Differences in optical properties of fruit tissues between stone fruits and citrus fruits

• Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through...
Ausführliche Beschreibung

Gespeichert in:

Autor*in:	Wang, Guantian [verfasserIn] Liu, Yande Li, Xiong Zhang, Yu Wang, Jungang Jiang, Xiaogang

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2021transfer abstract

Schlagwörter:	Citrus fruits Soluble solids content Diffuse reflection Optical properties Stone fruits Fruit tissue

Übergeordnetes Werk:	Enthalten in: 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia - da Silva Costa, Fabricio ELSEVIER, 2014, an international research journal, Amsterdam [u.a.]
Übergeordnetes Werk:	volume:112 ; year:2021 ; pages:0

Links:	Volltext

DOI / URN:	10.1016/j.infrared.2020.103599

Katalog-ID:	ELV052758222

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520			\|a • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light.
520			\|a • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light.
650		7	\|a Citrus fruits \|2 Elsevier
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650		7	\|a Diffuse reflection \|2 Elsevier
650		7	\|a Optical properties \|2 Elsevier
650		7	\|a Stone fruits \|2 Elsevier
650		7	\|a Fruit tissue \|2 Elsevier
700	1		\|a Liu, Yande \|4 oth
700	1		\|a Li, Xiong \|4 oth
700	1		\|a Zhang, Yu \|4 oth
700	1		\|a Wang, Jungang \|4 oth
700	1		\|a Jiang, Xiaogang \|4 oth
773	0	8	\|i Enthalten in \|n Elsevier Science \|a da Silva Costa, Fabricio ELSEVIER \|t 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia \|d 2014 \|d an international research journal \|g Amsterdam [u.a.] \|w (DE-627)ELV012544043
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author_variant	g w gw
matchkey_str	wangguantianliuyandelixiongzhangyuwangju:2021----:ifrneiotclrprisfritsusewesoe
hierarchy_sort_str	2021transfer abstract
publishDate	2021
allfields	10.1016/j.infrared.2020.103599 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000001272.pica (DE-627)ELV052758222 (ELSEVIER)S1350-4495(20)30647-2 DE-627 ger DE-627 rakwb eng 610 VZ 570 VZ BIODIV DE-30 fid Wang, Guantian verfasserin aut Differences in optical properties of fruit tissues between stone fruits and citrus fruits 2021transfer abstract nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue Elsevier Liu, Yande oth Li, Xiong oth Zhang, Yu oth Wang, Jungang oth Jiang, Xiaogang oth Enthalten in Elsevier Science da Silva Costa, Fabricio ELSEVIER 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia 2014 an international research journal Amsterdam [u.a.] (DE-627)ELV012544043 volume:112 year:2021 pages:0 https://doi.org/10.1016/j.infrared.2020.103599 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U FID-BIODIV SSG-OLC-PHA GBV_ILN_22 GBV_ILN_176 GBV_ILN_285 GBV_ILN_2003 GBV_ILN_2016 GBV_ILN_2563 AR 112 2021 0
spelling	10.1016/j.infrared.2020.103599 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000001272.pica (DE-627)ELV052758222 (ELSEVIER)S1350-4495(20)30647-2 DE-627 ger DE-627 rakwb eng 610 VZ 570 VZ BIODIV DE-30 fid Wang, Guantian verfasserin aut Differences in optical properties of fruit tissues between stone fruits and citrus fruits 2021transfer abstract nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue Elsevier Liu, Yande oth Li, Xiong oth Zhang, Yu oth Wang, Jungang oth Jiang, Xiaogang oth Enthalten in Elsevier Science da Silva Costa, Fabricio ELSEVIER 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia 2014 an international research journal Amsterdam [u.a.] (DE-627)ELV012544043 volume:112 year:2021 pages:0 https://doi.org/10.1016/j.infrared.2020.103599 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U FID-BIODIV SSG-OLC-PHA GBV_ILN_22 GBV_ILN_176 GBV_ILN_285 GBV_ILN_2003 GBV_ILN_2016 GBV_ILN_2563 AR 112 2021 0
allfields_unstemmed	10.1016/j.infrared.2020.103599 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000001272.pica (DE-627)ELV052758222 (ELSEVIER)S1350-4495(20)30647-2 DE-627 ger DE-627 rakwb eng 610 VZ 570 VZ BIODIV DE-30 fid Wang, Guantian verfasserin aut Differences in optical properties of fruit tissues between stone fruits and citrus fruits 2021transfer abstract nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue Elsevier Liu, Yande oth Li, Xiong oth Zhang, Yu oth Wang, Jungang oth Jiang, Xiaogang oth Enthalten in Elsevier Science da Silva Costa, Fabricio ELSEVIER 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia 2014 an international research journal Amsterdam [u.a.] (DE-627)ELV012544043 volume:112 year:2021 pages:0 https://doi.org/10.1016/j.infrared.2020.103599 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U FID-BIODIV SSG-OLC-PHA GBV_ILN_22 GBV_ILN_176 GBV_ILN_285 GBV_ILN_2003 GBV_ILN_2016 GBV_ILN_2563 AR 112 2021 0
allfieldsGer	10.1016/j.infrared.2020.103599 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000001272.pica (DE-627)ELV052758222 (ELSEVIER)S1350-4495(20)30647-2 DE-627 ger DE-627 rakwb eng 610 VZ 570 VZ BIODIV DE-30 fid Wang, Guantian verfasserin aut Differences in optical properties of fruit tissues between stone fruits and citrus fruits 2021transfer abstract nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue Elsevier Liu, Yande oth Li, Xiong oth Zhang, Yu oth Wang, Jungang oth Jiang, Xiaogang oth Enthalten in Elsevier Science da Silva Costa, Fabricio ELSEVIER 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia 2014 an international research journal Amsterdam [u.a.] (DE-627)ELV012544043 volume:112 year:2021 pages:0 https://doi.org/10.1016/j.infrared.2020.103599 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U FID-BIODIV SSG-OLC-PHA GBV_ILN_22 GBV_ILN_176 GBV_ILN_285 GBV_ILN_2003 GBV_ILN_2016 GBV_ILN_2563 AR 112 2021 0
allfieldsSound	10.1016/j.infrared.2020.103599 doi /cbs_pica/cbs_olc/import_discovery/elsevier/einzuspielen/GBV00000000001272.pica (DE-627)ELV052758222 (ELSEVIER)S1350-4495(20)30647-2 DE-627 ger DE-627 rakwb eng 610 VZ 570 VZ BIODIV DE-30 fid Wang, Guantian verfasserin aut Differences in optical properties of fruit tissues between stone fruits and citrus fruits 2021transfer abstract nicht spezifiziert zzz rdacontent nicht spezifiziert z rdamedia nicht spezifiziert zu rdacarrier • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. • Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light. Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue Elsevier Liu, Yande oth Li, Xiong oth Zhang, Yu oth Wang, Jungang oth Jiang, Xiaogang oth Enthalten in Elsevier Science da Silva Costa, Fabricio ELSEVIER 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia 2014 an international research journal Amsterdam [u.a.] (DE-627)ELV012544043 volume:112 year:2021 pages:0 https://doi.org/10.1016/j.infrared.2020.103599 Volltext GBV_USEFLAG_U GBV_ELV SYSFLAG_U FID-BIODIV SSG-OLC-PHA GBV_ILN_22 GBV_ILN_176 GBV_ILN_285 GBV_ILN_2003 GBV_ILN_2016 GBV_ILN_2563 AR 112 2021 0
language	English
source	Enthalten in 274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia Amsterdam [u.a.] volume:112 year:2021 pages:0
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container_title	274: Low-dose aspirin improves trophoblastic function in early-onset pre-eclampsia
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The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">• Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. 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author	Wang, Guantian
spellingShingle	Wang, Guantian ddc 610 ddc 570 fid BIODIV Elsevier Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue Differences in optical properties of fruit tissues between stone fruits and citrus fruits
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topic_title	610 VZ 570 VZ BIODIV DE-30 fid Differences in optical properties of fruit tissues between stone fruits and citrus fruits Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue Elsevier
topic	ddc 610 ddc 570 fid BIODIV Elsevier Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue
topic_unstemmed	ddc 610 ddc 570 fid BIODIV Elsevier Citrus fruits Elsevier Soluble solids content Elsevier Diffuse reflection Elsevier Optical properties Elsevier Stone fruits Elsevier Fruit tissue
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title	Differences in optical properties of fruit tissues between stone fruits and citrus fruits
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title_full	Differences in optical properties of fruit tissues between stone fruits and citrus fruits
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title_sort	differences in optical properties of fruit tissues between stone fruits and citrus fruits
title_auth	Differences in optical properties of fruit tissues between stone fruits and citrus fruits
abstract	• Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light.
abstractGer	• Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light.
abstract_unstemmed	• Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light.
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title_short	Differences in optical properties of fruit tissues between stone fruits and citrus fruits
url	https://doi.org/10.1016/j.infrared.2020.103599
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author2	Liu, Yande Li, Xiong Zhang, Yu Wang, Jungang Jiang, Xiaogang
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up_date	2024-07-06T17:04:13.776Z
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The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. Therefore, we can confirm that under the same detection device, when the light passes through the two kinds of fruits, peach reflects more light. • A comparison of the spectra before and after pit removal shows that the spectral energies after pit removal are lower than before pit removal. The smaller the diameter of the peach, the greater the energy difference in the spectrum before and after kernel removal. This means that peach kernels have a scattering effect on transmitted light.</subfield></datafield><datafield tag="520" ind1=" " ind2=" "><subfield code="a">• Navel oranges are citrus fruits. The cores are mostly grains and small, concentrated in the center of the fruit. Peaches belong to the category of stone fruits, with a single core and a large core located in the center of the fruit. During the spectrum detection process, when light passes through the pulp, the impact of the core on the light is usually not negligible. • In the range of 600–900 nm, the diffuse reflectance spectrum energy of peach is about twice as strong as that of navel orange, and the energy at its wave peak changes obviously. It may be because there is a large pit in the center of the peach, which reflects part of the light and strengthens the intensity of the diffuse reflection spectrum. The navel orange is citrus fruits with no or small grains inside, which does not affect the light path. • The more light is reflected into the fruit tissue, the more information will be obtained for the diffuse reflection mode, and the prediction accuracy of the established model will be more accurate. The experimental results show that the SSC model's prediction accuracy and the accuracy of SSC online sorting of peach are higher than that of the navel orange. 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