Novel Signal Separation Principle Based on DFT with Extended Frame Fourier Analysis

Noriyoshi KUROYANAGI; Lili GUO; Naoki SUEHIRO

IEICE TRANSACTIONS on Communications

Novel Signal Separation Principle Based on DFT with Extended Frame Fourier Analysis

Noriyoshi KUROYANAGI, Lili GUO, Naoki SUEHIRO

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In general, a time-limited signal such as a single sinusoidal waveform framed by a frame period T can be utilized for conveying a multi-level symbol in data transmission. If such a signal is analyzed by the conventional DFT (Discrete Fourier Transform) analysis, the infinite number of frequency components with frequency spacing f_D = T¹ is needed. This limits the accuracy with which the original frequency of the unframed sinusoidal waverform can be identified. It is especially difficult to identify two similar framed sinusoids whose frequency spacing is narrower than f_D. An analytical principle for time-limited signals is therefore proposed by introducing the concept of an Extended Frame into DFT. Waveform analysis more accurate than DFT is achieved by taking into account multiple correlations between extended frames made of an input frame signal and the element frequency components corresponding to the length of each extended frame. In this approach, it is possible to use arbitrary element frequency spacing less than f_D. It also allows an element frequency to be selected as a real number times of f_D, rather than as an integer times of f_D that is used for DFT. With this analyzing mechanism, it is verified that an input frame signal with only the frequency components which coincide with any of the element frequencies can be exactly analyzed. The disturbance caused by the input white noise is examined. As a result, it is found that the superior noise suppression function is achieved by this method over a conventional matched filter. In addition, the error caused by using a finite number of element frequencies and the A/D conversion accuracy required for sampling an input signal are examined, and it is shown that these factors need not impede practical implementation. For this reason, this principle is useful for multi-ary transmission systems, noise tolerant receivers, or systems requiring precise filtering of time limited waveforms.

Publication: IEICE TRANSACTIONS on Communications Vol.E79-B No.2 pp.182-190

Publication Date: 1996/02/25

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Type of Manuscript: PAPER

Category: Communication Theory

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Noriyoshi KUROYANAGI, Lili GUO, Naoki SUEHIRO, "Novel Signal Separation Principle Based on DFT with Extended Frame Fourier Analysis" in IEICE TRANSACTIONS on Communications, vol. E79-B, no. 2, pp. 182-190, February 1996, doi: .
Abstract: In general, a time-limited signal such as a single sinusoidal waveform framed by a frame period T can be utilized for conveying a multi-level symbol in data transmission. If such a signal is analyzed by the conventional DFT (Discrete Fourier Transform) analysis, the infinite number of frequency components with frequency spacing f_D = T¹ is needed. This limits the accuracy with which the original frequency of the unframed sinusoidal waverform can be identified. It is especially difficult to identify two similar framed sinusoids whose frequency spacing is narrower than f_D. An analytical principle for time-limited signals is therefore proposed by introducing the concept of an Extended Frame into DFT. Waveform analysis more accurate than DFT is achieved by taking into account multiple correlations between extended frames made of an input frame signal and the element frequency components corresponding to the length of each extended frame. In this approach, it is possible to use arbitrary element frequency spacing less than f_D. It also allows an element frequency to be selected as a real number times of f_D, rather than as an integer times of f_D that is used for DFT. With this analyzing mechanism, it is verified that an input frame signal with only the frequency components which coincide with any of the element frequencies can be exactly analyzed. The disturbance caused by the input white noise is examined. As a result, it is found that the superior noise suppression function is achieved by this method over a conventional matched filter. In addition, the error caused by using a finite number of element frequencies and the A/D conversion accuracy required for sampling an input signal are examined, and it is shown that these factors need not impede practical implementation. For this reason, this principle is useful for multi-ary transmission systems, noise tolerant receivers, or systems requiring precise filtering of time limited waveforms.
URL: https://global.ieice.org/en_transactions/communications/10.1587/e79-b_2_182/_p

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@ARTICLE{e79-b_2_182,
author={Noriyoshi KUROYANAGI, Lili GUO, Naoki SUEHIRO, },
journal={IEICE TRANSACTIONS on Communications},
title={Novel Signal Separation Principle Based on DFT with Extended Frame Fourier Analysis},
year={1996},
volume={E79-B},
number={2},
pages={182-190},
abstract={In general, a time-limited signal such as a single sinusoidal waveform framed by a frame period T can be utilized for conveying a multi-level symbol in data transmission. If such a signal is analyzed by the conventional DFT (Discrete Fourier Transform) analysis, the infinite number of frequency components with frequency spacing f_D = T¹ is needed. This limits the accuracy with which the original frequency of the unframed sinusoidal waverform can be identified. It is especially difficult to identify two similar framed sinusoids whose frequency spacing is narrower than f_D. An analytical principle for time-limited signals is therefore proposed by introducing the concept of an Extended Frame into DFT. Waveform analysis more accurate than DFT is achieved by taking into account multiple correlations between extended frames made of an input frame signal and the element frequency components corresponding to the length of each extended frame. In this approach, it is possible to use arbitrary element frequency spacing less than f_D. It also allows an element frequency to be selected as a real number times of f_D, rather than as an integer times of f_D that is used for DFT. With this analyzing mechanism, it is verified that an input frame signal with only the frequency components which coincide with any of the element frequencies can be exactly analyzed. The disturbance caused by the input white noise is examined. As a result, it is found that the superior noise suppression function is achieved by this method over a conventional matched filter. In addition, the error caused by using a finite number of element frequencies and the A/D conversion accuracy required for sampling an input signal are examined, and it is shown that these factors need not impede practical implementation. For this reason, this principle is useful for multi-ary transmission systems, noise tolerant receivers, or systems requiring precise filtering of time limited waveforms.},
keywords={},
doi={},
ISSN={},
month={February},}

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TY - JOUR
TI - Novel Signal Separation Principle Based on DFT with Extended Frame Fourier Analysis
T2 - IEICE TRANSACTIONS on Communications
SP - 182
EP - 190
AU - Noriyoshi KUROYANAGI
AU - Lili GUO
AU - Naoki SUEHIRO
PY - 1996
DO -
JO - IEICE TRANSACTIONS on Communications
SN -
VL - E79-B
IS - 2
JA - IEICE TRANSACTIONS on Communications
Y1 - February 1996
AB - In general, a time-limited signal such as a single sinusoidal waveform framed by a frame period T can be utilized for conveying a multi-level symbol in data transmission. If such a signal is analyzed by the conventional DFT (Discrete Fourier Transform) analysis, the infinite number of frequency components with frequency spacing f_D = T¹ is needed. This limits the accuracy with which the original frequency of the unframed sinusoidal waverform can be identified. It is especially difficult to identify two similar framed sinusoids whose frequency spacing is narrower than f_D. An analytical principle for time-limited signals is therefore proposed by introducing the concept of an Extended Frame into DFT. Waveform analysis more accurate than DFT is achieved by taking into account multiple correlations between extended frames made of an input frame signal and the element frequency components corresponding to the length of each extended frame. In this approach, it is possible to use arbitrary element frequency spacing less than f_D. It also allows an element frequency to be selected as a real number times of f_D, rather than as an integer times of f_D that is used for DFT. With this analyzing mechanism, it is verified that an input frame signal with only the frequency components which coincide with any of the element frequencies can be exactly analyzed. The disturbance caused by the input white noise is examined. As a result, it is found that the superior noise suppression function is achieved by this method over a conventional matched filter. In addition, the error caused by using a finite number of element frequencies and the A/D conversion accuracy required for sampling an input signal are examined, and it is shown that these factors need not impede practical implementation. For this reason, this principle is useful for multi-ary transmission systems, noise tolerant receivers, or systems requiring precise filtering of time limited waveforms.
ER -

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Novel Signal Separation Principle Based on DFT with Extended Frame Fourier Analysis

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Novel Signal Separation Principle Based on DFT with Extended Frame Fourier Analysis

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