The AAPM/RSNA Physics Tutorial for Residents1
The low radiation dose rates used in nuclear medicine necessitate image formation and measurements that are severely count limited. This limitation may mask our ability to perceive contrast in an image or may affect our confidence in quantitative functional measurements. The randomness of the signal...
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| Veröffentlicht in: | Radiographics 1999-05, Vol.19 (3), p.765 |
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| container_title | Radiographics |
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| creator | Mark S. Rzeszotarski |
| description | The low radiation dose rates used in nuclear medicine necessitate image formation and measurements that are severely count
limited. This limitation may mask our ability to perceive contrast in an image or may affect our confidence in quantitative
functional measurements. The randomness of the signal can be described by using the Poisson probability distribution with
its associated mean and variance. The validity of a measurement and uncertainties in a re-sult can be determined by examining
the count statistics. If multiple measurements are used to derive a result, confidence levels can be determined by examination
of the propagation of errors. The statistical properties of the detected signal can also be evaluated to determine if the
equipment is functioning properly. For example, the Ï 2 test can be used to determine if there is too much or too little variability in count samples. Finally, image formation with
limited numbers of photons results in noisy images that may be difficult to interpret. An understanding of the trade-offs
between contrast, noise, and object size is required to set proper image acquisition parameters and thereby ensure that the
information required to make a diagnosis is contained in the final image. |
| format | Article |
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limited. This limitation may mask our ability to perceive contrast in an image or may affect our confidence in quantitative
functional measurements. The randomness of the signal can be described by using the Poisson probability distribution with
its associated mean and variance. The validity of a measurement and uncertainties in a re-sult can be determined by examining
the count statistics. If multiple measurements are used to derive a result, confidence levels can be determined by examination
of the propagation of errors. The statistical properties of the detected signal can also be evaluated to determine if the
equipment is functioning properly. For example, the Ï 2 test can be used to determine if there is too much or too little variability in count samples. Finally, image formation with
limited numbers of photons results in noisy images that may be difficult to interpret. An understanding of the trade-offs
between contrast, noise, and object size is required to set proper image acquisition parameters and thereby ensure that the
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limited. This limitation may mask our ability to perceive contrast in an image or may affect our confidence in quantitative
functional measurements. The randomness of the signal can be described by using the Poisson probability distribution with
its associated mean and variance. The validity of a measurement and uncertainties in a re-sult can be determined by examining
the count statistics. If multiple measurements are used to derive a result, confidence levels can be determined by examination
of the propagation of errors. The statistical properties of the detected signal can also be evaluated to determine if the
equipment is functioning properly. For example, the Ï 2 test can be used to determine if there is too much or too little variability in count samples. Finally, image formation with
limited numbers of photons results in noisy images that may be difficult to interpret. An understanding of the trade-offs
between contrast, noise, and object size is required to set proper image acquisition parameters and thereby ensure that the
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limited. This limitation may mask our ability to perceive contrast in an image or may affect our confidence in quantitative
functional measurements. The randomness of the signal can be described by using the Poisson probability distribution with
its associated mean and variance. The validity of a measurement and uncertainties in a re-sult can be determined by examining
the count statistics. If multiple measurements are used to derive a result, confidence levels can be determined by examination
of the propagation of errors. The statistical properties of the detected signal can also be evaluated to determine if the
equipment is functioning properly. For example, the Ï 2 test can be used to determine if there is too much or too little variability in count samples. Finally, image formation with
limited numbers of photons results in noisy images that may be difficult to interpret. An understanding of the trade-offs
between contrast, noise, and object size is required to set proper image acquisition parameters and thereby ensure that the
information required to make a diagnosis is contained in the final image.</abstract><pub>Radiological Society of North America</pub><pmid>10336202</pmid></addata></record> |
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| ispartof | Radiographics, 1999-05, Vol.19 (3), p.765 |
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| language | eng |
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| title | The AAPM/RSNA Physics Tutorial for Residents1 |
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