An improved pixel-based water vapor tomography model

Yao, Yibin; Xin, Linyang; Zhao, Qingzhi

doi:https://doi.org/10.5194/angeo-37-89-2019

Articles | Volume 37, issue 1

https://doi.org/10.5194/angeo-37-89-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Special issue:

Advanced Global Navigation Satellite Systems tropospheric...

https://doi.org/10.5194/angeo-37-89-2019

© Author(s) 2019. This work is distributed under
the Creative Commons Attribution 4.0 License.

Articles | Volume 37, issue 1

Regular paper

|

01 Feb 2019

Regular paper |

| 01 Feb 2019

An improved pixel-based water vapor tomography model

Yibin Yao, Linyang Xin, and Qingzhi Zhao

Viewed

Total article views: 2,368 (including HTML, PDF, and XML)

HTML	PDF	XML	Total	BibTeX	EndNote
1,657	659	52	2,368	58	61

HTML: 1,657
PDF: 659
XML: 52
Total: 2,368
BibTeX: 58
EndNote: 61

Views and downloads (calculated since 23 May 2018)

Month	HTML	PDF	XML	Total
May 2018	98	8	2	108
Jun 2018	157	13	1	171
Jul 2018	52	17	1	70
Aug 2018	27	12	2	41
Sep 2018	26	12	0	38
Oct 2018	15	1	0	16
Nov 2018	20	6	1	27
Dec 2018	13	8	0	21
Jan 2019	15	6	0	21
Feb 2019	204	27	1	232
Mar 2019	69	22	3	94
Apr 2019	27	10	1	38
May 2019	26	16	1	43
Jun 2019	19	12	0	31
Jul 2019	10	3	0	13
Aug 2019	8	12	2	22
Sep 2019	15	5	0	20
Oct 2019	43	11	1	55
Nov 2019	12	8	0	20
Dec 2019	26	9	0	35
Jan 2020	19	7	0	26
Feb 2020	18	6	0	24
Mar 2020	12	12	0	24
Apr 2020	8	10	0	18
May 2020	36	5	1	42
Jun 2020	20	11	0	31
Jul 2020	22	15	3	40
Aug 2020	18	8	2	28
Sep 2020	17	7	0	24
Oct 2020	14	11	2	27
Nov 2020	11	11	0	22
Dec 2020	15	12	0	27
Jan 2021	17	14	0	31
Feb 2021	8	6	0	14
Mar 2021	16	8	0	24
Apr 2021	12	11	1	24
May 2021	11	8	0	19
Jun 2021	5	7	0	12
Jul 2021	10	18	1	29
Aug 2021	6	12	0	18
Sep 2021	11	10	0	21
Oct 2021	5	25	0	30
Nov 2021	16	13	0	29
Dec 2021	12	11	2	25
Jan 2022	16	10	0	26
Feb 2022	14	7	1	22
Mar 2022	9	7	0	16
Apr 2022	10	5	1	16
May 2022	11	6	0	17
Jun 2022	14	5	2	21
Jul 2022	10	4	0	14
Aug 2022	18	10	0	28
Sep 2022	24	3	0	27
Oct 2022	39	4	1	44
Nov 2022	15	14	1	30
Dec 2022	16	5	1	22
Jan 2023	18	7	0	25
Feb 2023	19	6	1	26
Mar 2023	22	8	0	30
Apr 2023	16	6	1	23
May 2023	17	12	4	33
Jun 2023	18	5	0	23
Jul 2023	21	4	1	26
Aug 2023	22	6	1	29
Sep 2023	17	6	2	25
Oct 2023	17	5	0	22
Nov 2023	10	5	1	16
Dec 2023	17	7	3	27
Jan 2024	10	3	0	13
Feb 2024	3	6	0	9
Mar 2024	7	12	1	20
Apr 2024	6	5	2	13

Cumulative views and downloads (calculated since 23 May 2018)

Month	HTML	PDF	XML	Total
May 2018	98	8	2	108
Jun 2018	157	13	1	171
Jul 2018	52	17	1	70
Aug 2018	27	12	2	41
Sep 2018	26	12	0	38
Oct 2018	15	1	0	16
Nov 2018	20	6	1	27
Dec 2018	13	8	0	21
Jan 2019	15	6	0	21
Feb 2019	204	27	1	232
Mar 2019	69	22	3	94
Apr 2019	27	10	1	38
May 2019	26	16	1	43
Jun 2019	19	12	0	31
Jul 2019	10	3	0	13
Aug 2019	8	12	2	22
Sep 2019	15	5	0	20
Oct 2019	43	11	1	55
Nov 2019	12	8	0	20
Dec 2019	26	9	0	35
Jan 2020	19	7	0	26
Feb 2020	18	6	0	24
Mar 2020	12	12	0	24
Apr 2020	8	10	0	18
May 2020	36	5	1	42
Jun 2020	20	11	0	31
Jul 2020	22	15	3	40
Aug 2020	18	8	2	28
Sep 2020	17	7	0	24
Oct 2020	14	11	2	27
Nov 2020	11	11	0	22
Dec 2020	15	12	0	27
Jan 2021	17	14	0	31
Feb 2021	8	6	0	14
Mar 2021	16	8	0	24
Apr 2021	12	11	1	24
May 2021	11	8	0	19
Jun 2021	5	7	0	12
Jul 2021	10	18	1	29
Aug 2021	6	12	0	18
Sep 2021	11	10	0	21
Oct 2021	5	25	0	30
Nov 2021	16	13	0	29
Dec 2021	12	11	2	25
Jan 2022	16	10	0	26
Feb 2022	14	7	1	22
Mar 2022	9	7	0	16
Apr 2022	10	5	1	16
May 2022	11	6	0	17
Jun 2022	14	5	2	21
Jul 2022	10	4	0	14
Aug 2022	18	10	0	28
Sep 2022	24	3	0	27
Oct 2022	39	4	1	44
Nov 2022	15	14	1	30
Dec 2022	16	5	1	22
Jan 2023	18	7	0	25
Feb 2023	19	6	1	26
Mar 2023	22	8	0	30
Apr 2023	16	6	1	23
May 2023	17	12	4	33
Jun 2023	18	5	0	23
Jul 2023	21	4	1	26
Aug 2023	22	6	1	29
Sep 2023	17	6	2	25
Oct 2023	17	5	0	22
Nov 2023	10	5	1	16
Dec 2023	17	7	3	27
Jan 2024	10	3	0	13
Feb 2024	3	6	0	9
Mar 2024	7	12	1	20
Apr 2024	6	5	2	13

Viewed (geographical distribution)

Total article views: 2,368 (including HTML, PDF, and XML) Thereof 2,138 with geography defined and 230 with unknown origin.

Country	#	Views	%

1

1

Cited

Latest update: 22 Apr 2024

Short summary

In this paper, we propose an improved pixel-based water vapor tomography model, which uses layered optimal polynomial functions by adaptive training for water vapor retrieval. Under different scenarios, tomography results show that the new model outperforms the traditional one by reducing the root-mean-square error (RMSE), and this improvement is more pronounced, at 5.88 % in voxels without the penetration of GNSS rays. The improved model also has advantages in more convenient expression.

An improved pixel-based water vapor tomography model

Viewed

Viewed (geographical distribution)

Cited

7 citations as recorded by crossref.

6 citations as recorded by crossref.

1 citations as recorded by crossref.


Total:	0
HTML:	0
PDF:	0
XML:	0


Total:	0
HTML:	0
PDF:	0
XML:	0


Total:	0
HTML:	0
PDF:	0
XML:	0