Simple and accurate closed-form expressions for Gaussian Q-function
Gaussian functions can be found in the fields of natural science, social science, mathematics and engineering. This type of functions does not have a closed form. It is very difficult to handle mathematically due to its non-elementary integral form which cannot be expressed as a finite compositio...
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sg-ntu-dr.10356-760242023-07-04T15:56:54Z Simple and accurate closed-form expressions for Gaussian Q-function Lei, Hao Li Kwok Hung School of Electrical and Electronic Engineering DRNTU::Engineering::Electrical and electronic engineering Gaussian functions can be found in the fields of natural science, social science, mathematics and engineering. This type of functions does not have a closed form. It is very difficult to handle mathematically due to its non-elementary integral form which cannot be expressed as a finite composition of simple mathematical functions. For this reason, the development of approximations and tight bounds for the Q -function is quite significant. Generally speaking, researchers may use one acceptable approximation to replace the exact Gaussian integral because that it would take much more time to do the integration, provided that this approximation function performs well. However, depending on different conditions, researchers may choose an approximation according to the actual condition. According to the Gaussian Q -function application requirements this report provided approximation selection scheme, and compared several approximations of the Gaussian Q -function with figures, tables, relative errors, and other aspects. When designing the entire comparison process, the functional modules of the application are considered, and the process is finished through MATLAB simulation. The simulation results in terms of figures and tables, to show the accuracy of approximation functions are talked in Chapter 3, while the applications of the approximation function, such as simulation design of BPSK, QAM modulation are talked in Chapter 4. This report also demonstrated some important codes in Chapter 4. After the simulation part , the conclusion and recommendation in future work are given. Master of Science (Communications Engineering) 2018-09-18T06:52:30Z 2018-09-18T06:52:30Z 2018 Thesis http://hdl.handle.net/10356/76024 en 63 p. application/pdf |
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DRNTU::Engineering::Electrical and electronic engineering Lei, Hao Simple and accurate closed-form expressions for Gaussian Q-function |
| description |
Gaussian functions can be found in the fields of natural science, social science,
mathematics and engineering. This type of functions does not have a closed form. It is
very difficult to handle mathematically due to its non-elementary integral form which
cannot be expressed as a finite composition of simple mathematical functions. For this
reason, the development of approximations and tight bounds for the Q -function is
quite significant.
Generally speaking, researchers may use one acceptable approximation to replace the
exact Gaussian integral because that it would take much more time to do the
integration, provided that this approximation function performs well. However,
depending on different conditions, researchers may choose an approximation
according to the actual condition.
According to the Gaussian Q -function application requirements this report provided
approximation selection scheme, and compared several approximations of the
Gaussian Q -function with figures, tables, relative errors, and other aspects. When
designing the entire comparison process, the functional modules of the application are
considered, and the process is finished through MATLAB simulation. The simulation
results in terms of figures and tables, to show the accuracy of approximation functions
are talked in Chapter 3, while the applications of the approximation function, such as
simulation design of BPSK, QAM modulation are talked in Chapter 4. This report
also demonstrated some important codes in Chapter 4. After the simulation part , the
conclusion and recommendation in future work are given. |
| author2 |
Li Kwok Hung |
| author_facet |
Li Kwok Hung Lei, Hao |
| format |
Theses and Dissertations |
| author |
Lei, Hao |
| author_sort |
Lei, Hao |
| title |
Simple and accurate closed-form expressions for Gaussian Q-function |
| title_short |
Simple and accurate closed-form expressions for Gaussian Q-function |
| title_full |
Simple and accurate closed-form expressions for Gaussian Q-function |
| title_fullStr |
Simple and accurate closed-form expressions for Gaussian Q-function |
| title_full_unstemmed |
Simple and accurate closed-form expressions for Gaussian Q-function |
| title_sort |
simple and accurate closed-form expressions for gaussian q-function |
| publishDate |
2018 |
| url |
http://hdl.handle.net/10356/76024 |
| _version_ |
1772828034285436928 |