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Accuracy and precision

January 01, 1970

Accuracy and precision are two measures of observational error.

Accuracy is how close a given set of measurements (observations or readings) are to their true value.

Precision is how close the measurements are to each other.

In other words:

  1. More commonly, a description of systematic errors (a measure of statistical bias of a given measure of central tendency). Low accuracy causes a difference between a result and a true value. This secondary measure is referred to as trueness by ISO.
  2. A combination of both types of observational error (random and systematic), so high accuracy requires both high precision and high trueness.

In the first, more common definition of "accuracy" above, the concept is independent of "precision", so a particular set of data can be said to be accurate, precise, both, or neither.

In simpler terms, given a statistical sample or set of data points from repeated measurements of the same quantity, the sample or set can be said to be accurate if their average is close to the true value of the quantity being measured, while the set can be said to be precise if their standard deviation is relatively small.

Common technical definition edit

 
Accuracy is the proximity of measurement results to the accepted value; precision is the degree to which repeated (or reproducible) measurements under unchanged conditions show the same results.

In the fields of science and engineering, the accuracy of a measurement system is the degree of closeness of measurements of a quantity to that quantity's true value.[2] The precision of a measurement system, related to reproducibility and repeatability, is the degree to which repeated measurements under unchanged conditions show the same results.[2][3] Although the two words precision and accuracy can be synonymous in colloquial use, they are deliberately contrasted in the context of the scientific method.

The field of statistics, where the interpretation of measurements plays a central role, prefers to use the terms bias and variability instead of accuracy and precision: bias is the amount of inaccuracy and variability is the amount of imprecision.

A measurement system can be accurate but not precise, precise but not accurate, neither, or both. For example, if an experiment contains a systematic error, then increasing the sample size generally increases precision but does not improve accuracy. The result would be a consistent yet inaccurate string of results from the flawed experiment. Eliminating the systematic error improves accuracy but does not change precision.

A measurement system is considered valid if it is both accurate and precise. Related terms include bias (non-random or directed effects caused by a factor or factors unrelated to the independent variable) and error (random variability).

The terminology is also applied to indirect measurements—that is, values obtained by a computational procedure from observed data.

In addition to accuracy and precision, measurements may also have a measurement resolution, which is the smallest change in the underlying physical quantity that produces a response in the measurement.

In numerical analysis, accuracy is also the nearness of a calculation to the true value; while precision is the resolution of the representation, typically defined by the number of decimal or binary digits.

In military terms, accuracy refers primarily to the accuracy of fire (justesse de tir), the precision of fire expressed by the closeness of a grouping of shots at and around the centre of the target.[4]

Quantification edit

See also: False precision

In industrial instrumentation, accuracy is the measurement tolerance, or transmission of the instrument and defines the limits of the errors made when the instrument is used in normal operating conditions.[5]

Ideally a measurement device is both accurate and precise, with measurements all close to and tightly clustered around the true value. The accuracy and precision of a measurement process is usually established by repeatedly measuring some traceable reference standard. Such standards are defined in the International System of Units (abbreviated SI from French: Système international d'unités) and maintained by national standards organizations such as the National Institute of Standards and Technology in the United States.

This also applies when measurements are repeated and averaged. In that case, the term standard error is properly applied: the precision of the average is equal to the known standard deviation of the process divided by the square root of the number of measurements averaged. Further, the central limit theorem shows that the probability distribution of the averaged measurements will be closer to a normal distribution than that of individual measurements.

With regard to accuracy we can distinguish:

  • the difference between the mean of the measurements and the reference value, the bias. Establishing and correcting for bias is necessary for calibration.
  • the combined effect of that and precision.

A common convention in science and engineering is to express accuracy and/or precision implicitly by means of significant figures. Where not explicitly stated, the margin of error is understood to be one-half the value of the last significant place. For instance, a recording of 843.6 m, or 843.0 m, or 800.0 m would imply a margin of 0.05 m (the last significant place is the tenths place), while a recording of 843 m would imply a margin of error of 0.5 m (the last significant digits are the units).

A reading of 8,000 m, with trailing zeros and no decimal point, is ambiguous; the trailing zeros may or may not be intended as significant figures. To avoid this ambiguity, the number could be represented in scientific notation: 8.0 × 103 m indicates that the first zero is significant (hence a margin of 50 m) while 8.000 × 103 m indicates that all three zeros are significant, giving a margin of 0.5 m. Similarly, one can use a multiple of the basic measurement unit: 8.0 km is equivalent to 8.0 × 103 m. It indicates a margin of 0.05 km (50 m). However, reliance on this convention can lead to false precision errors when accepting data from sources that do not obey it. For example, a source reporting a number like 153,753 with precision +/- 5,000 looks like it has precision +/- 0.5. Under the convention it would have been rounded to 150,000.

Alternatively, in a scientific context, if it is desired to indicate the margin of error with more precision, one can use a notation such as 7.54398(23) × 10−10 m, meaning a range of between 7.54375 and 7.54421 × 10−10 m.

Precision includes:

  • repeatability — the variation arising when all efforts are made to keep conditions constant by using the same instrument and operator, and repeating during a short time period; and
  • reproducibility — the variation arising using the same measurement process among different instruments and operators, and over longer time periods.

In engineering, precision is often taken as three times Standard Deviation of measurements taken, representing the range that 99.73% of measurements can occur within.[6] For example, an ergonomist measuring the human body can be confident that 99.73% of their extracted measurements fall within ± 0.7 cm - if using the GRYPHON processing system - or ± 13 cm - if using unprocessed data.[7]

ISO definition (ISO 5725) edit

 
According to ISO 5725-1, accuracy consists of trueness (proximity of measurement results to the true value) and precision (repeatability or reproducibility of the measurement).

A shift in the meaning of these terms appeared with the publication of the ISO 5725 series of standards in 1994, which is also reflected in the 2008 issue of the BIPM International Vocabulary of Metrology (VIM), items 2.13 and 2.14.[2]

According to ISO 5725-1,[1] the general term "accuracy" is used to describe the closeness of a measurement to the true value. When the term is applied to sets of measurements of the same measurand, it involves a component of random error and a component of systematic error. In this case trueness is the closeness of the mean of a set of measurement results to the actual (true) value and precision is the closeness of agreement among a set of results.

ISO 5725-1 and VIM also avoid the use of the term "bias", previously specified in BS 5497-1,[8] because it has different connotations outside the fields of science and engineering, as in medicine and law.

Accuracy of a target grouping according to BIPM and ISO 5725
  •  
    Low accuracy due to low precision
  •  
    Low accuracy even with high precision

In classification edit

In binary classification edit

Main article: Evaluation of binary classifiers § Single metrics

Accuracy is also used as a statistical measure of how well a binary classification test correctly identifies or excludes a condition. That is, the accuracy is the proportion of correct predictions (both true positives and true negatives) among the total number of cases examined.[9] As such, it compares estimates of pre- and post-test probability. To make the context clear by the semantics, it is often referred to as the "Rand accuracy" or "Rand index".[10][11][12] It is a parameter of the test. The formula for quantifying binary accuracy is:

 
where TP = True positive; FP = False positive; TN = True negative; FN = False negative

In this context, the concepts of trueness and precision as defined by ISO 5725-1 are not applicable. One reason is that there is not a single “true value” of a quantity, but rather two possible true values for every case, while accuracy is an average across all cases and therefore takes into account both values. However, the term precision is used in this context to mean a different metric originating from the field of information retrieval (see below).

In multiclass classification edit

When computing accuracy in multiclass classification, accuracy is simply the fraction of correct classifications:[13]

 
This is usually expressed as a percentage. For example, if a classifier makes ten predictions and nine of them are correct, the accuracy is 90%.

Accuracy is also called top-1 accuracy to distinguish it from top-5 accuracy, common in convolutional neural network evaluation. To evaluate top-5 accuracy, the classifier must provide relative likelihoods for each class. When these are sorted, a classification is considered correct if the correct classification falls anywhere within the top 5 predictions made by the network. Top-5 accuracy was popularized by the ImageNet challenge. It is usually higher than top-1 accuracy, as any correct predictions in the 2nd through 5th positions will not improve the top-1 score, but do improve the top-5 score.

In psychometrics and psychophysics edit

In psychometrics and psychophysics, the term accuracy is interchangeably used with validity and constant error. Precision is a synonym for reliability and variable error. The validity of a measurement instrument or psychological test is established through experiment or correlation with behavior. Reliability is established with a variety of statistical techniques, classically through an internal consistency test like Cronbach's alpha to ensure sets of related questions have related responses, and then comparison of those related question between reference and target population.[citation needed]

In logic simulation edit

In logic simulation, a common mistake in evaluation of accurate models is to compare a logic simulation model to a transistor circuit simulation model. This is a comparison of differences in precision, not accuracy. Precision is measured with respect to detail and accuracy is measured with respect to reality.[14][15]

In information systems edit

Information retrieval systems, such as databases and web search engines, are evaluated by many different metrics, some of which are derived from the confusion matrix, which divides results into true positives (documents correctly retrieved), true negatives (documents correctly not retrieved), false positives (documents incorrectly retrieved), and false negatives (documents incorrectly not retrieved). Commonly used metrics include the notions of precision and recall. In this context, precision is defined as the fraction of retrieved documents which are relevant to the query (true positives divided by true+false positives), using a set of ground truth relevant results selected by humans. Recall is defined as the fraction of relevant documents retrieved compared to the total number of relevant documents (true positives divided by true positives+false negatives). Less commonly, the metric of accuracy is used, is defined as the total number of correct classifications (true positives plus true negatives) divided by the total number of documents.

None of these metrics take into account the ranking of results. Ranking is very important for web search engines because readers seldom go past the first page of results, and there are too many documents on the web to manually classify all of them as to whether they should be included or excluded from a given search. Adding a cutoff at a particular number of results takes ranking into account to some degree. The measure precision at k, for example, is a measure of precision looking only at the top ten (k=10) search results. More sophisticated metrics, such as discounted cumulative gain, take into account each individual ranking, and are more commonly used where this is important.

In cognitive systems edit

In cognitive systems, accuracy and precision is used to characterize and measure results of a cognitive process performed by biological or artificial entities where a cognitive process is a transformation of data, information, knowledge, or wisdom to a higher-valued form. (DIKW Pyramid) Sometimes, a cognitive process produces exactly the intended or desired output but sometimes produces output far from the intended or desired. Furthermore, repetitions of a cognitive process do not always produce the same output. Cognitive accuracy (CA) is the propensity of a cognitive process to produce the intended or desired output. Cognitive precision (CP) is the propensity of a cognitive process to produce only the intended or desired output.[16][17][18] To measure augmented cognition in human/cog ensembles, where one or more humans work collaboratively with one or more cognitive systems (cogs), increases in cognitive accuracy and cognitive precision assist in measuring the degree of cognitive augmentation.

See also edit

References edit

  1. ^ a b BS ISO 5725-1: "Accuracy (trueness and precision) of measurement methods and results - Part 1: General principles and definitions.", p.1 (1994)
  2. ^ a b c JCGM 200:2008 International vocabulary of metrology — Basic and general concepts and associated terms (VIM)
  3. ^ Taylor, John Robert (1999). An Introduction to Error Analysis: The Study of Uncertainties in Physical Measurements. University Science Books. pp. 128–129. ISBN 0-935702-75-X.
  4. ^ North Atlantic Treaty Organization, NATO Standardization Agency AAP-6 – Glossary of terms and definitions, p 43.
  5. ^ Creus, Antonio. Instrumentación Industrial[citation needed]
  6. ^ Black, J. Temple (21 July 2020). DeGarmo's materials and processes in manufacturing. John Wiley & Sons. ISBN 978-1-119-72329-5. OCLC 1246529321.
  7. ^ Parker, Christopher J.; Gill, Simeon; Harwood, Adrian; Hayes, Steven G.; Ahmed, Maryam (2021-05-19). "A Method for Increasing 3D Body Scanning's Precision: Gryphon and Consecutive Scanning". Ergonomics. 65 (1): 39–59. doi:10.1080/00140139.2021.1931473. ISSN 0014-0139. PMID 34006206.
  8. ^ BS 5497-1: "Precision of test methods. Guide for the determination of repeatability and reproducibility for a standard test method." (1979)
  9. ^ Metz, CE (October 1978). "Basic principles of ROC analysis" (PDF). Semin Nucl Med. 8 (4): 283–98. doi:10.1016/s0001-2998(78)80014-2. PMID 112681. Archived (PDF) from the original on 2022-10-09.
  10. ^ (PDF). Archived from the original (PDF) on 2015-03-11. Retrieved 2015-08-09.{{cite web}}: CS1 maint: archived copy as title (link)
  11. ^ Powers, David M. W. (2015). "What the F-measure doesn't measure". arXiv:1503.06410 [cs.IR].
  12. ^ David M W Powers. "The Problem with Kappa" (PDF). Anthology.aclweb.org. Archived (PDF) from the original on 2022-10-09. Retrieved 11 December 2017.
  13. ^ "3.3. Metrics and scoring: quantifying the quality of predictions". scikit-learn. Retrieved 17 May 2022.
  14. ^ Acken, John M. (1997). "none". Encyclopedia of Computer Science and Technology. 36: 281–306.
  15. ^ Glasser, Mark; Mathews, Rob; Acken, John M. (June 1990). "1990 Workshop on Logic-Level Modelling for ASICS". SIGDA Newsletter. 20 (1).
  16. ^ Fulbright, Ron (2020). Democratization of Expertise: How Cognitive Systems Will Revolutionize Your Life (1st ed.). Boca Raton, FL: CRC Press. ISBN 978-0367859459.
  17. ^ Fulbright, Ron (2019). "Calculating Cognitive Augmentation – A Case Study". Augmented Cognition. Lecture Notes in Computer Science. Vol. 11580. Springer Cham. pp. 533–545. arXiv:2211.06479. doi:10.1007/978-3-030-22419-6_38. ISBN 978-3-030-22418-9. S2CID 195891648.
  18. ^ Fulbright, Ron (2018). "On Measuring Cognition and Cognitive Augmentation". Human Interface and the Management of Information. Information in Applications and Services. Lecture Notes in Computer Science. Vol. 10905. Springer Cham. pp. 494–507. arXiv:2211.06477. doi:10.1007/978-3-319-92046-7_41. ISBN 978-3-319-92045-0. S2CID 51603737.

External links edit

 
Look up accuracy, or precision in Wiktionary, the free dictionary.
 
Wikimedia Commons has media related to Accuracy and precision.
  • BIPM - Guides in metrology, Guide to the Expression of Uncertainty in Measurement (GUM) and International Vocabulary of Metrology (VIM)
  • "Beyond NIST Traceability: What really creates accuracy", Controlled Environments magazine
  • Precision and Accuracy with Three Psychophysical Methods
  • Appendix D.1: Terminology, Guidelines for Evaluating and Expressing the Uncertainty of NIST Measurement Results
  • Accuracy and Precision
  • Accuracy vs Precision — a brief video by Matt Parker
  • What's the difference between accuracy and precision? by Matt Anticole at TED-Ed

January 01, 1970
accuracy, precision, measures, observational, error, accuracy, close, given, measurements, observations, readings, their, true, value, precision, close, measurements, each, other, other, words, precision, description, random, errors, measure, statistical, vari. Accuracy and precision are two measures of observational error Accuracy is how close a given set of measurements observations or readings are to their true value Precision is how close the measurements are to each other In other words Precision is a description of random errors a measure of statistical variability Accuracy has two definitions per ISO 1 More commonly a description of systematic errors a measure of statistical bias of a given measure of central tendency Low accuracy causes a difference between a result and a true value This secondary measure is referred to as trueness by ISO A combination of both types of observational error random and systematic so high accuracy requires both high precision and high trueness In the first more common definition of accuracy above the concept is independent of precision so a particular set of data can be said to be accurate precise both or neither In simpler terms given a statistical sample or set of data points from repeated measurements of the same quantity the sample or set can be said to be accurate if their average is close to the true value of the quantity being measured while the set can be said to be precise if their standard deviation is relatively small Contents 1 Common technical definition 1 1 Quantification 2 ISO definition ISO 5725 3 In classification 3 1 In binary classification 3 2 In multiclass classification 4 In psychometrics and psychophysics 5 In logic simulation 6 In information systems 7 In cognitive systems 8 See also 9 References 10 External linksCommon technical definition edit nbsp Accuracy is the proximity of measurement results to the accepted value precision is the degree to which repeated or reproducible measurements under unchanged conditions show the same results In the fields of science and engineering the accuracy of a measurement system is the degree of closeness of measurements of a quantity to that quantity s true value 2 The precision of a measurement system related to reproducibility and repeatability is the degree to which repeated measurements under unchanged conditions show the same results 2 3 Although the two words precision and accuracy can be synonymous in colloquial use they are deliberately contrasted in the context of the scientific method The field of statistics where the interpretation of measurements plays a central role prefers to use the terms bias and variability instead of accuracy and precision bias is the amount of inaccuracy and variability is the amount of imprecision A measurement system can be accurate but not precise precise but not accurate neither or both For example if an experiment contains a systematic error then increasing the sample size generally increases precision but does not improve accuracy The result would be a consistent yet inaccurate string of results from the flawed experiment Eliminating the systematic error improves accuracy but does not change precision A measurement system is considered valid if it is both accurate and precise Related terms include bias non random or directed effects caused by a factor or factors unrelated to the independent variable and error random variability The terminology is also applied to indirect measurements that is values obtained by a computational procedure from observed data In addition to accuracy and precision measurements may also have a measurement resolution which is the smallest change in the underlying physical quantity that produces a response in the measurement In numerical analysis accuracy is also the nearness of a calculation to the true value while precision is the resolution of the representation typically defined by the number of decimal or binary digits In military terms accuracy refers primarily to the accuracy of fire justesse de tir the precision of fire expressed by the closeness of a grouping of shots at and around the centre of the target 4 Quantification edit See also False precision In industrial instrumentation accuracy is the measurement tolerance or transmission of the instrument and defines the limits of the errors made when the instrument is used in normal operating conditions 5 Ideally a measurement device is both accurate and precise with measurements all close to and tightly clustered around the true value The accuracy and precision of a measurement process is usually established by repeatedly measuring some traceable reference standard Such standards are defined in the International System of Units abbreviated SI from French Systeme international d unites and maintained by national standards organizations such as the National Institute of Standards and Technology in the United States This also applies when measurements are repeated and averaged In that case the term standard error is properly applied the precision of the average is equal to the known standard deviation of the process divided by the square root of the number of measurements averaged Further the central limit theorem shows that the probability distribution of the averaged measurements will be closer to a normal distribution than that of individual measurements With regard to accuracy we can distinguish the difference between the mean of the measurements and the reference value the bias Establishing and correcting for bias is necessary for calibration the combined effect of that and precision A common convention in science and engineering is to express accuracy and or precision implicitly by means of significant figures Where not explicitly stated the margin of error is understood to be one half the value of the last significant place For instance a recording of 843 6 m or 843 0 m or 800 0 m would imply a margin of 0 05 m the last significant place is the tenths place while a recording of 843 m would imply a margin of error of 0 5 m the last significant digits are the units A reading of 8 000 m with trailing zeros and no decimal point is ambiguous the trailing zeros may or may not be intended as significant figures To avoid this ambiguity the number could be represented in scientific notation 8 0 103 m indicates that the first zero is significant hence a margin of 50 m while 8 000 103 m indicates that all three zeros are significant giving a margin of 0 5 m Similarly one can use a multiple of the basic measurement unit 8 0 km is equivalent to 8 0 103 m It indicates a margin of 0 05 km 50 m However reliance on this convention can lead to false precision errors when accepting data from sources that do not obey it For example a source reporting a number like 153 753 with precision 5 000 looks like it has precision 0 5 Under the convention it would have been rounded to 150 000 Alternatively in a scientific context if it is desired to indicate the margin of error with more precision one can use a notation such as 7 54398 23 10 10 m meaning a range of between 7 54375 and 7 54421 10 10 m Precision includes repeatability the variation arising when all efforts are made to keep conditions constant by using the same instrument and operator and repeating during a short time period and reproducibility the variation arising using the same measurement process among different instruments and operators and over longer time periods In engineering precision is often taken as three times Standard Deviation of measurements taken representing the range that 99 73 of measurements can occur within 6 For example an ergonomist measuring the human body can be confident that 99 73 of their extracted measurements fall within 0 7 cm if using the GRYPHON processing system or 13 cm if using unprocessed data 7 ISO definition ISO 5725 edit nbsp According to ISO 5725 1 accuracy consists of trueness proximity of measurement results to the true value and precision repeatability or reproducibility of the measurement A shift in the meaning of these terms appeared with the publication of the ISO 5725 series of standards in 1994 which is also reflected in the 2008 issue of the BIPM International Vocabulary of Metrology VIM items 2 13 and 2 14 2 According to ISO 5725 1 1 the general term accuracy is used to describe the closeness of a measurement to the true value When the term is applied to sets of measurements of the same measurand it involves a component of random error and a component of systematic error In this case trueness is the closeness of the mean of a set of measurement results to the actual true value and precision is the closeness of agreement among a set of results ISO 5725 1 and VIM also avoid the use of the term bias previously specified in BS 5497 1 8 because it has different connotations outside the fields of science and engineering as in medicine and law Accuracy of a target grouping according to BIPM and ISO 5725 nbsp Low accuracy due to low precision nbsp Low accuracy even with high precisionIn classification editIn binary classification edit Main article Evaluation of binary classifiers Single metrics Accuracy is also used as a statistical measure of how well a binary classification test correctly identifies or excludes a condition That is the accuracy is the proportion of correct predictions both true positives and true negatives among the total number of cases examined 9 As such it compares estimates of pre and post test probability To make the context clear by the semantics it is often referred to as the Rand accuracy or Rand index 10 11 12 It is a parameter of the test The formula for quantifying binary accuracy is Accuracy T P T N T P T N F P F N displaystyle text Accuracy frac TP TN TP TN FP FN nbsp where TP True positive FP False positive TN True negative FN False negative In this context the concepts of trueness and precision as defined by ISO 5725 1 are not applicable One reason is that there is not a single true value of a quantity but rather two possible true values for every case while accuracy is an average across all cases and therefore takes into account both values However the term precision is used in this context to mean a different metric originating from the field of information retrieval see below In multiclass classification edit When computing accuracy in multiclass classification accuracy is simply the fraction of correct classifications 13 Accuracy correct classifications all classifications displaystyle text Accuracy frac text correct classifications text all classifications nbsp This is usually expressed as a percentage For example if a classifier makes ten predictions and nine of them are correct the accuracy is 90 Accuracy is also called top 1 accuracy to distinguish it from top 5 accuracy common in convolutional neural network evaluation To evaluate top 5 accuracy the classifier must provide relative likelihoods for each class When these are sorted a classification is considered correct if the correct classification falls anywhere within the top 5 predictions made by the network Top 5 accuracy was popularized by the ImageNet challenge It is usually higher than top 1 accuracy as any correct predictions in the 2nd through 5th positions will not improve the top 1 score but do improve the top 5 score In psychometrics and psychophysics editIn psychometrics and psychophysics the term accuracy is interchangeably used with validity and constant error Precision is a synonym for reliability and variable error The validity of a measurement instrument or psychological test is established through experiment or correlation with behavior Reliability is established with a variety of statistical techniques classically through an internal consistency test like Cronbach s alpha to ensure sets of related questions have related responses and then comparison of those related question between reference and target population citation needed In logic simulation editIn logic simulation a common mistake in evaluation of accurate models is to compare a logic simulation model to a transistor circuit simulation model This is a comparison of differences in precision not accuracy Precision is measured with respect to detail and accuracy is measured with respect to reality 14 15 In information systems editInformation retrieval systems such as databases and web search engines are evaluated by many different metrics some of which are derived from the confusion matrix which divides results into true positives documents correctly retrieved true negatives documents correctly not retrieved false positives documents incorrectly retrieved and false negatives documents incorrectly not retrieved Commonly used metrics include the notions of precision and recall In this context precision is defined as the fraction of retrieved documents which are relevant to the query true positives divided by true false positives using a set of ground truth relevant results selected by humans Recall is defined as the fraction of relevant documents retrieved compared to the total number of relevant documents true positives divided by true positives false negatives Less commonly the metric of accuracy is used is defined as the total number of correct classifications true positives plus true negatives divided by the total number of documents None of these metrics take into account the ranking of results Ranking is very important for web search engines because readers seldom go past the first page of results and there are too many documents on the web to manually classify all of them as to whether they should be included or excluded from a given search Adding a cutoff at a particular number of results takes ranking into account to some degree The measure precision at k for example is a measure of precision looking only at the top ten k 10 search results More sophisticated metrics such as discounted cumulative gain take into account each individual ranking and are more commonly used where this is important In cognitive systems editIn cognitive systems accuracy and precision is used to characterize and measure results of a cognitive process performed by biological or artificial entities where a cognitive process is a transformation of data information knowledge or wisdom to a higher valued form DIKW Pyramid Sometimes a cognitive process produces exactly the intended or desired output but sometimes produces output far from the intended or desired Furthermore repetitions of a cognitive process do not always produce the same output Cognitive accuracy CA is the propensity of a cognitive process to produce the intended or desired output Cognitive precision CP is the propensity of a cognitive process to produce only the intended or desired output 16 17 18 To measure augmented cognition in human cog ensembles where one or more humans work collaboratively with one or more cognitive systems cogs increases in cognitive accuracy and cognitive precision assist in measuring the degree of cognitive augmentation See also editBias variance tradeoff in statistics and machine learning Accepted and experimental value Data quality Engineering tolerance Exactness disambiguation Experimental uncertainty analysis F score Floating point arithmetic section Accuracy problems Hypothesis tests for accuracy Information quality Measurement uncertainty Precision statistics Probability Random and systematic errors Sensitivity and specificity Significant figures Statistical significanceReferences edit a b BS ISO 5725 1 Accuracy trueness and precision of measurement methods and results Part 1 General principles and definitions p 1 1994 a b c JCGM 200 2008 International vocabulary of metrology Basic and general concepts and associated terms VIM Taylor John Robert 1999 An Introduction to Error Analysis The Study of Uncertainties in Physical Measurements University Science Books pp 128 129 ISBN 0 935702 75 X North Atlantic Treaty Organization NATO Standardization Agency AAP 6 Glossary of terms and definitions p 43 Creus Antonio Instrumentacion Industrial citation needed Black J Temple 21 July 2020 DeGarmo s materials and processes in manufacturing John Wiley amp Sons ISBN 978 1 119 72329 5 OCLC 1246529321 Parker Christopher J Gill Simeon Harwood Adrian Hayes Steven G Ahmed Maryam 2021 05 19 A Method for Increasing 3D Body Scanning s Precision Gryphon and Consecutive Scanning Ergonomics 65 1 39 59 doi 10 1080 00140139 2021 1931473 ISSN 0014 0139 PMID 34006206 BS 5497 1 Precision of test methods Guide for the determination of repeatability and reproducibility for a standard test method 1979 Metz CE October 1978 Basic principles of ROC analysis PDF Semin Nucl Med 8 4 283 98 doi 10 1016 s0001 2998 78 80014 2 PMID 112681 Archived PDF from the original on 2022 10 09 Archived copy PDF Archived from the original PDF on 2015 03 11 Retrieved 2015 08 09 a href Template Cite web html title Template Cite web cite web a CS1 maint archived copy as title link Powers David M W 2015 What the F measure doesn t measure arXiv 1503 06410 cs IR David M W Powers The Problem with Kappa PDF Anthology aclweb org Archived PDF from the original on 2022 10 09 Retrieved 11 December 2017 3 3 Metrics and scoring quantifying the quality of predictions scikit learn Retrieved 17 May 2022 Acken John M 1997 none Encyclopedia of Computer Science and Technology 36 281 306 Glasser Mark Mathews Rob Acken John M June 1990 1990 Workshop on Logic Level Modelling for ASICS SIGDA Newsletter 20 1 Fulbright Ron 2020 Democratization of Expertise How Cognitive Systems Will Revolutionize Your Life 1st ed Boca Raton FL CRC Press ISBN 978 0367859459 Fulbright Ron 2019 Calculating Cognitive Augmentation A Case Study Augmented Cognition Lecture Notes in Computer Science Vol 11580 Springer Cham pp 533 545 arXiv 2211 06479 doi 10 1007 978 3 030 22419 6 38 ISBN 978 3 030 22418 9 S2CID 195891648 Fulbright Ron 2018 On Measuring Cognition and Cognitive Augmentation Human Interface and the Management of Information Information in Applications and Services Lecture Notes in Computer Science Vol 10905 Springer Cham pp 494 507 arXiv 2211 06477 doi 10 1007 978 3 319 92046 7 41 ISBN 978 3 319 92045 0 S2CID 51603737 External links edit nbsp Look up accuracy or precision in Wiktionary the free dictionary nbsp Wikimedia Commons has media related to Accuracy and precision BIPM Guides in metrology Guide to the Expression of Uncertainty in Measurement GUM and International Vocabulary of Metrology VIM Beyond NIST Traceability What really creates accuracy Controlled Environments magazine Precision and Accuracy with Three Psychophysical Methods Appendix D 1 Terminology Guidelines for Evaluating and Expressing the Uncertainty of NIST Measurement Results Accuracy and Precision Accuracy vs Precision a brief video by Matt Parker What s the difference between accuracy and precision by Matt Anticole at TED Ed Retrieved from https en wikipedia org w index php title Accuracy and precision amp oldid 1220739681, wikipedia, wiki, book, books, library,

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