constant The Avogadro constant (symbols: L, N_A), also called the Avogadro number is the number of "entities" (usually, atoms or molecules) in one mole,^[1]^[2] that is the number of carbon-12 atoms in 12 grams (0. . This approach determines the Avogadro constant and hence the mass of the carbon 12 atom in kilograms.

b) Buildup build·up also build-up
n.
1. The act or process of amassing or increasing: a military buildup; a buildup of tension during the strike.

2. a macroscopic object atom by atom while counting the number of atoms as they accumulate. In one approach currently being pursued, gold ions from an ion beam Noun 1. ion beam - a beam of ions moving in the same direction at the same speed
ionic beam

particle beam - a collimated flow of particles (atoms or electrons or molecules) are deposited on a target [28]. When the total current is measured in terms of the Josephson and quantum Hall effects, and the target is weighed, the result is a value of the Avogadro constant and again the mass of the carbon 12 atom in kilograms.

None of these approaches has been able to rival the present artifact definition yet. However, competing with the present definition requires achieving a minimum level of precision on the order of 1 X [10.sup.-8].

1.9 Conclusions

The instability and the continuous risks associated with the artifact definition have far reaching consequences. Any change in the kilogram directly affects other related base units, fundamental constants, and derived units such as density, force, and pressure. While the ultimate goal remains to replace the artifact definition with an invariant definition, a goal that is hopefully no longer far out of reach, artifact metrology remains an integral part of mass metrology. Understanding the stability of the artifact definition will, for the near future, remain a crucial factor since no matter how the unit will be realized in the future, the dissemination system will most likely rely on artifacts.

2. Force Metrology

2.1 The Unit of Force

The General Conference on Weights and Measures The General Conference on Weights and Measures is the English name of the Conférence générale des poids et mesures (CGPM, never GCWM). It is one of the three organizations established to maintain the International System of Units (SI) under the terms of the Convention (CGPM) ruled in 1901 that force is derived from the basic units of mass, length, and time. In 1960, the 11th CGPM adopted the newton as the unit of force in the International System of Units (SI), where one newton is the force required to accelerate a mass of one kilogram to one m/[s.sup.2], expressed in terms of SI base units as kg * m * [s.sup.-2]. At a given location, the force exerted by an object on its supporting structure can be computed from the mass of the object and the free fall acceleration of gravity acceleration of gravity
n. Abbr. g
The acceleration of freely falling bodies under the influence of terrestrial gravity, equal to approximately 9.81 meters (32 feet) per second per second. provided that there are no other vertical forces acting on the object.

Although force is a derived unit, it is of such importance that almost all of the national measurement institutes (NMIs) of the countries participating in the Treaty of the Meter maintain facilities for its realization and dissemination. Indeed, accurate force measurements are required in almost all industries. For example, such measurements are critical when testing mechanical structures such as bridges, buildings, aircraft, and medical prosthetics pros·thet·ics
n.
The branch of medicine or surgery that deals with the production and application of artificial body parts.

pros . Force measurements are required to calibrate the testing machines testing machine

Machine used in materials science to determine the properties of a material. Machines have been devised to measure tensile strength, strength in compression, shear, and bending (see strength of materials), ductility, hardness, impact strength ( used to evaluate the strength of materials strength of materials, measurement in engineering of the capacity of metal, wood, concrete, and other materials to withstand stress and strain. Stress is the internal force exerted by one part of an elastic body upon the adjoining part, and strain is the deformation , to assure quality control in production lines, to measure the thrust of engines, and to certify load cells used in weighing systems.

2.2 Force Realization at NIST

Over the range of 44 N to 4.448 MN, NIST realizes discrete static forces by suspending weights of known mass in a known gravity field. In addition, a hydraulic machine hydraulic machine, machine that derives its power from the motion or pressure of water or some other liquid. Hydraulic Engines

Water falling from one level to a lower one is used to drive machines like the water wheel and the turbine. capable of generating forces up to 53 MN is available for calibrating large capacity force transducers through comparison with secondary force transfer standards maintained by NIST.

2.2.1 The NIST Deadweight Machines

To cover the range of 44 N to 4.448 MN, NIST developed six deadweight machines in which discrete forces are generated by deadweights. The characteristics of these deadweight machines are given in Table 2. Th traceability of the primary force standards at NIST to the fundamental SI units (Système International d'Unites) A system of standard units of measurement finalized at the 14th General Conference on Weights and Measures in 1971. It is based on seven units of measure, including three from the MKS system (meter-kilogram-second), the ampere for is shown in Fig.7.

The deadweights of all NIST deadweight machines are made of stainless steel. This material was chosen because of its well-known long-term stability The long-term stability of an oscillator, the degree of uniformity of frequency over time, when the frequency is measured under identical environmental conditions, such as supply voltage, load, and temperature. . Moreover, the working mass standards used in the NIST Mass Laboratories to calibrate deadweights are also made of stainless steel. Therefore, the transfer errors associated with air buoyancy adjustments are minimized. The particular alloy used for each deadweight machine is listed in Table 2. The design principle involved in the three smallest and the larger NIST deadweight machines are shown in Figs. 8 and 9, respectively.

With the exception of the 27 kN (6.1 klbf) machine, the NIST deadweight machines are fully automated. Further, except for the 27 kN and the 4.448 MN machines, all are equipped with environmental chambers to allow for the characterization of load cells as a function of temperature in a range of -10[degrees]C to 40[degrees]C. Today all NIST deadweight machines are able to apply forces in ascending and descending Ascending and Descending is a lithograph print by the Dutch artist M. C. Escher which was first printed in March 1960.

The original print measures 14" x 11 1/4”. The lithograph depicts a large building roofed by a never-ending staircase. fashion. Originally, actuation ac·tu·ate
tr.v. ac·tu·at·ed, ac·tu·at·ing, ac·tu·ates
1. To put into motion or action; activate: electrical relays that actuate the elevator's movements.

2. of the deadweights of the 113 kN and 2.2 kN deadweight machines was such that the weight frame needed to be unloaded from the device under test, permitting only return-to-zero loading sequences [29]. During the automation of the force laboratory in 1989, this limitation was overcome by installing pneumatically pneu·mat·ic   also pneu·mat·i·cal
adj.
1. Of or relating to air or other gases.

2. Of or relating to pneumatics.

3.
a. Run by or using compressed air: a pneumatic drill. operated stabilizing mechanisms on these two machines, enabling their deadweights to be changed while the frame is loaded without incurring either excessive wear on the deadweight seats or swinging of the weight frame. These mechanisms retract TO RETRACT. To withdraw a proposition or offer before it has been accepted.
     2. This the party making it has a right to do is long as it has not been accepted; for no principle of law or equity can, under these circumstances, require him to persevere in it. from the weight frame shafts after each deadweight change. Ascending and descending force sequences can now be applied in these machines. The automation of the NIST deadweight machines has been fully described in Ref. (30).

2.2 kN (505 lbf) Deadweight Machine

Air-powered cylinders manipulate lifting bars that allow the individual deadweights to be applied or removed from the main shaft of the machine at any time during the measurement.

27 kN (6.1 klbf) Deadweight Machine

Hydraulic cylinders Hydraulic cylinders (also called linear hydraulic motors) are mechanical actuators that are used to give a linear force through a linear stroke. Operation
Hydraulic cylinders get their power from pressurized hydraulic fluid, which is typically oil. raise and lower the deadweights individually onto the main shaft, usually only while the machine is in the unloaded position. When the required deadweight complement is selected, the main shaft is positioned to allow force application to the unit-undertest. Limited ascending and descending loading is possible in this machine under special circumstances special circumstances n. in criminal cases, particularly homicides, actions of the accused or the situation under which the crime was committed for which state statutes allow or require imposition of a more severe punishment. . A unique feature of this deadweight machine is that nominal metric forces can be applied by activating an auxiliary deadweight set. This deadweight machine is operated manually.

113 kN (25.3 klbf) Deadweight Machine

Each deadweight is positioned by a pair of hydraulic cylinders. These cylinders allow application or removal of the deadweight to the main shaft at any time. A manually placed set of auxiliary metric conversion deadweights is available for this machine, which produces nominal forces in 4.903 kN increments up to 107.873 kN. These conversion deadweights are used only in nonautomated measurements.

498 kN (112 klbf) Deadweight Machine

Calibration forces are generated in this machine by serially applying deadweights from two different stacks. The minimum force is 13.3 kN (3000 lbf) which consists of the calibrated frame and main shaft of the machine and is always included as the first applied force. All other applied forces must be added to this minimum. The main stack consists of ten 44.4 kN (1000 lbf) deadweights. The second stack consists of nine 4.44 kN (1000 lbf) deadweights. The deadweights are removed or added to the minimum 13.3 kN (3000 lbf) frame in increments of 4.44 kN (1 000 lbf). An examination of the available deadweight combinations reveals that in some cases it is necessary to unload To remove a program from memory or take a tape or disk out of its drive. part of the small stack in order to reach a particular ascending ascending /as·cend·ing/ (ah-send´ing) having an upward course.

ascending

progressing to higher levels, usually used in reference to the nervous system. force without first overshooting Overshooting

The tendency of a pool of MBS to reflect an especially high rate of prepayments the first time it crosses the threshold for refinancing, specially if two or more years have passed since the date of issue without the weighted average coupon of the pool crossing the it.

1.33 MN (300 000 lbf) Deadweight Machine

All deadweights in this machine are applied sequentially with no further individual manipulation possible. The deadweights are of three different sizes. There are thirteen 44 kN (10 klbf) deadweights, four 89 kN (20 klbf) deadweights and three 133 kN (30 klbf) deadweights. This arrangement allows the sequential calibration in ten equally spaced increments of nominal 444 kN (100 klbf), 890 kN (200 klbf), and 1.33 MN (300 klbf) force transducers.

4.45 MN (1 000 000 lbf) Deadweight Machine

This deadweight machine simply applies twenty 222 kN (50 000 lbf) forces sequentially. The main lifting frame raises hydraulically to pick up additional deadweights in the stack. This machine has been fully automated.

2.2.2 Weight Adjustment

When the force laboratory was built in 1965 the force measurement unit in English speaking countries was the pound force (lbf). Accordingly, in 1965, a decision was made to adjust the mass of the weights of the deadweight machines to exert nominal pound forces; the standard pound force being defined as the force acting on a one-pound mass in a gravitational field for which the acceleration of free fall is 9.80665 m/[s.sup.2]. The actual mass required to produce a nominal force was computed from the following equation:

F = mg/9.80665 m/[s.sup.2](1-[[rho].sub.a]/[[rho].sub.w]), (9)

where F is the generated standard pound force, m is the mass of the weight in lb, g is the local acceleration of free fall at the elevation of the center of gravity of the weight in m/[s.sup.2] [[rho].sub.a] is the air density, and [[rho].sub.w] is the density of the weight material. The uncertainties in the determination of m, [[rho].sub.a], and g are the principal sources of uncertainty in the realized force.

The mass of each weight of the NIST deadweight machines was determined in the Mass Laboratories of the National Bureau of Standards (NBS), the predecessor of NIST. These calibrations were performed in 1965 prior to the assembly of the deadweights in the machines. Over the years some of the deadweights were recalibrated in the Mass Laboratories.

The 498 kN deadweight machine was partially disassembled in 1971, and again in 1979 and in 1989, with most of its deadweights removed and recalibrated each time. Any changes in the mass of the deadweights of the small and large weight stacks were well within the assigned uncertainties. The 2.2 kN deadweight machine was completely refurbished in 1996, and all of its deadweights were removed and recalibrated at that time; the changes in the mass of the weights were again well within the stated uncertainties. The results of the recalibration of the weights indicate that, as expected, the alloys used in both the smaller and larger NIST deadweight machines are very stable over time.

For each of the larger machines, the value of g was estimated at the approximate center of gravity of the major components and at the center of gravity of the deadweight stacks. The gravity reference is located on the concrete slab Concrete slab

A shallow, reinforced-concrete structural member that is very wide compared with depth. Spanning between beams, girders, or columns, slabs are used for floors, roofs, and bridge decks. in Room 129 of the first floor of Building 202 at the NIST site in Gaithersburg, MD, where the deadweight machines are located. A second site located in the basement of the same room, approximately 9 m laterally and 2.2 m below the first site, was chosen to establish a permanent reference point for absolute determination of the acceleration of free fall by gravity meter Noun 1. gravity meter - a measuring instrument for measuring variations in the gravitational field of the earth
gravimeter

measuring device, measuring instrument, measuring system - instrument that shows the extent or amount or quantity or degree of something measurements. The assigned value of g at this location is (9.801018 [+ or -] 5 X [10.sup.-6]) m/[s.sup.2], this value is based upon an absolute determination conducted by Tate in 1965. All other gravity values are based upon a gravity gradient Noun 1. gravity gradient - a gradient in the gravitational forces acting on different parts of a nonspherical object; "the gravity gradient of the moon causes the ocean tides on Earth"
gradient - a graded change in the magnitude of some physical quantity or dimension of -0.000003 m/[s.sup.2] per meter elevation [31]. Subsequent gravity surveys conducted at several locations within the force laboratory by the National Oceanic and Atmospheric Administration Noun 1. National Oceanic and Atmospheric Administration - an agency in the Department of Commerce that maps the oceans and conserves their living resources; predicts changes to the earth's environment; provides weather reports and forecasts floods and hurricanes and confirmed the results obtained in 1965, and tied the measured values to the National gravity base.

During a year, the air density at the Gaithersburg site may vary over a range of 1.145 kg/[m.sup.3] to 1.226 kg/[m.sup.3]. In 1965, when the facility was built, a decision was made to use an average yearly value of air density equal to 1.185 kg/[m.sup.3].

2.2.3 Uncertainty in the Forces Realized by Deadweights

The relative combined standard uncertainties of the forces realized by the deadweight machines over the range of 44 N to 4.448 MN incorporate the uncertainties associated with the determination of the mass of the deadweights, the acceleration due to gravity Acceleration due to gravity can refer to:

Gravitational acceleration, the acceleration due to the gravitational attraction of massive bodies, in particular that due to the Earth's gravity
Standard gravity, or g

, and the air density as follows:

(a) The relative standard uncertainty in the determination of the mass of the deadweights, [u.sub.wa]<0.0003%.

(b) The maximum uncertainty caused by the use of an average air density. This is the largest systematic uncertainty in the applied force and is equal to 0.0005 %. The estimated relative standard uncertainty, assuming a rectangular probability distribution Probability distribution

A function that describes all the values a random variable can take and the probability associated with each. Also called a probability function.

probability distribution , is [u.sub.wb] [approximately equal to] 0.0003 %.

(c) The relative standard uncertainty associated with the variation in the acceleration of free fall with height, assuming a rectangular probability distribution, is [u.sub.wc] [less than or equal to] 0.0001 %.

The combined standard uncertainty in the force realized by deadweight application is computed as

[u.sub.w] = [square root of ([u.sup.2.sub.wa]+[u.sup.2.sub.wb]+[u.sup.2.sub.wc])]. (10)

using the values listed in (a), (b), and (c) above yields combined relative standard uncertainty in the realize force [u.sub.w] = 0.0005 % [32].

2.3 Comparison Force Calibration

Above 4.448 MN, NIST provides compression calibrations up to 53 MN by comparison with NIST transfer standard strain gage Strain gage

A device which measures mechanical deformation (strain). Normally it is attached to a structural element, and uses the change of electrical resistance of a wire or semiconductor under tension. Capacity, inductance, and reluctance are also used. load cells using a 53 MN capacity universal testing machine A Universal Testing Machine is used to test the tensile and compressive properties of materials. Such machines generally have two columns but single column types are also available. shown schematically sche·mat·ic
adj.
Of, relating to, or in the form of a scheme or diagram.

n.
A structural or procedural diagram, especially of an electrical or mechanical system. in Fig. 10 [33]. For this purpose, NIST maintains a set of three 4.448 MN NIST transfer standards, each calibrated the 4.448 MN deadweight machine, and a set of four 13 MN transfer standards each calibrated by comparison with three 4.448 MN transfer standards. In the range of 4.5 MN to 13 MN, three 4.448 MN transfer standards loaded in parallel are used, as shown in Fig. 11. The resulting standard uncertainty, computed by combining in quadrature quadrature, in astronomy, arrangement of two celestial bodies at right angles to each other as viewed from a reference point. If the reference point is the earth and the sun is one of the bodies, a planet is in quadrature when its elongation is 90°. the uncertainties contributed by each of the three transfer standards, is estimated at 1.7 kN, constant over the interval. Thus, the relative standard uncertainty ranges from 0.038 % at 4.5 MN to 0.013 % at 13 MN. From 13 MN to 40 MN, three 13 MN transfer standards are used. The resulting standard uncertainty is estimated at 5 kN, constant over the interval, with relativ e standard uncertainties ranging from 0.038 % at 13 MN to 0.013 % at 40 MN. From 40 MN to 53 MN, four 13 MN transfer standards are used resulting in an estimated standard uncertainty of 5.9 kN, and a relative standard uncertainty ranging from 0.015 % at 40 MN to 0.011 % at 53 MN.

The standard uncertainty, in both absolute and relative terms, in the forces realized at NIST over the entire range of 44 N to 53 MN is shown in Fig. 12.

2.4 Instrumentation

2.4.1 Deadweight Machine Control Instrumentation

As mentioned previously, except for the 27 kN deadweight machine, all NIST deadweight machines have been instrumented for automated control. With the exception of the mounting and positioning of the force sensor into the deadweight machine, all machine operations can be done under computer control. Details of the automation have been described elsewhere (30). A force measurement system has two components: a sensing component normally called a transducer, and an indicating component, called an indicator. For example, if the transducer is a proving ring, the transducer's response, that is the change in diameter as the ring distorts under an applied force, is indicated by a vibrating reed Noun 1. vibrating reed - a vibrator consisting of a thin strip of stiff material that vibrates to produce a tone when air streams over it; "the clarinetist fitted a new reed onto his mouthpiece"
reed and a spherical spher·i·cal
adj.
Having the shape of or approximating a sphere; globular. button mounted on the end of a micrometer micrometer (mīkrŏm`ətər, mī`krōmē'tər).

1 Instrument used for measuring extremely small distances. . For strain gage load cells, the change in strain along the surface of the sensing element is indicated by a change in the output signal relative to the voltage applied to the load cell bridge. Only the reading of load cell indicators has been automated. Accordingly, me asurements on proving rings are performed manually while measurements of most load cells are performed automatically.

The benefits derived from the automation implemented in the Force Laboratories are numerous. They include the ability to perform measurements with complex loading sequences, precise control of the loading time In airlift operations, a specified time, established jointly by the airlift and airborne commanders concerned, when aircraft and loads are available and loading is to begin. intervals, and more consistent indicator readings. In addition, evaluations of prototype load cells involve the determination of the effects of environmental factors on load cell characteristics. For some of these tests positioning of the load cell in the deadweight machine is required only once, at the beginning of a test. The associated equipment required for these environmental tests Environmental tests are used to verify a piece of equipment can withstand the rigors of harsh environments, for example:

extremely high and low temperatures
large, swift variations in temperature
blown and settling sand and dust
salt spray and salt fog

has also been automated. Thus, the thermal bath For the use of the term in thermodynamics and statistical mechanics, see .

A thermal bath is a warm body of water. It is often referred to as a spa, which is traditionally used to mean a place where the water is believed to have special health-giving properties, units used to heat and cool the environmental chamber, and the sensors used to monitor conditions within the chamber, including the temperature of the load cell, are also under computer control. These tests, which typically take several days, can thus be conducted around the clock without any manual intervention.

2.4.2 Voltage Ratio Instrumentation

The force applied to a load cell produces a change in the resistive resistive /re·sis·tive/ (re-zis´tiv) pertaining to or characterized by resistance. unbalance in the load cell strain gage bridge. For most load cell measurements performed at NIST, this resistive bridge unbalance is measured with a calibrated NIST voltage-ratio indicating system. The NIST indicating system supplies direct current excitation excitation

Addition of a discrete amount of energy to a system that changes it usually from a state of lowest energy (ground state) to one of higher energy (excited state). For example, in a hydrogen atom, an excitation energy of 10. to the load cell, through the use of a specially built power supply which applies DC voltages to the load cell excitation input leads of [+ or -] 5 V relative to the load cell ground wire, yielding a 10 V difference between the leads. This excitation voltage is stable to within [+ or -]5 mV over a time period of 15 s. The power supply was designed to switch internally the wires going to the load cell terminals by means of a computer command, thus reversing the polarity (1) The direction of charged particles, which may determine the binary status of a bit.

(2) In micrographics, the change in the light to dark relationship of an image when copies are made. of the excitation signal to the load cell. This action makes it possible to cancel out Verb 1. cancel out - wipe out the effect of something; "The new tax effectively cancels out my raise"; "The `A' will cancel out the `C' on your record"
wipe out small thermal biases in the strain-gage bridge and connecting wires, as well as any zero offsets in the rest of the indicating system. The switching is not done if the load cell is not designed to accommodate reversed polarity excitation. The excitation voltage and the load cell output voltage are sampled simultaneously by an 8.5 digit computing voltmeter operating in the voltage-ratio mode; the voltmeter calculates the corresponding voltage ratio internally and returns that value in digital form to the computer. The voltmeter is read several times, with the excitation voltage polarity reversed between readings; the final voltage ratio is taken as the average of the voltage ratios measured at each polarity. The sampling time at each polarity, and the delay after switching polarity before resuming the sampling, are specified by the operator through the computer control/acquisition program. A typical time for one complete voltage ratio reading is 10 s. This time can be shortened or lengthened length·en
tr. & intr.v. length·ened, length·en·ing, length·ens
To make or become longer.

lengthen·er n. as appropriate for the measurement being conducted. Calibration of the voltmeters in the voltage-ratio mode is done by providing calibrated DC voltage signals simultaneously to both inputs, with the DC calibrated signals derived from a 10 V Josephson junction An ultra-fast switching technology that uses superconductor materials, originally conceived by Brian Josephson. Circuits are immersed in liquid helium to obtain near-absolute zero degrees required for operation. Switching takes place in a few picoseconds. reference voltage array maintained by the Electricity Division of the NIST Electronics and Electrical Engineering electrical engineering: see engineering.

electrical engineering

Branch of engineering concerned with the practical applications of electricity in all its forms, including those of electronics. Laboratory. The NIST Electricity Division calibrates the Force Laboratories voltmeters each year. In the Force Laboratories the calibration of all voltmeters is maintained by monthly comparison with the voltmeter most recently calibrated by the Electricity Division. This is accomplished through the use of two devices: a precision voltage reference A voltage reference is an electronic device (circuit or component) that produces a fixed (constant) voltage irrespective of the loading on the device, power supply variation and temperature. divider divider

See European currency quotation. having a 100:1 ratio and a load cell simulator that is stable to within [+ or -]5 nV/V over a 24 h time interval.

2.4.3 Uncertainty in Voltage Ratio Measurement

The standard uncertainty associated with the digital voltmeters Noun 1. digital voltmeter - an electronic voltmeter that gives readings in digits
alphanumeric display, digital display - a display that gives the information in the form of characters (numbers or letters) used in the NIST Force Laboratories for voltage-ratio measurement arises from the following:

(a) The uncertainty in calibration of the voltage-ratio of the voltmeters as determined by the NIST Electricity Division using a Josephson junction voltage array as a primary standard; the relative standard uncertainty in the voltage ratio over the range from 1 mV/V to 10 mV/V is

[u.sub.va] [less than or equal to] 0.0002 %.

(b) Differences between voltmeter calibrations performed by the NIST Electricity Division and comparisons to a 10 mV/V reference ratio obtained with a precision reference divider used in the Force Laboratories to track the voltmeter drift. The estimated relative standard uncertainty of these differences is [u.sub.vb] [approximately equal to] 0.0003 %.

(c) The repeatability in measurements for each voltmeter (made at one-month intervals) of the 10 mV/V response relative to the precision reference divider; the relative standard uncertainty for an individual voltmeter is [u.sub.vc] = 0.0003 % of the reference ratio.

(d) The non-linearity in the voltage-ratio measurement response of the voltmeters in the range of 1 mV/V to 10 mV/V; the estimated relative standard uncertainty based on Electricity Division data is [u.sub.vd] [approximately equal to] 0.0001 % of the reference ratio.

The combined standard uncertainty in the voltageratio instrument is given by:

[u.sub.v] = [square root of ([u.sup.2.sub.va] + [u.sup.2.sub.vb] + [u.sup.2.sub.vc] + [u.sup.2.sub.vd])]. (11)

Inserting the values given above yields a relative standard uncertainty for the voltage ratio of about 0.0005 %.

2.5 Procedures

The forces realized at NIST are disseminated to industry, government, and the research community through the force calibration services that NIST provides. The objective in calibrating a force sensor is to determine the functional relationship between the applied load and the sensor response. In the Force Laboratory, this is accomplished by applying a series of well-known forces to the sensor and observing its response on a readout (1) A small display device that typically shows only a few digits or a couple of lines of data.

(2) Any display screen or panel. instrument. Many force sensors can be calibrated in both tension and compression modes with the responses expected to be somewhat different in each mode. Due to hysteresis hysteresis (hĭs'tərē`sĭs), phenomenon in which the response of a physical system to an external influence depends not only on the present magnitude of that influence but also on the previous history of the system. effects, the response may also depend on whether the loads are applied in ascending or descending order. Accordingly, for any one sensor, there may be several distinct calibration curves In analytical chemistry, a calibration curve is a general method for determining the concentration of a substance in an unknown sample by comparing the unknown to a set of standard samples of known concentration. .

Force calibrations at NIST are usually performed according to according to
prep.
1. As stated or indicated by; on the authority of: according to historians.

2. In keeping with: according to instructions.

3. the procedures specified by the American Society for Testing and Materials (ASTM ASTM
abbr.
American Society for Testing and Materials ) Standard Practice E74 (34). A minimum of 30 forces are applied during the course of each calibration. These forces are applied in two or more calibration runs with typically three positions of the sensor in the deadweight machine to minimize the machine-sensor interactions (35-36). The applied forces are selected at approximately every 10 % increment To add a number to another number. Incrementing a counter means adding 1 to its current value. over of the entire calibration range. Upon request, a device may be calibrated by modified procedures tailored to meet particular end uses. For example, additional loads may be added, and the loading sequence may include both ascending and descending loads to thoroughly characterize the hysteresis of the force transducer. To obtain the actual response of the transducer, the indicator reading observed during a force application is corrected for the reading observed without any force application. The calibration curve is d erived by fining a polynomial polynomial, mathematical expression which is a finite sum, each term being a constant times a product of one or more variables raised to powers. With only one variable the general form of a polynomial is a₀xⁿ+a to the data using the method of least squares Noun 1. method of least squares - a method of fitting a curve to data points so as to minimize the sum of the squares of the distances of the points from the curve
least squares . The calibration curve is of the form:

D = [A.sub.0] + [SIGMA] [A.sub.i] [F.sup.i], (12)

where D is the response, F is the applied force, [A.sub.i] are the coefficients yielded by the least-squares fit and the summation is usually carried to an order of two or three.

ASTM E 74-95 (34) specifies a standard deviation that is calculated from the differences between the values observed during the course of calibration and the corresponding values computed from the calibration curve. This standard deviation is given by:

s = [square root of ([SIGMA][d.sup.2.sub.j]/(n-m))]' (13)

where s is the standard deviation, the [d.sub.j] are the differences between the measured and calculated deflections, n is the number of measured deflections, and m is the number of degrees of freedom in the polynomial, which is the degree of the polynomial plus one. This standard deviation is one of the terms used in estimating the combined uncertainty as reported in the NIST calibration reports where it is denoted as [u.sub.r]. The uncertainties contained in [u.sub.r] are ordinarily much greater than the uncertainty in the applied load. The two major sources of systematic errors are mechanical misalignment mis·a·ligned
adj.
Incorrectly aligned.

misa·lignment n. and load-time effects (35,36). Complex mechanical interactions between the force sensor and the deadweight machine can cause bending, shear, and torsional tor·sion
n.
1.
a. The act of twisting or turning.

b. The condition of being twisted or turned.

2. loads to act in combination with the precisely known vertical force. In addition, the transducer response is also dependent upon the load history. A detailed statistical analysis that yields separate estimates of uncertainty arising from various possibl e sources of error can be found in Ref. (37).

The combined standard uncertainty stated in NIST force calibration reports is computed using the following equation:

[U.sub.c] = [square root of ([u.sup.2.sub.w]+[u.sup.2.sub.v]+[u.sup.2.sub.r])]. (14)

where [U.sub.c] is the, combined standard uncertainty as defined in Ref. (17), [u.sub.w] is the standard uncertainty of the applied deadweight, [u.sub.v] is the standard uncertainty of the calibration of the voltage-ratio measurement instrumentation, and [u.sub.r] is the standard deviation calculated accordingly to ASTM E 74-95. It should be noted that the term [u.sub.r] applies only in calibrations involving voltage-ratio measurements performed using the NIST voltmeters.

In addition to performing calibrations, the Force Laboratory performs pattern evaluation tests of load cells used in weighing systems, which provide the basis for the classification by weights and measures officials of load cell families used in weighing systems. These tests are performed in accordance with the specifications of the National Conference of Weights and Measures Publication 14 [38], and a similar international standard, OIML OIML Organisation Internationale de Métrologie Légale (International Organization of Legal Metrology) R60 [39], adopted by the International Organization of Legal Metrology The International Organization of Legal Metrology or Organization Internationale de Métrologie Légale (OIML) is an intergovernmental treaty organization. It is made up of approximately 60 nations from around the world. [1]. . While there are some differences between the national and international standards, they are minimal. Both procedures prescribe deadweight loading tests of prototype load cells for the linearity, hysteresis, repeatability, and creep over a temperature range of u10 [degrees]C to 40 0C. In addition, both require that canister load cells be tested for atmospheric pressure atmospheric pressure
or barometric pressure

Force per unit area exerted by the air above the surface of the Earth. Standard sea-level pressure, by definition, equals 1 atmosphere (atm), or 29.92 in. (760 mm) of mercury, 14.70 lbs per square in., or 101. sensitivity over a range of 95kPato 105 kPa.

2.6 Current Force Metrology Research

Two main efforts are now underway at NIST in the area of force metrology. They include:

a) The development of a research laboratory for the realization, measurement and repeatable dissemination of very small forces (in the micro- and nano-newton range) to address the emergent emergent /emer·gent/ (e-mer´jent)
1. coming out from a cavity or other part.

2. pertaining to an emergency.

emergent

1. coming out from a cavity or other part.

2. coming on suddenly. force measurement needs of a growing class of nanotechnologies, including atomic microscopes, nanoindentors, and micro-electromechanical systems (MEMS (MicroElectroMechanical Systems) Tiny mechanical devices that are built onto semiconductor chips and are measured in micrometers. In the research labs since the 1980s, MEMS devices began to materialize as commercial products in the mid-1990s. ); and

b) The development of a testing facility to assess the susceptibility of digital load cells to electromagnetic radiation electromagnetic radiation, energy radiated in the form of a wave as a result of the motion of electric charges. A moving charge gives rise to a magnetic field, and if the motion is changing (accelerated), then the magnetic field varies and in turn produces an .

Acknowledgments

The authors gratefully acknowledge the dedication of T. Bartel, K. Chesnutwood, W. Crupe, S. Ho, J. Keller, L. Martinez, and R. Seifarth in providing measurement services of the highest quality to the U.S. Government and industry. Z. J. J. gratefully acknowledges V. Lee for the automation of the balances and M. C. Croarkin of the Statistical Engineering Division of the NIST Information Technology Laboratory for her invaluable contributions to the development and implementation of statistical process control procedures.

About the authors: Zeina J. Jabbour joined the Physics Laboratory at NIST in 1994 as a National Research Council Postdoctoral post·doc·tor·al   also post·doc·tor·ate
adj.
Of, relating to, or engaged in academic study beyond the level of a doctoral degree.

Noun 1. fellow. She is currently the Leader of the Mass and Force Group of the Manufacturing Metrology Division in the Manufacturing Engineering Manufacturing engineering

Engineering activities involved in the creation and operation of the technical and economic processes that convert raw materials, energy, and purchased items into components for sale to other manufacturers or into end products for Laboratory at NIST Simone L. Yaniv served as the Leader of the Force Group from August 1986 through October 2000. She served as the senior program analyst in the Director's Office of the Manufacturing Engineering Laboratory from 1994 to 1995, and as the Deputy Chief of the Automated Production Technology Division, the predecessor of the Manufacturing Metrology Division, from 1995 to 1998. She is now retired.

3. References

(1.) L. V. Judson, Weights and measures standards of the United States, a brief history, NBS Spec. Pub. 447 (1963) updated (1976).

(2.) H. P. Chester and P. Vigoureux, eds, The International Bureau of Weights and Measures The International Bureau of Weights and Measures is the English translation of the name of the Bureau international des poids et mesures (BIPM), a standards organisation, one of the three organisations established to maintain the International System of Units (SI) 1875-1975, NBS Spec. Pub. 420 (1975).

(3.) H. E. Almer, National Bureau of Standards kilogram balance NBS no. 2, J. Res. Natl. Bur. Stand. (U.S) 76C, 1-10 (1972).

(4.) Girard G., The third periodic verification of national prototypes of the kilogram (1988-1992), Metrologia 31, 317-336 (1994).

(5.) Girard G., The washing and cleaning of kilogram prototypes at the BIPM, BIPM (1990).

(6.) BIPM, Proc.-Verb. Com. Int. Poids Mesures 57, 15-17 (1989).

(7.) Z. J. Jabbour, Effects of cleaning on mass standards, manuscript in preparation.

(8.) R. S. Davis, Equation for the determination of the density of moist air (1981/91), Metrologia 29, 67-70 (1992).

(9.) R. M. Schoonover and R. S. Davis, Quick and accurate density determination of laboratory weights, Proc. 8th conf. IMEKO IMEKO International Measurement Confederation (Budapest, Hungary)  Tech. Comm See comms. . TC3 (1980).

(10.) H. A. Bowman and R. M. Schoonover, Procedure for high-precision density determinations by hydrostatic weighing, J. Res. Natl. Bur. Stand. (U.S.) 71C (3), 179-198 (1967).

(11.) H. A. Bowman, R. M. Schoonover, C. L. Carroll, The utilization of solid objects as reference standards in density measurements, Metrologia 10, 117-121 (1974).

(12.) R. D. Deslattes, Proceedings of course LXVIII Metrology and Fundamental Constants, Summer School of Physics--Enrico Fermi, Varenna Italy (1976), Soc. Italiana di Fisica, Bologna Bologna (bōlô`nyä), city (1991 pop. 404,378), capital of Emilia-Romagna and of Bologna prov., N central Italy, at the foot of the Apennines and on the Aemilian Way. , 38-113 (1980).

(13.) R. S. Davis, Private Communication.

(14.) R. S. Davis, Note on the choice of a sensitivity weight in precision weighing, J. Res. Natl. Bur. Stand. (U.S.) 92 (3), 239-242 (1987).

(15.) J. M. Cameron, M. C. Croarkin, and R. C. Raybold, Designs for the calibration of standards of mass, NBS Tech. Note 952 (1977).

(16.) R. N. Varner, R. C. Raybold, National Bureau of Standards mass calibrations andomputer software, NBS Tech. Note 1127 (1980).

(17.) Guide to the expression of uncertainty in measurement, ISO (1993).

(18.) M. C. Croarkin, An extended error model for comparison calibration, Metrologia 26, 107-113 (1989).

(19.) R. S. Davis, Recalibration of the U.S. national prototype kilogram, J. Res. Natl. Bur. Stand. (U.S.) 90 (4), 263-283 (1985).

(20.) P. E. Pontius, J. M. Cameron, Realistic uncertainties and the mass measurement process, NBS Monogr. 163, (1979).

(21.) A. T. Pienkowsky, Short tests for sets of laboratory weights, Sci. papers Bur. Stand. (S-527) 21, 65-93 (1926).

(22.) V. Lee, Technical Documentation for the Mass Calibration Laboratory Balance Automation, NISTIR NISTIR National Institute of Standards and Technology Interagency Report
NISTIR National Institute of Standards and Technology Internal Report 6283 (1999).

(23.) R. S. Davis, Determining the magnetic properties of 1 kg mass standards, J. Res. Natl. Inst. Stand. Technol. 100 (3), 209-225 (1995).

(24.) E. Paul, Private Communication.

(25.) Z. J. Jabbour and C. J. Evans, Surface roughness and profiles of platinum-iridium prototype kilograms, manuscript in preparation.

(26.) R. E. Elmquist, M. E. Cage, Y. T. Tang tang, in zoology
tang: see butterfly fish. , A. Jeffery, J. R. Kinard R. F. Dziuba, N. M. Oldham, and E. R. Williams, The Ampere and Electrical Standards, J. Res. Natl. Inst. Stand. Technol. 000 (2001).

(27.) P. Seyfried and P. Becker, The role of NA in the SI: an atomic path to the kilogram, Metrologia 31, 167-172 (1994).

(28.) M. Glaeser, Proposal for a novel method of precisely determining the atomic mass Unit atomic mass unit or amu, in chemistry and physics, unit defined as exactly 1-12 the mass of an atom of carbon-12, the isotope of carbon with six protons and six neutrons in its nucleus. One amu is equal to approximately 1. by the accumulation of ions, Rev. Sci. Instrum. 62, 2493-2494 (1991).

(29.) R. A. Mitchell, Force Calibration at the National Bureau of Standards, NBS Technical Note 1227, U.S. Department of Commerce, National Bureau of Standards, Gaithersburg, MD (1986).

(30.) K. W. Yee, Automation of Strain Gage Load Cell Force Calibrations, Proc. 1992 Natl. Conf. of Stand. Lab. Workshop and Symposium, Washington, DC (1992) pp. 387-391

(31.) R. D. Tate, Acceleration Due to Gravity at the National Bureau of Standards, J. Res. Natl. Bur. Stand. (U.S.) 72(1), 1-20(1967).

(32.) T. W. Bartel, S. L. Yaniv, and R. L. Seifarth, Force Measurement Services at NIST: Equipment, Procedures, and Uncertainty, 1997 Natl. Conf. of Stad. Lab. Workshop and Symposium (1997) pp. 421-431

(33.) A. F. Kirkstein, Universal Testing Machine of 12-Million lbf Capacity at the national Bureau of Standards, Spec.Pub. 355 (1971).

(34.) ASTM E 74-95, Standard Practice of Calibration of Force-Measuring Instruments for Verifying the Force Indication of Testing Machines, ASTM Annual Book of ASTM Standards, Volume 03.01 (1996).

(35.) R. A. Mitchell and P. E. Pontius, Inherent Problems in Force Measurement, Exper. Mech. 22, 81-88 (1982).

(36.) M. Peters, A. Sawla, and D. Pesehel, Uncertainty in Force Measurement, Report of the CCM CCM Contemporary Christian Music
CCM Critical Care Medicine
CCM County College of Morris (New Jersey)
CCM Chama Cha Mapinduzi (political party, Tanzania)
CCM CORBA Component Model Working Group Force, PTBTericht MA-17 (1990).

(37.) C.P. Reeve REEVE. The name of an ancient English officer of justice, inferior in rank to an alderman.
     2. He was a ministerial officer, appointed to execute process, keep the king's peace, and put the laws in execution. , A Statistical Model for the Calibration of Force Sensors, NBS Technical Note 1246, (1988).

(38.) NIST handbook 44, Specifications, Tolerances, and Other Technical Requirements for Weighing and Measuring Devices This is an incomplete list of measuring devices.

word Measures
accelerometer acceleration
actinometer heating power of sunlight
alcoholometer alcoholic strength of liquids
altimeter altitude
ammeter electric current, amperage , (1999).

(39.) International Organization for Legal Metrology R60, Metrological Regulations for Load Cells, Bureau International for Legal Metrology, Paris, France (1991).

[Figure 1 omitted]

[Figure 4 omitted]

[Figure 7 omitted]

[Figure 12 omitted]

Table 1.

Year of calibration and masses reported by BIPM for the U.S. prototypes

Year        K20              K4

1889  1 kg - 0.039 mg  1 kg - 0.075 mg
1937  1 kg - 0.021 mg
1948  1 kg - 0.019 mg
1984  1 kg - 0.022 mg  1 kg - 0.106 mg
1992  1 kg - 0.021 mg
1999  1 kg - 0.039 mg  1 kg - 0.116 mg
Table 2.

Characteristics of the six NIST deadweight machines

Capacity,
 kN                         2.2      27     113     498   1334    4448
 (klbf)                   (0.505)  (6.1)   (25.3)  (112)  (300)  (1000)

Min. load,
 kN                        0.044    0.44    0.89    13     44     222
 (klbf)                   (0.01)   (0.1)   (0.2)    (3)   (10)    (50)
Min. increment
 kN                        0.022    0.22    0.44    4.4    44     222
 (klbf)                   (0.005)  (0.05)  (0.1)    (1)   (10)    (50)
Compression setup space:
 Vertical (m)              0.25     0.61    0.76   1.02   1.65    1.98
 Horizontal (m)            0.29     0.47    0.50   0.71   0.91    0.86
Tension setup space:
 Vertical (m)              0.56     0.76    0.91   2.16   2.49    4.45
 Horizontal (m)            0.29     0.64    0.66   0.71   0.91    1.17
Alloy of weights
 AISI series                302     302     302     410    410    410
Density of weights
 at 20 [degrees]C
 kg/[m.sup.3]              7890     7890    7890   7720   7720    7720

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Author:	Yaniv, S.L.
Publication:	Journal of Research of the National Institute of Standards and Technology
Geographic Code:	1USA
Date:	Jan 1, 2001
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