In engineering, tolerance is the permissible limit of variation in 1) a physical dimension, 2) a measured value or property of a material, manufactured object, system, or service, or 3) other measured values (such as temperature, humidity, etc). Engineering is the discipline of acquiring and applying knowledge to design, analysis, and/or construction of works for practical purposes. ... 2-dimensional renderings (ie. ... Manufacturing (from Latin manu factura, making by hand) is the use of tools and labor to make things for use or sale. ...

Dimensions, properties, or conditions may vary within certain practical limits without significantly affecting functioning of equipment or a process. Tolerances are specified to allow reasonable leeway for imperfections and inherent variability without compromising performance.

Engineering tolerances

The tolerance may be specified as a factor or percentage of the nominal value, a maximum deviation from a nominal value, an explicit range of allowed values, be specified by a note or published standard with this information, or be implied by the numeric accuracy of the nominal value. Tolerance can be symmetrical, as in 40±0.1, or asymmetrical, such as 40+0.2/−0.1. Look up range in Wiktionary, the free dictionary. ...

It is often desireable to specify the largest possible tolerance while maintaining proper functionality. Closer or tighter tolerances are more difficult, and hence costly, to achieve. Conversely, larger or looser tolerances may significantly affect the operation of the device.

However exacting the requirements, there will always be an acceptable tolerance; an exact value is totally meaningless in most cases. What do we mean by, say, a diameter of 1 mm exactly? Is it permissible to add or remove a couple of atoms? What about thermal expansion or contraction? Wear? Do we mean as accurately as we can measure with a micrometer in a machine shop? Or must it be accurate within a fraction of a wavelength of light, for optical use? DIAMETER is a computer networking protocol for AAA (Authentication, Authorization and Accounting). ... In physics, thermal expansion is the tendency of matter to increase in volume or pressure when heated. ... In physics, thermal expansion is the tendency of matter to increase in volume or pressure when heated. ... Outside, inside, and depth micrometers A micrometer, also known as a micrometer screw gauge, is a widely used device in mechanical engineering for precisely measuring thickness of blocks, outer and inner diameters of shafts and depths of slots. ... A lathe is a common tool used in machining. ... This article does not cite any references or sources. ... See also list of optical topics. ...

Tolerance is different from safety factor, but an adequate safety factor will take into account relevant tolerances as well as other possible variations. Factor of safety (FoS) can mean either the fraction of structural capability over that required, or a multiplier applied to the maximum expected load (force, torque, bending moment or a combination) to which a component or assembly will be subjected. ...

Electrical component tolerance

An electrical specification might call for a resistor with a nominal value of 100 Ω (ohms), but will also state a tolerance such as "±1%". This means that any resistor with a value in the range 99 Ω to 101 Ω is acceptable. For critical components, one might specify that the actual resistance must remain within tolerance within a specified temperature range, over a specified lifetime, and so on. Resistor symbols (non-European) Resistor symbols (Europe, IEC) Axial-lead resistors on tape. ... The ohm (symbol: Ω) is the SI unit of electric resistance. ...

Many commercially available resistors and capacitors of standard types, and some small inductors, are often marked with coloured bands to indicate their value and the tolerance. High-precision components of non-standard values may have numerical information printed on them. Resistor symbols (non-European) Resistor symbols (Europe, IEC) Axial-lead resistors on tape. ... See Capacitor (component) for a discussion of specific types. ... An inductor is a passive electrical device employed in electrical circuits for its property of inductance. ... The electronic color code discussed here is used to indicate the values or ratings of electronic components, very commonly for resistors, but also for capacitors, inductors, and others. ...

Mechanical component tolerance

Tolerance is related to, but different from fit in mechanical engineering, which is a designed–in clearance or interference between two parts. For example, if a shaft with a nominal diameter of 10 millimeters is to have a sliding fit within a hole, the shaft might be specified with a tolerance range from 9.964 to 10.000 millimeters and the hole might be specified with a tolerance range from 10.04 to 10.076 millimeters. This would provide a clearance fit of somewhere between 0.04 millimeter (largest shaft paired with the smallest hole) and 0.112 millimeter (smallest shaft paired with the largest hole). In this case the size of the tolerance range for both the shaft and hole is chosen to be the same (0.036 millimeter), but this need not be the case in general.

When designing mechanical components, standardized tolerances are often used. The standard (size) tolerances are divided into two categories: hole and shaft. They are labeled with a letter (capitals for holes and lowercase for shafts) and a number. For example: H7 (hole) and h7 (shaft). H7/h6 is a very common standard tolerance which gives a rather tight fit, but not so tight that you can't put the shaft in the hole by hand. The tolerances work in such a way that for a hole H7 means that the hole should be made slightly larger than the base dimension (in this case for an ISO fit 10+0.015-0, meaning that it may be up to 0.15mm larger than the base dimension, and 0mm smaller). The actual amount bigger/smaller depends on the base dimension. For a shaft of the same size h6 would mean 10+0-0.009, which is the opposite of H7. This method of standard tolerances is also known as Limits and Fits and can be found in ISO 286-2 [Link to ISO page].

An analysis of fit by Statistical interference is also extremely useful: It indicates the frequency (or probability) of parts properly fitting together. When two probability distributions overlap, statistical interference exists. ...

Considerations when setting tolerances

A primary concern is to determine how wide the tolerances may be without affecting other factors or the outcome of a process. This can be by the use of scientific principles, engineering knowledge, and professional experience. Experimental investigation is very useful to investigate the effects of tolerances: designed experiments, formal engineering evaluations, etc. The first statistician to consider a methodology for the design of experiments was Sir Ronald A. Fisher. ...

A good set of engineering tolerances in a specification, by itself, does not imply that compliance with those tolerances will be achieved. Actual production of any product (or operation of any system) involves some inherent variation of input and output. Measurement error and statistical uncertainty are also present in all measurements. With a normal distribution, the tails of measured values may extend well beyond plus and minus three standard deviations from the process average. One, or both, tails might extend beyond the specified tolerance. Specification may refer to several different concepts: Specification (standards) refers to specific standards Specificatio - a legal concept Specification (regression) refers to the practice of translating theory into a regression model Category: ... The normal distribution, also called the Gaussian distribution, is an important family of continuous probability distributions, applicable in many fields. ...

The process capability of systems, materials, and products needs to be compatible with the specified engineering tolerances. Process controls must be in place and an effective Quality management system, such as Total Quality Management, needs to keep actual production within the desired tolerances. The Process Capability Study answers the question, is my process good enough? This is quite different from the question answered by a Control chart, which is, has my process changed? Properly, use of a Control Chart to establish that a process is stable and predictable precedes the use of a... Process control is an engineering discipline that deals with architectures, mechanisms, and algorithms for controlling the output of a specific process. ... A quality management system (QMS) is a system that outlines the policies and procedures necessary to improve and control the various processes that will ultimately lead to improved business performance. ... Total Quality Management (TQM) is a management strategy aimed at embedding awareness of quality in all organizational processes. ...

The choice of tolerances is also affected by the intended statistical sampling plan and its characteristics such as the Acceptable Quality Level. This relates to the question of whether tolerances must be extremely rigid (high confidence in 100% conformance) or whether some small percentage of being out-of-tolerance may sometimes be acceptable.

An alternative view of tolerances

Some people (Genichi Taguchi, and others), suggest that traditional two-sided tolerances are analogous to "goal posts" in a football game: It implies that all data within those tolerances are equally acceptable. The alternative is that best product has a measurement which is precisely on target. There is an increasing loss which is a function of the deviation or variability from the target value of any design parameter. The greater the deviation from target, the greater is the loss. This is described as the "Taguchi loss function" or "quality loss function". Genichi Taguchi (田口 玄一) (born January 1, 1924 in Tokamachi, Japan) is an engineer and statistician. ...

See also

• process capability
• Specification (technical standard)
• statistical process control
• Taguchi methods
• Tolerance stacks
• Verification and Validation‎

The Process Capability Study answers the question, is my process good enough? This is quite different from the question answered by a Control chart, which is, has my process changed? Properly, use of a Control Chart to establish that a process is stable and predictable precedes the use of a... “Specification” redirects here. ... Statistical process control (SPC) is a method for achieving quality control in manufacturing processes. ... Taguchi methods are statistical methods developed by Genichi Taguchi to improve the quality of manufactured goods. ... Tolerance stacks also known as stack-ups, stacks, or tolerance analysis is the process in mechanical engineering of calculating the effects of dimensions and tolerances. ... In software project management, software testing, and software engineering, Verification and Validation (V&V) is the process of checking that a software system meets specifications and that it fulfils its intended purpose. ...

References

• Pyzdek, T, "Quality Engineering Handbook", 2003, ISBN 0824746147
• Godfrey, A. B., "Juran's Quality Handbook", 1999, ISBN 007034003
• ASTM D4356 Standard Practice for Establishing Consistent Test Method Tolerances